CN115489608A - Lightweight welding aluminum alloy sub vehicle frame - Google Patents

Abstract

The invention belongs to the technical field of aluminum alloy auxiliary frames, and provides a lightweight welded aluminum alloy auxiliary frame which comprises a front cross beam, a rear cross beam, a middle cross beam and longitudinal beams, wherein the front part and the rear part of each longitudinal beam are respectively connected with the front cross beam and the rear cross beam, each longitudinal beam is divided into a left longitudinal beam and a right longitudinal beam, the middle cross beam is connected between the left longitudinal beam and the right longitudinal beam, a front vehicle body mounting bracket is connected between the front cross beam and the longitudinal beams, and a part between the front vehicle body mounting bracket and the longitudinal beams is provided with a part which ensures that the longitudinal beams are pressed in the collision process of the auxiliary frame

And the bending modes are dispersed to the transmission releasing structure of the middle cross beam of the auxiliary frame and the mounting bracket of the rear vehicle body. The invention has the advantages that through reasonably designing the welding and lapping structure of the aluminum profile and other components, the light weight is realized, meanwhile, the overall modal, rigidity, strength, fatigue and other performance indexes of the auxiliary frame can also meet and exceed the target requirements, and the overall frame of the auxiliary frame has good performance in the working conditions of responding to 100% frontal collision and 25% offset collision of the whole vehicle, thereby meeting the target requirements.

Description

Lightweight welding aluminum alloy sub vehicle frame

Technical Field

The invention belongs to the technical field of aluminum alloy auxiliary frames and relates to a lightweight welded aluminum alloy auxiliary frame.

Background

The front and rear power assembly layout of the electric automobile is simpler than that of a traditional fuel vehicle power assembly, the overall layout requirement of the auxiliary frame is smoother, an application space is provided for welding the auxiliary frame by using aluminum alloy sections, the aluminum sections have good formability and crumple characteristics, the production efficiency is high, the yield is high, important functions are exerted on collision safety structural members such as collision beams, doorsill beams and auxiliary frames around the whole automobile, the aluminum sections are applied to the auxiliary frame, the collision requirements of the whole automobile are facilitated, the auxiliary frame is manufactured by adopting an integral die casting auxiliary frame, the production efficiency is low, the development cost is high, and the collision energy absorption effect of the whole automobile is poor; and adopt steel sub vehicle frame frock with high costs, and overall structure is heavier than aluminium sub vehicle frame, and size precision is lower, and the overlap joint scheme is complicated to lead to welding seam length longer, is unfavorable for the lightweight demand.

Disclosure of Invention

The invention aims to solve the technical problem and provides a lightweight welded aluminum alloy auxiliary frame aiming at the current situation of the prior art, and through reasonably designing a welding and lapping structure of an aluminum profile and other components, the lightweight auxiliary frame can meet and exceed the target requirements on the overall modal, rigidity, strength, fatigue and other performance indexes.

The technical scheme adopted by the invention for solving the technical problems is as follows: the utility model provides a lightweight welding aluminum alloy sub vehicle frame, includes front beam, rear frame member, middle cross beam and longeron, front beam and rear frame member are connected respectively to the front portion and the rear portion of longeron, the longeron divide into left longeron and right longeron, middle cross beam connects between left longeron and right longeron, a serial communication port, front beam and longeron between be connected with the preceding of the transmission bridge that is used for collision energyA vehicle body mounting bracket, a front vehicle body mounting bracket and a longitudinal beam are arranged between the front vehicle body mounting bracket and the longitudinal beam, and the auxiliary vehicle frame is used for ensuring the longitudinal beam to press in the collision process

And the bending modes are dispersed to the transmission releasing structure of the middle cross beam of the auxiliary frame and the rear vehicle body mounting bracket.

In the lightweight welded aluminum alloy auxiliary frame, energy-absorbing box mounting brackets are welded on two sides of the front end of the front cross beam, the front vehicle body mounting brackets are respectively connected with the front cross beam and the longitudinal beam, and a vehicle body mounting sleeve is mounted on each front vehicle body mounting bracket.

In the lightweight welded aluminum alloy auxiliary frame, the longitudinal beam is respectively welded with the front cross beam and the rear vehicle body mounting bracket, and the longitudinal beam and the rear vehicle body mounting bracket form a U-shaped lap welding.

In foretell lightweight welding aluminum alloy sub vehicle frame, the rear cross beam be bayonet butt joint with being connected of back automobile body installing support, the longeron on be provided with middle automobile body installing support and preceding lower swing arm support, middle automobile body installing support pass through U type overlap joint and longeron splice welding, preceding lower swing arm support passes through U type overlap joint and longeron welding in Z direction.

In foretell lightweight welding aluminum alloy sub vehicle frame, the cross-section of longeron be the style of calligraphy of a day, the front end of longeron seted up U type groove, transmission release structure is including setting up at the punching press book groove of longeron rear end bottom and setting at the circular port at longeron rear end top, the punching press book groove be the V style of calligraphy.

In the above-mentioned lightweight welded aluminum alloy subframe, the cross-section of the stringer has a first cross-section and a second cross-section, the circular hole penetrates through the upper portion of the first cross-section and the upper portion of the second cross-section, the stamping folding groove is located at the bottom of the second cross-section, and the circular hole is located right above the stamping folding groove.

In the light-weight welding aluminum alloy auxiliary frame, the U-shaped groove and the middle cross beam are provided with the steering engine rivet pressing sleeve.

In the lightweight welded aluminum alloy auxiliary frame, the energy absorption box mounting bracket is connected to the front part of the front cross beam, one end of the longitudinal beam is connected to the rear part of the front cross beam, the vehicle body mounting bracket is connected to the rear part of the front cross beam and the side part of the longitudinal beam, and a cross beam reinforcing bracket is connected between the middle cross beam and the longitudinal beam.

In foretell lightweight welding aluminum alloy sub vehicle frame, the cross-section of automobile body installing support be the style of calligraphy of chinese character ri, the automobile body installing support have first cavity and second cavity, have preceding ladder overlap joint mouth between the front portion of first cavity and the front portion of second cavity, the rear portion of first cavity and the rear portion of second cavity between have the back ladder overlap joint mouth, back ladder overlap joint mouth be located by U type groove, have first overlap joint between the rear portion of first cavity and the longeron and weld the connection face, first overlap joint weld the connection face and be located the first cross-section lateral part of longeron, the rear portion of second cavity and longeron between have the second overlap joint weld the connection face, the second overlap joint weld the connection face and be located the lateral part of the second cross-section of longeron.

In foretell lightweight welding aluminum alloy sub vehicle frame, the front beam be the arc, the front beam has three cavity structures, is provided with middle strengthening rib in three cavity structures.

Compared with the prior art, the invention has the advantages that:

1. through rational design aluminium alloy and other subassembly welding overlap joint structures, in the lightweight, sub vehicle frame whole mode, rigidity, performance index such as intensity and fatigue also can satisfy and be higher than the target demand, extrude the overlap joint relation and the connection structure of section bar each other through the adjustment aluminum alloy, each installation hard spot of rational arrangement, sub vehicle frame whole frame is good in dealing with whole car 100% head-on collision and 25% offset collision operating mode, satisfies the target requirement.

2. The longitudinal beam effectively avoids the envelope of a steering machine and a sheath in a mode of machining a U-shaped groove, and the process cost of avoiding the punched groove is reduced;

3. the U-shaped groove structure at the front end of the longitudinal beam is matched with the V-shaped stamping folding groove at the bottom of the rear end of the longitudinal beamAnd a circular induced collapse feature at the top of the rear end of the longitudinal beam, so that the deformation form of the longitudinal beam reaches 'during collision of the auxiliary frame'

The bending mode effectively protects the power assembly and the front cabin high-pressure casting part, reduces the after-sale maintenance cost and improves the safety of the vehicle.

4. Thin-wall aluminum profile accessible section bar wall thickness adjustment is extruded to front beam, longeron, preceding automobile body installing support etc. satisfies sub vehicle frame performance demand under the different load conditions, and the flexibility is high, and full play extrudees the advantage of section bar crumple energy-absorbing, satisfies sub vehicle frame whole car collision requirement, and the security is high, utilizes the section bar yields height, and size precision is high, and production efficiency is high, has reduced product development and manufacturing cost.

Drawings

FIG. 1 is a schematic view of the overall structure of the lightweight welded aluminum alloy subframe;

FIG. 2 is a schematic structural view of the longitudinal beam, the front cross beam and the vehicle body after the bracket is installed;

FIG. 3 is a schematic perspective view of a longitudinal beam of the lightweight welded aluminum alloy subframe;

FIG. 4 is a schematic cross-sectional view of a stringer of the present lightweight welded aluminum alloy subframe;

FIG. 5 is a perspective view of the front cross member;

fig. 6 is a schematic structural view of the lower swing arm support.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments. It is to be understood that the described embodiments are merely a few embodiments of the invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "central," "lateral," "longitudinal," "front," "rear," "left," "right," "upper," "lower," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for convenience in describing the invention and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and are not to be considered limiting to the scope of the present invention.

In the figure, a front cross member 100; the rear cross member 200; a middle cross member 300; a left longitudinal beam 400; a right stringer 500; a left crash box mounting bracket 600; a right crash box mounting bracket 700; a left front body mount bracket 800; a right front body mount bracket 900; a left rear body mount bracket 1000; a right rear vehicle body mounting bracket 1001; a left front sleeve 1002 of the steering gear; a steering engine right front sleeve 1003; a steering rear sleeve 1004; a U-shaped groove 1005; a stamped folded slot 1006; a first cross-section 1007; a second cross-section 1008; a middle stiffener 1009; a front step lap joint 1010; a rear step lap 1011; a first lap weld joint face 1012; a second lap weld joint surface 1013; left cross member reinforcing bracket 1014; right beam reinforcing brackets 1015; a left center body mount bracket 1016; a right mid-body mounting bracket 1017; a left front lower swing arm support 1018; a right front lower swing arm bracket 1019; a circular hole 1020; a vehicle body mount bushing 1021.

As shown in figure 1, the lightweight welded aluminum alloy auxiliary frame comprises a front cross beam 100, a rear cross beam 200, a middle cross beam 300 and longitudinal beams, wherein the front portion and the rear portion of each longitudinal beam are respectively connected with the front cross beam 100 and the rear cross beam 200, each longitudinal beam is divided into a left longitudinal beam 400 and a right longitudinal beam 500, the middle cross beam 300 is connected between the left longitudinal beam 400 and the right longitudinal beam 500, a front vehicle body mounting bracket for transmitting collision energy is connected between the front cross beam 100 and the longitudinal beams, and a device for ensuring the longitudinal beams to press the longitudinal beams in the collision process of the auxiliary frame is arranged between the front vehicle body mounting bracket and the longitudinal beams

The bending modes are dispersed to the transmission release structure of the auxiliary frame middle cross beam 300 and the rear vehicle body mounting bracket, so that the power assembly and the front cabin high-pressure casting part can be effectively protected,the after-sale maintenance cost is reduced, and the safety of the vehicle is improved.

Specifically, energy-absorbing box mounting brackets are welded on two sides of the front end of the front cross beam 100, the energy-absorbing box mounting brackets are divided into a left energy-absorbing box mounting bracket 600 and a right energy-absorbing box mounting bracket 700, the left energy-absorbing box mounting bracket 600 and the right energy-absorbing box mounting bracket 700 are fixed on two sides of the front end of the front cross beam 100 of the subframe in a welding mode, the front vehicle body mounting bracket is used as a transmission bridge of collision energy and is respectively connected with the front cross beam 100 and a longitudinal beam, the front vehicle body mounting bracket is divided into a left front vehicle body mounting bracket 800 and a right front vehicle body mounting bracket 900, a vehicle body mounting sleeve 1021 is arranged on the front vehicle body mounting bracket, the longitudinal beam is respectively welded with the front cross beam 100 and a rear vehicle body mounting bracket, the longitudinal beam and the rear vehicle body mounting bracket form a U-shaped lap joint, the rear vehicle body mounting bracket is also divided into a left rear vehicle body mounting bracket 1000 and a right rear vehicle body mounting bracket 1001, so that the length of a welding seam is prolonged and the welding strength of the region is improved, the fatigue risk is reduced, the U-shaped groove 1005 and the middle cross beam 300 are provided with steering engine press riveting sleeves, the steering engine press riveting sleeves of the U-shaped groove 1005 are divided into a steering engine left front sleeve 1002 and a steering engine right front sleeve 1003, the steering engine left front sleeve 1002 and the steering engine right front sleeve 1003 are respectively fixed on the left longitudinal beam 400 and the right longitudinal beam 500 through a cold connecting press riveting mode and are used as mounting supports of the steering engine, the steering engine rear sleeve 1004 is fixed inside the middle cross beam 300 through a two-point or four-point press riveting mode in a sub-part stage, the scheme adopts a cold connecting process, the welding deformation can be reduced, the connection between the rear cross beam 200 and a rear vehicle body mounting bracket is optimized as plug-in butt joint, the structural strength and the rigidity are improved, the longitudinal beams are provided with a middle vehicle body mounting bracket and a front lower swing arm bracket, the middle vehicle body mounting bracket is divided into a left middle vehicle body mounting bracket 1016 and a right middle vehicle body mounting bracket 1017, preceding lower swing arm support divide into lower swing arm support 1018 before left and lower swing arm support 1019 before the right side, middle automobile body installing support passes through U type overlap joint and longeron splice welding, improve preceding lower swing arm Z of sub vehicle frame and to dynamic rigidity, satisfy whole car NVH requirement, as optimizing, as shown in fig. 6, preceding lower swing arm support passes through U type overlap joint and longeron welding to Z, reduce like this and break away from the risk in the whole car collision operating mode in the swing arm support fracture, can furthest's satisfied vehicle safety demand in the vehicle collision operating mode.

As shown in figures 3 and 4, the longitudinal beam is formed by aluminum alloy in an extrusion mode, the cross section of the longitudinal beam is in a shape like a Chinese character 'ri', the wall thickness size range of the longitudinal beam is +/-2 mm, the length and width size range of the cross section is +/-15 mm, the development requirements of various auxiliary frame longitudinal beams can be met, a U-shaped groove 1005 is formed in the front end of the longitudinal beam, the U-shaped groove 1005 is mainly used for avoiding a gap of a steering machine, the problem that the longitudinal beam and the steering machine are pressed and riveted with a sleeve is solved, the biggest innovation of the patent is that the rear end of the longitudinal beam is provided with a U-shaped groove 1005 which is matched with the U-shaped groove 1005, and the longitudinal beam is guaranteed to be pressed and riveted on the auxiliary frame in the collision process

The type is bent mode's transmission release structure, here will collide the energy and will transmit to longeron department and absorb and transmit when whole sub vehicle frame receives the collision, and this patent mainly utilizes transmission release structure to release the energy, make sub vehicle frame in the collision process, the deformation form of longeron reaches

The transmission releasing structure comprises a stamping folding groove 1006 arranged at the bottom of the rear end of the longitudinal beam and a circular hole 1020 arranged at the top of the rear end of the longitudinal beam, the stamping folding groove 1006 is V-shaped, the cross section of the longitudinal beam is provided with a first cross section 1007 and a second cross section 1008, the circular hole 1020 penetrates through the upper part of the first cross section 1007 and the upper part of the second cross section 1008, the stamping folding groove 1006 is arranged at the bottom of the second cross section 1008, the circular hole 1020 is arranged right above the stamping folding groove 1006 and is further optimized, the U-shaped groove 1005 is arranged on the first cross section 1007, a steering machine riveting sleeve is arranged on the U-shaped groove 1005, collision energy generated in the collision process of the secondary frame is transmitted to the longitudinal beam, due to the existence of the U-shaped groove, the whole longitudinal beam can be in an upward folding state 1020, and meanwhile, due to the existence of the circular hole and the stamping folding groove 1006, the circular hole 1020 and the stamping folding groove 1006 are equivalent to an induced collapse opening, energy is induced to be induced to the existence of the energyLeading to the rear end, a downward condition is created at the stamped crease 1006, which allows the subframe to achieve a frontal 100% rigid wall impact condition

The type mode of bending, the collision mode of collapsing satisfies whole car requirement, satisfies whole car and bends the mode demand to sub vehicle frame collision.

Here, in the longitudinal beam in fig. 3, a front cross beam 100, a vehicle body mounting bracket and an energy absorption box mounting bracket are arranged at the front part of the longitudinal beam, as shown in fig. 5, the front cross beam 100 is integrally arc-shaped, the front cross beam 100 is mainly designed through a three-cavity structure, the arrangement of a middle reinforcing rib 1009 plays an important role in the transmission of collision energy, the wall thickness size range of the front cross beam 100 is ± 1mm, the length and width size range of a cavity is ± 10mm, the angle variation range is ± 10 °, various sub-frame performance development requirements can be met, the energy absorption box mounting bracket is connected at the front part of the front cross beam 100, one end of the longitudinal beam is connected at the rear part of the front cross beam 100, and the vehicle body mounting bracket is connected at the rear part of the front cross beam 100 and the side part of the longitudinal beam, wherein the energy absorption box mounting bracket is used for mounting the energy absorption box, the vehicle body mounting bracket plays a role of a collision energy transmission bridge, collision energy is dispersed to the sub-frame middle cross beam 300 and the rear mounting bracket through the energy absorption box mounting bracket, so as to meet the requirements of a bending mode.

The cross section of the vehicle body mounting bracket is in a shape of Chinese character 'ri', the vehicle body mounting bracket is provided with a first cavity and a second cavity, a front step overlapping opening 1010 is arranged between the front part of the first cavity and the front part of the second cavity, a rear step overlapping opening 1011 is arranged between the rear part of the first cavity and the rear part of the second cavity, the rear step overlapping opening 1011 is positioned beside the U-shaped groove 1005, the problem of height difference connection of a gap position of the U-shaped groove 1005 of the front cross beam 100 and the longitudinal beam can be solved through the front step overlapping opening 1010 and the rear step overlapping opening 1011, a first overlapping welding connection surface 1012 is arranged between the rear part of the first cavity and the longitudinal beam, and the first overlapping welding connection surface 1012 is positioned on the side part of a first cross section 1007 of the longitudinal beam, a second lap joint welding connecting surface 1013 is arranged between the rear part of the second cavity and the longitudinal beam, the second lap joint welding connecting surface 1013 is positioned at the side part of the second cross section 1008 of the longitudinal beam, on one hand, collision energy can be better transmitted to the longitudinal beam for transmission and absorption through the first lap joint welding connecting surface 1012 and the second lap joint welding connecting surface 1013, on the other hand, lap joint welding consisting of two surfaces is formed, the length of a welding seam is prolonged, the welding strength of the area is improved, and the fatigue risk is reduced, a cross beam reinforcing bracket is connected between the middle cross beam 300 and the longitudinal beam and is divided into a left cross beam reinforcing bracket 1014 and a right cross beam reinforcing bracket 1015, and the cross beam reinforcing brackets are welded in an angle lap joint mode and can provide stress support in 25% small offset collision of the auxiliary frame; the performance indexes of the whole frame structure in all aspects meet the requirements of the whole vehicle, the welding and lapping structure is stable and reliable,

and the front cross beam 100, the longitudinal beam, the vehicle body mounting bracket and the like can extrude thin-wall aluminum profiles through profile wall thickness adjustment, the performance requirements of the auxiliary frame under different load conditions are met, the flexibility is high, the advantages of collapse and energy absorption of the extruded profiles are fully exerted, the collision requirements of the auxiliary frame on the whole vehicle are met, the safety is high, the yield of the utilized profiles is high, the size precision is high, the production efficiency is high, and the product development and production cost is reduced.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the described embodiments may be made by those skilled in the art without departing from the scope and spirit of the invention as defined by the accompanying claims.

Claims (10)

1. The utility model provides a lightweight welding aluminum alloy sub vehicle frame, includes front beam, rear frame member, middle cross beam and longeron, front beam and rear frame member are connected respectively to the front portion and the rear portion of longeron, the longeron divide into left longeron and right longeron, middle cross beam connects between left longeron and right longeron, a serial communication port, front beam and longeron between be connected with the preceding automobile body installing support that is used for the transmission bridge of collision energy, have between preceding automobile body installing support and longeron and guarantee the longeron according to the collision process at the auxiliary frame and press at the auxiliary frame member

And the bending modes are dispersed to the transmission releasing structure of the middle cross beam of the auxiliary frame and the rear vehicle body mounting bracket.

2. The lightweight welded aluminum alloy subframe according to claim 1, wherein energy-absorbing box mounting brackets are welded to both sides of the front end of the front cross beam, the front body mounting brackets are respectively connected with the front cross beam and the longitudinal beam, and a body mounting sleeve is mounted on each front body mounting bracket.

3. The lightweight welded aluminum alloy subframe according to claim 1 or 2, wherein the side members are welded to the front cross member and the rear body mounting bracket, respectively, and the side members and the rear body mounting bracket are welded together in a U-shaped lap joint.

4. The lightweight welded aluminum alloy subframe according to claim 3, wherein the rear cross member is connected to the rear body mount bracket in a plug-in butt joint manner, the side member is provided with a center body mount bracket and a front lower swing arm bracket, the center body mount bracket is welded to the side member by a U-lap joint, and the front lower swing arm bracket is welded to the side member by a Z-direction U-lap joint.

5. The lightweight welded aluminum alloy auxiliary frame as claimed in claim 1, wherein the cross section of the longitudinal beam is a rectangular shape, the front end of the longitudinal beam is provided with a U-shaped groove, the transmission release structure comprises a stamped folded groove formed in the bottom of the rear end of the longitudinal beam and a circular hole formed in the top of the rear end of the longitudinal beam, and the stamped folded groove is V-shaped.

6. The lightweight welded aluminum alloy subframe according to claim 5, wherein the cross section of the side member has a first cross section and a second cross section, the circular hole penetrates through an upper portion of the first cross section and an upper portion of the second cross section, the stamped folded groove is located at a bottom of the second cross section, and the circular hole is located directly above the stamped folded groove.

7. The lightweight welded aluminum alloy subframe as claimed in claim 5, wherein the U-shaped groove and the middle cross beam are provided with steering gear rivet pressing sleeves.

8. The lightweight welded aluminum alloy subframe according to claim 2, wherein the crash box mounting bracket is connected to a front portion of the front cross member, one end of the side member is connected to a rear portion of the front cross member, the body mounting bracket is connected to a rear portion of the front cross member and side portions of the side member, and a cross member reinforcing bracket is connected between the middle cross member and the side member.

9. The lightweight welded aluminum alloy subframe according to claim 8, wherein the body mount bracket has a cross-section in a shape of a Chinese character 'ri', the body mount bracket has a first cavity and a second cavity, a front step overlapping opening is provided between a front portion of the first cavity and a front portion of the second cavity, a rear step overlapping opening is provided between a rear portion of the first cavity and a rear portion of the second cavity, the rear step overlapping opening is located beside the U-shaped groove, a first lap-welded joint surface is provided between the rear portion of the first cavity and the side member, the first lap-welded joint surface is located on a side portion of the first cross-section of the side member, a second lap-welded joint surface is provided between the rear portion of the second cavity and the side member, and the second lap-welded joint surface is located on a side portion of the second cross-section of the side member.

10. The lightweight welded aluminum alloy subframe as set forth in claim 1, wherein said front cross member is curved, and has a three-cavity structure with intermediate ribs disposed therein.

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