阅读说明：本技术 汽车扭力梁结构 (Torsion beam structure of automobile ) 是由 鄢子超 孟凡亮 周鸣昊 于 2020-06-01 设计创作，主要内容包括：本公开提供了一种汽车扭力梁结构,属于车辆的零部件技术领域。弹簧安装盘均包括弹簧安装板、横梁支撑板、第一纵梁支撑板与第二纵梁支撑板,弹簧安装板与横梁及两个纵梁间隔设置,横梁支撑板的一边、第一纵梁支撑板的一边、第二纵梁支撑板的一边分别间隔连接在弹簧安装板的边缘,横梁支撑板与横梁固定连接,第一纵梁支撑板与第二纵梁支撑板均与纵梁的外周壁固定连接。加强弹簧安装板与纵梁之间的相互支撑作用。弹簧安装板的板面,与横梁及两个纵梁所在平面之间的夹角为锐角,弹簧安装盘可以承受部分垂直于横梁及两个纵梁所在平面的方向的作用力,减小横梁与纵梁之间的连接处因垂直于横梁及两个纵梁所在平面的方向的作用力而损坏的可能。(The utility model provides an automobile torsion beam structure belongs to the spare part technical field of vehicle. The spring mounting plate comprises a spring mounting plate, a cross beam supporting plate, a first longitudinal beam supporting plate and a second longitudinal beam supporting plate, the spring mounting plate is arranged at intervals with a cross beam and two longitudinal beams, one side of the cross beam supporting plate, one side of the first longitudinal beam supporting plate and one side of the second longitudinal beam supporting plate are respectively connected to the edge of the spring mounting plate at intervals, the cross beam supporting plate is fixedly connected with the cross beam, and the first longitudinal beam supporting plate and the second longitudinal beam supporting plate are fixedly connected with the outer peripheral wall of the longitudinal beam. The mutual supporting function between the spring mounting plate and the longitudinal beam is strengthened. The plate surface of the spring mounting plate, and the plane of the cross beam and the two longitudinal beams form an acute angle, the spring mounting plate can bear partial acting force in the direction perpendicular to the plane of the cross beam and the two longitudinal beams, and the possibility that the joint between the cross beam and the longitudinal beams is damaged due to the acting force in the direction perpendicular to the plane of the cross beam and the two longitudinal beams is reduced.)

1. The automobile torsion beam structure comprises a cross beam (10), two longitudinal beams (20) and two spring mounting discs (30), wherein the peripheral walls of the two longitudinal beams (20) are respectively connected to two ends of the cross beam (10), one spring mounting disc (30) is connected between the cross beam (10) and each longitudinal beam (20),

the spring mounting plate is characterized in that each spring mounting plate (30) comprises a spring mounting plate (301) and a beam support plate (302), a first longitudinal beam support plate (303) and a second longitudinal beam support plate (304) which are connected to the edge of the spring mounting plate (301), the spring mounting plate (301) is connected with the beam (10) and the two longitudinal beams (20) at intervals, one side of the beam support plate (302), one side of the first longitudinal beam support plate (303) and one side of the second longitudinal beam support plate (304) are respectively connected to the edge of the spring mounting plate (301) at intervals, the beam support plate (302) is fixedly connected with the beam (10), the first longitudinal beam support plate (303) and the second longitudinal beam support plate (304) are fixedly connected with the peripheral wall of the longitudinal beam (20), and the surface of the spring mounting plate (301), and an included angle (alpha) between the cross beam (10) and the plane where the two longitudinal beams (20) are located is an acute angle.

2. The torsion beam structure for vehicle according to claim 1, wherein the spring mounting plate (301) is a circular plate, and the cross beam support plate (302), the first longitudinal beam support plate (303), and the second longitudinal beam support plate (304) are distributed at intervals along a circumferential direction of the spring mounting plate (301).

3. The torsion beam structure for the automobile according to claim 2, wherein a plate surface of the first longitudinal beam support plate (303) is perpendicular to a plate surface of the spring mounting plate (301), the first longitudinal beam support plate (303) has an arc-shaped notch (3031), and the longitudinal beam (20) is located in the arc-shaped notch (3031) and connected with the first longitudinal beam support plate (303).

4. The automobile torsion beam structure according to any one of claims 1 to 3, wherein both end surfaces of the cross beam (10) are recessed semi-cylindrical surfaces, the two longitudinal beams (20) are cylindrical and are respectively disposed in the two semi-cylindrical surfaces, and the diameters of the semi-cylindrical surfaces are equal to the outer diameters of the longitudinal beams (20).

5. The torsion beam structure for vehicle according to any one of claims 1 to 3, wherein the cross-sectional area of the middle portion of the cross-member (10) is smaller than the cross-sectional areas of both ends of the cross-member (10).

6. The torsion beam structure for the vehicle according to any one of claims 1 to 3, further comprising two connecting brackets (40), one connecting bracket (40) being connected to each of the longitudinal beams (20), wherein the connecting brackets (40) comprise an intermediate transition plate (401) and two reinforcing straps (402), the intermediate transition plate (401) and the two reinforcing straps (402) are fixedly connected, the two reinforcing straps (402) are arranged at intervals along a length direction of the longitudinal beam (20), one of the two reinforcing straps (402) is connected to the outer peripheral wall of the longitudinal beam (20), and the other of the two reinforcing straps (402) is connected to an end surface of the longitudinal beam (20).

7. The torsion beam structure for vehicle according to claim 6, wherein the two reinforcing straps (402) are parallel to each other, and the reinforcing straps (402) are perpendicular to the extending direction of the side member (20).

8. The torsion beam structure for vehicles according to claim 6, wherein the intermediate transition plate (401) has deformation-resistant recesses (4011) thereon.

9. The torsion beam structure for vehicle according to claim 6, wherein a damper attachment bracket (60) is further attached to the attachment bracket (40).

10. The torsion beam structure for vehicle according to claim 9, wherein the damper attachment frame (60) includes two ear plates (601) spaced in parallel, the two ear plates (601) being attached to one of the two reinforcing straps (402) at the end of the side member (20).

Technical Field

The disclosure relates to the technical field of parts of vehicles, in particular to an automobile torsion beam structure.

Background

The torsion beam structure is one of key parts of an automobile chassis, and mainly plays a role in transferring force to balance up-and-down jumping of wheels, reduce shaking of the automobile and guarantee stable running of the automobile.

Disclosure of Invention

The embodiment of the disclosure provides an automobile torsion beam structure, which can reduce the possibility of damage of the automobile torsion beam structure from the joint of a cross beam and a longitudinal beam, and ensure the stable operation of the automobile torsion beam structure. The technical scheme is as follows:

the disclosed embodiment provides an automobile torsion beam structure, which comprises a cross beam, two longitudinal beams and two spring mounting discs, wherein the peripheral walls of the two longitudinal beams are respectively connected with two ends of the cross beam, one spring mounting disc is connected between the cross beam and each longitudinal beam,

every the spring mounting dish all includes spring mounting board and connects crossbeam backup pad, first longeron backup pad and the second longeron backup pad at spring mounting board's edge, spring mounting board with crossbeam and two the longeron interval sets up, on one side of crossbeam backup pad the one side of first longeron backup pad the one side difference interval of second longeron backup pad is connected the edge of spring mounting board, the crossbeam backup pad with crossbeam fixed connection, first longeron backup pad the second longeron backup pad all with the periphery wall fixed connection of longeron, spring mounting board's face, with the crossbeam reaches the contained angle between two longeron place planes is the acute angle.

Optionally, the spring mounting plate is a circular plate, and the cross beam support plate, the first longitudinal beam support plate and the second longitudinal beam support plate are distributed along the circumferential direction of the spring mounting plate at intervals.

Optionally, the face of first longeron backup pad is perpendicular to the face of spring mounting panel, the arc breach has in the first longeron backup pad, the longeron is located in the arc breach and with the first longeron backup pad links to each other.

Optionally, two terminal surfaces of crossbeam are sunken semicylinder, two longerons all are the tube-shape and set up respectively in two the semicylinder, the diameter of semicylinder with the external diameter of longeron equals.

Optionally, the cross-sectional area of the middle portion of the cross beam is smaller than the cross-sectional areas of the two ends of the cross beam.

Optionally, the torsion beam structure of the automobile further includes two connecting supports, each of the longitudinal beams is connected with one of the connecting supports, each of the connecting supports includes a middle transition plate and two reinforcing bridging plates, the middle transition plate is fixedly connected with the two reinforcing bridging plates, the two reinforcing bridging plates are arranged at intervals along the length direction of the longitudinal beam, one of the two reinforcing bridging plates is connected with the outer peripheral wall of the longitudinal beam, and the other of the two reinforcing bridging plates is connected with the end face of the longitudinal beam.

Optionally, the two reinforcing straps are parallel to each other, and the reinforcing straps are perpendicular to the extending direction of the longitudinal beam.

Optionally, the intermediate transition plate has deformation-resistant dimples thereon.

Optionally, a shock absorber connecting frame is further connected to the connecting bracket.

Optionally, the shock absorber link includes two parallel spaced-apart ear plates connected to one of the two reinforcement straps and located at an end of the stringer.

The beneficial effects brought by the technical scheme provided by the embodiment of the disclosure at least comprise:

the torsion beam structure of the automobile comprises a cross beam, two longitudinal beams and a spring mounting disc, the middle parts of the two longitudinal beams are connected to the two ends of the cross beam respectively, and one spring mounting disc is connected between each cross beam and one longitudinal beam. The torsion beam structure can be arranged on a chassis of an automobile, a spring on the chassis of the automobile is connected with a spring mounting disc, and the torsion beam structure of the automobile plays a role in transferring force integrally. Every spring mounting dish all includes spring mounting board, crossbeam backup pad, first longeron backup pad and second longeron backup pad, and spring mounting board and crossbeam and two longeron intervals set up, and the edge at spring mounting board is connected at one side of crossbeam backup pad, one side of first longeron backup pad, one side of second longeron backup pad interval respectively, crossbeam backup pad and crossbeam fixed connection, first longeron backup pad and second longeron backup pad all with the periphery wall fixed connection of longeron. The whole joint strength that can strengthen between crossbeam and the longeron of spring mounting dish reduces the junction between crossbeam and the longeron because of the too big possibility of damaging of atress, and the first longeron backup pad and the second longeron backup pad that set up between spring mounting board and the longeron can strengthen the supporting interaction between spring mounting board and the longeron, reduces the possibility that spring mounting dish and longeron itself appear warping. The included angle between the plate surface of the spring mounting plate and the plane where the cross beam and the two longitudinal beams are located is an acute angle, the spring mounting plate can bear the acting force in the direction of the plane where the cross beam and the two longitudinal beams are located, the possibility of cracks or damage at the joint between the cross beam and the longitudinal beams due to the acting force in the direction of the plane where the cross beam and the two longitudinal beams are located is reduced, and the stable work of the torsion beam structure of the automobile is guaranteed.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present disclosure, the drawings used in the description of the embodiments will be briefly introduced below, it is obvious that the drawings in the following description are only some embodiments of the present disclosure, and for those skilled in the art, other drawings can be obtained according to the drawings without inventive efforts,

fig. 1 is a schematic structural view of a torsion beam structure of an automobile provided in an embodiment of the present disclosure;

FIG. 2 is a schematic view of the positions between the spring mounting plate and the longitudinal and transverse beams provided by the embodiment of the present disclosure;

FIG. 3 is a schematic structural diagram of a beam provided by an embodiment of the present disclosure;

FIG. 4 is a schematic view of the spring mounting plate cooperating with the longitudinal beam and the cross beam according to the embodiment of the present disclosure;

FIG. 5 is a schematic view of the attachment bracket and stringer mating provided in accordance with an embodiment of the present disclosure;

fig. 6 is a schematic structural diagram of a connection bracket provided in an embodiment of the present disclosure.

The drawings are identified as follows:

the shock absorber comprises a cross beam 10, a longitudinal beam 20, a cylindrical main body 101, a conical cylinder 102, a spring mounting plate 30, a spring mounting plate 301, a cross beam support plate 302, a first longitudinal beam support plate 303, an arc groove 3031, a second longitudinal beam support plate 304, a connecting bracket 40, a middle transition plate 401, a deformation-resistant pit 4011, a lightening hole 4012, a mounting hole 4013, a reinforcing bridging plate 402, a sleeve 50, a shock absorber connecting frame 60, an ear plate 601, a connecting plate 602, a plug welding hole 6021 and a reinforcing rib plate 603.

Detailed Description

To make the objects, technical solutions and advantages of the present disclosure more apparent, embodiments of the present disclosure will be described in detail with reference to the accompanying drawings.

Fig. 1 is a schematic structural diagram of a torsion beam structure of an automobile provided in an embodiment of the present disclosure, and as shown in fig. 1, the torsion beam structure of an automobile includes a cross beam 10, two longitudinal beams 20, and two spring mounting plates 30, peripheral walls of the two longitudinal beams 20 are respectively connected to two ends of the cross beam 10, and one spring mounting plate 30 is connected between the cross beam 10 and each longitudinal beam 20.

Every spring mounting dish 30 all includes spring mounting plate 301 and connects the crossbeam backup pad 302 at spring mounting plate 301's edge, first longeron backup pad 303 and second longeron backup pad 304, spring mounting plate 301 sets up with crossbeam 10 and two longerons 20 intervals, the one side of crossbeam backup pad 302, the one side of first longeron backup pad 303, the edge at spring mounting plate 301 is connected at the one side of second longeron backup pad 304 interval respectively, crossbeam backup pad 302 and crossbeam 10 fixed connection, first longeron backup pad 303, second longeron backup pad 304 all with the periphery wall fixed connection of longeron 20, the face of spring mounting plate 301, with crossbeam 10 and the contained angle alpha between the plane of two longerons 20 place be the acute angle.

The torsion beam structure of the automobile comprises a cross beam 10, two longitudinal beams 20 and a spring mounting disc 30, wherein the peripheral walls of the two longitudinal beams 20 are respectively connected to two ends of the cross beam 10, and the spring mounting disc 30 is connected between each cross beam 10 and one longitudinal beam 20. The torsion beam structure can be installed on the chassis of the automobile, the spring on the chassis of the automobile is connected with the spring installation plate 30, and the torsion beam structure of the automobile plays a role in transferring force integrally. Each spring mounting plate 30 includes a spring mounting plate 301, a cross beam support plate 302, a first longitudinal beam support plate 303, and a second longitudinal beam support plate 304. The spring mounting plate 301, the cross beam 10 and the two longitudinal beams 20 are arranged at intervals, one side of the cross beam support plate 302, one side of the first longitudinal beam support plate 303 and one side of the second longitudinal beam support plate 304 are respectively connected to the edge of the spring mounting plate 301 at intervals, the cross beam support plate 302 is fixedly connected with the cross beam 10, and the first longitudinal beam support plate 303 and the second longitudinal beam support plate 304 are fixedly connected with the outer peripheral wall of the longitudinal beam 20. The spring mounting plate 30 can strengthen the connection strength between the cross beam 10 and the longitudinal beam 20, and reduce the possibility that the connection part between the cross beam 10 and the longitudinal beam 20 is damaged due to excessive stress. And the first longitudinal beam support plate 303 and the second longitudinal beam support plate 304 arranged between the spring mounting plate 301 and the longitudinal beam 20 can strengthen the mutual supporting action between the spring mounting plate 301 and the longitudinal beam 20, and reduce the possibility of deformation of the spring mounting plate 30 and the longitudinal beam 20. The included angle alpha between the plate surface of the spring mounting plate 301 and the plane where the cross beam 10 and the two longitudinal beams 20 are located is an acute angle, the spring mounting plate 30 can bear partial acting force in the direction perpendicular to the plane where the cross beam 10 and the two longitudinal beams 20 are located, the possibility that cracks or damage occur at the connecting part between the cross beam 10 and the longitudinal beams 20 due to the acting force in the direction perpendicular to the plane where the cross beam 10 and the two longitudinal beams 20 are located can be reduced, and the stable work of the torsion beam structure of the automobile is guaranteed. And the included angle alpha between the planes of the cross beam 10 and the two longitudinal beams 20 is an acute angle, so that when the spring on the automobile is installed on the spring installation plate 30, the spring installation plate 30 can be as close to the horizontal plane as possible, and the acting force can be stably transmitted between the spring on the automobile and the cross beam 10 and the longitudinal beams 20.

Because the junction between the crossbeam 10 and the longeron 20 is not fragile, also can suitably strengthen the tensile strength and the fatigue strength of crossbeam 10 and longeron 20 itself, the improvement of tensile strength and the fatigue strength of crossbeam 10 and longeron 20 of automobile torsion beam structure for automobile torsion beam structure can be used in the great automobile of specification, improves automobile torsion beam structure's commonality. The automobile torsion beam structure provided in the disclosure is overall simpler, the lightweight development requirement of the automobile torsion beam structure is met, the upper limit of the acting force which can be borne by the automobile torsion beam structure is improved on the premise of not increasing excessive cost, and the requirements of different application occasions are met.

In the implementation provided by the present disclosure, the cross beam 10 and the two longitudinal beams 20 may be coplanar, and the plate surfaces of the two spring mounting plates 301 may be coplanar.

To facilitate understanding of the present disclosure, fig. 2 is provided here, fig. 2 is a schematic position diagram between the spring mounting plate and the longitudinal beam and the transverse beam provided in the embodiment of the present disclosure, in fig. 2, a plane a represents a plane where the longitudinal beam 20 and the transverse beam 10 are located, a plane B represents a plane where the plate surface of the spring mounting plate 301 is located, and as shown in fig. 2, an included angle α between the plane a and the plane B is an acute angle.

Optionally, an included angle α between the plane a where the longitudinal beam 20 and the cross beam 10 are located and the plane B where the plate surface of the spring mounting plate 301 is located may be between 3 ° and 10 °.

When the included angle alpha between the plane A and the plane B is between 3 degrees and 10 degrees, the spring mounting disc 30 has a good supporting effect on the longitudinal beam 20 and the cross beam 10, and the spring mounting disc 30 also has good use strength and is not easy to deform, so that the integral stable use of the automobile torsion beam structure can be ensured.

Referring to fig. 1, the torsion beam structure of the automobile may further include sleeves 50, one end of each longitudinal beam 20 is fixedly connected to the outer circumferential wall of one sleeve 50, and the sleeves 50 of the two longitudinal beams 20 are disposed opposite to each other.

The sleeve 50 is arranged at one end of the longitudinal beams 20, and the two longitudinal beams 20 can be connected with other structures on the automobile, such as a frame, through the sleeve 50, so that the integral installation of the torsion beam structure of the automobile is facilitated.

Alternatively, the cross-sectional area of the middle portion of the cross member 10 is smaller than the cross-sectional area of both ends of the cross member 10.

The area of the cross section of the middle part of the cross beam 10 is smaller than the area of the cross sections of the two ends of the cross beam 10, so that the manufacturing cost of the cross beam 10 can be reduced, and meanwhile, the connection strength of the cross beam 10 and the longitudinal beams 20 at the two ends of the cross beam 10 can be improved. The manufacturing cost of the torsion beam structure of the automobile can be reduced as far as possible while the using strength of the torsion beam structure of the automobile is met. Moreover, with the adoption of the structure of the cross beam 10, when the cross beam 10 encounters torque, the cross beam 10 can be slightly twisted on the premise of not generating plastic deformation, partial load on the cross beam 10 is released, and the stable use of the cross beam 10 is ensured.

It should be noted that, in the implementation provided in the present disclosure, the cross section of the cross beam 10 is a section of the cross beam 10 perpendicular to the length direction.

Optionally, both end surfaces of the cross beam 10 are recessed semi-cylindrical surfaces, the two longitudinal beams 20 are both cylindrical and are respectively disposed in the two semi-cylindrical surfaces, and the diameters of the semi-cylindrical surfaces are equal to the outer diameters of the longitudinal beams 20.

The cross beam 10 and the two longitudinal beams 20 can be cylindrical, so that the whole torsion beam structure of the automobile is lighter. The two longitudinal beams 20 are cylindrical and are respectively arranged in the two end faces of the cross beam 10, which are concave semi-cylindrical surfaces, and the matching connection between the cross beam 10 and the longitudinal beams 20 is stable. And the diameter of the semi-cylindrical surface is equal to the outer diameter of the longitudinal beam 20, the connecting position of the cross beam 10 and the longitudinal beam 20 is smoother, the transmission of the acting force between the cross beam 10 and the longitudinal beam 20 is more uniform, and the damage of the longitudinal beam 20 or the cross beam 10 caused by the stress concentration at the connecting position of the cross beam 10 and the longitudinal beam 20 is not easy to occur.

It should be noted that, in other implementation manners provided by the present disclosure, the end surface of the cross beam 20 may also be provided with other shapes, or the cross beam 20 and the longitudinal beam 10 may also be connected by inserting and fixing the cross beam 20 in the longitudinal beam 10, and the present disclosure is not limited herein.

Fig. 3 is a schematic structural diagram of a cross beam provided by an embodiment of the present disclosure, and referring to fig. 3, the cross beam 10 may include a cylindrical main body 101 and a tapered cylinder 102 connected to two ends of the cylindrical main body 101, wherein one end of the tapered cylinder 102 having a smaller diameter is connected to the cylindrical main body 101.

The cross beam 10 comprises a cylindrical main body 101 and conical cylinders 102 connected to two ends of the cylindrical main body 101, the cylindrical main body 101 obtains a form that the area of the cross section is not changed, the cross beam 10 ensures the use strength, meanwhile, the transmission of acting force on the cross beam 10 can be relatively uniform, and the condition that the cross beam 10 is damaged due to stress concentration is reduced.

Alternatively, in one implementation provided by the present disclosure, the cross beam 10 may be obtained by steel pipe stamping. Facilitating the fabrication and acquisition of the beam 10.

In other implementations provided by the present disclosure, the cross beam 10 may also be manufactured by other forming methods, which is not limited by the present disclosure.

Fig. 4 is a schematic view illustrating the spring mounting plate, the longitudinal beam and the cross beam according to the embodiment of the disclosure, and referring to fig. 4, the spring mounting plate 301 is a circular plate, and the cross beam support plate 302, the first longitudinal beam support plate 303 and the second longitudinal beam support plate 304 are distributed at intervals along the circumferential direction of the spring mounting plate 301. The connection and support among the spring mounting plate 301, the first longitudinal beam support plate 303 and the second longitudinal beam support plate 304, the cross beam 10 and the longitudinal beam 20 are easy to realize.

Illustratively, the cross beam support plate 302, the first longitudinal beam support plate 303, and the second longitudinal beam support plate 304 may be disposed on the side wall of the spring mounting plate 301 at intervals along the circumferential direction of the spring mounting plate 301. Facilitating a stable connection between the spring mounting plate 301 and other structures.

Alternatively, the cross member support plate 302, the first longitudinal member support plate 303, and the second longitudinal member support plate 304 may extend in the thickness direction of the spring mounting plate 301. At this time, the cross beam support plate 302, the first longitudinal beam support plate 303, the second longitudinal beam support plate 304 and the spring mounting plate 301 are all in a non-coplanar state, and a better support effect is achieved on the spring mounting plate 301.

Referring to fig. 4, the beam support plate 302 may be fixedly connected to the spring mounting plate 301, a length direction of the beam support plate 302 may be parallel to a length direction of the beam 10, and the beam support plate 302 may be connected to the beam 10 in parallel. At this time, the connection area between the beam support plate 302 and the beam 10 is large, and the connection strength is good.

Alternatively, in the case where the cross member 10 includes the cylindrical body 101 and the tapered cylinder 102, the cross member support plate 302 may be attached to the tapered cylinder 102. The integral connection strength is better.

Alternatively, the plate surface of the first longitudinal beam support plate 303 may be perpendicular to the plate surface of the spring mounting plate 301, the first longitudinal beam support plate 303 has an arc-shaped groove 3031 thereon, the extension direction of the arc-shaped groove 3031 is perpendicular to the plate surface of the first longitudinal beam support plate 303, and one longitudinal beam 20 is disposed in the arc-shaped groove 3031.

The plate surface of the first longitudinal beam supporting plate 303 can be perpendicular to the plate surface of the spring mounting plate 301, the first longitudinal beam supporting plate 303 can reinforce the strength of the side wall part of the spring mounting plate 301, further reinforce the connection strength between the spring mounting plate 301 and the longitudinal beam 20, reduce the deformation of the longitudinal beam 20 and the spring mounting plate 30, and ensure the stable work of the torsion beam structure of the automobile. The first longitudinal beam supporting plate 303 is provided with an arc groove 3031, the extending direction of the arc groove 3031 is perpendicular to the plate surface of the first longitudinal beam supporting plate 303, one longitudinal beam 20 is arranged in the arc groove 3031, the acting force received by the first longitudinal beam supporting plate 303 from the longitudinal beam 20 is different from the acting force received by the first longitudinal beam supporting plate 303 from the spring mounting plate 301, the first longitudinal beam supporting plate 303 can be used as a middle transition piece to stably transmit the acting force from the longitudinal beam 20 to the spring mounting plate 301, and also can be used for stably transmitting the acting force from the spring mounting plate 301 to the longitudinal beam 20, so that the condition of stress concentration of the spring mounting plate 301 or the longitudinal beam 20 is reduced, and the stable use.

Illustratively, the first stringer support plate 303 may extend circumferentially of the spring mounting plate 301. The supporting effect on the spring mounting plate 301 is better.

Illustratively, the length direction of the second stringer support plate 304 may be parallel to the length direction of the stringer 20, and the second stringer support plate 304 is connected parallel to the stringer 20. The coupling strength between the spring mounting plate 301 and the longitudinal beam 20 can be strengthened.

Optionally, the plate surface of the first longitudinal beam support plate 303 is perpendicular to the plate surface of the spring mounting plate 301, an arc notch 3031 is formed in the first longitudinal beam support plate 303, and the longitudinal beam 20 is located in the arc notch 3031 and connected to the first longitudinal beam support plate 303.

The plate surface of the first longitudinal beam support plate 303 is perpendicular to the plate surface of the spring mounting plate 301, an arc notch 3031 is formed in the first longitudinal beam support plate 303, and the longitudinal beam 20 is located in the arc notch 3031 and connected with the first longitudinal beam support plate 303. The first longitudinal beam support plate 303, the second longitudinal beam support plate 304 and the longitudinal beam 20 are connected in different modes, and the acting forces from the longitudinal beam 20, which can be received by the first longitudinal beam support plate 303 and the second longitudinal beam support plate 304, are also different, so that the longitudinal beam 20 can be supported by the first longitudinal beam support plate 303, the second longitudinal beam support plate 304 and the spring mounting plate 301 in different directions, the possibility of deformation and damage of the longitudinal beam 20 is reduced, and the stable use of the torsion beam structure of the automobile is ensured.

Referring to fig. 4, the torsion beam structure of the automobile further includes two connecting brackets 40, one connecting bracket 40 is connected to each longitudinal beam 20, each connecting bracket 40 includes a middle transition plate 401 and two reinforcing straps 402, the middle transition plate 401 is fixedly connected to both the two reinforcing straps 402, the two reinforcing straps 402 are arranged at intervals along the length direction of the longitudinal beam 20, one of the two reinforcing straps 402 is connected to the outer peripheral wall of the longitudinal beam 20, and the other of the two reinforcing straps 402 is connected to the end face of the longitudinal beam 20.

The connecting bracket 40 can carry out limit support on one end of the longitudinal beam 20 close to the spring mounting plate 30, and the possibility of deformation of the longitudinal beam 20 is reduced. In the connecting bracket 40, two reinforcing overlapping plates 402 are arranged at intervals along the length direction of the longitudinal beam, one of the two reinforcing overlapping plates 402 is connected with the outer peripheral wall of the longitudinal beam, the other of the two reinforcing overlapping plates 402 is connected with the end face of the longitudinal beam, and the radial direction and the length direction of the longitudinal beam 20 can be supported, so that the possibility of deformation of the longitudinal beam 20 can be reduced, and the stable operation of the torsion beam structure of the automobile can be ensured.

Optionally, the two reinforcing straps 402 are parallel to each other, and the reinforcing straps 402 are perpendicular to the extension direction of the longitudinal beam 20.

The two reinforcing straps 402 are parallel to each other, and the reinforcing straps 402 are perpendicular to the extending direction of the longitudinal beams 20. The connecting bracket 40 is stable in structure and can support the longitudinal beam 20.

Illustratively, the intermediate transition plate 401 may be perpendicular to the two reinforcing straps 402. The effect of the overall force transmission of the linking bracket 40 is now better.

Referring to fig. 4, a certain space S is formed between the intermediate transition plate 401 and the two reinforcing straps 402.

The structure of the connecting bracket 40 can offset partial acting force from each other in the space S formed between the middle transition plate 401 and the two reinforcing bridging plates 402, and the possibility of damage of the torsion beam structure of the automobile caused by excessive acting force is reduced.

Referring to fig. 4, a shock absorber connecting bracket 60 is also connected to the connecting bracket 40.

The shock absorber connecting frame 60 on the connecting support 40 can be convenient for realize that the connecting support 40 is connected with structures such as shock absorbers on the automobile, and the like, absorbs and converts the impact received by the shock absorbers and the like, and ensures the integral stable operation of the automobile. And the shock absorber coupling brackets 60 are provided on the coupling brackets 40 instead of the side members 20, damage to the side members 20 can be prevented.

Alternatively, the shock absorber attachment bracket 60 may include two ear plates 601 spaced in parallel, the two ear plates 601 being attached to one of the two reinforcement straps 402 at the ends of the side rails 20. The connection between the whole automobile torsion beam structure and the shock absorber 60 is convenient to realize. And the force to which the shock absorber link 60 is subjected can be directly transmitted to the side member 20 through the reinforcing straps 402.

Illustratively, the shock absorber connecting frame 60 may further include a connecting plate 602, the connecting plate 602 is located between the two ear plates 601 and fixed to the two ear plates 601, and a plate surface of the connecting plate 602 is fixed to one of the reinforcing bridging plates 402.

The connecting plate 602 can reinforce the connection strength between the two ear plates 602 and the reinforcing lapping plate 402, and ensure the stable connection between the whole shock absorber connecting frame 60 and the connecting bracket 40.

Optionally, a plug welding hole 6021 may be further disposed on the connecting plate 602, and the plug welding hole 6021 of the connecting plate 602 may be welded and fixed with the reinforcement lapping plate 402.

The connecting plate 602 can also be provided with plug welding holes 6021, the plug welding holes 6021 of the connecting plate 602 can be welded and fixed with the reinforcing lapping plate 402, the connecting strength between the shock absorber connecting frame 60 and the reinforcing lapping plate 402 can be enhanced, and the stable use of the whole structure of the automobile torsion beam is ensured.

Illustratively, the damper connecting frame 60 may further include a reinforcing rib plate 603, and the reinforcing rib plate 603 is disposed perpendicular to one of the ear plates 601 and perpendicular to the plate surface of the same ear plate 601. The stiffener plates 603 may increase the support strength of the ear plate 601.

It should be noted that the two ear plates 601, the connecting plate 602 and the reinforcing rib plate 603 may be an integrated structure. The connection with the connecting bracket 40 is easily accomplished.

In other implementations provided by the present disclosure, the two ear plates 601, the connecting plate 602, and the stiffener plate 603 may also be fabricated in bulk, which is not limited by the present disclosure.

Fig. 5 is a schematic view of the connection bracket and the longitudinal beam provided by the embodiment of the disclosure, and as shown in fig. 5, the middle transition plate 401 may have a deformation-resistant recess 4011.

The anti-deformation concave pits 4011 on the middle transition plate 401 can increase the anti-torque capacity of the middle transition plate 401, and ensure stable connection and use between the connecting bracket 40 and the longitudinal beam 20.

Fig. 6 is a schematic structural diagram of a connection bracket according to an embodiment of the present disclosure, and referring to fig. 6, it can be seen that a deformation-resistant recess 4011 may be formed on the intermediate transition plate 401, and the deformation-resistant recess 4011 may also be disposed between the intermediate transition plate 401 and a reinforcing bridging plate 402. The deformation resistance of the connecting bracket 40 is increased.

Referring to fig. 6, the intermediate transition plate 401 may further include lightening holes 4012. The deformation cost of the attaching bracket 40 can be reduced while the overall strength of the attaching bracket 40 is ensured.

Optionally, a plurality of mounting holes 4013 may be further disposed on the intermediate transition plate 401. Facilitating the connection of the intermediate transition plate 401 to the chucks of the tires on the vehicle.

The above description is intended to be exemplary only and not to limit the present disclosure, and any modification, equivalent replacement, or improvement made without departing from the spirit and scope of the present disclosure is to be considered as the same as the present disclosure.