外文翻译-齿轮机构

Gears are vital factors in machinery. One of the first mechanism invented using gears was the clocks. In fact, a clock is little more than a train of study and research have been made on gears in recent years because of their wide use under exacting conditions. They have to transmit heavier loads and run at higher speeds than ever before. The engineers and the machinists all consider gearing the prime elementin nearly all classes of machinery.齿轮在机械中占有极为重要的作用。

第一个利用齿轮做成的机械装置确实是钟表，事实上，它只只是是用了一系列的齿轮。

关于它能够在严格的条件下的普遍利用，在齿轮上做了大量的学习和研究。

相较过去，它们此刻必需在更高的速度下传递更重的负荷。

工程师和机械操纵工人都以为齿轮在几乎所有的机械的零件中占有首要的因素。

1. Spur gearsSpur gears are used to transmit power and rotary motion between parallel shafts. The teeth are cut parallel to the axis of the shaft on which the gears are mounted. The smaller of two gears in mesh is called the pinion and the larger is customarily Designated as the gear. In most applications, the pinion is the driving element whereas the gear is the driven element.1.直齿圆柱齿轮直齿圆柱齿轮用于平行轴之间传递力和回转运动，轮齿被切制成与安装齿轮的轴之轴线相平行。

一．齿轮gear行星齿轮planetary gear/planet gear/epicyclic gear小齿轮pinion大齿轮wheel/gear主动齿轮driving gear从动齿轮driven gear太阳轮sun gear直齿轮spur gear斜齿轮helical gear锥齿轮bevel gear外齿轮external gear齿轮internal gear外直齿轮external spur gear直齿轮internal spur gear圆柱齿轮cylindrical gear螺旋锥齿轮sprial bevel gear直齿锥齿轮straight bevel gear斜齿锥齿轮helical bevel gear弧齿锥齿轮spiral bevel gear圆柱齿弧锥齿轮sprial bevel gear with circle arc tooth profile 8字啮合锥齿轮octoid gear锥齿轮当量圆柱齿轮virtual cylindrical gear of bevel gear曲面齿锥齿轮curved tooth bevel gear摆线齿锥齿轮enicycloid bevel gear零度锥齿齿轮zerot bevel gear冠轮crown gear链轮sprocket人字齿轮double helical gear配对齿轮/啮合齿轮mating gear端面齿轮contrate gear准双曲面齿轮hypoid gear椭圆齿轮elliptical gear非圆齿轮non-circular gear变位齿轮X-gears/gears with addendum modification 非变位齿轮X-gero gear标准齿轮standard gear产形齿轮generating gear渐开线齿轮involute cylindrical gear针轮cylindsical tan tein gear/pin-wheel柔性齿轮flexspine刚性齿轮circular spline摆线齿轮cycloidal gear圆弧齿轮circular-arc gear/W-N gear双圆弧齿轮double-circular-arc gear皮带轮belt wheel减速器齿轮speed reducer gear减速箱positive speed gearbox前末端齿轮front terminal end gear双齿轮double gear人字齿轮、双螺旋齿轮herring bone gear输出轴（取力器）power take off shaft角磨机angle grinder蜗轮worm wheel蜗杆worm锥蜗轮spiroid gear锥蜗杆spiroid锥蜗轮蜗杆spiroid gear pair锥蜗杆spiroid平面蜗杆planar worm wheel; IP-worm wheel 圆柱蜗杆cylindrical worm环面蜗杆enveloping worm圆弧圆柱蜗杆ZC-worm锥面包络圆柱蜗杆ZK-worm法向直廓蜗杆ZN-worm平面包络环面蜗轮planar double锥面包络环面蜗杆TK-worm wheel渐开线包络环面蜗杆TI-worm平面二次包络蜗杆TP-worm变速箱transmission轴和套shaft and sleeve二．渐开线involute 花键spline渐开线外花键external involute spline渐开线花键internal involute spline渐开线公差involute tolerance花键齿节距spline pitch(花键)外径/大径major diameter(花键)径/小径minor diameter成形直径form diameter花键类型：a. flat root,side fit 平根，齿侧配合b. fillet root,side fit 齿根圆角，齿侧配合Product series:Spur gear, bevel gear, spiral bevel gear, internal gear, sprocket, transmission, reducer, shaft and sleeve etc.(直齿轮，斜齿轮，伞齿轮，螺旋伞齿轮，齿轮，链轮，变速箱，减速箱，轴类，套类)30/40 型刮板运输机：type 30/40 scraper conveyor取力器前后壳：power take before and after the shell花键轴：spline shaft变速箱取力器总成及配件：transmission power take off assembly and accessories秸秆粉碎机齿轮：straw grinder gear (straw crusher)旋耕机：rotary拖拉机：tractor前驱动桥：front drive axle拖拉机前驱动桥总成及配件：tractor front drive axle assembly and parts玉米联合收割机: corn combine harvester割台箱：box header玉米联合收获机割台箱总成及配件：corn combine harvester header box assembly and parts.斯太尔汽车：Steyr automobile中桥：vehicle bridge驱动桥：driving axle后桥：rear axle齿轮加工，滚齿，磨齿，剃齿，插齿：gear machining, hobbing, grinding teeth, shaving, slotting农机厂：agricultural machinery plant矿山机械厂：mining machinery factory弧齿锥齿轮铣齿机，滚齿机，磨齿机，剃齿机，数控车床，精密磨床，花键磨床，平面磨床，卧式拉床等：sprial bevel gear milling machine, hobbing machine, grinding machine, gear shaving machine, CNC lathes, precision grinding, spline grinding machine, surface grinder, horizontal broaching machine and so on.Numerical control lathes 数控车床Black oxide 黑氧化Sprial bevel gear axle螺旋伞齿轮轴三．常见其他词汇齿数number of teeth/teeth guantity 当量齿数virtual number of teeth头数number of starts/threads齿顶crest/top land比率ratio齿圈ring gear螺纹thread螺纹孔tapped holes毛边，毛刺burr心轴arbor齿条rack基本齿条basic rack产形齿条counterpart rack直齿条spur rack斜齿条helical rack基本齿条类型basic rack type (heel end 末端) 轴承bearing半轴half-axle离合器clutch刀片blade毛坯blank卡盘chuck圈lap刀盘cutter切齿干涉cutter reference刀具半径cutter radius刀刃圆角半径cutter edge radius传感器sensor大端接触heel pattern与成对轮齿大端接触heel pattern with the pair gear tooth 齿锥度tooth taper打字joined tooth gear lettering中凸齿barrel-shaped teeth四．关联词汇基圆base circle基圆直径base diameter基节base pitch基圆半径base radius节圆pitch circle节圆直径pitch diameter 径节diametral pitch 节线pitch line节线跳动pitchline runout分度圆reference circle分度圆直径reference diameter根圆root circle根圆直径root diameter顶圆tip circle顶圆直径tip diameter顶隙圆clearance circle周节circular pitch外径outside diameter齿根圆dedendum circle齿根直径root diameter齿根圆角半径(过滤圆角半径) fillet radius背锥back cone面锥face cone节锥pitch cone根锥root cone分锥reference cone分锥顶点reference cone apex齿顶高addendum齿根高dedendum全齿高whole depth齿高tooth depth/height弦齿高chordal height固定弦齿高constant chord height齿宽face width有效齿宽effective width齿厚tooth thickness端面齿厚transerse tooth thickness法向齿厚normal tooth thickness端面基圆齿厚transverse base thickness法向基圆齿厚normal base thickness弦齿厚chordal thickness/arc tooth thickness 端面弦齿厚transverse chordal tooth thickenss 固定弦齿厚constant chord弧齿厚circular thickness前锥面front cone中锥面middle cone背锥面back cone背锥母线backcone element总误差total accumulated spacing error五．角angle背锥角back (cone) angle面锥角face angle节锥角pitch angle根锥角root angle分锥角reference cone angle顶锥角tip angle齿锥角tooth cone angle压力角pressure angle主压力角main pressure angle轴交角shaft angle齿顶角addendum angle齿根角dedendum angle传动轴角transmission axes angle螺旋角spiral angle任意点螺旋角spiral angle at a point重点螺旋角mean spiral angle大端螺旋角outer spiral angle小端螺旋角inner spiral angle齿形角nominal pressure angle倒角chamfer啮合角working pressure angle齿宽角width angle工作压力角pressure angle (operating)齿厚半角tooth thickness half angle槽宽半角space width half angle任意点压力角pressure angle at a point任意点法向压力角normal pressure angle at a point任意点端面压力角transverse pressure angle at a point总作用角total angle of transmission导程角lead angle端面作用角transverse angle of transmission纵向作用角overlap angle轮廓有效位置渐开线绞孔角度the evolvent reaming angle of the profile active site 有效面积渐开线展开轮廓角度the angle developed profile of involute of the active area六．距distance齿距pitch齿距公差pitch tolerance锥距cone distance外锥距outer cone distance锥距inner cone distance锥距inner cone distance重(中)点锥距mean cone distance背锥距back cone distance背角距back angle distance花键齿节距spline pitch中心距centre distance标准中心距reference centre distance实际中心距center distance (operating)位置距offset冠顶距apex to crown轮冠距tip distance/crown to back安装距mounting distance/locating distance 齿端距angular pitch工具头部刀顶距point width of the tool head七．齿面flank齿面tooth flank右侧齿面right flank左侧齿面lefe flank同侧齿面corresponding flank异侧齿面opposite flank上齿面addendum flank下齿面dedendum flank工作齿面working flank非工作齿面non-working flank啮合齿面mating flank共轭齿面conjugate flank可用齿面usable flank有效齿面active flank产形齿面generating flank八．面齿顶面face齿根面flank阿基米德螺旋面screw helicoid球面渐开螺旋面spherical involute 定位面locating face凸面convex side凹面concace face圆环面tosoid齿根圆环面root tosoid分度圆环面reference tosoid圆环面的母圈generant of the tosoid圆环面的中性圈middle circle of the tosoid 圆环面的中间平面middle plane of the tosoid 圆环面的圈inner circle of the tosoid基准平面datum plane轴平面axial plane节平面pitch plane端平面transverse plane法平面normal plane啮合平面plane of action中平面middle plane喉平面gorge plane咽喉面gorge咽喉半径gorge radius喉圆gorge circle齿根过渡曲面fillet啮合曲面surface of action分度曲面reference surface 节曲面pitch surface齿顶曲面tip surface齿根曲面root surface假想曲面imaginary surface 分度圆柱面reference cylinder 节圆柱面pitch cylinder基圆柱面basic cylinder齿顶圆柱面tip cylinder齿根圆柱面root cylinder九．线齿线tooth trace渐开线involute延伸渐开线prolate involute 缩短渐开线curtate involute 球面渐开线spherical involute渐开螺旋线involute helicoid螺旋线helix分度圆涡旋线reference helix圆锥螺旋线conical spiral阿基米德螺旋线archimedes spiral基准线datum line连心线line of centres摆线cycloid长幅摆线prolate cycloid短幅摆线curtate cycloid摆线hypo cycloid外摆线epoi cycloid长幅外摆线prolate epoicycloid长幅摆线prolate hypocycloid短幅外摆线curtate epoicycloid短幅摆线curtate hypocycloid瞬时接触线line of contact端面啮合线transverse path of contact十．啮合啮合齿轮mating gear啮合平面plane of action啮合曲面surface of action相啮齿面mating flank啮合干涉meshing interefence 啮合区域zone of action啮合角working pressure angle十一. PitchPitch 齿距Pitch tolerance 齿距公差Pitch circle 节圆Pitch diameter 节圆直径Pitch line 节线Pitch point 节点Pitch plane 节平面Pitch surface 节曲面Pitch cylinder 节圆柱面Pitch cone 节锥Pitch cone angle 节锥角十二. Tooth/teethTooth type 齿形Tooth trace direction 齿向：a) right-hand teeth 左旋齿b) left –hand teeth 右旋齿tooth crown 齿冠tooth trace 齿线tooth tip 齿棱tooth depth 齿高tooth flank 齿面tooth profile 齿廓tooth space 齿槽tooth guantity 齿数pitch 齿距齿根bottom land十三. 顶公共锥顶common apex十四. 模数模数module端面模数transverse module外端面模数exterior transverse module 法向模数normal module轴向模数axial module平均正常模数average normal modle 十五. 比（率）/重合度齿数比gear ratio传动比transmission ratio总重合度total contact ratio端面重合度transverse ratio纵向重合度overlap ratio精确度accuracy degree修正度degree of correction十六齿廓( profile)齿廓tooth profile齿廓型修profile modification端面齿廓transverse profile法向齿廓normal profile法基本齿廓normal basic rack profile轴向齿廓axial profile背锥齿廓back cone tooth profile基本齿廓basic tooth profile十七. 系数（coefficient）变位系数modification coefficient/shifting coefficient切向变为系数tangential MC齿顶系数、顶隙系数addendum coefficient /bottom clearance coefficient 径向变位系数addendum modification coefficient中心距变位系数centre distance modification coefficient径向间隙系数radial clearance factor头部厚度系数coefficient of head thickness过滤曲线弯曲半径系数factor of radius of curvature of transition curve齿厚变化系数coefficient of tooth thickness change十八. 量（公差/偏差）齿线偏移量offset of tooth trace容许加铅量lead tolerance变位量addendum modification渐开线公差involute tolerance轴距测量极限偏差limit deviations of measuring interaxle distance报废限度bore condemning limit全程中成对轴角测量偏差余量allowance for variation of measuring pair axes angle of one tooth轴向运动测量偏差varation tolerance of the measurement axial movement十九. 隙顶隙(bottom) clearance齿侧背隙backlash周圆侧隙circumferential blacklash法向侧隙normal backlash径向侧隙radial backlash最小侧间隙min side clearance二十. 厚齿厚tooth thickness端面齿厚transverse tooth thickness法向齿厚normal tooth thickness端面齿顶厚crest width法向齿顶厚normal crest width弦齿厚chordal thickness固定弦齿厚constant chord端面弦齿厚transverse chordal tooth thickness弦上齿厚tooth thickness on the chord弧齿厚circular thickness外圆弧齿厚external circular tooth thickness分度圆圆弧上弧齿厚circular tooth thickness on the arc of a reference circle 端面基圆齿厚transverse base thickness法向基圆齿厚normal base thickness二十一. 宽（width）齿宽face width有效齿宽effective facewidth端面齿槽宽transverse space width法向齿槽宽normal space width涡轮齿宽worm wheel facewidth蜗杆齿宽worm facewidth二十二. (交) 点瞬时接触点point of contact轴线交点crossing point of axes二十三. 弧总作用弧total arc of transmission端面作用弧transverse arc of transmission 纵向作用弧overlap arc二十四. 轴瞬时轴instantaneous axis二十五. 半径(radius) & diameter(原始轮廓)过渡曲线弯曲半径radius of curvature of transition curve (original profile) 刀具半径cutter radius刀刃圆角半径cutter edge radius齿轮刀具名义直径gear cutter nominal diameter有效分度圆直径effective reference diameter二十六.长度（length）公法线长度base tangent length二十七.高度（深度）工作高度working depth齿顶高addendum齿根高dedendum弦齿高chordal height固定弦齿高constant chord height全齿高whole depth齿高tooth height到弦的测量高度measuring height up to the chard二十八. 其他修缘tip relief修根root relief齿向修正axial modification齿端修补end relief鼓形修正crowning鼓形齿crowned teeth挖根undercut导程lead最小齿顶高修正min addendum modification凸台boss紧固件fastener加强肋rib垫儿pad凹槽recess 切洞cutout 夹具JIG。

齿轮术语中英文对照表 阿基米德蜗杆 Archimedes worm 安全系数 safety factor; factor of safety 安全载荷 safe load 变形 deformation 摆线齿轮 cycloidal gear 摆线齿形 cycloidal tooth profile 背锥角 back angle 背锥距 back cone distance 比例尺 scale 变速 speed change 变速齿轮 change gear ; change wheel 变位齿轮 modified gear 变位系数 modification coefficient 标准齿轮 standard gear 标准直齿轮 standard spur gear 表面粗糙度 surface roughness 不完全齿轮机构 intermittent gearing 补偿 compensation 参数化设计 parameterization design, PD 残余应力 residual stress 操纵及控制装置 operation control device 槽数 Geneva numerate 侧隙 backlash 差动轮系 differential gear train 差动螺旋机构 differential screw mechanism 差速器 differential常用机构 conventional mechanism; mechanism in common use 齿根圆 dedendum circle 齿厚 tooth thickness 齿距 circular pitch 齿宽 face width 齿廓 tooth profile 齿廓曲线 tooth curve 齿轮 gear 齿轮变速箱 speed-changing gear boxes 齿轮齿条机构 pinion and rack 齿轮插刀 pinion cutter; pinion-shaped shaper cutter 齿轮滚刀 hob ,hobbing cutter 齿轮机构 gear 齿轮轮坯 blank 齿轮传动系 pinion unit 齿轮联轴器 gear coupling 齿条传动 rack gear 齿数 tooth number齿数比 gear ratio齿条 rack承载量系数 bearing capacity factor 承载能力 bearing capacity 成对安装 paired mounting 尺寸系列 dimension series 齿槽 tooth space 齿槽宽 spacewidth 齿侧间隙 backlash 齿顶高 addendum 齿顶圆 addendum circle 齿根高 dedendum 齿根圆 dedendum circle 齿厚 tooth thickness 齿距 circular pitch 齿宽 face width 齿廓 tooth profile 齿廓曲线 tooth curve 齿轮 gear 承载量系数 bearing capacity factor 承载能力 bearing capacity 成对安装 paired mounting 尺寸系列 dimension series 齿槽 tooth space 齿槽宽 spacewidth 齿侧间隙 backlash 齿顶高 addendum 齿顶圆 addendum circle 齿根高 dedendum 根圆 dedendum circle 齿厚 tooth thickness 齿距 circular pitch 齿宽 face width 齿廓 tooth profile 齿廓曲线 tooth curve 齿轮 gear 齿轮变速箱 speed-changing gear boxes 齿轮齿条机构 pinion and rack 齿轮插刀 pinioncutter; pinion-shaped shape 齿轮滚刀 hob ,hobbing cutter 齿轮机构 gear 齿轮轮坯 blank 齿轮传动系 pinion unit 齿轮联轴器 gear coupling 齿条传动 rack gear 齿数 tooth number齿条插刀 rack cutter; rack-shaped shaper cutter 齿形链、无声链 silent chain 齿形系数 form factor 齿式棘轮机构 tooth ratchet mechanism 插齿机 gear shaper 重合点 coincident points 重合度 contact ratio 传动比 transmission ratio, speed ratio 传动装置 gearing; transmission gear 传动系统 driven system 传动角 transmission angle 传动轴 transmission shaft 创新设计 creation design 垂直载荷、法向载荷 normal load 从动带轮 driven pulley 从动件 driven link, follower 从动件平底宽度 width of flat-face 从动件停歇 follower dwell 从动件运动规律 follower motion 从动轮 driven gear 粗线 bold line 粗牙螺纹 coarse thread 大齿轮 gear wheel 打滑 slipping 带传动 belt driving 单列轴承 single row bearing 单位矢量 unit vector 当量齿轮 equivalent spur gear; virtual gear 当量齿数 equivalent teeth number; virtual number of teeth 非接触式密封 non-contact seal 非周期性速度波动 aperiodic speed fluctuation 非圆齿轮 non-circular gear 粉末合金 powder metallurgy 分度线 reference line; standard pitch line 分度圆 reference circle; standard (cutting) pitch circle 分度圆柱导程角 lead angle at reference cylinder 分度圆柱螺旋角 helix angle at reference cylinder 分母 denominator 分子 numerator 分度圆锥 reference cone; standard pitch cone 封闭差动轮系 planetary differential 刚度系数 stiffness coefficient 钢丝软轴 wire soft shaft 根切 undercutting 公称直径 nominal diameter 高度系列 height series 功 work 工况系数 application factor 当量摩擦系数 equivalent coefficient of friction 当量载荷 equivalent load 刀具 cutter 导数 derivative 倒角 chamfer 导程 lead 导程角 lead angle 等效质量 equivalent mass （疲劳）点蚀 pitting 垫圈 gasket 垫片密封 gasket seal 顶隙 bottom clearance 定轴轮系 ordinary gear train; gear train with fixed axes 动力学 dynamics 动密封 kinematical seal 动能 dynamic energy 动力粘度 dynamic viscosity 动力润滑 dynamic lubrication 动载荷 dynamic load 端面 transverse plane 端面参数 transverse parameters 端面齿距 transverse circular pitch 端面齿廓 transverse tooth profile 端面重合度 transverse contact ratio 端面模数 transverse module 端面压力角 transverse pressure angle 锻造 forge 惰轮 idle gear 额定寿命 rating life 额定载荷 load rating 发生线 generating line 发生面 generating plane 法面 normal plane 法面参数 normal parameters 法面齿距 normal circular pitch 法面模数 normal module 法面压力角 normal pressure angle 法向齿距 normal pitch 法向齿廓 normal tooth profile 法向直廓蜗杆 straight sided normal worm 法向力 normal force 反正切 Arctan 干涉 interference 范成法 generating cutting 仿形法 form cutting 非标准齿轮 nonstandard gear 复合应力 combined stress复式螺旋机构 Compound screw mechanism工艺设计 technological design工作循环图working cycle diagram滚刀 hob过度切割 undercutting耗油量 oil consumption耗油量系数oil consumption factor横坐标 abscissa互换性齿轮 interchangeable gears花键 spline滑键、导键 feather key滑动率 sliding ratio环面蜗杆toroid helicoids worm缓冲装置 shocks; shock-absorber机械 machinery机械平衡balance of machinery机械设计machine design; mechanical design机械特性 mechanical behavior计算弯矩calculated bending moment间隙 backlash减速比 reduction ratio减速齿轮、减速装置 reduction gear减速器 speed reducer渐开螺旋面 involute helicoid渐开线 involute渐开线齿廓 involute profile渐开线齿轮 involute gear渐开线发生线generating line of involute渐开线方程 involute equation渐开线函数 involute function渐开线蜗杆 involute worm渐开线压力角pressure angle of involute渐开线花键 involute spline键 key键槽 keyway交变应力 repeated stress交变载荷repeated fluctuating load交叉带传动 cross-belt drive节距circular pitch; pitch of teeth节线 pitch line节圆 pitch circle节圆齿厚thickness on pitch circle节圆直径 pitch diameter节圆锥 pitch cone节圆锥角pitch cone angle解析设计 analytical desig径节 diametral pitch径向 radial direction径向当量动载荷dynamic equivalent radial load 工作机构 operation mechanism工作载荷 external loads工作空间 working space工作应力 working stress工作阻力 effective resistance工作阻力矩effective resistance moment公法线common normal line公制齿轮 metric gears功率 power功能分析设计 function analyses design共轭齿廓 conjugate profiles共轭凸轮 conjugate cam惯性力矩moment of inertia ,shaking moment惯性力平衡balance of shaking force冠轮 crown gear轨迹生成 path generation轨迹发生器 path generator机械调速mechanical speed governors机械效率 mechanical efficiency机械原理theory of machines and mechanisms机械无级变速mechanical stepless speed changes基础机构 fundamental mechanism基本额定寿命basic rating life基于实例设计 case-based design,CBD基圆 base circle基圆半径radius of base circle基圆齿距 base pitch基圆压力角pressure angle of base circle基圆柱 base cylinder基圆锥 base cone极限位置extreme (or limiting) position极位夹角crank angle between extreme (or limiting) positions计算机辅助设计computer aided design, CAD计算机辅助制造computer aided manufacturing, CAM 计算机集成制造系统computer integrated manufacturing system, CIMS计算力矩factored moment; calculation moment交错轴斜齿轮 crossed helical gears胶合 scoring角速度 angular velocity角速比angular velocity ratio结构 structure结构设计 structural design截面 section节点 pitch point紧边 tight-side紧固件 fastener径向当量静载荷 static equivalent radial load 径向基本额定动载荷 basic dynamic radial load rating 径向基本额定静载荷 basic static radial load tating 偏距圆 offset circle 偏心盘 eccentric 切齿深度 depth of cut 曲齿锥齿轮 spiral bevel gear 曲率 curvature 曲率半径 radius of curvature 曲面从动件 curved-shoe follower 曲线运动 curvilinear motion 全齿高 whole depth 权重集 weight sets 球面副 spheric pair 球面渐开线 spherical involute 球面运动 spherical motion 人字齿轮 herringbone gear 润滑装置 lubrication device 润滑 lubrication 三角形花键 serration spline 三角形螺纹 V thread screw 少齿差行星传动 planetary drive with small teeth difference 升程 rise 升距 lift 实际廓线 cam profile 输出轴 output shaft 实际啮合线 actual line of action 双曲面齿轮 hyperboloid gear 顺时针 clockwise 瞬心 instantaneous center 死点 dead point 太阳轮 sun gear 特性 characteristics 图册、图谱 atlas 图解法 graphical method 退火 anneal 陀螺仪 gyroscope 外力 external force 外形尺寸 boundary dimension 网上设计 on-net design, OND 微动螺旋机构 differential screw mechanism 位移 displacement 蜗杆 worm 蜗杆传动机构 worm gearing 蜗杆头数 number of threads 蜗杆直径系数 diametral quotient 蜗杆蜗轮机构 worm and worm gear 蜗杆形凸轮步进机构 worm cam interval mechanism 蜗杆旋向 hands of worm 蜗轮 worm gear 径向接触轴承 radial contact bearing径向平面 radial plane 径向游隙 radial internal clearance 径向载荷 radial load 径向载荷系数 radial load factor 径向间隙 clearance 静力 static force 静平衡 static balance 静载荷 static load 绝对运动 absolute motion 绝对速度 absolute velocity 可靠性 reliability 可靠性设计 reliability design, RD 理论廓线 pitch curve 理论啮合线 theoretical line of action 力矩 moment 力平衡 equilibrium 力偶 couple 力偶矩 moment of couple 轮坯 blank 螺旋副 helical pair 螺旋机构 screw mechanism 螺旋角 helix angle 螺旋线 helix ,helical line 模块化设计 modular design, MD 模数 module 磨损 abrasion ;wear; scratching 耐磨性 wear resistance 内齿轮 internal gear 内齿圈 ring gear 内力 internal force 内圈 inner ring 啮合 engagement, mesh, gearing 啮合点 contact points 啮合角 working pressure angle 啮合线 line of action 啮合线长度 length of line of action 盘形转子 disk-like rotor 抛物线运动 parabolic motion 疲劳极限 fatigue limit 疲劳强度 fatigue strength 偏置式 offset 偏 ( 心 ) 距 offset distance 偏心率 eccentricity ratio 偏心质量 eccentric mass无级变速装置stepless speed changes devices斜齿轮的当量直齿轮equivalent spur gear of the helical gear 心轴 spindle行程速度变化系数coefficient of travel speed variation行程速比系数advance-to return-time ratio行星齿轮装置 planetary transmission行星轮 planet gear行星轮变速装置planetary speed changing devices行星轮系planetary gear train轴 shaft轴承盖 bearing cup轴承合金 bearing alloy轴承座 bearing block轴承外径bearing outside diameter轴颈 journal轴瓦、轴承衬 bearing bush轴端挡圈shaft end ring轴环 shaft collar轴肩 shaft shoulder轴角 shaft angle轴向 axial direction轴向齿廓 axial tooth profile转动副 revolute (turning) pair转速swiveling speed ; rotating speed转轴 revolving shaft转子 rotor装配条件 assembly condition锥齿轮 bevel gear锥顶common apex of cone锥距 cone distance锥轮bevel pulley; bevel wheel锥齿轮的当量直齿轮equivalent spur gear of the bevel gear 锥面包络圆柱蜗杆 milled helicoids worm准双曲面齿轮 hypoid gear自由度degree of freedom, mobility总重合度 total contact ratio总反力 resultant force总效率combined efficiency; overall efficiency组成原理theory of constitution组合齿形composite tooth form组合安装 stack mounting最少齿数minimum teeth number最小向径 minimum radius作用力 applied force坐标系 coordinate frame圆锥滚子轴承tapered roller bearing圆锥齿轮机构 bevel gears圆锥角 cone angle 相对速度 relative velocity 相对运动 relative motion 相对间隙 relative gap象限 quadrant橡皮泥 plasticine小齿轮 pinion小径 minor diameter谐波齿轮 harmonic gear谐波传动 harmonic driving旋转运动 rotary motion压力角 pressure angle应力图 stress diagram应力—应变图 stress-strain diagram 优化设计 optimal design油杯 oil bottle有效圆周力effective circle force圆带传动round belt drive圆弧齿厚 circular thickness圆弧圆柱蜗杆hollow flank worm圆角半径 fillet radius圆盘摩擦离合器disc friction clutch圆盘制动器 disc brake原动机 prime mover原始机构 original mechanism圆形齿轮 circular gear圆柱滚子 cylindrical roller圆柱滚子轴承cylindrical roller bearing 圆柱副 cylindric pair圆柱蜗杆 cylindrical worm圆锥滚子 tapered roller运动副 kinematic pair运动粘度 kenematic viscosity载荷 load展成法 generating直齿圆柱齿轮 spur gear直齿锥齿轮straight bevel gear直径系数 diametral quotient直径系列 diameter series直廓环面蜗杆 hindley worm质量 mass中心距 center distance中心距变动center distance change中径 mean diameter终止啮合点final contact, end of contact 周节 pitch。

(文档含英文原文和中文翻译)中英文资料对照外文翻译Machine Parts (I)GearsGears are direct contact bodies, operating in pairs, that transmit motion and force from one rotating shaft to another or from a shaft to a slide (rack), by means of successively engaging projections called teeth.Tooth profiles. The contacting surfaces of gear teeth must be aligned in such a way that the drive is positive; i.e., the load transmitted must not depend on frictional contact. As shown in the treatment of direct contact bodies, this requires that thecommon normal to the surfaces not to pass through the pivotal axis of either the driver or the follower.As it is known as direct contact bodies, cycloidal and involute profiles profiles provide both a positive drive and a uniform velocity ratio;i.e., conjugate action.Basic relations. The smaller of a gear pair is called the pinion and the larger is the gear. When the pinion is on the driving shaft the pair is called the pinion and the larger is the gear. When the pinion is on the driving shaft the pair acts as a speed reducer; When the gear drives, the pair is a speed incrreaser. Gears are more frequently used to reduce speed than to increase it.If a gear having N teeth rotates at n revolutions per minute, the product N*n has the dimension “teeth per minute”. This product must be the same for both members of a mating pair if each tooth acquires a partner from the mating gear as it passes through the region of tooth engagement.For conjugate gears of all types, the gear ratio and the speed ratio are both given by the ratio of the number of teeth on the gear to the number of teeth on the pinion. If a gear has 100 teeth and a mating pinion has 20, the ratio is 100/20=5. Thus the pinion rotates five times as fast as the gear, regardless of the gear. Their point of tangency is called the pitch point, and since it lies on the line of centers, it is the only point at which the profiles have pure roling contact. Gears on nonparallel, non-intersecting shafts also have pitch circles, but the rolling-pitch –circle concept is not valid.Gear types are determined largely by the disposition of the shafts; in addition, certain types are better suited than others for large speed changes. This means that if a specific disposition of the shafts is required, the type of gear will more or less be fixed. On the other hand, if a required speed change demands a certain type, the shaft positions will also be fixed.Spur gears and helical gears. A gear having tooth elements that are straight and parallel to its axis is known as a spur gear. A spur pair can be used to connect parallel shafts only.If an involute spur pinion were made of rubber and twisted uniformly so that the ends rotated about the axis relative to one another, the elements of the teeth, initially straight and parallel to the axis, would become helices. The pinion then in effect would become a helical gear.Worm and bevel gears. In order to achieve line contact and improve the load carrying capacity of the crossed axis helical gears, the gear can be made to curvepartially around the pinion, in somewhat the same way that a nut envelops a screw. The result would be a cylindrical worm and gear. Worms are also made in the shape of an hourglass, instead of cylindrical, so that they partially envelop the gear. This results in a further increase in load-carrying capacity.Worm gears provide the simplest means of obtaining large ratios in a single pair. They are usually less efficient than parallel-shaft gears, however, because of an additional sliding movement along the teeth.V-beltThe rayon and rubber V-belt are widely used for power transmission. Such belts are made in two series: the standard V-belt and the high capacity V-belt. The belts can be used with short center distances and are made endless so that difficulty with splicing devices is avoided.First, cost is low, and power output may be increased by operating several belts side by side. All belts in the drive should stretch at the same rate in order to keep the load equally divided among them. When one of the belts breaks, the group must usually be replaced. The drive may be inclined at any angle with tight side either top or bottom. Since belts can operate on relatively small pulleys, large reductions of speed in a single drive are possible.Second，the included angle for the belt groove is usually from 34°to 38°.The wedging action of the belt in the groove gives a large increase in the tractive force developed by the belt.Third，pulley may be made of cast iron, sheet steel, or die-cast metal. Sufficient clearance must be provided at the bottom of the groove to prevent the belt from bottoming as it becomes narrower from wear. Sometimes the larger pulley is not grooved when it is possible to develop the required tractive force by running on the inner surface of the belt. The cost of cutting the grooves is thereby eliminated. Pulleys are on the market that permit an adjustment in the width of the groove. The effective pitch diameter of the pulley is thus varied, and moderate changes in the speed ratio can be secured.Chain DrivesThe first chain-driven or “safety” bicycle appeared in 1874, and chains were used for driving the rear wheels on early automobiles. Today, as the result of modern design and production methods, chain drives that are much superior to their prototypes are available, and these have contributed greatly to thedevelopment of efficient agricultural machinery, well-drilling equipment, and mining and construction machinery. Since about 1930 chain drives have become increasingly popular, especially for power saws, motorcycle, and escalators etc.There are at least six types of power-transmission chains; three of these will be covered in this article, namely the roller chain, the inverted tooth, or silent chain, and the bead chain. The essential elements in a roller-chain drive are a chain with side plates, pins, bushings (sleeves), and rollers, and two or more sprocket wheels with teeth that look like gear teeth. Roller chains are assembled from pin links and roller links. A pin link consists of two side plates connected by two pins inserted into holes in the side plates. The pins fit tightly into the holes, forming what is known as a press fit. A roller link consists of two side plates connected by two press-fitted bushings, on which two hardened steel rollers are free to rotate. When assembled, the pins are a free fit in the bushings and rotate slightly, relative to the bushings when the chain goes on and leaves a sprocket.Standard roller chains are available in single strands or in multiple strands, In the latter type, two or more chains are joined by common pins that keep the rollers in the separate strands in proper alignment. The speed ratio for a single drive should be limited to about 10∶1; the preferred shaft center distance is from 30 to 35 times the distance between the rollers and chain speeds greater than about 2500 feet (800 meters) per minute are not recommended. Where several parallel shafts are to be driven without slip from a single shaft, roller chains are particularly well suited.An inverted tooth, or silent chain is essentially an assemblage of gear racks, each with two teeth, pivotally connected to form a closed chain with the teeth on the inside, and meshing with conjugate teeth on the sprocket wheels. The links are pin-connected flat steel plates usually having straight-sided teeth with an included angle of 60 degrees. As many links are necessary to transmit the power and are connected side by side. Compared with roller-chain drives, silent-chain drives are quieter, operate successfully at higher speeds, and can transmit more load for the same width. Some automobiles have silent-chain camshaft drives.Bead chains provide an inexpensive and versatile means for connecting parallel or nonparallel shafts when the speed and power transmitted are low. The sprocket wheels contain hemispherical or conical recesses into which the beads fit. The chains look like key chains and are available in plain carbon and stainless steel and also in the form of solid plastic beads molded on a cord. Bead chains are used oncomputers, air conditioners, television tuners, and Venetian blinds. The sprockets may be steel, die-cast zinc or aluminum, or molded nylon.Machine Parts (II)FastenerFasteners are devices which permit one part to be joined to a second part and, hence, they are involved in almost all designs.There are three main classifications of fasteners, which are described as follows：(1) Removable. This type permits the parts to be readily disconnected without damaging the fastener. An example is the ordinary nut-and-bolt fastener.(2) Semi permanent. For this type, the parts can be disconnected, but some damage usually occurs to the fastener. One such example is a cotter pin.(3) Permanent. When this type of fastener is used, it is intended that the parts will never be disassembled. Examples are riveted joints and welded joints.The importance of fasteners can be realized when referring to any complex product. In the case of the automobile, there are literally thousands of parts which are fastened together to produce the total product. The failure or loosening of a single fastener could result in a simple nuisance such as a door rattle or in a serious situation such as a wheel coming off. Such possibilities must be taken into account in the selection of the type of fastener for the specific application.Nuts, bolts, and screws are undoubtedly the most common means of joining materials. Since they are so widely used, it is essential that these fasteners attain maximum effectiveness at the lowest possible cost. Bolts are, in reality, carefully engineered products with a practically infinite use over a wide range of services.An ordinary nut loosens when the forces of vibration overcome those of friction. In a nut and lock washer combination, the lock washer supplies an independent locking feature preventing the nut from loosening. The lock washer is useful only when the bolt might loosen because of a relative change between the length of the bolt and the parts assembled by it. This change in the length of the bolt can be caused by a number of factors-creep in the bolt, loss of resilience, difference in thermal expansion between the bolt and the bolted members, or wear. In the above static cases, the expanding lock washer holds the nut under axial load and keeps the assembly tight. When relative changes are caused by vibration forces, the lock washer is not nearly as effective.Rivets are permanent fasteners. They depend on deformation of their structure for their holding action. Rivets are usually stronger than the thread-type fastener and are more economical on a first-cost basis. Rivets are driven either hot or cold,depending upon the mechanical properties of the rivet material. Aluminum rivets, for instance, are cold-driven, since cold working improves the strength of aluminum. Most large rivets are hot-driven, however.ShaftVirtually all machines contain shafts. The most common shape for shafts is circular and the cross section can be either solid or hollow (hollow shafts can result in weight savings).Shafts are mounted in bearings and transmit power through such devices as gears, pulleys, cams and clutches. These devices introduce forces which attempt to bend the shaft; hence, the shaft must be rigid enough to prevent overloading of the supporting bearings. In general, the bending deflection of a shaft should not exceed 0.01 in. per ft. of length between bearing supports.For diameters less than 3 in., the usual shaft material is cold-rolled steel containing about 0.4 percent carbon. Shafts are either cold-rolled or forged in sizes from 3 in. to 5 in. .For sizes above 5 in. , shafts are forged and machined to size. Plastic shafts are widely used for light load applications. One advantage of using plastic is safety in electrical applications, since plastic is a poor conductor of electricity.Another important aspect of shaft design is the method of directly connecting one shaft to another. This is accomplished by devices such as rigid and flexible couplings.BearingA bearing can be defined as a member specifically designed to support moving machine components. The most common bearing application is the support of a rotating shaft that is transmitting power from one location to another. Since there is always relative motion between a bearing and its mating surface, friction is involved. In many instances, such as the design of pulleys, brakes, and clutches, friction is desirable. However, in the case of bearings, the reduction of friction is one of the prime considerations：Friction results in loss of power, the generation of heat, and increased wear of mating surfaces.The concern of a machine designer with ball bearings and roller bearings is fivefold as follows：(1) Life in relation to load; (2) stiffness, i.e. deflections under load;(3) friction; (4) wear; (5) noise. For moderate loads and speeds the correct selection ofa standard bearing on the basis of load rating will usually secure satisfactoryperformance. The deflection of the bearing elements will become important where loads are high, although this is usually of less magnitude than that of the shafts or other components associated with the bearing. Where speeds are high special cooling arrangements become necessary which may increase frictional drag. Wear is primarily associated with the introduction of contaminants, and sealing arrangements must be chosen with regard to the hostility of the environment.Notwithstanding the fact that responsibility for the basic design of ball bearings and roller bearings rests with the bearing manufacturer, the machine designer must form a correct appreciation of the duty to be performed by the bearing and be concerned not only with bearing selection but with the conditions for correct installation.The fit of the bearing races onto the shaft or onto the housings is of critical importance because of their combined effect on the internal clearance of the bearing as well as preserving the desired degree of interference fit. Inadequate interference can induce serious trouble from fretting corrosion. The inner race is frequently located axially by abutting against a shoulder. A radius at this point is essential for the avoidance of stress concentration and ball races are provided with a radius or chamfer to allow space for this.A journal bearing, in its simplest form, is a cylindrical bushing made of a suitable material and containing properly machined inside and outside diameters. The journal is usually the part of a shaft or pin that rotates inside the bearing.Journal bearings operate with sliding contact, to reduce the problems associated with sliding friction in journal bearings, a lubricant is used in conjunction with compatible mating materials. When selecting the lubricant and mating materials, one must take into account bearing pressures, temperatures and also rubbing velocities. The principle function of the lubricant in sliding contact bearings is to prevent physical contact between the rubbing surfaces. Thus the maintenance of an oil film under varying loads, speeds and temperature is the prime consideration in sliding contact bearings.Introduction to Machinery DesignMachinery design is either to formulate an engineering plan for the satisfaction of a specified need or to solve an engineering problem. It involves a range of disciplines in materials, mechanics, heat, flow, control, electronics and production.Machinery design may be simple or enormously complex, easy or difficult, mathematical or nonmathematical, it may involve a trivial problem or one of great importance. Good design is the orderly and interesting arrangement of an idea to provide certain results or effects. A well-designed product is functional, efficient, and dependable. Such a product is less expensive than a similar poorly designed product that does not function properly and must constantly be repaired.People who perform the various functions of machinery design are typically called industrial designers. He or she must first carefully define the problem, using an engineering approach, to ensure that any proposed solution will solve the right problem. It is important that the designer begins by identifying exactly how he or she will recognize a satisfactory alternative, and how to distinguish between two satisfactory alternatives in order to identify the better. So industrial designers must have creative imagination, knowledge of engineering, production techniques, tools, machines, and materials to design a new product for manufacture, or to improve an existing product.In the modern industrialized world, the wealth and living standards of a nation are closely linked with their capabilities to design and manufacture engineering products. It can be claimed that the advancement of machinery design and manufacturing can remarkably promote the overall level of a country’s industrization. Our country is playing a more and more vital role in the global manufacturing industry. To accelerate such an industrializing process, highly skilled design engineers having extensive knowledge and expertises are needed.Machinery ComponentsThe major part of a machine is the mechanical system. And the mechanical system is decomposed into mechanisms, which can be further decomposed into mechanical components. In this sense, the mechanical components are the fundamental elements of machinery. On the whole, mechanical components can be classified as universal and special components. Bolts, gear, and chains are the typical examples of the universal components, which can be used extensively in different machines across various industrial sectors. Turbine blades, crankshaft and aircraftpropeller are the examples of the special components, which are designed for some specific purposes.Mechanical Design ProcessProduct design requires much research and development. Many concepts of an idea must be studied, tried, refined, and then either used or discarded. Although the content of each engineering problem is unique, the designers follow the similar process to solve the problems.Recognition of NeedSometimes, design begins when a designer recognizes a need and decides to do something about it. The need is often not evident at, all; recognition is usually triggered by a particular adverse circumstance or a set of random circumstances, which arise almost simultaneously. Identification of need usually consists of an undefined and vague problem statement.Definition of ProblemDefinition of problem is necessary to fully define and understand the problem, after which it is possible to restate the goal in a more reasonable and realistic way than the original problem statement. Definition of the problem must include all the specifications for the thing that is to be designed. Obvious items in the specifications are the speeds, feeds, temperature limitations, maximum range, expected variation in the variables, and dimensional and weight limitations.SynthesisThe synthesis is one in which as many alternative possible design approaches are sought, usually without regard for their value or quality. This is also sometimes called the ideation and invention step in which the largest possible number of creative solutions is generated. The synthesis activity includes the specification of material, addition of geometric features, and inclusion of greater dimensional detail to the aggregate design.AnalysisAnalysis is a method of determining or describing the nature of something by separating it into its parts. In the process the elements, or nature of the design, are analyzed to determine the fit between the proposed design and the original design goals.EvaluationEvaluation is the final proof of a successful design and usually involves thetesting of a prototype in the laboratory. Here we wish to discover if the design really satisfies the needs.The above description may give an erroneous impression that this process can be accomplished in a linear fashion as listed. On the contrary, iteration is required within the entire process, moving from any step back to any previous step, in all possible combinations, and doing this repeatedly.PresentationCommunicating the design to others is the finial, vital presentation step in the design process. Basically, there are only three means of communication. These are the written, the oral, and the graphical forms. A successful engineer will be technically competent and versatile in all three forms of communication. The competent engineer should not be afraid of the possibility of not succeeding in a presentation. In fact, the greatest gains are obtained by those willing to risk defeat.Contents of Machinery DesignMachinery design is an important technological basic course in mechanical engineering education. Its objective is to provide the concepts, procedures, data, and decision analysis techniques necessary to design machine elements commonly found in mechanical devices and systems; to develop engineering students’ competence of machine design that is the primary concern of machinery manufacturing and the key to manufacture good products.Machinery design covers the following contents：Provides an introduction to the design process, problem formulation, safety factors.Reviews the material properties and static and dynamic loading analysis, including beam, vibration and impact loading.Reviews the fundamentals of stress and defection analysis.Introduces static failure theories and fracture-mechanics analysis for static loads.Introduces fatigue-failure theory with the emphasis on stress-life approaches to high-cycle fatigue design, which is commonly used in the design of rotation machinery.Discusses thoroughly the phenomena of wear mechanisms, surface contact stresses, and surface fatigue.Investigates shaft design using the fatigue-analysis techniques.Discusses fluid-film and rolling-element bearing theory and application.Gives a thorough introduction to the kinematics, design and stress analysis of spur gears, and a simple introduction to helical, bevel, and worm gearing.Discusses spring design including helical compression, extension and torsion springs.Deals with screws and fasteners including power screw and preload fasteners.Introduces the design and specification of disk and drum clutches and brakes.机械零件(I)齿轮齿轮是直接接触，成对工作的实体，在称为齿的凸出物的连续啮合作用下，齿轮能将运动和力从一个旋转轴传递到另一个旋转轴，或从一个轴传递到一个滑块(齿条)。

外文原文：Kinematic Synthesis ，Cams and Gears Mechanisms form the basic geometrical elements of many mechanical devices including automatic packaging machinery, typewriters, mechanical toys, textile machinery, and others. A mechanism typically is designed to create a desired motion of a rigid body relative to a reference member. Kinematic design, or kinematic syntheses, of mechanisms often is the first step in the design of a complete machine. When forces are considered, the additional problems of dynamics, bearing loads, stresses, lubrication, and the like are introduced, and the larger problem becomes one of machine design.A kinematician defined kinematics as “the study of the motion of mechanisms and methods of creating them.” The first part of this definition deals with kinematic analysis. Given a certain mechanism, the motion characteristics of its components will be determined by kinematic analysis. The statement of the tasks of analysis contains all principal dimensions of the mechanism, the interconnections of its links, and the specification of the input motion or method of actuation. The objective is to find the displacements, velocities, accelerations, shock or jerk (second acceleration) , and perhaps higher accelerations of the various members, as well as the paths described and motions performed by certain elements. In short, in kinematic analysis we determine the performance of a given mechanism. The second part of definition may be paraphrased in two ways:1. The study of methods of creating a given motion by means of mechanisms.2. The study of methods of creating mechanisms having a given motion.In either version, the motion is given and the mechanism is to be found. This is the essence of kinematic synthesis. Thus kinematic synthesis deals with the systematic design of mechanisms for a given performance. The area of synthesis may be grouped into two categories.1. Type synthesis. Given the required performance, what type of mechanism will be suitable? (Gear trains? Linkages? Cam mechanisms? ) Also, how many links should the mechanism have? How many degrees of freedom are required? What configuration id desirable? And so on. Deliberations involving the number of links and degrees of freedom are often referred to as the province of a subcategory of type synthesis called number synthesis.2. Dimensional synthesis. The second major category of kinematic synthesis is best defined by way of its objective: Dimensional synthesis seeks to determine the significant dimensions and the starting position of a mechanism of preconceived type for a specified task and prescribed performance.Significant dimensions mean link lengths or distances on binary, ternary, and so on, links, angles between axis, cam-contour dimensions and cam-follower diameters, eccentricities, gear rations, and so forth. A mechanism of preconceived type may be a slider-crank linkage, a four-bar linkage, a cam with flat follower, or a more complex linkage of a certain configuration defined topologically but not dimensionally. Thereare three customary tasks for kinematic synthesis: function generation, path generation and motion generation.In function generation mechanisms rotation or sliding motions of input and output links must be correlated. For an arbitrary function )(x f y =, a kinematic synthesis task may be to design a linkage to correlate input and output such that the input moves by x , the output moves by )(x f y = for the range 10+<<n x x x . In the case of rotary input and output, the angles of rotation ϕ and ψ are the linear analogs of x and y respectively. When the input link is rotated to a value of the independent x , the mechanism in a “black box” causes the output link to turn to the corresponding value of the dependent variable )(x f y =. This may be regarded as a simple case of a mechanical analog computer. A variety of different mechanisms cou ld be contained within the “black box”. However, the four -bar linkage is not capable of error-free generation of an arbitrary function and can match the function at only a limited number of precision points. It is widely used in industry because the four-bar linkage id simple to construct and maintain.In path generation mechanism a point on a “floating link” is to trace a path defined with respect to a fixed frame of reference. If the path points are to be correlated with either time or input-link positions, the task is called path generation with prescribed timing. An example of path generation mechanisms id a four-bar linkage designed to pitch a baseball or tennis ball. In this case the trajectory of point p would be such as to pick up a ball at a prescribed location and to deliver the ball along a prescribed path with prescribed timing for reaching a suitable throw-velocity and direction.There are many situations in the design of mechanical devises in which it is necessary either to guide a rigid body through a series of specified, finitely separated positions or to impose constraints on the velocity and/or acceleration of the moving body at a reduced number of finitely separated positions. Motion-generation or rigid-body guidance mechanism requires that an entire body be guided through a prescribed motion sequence. The body to be guided usually is a part of a floating link, of which not only is the path of a point p prescribed, but also the rotation of a line passing through the point and embedded in the body,. For instance, the line might represent a carrier link in a automatic machinery where a point located on the carrier link has a prescribed path while the carrier has a prescribed angular orientation. Prescribing the movement of the bucket for a bucket loader id another example of motion generation mechanisms, the path of tip of the bucket is critical since the tip must perform a scooping trajectory followed by a lifting and a dumping trajectory. The angular orientation of the bucket are equally important to ensure that load is dumped from the correct position.A cam is a convenient device for transforming one motion into another. Thismachine element has a curved or grooved surface which mates with a follower and imparts motion to it. The motion of the cam (usually rotation) is transformed into follower oscillation, translation, or both. Because of the various cam geometries and the large number of cam and follower combinations, the cam is an extremely versatile mechanical element. Although a cam and follower may be designed for motion, path, or function generation, the majority of applications utilize the cam and follower for function generation.The most common cam types according to cam shapes are: disk or plate translating (two-dimensional or planar), and cylindrical (three-dimensional or spatial) cams. Followers can be classified in several ways: according to follower motion, such as translation or oscillation; according to whether the translational (straight-line) follower motion is radial of offset from the center of the cam shaft; and according to the shape of the follower contact surface (e. g. , flat-face, roller, point (knife-edge), spherical, planar curved, or spatial-curved surface).In the case of a disk cam with a radial (in-line) translating roller follower the smallest circle that can be drawn tangent to the cam surface and concentric with the camshaft is the base circle. The tracer point is a point at the center of the roller center and the normal to the pitch curve. The pressure angle is the angle between the direction of the path of the roller center and the normal to the pitch curve through the center of the roller and is the complement of the transmission angle. Neglecting friction, this normal is collinear with the contact force between the cam and follower. As in a linkage, the pressure angle varies during the cycle and is a measure of the ability of the cam to transfer motive effort to the follower. A large pressure angle will produce an appreciable lateral force exerted on the stem of the follower, which, in the presence of friction, would tend to bind the follower in the guide.Numerous applications in automatic machinery require intermittent motion. A typical example will call for a rise-dwell-return and perhaps another dwell period of a specified number of degrees each, together with a required follower displacement measured in centimeters or degrees. The designer’s job is to lay out the cam accordingly. The first decision to be made is to choose the cam follower type. The specified application may dictate the combination of the cam and follower. Some factors that should enter into the decision are: geometric considerations, dynamic considerations, environmental considerations and economic matters. Once a type of cam and follower pair has been selected, the follower motion must be chosen. Therefore, the velocity, acceleration, and in some cases further derivatives of the displacement of the follower are of great importance.Gears are machine elements that transmit motion by means of successively engaging teeth. Gears transmit motion from one rotating shaft to another, or to a rack that translates. Numerous applications exist in which a constant angular velocity ratio (or constant torque ratio) must be transmitted between shafts. Based on the variety of gear types available, there is no restriction that the input and the output shafts need be either in-line or parallel. Nonlinear angular velocity ratios are also available by using noncircular gears. In order to maintain a constant angular velocity, the individual tooth profile must obey the fundamental law of gearing: for a pair of gears to transmita constant angular velocity ratio, the shape of their contacting profiles must be such that the common normal passes through a fixed point on the line of the centers.Any two mating tooth profiles that satisfy the fundamental law of gearing are called conjugate profiles. Although there are many tooth shapes possible in which a mating tooth could be designed to satisfy the fundamental law, only two are in general use: the cycloidal and involute profiles. The involute has important advantages: it is easy to manufacture and the center distance between a pair of involute gears can be varied without changing the velocity ratio. Thus chose tolerances between shafts are not required when utilizing the involute profile.There are several standard gear types. For applications with parallel shafts, straight spur gear, parallel helical, or herringbone gears are usually used. In the case of intersecting shafts, straight bevel of spiral bevel gears are employed. For nonintersecting and nonparallel shafts, crossed helical, worm, face, skew bevel or hypoid gears would be acceptable choices. For spur gears, the pitch circles of mating gears are tangent to each other. They roll on one another without sliding. The addendum is the height by which a tooth projects beyond the pitch circle (also the radial distance between the pitch circle and the addendum circle). The clearance is the amount by which the addendum (tooth height below the pitch circle) in a given gears exceeds the addendum of its mating gear. The tooth thickness is the distance across the tooth along the arc of the pitch circle while the tooth space is the distance between adjacent teeth along the arc of the pitch circle. The backlash is the amount by which the width of the tooth space exceeds the thickness of the engaging tooth at the pitch circle.中文译文：运动的综合，凸轮和齿轮机构是形成许多机械装置的基本几何结构单元，这些机械装置包括自动包装机、打印机、机械玩具、纺织机械和其他机械等。

中间齿轮intermediate gear(counter gear) 副轴齿轮counter shaft gear副轴counter shaft变速器输入轴transmission imput shaft变速器输出轴transmission output shaft变速器主动齿轮轴transmission drive gear shaft变速器主轴transmission main shaft变速器中间轴transmission countershaft 变速器轴的刚度rigidity of shaft变速齿轮比(变速比)transmission gear ratio 传动比gear ratio主压力line pressure调制压力modulated pressure真空调制压力vacuum modulator pressure 速控压力governor pressure缓冲压力compensator or trimmer pressure限档压力hold presure前油泵front pump (input pump )液力传动装置充油压力hydrodynamic unit change pressure后油泵gear pump (output pump )回油泵scavenge oil pump阿基米德蜗杆 Archimedes worm安全系数safety factor; factor of safety安全载荷 safe load变形 deformation 摆线齿轮 cycloidal gear摆线齿形 cycloidal tooth profile背锥角 back angle背锥距 back cone distance比例尺 scale变速 speed change变速齿轮 change gear ; change wheel变位齿轮 modified gear变位系数 modification coefficient标准齿轮 standard gear标准直齿轮 standard spur gear表面粗糙度 surface roughness不完全齿轮机构 intermittent gearing补偿 compensation参数化设计 parameterization design, PD 残余应力 residual stress操纵及控制装置operation control device槽数 Geneva numerate侧隙 backlash差动轮系 differential gear train差动螺旋机构differential screw mechanism差速器 differential常用机构conventional mechanism; mechanism in common use承载量系数 bearing capacity factor承载能力 bearing capacity成对安装 paired mounting尺寸系列 dimension series齿槽 tooth space齿槽宽 spacewidth齿侧间隙 backlash齿顶高 addendum齿顶圆 addendum circle齿根高 dedendum齿根圆 dedendum circle齿厚 tooth thickness齿距 circular pitch齿宽 face width齿廓 tooth profile齿廓曲线 tooth curve齿轮 gear齿轮变速箱 speed-changing gear boxes齿轮齿条机构 pinion and rack齿轮插刀 pinion cutter; pinion-shaped shaper cutter齿轮滚刀 hob ,hobbing cutter齿轮机构 gear齿轮轮坯 blank齿轮传动系 pinion unit齿轮联轴器 gear coupling齿条传动 rack gear齿数 tooth number齿数比 gear ratio齿条 rack齿条插刀rack cutter; rack-shaped shaper cutter齿形链、无声链 silent chain齿形系数 form factor齿式棘轮机构 tooth ratchet mechanism 插齿机 gear shaper重合点 coincident points重合度 contact ratio传动比 transmission ratio, speed ratio 传动装置 gearing; transmission gear传动系统 driven system传动角 transmission angle传动轴 transmission shaft创新设计 creation design垂直载荷、法向载荷 normal load从动带轮 driven pulley从动件 driven link, follower从动件平底宽度 width of flat-face从动件停歇 follower dwell从动件运动规律 follower motion从动轮 driven gear粗线 bold line粗牙螺纹 coarse thread大齿轮 gear wheel打滑 slipping带传动 belt driving单列轴承 single row bearing单位矢量 unit vector当量齿轮 equivalent spur gear; virtual gear当量齿数equivalent teeth number; virtual number of teeth 当量摩擦系数 equivalent coefficient of friction当量载荷 equivalent load刀具 cutter导数 derivative倒角 chamfer导程 lead导程角 lead angle等效质量 equivalent mass（疲劳）点蚀 pitting垫圈 gasket垫片密封 gasket seal顶隙 bottom clearance定轴轮系ordinary gear train; gear train with fixed axes动力学 dynamics动密封 kinematical seal动能 dynamic energy动力粘度 dynamic viscosity动力润滑 dynamic lubrication动载荷 dynamic load端面 transverse plane端面参数 transverse parameters端面齿距 transverse circular pitch端面齿廓 transverse tooth profile端面重合度 transverse contact ratio端面模数 transverse module端面压力角 transverse pressure angle 锻造 forge惰轮 idle gear额定寿命 rating life额定载荷 load rating发生线 generating line发生面 generating plane法面 normal plane法面参数 normal parameters法面齿距 normal circular pitch法面模数 normal module法面压力角 normal pressure angle法向齿距 normal pitch法向齿廓 normal tooth profile法向直廓蜗杆 straight sided normal worm 法向力 normal force反正切 Arctan范成法 generating cutting仿形法 form cutting非标准齿轮 nonstandard gear非接触式密封 non-contact seal非周期性速度波动aperiodic speed fluctuation非圆齿轮 non-circular gear粉末合金 powder metallurgy分度线 reference line; standard pitch line分度圆reference circle; standard (cutting) pitch circle分度圆柱导程角 lead angle at reference cylinder分度圆柱螺旋角 helix angle at reference cylinder分母 denominator分子 numerator分度圆锥 reference cone; standard pitch cone封闭差动轮系 planetary differential复合应力 combined stress复式螺旋机构 Compound screw mechanism 干涉 interference刚度系数 stiffness coefficient钢丝软轴 wire soft shaft根切 undercutting公称直径 nominal diameter高度系列 height series功 work工况系数 application factor工艺设计 technological design工作循环图 working cycle diagram工作机构 operation mechanism工作载荷 external loads工作空间 working space工作应力 working stress工作阻力 effective resistance工作阻力矩 effective resistance moment 公法线 common normal line公制齿轮 metric gears功率 power功能分析设计 function analyses design 共轭齿廓 conjugate profiles 共轭凸轮 conjugate cam惯性力矩moment of inertia ,shaking moment惯性力平衡 balance of shaking force冠轮 crown gear轨迹生成 path generation轨迹发生器 path generator滚刀 hob过度切割 undercutting耗油量 oil consumption耗油量系数 oil consumption factor横坐标 abscissa互换性齿轮 interchangeable gears花键 spline滑键、导键 feather key滑动率 sliding ratio环面蜗杆 toroid helicoids worm缓冲装置 shocks; shock-absorber机械 machinery机械平衡 balance of machinery机械设计machine design; mechanical design机械特性 mechanical behavior机械调速 mechanical speed governors机械效率 mechanical efficiency机械原理theory of machines and mechanisms机械无级变速 mechanical stepless speed changes基础机构 fundamental mechanism基本额定寿命 basic rating life基于实例设计 case-based design,CBD基圆 base circle基圆半径 radius of base circle基圆齿距 base pitch基圆压力角pressure angle of base circle基圆柱 base cylinder基圆锥 base cone极限位置 extreme (or limiting) position 极位夹角 crank angle between extreme (or limiting) positions计算机辅助设计 computer aided design, CAD计算机辅助制造computer aided manufacturing, CAM计算机集成制造系统 computer integrated manufacturing system, CIMS计算力矩 factored moment; calculation moment计算弯矩 calculated bending moment间隙 backlash减速比 reduction ratio减速齿轮、减速装置 reduction gear减速器 speed reducer渐开螺旋面 involute helicoid渐开线 involute渐开线齿廓 involute profile渐开线齿轮 involute gear渐开线发生线generating line of involute渐开线方程 involute equation渐开线函数 involute function渐开线蜗杆 involute worm渐开线压力角 pressure angle of involute 渐开线花键 involute spline键 key键槽 keyway交变应力 repeated stress交变载荷 repeated fluctuating load交叉带传动 cross-belt drive交错轴斜齿轮 crossed helical gears胶合 scoring角速度 angular velocity角速比 angular velocity ratio结构 structure结构设计 structural design截面 section节点 pitch point节距 circular pitch; pitch of teeth节线 pitch line节圆 pitch circle节圆齿厚 thickness on pitch circle节圆直径 pitch diameter节圆锥 pitch cone节圆锥角 pitch cone angle解析设计 analytical design紧边 tight-side 紧固件 fastener径节 diametral pitch径向 radial direction径向当量动载荷dynamic equivalent radial load径向当量静载荷static equivalent radial load径向基本额定动载荷basic dynamic radial load rating径向基本额定静载荷 basic static radial load tating径向接触轴承 radial contact bearing径向平面 radial plane径向游隙 radial internal clearance径向载荷 radial load径向载荷系数 radial load factor径向间隙 clearance静力 static force静平衡 static balance静载荷 static load绝对运动 absolute motion绝对速度 absolute velocity可靠性 reliability可靠性设计 reliability design, RD理论廓线 pitch curve理论啮合线 theoretical line of action 力矩 moment力平衡 equilibrium力偶 couple力偶矩 moment of couple轮坯 blank螺旋副 helical pair螺旋机构 screw mechanism螺旋角 helix angle螺旋线 helix ,helical line模块化设计 modular design, MD模数 module磨损 abrasion ;wear; scratching耐磨性 wear resistance内齿轮 internal gear内齿圈 ring gear内力 internal force内圈 inner ring啮合 engagement, mesh, gearing啮合点 contact points啮合角 working pressure angle啮合线 line of action啮合线长度 length of line of action盘形转子 disk-like rotor抛物线运动 parabolic motion疲劳极限 fatigue limit疲劳强度 fatigue strength偏置式 offset偏 ( 心 ) 距 offset distance偏心率 eccentricity ratio偏心质量 eccentric mass偏距圆 offset circle偏心盘 eccentric切齿深度 depth of cut曲齿锥齿轮 spiral bevel gear曲率 curvature曲率半径 radius of curvature曲面从动件 curved-shoe follower曲线运动 curvilinear motion全齿高 whole depth权重集 weight sets球面副 spheric pair球面渐开线 spherical involute球面运动 spherical motion人字齿轮 herringbone gear润滑装置 lubrication device润滑 lubrication三角形花键 serration spline三角形螺纹 V thread screw少齿差行星传动 planetary drive with small teeth difference升程 rise升距 lift实际廓线 cam profile输出轴 output shaft实际啮合线 actual line of action双曲面齿轮 hyperboloid gear顺时针 clockwise瞬心 instantaneous center死点 dead point太阳轮 sun gear特性 characteristics图册、图谱 atlas 图解法 graphical method退火 anneal陀螺仪 gyroscope外力 external force外形尺寸 boundary dimension网上设计 on-net design, OND微动螺旋机构differential screw mechanism位移 displacement蜗杆 worm蜗杆传动机构 worm gearing蜗杆头数 number of threads蜗杆直径系数 diametral quotient蜗杆蜗轮机构 worm and worm gear蜗杆形凸轮步进机构 worm cam interval mechanism蜗杆旋向 hands of worm蜗轮 worm gear无级变速装置stepless speed changes devices相对速度 relative velocity相对运动 relative motion相对间隙 relative gap象限 quadrant橡皮泥 plasticine小齿轮 pinion小径 minor diameter谐波齿轮 harmonic gear谐波传动 harmonic driving斜齿轮的当量直齿轮equivalent spur gear of the helical gear心轴 spindle行程速度变化系数 coefficient of travel speed variation行程速比系数advance-to return-time ratio行星齿轮装置 planetary transmission行星轮 planet gear行星轮变速装置planetary speed changing devices行星轮系 planetary gear train旋转运动 rotary motion压力角 pressure angle应力图 stress diagram应力—应变图 stress-strain diagram 优化设计 optimal design油杯 oil bottle有效圆周力 effective circle force圆带传动 round belt drive圆弧齿厚 circular thickness圆弧圆柱蜗杆 hollow flank worm圆角半径 fillet radius圆盘摩擦离合器 disc friction clutch圆盘制动器 disc brake原动机 prime mover原始机构 original mechanism圆形齿轮 circular gear圆柱滚子 cylindrical roller圆柱滚子轴承cylindrical roller bearing圆柱副 cylindric pair圆柱蜗杆 cylindrical worm圆锥滚子 tapered roller圆锥滚子轴承 tapered roller bearing圆锥齿轮机构 bevel gears圆锥角 cone angle运动副 kinematic pair运动粘度 kenematic viscosity载荷 load展成法 generating直齿圆柱齿轮 spur gear直齿锥齿轮 straight bevel gear直径系数 diametral quotient直径系列 diameter series直廓环面蜗杆 hindley worm质量 mass中心距 center distance中心距变动 center distance change中径 mean diameter终止啮合点final contact, end of contact周节 pitch轴 shaft轴承盖 bearing cup轴承合金 bearing alloy轴承座 bearing block轴承外径 bearing outside diameter轴颈 journal 轴瓦、轴承衬 bearing bush轴端挡圈 shaft end ring轴环 shaft collar轴肩 shaft shoulder轴角 shaft angle轴向 axial direction轴向齿廓 axial tooth profile转动副 revolute (turning) pair转速 swiveling speed ; rotating speed 转轴 revolving shaft转子 rotor装配条件 assembly condition锥齿轮 bevel gear锥顶 common apex of cone锥距 cone distance锥轮 bevel pulley; bevel wheel锥齿轮的当量直齿轮equivalent spur gear of the bevel gear锥面包络圆柱蜗杆 milled helicoids worm 准双曲面齿轮 hypoid gear自由度 degree of freedom, mobility总重合度 total contact ratio总反力 resultant force总效率combined efficiency; overall efficiency组成原理 theory of constitution组合齿形 composite tooth form组合安装 stack mounting最少齿数 minimum teeth number最小向径 minimum radius作用力 applied force坐标系 coordinate frame电磁阀调压阀solenoid regulator valve液力变矩器旁通阀converter bypass valve速控阀governor valve选档阀selectro valve换档阀shift valve信号阀signal valve继动阀relay valve换档指令发生器shift pattern generator档位指示器shift indicator(shift torwer)先导阀priority valve流量阀flow valve重迭阀overlap valve液力减速器控制阀retarder control valve欢迎您的下载，资料仅供参考！致力为企业和个人提供合同协议，策划案计划书，学习资料等等打造全网一站式需求。

阿基米德蜗杆 Archimedes worm安全系数 safety factor; factor of safety安全载荷 safe load变形 deformation摆线齿轮 cycloidal gear摆线齿形 cycloidal tooth profile背锥角 back angle背锥距 back cone distance比例尺 scale变速 speed change变速齿轮 change gear ; change wheel变位齿轮 modified gear变位系数 modification coefficient标准齿轮 standard gear标准直齿轮 standard spur gear表面粗糙度 surface roughness不完全齿轮机构 intermittent gearing补偿 compensation参数化设计 parameterization design, PD残余应力 residual stress操纵及控制装置 operation control device槽数 Geneva numerate侧隙 backlash差动轮系 differential gear train差动螺旋机构 differential screw mechanism差速器 differential常用机构 conventional mechanism; mechanism in common use承载量系数 bearing capacity factor承载能力 bearing capacity成对安装 paired mounting尺寸系列 dimension series齿槽 tooth space齿槽宽 spacewidth齿侧间隙 backlash齿顶高 addendum齿顶圆 addendum circle齿根高 dedendum齿根圆 dedendum circle齿厚 tooth thickness齿距 circular pitch齿宽 face width齿廓 tooth profile齿廓曲线 tooth curve齿轮 gear齿轮变速箱 speed-changing gear boxes齿轮齿条机构 pinion and rack齿轮插刀 pinion cutter; pinion-shaped shaper cutter齿轮滚刀 hob ,hobbing cutter齿轮机构 gear齿轮轮坯 blank齿轮传动系 pinion unit齿轮联轴器 gear coupling齿条传动 rack gear齿数 tooth number齿数比 gear ratio齿条 rack齿条插刀 rack cutter; rack-shaped shaper cutter齿形链、无声链 silent chain齿形系数 form factor齿式棘轮机构 tooth ratchet mechanism插齿机 gear shaper重合点 coincident points重合度 contact ratio传动比 transmission ratio, speed ratio传动装置 gearing; transmission gear传动系统 driven system传动角 transmission angle传动轴 transmission shaft创新设计 creation design垂直载荷、法向载荷 normal load从动带轮 driven pulley从动件 driven link, follower从动件平底宽度 width of flat-face从动件停歇 follower dwell从动件运动规律 follower motion从动轮 driven gear粗线 bold line粗牙螺纹 coarse thread大齿轮 gear wheel打滑 slipping带传动 belt driving单列轴承 single row bearing单位矢量 unit vector当量齿轮 equivalent spur gear; virtual gear 当量齿数 equivalent teeth number; virtual number of teeth当量摩擦系数 equivalent coefficient of friction当量载荷 equivalent load刀具 cutter导数 derivative倒角 chamfer导程 lead导程角 lead angle等效质量 equivalent mass（疲劳）点蚀 pitting垫圈 gasket垫片密封 gasket seal顶隙 bottom clearance定轴轮系 ordinary gear train; gear train with fixed axes动力学 dynamics动密封 kinematical seal动能 dynamic energy动力粘度 dynamic viscosity动力润滑 dynamic lubrication动载荷 dynamic load端面 transverse plane端面参数 transverse parameters端面齿距 transverse circular pitch端面齿廓 transverse tooth profile端面重合度 transverse contact ratio端面模数 transverse module端面压力角 transverse pressure angle锻造 forge惰轮 idle gear额定寿命 rating life额定载荷 load rating发生线 generating line发生面 generating plane法面 normal plane法面参数 normal parameters法面齿距 normal circular pitch法面模数 normal module法面压力角 normal pressure angle法向齿距 normal pitch法向齿廓 normal tooth profile法向直廓蜗杆 straight sided normal worm法向力 normal force反正切 Arctan范成法 generating cutting仿形法 form cutting非标准齿轮 nonstandard gear非接触式密封 non-contact seal非周期性速度波动 aperiodic speed fluctuation非圆齿轮 non-circular gear粉末合金 powder metallurgy分度线 reference line; standard pitch line分度圆 reference circle; standard (cutting) pitch circle分度圆柱导程角 lead angle at reference cylinder 分度圆柱螺旋角 helix angle at reference cylinder分母 denominator分子 numerator分度圆锥 reference cone; standard pitch cone 封闭差动轮系 planetary differential复合应力 combined stress复式螺旋机构 Compound screw mechanism干涉 interference刚度系数 stiffness coefficient钢丝软轴 wire soft shaft根切 undercutting公称直径 nominal diameter高度系列 height series功 work工况系数 application factor工艺设计 technological design工作循环图 working cycle diagram工作机构 operation mechanism工作载荷 external loads工作空间 working space工作应力 working stress工作阻力 effective resistance工作阻力矩 effective resistance moment公法线 common normal line公制齿轮 metric gears功率 power功能分析设计 function analyses design共轭齿廓 conjugate profiles共轭凸轮 conjugate cam惯性力矩 moment of inertia ,shaking moment 惯性力平衡 balance of shaking force冠轮 crown gear轨迹生成 path generation轨迹发生器 path generator滚刀 hob过度切割 undercutting耗油量 oil consumption耗油量系数 oil consumption factor横坐标 abscissa互换性齿轮 interchangeable gears花键 spline滑键、导键 feather key滑动率 sliding ratio环面蜗杆 toroid helicoids worm缓冲装置 shocks; shock-absorber机械 machinery机械平衡 balance of machinery机械设计 machine design; mechanical design 机械特性 mechanical behavior 机械调速 mechanical speed governors 机械效率 mechanical efficiency 机械原理 theory of machines and mechanisms 机械无级变速 mechanical stepless speed changes 基础机构 fundamental mechanism 基本额定寿命 basic rating life 基于实例设计 case-based design,CBD 基圆 base circle 基圆半径 radius of base circle 基圆齿距 base pitch 基圆压力角 pressure angle of base circle 基圆柱 base cylinder 基圆锥 base cone 极限位置 extreme (or limiting) position 极位夹角 crank angle between extreme (or limiting) positions 计算机辅助设计 computer aided design, CAD 计算机辅助制造 computer aided manufacturing, CAM 计算机集成制造系统 computer integrated manufacturing system, CIMS 计算力矩 factored moment; calculation moment 计算弯矩 calculated bending moment 间隙 backlash 减速比 reduction ratio 减速齿轮、减速装置 reduction gear 减速器 speed reducer 渐开螺旋面 involute helicoid 渐开线 involute 渐开线齿廓 involute profile 渐开线齿轮 involute gear 渐开线发生线 generating line of involute 渐开线方程 involute equation 渐开线函数 involute function 渐开线蜗杆 involute worm 渐开线压力角 pressure angle of involute 渐开线花键 involute spline 键 key 键槽 keyway 交变应力 repeated stress 交变载荷 repeated fluctuating load 交叉带传动 cross-belt drive 交错轴斜齿轮 crossed helical gears 胶合 scoring 角速度 angular velocity 角速比 angular velocity ratio 结构 structure 结构设计 structural design 截面 section 节点 pitch point 节距 circular pitch; pitch of teeth 节线 pitch line 节圆 pitch circle 节圆齿厚 thickness on pitch circle 节圆直径 pitch diameter 节圆锥 pitch cone 节圆锥角 pitch cone angle 解析设计 analytical design 紧边 tight-side 紧固件 fastener 径节 diametral pitch 径向 radial direction 径向当量动载荷 dynamic equivalent radial load 径向当量静载荷 static equivalent radial load 径向基本额定动载荷 basic dynamic radial load rating 径向基本额定静载荷 basic static radial load tating 径向接触轴承 radial contact bearing 径向平面 radial plane 径向游隙 radial internal clearance 径向载荷 radial load 径向载荷系数 radial load factor 径向间隙 clearance 静力 static force 静平衡 static balance 静载荷 static load 绝对运动 absolute motion 绝对速度 absolute velocity 可靠性 reliability 可靠性设计 reliability design, RD 理论廓线 pitch curve 理论啮合线 theoretical line of action 力矩 moment 力平衡 equilibrium 力偶 couple 力偶矩 moment of couple 轮坯 blank 螺旋副 helical pair 螺旋机构 screw mechanism 螺旋角 helix angle 螺旋线 helix ,helical line 模块化设计 modular design, MD 模数 module 磨损 abrasion ;wear; scratching耐磨性 wear resistance内齿轮 internal gear内齿圈 ring gear内力 internal force内圈 inner ring啮合 engagement, mesh, gearing啮合点 contact points啮合角 working pressure angle啮合线 line of action啮合线长度 length of line of action盘形转子 disk-like rotor抛物线运动 parabolic motion疲劳极限 fatigue limit疲劳强度 fatigue strength偏置式 offset偏 ( 心 ) 距 offset distance偏心率 eccentricity ratio偏心质量 eccentric mass偏距圆 offset circle偏心盘 eccentric切齿深度 depth of cut曲齿锥齿轮 spiral bevel gear曲率 curvature曲率半径 radius of curvature曲面从动件 curved-shoe follower曲线运动 curvilinear motion全齿高 whole depth权重集 weight sets球面副 spheric pair球面渐开线 spherical involute球面运动 spherical motion人字齿轮 herringbone gear润滑装置 lubrication device润滑 lubrication三角形花键 serration spline三角形螺纹 V thread screw少齿差行星传动 planetary drive with small teeth difference升程 rise升距 lift实际廓线 cam profile输出轴 output shaft实际啮合线 actual line of action双曲面齿轮 hyperboloid gear顺时针 clockwise瞬心 instantaneous center死点 dead point太阳轮 sun gear 特性 characteristics图册、图谱 atlas图解法 graphical method退火 anneal陀螺仪 gyroscope外力 external force外形尺寸 boundary dimension网上设计 on-net design, OND微动螺旋机构 differential screw mechanism位移 displacement蜗杆 worm蜗杆传动机构 worm gearing蜗杆头数 number of threads蜗杆直径系数 diametral quotient蜗杆蜗轮机构 worm and worm gear蜗杆形凸轮步进机构 worm cam interval mechanism蜗杆旋向 hands of worm蜗轮 worm gear无级变速装置 stepless speed changes devices 相对速度 relative velocity相对运动 relative motion相对间隙 relative gap象限 quadrant橡皮泥 plasticine小齿轮 pinion小径 minor diameter谐波齿轮 harmonic gear谐波传动 harmonic driving斜齿轮的当量直齿轮 equivalent spur gear of the helical gear心轴 spindle行程速度变化系数 coefficient of travel speed variation行程速比系数 advance-to return-time ratio行星齿轮装置 planetary transmission行星轮 planet gear行星轮变速装置 planetary speed changing devices行星轮系 planetary gear train旋转运动 rotary motion压力角 pressure angle应力图 stress diagram应力—应变图 stress-strain diagram优化设计 optimal design油杯 oil bottle有效圆周力 effective circle force圆带传动 round belt drive圆弧齿厚 circular thickness圆弧圆柱蜗杆 hollow flank worm圆角半径 fillet radius圆盘摩擦离合器 disc friction clutch圆盘制动器 disc brake原动机 prime mover原始机构 original mechanism圆形齿轮 circular gear圆柱滚子 cylindrical roller圆柱滚子轴承 cylindrical roller bearing 圆柱副 cylindric pair圆柱蜗杆 cylindrical worm圆锥滚子 tapered roller圆锥滚子轴承 tapered roller bearing圆锥齿轮机构 bevel gears圆锥角 cone angle运动副 kinematic pair运动粘度 kenematic viscosity载荷 load展成法 generating直齿圆柱齿轮 spur gear直齿锥齿轮 straight bevel gear直径系数 diametral quotient直径系列 diameter series直廓环面蜗杆 hindley worm质量 mass中心距 center distance中心距变动 center distance change中径 mean diameter终止啮合点 final contact, end of contact 周节 pitch轴 shaft轴承盖 bearing cup轴承合金 bearing alloy轴承座 bearing block轴承外径 bearing outside diameter轴颈 journal轴瓦、轴承衬 bearing bush轴端挡圈 shaft end ring轴环 shaft collar轴肩 shaft shoulder轴角 shaft angle轴向 axial direction轴向齿廓 axial tooth profile转动副 revolute (turning) pair转速 swiveling speed ; rotating speed转轴 revolving shaft转子 rotor 装配条件 assembly condition锥齿轮 bevel gear锥顶 common apex of cone锥距 cone distance锥轮 bevel pulley; bevel wheel锥齿轮的当量直齿轮 equivalent spur gear of the bevel gear锥面包络圆柱蜗杆 milled helicoids worm准双曲面齿轮 hypoid gear自由度 degree of freedom, mobility总重合度 total contact ratio总反力 resultant force总效率 combined efficiency; overall efficiency组成原理 theory of constitution组合齿形 composite tooth form组合安装 stack mounting最少齿数 minimum teeth number最小向径 minimum radius作用力 applied force坐标系 coordinate frame齿轮术语中英文对照表阿基米德蜗杆 Archimedes worm安全系数 safety factor; factor ofsafety安全载荷 safe load变形 deformation摆线齿轮 cycloidal gear摆线齿形 cycloidal tooth profile背锥角 back angle背锥距 back cone distance比例尺 scale变速 speed change变速齿轮 change gear ; change wheel变位齿轮 modified gear变位系数 modification coefficient标准齿轮 standard gear标准直齿轮 standard spur gear表面粗糙度 surface roughness不完全齿轮机构 intermittent gearing补偿 compensation参数化设计 parameterization design,PD残余应力 residual stress操纵及控制装置 operation controldevice槽数 Geneva numerate侧隙 backlash差动轮系 differential gear train差动螺旋机构 differential screw mechanism差速器 differential常用机构 conventional mechanism; mechanism in common use承载量系数 bearing capacity factor承载能力 bearing capacity成对安装 paired mounting尺寸系列 dimension series齿槽 tooth space齿槽宽 spacewidth齿侧间隙 backlash齿顶高 addendum齿顶圆 addendum circle齿根高 dedendum齿根圆 dedendum circle齿厚 tooth thickness齿距 circular pitch齿宽 face width齿廓 tooth profile齿廓曲线 tooth curve齿轮 gear齿轮变速箱 speed-changing gear boxes齿轮齿条机构 pinion and rack齿轮插刀 pinion cutter; pinion-shaped shaper cutter齿轮滚刀 hob ,hobbing cutter齿轮机构 gear齿轮轮坯 blank齿轮传动系 pinion unit齿轮联轴器 gear coupling齿条传动 rack gear齿数 tooth number齿数比 gear ratio齿条 rack齿条插刀 rack cutter; rack-shaped shaper cutter齿形链、无声链 silent chain齿形系数 form factor齿式棘轮机构 tooth ratchet mechanism插齿机 gear shaper重合点 coincident points重合度 contact ratio传动比 transmission ratio, speed ratio 传动装置 gearing; transmission gear传动系统 driven system 传动角 transmission angle传动轴 transmission shaft创新设计 creation design垂直载荷、法向载荷 normal load从动带轮 driven pulley从动件 driven link, follower从动件平底宽度 width of flat-face 从动件停歇 follower dwell从动件运动规律 follower motion从动轮 driven gear粗线 bold line粗牙螺纹 coarse thread大齿轮 gear wheel打滑 slipping带传动 belt driving单列轴承 single row bearing单位矢量 unit vector当量齿轮 equivalent spur gear; virtual gear当量齿数 equivalent teeth number; virtual number of teeth当量摩擦系数 equivalent coefficient of friction当量载荷 equivalent load刀具 cutter导数 derivative倒角 chamfer导程 lead导程角 lead angle等效质量 equivalent mass（疲劳）点蚀 pitting垫圈 gasket垫片密封 gasket seal顶隙 bottom clearance定轴轮系 ordinary gear train; gear train with fixed axes动力学 dynamics动密封 kinematical seal动能 dynamic energy动力粘度 dynamic viscosity动力润滑 dynamic lubrication动载荷 dynamic load端面 transverse plane端面参数 transverse parameters端面齿距 transverse circular pitch 端面齿廓 transverse tooth profile 端面重合度 transverse contact ratio 端面模数 transverse module端面压力角 transverse pressure angle锻造 forge惰轮 idle gear额定寿命 rating life额定载荷 load rating发生线 generating line发生面 generating plane法面 normal plane法面参数 normal parameters法面齿距 normal circular pitch法面模数 normal module法面压力角 normal pressure angle法向齿距 normal pitch法向齿廓 normal tooth profile法向直廓蜗杆 straight sided normal worm 法向力 normal force反正切 Arctan范成法 generating cutting仿形法 form cutting非标准齿轮 nonstandard gear非接触式密封 non-contact seal非周期性速度波动 aperiodic speed fluctuation非圆齿轮 non-circular gear粉末合金 powder metallurgy分度线 reference line; standard pitch line分度圆 reference circle; standard (cutting) pitch circle分度圆柱导程角 lead angle at reference cylinder分度圆柱螺旋角 helix angle at reference cylinder分母 denominator分子 numerator分度圆锥 reference cone; standard pitch cone封闭差动轮系 planetary differential复合应力 combined stress复式螺旋机构 Compound screw mechanism 干涉 interference刚度系数 stiffness coefficient钢丝软轴 wire soft shaft根切 undercutting公称直径 nominal diameter高度系列 height series功 work工况系数 application factor 工艺设计 technological design工作循环图 working cycle diagram工作机构 operation mechanism工作载荷 external loads工作空间 working space工作应力 working stress工作阻力 effective resistance工作阻力矩 effective resistance moment公法线 common normal line公制齿轮 metric gears功率 power功能分析设计 function analyses design共轭齿廓 conjugate profiles共轭凸轮 conjugate cam惯性力矩 moment of inertia ,shaking moment惯性力平衡 balance of shaking force 冠轮 crown gear轨迹生成 path generation轨迹发生器 path generator滚刀 hob过度切割 undercutting耗油量 oil consumption耗油量系数 oil consumption factor 横坐标 abscissa互换性齿轮 interchangeable gears花键 spline滑键、导键 feather key滑动率 sliding ratio环面蜗杆 toroid helicoids worm缓冲装置 shocks; shock-absorber机械 machinery机械平衡 balance of machinery机械设计 machine design; mechanical design机械特性 mechanical behavior机械调速 mechanical speed governors 机械效率 mechanical efficiency机械原理 theory of machines and mechanisms机械无级变速 mechanical stepless speed changes基础机构 fundamental mechanism基本额定寿命 basic rating life基于实例设计 case-based design,CBD 基圆 base circle基圆半径 radius of base circle基圆齿距 base pitch基圆压力角 pressure angle of base circle 基圆柱 base cylinder基圆锥 base cone极限位置 extreme (or limiting) position 极位夹角 crank angle between extreme (or limiting) positions计算机辅助设计 computer aided design, CAD计算机辅助制造 computer aided manufacturing, CAM计算机集成制造系统 computer integrated manufacturing system, CIMS计算力矩 factored moment; calculation moment计算弯矩 calculated bending moment间隙 backlash减速比 reduction ratio减速齿轮、减速装置 reduction gear减速器 speed reducer渐开螺旋面 involute helicoid渐开线 involute渐开线齿廓 involute profile渐开线齿轮 involute gear渐开线发生线 generating line of involute 渐开线方程 involute equation渐开线函数 involute function渐开线蜗杆 involute worm渐开线压力角 pressure angle of involute 渐开线花键 involute spline键 key键槽 keyway交变应力 repeated stress交变载荷 repeated fluctuating load交叉带传动 cross-belt drive交错轴斜齿轮 crossed helical gears胶合 scoring角速度 angular velocity角速比 angular velocity ratio结构 structure结构设计 structural design截面 section节点 pitch point节距 circular pitch; pitch of teeth节线 pitch line节圆 pitch circle节圆齿厚 thickness on pitch circle 节圆直径 pitch diameter节圆锥 pitch cone节圆锥角 pitch cone angle解析设计 analytical design紧边 tight-side紧固件 fastener径节 diametral pitch径向 radial direction径向当量动载荷 dynamic equivalent radial load径向当量静载荷 static equivalent radial load径向基本额定动载荷 basic dynamic radial load rating径向基本额定静载荷 basic static radial load tating径向接触轴承 radial contact bearing 径向平面 radial plane径向游隙 radial internal clearance 径向载荷 radial load径向载荷系数 radial load factor径向间隙 clearance静力 static force静平衡 static balance静载荷 static load绝对运动 absolute motion绝对速度 absolute velocity可靠性 reliability可靠性设计 reliability design, RD理论廓线 pitch curve理论啮合线 theoretical line of action 力矩 moment力平衡 equilibrium力偶 couple力偶矩 moment of couple轮坯 blank螺旋副 helical pair螺旋机构 screw mechanism螺旋角 helix angle螺旋线 helix ,helical line模块化设计 modular design, MD模数 module磨损 abrasion ;wear; scratching耐磨性 wear resistance内齿轮 internal gear内齿圈 ring gear内力 internal force内圈 inner ring啮合 engagement, mesh, gearing啮合点 contact points啮合角 working pressure angle啮合线 line of action啮合线长度 length of line of action 盘形转子 disk-like rotor抛物线运动 parabolic motion疲劳极限 fatigue limit疲劳强度 fatigue strength偏置式 offset偏 ( 心 ) 距 offset distance偏心率 eccentricity ratio偏心质量 eccentric mass偏距圆 offset circle偏心盘 eccentric切齿深度 depth of cut曲齿锥齿轮 spiral bevel gear曲率 curvature曲率半径 radius of curvature曲面从动件 curved-shoe follower曲线运动 curvilinear motion全齿高 whole depth权重集 weight sets球面副 spheric pair球面渐开线 spherical involute球面运动 spherical motion人字齿轮 herringbone gear润滑装置 lubrication device润滑 lubrication三角形花键 serration spline三角形螺纹 V thread screw少齿差行星传动 planetary drive with small teeth difference升程 rise升距 lift实际廓线 cam profile输出轴 output shaft实际啮合线 actual line of action双曲面齿轮 hyperboloid gear顺时针 clockwise瞬心 instantaneous center死点 dead point太阳轮 sun gear特性 characteristics图册、图谱 atlas图解法 graphical method退火 anneal陀螺仪 gyroscope 外力 external force外形尺寸 boundary dimension网上设计 on-net design, OND微动螺旋机构 differential screw mechanism位移 displacement蜗杆 worm蜗杆传动机构 worm gearing蜗杆头数 number of threads蜗杆直径系数 diametral quotient蜗杆蜗轮机构 worm and worm gear蜗杆形凸轮步进机构 worm cam interval mechanism蜗杆旋向 hands of worm蜗轮 worm gear无级变速装置 stepless speed changes devices相对速度 relative velocity相对运动 relative motion相对间隙 relative gap象限 quadrant橡皮泥 plasticine小齿轮 pinion小径 minor diameter谐波齿轮 harmonic gear谐波传动 harmonic driving斜齿轮的当量直齿轮 equivalent spur gear of the helical gear心轴 spindle行程速度变化系数 coefficient of travel speed variation行程速比系数 advance-to return-time ratio行星齿轮装置 planetary transmission 行星轮 planet gear行星轮变速装置 planetary speed changing devices行星轮系 planetary gear train旋转运动 rotary motion压力角 pressure angle应力图 stress diagram应力—应变图 stress-strain diagram 优化设计 optimal design油杯 oil bottle有效圆周力 effective circle force圆带传动 round belt drive圆弧齿厚 circular thickness圆弧圆柱蜗杆 hollow flank worm圆角半径 fillet radius圆盘摩擦离合器 disc friction clutch圆盘制动器 disc brake原动机 prime mover原始机构 original mechanism圆形齿轮 circular gear圆柱滚子 cylindrical roller圆柱滚子轴承 cylindrical roller bearing 圆柱副 cylindric pair圆柱蜗杆 cylindrical worm圆锥滚子 tapered roller圆锥滚子轴承 tapered roller bearing圆锥齿轮机构 bevel gears圆锥角 cone angle运动副 kinematic pair运动粘度 kenematic viscosity载荷 load展成法 generating直齿圆柱齿轮 spur gear直齿锥齿轮 straight bevel gear直径系数 diametral quotient直径系列 diameter series直廓环面蜗杆 hindley worm质量 mass中心距 center distance中心距变动 center distance change中径 mean diameter终止啮合点 final contact, end of contact 周节 pitch轴 shaft轴承盖 bearing cup轴承合金 bearing alloy轴承座 bearing block轴承外径 bearing outside diameter轴颈 journal轴瓦、轴承衬 bearing bush轴端挡圈 shaft end ring轴环 shaft collar轴肩 shaft shoulder轴角 shaft angle轴向 axial direction轴向齿廓 axial tooth profile转动副 revolute (turning) pair转速 swiveling speed ; rotating speed 转轴 revolving shaft转子 rotor装配条件 assembly condition锥齿轮 bevel gear 锥顶 common apex of cone锥距 cone distance锥轮 bevel pulley; bevel wheel锥齿轮的当量直齿轮 equivalent spur gear of the bevel gear锥面包络圆柱蜗杆 milled helicoids worm准双曲面齿轮 hypoid gear自由度 degree of freedom, mobility 总重合度 total contact ratio总反力 resultant force总效率 combined efficiency; overall efficiency组成原理 theory of constitution组合齿形 composite tooth form组合安装 stack mounting最少齿数 minimum teeth number最小向径 minimum radius作用力 applied force坐标系 coordinate frame齿轮及齿轮加工设备的相关词汇A.abrasive tooth wear 齿面研磨磨损absolute tangential velocity 绝对切向速度accelerometer 加速表addendum 齿顶高addendum angle 齿顶角addendum circle 齿顶圆addendum surface 上齿面adhesive wear 粘着磨损adjustability 可调性adjustability coefficients 可调系数adjusting wedge 圆盘端铣刀的可调型楔块allowable stress 允许应力alternate blade cutter 双面刀盘angular backlash 角侧隙angular bevel gears 斜交锥齿轮angular displacement 角移位angular pitch 齿端距angular testing machine 可调角度试验机approach action 啮入arbor 心轴arbor distance 心轴距arc of approach 啮入弧arc of recess 啮出弧attraction 收紧average cutter diameter 平均刀尖直径axial displacement 轴向位移axial factor 轴向系数axial locating surface 轴向定位面axial pitch 轴向齿距axial plane 轴向平面axial rakeangle 轴向前角axial thrust 轴向推力axle testing machine 传动桥试验机B.back angle 背锥角Back angle distance 背角距（在背锥母线方向）Back cone 背锥Back cone distance 背锥距Back cone element 背锥母线Backlash 侧隙Backlash tolerance 侧隙公差Backlash variation 侧隙变量Backlash variation tolerance 侧隙变量公差Bandwidth 频带宽Base circle 基圆Base diameter 基圆直径Base pitch 基节Base radius 基圆半径Base spiral angle 基圆螺旋角Basic rack 基本齿条Bearing 轴承Bearing preload 轴承预负荷Bearing spacing／spread 轴承间距Bending fatigue 弯曲疲劳Bending stress 弯曲应力Bevel gears 锥齿轮Bias 对角接触Bias in 内对角接触Bias out 外对角接触Blade angle 刀齿齿廓角Blade edge radius 刀尖圆角半径Blade letter 刀尖凸角代号Blade life 刀尖寿命Blade point width 刀顶宽Blank offset 毛坯偏置距Bland position 毛坯位置Bottom land 齿槽底面Boundary lubrication 界面润滑Breakage 破裂Bridged contact pattern 桥型接触斑点Broach 拉刀Burnishing 挤齿C．Case crushing 齿面塌陷CBN 立方氮化硼chamfer 倒角chordal addendum 弦齿高chordal thickness 弦齿厚chuck 卡盘circular broach 圆拉刀circular face-mill 圆盘端面铣刀circular peripheral-mill 圆盘铣刀circular pitch 周节circular thickness 弧齿厚circular thickness factor 弧齿厚系数clearance 顶隙clearance angle 后角coarse pitch 大节距coast side 不工作齿侧combination 组合combined preload 综合预负荷complementary crown gears 互补冠状齿轮completing cycle 全工序循环composite action 双面啮合综合检验误差compressive stress 压应力concave side 凹面concentricity 同心度concentricity tester 同心度检查仪cone distance 锥距cone element 锥面母线conformal surfaces 共型表面coniskoid 斜锥齿轮conjugate gears 共轭齿轮conjugate racks 共轭齿条contact fatigue 接触疲劳contact norma 接触点法线contact pattern (tooth contact pattern) 轮齿接触斑点contact ratio 重合度contact stress 接触应力continuous index 连续分度control gear 标准齿轮，检验用齿轮convex side 凸面coolant 冷却液corrosive wear 腐蚀性磨损corrugated tool 阶梯刨刀counter forma surfaces 反法向表面cradle 摇台cradle test roll 摇台角cross 大小端接触crossing point 交错点crown 齿冠crown circle 锥齿轮冠圆crowned teeth 鼓形齿crown gear 冠轮crown to back （轮冠距）轮冠至安装定位面距离crown to crossing point 轮冠至相错点距离cutter 刀盘cutter axial 刀盘的轴向位置cutter axial plane 刀盘轴向平面cutter axis 刀盘轴线cutter diameter 刀盘直径cutter edge radius 刀刃圆角半径cutter head 刀盘体cutter number 刀号cutter parallel 刀盘平垫片cutter point diameter 刀尖直径cutter point radius 刀尖半径cutter point width 刀顶距cutter spindle 刀盘主轴cutter spindle rotation angle 刀盘主轴转角cutting distance 切齿安装距C.V. testing mashing 常速试验机cyclex 格里森粗铣精拉法圆盘端铣刀cylindrical gears 圆柱齿轮D.Datum tooth 基准齿Debur 去毛刺Decibel (CB) （噪音）分贝Decimal ratio 挂轮比值Dedendum 齿根高Dendendum angle 齿根角Dedendum surface 下齿面Deflection 挠曲Deflection test 挠曲试验Deflection testing machine 挠曲试验机Depthwise taper 齿高收缩Design data sheet 设计数据表Destructive pitting 破坏性点蚀Destructive wear 破坏性磨损Developed setting 试切调整Dial indicator 度盘式指示表Diametral pitch 径节Diamond 菱形接触Dinging ball check 钢球敲击检查Disc-mill cuter 盘铣刀Dish angle 凹角Displacement 位移Displacement error 位移误差Double index 双分度Double roll 双向滚动Down roll 向下滚动Drive side 工作齿侧Duplete 双刃刀Duplex 双重双面法Duplex helical 双重螺旋法（加工方法之一）Duplex spread blade 双重双面刀齿（加工／磨齿方法）Duplex taper 双重收缩齿Durability factor 耐久系数Dynamic factor 动载荷系数E Ease-off 修正、失配Eccentric 偏心Eccentric angle 偏心角Eccentricity 偏心度Edge radius 刀尖圆角半径Effective bearing spacing 轴承有效间距Effective face width 有效宽度（有效齿宽）Elastic coefficient 弹性系数Elastic deformation 弹性变形Elastic limit 弹性极限Elastohydrodynamic lubrication 弹性液压润滑Element 母线、要素End movement 轴向移动Endrem 修内端凸轮、导程凸轮Endurance life 耐久寿命Endurance limit 耐久极限Engine torque 发动机扭矩Enveloping 包络EP lubricant, EP 极压润滑剂EPG check, “EPG” 检查Equal addendum teeth 等齿顶高齿Equicurv 等高齿大轮成形法Equidep 等高齿Equiside 等边Equivalent fear ratio 当量传动比Equivalent number of teeth 当量齿数Equivalent pitch radius 当量节圆半径Equivalent rack 当量齿条Expander 涨胎Expanding arbor 可张心轴Extreme pressure lubricant 极压润滑剂F Face acvance 斜齿轮扭曲量Face angle 顶锥角（面锥角）Face angle distance 顶锥角距Face apex 顶锥顶Face apex beyond crossing point 顶锥顶至相错点距离Face cone 顶锥Face cone element 齿顶圆锥母线，面锥母线Face contact ratio 齿长重合度，轴向重合度（圆柱齿轮）Face line 齿面与轴面交线Face width 齿宽Factor of safety 安全系数Fatigue breakage 疲劳破裂Fatigue failure 疲劳失效Fatigue test 疲劳测试Feed cam 进给凸轮Feed gears 进给齿轮Fillet 齿根圆角Fillet curve 齿根过渡曲线Fillet radius 齿根圆角半径Film strength 液膜强度Filter (electronic) （电子的）滤波器Filter (mechanical) （机械的）滤波器Fine pitch （小模数）细径节Finisher 精切机床Fishtail 鱼尾形Fixed setting 固定安装法Flank 下齿面Flanking 下齿面加工Formarc 加工齿轮用的曲线齿廓刀具Formate 成形法Former 齿廓样板，靠模Forming 成型，在磨具内挤压成型Form tool 成形刀Fourier analysis 傅里叶分析Frequency 频率Friction load 摩擦负荷Front angle 前角Front cone 前锥Front crown 前锥齿冠Front crown to crossing point 前锥齿冠至交错点Full-depth teeth 全齿高齿Fundametal 基频G Gable 山形齿沟底面Gear 齿轮Gear axial displacement 齿轮轴向位移Gear axial plane 齿轮轴向平面Gear axis 齿轮轴线Gear center 齿轮中心Gear combination 齿轮组合Gear cone 大轮锥距Geared index 齿轮系分度Gear finisher 成形法齿轮精切机床Gear manufacturing summary 齿轮加工调整卡Gear marking compound 检查齿轮啮合涂色剂Gear member 大轮Gear planer 成型刨齿机Gear ratio 齿数比Gear rougher 齿轮粗切机床Gears 齿轮组Gear tipping 齿轮倾斜Generated gear 展成法齿轮Generating cam 展成凸轮Generating gear 展成齿轮Generating pressure angle 产形轮压力角Generating train 展成传动键Generation 展成Generator 展成齿轮加工机床Geneva index 星形轮分度，槽轮分度Geometry factor-durability 齿面接触强度几何系数Geometry factor0-strength 强度几何系数G-flow 格里森制金属件的商标，采用冷挤压成形法G-form 采用热锻成形法制造GLE-sine 砂轮内外压力角正弦波进行修整用机构G-plete 全工序法Gradeability 托曳力Grinding cracks 磨削裂纹G-spin 精密主轴的机床G-trac 圆柱齿轮的无端链式机床的商标H．Hand of cutter 刀盘方向Hand of spiral 螺旋方向。

•齿轮的主要术语轮齿（齿）——齿轮上的每一个用于啮合的凸起部分。

一般说来，这些凸起部分呈辐射状排列。

配对齿轮上轮齿互相接触，导致齿轮的持续啮合运转。

齿槽——齿轮上两相邻轮齿之间的空间。

端面——在圆柱齿轮或圆柱蜗杆上垂直于齿轮或蜗杆轴线的平面。

法面——在齿轮上，法面指的是垂直于轮齿齿线的平面。

齿顶圆——齿顶端所在的圆。

齿根圆——槽底所在的圆。

基圆——形成渐开线的发生线在其上作纯滚动的圆。

分度圆——在端面内计算齿轮几何尺寸的基准圆，对于直齿轮，在分度圆上模数和压力角均为标准值。

齿面——轮齿上位于齿顶圆柱面和齿根圆柱面之间的侧表面。

齿廓——齿面被一指定曲面（对圆柱齿轮是平面）所截的截线。

齿线——齿面与分度圆柱面的交线。

端面齿距——相邻两同侧端面齿廓之间的分度圆弧长。

模数m——齿距除以圆周率π所得到的商,以毫米计。

径节p——模数的倒数，以英寸计。

齿厚s ——在端面上一个轮齿两侧齿廓之间的分度圆弧长。

槽宽e——在端面上一个齿槽的两侧齿廓之间的分度圆弧长。

齿顶高hɑ──齿顶圆与分度圆之间的径向距离。

齿根高hf──分度圆与齿根圆之间的径向距离。

全齿高h──齿顶圆与齿根圆之间的径向距离。

齿宽b──轮齿沿轴向的尺寸。

端面压力角ɑt── 过端面齿廓与分度圆的交点的径向线与过该点的齿廓切线所夹的锐角。

基准齿条(Standard Rack) ——只基圆之尺寸,齿形,全齿高,齿冠高及齿厚等尺寸均合乎标准正齿轮规格之齿条,依其标准齿轮规格所切削出来之齿条称为基准齿条.基准节圆(Standard Pitch Circle) ——用来决定齿轮各部尺寸基准圆.为齿数x模数基准节线(Standard Pitch Line) ——齿条上一条特定节线或沿此线测定之齿厚,为节距二分之一.作用节圆(Action Pitch Circle) ——一对正齿轮咬合作用时,各有一相切做滚动圆.基准节距(Standard Pitch) ——以选定标准节距做基准者,与基准齿条节距相等.节圆(Pitch Circle) ——两齿轮连心线上咬合接触点各齿轮上留下轨迹称为节圆.节径(Pitch Diameter) ——节圆直径.有效齿高(Working Depth) ——一对正齿轮齿冠高和.又称工作齿高.齿冠高(Addendum) ——齿顶圆与节圆半径差.齿隙(Backlash) ——两齿咬合时,齿面与齿面间隙.齿顶隙(Clearance) ——两齿咬合时,一齿轮齿顶圆与另一齿轮底间空隙.节点(Pitch Point) ——一对齿轮咬合与节圆相切点.节距(Pitch) ——相邻两齿间相对应点弧线距离.法向节距(Normal Pitch) ——渐开线齿轮沿特定断面同一垂线所测节距.A.1. abrasive tooth wear 齿面研磨磨损2. absolute tangential velocity 绝对切向速度3. accelerometer 加速表4. addendum 齿顶高5. addendum angle 齿顶角6. addendum circle 齿顶圆7. addendum surface 上齿面8. adhesive wear 粘着磨损9. adjustability 可调性10. adjustability coefficients 可调系数11. adjusting wedge 圆盘端铣刀的可调型楔块12. allowable stress 允许应力13. alternate blade cutter 双面刀盘14. angular backlash 角侧隙15. angular bevel gears 斜交锥齿轮16. angular displacement 角移位17. angular pitch 齿端距18. angular testing machine 可调角度试验机19. approach action 啮入20. arbor 心轴21. arbor distance 心轴距22. arc of approach 啮入弧23. arc of recess 啮出弧24. attraction 收紧25. average cutter diameter 平均刀尖直径26. axial displacement 轴向位移27. axial factor 轴向系数28. axial locating surface 轴向定位面29. axial pitch 轴向齿距30. axial plane 轴向平面31. axial rakeangle 轴向前角32. axial thrust 轴向推力33. axle testing machine 传动桥试验机B.1． back angle 背锥角2． Back angle distance 背角距（在背锥母线方向）3． Back cone 背锥4． Back cone distance 背锥距5． Back cone element 背锥母线6． Backlash 侧隙7． Backlash tolerance 侧隙公差8． Backlash variation 侧隙变量9． Backlash variation tolerance 侧隙变量公差10． Bandwidth 频带宽11． Base circle 基圆12． Base diameter 基圆直径13． Base pitch 基节14． Base radius 基圆半径15． Base spiral angle 基圆螺旋角16． Basic rack 基本齿条17． Bearing 轴承18． Bearing preload 轴承预负荷19． Bearing spacing／spread 轴承间距20． Bending fatigue 弯曲疲劳21． Bending stress 弯曲应力22． Bevel gears 锥齿轮23． Bias 对角接触24． Bias in 内对角接触25． Bias out 外对角接触26． Blade angle 刀齿齿廓角27． Blade edge radius 刀尖圆角半径28． Blade letter 刀尖凸角代号29． Blade life 刀尖寿命30． Blade point width 刀顶宽31． Blank offset 毛坯偏置距32． Bland position 毛坯位置33． Bottom land 齿槽底面34． Boundary lubrication 界面润滑35． Breakage 破裂36． Bridged contact pattern 桥型接触斑点37． Broach 拉刀38． Burnishing 挤齿C．1. Case crushing 齿面塌陷2. CBN 立方氮化硼3. chamfer 倒角4. chordal addendum 弦齿高5. chordal thickness 弦齿厚6. chuck 卡盘7. circular broach 圆拉刀8. circular face-mill 圆盘端面铣刀9. circular peripheral-mill 圆盘铣刀10. circular pitch 周节11. circular thickness 弧齿厚12. circular thickness factor 弧齿厚系数13. clearance 顶隙14. clearance angle 后角15. coarse pitch 大节距16. coast side 不工作齿侧17. combination 组合18. combined preload 综合预负荷19. complementary crown gears 互补冠状齿轮20. completing cycle 全工序循环21. composite action 双面啮合综合检验误差22. compressive stress 压应力23. concave side 凹面24. concentricity 同心度25. concentricity tester 同心度检查仪26. cone distance 锥距27. cone element 锥面母线28. conformal surfaces 共型表面29. coniskoid 斜锥齿轮30. conjugate gears 共轭齿轮31. conjugate racks 共轭齿条32. contact fatigue 接触疲劳33. contact norma 接触点法线34. contact pattern (tooth contact pattern) 轮齿接触斑点35. contact ratio 重合度36. contact stress 接触应力37. continuous index 连续分度38. control gear 标准齿轮，检验用齿轮39. convex side 凸面40. coolant 冷却液41. corrosive wear 腐蚀性磨损42. corrugated tool 阶梯刨刀43. counter forma surfaces 反法向表面44. cradle 摇台45. cradle test roll 摇台角46. cross 大小端接触47. crossing point 交错点48. crown 齿冠49. crown circle 锥齿轮冠圆50. crowned teeth 鼓形齿51. crown gear 冠轮52. crown to back （轮冠距）轮冠至安装定位面距离53. crown to crossing point 轮冠至相错点距离54. cutter 刀盘55. cutter axial 刀盘的轴向位置56. cutter axial plane 刀盘轴向平面57. cutter axis 刀盘轴线58. cutter diameter 刀盘直径59. cutter edge radius 刀刃圆角半径60. cutter head 刀盘体61. cutter number 刀号62. cutter parallel 刀盘平垫片63. cutter point diameter 刀尖直径64. cutter point radius 刀尖半径65. cutter point width 刀顶距66. cutter spindle 刀盘主轴67. cutter spindle rotation angle 刀盘主轴转角68. cutting distance 切齿安装距69. C.V. testing mashing 常速试验机70. cyclex 格里森粗铣精拉法圆盘端铣刀71. cylindrical gears 圆柱齿轮D.1． Datum tooth 基准齿2． Debur 去毛刺3． Decibel (CB) （噪音）分贝4． Decimal ratio 挂轮比值5． Dedendum 齿根高6． Dendendum angle 齿根角7． Dedendum surface 下齿面8． Deflection 挠曲9． Deflection test 挠曲试验10． Deflection testing machine 挠曲试验机11． Depthwise taper 齿高收缩12． Design data sheet 设计数据表13． Destructive pitting 破坏性点蚀14． Destructive wear 破坏性磨损15． Developed setting 试切调整16． Dial indicator 度盘式指示表17． Diametral pitch 径节18． Diamond 菱形接触19． Dinging ball check 钢球敲击检查20． Disc-mill cuter 盘铣刀21． Dish angle 凹角22． Displacement 位移23． Displacement error 位移误差24． Double index 双分度25． Double roll 双向滚动26． Down roll 向下滚动27． Drive side 工作齿侧28． Duplete 双刃刀29． Duplex 双重双面法30． Duplex helical 双重螺旋法（加工方法之一）31． Duplex spread blade 双重双面刀齿（加工／磨齿方法）32． Duplex taper 双重收缩齿33． Durability factor 耐久系数34． Dynamic factor 动载荷系数E1． Ease-off 修正、失配2． Eccentric 偏心3． Eccentric angle 偏心角4． Eccentricity 偏心度5． Edge radius 刀尖圆角半径6． Effective bearing spacing 轴承有效间距7． Effective face width 有效宽度（有效齿宽）8． Elastic coefficient 弹性系数9． Elastic deformation 弹性变形10． Elastic limit 弹性极限11． Elastohydrodynamic lubrication 弹性液压润滑12． Element 母线、要素13． End movement 轴向移动14． Endrem 修内端凸轮、导程凸轮15． Endurance life 耐久寿命16． Endurance limit 耐久极限17． Engine torque 发动机扭矩18． Enveloping 包络19． EP lubricant, EP 极压润滑剂20． EPG check, “EPG”检查21． Equal addendum teeth 等齿顶高齿22． Equicurv 等高齿大轮成形法23． Equidep 等高齿24． Equiside 等边25． Equivalent fear ratio 当量传动比26． Equivalent number of teeth 当量齿数27． Equivalent pitch radius 当量节圆半径28． Equivalent rack 当量齿条29． Expander 涨胎30． Expanding arbor 可张心轴31． Extreme pressure lubricant 极压润滑剂F.1． Face acvance 斜齿轮扭曲量2． Face angle 顶锥角（面锥角）3． Face angle distance 顶锥角距4． Face apex 顶锥顶5． Face apex beyond crossing point 顶锥顶至相错点距离6． Face cone 顶锥7． Face cone element 齿顶圆锥母线，面锥母线8． Face contact ratio 齿长重合度，轴向重合度（圆柱齿轮）9． Face line 齿面与轴面交线10． Face width 齿宽11． Factor of safety 安全系数12． Fatigue breakage 疲劳破裂13． Fatigue failure 疲劳失效14． Fatigue test 疲劳测试15． Feed cam 进给凸轮16． Feed gears 进给齿轮17． Fillet 齿根圆角18． Fillet curve 齿根过渡曲线19． Fillet radius 齿根圆角半径20． Film strength 液膜强度21． Filter (electronic) （电子的）滤波器22． Filter (mechanical) （机械的）滤波器23． Fine pitch （小模数）细径节24． Finisher 精切机床25． Fishtail 鱼尾形26． Fixed setting 固定安装法27． Flank 下齿面28． Flanking 下齿面加工29． Formarc 加工齿轮用的曲线齿廓刀具30． Formate 成形法31． Former 齿廓样板，靠模32． Forming 成型，在磨具内挤压成型33． Form tool 成形刀34． Fourier analysis 傅里叶分析35． Frequency 频率36． Friction load 摩擦负荷37． Front angle 前角38． Front cone 前锥39． Front crown 前锥齿冠40． Front crown to crossing point 前锥齿冠至交错点41． Full-depth teeth 全齿高齿42． Fundametal 基频G.1． Gable 山形齿沟底面2． Gear 齿轮3． Gear axial displacement 齿轮轴向位移4． Gear axial plane 齿轮轴向平面5． Gear axis 齿轮轴线6． Gear center 齿轮中心7． Gear combination 齿轮组合8． Gear cone 大轮锥距9． Geared index 齿轮系分度10． Gear finisher 成形法齿轮精切机床11． Gear manufacturing summary 齿轮加工调整卡12． Gear marking compound 检查齿轮啮合涂色剂13． Gear member 大轮14． Gear planer 成型刨齿机15． Gear ratio 齿数比16． Gear rougher 齿轮粗切机床17． Gears 齿轮组18． Gear tipping 齿轮倾斜 @U UlsC|3.19． Generated gear 展成法齿轮20． Generating cam 展成凸轮21． Generating gear 展成齿轮22． Generating pressure angle 产形轮压力角23． Generating train 展成传动键24． Generation 展成25． Generator 展成齿轮加工机床26． Geneva index 星形轮分度，槽轮分度27． Geometry factor-durability 齿面接触强度几何系数28． Geometry factor0-strength 强度几何系数29． G-flow 格里森制金属件的商标，采用冷挤压成形法30． G-form 采用热锻成形法制造31． GLE-sine 砂轮内外压力角正弦波进行修整用机构32． G-plete 全工序法33． Gradeability 托曳力34． Grinding cracks 磨削裂纹35． G-spin 精密主轴的机床36． G-trac 圆柱齿轮的无端链式机床的商标H．1． Hand of cutter 刀盘方向2． Hand of spiral 螺旋方向3． Hand-rolling tester 手动滚动试验机4． Hardac 镶篇淬硬刀体精切刀盘5． Hard finishing 硬齿面精加工6． Hardness ratio factor 硬度比系数7． Harmonic 谐振8． Harmonic search 谐振追踪9． Harmonic sweep 谐振扫描10． Heel 轮齿大端11． Heel pattern 大端接触12． Helical duplex 双重螺旋法13． Helical motion 螺旋运动14． Helixact 螺旋运动法15． Helixform 螺旋成形法16． Hertz (Hz) 赫兹17． Hook angle 断面前角18． Horizontal displacement 水平位移19． Horizontal offset 水平偏置20． HRH 高减速比准双曲面齿轮（大于10：1的减速比）21． Hunting tooth combination 大小齿轮齿数无公因数的齿轮副22． Hudrodynamic lubrication 液压润滑23． Hupermesh 超配合24． Hypoid gears 准双曲面齿轮25． Hypoid offset 准双曲面齿轮偏置距I.1． Imaginary generating gear 假想成形法2． Incremental index 逐齿分度3． Index gears 分度齿轮4． Index interval 分度跳跃齿齿数5． Index plate 分度盘6． Index tolerance 分度公差7． Index variation 分度变化量8． Indicator anchorage 指示表支撑座9． Inertia factor 惯量系数10． Initial pitting 初期点蚀11． Inner addendum 小端齿顶高12． Inner cone distance 小端锥距13． Inner dedendum 小端齿根高14． Inner slot width 小端槽宽15． Inner spiral angle 小端螺旋角16． Inserted blade cutter 镶片刀盘17． Inside blade 内切刀齿18． Inside point diameter 内切刀尖直径19． Instantaneous contact pattern 瞬时接触斑点20． Interference 干涉21． Interference point 干涉点22． Interlocking disc-mill cutters 交错齿盘形铣刀23． Intermittent index 间断分度24． Internal bevel gear 内锥齿轮25． Inverse gear ratio 反齿数比26． Involute 渐开线27． Involute gear 渐开线齿轮28． Involute interference point 渐开线干涉点29． Involute spiral angle 渐开线螺旋角30． Involute teeth 渐开线齿J.1． Jet lubrication 喷射润滑L.1． Lame 顶根接触2． Lapping 研磨3． Lead cam 导程凸轮4． Length of action 啮合长度5． Lengthwise bridge 纵向桥型接触6． Lengthwise mismatch 纵向失配7． Lengthwise sliding velocity 纵向滑动速度8． Life factor 寿命系数9． Lift 垂直位移10． Limit point width 极限刀顶距11． Limit pressure angle 极限压力角12． Linear displacement transducer 线性位移传感器13． Line of action 啮合线14． Line of centers 中心线15． Line of contact 接触线16． Load sharing ratio 负荷分配比17． Localized tooth contact 齿局部接触18． Locating surface 定位表面19． Long-and-short-addendum teeth 高变位齿轮20． Long-toe-short-heel 小端长，大端短接触21． Lubricant 润滑剂22． Lubrication 润滑23． Lubricity 润滑性M.1． Machine center 基床中心点2． Machine center to back 机床中心至工件安装基准面3． Machine plane 机床切削平面4． Machine root angle 毛坯安装角5． Marking compound 检查齿轮啮合型情况使用的涂色剂6． Master blade 标准刀齿7． Master gear 标准齿轮8． Mean addendum 中点齿顶高9． Mean cone distance 中点锥距10． Mean dedendum 中点齿根高11． Mean diametral pitch 中点径节12． Mean measuring addendum 中点测量齿顶高13． Mean measuring depth 中点测量齿高14． Mean measuring thickness 中点测量厚度15． Mean normal base pitch 中点法向基节16． Mean normal diameter pitch 中点法向径节17． Mean normal module 中点法向模数18． Mean point 中点，平均点19． Mean radius 中点半径20． Mean section 中点截面21． Mean slot width 中点齿槽宽22． Mean spiral angle 中点螺旋角23． Measuring addendum 测量齿顶高24． Measuring tooth thickness 测量齿厚25． Member 齿轮，元件26． Mesh point 啮合点27． Minimum slot width 最小槽宽28． Mismatch 失配29． Miter gears 等齿数整角锥齿轮副30． Mixed lubrication 混合润滑31． Modified contact ratio 修正总重合度32． Modified roll 滚修正比33． Module 模数34． Motion curves 运动曲线35． Motor torque 电机扭矩36． Mounting distance 安装距37． Mounting surface 安装面英语站N.1． Narrow-tow-wide-heel 小端窄大端宽接触2． No load 空载3． Nominal 名义4． Non-generated gear 非展成大轮5． Normal 法向，法线，法面6． Normal backlash 法向侧隙7． Normal backlash tolerance 法向侧隙公差8． Normal base pitch 法向基节9． Normal chordal addendum 法向弦齿高10． Normal chordal thickness 法向弦齿厚11． Normal circular pitch 法向周节12． Normal circular thickness 法向弧齿厚13． Normal contact ratio 法向重合度14． Normal diametral pitch 法向径节15． Normal direction 法线方向16． Normal (perpendicular) load 法向（垂直）负载17． Normal module 法向模数18． Normal plane 法向平面19． Normal pressure angle 法向压力角20． Normal section 法向截面21． Normal space-width taper 正常齿槽宽收缩22． Normal thickness taper 正常齿厚收缩23． Normal tilt 法向刀倾24． Normal wear 正常磨损25． No-roll roughing 无滚动粗切26． Number of teeth 齿数英语站O．1． Octoid teeth 锥齿轮的“8”字啮合2． Offset 偏置距3． Operating load 工作负荷4． Operating pressure angle 工作压力角5． Operating torque 工作扭矩6． Outer addendum 大端齿顶高7． Outer cone distance 外锥距8． Outer dedendum 大端齿根高9． Outer slot width 大端槽宽10． Outer spiral angle 大端螺旋角11． Outside blade 外切刃点12． Outside diameter 外径，大端直径14． Outside radius 齿顶圆半径15． Outside surface 外表面16． Overhung mounting 双支承安装17． Overload breakage 超负荷破裂18． Overload factor 超负荷系数英语站P.1． Path of action 啮合点轨迹2． Path of contact 接触迹3． Peak load 峰值负荷4． Peak torque 峰值扭矩5． Pedestal bearings 安装差速器壳的架座轴承6． Performance torque 性能扭矩7． Perim-mate 研磨锥齿轮和准双面齿轮用的全齿面研磨法8． Pinion 小轮9． Pinion axial displacement 小轮轴向位移10． Pinion cone 小轮锥距11． Pinion front bearing 小轮前端轴承12． Pinion head bearing 小轮后端前轴承13． Pinion rear bearing 小轮后端后轴承14． Pinion rougher 小轮粗切机15． Pinion offset 小轮偏置距16． Pitch 节距，齿距17． Pitch angle 节锥角18． Pitch apex 节锥顶19． Pitch apex beyond crossing point 节锥顶超出至相错点20． Pitch apex to back 节锥顶至安装端面21． Pitch apex to crown 节锥顶至轮冠22． Pitch circle 节圆23． Pitch cone 节锥24． Pitch curve 节面曲线25． Pitch diameter 节径26． Pitch element 节面母线27． Pitch line 节线28． Pitch-line chuck 节圆夹具 u< ` da E29． Pitch-line runout 节线跳动30． Pitch plane 节面31． Pitch point 节点32． Pitch radius 节圆半径33． Pitch surfaces 节曲面34． Pitch tolerance 齿距公差35． Pitch trace 节线36． Pitch variation 齿距变化量37． Pitting 点蚀38． Plane of action 啮合平面39． Plane of rotation 旋转平面40． Planning generator 展成法刨齿机41． Plastic deformation 塑性变形42． Plastic flow 塑性流动43． Plate index 分度盘44． Point diameter 刀尖直径45． Point of contact 接触点46． Point radius 刀尖半径47． Point width 刀顶距48． Point width taper 刀顶距收缩49． Pressure lubrication 压力润滑50． Prime mover torque 原动机扭矩51． Profile angle 齿廓角52． Profile bridge 齿廓桥形接触53． Profile contact ratio 齿廓重合度54． Profile mismatch 齿廓啮合失配55． Profile radius of curvature 齿廓曲率半径56． Proof surface 检测基准面Q．1． Quality measurement system 质量检测系统2． Quenching cracks 淬火裂纹3． Quenching die 淬火压模4． Quenching press 淬火压床英语站R．1． Rack 齿条2． Radial 径向刀位3． Radial load 径向负荷4． Radial locating surface 径向定位表面5． Radial rake angle 径向前角6． Ratio control roughing 变滚比粗切7． Ratio gears 滚比挂轮8． Ratio of roll 滚比9． Ratio of roll gears 滚比挂轮10． Recess action 啮出11． Relative displacement 相对位移12． Relative movement 相对运动13． Relative radius of curvature 相对曲率半径14． Residual stress 残余应力15． Revacycle 直齿锥齿轮圆拉法用机床及刀具16． Revex 直齿锥齿轮粗拉法17． Ridg-AC 镶片圆盘端面粗铣刀18． Ridging 沟条变形19． Ring gear 大轮，环形齿轮20． Rippling 振纹21． Roll centering 滚动定心22． Roll queching 滚动式淬火压床23． Roll gears 摆角挂轮24． Rolling 滚轧25． Rolling velocity 滚动速度26． Root angle 根锥角27． Root angle tilt 齿根角倾斜28． Root apex 根锥顶29． Root apex beyond crossing point 根锥顶至相错点的距离30． Root apex to back 根锥顶至安装基准面距离31． Root circle 齿根圆32． Root cone 根锥33． Root diameter 根圆直径34． Root line 齿根线35． Root radius 根圆半径36． Root surface 齿根曲面37． Roughac 弧齿锥齿轮粗切刀38． Rougher 粗切机39． RSR 弧齿锥齿轮条形刀齿铣刀盘40． Runout 径向跳动41． Runout tolerance 径向跳动公差S.1． Scoring 胶合2． Scoring index 胶合指数3． Scuffing 胶合4． Sector 扇形齿／齿弧5． Segment 扇形齿／体6． Segmental-blade cutter 大轮精切刀7． Separation 分离间隙8． Separating factor 分离系数9． Separating force 分离力10． Set-in 补充切入，进刀11． Set-over 补充转角，调整转换12． Shaft angle 轴转角13． Shot peening 喷丸强化14． Sidebank 边频15． Side movement 侧向位移16． Side rake angle 侧前角17． Single cycle 单循环法18． Single roll 单滚动19． Single setting 单面调整法20． Single side 单面精切法21． Single-side taper 齿槽收缩22． Size factor 尺寸系数23． Skew bevel gears 斜直齿锥齿轮24． Skip index 跳齿分度25． Slide-roll ratio 单位滑滚比，比滑26． Sliding base 床鞍，滑座27． Sliding base setting 床鞍调整，滑座调整28． Sliding velocity 滑动速度29． Slip-chip 直齿锥齿轮一次成形刀30． Slip torque 滑移扭矩31． Slotting tool 切槽刀32． Slot width 槽宽33． Slot-width taper 槽宽收缩34． Small cutter development 小刀盘试切，能产生接近渐开线的刀具35． Solid cutter 整体刀盘36． Sound test 噪声试验37． Space-width taper 齿距收缩38． Spacing tolerance 齿距公差39． Spacing variation 齿距变动量40． Spalling 剥落41． Specific sliding 单位滑动比42． Speed gears 速度挂轮43． Spherical involute teeth 球面渐开线齿44． Spherica limacon teeth 球面钳线齿45． Spindle rotation angle 主轴旋转角46． Spiral angle 螺旋角47． Spiral bevel gears 弧齿锥齿轮48． Splash lubrication 飞溅润滑49． Split profile 齿型中断50． Spread blade 双面刀51． Spread blade 双面刀渐缩52． Standard depthwise taper 标准深锥度53． Standard taper 正常收缩54． Standard thickness 正常齿厚收缩55． Stock allowance 毛坯加工流量56． Straddle cutter 双列刀齿刀盘57． Straddle mounting 跨装58． Straight bevel gears 直齿锥齿轮59． Strength factor 强度系数英语站60． Stress concentration factor 应力集中系数61． Stub teeth 短齿62． Subsurface initiated fatigue breakage 金属表面斜层初始疲劳破裂63． Summary of machine settings 机床调整卡64． Sump lubrication 油槽润滑65． Sum velocity 总速度66． Surface asperities 表面粗糙度67． Surface condition factor 表面条件系数68． Surface deformation 表面变形69． Surface durability 表面耐久度70． Surface fatigue 表面疲劳71． Surface initiated fatigue breakage 表面初始疲劳破裂72． Surface of action 啮合面73． Surface of revolution 回转面74． Surface treatment 表面处理75． Swinging base 回转底座76． Swing pinion cone 摆动小轮节锥法77． Swivel 刀转78． Swivel angle 刀转角79． Symmetrical rack 对称齿条80． Symmetrical rack proportions 对称齿条比例T.1． Tangential load 切向负荷2． Tangent plane 切平面3． Tanline 小轮夹具4． Tanruf 双联粗切刀，8.5模数一下5． Tan-tru 用在加工1016－2540mm的锥齿刀具6． Taper roughing 具有刀顶距收缩的大小轮粗切过程7． Temperature factor 温度系数8． Testing machine 试验机9． Thickness taper 齿厚收缩10． Tilt 刀倾11． Tilt angle 刀倾角12． Tilted rootline taper 倾斜齿根收缩13． Tip radius 齿顶圆角半径14． Toe 轮齿小端15． Toe pattern 小端接触16． Tool 刀具17． Tool advance 刀具进刀18． Tool edge radius 刀刃圆角半径19． Tool point width 刀顶距20． Tooth angle 齿角21． Tooth bearing 齿支撑面，轮齿接触面22． Tooth contact analysis 轮齿接触分析23． Tooth contact pattern 轮齿接触斑点24． Tooth horizontal 齿水平面25． Tooth layout 轮齿剖面图26． Tooth-mesh frequency 齿啮合频率27． Tooth number 齿数28． Tooth profile 齿形，齿廓29． Tooth spacing testing 齿距检查仪30． Tooth spiral 齿螺旋线31． Tooth surface 轮齿表面32． Tooth taper 轮齿收缩33． Tooth-to-tooth composite tolerance 一齿度量中心距公差34． Tooth-to- Tooth composite variation 一齿度量中心距变量35． Tooth trace 齿线36． Tooth vertical 齿垂直面37． Top 齿顶38． Topland 齿顶面39． Topland width 齿顶面宽度40． Topping 修顶41． Top relief angle 顶刃后角42． Toprem 修根刀片43． Toprem angle 刀齿突角角度44． Top slope angle 刀齿顶刃倾角45． Total composite tolerance 总综合公差46． Total composite variation 总度量中心距变动量47． Total contact ratio 总重合度48． Total index tolerance 总分度公差49． Total index variation 总分度变动量50． Tractive effort torque 牵引力扭矩51． Transverse circular pitch 端面周节52． Transverse circular thickness 端面弧齿厚53． Transverse contact ratio 端面重合度54． Transverse diametral pitch 端面径节55． Transverse module 端面模数56． Transverse plane 端平面57． Transverse pressure angle 端面压力角58． Transverse space-width taper 端面槽宽收缩59． Transverse thickness taper 端面齿厚收缩60．Tredgold’s approximation 背锥近似法61． Tribology 润滑与磨损学62． Triplex 三面刃圆盘端铣刀63． Two-tool generator 双刀展成加工机床U.1． Undercut 根切2． Undeveloped settings 试切前调整3． Uniform roll 匀速滚动4． Uniform velocity tester 匀速试验机5． Uni-spand 大轮心轴6． Unit load 单位负荷7． Unitool 曲面镶片刀8． Up-roll 向上滚动V.1． V and H check 锥齿轮啮合的VH检查2． Variable roll 变滚动3． Velocity factor 速度系数4． Versacut 弧齿锥齿轮加工多用刀盘5． Vers-grip 卡紧小齿轮用的卡盘（商标名称）6． Vertical direction 垂直方向7． Vertical displacement 垂直位移8． Vertical factor 垂直系数9． Vertical force 垂直力10． Vertical offset 垂直偏置距11． Vertical plane 垂直面12． Virtual number of teeth 当量齿数13． Virtual pitch radius 当量节圆半径14． Viscosity 粘度15． V-tool V型刀具W.1． Waveform 波形2． Wear 磨损3． Webless-type gear 无幅板式齿轮4． Web-type gear 幅板式齿轮5． Wheel slip torque 车轮打滑扭矩6． Whole depth 齿全高7． Workhead 工件头座8． Workhead offset 垂直轮位9． Workholding equipment 工件夹具10． Working depth 工作齿高11． Working stress 工作允许应力12． Work tests roll 检验工件主轴转角X.1．X-pandisk 大轮蝶形，涨胎心轴Z.1． Zero depthwise taper 等齿高2． Zerol 零度锥齿轮。

Gears and gear driveGears are the most durable and rugged of all mechanical drives. They can transmit high power at efficiencies up to 98% and with long service lives. For this reason, gears rather than belts or chains are found in automotive transmissions and most heavy-duty machine drives. On the other hand, gears are more expensive than other drives, especially if they are machined and not made from power metal or plastic.Gear cost increases sharply with demands for high precision and accuracy. So it is important to establish tolerance requirements appropriate for the application. Gears that transmit heavy loads or than operate at high speeds are not particularly expensive, but gears that must do both are costly.Silent gears also are expensive. Instrument and computer gears tend to be costly because speed or displacement ratios must be exact. At the other extreme, gears operating at low speed in exposed locations are normally termed no critical and are made to minimum quality standards.For tooth forms, size, and quality, industrial practice is to follow standards set up by the American Gear Manufactures Association (AGMA).Tooth formStandards published by AGMA establish gear proportions and tooth profiles. Tooth geometry is determined primarily by pitch, depth, and pressure angle.Pitch：Standards pitches are usually whole numbers when measured as diametral pitch P. Coarse-pitch gearing has teeth larger than 20 diametral pitch –usually 0.5 to 19.99. Fine-pitch gearing usually has teeth of diametral pitch 20 to 200.Depth: Standardized in terms of pitch. Standard full-depth have working depth of 2/p. If the teeth have equal addenda(as in standard interchangeable gears) the addendum is 1/p. Stub teeth have a working depth usually 20% less than full-depth teeth. Full-depth teeth have a larger contract ratio than stub teeth. Gears with small numbers of teeth may have undercut so than they do not interfere with one another during engagement. Undercutting reduce active pro weakens the tooth.Mating gears with long and short addendum have larger load-carrying capacity than standard gears. The addendum of the smaller gear (pinion) is increased while that of largergear is decreased, leaving the whole depth the same. This form is know as recess-action gearing.Pressure Angle: Standard angles are 025. Earlier standards include a20and 014-02/1pressure angle that is still used. Pressure angle affects the force that tends to separate mating gears. High pressure angle decreases the contact ratio (ratio of the number of teeth in contact) but provides a tooth of higher capacity and allows gears to have fewer teeth without undercutting.Backlash: Shortest distances between the non-contacting surfaces of adjacent teeth .Gears are commonly specified according to AGMA Class Number, which is a code denoting important quality characteristics. Quality number denote tooth-element tolerances. The higher the number, the closer the tolerance. Number 8 to 16 apply to fine-pitch gearing.Gears are heat-treated by case-hardening, through-hardening, nitriding, or precipitation hardening. In general, harder gears are stronger and last longer than soft ones. Thus, hardening is a device that cuts the weight and size of gears. Some processes, such as flame-hardening, improve service life but do not necessarily improve strength.Design checklistThe larger in a pair is called the gear, the smaller is called the pinion.Gear Ratio: The number of teeth in the gear divide by the number of teeth in the pinion. Also, ratio of the speed of the pinion to the speed of the gear. In reduction gears, the ratio of input to output speeds.Gear Efficiency:Ratio of output power to input power. (includes consideration of power losses in the gears, in bearings, and from windage and churning of lubricant.) Speed: In a given gear normally limited to some specific pitchline velocity. Speed capabilities can be increased by improving accuracy of the gear teeth and by improving balance of the rotating parts.Power: Load and speed capacity is determined by gear dimensions and by type of gear. Helical and helical-type gears have the greatest capacity (to approximately 30,000 hp). Spiral bevel gear are normally limited to 5,000 hp, and worm gears are usually limited to about 750 hp.Special requirementsMatched-Set Gearing:In applications requiring extremely high accuracy, it may benecessary to match pinion and gear profiles and leads so that mismatch does not exceed the tolerance on pro lead for the intended application.Tooth Spacing:Some gears require high accuracy in the circular of teeth. Thus, specification of pitch may be required in addition to an accuracy class specification.Backlash:The AMGA standards recommend backlash ranges to provide proper running clearances for mating gears. An overly tight mesh may produce overload. However, zero backlash is required in some applications.Quiet Gears: To make gears as quit as possible, specify the finest pitch allowable for load conditions. (In some instances, however, pitch is coarsened to change mesh frequency to produce a more pleasant, lower-pitch sound.) Use a low pressure angle. Use a modified pro include root and tip relief. Allow enough backlash. Use high quality numbers. Specify a surface finish of 20 in. or better. Balance the gear set. Use a nonintegral ratio so that the same teeth do not repeatedly engage if both gear and pinion are hardened steel. (If the gear is made of a soft material, an integral ratio allows the gear to cold-work and conform to the pinion, thereby promoting quiet operation.) Make sure critical are at least 20% apart from operating speeding or speed multiples and from frequency of tooth mesh.Multiple mesh gearMultiple mesh refers to move than one pair of gear operating in a train. Can be on parallel or nonparallel axes and on intersection or nonintersecting shafts. They permit higer speed ratios than are feasible with a single pair of gears .Series trains:Overall ratio is input shaft speed divided by output speed ,also the product of individual ratios at each mesh ,except in planetary gears .Ratio is most easily found by dividing the product of numbers of teeth of driven gears by the product of numbers of teeth of driving gears.Speed increasers (with step-up rather than step-down ratios) may require special care in manufacturing and design. They often involve high speeds and may creste problems in gear dynamics. Also, frictional and drag forces are magnified which, in extreme cases , may lead to operational problems.Epicyclic Gearing:Normally, a gear axis remains fixed and only the gears rotates. But in an epicyclic gear train, various gears axes rotate about one anther to provide specialized output motions. With suitable clutchse and brakes, an epicyclic train serves as the planetarygear commonly found in automatic transmissions.Epicyclic trains may use spur or helical gears, external or internal, or bevel gears. In transmissions, the epicyclic (or planetary) gears usually have multiple planets to increase load capacity.In most cases, improved kinematic accuracy in a gearset decreases gear mesh excitation and results in lower drive noise. Gearset accuracy can be increased by modifying the tooth involute profile, by substituting higher quality gearing with tighter manufacturing tolerances, and by improving tooth surface finish. However, if gear mesh excitation generaters resonance somewhere in the drive system, nothing short of a “perfect” gearset will substantially reduce vibration and noise.Tooth profiles are modified to avoid interferences which can result from deflections in the gears, shafts, and housing as teeth engage and disendgage. If these tooth interferences are not compensated for by pro, gears load capacity can be seriously reduced. In addition, the drive will be noisier because tooth interferences generate high dynamic loads. Interferences typically are eliminated by reliving the tooth tip, the tooth flank, or both. Such pro are especially important for high-load , high-speed drives. The graph of sound pressure levelvs tip relief illustrates how tooth pro can affect overall drive noise. If the tip relief is less than this optimum value, drive noise increases because of greater tooth interference; a greater amount of tip relief also increase noise because the contact ratio is decreased.Tighter manufacturing tolerances also produce quietier gears. Tolerances for such parameters as pro, pitch AGMA quality level. For instance, the graph depicting SPL vs both speed and gear quality shows how noise decreases example, noise is reduced significantly by an increase in accuracy from an AGMA Qn 11 quality to an AGNA Qn 15 quality. However, for most commercial drive applications, it is doubtful that the resulting substantial cost increase for such an accuracy improvement can be justified simply on the basis of reduced drive noise.Previously, it was mentioned that gears must have adequate clearance when loaded to prevent tooth interference during the course of meshing. Tip and flank relief are common pro that control such interference. Gears also require adequate backlash and root clearance. Noise considerations make backlash an important parameter to evaluate during drive design. Sufficient backlash must be provided under all load and temperature conditions to avoid atight mesh, which creates excessively high noise level. A tight mesh due to insufficient backlash occurs when the drive and coast side of a tooth are in contact simultaneously. On the other hand, gears with excessive backlash also are noisy because of impacting teeth during periods of no load or reversing load. Adequate backlash should be provided by tooth thinning rather than by increase in center distance. Tooth thinning dose not decrease the contact ratio, whereas an increase in center distance does. However, tooth thinning does reduce the bending fatigue, a reduction which is small for most gearing systems.齿轮和齿轮传动在所有的机械传动形式中，齿轮传动是一种最结实耐用的传动方式。

外文原文：The Introduction of the gearsIn the force analysis of spur gears, the forces are assumed to act in a single plane. We shall study gears in which the forces have three dimensions. The reason for this, in the case of helical gears, is that the teeth are not parallel to the axis of rotation. And in the case of bevel gears, the rotational axes are not parallel to each other. There are also other reasons, as we shall learn.Helical gears are used to transmit motion between parallel shafts. The helix angle is the same on each gear, but one gear must have a right-hand helix and the other a left-hand helix. The shape of the tooth is an involute helicoid. If a piece of paper cut in the shape of a parallelogram is wrapped around a cylinder, the angular edge of the paper becomes a helix. If we unwind this paper, each point on the angular edge generates an involute curve. The surface obtained when every point on the edge generates an involute is called an involute helicoid.The initial contact of spur-gear teeth is a line extending all the way across the face of the tooth. The initial contact of helical gear teeth is a point, which changes into a line as the teeth come into more engagement. In spur gears the line of contact is parallel to the axis of the rotation; in helical gears, the line is diagonal across the face of the tooth. It is this gradual of the teeth and the smooth transfer of load from one tooth to another, which give helical gears the ability to transmit heavy loads at high speeds. Helical gears subject the shaft bearings to both radial and thrust loads. When the thrust loads become high or are objectionable for other reasons, it may be desirable to use double helical gears. A double helical gear (herringbone) is equivalent to two helical gears of opposite hand, mounted side by side on the same shaft. They develop opposite thrust reactions and thus cancel out the thrust load. When two or more single helical gears are mounted on the same shaft, the hand of the gears should be selected so as to produce the minimum thrust load.Crossed-helical, or spiral, gears are those in which the shaft centerlines are neither parallel nor intersecting. The teeth of crossed-helical fears have point contact with each other, which changes to line contact as the gears wear in. For this reason they will carry outvery small loads and are mainly for instrumental applications, and are definitely not recommended for use in the transmission of power. There is on difference between a crossed helical gear and a helical gear until they are mounted in mesh with each other. They are manufactured in the same way. A pair of meshed crossed helical gears usually have the same hand; that is ,a right-hand driver goes with a right-hand driven. In the design of crossed-helical gears, the minimum sliding velocity is obtained when the helix angle are equal. However, when the helix angle are not equal, the gear with the larger helix angle should be used as the driver if both gears have the same hand.Worm gears are similar to crossed helical gears. The pinion or worm has a small number of teeth, usually one to four, and since they completely wrap around the pitch cylinder they are called threads. Its mating gear is called a worm gear, which is not a true helical gear. A worm and worm gear are used to provide a high angular-velocity reduction between nonintersecting shafts which are usually at right angle. The worm gear is not a helical gear because its face is made concave to fit the curvature of the worm in order to provide line contact instead of point contact. However, a disadvantage of worm gearing is the high sliding velocities across the teeth, the same as with crossed helical gears.Worm gearing are either single or double enveloping. A single-enveloping gearing is one in which the gear wraps around or partially encloses the worm.. A gearing in which each element partially encloses the other is, of course, a double-enveloping worm gearing. The important difference between the two is that area contact exists between the teeth of double-enveloping gears while only line contact between those of single-enveloping gears. The worm and worm gear of a set have the same hand of helix as for crossed helical gears, but the helix angles are usually quite different. The helix angle on the worm is generally quite large, and that on the gear very small. Because of this, it is usual to specify the lead angle on the worm, which is the complement of the worm helix angle, and the helix angle on the gear; the two angles are equal for a 90-deg. Shaft angle.When gears are to be used to transmit motion between intersecting shaft, some of bevel gear is required. Although bevel gear are usually made for a shaft angle of 90 deg. They may be produced for almost any shaft angle. The teeth may be cast, milled, or generated. Only the generated teeth may be classed as accurate. In a typical bevel gearmounting, one of the gear is often mounted outboard of the bearing. This means that shaft deflection can be more pronounced and have a greater effect on the contact of teeth. Another difficulty, which occurs in predicting the stress in bevel-gear teeth, is the fact the teeth are tapered.Straight bevel gears are easy to design and simple to manufacture and give very good results in service if they are mounted accurately and positively. As in the case of squr gears, however, they become noisy at higher values of the pitch-line velocity. In these cases it is often good design practice to go to the spiral bevel gear, which is the bevel counterpart of the helical gear. As in the case of helical gears, spiral bevel gears give a much smoother tooth action than straight bevel gears, and hence are useful where high speed are encountered.It is frequently desirable, as in the case of automotive differential applications, to have gearing similar to bevel gears but with the shaft offset. Such gears are called hypoid gears because their pitch surfaces are hyperboloids of revolution. The tooth action between such gears is a combination of rolling and sliding along a straight line and has much in common with that of worm gears.中文译文：齿轮简介在直齿圆柱齿轮的受力分析中，是假定各力作用在单一平面的。

外文原文GearsGears are vital factors in machinery ,which are uses to transmit power or motion from one shaft to another .They may be used only to transmit motion from one part of a machine to another,or they may be used to change the speed or the torque of one shaft with with relation to another.One of the first mechanism invented using gears wad the clock.In fact,a clock is little more than a train of gears.Considerable study and research have been made on gears in recent years because of their wide use under exacting conditions.They have to transmit heavier loads and run at high speeds than ever before.The engineers and the machinists all consider gearing the prime element in nearly all classes of machinery.Super GearsSpur gears will be considered first for several reasons.In the first place ,they are simplest and the least expensive of gears and they may be used to transmit power between parallel shafts,also,spur gears definitions are usually applicable to other types .It is important go understand the following definitions,since they are important factors in the design of any equipment utilizing gears.Diametric PitchThe number of teeth per inch of pitch cirle diameter .The diameter pitch is usually an integer .A small number for the pitch implies a large tooth size.Meshing spur gears must have the same diameter pitch .The speed ratio is based on the fact that meshing gears may have different-sized pitch circles and hence different number of teeth.Circular PitchThe distance from a point on one tooth to the corresponding point on an adjacent tooth ,measrued along the pitch circle.This is a liner dimension and thus bas liner units.Pitch CircleThe circle on which the ratio of the gear set is based,when two gears are meshing ,the two pitch circles must be exactly tangent if the gears are to function properly.The tangency point is known as the pitch point. Pressure AngleThe angle between the line of action and a line perpendicular to the centerlines of the two gears in mesing .Pressure Angles for spur gears are usually 14.5 or 20 degrees,although other values can be used.Meshing gears must have the same pressure angles.In the case of a rack,the teeth have the straight sides inclined at an angle corresponding to the pressure angle.Base CircleA circle tangent to the line of action (or pressure line ) .The base circle is the imaginary circle about which an involutes cure is developed .Most spur gears follow an involutes cure from the base circle to the top of the tootch,this cure can be visualized by observing a point on a taut cord an it is unwound from a cylinder .In a gear ,the cylinder is the best circle.AddendumThe radial distance form the pitch circle to the top of the tooth . DedendumThe radial distance from file pitch circle to the root of the tooth. ClearanceThe difference between the addendum and the addendum.Face WidthThe width of the tooth measured axially.FaceThe surface between the pitch circle and the top of the tooth. FlankThe surface between the pitch circle and the bottom of the tooth. Helical GearsThese gears have their tooth element at an angle or helix to the axis of the gear.They are more difficult and expensive to make than spur gears,but are quieter and stronger. They may be used to transmit power between parallel shafts at an angle to each in the same or different planes.Herringbone GearsA herringbone gear is equivalent to a right-hand and a left-hand helical gear placed side by side.Because of the angle of the tooth,helical gears create considerable side thrust on the shaft. A herringbone gear corrects this thrust by neutralizing it ,allowing the use of a small thrust bearing instead of a large one and perhaps eliminating one altogether.Often a central groove is made round the gear for ease in machining.Bevel GearsBevel gears are used to connect shafts, which are not parallel to each ually the shafts are 90 deg.To each other, but they may be more or less than 90 deg.The two meshing gears may have the same number of teeth for the purpose of changing direction of motion only,or they may have a different number of teeth for the purpose of changing both speed and direction .The faces of the teeth lie on the surface of the frustum of a cone,therefore the teeth elements are not parallel to each other it can be seen that this lack of parallelism creates a machining problem so that two passes with a tool must be made.The tooth elements may be straight or spiral ,so that we have plain anti spiral evel gears.Worm and Worm GearsA worm-and-worm-gear combination is used chiefly where it is desired to obtain a high gear reduction in a limited space,normally the worm drivers the worm gear and is not reversible ,that is to say,the worm gear can not drive the worm.Most worms can be rotated in either direction,clockwise or counterclockwise.RacksA rack is a gear with an infinite radius,or a gear with its perimeter stretched out into a straight line.It is used to change reciprocating motion to rotary motion or vice versa.A lathe rack and pinion is a good example of this mechanism.Various materials are used in manufacturing gears .Usually,the materials selected depends on the method used for making the gear and the application to which it will be put.Gears can be cast,cut,or extruded.Typical materials include cast iron,cast steel,plain carbon steel,alloy steel aluminum,phosphor bronze,laminated phonetics,and nylon.中文翻译齿轮齿轮是机器中的动力元件,用来传递轴与轴之间的运动及动力。

齿轮术语中英文对照表阿基米德蜗杆Archimedes worm安全系数safety factor；factor of safety安全载荷safe load变形deformation摆线齿轮cycloidal gear摆线齿形cycloidal tooth profile背锥角back angle背锥距back cone distance比例尺scale变速speed change变速齿轮change gear ；change wheel变位齿轮modified gear变位系数modification coefficient标准齿轮standard gear标准直齿轮standard spur gear表面粗糙度surface roughness不完全齿轮机构intermittent gearing补偿compensation参数化设计parameterization design，PD 残余应力residual stress操纵及控制装置operation control device槽数Geneva numerate侧隙backlash差动轮系differential gear train差动螺旋机构differential screw mechanism 差速器differential常用机构conventional mechanism; mechanism in common use承载量系数bearing capacity factor承载能力bearing capacity成对安装paired mounting尺寸系列dimension series齿槽tooth space齿槽宽spacewidth齿侧间隙backlash齿顶高addendum齿顶圆addendum circle齿根高dedendum齿根圆dedendum circle齿厚tooth thickness齿距circular pitch 齿宽face width齿廓tooth profile齿廓曲线tooth curve齿轮gear齿轮变速箱speed-changing gear boxes齿轮齿条机构pinion and rack齿轮插刀pinion cutter；pinion-shaped shaper cutter齿轮滚刀hob ，hobbing cutter齿轮机构gear齿轮轮坯blank齿轮传动系pinion unit齿轮联轴器gear coupling齿条传动rack gear齿数tooth number齿数比gear ratio齿条rack齿条插刀rack cutter; rack—shaped shaper cutter齿形链、无声链silent chain齿形系数form factor齿式棘轮机构tooth ratchet mechanism插齿机gear shaper重合点coincident points重合度contact ratio传动比transmission ratio，speed ratio传动装置gearing；transmission gear传动系统driven system传动角transmission angle传动轴transmission shaft创新设计creation design垂直载荷、法向载荷normal load从动带轮driven pulley从动件driven link，follower从动件平底宽度width of flat-face从动件停歇follower dwell从动件运动规律follower motion从动轮driven gear粗线bold line粗牙螺纹coarse thread大齿轮gear wheel打滑slipping带传动belt driving单列轴承single row bearing单位矢量unit vector当量齿轮equivalent spur gear; virtual gear 当量齿数equivalent teeth number; virtual number of teeth当量摩擦系数equivalent coefficient of friction当量载荷equivalent load刀具cutter导数derivative倒角chamfer导程lead导程角lead angle等效质量equivalent mass（疲劳）点蚀pitting垫圈gasket垫片密封gasket seal顶隙bottom clearance定轴轮系ordinary gear train；gear train with fixed axes动力学dynamics动密封kinematical seal动能dynamic energy动力粘度dynamic viscosity动力润滑dynamic lubrication动载荷dynamic load端面transverse plane端面参数transverse parameters端面齿距transverse circular pitch端面齿廓transverse tooth profile端面重合度transverse contact ratio端面模数transverse module端面压力角transverse pressure angle锻造forge惰轮idle gear额定寿命rating life额定载荷load rating发生线generating line发生面generating plane法面normal plane法面参数normal parameters法面齿距normal circular pitch法面模数normal module法面压力角normal pressure angle法向齿距normal pitch 法向齿廓normal tooth profile法向直廓蜗杆straight sided normal worm法向力normal force反正切Arctan范成法generating cutting仿形法form cutting非标准齿轮nonstandard gear非接触式密封non—contact seal非周期性速度波动aperiodic speed fluctuation非圆齿轮non-circular gear粉末合金powder metallurgy分度线reference line；standard pitch line 分度圆reference circle; standard (cutting）pitch circle分度圆柱导程角lead angle at reference cylinder分度圆柱螺旋角helix angle at reference cylinder分母denominator分子numerator分度圆锥reference cone; standard pitch cone 封闭差动轮系planetary differential复合应力combined stress复式螺旋机构Compound screw mechanism 干涉interference刚度系数stiffness coefficient钢丝软轴wire soft shaft根切undercutting公称直径nominal diameter高度系列height series功work工况系数application factor工艺设计technological design工作循环图working cycle diagram工作机构operation mechanism工作载荷external loads工作空间working space工作应力working stress工作阻力effective resistance工作阻力矩effective resistance moment公法线common normal line公制齿轮metric gears功率power功能分析设计function analyses design共轭齿廓conjugate profiles共轭凸轮conjugate cam惯性力矩moment of inertia ,shaking moment惯性力平衡balance of shaking force冠轮crown gear轨迹生成path generation轨迹发生器path generator滚刀hob过度切割undercutting耗油量oil consumption耗油量系数oil consumption factor横坐标abscissa互换性齿轮interchangeable gears花键spline滑键、导键feather key滑动率sliding ratio环面蜗杆toroid helicoids worm缓冲装置shocks; shock—absorber机械machinery机械平衡balance of machinery机械设计machine design; mechanical design 机械特性mechanical behavior机械调速mechanical speed governors机械效率mechanical efficiency机械原理theory of machines and mechanisms机械无级变速mechanical stepless speed changes基础机构fundamental mechanism基本额定寿命basic rating life基于实例设计case-based design，CBD基圆base circle基圆半径radius of base circle基圆齿距base pitch基圆压力角pressure angle of base circle基圆柱base cylinder基圆锥base cone极限位置extreme （or limiting) position极位夹角crank angle between extreme （or limiting）positions计算机辅助设计computer aided design，CAD 计算机辅助制造computer aided manufacturing，CAM计算机集成制造系统computer integrated manufacturing system, CIMS计算力矩factored moment；calculation moment计算弯矩calculated bending moment间隙backlash减速比reduction ratio减速齿轮、减速装置reduction gear减速器speed reducer渐开螺旋面involute helicoid渐开线involute渐开线齿廓involute profile渐开线齿轮involute gear渐开线发生线generating line of involute渐开线方程involute equation渐开线函数involute function渐开线蜗杆involute worm渐开线压力角pressure angle of involute渐开线花键involute spline键key键槽keyway交变应力repeated stress交变载荷repeated fluctuating load交叉带传动cross—belt drive交错轴斜齿轮crossed helical gears胶合scoring角速度angular velocity角速比angular velocity ratio结构structure结构设计structural design截面section节点pitch point节距circular pitch；pitch of teeth节线pitch line节圆pitch circle节圆齿厚thickness on pitch circle节圆直径pitch diameter节圆锥pitch cone节圆锥角pitch cone angle解析设计analytical design紧边tight-side紧固件fastener径节diametral pitch径向radial direction径向当量动载荷dynamic equivalent radial load径向当量静载荷static equivalent radial load 径向基本额定动载荷basic dynamic radial load rating径向基本额定静载荷basic static radial load tating径向接触轴承radial contact bearing径向平面radial plane径向游隙radial internal clearance径向载荷radial load径向载荷系数radial load factor径向间隙clearance静力static force静平衡static balance静载荷static load绝对运动absolute motion绝对速度absolute velocity可靠性reliability可靠性设计reliability design, RD理论廓线pitch curve理论啮合线theoretical line of action力矩moment力平衡equilibrium力偶couple力偶矩moment of couple轮坯blank螺旋副helical pair螺旋机构screw mechanism螺旋角helix angle螺旋线helix ,helical line模块化设计modular design, MD模数module磨损abrasion ；wear；scratching耐磨性wear resistance内齿轮internal gear内齿圈ring gear内力internal force内圈inner ring啮合engagement，mesh, gearing啮合点contact points啮合角working pressure angle 啮合线line of action啮合线长度length of line of action盘形转子disk-like rotor抛物线运动parabolic motion疲劳极限fatigue limit疲劳强度fatigue strength偏置式offset偏( 心) 距offset distance偏心率eccentricity ratio偏心质量eccentric mass偏距圆offset circle偏心盘eccentric切齿深度depth of cut曲齿锥齿轮spiral bevel gear曲率curvature曲率半径radius of curvature曲面从动件curved—shoe follower曲线运动curvilinear motion全齿高whole depth权重集weight sets球面副spheric pair球面渐开线spherical involute球面运动spherical motion人字齿轮herringbone gear润滑装置lubrication device润滑lubrication三角形花键serration spline三角形螺纹V thread screw少齿差行星传动planetary drive with small teeth difference升程rise升距lift实际廓线cam profile输出轴output shaft实际啮合线actual line of action双曲面齿轮hyperboloid gear顺时针clockwise瞬心instantaneous center死点dead point太阳轮sun gear特性characteristics图册、图谱atlas图解法graphical method退火anneal陀螺仪gyroscope外力external force外形尺寸boundary dimension网上设计on-net design, OND微动螺旋机构differential screw mechanism 位移displacement蜗杆worm蜗杆传动机构worm gearing蜗杆头数number of threads蜗杆直径系数diametral quotient蜗杆蜗轮机构worm and worm gear蜗杆形凸轮步进机构worm cam interval mechanism蜗杆旋向hands of worm蜗轮worm gear无级变速装置stepless speed changes devices相对速度relative velocity相对运动relative motion相对间隙relative gap象限quadrant橡皮泥plasticine小齿轮pinion小径minor diameter谐波齿轮harmonic gear谐波传动harmonic driving斜齿轮的当量直齿轮equivalent spur gear of the helical gear心轴spindle行程速度变化系数coefficient of travel speed variation行程速比系数advance—to return-time ratio 行星齿轮装置planetary transmission行星轮planet gear行星轮变速装置planetary speed changing devices行星轮系planetary gear train旋转运动rotary motion压力角pressure angle应力图stress diagram应力—应变图stress—strain diagram优化设计optimal design油杯oil bottle有效圆周力effective circle force 圆带传动round belt drive圆弧齿厚circular thickness圆弧圆柱蜗杆hollow flank worm圆角半径fillet radius圆盘摩擦离合器disc friction clutch圆盘制动器disc brake原动机prime mover原始机构original mechanism圆形齿轮circular gear圆柱滚子cylindrical roller圆柱滚子轴承cylindrical roller bearing圆柱副cylindric pair圆柱蜗杆cylindrical worm圆锥滚子tapered roller圆锥滚子轴承tapered roller bearing圆锥齿轮机构bevel gears圆锥角cone angle运动副kinematic pair运动粘度kenematic viscosity载荷load展成法generating直齿圆柱齿轮spur gear直齿锥齿轮straight bevel gear直径系数diametral quotient直径系列diameter series直廓环面蜗杆hindley worm质量mass中心距center distance中心距变动center distance change中径mean diameter终止啮合点final contact，end of contact 周节pitch轴shaft轴承盖bearing cup轴承合金bearing alloy轴承座bearing block轴承外径bearing outside diameter轴颈journal轴瓦、轴承衬bearing bush轴端挡圈shaft end ring轴环shaft collar轴肩shaft shoulder轴角shaft angle轴向axial direction轴向齿廓axial tooth profile转动副revolute (turning）pair转速swiveling speed ; rotating speed转轴revolving shaft转子rotor装配条件assembly condition锥齿轮bevel gear锥顶common apex of cone锥距cone distance锥轮bevel pulley；bevel wheel锥齿轮的当量直齿轮equivalent spur gear of the bevel gear锥面包络圆柱蜗杆milled helicoids worm准双曲面齿轮hypoid gear自由度degree of freedom，mobility总重合度total contact ratio总反力resultant force总效率combined efficiency；overall efficiency组成原理theory of constitution组合齿形composite tooth form组合安装stack mounting最少齿数minimum teeth number最小向径minimum radius作用力applied force坐标系coordinate frame。

译文原文题目：gear and shaft introduce 译文题目：齿轮和轴的介绍学院：机电工程学院专业班级：机械工程及自动化06级（3）班学生姓名：齿轮和轴的介绍摘要：在传统机械和现代机械中齿轮和轴的重要地位是不可动摇的。

齿轮和轴主要安装在主轴箱来传递力的方向。

通过加工制造它们可以分为许多的型号，分别用于许多的场合。

所以我们对齿轮和轴的了解和认识必须是多层次多方位的。

关键词：齿轮；轴在直齿圆柱齿轮的受力分析中，是假定各力作用在单一平面的。

我们将研究作用力具有三维坐标的齿轮。

因此，在斜齿轮的情况下，其齿向是不平行于回转轴线的。

而在锥齿轮的情况中各回转轴线互相不平行。

像我们要讨论的那样，尚有其他道理需要学习，掌握。

斜齿轮用于传递平行轴之间的运动。

倾斜角度每个齿轮都一样，但一个必须右旋斜齿，而另一个必须是左旋斜齿。

齿的形状是一溅开线螺旋面。

如果一张被剪成平行四边形（矩形）的纸张包围在齿轮圆柱体上，纸上印出齿的角刃边就变成斜线。

如果我展开这张纸，在血角刃边上的每一个点就发生一渐开线曲线。

直齿圆柱齿轮轮齿的初始接触处是跨过整个齿面而伸展开来的线。

斜齿轮轮齿的初始接触是一点，当齿进入更多的啮合时，它就变成线。

在直齿圆柱齿轮中，接触是平行于回转轴线的。

在斜齿轮中，该先是跨过齿面的对角线。

它是齿轮逐渐进行啮合并平稳的从一个齿到另一个齿传递运动，那样就使斜齿轮具有高速重载下平稳传递运动的能力。

斜齿轮使轴的轴承承受径向和轴向力。

当轴向推力变的大了或由于别的原因而产生某些影响时，那就可以使用人字齿轮。

双斜齿轮（人字齿轮）是与反向的并排地装在同一轴上的两个斜齿轮等效。

他们产生相反的轴向推力作用，这样就消除了轴向推力。

当两个或更多个单向齿斜齿轮被在同一轴上时，齿轮的齿向应作选择，以便产生最小的轴向推力。

交错轴斜齿轮或螺旋齿轮，他们是轴中心线既不相交也不平行。

交错轴斜齿轮的齿彼此之间发生点接触，它随着齿轮的磨合而变成线接触。

机械原理术语英汉对照以下是机械原理中常见的术语的英汉对照。

这些术语对于理解和学习机械原理非常重要。

1. Machine 机器2. Mechanism 机构3. Kinematics 运动学4. Dynamics 动力学5. Force 力6. Work 功7. Energy 能量8. Friction 摩擦9. Torque 扭矩10. Moment of inertia 惯性矩11. Velocity 速度12. Acceleration 加速度13. Displacement 位移14. Motion 运动15. Equilibrium 平衡16. Linkage 连杆机构17. Gear 齿轮18. Cam 凸轮19. Slider- Crank Mechanism 曲柄滑块机构20. Belt and Pulley System 带轮系统21. Chain Drive 链传动22. Bearing 轴承23. Mechanical Advantage 机械优势24. Efficiency 效率25. Stress 应力26. Strain 应变27. Deformation 变形28. Elasticity 弹性29. Plasticity 塑性30. Safety Factor 安全系数31. Tolerance 公差32. Clearance 间隙33. Stiffness 刚度34. Damping 阻尼35. Vibration 振动36. Oscillation 摆动37. Resonance 共振38. Inertia 惯性39. Centrifugal Force 离心力40. Centripetal Force 向心力41. Conservation of Energy 能量守恒42. Conservation of Momentum 动量守恒43. Principle of Work and Energy 功与能量原理44. Simple Machines 简单机械45. Lever 杠杆46. Wheel and Axle 轮轴47. Pulley 滑轮48. Inclined Plane 斜面49. Wedge 楔形物50. Screw 螺纹51. Cam and Follower 凸轮与从动件52. Governor 调速器53. Flywheel 轮盘54. Five- bar linkage 五杆机构55. Six-bar linkage 六杆机构56. Four-bar linkage 四杆机构57. Planar motion 平面运动58. Spatial motion 空间运动59. Driveshaft 传动轴60. Pitman Arm 驱动臂61. Eccentric 扔率轮62. Power Transmission 传动63. Parallel Motion 平行运动64. Point of Action 作用点65. Return Spring 回弹簧66. Over-center Device 过中心装置67. Film Lubrication 薄膜润滑68. Hydrodynamic Lubrication 流体动力润滑69. Hydrostatic Lubrication 静液润滑70. Elastohydrodynamic Lubrication 弹道液体动力润滑71. Boundary Lubrication 边界润滑72. Journal Bearing 轴承73. Rolling Bearing 滚动轴承74. Sliding Bearing 滑动轴承75. Roller Bearing 滚子轴承76. Thrust Bearing 推力轴承77. Ball Bearing 球面轴承78. Angular Contact Ball Bearing 角接触球轴承79. Tapered Roller Bearing 锥面滚子轴承80. Spherical Roller Bearing 球面滚子轴承81. Needle Roller Bearing 针型滚子轴承82. Cylindrical Roller Bearing 圆柱滚子轴承83. Spherical Plain Bearing 球面铜套轴承84. Thrust Washers 推力垫圈85. O-ring 封圈86. Seal 密封件87. Coupling 联轴器88. Clutch 离合器89. Brake 制动器90. Gearbox 变速箱91. Differential Differential92. Transmission 传动系93. Gear Ratio 齿轮比94. Worm and Worm Gear 小齿轮和大齿轮95. Rack and Pinion 齿条和小齿轮96. Helical Gear 螺旋齿轮97. Bevel Gear 锥齿轮98. Spiral Bevel Gear 螺旋锥齿轮99. Planetary Gear 行星齿轮100. Spline 长键101. Key 键102. Locking Device 锁紧装置103. Lubrication System 润滑系统104. Hydraulic System 液压系统105. Pneumatic System 气动系统106. Material Material108. Tensile Stress 张应力109. Shear Stress 剪应力110. Bending Stress 弯曲应力111. Balancing 平衡112. Dynamic Balancing 动平衡113. Static Balancing 静平衡114. Staybolt 支柱115. Nuts and Bolts 螺母和螺栓116. Threaded Fasteners 螺纹连接件117. Threaded Joint 螺纹连接118. Rivet 铆钉119. Welding 焊接120. Adhesive Bonding 粘接121. Surface Finish 表面精度122. Surface Coating 表面涂层123. Corrosion 腐蚀124. Wear 磨损125. Fatigue 疲劳126. Creep 羊毛现象127. Material Selection 材料选择128. Material Properties 材料性能129. Hardness 硬度。

机械制造毕业设计外文英文文献翻译齿轮和齿轮传动Gears and gear driveGears are the most durable and rugged of all mechanical drives. They can transmit high power at efficiencies up to 98% and with long service lives. For this reason, gears rather than belts or chains are found in automotive transmissions and most heavy-duty machine drives. On the other hand, gears are more expensive than other drives, especially if they are machined and not made from power metal or plastic.Gear cost increases sharply with demands for high precision and accuracy. So it is important to establish tolerance requirements appropriate for the application. Gears that transmit heavy loads or than operate at high speeds are not particularly expensive, but gears that must do both are costly.Silent gears also are expensive. Instrument and computer gears tend to be costly because speed or displacement ratios must be exact. At the other extreme, gears operating at low speed in exposed locations are normally termed no critical and are made to minimum quality standards.For tooth forms, size, and quality, industrial practice is to follow standards set up by the American Gear Manufactures AssociationAGMA.Tooth formStandards published by AGMA establish gear proportions and tooth profiles. Tooth geometry is determined primarily by pitch, depth, and pressure angle.Pitch：Standards pitches are usually whole numbers when measured as diametral pitch P. Coarse-pitch gearing has teeth larger than 20 diametral pitch ?usually 0.5 to 19.99. Fine-pitch gearing usually has teeth of diametral pitch 20 to 200.Depth: Standardized in terms of pitch. Standard full-depth have working depth of 2/p. If the teeth have equal addendaas in standard interchangeable gears the addendum is 1/p. Stub teeth have a working depth usually 20% less than full-depth teeth. Full-depth teeth have a larger contract ratio than stub teeth. Gears with small numbers of teeth may have undercut so than they do not interfere with one another during engagement. Undercutting reduce active profile and weakens the tooth.Mating gears with long and short addendum have larger load-carrying capacity than standard gears. The addendum of the smaller gear pinion is increased while that of larger gear is decreased, leaving the whole depth the same. This form is know as recess-action gearing.Pressure Angle: Standard angles are and . Earlier standards include a 14-pressure angle that is still used. Pressure angle affectsthe force that tends to separate mating gears. High pressure angle decreases the contact ratio ratio of the number of teeth in contact but provides a tooth of higher capacity and allows gears to have fewer teeth without undercutting.Backlash: Shortest distances between the non-contacting surfaces of adjacent teeth .Gears are commonly specified according to AGMA Class Number, which is a code denoting important quality characteristics. Quality number denote tooth-element tolerances. The higher the number, the closer the tolerance. Number 8 to 16 apply to fine-pitch gearing.Gears are heat-treated by case-hardening, through-hardening, nitriding, or precipitation hardening. In general, harder gears are stronger and last longer than soft ones. Thus, hardening is a device that cuts the weight and size of gears. Some processes, such as flame-hardening, improve service life but do not necessarily improve strength.Design checklistThe larger in a pair is called the gear, the smaller is called the pinion.Gear Ratio: The number of teeth in the gear divide by the number of teeth in the pinion. Also, ratio of the speed of the pinion to the speed of the gear. In reduction gears, the ratio of input to output speeds.Gear Efficiency: Ratio of output power to input power. includesconsideration of power losses in the gears, in bearings, and from windage and churning of lubricant.Speed: In a given gear normally limited to some specific pitchline velocity. Speed capabilities can be increased by improving accuracy of the gear teeth and by improving balance of the rotating parts.Power: Load and speed capacity is determined by gear dimensions and by type of gear. Helical and helical-type gears have the greatest capacity to approximately 30,000 hp. Spiral bevel gear are normally limited to 5,000 hp, and worm gears are usually limited to about 750 hp.Special requirementsMatched-Set Gearing: In applications requiring extremely high accuracy, it may be necessary to match pinion and gear profiles and leads so that mismatch does not exceed the tolerance on profile or lead for the intended application.Tooth Spacing: Some gears require high accuracy in the circular of teeth. Thus, specification of pitch may be required in addition to an accuracy class specification.Backlash: The AMGA standards recommend backlash ranges to provide proper running clearances for mating gears. An overly tight mesh may produce overload. However, zero backlash is required in some applications.Quiet Gears: To make gears as quit as possible, specify thefinest pitch allowable for load conditions. In some instances, however, pitch is coarsened to change mesh frequency to produce a more pleasant, lower-pitch sound. Use a low pressure angle. Use a modified profile to include root and tip relief. Allow enough backlash. Use high quality numbers. Specify a surface finish of 20 in. or better. Balance the gear set. Use a nonintegral ratio so that the same teeth do not repeatedly engage if both gear and pinion are hardened steel. If the gear is made of a soft material, an integral ratio allows the gear to cold-work and conform to the pinion, thereby promoting quiet operation. Make sure critical are at least 20% apart from operating speeding or speed multiples and from frequency of tooth mesh.Multiple mesh gearMultiple mesh refers to move than one pair of gear operating in a train. Can be on parallel or nonparallel axes and on intersection or nonintersecting shafts. They permit higer speed ratios than are feasible with a single pair of gears .Series trains:Overall ratio is input shaft speed divided by output speed ,also the product of individual ratios at each mesh ,except in planetary gears .Ratio is most easily found by dividing the product of numbers of teeth of driven gears by the product of numbers of teeth of driving gears.Speed increasers with step-up rather than step-down ratios mayrequire special care in manufacturing and design. They often involve high speeds and may creste problems in gear dynamics. Also, frictional and drag forces are magnified which, in extreme cases , may lead to operational problems.Epicyclic Gearing:Normally, a gear axis remains fixed and only the gears rotates. But in an epicyclic gear train, various gears axes rotate about one anther to provide specialized output motions. With suitable clutchse and brakes, an epicyclic train serves as the planetary gear commonly found in automatic transmissions.Epicyclic trains may use spur or helical gears, external or internal, or bevel gears. In transmissions, the epicyclic or planetary gears usually have multiple planets to increase load capacity.In most cases, improved kinematic accuracy in a gearset decreases gear mesh excitation and results in lower drive noise. Gearset accuracy can be increased by modifying the tooth involute profile, by substituting higher quality gearing with tighter manufacturing tolerances, and by improving tooth surface finish. However, if gear mesh excitation generaters resonance somewhere in the drive system, nothing short of a “perfect” gearset will substantially reduce vibration and noise.Tooth profiles are modified to avoid interferences which can result from deflections in the gears, shafts, and housing as teeth engageand disendgage. If these tooth interferences are not compensated for by profile modifications, gears load capacity can be seriously reduced. In addition, the drive will be noisier because tooth interferences generate high dynamic loads. Interferences typically are eliminated by reliving the tooth tip, the tooth flank, or both. Such profile modifications are especially important for high-load , high-speed drives. The graph of sound pressure levelvs tip relief illustrates how tooth profile modifications can affect overall drive noise. If the tip relief is less than this optimum value, drive noise increases because of greater tooth interference; a greater amount of tip relief also increase noise because the contact ratio is decreased.Tighter manufacturing tolerances also produce quietier gears. Tolerances for such parameters as profile error, pitch AGMA quality level. For instance, the graph depicting SPL vs both speed and gear quality shows how noise decreases example, noise is reduced significantly by an increase in accuracy from an AGMA Qn 11 quality to an AGNA Qn 15 quality. However, for most commercial drive applications, it is doubtful that the resulting substantial cost increase for such an accuracy improvement can be justified simply on the basis of reduced drive noise.Previously, it was mentioned that gears must have adequate clearance when loaded to prevent tooth interference during the course of meshing. Tip and flank relief are common profile modifications thatcontrol such interference. Gears also require adequate backlash and root clearance. Noise considerations make backlash an important parameter to evaluate during drive design. Sufficient backlash must be provided under all load and temperature conditions to avoid a tight mesh, which creates excessively high noise level. A tight mesh due to insufficient backlash occurs when the drive and coast side of a tooth are in contact simultaneously. On the other hand, gears with excessive backlash also are noisy because of impacting teeth during periods of no load or reversing load. Adequate backlash should be provided by tooth thinning rather than by increase in center distance. Tooth thinning dose not decrease the contact ratio, whereas an increase in center distance does. However, tooth thinning does reduce the bending fatigue, a reduction which is small for most gearing systems.齿轮和齿轮传动在所有的机械传动形式中，齿轮传动是一种最结实耐用的传动方式。

毕业设计中英文翻译 学生姓名：学生姓名：学号：学号： 学 院：院：专 业：业：指导教师：指导教师：年月机械设计制造及其自动化Planetary GearsIntroductionThe Tamiya planetary gearbox is driven by a small DC motor that runs at about 10,500 rpm on 3.0V DC and draws about 1.0A. The maximum speed ratio is 1:400, giving an output speed of about 26 rpm. Four planetary stages are supplied with the gearbox, two 1:4 and two 1:5, and any combination can be selected. Not only is this a good drive for small mechanical applications, it provides an excellent review of epicycle gear trains. The gearbox is a very well-designed plastic kit that can be assembled in about an hourwith very few tools. The source for the kit is given in the References.Let's begin by reviewing the fundamentals of gearing, and the trick of analyzing epicyclic gear trains.Epicyclic Gear TrainsA pair of spur gears is represented in the diagram by their pitch circles, which are tangent at the pitch point P. The meshing gear teeth extend beyond the pitch circle by the addendum, and the spaces between them have a depth beneath the pitch circle by the dedendum. If the radii of the pitch circles are a and b, the distance between the gear shafts is a + b. In the action of the gears, the pitch circles roll on one another without slipping. To ensure this, the gear teeth must have a proper shape so that when the driving gear moves uniformly, so does the driven gear. This means that the line of pressure, normal to the tooth profiles in contact, passes through the pitch point. Then, the transmission of power will be free of vibration and high speeds are possible. We won't talk further about gear teeth here, having stated this fundamental principle of gearing.If a gear of pitch radius a has N teeth, then the distance between corresponding points on successive teeth will be 2πa/N, a quantity called the circular pitch. If two gears are to mate, the circular pitches must be the same. The pitch is usually stated as the ration 2a/N, called the diametral pitch. If you count the number of teeth on a gear, then the pitch diameter is the number of teeth times the diametral pitch. If you know the pitch diameters of two gears, then you can specify the distance between the shafts.The velocity ratio r of a pair of gears is the ratio of the angular velocity of the driven gear to the angular velocity of the driving gear. By the condition of rolling of pitch circles, r = -a/b = -N1/N2, since pitch radii are proportional to the number of teeth. The angular velocity n of the gears may be given in radians/sec, revolutions per minute (rpm), or any similar units. If we take one direction of rotation as positive, then the other direction is negative. This is the reason for the (-) sign in the above expression. If one of the gears is internal (having teeth on its inner rim), then the velocity ratio is positive, since the gears will rotate in the same direction.The usual involute gears have a tooth shape that is tolerant of variations in the distance between the axes, so the gears will run smoothly if this distance is not quite correct. The velocity ratio of the gears does not depend on the exact spacing of the axes, but is fixed by the number of teeth, or what is the same thing, by the pitch diameters. Slightly increasing the distance above its theoretical value makes the gears run easier, since the clearances are larger. On the other hand, backlash is also increased, which may not be desired in some applications.An epicyclic gear train has gear shafts mounted on a moving arm or carrier that can rotate about the axis, as well as the gears themselves. The arm can be an input element, or an output element, and can be held fixed or allowed to rotate. The outer gear is the ring gear or annulus. A simple but very commonepicyclic train is the sun-and-planet epicyclic train, shown in the figure at the left. Three planetary gears are used for mechanical reasons; they may be considered as one in describing the action of the gearing. The sun gear, the arm, or the ring gear may be input or output links.If the arm is fixed, so that it cannot rotate, we have a simple train of three gears. Then, n2/n1 = -N1/N2, n3/n2 = +N2/N3, and n3/n1 = -N1/N3. This is very simple, and should not be confusing. If the arm is allowed to move, figuring out the velocity ratios taxes the human intellect. Attempting this will show the truth of the statement; if you can manage it, you deserve praise and fame. It is by no means impossible, just invoved. However, there is a very easy way to get the desired result. First, just consider the gear train locked, so it moves as a rigid body, arm and all. All three gears and the arm then have a unity velocity ratio. The trick is that any motion of the gear train can carried out by first holding the arm fixed and rotating the gears relative to one another, and then locking the train and rotating it about the fixed axis. The net motionis the sum or difference of multiples of the two separate motions that satisfies the conditions of the problem (usually that one element is held fixed). To carry out this program, construct a table in which the angular velocities of the gears and arm are listed for each, for each of the two cases. The locked train gives 1, 1, 1, 1 for arm, gear 1, gear 2 and gear 3. Arm fixed gives 0, 1, -N1/N2, -N1/N3. Suppose we want the velocity ration between the arm and gear 1, when gear 3 is fixed. Multiply the first row by a constant so that when it is added to the second row, the velocity of gear 3 will be zero. This constant is N1/N3. Now, doing one displacement and then the other corresponds to adding the two rows. We find N1/N3, 1 + N1/N3, N1/N3 -N1/N2.The first number is the arm velocity, the second the velocity of gear 1, so the velocity ratio between them is N1/(N1 + N3), after multiplying through by N3. This is the velocity ratio we need for the Tamiya gearbox, where the ring gear does not rotate, the sun gear is the input, and the arm is the output. The procedure is general, however, and will work for any epicyclic train.One of the Tamiya planetary gear assemblies has N1 = N2 = 16, N3 = 48, while the other has N1 = 12, N2 = 18, N3 = 48. Because the planetary gears must fit between the sun and ring gears, the condition N3 = N1 + 2N2 must be satisfied. It is indeed satisfied for the numbers of teeth given. The velocity ratio of the first set will be 16/(48 + 16) = 1/4. The velocity ratio of the second set will be 12/(48 + 12) = 1/5. Both ratios are as advertised. Note that the sun gear and arm will rotate in the same direction.The best general method for solving epicyclic gear trains is the tabular method, since it does not contain hidden assumptions like formulas, nor require the work of the vector method. The first step is to isolate the epicyclic train, separating the gear trains for inputs and outputs from it. Find the input speeds or turns, using the input gear trains. There are, in general, two inputs, one of which may be zero in simple problems. Now prepare two rows of the table of turns or angular velocities. The first row corresponds to rotating around the epicyclic axis once, and consists of all 1's. Write down the second row assuming that the arm velocity is zero, using the known gear ratios. The row that you want is a linear combination of these two rows, with unknown multipliers x and y. Summing the entries for the input gears gives two simultaneous linear equations for x and y in terms of the known input velocities. Now the sum of the two rows multiplied by their respective multipliers gives the speeds of all the gears of interest. Finally, find the output speed with the aid of the output gear train. Be careful to get the directions of rotation correct, with respect to a direction taken as positive.The Tamiya Gearbox KitThe parts are best cut from the sprues with a flush-cutter of the type used in electronics. The very small bits of plastic remaining can then be removed with a sharp X-acto knife. Carefully remove all excess plastic, as the instructions say.Read the instructions carefully and make sure that things are the right way up and in the correct relative positons. The gearbox units go together easily with light pressure. Note that the brown ones must go together in the correct relative orientation. The 4mm washers are the ones of which two are supplied, and there is also a full-size drawing of one in the instructions. The smaller washers will not fit over the shaft, anyway. The output shaft is metal. Use larger long-nose pliers to press the E-ring into position in its groove in front of the washer. There is a picture showing how to do this. There was an extra E-ring in my kit. The three prongs fit into the carriers for the planetary gears, and are driven by them.Now stack up the gearbox units as desired. I used all four, being sure to put a 1:5 unit on the end next to the motor. Therefore, I needed the long screws. Press the orange sun gear for the last 1:5 unit firmly on the motor shaft as far as it will go. If it is not well-seated, the motor clip will not close. It might be a goodidea to put some lubricant on this gear from the tube included with the kit. If you use a different lubricant, test it first on a piece of plastic from the kit to make sure that it is compatible. A dry graphite lubricant would also work quite well. This should spread lubricant on all parts of the last unit, which is the one subject to the highest speeds. Put the motor in place, gently but firmly, wiggling it so that the sun gear meshes. If the sun gear is not meshed, the motor clip will not close. Now put the motor terminals in a vertical column, and press on the motor clamp.The reverse of the instructions show how to attach the drive arm and gives some hints on use of the gearbox. I got an extra spring pin, and two extra 3 mm washers. If you have some small washers, they can be used on the machine screws holding the gearbox together. Enough torque is produced at the output to damage things (up to 6 kg-cm), so make sure the output arm can rotate freely. I used a standard laboratory DC supply with variable voltage and current limiting, but dry cells could be used as well. The current drain of 1 A is high even for D cells, so a power supply is indicated for serious use. The instructions say not to exceed 4.5V, which is good advice. With 400:1 reduction, the motor should run freely whatever the output load.My gearbox ran well the first time it was tested. I timed the output revolutions with a stopwatch, and found 47s for 20 revolutions, or 25.5 rpm. This corresponds to 10,200 rpm at the motor, which is close to specifications. It would be easy to connect another gearbox in series with this one (parts are included to make this possible), and get about 4 revolutions per hour. Still another gearbox would produce about one revolution in four days. This is an excellent kit, and I recommend it highly.Other Epicyclic TrainsA very famous epicyclic chain is the Watt sun-and-planet gear, patented in 1781 as an alternative to the crank for converting the reciprocating motion of a steam engine into rotary motion. It was invented by William Murdoch. The crank, at that time, had been patented and Watt did not want to pay royalties. An incidental advantage was a 1:2 increase in the rotative speed of the output. However, it was more expensive than a crank, and was seldom used after the crank patent expired. Watch the animation on Wikipedia.The input is the arm, which carries the planet gear wheel mating with the sun gear wheel of equal size. The planet wheel is prevented from rotating by being fastened to the connecting rod. It oscillates a little, but always returns to the same place on every revolution. Using the tabular method explained above, the first line is 1, 1, 1 where the first number refers to the arm, the second to the planet gear, and the third to the sun gear. The second line is 0, -1, 1, where we have rotated the planet one turn anticlockwise. Adding, we get 1, 0, 2, which means that one revolution of the arm (one double stroke of the engine) gives two revolutions of the sun gear.We can use the sun-and-planet gear to illustrate another method for analyzing epicyclical trains in which we use velocities. This method may be more satisfying than the tabular method and show moreclearly how the train works. In the diagram at the right, A and O are the centres of the planet and sun gears, respectively. A rotates about O with angular velocity ω1, which we assume clockwise. At the position shown, this gives Aa velocity 2ω1 upward, as shown. Now the planet gear does not rotate, so all points in it move with the same velocity as A. This includes the pitch point P, which is also a point in the sun gear, which rotates about the fixed axis O with angular velocity ω2. Therefore, ω2 = 2ω1, the same result as with the tabular method.The diagram at the left shows how the velocity method is applied to the planetary gear set treated above. The sun and planet gears are assumed to be the same diameter (2 units). The ring gear is then of diameter 6. Let us assume the sun gear is fixed, so that the pitch point P is also fixed. The velocity of point A is twice the angular velocity of the arm. Since P is fixed, P' must move at twice the velocity of A, or fourtimes the velocity of the arm. However, the velocity of P' is three times the angular velocity of the ring gear as well, so that 3ωr = 4ωa. If the arm is the input, the velocity ratio is then 3:4, while if the ring is the input, the velocity ratio is 4:3.A three-speed bicycle hub may contain two of these epicyclical trains, with the ring gears connected (actually, common to the two trains). The input from the rear sprocket is to the arm of one train, while the output to the hub is from the arm of the second train. It is possible to lock one or both of the sun gears to the axle, or else to lock the sun gear to the arm and free of the axle, so that the train gives a 1:1 ratio. The three gears are: high, 3:4, output train locked; middle, 1:1, both trains locked, and low, 4:3 input train locked. Of course, this is just one possibility, and many different variable hubs have been manufactured. The planetary variable hub was introduced by Sturmey-Archer in 1903. The popular AW hub had the ratios mentioned here.Chain hoists may use epicyclical trains. The ring gear is stationary, part of the main housing. The input is to the sun gear, the output from the planet carrier. The sun and planet gears have very different diameters, to obtain a large reduction ratio.The Model T Ford (1908-1927) used a reverted epicyclic transmission in which brake bands applied to the shafts carrying sun gears selected the gear ratio. The low gear ratio was 11:4 forward, while the reverse gear ratio was -4:1. The high gear was 1:1. Reverted means that the gears on the planet carrier shaft drove other gears on shafts concentric with the main shaft, where the brake bands were applied. The floor controls were three pedals: low-neutral-high, reverse, transmission brake. The hand brake applied stopped theleft-hand pedal at neutral. The spark advance and throttle were on the steering column.The automotive differential, illustrated at the right, is a bevel-gear epicyclic train. The pinion drives the ring gear (crown wheel) which rotates freely, carrying the idler gears. Only one idler is necessary, but more than one gives better symmetry. The ring gear corresponds to the planet carrier, and the idler gears to the planet gears, of the usual epicyclic chain. The idler gears drive the side gears on the half-axles, which correspond to the sun and ring gears, and are the output gears. When the two half-axles revolve at the same speed, the idlers do not revolve. When the half-axles move at different speeds, the idlers revolve. The differential applies equal torque to the side gears (they are driven at equal distances by the idlers) while allowing them to rotate at different speeds. If one wheel slips, it rotates at double speed while the other wheel does not rotate. The same (small) torque is, nevertheless, applied to both wheels.The tabular method is easily used to analyze the angular velocities. Rotating the chain as a whole gives 1, 0, 1, 1 for ring, idler, left and right side gears. Holding the ring fixed gives 0, 1, 1, -1. If the right side gear is held fixed and the ring makes one rotation, we simply add to get 1, 1, 2, 0, which says that the left side gear makes two revolutions. The velocity method can also be used, of course. Considering the (equal) forces exerted on the side gears by the idler gears shows that the torques will be equal.ReferencesTamiya Planetary Gearbox Set, Item 72001-1400. Edmund Scientific, Catalog No. C029D, itemD30524-08 ($19.95).C. Carmichael, ed., Kent's Mechanical Engineer's Handbook, 12th ed. (New York: John Wiley and Sons, 1950). Design and Production V olume, p.14-49 to 14-43.V. L. Doughtie, Elements of Mechanism, 6th ed. (New York: John Wiley and Sons, 1947). pp. 299-311. Epicyclic gear. Wikipedia article on epicyclic trains.Sun and planet gear. Includes an animation.行星齿轮机构简介简介Tamiya 行星轮变速箱由一个约行星轮变速箱由一个约 10500 10500 r/min,3.0V r/min,3.0V，，1.0A 的直流电机运行。

翻译部分英文原文Gear mechanismsGear mechanisms are used for transmitting motion and power from one shaft to another by means of the positive contact of successively engaging teeth. In about 2,600B.C., Chinese are known to have used a chariot incorporating a complex series of gears like those illustrated in Fig.2.7. Aristotle, in the fourth century B .C .wrote of gears as if they were commonplace. In the fifteenth century A.D., Leonardo da Vinci designed a multitude of devices incorporating many kinds of gears. In comparison with belt and chain drives ,gear drives are more compact ,can operate at high speeds, and can be used where precise timing is desired. The transmission efficiency of gears is as high as 98 percent. On the other hand, gears are usually more costly and require more attention to lubrication, cleanliness, shaft alignment, etc., and usually operate in a closed case with provision for proper lubrication.Gear mechanisms can be divided into planar gear mechanisms and spatial gear mechanisms. Planar gear mechanisms are used to transmit motion and spatial gear mechanisms. Planar gear mechanisms are used to transmit motion and power between parallel shafts ,and spatial gear mechanisms between nonparallel shafts.Types of gears(1)Spur gears. The spur gear has a cylindrical pitch surface and has straight teeth parallel to its axis as shown in Fig. 2.8. They are used to transmit motion and power between parallel shafts. The tooth surfaces of spur gears contact on a straight line parallel to the axes of gears. This implies that tooth profiles go into and out of contact along the whole facewidth at the same time. This will therefore result in the sudden loading and sudden unloading on teeth as profiles go into and out of contact. As aresult, vibration and noise are produced.(2)Helical gears. These gears have their tooth elements at an angle or helix to the axis of the gear(Fig.2.9). The tooth surfaces of two engaging helical gears inn planar gear mechanisms contact on a straight line inclined to the axes of the gears. The length of the contact line changes gradually from zero to maximum and then from maximum to zero. The loading and unloading of the teeth become gradual and smooth. Helical gears may be used to transmit motion and power between parallel shafts[Fig.2.9(a)]or shafts at an angle to each other[Fig. 2.9(d)]. A herringbone gear [Fig. 2.9(c)] is equivalent to a right-hand and a left-hand helical gear placed side by side. Becauseof the angle of the tooth, helical gears create considerable side thrust on the shaft. A herringbone gear corrects this thrust by neutralizing it , allowing the use of a small thrust bearing instead of a large one and perhaps eliminating one altogether. Often a central groove is made around the gear for ease in machining.(3)Bevel gars. The teeth of a bevel gear are distributed on the frustum of a cone. The corresponding pitch cylinder in cylindrical gears becomes pitch cone. The dimensions of teeth on different transverse planes are different. For convenience, parameters and dimensions at the large end are taken to be standard values. Bevel gears are used to connect shafts which are not parallel to each other. Usually the shafts are 90 deg. to each other, but may be more or less than 90 deg. The two mating gears may have the same number of teeth for the purpose of changing direction of motion only, or they may have a different number of teeth for the purpose of changing both speed and direction. The tooth elements may be straight or spiral, so that we have plain and spiral bevel gears. Hypoid comes from the word hyperboloid and indicates the surface on which the tooth face lies. Hypoid gears are similar to bevel gears, but the two shafts do not intersect. The teeth are curved, and because of the nonintersection of the shafts, bearings can be placed on each side of each gear. The principal use of thid type of gear is in automobile rear ends for the purpose of lowering the drive shaft, and thus the car floor.(4)Worm and worm gears. Worm gear drives are used to transmit motion and ower between non-intersecting and non-parallel shafts, usually crossing at a right angle, especially where it is desired to obtain high gear reduction in a limited space. Worms are a kind of screw, usually right handed for convenience of cutting, or left handed it necessary. According to the enveloping type, worms can be divided into single and double enveloping. Worms are usually drivers to reduce the speed. If not self-locking, a worm gear can also be the driver in a so called back-driving mechanism to increase the speed. Two things characterize worm gearing (a) large velocity ratios, and (b) high sliding velocities. The latter means that heat generation and power transmission efficiency are of greater concern than with other types of gears.(5)Racks. A rack is a gear with an infinite radius, or a gear with its perimeter stretched out into a straight line. It is used to change reciprocating motion to rotary motion or vice versa. A lathe rack and pinion is good example of this mechanism.Geometry of gear toothThe basic requirement of gear-tooth geometry is the provision of angular velocity rations that are exactly constant. Of course, manufacturing inaccuracies andtooth deflections well cause slight deviations in velocity ratio; but acceptable tooth profiles are based on theoretical curves that meet this criterion.The action of a pair of gear teeth satisfying this requirement is termed conjugate gear-tooth action, and is illustrated in Fig. 2.12. The basic law of conjugate gear-tooth action states that as the gears rotate, the common normal to the surfaces at the point of contact must always intersect the line of centers at the same point P called the pitch point.The law of conjugate gear-tooth can be satisfied by various tooth shapes, but the only one of current importance is the involute, or, more precisely, the involute of the circle. (Its last important competitor was the cycloidal shape, used in the gears of Model T Ford transmissions.) An involute (of the circle) is the curve generated by any point on a taut thread as it unwinds from a circle, called the base circle. The generation of two involutes is shown in Fig. 2.13. The dotted lines show how these could correspond to the outer portion of the right sides of adjacent gear teeth. Correspondingly, involutes generated by unwinding a thread wrapped counterclockwise around the base circle would for the outer portions of the left sides of the teeth. Note that at every point, the involute is perpendicular to the taut thread, since the involute is a circular arc with everincreasing radius, and a radius is always perpendicular to its circular arc. It is important to note that an involute can be developed as far as desired outside the base circle, but an involute cannot exist inside its base circle.Let us now develop a mating pair of involute gear teeth in three steps: friction drive, belt drive, and finally, involute gear-tooth drive. Figure 2.14 shows two pitch circles. Imagine that they represent two cylinders pressed together. If slippage does not occur, rotation of one cylinder (pitch circle) will cause rotation of the other at an angular velocity ratio inversely proportional to their diameters. In any pair of mating gears, the smaller of the two is called the pinion and the larger one the gear. (The term “gear” is used in a general sense to indicate either of the members, and also in a specific sense to indicate the larger of the two.) Using subscripts p and g to denote pinion and gear, respectively.In order to transmit more torque than is possible with friction drive alone, we now add a belt drive running between pulleys representing the base circles, as in Fig 2.15. If the pinion is turned counterclockwise a few degrees, the belt will cause the gear to rotate in accordance with correct velocity ratio. In gear parlance, an gle Φ is called the pressure angle. From similar triangles, the base circles have the same ratio as the pitch; thus, the velocity ratio provided by the friction and belt drives are the same.In Fig. 2.16 the belt is cut at point c, and the two ends are used to generate involute profiles de and fg for the pinion and gear, respectively. It should now be clear why Φ is called the pressure angle: neglecting sliding friction, the force of one involute tooth pushing against the other is always at an angle equal to the pressure angle. A comparison of Fig. 2.16 and Fig.2.12 shows that the involute profiles do indeed satisfy the fundamental law of conjugate gear-tooth action. Incidentally, the involute is the only geometric profile satisfying this law that maintains a constant pressure angle as the gears rotate. Note especially that conjugate involute action can take place only outside of both base circles.Nomenclature of spur gearThe nomenclature of spur gear (Fig .2.17) is mostly applicable to all other type of gears.The diameter of each of the original rolling cylinders of two mating gears is called the pitch diameter, and the cylinder’s sectional outline is called the pitch circle. The pitch circles are tangent to each other at pitch point. The circle from which the involute is generated is called the base circle. The circle where the tops of the teeth lie is called the dedendum circle. Similarly, the circle where the roots of the teeth lie is called the dedendum circle. Between the addendum circle and the dedendum circle, there is an important circle which is called the reference circle. Parameters on the reference circle are standardized. The module m of a gear is introduced on the reference circle as a basic parameter, which is defined as m=p/π. Sizes of the teeth and gear are proportional to the module m.The addendum is the radial distance from the reference circle to the addendum circle. The dedendum is the radial distance from the reference circle to the dedendum circle. Clearance is the difference between addendum and dedendum in mating gears. Clearance prevents binding caused by any possible eccentricity.The circular pitch p is the distance between corresponding side of neighboring teeth, measured along the reference circle. The base pitch is similar to the circular pitch is measured along the base circle instead of along the reference circle. It can easily be seen that the base radius equals the reference radius times the cosine of the pressure angle. Since, for a given angle, the ratio between any subtended arc and its radius is constant, it is also true that the base pitch equals the circular pitch times the cosine of the pressure angle. The pressure angle is the angle between the normal and the circumferential velocity of the point on a specific circle. The pressure angle on the reference circle is also standardized. It is most commonly 20º(sometimes 15º).The line of centers is a line passing through the centers of two mating gears. The center distance (measured along the line of centers) equals the sum of the pitchradii of pinion and gear.Tooth thickness is the width of the tooth, measured along the reference circle, is also referred to as tooth thickness. Width of space is the distance between facing side of adjacent teeth, measured along the reference circle. Tooth thickness plus width of space equals the circular pitch. Backlash is the width of space minus the tooth thickness. Face width measures tooth width in an axial direction.The face of the tooth is the active surface of the tooth outside the pitch cylinder. The flank of the tooth is the active surface inside the pitch cylinder. The fillet is the rounded corner at the base of the tooth. The working depth is the sum of the addendum of a gear and the addendum of its mating gear.In order to mate properly, gears running together must have: (a) the same module; (b) the same pressure angle; (c) the same addendum and dedendum. The last requirement is valid for standard gears only.Rolling-ContactbearingsThe rolling-contact bearing consists of niier and outer rings sepatated by a number of rolling elements in the form of balls ,which are held in separators or retainers, and roller bearings have mainly cyinndrical, conical , or barrelcage.The needles are retainde by integral flanges on the outer race,Bearigs with rolling contact have no skopstick effect,low statting torqeu and running friction,and unlike as in journal bearings. The coefficient of friction varies little with load or opeed.Probably the outstanding of a rolling-contant beating over a sliding bearing is its low statting friction.The srdinary sliding bearing starts from rest with practically metal to metal contact and has a high coefficient of friction as compared with that between rolling members.This teature is of particular important in the case of beatings whcch vust carry the same laode at test as when tunning,for example.less than one-thirtieth as much force is required to start a raliroad freight car equopped with roller beatings as with plain journal bearings.However.most journal bearing can only carry relatively light loads while starting and do not become heavily loaded until the speed is high enough for a hydrodynamic film to be built up.At this time the friction id that in the luvricant ,and in a properly designed journal bearing the viscous friction will be in the same order of magnitude ad that for a that for a rolling-conanct bearing.中文译文齿轮机构齿轮机构用来传递运动和动力，通过连续啮合轮齿的正确接触，从一根轴传动到另一根轴。