外文翻译：汽车制动系统2

附录附录ABraking system function is to make the car driving in accordance with the requirements of the pilot required even slow down park; They offend car has in various road conditions (including in the slope stability) in car; Make the downhill cars speed to be stable.For car up the role of brake is only in the car and role with the direction of the car driving direction opposite forces, and the size of these forces are random, do not control, so cars must be installed on a series of special equipment to achieve the function.Automobile brake system is to point to to ensure that the car in technology, improve the safe driving car average speed, etc., and the admiration installed in the car brake special brake institutions. In general automobile brake system including crane brake system and parking brake two sets of independent device. One crane brake device is a driver with feet to manipulate, and it said the foot brake. Parking brake device is a pilot with the hand, so it says of the manipulation of the hand brake. The function of the crane brake system is to make the car slow down or running in the shortest distance parking within. And parking brake function is to make had stopped the car on the road all keep still. But, sometimes, in an emergency, two braking device can be used at the same time and increase the effect of auto brake. Some special purpose of cars and often in the mountains cars, long and frequently brake will lead to crane brake system overheating, so in these cars often add all sorts of different types of auxiliary braking equipment, so as to speed up the hill stability.According to the braking energy situation, brake system can also be divided into human brake system, power brake system, and servo brake system, three. Human brake system to the driver's physical strength as braking energy; Power brake system engine power to the transformation of the air pressure or hydraulic braking energy as; And servo brake system is the most human and engine power as a brake energy. In addition, according to the braking energy transfer mode, brake system and can be divided into mechanical and hydraulic, pneumatic type and assolenoid style wait until a few kinds.In the types of brake system, the brake is car brake system to produce stop the traffic movement or movement trend components. Force At present, the kind used by car is friction brakes brake, also is to prevent the braking torque motor sports from fixed components and rotation of the friction between the work surface.附录B制动系统作用是使行驶中的汽车按照驾驶员的要求进行强制减速甚至停车；使已停驶的汽车在各种道路条件下(包括在坡道上)稳定驻车；使下坡行驶的汽车速度保持稳定。

制动系统汉英对照1制动装备braking equipment2 制动系braking system2.1.1行车制动系（常用制动系）service braking system2.1.2 应急制动系emergency braking system2.1.3 驻车制动系parking braking system2.1.4 辅助制动系auxiliary braking system2.1.5 自动制动系automatic braking system2.2.1 人力制动系muscular energy braking system2.2.2 动力制动系non-muscular energy braking system2.2.3 伺服制动系（助力制动系）servo braking system(energyassisted braking system)2.2.4 惯性制动系inertia braking system2.2.5重力制动系gravity braking system2.3.1 气压制动系（气制动系）air braking system2.3.2 液压制动系hydraulic braking system2.3.3 电磁制动系electromagnetic braking system2.3.4 机械制动系mechanical braking system2.3.5 组合制动系combination braking system2.4.1 单回路制动系single-circuit braking system2.4.2 双回路制动系dual-circuit braking system2.4.3 多回路制动系multi-circuit braking system2.5.1 单管（线）路制动系singlep-line braking system2.5.2 双管（线）路制动系dual-line braking system2.5.3 多管（线）路制动系multi-line braking system2.5.4 连续制动系continuous braking system2.5.5 半连续制动系semi continuous braking system2.5.6 非连续制动系non continuous braking system2.6 渐进制动gradual braking3 组成部分constituent elements3.1供能装置energy supplying device3.1.1 制动能源braking energy source3.2 控制装置control device3.3 传能装置transmission device3.4 制动器brake3.4.1 磨擦式制动器friction brake3.4.1.1 鼓式制动器drum brake3.4.1.1.1 内张型鼓式制动器internal expanding drum brake 3.4.1.1.1.1 双领蹄式制动器（2L式制动器）two leading shoebrake3.4.1.1.1.2 双从蹄式制动器（2T式制动器）two trailing shoebrake3.4.1.1.1.3 双向双领蹄式制动器（D2L式制动器）duo twoleading shoe brake3.4.1.1.1.4 双向双从蹄式制动器（D2T式制动器）duo twotrailing shoe brake3.4.1.1.1.5 领从蹄式制动器（LT式制动器）leading trailingshoe brake3.4.1.1.1.6 单向伺服式制动器（US式制动器）uni-servo brake 3.4.1.1.1.7 双向伺服式制动器（DS式制动器）duo- servo brake 3.4.1.1.2 外收缩型鼓式制动器external contracting drumbrake3.4.1.1.2.1 带式制动器band brake3.4.1.2 盘式制动器disc brake3.4.1.2.1 钳盘式制动器caliper disc brake3.4.1.2.1.1 定钳盘式制动器disc brake with fixed caliper 3.4.1.2.1.2 浮钳盘式制动器disc brake with floatingcaliper3.4.1.2.1.3 浮盘式制动器floating disc brake3.4.1.2.2 全盘式制动器complete disc brake3.4.1.3 凸轮张开式制动器cam brake3.4.1.4 楔式制动器wedge brake3.4.1.5 轮缸（柱塞）式制动器wheel cylinder brake3.4.2 刚性接合式制动器（锁止式制动器）positiveengagement brake3.5 缓速装置(缓冲器) retarder3.5.1 发动机缓速装置retarder by combustion engine3.5.2 电机缓速装置retarder by electrictraction motor3.5.3 液力缓速器hydro-dynamic retarder3.5.4 空气动力缓速装置aerodynamic retarder3.5.5 电磁缓速器electromagnetic retarder3.6 制动管（线）路braking line3.6.1 供能管（线）路feed line3.6.2 促动管（线）路actuating line3.6.3 操纵管（线）路pilot line3.6.4.1 供给管（线）路supply line3.6.4.2 控制管（线）路control line3.6.4.3 共用管（线）路common line3.6.4.4 应急管（线）路emergency line3.7 附加装置additional device3.8 辅助装置auxiliary device3.8.1 报警装置alarm device3.8.1.1 报警压力alarm pressure3.8.2 保护压力装置protection pressure device3.8.2.1 保护压力protection pressure3.8.3 制动蹄作用压力application pressure of brake shoeassembly3.8.4 制动蹄放松压力release pressure of brake shoeassembly3.8.5 制动力调节装置device to apply correction tobraking force3.8.6 车轮防抱死装置anti-loke device3.8.6.1 装置的部件3.8.6.1.1 传感器sensor3.8.6.1.2 控制器controller3.8.6.1.3 调节器modulator3.8.6.2 车轮控制类型3.8.6.2.1 单轮控制individual wheel control3.8.6.2.2 多轮控制multi wheel control3.8.6.2.2.1 轴控制axle control3.8.6.2.2.2 边控制side control3.8.6.2.2.3 对角控制diagonal control3.8.6.2.2.4 组合多角控制combined multi-axle control3.8.6.3.1 可变选择variable selection3.8.6.3.1.1 低选择select-low3.8.6.3.1.2 高选择select-high3.8.6.3.2 预定选择predetermined selection3.8.6.3.2.1 车轮选择selection by wheel3.8.6.3.2.2 平均选择average selection3.8.6.4.1 最低控制速度minimum control speed3.8.6.4.2 传感器信号sensor signal3.8.6.4.3 分辨率（脉冲式车轮速度传感器的分辨率）resolutionRate (of an impulese wheel speed sensor)3.8.6.4控制周期control cycle3.8.6.4.4控制频率control frequency4.制动力学braking mechanics力，力矩4．1．1控制力Fc control force4.1.2 作用力Fs application force4.1.3 制动力矩Mf braking torque4.1.4 总制动力Ff total braking force4.1.5 干扰后效制动力矩disturbing residual braking torque 4.1.6 制动力分配率braking force distribution4.1.7 制动因数Z braking efficiency factor4.1.8 制动器效能因数brake efficiency4.1.9 制动蹄效能因数C brake shoe efficirncy factor4.2 制动系的滞后braking system hysteresis4.3 制动器的滞后brake hysteresis4.4 时间4．4．1 控制装置开始作用时刻t0 instant at which the movement of the control device begins4.4.2 减速度开始产生的时刻t1 instant at which thedeceleration begins4.4.3 减速度接近于稳定的开始时刻t2 instant at which the deceleration begins to beapproximately stable4.4.4 减速度开始急剧下降时刻t3 instant at which the deceleration beging to decrease rapidly4.4.5 减速度终止时刻t4 instant at which the deceleration beging to decrease rapidly4.4.6 驾驶员反应时间表reaction time of driver4.4.7 促动时间actuatig time4.4.8 机构滞后时间mechanism hysteresis time4.4.9 增长时间build-up time4.4.10 有效制动时间active braking time4.4.11 放松时间release time4.4.12 主制动时间main braking time4.4.13 总制动时间total braking time4.4.14 停车时间stopping time4.5 距离4.5.1 停车距离stopping distance4.5.2 总制动距离total braking distance4.5.3 有效制动距离active braking distance4.5.4 踏板行程pedal travel4.5.5 踏板自由行程free pedal travel4.5.6 踏板最大行程maximum pedal travel4.6 制动功W braking work4.7 瞬时制动功率P instantaneous braking power4.8 速度，减速度4.8.1 制动初速度v1 initial speed of braking4.8.2 制动终速度v2 final speed of braking4.8.3 制动减速度braking deceleration4.8.3.1 瞬时制动减速度a instantaneous braking deceleration 4.8.3.2 平均制动减速度am mean braking deceleration4.8.3.3 最大制动减速度Amax maximum braking deceleration5 制动过程中的现象phenomenon on braking course5.1 热衰退heat fade5.2 水衰退water fade5.3 恢复recovery5.4 过恢复over recovery5.5 增强（突升）build up5.6 制动气阻braking vapour lock5.7 龟裂cracks5.7.1 热龟裂heat cracks5.8 制动拖滞braking drag5.9 冷制动痹病cola braking sickness5.10 制动颤振brake chatter5.11制动噪声brake noise5.12 车轮抱死wheel lock5.13 制动跑偏braking deviation from5.14 制动甩尾braking swerve5.15 制动折叠braking jack-knifing5.16 制动跳动braking hop5.17 制动失效braking failure5.18 制动滑移braking skid5.19 制动点头braking nose dive制动系统零部件英汉对照检查2.1真空泵vacuum pump2.2喷射器ejector2.3真空罐（真空筒）vacuum tank2.4空气机（压气机）air compressor2.4.1气缸盖cylinder head2.4.2气缸体cylinder block2.4.3活塞piston2.4.4活塞环piston ring2.4.5连杆connecting rod2.4.6活塞销piston pin2.4.7曲轴cyank shaft2.4.8进气阀intake valve2.4.9排气阀exhaust valve2.5储气罐（储气筒）air storage reservoir2.6调压阀pressure regulating valve2.7单向阀（止回阀）single check valve(check valve) 2.8滤清器filter2.8.1进气滤清器air intake filter2.8.2排气滤清器air exhaust filter2.8.3管路滤清器line filter2.8.4滤网（芯）strainer2.9油水分离器oil and water separator2.10防冻器anti-freezer2.11空气干燥器air dryer2.12排放阀drain valve2.13压力保护阀pressure protection valve3.1行车制动踏板装置service braking pedal device 3.1.1制动踏板braking pedal3.1.2踏板护套pedal pad3.1.3踏板支架pedal bracket3.1.4衬套bushing3.1.5套管collar3.1.6销轴axis pin3.1.7回位弹簧return spring3.2驻车制动操纵装置parking braking control device3.2.1操纵杆control lever3.2.2操纵杆支架control lever bracket3.2.3操纵杆导套control lever guide collar3.2.4齿杆（棘轮）rod rach (ratchet)3.2.5棘爪ratchet pawl3.2.6操纵缆绳control cable3.2.7平衡臂equalizer3.2.8拉杆（拉绳）pull rod(pull wire)3.2.9拉杆导套pull rod guide collar(pull wire guidecollar)3.3气制动阀air brake valve3.3.1单腔气制动阀single-chamber air brake valve3.3.1.1推杆plunger3.3.1.2气阀air valve3.3.1.3平衡弹簧equalizing spring3.3.1.4膜片diaphragm3.3.2双腔制动阀dual-chamber air brake valve3.3.2.1串列式双腔制动阀series dual-chamber air brakevalve3.3.2.1并列式双腔制动阀parallel dual-chamber air brakevalve3.3.3三腔气制动阀triple- chamber air brake valve3.4三通路控制阀three way control valve3.5双向止回阀（双通换向阀）dual way check valve3.6继动阀relay valve3.7快放阀quick release valve3.8继动快放阀relay and quick release valve3.9挂车制动阀trailer braking valve3.10挂车制动应急继动阀trailer braking relay emergencyvalve3.11挂车制动保护阀trailer braking protection valve3.12挂车制动放松阀trailer braking relax valve3.13手控制动阀hand braking valve4.1制动主缸brake master cylinder4.1.1有补偿孔式制动主缸compensating brake mastercylinder4.1.1,1 主缸缸体master cylinder body4.1.1.2 皮碗防护垫cup protector4.1.1.3 主皮碗primary cup4.1.1.4 皮圈（副皮碗）ring cup (secondary cup)4.1.1.5 弹簧座spring seat4.1.1.6 活塞挡圈piston stopper4.1.1.7 卡环snap ring4.1.1.8 主缸推杆master cylinder push rod4.1.1.9 连接叉clevis4.1.1.10 防尘罩（套）boot4.1.1.11 残留阀residual valve4.1.1.12 储液室fluid reservoir4.1.1.13 储液室盖fluid reservoir cop4.1.2 无补偿孔式制动主缸portless brake master cylinder 4.1.2.1 进油阀inlet valve4.1.3 串列双腔式制动主缸series dual-chamber brake master cylinder4.1.3.1 第一活塞first piston4.1.3.2 第二活塞secondary piston4.2 轮缸wheel cylinder4.3 伺服机构（助力器）servo mechanism (booster)4.3.1 真空助力器vacuum booster4.3.1.1 反馈杠杆reaction lever4.3.1.2 反馈盘reaction plate4.3.1.3 伺服阀servo valve4.3.1.4 反馈柱塞reaction plunger4.3.1.5 伺服活塞（助力活塞）servo piston (boosting piston) 4.3.1.6 伺服膜片(助力膜片) servo diaphragm(boosting diaphragm4.3.2 真空增压器vacuumintensifier4.3.2.1 控制阀体control valve body4.3.2.2 阀弹簧valve spring4.3.2.3 控制膜片回位弹簧control diaphragm return spring 4.3.2.4 控制膜片control diaphragm4.3.2.5 控制活塞control piston4.3.2.6 控制活塞皮碗control piston cup4.3.2.7 辅助缸缸体auxiliary cylinder body4.3.2.8 液压活塞hydraulic piston4.3.2.9 液压阀hydraulic valve4.3.2.10 端盖end plate4.3.3 气压助力器air booster4.3.4 气压-液压增压器（气顶油助力器）air over hydraulic intensifier(air over hydraulic booster)4.4 制动管（线）路braking line4.4.1 导线（电缆）wire (cable of wire)4.4.2 管件（制动管组件）pipe unit (braking pipe unit)4.4.2.1 刚性管rigid pipe4.4.2.2 半刚性管semi-rigid pipe4.4.2.3 软管（制动软管）hose(braking hose)4.4.2.3.1 液压软管hydraulic hose4.4.2.3.2 软管保护管hose protector4.4.2.3.3 软管卡子hose clip4.4.2.3.4 气制动软管air brake hose4.4.2.3.5 跨接软管jumper hose4.4.2.4 桥式管bridge pipe4.4.3 管接头（管连接件）pipe fittings4.4.3.1 压力接头compression fittings4.4.3.1.1 接头体fittings body4.4.3.1.2 密封圈sealing ring4.4.3.1.3 压力环pressure ring4.4.3.1.4 管座（密封管座）pipe seat(sealing pipe seat)4.4.3.1.5 管螺母pipe nut4.4.3.2 推力接头thrust fittings4.4.3.2.1 内锥座接头fitting body with innerconical seat 4.4.3.3 快速接头quick fittings4.4.4 跨接软管连接器（气制动管连接器）jumper hose connections(pneumatic braking connections)4.5制动气室brake chamber4.5.1 膜片式制动气室diapheagm brake chamber4.5.2 活塞式制动气室piston brake chamber4.5.3 储能弹簧制动气室energy storage spring brake chamber4.5.3.1 储能弹簧室energy storage spring chamber4.5.3.2 储能弹簧energy storage spring4.5.3.3 储能弹簧放松机构energy storage spring release mechanical4.5.3.4 随动件followor4.5.3.5 推杆pusher4.5..4 锁止式制动气室lock brake chamber4.5.4.1 锁止腔lock chamber4.5.4.2 锁止弹簧lock spring4.5.4.3 楔环wedge ring4.6 制动蹄促动器brake shoe actuator4.6.1 制动凸轮轴brake camshaft5.。

Automobile Brake SystemThe braking system is the most important system in cars. If the brakes fail，the result can be disastrous. Brakes are actually energy conversion devices，which convert the kinetic energy (momentum) of the vehicle into thermal energy (heat).When stepping on the brakes，the driver commands a stopping force ten times as powerful as the force that puts the car in motion. The braking system can exert thousands of pounds of pressure on each of the four brakes.Two complete independent braking systems are used on the car. They are the service brake and the parking brake.The service brake acts to slow，stop，or hold the vehicle during normal driving. They are foot-operated by the driver depressing and releasing the brake pedal. The primarypurpose of the brake is to hold the vehicle stationary while it is unattended. The parking brake is mechanically operated by when a separate parking brake foot pedal or hand lever is set.The brake system is composed of the following basic components: the “master cylinder” which is located under the hood，and is directly connected to the brake pedal，converts driver foot’s mechanical pressure into hydraulic pressure. Steel “brake lines” and flexible “brake hoses” connect the master cylinder to the “slave cylinders” located at each wheel. Brake fluid，specially designed to work in extreme conditions，fills the system. “Shoes” and “pads” are pushed by the slave cylinders to contact the “drums” and “rotors” thus causing drag，which (hopefully) slows the car.The typical brake system consists of disk brakes in front and either disk or drum brakes in the rear connected by a system of tubes and hoses that link the brake at each wheel to the master cylinder (Figure).Basically，all car brakes are friction brakes. When the driver applies the brake，the control device forces brake shoes，or pads，against the rotating brake drum or disks at wheel. Friction between the shoes or pads and the drums or disks then slows or stops the wheel so that the car is braked.In most modern brake systems (see Figure 15.1)，there is a fluid-filled cylinder，called master cylinder，which contains two separate sections，there is a piston in each section and both pistons are connected to a brake pedal in the driver’s compartment. When the brake is pushed down，brake fluid is sent from the master cylinder to the wheels. At the wheels，the fluid pushes shoes，or pads，against revolving drums or disks. The friction between the stationary shoes，or pads，and the revolving drums or disks slows and stops them. This slows or stops the revolving wheels，which，in turn，slow or stop the car.The brake fluid reservoir is on top of the master cylinder. Most cars today have a transparent r reservoir so that you can see the level without opening the cover. The brake fluid level will drop slightly as the brake pads wear. This is a normal condition and no cause for concern. If the level drops noticeably over a short period of time or goes down to about two thirds full，have your brakes checked as soon as possible. Keep the reservoir covered except for the amount of time you need to fill it and never leave a cam of brake fluid uncovered. Brake fluid must maintain a very high boiling point. Exposure to air will cause the fluid to absorb moisture which will lower that boiling point.The brake fluid travels from the master cylinder to the wheels through a series of steel tubes and reinforced rubber hoses. Rubber hoses are only used in places that require flexibility，such as at the front wheels，which move up and down as well as steer. The rest of the system uses non-corrosive seamless steel tubing with special fittings at all attachment points. If a steel line requires a repair，the best procedure is to replace the compete line. If this is not practical，a line can be repaired using special splice fittings that are made for brake system repair. You must never use copper tubing to repair a brake system. They are dangerous and illegal.Drum brakes，it consists of the brake drum，an expander，pull back springs，a stationary back plate，two shoes with friction linings，and anchor pins. The stationaryback plate is secured to the flange of the axle housing or to the steering knuckle. The brake drum is mounted on the wheel hub. There is a clearance between the inner surface of the drum and the shoe lining. To apply brakes，the driver pushes pedal，the expander expands the shoes and presses them to the drum. Friction between the brake drum and the friction linings brakes the wheels and the vehicle stops. To release brakes，the driver release the pedal，the pull back spring retracts the shoes thus permitting free rotation of the wheels.Disk brakes，it has a metal disk instead of a drum. A flat shoe，or disk-brake pad，is located on each side of the disk. The shoes squeeze the rotating disk to stop the car. Fluid from the master cylinder forces the pistons to move in，toward the disk. This action pushes the friction pads tightly against the disk. The friction between the shoes and disk slows and stops it. This provides the braking action. Pistons are made of either plastic or metal. There are three general types of disk brakes. They are the floating-caliper type，the fixed-caliper type，and the sliding-caliper type. Floating-caliper and sliding-caliper disk brakes use a single piston. Fixed-caliper disk brakes have either two or four pistons.The brake system assemblies are actuated by mechanical，hydraulic or pneumatic devices. The mechanical leverage is used in the parking brakes fitted in all automobile. When the brake pedal is depressed，the rod pushes the piston of brake master cylinder which presses the fluid. The fluid flows through the pipelines to the power brake unit and then to the wheel cylinder. The fluid pressure expands the cylinder pistons thus pressing the shoes to the drum or disk. If the pedal is released，the piston returns to the initial position，the pull back springs retract the shoes，the fluid is forced back to the master cylinder and braking ceases.The primary purpose of the parking brake is to hold the vehicle stationary while it is unattended. The parking brake is mechanically operated by the driver when a separate parking braking hand lever is set. The hand brake is normally used when the car has already stopped. A lever is pulled and the rear brakes are approached and locked in the “on” position. The car may now be left without fear of its rolling away. When the driver wants to move the car again，he must press a button before the lever can be released. The hand brake must also be able to stop the car in the event of the foot brake failing. For this reason，it is separate from the foot brake uses cable or rods instead of the hydraulic system.Anti-lock Brake SystemAnti-lock brake systems make braking safer and more convenient，Anti-lock brakesystems modulate brake system hydraulic pressure to prevent the brakes from locking and the tires from skidding on slippery pavement or during a panic stop.Anti-lock brake systems have been used on aircraft for years，and some domestic car were offered with an early form of anti-lock braking in late 1990’s. Recently，several automakers have introduced more sophisticated anti-lock system. Investigations in Europe，where anti-lock braking systems have been available for a decade，have led one manufacture to state that the number of traffic accidents could be reduced by seven and a half percent if all cars had anti-lock brakes. So some sources predict that all cars will offer anti-lock brakes to improve the safety of the car.Anti-lock systems modulate brake application force several times per second to hold the tires at a controlled amount of slip; all systems accomplish this in basically the same way. One or more speed sensors generate alternating current signal whose frequency increases with the wheel rotational speed. An electronic control unit continuously monitors these signals and if the frequency of a signal drops too rapidly indicating that a wheel is about to lock，the control unit instructs a modulating device to reduce hydraulic pressure to the brake at the affected wheel. When sensor signals indicate the wheel is again rotating normally，the control unit allows increased hydraulic pressure to the brake. This release-apply cycle occurs several time per second to “pump” the brakes like a driver might but at a much faster rate.In addition to their basic operation，anti-lock systems have two other things in common. First，they do not operate until the brakes are applied with enough force to lock or nearly lock a wheel. At all other times，the system stands ready to function but does not interfere with normal braking. Second，if the anti-lock system fail in any way，the brakes continue to operate without anti-lock capability. A warning light on the instrument panel alerts the driver when a problem exists in the anti-lock system.The current Bosch component Anti-lock Braking System (ABSⅡ)，is a second generation design wildly used by European automakers such as BWM，Mercedes-Benz and Porsche. ABSⅡsystem consists of : four wheel speed sensor，electronic control unit and modulator assembly.A speed sensor is fitted at each wheel sends signals about wheel rotation to control unit. Each speed sensor consists of a sensor unit and a gear wheel. The front sensor mounts to the steering knuckle and its gear wheel is pressed onto the stub axle that rotates with thewheel. The rear sensor mounts the rear suspension member and its gear wheel is pressed onto the axle. The sensor itself is a winding with a magnetic core. The core creates a magnetic field around the winding，and as the teeth of the gear wheel move through this field，an alternating current is induced in the winding. The control unit monitors the rate o change in this frequency to determine impending brake lockup.The control unit’s function can be divided into three parts: signal processing，logic and safety circuitry. The signal processing section is the converter that receives the alternating current signals form the speed sensors and converts them into digital form for the logic section. The logic section then analyzes the digitized signals to calculate any brake pressure changes needed. If impending lockup is sensed，the logic section sends commands to the modulator assembly.Modulator assemblyThe hydraulic modulator assembly regulates pressure to the wheel brakes when it receives commands from the control utuit. The modulator assembly can maintain or reduce pressure over the level it receives from the master cylinder，it also can never apply the brakes by itself. The modulator assembly consists of three high-speed electric solenoid valves，two fluid reservoirs and a turn delivery pump equipped with inlet and outlet check valves. The modulator electrical connector and controlling relays are concealed under a plastic cover of the assembly.Each front wheel is served by electric solenoid valve modulated independently by the control unit. The rear brakes are served by a single solenoid valve and modulated together using the select-low principle. During anti-braking system operation，the control unit cycles the solenoid valves to either hold or release pressure the brake lines. When pressure is released from the brake lines during anti-braking operation，it is routed to a fluid reservoir. There is one reservoir for the front brake circuit. The reservoirs are low-pressure accumulators that store fluid under slight spring pressure until the return delivery pump can return the fluid through the brake lines to the master cylinder.汽车制动系统制动系统是汽车中最重要的系统。

Automobile Brake SystemThe braking system is the most important system in cars. If the brakes fail, the result can be disastrous. Brakes are actually energy conversion devices, which convert the kinetic energy (momentum) of the vehicle into thermal energy (heat).When stepping on the brakes, the driver commands a stopping force ten times as powerful as the force that puts the car in motion. The braking system can exert thousands of pounds of pressure on each of the four brakes.Two complete independent braking systems are used on the car. They are the service brake and the parking brake.The service brake acts to slow, stop, or hold the vehicle during normal driving. They are foot-operated by the driver depressing and releasing the brake pedal. The primary purpose of the brake is to hold the vehicle stationary while it is unattended. The parking brake is mechanically operated by when a separate parking brake foot pedalor hand lever is set.The brake system is composed of the following basic components: the “master cylinder” which is located under the hood, and is directly connected to the brake pedal, converts driver foot’s mechanical pressure into hydraulic pressure. Steel “brake lines” and flexible “brake hoses” connect the master cylinder to the “slave cylinders” located at each wheel. Brake fluid, specially designed to work in extreme conditions, fills the system. “Shoes” and “pads” are pushed by the slave cylinders to contact the “drums” and “rotors” thus causing drag, which (hopefully) slows the car.The typical brake system consists of disk brakes in front and either disk or drum brakes in the rear connected by a system of tubes and hoses that link the brake at each wheel to the master cylinder (Figure).Basically, all car brakes are friction brakes. When the driver applies the brake, the control device forces brake shoes, or pads, against the rotating brake drum or disks at wheel. Friction between the shoes or pads and the drums or disks then slows or stops the wheel so that the car is braked.In most modern brake systems (see Figure 15.1), there is a fluid-filled cylinder, called master cylinder, which contains two separate sections, there is a piston in each section and both pistons are connected to a brake pedal in the driver’s compartment. When the brake is pushed down, brake fluid is sent from the master cylinder to the wheels.At the wheels, the fluid pushes shoes, or pads, against revolving drums or disks. The friction between the stationary shoes, or pads, and the revolving drums or disks slows and stops them. This slows or stops the revolving wheels, which, in turn, slow or stop the car.The brake fluid reservoir is on top of the master cylinder. Most cars today have a transparent r reservoir so that you can see the level without opening the cover. The brake fluid level will drop slightly as the brake pads wear. This is a normal condition and no cause for concern. If the level drops noticeably over ashort period of time or goes down to about two thirds full, have your brakes checked as soon as possible. Keep the reservoir covered except for the amount of time you need to fill it and never leave a cam of brake fluid uncovered. Brake fluid must maintain a very high boiling point. Exposure to air will cause the fluid to absorb moisture which will lower that boiling point.The brake fluid travels from the master cylinder to the wheels through a series of steel tubes and reinforced rubber hoses. Rubber hoses are only used in places that require flexibility, such as at the front wheels, which move up and down as well as steer. The rest of the system uses non-corrosive seamless steel tubing with special fittings at all attachment points. If a steel line requires a repair, the best procedure is to replace the compete line. If this is not practical, a line can be repaired using special splice fittings that are made for brake system repair. You must never use copper tubing to repair a brake system. They are dangerous and illegal.Drum brakes, it consists of the brake drum, an expander, pull back springs, a stationary back plate, two shoes with friction linings, and anchor pins. The stationary back plate is secured to the flange of the axle housing or to the steering knuckle. The brake drum is mounted on the wheel hub. There is a clearance between the inner surface of the drum and the shoe lining. To apply brakes, the driver pushes pedal, the expander expands the shoes and presses them to the drum. Friction between the brake drum and the friction linings brakes the wheels and the vehicle stops. To releaseAnti-lock brake systems make braking safer and more convenient, Anti-lock brake systems modulate brake system hydraulic pressure to prevent the brakes from locking and the tires from skidding on slippery pavement or during a panic stop.Anti-lock brake systems have been used on aircraft for years, and some domestic car were offered with an early form of anti-lock braking in late 1990’s. Recently, several automakers have introduced more sophisticated anti-lock system. Investigations in Europe, where anti-lock brakin g systems have been available for a decade, have led one manufacture to state that the number of traffic accidents could be reduced by seven and a half percent if all cars had anti-lock brakes. So some sources predict that all cars will offer anti-lock brakes to improve the safety of the car.Anti-lock systems modulate brake application force several times per second to hold the tires at a controlled amount of slip; all systems accomplish this in basically the same way. One or more speed sensors generate alternating current signal whose frequency increases with the wheel rotational speed. An electronic control unit continuously monitors these signals and if the frequency of a signal drops too rapidly indicating that a wheel is about to lock, the control unit instructs a modulating device to reduce hydraulic pressure to the brake at the affected wheel. When sensor signals indicate the wheel is again rotating normally, the control unit allows increased hydraulic pressure to the brake. This release-apply cycle occurs several time per second to “pump” the brakes like a driver might but a t a much faster rate.In addition to their basic operation, anti-lock systems have two other things in common. First, they do not operate until the brakes are applied with enough force to lock or nearly lock a wheel. At all other times, the system stands ready to function but does not interfere with normal braking. Second, if the anti-lock system fail in any way, the brakes continue to operate without anti-lock capability. A warning light on the instrument panel alerts the driver when a problem exists in the anti-lock system.The current Bosch component Anti-lock Braking System (ABSⅡ), is a second generation design wildly used by European automakers such as BWM,Mercedes-Benz and Porsche. ABSⅡsystem consists of : four wheel speed sensor, electronic control unit and modulator assembly.A speed sensor is fitted at each wheel sends signals about wheel rotation to control unit. Each speed sensor consists of a sensor unit and a gear wheel. The front sensor mounts to the steering knuckle and its gear wheel is pressed onto the stub axle that rotates with the wheel. The rear sensor mounts the rear suspension member and its gear wheel is pressed onto the axle. The sensor itself is a winding with a magnetic core. The core creates a magnetic field around the winding, and as the teeth of the gear wheel move through this field, an alternating current is induced in the winding. The control unit monitors the rate o change in this frequency to determine impending brake lockup.The control unit’s function can be divided into three parts: signal processing, logic and safety circuitry. The signal processing section is the converter that receives the alternating current signals form the speed sensors and converts them into digital form for the logic section. The logic section then analyzes the digitized signals to calculate any brake pressure changes needed. If impending lockup is sensed, the logic section sends commands to the modulator assembly.Modulator assemblyThe hydraulic modulator assembly regulates pressure to the wheel brakes when it receives commands from the control utuit. The modulator assembly can maintain or reduce pressure over the level it receives from the master cylinder, it also can never apply the brakes by itself. The modulator assembly consists of three high-speed electric solenoid valves, two fluid reservoirs and a turn delivery pump equipped with inlet and outlet check valves. The modulator electrical connector and controlling relays are concealed under a plastic cover of the assembly.Each front wheel is served by electric solenoid valve modulated independently by the control unit. The rear brakes are served by a single solenoid valve and modulated together using the select-low principle. During anti-braking system operation, the control unit cycles the solenoid valves to either hold or release pressure the brake lines. When pressure is released from the brake lines during anti-braking operation, it is routed to a fluid reservoir. There is one reservoir for the front brake circuit. The reservoirs are low-pressure accumulators that store fluid under slight spring pressure until the return delivery pump can return the fluid through the brake lines to the master cylinder.汽车制动系统制动系统是汽车中最重要的系统。

Automobile Brake SystemThe braking system is the most important system in cars. If the brakes fail, the result can be disastrous. Brakes are actually energy conversion devices, which convert the kinetic energy (momentum) of the vehicle into thermal energy (heat).When stepping on the brakes, the driver commands a stopping force ten times as powerful as the force that puts the car in motion. The braking system can exert thousands of pounds of pressure on each of the four brakes.Two complete independent braking systems are used on the car. They are the service brake and the parking brake.The service brake acts to slow, stop, or hold the vehicle during normal driving. They are foot-operated by the driver depressing and releasing the brake pedal. The primary purpose of the brake is to hold the vehicle stationary while it is unattended. The parking brake is mechanically operated by when a separate parking brake foot pedal or hand lever is set.The brake system is composed of the following basic components: t he “master cylinder” which is located under the hood, and is directly connected to the brake pedal, converts driver foot’s mechanical pressure into hydraulic pressure. Steel “brake lines” and flexible “brake hoses” connect the master cylinder to the “slave cylinders” located at each wheel. Brake fluid, specially designed to work in extreme conditions, fills the system. “Shoes” and “pads” are pushed by the slave cylinders to contact the “drums” and “rotors” thus causing drag, which (hopefully) slows the car.The typical brake system consists of disk brakes in front and either disk or drum brakes in the rear connected by a system of tubes and hoses that link the brake at each wheel to the master cylinder (Figure).Basically, all car brakes are friction brakes. When the driver applies the brake, the control device forces brake shoes, or pads, against the rotating brake drum or disks at wheel. Friction between the shoes or pads and the drums or disks then slows or stops the wheel so that the car is braked.In most modern brake systems (see Figure 15.1), there is a fluid-filled cylinder, called master cylinder, which contains two separate sections, there is a piston in each section and both pistons are connected to a brake pedal in the driver’s compartment. When th e brake is pushed down, brake fluid is sent from the master cylinder to the wheels.At the wheels, the fluid pushes shoes, or pads, against revolving drums or disks. The friction between the stationary shoes, or pads, and the revolving drums or disks slows and stops them. This slows or stops the revolving wheels, which, in turn, slow or stop the car.The brake fluid reservoir is on top of the master cylinder. Most cars today have a transparent r reservoir so that you can see the level without opening the cover. The brake fluid level will drop slightly as the brake pads wear. This is a normal condition and no cause for concern. If the level drops noticeably over ashort period of time or goes down to about two thirds full, have your brakes checked as soon as possible. Keep the reservoir covered except for the amount of time you need to fill it and never leave a cam of brake fluid uncovered. Brake fluid must maintain a very high boiling point. Exposure to air will cause the fluid to absorb moisture which will lower that boiling point.The brake fluid travels from the master cylinder to the wheels through a series of steel tubes and reinforced rubber hoses. Rubber hoses are only used in places that require flexibility, such asat the front wheels, which move up and down as well as steer. The rest of the system uses non-corrosive seamless steel tubing with special fittings at all attachment points. If a steel line requires a repair, the best procedure is to replace the compete line. If this is not practical, a line can be repaired using special splice fittings that are made for brake system repair. You must never use copper tubing to repair a brake system. They are dangerous and illegal.Drum brakes, it consists of the brake drum, an expander, pull back springs, a stationary back plate, two shoes with friction linings, and anchor pins. The stationary back plate is secured to the flange of the axle housing or to the steering knuckle. The brake drum is mounted on the wheel hub. There is a clearance between the inner surface of the drum and the shoe lining. To apply brakes, the driver pushes pedal, the expander expands the shoes and presses them to the drum. Friction between the brake drum and the friction linings brakes the wheels and the vehicle stops. To release brakes, the driver release the pedal, the pull back spring retracts the shoes thus permitting free rotation of the wheels.Disk brakes, it has a metal disk instead of a drum. A flat shoe, or disk-brake pad, is located on each side of the disk. The shoes squeeze the rotatin g disk to stop the car. Fluid from the master cylinder forces the pistons to move in, toward the disk. This action pushes the friction pads tightly against the disk. The friction between the shoes and disk slows and stops it. This provides the braking action. Pistons are made of either plastic or metal. There are three general types of disk brakes. They are the floating-caliper type, the fixed-caliper type, and the sliding-caliper type. Floating-caliper and sliding-caliper disk brakes use a single piston. Fixed-caliper disk brakes have either two or four pistons.The brake system assemblies are actuated by mechanical, hydraulic or pneumatic devices. The mechanical leverage is used in the parking brakes fitted in all automobile. When the brake pedal is depressed, the rod pushes the piston of brake master cylinder which presses the fluid. The fluid flows through the pipelines to the power brake unit and then to the wheel cylinder. The fluid pressure expands the cylinder pistons thus pressing the shoes to the drum or disk. If the pedal is released, the piston returns to the initialposition, the pull back springs retract the shoes, the fluid is forced back to the master cylinder and braking ceases.The primary purpose of the parking brake is to hold the vehicle stationary while it is unattended. The parking brake is mechanically operated by the driver when a separate parking braking hand lever is set. The hand brake is normally used when the car has already stopped. A lever is pulled and t he rear brakes are approached and locked in the “on” position. The car may now be left without fear of its rolling away. When the driver wants to move the car again, he must press a button before the lever can be released. The hand brake must also be able to stop the car in the event of the foot brake failing. For this reason, it is separate from the foot brake uses cable or rods instead of the hydraulic system.Anti-lock Brake SystemAnti-lock brake systems make braking safer and more convenient, Anti-lock brake systems modulate brake system hydraulic pressure to prevent the brakes from locking and the tires from skidding on slippery pavement or during a panic stop.Anti-lock brake systems have been used on aircraft for years, and some domestic car were offered with an early form of anti-lock braking in late 1990’s. Recently, several automakers have introduced more sophisticated anti-lock system. Investigations in Europe, where anti-lock brakin g systems have been available for a decade, have led one manufacture to state that the number oftraffic accidents could be reduced by seven and a half percent if all cars had anti-lock brakes. So some sources predict that all cars will offer anti-lock brakes to improve the safety of the car.Anti-lock systems modulate brake application force several times per second to hold the tires at a controlled amount of slip; all systems accomplish this in basically the same way. One or more speed sensors generate alternating current signal whose frequency increases with the wheel rotational speed. An electronic control unit continuously monitors these signals and if the frequency of a signal drops too rapidly indicating that a wheel is about to lock, the control unit instructs a modulating device to reduce hydraulic pressure to the brake at the affected wheel. When sensor signals indicate the wheel is again rotating normally, the control unit allows increased hydraulic pressure to the brake. This release-apply cycle occurs several time per second to “pump” the brakes like a dr iver might but at a much faster rate.In addition to their basic operation, anti-lock systems have two other things in common. First, they do not operate until the brakes are applied with enough force to lock or nearly lock a wheel. At all other times, the system stands ready to function but does not interfere with normal braking. Second, if the anti-lock system fail in any way, the brakes continue to operate without anti-lock capability. A warning light on the instrument panel alerts the driver when a problem exists in the anti-lock system.The current Bosch component Anti-lock Braking System (ABSⅡ), is a second generation design wildly used by European automakers such as BWM, Mercedes-Benz and Porsche. ABSⅡsystem consists of : four wheel speed sensor, electronic control unit and modulator assembly.A speed sensor is fitted at each wheel sends signals about wheel rotation to control unit. Each speed sensor consists of a sensor unit and a gear wheel. The front sensor mounts to the steering knuckle and its gear wheel is pressed onto the stub axle that rotates with the wheel. The rear sensor mounts the rear suspension member and its gear wheel is pressed onto the axle. The sensor itself is a winding with a magnetic core. The core creates a magnetic field around the winding, and as the teeth of the gear wheel move through this field, an alternating current is induced in the winding. The control unit monitors the rate o change in this frequency to determine impending brake lockup.The control unit’s functi on can be divided into three parts: signal processing, logic and safety circuitry. The signal processing section is the converter that receives the alternating current signals form the speed sensors and converts them into digital form for the logic section. The logic section then analyzes the digitized signals to calculate any brake pressure changes needed. If impending lockup is sensed, the logic section sends commands to the modulator assembly.Modulator assemblyThe hydraulic modulator assembly regulates pressure to the wheel brakes when it receives commands from the control utuit. The modulator assembly can maintain or reduce pressure over the level it receives from the master cylinder, it also can never apply the brakes by itself. The modulator assembly consists of three high-speed electric solenoid valves, two fluid reservoirs and a turn delivery pump equipped with inlet and outlet check valves. The modulator electrical connector and controlling relays are concealed under a plastic cover of the assembly.Each front wheel is served by electric solenoid valve modulated independently by the control unit. The rear brakes are served by a single solenoid valve and modulated together using the select-low principle. During anti-braking system operation, the control unit cycles the solenoid valves to either hold or release pressure the brake lines. When pressure is released from the brakelines during anti-braking operation, it is routed to a fluid reservoir. There is one reservoir for the front brake circuit. The reservoirs are low-pressure accumulators that store fluid under slight spring pressure until the return delivery pump can return the fluid through the brake lines to the master cylinder.汽车制动系统制动系统是汽车中最重要的系统。

汽车制动系统-英文文献及翻译————————————————————————————————作者：————————————————————————————————日期：Brake systemsWe all know that pushing down on the brake pedal slows a car to a stop. But how does this happen? How does your car transmit the force from your leg to its wheels? How does it multiply the force so that it is enough to stop something as big as a car?Brake Image GalleryLayout of typical brake system. See more brake images.When you depress your brake pedal, your car transmits the force from your foot to its brakes through a fluid. Since the actual brakes require a much greater force than you could apply with your leg, your car must also multiply the force of your foot. It does this in two ways:•Mechanical advantage (leverage)•Hydraulic force multiplicationThe brakes transmit the force to the tires using friction, and the tires transmit that force to the road using friction also. Before we begin our discussion on the components of the brake system, we'll cover these three principles:•Leverage•Hydraulics•FrictionLeverage and HydraulicsIn the figure below, a force F is being applied to the left end of the lever. The left end of the lever is twice as long (2X) as the right end (X). Therefore, on the right end of the lever a force of 2F is available, but it acts through half of the distance (Y) that the left end moves (2Y). Changing the relative lengths of the left and right ends of the lever changes the multipliers.The pedal is designed in such a way that it can multiply the force from yourleg several times before any force is even transmitted to the brake fluid.The basic idea behind any hydraulic system is very simple: Force applied at one point is transmitted to another point using an incompressible fluid, almost always an oil of some sort. Most brake systems also multiply the force in the process. Here you can see the simplest possible hydraulic system:Your browser does not support JavaScript or it is disabled.Simple hydraulic systemIn the figure above, two pistons (shown in red) are fit into two glass cylinders filled with oil (shown in light blue) and connected to one another with an oil-filled pipe. If youapply a downward force to one piston (the left one, in this drawing), then the force is transmitted to the second piston through the oil in the pipe. Since oil is incompressible, the efficiency is very good -- almost all of the applied force appears at the second piston. The great thing about hydraulic systems is that the pipe connecting the two cylinders can be any length and shape, allowing it to snake through all sorts of things separating the twopistons. The pipe can also fork, so that one master cylinder can drive more than one slave cylinder if desired, as shown in here:Your browser does not support JavaScript or it is disabled.Master cylinder with two slavesThe other neat thing about a hydraulic system is that it makes force multiplication (or division) fairly easy. If you have read How a Block and Tackle Works or How Gear Ratios Work, then you know that trading force for distance is very common in mechanical systems. In a hydraulic system, all you have to do is change the size of one piston and cylinder relative to the other, as shown here:Your browser does not support JavaScript or it is disabled.Hydraulic multiplicationTo determine the multiplication factor in the figure above, start by looking at the size of the pistons. Assume that the piston on the left is 2 inches (5.08 cm) in diameter (1-inch / 2.54 cm radius), while the piston on the right is 6 inches (15.24 cm) in diameter (3-inch / 7.62 cm radius). The area of the two pistons is Pi * r2. The area of the left piston is therefore 3.14, while the area of the piston on the right is 28.26. The piston on the right is nine times larger than the piston on the left. This means that any force applied to theleft-hand piston will come out nine times greater on the right-hand piston. So, if you apply a 100-pound downward force to the left piston, a 900-pound upward force will appear on the right. The only catch is that you will have to depress the left piston 9 inches (22.86 cm) to raise the right piston 1 inch (2.54 cm).A Simple Brake SystemBefore we get into all the parts of an actual car brake system, let's look at a simplified system:Your browser does not support JavaScript or it is disabled.A simple brake systemYou can see that the distance from the pedal to the pivot is four times the distance from the cylinder to the pivot, so the force at the pedal will be increased by a factor of four before it is transmitted to the cylinder.You can also see that the diameter of the brake cylinder is three times the diameter of the pedal cylinder. This further multiplies the force by nine. All together, this system increases the force of your foot by a factor of 36. If you put 10 pounds of force on the pedal, 360 pounds (162 kg) will be generated at the wheel squeezing the brake pads.There are a couple of problems with this simple system. What if we have a leak? If it is a slow leak, eventually there will not be enough fluid left to fill the brake cylinder, and the brakes will not function. If it is a major leak, then the first time you apply the brakes all of the fluid will squirt out the leak and you will have complete brake failure.Drum brakes work on the same principle as disc brakes: Shoes press against a spinning surface. In this system, that surface is called a drum.Figure 1. Location of drum brakes. See more drum brakepictures.Many cars have drum brakes on the rear wheels and disc brakes on the front. Drum brakes have more parts than disc brakes and are harder to service, but they are less expensive to manufacture, and they easily incorporate an emergency brake mechanism.In this edition of HowStuffWorks, we will learn exactly how a drum brake system works, examine the emergency brake setup and find out what kind of servicing drum brakes need.Figure 2. Drum brake with drum in placeFigure 3. Drum brake without drum in placeLet's start with the basics.The Drum BrakeThe drum brake may look complicated, and it can be pretty intimidating when you open one up. Let's break it down and explain what each piece does.Figure 4. Parts of a drum brakeLike the disc brake, the drum brake has two brake shoes and a piston. But the drum brake also has an adjuster mechanism, an emergency brake mechanism and lots of springs.First, the basics: Figure 5 shows only the parts that provide stopping power.Your browser does not support JavaScript or it isdisabled.Figure 5. Drum brake in operationWhen you hit the brake pedal, the piston pushes the brake shoes against the drum. That's pretty straightforward, but why do we need all of those springs?This is where it gets a little more complicated. Many drum brakes are self-actuating. Figure 5 shows that as the brake shoes contact the drum, there is a kind of wedging action, which has the effect of pressing the shoes into the drum with more force.The extra braking force provided by the wedging action allows drum brakes to use a smaller piston than disc brakes. But, because of the wedging action, the shoes must be pulled away from the drum when the brakes are released. This is the reason for some of the springs. Other springs help hold the brake shoes in place and return the adjuster arm after it actuates.Brake AdjusterFor the drum brakes to function correctly, the brake shoes must remain close to the drum without touching it. If they get too far away from the drum (as the shoes wear down, for instance), the piston will require more fluid to travel that distance, and your brake pedal will sink closer to the floor when you apply the brakes. This is why most drum brakes have an automatic adjuster.Figure 6. Adjuster mechanismNow let's add in the parts of the adjuster mechanism. The adjuster uses theself-actuation principle we discussed above.Your browser does not support JavaScript or it is disabled.Figure 7. Drum brake adjuster in operationIn Figure 7, you can see that as the pad wears down, more space will form between the shoe and the drum. Each time the car stops while in reverse, the shoe is pulled tight against the drum. When the gap gets big enough, the adjusting lever rocks enough to advance the adjuster gear by one tooth. The adjuster has threads on it, like a bolt, so that it unscrews a little bit when it turns, lengthening to fill in the gap. When the brake shoes wear a little more, the adjuster can advance again, so it always keeps the shoes close to the drum.Some cars have an adjuster that is actuated when the emergency brake is applied. This type of adjuster can come out of adjustment if the emergency brake is not used forlong periods of time. So if you have this type of adjuster, you should apply your emergency brake at least once a week.ServicingThe most common service required for drum brakes is changing the brake shoes. Some drum brakes provide an inspection hole on the back side, where you can see how much material is left on the shoe. Brake shoes should be replaced when the friction material has worn down to within 1/32 inch (0.8 mm) of the rivets. If the friction material is bonded to the backing plate (no rivets), then the shoes should be replaced when they have only 1/16 inch (1.6 mm) of material left.Photo courtesy of a local AutoZone storeFigure 9. Brake shoeJust as in disc brakes, deep scores sometimes get worn into brake drums. If aworn-out brake shoe is used for too long, the rivets that hold the friction material to the backing can wear grooves into the drum. A badly scored drum can sometimes be repaired by refinishing. Where disc brakes have a minimum allowable thickness, drum brakes have a maximum allowable diameter. Since the contact surface is the inside of the drum, as you remove material from the drum brake the diameter gets bigger.Figure 10. Brake drum制动系统众所周知，踩下制动踏板可以使汽车减速至停止。

汽车制动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)Brake systemsWe all know that pushing down on the brake pedal slows a car to a stop. But how does this happen? How does your car transmit the force from your leg to its wheels? How does it multiply the force so that it is enough to stop something as big as a car?Brake Image GalleryLayout of typical brake system. See more brake images.When you depress your brake pedal, your car transmits the force from your foot to its brakes through a fluid. Since the actual brakes require a much greater force than you could apply with your leg, your car must also multiply the force of your foot. It does this in two ways:∙Mechanical advantage (leverage)∙Hydraulic force multiplicationThe brakes transmit the force to the tires using friction, and the tires transmit that force to the road using friction also. Before we begin our discussion on the components of the brake system, we'll cover these three principles:∙Leverage∙Hydraulics∙FrictionLeverage and HydraulicsIn the figure below, a force F is being applied to the left end of the lever. The left end of the lever is twice as long (2X) as the right end (X). Therefore, on the right end of the lever a force of 2F is available, but it acts through half of the distance (Y) that the left end moves (2Y). Changing the relative lengths of the left and right ends of the lever changes the multipliers.The pedal is designed in such a way that it can multiply the force from yourleg several times before any force is even transmitted to the brake fluid.The basic idea behind any hydraulic system is very simple: Force applied at one point is transmitted to another point using an incompressible fluid, almost always an oil of some sort. Most brake systems also multiply the force in the process. Here you can see the simplest possible hydraulic system:Your browser does not support JavaScript or it is disabled.Simple hydraulic systemIn the figure above, two pistons (shown in red) are fit into two glass cylinders filled with oil (shown in light blue) and connected to one another with an oil-filled pipe. If youapply a downward force to one piston (the left one, in this drawing), then the force is transmitted to the second piston through the oil in the pipe. Since oil is incompressible, the efficiency is very good -- almost all of the applied force appears at the second piston. The great thing about hydraulic systems is that the pipe connecting the two cylinders can be any length and shape, allowing it to snake through all sorts of things separating the twopistons. The pipe can also fork, so that one master cylinder can drive more than one slave cylinder if desired, as shown in here:Your browser does not support JavaScript or it is disabled.Master cylinder with two slavesThe other neat thing about a hydraulic system is that it makes force multiplication (or division) fairly easy. If you have read How a Block and Tackle Works or How Gear Ratios Work, then you know that trading force for distance is very common in mechanical systems. In a hydraulic system, all you have to do is change the size of one piston and cylinder relative to the other, as shown here:Your browser does not support JavaScript or it is disabled.Hydraulic multiplicationTo determine the multiplication factor in the figure above, start by looking at the size of the pistons. Assume that the piston on the left is 2 inches (5.08 cm) in diameter (1-inch / 2.54 cm radius), while the piston on the right is 6 inches (15.24 cm) in diameter (3-inch / 7.62 cm radius). The area of the two pistons is Pi * r2. The area of the left piston is therefore 3.14, while the area of the piston on the right is 28.26. The piston on the right is nine times larger than the piston on the left. This means that any force applied to theleft-hand piston will come out nine times greater on the right-hand piston. So, if you apply a 100-pound downward force to the left piston, a 900-pound upward force will appear on the right. The only catch is that you will have to depress the left piston 9 inches (22.86 cm) to raise the right piston 1 inch (2.54 cm).A Simple Brake SystemBefore we get into all the parts of an actual car brake system, let's look at a simplified system:Your browser does not support JavaScript or it is disabled.A simple brake systemYou can see that the distance from the pedal to the pivot is four times the distance from the cylinder to the pivot, so the force at the pedal will be increased by a factor of four before it is transmitted to the cylinder.You can also see that the diameter of the brake cylinder is three times the diameter of the pedal cylinder. This further multiplies the force by nine. All together, this system increases the force of your foot by a factor of 36. If you put 10 pounds of force on the pedal, 360 pounds (162 kg) will be generated at the wheel squeezing the brake pads.There are a couple of problems with this simple system. What if we have a leak? If it is a slow leak, eventually there will not be enough fluid left to fill the brake cylinder, and the brakes will not function. If it is a major leak, then the first time you apply the brakes all of the fluid will squirt out the leak and you will have complete brake failure.Drum brakes work on the same principle as disc brakes: Shoes press against a spinning surface. In this system, that surface is called a drum.Figure 1. Location of drum brakes. See more drum brakepictures.Many cars have drum brakes on the rear wheels and disc brakes on the front. Drum brakes have more parts than disc brakes and are harder to service, but they are less expensive to manufacture, and they easily incorporate an emergency brake mechanism.In this edition of HowStuffWorks, we will learn exactly how a drum brake system works, examine the emergency brake setup and find out what kind of servicing drum brakes need.Figure 2. Drum brake with drum in placeFigure 3. Drum brake without drum in placeLet's start with the basics.The Drum BrakeThe drum brake may look complicated, and it can be pretty intimidating when you open one up. Let's break it down and explain what each piece does.Figure 4. Parts of a drum brakeLike the disc brake, the drum brake has two brake shoes and a piston. But the drum brake also has an adjuster mechanism, an emergency brake mechanism and lots of springs.First, the basics: Figure 5 shows only the parts that provide stopping power.Your browser does not support JavaScript or it is disabled.Figure 5. Drum brake in operationWhen you hit the brake pedal, the piston pushes the brake shoes against the drum. That's pretty straightforward, but why do we need all of those springs?This is where it gets a little more complicated. Many drum brakes are self-actuating. Figure 5 shows that as the brake shoes contact the drum, there is a kind of wedging action, which has the effect of pressing the shoes into the drum with more force.The extra braking force provided by the wedging action allows drum brakes to use a smaller piston than disc brakes. But, because of the wedging action, the shoes must be pulled away from the drum when the brakes are released. This is the reason for some of the springs. Other springs help hold the brake shoes in place and return the adjuster arm after it actuates.Brake AdjusterFor the drum brakes to function correctly, the brake shoes must remain close to the drum without touching it. If they get too far away from the drum (as the shoes wear down, for instance), the piston will require more fluid to travel that distance, and your brake pedal will sink closer to the floor when you apply the brakes. This is why most drum brakes have an automatic adjuster.Figure 6. Adjuster mechanismNow let's add in the parts of the adjuster mechanism. The adjuster uses theself-actuation principle we discussed above.Your browser does not support JavaScript or it is disabled.Figure 7. Drum brake adjuster in operationIn Figure 7, you can see that as the pad wears down, more space will form between the shoe and the drum. Each time the car stops while in reverse, the shoe is pulled tight against the drum. When the gap gets big enough, the adjusting lever rocks enough to advance the adjuster gear by one tooth. The adjuster has threads on it, like a bolt, so that it unscrews a little bit when it turns, lengthening to fill in the gap. When the brake shoes wear a little more, the adjuster can advance again, so it always keeps the shoes close to the drum.Some cars have an adjuster that is actuated when the emergency brake is applied. This type of adjuster can come out of adjustment if the emergency brake is not used forlong periods of time. So if you have this type of adjuster, you should apply your emergency brake at least once a week.ServicingThe most common service required for drum brakes is changing the brake shoes. Some drum brakes provide an inspection hole on the back side, where you can see how much material is left on the shoe. Brake shoes should be replaced when the friction material has worn down to within 1/32 inch (0.8 mm) of the rivets. If the friction material is bonded to the backing plate (no rivets), then the shoes should be replaced when they have only 1/16 inch (1.6 mm) of material left.Photo courtesy of a local AutoZone storeFigure 9. Brake shoeJust as in disc brakes, deep scores sometimes get worn into brake drums. If aworn-out brake shoe is used for too long, the rivets that hold the friction material to the backing can wear grooves into the drum. A badly scored drum can sometimes be repaired by refinishing. Where disc brakes have a minimum allowable thickness, drum brakes have a maximum allowable diameter. Since the contact surface is the inside of the drum, as you remove material from the drum brake the diameter gets bigger.Figure 10. Brake drum制动系统众所周知，踩下制动踏板可以使汽车减速至停止。

Automobile Brake SystemThe braking system is the most important system in cars. If the brakes fail, the result can be disastrous. Brakes are actually energy conversion devices, which convert the kinetic energy (momentum) of the vehicle into thermal energy (heat).When stepping on the brakes, the driver commands a stopping force ten times as powerful as the force that puts the car in motion. The braking system can exert thousands of pounds of pressure on each of the four brakes.Two complete independent braking systems are used on the car. They are the service brake and the parking brake.The service brake acts to slow, stop, or hold the vehicle during normal driving. They are foot-operated by the driver depressing and releasing the brake pedal. The primary purpose of the brake is to hold the vehicle stationary while it is unattended. The parking brake is mechanically operated by when a separate parking brake foot pedal or hand lever is set.The brake system is composed of the following basic components: t he “master cylinder” which is located under the hood, and is directly connected to the brake pedal, converts driver foot’s mechanical pressure into hydraulic pressure. Steel “brake lines” and flexible “brake hoses” connect the master cylinder to the “slave cylinders” located at each wheel. Brake fluid, specially designed to work in extreme conditions, fills the system. “Shoes” and “pads” are pushed by the slave cylinders to contact the “drums” and “rotors” thus causing drag, which (hopefully) slows the car.The typical brake system consists of disk brakes in front andeither disk or drum brakes in the rear connected by a system of tubesand hoses that link the brake at each wheel to the master cylinder (Figure).Basically, all car brakes are friction brakes. When the driver applies the brake, the control device forces brake shoes, or pads, against the rotating brake drum or disks at wheel. Friction between the shoes or pads and the drums or disks then slows or stops the wheel sothat the car is braked.In most modern brake systems (see Figure 15.1), there is a fluid-filled cylinder, called master cylinder, which contains two separate sections, there is a piston in each section and both pistons are connected to a brake pedal in the driver’s compartme nt. When th e brake is pushed down, brake fluid is sent from the master cylinder to the wheels.At the wheels, the fluid pushes shoes, or pads, against revolving drums or disks. The friction between the stationary shoes, or pads, and the revolving drums or disks slows and stops them. This slows or stops the revolving wheels, which, in turn, slow or stop the car.The brake fluid reservoir is on top of the master cylinder. Most cars today have a transparent r reservoir so that you can see the level without opening the cover. The brake fluid level will drop slightly as the brake pads wear. This is a normal condition and no cause for concern. If the level drops noticeably over ashort period of time or goes down to about two thirds full, have your brakes checked as soon as possible. Keep the reservoir covered except for the amount of time you need tofill it and never leave a cam of brake fluid uncovered. Brake fluid must maintain a very high boiling point. Exposure to air will cause the fluid to absorb moisture which will lower that boiling point.The brake fluid travels from the master cylinder to the wheels through a series of steel tubes and reinforced rubber hoses. Rubber hoses are only used in places that require flexibility, such asat the front wheels, which move up and down as well as steer. The rest of the system uses non-corrosive seamless steel tubing with special fittings at all attachment points. If a steel line requires a repair, the best procedure is to replace the compete line. If this is not practical, a line can be repaired using special splice fittings that are made for brake system repair. You must never use copper tubing to repair a brake system. They are dangerous and illegal.Drum brakes, it consists of the brake drum, an expander, pull back springs, a stationary back plate, two shoes with friction linings, and anchor pins. The stationary back plate is secured to the flange of the axle housing or to the steering knuckle. The brake drum is mounted on the wheel hub. There is a clearance between the inner surface of the drum and the shoe lining. To apply brakes, the driver pushes pedal, the expander expands the shoes and presses them to the drum. Friction between the brake drum and the friction linings brakes the wheels and the vehicle stops. To release brakes, the driver release the pedal, the pull back spring retracts the shoes thus permitting free rotation of the wheels.Disk brakes, it has a metal disk instead of a drum. A flat shoe, or disk-brake pad, is located on each side of the disk. The shoes squeezethe rotatin g disk to stop the car. Fluid from the master cylinderforces the pistons to move in, toward the disk. This action pushes the friction pads tightly against the disk. The friction between the shoes and disk slows and stops it. This provides the braking action. Pistons are made of either plastic or metal. There are three general types of disk brakes. They are the floating-caliper type, the fixed-caliper type, and the sliding-caliper type. Floating-caliper and sliding-caliper disk brakes use a single piston. Fixed-caliper disk brakes have either two or four pistons.The brake system assemblies are actuated by mechanical, hydraulicor pneumatic devices. The mechanical leverage is used in the parking brakes fitted in all automobile. When the brake pedal is depressed, the rod pushes the piston of brake master cylinder which presses the fluid. The fluid flows through the pipelines to the power brake unit and thento the wheel cylinder. The fluid pressure expands the cylinder pistons thus pressing the shoes to the drum or disk. If the pedal is released, the piston returns to the initialposition, the pull back springs retract the shoes, the fluid is forced back to the master cylinder and braking ceases.The primary purpose of the parking brake is to hold the vehicle stationary while it is unattended. The parking brake is mechanically operated by the driver when a separate parking braking hand lever is set. The hand brake is normally used when the car has already stopped. Alever is pulled and t he rear brakes are approached and locked in the “on” position. The car may now be left without fear of its rolling away. When the driver wants to move the car again, he must press abutton before the lever can be released. The hand brake must also beable to stop the car in the event of the foot brake failing. For this reason, it is separate from the foot brake uses cable or rods instead of the hydraulic system.Anti-lock Brake SystemAnti-lock brake systems make braking safer and more convenient,Anti-lock brake systems modulate brake system hydraulic pressure to prevent the brakes from locking and the tires from skidding on slippery pavement or during a panic stop.Anti-lock brake systems have been used on aircraft for years, and some domestic car were offered with an early form of anti-lock braking in late 1990’s. Recently, several automakers have introduced more sophisticated anti-lock system. Investigations in Europe, where anti-lock brakin g systems have been available for a decade, have led one manufacture to state that the number oftraffic accidents could be reduced by seven and a half percent if all cars had anti-lock brakes. So some sources predict that all carswill offer anti-lock brakes to improve the safety of the car.Anti-lock systems modulate brake application force several times per second to hold the tires at a controlled amount of slip; all systems accomplish this in basically the same way. One or more speed sensors generate alternating current signal whose frequency increases with the wheel rotational speed. An electronic control unit continuously monitors these signals and if the frequency of a signal drops too rapidly indicating that a wheel is about to lock, the control unit instructs a modulating device to reduce hydraulic pressure to the brake at theaffected wheel. When sensor signals indicate the wheel is again rotating normally, the control unit allows increased hydraulic pressure to the brake. This release-apply cycle occurs several time per second to “pump” the brakes like a dr iver might but at a much faster rate.In addition to their basic operation, anti-lock systems have two other things in common. First, they do not operate until the brakes are applied with enough force to lock or nearly lock a wheel. At all other times, the system stands ready to function but does not interfere with normal braking. Second, if the anti-lock system fail in any way, the brakes continue to operate without anti-lock capability. A warning light on the instrument panel alerts the driver when a problem exists in the anti-lock system.The current Bosch component Anti-lock Braking System (ABSⅡ), is a second generation design wildly used by European automakers such as BWM, Mercedes-Benz and Porsche. ABSⅡsystem consists of : fou r wheel speed sensor, electronic control unit and modulator assembly.A speed sensor is fitted at each wheel sends signals about wheel rotation to control unit. Each speed sensor consists of a sensor unitand a gear wheel. The front sensor mounts to the steering knuckle andits gear wheel is pressed onto the stub axle that rotates with the wheel. The rear sensor mounts the rear suspension member and its gear wheel is pressed onto the axle. The sensor itself is a winding with a magnetic core. The core creates a magnetic field around the winding, and as the teeth of the gear wheel move through this field, an alternating current is induced in the winding. The control unit monitors the rate o changein this frequency to determine impending brake lockup.The control unit’s functi on can be divided into three parts:signal processing, logic and safety circuitry. The signal processing section is the converter that receives the alternating current signals form the speed sensors and converts them into digital form for the logic section. The logic section then analyzes the digitized signals to calculate any brake pressure changes needed. If impending lockup is sensed, the logic section sends commands to the modulator assembly.Modulator assemblyThe hydraulic modulator assembly regulates pressure to the wheel brakes when it receives commands from the control utuit. The modulator assembly can maintain or reduce pressure over the level it receives from the master cylinder, it also can never apply the brakes by itself. The modulator assembly consists of three high-speed electric solenoid valves, two fluid reservoirs and a turn delivery pump equipped with inlet and outlet check valves. The modulator electrical connector and controlling relays are concealed under a plastic cover of the assembly.Each front wheel is served by electric solenoid valve modulated independently by the control unit. The rear brakes are served by asingle solenoid valve and modulated together using the select-low principle. During anti-braking system operation, the control unit cycles the solenoid valves to either hold or release pressure the brake lines. When pressure is released from the brakelines during anti-braking operation, it is routed to a fluid reservoir. There is one reservoir for the front brake circuit. The reservoirs are low-pressure accumulators that store fluid under slightspring pressure until the return delivery pump can return the fluid through the brake lines to the master cylinder.汽车制动系统制动系统是汽车中最重要的系统。

Automobile Brake System汽车制动系统The braking system is the most important system in cars. If the brakes fail, the result can be disastrous. Brakes are actually energy conversion devices, which convert the kinetic energy (momentum) of the vehicle into thermal energy (heat).When stepping on the brakes, the driver commands a stopping force ten times as powerful as the force that puts the car in motion. The braking system can exert thousands of pounds of pressure on each of the four brakes.Two complete independent braking systems are used on the car. They are the service brake and the parking brake.The service brake acts to slow, stop, or hold the vehicle during normal driving. They are foot-operated by the driver depressing and releasing the brake pedal. The primary purpose of the brake is to hold the vehicle stationary while it is unattended. The parking brake is mechanically operated by when a separate parking brake foot pedalor hand lever is set.The brake system is composed of the following basic components: the “master cylinder” which is located under the hood, and is directly connected to the brake pedal, converts driver foot’s mechanical pressure into hydraulic pressure. Steel “brake lines” and flexible “brake hoses” connect the master cylinder to the “slave cylinders” located at each wheel. Brake fluid, specially designed to work in extreme conditions, fills the system. “Shoes” and “pads” are pushed by the slave cylinders to contact the “drums” and “rotors” thus causing drag, which (hopefully) slows the c ar.The typical brake system consists of disk brakes in front and either disk or drum brakes in the rear connected by a system of tubes and hoses that link the brake at each wheel to the master cylinder (Figure).Basically, all car brakes are friction brakes. When the driver applies the brake, the control device forces brake shoes, or pads, against the rotating brake drum or disks at wheel. Friction between the shoes or pads and the drums or disks then slows or stops the wheel so that the car is braked.In most modern brake systems (see Figure 15.1), there is a fluid-filled cylinder, called master cylinder, which contains two separate sections, there is a piston in each section and both pistons are connected to a brake pedal in the driver’s compartment. When the brake is pushed down, brake fluid is sent from the master cylinder to the wheels.At the wheels, the fluid pushes shoes, or pads, against revolving drums or disks. The friction between the stationary shoes, or pads, and the revolving drums or disks slows and stops them. This slows or stops the revolving wheels, which, in turn, slow or stop the car.The brake fluid reservoir is on top of the master cylinder. Most cars today have a transparent r reservoir so that you can see the level without opening the cover. The brake fluid level will drop slightly as the brake pads wear. This is a normal condition and no cause for concern. If the level drops noticeably over ashort period of time or goes down to about two thirds full, have your brakes checked as soon as possible. Keep the reservoir covered except for the amount of time you need to fill it and never leave a cam of brake fluid uncovered. Brake fluid must maintain a very high boiling point. Exposure to air will cause the fluid to absorb moisture which will lower that boiling point.The brake fluid travels from the master cylinder to the wheels through a series of steel tubes and reinforced rubber hoses. Rubber hoses are only used in places that require flexibility, such as at the front wheels, which move up and down as well as steer. The rest of the system uses non-corrosive seamless steel tubing with special fittings at all attachment points. If a steel line requires a repair, the best procedure is to replace the compete line. If this is not practical, a line can be repaired using special splice fittings that are made for brake system repair. You must never use copper tubing to repair a brake system. They are dangerous and illegal.Drum brakes, it consists of the brake drum, an expander, pull back springs, a stationary back plate, two shoes with friction linings, and anchor pins. The stationary back plate is secured to the flange of the axle housing or to the steering knuckle. The brake drum is mounted on the wheel hub. There is a clearance between the inner surface of the drum and the shoe lining. To apply brakes, the driver pushes pedal, the expander expands the shoes and presses them to the drum. Friction between the brake drum and the friction linings brakes the wheels and the vehicle stops. To releasebrakes, the driver release the pedal, the pull back spring retracts the shoes thus permitting free rotation of the wheels.Disk brakes, it has a metal disk instead of a drum. A flat shoe, or disk-brake pad, is located on each side of the disk. The shoes squeeze the rotatin g disk to stop the car. Fluid from the master cylinder forces the pistons to move in, toward the disk. This action pushes the friction pads tightly against the disk. The friction between the shoes and disk slows and stops it. This provides the braking action. Pistons are made of either plastic or metal. There are three general types of disk brakes. They are the floating-caliper type, the fixed-caliper type, and the sliding-caliper type.Floating-caliper and sliding-caliper disk brakes use a single piston. Fixed-caliper disk brakes have either two or four pistons.The brake system assemblies are actuated by mechanical, hydraulic or pneumatic devices. The mechanical leverage is used in the parking brakes fitted in all automobile. When the brake pedal is depressed, the rod pushes the piston of brake master cylinder which presses the fluid. The fluid flows through the pipelines to the power brake unit and then to the wheel cylinder. The fluid pressure expands the cylinder pistons thus pressing the shoes to the drum or disk. If the pedal is released, the piston returns to the initialposition, the pull back springs retract the shoes, the fluid is forced back to the master cylinder and braking ceases.The primary purpose of the parking brake is to hold the vehicle stationary while it is unattended. The parking brake is mechanically operated by the driver when a separate parking braking hand lever is set. The hand brake is normally used when the car has already stopped. A lever is pulled and the rear brakes are approached and locked in the “on” position. The car may now be left without fear of its rolling away. When the driver wants to move the car again, he must press a button before the lever can be released. The hand brake must also be able to stop the car in the event of the foot brake failing. For this reason, it is separate from the foot brake uses cable or rods instead of the hydraulic system.Anti-lock Brake SystemAnti-lock brake systems make braking safer and more convenient, Anti-lock brake systems modulate brake system hydraulic pressure to prevent the brakes from locking and the tires from skidding on slippery pavement or during a panic stop.Anti-lock brake systems have been used on aircraft for years, and some domestic car were offered with an early form of anti-lock braking in late 1990’s. Recently, several automakers have introduced more sophisticated anti-lock system. Investigations in Europe, where anti-lock brakin g systems have been available for a decade, have led one manufacture to state that the number of traffic accidents could be reduced by seven and a half percent if all cars had anti-lock brakes. So some sources predict that all cars will offer anti-lock brakes to improve the safety of the car.Anti-lock systems modulate brake application force several times per second to hold the tires at a controlled amount of slip; all systems accomplish this in basically the same way. One or more speed sensors generate alternating current signal whose frequency increases with the wheel rotational speed. An electronic control unit continuously monitors these signals and if the frequency of a signal drops too rapidly indicating that a wheel is about to lock, the control unit instructs a modulating device to reduce hydraulic pressure to the brake at the affected wheel. When sensor signals indicate the wheel is again rotating normally, the control unit allows increased hydraulic pressure to the brake. This release-apply cycle occurs several time per second to “pump” the brakes like a driver might but at a much faster rate.In addition to their basic operation, anti-lock systems have two other things in common. First, they do not operate until the brakes are applied with enough force to lock or nearly lock a wheel. At all other times, the system stands ready to function but does not interfere with normal braking. Second, if the anti-lock system fail in any way, the brakes continue to operate without anti-lock capability. A warning light on the instrument panel alerts the driver when a problem exists in the anti-lock system.The current Bosch component Anti-lock Braking System (ABSⅡ), is a second generation design wildly used by European automakers such as BWM,Mercedes-Benz and Porsche. ABSⅡsystem consists of : four wheel speed sensor, electronic control unit and modulator assembly.A speed sensor is fitted at each wheel sends signals about wheel rotation to control unit. Each speed sensor consists of a sensor unit and a gear wheel. The front sensor mounts to the steering knuckle and its gear wheel is pressed onto the stub axle that rotates with the wheel. The rear sensor mounts the rear suspension member and its gear wheel is pressed onto the axle. The sensor itself is a winding with a magnetic core. The core creates a magnetic field around the winding, and as the teeth of the gear wheel move through this field, an alternating current is induced in the winding. The control unit monitors the rate o change in this frequency to determine impending brake lockup.The control unit’s function can be divide d into three parts: signal processing, logic and safety circuitry. The signal processing section is the converter that receives the alternating current signals form the speed sensors and converts them into digital form for the logic section. The logic section then analyzes the digitized signals to calculate any brake pressure changes needed. If impending lockup is sensed, the logic section sends commands to the modulator assembly.Modulator assemblyThe hydraulic modulator assembly regulates pressure to the wheel brakes when it receives commands from the control utuit. The modulator assembly can maintain or reduce pressure over the level it receives from the master cylinder, it also can never apply the brakes by itself. The modulator assembly consists of three high-speed electric solenoid valves, two fluid reservoirs and a turn delivery pump equipped with inlet and outlet check valves. The modulator electrical connector and controlling relays are concealed under a plastic cover of the assembly.Each front wheel is served by electric solenoid valve modulated independently by the control unit. The rear brakes are served by a single solenoid valve and modulated together using the select-low principle. During anti-braking system operation, the control unit cycles the solenoid valves to either hold or release pressure the brake lines. When pressure is released from the brake lines during anti-braking operation, it is routed to a fluid reservoir. There is one reservoir for the front brake circuit. The reservoirs are low-pressure accumulators that store fluid under slight spring pressure until the return delivery pump can return the fluid through the brake lines to the master cylinder.汽车制动系统制动系统是汽车中最重要的系统。

中英文对照外文翻译THE BRAKESDon't expect miracles from tuning on the brakes-improvement, yes-but no miracles. There are two reasons for this. First, the racing disc brake system has been developed to a very high state indeed so that there just isn't a lot left in the line of practical improvement and, second, we just don't spend very much time under the brakes. On the average road racing circuit, something less than ten percent of the time required to complete a lap is spent braking. Therefore, a five percent improvement in braking performance (not brake efficiency) would net a theoretical improvement in lap time of one half of one percent or about one half second in a 90 second lap. In actuality, the improvement would be somewhat less because human and practical limitations always prevent us from realizing the full potential benefit from any performance improvement.The big payoff of a well sorted out braking system comes, not from any increase in braking power itself, but in the confidence, consistency and controlability that it provides to the driver. This is particularly true when it comes to corner entry-entry speed, placement, precision and repeatability are all directly dependent upon braking performance and consistency.I would be astonished to learn of a modern road racing car which was delivered with inadequate brakes. Badly arranged or badly set up I'm willing to believe, but inadequate-NO. This statement is valid only so long as we do not change tire size, power output and/or gross weight all out of proportion to the original design. It is definitely not true in those classes of production based touring car and G.T. Car racing where the sanctioning body, through sheer ignorance and/or bloody mindedness prohibits changes to the braking system.BRAKING POWER: WHERE DOES IT COME FROM?It takes an astonishing amount of energy to decelerate a moving vehicle-in fact it takes the same amount of energy to decelerate from one speed to another as it would to accelerate between the two speeds-except that we can decelerate faster because most of the inertial forces are working for us rather than against us. The actual energy required to decelerate our racer is given by the equation:Energy (Ib/ft) = .0335 x [(mph max)2 (mph min)2] x gross weight (lb).For a 1760 Ib car braking from 150 mph to 60 mph we are talking about .0335 x [( 150)2_(60)2] x 1760 = I, I 14,344 Ib/ft.No matter what terminology we use, this is a hell of a lot of energy absorbed in a very short period of time. Somebody once converted the braking energy put out by a GT 40 over the twelve hours of Sebring and came to the conclusion that the same amount of energy could supply the electrical requirements of a fair sized city for a goodly period of time. So where does the energy come from-what actually stops the car?Some comes from the rolling resistance of the tires-not much, but some. A notable amount, at least at high road speeds, comes from the vehicle's aerodynamic drag. A little bit comes from the friction generated between the moving parts of the entire mechanism. Most of it, however, must come from the vehicle's braking system which converts the kinetic energy of vehicle inertia into thermal energy which must then be dissipated into the airstream-because we have yet to figure out a practical method to collect it, store it, and use it for propulsive thrust. We really aren't very efficient. This chapter is devoted to investigating the braking system itself. We shall conveniently ignore the other factors which slow the car because what we really want to do with them is minimize them to increase the acceleration of the vehicle.WHAT WE CAN EXPECT FROM THE BRAKESWhat exactly are we looking for in braking system performance? First of all we need a braking system which is capable of developing enough braking force to exceed the deceleration capacity of the tires-at any speed that the vehicle can reach-time after time, for the duration of the race. All racing cars, and many modified production cars, have such a system-provided that it is properly installed, adjusted and maintained. The braking effortproduced must be directly and linearly proportional to the pedal pressure exerted by the driver. Further, the driver effort required must be reasonable, pedal pressures must be neither so great that Godzilla is required to stop the car nor so light that it will be easy to lock the tires. The pedal position must be correctly matched to the geometry of the driver's foot and ankle, must remain at a constant height and should be really firm and have minimum travel. The system must deliver optimum balance of braking force between the front and rear tires so that the driver can maintain steering control under very heavy braking and yet use all of the decelerative capacity of all four tires. Lastly, the system must offer complete reliability. If the driver is braking as deep and as hard as he should be, any brake system failure will inevitably result in the car leaving the circuit. What happens after that is up to the man upstairs. Brake failure in a racing car at the limit has to be experienced to be understood. This is why even the most heroic drivers are liable to give the brake pedal a reassuring tap before they arrive at their braking marker.We need a vehicle suspension system capable of dealing with the loads and forces generated by heavy braking without wheel hop, suspension bottoming, compliance, adverse camber effects, pull or darting. Most of all we need a driver sensitive and skillful enough to balance the car on the edge of the traction circle under braking and under the combination of braking and cornering. If we do not provide the driver with all of the system parameters listed above, he can not provide us with the skill and daring necessary to ride the edge of the traction circle.EV ALUATION AND DRIVER TECHNIQUEWe'll start out with what is probably the most difficult part of the whole braking scene-evaluation of what you have. Measuring the braking performance of your particular projectile against that of the competition is no easier than comparing any other aspect of vehicle performance-and for the same reasons-too many variables and too much ego involved. This is where instrumentation is invaluable. The biggest variable is, of course, the driver. The very last thing that a really good racing driver learns to do truly well is to use the brakes. Most people take too long to get them on hard, leave them hard on too long and brake too heavily too deep into the corner. Almost invariably the lap times generated by the King of The LateBrakers are slow. His adrenalin level is liable to be abnormally high and he has a tendency to fall off the road. There are several reasons for these characteristics. When you leave your braking too late you are very liable to arrive at the point on the race track where you really want to start your turn only to find that the car will not turn. It will not do so because, in your efforts to save your life, you have the binders on so hard that all of the front tires' available traction is being used in deceleration and there is none left to allow the generation of the side force necessary to turn the car-or, should you somehow succeed in initiating a turn, to keep it in a balanced cornering state. In addition, the front tires are liable to be very nearly on fire and dangerously close to the compound temperature limit. Thirdly, if you are still hard on the brakes when the turn is initiated, forward load transfer has unbalanced the car, the front suspension travel is about used up, the front tires are steeply cambered and, if the thing turns at all, things are going to happen a bit quickly.If you persist in braking too late, the spectators will "ooh" and "ahh" and be impressed no end and the announcer will mention your name frequently-noting that you are really trying out there. You will complain pitifully about corner entry understeer followed by an incredibly rapid transition to power on oversteer. The other drivers will pour by you-either while you are exploring the grey areas of the track in your frantic scrabble for traction or on the way out of the corner when they have both higher exit speed and a better bite. You will do a lot of exploring as your self induced understeer forces you into unintentional late corner entries. Your team manager will eventually catch on, wander out on the course and observe your antics. If the ensuing frank discussion of technique does not inspire you to mend your ways, he will seriously consider either another driver (if you don't own the car) or another job (if you do).So any time that you are going in noticeably deeper than the competent opposition (assuming similar cars) but your lap times are not reflecting the degree of heroism that you feel they should-and the car is entering corners badly-have a good think about the wisdom of your braking points. Slow in and fast out will beat fast in and slow out every time. Of course fast in and fast out beats either of the above-and that's what we are trying to achieve-but you won't come out fast if you go in with the car unbalanced and the front tires on fire. This is notto say that a super late brake application followed by a deliberate early corner entry and a bit of slithering around which uses up a portion of the track that might otherwise be useful to someone else is not a valid desperation maneuver. It is, and it will continue to be-but it isn't very often fast and it is even less often repeatedly fast.THE BRAKE PEDALHaving disposed of the system actuator, it is time to discuss hardware. We will begin with the brake pedal since it is the closest part to the driver. The brake pedal should be very strong-and so should its attachment to the chassis. This may sound very basic and a bit ridiculous-and so it should. Any fool should be able to figure out that if the brake pedal, or any of the associated bits, fractures, bends or tears out of its mountings, big trouble is about to happen. And yet it happens-not very frequently-but it does happen. It has even happened to very good operations. Don't let it happen to you. Take a long hard look at the pedal/master cylinder setup and, if anything even looks like being questionable, redesign and/or reinforce as seems necessary. Remember that the typical brake pedal has a mechanical advantage of at least 3: I and it may be as much as 8: I. The pedal arm must be plenty stout and it must be generously gusseted at the intersection of the bias bearing tube. If the pedal bracket is a chunk of 20 gauge aluminum pop riveted to the floor, it won't be good enough. If it doesn't eventually tear out, it will distort and it is difficult enough to modulate brake pressure without the pedal waving about. The pedal pivot support should be at least 18 gauge steel, it should be either boxed or flanged and it should tie into a corner of major structure. You are going to lean on the pedal very frequently and plenty hard. If the master cylinders are mounted to either sheet metal or to slightly stiffened sheet metal, you will end up with a soft or vague pedal. This particulardesign sin is nowhere near so rare as it should be-especially in those vehicles which do not employ a front bulkhead (a major Sin In Itself). I'll be damned if I know why this is ever allowed, but it is easily detected and remedied. Also look at the master cylinder push rods. It is very desirable that they should not bend. In normal lengths the stock Girting bits will do just fine. Trouble starts at about six inches. We can also get into trouble with really thin wall tubular extensions and with butt welds.PEDAL GEOMETRY AND ADJUSTMENTTake some time and adjust the fore and aft position of the brake (and clutch) pedal to suit the driver's geometry and preference. To do this right may not be as simple as it sounds. The easiest method is that practiced by Lolas, who screw the foot pad into the pedal shaft with a long bolt which is welded to the pad. This gives lots of adjustment without deranging the pedal geometry and offers the added advantage of allowing you to install the pad at an angle should your driver prefer.It is vital that the swing of the pedal be properly positioned on its arc. If the pedal is allowed to go over center as it is pushed, we will have an unfortunate situation where, the harder we push on the pedal, the less braking effort we get-and confusion is a certain result. Once the (minimal) free play has been taken up, we are not going to push the pedal very far, just hard, so that it is a relatively simple matter to adjust the actuating rod length and the position of the pedal pivot so that increased pressure results in increased, or at least linear mechanical advantage. Do so. All of this may involve new brackets, actuating rods, or even a new pedal. It really is important, so do it.We no longer row our way down through the gears to decelerate the car-pity, one more glorious sound gone away. The present racing disc brake system is plenty powerful enough to exceed the tire capacity without help from engine friction. Downshifting while braking merely upsets the balance of the car, involves unnecessary foot movements and makes it more difficult to precisely modulate braking effort. However, we still do downshift. So long as racing drivers must downshift, the traditional heel and toe exercise with the brake and the throttle is a necessity. Otherwise, we will snatch the rear wheels when the clutch engages and instantaneous oversteer will be achieved. As the downshift always occurs either during corner entry or immediately prior to it, oversteer-even transient oversteer-is not to be desired. Whilst downshifting, we are, by definition, braking and, more than likely, braking hard. It would be best if the driver could still modulate the brakes while jabbing at the accelerator. The common deficiency in this department is for the driver to unintentionally decrease brake pedal pressure while stabbing the throttle. Watch the braking area before a slow corner at any race-you can actually see the noses of the slow cars come up during downshifts. Next watch the aces andnote the difference. You will also notice that the nose of the ace's car comes up before the car is locked over into the corner. At any rate, if the driver is not going to upset the pedal pressure while downshifting, the relative positions of the brake and throttle pedals must be perfect-for the individual driver.There are two workable methods of "heel and toeing"-that I know of. The first involves rocking the right foot sideways and catching the throttle with the side of the foot. This is probably the more popular method, but it is difficult to control brake pressure while rocking the foot. The second way is to so arrange things that the heel of the right foot is carried further outboard than the ball and to jab the throttle by extending the heel. It is very much a case of personal preference and ankle geometry. In either case, the throttle pedal, or some part thereof had better be ready to foot when the time comes-we do not want to either hunt for it or stretch for it. Contrariwise, it must be impossible for the driver to inadvertently hit the throttle when he goes for the brakes or to get his foot tangled between the pedals-don't laugh. The necessary fiddling about and moving of things can be greatly facilitated by a bit of forethought. The pedal system most compatible with human geometry and lie down cars is to pivot the brake (and clutch) pedals on the floor and hang the accelerator from the ceiling. It helps a lot if the throttle setup incorporates a left and right hand threaded connector at the pedal end. It is unlikely that your first efforts at getting it right will be successful-drivers have trouble making up their minds and what feels right sitting on the jack stands may not be worth a damn on the race track-especially if the driver was wearing street shoes when you set it up. You may get to do a lot of this sort of thing for a while (sometimes I regret telling drivers that the pedals can be adjusted) so you may as well make it easy on yourself. This may well include making a larger access hole in the top of the tub for your hands. Remember that after each adjustment to the throttle pedal you get to reset the full throttle stop and that, if you change master cylinder sizes, you get to do it all over again.Playing with the shape of the throttle pedal and its arch often pays unexpected dividends.Most drivers insist on some sort of heel locating plate or brace running transversely across the cockpit floor. If the driver does not insist on one, you should-he needs It.The last pedal is the left footrest. There should be one. It provides a place for the driverto brace himself and does away with the worrisome possibility that he might unintentionally rest his left foot on the clutch to the detriment of the clutch plates. Its height should be the same as the clutch pedal and it should be located slightly behind the clutch so that the left foot can simply be slid sideways when required. It should be as wide as practical-making sure that the clutch can be depressed without getting the foot trapped between the two. There usually isn't a lot of excess room in the foot well so the clutch pedal may have to be made more narrow in order to create room for the dead pedal. The footrest should be well attached to the chassis because it will take a lot of pressure, and it is bad if it comes undone.BIG FEET IN SMALL COCKPITSAll English racing drivers must have size six feet! If your hero features size twelve, his fancy footwork in the average kit car is going to suffer some impairment due to interference between his toes and the bodywork, the tub, the anti-roll bar or the steering rack. This is one of the major reasons why the cockpit extends so far forward on the present Formula One Cars. Extensions and/or blisters are sometimes a necessity. Occasionally you will run into foot interference of a more serious nature-worst possible case being the steering rack-the anti-roll bar is a less serious case because it is easier to move. A situation of this nature calls for moving either the offending member or the driver-or maybe finding a driver with smaller feet. Minor interference can be cured by shoe surgery. If you move the driver you will also have to move the pedals. If you move the rack, you will have to re-do the geometry. It is easier not to buy a car with this type of built-in problem. Finding out about this sort of thing on your first test can ruin your whole day-so find out early-particularly if your driver, or his feet, are oversized.DISC BELLS OR TOP HATSWe have now arrived at a point where the pedals fit the driver and nothing is going to bend or fall off-so what can we do to help the actual retarding mechanism? Prepare to Win covered the plumbing, installation and maintenance ends of things and all of this has to be done-step by step. It did not, however, cover the now popular method of attaching the brake discs to the top hats or bells by six bolts in single shear. It did not cover it for the excellentreason that I had not dreamed that anyone would do such a thing. Wrong again! I had reckoned without Lola and March. Not only do these otherwise fine firms cheerfully commit this crime against nature, but they do not allow sufficient bolt hole edge distance or flange thickness to stabilize the bolts and they have been known to use less than optimum grades of aluminum for the bells. They also use fully threaded Allen bolts. Talk about looking for trouble! Chevron also use the same basic system, but their flange thickness is sufficient to get away with it.The layout is a lot less bad and critical on Formula Atlantic cars simply because both vehicle speed and vehicle mass are considerably less than, say Can Am Cars, and so the brake torque is less. Still I have seen the rear bells shear on an Atlantic car. Nothing good has ever been reported about this sort of thing. If you happen to have lots of money, the obvious solution is to get rid of the whole mess and install dog drive discs and bells. This is probably not practical as the dog drive top hats are very expensive to make. So let's explore the alternatives.Step one is to scrap the stock bolts. They are not the prime offenders, but getting rid of them is both cheap and easy. You will have to use either a twelve point or an internal wrenching NAS bolt. If you cannot obtain them, use an "Unbrako" Allen bolt with the correct grip length and cut off the unneeded thread. If you can get the NAS bolts, you may have to turn down the heads to make them fit. In some installations, it is just not possible to use a washer under the bolt head-even a turned down washer. In this case, the bolt hole must be countersunk to clear the radius under the head of the NAS bolts. Do not use stainless or titanium bolts in this application, and use all metal lock nuts.Unfortunately, the prime offender is the top hat itself. It may have several shortcomings. Normally there is both insufficient flange thickness to stabilize the bolt and insufficient edge distance to prevent the bolt from tearing out. The material may also be soft, allowing the bolt head to work into the aluminum which results in a loose assembly and eventual self destruction. The alloy may also be unstable under the heat involved which will cause disc runout. If you check the stupid things as frequently as you should, you will detect the symptoms before a disaster occurs-unless, of course, you are running on a really severe coursewhere you get airborne under the brakes-like Long Beach or Elkhart Lake. In this case the disaster may happen before you notice the symptoms and your driver will go through the experience of shearing the discs off the bells. He will not enjoy the experience, and you will not enjoy rebuilding the resultant wreck.For about 50% of the cost of a stock disc bell, any decent machine shop can make units from high quality forged alloy stock. Probably the best alloy to use is 2024-T4 with 7075T651 and 2017-T451 being acceptable. 6061 is not a good alloy for this application. If space permits, increase both the edge distance and the flange thickness. Save yourself some money by drilling twelve bolt holes instead of the required six and indexing the disc when the holes show elongation or cracking. In addition to lasting a lot longer, the bells will remain more true-especially if you set them up in a lathe and take a truing cut off them every so often. Tilton Engineering makes good top hats and a very clever steel plate to convert bolt on discs to dog drive.制动系统不要指望从调整刹车改进，奇迹，但没有奇迹。

Automobile Brake SystemThe braking system is the most important system in cars. If the brakes fail, the result can be disastrous. Brakes are actually energy conversion devices, which convert the kinetic energy (momentum) of the vehicle into thermal energy (heat).When stepping on the brakes, the driver commands a stopping force ten times as powerful as the force that puts the car in motion. The braking system can exert thousands of pounds of pressure on each of the four brakes.Two complete independent braking systems are used on the car. They are the service brake and the parking brake.The service brake acts to slow, stop, or hold the vehicle during normal driving. They are foot-operated by the driver depressing and releasing the brake pedal. The primary purpose of the brake is to hold the vehicle stationary while it is unattended. The parking brake is mechanically operated by when a separate parking brake foot pedal or hand lever is set.The brake system is composed of the following basic components: the “master cylinder” which is located under the hood, and is directly connected to the brake pedal, converts driver foot’s mechanical pressure into hydraulic pressure. Steel “brake lines” and flexible “brake hoses” connect the master cylinder to the “slave cylinders” located at each wheel. Brake fluid, specially designed to work in extreme conditions, fills the system. “Shoes” and “pads” are pushed by the slave cylinders to contact the “drums” and “rotors” thus causing drag, which (hopefully) slows the car.The typical brake system consists of disk brakes in front and either disk or drum brakes in the rear connected by a system of tubes and hoses that link the brake at each wheel to the master cylinder .Basically, all car brakes are friction brakes. When the driver applies the brake, the control device forces brake shoes, or pads, against the rotating brake drum or disks atwheel. Friction between the shoes or pads and the drums or disks then slows or stops the wheel so that the car is braked.In most modern brake systems, there is a fluid-filled cylinder, called master cylinder, which contains two separate sections, there is a piston in each section and both pistons are connected to a brake pedal in the driver’s compartment. When the brake is pushed down, brake fluid is sent from the master cylinder to the wheels.At the wheels, the fluid pushes shoes, or pads, against revolving drums or disks. The friction between the stationary shoes, or pads, and the revolving drums or disks slows and stops them. This slows or stops the revolving wheels, which, in turn, slow or stop the car.The brake fluid reservoir is on top of the master cylinder. Most cars today have a transparent r reservoir so that you can see the level without opening the cover. The brake fluid level will drop slightly as the brake pads wear. This is a normal condition and no cause for concern. If the level drops noticeably over ashort period of time or goes down to about two thirds full, have your brakes checked as soon as possible. Keep the reservoir covered except for the amount of time you need to fill it and never leave a cam of brake fluid uncovered. Brake fluid must maintain a very high boiling point. Exposure to air will cause the fluid to absorb moisture which will lower that boiling point.The brake fluid travels from the master cylinder to the wheels through a series of steel tubes and reinforced rubber hoses. Rubber hoses are only used in places that require flexibility, such as at the front wheels, which move up and down as well as steer. The rest of the system uses non-corrosive seamless steel tubing with special fittings at all attachment points. If a steel line requires a repair, the best procedure is to replace the compete line. If this is not practical, a line can be repaired using special splice fittings that are made for brake system repair. You must never use copper tubing to repair a brake system. They are dangerous and illegal.Drum brakes, it consists of the brake drum, an expander, pull back springs, a stationary back plate, two shoes with friction linings, and anchor pins. The stationary back plate is secured to the flange of the axle housing or to the steering knuckle. The brake drum is mounted on the wheel hub. There is a clearance between the inner surface of the drum and the shoe lining. To apply brakes, the driver pushes pedal, the expander expands the shoes and presses them to the drum. Friction between the brake drum and the friction linings brakes the wheels and the vehicle stops. To release brakes, the driver release the pedal, the pull back spring retracts the shoes thus permitting free rotation of the wheels.Disk brakes, it has a metal disk instead of a drum. A flat shoe, or disk-brake pad, is located on each side of the disk. The shoes squeeze the rotatin g disk to stop the car. Fluid from the master cylinder forces the pistons to move in, toward the disk. This action pushes the friction pads tightly against the disk. The friction between the shoes and disk slows and stops it. This provides the braking action. Pistons are made of either plastic or metal. There are three general types of disk brakes. They are the floating-caliper type, the fixed-caliper type, and the sliding-caliper type.Floating-caliper and sliding-caliper disk brakes use a single piston. Fixed-caliper disk brakes have either two or four pistons.Brakes - what do they do?Brakes are designed to slow down your vehicle but probably not by the means that you think. The common misconception is that brakes squeeze against a drum or disc, and the pressure of the squeezing action is what slows you down. This in fact is only part of the equation. Brakes are essentially a mechanism to change energy types. When you're travelling at speed, your vehicle has kinetic energy. When you apply the brakes, the pads or shoes that press against the brake drum or rotor convert that energy into thermal energy via friction. The cooling of the brakes dissipates the heat and the vehicle slows down. It's the First Law of Thermodynamics, sometimes known as the law of conservation of energy. This states that energy cannot be created nordestroyed, it can only be converted from one form to another. In the case of brakes, it is converted from kinetic energy to thermal energy.Angular force. Because of the configuration of the brake pads and rotor in a disc brake, the location of the point of contact where the friction is generated also provides a mechanical moment to resist the turning motion of the rotor.Thermodynamics, brake fade and drilled rotors.If you ride a motorbike or drive a race car, you're probably familiar with the term brake fade, used to describe what happens to brakes when they get too hot. A good example is coming down a mountain pass using your brakes rather than your engine to slow you down. As you start to come down the pass, the brakes on your vehicle heat up, slowing you down. But if you keep using them, the rotors or drums stay hot and get no chance to cool off. At some point they can't absorb any more heat so the brake pads heat up instead. In every brake pad there is the friction material that is held together with some sort of resin and once this starts to get too hot, the resin starts to vapourise, forming a gas. Because the gas can't stay between the pad and the rotor, it forms a thin layer between the two whilst trying to escape. The pads lose contact with the rotor, reducing the amount of friction and voila. Complete brake fade.。

Automobile Brake SystemThe braking system is the most important system in cars. If the brakes fail, the result can be disastrous. Brakes are actually energy conversion devices, which convert the kinetic energy (momentum) of the vehicle into thermal energy (heat).When stepping on the brakes, the driver commands a stopping force ten times as powerful as the force that puts the car in motion. The braking system can exert thousands of pounds of pressure on each of the four brakes.Two complete independent braking systems are used on the car. They are the service brake and the parking brake.The service brake acts to slow, stop, or hold the vehicle during normal driving. They are foot-operated by the driver depressing and releasing the brake pedal. The primary purpose of the parking brake is to hold the vehicle stationary while it is unattended. The parking brake is mechanically operated by when a separate parking brake foot pedal or hand lever is set.The brake system is composed of the following basic c omponents: the “master cylinder” which is located under the hood, and is directly connected to the brake pedal, converts driver foot’s mechanical pressure into hydraulic pressure. Steel “brake lines” and flexible “brake hoses” connect the master cylinder to the “slave cylinders” located at each wheel. Brake fluid, specially designed to work in extreme conditions, fills the system. “Shoes” and “pads” are pushed by the slave cylinders to contact the “drums” and “rotors” thus causing drag, which (hopefully) slows the car.The typical brake system consists of disk brakes in front and either disk or drum brakes in the rear connected by a system of tubes and hoses that link the brake at each wheel to the master cylinder (Figure).Basically, all car brakes are friction brakes. When the driver applies the brake, the control device forces brake shoes, or pads, against the rotating brake drum or disks at wheel. Friction between the shoes or pads and the drums or disks then slows or stops the wheel so that the car is braked.In most modern brake systems (see Figure 15.1), there is a fluid-filled cylinder, called master cylinder, which contains two separate sections, there is a piston in each section and both pistons are connected to a brake pedal in the driver’s compartment. When the brake is pushed down, brake fluid is sent from the master cylinder to the wheels.At the wheels, the fluid pushes shoes, or pads, against revolving drums or disks. The friction between the stationary shoes, or pads, and the revolving drums or disks slows and stops them. This slows or stops the revolving wheels, which, in turn, slow or stop the car.The brake fluid reservoir is on top of the master cylinder. Most cars today have a transparent reservoir so that you can see the level without opening the cover. The brake fluid level will drop slightly as the brake pads wear. This is a normal condition and no cause for concern. If the level drops noticeably over ashort period of time or goes down to about two thirds full, have your brakes checked as soon as possible. Keep the reservoir covered except for the amount of time you need to fill it and never leave a cam of brake fluid uncovered. Brake fluid must maintain a very high boiling point. Exposure to air will cause the fluid to absorb moisture which will lower that boiling point.The brake fluid travels from the master cylinder to the wheels through a series of steel tubes and reinforced rubber hoses. Rubber hoses are only used in places that require flexibility, such as at the front wheels, which move up and down as well as steer. The rest of the system uses non-corrosive seamless steel tubing with special fittings at all attachment points. If a steel line requires a repair, thebest procedure is to replace the compete line. If this is not practical, a line can be repaired using special splice fittings that are made for brake system repair. You must never use copper tubing to repair a brake system. They are dangerous and illegal.Drum brakes, it consists of the brake drum, an expander, pull back springs, a stationary back plate, two shoes with friction linings, and anchor pins. The stationary back plate is secured to the flange of the axle housing or to the steering knuckle. The brake drum is mounted on the wheel hub. There is a clearance between the inner surface of the drum and the shoe lining. To apply brakes, the driver pushes pedal, the expander expands the shoes and presses them to the drum. Friction between the brake drum and the friction linings brakes the wheels and the vehicle stops. To release brakes, the driver release the pedal, the pull back spring retracts the shoes thus permitting free rotation of the wheels.Disk brakes, it has a metal disk instead of a drum. A flat shoe, or disk-brake pad, is located on each side of the disk. The shoes squeeze the rotatin g disk to stop the car. Fluid from the master cylinder forces the pistons to move in, toward the disk. This action pushes the friction pads tightly against the disk. The friction between the shoes and disk slows and stops it. This provides the braking action. Pistons are made of either plastic or metal. There are three general types of disk brakes. They are the floating-caliper type, the fixed-caliper type, and thesliding-caliper type. Floating-caliper and sliding-caliper disk brakes use a single piston. Fixed-caliper disk brakes have either two or four pistons.The brake system assemblies are actuated by mechanical, hydraulic or pneumatic devices. The mechanical leverage is used in the parking brakes fitted in all automobile. When the brake pedal is depressed, the rod pushes the piston of brake master cylinder which presses the fluid. The fluid flows through the pipelines to the power brake unit and then to the wheel cylinder. The fluidpressure expands the cylinder pistons thus pressing the shoes to the drum or disk. If the pedal is released, the piston returns to the initialposition, the pull back springs retract the shoes, the fluid is forced back to the master cylinder and braking ceases.The primary purpose of the parking brake is to hold the vehicle stationary while it is unattended. The parking brake is mechanically operated by the driver when a separate parking braking hand lever is set. The hand brake is normally used when the car has already stopped. A lever is pulled and the rear brakes are approached and locked in the “on” position. The car may now be left without fear of its rolling away. When the driver wants to move the car again, he must press a button before the lever can be released. The hand brake must also be able to stop the car in the event of the foot brake failing. For this reason, it is separate from the foot brake uses cable or rods instead of the hydraulic system.Anti-lock Brake SystemAnti-lock brake systems make braking safer and more convenient, Anti-lock brake systems modulate brake system hydraulic pressure to prevent the brakes from locking and the tires from skidding on slippery pavement or during a panic stop.Anti-lock brake systems have been used on aircraft for years, and some domestic car were offered with an early form of anti-lock braking in late 1990’s. Recently, several automakers have introduced more sophisticated anti-lock system. Investigations in Europe, where anti-lock brakin g systems have been available for a decade, have led one manufacture to state that the number of traffic accidents could be reduced by seven and a half percent if all cars had anti-lock brakes. So some sources predict that all cars will offer anti-lock brakes to improve the safety of the car.Anti-lock systems modulate brake application force several times per second to hold the tires at a controlled amount of slip; all systems accomplish this in basically the same way. One or more speed sensors generate alternating current signal whose frequency increases with the wheel rotational speed. An electronic control unit continuously monitors these signals and if the frequency of a signal drops too rapidly indicating that a wheel is about to lock, the control unit instructs a modulating device to reduce hydraulic pressure to the brake at the affected wheel. When sensor signals indicate the wheel is again rotating normally, the control unit allows increased hydraulic pressure to the brake. This release-apply cycle occurs several time per second to “pump” the brakes like a driver might but at a much faster rate.In addition to their basic operation, anti-lock systems have two other things in common. First, they do not operate until the brakes are applied with enough force to lock or nearly lock a wheel. At all other times, the system stands ready to function but does not interfere with normal braking. Second, if the anti-lock system fail in any way, the brakes continue to operate without anti-lock capability. A warning light on the instrument panel alerts the driver when a problem exists in the anti-lock system.The current Bosch component Anti-lock Braking System (ABSⅡ), is a second generation design wildly used by European automakers such as BWM, Mercedes-Benz and Porsche. ABSⅡ system consists of : four wheel speed sensor, electronic control unit and modulator assembly.A speed sensor is fitted at each wheel sends signals about wheel rotation to control unit. Each speed sensor consists of a sensor unit and a gear wheel. The front sensor mounts to the steering knuckle and its gear wheel is pressed onto the stub axle that rotates with the wheel. The rear sensor mounts the rear suspension member and its gear wheel is pressed onto the axle. The sensor itself is awinding with a magnetic core. The core creates a magnetic field around the winding, and as the teeth of the gear wheel move through this field, an alternating current is induced inthe winding. The control unit monitors the rate o change in this frequency to determine impending brake lockup.The control unit’s function can be divided into three parts: signal processing, logic and safety circuitry. The signal processing section is the converter that receives the alternating current signals form the speed sensors and converts them into digital form for the logic section. The logic section then analyzes the digitized signals to calculate any brake pressure changes needed. If impending lockup is sensed, the logic section sends commands to the modulator assembly.Modulator assemblyThe hydraulic modulator assembly regulates pressure to the wheel brakes when it receives commands from the control utuit. The modulator assembly can maintain or reduce pressure over the level it receives from the master cylinder, it also can never apply the brakes by itself. The modulator assembly consists of threehigh-speed electric solenoid valves, two fluid reservoirs and a turn delivery pump equipped with inlet and outlet check valves. The modulator electrical connector and controlling relays are concealed under a plastic cover of the assembly.Each front wheel is served by electric solenoid valve modulated independently by the control unit. The rear brakes are served by a single solenoid valve and modulated together using the select-low principle. During anti-braking system operation, the control unit cycles the solenoid valves to either hold or release pressure the brake lines. When pressure is released from the brake lines during anti-braking operation, it is routed to a fluid reservoir. There is one reservoir for the front brake circuit. The reservoirs are low-pressure accumulators that storefluid under slight spring pressure until the return delivery pump can return the fluid through the brake lines to the master cylinder.汽车制动系统制动系统是汽车上最重要的系统。

Brake systemsWe all know that pushing down on the brake pedal slows a car to a stop. But how does this happen？How does your car transmit the force from your leg to its wheels？ How does it multiply the force so that it is enough to stop something as big as a car?Brake Image GalleryLayout of typical brake system. See more brakeimages。

When you depress your brake pedal， your car transmits the force from your foot to its brakes through a fluid. Since the actual brakes require a much greater force than you could apply with your leg， your car must also multiply the force of your foot. It does this in two ways：•Mechanical advantage (leverage)•Hydraulic force multiplicationThe brakes transmit the force to the tires using friction， and the tires transmit that force to the road using friction also。

Before we begin our discussion on the components of the brake system, we’ll cover these three principles:•Leverage•Hydraulics•FrictionLeverage and HydraulicsIn the figure below, a force F is being applied to the left end of the lever. The left end of the lever is twice as long (2X) as the right end （X）。

制动系 braking system行车制动系统 service braking system应急制动系统 secondary (emergency )braking system 驻车制动系统 parking braking system辅助制动系统 auxiliary braking system自动制动系统 automatic braking system人力制动系统 muscular energy braking system助力制动系统 energy assisted braking system动力制动系统 non-muscular energy braking system惯性制动系统 inertial braking system重力制动系统 gravity braking system单回路制动系统 single-circuit braking system双回路制动系统 dual -circuits braking system单管路制动系统 single-line braking system双管路制动系统 dual braking system多管路制动系统 multi-line braking system连续制动系统 continuous braking system半连续制动系统 semi-continuous braking system非连续制动系统 non-continuous braking system伺服制动系统 servo braking system液压制动系统 hydraulic braking system电磁制动系统 electromagnetic braking system机械制动系统 mechanical braking system组合制动系统 combination braking system基本术语 basic terms制动装备 braking equipment组成部件 constituent elements制动力学 braking mechanics渐进制动 gradual braking制动能源 braking energy source制动力矩 braking torque总制动力 total braking force干扰后效制动力矩 disturbing residual braking torque 总制动距离 total braking distance有效制动距离 active braking distance制动力分配率 braking force distaribution rate制动效能因素（制动强度） braking efficiency factor 制动力 braking work瞬时制动功率 instantaneous braking power保护压力 protection pressure报警压力 alarm pressure制动系滞后 braking system hysteresis制动效果百分数 percentage of the braking efficiency停车距离（制动距离） stopping distance充分发出的平均减速度 mean fully developed braking deceleration (MFDD) 制动反应时间 reaction time促动时间 actuating time初始反应时间 initial response time制动力增长时间 build-up time of braking force有效制动时间 active braking time释放时间 release time驾驶员反应时间 reaction time of driver机构滞后时间 mechanism hysteresis time增长时间 build-up time of braking force主制动时间 main braking time总制动时间 total braking time停车时间 stopping time开启行程 opening travel空行程 spare travel中间行程 mid-travel制动储备行程 reserve brake travel断油行程 cut-off travel行程损失 loss of travel缩小比（减压比） reduction ratio回缩 retraction两片法 two-plate method单片法 single-plate method含水量 moistrue content单轮控制 individual wheel control多轮控制 multi wheel control轴控制 axle control边控制 side control对角控制 diagonal control组合多轴控制 combined multi-axle control可变选择 variable selection最低控制速度 minimum control speed传感器信号选择 sensor signal低选择 select -low高选择 select-high预定选择 predetermined selection车轮选择 selection by wheel平均选择 average selection分辨率 resolution rate控制周期 control cycle控制频率 control frequency控制力 control force作用力 control force制动器效能因素 application force制动器材的滞后 brake hysteresis制动器输出力矩 brake output torque制动器额定力矩 brake rating torque制动蹄效能因素 brake shoe efficiency factor制动蹄作用压力 application pressure of brake shoe assembly 制动蹄释放压力 release pressure of brake shoe最大制动蹄中心升程 maximum shoe center lift制动鼓直径 drum diameter制动鼓宽度 drum width制动鼓厚度 drum thickness制动盘厚度 disc thickness（鼓或盘）的摩擦面积 swept area制动衬片吸收功率 power absorption of lining制动衬片包角 lining arc制动衬片单位面积制动力 lining drag衬片摩擦系数 lining mu衬片摩擦面积/每轴 lining area/axle衬片摩擦面积/每个制动器 lining area/brake踏板行程 pedal travel踏板自由行程 free pedal travel踏板最大行程 maximum pedal travel踏板力 pedal effort有效踏板长度 effective pedal length踏板速比 pedal velocity ratio踏板回位弹簧力 pedal return spring load踏板回位弹簧刚度 pedal return spring rate制动初速度 initial speed of braking制动减速度 braking deceleration瞬时制动减速度 instantaneous braking deceleration平均制动减速度 mean braking deceleration最大制动减速度 maximum braking deceleration石油基制动液 petroleum base brake fluid非石油基制动液 non-petroleum base brake fluid最低湿沸点 minimum wet boiling point防冻液 anti-freeze liquid冷却液 cooling liquid供能装置 energy supplying device真空泵 vacuum pump喷射器 ejector真空罐（筒） vacuum tank空压机 air compressor气缸盖 cylinder head气缸体 cylinder block活塞 piston火塞环 piston ring连杆 connecting rod活塞销 piston pin曲轴 crank shaft进气阀 intake valve排气阀 exhaust valve储气罐（筒） air storage reservoir调压阀 pressure regulating valve单向阀 single check valve止回阀、单向阀 check valve滤清器 filter进气滤清器 air intake filter排气滤清器 air exhaust filter管路滤清器 line filter滤网（芯） strainer油水分离器 oil and water separator防冻器 aiti-freezer空气干燥器 air dryer排放阀 drain valve压力保护阀 pressure protection valve控制装置 control device行车制动踏板装置 service braking pedal device 制动踏板 braking pedal踏板护套 pedal pad踏板支架 pedal bracket衬套 bushing套管 collar销轴 axis pin回位弹簧 return spring驻车制动操纵装置 parking brake control device 操纵杆 control lever操纵杆支架 control lever bracket操纵杆导套 control lever guide collar齿杆（棘轮） rod rack(ratchet)棘抓 ratchet pawl。

附录1Hydraulic Brake SystemsThe braking system is the most important system in cars. If the brake system fail, the result can be disastrous.When you step on the brake pedal, you expect the vehicle to stop. The brake pedal operates a hydraulic system that is used for two reasons. First, fluid under pressure can be carried to all parts of the vehicle by small hoses or metal lines with out taking up a lot of room or causing routing problems. Second, the hydraulic fluid offers a great mechanical advantage-little foot pressure is required on the pedal, but a great deal of pressure is generated at the wheels. The brake pedal is linked to a piston in the brake master cylinder, which is filled with hydraulic brake fluid. The master cylinder consists of a cylinder containing a small piston and a fluid reservoir.Modern master cylinders are actually two separate cylinders. Such a system is called a dual circuit, because the front cylinder is connected to the front brakes and the rear cylinder to the rear brakes. (Some vehicles are connected diagonally.) The two cylinders are actually separated, allowing for emergency stopping power should one part of the system fail.The entire hydraulic system from the master cylinder to the wheels is full of hydraulic brake fluid. When the brake pedal is depressed, the pistons in the master cylinder are forced to move, exerting tremendous force on the fluid in the lines. The fluid has nowhere to go, and forces the wheel cylinder pistons (drum brakes) or caliper pistons (disc brakes) to exert pressure on the brake shoes or pads. The friction between the brake shoe and wheel drum or the brake pad and rotor (disc) slows the vehicle and eventually stops it.Also attached to the brake pedal is a switch that lights the brake lights as the pedal is depressed. The lights stay on until the brake pedal is released and returns to its normal position.Each wheel cylinder in a drum brake system contains two pistons, one at either end, which push outward in opposite directions. In disc brake systems, the wheel cylinders are part of the caliper (there can be as many as four or as few as one). Whether disc or drum type, all pistons use some type of rubber seal to prevent leakage around the piston, and a rubber dust boot seals the outer ends of the wheel cylinders against dirt and moisture.When the brake pedal is released, a spring pushes the master cylinder pistons back to their normal positions. Check valves in the master cylinder piston allow fluid to flow toward the wheel cylinders or calipers as the piston returns. Then as the brake shoe return springs pullthe brake shoes back to the released position, excess fluid returns to the master cylinder through compensating ports, which have been uncovered as the pistons move back. Any fluid that has leaked from the system will also be replaced through the compensating ports.All dual circuit brake systems use a switch to activate a light, warning of brake failure. The switch is located in a valve mounted near the master cylinder. A piston in the valve receives pressure on each end from the front and rear brake circuits. When the pressures are balanced, the piston remains stationary, but when one circuit has a leak, greater pressure during the application of the brakes will force the piston to one side or the other, closing the switch and activating the warning light. The light can also be activated by the ignition switch during engine starting or by the parking brake.Front disc, rear drum brake systems also have a metering valve to prevent the front disc brakes from engaging before the rear brakes have contacted the drums. This ensures that the front brakes will not normally be used alone to stop the vehicle. A proportioning valve is also used to limit pressure to the rear brakes to prevent rear wheel lock-up during hard braking.1. Friction materialsBrake shoes and pads are constructed in a similar manner. The pad or shoe is composed of a metal backing plate and a friction lining. Thelining is either bonded (glued) to the metal, or riveted. Generally, riveted linings provide superior performance, but good quality bonded linings are perfectly adequate.Friction materials will vary between manufacturers and type of pad and the material compound may be referred to as: asbestos, organic, semi-metallic, metallic. The difference between these compounds lies in the types and percentages of friction materials used, material binders and performance modifiers.Generally speaking, organic and non-metallic asbestos compound brakes are quiet, easy on rotors and provide good feel. But this comes at the expense of high temperature operation, so they may not be your best choice for heavy duty use or mountain driving. In most cases, these linings will wear somewhat faster than metallic compound pads, so you will usually replace them more often. But, when using these pads, rotors tend to last longer.Semi-metallic or metallic compound brake linings will vary in performance based on the metallic contents of the compound. Again, generally speaking, the higher the metallic content, the better the friction material will resist heat. This makes them more appropriate for heavy duty applications, but at the expense of braking performance before the pad reaches operating temperature. The first few applications on a cold morning may not give strong braking. Also, metallic andsemi-metallic are more likely to squeal. In most cases, metallic compounds last longer than non-metallic pads, but they tend to cause more wear on the rotors. If you use metallic pads, expect to replace the rotors more often.When deciding what type of brake lining is right for you, keep in mind that today's modern cars have brake materials which are matched to the expected vehicle＇s performance capabilities. Changing the material from OEM specification could adversely affect brake feel or responsiveness. Before changing the brake materials, talk to your dealer or parts supplier to help decide what is most appropriate for your application. Remember that heavy use applications such as towing, stop and go driving, driving down mountain roads, and racing may require a change to a higher performance material.Some more exotic materials are also used in brake linings, among which are Kevlar and carbon compounds. These materials have the capability of extremely good performance for towing, mountain driving or racing. Wear characteristics can be similar to either the metallic or the non-metallic linings, depending on the product you buy. Most race applications tend to wear like metallic linings, while many of the street applications are more like the non-metallic.2. Brake fluidOn a disk brake, the fluid from the master cylinder is forced into acaliper where it presses against a piston. The piston, in-turn, squeezes two brake pads against the disk(rotor)which is attached to the wheel, forcing it to slow down or stop. This process is similar to a bicycle brake where two rubber pads rub against the wheel rim creating friction.With drum brakes, fluid is forced into the wheel cylinder which pushes the brake shoes out so that the friction linings are pressed against the drum which is attached to the wheel, causing the wheel to stop.In either case, the friction surfaces of the pads on a disk brake system, or the shoes on a drum brake convert the forward motion of the vehicle into heat. Heat is what causes the friction surfaces (linings) of the pads and shoes to eventually wear out and require replacement.Brake fluid is a special oil that has specific properties. It is designed to withstand cold temperatures without thickening as well as very high temperatures without boiling.(If the brake fluid should boil, it will cause you to have a spongy pedal and the car will be hard to stop). Figure shows a brake hydraulic system.The brake fluid reservoir is on top of the master cylinder. Most cars today have a transparent r reservoir so that you can see the level without opening the cover. The brake fluid level will drop slightly as the brake pads wear. This is a normal condition and no cause for concern. If the level drops noticeably over a short period of time or goes down to abouttwo thirds full, have your brakes checked as soon as possible. Keep the reservoir covered except for the amount of time you need to fill it and never leave a cam of brake fluid uncovered. Brake fluid must maintain a very high boiling point. Exposure to air will cause the fluid to absorb moisture which will lower that boiling point.The brake fluid travels from the master cylinder to the wheels through a series of steel tubes and reinforced rubber hoses. Rubber hoses are only used in places that require flexibility, such as at the front wheels, which move up and down as well as steer. The rest of the system uses non-corrosive seamless steel tubing with special fittings at all attachment points. If a steel line requires a repair, the best procedure is to replace the compete line. If this is not practical, a line can be repaired using special splice fittings that are made for brake system repair. You must never use copper tubing to repair a brake system. They are dangerous and illegal.制动系统制动系统是汽车中最重要的系统。