轴承的摩擦与润滑外文翻译

中英文资料翻译(文档含英文原文和中文翻译)EXTENDING BEARING LIFEAbstract：Nature works hard to destroy bearings, but their chances of survival can be improved by following a few simple guidelines. Extreme neglect in a bearing leads to overheating and possibly seizure or, at worst, an explosion. But even a failed bearing leaves clues as to what went wrong. After a little detective work, action can be taken to avoid a repeat performance.Keywords: bearings failures lifeBearings fail for a number of reasons，but the most common are misapplication，contamination，improper lubricant，shipping or handling damage，and misalignment. The problem is often not difficult to diagnose because a failed bearing usually leaves telltale signs about what went wrong．However，while a postmortem yields good information，it is better to avoid the process altogether by specifying the bearing correctly in The first place．To do this，it is useful to review the manufacturers sizing guidelines and operating characteristics for the selected bearing.Equally critical is a study of requirements for noise, torque, and runout, as well as possible exposure to contaminants, hostile liquids, and temperature extremes. This can provide further clues as to whether a bearing is right for a job.1 Why bearings failAbout 40% of ball bearing failures are caused by contamination from dust, dirt, shavings, and corrosion. Contamination also causes torque and noise problems, and is often the result of improper handling or the application environment．Fortunately, a bearingfailure caused by environment or handling contamination is preventable，and a simple visual examination can easily identify the cause．Conducting a postmortem il1ustrates what to look for on a failed or failing bearing．Then，understanding the mechanism behind the failure, such as brinelling or fatigue, helps eliminate the source of the problem.Brinelling is one type of bearing failure easily avoided by proper handing and assembly. It is characterized by indentations in the bearing raceway caused by shock loading－such as when a bearing is dropped-or incorrect assembly. Brinelling usually occurs when loads exceed the material yield point(350,000 psi in SAE 52100 chrome steel)．It may also be caused by improper assembly, Which places a load across the races．Raceway dents also produce noise，vibration，and increased torque.A similar defect is a pattern of elliptical dents caused by balls vibrating between raceways while the bearing is not turning．This problem is called false brinelling. It occurs on equipment in transit or that vibrates when not in operation. In addition, debris created by false brinelling acts like an abrasive, further contaminating the bearing. Unlike brinelling, false binelling is often indicated by a reddish color from fretting corrosion in the lubricant.False brinelling is prevented by eliminating vibration sources and keeping the bearing well lubricated. Isolation pads on the equipment or a separate foundation may be required to reduce environmental vibration. Also a light preload on the bearing helps keep the balls and raceway in tight contact. Preloading also helps prevent false brinelling during transit.Seizures can be caused by a lack of internal clearance, improper lubrication, or excessive loading. Before seizing, excessive, friction and heat softens the bearing steel. Overheated bearings often change color，usually to blue-black or straw colored．Friction also causes stress in the retainer，which can break and hasten bearing failure．Premature material fatigue is caused by a high load or excessive preload．When these conditions are unavoidable，bearing life should be carefully calculated so that a maintenance scheme can be worked out．Another solution for fighting premature fatigue is changing material．When standard bearing materials，such as 440C or SAE 52100，do not guarantee sufficient life，specialty materials can be recommended. In addition，when the problem is traced back to excessive loading，a higher capacity bearing or different configuration may be used．Creep is less common than premature fatigue．In bearings．it is caused by excessive clearance between bore and shaft that allows the bore to rotate on the shaft．Creep can be expensive because it causes damage to other components in addition to the bearing．0ther more likely creep indicators are scratches，scuff marks，or discoloration to shaftand bore．To prevent creep damage，the bearing housing and shaft fittings should be visually checked．Misalignment is related to creep in that it is mounting related．If races are misaligned or cocked．The balls track in a noncircumferencial path．The problem is incorrect mounting or tolerancing，or insufficient squareness of the bearing mounting site．Misalignment of more than 1/4·can cause an early failure．Contaminated lubricant is often more difficult to detect than misalignment or creep．Contamination shows as premature wear．Solid contaminants become an abrasive in the lubricant．In addition。

外文原文：LUBRICATION AND JOURNAL BEARINGS1 IntroductionA 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 which is transmitting power from one location to another; one example is the crankshaft bearings of automatic engine; another example is the shaft bearings used all types of electric motors. 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 prime considerations:friction results in loss of power, generation of heat and wear of mating surfaces.Journal and antifriction bearings are the two general types of bearings existence. Journal bearings operate with sliding contact, whereas antifriction bearings experience predominantly rolling contact. The amount of sliding friction in journal bearings depends on the surface finishes, materials, sliding velocities and the type of lubricant used. The principle motion-retarding effect in antifriction bearings is called rolling resistance rather than rolling friction. This is so because the resistance of motion is essentially due to the deformation of the rolling elements and, hence, it is not a sliding phenomenon. Antifriction bearings will be in chapter 1.4.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 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.2 Theory of FrictionFriction is the resistance one part exerts on a second part when relative sliding motion occurs or is attempted. Thus friction takes place whenever two surfaces rub together. The cause of friction is the inevitable interlocking of the tiny irregularities of the two mating surfaces. A force is required to deform the tiny peaks and valleys topermit motion.When a block of weight W rests on a horizontal fixed surface, a force P is applied to the block. Initially, P equals zero, but its value constantly increases as a function of time. Due to friction, a force F is created between block and fixed surface. The direction of the frictional force, F, is opposite that of P, because friction always opposes motion or attempted motion. Also note that the normal force, N, acting perpendicular to the mating surface is equal and opposite to the weight, W, of the block.Rolling Contact BearingsThe concern of a machine designer with ball and roller bearings is fivefold as follows:(a) life in relation to load; (b) stiffness, i. e. deflections under load; (c) friction;(d) wear; (e) noise. For moderate loads and speeds the correct selection of a standard bearing on the basis of load rating 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.Because the high quality and low price of ball and roller bearings depends on quantity production, the task of the machine designer becomes one of selection rather than design. Rolling-contact bearings are generally made with steel which is through-hardened to about 900 HV, although in many mechanisms special races are not provided and the interacting surfaces are hardened to about 600 HV. It is not surprising that, owing to the high stresses involved, a predominant form of failure should be metal fatigue, and a good deal of work is based on accepted values of life and it is general practice in the bearing industry to define the load capacity of the bearing as that value below which 90 per cent of a batch will exceed a life of one million revolutions.Notwithstanding the fact that responsibility for the basic design of ball 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 criticalimportance 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.Where life is not the determining factor in design, it is usual to determine maximum loading by the amount to which a bearing will deflect under load. Thus the concept of “static load-carrying capacity” is understood to mean the load that can be applied to a bearing, which is either stationary or subject to slight swiveling motions, without impairing its running qualities for subsequent rotational motion. This has been determined by practical experience as the load which when applied to a bearing results in a total deformation of the rolling-element diameter. This would correspond to a permanent deformation of 0.0025 mm for a ball 25 mm in diameter.The successful functioning of many bearings depends upon providing them with adequate protection against their environment, and in some circumstances the environment must be protected from lubricants or products of deterioration of the bearing design. Moreover, seals which are applied to moving parts for any purpose are of interest to tribologists because they are components of bearing systems and can only be designed satisfactorily on the basis of the appropriate bearing theory.Notwithstanding their importance, the amount of research effort that has been devoted to the understanding of the behavior of seals has been small when compared with that devoted to other aspects of bearing technology.Numerical ControlOne of the most fundamental concepts in the area of advanced manufacturing technologies is numerical control (NC). Prior to the advent of NC, all machine tools were manually operated and controlled .Among the many limitations associated with manual control machine tools, perhaps none is more prominent than the limitation of operator skills. With manual control, the quality of the product is directly related to and limited to the skills of the operator. Numerical control represents the first major step away from human control of machine tools.Numerical control means the control of machine tools and other manufacturing systems through the use of prerecorded, written symbolic instructions. Rather thanoperating a machine tool, an NC technician writes a program that issues operational instructions to the machine tool. For a machine tool to be numerically controlled, it must be interfaced with a device for accepting and decoding the programmed instructions, known as a reader.Numerical control was developed to overcome the limitation of human operators, and it has done so. Numerical control machines are more accurate than manually operated machines, they can produce parts more uniformly, they are faster, and the long-run tooling costs are lower. The development of NC led to the development of several other innovations in manufacturing technology:1.Electrical discharge machining.ser cutting.3.Electron beam welding.Numerical control has also made machine tools more versatile than their manually operated predecessors. An NC machine tool can automatically produce a wide variety of parts, each involving an assortment of widely varied and complex machining processes. Numerical control has allowed manufacturers to undertake the production of products that would not have been feasible from an economic perspective using manually controlled machine tools and processes.Like so many advanced technologies, NC was born in the laboratories of the Massachusetts Institute of Technology. The concept of NC was developed in the early 1950s with funding provided by the U. S. Air force. In its earliest stages, NC machines were able to make straight cuts efficiently and effectively.However, curved paths were a problem because the machine tool had to be programmed to undertake a series of horizontal and vertical steps to produce a curve. The shorter is the straight lines making up the steps, the smoother is the curve. Each line segment in the steps had to be calculated.This problem led to the development in 1959 of the Automatically Programmed Tools (APT) language. This is a special programming language for NC that uses statements similar to English language to define the part geometry, describe the cutting tool configuration, and specify the necessary motions. The development of the APT language was a major step forward in the further development of NC technology. The original NC systems were vastly different from those used today. The machines had hardwired logic circuits. The instructional programs were written on punched paper, which was later to be replaced by magnetic plastic tape. A tape reader was usedto interpret the instructions written on the tape for the machine. Together, all of this represented a giant step forward in the control of machine tools. However, there were a number of problems with NC at this point in its development.A major problem was the fragility of the punched paper tape medium. It was common for the paper tape containing the programmed instructions to break or tear during a machining process. This problem was exacerbated by the fact that each successive time a part was produced on a machine tool, the paper tape carrying the programmed instructions had to be rerun through the reader. If it was necessary to produce 100 copies of a given part, it was also necessary to run the paper tape through the reader 100 separate times. Fragile paper tapes simply could not withstand the rigors of a shop floor environment and this kind of repeated use.This led to the development of a special magnetic plastic tape. Whereas the paper tape carried the programmed instructions as a series of holes punched in the tape, the plastic tape carried the instructions as a series of holes punched in the tape, the plastic tape carried the instructions as a series of magnetic dots. The plastic tape was much stronger than the paper taps, which solved the problem of frequent tearing and breakage. However, it still left two other problems.The most important of these was that it was difficult or impossible to change the instructions entered on the tape. To make even the most minor adjustments in a program of instructions, it was necessary to interrupt machining operations and make a new tape .It was also still necessary to run the tape through the reader as many times as there were parts to be produced. Fortunately, computer technology became a reality and soon solved the problems of NC associated with punched paper and plastic tape.The development of a concept known as direct numerical control (DNC) solved the paper and plastic tape problems associated with numerical control by simply eliminating tape as the medium for carrying the programmed instructions. In direct numerical control .machine tools are tied, via a data transmission link, to a host computer. Programs for operating the machine tools are stored in the host computer and fed to the machine tool as needed via the data transmission linkage. Direct numerical control represented a major step forward over punched tape and plastic tape. However, it is subject to the same limitations as all technologies that depend on a host computer. When the lost computer goes down, the machine tools also experience downtime. This problem led to the development of computer numerical control.The development of the microprocessor allowed for the development ofprogrammable logic controllers (PLCs) and microcomputers. These two technologies allowed for the development of computer numerical control (CNC).With CNC, each machine tool has a PLC or a microcomputer that serves the same purpose. This allows programs to be input and stored at each individual machine tool. It also allows programs to be developed off-line and downloaded at the individual machine tool. CNC solved the problems associated with downtime of the host computer, but it introduced another known as data management. The same program might be loaded on ten different microcomputers with no communication among them. This problem is in the process of being solved by local area networks that connect microcomputers for better data management.中文译文：润滑和轴颈轴承1 介绍专用与支撑机器部件进行回转运动的原件可以被称为轴承。

slewing ring bearing (slewving bearing)回转支承轴承即转盘轴承1. adapter bearing带固接套的轴承2. adjustable bearing可调轴承3. adjustable cone colter bearing圆犁刀的可调式锥形轴承4. aerostatic bearing空气静力轴承5. agate bearing玛瑙轴承6. air journal bearing气体轴承7. air lubricated thrust bearing空气润滑止推轴承8. aligning bearing(直线)对位轴承9. alkaline-friction bearing抗磨轴承10. allowable bearing容许支承力11. all-rubber type bearing全胶式轴承。

全橡胶轴承12. aluminum base bearing铝基合金轴承13. aluminum-tin bearing铝锡合金轴承14. angular ball bearing径向止推滚珠轴承15. angular contact ball bearing角面接触滚珠轴承，向心止推滚珠轴承16. angular contact journal bearing角面接触轴颈轴承17. annular ball bearing向心球轴承，径向滚珠轴承18. annular contact thrust ball bearing推力向心球轴承19. antenna bearing(电磁)天线方位20. antifriction thrust bearing减磨推力轴承，减磨止推轴承21. antithrust bearing止推轴承22. asymmetrical roller bearing非对称滚子轴承23. axial bearing支撑轴承，止推轴承24. axial thrust bearing轴向推力轴承25. axle box bearing轴箱轴承26. azimuth bearing方位27. babbit metal (cast) bearing(铸造)巴氏合金轴承28. babbit-lined bearing巴氏合金衬套轴承，衬巴氏合金的轴承29. ba ck be aring反象限角，后轴承，反方位(炮)30. back-to-back duplex bearing成对双联轴承(外圈宽端面相对)31. ball bearing滚珠轴承32. ball collar thrust bearing滚珠环止推轴承，滚珠环推力轴承33. ball journal bearing球颈轴承34. ball thrust bearing止推滚珠轴承35. barrel bearing圆筒轴承36. base bearing主轴承，底轴承，基轴承37. bellbearing钟杆推力轴承，小钟杆平球架，炉钟杠杆38. bevel pinion front bearing小锥齿轮前[后]轴承39. big-end bearing大端轴承40. blade bearing刃型支承41. blo ck be aring支承轴承，止推轴承42. boring bar bearing镗杆轴承43. box bearing空转轴承44. bracket bearing托架轴承45. bushing bearing衬套轴承46. cageless rolling bearing无保持架轴承47. camshaft bearing凸轮轴轴承48. center bearing下心盘,下心盘支承面;中心支承49. centring spring rod bearing调准簧杆轴承50. ceramic bearing陶瓷轴承51. che ck be aring检验方位,检验轴承52. circular unidirectional thrust bearing环状单向推力轴承53. closed-type bearing密闭形轴承54. clutch release bearing离合器分离轴承55. collar (thrust) bearing环形止推轴承56. combination bearing组合轴承57. commutator side bearing整流子侧支座58. composite bearing多层轴瓦,复合轴承59. compressed air bearing压缩空气轴承,压气轴承60. concentric adjustable bearing同心调整轴承61. conical bearing圆锥轴承62. corrugated bearing梳状轴承,槽形轴承63. countershaft gear bearing副轴齿轮轴承64. crank(ed) bearing曲轴轴承,曲柄轴承,连杆轴承65. cross head holt bearing十字头销轴承66. cross head pin bearing十字头销轴承67. cryogenic bearing低温轴承68. cup-and-cone bearing对开径向上止推轴承69. cutter bearing滚刀轴承70. declutch shaft bearing离合器操纵轴承,分离轴轴承71. diamond bearing金刚石轴承72. die cast bearing模铸轴承73. differential drive pinion cage bearing差速器主小齿轮轴承罩74. differential side bearing差速器壳轴承75. disk bearing圆盘轴承76. disk harrow bearing圆盘耙轴承77. distributor upper bearing配电器上轴承78. double bearing双列轴承79. double shield bearing双(护)罩轴承80. double thrust bearing双止推轴承81. double-row angular contact ball bearing双列向心推力球轴承82. double-row ball journal bearing双列径向滚珠轴承83. double-row radial ball bearing双列向心球轴承84. double-row radial spherical roller bearing双列向心鼓面滚子轴承85. double-row self-aligning spherical roller86. bearing双列向心球面滚子轴承(自动调心型)87. drag link bearing拉杆支座88. drive end bearing主动端轴承,驱动端轴承89. drive pinion cone bearing主动小齿轮锥形轴承90. drive shaft bearing主动轴轴承91. drop-hanger bearing悬挂轴承92. drum roller bearing鼓形滚柱轴承93. dry bearing干轴承94. duplex bearing双轴承95. duplex ball bearing成对双联向心推力球轴承96. dynamo bearing发电机轴承97. elastically yielding bearing弹性退让轴承98. elliptical bearing椭圆形轴承99. enclosed tubular bearing密封套管轴承(属于油浴润滑式轴承) 100. end journal bearing端枢轴承101. end shield bearing机油滤清器内盖头轴承102. end thrust bearing止推轴承103. end-mounted bearing(耙组)两端安装的轴承104. engine thrust ball bearing止推滚珠轴承105. established line bearing非标准轴承106. expansion bearing活动支承,温度)伸胀支承107. expansive end bearing of bridge活动桥支座108. fabric bearing夹布胶木轴承109. fan end thrust ball bearing风扇端止推滚球轴承110. fan shaft bearing风扇轴轴承111. Ferro porit bearing渗硫铁系含油轴承112. filling slot type bearing填槽式轴承113. film bearing油膜轴承114. film lubrication bearing油膜轴承,液体摩擦轴承115. fixed-type bearing固定轴承116. flange bearing带法兰盘轴承117. flanged cup bearing外环凸缘轴承118. flexible bearing挠性轴承119. floating bush bearing浮动衬套轴承120. flood-lubricated bearing液体摩擦轴承,油膜轴承121. fluid bearing液压轴承122. fluid-film bearing流体膜轴承123. footstep bearing立轴承124. fore bearing前轴承125. fork bearing叉轴承126. forward bearing前象限角127. four-row tapered roller bearing四列圆锥滚柱轴承128. free end bearing活动支承,自由支承129. friction bearing滑动轴承130. friction thrust bearing摩擦止推轴承131. front main bearing前主轴承132. fulcrum bearing支承133. full-journal bearing全围式滑动轴承full-molded type rubber bearing整体模制式橡胶轴承134. gas-lubricated bearing气体润滑轴承135. gear shaft roller bearing齿轮轴滚柱轴承136. globe bearing球面轴承137. graphite bearing石墨板(离合器分离的),石墨轴承138. graphite-containing bearing含石墨的轴承139. graphited oilless bearing石墨润滑的无油轴承140. gravity side bearing重力复原旁承141. grid bearing坐标(网)方位142. grinding wheel bearing砂轮轴承143. groove ball bearing带沟球轴承144. guardbearing动力输出轴的)护罩轴承145. gudgeon pin bearing活塞销轴承,耳轴销轴承146. guide bearing导向轴承,导引轴承,定向轴承,导引方位角147. guide spindle bearing导轴轴承148. gunmetal bearing炮铜轴承149. half-and-haif bearing半轴承无盖轴承150. hanging bearing吊挂轴承151. hardwood bearing硬木轴承152. head bearing止端轴承153. heavy-duty bearing重载轴承154. hydrodynamic journal bearing液体动压轴承,油膜轴承155. hydrostatic bearing静压轴承156. idler shaft bearing空转轴轴承157. inclined bearing(倾)斜轴承,斜支承158. inner bearing内轴承159. intermediate bearing中间轴承160. jack shaft bearing曲柄轴轴承161. jewelled bearing宝石轴承162. Jordan bearing推力套筒轴承163. journal bearing经向轴承164. kick-starter bearing冲式起动器的曲柄轴承165. kingpin bearing凸轮止推回转轴承,止推销轴承,止推枢轴承,中心(转向节)轴承166. knife-edge bearing刃形支承,刃支承,刀口承167. knuckle bearing铰式支座,球形支座,关节轴承168. labyrinth bearing迷宫轴承,曲径式密封轴承169. laminated bearing夹布胶木轴承,层压轴承170. leading -screw bearing传动螺杆轴承171. lignumvitae bearing层压胶木轴承172. locating bearing止推轴承,定位轴承173. lock nut bearing锁紧螺帽座174. longitudinal wall hanger bearing墙托架轴承175. long-path bearing远距离方位176. lower bearing下轴承177. lower half bearing轴承下瓦178. lubed-for-life bearing永久润滑轴承(即橡胶轴承)179. lubri-seal bearing阻油环轴承180. magnetic bearing磁向位,磁方位181. magnetic thrust bearing磁性推力轴承182. main bearing主轴承183. main rod bearing主杆轴承184. mainshaft bearing主轴轴承185. maintenance-free bearing自润滑轴承186. mechanical bearing轴承(总称)187. midship shaft bearing中间轴轴承188. miniature bearing微型轴承,超小型轴承189. molded-fabric bearing(设计)模制纤维轴承190. motor support bearing电动机支承轴承191. movable bearing活动支承192. multi-roll bearing滚针轴承193. multirow bearing多列轴承194. multipart bearing弓形轴承,扇形轴承195. multiple-groove bearing多油槽轴承196. neck bearing中间轴承197. needle bearing滚针轴承198. needle(type) roller bearing滚针轴承199. noise-free bearing低噪声轴承200. nonfilling slot type bearing无滚珠槽的滚动轴承201. non-locating bearing浮动轴承,不定位轴承202. non-porous bearing无孔轴承203. oil film bearing油膜轴承204. oil flooded bearing油膜轴承,液体摩擦轴承205. oil-bath type bearing油浴润滑式轴承206. oilless bearing不加油轴承自动润滑轴承石墨润滑轴承，含油轴承207. oil-retaining bearing含油轴承208. open spindle bearing开式锭子轴承209. oscillating bearing关节轴承210. oscillating journal bearing摆动轴径轴承211. outboard bearing外置轴承212. parallel bearing滑动轴承213. parallel-roller bearing平行滚柱轴承214. partial bearing半轴承215. partial journal bearing半围轴承(轴瓦在180°范围内包围着轴颈的滑动轴承) 216. pedestal bearing支承轴承217. pendulum bearing钟摆轴承218. pin rocker bearing铰接支座,圆柱枢轴摆动轴承219. pinion bearing小齿轮轴承220. piston pin bearing活塞销轴承221. pivot bearing枢轴承,摆动支座,中心(轴尖)支承,立式止推轴承222. plain-and -ball bearing滑动与滚动组合轴承223. plane bearing平面轴承224. plummer block bearing架座,止推轴承225. pneumatic bearing空气轴承226. pocket bearing油盘轴承227. porous bearing多孔轴承228. powdiron bearing多孔铁轴承,粉未铁轴承229. power take-off lever bearing动力输出轴轴承230. preloaded bearing预紧轴承231. prelubricated bearing预(加)润滑[油密封]轴承,一次润滑轴承232. pressure-feed air bearing静压空气轴承233. pressure-loaded bearing承压轴承234. proper bearing紧密接触轴承235. pump bearing泵轴承236. quill bearing滚针轴承237. radial journal bearing径向轴承,支持轴承,轴颈轴承238. radial spherical roller bearing径向球形滚柱轴承239. radial-thrust bearing径向止推轴承240. rail bearing轨枕,轨承,轨底支承面241. rear bearing后轴承(车床)242. rigid type bearing刚性支承点,刚性支承面非自位滚动轴承243. rim bearing轮缘座,环承244. ring-oiled sleeve bearing油环润滑式滑动轴承;油环式滑动轴承245. rocker bearing桥架)摇轴支座; (桁架)伸缩支座246. rod bearing杆轴承247. roller bearing滚柱轴承248. roller step bearing滚柱止推轴承249. rolling-contact bearing滚动接触轴承250. rotating journal bearing转动轴颈轴承251. round bearing转动件轴承252. rubber bearing橡胶轴承253. sealed roller bearing密封式滚子轴承254. sector gear bearing扇形齿轮轴承255. segmental bearing弓形轴承,弧形轴承,分片互轴承,轴瓦块轴承256. self-acting air bearing动压空气轴承257. self-aligning bearing球面轴承,自位轴承258. self-setting bearing多向调整轴承259. shafting bearing轴承260. shell bearing轴承壳261. shifting bearing活动支座262. shock absorber bearing减震器座263. side rod bearing边杆轴承264. single plate ball bearing单垫片滚珠轴承265. single row angular contact ball bearing单列向心推力球轴承266. single row cylindrical roller bearing单列短圆柱滚子轴承267. single shield bearing单罩轴承268. single thrust bearing单向推力轴承,单向止推轴承269. single-row bearing单列轴承270. single-row separable ball bearing分离型向心推力球轴承271. single-row tapered roller bearing单列圆锥滚子轴承272. sintered metal bearing烧结金属轴承273. sleeve bearing套筒轴承,滑动轴承274. slewing bearing旋转枢轴轴承275. slide bearing滑动轴承276. sliding double bearing滑动复式轴承277. snap-ring bearing开口环轴承278. snap-ring ball bearing(在负荷端)带止动垫圈的滚珠轴承279. solid journal bearing整体轴颈轴承280. solid roller bearing实心滚子轴承,整体滚柱轴承281. special guide bearing特种导承282. spherical bearing球面轴承,球形支座,球面支承283. spherical roller thrust bearing推力球面滚子轴承284. spigot bearing导向轴承,套筒轴承，小载荷轴承,轻载轴承，插口轴承285. spindle bolt bearing心轴螺栓轴承286. spiral roller bearing螺旋(式)滚子轴承287. spot contact bearing滚珠轴承288. spring plank bearing摇枕吊轴289. sprocket shaft bearing链轮轴轴承290. square-bore ball bearing方(轴)孔滚珠轴承291. squeeze film bearing(挤)压(油)膜轴承292. starter main shaft bearing起动机主轴轴承293. steady bearing支撑轴承(防止长轴摆动)294. steep angle bearing大锥角滚柱轴承295. steering gear worm thrust bearing转向蜗杆止推轴承296. steering knuckle thrust bearing转向关节主动轴承297. steering worm bearing转向蜗杆轴承298. steering worm sector bearing转向器扇形蜗轮轴承299. step bearing立式止推轴承,踏板轴承,阶式止推轴承300. straight roller bearing普通滚柱轴承301. stuffing box bearing填料压盖轴承,密封轴承302. suspension bearing吊轴承303. swing bearing摆动支座,摆锤支座304. swivel bearing旋转轴承305. taper-bore cylindrical-roller bearing 锥孔圆柱滚子轴承306. taper-roller bearing锥形滚柱轴承307. textolite bearing夹布胶木轴承308. thermo-expansion compensation angular ball bearing热胀补偿向心球轴承309. thrust bearing推力轴承,止推轴承推力座310. tin-copper-graphite bearing青铜石墨轴承311. tip bearing枢轴承,枢支座312. toe bearing立式止推轴承313. top bearing上盖(顶盖)轴承314. Torrington needle bearing(无内座圈的)冲压外座圈滚针轴承315. torsion bearing抠转轴承316. transverse bearing径向轴承317. truck side bearing(机车的)下旁承,底板,镶板,闸瓦托318. trunnion bearing耳轴承319. tumbler bearing铰式支座,摆动支座(轴承)320. two-direction self-aligning ball thrust321. bearing双球面止推滚珠轴承,自调止推滚珠轴承322. two-piece bearing对开轴承,拼合轴承,可调轴承323. two-point bearing二点交叉定位324. uncoupling lever shaft bearing互钩开关杆轴承325. universal-joint cross bearing万向接头轴承326. universal-joint needle bearing万向节针式轴承327. upper bearing上轴承,上轴瓦328. upper center crankshaft bearing曲轴主轴承上中轴瓦329. water lubricated bearing水润滑轴承330. water pump shaft bearing水泵轴轴承331. water-sealed bearing防水轴承332. weight-carrying roller bearing径向滚柱轴承333. wheel bearing轮轴轴承334. wick-lubricated bearing油渑润滑轴承335. winch worm shaft bearing绞车蜗杆轴承336. wire race ball bearing钢丝滚道球轴承337. wooden bearing木制轴承338. worm bearing蜗杆轴承339. worm shaft roller conical bearing蜗杆锥棍轴承340. worm thrust bearing蜗杆止推轴承341. wrist-pin bearing十字头销衬套,活塞销衬套。

关于轴承的术语，大家了解多少呢？今天为大家带来轴承术语大全中英文对照版。

带固接套的轴承adapter bearing；可调轴承adjustable bearing；圆犁刀的可调式锥形轴承adjustable cone colter bearing空气静力轴承aerostatic bearing；玛瑙轴承agate bearing；气体轴承air journal bearing；空气润滑止推轴承air lubricated thrust bearing (直线)对位轴承aligning bearing；抗磨轴承alkaline-friction bearing；容许支承力allowable bearing；全胶式轴承。

全橡胶轴承all-rubber type bearing；铝基合金轴承aluminum base bearing；铝锡合金轴承aluminum-tin bearing；径向止推滚珠轴承angular ball bearing；角面接触滚珠轴承，向心止推滚珠轴承angular contact ball bearing；角面接触轴颈轴承angular contact journal bearing；向心球轴承，径向滚珠轴承annular ball bearing；推力向心球轴承annular contact thrust ball bearing；(电磁)天线方位antenna bearing；减磨推力轴承，减磨止推轴承antifriction thrust bearing；止推轴承antithrust bearing；非对称滚子轴承asymmetrical roller bearing；支撑轴承，止推轴承axial bearing；轴向推力轴承axial thrust bearing；轴箱轴承axle box bearing；方位azimuth bearing；反象限角，后轴承，反方位(炮)back bearing；成对双联轴承(外圈宽端面相对)back-to-back duplex bearing；滚珠轴承ball bearing；滚珠环止推轴承，滚珠环推力轴承ball collar thrust bearing；球颈轴承ball journal bearing；止推滚珠轴承ball thrust bearing；圆筒轴承barrel bearing；主轴承，底轴承，基轴承base bearing；钟杆推力轴承，小钟杆平球架，炉钟杠杆bellbearing；小锥齿轮前[后]轴承bevel pinion front bearing；大端轴承big-end bearing；刃型支承blade bearing；支承轴承，止推轴承block bearing；镗杆轴承boring bar bearing；空转轴承box bearing；托架轴承bracket bearing；衬套轴承bushing bearing；无保持架轴承cageless rolling bearing；凸轮轴轴承camshaft bearing；下心盘,下心盘支承面;中心支承center bearing；调准簧杆轴承centring spring rod bearing；陶瓷轴承ceramic bearing；检验方位,检验轴承check bearing；环状单向推力轴承circular unidirectional thrust bearing；密闭形轴承closed-type bearing；离合器分离轴承clutch release bearing；环形止推轴承collar (thrust) bearing；组合轴承combination bearing；整流子侧支座commutator side bearing；多层轴瓦,复合轴承composite bearing；压缩空气轴承,压气轴承compressed air bearing；同心调整轴承concentric adjustable bearing；圆锥轴承conical bearing；梳状轴承,槽形轴承corrugated bearing；副轴齿轮轴承countershaft gear bearing；曲轴轴承,曲柄轴承,连杆轴承crank(ed) bearing；十字头销轴承cross head holt bearing；十字头销轴承cross head pin bearing；低温轴承cryogenic bearing；对开径向上止推轴承cup-and-cone bearing；滚刀轴承cutter bearing；离合器操纵轴承,分离轴轴承declutch shaft bearing；金刚石轴承diamond bearing；模铸轴承die cast bearing；差速器主小齿轮轴承罩differential drive pinion cage bearing；差速器壳轴承differential side bearing；圆盘轴承disk bearing；圆盘耙轴承disk harrow bearing；配电器上轴承distributor upper bearing；双列轴承double bearing；双(护)罩轴承double shield bearing；双止推轴承double thrust bearing；双列向心推力球轴承double-row angular contact ball bearing；双列径向滚珠轴承double-row ball journal bearing；双列向心球轴承double-row radial ball bearing；双列向心鼓面滚子轴承double-row radial spherical roller bearing；双列向心球面滚子轴承(自动调心型)double-row self-aligning spherical roller bearing；拉杆支座drag link bearing；主动端轴承,驱动端轴承drive end bearing；主动小齿轮锥形轴承drive pinion cone bearing；主动轴轴承drive shaft bearing；悬挂轴承drop-hanger bearing；鼓形滚柱轴承drum roller bearing；干轴承dry bearing；双轴承duplex bearing；成对双联向心推力球轴承duplex ball bearing；发电机轴承dynamo bearing；弹性退让轴承elastically yielding bearing；椭圆形轴承elliptical bearing；密封套管轴承(属于油浴润滑式轴承)enclosed tubular bearing；端枢轴承end journal bearing；机油滤清器内盖头轴承end shield bearing；止推轴承end thrust bearing；(耙组)两端安装的轴承end-mounted bearing；止推滚珠轴承engine thrust ball bearing；非标准轴承established line bearing；活动支承,温度)伸胀支承expansion bearing；活动桥支座expansive end bearing of bridge；夹布胶木轴承fabric bearing；风扇端止推滚球轴承fan end thrust ball bearing；风扇轴轴承fan shaft bearing；渗硫铁系含油轴承Ferro porit bearing；填槽式轴承filling slot type bearing；油膜轴承film bearing；油膜轴承,液体摩擦轴承film lubrication bearing；固定轴承fixed-type bearing；带法兰盘轴承flange bearing；外环凸缘轴承flanged cup bearing；挠性轴承flexible bearing；浮动衬套轴承floating bush bearing；液体摩擦轴承,油膜轴承flood-lubricated bearing；液压轴承fluid bearing；流体膜轴承fluid-film bearing；立轴承footstep bearing；前轴承fore bearing；叉轴承fork bearing；前象限角forward bearing；四列圆锥滚柱轴承four-row tapered roller bearing；活动支承,自由支承free end bearing；滑动轴承friction bearing；摩擦止推轴承friction thrust bearing；前主轴承front main bearing；支承fulcrum bearing；全围式滑动轴承full-journal bearing；整体模制式橡胶轴承full-molded type rubber bearing；气体润滑轴承gas-lubricated bearing；齿轮轴滚柱轴承gear shaft roller bearing；球面轴承globe bearing；石墨板(离合器分离的),石墨轴承graphite bearing；含石墨的轴承graphite-containing bearing；石墨润滑的无油轴承graphited oilless bearing；重力复原旁承gravity side bearing；坐标(网)方位grid bearing；砂轮轴承grinding wheel bearing；带沟球轴承groove ball bearing；动力输出轴的)护罩轴承guardbearing；活塞销轴承,耳轴销轴承gudgeon pin bearing；导向轴承,导引轴承,定向轴承,导引方位角guide bearing；导轴轴承guide spindle bearing；炮铜轴承gunmetal bearing；半轴承无盖轴承half-and-haif bearing；吊挂轴承hanging bearing；硬木轴承hardwood bearing；止端轴承head bearing；重载轴承heavy-duty bearing；液体动压轴承,油膜轴承hydrodynamic journal bearing；静压轴承hydrostatic bearing；空转轴轴承idler shaft bearing；(倾)斜轴承,斜支承inclined bearing；内轴承inner bearing；中间轴承intermediate bearing；曲柄轴轴承jack shaft bearing；宝石轴承jewelled bearing；推力套筒轴承Jordan bearing；经向轴承journal bearing；冲式起动器的曲柄轴承kick-starter bearing；凸轮止推回转轴承,止推销轴承,止推枢轴承,中心(转向节)轴承kingpin bearing；刃形支承,刃支承,刀口承knife-edge bearing；铰式支座,球形支座,关节轴承knuckle bearing；迷宫轴承,曲径式密封轴承labyrinth bearing；夹布胶木轴承,层压轴承laminated bearing；传动螺杆轴承leading -screw bearing；层压胶木轴承lignumvitae bearing；止推轴承,定位轴承locating bearing；锁紧螺帽座lock nut bearing；墙托架轴承longitudinal wall hanger bearing；远距离方位long-path bearing；下轴承lower bearing；轴承下瓦lower half bearing；永久润滑轴承(即橡胶轴承)lubed-for-life bearing；阻油环轴承lubri-seal bearing；磁向位,磁方位magnetic bearing；磁性推力轴承magnetic thrust bearing；主轴承main bearing；主杆轴承main rod bearing；主轴轴承mainshaft bearing；自润滑轴承maintenance-free bearing；轴承(总称)mechanical bearing；中间轴轴承midship shaft bearing；微型轴承,超小型轴承miniature bearing；(设计)模制纤维轴承molded-fabric bearing；电动机支承轴承motor support bearing；活动支承movable bearing；滚针轴承multi-roll bearing；多列轴承multirow bearing；弓形轴承,扇形轴承multipart bearing；多油槽轴承multiple-groove bearing；中间轴承neck bearing；needle bearing滚针轴承；滚针轴承needle(type) roller bearing；低噪声轴承noise-free bearing；无滚珠槽的滚动轴承nonfilling slot type bearing；浮动轴承,不定位轴承non-locating bearing；无孔轴承non-porous bearing；油膜轴承oil film bearing；油膜轴承,液体摩擦轴承oil flooded bearing；油浴润滑式轴承oil-bath type bearing；不加油轴承自动润滑轴承石墨润滑轴承，含油轴承oilless bearing；含油轴承oil-retaining bearing；开式锭子轴承open spindle bearing；希望能帮到大家更加好地了解轴承，如果喜欢的话，大家可以收藏。

lower half bearing轴承下瓦lubed-for-life bearing永久润滑轴承(即橡胶轴承)lubri-seal bearing阻油环轴承magnetic bearing磁向位,磁方位magnetic thrust bearing磁性推力轴承main bearing主轴承main rod bearing主杆轴承mainshaft bearing主轴轴承maintenance-free bearing自润滑轴承mechanical bearing轴承(总称)midship shaft bearing中间轴轴承miniature bearing微型轴承,超小型轴承molded-fabric bearing(设计)模制纤维轴承motor support bearing电动机支承轴承movable bearing活动支承multi-roll bearing滚针轴承multirow bearing多列轴承multipart bearing弓形轴承,扇形轴承multiple-groove bearing多油槽轴承neck bearing中间轴承needle bearing滚针轴承needle(type) roller bearing滚针轴承noise-free bearing低噪声轴承nonfilling slot type bearing无滚珠槽的滚动轴承non-locating bearing浮动轴承,不定位轴承non-porous bearing无孔轴承oil film bearing油膜轴承oil flooded bearing油膜轴承,液体摩擦轴承oil-bath type bearing油浴润滑式轴承oilless bearing不加油轴承自动润滑轴承石墨润滑轴承，含油轴承oil-retaining bearing含油轴承open spindle bearing开式锭子轴承oscillating bearing关节轴承oscillating journal bearing摆动轴径轴承outboard bearing外置轴承parallel bearing滑动轴承parallel-roller bearing平行滚柱轴承partial bearing半轴承partial journal bearing半围轴承(轴瓦在180°范围内包围着轴颈的滑动轴承) pedestal bearing支承轴承pendulum bearing钟摆轴承pin rocker bearing铰接支座,圆柱枢轴摆动轴承pinion bearing小齿轮轴承piston pin bearing活塞销轴承轴承的中英文对照（三）2007-03-05 16:39gyro bearing旋转方位,陀螺仪方位,回转器方向half-and-haif bearing半轴承无盖轴承hanging bearing吊挂轴承hardwood bearing硬木轴承head bearing止端轴承heavy-duty bearing重载轴承hydrodynamic journal bearing液体动压轴承,油膜轴承hydrostatic bearing静压轴承idler shaft bearing空转轴轴承inclined bearing(倾)斜轴承,斜支承inner bearing内轴承intermediate bearing中间轴承jack shaft bearing曲柄轴轴承jewelled bearing宝石轴承Jordan bearing推力套筒轴承journal bearing经向轴承kick-starter bearing冲式起动器的曲柄轴承kingpin bearing凸轮止推回转轴承,止推销轴承,止推枢轴承,中心(转向节)轴承knife-edge bearing刃形支承,刃支承,刀口承knuckle bearing铰式支座,球形支座,关节轴承labyrinth bearing迷宫轴承,曲径式密封轴承laminated bearing夹布胶木轴承,层压轴承leading -screw bearing传动螺杆轴承lignumvitae bearing层压胶木轴承load bearing承载,承重locating bearing止推轴承,定位轴承lock nut bearing锁紧螺帽座longitudinal wall hanger bearing墙托架轴承long-path bearing远距离方位lower bearing下轴承lower half bearing轴承下瓦lubed-for-life bearing永久润滑轴承(即橡胶轴承)lubri-seal bearing阻油环轴承magnetic bearing磁向位,磁方位magnetic thrust bearing磁性推力轴承main bearing主轴承main rod bearing主杆轴承mainshaft bearing主轴轴承maintenance-free bearing自润滑轴承mechanical bearing轴承(总称)midship shaft bearing中间轴轴承miniature bearing微型轴承,超小型轴承molded-fabric bearing(设计)模制纤维轴承motor support bearing电动机支承轴承movable bearing活动支承multi-roll bearing滚针轴承multirow bearing多列轴承multipart bearing弓形轴承,扇形轴承multiple-groove bearing多油槽轴承neck bearing中间轴承needle bearing滚针轴承needle(type) roller bearing滚针轴承noise-free bearing低噪声轴承nonfilling slot type bearing无滚珠槽的滚动轴承non-locating bearing浮动轴承,不定位轴承non-porous bearing无孔轴承oil film bearing油膜轴承oil flooded bearing油膜轴承,液体摩擦轴承oil-bath type bearing油浴润滑式轴承oilless bearing不加油轴承自动润滑轴承石墨润滑轴承，含油轴承oil-retaining bearing含油轴承open spindle bearing开式锭子轴承oscillating bearing关节轴承oscillating journal bearing摆动轴径轴承outboard bearing外置轴承parallel bearing滑动轴承parallel-roller bearing平行滚柱轴承partial bearing半轴承partial journal bearing半围轴承(轴瓦在180°范围内包围着轴颈的滑动轴承) pedestal bearing支承轴承pendulum bearing钟摆轴承pin rocker bearing铰接支座,圆柱枢轴摆动轴承pinion bearing小齿轮轴承piston pin bearing活塞销轴承pivot bearing枢轴承,摆动支座,中心(轴尖)支承,立式止推轴承plain-and -ball bearing滑动与滚动组合轴承plane bearing平面轴承plummer block bearing架座,止推轴承pneumatic bearing空气轴承pocket bearing油盘轴承porous bearing多孔轴承powdiron bearing多孔铁轴承,粉未铁轴承power take-off lever bearing动力输出轴轴承preloaded bearing预紧轴承prelubricated bearing预(加)润滑[油密封]轴承,一次润滑轴承pressure-feed air bearing静压空气轴承pressure-loaded bearing承压轴承proper bearing紧密接触轴承盖世汽车社区。

BEARING LIFE ANALYSISABSTRACTNature works hard to destroy bearings, but their chances of survival can be improved by following a few simple guidelines. Extreme neglect in a bearing leads to overheating and possibly seizure or, at worst, an explosion. But even a failed bearing leaves clues as to what went wrong. After a little detective work, action can be taken to avoid a repeat performance.1 .WHY BEARINGS FAILAn individual bearing may fail for several reasons; however, the results of an endurance tes t series are only meaningful when the test bearings fail by fatigue-related mechanisms. The experimenter must control the test process to ensure that this occurs. Some of the other failure modes that can be experienced are discussed in detail by Tallian [19.2]. The following paragraphs deal with a few specific failure types that can affect the conduct of a life test sequence.In Chapter 23, the influence of lubrication on contact fatigue life is discussed from the standpoint of EHL film generation. There ar e also other lubrication-related effects that can affect the outcome of the test series. The first is particulate contaminants in the lubricant. Depending on bearing size, operating speed, and lubricant rheology, the overall thickness of the lubricant film developed at the rolling element-raceway contacts may fall between 0.05 and 0.5 m . Solid particles and damage the raceway and rolling element surfaces, leading to substantially shortened endurances. This has been amply demonstrated by Sayles and MacPherson [19.6] and others.Therefore, filtration of the lubricant to the desired level is necessary to ensure meaningful test result. The desired level is determined by the application which the testing purports to approximate. If thi s degree of filtration is not provided, effects of contamination must be considered when evaluating test results. Chapter 23 discusses the effect of various degrees of particulate contamination, and hence filtration, on bearing fatigue life.The moisture content in the lubricant is another important consideration. It has long been apparent that quantities of free water in the oil cause corrosion of the rolling contact surfaces and thus have a detrimental effect on bearing life. It has been further shown b y Fitch[19.7] and others, however, that water levels as low as 50-100 parts per million(ppm) may also have a detrimental effect, even with no evidence of corrosion. This is due to hydrogen embrittlement of the rolling element and raceway material. See als o Chapter 23. Moisture control in test lubrication systems is thus a major concern, and the effect of moisture needs to be considered during the evaluation of life test results. A maximum of 40 ppm is considered necessary to minimize life reduction effects.The chemical composition of the test lubricant also requires consideration. Most commercial lubricants contain a number of proprietary additives developed for specific purposes; for example, to provide antiwear properties, to achieve extreme pressure and/or thermal stability, and to provide boundary lubrication in case of marginal lubricant films. These additives can also affect the endurance of rolling bearings, either immediately or after experiencing time-related degradation. Care must be taken to ensu re that the additives included in the test lubricant will not suffer excessive deterioration as a result of accelerated life test conditions. Also for consistency of results and comparing life test groups, it is good practice to utilize one standard test lubricant from a particular producer for the conduct of all general life tests.The statistical nature of rolling contact fatigue requires many test samples to obtain a reasonable estimate of life. A bearing life test sequence thus needs a long time. A majo r job of the experimentalist is to ensure the consistency of the applied test conditions throughout the entire test period. This process is not simple because subtle changes can occur during the test period. Such changes might be overlooked until their effects become major. At that time it is often too late to salvage the collected data, and the test must be redone under better controls.For example, the stability of the additive packages in a test lubricant can be a source of changing test conditions. Some lubricants have been known to suffer additive depletion after an extended period of operation. The degradation of the additive package can alter the EH L conditions in the rolling content, altering bearing life. Generally, the normal chemical tests used to evaluate lubricants do not determine the conditions of the additive content. Therefore if a lubricant is used for endurance testing over a long time, a sample of the fluid should be returned to the producer at regular intervals, say annually, for a detailed evaluation of its condition.Adequate temperature controls must also be employed during the test. The thickness of the EHL film is sensitive to the contact temperature. Most test machines are located in standard industrial environments where rather wide fluctuations in ambient temperature are experienced over a period of a year. In addition, the heat generation rates of individual bearings can vary as a result of the combined effects of normal manufacturing tolerances. Both of these conditions produce variations in operating temperature levels in a lot of bearings and affect the validity of the life data. A means must be provided to monitor and control the operating temperature level of each bearing to achieve a degree of consistency. A tolerance level of 3C is normally considered adequate for the endurance test process.The deterioration of the condition of the mounting hardware used with the bearings is another area requiring constant monitoring. The heavy loads used for life te sting require heavy interference fits between the bearing inner rings and shafts. Repeated mounting and dismounting of bearings can produce damage to the shaft surface, which in turn can alter the geometry of a mounted ring. The shaft surface and the bore of the housing are also subject to deterioration from fretting corrosion. Fretting corrosion results from the oxidation of the fine wear particlesgenerated by the vibratory abrasion of the surface, which is accelerated by the heavy endurance test loading.This mechanism can also produce significant variations in the geometry of the mounting surfaces, which can alter the internal bearing geometry. Such changes can have a major effect in reducing bearing test life.The detection of bearing failure is also a major consideration in a life test series. The fatigue theory considers failure as the initiation of the first crack in the bulk material. Obviously there is no way to detect this occurrence in practice. To be detectable the crack must propagate to the surface and produce a spall of sufficient magnitude to produce a marked effect on an operating parameter of the bearing: for example, noise, vibration, and/or temperature. Techniques exit for detecting failures in application systems. The ability of these sys tems to detect earl y signs of failure varies with the complexity of the test system, the type of bearing under evaluation, and other test conditions. Currentl y no single system exists that can consistently provide the failure discrimination necessary for a ll types of bearing life tests. It is then necessary to select a system that will repeatedl y terminate machine operation with a consistent minimal degree of damage.The rate of failure propagation is therefore important. If the degree of damage at test ter mination is consistent among test elements, the only variation between the experimental and theoretical lives is the lag in failure detection. In standard through-hardened bearing steels the failure propagation rate is quite rapid under endurance test cond itions, and this is not a major factor, considering the t ypical dispersion of endurance test data and the degree of confidence obtained from statistical analysis. This may not, however, be the case with other experimental materials or with surface-hardened steels or steels produced by experimental techniques. Care must be used when evaluating these latter results and particularl y when comparing theexperimental lives with those obtained from standard steel lots.The ultimate means of ensuring that an endura nce test series was adequately controlled is the conduct of a post-test analysis. This detailed examination of all the tested bearings uses high-magnification optical inspection, higher-magnification scanning electron microscopy, metallurgical and dimensio nal examinations, and chemicalevaluations as required. The characteristics of the failures are examined to establish their origins and the residual surface conditions are evaluated for indications of extraneous effects that may have influenced the bearin g life. This technique allows the experimenter to ensure that the data are indeed valid. The “Damage Atlas” compiled by Tallian et al. [19.8] containing numerous black and white photographs of the various bearing failure modes can provide guidance for thes e types of determinations. This work was subsequently updated by Tallian [19.9], now including color photographs as well.The post-test analysis is, by definition, after the fact. To provide control throughout the test series and to eliminate all quest ionable areas, the experimenter should conduct a preliminary study whenever a bearing is removed from the test machine. In this portion of the investigation each bearing is examined optically at magnifications up to 30 for indications of improper or out-of-control test parameters. Examples of the types of indications that can be observed are given in Figs. 19.2-19.6.Figure 19.2 illustrates the appearance of a typical fatigue-originated spall on a ball bearing raceway. Figure 19.3 contains a spalling failure on the raceway of a roller bearing that resulted from bearing misalignment, and Fig. 19.4 contains a spalling failure on the outer ring of a ball bearing produced by fretting corrosion on the outer diameter. Figure 19.5 illustr ates a more subtle form of test alteration, `where the spalling failure originated from the presence of a debris denton the surface. Figure 19.6 gives an example of a totally different failure mode produced by the loss of internal bearing clearance due to thermal unbalance of the system.The last four failures are not valid fatigue spalls and indicate the need to correct the test methods. Furthermore, these data points would need to be eliminated from the failure data to obtain a valid estimate of the experimental bearing life.2 .AVOIDING FAILURESThe best way to handle bearing failures is to avoid them．This can be done in the selection process by recognizing critical performance characteristics．These include noise，starting and running torque，stiffness，non-repetitive run out，and radial and axial play．In some applications, these items are so critical that specifying an ABEC level alone is not sufficient．Torque requirements are determined by the lubricant，retainer，raceway quality(roundness cross curvature a nd surface finish)，and whether seals or shields are used．Lubricant viscosity must be selected carefull y because inappropriate lubricant，especially in miniature bearings，causes excessive torque．Also，different lubricants have varying noise characteristics th at should be matched to the application. For example，greases produce more noise than oil．Non-repetitive run out(NRR)occurs during rotation as a random eccentricit y between the inner and outer races，much like a cam action．NRR can be caused by retainer tole rance or eccentricities of theraceways and balls．Unlike repetitive run out, no compensation can be made for NRR.NRR is reflected in the cost of the bearing．It is common in the industry to provide different bearing types and grades for specific applications．For example，a bearing with an NRR of less than 0.3um is used when minimal run out is needed，such as in disk—drive spindle motors．Similarly，machine—tool spindles tolerate only minimal deflections to maintain precision cuts．Consequently, bearings are manufactured with low NRR just for machine-tool applications．Contamination is unavoidable in many industrial products，and shields and seals are commonly used to protect bearings from dust and dirt．However，a perfect bearing seal is not possible because of the movement between inner and outer races．Consequently，lubrication migration and contamination are always problems．Once a bearing is contaminated, its lubricant deteriorates and operation becomes noisier．If it overheats，the bearing can seize．At the very least，contamination causes wear as it works between balls and the raceway，becoming imbedded in the races and acting as an abrasive between metal surfaces．Fending off dirt with seals and shields illustrates some methods for controlling contamination．Noise is as an indicator of bearing quality．Various noise grades have been developed to classify bearing performance capabilities．Noise anal ysis is done with an Ander-on-meter, which is used forquality control in bearing production and also when failed bearings ar e returned for anal ysis. A transducer is attached to the outer ring and the inner race is turned at 1,800rpm on an air spindle. Noise is measured in andirons, which represent ball displacement in μm/rad.With experience, inspectors can identify the smalles t flaw from their sound. Dust, for example, makes an irregular crackling. Ball scratches make a consistent popping and are the most difficult to identify. Inner-race damage is normally a constant high-pitched noise, while a damaged outer race makes an inte rmittent sound as it rotates.Bearing defects are further identified by their frequencies. Generally, defects are separated into low, medium, and high wavelengths. Defects are also referenced to the number of irregularities per revolution.Low-band noise is the effect of long-wavelength irregularities that occur about 1.6 to 10 times per revolution. These are caused by a variety of inconsistencies, such as pockets in the race. Detectable pockets are manufacturing flaws and result when the race is mounted too tightly in multiple jaw chucks.Medium-hand noise is characterized by irregularities that occur 10 to 60 times per revolution. It is caused by vibration in the grinding operation that produces balls and raceways. High-hand irregularities occur at 60 to 300 times per revolution and indicate closely spaced chatter marks or widely spaced, rough irregularities.Classifying bearings by their noise characteristics allows users to specify a noise grade in addition to the ABEC standards used by most manufacturers. ABEC defines physical tolerances such as bore, outer diameter, and run out. As the ABEC class number increase (from 3 to 9), tolerances are tightened. ABEC class, however, does not specify other bearing characteristics such as raceway quality, finish, or noise. Hence, a noise classification helps improve on the industry standard.(come from Lu,Zhengran . Study of the bearing capacity of fastener steel tube full hall formwork support using the theory ofstability of pressed pole with three-point rotation restraint[J] . China Civil Engineering Journal 2012-5 )轴承寿命分析摘要自然界苛刻的工作条件会导致轴承的失效，但是如果遵循一些简单的规则，轴承正常运转的机会是能够被提高的。

English-chinese technical terms of ball and roller bearings AAA(American Automobile Association)美国汽车学会Abatement减少，消除，中断，失效，废料Abbreviation缩写，简称，简化，略语ABEC（Annular Bearing Engineers Committee）美国向心轴承工程师委员会Aberration 脱轨，失常，畸变，变形，偏差Ability 能力Ability to support load承载能力ABMTM(associated british machine tool makers)英国机床制造商协会Abolish废除，取消Abolishment 废除，取消Abradant 磨料研磨剂，金刚砂研磨用的Abrade 擦伤，磨损，研磨Abrasion磨粒磨损Abrasion resistance 抗磨性/力Abrasive 磨料，研磨剂，磨料的，磨损的，研磨的Abrasive action 磨损作用Abrasive cloth 砂布Abrasive cut-off wheel切割砂轮Abrasive dirt particles 研磨粉尘Abrasive dust磨屑Abrasive erosion 磨粒侵蚀Abrasive grain 磨料粒度Abrasive-hardness test 磨蚀硬度实验Abrasive machining磨削加工，强力磨削Abrasive material 磨料Abrasive paper 砂纸Abrasive powder 研磨粉，金刚砂粉Abrasive product 磨料制品Abrasive resistance 磨蚀阻力，耐磨能力Abrasive stick 砂条，油石Abrasive wear 磨粒磨损，磨耗Abrasive wheel砂轮Abridge缩短，省略，简化Abrupt 切割的，突然的，意外的ABS（american bureau of standards）美国标准局Abscissa横座标，横线Absence of play 无游隙Absolute dimension 绝对尺寸Absolute viscosity 绝对粘度Absorb 吸收，减震，承担Absorbability 吸收量/能力Absorption capacity吸收能力Abstract提取，抽出，文摘，摘要，简介，抽象Abstraction分离，提取，除去Abundant丰富的，大量的，许多的，充足的Abut连接，接近，支撑Abutment轴承支座，定位台肩，接合面Abutment ring 定位环Abutment sleeve 定位套筒Abutting end 对接端Abutting surface 相邻表面，相接面Accelerate 加速，促进Accelerated aging test 加速老化实验Acceleration 加速度Acceleration curve 加速度曲线Accelerator 加速器Accelerometer 加速计，过载指示器Accept 接受，验收合格，允许，认可Acceptability 可接受的，合格的Acceptable 可接受的，容许的，合格的Acceptable quality level（AQL）质量验收标准Acceptance 验收，答应，承认Acceptance control 验收管理规程Acceptance factory test 工厂验收试验Acceptance inspection 验收检查Acceptance test 验收试验Acceptance tolerance 验收公差Access接近，进入，入口，通路Accessibility 易接近性Accessory 附属的，次要的，附件，辅助设备Accident 事故，偶然性，意外，紧急用的Accident prevention measure 安全保护措施Accident-prevention rule 安全保护条例Accident-proof 防止事故的Accommodate 调节，适应，供应Accommodation 调节，适应Accomplish 完成，达到，实行Accomplishment 完成，实行，成就According to 按照，根据According to sample 根据样品Accumulate 累积，储存，聚集Accumulation 累积，储存Accuracy 精度，精密性Accuracy of angle measurement 角度测量精度Accuracy of measurement 测量精度Accuracy of reading 度数精度Accuracy of running 轴承旋转精度Accuracy to size 尺寸精度Accurate 准确的，精密的Accurate alignment 准确校直/对正Accurate dimension 准确尺寸Accurate grinding 精密磨削Accurate to dimension 符合加工尺寸Accurate to size 符合加工尺寸Acetate fiber 醋酸纤维Acetate rayon 醋酸人造纤维Acetate silk 醋酸纤维丝Acetone 丙酮Acetylene 乙炔，电石气Achieve 完成，达到，实现，获得Achievement 完成达到，成就Acid 酸，酸性的Acid bessemer steel 酸性转炉钢Acidiferous liquid 含酸的溶液Acid number/acid value 酸值，酸价Acidulous liquid 酸性溶液Acme thread 梯形螺纹Acting force 作用力Action 作用，动作Active 主动的Active power有功效功率，平均功率Actual bearing height 轴承实际高度Actual conditions 实际情况Actual dimension 实际尺寸Actual length of roller 滚子实测长度Actual output 实际输出量Actual power 实际功率Actual profile 实际外形Actual single width 实测单一宽度Actual size 实际尺寸Actual slip 实际滑移Actuate 开动，动作，操纵，鼓励Actuating cam 驱动凸轮Actuating mechanism 执行机构Acute angle 锐角Adapt 适应，配上，修改Adaptability 适应性，适应能力Adaptation 适应，匹配，配合，改编Adapter 紧定套，管接头，连接装置，衬套Adapter assembly 紧定套组件（包括套，锁母，花垫或锁紧片）Adapter dimensions 紧定套尺寸。

(ball) lot diameter variation球)批直径变动量(ball) lot mean diameter球)批平均直径(groove) shoulder沟)肩(lot) deviation from ball gauge批)球规值偏差(roller ) gauge lot规值批(滚子)(roller) gauge lot diameter variation规值批直径变动量(滚子) (separate) thrust collar斜挡圈(可分离的)2-point roundness椭圆ACBB角接触球轴承actual bearing height轴承实际高度actual bearing width轴承实际宽度actual length of a roller滚子实际长度adapter附件adapter sleeve紧定套adjusted rating life修正额正寿命agitation搅拌airframe bearing飞机机架轴承aligning housing ring调心外座圈aligning housing washer调心座圈aligning outer ring调心外圈aligning seat washer调心座垫圈aligning surface centre height调心表面中心高度aligning surface radius调心表面半径angle series角度系列angular contact bearing角接触轴承angular contact radial bearing角接触向心轴承angular contact thrust bearing角接触推力轴承annealing退火assembled bearing cone back face runout with raceway 成套轴承圆锥内圈背面对滚道的跳动(圆锥滚子轴承)assembled bearing cup back face runout with raceway 成套轴承圆锥外圈背面对滚道的跳动(圆锥滚子轴承)assembled bearing inner ring face runout with raceway 成套轴承内圈端面对滚道的跳动(沟型球轴承)assembled bearing outer ring face runout with raceway 成套轴承外圈端面对滚道的跳动(沟型球轴承)assembly组件，装配asymmetrical roller非对称滚子axial chamfer dimension轴向倒角尺寸axial contact bearing轴向接触轴承axial direction轴向axial distance轴向距离axial internal clearance 轴向游隙(在两个方向上能承受轴向负荷的轴承，非予紧状态)axial load轴向载荷,轴向负荷axial plane轴向平面axial single chamfer dimension轴向单一倒角尺寸back face背(端)面back-to-back arrangement背对背配置ball钢球；球ball (roller) and cage assembly球（滚子）和保持架组件ball (roller) complement球(滚子)总体ball (roller) set球(滚子)组ball and cage radial (thrust) assembly球和保持架向心（推力）组件ball bearing球轴承ball bushing关节轴承ball complement bore diameter (outside diameter)球总体内径(外径)ball diameter球直径ball diameter variation球直径变动量ball gauge球规值ball grade球等级ball lot球批ball set bore diameter (outside diameter)球组内径(外径)ball subgauge球分规值bar梁basic dynamic radial (axial) load rating径向(轴向)基本额定动负荷basic load rating基本额定负荷basic rating life基本额定寿命basic static radial (axial) load rating径向(轴向)基本额定静负荷BB球轴承bearing轴承bearing arrangement轴承配置bearing axis轴承轴心线bearing bore轴承内孔bearing bore diameter轴承内径bearing height轴承高度bearing outside diameter轴承外径bearing outside surface轴承外表面bearing part轴承零件bearing ring轴承套圈bearing seating轴承支撑面bearing series轴承系列bearing washer轴承垫圈bearing width轴承宽度black ring淬火圈bore内孔；内圆bore diameter (outside diameter) variation内径(外径)变动量bore diameter (outside diameter) variation in a singleradial plane内径(外径)在单一径向平面内的变动量bore diameter of a ball (roller) and cage radialassembly球(滚子)和保持架向心组件内径bore diameter of a ball (roller) and cage thrustassembly球(滚子)和保持架推力组件内径boundary dimension外形尺寸boxcage保持架cage bar保持架梁cage pin保持架支柱cage pocket保持架兜(窗)孔cage prong保持架爪cage riding land引导保持架的表面cage stay保持架撑条capped bearing闭型轴承carbide banding条状碳化物carburize渗碳carton小盒CCCcentral washer中圈centre rib中挡边centric axial load中心轴向负荷chamfer倒斜角change over换活characteristic特征、特性chip碎片clearance游隙coating thickness涂层厚度coefficient系数combined load联合载荷component零件concave roller凹面滚子concave roller bearing凹面滚子轴承concentration浓度concentric collar偏心套concentric locking collar同心套concentricity同轴度cone圆锥轴承内圈cone (cup) axis圆锥内圈(外圈)轴心线cone assembly圆锥内圈组件cone back face rib圆锥内圈背面挡边cone front face rib圆锥内圈前面挡边conformity吻合率contact angle接触角contact angle (nominal contact angle)接触角(公称接触角) contamination杂质convex asymmetrical roller非对称球面滚子convex roller凸)球凸面滚子convex roller bearing凸）球面滚子轴承convex symmetrical roller对称球面滚子coolant冷却液coordinate坐标Cor基本额定静负荷counterbored ball bearing锁口球轴承counterbored outer ring锁口外圈Cr基本额定动负荷CRACK开裂crane起重机CRB圆柱滚子轴承crossed roller bearing交叉滚子轴承crowned raceway凸度滚道crowned roller凸度滚子CRR变更申请crystal晶粒cup圆锥轴承外圈cup angle圆锥外圈角cup front face rib圆锥外圈前面挡边cup small inside diameter圆锥外圈小内径cylindrical bore圆柱形内孔cylindrical roller圆柱滚子cylindrical roller bearing圆柱滚子轴承cylindrical roller thrust bearing推力圆柱滚子轴承DB背对背de-carburization脱碳deep groove ball bearing深沟球轴承deflection偏斜、偏差deformation变形de-magnetic退磁deviation偏差deviation from circular form圆度误差deviation from cylindrical form圆柱度误差deviation from spherical form球形误差(基本球形表面的) deviation of a single bore diameter (outside diameter)单一内径(外径)偏差deviation of a single ring width套圈单一宽度偏差deviation of the actual bearing height轴承实际高度偏差deviation of the actual bearing width轴承实际宽度偏差DF面对面DGBB深沟球轴承dial bore gage量缸表diameter series直径系列diamond roll金刚滚轮dimension plan尺寸方案dimension series尺寸系列displacement位移double cone双滚道圆锥内圈double cup双滚道圆锥外圈double fracture双破口double row bearing双列轴承double row double-direction thrust bearing双列双向推力轴承double row single-direction thrust ball bearing双排单向推力球轴承double-direction thrust bearing双向推力轴承double-split bearing ring剖分轴承套圈double-split cage双剖分保持架drawn cup冲压外圈drawn cup needle roller bearing冲压外圈滚针轴承dress修整dresser修整器DT串联duplex bearing成对轴承dynamic equivalent radial (axial) load径向(轴向)当量动负荷dynamic load动负荷eccentric locking collar偏心套ECN工程变更EDM线切割end face端面equivalent load当量负荷extended inner ring宽内圈external aligning bearing外调心轴承face端面face notching端面开应力槽face runout with bore端面对内孔的跳动(内圈基准端面) face-to-face arrangement面对面配置failure失效fillet倒圆角filling slot装填槽filling slot ball bearing装填槽球轴承film thickness油膜厚度final finish grinding终磨fixed side固定端fixture夹具flange凸缘,档边flange back face凸缘背(端)面flange height凸缘高度flange width凸缘宽度flanged bearing凸缘轴承flanged housing凸缘轴承座flanged outer ring凸缘外圈flatness平面度flinger护圈floating side浮动端fluctuating load脉动负荷forging锻four point contact ball bearing四点接触球轴承free acid游酸friction摩擦front face前面full complement bearing满装滚动体轴承gage仪表gage room计量室green ring车工圈grind burn磨削烧伤grinding parameter磨削参数grinding undercut越程槽groove ball bearing沟型球轴承guide ring导圈；隔圈heated assembly加热装配height series高度系列housing轴承座housing washer座圈housing washer back face chamfer座圈背面倒角ID内径impact load冲击载荷inch bearing英制轴承inch series bearing英制系列轴承indeterminate direction load方向不定的负荷inertia惯性inner内圈inner ring内圈inner ring (shaft washer) axis内圈(轴圈)轴心线inner ring back face (front face) chamfer内圈背面(前面)倒角inner ring cage and ball (roller) assembly内圈、保持架和球（滚子）组件inner ring raceway to bore thickness variation 内圈滚道对内孔的厚度变动量(向心轴承)insert bearing外球面轴承instrument precision bearing仪器精密轴承interchangeable bearing ring (bearing washer)可互换轴承套圈(轴承垫圈) interchangeable sub-unit可互换分部件IR内圈iron content铁浓度jig夹具L1010%可靠度额定寿命land riding cage挡边引导的保持架largest permissible single chamfer dimension允许的最大单一倒角尺寸laser marking激光打标life寿命(指一套轴承的)life adjustment factor寿命修正系数life factor寿命系数limiting speed极限转速linear (motion) bearing直线（运动）轴承linear bearing直线轴承load负荷；载荷；负载load capacity承载能力load centre载荷中心load rating额定负荷locating snap ring止动环locking collar锁定套locknut锁紧螺母lockwasher锁紧垫圈log book过程记录单loose rib平挡圈lubrication润滑油lubrication groove润滑槽lubrication hole润滑孔magnetic particle inspection磁力探伤magneto ball bearing磁电机球轴承master样圈matched bearing组配轴承matched pair配对matched stack组配mean bore diameter (outside diameter)平均内径(外径)mean bore diameter (outside diameter) deviation平均内径(外径)偏差mean bore diameter (outside diameter) variation平均内径(外径)变动量mean diameter of a ball球平均直径mean effective load平均有效负荷mean ring width套圈平均宽度median life中值寿命median rating life中值额定寿命metric bearing米制轴承metric series bearing米制系列轴承middle raceway滚道中部misalignment未对准molycoatmolycoat viscosity粘度moment load力矩载荷multi-row bearing多列轴承needle滚针needle roller滚针needle roller bearing滚针轴承needle roller bearing without inner ring无内圈的滚针轴承needle roller thrust bearing推力滚针轴承nital etch酸洗NMTP非马氏体组织nominal ball diameter球公称直径nominal bearing width (bearing height)轴承公称宽度(轴承高度) nominal bore diameter (outside diameter)公称内径(外径)nominal chamfer dimension公称倒角尺寸nominal contact point公称接触点nominal diameter公称直径nominal diameter of a roller滚子公称直径nominal ring width套圈公称宽度nomnial length of a roller滚子公称长度non-fluorecent magnetic particle examination非萤光磁力探伤non-separable bearing不可分离轴承notch装子缺口notching开应力槽NRB滚针轴承OD外径open bearing开型轴承OR外圈oscillating load摆动负荷outer外圈outer ring外圈outer ring (housing washer) axis外圈(座圈)轴心线outer ring back face (front face) chamfer外圈背面(前面)倒角outer ring cage and ball (roller) assembly外圈、保持架和球（滚子）组件outer ring flange外圈凸缘outer ring raceway to outside surface thickness variation 外圈滚道对外表面的厚度变动量(向心轴承)outside diameter of a ball (roller) and cage radialassembly球(滚子)和保持架向心组件外径outside diameter of a ball (roller) and cage thrustassembly球(滚子)和保持架推力组件外径P/N零件号packing包装paired mounting成对安装parallelism平行度perpendicularity垂直度phosphate磷化pin柱销pin type cage支柱型保持架pitch diameter节圆直径pitch diameter of ball set球组的节圆直径pitch diameter of roller set滚子组的节圆直径play移动量；游隙plummer block带座轴承plummer block housing立式座Plummer housing立式轴承座pocket兜孔precision精度preload预负荷prelubricated bearing予润滑轴承process audit过程审核process flow流程process sheet流转卡profile轮廓度prong爪prong type cage爪形保持架quadruplex bearing4联成对轴承race滚道raceway contact diameter滚道接触直径raceway groove沟道raceway pararalleism with face 滚道对端面的平行度(沟型球轴承内圈或外圈的基准端面)radial (axial) distance径向(轴向)距离radial (axial) load factor径向(轴向)负荷系数radial ball bearing向心球轴承radial bearing径向轴承radial chamfer dimension径向倒角尺寸radial contact bearing径向接触轴承radial direction径向radial internal clearance 径向游隙(能承受纯径向负荷的轴承，非予紧状态)radial load径向载荷radial plane径向平面radial roller bearing向心滚子轴承radial runout of assembled bearing inner ring成套轴承(向心轴承)内圈的径向跳动radial runout of assembled bearing outer ring成套轴承(向心轴承)外圈的径向跳动radial single chamfer dimension径向单一倒角尺寸radius半径railway axlebox bearing铁路轴箱轴承rapid approach快速趋近rating life额定寿命raw material原材料RB滚子轴承recess凹坑recirculating ball (roller) linear bearing循环球（滚子）直线轴承reference face of a ring (a washer)套圈(垫圈)基准端面reliability可靠性(指轴承寿命的)relieved end roller修形滚子relubricatable bearing可再润滑轴承retainer保持架retaining snap ring锁圈rework返工RFQ报价rib挡边ribbon cage浪形保持架RIC径向游隙riding land引导面rigid bearing刚性轴承rigidity刚性ring套圈ring (washer) chamfer套圈(垫圈)倒角ring (washer) chamfer dimension套圈(垫圈)倒角尺寸ring (washer) face套圈(垫圈)端面ring width套圈宽度ring width variation套圈宽度变动量rivet铆钉rod end bearing杆端轴承roller滚子roller and cage radial (thrust) assembly滚子和保持架向心（推力）组件roller bearing滚子轴承roller chamfer滚子倒角roller complement bore diameter (outside diameter)滚子总体内径(外径)roller diameter滚子直径roller end face滚子端面roller gauge滚子规值roller grade滚子等级roller large end face滚子大端面roller length滚子长度roller recess滚子凹穴roller set bore diameter (outside diameter)滚子组内径(外径)roller small end face滚子小端面rolling bearing滚动轴承rolling element滚动体rolling element and cage assembly滚动体和保持架组件rotating inner ring (shaft washer) load旋转的内圈(轴圈)负荷rotating outer ring (housing washer) load旋转的外圈(座圈)负荷rotation factor旋转系数rough grinding粗磨roughness粗糙度roundness圆度router paper跟踪卡row列running torque旋转力矩runout跳动scrap报废seal密封圈；密封件seal (shield) groove密封圈(防尘盖)槽sealed bearing密封轴承sealing (contact) surface密封(接触)表面self-aligning bearing自调心轴承semi-finish grinding细磨separable bearing可分离轴承separable bearing ring (bearing washer)可分离的轴承套圈(轴承垫圈) separable ring可分离的套圈separator隔离件setting设置setup调整shaft (housing) shoulder轴(座)肩shaft washer轴圈shaft washer (housing washer) back face轴圈(座圈)背面shaft washer back face chamfer轴圈背面倒角shield防尘盖shielded bearing防尘盖轴承shim塞尺shipping发运shoe支承shoe body支承体shoe mark支承痕shoulder肩single bore diameter (outside diameter)单一内径(外径)single diameter of a ball球单一直径single diameter of a roller滚子单一直径single direction thrust bearing单向推力轴承single fracture单破口single plane mean bore diameter (outside diameter)单一平面平均内径(外径) single plane mean bore diameter (outside diameter)deviation单一平面平均内径(外径)偏差single plane mean roller diameter滚子单一平面平均直径single plane roller diameter variation滚子单一平面直径变动量single point dress单点修整single ring width套圈单一宽度single row bearing单列轴承single row double-direction thrust ball bearing单列双向推力球轴承single-split bearing单缝轴承套圈smallest permissible single chamfer dimension允许的最小单一倒角尺寸snap cage弹性保持架snap ring止动环snap ring groove止动环槽snap ring groove depth止动环槽深度snap ring groove diameter止动环槽直径snap ring groove width止动环槽宽度soap清洗剂solution标液spacer隔圈spark火花SPEC.标准speed factor速度系数spherical back face球形背面spherical outside surface球形外表面spherical plain bearing关节轴承spherical raceway球面滚道spherical roller球面滚子spherical roller bearing球面滚子轴承spherical thrust roller bearing推力球面滚子轴承spiral wound roller螺旋滚子split bearing剖分轴承squareness垂直度SRB调心滚子轴承stack mounting组合安装starting torque启动力矩static equivalent radial (axial) load径向(轴向)当量静负荷static load静负荷stationary inner ring (shaft washer) load固定的内圈(轴圈)负荷stationary outer ring (housing washer) load固定的外圈(座圈)负荷stepped inner ring锁口内圈stock留量straight直线度straight raceway直滚道strapping捆扎stud type track roller (rolling bearing)螺栓型滚轮（滚动）轴承sub-unit分部件sufficient充分的Super-finish超精swing gage摇摆仪symmetrical对称度symmetrical roller对称滚子take-up housing滑块座tandem arrangement串联配置tapered bore圆锥形内孔tapered bore bearing锥孔轴承tapered roller圆锥滚子tapered roller bearing圆锥滚子轴承tapered roller thrust bearing推力圆锥滚子轴承template样板theoretical radial internal clearance理论径向游隙(径向接触轴承) thermal expansion热膨胀three point contact ball bearing三点接触球轴承thrust ball bearing推力球轴承thrust bearing推力轴承thrust roller bearing推力滚子轴承tolerance公差tolerance grade公差等级torque力矩total acid总酸track roller (rolling bearing)滚轮轴承TRB圆锥滚子轴承turning车加工turning free旋转灵活two-piece bearing ring (bearing washer)双半轴承套圈(轴承垫圈)two-piece cage两半保持架undercut越程槽universal matching bearing万能组配轴承variation变动量variation of outside surface generatrix inclination with face 外表面母线对基准端面倾斜度的变动量(外圈基本为圆柱表面)VCI paper气相防锈纸vibration振动wall thickness壁厚washer height垫圈高度washer raceway to back face thickness variation 垫圈滚道对背面的厚度变动量(推力轴承的轴圈或座圈的平底背面)waviness波纹度wheel砂轮wide inner ring宽内圈width宽度width series宽度系列window type cage窗式保持架WIP过程打包withdrawal sleeve退卸套workpiece工件yoke type track roller (rolling bearing)挡圈型滚轮（滚动）轴承adjust调整air switch; air-break switch空气开关alarm报警anneal退火austenite奥氏体back off后退bainite贝氏体ballscrew滚珠丝杆belt皮带blank毛坯Bore grinder内圆磨building structure建筑结构carbide碳化物carbide build-up带状碳化物carbide network网状碳化物carbonitride碳氮共渗carbonize渗碳CNC数控车床coder编码器communication通讯compress air压缩空气constant power恒功率constant pressure恒压力control控制cooling冷却correct修正count计数crack裂纹cut； disconnection断开cutability切削性能CVD化学气相沉淀cycle循环delayed over-grinded延时过磨demagnetization退磁diagnosis诊断driver驱动器dynamic balance动平衡electric magnetic chuck电磁吸盘electromagnetism valve电磁阀electromotor电动机equivalent cross section有效壁厚exhaust排污external centerless grinder外圆无心磨face grinder端面磨ferrite铁素体finish approch精进给fire protection消防forge锻造forward前进frequency频率frequency conversion变频fresh air compensate新风补偿fuse保险丝gear齿轮grain size晶粒度grease油脂grind wheel砂轮grinding head磨架guide wheel导轮hardness硬度harmonic reducer谐波减速器heating采暖HT热处理humidity湿度hydraulic pressure液压impact toughness冲击韧性impulse equivalent脉冲当量induction harden感应加热淬火induction non-trigger switch感应无触点开关in-process gage在线测量launching下水lead导线loading上料lubricate润滑magnetic grid磁栅man-machine interface人机界面manually operation手动marquench等温淬火martemper分级淬火martensite马氏体measuring jaw测爪microstructure显微组织mist exhaust apparatus吸雾装置modulus numerical convert模数转换NCNitrogen/Methanol gas氮甲醇基气氛nitrogenize渗氮no spark grinding光磨non-destructive inspection无损检测normalize正火nut螺母oil油oil water emulsion乳化液PCpearlite珠光体PLCpower supply电源press quench压模淬火pressure reducing valve减压阀pressure relay压力继电器protective atmosphere保护气氛public facility公共设施PVD物理气相沉淀quench淬火quenchant淬火剂rapid approach快进给raster光栅relay继电器reset复位restart软启动return返回rolling guide滚动导轨rotate speed转速rough approach粗进给screw丝杆screw； external screw螺丝semi-automatism半自动semi-finish approach细进给service life使用寿命servo伺服shielding guard； preventor防护罩壳skip快跳sliding guide滑动导轨speed regulator； rate governor调速器start起动step infeed步进stock head车头stop停止strengh强度stress应力structure组织superfinisher超精机surge振荡temper回火temperature温度thermocouple热电偶throttle valve节流阀timing定时toughness韧性transformation变压travelling crane行车turn-on； switch on接通unloading下料vacuum filtrate真空过滤velocity pressure； wind pressure风压ventilation通风vibratory tumbling振动光栅机vitta油管water cooled unit水冷机组working lamp工作灯zero-adjustment零位设置二位三通三位四通上水数模转换。

第1章滚动轴承(rolling bearing1.1 向心轴承(contact ball bearing1.1.1 深沟球轴承(deep grove ball bearing)1.1.2 圆柱滚子轴承(cylindrical roller bearing)1.1.3 滚针轴承(needle bearing)1.1.4 调心球轴承(self-aligning ball bearing)1.1.5 角接触球轴承(angular-contact ball bearing)1.1.6 圆锥滚子轴承(tapered roller bearing)1.1.7 调心滚子轴承(self-aligning roller bearing)1.2 推力轴承(thrust bearing)1.2.1 推力球轴承(thrust ball bearing)1.2.2 推力圆柱滚子轴承(thrust cylindrical roller bearing)1.2.3 推力滚针轴承(thrust needle bearing)1.2.4 推力角接触球轴承(thrust angular-contact ball bearing) 1.2.5 推力调心滚子轴承(thrust self-aligning roller bearing) 1.3 组合轴承(combined bearing)1.4 外球面球轴承(spherical surface ball bearing)1.5 直线运动滚动支承(linear roll bearing)1.6 滚轮滚针轴承（tracd & needle roller bearing）1.7 水泵轴连轴承（water pump bearing）1.8 专用轴承(special bearing)1.9 滚动轴承附件(fitting parts for rolling bearing)第2章滑动轴承(plain bearing)2.1 关节轴承(articulated bearing)2.1.1 杆端关节轴承(rod end & spherical plain bearing)2.1.2 向心关节轴承(plain radial bearing)2.1.3 角接触关节轴承(angular-contact articulated bearing)2.1.4 推力关节轴承(thrust articulated bearing)2.2 其他滑动轴承(others plain bearing)2.3 滑动轴承轴套与轴瓦(bushing & half-liner of plain bearing) 2.3.1 轴套(plain bearing bushing)2.3.2 轴瓦(plain bearing half-liner)2.4 滑动轴承附件(fitting parts for plain bearing)adapter bearing带固接套的轴承adjustable bearing可调轴承adjustable cone colter bearing圆犁刀的可调式锥形轴承aerostatic bearing空气静力轴承agate bearing玛瑙轴承air journal bearing气体轴承air lubricated thrust bearing空气润滑止推轴承aligning bearing(直线)对位轴承alkaline-friction bearing抗磨轴承allowable bearing容许支承力all-rubber type bearing全胶式轴承。

轴承专业英语⼤全解析轴承专业英语（⼀）滚动轴承总论1. 滚动轴承rolling bearing ['r?uli?]2. 单列轴承single row bearing [rau]3. 双列轴承double row bearing4. 多列轴承multi-row bearing ['m?lti]5. 满装滚动体轴承full complement bearing [ful] ['k?mplim?nt]6. ⾓接触轴承angular contact bearing ['??ɡjul?]7. ⾃动调⼼轴承automatic self-aligning bearing [?‘laini?]8. 可分离的轴承separable bearing ['sep?r?bl]9. 不可分离轴承non-separable bearing10. 英制轴承inch bearing inch [int?]11. 开型轴承open bearing open ['?up?n]12. 密封圈轴承sealed bearing sealed [si:ld]13. 防尘盖轴承shielded bearing shielded ['?i:ldid]14. 闭型轴承capped bearing15. 预润滑轴承prelubricated bearing [pri:‘ljubrikeitid]16. 仪器精密轴承instrument precision bearing ['instrum?nt] [pri'si??n]17. 组配轴承matched bearing（⼆）向⼼轴承1. 向⼼轴承radial bearing ['reidi?l]2. 径向接触轴承radial contact bearing contact ['k?nt?kt]3. ⾓接触向⼼轴承angular contact radial bearing ['??ɡjul?]4. 外球⾯轴承insert bearing insert [in's?:t]5. 锥孔轴承tapered bore bearing ['teip?d]6. 凸缘轴承flanged bearing [fl?nd?] flanged adj. 带凸缘的；装有法兰的；带法兰的；折边的7. 滚轮（滚动）轴承track roller (rolling bearing) ['r?ul?]8. 万能组配轴承universal matching bearing [,ju:ni'v?:s?l]（三）球轴承1. 球轴承ball bearing2. 向⼼球轴承radial ball bearing3. 深沟球轴承deep groove ball bearing4. 装填槽球轴承filling slot ball bearing5. 三点接触球轴承three point contact ball bearing6. 四点接触球轴承four point contact ball bearing7. 推⼒球轴承thrust ball bearing8. 单列双向推⼒球轴承single row double-direction thrust ball bearing9. 双排单向推⼒球轴承doubel row single-direction thrust ball bearing10. 特种轴承special bearing11. 带⽌动环球轴承ball bearing with snap ring12. 外球⾯体球轴承external sphere ball bearing（四）轴承零件1. 轴承零件bearing part [pɑ:t]2. 轴承套圈bearing ring [ri?]3. 轴承垫圈bearing washer4. ⽌动环snap ring [sn?p] [ri?]5. 隔圈spacer ['speis?]6. 密封圈seal [si:l]7.防尘盖shield8. 挡圈slinger ['sli??]9. 滚动体rolling element ['r?uli?]['elim?nt]10. 保持架cage or retainer [ri'tein?]11. 内圈inner ring ['in?]12. 外圈outer ring ['aut?]13. 油脂grease [ɡri:s]14. 钢球steel ball steel [sti:l] : 钢，钢的15. 偏⼼套eccentric collar [ik'sentrik]16. 锁紧套locking collar17. ⽌动销钉anti-rotation pin [pin]18. 轴承座housing ['hauzi?]19. 橡胶套rubber grommet ['ɡromit]20. 紧定衬套adapter sleeve [?'d?pt?(r)] [sli:v]21、尺⼨：dimension [di'men??n]22、直径：diameter [dai'?mit?]23、宽度：width [widθ, witθ]24、长度：length [l e?θ]25、⾼度：height [hait]26、⾓度：angle ['??ɡl]27、半径：radius ['reidi?s]28、厚度：thickness ['θiknis]29、轴向的：axial ['?ksi?l]30、径向的：radial ['reidj?l]31、外圆（外径）outside surface32、内圆（内径）inner surface33、沟道raceway（五）技术常⽤词1、公差：tolerance ['t?l?r?ns] n. 公差；容忍；宽容；公差2、游隙：clearance ['kli?r?ns] 清除；清理；出清，出空【机械】余隙，间隙3、噪⾳：noise [n?iz] n. 响声；杂⾳；噪⾳4、扭矩：torque [t?:k] n. 转矩，扭矩；项圈，⾦属领圈5、硬度：hardness ['hɑ:dnis] n. 硬度；坚硬；困难；冷酷6、倒⾓: chamfer ['t??mf?] vt. 去⾓；挖槽；斜切 n. 斜⾯；凹槽7、精度：precision [pri'si??n] n. 精确；精度，精密度 adj. 精密的，精确的8、残磁：residual magnetism [ri'zidju?l] n. 剩余；残渣adj. 剩余的；残留的['m?ɡnitiz?m] n. 磁性，磁⼒；磁学；吸引⼒9、表⾯质量：surface quality ['s?:fis] n. 表⾯；外观；表层adj. 表⾯的，肤浅的['kw?l?ti] n. 质量，品质；特性；才能10、注脂量：grease fill [ɡri:s] vt. 涂脂于；贿赂 n. 油脂；贿赂grease volume11、打字：marking ['mɑ:ki?] n. 做记号；打分；标志；斑纹 v. 作记号于；注意；给…打分数12、包装：packaging ['p?kid?i?] n. 包装；包装业，包装风格v. 包装（package的ing形式）13、表⾯处理：surface finishing ['s?:fis] ['fini?i?]表⾯精加⼯，表⾯修整14、螺钉：set screw [set] [skru:] 固定螺钉；定位螺钉15、公称尺⼨：nominal dimension ['n?min?l] [di'men??n]15、振动/偏差：vibration [vai'brei??n]16、钢球等级：ball grade [ɡreid]17、清洁度：cleanliness ['klenlinis]18、⽑刺：burr [b?:] ⽑⼝，⽑边，⽑头，⽑刺19、锈蚀：rust [r?st] n. 锈；⽣锈；锈病vt. 使⽣锈；腐蚀vi. ⽣锈；成铁锈⾊；变迟钝20、极限转速：limiting speed（六）⼯序常⽤词1、割料cutting ['k?ti?] n. 切断；剪辑；开凿adj. 严寒的；锋利的；尖酸刻薄的v. 切开；采伐；削减（cut的ing形式）2、锻造forging ['f?:d?i?]n. 锻件,锻造(法)3、铸造casting ['kɑ:sti?]n. 投掷；铸造；铸件；⾓⾊分配 v. 投掷；铸造；投向；选派演员；扔掉（cast 的ing形式）4、热处理heat treatment[hi:t] ['tri:tm?nt]5、车加⼯turning ['t?:ni?]【机械⼯程】车削⼯作，车⼯⼯艺6、光饰tumbling ['t?mbli?]【⼯程】滚筒抛光7、磨加⼯grinding ['ɡraindi?] 磨制；研磨：8、粗磨rough grinding [r?f] ['ɡraindi?] 粗研磨9、软磨soft grinding10、精磨precision grinding [pri'si??n]【机械⼯程】精磨fine grinding11、修磨correct grinding12、光磨（⽆进给磨，即静⽌状态磨削）13、超精superfinishing [,sju:p?'fini?i?] 【冶⾦学】超级研磨14、磨孔bore grinding15、清洗washing ['w??i?] 洗；洗涤，洗濯；洗净16、装配assembly [?'sembli] n. 装配；集会，集合17、采购purchase18、原材料raw material19、坯件冲压（成型）blank punching20、抛光polish21、整形truing22、包装packing / packaging23、纸板盒carton / cardboard24、抽检/ 取样sampling inspection / sampling25、全检full inspection26、终检final inspection27、巡检tour inspection28、镀黄锌yellow zine plated29、热处理前软磨⾮基准⾯non-reference face grinding before heat treatment30、热处理前软磨两端⾯double face grinding before heat treatment31、车孔及⼀端外⾓bore and one side outer corner turning32、车两⾯防尘槽double-side shields groove turning33、车沟及另⼀外⾓raceway and receive of grinding34、磨削收发dispatch and receive of grinding35、定期防锈处理periodically anti-rust treatment（七）机械常⽤词1、Instrument ['instrum?nt] n. 仪器；器械；⼯具；⼿段；乐器2、Efficiency [i'fi??nsi]a. 有效的,⽣效的n. 效率3、Usage ['ju:zid?] n. ⽤法；使⽤；惯例4、Straight [streit] adj. 直的；正直的；整齐的；连续的；笔直的adv. 直接地；坦率地；⽴即；不断地n. 直线；直5、Horizontal adj. ⽔平的；地平线的；同⼀阶层的n. ⽔平线，⽔平⾯；⽔平位置['h?ri'z?nt?l]6、Vertical ['v?:tik?l] adj. 垂直的，直⽴的；头顶的，顶点的n. 垂直线，垂直⾯7、Incline [in'klain] vi. 倾斜；倾向；易于vt. 使倾斜；使倾向于n. 斜⾯；斜坡；倾斜8、Angle ['??gl] n. ⾓度，⾓9、Arc [ɑ:k] n. 弧（度）；弧形物；天穹；adj. 圆弧的；反三⾓函数的vt. ⾛弧线；形成电弧10、Scale [skeil] n. 刻度；⽐例；数值范围；天平；规模；鳞vi. 攀登；衡量；⽣⽔垢；剥落vt. 攀登；测量；刮鳞；依⽐例决定11、Tolerance ['t?l?r?ns]n. 宽容,容忍n.公差12、Interchangeable [,int?'t?eind??bl]adj. 可互换的；可交换的；可交替的13、Mechanism ['mek?niz?m]n. 机械装置；机制；技巧；原理，途径；进程14、Individual [,indi'vidju?l]adj. 个别的；个⼈的；独特的n. 个⼈，个体15、Impractical [im'pr?ktik?l]adj. 不切实际的，不现实的；不能实⾏的16、Perfect ['p?:fikt]adj. 完美的；最好的；精通的vt. 使完美；使熟练n. 完成式17、Worn [w?:n]adj. ⽤旧的；疲倦的v. 穿；佩戴；磨损（wear的过去分词）18、Slight [slait]adj. 轻微的，少量的；脆弱的；细长的；不重要的vt. 怠慢；轻视，忽略n. 怠慢；轻蔑19、Variation [,vε?ri'ei??n] n. 变异，变种；变化20、Minus ['main?s]prep. 减，减去n. 不⾜；负号，减号；负数adj. 负的；减的.21、shaft [?ɑ:ft] n. 拍杆；轴；箭杆；杆状物22、steady ['stedi] adj. 稳定的；不变的；沉着的23、rotary ['r?ut?ri] adj. 旋转的，转动的；轮流的24、friction ['frik??n] n. 摩擦，摩擦⼒25、component [k?m'p?un?nt] n. 成分；组件；元件26、efficiency [i'fi??nsi] n. 效率；效能；功效27、assembly [?'sembli] n. 装配；集会，集合28、groove[ɡru:v] n. 凹槽，槽；最佳状态；惯例29、installation [,inst?'lei??n] n. 安装，装置；就职30、transmission [tr?nz'mi??n] n. 传动装置，变速器；传递；传送；播送●密封的轴承系统减少夹持⼒并增加轴承寿命。

毕业设计（论文）外文文献翻译文献、资料中文题目：轴承的摩擦与润滑文献、资料英文题目：Friction , Lubrication of Bearing 文献、资料来源：文献、资料发表（出版）日期：院（部）：专业：班级：姓名：学号：指导教师：翻译日期： 2017.02.14Friction , Lubrication of BearingIn many of the problem thus far , the student has been asked to disregard or neglect friction . Actually , friction is present to some degree whenever two parts are in contact and move on each other. The term friction refers to the resistance of two or more parts to movement.Friction is harmful or valuable depending upon where it occurs. friction is necessary for fastening devices such as screws and rivets which depend upon friction to hold the fastener and the parts together. Belt drivers, brakes, and tires are additional applications where friction is necessary.The friction of moving parts in a machine is harmful because it reduces the mechanical advantage of the device. The heat produced by friction is lost energy because no work takes place. Also , greater power is required to overcome the increased friction. Heat is destructive in that it causes expansion. Expansion may cause a bearing or sliding surface to fit tighter. If a great enough pressure builds up because made from low temperature materials may melt.There are three types of friction which must be overcome in moving parts: (1)starting, (2)sliding, and(3)rolling. Starting friction is the friction between two solids that tend to resist movement. When two parts are at a state of rest, the surface irregularities of both parts tend to interlock and form a wedging action. T o produce motion in these parts, the wedge-shaped peaks and valleys of the stationary surfaces must be made to slide out and over each other. The rougher the two surfaces, the greater is starting friction resulting from their movement .Since there is usually no fixed pattern between the peaks and valleys of two mating parts, the irregularities do not interlock once the parts are in motion but slide over each other. The friction of the two surfaces is known as sliding friction. As shown in figure ,starting friction is always greater than sliding friction .Rolling friction occurs when roller devces are subjected to tremendous stress which cause the parts to change shape or deform. Under these conditions, the material in front of a roller tends to pile up and forces the object to roll slightly uphill. This changing of shape , known as deformation, causes a movement of molecules. As a result ,heat is produced from the added energy required to keep the parts turning and overcome friction.The friction caused by the wedging action of surface irregularities can be overcome partly by the precision machining of the surfaces. However, even these smooth surfaces may require the use of a substance between them to reduce the friction still more. This substance is usually a lubricant which provides a fine, thin oil film. The film keeps the surfaces apart and prevents the cohesive forces of the surfaces from coming in close contact and producing heat .Another way to reduce friction is to use different materials for the bearing surfaces and rotating parts. This explains why bronze bearings, soft alloys, and copper and tin iolite bearings are used with both soft and hardened steel shaft. The iolite bearing is porous. Thus, when the bearing is dipped in oil, capillary action carries the oil through the spaces of the bearing. This type of bearing carries its own lubricant to the points where the pressures are the greatest.Moving parts are lubricated to reduce friction, wear, and heat. The most commonly used lubricants are oils, greases, and graphite compounds. Each lubricant serves a different purpose. The conditions under which two moving surfaces are to work determine the type of lubricant to be used and the system selected for distributing the lubricant.On slow moving parts with a minimum of pressure, an oil groove is usually sufficient to distribute the required quantity of lubricant to the surfaces moving on each other .A second common method of lubrication is the splash system in which parts moving in a reservoir of lubricant pick up sufficient oil which is then distributed to all moving parts during each cycle. This system is used in the crankcase of lawn-mower engines to lubricate the crankshaft, connecting rod ,and parts of the piston.A lubrication system commonly used in industrial plants is the pressure system. In this system, a pump on a machine carries the lubricant to all of the bearing surfaces at a constant rate and quantity.There are numerous other systems of lubrication and a considerable number of lubricants available for any given set of operating conditions. Modern industry pays greater attention to the use of the proper lubricants than at previous time because of the increased speeds, pressures, and operating demands placed on equipment and devices.Although one of the main purposes of lubrication is reduce friction, any substance-liquid , solid , or gaseous-capable of controlling friction and wear between sliding surfaces can be classed as a lubricant.V arieties of lubricationUnlubricated sliding. Metals that have been carefully treated to remove all foreign materials seize and weld to one another when slid together. In the absence of such a high degree of cleanliness, adsorbed gases, water vapor ,oxides, and contaminants reduce frictio9n and the tendency to seize but usually result in severe wear; this is called “unlubricated ”or dry sliding.Fluid-film lubrication. Interposing a fluid film that completely separates the sliding surfaces results in fluid-film lubrication. The fluid may be introduced intentionally as the oil inthe main bearing of an automobile, or unintentionally, as in the case of water between a smooth tuber tire and a wet pavement. Although the fluid is usually a liquid such as oil, water, and a wide range of other materials, it may also be a gas. The gas most commonly employed is air.Boundary lubrication. A condition that lies between unlubricated sliding and fluid-film lubrication is referred to as boundary lubrication, also defined as that condition of lubrication in which the friction between surfaces is determined by the properties of the surfaces and properties of the lubricant other than viscosity. Boundary lubrication encompasses a significant portion of lubrication phenomena and commonly occurs during the starting and stopping off machines.Solid lubrication. Solid such as graphite and molybdenum disulfide are widely used when normal lubricants do not possess sufficient resistance to load or temperature extremes. But lubricants need not take only such familiar forms as fats, powders, and gases; even some metals commonly serve as sliding surfaces in some sophisticated machines.Function of lubricantsAlthough a lubricant primarily controls friction and ordinarily does perform numerous other functions, which vary with the application and usually are interrelated .Friction control. The amount and character of the lubricant made available to sliding surfaces have a profound effect upon the friction that is encountered. For example, disregarding such related factors as heat and wear but considering friction alone between the same surfaces with on lubricant. Under fluid-film conditions, friction is encountered. In a great range of viscosities and thus can satisfy a broad spectrum of functional requirements. Under boundary lubrication conditions , the effect of viscosity on friction becomes less significant than the chemical nature of the lubricant.Wear control. wear occurs on lubricated surfaces by abrasion, corrosion ,andsolid-to-solid contact wear by providing a film that increases the distance between the sliding surfaces ,thereby lessening the damage by abrasive contaminants and surface asperities.T emperature control. Lubricants assist in controlling corrosion of the surfaces themselves is twofold. When machinery is idle, the lubricant acts as a preservative. When machinery is in use, the lubricant controls corrosion by coating lubricated parts with a protective film that may contain additives to neutralize corrosive materials. The ability of a lubricant to control corrosion is directly relatly to the thickness of the lubricant film remaining on the metal surfaces and the chermical composition of the lubricant.Other functionsLubrication are frequently used for purposes other than the reduction of friction. Some of these applications are described below.Power transmission. Lubricants are widely employed as hydraulic fluids in fluid transmission devices.Insulation. In specialized applications such as transformers and switchgear , lubricants with high dielectric constants acts as electrical insulators. For maximum insulating properties, a lubricant must be kept free of contaminants and water.Shock dampening. Lubricants act as shock-dampening fluids in energy transferring devices such as shock absorbers and around machine parts such as gears that are subjected to high intermittent loads.Sealing. Lubricating grease frequently performs the special function of forming a seal to retain lubricants or to exclude contaminants.The object of lubrication is to reduce friction ,wear , and heating of machine pars which move relative to each other. A lubricant is any substance which, when inserted between the moving surfaces, accomplishes these purposes. Most lubricants are liquids(such as mineral oil, silicone fluids, and water),but they may be solid for use in dry bearings, greases for use in rolling element bearing, or gases(such as air) for use in gas bearings. The physical and chemical interaction between the lubricant and lubricating surfaces must be understood in order to provide the machine elements with satisfactory life.The understanding of boundary lubrication is normally attributed to hardy and doubleday , who found the extrememly thin films adhering to surfaces were often sufficient to assist relative sliding. They concluded that under such circumstances the chemical composition of fluid is important, and they introduced the term “boundary lubrication”. Boundary lubrication is at the opposite end of the spectrum from hydrodynamic lubrication.Five distinct of forms of lubrication that may be defined :(a) hydrodynamic;(b)hydrostatic;(c)elastohydrodynamic (d)boundary; (e)solid film.Hydrodynamic lubrication means that the load-carrying surfaces of the bearing are separated by a relatively thick film of lubricant, so as to prevent metal contact, and that the stability thus obtained can be explained by the laws of the lubricant under pressure ,though it may be; but it does require the existence of an adequate supply at all times. The film pressure iscreated by the moving surfaces itself pulling the lubricant under pressure, though it maybe. The film pressure is created by the moving surface to creat the pressure necessary to separate the surfaces against the load on the bearing . hydrodynamic lubrication is also called full film ,or fluid lubrication .Hydrostatic lubrication is obtained by introducing the lubricant ,which is sometime air or water ,into the load-bearing area at a pressure high enough to separate the surface with a relatively thick film of lubricant. So ,unlike hydrodynanmic lubrication, motion of one surface relative to another is not required .Elasohydrodynamic lubrication is the phenomenon that occurs when a lubricant is introduced between surfaces which are in rolling contact, such as mating gears or rolling bearings. The mathematical explanation requires the hertzian theory of contact stress and fluid mechanics.When bearing must be operated at exetreme temperatures, a solid film lubricant such as graphite or molybdenum disulfide must be use used because the ordinary mineral oils are not satisfactory. Must research is currently being carried out in an effort, too, to find composite bearing materials with low wear rates as well as small frictional coefficients.In a journal bearing, a shaft rotates or oscillates within the bearing , and the relative motion is sliding . in an antifriction bearing, the main relative motion is rolling . a follower may either roll or slide on the cam. Gear teeth mate with each other by a combination of rolling and sliding . pistions slide within their cylinders. All these applications require lubrication to reduce friction ,wear, and heating.The field of application for journal bearing s is immense. The crankshaft and connecting rod bearings of an automotive engine must poerate for thousands of miles at high temperatures and under varying load conditions . the journal bearings used in the steam turbines of power generating station is said to have reliabilities approaching 100 percent. At the other extreme there are thousands of applications in which the loads are light and the service relatively unimportant. a simple ,easily installed bearing is required ,suing little or no lubrication. In such cases an antifriction bearing might be a poor answer because because of the cost, the close ,the radial space required ,or the increased inertial effects. Recent metallurgy developments in bearing materials , combined with increased knowledge of the lubrication process, now make it possible to design journal bearings with satisfactory lives and very good reliabilities.参考文献：1. Chambers T. L., Parkinson A. R., 1998, “Knowledge Representation and Conversionof HybridExpert Systems.” Transactions of the ASME, v 120,pp 468-4742. Koelsch, James R., 1999, “Software boosts mold design efficiency“ MoldingSystems,v57, n 3,p 16-23.3. Lee, Rong-Shean, Chen, Y uh-Min, Lee, Chang-Zou,1997 “Development of aconcurrent molddesign system: A knowledge-based approach”, Computer IntegratedManufacturing Systems, v 10,n 4, p 287-3074. Steadman Sally, Pell Kynric M, 1995, “ Expert systems in engineering design: Anapplication forinjection molding of plastic parts“ Journal of Intelligent Manufacturing, v6, p 347-353.5. Fernandez A., Castany J., Serraller F., Javierre C., 1997, “CAD/CAE assistant for thedesign ofmolds and prototypes for in jection of thermoplastics “Information Technological, v 8, p 117-124.6. Douglas M Bryce, 1997, “Plastic injection molding -Material selection and productdesign”, v 2,pp 1-48.7. Douglas M Bryce, 1997, “Plastic injection molding-Mold design fundamentals”, v2,pp 1-120轴承的摩擦与润滑现在看来，有很多这种情况，许多学生在被问到关于摩擦的问题时，往往都没引起足够的重视，甚至是忽视它。

single-row ball bearing 单列滚珠轴承single-row centripetal ball bearing 单列向心滚珠轴承single-row centripetal bearing 单列向心轴承single-row radial ball bearing 单列星型滚珠轴承single-row radial thrust ball bearing 单列向心推力球轴承single-row roller bearing 单列滚柱轴承adapter bearing带固接套的轴承adjustable bearing可调轴承adjustable cone colter bearing圆犁刀的可调式锥形轴承aerostatic bearing空气静力轴承agate bearing玛瑙轴承air journal bearing气体轴承air lubricated thrust bearing气体润滑止推轴承aligning bearing排位轴承alkaline-friction bearing抗磨轴承all-rubber type bearing全胶式轴承。

全橡胶轴承aluminum base bearing铝基合金轴承aluminum-tin bearing铝锡合金轴承angular ball bearing径向止推滚珠轴承angular contact ball bearing角面接触滚珠轴承，向心止推滚珠轴承angular contact journal bearing角面接触轴颈轴承annular ball bearing向心球轴承，径向滚珠轴承annular contact thrust ball bearing推力向心球轴承antifriction thrust bearing抗推力轴承，抗磨止推轴承antithrust bearing止推轴承asymmetrical roller bearing非对称滚子轴承axial thrust bearing轴向推力轴承axle box bearing轴箱轴承azimuth bearing方位babbit metal (cast) bearing(铸造)巴氏合金轴承babbit-lined bearing巴氏合金衬套轴承，衬巴氏合金的轴承back bearing后轴承，反方位轴承back-to-back duplex bearing成对双联轴承(外圈宽端面相对)ball bearing滚珠轴承ball collar thrust bearing滚珠环止推轴承，滚珠环推力轴承ball journal bearing球颈轴承ball thrust bearing止推滚珠轴承barrel bearing圆筒轴承base bearing主轴承，底轴承，基轴承bellbearing钟杆推力轴承办人bevel pinion front bearing小锥齿轮前[后]轴承big-end bearing大端轴承blade bearing刃型支承block bearing支承轴承，止推轴承boring bar bearing镗杆轴承box bearing空转轴承bracket bearing托架轴承bushing bearing衬套轴承cageless rolling bearing无保持架轴承camshaft bearing凸轮轴轴承centring spring rod bearing调准簧杆轴承ceramic bearing陶瓷轴承check bearing检验方位,检验轴承circular unidirectional thrust bearing环状单向推力轴承closed-type bearing密闭形轴承clutch release bearing离合器分离轴承collar (thrust) bearing环形止推轴承combination bearing组合轴承commutator side bearing整流子侧支座composite bearing多层轴瓦,复合轴承compressed air bearing压缩空气轴承,压气轴承concentric adjustable bearing同心调整轴承conical bearing圆锥轴承corrugated bearing梳状轴承,槽形轴承countershaft gear bearing副轴齿轮轴承crank(ed) bearing曲轴轴承,曲柄轴承,连杆轴承cross head holt bearing十字头销轴承cross head pin bearing十字头销轴承cryogenic bearing低温轴承cutter bearing滚刀轴承declutch shaft bearing离合器操纵轴承,分离轴轴承diamond bearing金刚石轴承die cast bearing模铸轴承differential drive pinion cage bearing差速器主小齿轮罩轴承differential side bearing差速器壳轴承disk bearing圆盘轴承disk harrow bearing圆盘耙轴承distributor upper bearing配电器上轴承double bearing双列轴承double shield bearing双(护)罩轴承double thrust bearing双止推轴承double-row angular contact ball bearing双列向心推力球轴承double-row ball journal bearing双列径向滚珠轴承double-row radial ball bearing双列向心球轴承double-row radial spherical roller bearing双列向心鼓面滚子轴承double-row self-aligning spherical roller bearing双列向心球面滚子轴承(自动调心型) drag link bearing拉杆支座drive end bearing主动端轴承,驱动端轴承drive pinion cone bearing主动小齿轮锥形轴承drive shaft bearing主动轴轴承drop-hanger bearing悬挂轴承drum roller bearing鼓形滚柱轴承dry bearing干轴承duplex bearing双轴承duplex ball bearing成对双联向心推力球轴承dynamo bearing发电机轴承elastically yielding bearing弹性退让轴承elliptical bearing椭圆形轴承enclosed tubular bearing密封套管轴承(属于油浴润滑式轴承)end journal bearing端枢轴承end shield bearing机油滤清器内盖头轴承end thrust bearing止推轴承end-mounted bearing(耙组)两端安装的轴承engine thrust ball bearing止推滚珠轴承established line bearing非标准轴承expansion bearing活动支承,温度)伸胀支承expansive end bearing of bridge活动桥支座fabric bearing夹布胶木轴承fan end thrust ball bearing风扇端止推滚球轴承fan shaft bearing风扇轴轴承Ferro porit bearing渗硫铁系含油轴承filling slot type bearing填槽式轴承film bearing油膜轴承film lubrication bearing油膜轴承,液体摩擦轴承fixed-type bearing固定轴承flange bearing带法兰盘轴承flanged cup bearing外环凸缘轴承flexible bearing挠性轴承floating bush bearing浮动衬套轴承flood-lubricated bearing液体摩擦轴承,油膜轴承fluid bearing液压轴承fluid-film bearing流体膜轴承footstep bearing立轴承fore bearing前轴承fork bearing叉轴承forward bearing前象限角four-row tapered roller bearing四列圆锥滚柱轴承free end bearing活动支承,自由支承friction bearing滑动轴承friction thrust bearing摩擦止推轴承front main bearing前主轴承fulcrum bearing支承full-journal bearing全围式滑动轴承full-molded type rubber bearing整体模制式橡胶轴承gas-lubricated bearing气体润滑轴承gear shaft roller bearing齿轮轴滚柱轴承globe bearing球面轴承graphite bearing石墨板(离合器分离的),石墨轴承graphite-containing bearing含石墨的轴承graphited oilless bearing石墨润滑的无油轴承gravity side bearing重力复原旁承grid bearing坐标(网)方位grinding wheel bearing砂轮轴承groove ball bearing带沟球轴承guardbearing动力输出轴的)护罩轴承gudgeon pin bearing活塞销轴承,耳轴销轴承guide bearing导向轴承,导引轴承,定向轴承,导引方位角guide spindle bearing导轴轴承gunmetal bearing炮筒轴承half-and-haif bearing分成两半的轴承hanging bearing吊挂轴承hardwood bearing硬木轴承head bearing止端轴承heavy-duty bearing重载轴承hydrodynamic journal bearing液体动压轴承,油膜轴承hydrostatic bearing静压轴承idler shaft bearing空转轴轴承inclined bearing(倾)斜轴承,斜支承inner bearing内轴承intermediate bearing中间轴承jack shaft bearing曲柄轴轴承jewelled bearing宝石轴承Jordan bearing推力套筒轴承journal bearing经向轴承kick-starter bearing冲式起动器的曲柄轴承kingpin bearing凸轮止推回转轴承,止推销轴承,止推枢轴承knife-edge bearing刃形支承,刃支承,刀口承knuckle bearing铰式支座,球形支座,关节轴承labyrinth bearing迷宫轴承,曲径式密封轴承laminated bearing夹布胶木轴承,层压轴承leading -screw bearing传动螺杆轴承lignumvitae bearing层压胶木轴承locating bearing止推轴承,定位轴承lock nut bearing锁紧螺帽座longitudinal wall hanger bearing墙托架轴承long-path bearing远距离方位lower bearing下轴承lower half bearing轴承下瓦lubed-for-life bearing永久润滑轴承(即橡胶轴承)lubri-seal bearing阻油环轴承magnetic bearing磁向位,磁方位magnetic thrust bearing磁性推力轴承main bearing主轴承main rod bearing主杆轴承mainshaft bearing主轴轴承maintenance-free bearing自润滑轴承mechanical bearing轴承(总称)midship shaft bearing中间轴轴承miniature bearing微型轴承,超小型轴承molded-fabric bearing(设计)模制纤维轴承motor support bearing电动机支承轴承movable bearing活动支承multi-roll bearing滚针轴承multirow bearing多列轴承multipart bearing弓形轴承,扇形轴承multiple-groove bearing多油槽轴承neck bearing中间轴承needle bearing滚针轴承needle(type) roller bearing滚针轴承noise-free bearing低噪声轴承nonfilling slot type bearing无滚珠槽的滚动轴承non-locating bearing浮动轴承,不定位轴承non-porous bearing无孔轴承oil film bearing油膜轴承oil flooded bearing油膜轴承,液体摩擦轴承oil-bath type bearing油浴润滑式轴承oilless bearing不加油轴承自动润滑轴承石墨润滑轴承，含油轴承oil-retaining bearing含油轴承open spindle bearing开式锭子轴承oscillating bearing关节轴承oscillating journal bearing摆动轴径轴承outboard bearing外置轴承parallel bearing滑动轴承parallel-roller bearing平行滚柱轴承partial bearing半轴承partial journal bearing半围轴承(轴瓦在180°范围内包围着轴颈的滑动轴承) pedestal bearing支承轴承pendulum bearing钟摆轴承pin rocker bearing铰接支座,圆柱枢轴摆动轴承pinion bearing小齿轮轴承piston pin bearing活塞销轴承pivot bearing枢轴承,摆动支座,中心(轴尖)支承,立式止推轴承plain-and -ball bearing滑动与滚动组合轴承plane bearing平面轴承plummer block bearing架座,止推轴承pneumatic bearing空气轴承pocket bearing油盘轴承porous bearing多孔轴承powdiron bearing多孔铁轴承,粉未铁轴承power take-off lever bearing动力输出轴轴承preloaded bearing预紧轴承prelubricated bearing预(加)润滑[油密封]轴承,一次润滑轴承pressure-feed air bearing静压空气轴承pressure-loaded bearing承压轴承proper bearing紧密接触轴承pump bearing泵轴承quill bearing滚针轴承radial journal bearing径向轴承,支持轴承,轴颈轴承radial spherical roller bearing径向球形滚柱轴承radial-thrust bearing径向止推轴承rail bearing轨枕,轨承,轨底支承面ring-oiled sleeve bearing油环润滑式滑动轴承;油环式滑动轴承rocker bearing桥架)摇轴支座; (桁架)伸缩支座rod bearing杆轴承roller bearing滚柱轴承roller step bearing滚柱止推轴承rolling-contact bearing滚动接触轴承rotating journal bearing转动轴颈轴承round bearing转动件轴承rubber bearing橡胶轴承sealed roller bearing密封式滚子轴承sector gear bearing扇形齿轮轴承segmental bearing弓形轴承,弧形轴承,分片互轴承,轴瓦块轴承self-acting air bearing动压空气轴承self-aligning bearing球面轴承,自位轴承self-setting bearing多向调整轴承shafting bearing轴承shell bearing轴承壳shifting bearing活动支座shock absorber bearing减震器座side rod bearing边杆轴承single plate ball bearing单垫片滚珠轴承single row angular contact ball bearing单列向心推力球轴承single row cylindrical roller bearing单列短圆柱滚子轴承single shield bearing单罩轴承single thrust bearing单向推力轴承,单向止推轴承single-row bearing单列轴承single-row separable ball bearing分离型向心推力球轴承single-row tapered roller bearing单列圆锥滚子轴承sintered metal bearing烧结金属轴承sleeve bearing套筒轴承,滑动轴承slewing bearing旋转枢轴轴承slide bearing滑动轴承sliding double bearing滑动复式轴承snap-ring bearing开口环轴承snap-ring ball bearing(在负荷端)带止动垫圈的滚珠轴承solid journal bearing整体轴颈轴承solid roller bearing实心滚子轴承,整体滚柱轴承special guide bearing特种导承spherical bearing球面轴承,球形支座,球面支承spherical roller thrust bearing推力球面滚子轴承spigot bearing导向轴承,套筒轴承，小载荷轴承,轻载轴承，插口轴承spindle bolt bearing心轴螺栓轴承spiral roller bearing螺旋(式)滚子轴承spot contact bearing滚珠轴承spring plank bearing摇枕吊轴sprocket shaft bearing链轮轴轴承square-bore ball bearing方(轴)孔滚珠轴承squeeze film bearing(挤)压(油)膜轴承starter main shaft bearing起动机主轴轴承steady bearing支撑轴承(防止长轴摆动)steep angle bearing大锥角滚柱轴承steering gear worm thrust bearing转向蜗杆止推轴承steering knuckle thrust bearing转向关节主动轴承steering worm bearing转向蜗杆轴承steering worm sector bearing转向器扇形蜗轮轴承step bearing立式止推轴承,踏板轴承,阶式止推轴承straight roller bearing普通滚柱轴承stuffing box bearing填料压盖轴承,密封轴承suspension bearing吊轴承swing bearing摆动支座,摆锤支座swivel bearing旋转轴承taper-bore cylindrical-roller bearing 锥孔圆柱滚子轴承taper-roller bearing锥形滚柱轴承textolite bearing夹布胶木轴承thermo-expansion compensation angular ball bearing热胀补偿向心球轴承thrust bearing推力轴承,止推轴承tin-copper-graphite bearing青铜石墨轴承tip bearing枢轴承,枢支座toe bearing立式止推轴承top bearing上盖(顶盖)轴承Torrington needle bearing(无内座圈的)冲压外座圈滚针轴承torsion bearing抠转轴承transverse bearing径向轴承trunnion bearing耳轴承tumbler bearing铰式支座,摆动支座(轴承)two-direction self-aligning ball thrust bearing双球面止推滚珠轴承,自调止推滚珠轴承two-piece bearing一对轴承,拼合轴承two-point bearing二点交叉定位支承uncoupling lever shaft bearing互钩开关杆轴承universal-joint cross bearing万向接头轴承universal-joint needle bearing万向节针式轴承upper bearing上轴承,上轴瓦upper crankshaft bearing曲轴主轴承上轴瓦water lubricated bearing水润滑轴承water pump shaft bearing水泵轴轴承water-sealed bearing防水轴承weight-carrying roller bearing径向滚柱轴承wheel bearing轮轴轴承wick-lubricated bearing油渑润滑轴承winch worm shaft bearing绞车蜗杆轴承wire race ball bearing钢丝滚道球轴承wooden bearing木制轴承worm bearing蜗杆轴承worm shaft roller conical bearing蜗杆锥棍轴承worm thrust bearing蜗杆止推轴承wrist-pin bearing十字头销衬套,活塞销衬套接下来是“滚动轴承”的：一．轴承：(一)滚动轴承总论1. 滚动轴承rolling bearing在支承负荷和彼此相对运动的零件间作滚动运动的轴承，它包括有滚道的零件和带或不带隔离或引导件的滚动体组。

最新各种轴承英文翻译各种轴承英文翻译第1章滚动轴承(rolling bearing1.1 向心轴承(contact ball bearing1.1.1 深沟球轴承(deep grove ball bearing)1.1.2 圆柱滚子轴承(cylindrical roller bearing)1.1.3 滚针轴承(needle bearing)1.1.4 调心球轴承(self-aligning ball bearing)1.1.5 角接触球轴承(angular-contact ball bearing)1.1.6 圆锥滚子轴承(tapered roller bearing)1.1.7 调心滚子轴承(self-aligning roller bearing)1.2 推力轴承(thrust bearing)1.2.1 推力球轴承(thrust ball bearing)1.2.2 推力圆柱滚子轴承(thrust cylindrical roller bearing) 1.2.3 推力滚针轴承(thrust needle bearing)1.2.4 推力角接触球轴承(thrust angular-contact ball bearing) 1.2.5 推力调心滚子轴承(thrust self-aligning roller bearing) 1.3 组合轴承(combined bearing)1.4 外球面球轴承(spherical surface ball bearing)1.5 直线运动滚动支承(linear roll bearing)1.6 滚轮滚针轴承（tracd & needle roller bearing）1.7 水泵轴连轴承（water pump bearing）1.8 专用轴承(special bearing)1.9 滚动轴承附件(fitting parts for rolling bearing)第2章滑动轴承(plain bearing)2.1 关节轴承(articulated bearing)2.1.1 杆端关节轴承(rod end & spherical plain bearing)2.1.2 向心关节轴承(plain radial bearing)2.1.3 角接触关节轴承(angular-contact articulated bearing)2.1.4 推力关节轴承(thrust articulated bearing)2.2 其他滑动轴承(others plain bearing)2.3 滑动轴承轴套与轴瓦(bushing & half-liner of plain bearing)2.3.1 轴套(plain bearing bushing)2.3.2 轴瓦(plain bearing half-liner)2.4 滑动轴承附件(fitting parts for plain bearing)adapter bearing带固接套的轴承adjustable bearing可调轴承adjustable cone colter bearing圆犁刀的可调式锥形轴承aerostatic bearing空气静力轴承agate bearing玛瑙轴承air journal bearing气体轴承air lubricated thrust bearing空气润滑止推轴承aligning bearing(直线)对位轴承alkaline-friction bearing抗磨轴承allowable bearing容许支承力all-rubber type bearing全胶式轴承。

轴承专业英语看懂英⽂报告再也不是问题了！轴承⼈，学点轴承专业英语，很有必要！--CHIPRO⼀、轴承(⼀)滚动轴承总论1.滚动轴承 rolling bearing ['rəuliŋ]2.单列轴承 single row bearing [rau]3.双列轴承 double row bearing4.多列轴承 multi-row bearing ['mʌlti]5.满装滚动体轴承 full complement bearing [ful] ['kɔmplimənt]6.⾓接触轴承 angular contact bearing ['æŋɡjulə]7.调⼼轴承 self-aligning bearing [ə‘lainiŋ]8.可分离的轴承 separable bearing ['sepərəbl]9.不可分离轴承 non-separable bearing10.单列深沟球轴承是球轴承中最普通的种类，应⽤及其⼴泛。

Single row deep groove ball bearings are the most common type of rolling bearing and areused in a wide variety [və'raiəti] of applications.The moment of friction of high-speed grease-lubricated rolling bearing determines its power consumption and heat output,and the heat output has a direct effect on its temperature rise.在⾼速脂润滑滚动轴承中,摩擦⼒矩的⼤⼩决定了轴承的功率消耗和发热量的⼤⼩,发热量的⼤⼩直接影响轴承的温升失效。

Rolling Contact BearingsThe concern of machine designer with ball and roller bearings is fivefold as follows: (a) life in rlation to load; (b) stiffness, i.e. deflection under load; (c) friction;(d) wear; (e) noise. For moderat loads and speeds the correct selection of a standard bearing on the basis of load rating will usually secure satisfactory performance. The deflection of the bearing elements will become important where loads are high, although this is uaually od less magnitude than that of the shafts or other componentsassociated 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.Became the high quality and low price of ball and roller bearings dependson quantity production, the task of the machine designer becomes one of selection rather than design. Rolling-contact bearings are generally made with steel which is through-hardened to about 900 HV, although in many mechanisms special races are not provided and the interacting surfaces are hardened to about 600 HV. It is not surprising that, owing to the high stresses involved, a predominant form of failure should be metal fatigue, and a good deal of work is currently in progress intended to improve the reliability of this type of bearing. Design can be based on accepted values of life and it is general practice in the bearing industry to define the load capacity of the bearing as that value below which 90 per cent of a batch will exceed a life of one million revolutions.Notwithstanding the fact that responsibility for the basic design of ball 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.Where life is not the determining factor in design, it is usual to determinemaximum loading by the amount to which a bearing will deflect under load. Thus the concept of "static load-carrying capacity" is understood to mean the load that can be applied to a beating, which is either stationary or subject to slight swiveling motions, without impairing its running qualities for subsequent rotational motion. This has been determined by practical experience as the load which when applied to a bearing results in a total deformation of the rolling element and raceway at any point of contact not exceeding 0.01 per cent of the rolling-element diameter. This would correspond to a permanent deformation of 0.0025 mm for a ball 25 mm in diameter.The successful functioning of many beatings depends upon providing them, with adequate protection against their environment, and in some circumstances the environment must be protected from lubricants'or products of deterioration of the bearing surfaces. Achievement of the correct functioning of seals is at essential part of bearing design. Moreover, seals which are applied to moving parts for any purpose are of interest to tribelogists because they are components of bearing systems and can only be designed satisfactorily on the basis of appropriate bearing theory. Notwithstanding their importance, the amount research effort that has been devoted to the understanding of the behavior seals has been small when compared with that devoted to other aapects of bearing technology.Virtually all machines contain shafts. The most common shape for shafts is circular result in and the cross section can be either solid or hollow (hollow shafts can weight savings).Rectangular shafts，are sometimes used as in screwdriver blades，socket wrenches and control knob stems.A shaft must have adequate tensional strength to transmit torque and not be overstressed. It must also be torsionally stiff enough so that one mounted component does not deviate excessively from its original angular position relative to a second component mounted on the same shaft. Generally speaking, the angle of twist should not exceed one degree in a shaft length equal to 20 diameters.Shafts are mounted in bearings and transmit power 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. Perft of length between bearing supports.In addition，the shaft must he able to sustain a combination of bending and torsional loads. Thus an equivalent load must he considered which takes into accountboth torsion and bending. Also, the allowable stress must contain a factor of safety which includes fatigue; since torsional and bending stress reversals occur For diameters less than 3 in，the usual shaft material is cold-rolled steel containing abort 0.4 percent carbon. Shafts are either cold-rolled or forged in sizes form 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.Components such as gears and pulleys are mounted，on shafts by means of key. The design of the key and the corresponding keyway in the shaft must be properly evaluated. For example，stress concentrations in shafts due to keyways, and the material removed to form the keyway further weakens the shaft.If shafts are run at critical speeds，severe vibrations can occur which can seriously damage a machine. It is important to know the magnitude of these critical speeds so that they can be avoided. As a general rule of thumb，the difference between the operating speed and the critical speed should be at least 20 percent.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.A coupling is a device for connecting the ends of adjacent shafts. In machine construction，couplings are used to effect a semipermanent connection between adjacent rotating shafts. The connection is permanent in the sense that it is not meant to be broken during the useful life of the machine, but it can be broken and restored. In an emergency or when worn parts are replaced.There are several types of shaft couplings，their characteristics depend on the purpose for which they are used. If an exceptionally long shaft is required in a manufacturing plant or a propeller shaft on a ship, it is made in sections that are coupled together with rigid couplings. A common type of rigid coupling consists of two mating radial flanges (disks) that are attached by key-driven hubs to the ends of adjacent shaft sections and bolted together through the flanges to form a rigid connection. Alignment of the connected shafts is usually effected by means of a rabbet joint on the face of the flanges.In connecting shafts belonging to separate devices(such，an electric motor and a gearbox)，precise aligning of the shafts is difficult and，flexible coupling is used.This coupling connects the shafts in such a way as to minimize the harmful effects of shaft misalignment. Flexible couplings also permit the shafts to deflect under their separate systems, of loads and to move freely (float) in the axial direction without interfering with one another. Flexible couplings can also serve to reduce the intensity of shock loads and vibrations transmitted from one shaft to another.滚动轴承对于球轴承和滚子子轴承，一个机器设计人员应该考虑下面五个方面：（a）寿命与在和的关系；（b）刚度，也是在载荷作用下的变形；（c）摩擦，（d）磨损；（e）噪音。

腐蚀磨损corrosive wear金属表面在磨擦过程中与周围介质在化学与电化学反应作用下产生的磨损过程。

干摩擦dry friction两物体间名义上无任何形式的润滑剂存在时的摩擦。

严格地说，干摩擦时在接触表面上无任何其他介质，如湿气及自然污染膜。

分散润滑individual point lubrication使用便携式工具向润滑点手动加油的润滑方式。

防锈添加剂anti-rust additive,rust preventive additive能防止金属机件生锈，延迟或限制生锈时间，减轻生锈程度的添加剂。

动磨擦kinetic friction相对运动两表面之间的磨擦。

此时的磨擦系数称为动磨擦系数。

多效添加剂multipurpose additive能同时改善油品两种性能以上的添加剂。

多用途润滑脂multipurpose grease适合于多种用途的润滑脂。

可用于润滑汽车中的底盘齿轮轴承、万向节和水泵等。

多线式润滑系统multiline lubricating system油泵的多个出油口，各有一条管路直接将定量的润滑剂供送至各润滑点的集中润滑系统。

稠化剂densifier能提高润滑油、液压油或润滑脂的粘度或稠度的物质。

冲击磨损impact wear是一种磨料磨损类型，磨料垂直或以一定的倾角落在材料表面上。

其情况与冲蚀磨损很相似，但局部应力要高得多。

沉积膜deposit film润滑油中某程组分沉积在摩擦表面上形成的边界膜。

冲刷磨损erosive wear摩擦表面经受高速介质（液、气流或液、气流中夹带砂粒）的冲刷作用而导致表面材料磨损的现象。

边界润滑boundary lubrication作相对运动的两表面之间的摩擦磨损特性，取决于两表面的特性和润滑剂与表面间的相互作用及所生成边界膜的性质的润滑状态。

边界摩擦boundary friction具有无体积特性的液体层隔开两固体作相对运动时的摩擦，即边界润滑状态下的摩擦。

ＵＨＭＷＰＥ基水润滑轴承摩擦及润滑特性的试验研究王艳真１，李虎林２，钟涛１，尹忠慰２（１．中国船舶及海洋工程设计研究院，上海　２０００１１；２．上海交通大学　设计学院，上海　２００２４０）摘要：针对纤维填料改性ＵＨＭＷＰＥ水润滑轴承的摩擦磨损性能进行研究。

在平面摩擦磨损试验机上对玻璃纤维及碳纤维填料对ＵＨＭＷＰＥ复合材料摩擦性能进行试验，并分析ＧＦ－ＣＦ－ＵＨＭＷＰＥ材料与ＴｈｏｒｄｏｎＳＸＬ材料在干摩擦、水润滑工况下的摩擦因数及磨损量。

最后，采用径向水润滑轴承试验台对比研究了ＧＦ－ＣＦ－ＵＨＭＷＰＥ轴承和ＴｈｏｒｄｏｎＳＸＬ轴承在不同载荷下摩擦因数随转速的变化规律。

结果表明：纤维填料能显著增强ＵＨＭＷＰＥ的减摩性和耐磨性，ＧＦ－ＣＦ－ＵＨＭＷＰＥ材料具有更好的耐温性能，线性热膨胀系数也显著减小；ＧＦ－ＣＦ－ＵＨＭＷＰＥ轴承具有相同载荷下启动转速低，启动摩擦因数小的特性。

关键词：滑动轴承；ＵＨＭＷＰＥ；复合材料；纤维；改性；摩擦；润滑中图分类号：ＴＨ１３３．３１；Ｕ６６３．５ 文献标志码：Ｂ ＤＯＩ：１０．１９５３３／ｊ．ｉｓｓｎ１０００－３７６２．２０２１．０１．０１２ＥｘｐｅｒｉｍｅｎｔａｌＳｔｕｄｙｏｎＦｒｉｃｔｉｏｎａｎｄＬｕｂｒｉｃａｔｉｏｎＰｅｒｆｏｒｍａｎｃｅｏｆＵＨＭＷＰＥＢａｓｅｄＷａｔｅｒＬｕｂｒｉｃａｔｅｄＢｅａｒｉｎｇｓＷＡＮＧＹａｎｚｈｅｎ１，ＬＩＨｕｌｉｎ２，ＺＨＯＮＧＴａｏ１，ＹＩＮＺｈｏｎｇｗｅｉ１（１．ＭａｒｉｎｅＤｅｓｉｇｎａｎｄＲｅｓｅａｒｃｈＩｎｓｔｉｔｕｔｅｏｆＣｈｉｎａ，Ｓｈａｎｇｈａｉ２０００１１，Ｃｈｉｎａ；２．ＳｃｈｏｏｌｏｆＤｅｓｉｇｎ，ＳｈａｎｇｈａｉＪｉａｏｔｏｎｇＵｎｉｖｅｒｓｉｔｙ，Ｓｈａｎｇｈａｉ２００２４０，Ｃｈｉｎａ）Ａｂｓｔｒａｃｔ：Ｔｈｅｆｒｉｃｔｉｏｎａｎｄｗｅａｒｐｒｏｐｅｒｔｉｅｓｏｆｗａｔｅｒ－ｌｕｂｒｉｃａｔｅｄＵＨＭＷＰＥｂｅａｒｉｎｇｍａｔｅｒｉａｌｓｍｏｄｉｆｉｅｄｗｉｔｈｆｉｂｅｒｆｉｌｌｅｒｓａｒｅｓｔｕｄｉｅｄ．Ａｆｒｉｃｔｉｏｎａｎｄｗｅａｒｔｅｓｔｅｒｉｓｕｓｅｄｔｏｓｔｕｄｙｔｈｅｉｎｆｌｕｅｎｃｅｏｆｇｌａｓｓｆｉｂｅｒａｎｄｃａｒｂｏｎｆｉｂｅｒｆｉｌｌｅｒｓｏｎｔｈｅｔｒｉｂｏ ｌｏｇｉｃａｌｂｅｈａｖｉｏｒｏｆＵＨＭＷＰＥｃｏｍｐｏｓｉｔｅｓ，ａｎｄａｃｏｍｐａｒａｔｉｖｅｓｔｕｄｙｏｆｔｈｅｆｒｉｃｔｉｏｎｃｏｅｆｆｉｃｉｅｎｔａｎｄｗｅａｒｒａｔｅｏｆＧＦ－ＣＦ－ＵＨＭＷＰＥａｎｄＴｈｏｒｄｏｎＳＸＬｕｎｄｅｒｄｒｙｆｒｉｃｔｉｏｎａｎｄｗａｔｅｒｌｕｂｒｉｃａｔｉｏｎｃｏｎｄｉｔｉｏｎｓｉｓｃｏｎｄｕｃｔｅｄ．Ｆｉｎａｌｌｙ，ｕｓｉｎｇａｗａｔｅｒ－ｌｕｂｒｉｃａｔｅｄｊｏｕｒｎａｌｂｅａｒｉｎｇｔｅｓｔｒｉｇ，ｔｈｅｖａｒｉａｔｉｏｎｏｆｔｈｅｆｒｉｃｔｉｏｎｃｏｅｆｆｉｃｉｅｎｔｗｉｔｈｒｏｔａｔｉｏｎａｌｓｐｅｅｄｏｆＧＦ－ＣＦ－ＵＨＭＷＰＥｂｅａｒｉｎｇｓａｎｄＴｈｏｒｄｏｎＳＸＬｂｅａｒｉｎｇｓｕｎｄｅｒｄｉｆｆｅｒｅｎｔｌｏａｄｓｉｓｃｏｍｐａｒａｔｉｖｅｌｙｓｔｕｄｉｅｄ．ＴｈｅｒｅｓｕｌｔｓｓｈｏｗｔｈａｔｔｈｅｆｉｂｅｒｆｉｌｌｅｒｓｃａｎｓｉｇｎｉｆｉｃａｎｔｌｙｒｅｄｕｃｅｔｈｅｆｒｉｃｔｉｏｎｃｏｅｆｆｉｃｉｅｎｔａｎｄｗｅａｒｒａｔｅｏｆＵＨＭＷＰＥ．ＧＦ－ＣＦ－ＵＨＭＷＰＥｍａｔｅｒｉａｌｈａｓｂｅｔｔｅｒｈｅａｔｒｅｓｉｓｔａｎｃｅａｎｄｌｏｗｅｒｌｉｎｅａｒｔｈｅｒｍａｌｅｘｐａｎｓｉｏｎｃｏｅｆｆｉｃｉｅｎｔ．Ｉｎａｄｄｉｔｉｏｎ，ＧＦ－ＣＦ－ＵＨＭＷＰＥｂｅａｒｉｎｇｓｈａｖｅｌｏｗｓｔａｒｔｉｎｇｒｏｔａｔｉｏｎａｌｓｐｅｅｄｕｎｄｅｒｓａｍｅｌｏａｄａｎｄｌｏｗｓｔａｒｔｉｎｇｆｒｉｃｔｉｏｎｃｏｅｆｆｉｃｉｅｎｔ．Ｋｅｙｗｏｒｄｓ：ｓｌｉｄｉｎｇｂｅａｒｉｎｇ；ＵＨＭＷＰＥ；ｃｏｍｐｏｓｉｔｅ；ｆｉｂｅｒ；ｍｏｄｉｆｉｃａｔｉｏｎ；ｆｒｉｃｔｉｏｎ；ｌｕｂｒｉｃａｔｉｏｎ 近年来，水作为润滑介质的滑动轴承在船舶、泵类、水轮机等设备上广泛应用。