A0-载货汽车驱动桥
摘要
驱动桥作为汽车的重要组成部分,它的性能的好坏直接影响整车性能。其一般由主减速器、差速器、半轴及桥壳四部分组成,基本功用是增大由传动轴或直接由变速器传来的转矩,将转矩分配给左、右车轮,并使左、右驱动车轮具有汽车行驶运动学所要求的差速功能;此外,还要承受作用于路面和车架或车厢之间的铅垂力、纵向力和横向力。此次设计先论述了驱动桥的总体结构,在分析驱动桥各部分结构型式、发展过程及其以往形式的优缺点的基础上,确定了总体设计方案:采用整体式驱动桥,主减速器的减速型式采用双级减速器,主减速器齿轮采用螺旋锥齿轮,差速器采用圆锥行星齿轮差速器,半轴采用全浮式型式,桥壳采用铸造整体式桥壳。此次设计中,主要完成了双级减速器、圆锥行星齿轮差速器、全浮式半轴的设计和桥壳的校核及材料选取等工作。
关键字:驱动桥、双级主减速器、弧齿锥齿轮、
ABSTRACT
Driving axle assembly is one of the important vehicle carrying pieces and can directly impact on the whole vehicle's performance and its effective life. Driving Axle is consisted of Main Decelerator, Differential Mechanism, Half Shaft and Axle Housing. The basic function of Driving Axle is to increase the torque transmitted by Drive Shaft or directly transmitted by Gearbox, then distributes it to left and right wheel, and make these two wheels have the differential function which is required in Automobile Driving Kinematics; besides, the Driving Axle must also stand the lead hangs down strength, the longitudinal force and the transverse force acted on the road surface, the frame or the compartment lead.The configuration of the Driving Axle is introduced in the thesis at first. On the basis of the analysis of the structure and the developing process of Driving Axle, the design adopted the Integral Driving Axle, Double Reduction Gear for Main Decelerator’s deceleration form, Spiral Bevel Gear for Main Decelerator’s gear, Full Floating for Axle and Casting Integral Axle Housing for Axle Housing. In the design, we accomplished the design for Double Reduction Gear, tapered Planetary Gear Differential Mechanism, Full Floating Axle, the checking of Axle Housing and the election of the material and so on.
Key words: Driving Axle;Double Main Decelerator;Single Reduction Final Drive
目录
摘要I
ABSTRACT II
目录III
第1章绪论1
1.1选题的目的和意义1
1.2研究现状1
1.2.1国内现状1
1.2.2国外现状2
第2章驱动桥结构方案分析4
第3章主减速器设计5
3.1主减速器的结构形式5
3.1.1主减速器的齿轮类型5
3.1.2主减速器的减速形式5
3.1.3主减速器主,从动锥齿轮的支承形式5
3.2主减速器的基本参数选择与设计计算6
3.2.1主减速器计算载荷的确定6
3.2.2主减速器基本参数的选择8
3.2.3主减速器圆弧锥齿轮的几何尺寸计算10
3.2.4主减速器圆弧锥齿轮的强度计算10
3.2.5主减速器齿轮的材料及热处理14
3.2.6主减速器轴承的计算15
第4章差速器设计22
4.1对称式圆锥行星齿轮差速器的差速原理22
4.2对称式圆锥行星齿轮差速器的结构23
4.3对称式圆锥行星齿轮差速器的设计24
4.3.1差速器齿轮的基本参数的选择24
4.3.2差速器齿轮的几何计算26
4.3.3差速器齿轮的强度计算26
第5章驱动半轴的设计28
5.1全浮式半轴计算载荷的确定28
5.2全浮式半轴的杆部直径的初选29
5.3全浮式半轴的强度计算29
5.4半轴花键的强度计算30
第6章驱动桥壳的设计31
6.1铸造整体式桥壳的结构31
6.2桥壳的受力分析与强度计算32
6.2.1桥壳的静弯曲应力计算32
6.2.2在不平路面冲击载荷作用下的桥壳强度计算35
6.2.3汽车以最大牵引力行驶时的桥壳强度计算35
结论38
致谢39
参考文献40
附录41
A0-载货汽车后桥壳体
A2-主动齿轮
A2-从动齿轮
A2-全浮式半轴
字数
摘要
目录
设计所包含文件
