机械毕业设计英文外文翻译398驱动桥_(2)

1、附 录 A 英文文献 Drive axle All vehicles have some type of drive axle/differential assembly incorporated into the driveline. Whether it is front, rear or four wheel drive, differentials are necessary for the smooth application of engine power to the road. Powerflow The drive axle must transmit power throu

2、gh a 90 angle. Theflow of power in conventional front engine/rear wheel drive vehicles moves from the engine to the drive axle in approximately a straight line. However, at the drive axle, the power must be turned at right angles (from the line of the driveshaft) and directed to the drive wheels. Th

3、is is accomplished by a pinion drive gear, which turns a circular ring gear. The ring gear is attached to a differential housing, containing a set of smaller gears that are splined to the inner end of each axle shaft. As the housing is rotated, the internal differential gears turn the axle shafts, w

4、hich are also attached to the drive wheels. RING GEAP 1 BEARING RIGHT AXLE SHAFT PINION GEAR LER-HAD I AXLE SHAH DRIVE HNMN DRIVE PINION, 二 BE omRENTIAL CASE 亠 /： Fig 1 Drive axle Rear-wheel drive Rear-wheel-drive vehicles are mostly trucks, very large seda ns and many sports car and coupe models. T

5、he typical rear wheel drive vehicle uses a front mounted engine and transmission assemblies with a driveshaft coupling the transmission to the rear drive axle. Drive in through the layout of the bridge, the bridge drive shaft arranged vertically in the same vertical plane, and not the drive axle sha

6、ft, respectively, i n their own sub-actuator with a direct conn ecti on, but the actuator is located at the front or the back of the adjace nt shaft of the two bridges is arranged in series. Vehicle before and after the two ends of the driv ing force of the drive axle, is the sub-actuator and the tr

7、an smissi on through the middle of the bridge. The adva ntage is not only a reduction of the number of drive shaft, and raise the driving axle of the common parts of each other, and to simplify the structure, reduces the volume and quality. Some vehicles do not follow this typical example. Such as t

8、he older Porsche or Volkswagen vehicles which were rear engine, rear drive. These vehicles use a rear mounted transaxle with halfshafts connected to the drive wheels. Also, some vehicles were produced with a front engine, rear transaxle setup with a driveshaft connecting the engine to the transaxle,

9、 and halfshafts linking the transaxle to the drive wheels. Differential operation In order to remove the wheel around in the kinematics due to the lack of co-ordination about the wheel diameter arising from a different or the same rolling radius of wheel travel required, inter-wheel motor vehicles a

10、re equipped with about differential, the latter to ensure that the car driver Bridge on both sides of the wheel when in range with a trip to the characteristics of rotating at different speeds to meet the requirements of the vehicle kinematics. The accompanying illustration has been provided to help

11、 understand how this occurs. 1. The drive pinion, which is turned by the driveshaft, turns the ring gear. 2. The ring gear, which is attached to the differential case, turns the case. 3. The pinion shaft, located in a bore in the differential case, is at right angles to the axle shafts and turns wit

12、h the case. 4. The differential pinion (drive) gears are mounted on the pinion shaft and rotate with the shaft . 5. Differential side gears (driven gears) are meshed with the pinion gears and turn with the differential housing and ring gear as a unit. 6. The side gears are splined to the inner ends

13、of the axle shafts and rotate the shafts as the housing turns. 7. When both wheels have equal traction, the pinion gears do not rotate on the pinion shaft, since the input force of the pinion gears is divided equally between the two side gears. 8. When it is necessary to turn a corner, the different

14、ial gearing becomes effective and allows the axle shafts to rotate at different speeds . Open-wheel differential on each general use the same amount of torque. To determine the size of the wheel torque to bear two factors: equipment and friction. In dry conditions, when a lot of friction, the wheel

15、bearing torque by engine size and gear restrictions are hours in the friction (such as driving on ice), is restricted to a maximum torque, so that vehicles will not spin round. So even if the car can produce more torque, but also need to have sufficient traction to transfer torque to the ground. If

16、you increase the throttle after the wheels slip, it will only make the wheels spin faster. Limited-slip and locking differential operation a tie shaft pinion shaft diffarartial 畑9哼 differenld ” pinion Fig 5Limited-slip differe ntial Differential settlement of a car in the uneven road surface and ste

17、ering wheel-drive n speed at about the differe nt requireme nts; but is followed by the existenee of differential in the side car wheel skid can not be effective when the power transmission, that is, the wheel slip can not produce the driv ing force, rather tha n spin the wheel and does not have eno

18、 ugh torque. Good non-slip differe ntial settleme nt of the car wheels skid on the side of the power transmission when the issue, that is, lock ing differe ntial, so that no Ion ger serve a useful differe ntial right and left sides of the wheel can be the same torque. Limited-slip and locking differ

19、ential operation can be divided into two major categories : (1) mandatory locking type in ordinary differentiallocking en forceme nt age ncies to in crease, whe n the side of the wheel skid occurs, the driver can be electric, pneumatic or mechanical means to manipulate the locking body meshing sets

20、of DIP Shell will be with the axle differe ntial lock into one, thus the temporary loss of differe ntial role. Relatively simple structure in this way, but it must be operated by the driver, and good roads to stop locking and restore the role of differential. (2) self-locking differential installed

21、in the oil viscosity or friction clutch coupling, when the side of the wheel skid occurs when both sides of the axle speed difference there, coupling or clutch friction resistance on the automatic, to make certain the other side of the wheel drive torque and the car continued to travel. When there i

22、s no speed difference on both sides of the wheel, the frictional resistance disappeared, the role of automatic restoration of differentials. More complicated structure in this way, but do not require drivers to operate. Has been increasingly applied in the car. About non-slip differential, not only

23、used for the differential between the wheels, but also for all-wheel drive vehicle inter-axle differential/. Gear ratio The drive axle of a vehicle is said to have a certain axle ratio. This number (usually a whole number and a decimal fraction) is actually a comparison of the number of gear teeth o

24、n the ring gear and the pinion gear. For example, a 4.11 rear means that theoretically, there are 4.11 teeth on the ring gear for each tooth on the pinion gear or, put another way, the driveshaft must turn 4.11 times to turn the wheels once.The role of the final drive is to reduce the speed from the

25、 drive shaft, thereby increasing the torque. Lord of the reduction ratio reducer, a driving force for car performance and fuel economy have a greater impact. In general, the more reduction ratio the greater the acceleration and climbing ability, and relatively poor fuel economy. However, if it is to

26、o large, it can not play the full power of the engine to achieve the proper speed. The main reduction ratio is more Smaller ，the speed is higher, fuel economy is better, but the acceleration and climbing ability will be poor. 附 录 B 文献翻译 驱动桥 所有的汽车都装有不同类型的驱动桥和差速器来驱动汽车行驶。 无论是前驱汽车， 后驱汽车还是四轮驱动的汽车， 对于将发动机

27、的动 力转化到车轮上差速器都是不可缺少的部件。 动力的传递 驱动桥必须把发动机的动力转一个直角后传递出去， 但人对于前 轮驱动汽车发动机输出的转矩与主减速器是在同一直线上的， 但是发 动机前置的后轮驱动的汽车发动机的动力必须以正确的角度传递出 去，来驱动车轮。 图中所示是齿轮驱动的过程， 即由一个相对小的齿轮驱动一个大 齿轮（主动齿轮和从动齿轮） ，从动锥齿轮和差速器壳连接在一起， 在半轴的根部有一对带有内花键的半轴齿轮， 半轴齿轮和半轴通过花 键来连接在一起。 当差速器壳旋转时， 就驱动内部的半齿轮转动从而 使半轴转动，将转矩传给车轮。 后驱动桥 后轮驱动的车辆大多是卡车， 大型轿车和大部分

28、跑车。 典型的后 轮驱动的车辆使用前置发动机和变速箱总成将转矩传输到后轮驱动 桥。多驱动桥汽车中，在贯通式驱动桥的布置中，各桥的传动轴布置 在同一纵向铅垂平面内， 并且各驱动桥不是分别用自己的传动轴与分 动器直接联接， 而是位于分动器前面的或后面的各相邻两桥的传动轴， 是串联布置的。 汽车前后两端的驱动桥的动力， 是经分动器并贯通中 间桥而传递的。其优点是，不仅减少了传动轴的数量，而且提高了各 驱动桥零件的相互通用性，并且简化了结构、减小了体积和质量。 一些车辆不是这个典型的例子。 如老式的保时捷或大众汽车引擎 在汽车后面， 是后轮驱动。 这些车辆使用的后方安装驱动桥与半轴来 驱动车轮。另外，

29、一些车辆是前置引擎，后桥与传动轴连接发动机来 驱动车轮。 差速器 为了消除由于左右车轮在运动学上的不协调而产生左右车轮外 径不同或滚动半径不相等而要求车轮行程， 汽车左右驱动轮间都装有 差速器，后者保证了汽车驱动桥两侧车轮在行程不等时具有以不同速 度旋转的特性，从而满足了汽车行驶运动学要求。 如图所示说明了其工作情况 1. 主动齿轮转动，从而驱动从动齿轮。 2. 从动齿轮将转矩作用于差速器壳，使其转动。 3. 位于差速器壳中的行星齿轮以适当的角度和半轴齿轮接触， 并随的差速器壳转动。 4. 行星齿轮 （驱动齿轮） 和十字轴连接， 和十字轴一起转动。 5. 半轴齿轮（被驱动齿轮）和行星齿轮啮合并且和从动齿轮 及差速器壳作为一个整体一起转