中英文文献翻译—非独立悬架

附录A 外文文献The structural characteristics of non-independent suspension on both sides of the wheel is an integral frame connected by the wheels together with the adoption of flexible suspension bridge hanging in the frame or body of the following. Non-independent suspension has a simple structure, low cost, high strength, easy maintenance, driving changes in the small front wheel alignment advantages, but because of its comfort and handling stability are poor, largely in the modern car is no longer in use more used in trucks and large passenger on. Independent suspension on each side of the wheel is individually through the elastic suspension is hanging in the frame or body below. The advantages are: light weight, reduced body shocks, and improve adhesion of the wheels on the ground; available small soft spring stiffness, improve vehicle comfort; can reduce engine position, car center of gravity is reduced, thereby improve the car's driving stability; about beating the wheel alone, independent of each other, can reduce the body's tilt and vibration. However, there are complex independent suspension, high cost and maintenance problem of inaccessibility. Modern cars are mostly used independent suspension, according to the different structure, independent wishbone suspension can be divided into longitudinal arm, multi-link, candle and McPherson suspension and so on. Arm Suspension means the horizontal plane in the car wheel independent suspension swing, according to the number of how many arm is divided into wishbone and single-arm suspension. Single-Arm has a simple structure, roll center height, with a strong anti-roll capability advantages. But with the increased speed of modern vehicles, roll center is too high will cause the wheel tread beats changes, tire wear increased, and in a sharp turn around the wheel vertical force when the transfer is too large, resulting in increased rear extraversion. Reduce rear-wheel cornering stiffness, resulting in a serious condition high-speed drift. Single-wishbone independent suspension in the rear suspension on a multi-application, but can not meet the requirements of high speed, the current limited application. Multi-link suspension are combined by the root pole position change control of the wheel suspension. Multi-link can wheel around the axis line with the vehicle at an angle within the swing axis is horizontal arm and vertical arm of the compromise, choose the right arm with the motor axis into a vertical line of the angle, can be varying degrees of access to wishbone suspension with the advantages of vertical arm, which can meet different performance requirements. Multi-link suspension of the main advantages are: the wheel tread and beating little change before the beam, both cars are in driving, braking status can be carried out by the driver of the Yi Tu smooth transition to its shortcomings in the automotive when the phenomenon of high-speed shaft swing. Mainly in the FR-link drive mode, and around the back axle of the integration (and the middle of the differential rigid connection) for use where, in the past to use more leaf spring support body, and now from the increased driving comfort considerations, multi-use Link back to say that the swing arm type and style, and use a good coil spring ride. Link in the left side of a pair, divided into upper and lower tie rod, as thelateral force transmission (car drivers) body, usually with a horizontal thrust bar again with the composition of the five-link form. Connect one end of the body lateral thrust rod, one end of the connecting axle, its purpose is to prevent the axle (or body) horizontal traverse. When the axle moves up and down because of the rough, the lateral thrust rod will be connected to contacts with the body axis, an art movement arc, through the General Assembly if the swing angle made between the axles and the body produces significant lateral relative motion, and the lower arm principle similar to the horizontal thrust rod longer than should be designed to reduce the swing angle. Link suspension and axle forming an integrated whole, the mass of the spring below, and not the independence movement around the wheel, so to face bumpy road vehicle impact energy generated by relatively large, poor ride comfort. So there arm methods, this approach is the only fixed-axle differential among left and right half shaft in the differential and universal joints located between the wheel and the center of its swing, used between the wheel and the frame Y-connection under the arm. "Y" at one end and a separate rigid wheel, the other two endpoints and the frame to connect and form a rotation axis. According to the rotation axis is parallel with the axle, swing arm type suspension is divided into full drag-type arm and half drag-style swing arm, parallel to the whole drag-style, non-parallel type is called semi-drag.Because comfort is the car one of the most important performance, and comfort with the body's natural vibration characteristics, whereas the body's natural vibration characteristics of a feature associated with the suspension. Therefore, the vehicle suspension is to ensure the comfort of the important parts. Meanwhile, the vehicle suspension as a frame (or body) and the axle (or wheel) to make the connection between the mechanical power transmission, it is important to ensure the safety of motor cars and parts. Therefore, the vehicle suspension components are often incorporated into the car as an important technical specifications of the table, as one of the indicators to measure the quality of cars.Active suspension is developed in the last ten years, a new type of computer-controlled suspension. It brings together mechanics and electronics, technical knowledge, is a more complex high-tech devices. For example, the installation of the French Citroen Sang Diya active suspension, the center of the car suspension system is a microcomputer, the suspension on five kinds of sensors were transmitted to the micro-computer speed, front wheel brake pressure, ride a fixed throttle pedal speed, body vertical amplitude and frequency, steering wheel angle and steering velocity data. Computer continuously receives the data and with pre-set threshold to compare, select the appropriate suspension state. Meanwhile, the microcomputer independent control of each wheel on the implementation of the components only by controlling the hydraulic shock absorber of changes within the tic, which can at any time, any wheels that meet the requirements of the suspension movement. Therefore, Sang Diya car a wide range of driving mode selection, drivers need only flip a deputy on the dashboard in the "normal" or "sport" button will automatically set the car's suspension in top condition, in order to The best comfort.Active suspension control of body movement with the function. When the car when braking or turning the inertia caused by the spring deformation, the active suspension forces will have to confront a force used to reduce the body position changes. 2000 Mercedes-Benz CL models such as Germany-based sports car, when the suspension when the vehicle turning sensor will immediately detect the body's tilt and lateral acceleration. Computer based on the sensor information, and pre-set threshold value of calculations to determine what position once the load will be added to the suspension on how to minimize body tilt.Wishbone independent suspension by upper and lower arm is so long, is divided into equal length wishbone and unequal length wishbone suspension of two. And other long-wishbone suspension in the wheel up and down beats, kingpin inclination to maintain the same, but the wheelbase change greatly (and similar single-Arm), resulting in severe tire wear, is now rarely used. The unequal length wishbone suspension, when properly selected to optimize the length of the upper and lower arm, and through a reasonable layout, you can make changes in tread and the front wheel alignment parameters were within acceptable limits to ensure the car good driving stability. Present unequal length wishbone suspension has been widely used in cars, front and rear suspension, the part of the sports car and the car's rear wheel has adopted this - suspension structure. Suspension roleSuspension is an important vehicle in the assembly, it is to frame the flexibility to link with the wheel bearing on a variety of performance cars. In appearance, a car suspension only by a number of rods, cylinders and springs form, but do not think it is very simple, opposite a car suspension is more difficult to achieve the perfect vehicle assembly requirements, this is because both suspension to meet the car's comfort requirements, but also to meet the requirements of its handling and stability, while these two aspects are mutually antagonistic. For example, in order to achieve good comfort, requires much buffer vehicle vibration, the spring must be designed so soft, but, it is easy for the spring soft place car brake "nod", the "rise" and roll about serious adverse tendency is not conducive to the car turn easily lead to vehicle handling and instability. Therefore, if the suspension is poorly designed, will significantly affect the performance of automotive products (such as turning a heavy, swing, tire eccentric wear and affect tire life, etc.).附录B 中文翻译非独立悬架的结构特点是两侧车轮由一根整体式车架相连，车轮连同车桥一起通过弹性悬架悬挂在车架或车身的下面。

汽车悬架英语词汇汽车悬架英语词汇（车身）高度阀levelling valveU型螺栓U bolt半径杆radius rod半椭圆形弹簧half-elliptic spring(semi-elliptic spring)臂轴arm shaft变截面弹簧tapered spring部件assembly and parts车架auxiliary tank充气减振器gas-filled shock absorber单横臂式singe trailing arm type单横臂式single transverse arm type单片式钢板弹簧single leaf spring单气室油气弹簧single chamber hydragas spring单斜臂式single oblique arm type弹簧架spring bracket弹簧静挠度spring static deflection弹簧卷耳spring eye弹簧跳动间隙bump clearance of spring弹簧中心距distance between spring centers弹簧主片spring leaf底盘弹簧chassis spring地面弹簧载荷量spring capacity at ground第迪安式De Dion type垫上弹簧载荷量spring capacity at pad动力减振器dynamic shock absorber独立悬架independent suspension短型车架stub frame多片式钢板弹簧muotileaved spring发动机支架engine mounting非独立悬架rigid axle suspension非对称钢板弹簧unsymmetrical leaf spring分开式车身和车架separated body and frame负荷调平式减振器load-levelling shock absorber 副钢板弹簧auxiliary spring钢板弹簧leaf spring(laminated spring)钢板弹簧衬套leaf spring bushing钢板弹簧吊耳leaf spring shackle钢板弹簧销leaf spring pin钢板弹簧中心螺栓leaf spring center bolt横臂transverse arm横向推力杆lateral rod横向稳定器stabilizer anti-roll bar横置板簧式transversal leaf spring type滑板sliding plate滑动座sliding seat缓冲块buffer stopper簧上质量sprung weight簧下质量unsprung weight减振器shock absorber减振器进油阀shock absorber intake valve 减振器示功图damper indicator diagram 减振器卸荷阀shock absorber relief valve 减振器液damper fluid金属弹簧式metal spring type可变刚度悬架variable rate suspension可调减振器adjustable shock absorber空气弹簧air spring空气弹簧式air spring type控制臂control arm拉杆tension rod类型type螺纹衬套screw bushing螺旋弹簧coil spring(helicalspring)麦弗逊式MacPherson type膜式空气弹簧diaphragm typeair spring磨擦式减振器frictional shock absorber囊式空气弹簧bellow type air spring扭矩套管torque tube扭矩套管式torque tube drive type平横臂equalizer平衡杆stabilizer bar平衡悬架equalizing type of suspension平衡轴trunnion shaft平衡轴支座trunnion base全椭圆形弹簧full elliptic spring三点悬架three-point suspension上控制臂upper control arm上弯式梁架upswept frame(kick up frame)上悬架臂upper suspension arm上置板簧式over slung type双横臂式double-wishbone type双横臂式double with-bone arm type双气室油气弹簧double chamber hydragas spring双纵臂式double trailing arm type双纵臂式double-trailing arm type四点悬架four-point suspension四分之三椭圆形弹簧three quarter elliptic spring 四分之一椭圆形弹簧quarter elliptic spring四连杆式four link type筒式减振器telescopic shock absorber下控制臂lower control arm下置板簧式under slung type限位块limiting stopper橡胶衬套rubber bushing橡胶弹簧rubber spring type橡胶弹簧式rubber spring type橡胶液体弹簧式hydro-rubber spring type斜臂oblique arm悬臂弹簧cantilever spring悬架suspension悬架臂suspension arm悬架系suspension system压杆strut bar摇臂式减振器lever type shock absorber液体弹簧hydraulic spring液体弹簧hydraulic spring液体弹簧式hydraulic spring type液压减振器dydraulic shock absorber油气弹簧hydro-pneumatic spring type 油气弹簧式hydro-pneumatic spring type 油压缓冲器hydraulic buffer整体车架unitized frame支撑杆strut bar支撑梁support beam制动反应杆brake reaction rod烛式sliding pillar type纵臂trailing arm纵向钢板弹簧longitudinal leaf spring纵向推力杆longitudinal rod纵置板簧式parallel leaf spring type组合式悬架combination suspension。

悬架系 suspension system悬架 suspension类型 type非独立悬架 rigid axle suspension独立悬架 independent suspension平衡悬架 equalizing type of suspension 组合式悬架 combination suspension可变刚度悬架 variable rate suspension 纵置板簧式 parallel leaf spring type上置板簧式 over slung type下置板簧式 under slung type双横臂式 double with-bone arm type横置板簧式 transversal leaf spring type 双纵臂式 double trailing arm type单横臂式 single transverse arm type双横臂式 double —wishbone type单横臂式 singe trailing arm type双纵臂式 double-trailing arm type单斜臂式 single oblique arm type四连杆式 four link type扭矩套管式 torque tube drive type第迪安式 De Dion type烛式 sliding pillar type麦弗逊式 MacPherson type金属弹簧式 metal spring type空气弹簧式 air spring type油气弹簧式 hydro—pneumatic spring type 橡胶液体弹簧式 hydro-rubber spring type 橡胶弹簧式 rubber spring type液体弹簧式 hydraulic spring type三点悬架 three—point suspension四点悬架 four—point suspension部件 assembly and parts悬架臂 suspension arm上悬架臂 upper suspension arm控制臂 control arm上控制臂 upper control arm下控制臂 lower control arm纵臂 trailing arm横臂 transverse arm斜臂 oblique arm支撑梁 support beam横向推力杆 lateral rod纵向推力杆 longitudinal rod拉杆 tension rod压杆 strut bar支撑杆 strut bar扭矩套管 torque tube变截面弹簧 tapered spring钢板弹簧 leaf spring(laminated spring)副钢板弹簧 auxiliary spring非对称钢板弹簧 unsymmetrical leaf spring单片式钢板弹簧 single leaf spring多片式钢板弹簧 muotileaved spring纵向钢板弹簧 longitudinal leaf spring螺旋弹簧 coil spring (helicalspring)空气弹簧 air spring囊式空气弹簧 bellow type air spring膜式空气弹簧 diaphragm typeair spring橡胶弹簧 rubber spring type液体弹簧 hydraulic spring油气弹簧 hydro—pneumatic spring type单气室油气弹簧 single chamber hydragas spring双气室油气弹簧 double chamber hydragas spring液体弹簧 hydraulic spring底盘弹簧 chassis spring四分之一椭圆形弹簧 quarter elliptic spring半椭圆形弹簧 half-elliptic spring(semi-elliptic spring) 四分之三椭圆形弹簧 three quarter elliptic spring全椭圆形弹簧 full elliptic spring悬臂弹簧 cantilever spring簧上质量 sprung weight簧下质量 unsprung weight垫上弹簧载荷量 spring capacity at pad地面弹簧载荷量 spring capacity at ground弹簧静挠度 spring static deflection弹簧跳动间隙 bump clearance of spring弹簧中心距 distance between spring centers减振器 shock absorber筒式减振器 telescopic shock absorber油压缓冲器 hydraulic buffer负荷调平式减振器 load -levelling shock absorber液压减振器 dydraulic shock absorber可调减振器 adjustable shock absorber摇臂式减振器 lever type shock absorber磨擦式减振器 frictional shock absorber充气减振器 gas-filled shock absorber动力减振器 dynamic shock absorber减振器卸荷阀 shock absorber relief valve减振器进油阀 shock absorber intake valve减振器示功图 damper indicator diagram减振器液 damper fluid横向稳定器 stabilizer anti—roll bar滑动座 sliding seat滑板 sliding plate弹簧架 spring bracket弹簧主片 spring leaf钢板弹簧吊耳 leaf spring shackle钢板弹簧衬套 leaf spring bushing钢板弹簧销 leaf spring pin弹簧卷耳 spring eyeU型螺栓 U bolt钢板弹簧中心螺栓 leaf spring center bolt橡胶衬套 rubber bushing缓冲块 buffer stopper限位块 limiting stopper平衡轴 trunnion shaft平衡轴支座 trunnion base臂轴 arm shaft平横臂 equalizer螺纹衬套 screw bushing（车身）高度阀 levelling valve车架 auxiliary tank整体车架 unitized frame上弯式梁架 upswept frame (kick up frame）短型车架 stub frame发动机支架 engine mounting半径杆 radius rod平衡杆 stabilizer bar制动反应杆 brake reaction rod分开式车身和车架 separated body and frame上海大众：帕萨特领驭悬架：前：四连杆独立式/ 后：纵向摆臂式制动：前通风盘式/后实心盘式，带前轮刹车片磨损过度报警装置,带贯通式双膜片（8+9英寸）真空刹车助力器东风雪铁龙:富康悬架:前：麦克弗逊独立式/后：连杆式独立悬架制动:前盘后鼓一汽大众：捷达悬架：前：麦克弗逊式单横臂/后：纵向拖臂式单纵臂制动：前盘后鼓海南马自达：福美来323悬架：前:麦克弗逊式独立悬架/后：TTL双天梯多连杆式独立悬架制动：通风盘/盘式北京现代：伊兰特悬架：前：麦克弗逊式/后：复合扭转梁式制动：前后盘式上汽通用：凯越悬架：Twin—Link四轮独立式悬架制动：前后轮盘式制动，四轮ABS+EBD东风:皮卡EQ1021H15Q悬架：前：双横臂式扭杆弹簧独立悬架/后:钢板弹簧制动：MABS防抱死装置、液压制动系统，管路采用H型布置厦门金龙：金凤凰悬架:6气囊悬架制动：鼓式双回路气制动储能弹簧驻车制动昌河铃木：昌铃王悬架:前：独立麦克佛逊式/后:非独立单纵摆臂式制动：前盘后鼓江铃汽车：陆风悬架：前：不等长双横臂扭杆弹簧独立悬架/后：纵置变截面少片簧制动:液压双管路，真空助力，前盘后鼓式制动器，带制动力比例阀独立悬架的左右车轮不是用整体车桥相连接,而是通过悬架分别与车架（或车身）相连，每侧车轮可独立下下运动.轿车和载重量1t以下的货车前悬架广为采用，轿车后悬架上采用也在增加。

汽车悬架（suspension）专业英语词汇螺纹衬套screw bushing螺旋弹簧coil spring(helicalspring)麦弗逊式MacPherson type膜式空气弹簧diaphragm typeair spring磨擦式减振器frictional shock absorber囊式空气弹簧bellow type air spring扭矩套管torque tube扭矩套管式torque tube drive type平横臂equalizer平衡杆stabilizer bar平衡悬架equalizing type of suspension平衡轴trunnion shaft平衡轴支座trunnion base全椭圆形弹簧full elliptic spring三点悬架three-point suspension上控制臂upper control arm上弯式梁架upswept frame(kick up frame)上悬架臂upper suspension arm上置板簧式over slung type双横臂式double-wishbone type双横臂式double with-bone arm type双气室油气弹簧double chamber hydragas spring 双纵臂式double trailing arm type双纵臂式double-trailing arm type四点悬架four-point suspension四分之三椭圆形弹簧three quarter elliptic spring 四分之一椭圆形弹簧quarter elliptic spring四连杆式four link type筒式减振器telescopic shock absorber下控制臂lower control arm下置板簧式under slung type限位块limiting stopper橡胶衬套rubber bushing橡胶弹簧rubber spring type橡胶弹簧式rubber spring type橡胶液体弹簧式hydro-rubber spring type斜臂oblique arm悬臂弹簧cantilever spring悬架suspension悬架臂suspension arm悬架系suspension system压杆strut bar摇臂式减振器lever type shock absorber液体弹簧hydraulic spring液体弹簧hydraulic spring液体弹簧式hydraulic spring type液压减振器dydraulic shock absorber油气弹簧hydro-pneumatic spring type油气弹簧式hydro-pneumatic spring type油压缓冲器hydraulic buffer整体车架unitized frame支撑杆strut bar支撑梁support beam制动反应杆brake reaction rod烛式sliding pillar type纵臂trailing arm纵向钢板弹簧longitudinal leaf spring纵向推力杆longitudinal rod纵置板簧式parallel leaf spring type组合式悬架combination suspension（车身）高度阀levelling valveU型螺栓U bolt半径杆radius rod半椭圆形弹簧half-elliptic spring(semi-elliptic spring)臂轴arm shaft变截面弹簧tapered spring部件assembly and parts车架auxiliary tank充气减振器gas-filled shock absorber单横臂式singe trailing arm type单横臂式single transverse arm type单片式钢板弹簧single leaf spring单气室油气弹簧single chamber hydragas spring 单斜臂式single oblique arm type弹簧架spring bracket弹簧静挠度spring static deflection弹簧卷耳spring eye弹簧跳动间隙bump clearance of spring弹簧中心距distance between spring centers弹簧主片spring leaf底盘弹簧chassis spring地面弹簧载荷量spring capacity at ground第迪安式De Dion type垫上弹簧载荷量spring capacity at pad动力减振器dynamic shock absorber独立悬架independent suspension短型车架stub frame多片式钢板弹簧muotileaved spring发动机支架engine mounting非独立悬架rigid axle suspension非对称钢板弹簧unsymmetrical leaf spring分开式车身和车架separated body and frame负荷调平式减振器load-levelling shock absorber 副钢板弹簧auxiliary spring钢板弹簧leaf spring(laminated spring)钢板弹簧衬套leaf spring bushing钢板弹簧吊耳leaf spring shackle钢板弹簧销leaf spring pin钢板弹簧中心螺栓leaf spring center bolt横臂transverse arm横向推力杆lateral rod横向稳定器stabilizer anti-roll bar横置板簧式transversal leaf spring type滑板sliding plate滑动座sliding seat缓冲块buffer stopper簧上质量sprung weight簧下质量unsprung weight减振器shock absorber减振器进油阀shock absorber intake valve 减振器示功图damper indicator diagram 减振器卸荷阀shock absorber relief valve 减振器液damper fluid金属弹簧式metal spring type可变刚度悬架variable rate suspension可调减振器adjustable shock absorber空气弹簧air spring空气弹簧式air spring type控制臂control arm拉杆tension rod。

附录AThe automotive vehicle suspension system frame (or Unibody) and axle (or wheel) power transmission connection between all devices in general. Its function is to act on the road wheels on the vertical force (support force), the vertical reaction force (traction and braking) and lateral reaction force and the torque reaction force caused by the transfer to the frame (or Unibody) on, in order to ensure the normal running car. Therefore, the suspension system performance and quality performance for the vehicle plays an important role. This paper suspension systems for passenger cars and trucks in the widely used leaf spring design calculation method for the in-depth analysis and research.The article on the current variety of automotive leaf spring design calculation method of intensive analysis and research, summed up the characteristics of various calculation methods, limitations and application. Automotive leaf spring from the elastic component in addition to the role, but also and play the guiding role, and multi-chip friction between the spring damping system also played. As the leaf spring structure is simple, use and maintenance, and easy maintenance, long leaf springs are widely used in the car. Usually the new car design, according to the layout of a given space vehicle, axle load full load minus the estimated quality of non-sprung mass, obtained in each pair of spring bearing on the quality. Generally before the rear axle, wheels, brake drums and steering knuckle, transmission shaft, steering assembly, such as non-vertical rod sprung mass. If the layout of the axle above the leaf spring, spring 3 / 4 the quality of the non-sprung mass, the next set spring, 1 / 4 non-sprung mass spring mass models based on different requirements, general arrangement is given by the straight length of spring control size.In the arrangement possible, try to increase the length of the spring, mainly to consider the following reasons. As the spring stiffness and is inversely proportional to the cube of the length of the spring, so from the perspective of improving vehicle ride comfort, hope springs length longer good. In the spring stiffness of the same case, the long wheel up and down in the spring, the spring from the two ears changes the volume is relatively small, the front suspension, the caster angle change is small, in favor of auto driving stability. Increase the length of the spring can reduce stress andstress amplitude spring working to improve spring life. Can be used to increase the length of the spring reed thick spring, thereby reducing the number of springs and spring reed thick volume ear piece to improve the strength of the main vehicle sprung mass vibration system with quality components to evaluate the natural frequency of vehicle ride comfort important parameters. Suspension design based on vehicle ride comfort requirements, should be given an empty car, fully loaded, front and rear suspension frequency range. If you know the frequency, you can find the suspension static deflection. Select the suspension static deflection, the hope after the suspension static deflection is less than the front suspension static deflection, and the best value close to two vehicles in order to prevent uneven roads often hit the buffer block, suspension design must be given adequate deflection value. Suspension dynamic deflection and car usage and the value of the static deflection due to ride height, suspension travel and dynamic properties of steel spring guide are all fully loaded car with a high arc, and therefore the arc spring loaded high-value should be based on vehicle and suspension performance requirements are given the appropriate value. Some vehicles get good handling and stability, full arc high negative value.附录B汽车悬架系统是汽车车架(或承载式车身)与车桥(或车轮)之间的一切传力连接装置的总称。

附录附录ABasic Parts and Types of the Suspension and Steering Systems Suspension SystemIf a vehicle's axles were bolted directly to its frame or body, every rough spot in the road would transmit a jarring force throughout the vehicle. Riding would be uncomfortable, and handling at freeway speeds would be impossible. The fact that the modern vehicle rides and handles well is a direct result of a suspension system.Even though the tires and wheels must follow the road contour, the body should be influenced as little as possible [1]. The purpose of any suspension system is to allow the body of the vehicle to travel forward with a minimum amount of up-and-down movement. The suspension should also permit the vehicle to make turns without excessive body roll or tire skidding.Suspension System ComponentsVehicle FrameA vehicle's frame or body must form a rigid structural foundation and provide solid anchorage points for the suspension system. There are two types of vehicle construction in common use today: body-over-frame construction, which uses a separate steel frame to which the body is bolted at various points and unibody construction, in which the body sections serve as structural members. Unibody construction is the most common, but body-over-frame construction is still used on pickup trucks and large cars.SpringsThe springs are the most obvious part of the suspension system. Every vehicle has a spring of some kind between the frame or body and the axles. There are three types of springs in general use today: leaf spring, coil spring, and torsion bar. Two different types of springs can be used on one vehicle. Air springs were once used in place of the other types of springs, but are now obsolete. Many modern vehicles have air-operated suspensions, but they are used to supplement the springs.Shock AbsorbersWhen the vehicle is traveling forward on a level surface and the wheels strike a bump, the spring is rapidly compressed (coil springs) or twisted (leaf springsand torsion bars). The spring will attempt to return to its normal loaded length. In so doing, it will rebound, causing the body of the vehicle to be lifted. Since the spring has stored energy, it will rebound past its normal length. The upward movement of the vehicle also assists in rebounding past the spring's normal length.The weight of the vehicle then pushes the spring down after the spring rebounds. The weight of the vehicle will push the spring down, but since the vehicle is traveling downward, the energy built up by the descending body will push the spring below its normal loaded height. This causes the spring to rebound again. This process, called spring oscillation, gradually diminishes until the vehicle is finally still. Spring oscillation can affect handling and ride quality and must be controlled.Air Shock AbsorbersSome suspension systems incorporate two adjustable air shock absorbers that are attached to the rear suspension and connected to an air valve with flexible tubing.Air operated shock absorbers have hydraulic dampening systems which operate in the same manner as those on conventional shocks. In addition, they contain a sealed air chamber, which is acted on by pressure from a height control sensor. Varying the pressure to the air chamber causes the air shock to increase or decrease its length or operating range.Air pressure is delivered to the air shocks through plastic tubing. The tubing connects the shocks to an air valve. Air pressure for raising the shocks is generally obtained from an outside source, such as a service station compressor, and is admitted through the air valve. To deplete the shocks of unwanted air (lower vehicle curb height), the air valve core is depressed, allowing air to escape.Control ArmsAll vehicles have either control arms or struts to keep the wheel assembly in the proper position. The control arms and struts allow the wheel to move up and down while preventing it from moving in any other direction. The wheel will tend to move in undesirable directions whenever the vehicle is accelerated, braked, or turned. Vehicle suspensions may have control arms only or a combination of control arms and struts.Types of the SuspensionFront Suspension SystemsAlmost all modern front suspension systems are independent. With anindependent suspension, each front wheel is free to move up and down with a minimum effect on the other wheel. In an independent suspension system, there is also far less twisting motion imposed on the frame than in a system with a solid axle. Nevertheless, a few off-road, four wheel drive vehicles and large trucks continue to use a solid axle front suspension. The two major types of independent front suspension are the conventional front suspension and the MacPherson strut front suspension.Conventional Front Suspension In the conventional front suspension system, one or two control arms are used at each wheel. In most systems, the coil springs are mounted between the vehicle's frame and the lower control arm. In older systems, coil springs are mounted between the upper control arm and vehicle body. In a torsion bar front suspension system, the lower arm moves upward, it twists the torsion bar.Coil Spring Front Suspension Fig.11-1 shows a typical independent front suspension that uses rubber bushing control arm pivots. The top of the coil spring rests in a cup-like spot against the frame (unshown). The bottom of the coil spring is supported by a pad on the lower control arm. The top of each shock absorber is fastened to the frame; the bottom is attached to the lower control arm.Torsion Bar Front Suspension A torsion bar is located on each side of the frame in the front of the vehicle. The lower control arm is attached to the free end of the torsion bar. When the wheel is driven upward, the lower control arm moves upward, twisting the long spring steel bar.Macpherson Strut Front Suspension Most modern vehicles, especially those with front-wheel drive, use the MacPherson strut front suspension systems, Fig.11-2. Note that the MacPherson strut contains a coil spring, which is mounted on top of the heavy strut-and-pedestal assembly. The entire MacPherson strut assembly is attached to the steering knuckle at the lower part of the pedestal. The bottom of the MacPherson strut assembly is attached to the single control arm through a ball joint.The entire strut assembly turns when the wheel is turned. A bearing or thrust plate at the top of the strut assembly allows relative movement between the assembly and the vehicle body. The ball joint allows the strut assembly to turn in relation to the control arm. The strut contains a damper, which operates in the same manner as a conventional shock absorber. Most damper assemblies have a protective cover that keeps dirt and water away from the damper piston rod.The advantage of the MacPherson strut is its compact design, which allows more room for service on small car bodies.Solid Axle Front Suspension The use of the solid axle front suspension (or dependent suspension) is generally confined to trucks and off-road vehicles. This system uses a solid steel dead.Rear Suspension SystemsRear suspensions on vehicles with a solid rear axle housing generally utilize coil springs or leaf springs. When the vehicle has an independent rear suspension system, coil springs, MacPherson struts, a single transverse leaf spring, or even torsion bars can be used.Steering SystemThe steering system is designed to allow the driver to move the front wheels to the right or left with a minimum of effort and without excessive movement of the steering wheel. Although the driver can move the wheels easily, road shocks are not transmitted to the driver. This absence of road shock transfer is referred to as the nonreversible feature of steering systems.The basic steering system can be divided into three main assemblies:The spindle and steering arm assemblies.The linkage assembly connecting the steering arms and steering gear.The steering wheel, steering shaft, and steering gear assembly.Steering GearThe steering gear is designed to multiply the driver's turning torque so the front wheels may be turned easily. When the parallelogram linkage is used, the torque developed by the driver is multiplied through gears and is then transmitted to the wheel spindle assemblies through the linkage. On the rack-and-pinion steering system, the steering shaft is connected directly to the pinion shaft. Turning the pinion moves the rack section, witch moves the linkage. Late-model vehicles use either manual steering gears or power steering gears.There are three types of the steering gears in use: recirculating ball steering gear, worm-and-roller steering gear and rack-and-pinion steering gear.Power SteeringPower steering is designed to reduce the effort needed to turn the steering wheel by utilizing hydraulic pressure to bolster (strengthen) the normal torque developed bythe steering gear. Power steering systems should ease steering wheel manipulation and, at the same time, offer enough resistance so that the driver can retain some road feel. Power steering is used with both conventional and rack-and-pinion systems (Fig.11-3).The self-contained steering gear contains the control valve mechanism, the power piston, and the gears. Pressure developed by the unit is applied to the pitman shaftThe power rack-and-pinion steering system also uses a rotary control valve that directs the hydraulic fluid from the pump to either side of the rack piston. An overall view of this setup is shown in Figure 11-3. Steering wheel motion is transferred to the pinion. From there, it is sent through the pinion teeth, which are in mesh with the rack teeth. The integral rack piston, which is connected to the rack, changes hydraulic pressure to a linear force (back and forth movement in a straight line). This, in turn, moves the rack in a right or left direction. The force is transmitted by the inner and outer tie rods to the steering knuckles, which, in turn, move the wheels.附录B悬架与转向系统悬架与转向系统的基本组成与类型1.悬架系统如果将一辆汽车的车桥直接固定到车架或车身上，道路上的每个凹凸不平的点都会将一个冲击力传递给车辆。

汽车悬架原理外文文献翻译(含：英文原文及中文译文)文献出处：Journal of Biomechanics, 2013, 4(5):30-39.英文原文The rinciple of Car SuspensionsWilliam HarrisUniversity of MichiganWhen people think of automobile performance, they normally think of horsepower, torque and zero-to-60 acceleration. But all of the power generated by a piston engine is useless if the driver can't control the car. That's why automobile engineers turned their attention to the suspension system almost as soon as they had mastered the four-stroke internal combustion engine.The job of a car suspension is to maximize the friction between the tires and the road surface, to provide steering stability with good handling and to ensure the comfort of the passengers. In this article, we'll explore how car suspensions work, how they've evolved over the years and where the design of suspensions is headed in the future.1.Vehicle DynamicsIf a road were perfectly flat, with no irregularities, suspensions wouldn't be necessary. But roads are far from flat. Even freshly paved highways have subtle imperfections that can interact with the wheels of acar. It's these imperfections that apply forces to the wheels. According to Newton's laws of motion, all forces have both magnitude and direction. A bump in the road causes the wheel to move up and down perpendicular to the road surface. The magnitude, of course, depends on whether the wheel is striking a giant bump or a tiny speck. Either way, the car wheel experiences a vertical acceleration as it passes over an imperfection. Without an intervening structure, all of wheel's vertical energy is transferred to the frame, which moves in the same direction. In such a situation, the wheels can lose contact with the road completely. Then, under the downward force of gravity, the wheels can slam back into the road surface. What you need is a system that will absorb the energy of the vertically accelerated wheel, allowing the frame and body to ride undisturbed while the wheels follow bumps in the road.The study of the forces at work on a moving car is called vehicle dynamics, and you need to understand some of these concepts in order to appreciate why a suspension is necessary in the first place. Most automobile engineers consider the dynamics of a moving car from two perspectives:1)Ride - a car's ability to smooth out a bumpy road2)Handling - a car's ability to safely accelerate, brake and cornerThese two characteristics can be further described in three important principles - road isolation, road holding and cornering. The table belowdescribes these principles and how engineers attempt to solve the challenges unique to each.A car's suspension, with its various components, provides all of the solutions described.2.The Chassis SystemThe suspension of a car is actually part of the chassis, which comprises all of the important systems located beneath the car's body.These systems include:1) T he frame - structural, load-carrying component that supports the car's engine and body, which are in turn supported by the suspension2) T he suspension system - setup that supports weight, absorbs and dampens shock and helps maintain tire contact3) T he steering system - mechanism that enables the driver to guide and direct the vehicle4) T he tires and wheels - components that make vehicle motion possible by way of grip and/or friction with the roadSo the suspension is just one of the major systems in any vehicle.With this big-picture overview in mind, it's time to look at the three fundamental components of any suspension: springs, dampers and anti-sway bars.3.SpringsToday's springing systems are based on one of four basic designs:1) Coil springs - This is the most common type of spring and is, in essence, a heavy-duty torsion bar coiled around an axis. Coil springs compress and expand to absorb the motion of the wheels.2) Leaf springs - This type of spring consists of several layers of metal (called "leaves") bound together to act as a single unit. Leaf springs were first used on horse-drawn carriages and were found on most American automobiles until 1985. They are still used today on most trucks and heavy-duty vehicles.3) Torsion bars - Torsion bars use the twisting properties of a steel bar to provide coil-spring-like performance. This is how they work: One end of a bar is anchored to the vehicle frame. The other end is attached to a wishbone, which acts like a lever that moves perpendicular to the torsion bar. When the wheel hits a bump, vertical motion is transferred to the wishbone and then, through the levering action, to the torsion bar. Thetorsion bar then twists along its axis to provide the spring force. European carmakers used this system extensively, as did Packard and Chrysler in the United States, through the 1950s and 1960s. 4) Air springs - Air springs, which consist of a cylindrical chamber of air positioned between the wheel and the car's body, use the compressive qualities of air to absorb wheel vibrations. The concept is actually more than a century old and could be found on horse-drawn buggies. Air springs from this era were made from air-filled, leather diaphragms, much like a bellows; they were replaced with molded-rubber air springs in the 1930s.Based on where springs are located on a car -- i.e., between the wheels and the frame -- engineers often find it convenient to talk about the sprung mass and the unsprung mass.4.Sprung and Unsprung MassThe sprung mass is the mass of the vehicle supported on the springs, while the unsprung mass is loosely defined as the mass between the road and the suspension springs. The stiffness of the springs affects how the sprung mass responds while the car is being driven. Loosely sprung cars, such as luxury cars (think Lincoln Town Car), can swallow bumps and provide a super-smooth ride; however, such a car is prone to dive and squat during braking and acceleration and tends to experience body sway or roll during cornering. Tightly sprung cars, such as sports cars (think Mazda Miata), are less forgiving on bumpy roads, but they minimizebody motion well, which means they can be driven aggressively, even around corners.So, while springs by themselves seem like simple devices, designing and implementing them on a car to balance passenger comfort with handling is a complex task. And to make matters more complex, springs alone can't provide a perfectly smooth ride. Why? Because springs are great at absorbing energy, but not so good at dissipating it. Other structures, known as dampers, are required to do this.5.Shock AbsorbersUnless a dampening structure is present, a car spring will extend and release the energy it absorbs from a bump at an uncontrolled rate. The spring will continue to bounce at its natural frequency until all of theenergy originally put into it is used up. A suspensionbuilt on springs alone would make for an extremely bouncy ride and, depending on the terrain, an uncontrollable car.Enter the shock absorber, or snubber, a device that controls unwanted spring motion through a process known as dampening. Shock absorbers slow down and reduce the magnitude of vibratory motions by turning the kinetic energy of suspension movement into heat energy that can be dissipated through hydraulic fluid. To understand how this works, it's best to look inside a shock absorber to see its structure and function.A shock absorber is basically an oil pump placed between the frame of the car and the wheels. The upper mount of the shock connects to the frame (i.e., the sprung weight), while the lower mount connects to the axle, near the wheel (i.e., the unsprung weight). In a twin-tube design, one of the most common types of shock absorbers, the upper mount is connected to a piston rod, which in turn is connected to a piston, which in turn sits in a tube filled with hydraulic fluid. The inner tube is known as the pressure tube, and the outer tube is known as the reserve tube. The reserve tube stores excess hydraulic fluid.When the car wheel encounters a bump in the road and causes the spring to coil and uncoil, the energy of the spring is transferred to the shock absorber through the upper mount, down through the piston rod and into the piston. Orifices perforate the piston and allow fluid to leakthrough as the piston moves up and down in the pressure tube. Because the orifices are relatively tiny, only a small amount of fluid, under great pressure, passes through. This slows down the piston, which in turn slows down the spring.Shock absorbers work in two cycles -- the compression cycle and the extension cycle. The compression cycle occurs as the piston moves downward, compressing the hydraulic fluid in the chamber below the piston. The extension cycle occurs as the piston moves toward the top of the pressure tube, compressing the fluid in the chamber above the piston.A typical car or light truck will have more resistance during its extension cycle than its compression cycle. With that in mind, the compression cycle controls the motion of the vehicle's unsprung weight, while extension controls the heavier, sprung weight.All modern shock absorbers are velocity-sensitive -- the faster the suspension moves, the more resistance the shock absorber provides. This enables shocks to adjust to road conditions and to control all of the unwanted motions that can occur in a moving vehicle, including bounce, sway, brake dive and acceleration squat.6.Struts and Anti-sway BarsAnother common dampening structure is the strut -- basically a shock absorber mounted inside a coil spring. Struts perform two jobs: They provide a dampening function like shock absorbers, and they provide structural support for the vehicle suspension. That means struts deliver a bit more than shock absorbers, which don't support vehicle weight -- they only control the speed at which weight is transferred in a car, not the weight itself.Because shocks and struts have so much to do with the handling of a car, they can be considered critical safety features. Worn shocks and struts can allow excessive vehicle-weight transfer from side to side and front to back. This reduces the tire's ability to grip the road, as well as handling and braking performance.7.Anti-sway BarsAnti-sway bars (also known as anti-roll bars) are used along with shock absorbers or struts to give a moving automobile additional stability. An anti-sway bar is a metal rod that spans the entire axle and effectively joins each side of the suspension together.When the suspension at one wheel moves up and down, the anti-sway bar transfers movement to the other wheel. This creates a more level ride and reduces vehicle sway. In particular, it combats the roll of a car on its suspension as it corners. For this reason, almost all cars today are fitted with anti-sway bars as standard equipment, although if they're not, kits make it easy to install the bars at any time.8.The Future of Car SuspensionsWhile there have been enhancements and improvements to both springs and shock absorbers, the basic design of car suspensions has not undergone a significant evolution over the years. But all of that's about to change with the introduction of a brand-new suspension design conceived by Bose -- the same Bose known for its innovations in acoustic technologies. Some experts are going so far as to say that the Bose suspension is the biggest advance in automobile suspensions since the introduction of an all-independent design.How does it work? The Bose system uses a linear electromagnetic motor (LEM) at each wheel in lieu of a conventional shock-and-spring setup. Amplifiers provide electricity to the motors in such a way that theirpower is regenerated with each compression of the system. The main benefit of the motors is that they are not limited by the inertia inherent in conventional fluid-based dampers. As a result, an LEM can extend and compress at a much greater speed, virtually eliminating all vibrations in the passenger cabin. The wheel's motion can be so finely controlled that the body of the car remains level regardless of what's happening at the wheel. The LEM can also counteract the body motion of the car while accelerating, braking and cornering, giving the driver a greater sense of control.Unfortunately, this paradigm-shifting suspension won't be available until 2009, when it will be offered on one or more high-end luxury cars. Until then, drivers will have to rely on the tried-and-true suspension methods that have smoothed out bumpy rides for centuries.中文译文汽车悬架原理研究作者：威廉·哈里斯密歇根大学当人们想到汽车性能时，他们通常会联想到马力，扭矩和零到60码加速度。

中英文文献翻译—悬架与转向系统悬架与转向系统的基本组成与类型附录附录ABasic Parts and Types of the Suspension and Steering Systems Suspension SystemIf a vehicle's axles were bolted directly to its frame or body, every rough spot in the road would transmit a jarring force throughout the vehicle. Riding would be uncomfortable, and handling at freeway speeds would be impossible. The fact that the modern vehicle rides and handles well is a direct result of a suspension system.Even though the tires and wheels must follow the road contour, the body should be influenced as little as possible [1]. The purpose of any suspension system is to allow the body of the vehicle to travel forward with a minimum amount of up-and-down movement. The suspension should also permit the vehicle to make turns without excessive body roll or tire skidding.Suspension System ComponentsVehicle FrameA vehicle's frame or body must form a rigid structural foundation and provide solid anchorage points for the suspension system. There are two types of vehicle construction in common use today: body-over-frame construction, which uses a separate steel frame to which the body is bolted at various points and unibody construction, in which the body sections serve as structural members. Unibody construction is the most common, but body-over-frame construction is still used on pickup trucks and large cars.SpringsThe springs are the most obvious part of the suspension system. Every vehicle has a spring of some kind between the frame or body and the axles. There are three types of springs in general use today: leaf spring, coil spring, and torsion bar. Two different types of springs can be used on one vehicle. Air springs were once used in place of the other types of springs, but are now obsolete. Many modern vehicles have air-operated suspensions, but they are used to supplement the springs.Shock AbsorbersWhen the vehicle is traveling forward on a level surface and the wheels strike a bump, the spring is rapidly compressed (coil springs) or twisted (leaf springsand torsion bars). The spring will attempt to return to its normal loaded length. In so doing, it will rebound, causing the body of the vehicle to be lifted. Since the spring has stored energy, it will rebound past its normal length. The upward movement of the vehicle also assists in rebounding past the spring's normal length.The weight of the vehicle then pushes the spring down after the spring rebounds. The weight of the vehicle will push the spring down, but since the vehicle is traveling downward, the energy built up by the descending body will push the spring below its normal loaded height. This causes the spring to rebound again. This process, called spring oscillation, gradually diminishes until the vehicle is finally still. Spring oscillation can affect handling and ride quality and must be controlled.Air Shock AbsorbersSome suspension systems incorporate two adjustable air shock absorbers that are attached to the rear suspension andconnected to an air valve with flexible tubing.Air operated shock absorbers have hydraulic dampening systems which operate in the same manner as those on conventional shocks. In addition, they contain a sealed air chamber, which is acted on by pressure from a height control sensor. Varying the pressure to the air chamber causes the air shock to increase or decrease its length or operating range.Air pressure is delivered to the air shocks through plastic tubing. The tubing connects the shocks to an air valve. Air pressure for raising the shocks is generally obtained from an outside source, such as a service station compressor, and is admitted through the air valve. To deplete the shocks of unwanted air (lower vehicle curb height), the air valve core is depressed, allowing air to escape.Control ArmsAll vehicles have either control arms or struts to keep the wheel assembly in the proper position. The control arms and struts allow the wheel to move up and down while preventing it from moving in any other direction. The wheel will tend to move in undesirable directions whenever the vehicle is accelerated, braked, or turned. Vehicle suspensions may have control arms only or a combination of control arms and struts.Types of the SuspensionFront Suspension SystemsAlmost all modern front suspension systems are independent. With anindependent suspension, each front wheel is free to move up and down with a minimum effect on the other wheel. In an independent suspension system, there is also far less twisting motion imposed on the frame than in a system with a solid axle.Nevertheless, a few off-road, four wheel drive vehicles and large trucks continue to use a solid axle front suspension. The two major types of independent front suspension are the conventional front suspension and the MacPherson strut front suspension.Conventional Front Suspension In the conventional front suspension system, one or two control arms are used at each wheel. In most systems, the coil springs are mounted between the vehicle's frame and the lower control arm. In older systems, coil springs are mounted between the upper control arm and vehicle body. In a torsion bar front suspension system, the lower arm moves upward, it twists the torsion bar.Coil Spring Front Suspension Fig.11-1 shows a typical independent front suspension that uses rubber bushing control arm pivots. The top of the coil spring rests in a cup-like spot against the frame (unshown). The bottom of the coil spring is supported by a pad on the lower control arm. The top of each shock absorber is fastened to the frame; the bottom is attached to the lower control arm.Torsion Bar Front Suspension A torsion bar is located on each side of the frame in the front of the vehicle. The lower control arm is attached to the free end of the torsion bar. When the wheel is driven upward, the lower control arm moves upward, twisting the long spring steel bar.Macpherson Strut Front Suspension Most modern vehicles, especially those with front-wheel drive, use the MacPherson strut front suspension systems, Fig.11-2. Note that the MacPherson strut contains a coil spring, which is mounted on top of the heavy strut-and-pedestal assembly. The entire MacPherson strut assembly is attached to the steering knuckle at the lower part ofthe pedestal. The bottom of the MacPherson strut assembly is attached to the single control arm through a ball joint.The entire strut assembly turns when the wheel is turned. A bearing or thrust plate at the top of the strut assembly allows relative movement between the assembly and the vehicle body. The ball joint allows the strut assembly to turn in relation to the control arm. The strut contains a damper, which operates in the same manner as a conventional shock absorber. Most damper assemblies have a protective cover that keeps dirt and water away from the damper piston rod.The advantage of the MacPherson strut is its compact design, which allows more room for service on small car bodies.Solid Axle Front Suspension The use of the solid axle front suspension (or dependent suspension) is generally confined to trucks and off-road vehicles. This system uses a solid steel dead.Rear Suspension SystemsRear suspensions on vehicles with a solid rear axle housing generally utilize coil springs or leaf springs. When the vehicle has an independent rear suspension system, coil springs, MacPherson struts, a single transverse leaf spring, or even torsion bars can be used.Steering SystemThe steering system is designed to allow the driver to move the front wheels to the right or left with a minimum of effort and without excessive movement of the steering wheel. Although the driver can move the wheels easily, road shocks are not transmitted to the driver. This absence of road shock transfer is referred to as the nonreversible feature of steering systems.The basic steering system can be divided into three main assemblies:The spindle and steering arm assemblies.The linkage assembly connecting the steering arms and steering gear.The steering wheel, steering shaft, and steering gear assembly.Steering GearThe steering gear is designed to multiply the driver's turning torque so the front wheels may be turned easily. When the parallelogram linkage is used, the torque developed by the driver is multiplied through gears and is then transmitted to the wheel spindle assemblies through the linkage. On the rack-and-pinion steering system, the steering shaft is connected directly to the pinion shaft. Turning the pinion moves the rack section, witch moves the linkage. Late-model vehicles use either manual steering gears or power steering gears.There are three types of the steering gears in use: recirculating ball steering gear, worm-and-roller steering gear and rack-and-pinion steering gear.Power SteeringPower steering is designed to reduce the effort needed to turn the steering wheel by utilizing hydraulic pressure to bolster (strengthen) the normal torque developed bythe steering gear. Power steering systems should ease steering wheel manipulation and, at the same time, offer enough resistance so that the driver can retain some road feel. Power steering is used with both conventional and rack-and-pinion systems (Fig.11-3).The self-contained steering gear contains the control valve mechanism, the power piston, and the gears. Pressure developed by the unit is applied to the pitman shaftThe power rack-and-pinion steering system also uses a rotary control valve that directs the hydraulic fluid from the pump to either side of the rack piston. An overall view of this setup is shown in Figure 11-3. Steering wheel motion is transferred to the pinion. From there, it is sent through the pinion teeth, which are in mesh with the rack teeth. The integral rack piston, which is connected to the rack, changes hydraulic pressure to a linear force (back and forth movement in a straight line). This, in turn, moves the rack in a right or left direction. The force is transmitted by the inner and outer tie rods to the steering knuckles, which, in turn, move the wheels.附录B悬架与转向系统悬架与转向系统的基本组成与类型1.悬架系统如果将一辆汽车的车桥直接固定到车架或车身上，道路上的每个凹凸不平的点都会将一个冲击力传递给车辆。

汽车悬架原理外文文献及翻译(文档含中英文对照即英文原文和中文翻译)The rinciple Of Car SuspensionsBy William HarrisUniversity of MichiganWhen people think of automobile performance, they normally think of horsepower, torque and zero-to-60 acceleration. But all of the power generated by a piston engine is useless if the driver can't control the car. That's why automobile engineers turned their attention to the suspension system almost as soon as they had mastered the four-stroke internal combustion engine.The job of a car suspension is to maximize the friction between the tires and the road surface, to provide steering stability with good handling and to ensure the comfort of the passengers. In this article, we'll explore how car suspensions work, how they've evolved over the years and where the design of suspensions is headed in the future.1.Vehicle DynamicsIf a road were perfectly flat, with no irregularities, suspensions wouldn't be necessary. But roads are far from flat. Even freshly paved highways have subtle imperfections that can interact with the wheels of a car. It's these imperfections that apply forces to the wheels. According to Newton's laws of motion, all forces have both magnitude and direction. A bump in the road causes the wheel to move up and down perpendicular to the road surface. The magnitude, of course, depends on whether the wheel is striking a giant bump or a tiny speck. Either way, the car wheel experiences a vertical acceleration as it passes over an imperfection.Without an intervening structure, all of wheel's vertical energy is transferred to the frame, which moves in the same direction. In such a situation, the wheels can lose contact with the road completely. Then, under the downward force of gravity, the wheels can slam back into the road surface. What you need is a system that will absorb the energy of the vertically accelerated wheel, allowing the frame and body to ride undisturbed while the wheels follow bumps in the road.The study of the forces at work on a moving car is called vehicle dynamics, and you need to understand some of these concepts in order to appreciate why a suspension is necessary in the first place. Most automobile engineers consider the dynamics of a moving car from two perspectives:1)Ride - a car's ability to smooth out a bumpy road2)Handling - a car's ability to safely accelerate, brake and cornerThese two characteristics can be further described in three important principles - road isolation, road holding and cornering. The table below describes these principles and how engineers attempt to solve the challenges unique to each.A car's suspension, with its various components, provides all of the solutions described.2.The Chassis SystemThe suspension of a car is actually part of the chassis, which comprises all of the important systems located beneath the car's body.These systems include:1)T he frame - structural, load-carrying component that supports the car's engine and body, which are in turn supported by the suspension2)T he suspension system - setup that supports weight, absorbs and dampens shock and helps maintain tire contact3)T he steering system - mechanism that enables the driver to guide and direct the vehicle4)T he tires and wheels - components that make vehicle motion possible by way of grip and/or friction with the roadSo the suspension is just one of the major systems in any vehicle.With this big-picture overview in mind, it's time to look at the three fundamental components of any suspension: springs, dampers and anti-sway bars.figure 2-1 Chassis3.SpringsToday's springing systems are based on one of four basic designs:1）Coil springs - This is the most common type of spring and is, in essence, a heavy-duty torsion bar coiled around an axis. Coil springs compress and expand to absorb the motion of the wheels.2）Leaf springs - This type of spring consists of several layers of metal (called "leaves") bound together to act as a single unit. Leaf springs were first used on horse-drawn carriages and were found on most American automobiles until 1985. They are still used today on most trucks and heavy-duty vehicles.3）Torsion bars - Torsion bars use the twisting properties of a steel bar to provide coil-spring-like performance. This is how they work: One end of a bar is anchored to the vehicle frame. The other end is attached to a wishbone, which acts like a lever that moves perpendicular to the torsion bar. When the wheel hits a bump, vertical motion is transferred to the wishbone and then, through the levering action, to the torsion bar. The torsion bar then twists along its axis to provide the spring force. European carmakers used this system extensively, as did Packard and Chrysler in the United States, through the 1950s and 1960s. 4）Air springs - Air springs, which consist of a cylindrical chamber of air positioned between the wheel and the car's body, use the compressive qualities of air to absorb wheel vibrations. The concept is actually more than a century old and could be found on horse-drawn buggies. Air springs from this era were made from air-filled, leather diaphragms, much like a bellows; they were replaced with molded-rubber air springs in the 1930s.Based on where springs are located on a car -- i.e., between the wheels and the frame -- engineers often find it convenient to talk about the sprung mass and the unsprung mass.4.Sprung and Unsprung MassThe sprung mass is the mass of the vehicle supported on the springs, while the unsprung mass is loosely defined as the mass between the road and the suspension springs. The stiffness of the springs affects how the sprung mass responds while the car is being driven. Loosely sprung cars, such as luxury cars (think Lincoln Town Car), can swallow bumps and provide a super-smooth ride; however, such a car is prone to dive and squat during braking and acceleration and tends to experience body sway or roll during cornering. Tightly sprung cars, such as sports cars (think Mazda Miata), are less forgiving on bumpy roads, but they minimize body motion well, which means they can be driven aggressively, even around corners.So, while springs by themselves seem like simple devices, designing and implementing them on a car to balance passenger comfort with handling is a complex task. And to make matters more complex, springs alone can't provide a perfectly smooth ride. Why? Because springs are great at absorbing energy, but not so good at dissipating it. Other structures, known as dampers, are required to do this.5.Shock AbsorbersUnless a dampening structure is present, a car spring will extend and release the energy it absorbs from a bump at an uncontrolled rate. The spring will continue to bounce at its natural frequency until all of the energy originally put into it is used up. A suspension built on springs alone would make for an extremely bouncy ride and, depending on the terrain, an uncontrollable car.Enter the shock absorber, or snubber, a device that controls unwanted spring motion through a process known as dampening. Shock absorbers slow down and reduce the magnitude of vibratory motions by turning the kinetic energy of suspension movement into heat energy that can be dissipated through hydraulic fluid. To understand how this works, it's best to look inside a shock absorber to see its structure and function.A shock absorber is basically an oil pump placed between the frame of the car and the wheels. The upper mount of the shock connects to the frame (i.e., the sprung weight), while the lower mount connects to the axle, near the wheel (i.e., the unsprung weight). In a twin-tube design, one of the most common types of shock absorbers, the upper mount is connected to a piston rod, which in turn is connected to a piston, which in turn sits in a tube filled with hydraulic fluid. The inner tube is known as the pressure tube, and the outer tube is known as the reserve tube. The reserve tube stores excess hydraulic fluid.When the car wheel encounters a bump in the road and causes the spring to coil and uncoil, the energy of the spring is transferred to the shock absorber through the upper mount, down through the piston rod and into the piston. Orifices perforate the piston and allow fluid to leak through as the piston moves up and down in the pressure tube. Because the orifices are relatively tiny, only a small amount of fluid, under great pressure, passes through. This slows down the piston, which in turn slows down the spring.Shock absorbers work in two cycles -- the compression cycle and the extension cycle. The compression cycle occurs as the piston moves downward, compressing the hydraulic fluid in the chamber below the piston. The extension cycle occurs as the piston moves toward the top of the pressure tube, compressing the fluid in the chamber above the piston. A typical car or light truck will have more resistance during its extension cycle than its compression cycle. With that in mind, the compression cycle controls the motion of the vehicle's unsprung weight, while extension controls the heavier, sprung weight.All modern shock absorbers are velocity-sensitive -- the faster the suspension moves, the more resistance the shock absorber provides. This enables shocks to adjust to road conditions and to control all of the unwanted motions that can occur in a moving vehicle, including bounce, sway, brake dive and acceleration squat.6.Struts and Anti-sway Barsfigure 6-1 Common strut designAnother common dampening structure is the strut -- basically a shock absorber mounted inside a coil spring. Struts perform two jobs: They provide a dampening function like shock absorbers, and they provide structural support for the vehicle suspension. That means struts deliver a bit more than shock absorbers, which don't support vehicle weight -- they only control the speed at which weight is transferred in a car, not the weight itself.Because shocks and struts have so much to do with the handling of a car, they can be considered critical safety features. Worn shocks and struts can allow excessive vehicle-weight transfer from side to side and front to back. This reduces the tire's ability to grip the road, as well as handling and braking performance.7.Anti-sway BarsAnti-sway bars (also known as anti-roll bars) are used along with shock absorbers or struts to give a moving automobile additional stability. An anti-sway bar is a metal rod that spans the entire axle and effectively joins each side of the suspension together.When the suspension at one wheel moves up and down, the anti-sway bar transfers movement to the other wheel. This creates a more level ride and reduces vehicle sway. Inparticular, it combats the roll of a car on its suspension as it corners. For this reason, almost all cars today are fitted with anti-sway bars as standard equipment, although if they're not, kits make it easy to install the bars at any time.8.The Future of Car SuspensionsWhile there have been enhancements and improvements to both springs and shock absorbers, the basic design of car suspensions has not undergone a significant evolution over the years. But all of that's about to change with the introduction of a brand-new suspension design conceived by Bose -- the same Bose known for its innovations in acoustic technologies. Some experts are going so far as to say that the Bose suspension is the biggest advance in automobile suspensions since the introduction of an all-independent design.How does it work? The Bose system uses a linear electromagnetic motor (LEM) at each wheel in lieu of a conventional shock-and-spring setup. Amplifiers provide electricity to the motors in such a way that their power is regenerated with each compression of the system. The main benefit of the motors is that they are not limited by the inertia inherent in conventional fluid-based dampers. As a result, an LEM can extend and compress at a much greater speed, virtually eliminating all vibrations in the passenger cabin. The wheel's motion can be so finely controlled that the body of the car remains level regardless of what's happening at the wheel. The LEM can also counteract the body motion of the car while accelerating, braking and cornering, giving the driver a greater sense of control.Unfortunately, this paradigm-shifting suspension won't be available until 2009, when it will be offered on one or more high-end luxury cars. Until then, drivers will have to rely on the tried-and-true suspension methods that have smoothed out bumpy rides for centuries.汽车悬架的原理当人们考虑汽车性能的时候，他们通常认为是马力，扭矩和零到60的加速时间。

汽车悬架系统中英文对照外文翻译文献汽车悬架系统中英文对照外文翻译文献(文档含英文原文和中文翻译)汽车悬架现代汽车中的悬架系统有两种，一种是从动悬架，另一种是主动悬架。

从动悬架即传统式的悬架，是由弹簧、减振器（减振筒）、导向机构等组成，它的功能是减弱路面传给车身的冲击力，衰减由冲击力而引起的承载系统的振动。

其中弹簧主要起减缓冲击力的作用，减振器的主要作用是衰减振动。

由于这种悬架是由外力驱动而起作用的，所以称为从动悬架。

而主动悬架的控制环节中安装了能够产生抽动的装置，采用一种以力抑力的方式来抑制路面对车身的冲击力及车身的倾斜力。

由于这种悬架能够自行产生作用力，因此称为主动悬架。

主动悬架是近十几年发展起来的，由电脑控制的一种新型悬架，具备三个条件：（1）具有能够产生作用力的动力源；（2）执行元件能够传递这种作用力并能连续工作；（3）具有多种传感器并将有关数据集中到微电脑进行运算并决定控制方式。

因此，主动悬架汇集了力学和电子学的技术知识，是一种比较复杂的高技术装置。

例如装置了主动悬架的法国雪铁龙桑蒂雅，该车悬架系统的中枢是一个微电脑，悬架上有5 种传感器，分别向微电脑传送车速、前轮制动压力、踏动油门踏板的速度、车身垂直方向的振幅及频率、转向盘角度及转向速度等数据。

电脑不断接收这些数据并与预先设定的临界值进行比较，选择相应的悬架状态。

同时，微电脑独立控制每一只车轮上的执行元件，通过控制减振器内油压的变化产生抽动，从而能在任何时候、任何车轮上产生符合要求的悬架运动。

因此，桑蒂雅桥车备有多种驾驶模式选择，驾车者只要扳动位于副仪表板上的“正常”或“运动”按钮，轿车就会自动设置在最佳的悬架状态，以求最好的舒适性能。

另外，主动悬架具有控制车身运动的功能。

当汽车制动或拐弯时的惯性引起弹簧变形时，主动悬架会产生一个与惯力相对抗的力，减少车身位置的变化。

例如德国奔驰2000 款CL 型跑车，当车辆拐弯时悬架传感器会立即检测出车身的倾斜和横向加速度，电脑根据传感器的信息，与预先设定的临界值进行比较计算，立即确定在什么位置上将多大的负载加到悬架上，使车身的倾斜减到最小。

Motor vehicle suspension on the vehicle suspension system is a very important system. Not only does it affect the comfort of the car (ride), but also to other properties such as the adoption, as well as the stability of the attachment have a significant impact on performance, each of the suspension by the elastic components (buffers), body-oriented (from Chuan And stabilizing role), as well as shock absorbers (from the role of shock absorption). However, not all of the suspension must have three components. As long as we can play to the role of the three.Vehicle maintenance for the conservation network 1, flying the classification1. Non-independent suspension: on both sides of the wheel mounted ona total-vehicle-bridge, the train-bridge to fly through the frame and connected. This suspension structure is simple and reliable power-but by two rounds of shock and vibration affecting each other. But also because of the quality of flying non-serious suspension of the poor performance of the buffer, the vibration of a moving car, the greater the impact. The suspension generally used for trucks, buses and a number of other ordinary vehicles. (2) independent suspension: each individual through a set of wheels mounted on the body or suspension of vehicular bridge, the use of off-Axle, in the middle of a fixed frame or body; such wheel on both sides of the suspension by the shock Hubuyingxiang, but due to non-flying than by the quality; buffer with a strong shock absorption capacity, ride comfort. The indicators are better than non-independent suspension, but the complex structure of the suspension, but it also drive axle, steering system has become complicated. The use of such suspension of the following two categories of vehicles. Cars, buses and passenger vehicles. Can be improved ride comfort, and high speed when driving the car to improve stability.Off-road vehicles, military vehicles and mining vehicles. In a bad way and have no say under the circumstances, we can make sure all the wheels on the ground and contacts to enhance stability and driving the car attached, to play a speed of the car.2.Flexible yuan for the type of (1) of the leaf spring: the long-range multi-chip and curvature ranging from the composite plate. After installed at both ends of the natural upward curve. In addition to the leaf spring with a buffer, there is a certain degree of shock absorption, vertical layout also has a force-oriented, non-independent suspension using most of the leaf spring so flexible components, save-oriented devices and shock absorbers, simple structure . (2) of the coil spring: only a cushion for the multi-car independent suspension. In the absence of damping force and mass functions must also be equipped with special shock absorbers and device-oriented. (3) oil and gas spring: a flexible medium as a gas, liquid as a medium-power, which not only has a good buffer capacity, also has a role in shock absorption and at the same time frame of a high degree of regulation may also be applicable to the use of heavy vehicles and buses. (4), torsion bar springs; will be made under the torsion bar springs fixed at one end of the frame, on the other side through the arm and connected to the wheels, and beat at wheel torsion bar the use of reverse deformation played the role of buffer, is suitable for independent The use of suspension.3. the use of shock absorber tube shock absorbers, the use of oil in the small role to cut energy consumption vibration. Shock absorber and the upper body frame or connected with the lower end of the train-bridge connected. Most of the trip can be done and the compression of the dual role of the role of shock absorber.4.device-oriented: the flexibility in the independent suspension components, most of them can only transfer the vertical loads and can not transmit vertical and horizontal, must be a separate device-oriented. As noted, under the arm and vertical, horizontal stabilizer, and so on.5. non-independent suspension: before and after the truckswere non-independent suspension bridge, some vehicles such as buses and cars and so on, after the bridge is also a non-independent suspension. Each car of the sedan chair by hoisting two independent non-vertical arrangement of the composition of the leaf spring. Leaf spring fixed in the middle of the train-bridge, with the front end hinged frame or body, the back-end with the frame or body through the ear hanging hinged or connected to use of skateboards. Top of the frame with a shock absorber then, with the lower end of the next school Axle. The truck rear axle and more without shock absorbers.6. many types of independent suspension, coil spring as the use of flexible components. Torsion bar springs for the independent suspension is also divided into vertical and horizontal torsion torque Cup two-under. Although many of the advantages of an independent suspension, but the car would turn the system, the Department of driving and driving more complicated structure of the bridge.。

汽车车辆专业悬架外文文献翻译、中英文翻译、外文翻译外文文献（二）外文原文Abstract： To improve the suspension performance and steering stability of light vehicles, we built a kinematic simulation model of a whole independent double-wishbone suspension system by using ADAMS software, created random excitations of the test platforms of respectively the left and the right wheels according to actual running conditions of a vehicle, and explored the changing patterns of the kinematic characteristic parameters in the process of suspension motion. The irrationality of the suspension guiding mechanism design was pointed out through simulation and analysis, and the existent problems of the guiding mechanism were optimized and calculated. The results show that all the front-wheel alignment parameters, including the camber, the toe, the caster and the inclination, only slightly change within corresponding allowable ranges in design before and after optimization. The optimization reduces the variation of the wheel-center distance from 47.01 mm to a change of 8.28 mm within the allowable range of -10 mm to 10 mm, promising an improvement of the vehicle steering stability. The optimization also confines the front-wheel sideways slippage to a much smaller change of 2.23 mm; this helps to greatly reduce the wear of tires and assure the straight running stability of the vehicle. Keywords： vehicle suspension; vehicle steering; riding qualities; independent double-wishbone suspension; kinematic characteristic parameter; wheel-center distance; front-wheel sideways slippage1 IntroductionThe function of a suspension system in a vehicle is to transmit all forces and moments exerted on the wheels to the girder frame of the vehicle, smooth the impact passing from the road surface to the vehicle body and damp the impact-caused vibration of the load carrying system. There are many different structures of vehicle suspension, of which the independent double-wishbone suspension is most extensively used. An independent double-wishbone suspension system is usually a group of space RSSR (revolute joint - spherical joint -spherical joint - revolute joint) four-bar linkage mechanisms. Its kinematic relations are complicated, its kinematic visualization is poor, and performance analysis is very difficult. Thus, rational settings of theposition parameters of the guiding mechanism are crucial to assuring good performance of the independent double-wishbone suspension. The kinematiccharacteristics of suspension directly influence the service performance of the vehicle, especially steering stability, ride comfort, turning ease, and tire life.In this paper, we used ADAMS software to build a kinematic analysis model of an independent double-wishbone suspension, and used the model to calculate and optimize the kinematic characteristic parameters of the suspension mechanism. The optimization results are helpful for improving the kinematic performance of suspension.12 Modeling independent double-wishbone suspensionThe performance of a suspension system is reflected by the changes of wheel alignment parameters when the wheels jump. Those changes should be kept within rational ranges to assure the designed vehicle running performance. Considering the symmetry of the left and right wheels of a vehicle, it is appropriate to study only the left or the right half of the suspension system to understand the entire mechanism, excluding the variation of WCD (wheel center distance). We established a model of the left half of an independent double-wishbone suspension system as shown in Figure 1.3 Kinematic simulation analysis of suspension modelConsidering the maximum jump height of the front wheel, we positioned the drives on the translational joints between the ground and the test platform, and imposed random displacement excitations on the wheels to simulate the operating conditions of a vehicle running on an uneven road surface.The measured road-roughness data of the left and right wheels were converted into the relationship between time and road roughness at a certain vehicle speed. The spline function CUBSPL in ADAMS was used to fit and generate displacement-time history curves of excitation. The simulationresults of the suspension system before optimization are illustrated in Figure 2.The camber angle, the toe angle, the caster angle and the inclination angle change only slightly within the corresponding designed ranges with the wheel jumping distance. This indicates an under-steering behavior together with an automatic returnability, good steering stability and safety in arunning process. However, WCD decreases from 1 849.97 mm to 1 896.98 mm and FWSS from 16.48 mm to -6.99 mm, showing remarkable variations of 47.01 mm and 23.47 mm, respectively. Changes so large in WCD and FWSS are adverse to the steering ease and straight-running stability, and cause quick wear, thus reducing tire life.For independent suspensions, the variation of WCD causes side deflectionof tires and then impairs steering stability through the lateral force input. Especially when the right and the left rolling wheels deviate in the same direction, the WCD-caused lateral forces on the right and the left sidescannot be offset and thus make steering unstable. Therefore, WCD variation should be kept minimum, and is required in suspension design to be within the range from -10 mm to 10 mm when wheels jump. It is obvious that the WCD ofnon-optimized structure of the suspension system goes beyond this range. The structure needs modifying to suppress FWSS and the change of WCD with thewheel jumping distance. ADMAS software is a strong tool for parameter optimization and analysis. It creates a parameterization model by simulating with different values of model design variables, and then analyzes the parameterization based on the returned simulation results and the final optimization calculation of all parameters. During optimization, the program automatically adjusts design variables to obtain a minimum objective function [8-10]. To reduce tire wear and improve steering stability, the Table 1 Values of camber angle α , toe angle θ , caster angle γ and inclination angle β before and after optimization2Table 1 The data tables of optimize the results4 ConclusionsThe whole kinematic simulation model of an independent double-wishbone suspension system built by using ADAMS software with the left and the right suspension parts under random excitations can improve the calculationprecision by addressing the mutual impacts of kinematic characteristic parameters of the left and the right suspension parts under random excitations. The optimization can overcome the problem of the too large variation of WCDand overly large FWSS with the wheel jumping distance. The kinematic characteristic parameters of the suspension system reach an ideal range, demonstrating that the optimization protocol is feasible. From a practicalperspective, the optimization is expected to reduce tire wear, and remarkably improve suspension performance and vehicle steering stability.Figure 1 simple picture of suspensionFigure 2 Curve with the parameters of the suspension3译文摘要：为了提高轻型车辆性能和行驶稳定，我们使用ADAMS软件建立一个独立双横臂悬架系统运动仿真模型，并建立随机激励的测试平台，根据车辆实际运行条件，探讨悬架的运动学特征参数的变化。

悬架系英文术语Suspension……………………悬架Independent suspension………非独立悬架Dependent suspension………...独立悬架Bellcrank……………………...摇臂Upright………………………..立柱Caliper………………………...卡钳Brake disc……………………..刹车盘The wheel core………………...轮芯Rim…………………………….轮辋Spoke…………………………..轮辐Bolt…………………………….螺栓Nut……………………………..螺母Sping washer……………….….弹簧垫圈Steering gear…………………...转向器Quick release…………………...快拆Gear…………………………….齿轮Rack…………………………….齿条Brake pedal……………………..制动踏板Accelerator pedal……………….加速踏板Clutch pedal……………….…….离合踏板Pedal assembly…………….……踏板组件Brake master cylinder…….…….制动主缸Balance bar………………..…….平衡杆Front brake……………….……..前制动器Rear brake………………………后制动器Reservoir………………………..贮存器Bracket………………………….托架/撑架Brake nuts………………….……制动螺母Jam nuts……………………..…..锁紧螺母Spherical bearing…………..……球面轴承Adjusting shaft…………….……调整轴Double a-arms……………..…....双A臂Bending moment…………...…...弯矩Damper……………………..…...阻尼器Push rod…………………...….....推杆Pull rod……………………..…...拉杆Upper arm…………………..…..上横臂/上三角臂A lower cross arm…………..…..下横臂/下三角臂Wheel traver……………………车轮行程Wheel radius……………………车轮半径Rod end bearing……………......杆端关节轴承Scrub radius/kingpin offset….....摆角半径（主销偏距）Sprung mass…………………....悬挂质量（簧载质量）Unsprung mass………………....非簧载质量Load pass…………………….…载荷传递Toe……………………………...前束Toe in…………………………...正前轮内倾Toe out………………………….负前轮内倾Camber…………………………倾角Caster angle…………………….主销后倾角Wheel hub……………………....车轮轮毂Steering arm…………………….转向臂Track width……………………..轨道宽度Wheel base……………………...轴距Tie and wheel…………………...轮胎和车轮King pin inclination…………….主销内倾角King pin………………………...主销Roll center………………………侧倾中心（滚动中心）Pitch center…………….………..纵倾中心（距中心）Off set…………………………...偏距Compliance……………………...屈服Slip angle………………………..滑动角Lateral force……………………..侧向力Shaft……………………………..轴Chassis…………………………..底盘Anti-dive………………………...抵抗减速前俯Anti-squat……………………….抵抗加速后蹲Track…………………………….轮距Torque…………………………...转矩Smallest clearance………………最小离地间隙Anti-roll bar……………………..防倾杆Revolute joints…………………转动副Kinematics…………………..…运动学Dynamic………………………..动力学Center of gravity……………….质心高度Sprung mass distribution………簧载质量分布Center of gravity location……...重心位置Understeer……………………...不足转向Oversteer……………………….过度转向Roll axis………………………...侧倾轴线Pitch axis………………………..纵倾轴线Instant axis………………………瞬时轴线Riding…………………………...平顺性Handing…………………………操纵性Frame……………………………车架Spring……………………………弹簧Spring-damper…………………..弹簧阻尼器/弹簧减震器Shock absorber…………………..减震器Frequency………………………..偏频Spring mount…………………….弹簧安装Spring lockring…………………..弹簧锁环Tire contact patch…………….….轮胎接地面积Roll resistance………………..….防倾阻力Universal joint………….……….万向节Spherical joint………….………..球节Revolute joint………….………..转动副Swivel………………….………..旋转（接头：轴承）Upper swivel joint……….……...上旋转接头Roll stiffness……………….……侧倾刚度Air resistance…………….……...空气阻力Bushing（isolator）…….……....轴套Top wishbone……………….…...顶臂Bottom/lower wishbone…….…...下臂Hub carrier………………….……轮毂载体Motion radio……………….…….传递比Bump……………………….…….跳动Warp……………………….……..扭曲Roll………………………………侧倾Pitch……………………………...纵倾Roll stiffness……………………..侧倾刚度Ride rate………………………….轮胎径向刚度Wheel rate……………………..…车轮刚度Suspension rate……….……….…悬架刚度Spring rate………………………..弹簧刚度部分悬架系英文术语解释1.瞬时中心和侧倾中心瞬时中心是悬架联接周围的几何中心。

悬架系 suspension system悬架 suspension类型 type非独立悬架 rigid axle suspension独立悬架 independent suspension平衡悬架 equalizing type of suspension 组合式悬架 combination suspension可变刚度悬架 variable rate suspension 纵置板簧式 parallel leaf spring type上置板簧式 over slung type下置板簧式 under slung type双横臂式 double with-bone arm type横置板簧式 transversal leaf spring type 双纵臂式 double trailing arm type单横臂式 single transverse arm type双横臂式 double —wishbone type单横臂式 singe trailing arm type双纵臂式 double-trailing arm type单斜臂式 single oblique arm type四连杆式 four link type扭矩套管式 torque tube drive type第迪安式 De Dion type烛式 sliding pillar type麦弗逊式 MacPherson type金属弹簧式 metal spring type空气弹簧式 air spring type油气弹簧式 hydro—pneumatic spring type 橡胶液体弹簧式 hydro-rubber spring type 橡胶弹簧式 rubber spring type液体弹簧式 hydraulic spring type三点悬架 three—point suspension四点悬架 four—point suspension部件 assembly and parts悬架臂 suspension arm上悬架臂 upper suspension arm控制臂 control arm上控制臂 upper control arm下控制臂 lower control arm纵臂 trailing arm横臂 transverse arm斜臂 oblique arm支撑梁 support beam横向推力杆 lateral rod纵向推力杆 longitudinal rod拉杆 tension rod压杆 strut bar支撑杆 strut bar扭矩套管 torque tube变截面弹簧 tapered spring钢板弹簧 leaf spring(laminated spring)副钢板弹簧 auxiliary spring非对称钢板弹簧 unsymmetrical leaf spring单片式钢板弹簧 single leaf spring多片式钢板弹簧 muotileaved spring纵向钢板弹簧 longitudinal leaf spring螺旋弹簧 coil spring (helicalspring)空气弹簧 air spring囊式空气弹簧 bellow type air spring膜式空气弹簧 diaphragm typeair spring橡胶弹簧 rubber spring type液体弹簧 hydraulic spring油气弹簧 hydro—pneumatic spring type单气室油气弹簧 single chamber hydragas spring双气室油气弹簧 double chamber hydragas spring液体弹簧 hydraulic spring底盘弹簧 chassis spring四分之一椭圆形弹簧 quarter elliptic spring半椭圆形弹簧 half-elliptic spring(semi-elliptic spring) 四分之三椭圆形弹簧 three quarter elliptic spring全椭圆形弹簧 full elliptic spring悬臂弹簧 cantilever spring簧上质量 sprung weight簧下质量 unsprung weight垫上弹簧载荷量 spring capacity at pad地面弹簧载荷量 spring capacity at ground弹簧静挠度 spring static deflection弹簧跳动间隙 bump clearance of spring弹簧中心距 distance between spring centers减振器 shock absorber筒式减振器 telescopic shock absorber油压缓冲器 hydraulic buffer负荷调平式减振器 load -levelling shock absorber液压减振器 dydraulic shock absorber可调减振器 adjustable shock absorber摇臂式减振器 lever type shock absorber磨擦式减振器 frictional shock absorber充气减振器 gas-filled shock absorber动力减振器 dynamic shock absorber减振器卸荷阀 shock absorber relief valve减振器进油阀 shock absorber intake valve减振器示功图 damper indicator diagram减振器液 damper fluid横向稳定器 stabilizer anti—roll bar滑动座 sliding seat滑板 sliding plate弹簧架 spring bracket弹簧主片 spring leaf钢板弹簧吊耳 leaf spring shackle钢板弹簧衬套 leaf spring bushing钢板弹簧销 leaf spring pin弹簧卷耳 spring eyeU型螺栓 U bolt钢板弹簧中心螺栓 leaf spring center bolt橡胶衬套 rubber bushing缓冲块 buffer stopper限位块 limiting stopper平衡轴 trunnion shaft平衡轴支座 trunnion base臂轴 arm shaft平横臂 equalizer螺纹衬套 screw bushing（车身）高度阀 levelling valve车架 auxiliary tank整体车架 unitized frame上弯式梁架 upswept frame (kick up frame）短型车架 stub frame发动机支架 engine mounting半径杆 radius rod平衡杆 stabilizer bar制动反应杆 brake reaction rod分开式车身和车架 separated body and frame上海大众：帕萨特领驭悬架：前：四连杆独立式/ 后：纵向摆臂式制动：前通风盘式/后实心盘式，带前轮刹车片磨损过度报警装置,带贯通式双膜片（8+9英寸）真空刹车助力器东风雪铁龙:富康悬架:前：麦克弗逊独立式/后：连杆式独立悬架制动:前盘后鼓一汽大众：捷达悬架：前：麦克弗逊式单横臂/后：纵向拖臂式单纵臂制动：前盘后鼓海南马自达：福美来323悬架：前:麦克弗逊式独立悬架/后：TTL双天梯多连杆式独立悬架制动：通风盘/盘式北京现代：伊兰特悬架：前：麦克弗逊式/后：复合扭转梁式制动：前后盘式上汽通用：凯越悬架：Twin—Link四轮独立式悬架制动：前后轮盘式制动，四轮ABS+EBD东风:皮卡EQ1021H15Q悬架：前：双横臂式扭杆弹簧独立悬架/后:钢板弹簧制动：MABS防抱死装置、液压制动系统，管路采用H型布置厦门金龙：金凤凰悬架:6气囊悬架制动：鼓式双回路气制动储能弹簧驻车制动昌河铃木：昌铃王悬架:前：独立麦克佛逊式/后:非独立单纵摆臂式制动：前盘后鼓江铃汽车：陆风悬架：前：不等长双横臂扭杆弹簧独立悬架/后：纵置变截面少片簧制动:液压双管路，真空助力，前盘后鼓式制动器，带制动力比例阀独立悬架的左右车轮不是用整体车桥相连接,而是通过悬架分别与车架（或车身）相连，每侧车轮可独立下下运动.轿车和载重量1t以下的货车前悬架广为采用，轿车后悬架上采用也在增加。