阅读说明：本技术 一种轮毂电机驱动汽车悬架系统 (Wheel hub motor driven automobile suspension system ) 是由 施德华 秦启瑞 江恒涛 谢耀东 汪若尘 陈龙 汪少华 朱镇 于 2021-01-15 设计创作，主要内容包括：本发明公开了一种轮毂电机驱动汽车悬架系统,属于车辆新型悬架技术领域。其中,主悬架系统通过上吊耳A与车身相连接,主悬架系统的下端通过下吊耳A与V型连杆机构中的连杆B相连,而连杆B的另一端通过可转动转点与连杆A相铰接,连杆A的另一端与轮毂电机定子外壳相铰接；减振器C的两端分别与连杆A与连杆B的中间部分相铰接；副悬架系统通过减振器B的下吊耳B与转向节相固定,上端通过减振器B的上吊耳B与V型连杆机构中的连杆A中间部分相铰接。车辆受到路面激励时,通过V型杆机构将主悬架系统、副悬架系统和减振器C连接,从而实现联动减振。本发明能够更好的减小轮毂电机驱动带来的垂向振动等问题,有效地改善整车的平顺性和安全性。(The invention discloses an automobile suspension system driven by a hub motor, and belongs to the technical field of novel suspensions of vehicles. The main suspension system is connected with a vehicle body through an upper lifting lug A, the lower end of the main suspension system is connected with a connecting rod B in a V-shaped connecting rod mechanism through a lower lifting lug A, the other end of the connecting rod B is hinged with the connecting rod A through a rotatable rotating point, and the other end of the connecting rod A is hinged with a hub motor stator shell; two ends of the shock absorber C are respectively hinged with the middle parts of the connecting rod A and the connecting rod B; the auxiliary suspension system is fixed with the steering knuckle through a lower lifting lug B of the shock absorber B, and the upper end of the auxiliary suspension system is hinged with the middle part of a connecting rod A in the V-shaped connecting rod mechanism through an upper lifting lug B of the shock absorber B. When the vehicle is excited by the road surface, the main suspension system, the auxiliary suspension system and the shock absorber C are connected through the V-shaped rod mechanism, so that linkage shock absorption is realized. The invention can better reduce the problems of vertical vibration and the like caused by the driving of the hub motor and effectively improve the smoothness and the safety of the whole vehicle.)

1. The utility model provides an in-wheel motor drive automobile suspension system which characterized in that: the suspension system comprises a shock absorber C (13), a main suspension system (100), a secondary suspension system (200) and a V-shaped link mechanism (300);

the V-shaped link mechanism (300) comprises a link A (14) and a link B (15); one end of the connecting rod B (15) is hinged with one end of the connecting rod A (14) at a rotatable end point (18), the other end of the connecting rod B (15) is connected with the main suspension system (100), the middle part of the connecting rod A (14) is connected with the auxiliary suspension system (200), and the other end of the connecting rod A (14) is connected with a stator (22) shell of the in-wheel motor; one end of the shock absorber C (13) is connected to the connecting rod B (15), and the other end of the shock absorber C (13) is connected to the connecting rod A (14).

2. The in-wheel motor driven vehicle suspension system according to claim 1, wherein the primary suspension system (100) comprises a shock absorber a (1), a spring a (2), an upper bracket a (3) and a lower bracket a (4), an upper lifting lug a (5) and a lower lifting lug a (6); the spring A (2) is sleeved on the shock absorber A (1) and is installed in parallel with the shock absorber A (1), the spring A (2) is installed between the upper support A (3) and the lower support A (4), the upper section of the spring A (2) is connected with the upper support A (3), and the lower section of the spring A (2) is connected with the lower support A (4); the main suspension system (100) is connected with a vehicle body (20) through an upper lifting lug A (5) of a shock absorber A (1), and is connected with one end of a connecting rod B (15) in the V-shaped connecting rod device (300) through a lower lifting lug A (6) of the shock absorber A (1).

3. The in-wheel motor driven vehicle suspension system according to claim 1, wherein the secondary suspension system (200) comprises a shock absorber B (7), a spring B (8), an upper bracket B (9), a lower bracket B (10), an upper lug B (11), and a lower lug B (12); the spring B (8) is sleeved on the shock absorber B (7) and is installed in parallel with the shock absorber B (7), the spring B (8) is installed between the upper support B (9) and the lower support B (10), the upper section of the spring B (8) is connected with the upper support B (9), and the lower section of the spring B (8) is connected with the lower support B (10); the auxiliary suspension system (200) is hinged with the middle part of a connecting rod A (14) in the V-shaped connecting rod device (300) through an upper lifting lug B (11) of a shock absorber B (7), and is fixed with a steering knuckle (21) through a lower lifting lug B (12) of the shock absorber B (7).

4. The in-wheel motor driven vehicle suspension system according to claim 1, wherein the left end of the V-shaped linkage (300) is hinged to the stator (22) housing of the in-wheel motor through the end point (19) of the connecting rod a (14); the right end of the V-shaped link mechanism (300) is connected with the lower lifting lug A (6) of the shock absorber A (1) through the other end of the connecting rod B (15) except the rotatable rotating point (18).

5. The in-wheel motor driven vehicle suspension system according to claim 1, wherein the upper ear C (16) of the shock absorber C (13) is hinged to the middle portion of the link B (15) in the V-shaped link mechanism (300), and the lower ear C (17) of the shock absorber C (13) is hinged to the middle portion of the link a (14) in the V-shaped link mechanism (300), and the shock absorber C (13) is formed at a roll angle to the horizontal.

6. The in-wheel motor driven automobile suspension system according to claim 1, further comprising a rotor (23) of the in-wheel motor fixed to the rim (24) so that vibration will be transmitted to the in-wheel motor rotor (23), wherein the in-wheel motor rotor (23) is connected to the in-wheel motor stator (22) so as to drive the in-wheel motor stator (22) to vibrate along with road excitation, the in-wheel motor stator (22) transmits vibration to the connecting rod A (14), and the connecting rod A (14) compresses the vibration absorber B (7) and the spring B (8) in the secondary suspension system (200) to achieve a primary vibration reduction effect; meanwhile, the auxiliary suspension system (200) plays a role of suspending the hub motor in the whole suspension system, and can better inhibit the vertical vibration of the automobile in the driving process compared with the suspension of the traditional hub motor driven automobile; due to the relative overall bouncing of the wheel part and the vehicle body, the shock absorber A (1) and the spring A (2) in the main suspension system (100) are forced to act under the excitation of the road surface, and the main suspension system (100) plays the most important shock absorption effect in the whole suspension system; meanwhile, when the main suspension system (100) and the auxiliary suspension system (200) work together, the connecting rod A (14) and the connecting rod B (15) in the V-shaped connecting rod mechanism (300) rotate relatively under the combined action, and the shock absorber C (13) is compressed.

7. The in-wheel motor driven vehicle suspension system according to claim 6, further comprising a shock absorber C (13) for transmitting the lateral force applied to the vehicle through the connecting rod A (14) of the V-shaped linkage mechanism (300) when the vehicle is impacted laterally, wherein the connecting rod A (14) and the connecting rod B (15) rotate relatively around the rotating point (18) due to the connection between the connecting rod A (14) and the connecting rod B (15) by the rotating point (18), and the shock absorber C (13) is compressed by the connecting rod A (14) and the connecting rod B (15).

Technical Field

The invention relates to a wheel hub motor driven automobile suspension system, and belongs to the technical field of vehicles.

Background

At present, with the successive departure of policy standards, the traditional power automobile gradually transits to a new energy automobile. The latter is significantly simpler in mechanical and electrical structure than the former. The traditional engine is replaced by the system integration of the motor and the battery. However, a further problem is that the transmission system is very complex, in addition to the corresponding simplification of the gearbox construction. At present, the driving technology of the hub motor is applied to a part of new energy automobiles and better progress is made. If the hub motor technology can be completely popularized, the existing transmission system of the automobile can be replaced, the transmission system is greatly simplified, and the development of a new energy automobile is facilitated.

The hub motor has a simple structure, is simply matched with the whole vehicle, omits a mechanical gear shifting device, a transmission shaft, a clutch, a transmission, a differential mechanism and the like, can improve the transmission efficiency and quick response, realizes the electric braking, mechanical composite braking and energy feedback braking of wheels, and simplifies the chassis structure of the vehicle, thereby increasing the internal space of the vehicle and improving the comfort. However, the hub motor technology has some technical difficulties, such as increasing unsprung mass and hub moment of inertia of the automobile, increasing the difficulty of suppressing vibration in the vertical direction of the automobile, and affecting comfort, ride comfort and control stability.

In addition, the structural size of the wheel rim limits the outer diameter size, and the suspension structure of the automobile limits the axial size; the heat dissipation condition of the hub motor is poor, and the heat dissipation problem of the hub motor under the overload condition needs to be solved.

Therefore, a novel vehicle suspension technology and a novel vehicle suspension structure need to be researched, so that the problems of vertical vibration and the like caused by driving of the hub motor can be better reduced, and the smoothness and the safety of the whole vehicle are effectively improved.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: the suspension hub motor can enable the hub motor to drive the vehicle to have better effect of inhibiting vertical vibration in the running process; secondly, the hub motor suspension mode saves the internal space of the hub; meanwhile, the effect of buffering side impact by the vehicle can be achieved.

In order to solve the technical problems, the technical scheme of the invention is as follows: a suspension system of an in-wheel motor driven automobile comprises a shock absorber C (13), a main suspension system (100), a secondary suspension system (200) and a V-shaped link mechanism (300);

the V-shaped link mechanism (300) comprises a link A (14) and a link B (15); one end of the connecting rod B (15) is hinged with one end of the connecting rod A (14) at a rotatable end point (18), the other end of the connecting rod B (15) is connected with the main suspension system (100), the middle part of the connecting rod A (14) is connected with the auxiliary suspension system (200), and the other end of the connecting rod A (14) is connected with a stator (22) shell of the in-wheel motor; one end of the shock absorber C (13) is connected to the connecting rod B (15), and the other end of the shock absorber C (13) is connected to the connecting rod A (14).

Further, the main suspension system (100) comprises a shock absorber A (1), a spring A (2), an upper support A (3), a lower support A (4), an upper lifting lug A (5) and a lower lifting lug A (6); the spring A (2) is sleeved on the shock absorber A (1) and is installed in parallel with the shock absorber A (1), the spring A (2) is installed between the upper support A (3) and the lower support A (4), the upper section of the spring A (2) is connected with the upper support A (3), and the lower section of the spring A (2) is connected with the lower support A (4); the main suspension system (100) is connected with a vehicle body (20) through an upper lifting lug A (5) of a shock absorber A (1), and is connected with one end of a connecting rod B (15) in the V-shaped connecting rod device (300) through a lower lifting lug A (6) of the shock absorber A (1).

Further, the secondary suspension system (200) comprises a shock absorber B (7), a spring B (8), an upper support B (9), a lower support B (10), an upper lifting lug B (11) and a lower lifting lug B (12); the spring B (8) is sleeved on the shock absorber B (7) and is installed in parallel with the shock absorber B (7), the spring B (8) is installed between the upper support B (9) and the lower support B (10), the upper section of the spring B (8) is connected with the upper support B (9), and the lower section of the spring B (8) is connected with the lower support B (10); the auxiliary suspension system (200) is hinged with the middle part of a connecting rod A (14) in the V-shaped connecting rod device (300) through an upper lifting lug B (11) of a shock absorber B (7), and is fixed with a steering knuckle (21) through a lower lifting lug B (12) of the shock absorber B (7).

Further, the left end of the V-shaped link mechanism (300) is hinged with the shell of the stator (22) of the hub motor through an end point (19) of a connecting rod A (14); the right end of the V-shaped link mechanism (300) is connected with the lower lifting lug A (6) of the shock absorber A (1) through the other end of the connecting rod B (15) except the rotatable rotating point (18).

Further, the upper lifting lug C (16) of the shock absorber C (13) is hinged with the middle part of the connecting rod B (15) in the V-shaped connecting rod mechanism (300), and the lower lifting lug C (17) of the shock absorber C (13) is hinged with the middle part of the connecting rod A (14) in the V-shaped connecting rod mechanism (300), so that the shock absorber C (13) forms a certain roll angle with the horizontal direction.

Furthermore, the wheel hub motor comprises a rotor (23) of the wheel hub motor and a rim (24) which are fixed, so that vibration is transmitted to the rotor (23) of the wheel hub motor, at the moment, the rotor (23) of the wheel hub motor is connected with a stator (22) of the wheel hub motor, the stator (22) of the wheel hub motor is driven to vibrate along with road excitation, the stator (22) of the wheel hub motor transmits the vibration to a connecting rod A (14), and the connecting rod A (14) compresses a vibration absorber B (7) and a spring B (8) in a secondary suspension system (200) to achieve a primary vibration attenuation effect; meanwhile, the auxiliary suspension system (200) plays a role of suspending the hub motor in the whole suspension system, and can better inhibit the vertical vibration of the automobile in the driving process compared with the suspension of the traditional hub motor driven automobile; due to the relative overall bouncing of the wheel part and the vehicle body, the shock absorber A (1) and the spring A (2) in the main suspension system (100) are forced to act under the excitation of the road surface, and the main suspension system (100) plays the most important shock absorption effect in the whole suspension system; meanwhile, when the main suspension system (100) and the auxiliary suspension system (200) work together, the connecting rod A (14) and the connecting rod B (15) in the V-shaped connecting rod mechanism (300) rotate relatively under the combined action, and the shock absorber C (13) is compressed.

Further, when the vehicle is impacted laterally, the transverse force borne by the vehicle is transmitted to the shock absorber C (13) through the connecting rod A (14) in the V-shaped connecting rod mechanism (300), and the connecting rod A (14) and the connecting rod B (15) are connected through the rotatable rotating point (18), so that the connecting rod A (14) and the connecting rod B (15) rotate around the rotatable rotating point (18) relatively, and the shock absorber C (13) is compressed by the connecting rod A (14) and the connecting rod B (15).

The invention has the following advantages:

(1) through suspension in-wheel motor, can effectively restrain in-wheel motor drive car at the vertical vibration of the in-process of traveling, overcome in-wheel motor drive car unsprung mass bigger and the problem of the vertical vibration aggravation that causes.

(2) Connect the motor through the connecting rod, remove the damping device of original direct mount in wheel hub inside to wheel hub outside to saved wheel hub inner space, provide great space possibility for the solution of wheel hub motor heat dissipation problem and sealed problem.

(3) The V-shaped structure formed by the two connecting rod devices and the shock absorber in the middle of the two connecting rod devices can play a certain role in damping and buffering when the vehicle is impacted by the side face, and the safety performance of the vehicle is improved when the vehicle is impacted by the side face.

(4) Through the mutual action of the two link devices, the plurality of vibration reduction devices are mutually linked, so that the sensitivity of the vibration reduction performance is improved.

Drawings

Fig. 1 is a schematic diagram of a system architecture of an embodiment of the invention.

In the figure: 1-a shock absorber a; 2-spring A; 3-upper support A; 4-lower support A; 5-upper lifting lug A; 6-lower lifting lug A; 7-shock absorber B; 8-spring B; 9-upper support B; 10-lower support B; 11-upper lifting lug B; 12-lower lifting lug B; 13-shock absorber C; 14-connecting rod a; 15-link B; 16-upper lifting lug C; 17-lower lifting lug C; 18-a rotatable pivot point; 19-a junction point; 20-a vehicle body; 21-a knuckle; 22-a hub motor stator; 23, a wheel hub motor rotor; 24-a rim; 25 tires; 100-a primary suspension system; 200-a secondary suspension system; 300-V type link mechanism.

Detailed Description

The technical solution of the present invention is further explained with reference to the accompanying drawings and specific embodiments.

In the suspension system of the wheel hub motor driven vehicle according to the embodiment of the invention, the main suspension system 100 comprises a shock absorber A1, a spring A2, an upper support A3, a lower support A4, an upper lifting lug A5 and a lower lifting lug A6, the shock absorber A1 is hinged on the vehicle body 20 through the upper lifting lug A5, and the other end of the shock absorber A1 is connected with a rod B15 through a lower lifting lug A6. The spring A2 is sleeved on the shock absorber A1 through an upper support A3 and a lower support A4. The V-shaped linkage 300 includes a link a14 and a link B15, the other end of the link B15 is connected with the link a14 through the rotatable pivot point 18, and the other end of the link a14 is hinged on the housing of the hub motor stator 22. The two ends of the shock absorber C13 are hinged with the middle parts of the connecting rod A14 and the connecting rod B15 respectively, and a certain inclination angle is formed between the connecting rod A14 and the connecting rod B15 and the horizontal direction. The secondary suspension system 200 is hinged to the intermediate portion of the link a14 of the V-link assembly 300 via the upper shackle B11 of the shock absorber B7, and is fixed to the knuckle 21 via the lower shackle B12 of the shock absorber B7. The lower lifting lug B12 of the shock absorber B7 is fixed on the steering knuckle 21, the upper lifting lug B11 of the shock absorber B7 is hinged with the middle part of the connecting rod A14, and the spring B8 is sleeved on the shock absorber B7 through an upper support B9 and a lower support B10.

The rotor 23 of the in-wheel motor is fixed to the rim 24.

The following describes the present invention with reference to the accompanying drawings.

During the running process of the vehicle, the tire 25 and the rim 24 of the vehicle are subjected to the action of road surface excitation to generate vertical vibration, because the in-wheel motor rotor 23 is fixed with the rim 24, the vibration is transmitted to the in-wheel motor rotor 23, and at the moment, because the in-wheel motor rotor 23 is connected with the in-wheel motor stator 22, the in-wheel motor stator 22 is driven to vibrate along with the road surface excitation. The hub motor stator 22 transmits vibration to the connecting rod A14, and the connecting rod A14 compresses a shock absorber B7 and a spring B8 in the secondary suspension system 200 to achieve a primary shock absorption effect; meanwhile, the auxiliary suspension system 200 plays a role of suspending the wheel hub motor in the whole suspension system, and can better inhibit the vertical vibration of the automobile in the driving process compared with the suspension of the traditional wheel hub motor driven automobile. Due to the relative bouncing of the wheel and the vehicle body as a whole, the shock absorber a1 and the spring a2 in the primary suspension system 100 will be forced to act under the excitation of the road surface, and the primary suspension system 100 will play the most important role in damping the shock in the whole suspension system. Meanwhile, when the primary suspension system 100 and the secondary suspension system 200 work together, the link a14 and the link B15 in the V-shaped link mechanism 300 rotate relatively under the combined action, so as to compress the shock absorber C13, and achieve a further shock absorbing effect. In summary, while the suspension system 100 and the secondary suspension system 200 work independently, the primary suspension system 100, the secondary suspension system 200 and the shock absorber C13 are interconnected through the a14 and the link B15 in the V-shaped linkage 300, and when the vehicle is excited by a road surface, the primary suspension system 100, the secondary suspension system 200 and the shock absorber C13 cooperate with each other under the adjustment of the V-shaped linkage, so that the overall sensitivity of the vehicle for damping vibration is improved.

When the vehicle is impacted laterally, the lateral force borne by the vehicle is transmitted to the shock absorber C13 through the connecting rod A14 in the V-shaped connecting rod mechanism 300, the connecting rod A14 is connected with the connecting rod B15 through the rotatable rotating point 18, so that the connecting rod A14 and the connecting rod B15 rotate around the rotatable rotating point 18 relatively, and at the moment, the connecting rod A14 and the connecting rod B15 compress the shock absorber C13 to achieve the effect of shock absorption and buffering. As described above, the present suspension system improves the safety of the vehicle when a side impact is applied to the vehicle by the linkage of the V-shaped link mechanism 300 and the shock absorber C13 therebetween.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the present invention. In the description herein, references to the description of the term "one embodiment," "some embodiments," "an illustrative embodiment," "an example," "a specific example," or "some examples" or the like mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.