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1、Elementary Vehicle Dynamics (汽车理论),Preface,What can we learn from this course?,Whats the aim of this course,To find out the reasonable method to design and use vehicle according to the relationship among the parameters of structure and performance of vehicle. (通过车辆结构参数与性能之间的关系,找到正确设计汽车的方法和合理使用汽车的途径)
2、,Chapter one Acceleration Performance,1.1 Evaluation Index(评价指标) 1.Maximum Vehicle Speed (Velocity)最高车速uamax (km/h): (1)Definition:The maximum speed which the vehicle can get under good and flat road with rated load (额定载荷). (2)Actual Measurement of uamax,2. Acceleration Ability(加速能力) (1)The accelera
3、tion ability for starting(原地起步加速能力) Test Condition : Full engine power (油门全开); Optimal shift point between gears(最佳换档时机) which are from low gear (第档) for start-up to high gear (最高档) for fuel economy. Evaluation IndexT T is the time needed by the vehicle to accelerate from 0 to 0.8Uamax under the abo
4、ve test condition or the time needed to pass through a fixed distance (400 m or mile(402.5m)). (用档起步,按最佳换档时间,逐次换至高档,油门全开,以最大加速度行驶,全力加速至 0.8uamax所需时间,或通过某 一预定距离所需时间) (2)The acceleration ability for high speed driving(超车加速能力) Test condition: Full engine power ; High gear(最高档)or inferior high gear(次高档)
5、 Evaluation indexT T is the time need to accelerate from the minimum stable speed of high gear(最高档的最小稳定车速)to 0.8Uamax or the time needed to pass through a fixed distance (400 m or mile). (在直接档工作时,油门全开,由该档的最小稳定车速全力加速至 0.8Uamax所需时间,或通过某一预定距离所需的时间),3.Maximum Gradeability of Vehicle imax(最大爬坡度),(1)Defin
6、ition: The maximum grade which the vehicle can climb in the first gear(档) under good road condition with fully rated load(额定满载). i=tg EQ140 imax=28% EQ240 imax=58% =30 (2)Actual Measurement of imax,1.2 Driving Mechanics of Vehicle,To analyze the balance between Total Roads(行驶阻力)and Tractive Force(驱动
7、力)along one degree of freedom(自由度) that is longitudinal direction(纵向). 1.Tractive Force(驱动力), Torque of Engine Flying Wheel Numerical Ratio of the Transmission Numerical Ratio of the Final drive Total efficiency of driveline Torque of Driving Wheel,(1)Torque of Engine,Engine maybe characterized by i
8、ts torque and power curve as a function of speed. Figure 1. shows typical curves for gasoline engine. Figure 1. Performance characteristics (外特性曲线) of gasoline,Full performance and Full performance with all the accessories (外特性与使用外特性),Useful formulas for Power calculation,Unit: Pe (kW) ; Ttq (Nm); n
9、(r/min)。,(2)Efficiencies of Driveline,The necessity of the introduction of T: The inefficiencies due to mechanical and viscous losses in the driveline components(transmission; driveshaft; differential and axles)have not been taken into account. These act to reduce the engine torque in proportion to
10、the products of the efficiencies of the individual components. T (combined efficiency of driveline) consists of four primary parts: 离合器 变速箱 传动轴 驱动桥,(3)Tire Radius,Definition: Nominal Radius(自由半径): the radius of tire without load (spare tire 备胎 radius). Static Loaded Radius(静力半径) :the distance from t
11、he center of static tire to the contact point with ground under vertical load only. Rolling Radius(滚动半径) : the radius which is measured by S (distance passed by vehicle)and n (rolling numbers).,(4)Graph of Tractive Force (驱动力图),How to make tractive force-speed characteristics graph: 1)Mathematical c
12、onversion between n(engine revolution speed) and (vehicle speed ) Note: (km/h) ; n (r/min); r (m),2)Make the graph,Two basic formulas for making the graph: Make the tractive force line of each gear (given )of the vehicle(given & given r and given ):,Make all the curves of the vehicle figure1.2: Figu
13、re 1.2 Tractive force-speed characteristics for a manual transmission,3)Conclutions from the graph of tractive force:,“Constant Engine Power” is equal to the maximum power of the engine; which is the upper limit of tractive force available, less any losses in the driveline. The curves illustrate vis
14、ually the need to provide a number of gear ratios for operation of the vehicle ( low gearing for start-up, and high gearing for high-speed driving). For maximum acceleration performance the optimum shift point between gears is the point where the line cross. The area between the lines for the differ
15、ent gears and the constant power curve is indicative of the deficiencies of(缺乏,不足) the transmission in providing maximum acceleration performance.,2. Road Load force (行驶阻力),(1)Rolling Resistance Force F f(滚动阻力) Energy losses: Due to the deflection of tires: Due to the deflection of road surface: con
16、verted into the heat within the tires caused by the friction of rubber particles Rolling resistance torque T f (滚动阻力偶矩) T f = F za,The mechanics analysis of driven wheel with constant revolution,assume Rolling Resistant Force of driven wheel (从动轮的滚动阻力) assume a/r = f ( Coefficient of rolling resista
17、nt) 滚动阻力系数 conclution: under given conditions( stiff road; constant revolution speed),assumed : driving force rolling resistance force of driving wheel total rolling resistance :,The mechanics analysis of driving wheel with constant revolution,Note:,1.Rolling resistance is present from the instant t
18、he wheels begin to turn. 2.The rolling resistance is the primary motion resistance force. 3.For off-high way, level ground operation, the rolling resistance is the only significant retardation force. 4. usually is equal to 0.012.,(2)Aerodynamic Drag(空气阻力),Aerodynamic forces interact with the vehicle
19、 causing drag,lift (or down load),lateral forces,and their individual moments. The Aerodynamic forces produced on a vehicle arise from two sources: Note: 1)Total Internal Drag comprises of air flow management of cooling system and inside ventilation of the body.(发动机冷却、车身通风) With no attention to the
20、need for air flow management, the air entering through the radiator dissipates much of its forward momentum against the vehicle components in the engine compartment before spilling out through the underside openings. The momentum exchange translates directly into increased drag.,2)Bernoullis Equatio
21、n: P -大气压; -空气密度;C-常数 Zero underbody(车身底板) air speed produces the pressure difference Lift Force unsmoothed underbody panel Induced Friction ( the projection of lift force along the longitudinal direction) (minimizing underbody drag is the use of a smooth underbody panel) 3)For minimizing Form Drag
22、we adopt the body of streamlined shape ( 流线形)which is usually be described as drop-like body.,Calculation of Aerodynamic Forces Fw Semi-empirical models: Where: Aerodynamic drag coefficient(空气阻力系数) Frontal area of the vehicle(迎风面积) Air density (空气密度) Relative Velocity(相对速度) International CD: China C
23、D Cars 0.300.35 Cars 0.4 Vans 0.330.35 Vans 0.6 Pickup trucks 0.420.46 Pickup trucks 0.8 Because of ua (km/h) ;ur(m/s);ur=ua/3.6 (m/s) (no wind) So,(3)Uphill Grade Resistance Force F i(坡道阻力),Define: Road Resistance (道路阻力) Define: Road Resistance Coefficient (道路阻力系数),(4)Acceleration ResistanceFj,1.Tr
24、anslational mass inertial force (平移质量惯性力)Fj1 G/g质量 du/dt加速度 2.Rotational mass inertial force (moment) (回转质量惯性力or 力矩)(Tj; Fj2) (rotating components comprise of fly wheel, gear system, shafts&axles, wheels) I转动惯量 d/dt角加速度 Inertial moment for fly wheel e angular velocity of fly wheel w angular velocity
25、 of wheel Ua vehicle speed r radius of wheel,Deliver Tf to driving wheel Tfw 2) Total inertial moment for wheel and rotational mass inertial force Tj;Fj2 3. Total Inertial Force Fj Assumed : rotational mass coefficient (回转质量换算系数) So,3.Driving Equation(行驶方程),1)General model of driven wheel: 2) Genera
26、l model of driving wheel:,3)General model of vehicle: Note: Fjw2 comprises of two parts :1) the rotational mass inertial force of fly wheel that is delivered into the driving wheel; 2) the rotational mass inertial force of the driving wheel itself ; For general model of the vehicle ,Fp and Ft are co
27、nsidered as internal forces ,so there is no Fp and Ft on the graph. Ft and Ff are the result of assumption , so there is neither Ft nor Ff on the graph.,1.3 Traction-Limited Acceleration,(1)Driving Condition of Acceleration When Level road: Constant speed: Level road & Constant speed: For constant s
28、peed: (匀速) acceleration: (加速) deceleration: (减速) So Driving Condition(驱动条件) is,(2)Limited Condition of Acceleration (附着条件) Presuming there is adequate power from the engine, the acceleration may be limited by the friction that is between the tire and road for anti-skid purpose. In this case is : (限制
29、车轮打滑的极限力) Where: Coefficient of friction (道路附着系数) Weight on drive wheels (驱动车轮上道路垂直反力) usually ranges from 0.7-0.8 (3)Traction-limited Acceleration (驱动附着条件),(4)Traction Limits (maximum tractive force) (最大牵引力),Clew : Independent front drive axle (maximum tractive force for front drive axle) Independe
30、nt rear drive axle (maximum tractive force for rear drive axle) 1) by(equilibrium of static equilibrium)(求矩) 2) when:,For rear drive axle(rear-wheel-drive cars) : Also in the case of front drive axle(front-wheel-drive cars): In the case of four-wheel-drive cars:,5)percentage of utilization of maximu
31、m tractive force (附着利用率),Definition: (汽车附着力/全轮驱动汽车附着力=附着利用率) Where: Maximum tractive force of front-wheel-drive cars Maximum tractive force of rear-wheel-drive cars Maximum tractive force of four-wheel-drive cars For front-wheel-drive cars: rear-wheel-drive cars: four-wheel-drive cars:,Graph of : No
32、te: increase leads to decrease in the case of fron-wheel-drive ; is the percentage of utilization of cars weight on the drive axle; Forward longitudinal weight transfer and increase in the case of front-wheel-drive car; (质心偏移) For cars the load on the front (drive) axle is usually higher than the lo
33、ad on the rear axle; (前部轴荷后部轴荷),1.4 Tractive Force & Driving ResistanceSpeed Characteristics (驱动力-行驶阻力平衡图),From Drivng Equation: when level road & constant speed To (Driving Resistance comprises of and ) Analyze : Acceleration Performance of the vehicle through Tractive Force & Driving Resistance-Sp
34、eed Characteristics. (1)Maximum Vehicle Speed (Velocity) (km/h): So is the corresponding x-coordinate of the cross point of the driving resistance curve and the tractive force curve of the fourth (high-speed) gear.,(2)Maximum Gradeability of Vehicle,The maximum uphill grade resistance force which th
35、e vehicle could overcome F i(坡道阻力) (3)Acceleration Ability Estimate : The acceleration ability of the vehicle at any speed(ua1). the tractive force which the vehicle need to drive with constant speed (ua1). the maximum tractive force which could be used to accelerate at this speed (ua) Conclusion: T
36、he acceleration ability changes with the change of gear. Higher gear leads to lower acceleration ability. Changing the position of pedal make the constant speed drive possible because the tractive force-speed curve would move up and down vertically with the change of injection system. (the force-spe
37、ed curves shown above is the upper limit ones of the vehicle),1.5 Dynamic Character of Vehicle (汽车的动力特性),In order to make the analysis of dynamic performance simpler ,we use another group of characteristic curves which comprise the Dynamic Characteristic Graph (动力特性图)of the vehicle. Method: (The rig
38、ht side of the equation concerns the grade ability and acceleration ability only ,it has nothing to do with the mass of the vehicleG/g ) Definition: So: where: Ddynamic factor (动力因数) road resistance coefficient (道路阻力系数) Note : D=f when : constant speed du/dt=0 level road =0 f=0.012 under the most si
39、tuation f0.02 when ua50 km/h where f0=0.012 ua f,Analyze: (1)Maximum Vehicle Speed (Velocity) (km/h): So is the corresponding x-coordinate of the cross point of f curve and D curve of the fourth (high-speed) gear. (2) Maximum Gradeability of Vehicle So when climbing the soft grade (坡度小) because cos=
40、1, sintgi, D=f+i when climbing the big grade(坡度大) because,(3)Acceleration ability: driving on the level road So How to calculate T which is the evaluation index of acceleration ability ?,1.6 Power Equilibrium,1.Equation of Power Equilibrium: 2. How to make the Graph of Power Equilibrium: because : (
41、功率平衡图),abreverse supply of power(后备功率),1. is the corresponding x-coordinate of the cross point of the resistance power curve and the full power curve of the fourth (high-speed) gear. 2. The reverse supply of power changes with the change of gear.- Higher gear leads to lower reverse supply of power and acceleration ability. 3. -The maximum difference between the resistance power curve from the full power curve of the first (-speed) gear,
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