JP2020147123A - Suspension arm and motor vehicle suspension structure - Google Patents

Abstract

To improve strength and rigidity in a suspension arm.SOLUTION: A lower arm 2 serving as a suspension arm has: a body 13 including a curved wall part 23; a first flange 31 protruding from the curved wall part 23 to the inner periphery side of the curved wall part 23 and extending along a longitudinal direction L1 of the curved wall part 23; a second flange 34 extending along the longitudinal direction L1 and joined to the first flange 31; and first and second extension parts 33, 36 provided at a tip of the first flange 31 and a tip of the second flange and extending in directions different from a direction in which each flange 31, 34 extends when viewed in the longitudinal direction L1.SELECTED DRAWING: Figure 4

Description

The present disclosure relates to suspension arms and automobile suspension structures.

The suspension arm described in Patent Document 1 is used for a double wishbone suspension.

JP-A-59-102606

In addition to the double wishbone suspension described above, there are strut suspensions and the like as automobile suspensions. The suspension arm provided in the suspension structure of the automobile has both to improve the strength as resistance to breakage and to improve the rigidity as the difficulty of deformation due to the external force during the running of the automobile. It has been demanded.

One of the objects of the present invention is to increase both the strength and the rigidity of the suspension arm.

The gist of the present invention is the following suspension arm and an automobile suspension structure.

(1) The main body including the curved part and
A first flange that protrudes from the curved portion toward the inner peripheral side of the curved portion and extends along the longitudinal direction of the curved portion.
A second flange extending along the longitudinal direction and joined to the first flange,
A predetermined extension portion provided at at least one of the tip of the first flange and the tip of the second flange, which extends in a direction different from the extension direction of each flange when viewed in the longitudinal direction. When,
The suspension arm is equipped with.

(2) The suspension arm according to (1).
Further provided with a ridgeline portion connecting the predetermined extension portion and the flange provided with the extension portion.
The ridge line portion is formed in a curved shape when viewed in the longitudinal direction.

(3) The suspension arm according to (1) or (2).
The second flange is provided on the curved portion, projects from the curved portion toward the inner peripheral side of the curved portion, and extends along the longitudinal direction of the curved portion.

(4) The suspension arm according to any one of (1) to (3).
As the predetermined extension portion, a first extension portion provided on the first flange and a second extension portion provided on the second flange are provided.

(5) The suspension arm according to (4).
Each of the flanges has a joint surface between the two flanges and an outer surface opposite to the joint surface.
When viewed in the longitudinal direction, the first extension portion extends toward the outer surface side of the first flange, and the second extension portion extends toward the outer surface side of the second flange.

(6) The suspension arm according to (4).
Each of the flanges has a joint surface between the two flanges and an outer surface opposite to the joint surface.
When viewed in the longitudinal direction, both the first extension portion and the second extension portion extend toward the outer surface side of the second flange.

(7) The suspension arm according to any one of (1) to (3).
As the predetermined extension portion, the first extension portion is provided on the first flange.
The second flange is not provided with the extension portion.

(8) The suspension arm according to (7).
The first extension portion extends toward the second flange side.

(9) The suspension arm according to any one of (1) to (8).
A reinforcing plate provided on at least one of the first flange and the second flange, further comprising a reinforcing plate formed of a member different from each of the flanges.
The reinforcing plate includes the extension portion.

The suspension arm according to (10).
The relationship between the plate thickness t1 of the reinforcing plate and the maximum plate thickness t2 as the maximum value of the plate thickness at each of the flanges is t1 ≧ t2.

(11) The suspension arm according to any one of (1) to (10).
The main body is a plate-shaped first half portion provided with the first flange and a plate-shaped second half portion provided with the second flange, and cooperates with the first half portion. It is formed by using a second half portion that forms a closed cross section in at least a part of the longitudinal direction when viewed in the longitudinal direction.

(12) The suspension arm according to any one of (1) to (11).
The predetermined extension portion is not provided in a portion of the main body other than the curved portion.

(13) The suspension arm according to any one of (1) to (12).
The member constituting the suspension arm includes a member having a plate thickness of 2.5 mm or less.

(14) The suspension arm according to any one of (1) to (13).
The member constituting the suspension arm includes a member formed of a steel plate having a tensile strength of 980 MPa or more.

(15) The suspension arm according to any one of (1) to (14).
The suspension arm is a lower arm or an upper arm included in an automobile suspension structure.

(16) An automobile suspension structure including the suspension arm according to any one of (1) to (15).

According to the present disclosure, both the strength and the rigidity of the suspension arm can be increased.

FIG. 1 is a diagram showing a part of a conventional suspension arm. FIG. 2 is a schematic plan view showing a main part of the automobile suspension structure according to the first embodiment of the present invention. FIG. 3 is a perspective view of the lower arm of the suspension structure of the automobile. FIG. 4 is a cross-sectional view taken along the line IV-IV of FIG. 5 (A) is a schematic cross-sectional view taken along the line VA-VA of FIG. 2, and FIG. 5 (B) is a schematic cross-sectional view taken along the line VB-VB of FIG. FIG. 6A is a diagram showing a main part of the first modified example, and FIG. 6B is a diagram showing a main part of the second modified example. FIG. 7A is a diagram showing a main part of the third modification, and FIG. 7B is a diagram showing a main part of the fourth modification. FIG. 8A is a diagram showing a main part of the fifth modified example, and FIG. 8B is a diagram showing a main part of the sixth modified example. FIG. 9 is a schematic side view showing a main part of the automobile suspension structure according to the second embodiment of the present invention. 10 (A) is a schematic cross-sectional view taken along the line XA-XA of FIG. 9, and the illustration behind the cross section along the line XA-XA is omitted. FIG. 10 (B) is a view. 9 is a schematic cross-sectional view taken along the line XB-XB, and the illustration behind the cross section along the line XB-XB is omitted.

Hereinafter, the background to the idea of the present invention will be described first, and then the embodiments will be described in detail.

[Background to the idea of the present invention]
In the present specification, the strength of the suspension arm means the resistance to breakage in the suspension arm (value indicating the resistance to breakage), and in the present specification, the rigidity of the suspension arm means the vehicle running with respect to the suspension arm. A value that indicates the difficulty of deformation due to external force at the time.

More specifically, the above-mentioned strength will be described more specifically. When the tire rides on the rim stone or when the tire collides with the rim stone while the vehicle is running, a large load (on the suspension arm via the tire and wheel of the vehicle) ( Especially impact load) may be applied. When such a large load is applied, the suspension arm may buckle. If the tires are misaligned due to buckling, the car cannot run. When a car becomes impossible to drive, it becomes difficult to move the car to a repair shop. Therefore, the suspension arm needs to have sufficient strength to withstand the above-mentioned large load. For example, the lower arm, which is a type of suspension arm, has a substantially L-shaped curved shape in a plan view. When the tire rides on the curb or collides with the curb, the lower arm receives a large load through the tire and undergoes bending deformation, and the curved portion of the suspension arm may undergo out-of-plane deformation.

The out-of-plane deformation occurs, for example, in the manner shown in FIG. FIG. 1 is a diagram showing a part of a conventional suspension arm 100. The suspension arm 100 is formed by welding two hat-shaped steel plates to each other with flat flanges 101 and 102. The flanges 101 and 102 project toward the inner peripheral side of the curved portion 103 formed on the suspension arm 100 and extend along the longitudinal direction of the curved portion 103. When a large load is applied to the suspension arm 100 from a tire and a wheel (not shown), the inner peripheral side portion of the curved portion 103 is bent and deformed so as to be compressed, and an out-of-plane deformed portion 104 is generated. As a result, the flanges 101 and 102 are deformed in a wavy manner from the state in which they are straight. That is, out-of-plane deformation occurs in which the flanges 101 and 102 are deformed in the direction in which the flanges 101 and 102 intersect the surfaces in contact with each other.

Further, the upper arm used for the multi-link suspension and having a bent portion bent in a substantially V shape when viewed in the vehicle length direction (vehicle front-rear direction) is a kind of suspension arm. This upper arm undergoes bending deformation due to input in the vehicle width direction when the tire collides with a curb from the side surface side of the tire due to side slip of the tire, and the same out-of-plane deformation as described above may occur at the bent portion. It is important to suppress such out-of-plane deformation from the viewpoint of improving strength.

Next, to explain the above-mentioned rigidity more specifically, it is important for the tires to reliably grip the road surface and travel in order to secure the steering stability performance of the automobile. The suspension arm that supports this tire is required from the viewpoint of steering stability performance to maintain the designed geometry without being deformed by the load from the road surface.

On the other hand, in order to reduce the weight of automobile bodies, the members that make up automobile bodies are becoming thinner. Suspension arms are also becoming thinner. When a member having a thin plate thickness and a curved portion undergoes bending deformation, if the compressive force is large on the surface receiving the compressive force, out-of-plane deformation is likely to occur. That is, the strength of the member is likely to be insufficient.

In particular, the suspension arm is often designed to have a curved portion or a bent portion due to restrictions on the layout of the automobile, and as a result, a compressive force is applied to the inner peripheral side portion of the curved portion (the portion near the center of curvature). Is likely to occur. If this compressive force is large, the above-mentioned out-of-plane deformation is likely to occur. When the flange is provided on the inner peripheral side portion (the portion near the center point of curvature) of the curved portion, it is expected that the out-of-plane deformation at the flange is suppressed. Here, when the suspension arm is provided with flanges, it is easy to secure a stacking allowance (stacking area) between the plurality of flanges, so that it is possible to weld a plurality of plates in a state where they are not easily affected by dimensional accuracy. However, since the tip of the flange is a free end, the flange itself is likely to undergo out-of-plane deformation.

In particular, when the plate thickness of the flange is thin, the conventional flat flange as shown in FIG. 1 may not have a sufficient effect of suppressing out-of-plane deformation. Further, when a flange is provided on the inner part of the curve in the curved portion of the suspension arm, and when a flat flange is simply provided, the flange is located far from the neutral axis of the bending deformation generated when an external force from the tire acts on the curved portion. It is difficult to secure enough material at the tip of the flange. Therefore, it is difficult to sufficiently secure the bending strength and the bending rigidity in the curved portion.

As a result of diligent research, the inventor of the present application has come to discover the above-mentioned problems. As a result of further diligent research, we have come up with a flange shape that can increase both strength and rigidity in a suspension arm that has a flange inside the curved portion.

[Explanation of Embodiment]
Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[First Embodiment]
FIG. 2 is a schematic plan view showing a main part of the automobile suspension structure 1 according to the first embodiment of the present invention. FIG. 3 is a perspective view of the lower arm 2 of the automobile suspension structure 1. FIG. 4 is a cross-sectional view taken along the line IV-IV of FIG. 5 (A) is a schematic cross-sectional view taken along the line VA-VA of FIG. 2, and FIG. 5 (B) is a schematic cross-sectional view taken along the line VB-VB of FIG.

Explaining with reference to FIGS. 2 to 5B, the automobile suspension structure 1 of the present embodiment is a strut type suspension and has a lower arm 2 as a suspension arm. Although the strut type suspension structure will be described as an example of the suspension structure in the present embodiment, the present invention may be applied to a suspension structure other than the strut type suspension. As such a suspension structure, an independent suspension type suspension structure such as a multi-link type suspension and a double wishbone type suspension can be exemplified. Further, as a suspension structure other than the independent suspension type suspension structure, a rigid axle type suspension structure can be exemplified. The present invention can be applied to any suspension structure having a suspension arm.

In the present embodiment, when the lower arm 2 is installed in a vehicle having the suspension structure 1, the length direction X of the lower arm 2 is along the vehicle length direction, the vehicle width direction, and the vehicle height direction of the vehicle. , Width direction Y, and height direction Z.

In the present embodiment, the lower arm 2 of the suspension structure 1 is formed in a substantially L shape in a plan view. The lower arm 2 is a hollow member having a closed cross section formed by welding a plurality of steel plates, and is formed in a flat shape in a side view. The lower arm 2 constitutes a first half portion 11 that constitutes one side portion (upper portion) of the lower arm 2 in the height direction Z, and a second portion (lower portion) that constitutes the other side portion (lower portion) of the lower arm 2 in the height direction Z. It has a half portion 12 and.

The first half portion 11 and the second half portion 12 are each formed into a plate shape by pressing a steel plate. This steel sheet is preferably a high-strength steel sheet, and the tensile strength of this steel sheet is preferably 780 MPa or more. This steel sheet is more preferably an ultra-high-strength steel sheet, and the tensile strength in this case is preferably 980 MPa or more. Further, preferably, at least one of the first half portion 11 and the second half portion 12 has a plate thickness of 2.5 mm or less. The plate thickness of each of the half portions 11 and 12 is more preferably 1.0 mm at the lower limit and 2.0 mm at the upper limit. The thinner the plate thickness of each of the half portions 11 and 12, the higher the effect of suppressing the out-of-plane deformation by providing the first flange unit 14 described later appears. The plate thickness of the first half portion 11 and the plate thickness of the second half portion 12 may be the same or different. In the present embodiment, the first half portion 11 and the second half portion 12 are integrated by flange coupling to form the lower arm 2.

The lower arm 2 has a main body 13 and a first flange unit 14, a second flange unit 15, and a third flange unit 16 formed on the main body 13.

The main body 13 has at least a part of a closed cross section (a cross section orthogonal to the horizontal plane is closed). The main body 13 is formed by using a plate-shaped first half portion 11 and a plate-shaped second half portion 12, and the first half portion 11 and the second half portion 12 cooperate with each other. When viewed in the longitudinal direction L1 of the curved wall portion 23 described later, the closed cross section is formed in at least a part of the longitudinal direction L1. This closed cross section is formed in the above cross section, for example, in a rectangular shape.

The main body 13 has a top plate 17 and a first vertical wall forming portion 18 formed on the first half portion 11, and a bottom plate 19 and a second vertical wall forming portion 20 formed on the second half portion 12. ing.

The top plate 17 is a portion forming the upper end portion of the lower arm 2, and extends substantially horizontally. The first vertical wall forming portion 18 is a vertical wall portion extending along the substantially height direction Z, and extends downward from the outer peripheral edge portion of the top plate 17.

The bottom plate 19 is a portion forming the lower end portion of the lower arm 2, and extends substantially horizontally. The second vertical wall forming portion 20 is a vertical wall portion extending along the substantially height direction Z, and extends upward from the outer peripheral edge portion of the bottom plate 19. The first vertical wall forming portion 18 and the second vertical wall forming portion 20 are arranged so as to face each other in the height direction Z.

The main body 13 having the above configuration has a front end portion 21, a rear end portion 22, a curved wall portion 23, and an opposing wall portion 24 facing the curved wall portion 23 in the width direction Y.

The front end portion 21 of the main body 13 is a portion extending in the width direction Y, and a first connecting portion 25 for connecting a ball joint (not shown) is formed at one end portion in the width direction Y. The first connecting portion 25 is formed in, for example, the first half portion 11, and is a hole portion extending in the height direction Z. The first connecting portion 25 is connected to the wheel and the tire 3 via the above-mentioned ball joint and a knuckle (not shown) supported by the ball joint. A second connecting portion 26 is provided at the other end of the front end portion 21 in the width direction Y. The second connecting portion 26 is a cylindrical portion extending in the length direction X. A bush (not shown) is press-fitted into the second connecting portion 26. The second connecting portion 26 is attached to, for example, a bracket of the vehicle body 4 by using a bolt passed through the bush and a nut screwed to the bolt.

The rear end portion 22 of the main body 13 is a portion facing the rear side in the length direction X. A third connecting portion 27 is provided at the rear end portion 22. The third connecting portion 27 is provided in, for example, the first half portion 11. In the present embodiment, the third connecting portion 27 is formed with a through hole facing the height direction Z. A bush (not shown) is press-fitted into the third connecting portion 27. The third connecting portion 27 is connected to, for example, a subframe of the vehicle body 4 by using a bolt passed through the bush and a nut screwed to the bolt. The third connecting portion 27 may be formed in a cylindrical shape extending in the length direction X, similarly to the second connecting portion 26.

With the above configuration, the load from the tire 3 is input from the first connecting portion 25 to the lower arm 2 and transmitted to the vehicle body 4 via the second and third connecting portions 26 and 27.

The curved wall portion 23 of the main body 13 is a wall portion that is curved so as to have a convex shape toward the inside of the lower arm 2 in a plan view. In the present embodiment, the curved wall portion 23 is formed so that one end side portion in the length direction X is convex toward the second connecting portion 26. In the present embodiment, when the lower arm 2 is attached to the vehicle body 4, the curved wall portion 23 is formed at a position facing outward in the width direction Y of the lower arm 2 incorporated in the vehicle body 4. When the lower arm 2 is attached to the vehicle body 4, the curved wall portion 23 advances toward the inside of the vehicle body 4 in the vehicle width direction (one side of the width direction Y) and the rear side (length direction) of the vehicle body in the length direction. It is formed in a shape that advances to one side of X) and is smoothly curved in a plan view. The longitudinal direction L1 of the curved wall portion 23 is a direction extending along the curved wall portion 23 in a plan view.

The facing wall portion 24 of the main body 13 is formed on the other end side of the lower arm 2 in the width direction Y. In the present embodiment, the facing wall portion 24 extends along the length direction X.

The first vertical wall forming portion 18 and the second vertical wall forming portion 20 of the main body 13 having the above-described configuration are connected by three flange units 14, 15 and 16. The first flange unit 14 connects the vertical wall forming portions 18 and 20 of the curved wall portion 23 of the main body 13 to each other. The second flange unit 15 connects the vertical wall forming portions 18 and 20 in the facing wall portion 24 of the main body 13 to each other. The third flange unit 16 connects the vertical wall forming portions 18 and 20 at the front end portion 21 of the main body 13 to each other.

The first flange unit 14 is a flange unit provided on the curved wall portion 23, and projects from the curved wall portion 23 to the inner peripheral side of the curved wall portion 23 (the curvature center point side of the curved wall portion 23).

The first flange unit 14 includes a first flange 31, a first ridge line portion 32 and a first extension portion 33 provided on the first half portion 11, and a second flange 34 and a second flange provided on the second half portion 12. It has a ridge line portion 35 and a second extension portion 36.

The first flange 31 projects from the lower end of the first vertical wall forming portion 18 toward the inner peripheral side of the curved wall portion 23, and extends along the longitudinal direction L1 of the curved wall portion 23. The second flange 34 projects from the upper end of the second vertical wall forming portion 20 toward the inner peripheral side of the curved wall portion 23, and extends along the longitudinal direction L1 of the curved wall portion 23. In the present embodiment, the first flange 31 is formed in a curved shape that is convex downward when viewed in the longitudinal direction L1. Further, in the present embodiment, the second flange 34 is formed in a curved shape that is convex upward when viewed in the longitudinal direction L1. The flanges 31 and 34 may be formed in a flat plate shape extending in parallel with each other, and the specific shape is not limited.

The inner side surface (lower side surface) of the first flange 31 and the inner side surface (upper side surface) of the second flange 34 have a joint surface 37 formed by being joined (fixed) to each other by welding or the like. As the above welding, arc welding, spot welding and laser welding can be exemplified, and as a fixing method other than welding, a fixing method using a structural adhesive can be exemplified. Further, the outer surface (upper side surface) of the first flange 31 and the outer surface (lower side surface) of the second flange 34 face in opposite directions to the joint surface 37. The amount of protrusion of the flanges 31 and 34 from the vertical wall forming portions 18 and 20 is not particularly limited. Although the position of the joint surface 37 between the flanges 31 and 34 in the height direction Z is not particularly limited, in the present embodiment, the position is aligned with the center position of the curved wall portion 23 in the height direction Z.

In the present embodiment, both the first half portion 11 and the second half portion 12 are described as an example in which both the first half portion 11 and the second half portion 12 are formed in a cross-sectional hat shape, but this may not be the case. For example, either one of the first half portion 11 and the second half portion 12 may be formed in a hat shape in cross section, and the other may be formed in a flat plate shape.

A first ridge line portion 32 and a first extension portion 33 are provided at the tip of the first flange 31, and a second ridge line portion 35 and a second extension portion 36 are provided at the tip of the second flange 34.

While the first ridge line portion 32 and the first extension portion 33 are provided, the second ridge line portion 35 and the second extension portion 36 may be omitted, or the second ridge line portion 35 and the second extension portion 36 are provided. On the other hand, the first ridge line portion 32 and the first extension portion 33 may be omitted.

Further, when the first extension portion 33 is provided, the first extension portion 33 may extend directly from the tip of the first flange 31 by omitting the first ridge line portion 32. Similarly, when the second extension portion 36 is provided, the second extension portion 36 may extend directly from the tip of the second flange 34 by omitting the second ridge line portion 35.

Next, a more specific example of the configuration of the first ridge line portion 32 and the first extension portion 33 will be described.

The first ridge line portion 32 connects the first extension portion 33 and the first flange 31 on which the first extension portion 33 is provided. The first ridge line portion 32 is formed in a curved shape when viewed in the longitudinal direction L1. In the present embodiment, the first ridge line portion 32 is formed at a position that advances from the joint surface 37 between the first flange 31 and the second flange 34 to the inner peripheral side (curvature center point side) of the curved wall portion 23. ing. In the present embodiment, the first ridge line portion 32 is formed in an arc shape when viewed in the longitudinal direction L1. In the present embodiment, the tip of the first ridge line portion 32 faces upward in the height direction Z. The first extension portion 33 is continuous with the tip of the first ridge line portion 32.

The first extension portion 33 is an example of a “predetermined extension portion”. The first extension portion 33 is provided to suppress out-of-plane deformation of the first flange unit 14. The first extension portion 33 extends along the longitudinal direction L1 and is provided on at least a part (in the present embodiment, all) of the curved wall portion 23 in the longitudinal direction L1 together with the first ridge line portion 32. In the present embodiment, the first extension portion 33 extends in parallel with the vertical wall forming portions 18 and 20, and extends in the height direction Z. By providing the first extension portion 33 in this way, the first extension portion 33 is different from the extension direction (horizontal direction) of the flanges 31 and 34 (particularly the first flange 31) in the longitudinal direction L1. It extends in different directions. The distance between the vertical wall forming portions 18 and 20 and the first extension portion 33 is appropriately set to be equal to or greater than the minimum value at which the out-of-plane deformation suppressing effect of the first extension portion 33 can be sufficiently exerted. In the present embodiment, in the height direction Z, the tip end (free end) of the first extension portion 33 is arranged below the upper surface of the top plate 17. The tip of the first extension portion 33 may be arranged at a position higher than the height position on the upper surface of the top plate 17. With such a configuration, the first extension portion 33 can have a higher effect of suppressing out-of-plane deformation.

Next, a more specific example of the configuration of the second ridge line portion 35 and the second extension portion 36 will be described.

In the present embodiment, the second ridge line portion 35 and the second extension portion 36 are formed in a shape symmetrical with the corresponding first ridge line portion 32 and the first extension portion 33 in the height direction Z.

The second ridge line portion 35 connects the second extension portion 36 and the second flange 34 on which the second extension portion 36 is provided. The second ridge line portion 35 is formed in a curved shape when viewed in the longitudinal direction L1. In the present embodiment, the tip of the second ridge line portion 35 faces downward in the height direction Z. The second extension portion 36 is continuous with the tip of the second ridge line portion 35.

The second extension portion 36 is an example of a “predetermined extension portion”. The second extension portion 36 is provided to suppress the out-of-plane deformation of the first flange unit 14, and in the present embodiment, the second extension portion 36 cooperates with the first extension portion 33 to exert an out-of-plane deformation suppression effect. .. The second extension portion 36 extends in a direction different from the extension direction (horizontal direction) of the flanges 31 and 34 (particularly the second flange 34) in the longitudinal direction L1. The second extension portion 36 extends along the longitudinal direction L1 and is provided on at least a part (in the present embodiment, all) of the curved wall portion 23 in the longitudinal direction L1 together with the second ridge line portion 35. In the present embodiment, in the height direction Z, the tip (free end) of the second extension portion 36 is arranged above the lower surface of the bottom plate 19. The tip of the second extension portion 36 may be arranged at a position lower than the height position on the lower surface of the bottom plate 19. With such a configuration, the second extension portion 36 can have a higher effect of suppressing out-of-plane deformation.

With the above configuration, in the present embodiment, the first extension portion 33 extends to the outer surface side (upper side) of the first flange 31, and the second extension portion 36 is the second flange when viewed in the longitudinal direction L1. It extends to the outer surface side (lower side) of 34. Further, both end faces of the first flange 31, the first ridge line portion 32, the first extension portion 33, the second flange 34, the second ridge line portion 35, and the second extension portion 36 in the longitudinal direction L1 are different from other members. Is an unbonded free end.

In the present embodiment, the first ridge line portion 32 and the first extension portion 33 are symmetrical with the second ridge line portion 35 and the second extension portion 36 in the height direction Z as an example. It does not have to be. The first ridge line portion 32 and the first extension portion 33 may be formed asymmetrically with the second ridge line portion 35 and the second extension portion 36 in the height direction Z. For example, even if the first extension portion 33 is arranged at a position higher than the height position on the upper surface of the top plate 17, while the second extension portion 36 is arranged at a position higher than the height position on the lower surface of the bottom plate 19. Good. In this case, the second extension 36 does not have to protrude downward with respect to the main body 13, and the minimum ground clearance of the lower arm 2 does not become excessively low, while the effect of suppressing the out-of-plane deformation by the first extension 33. Can be sufficiently secured.

The above is the schematic configuration of the first flange unit 14. Next, the configuration of the second flange unit 15 and the configuration of the third flange unit 16 will be described.

The second flange unit 15 is a flange unit provided on the facing wall portion 24, and extends substantially parallel to the facing wall portion 24.

The second flange unit 15 has a third flange 38 provided on the first half portion 11 and a fourth flange 39 provided on the second half portion 12.

The third flange 38 extends downward from the lower end of the first vertical wall forming portion 18 of the facing wall portion 24. The fourth flange 39 extends upward from the upper end of the second vertical wall forming portion 20 of the facing wall portion 24. The third flange 38 and the fourth flange 39 are formed in a flat plate shape in the present embodiment.

The inner surface of the third flange 38 and the outer surface of the fourth flange 39 are joined (fixed) to each other by welding or the like. As the above-mentioned fixing method, a configuration similar to the configuration in which the first flange 31 and the second flange 34 are fixed to each other can be exemplified.

The third flange unit 16 is a flange unit provided at the front end portion 21 and extends along the width direction Y.

The third flange unit 16 has a fifth flange 40 provided on the first half portion 11 and a sixth flange 41 provided on the second half portion 12.

The fifth flange 40 extends downward from the lower end of the first vertical wall forming portion 18 of the front end portion 21. The sixth flange 41 extends upward from the upper end of the second vertical wall forming portion 20 of the front end portion 21. The fifth flange 40 and the sixth flange 41 are formed in a flat plate shape in the present embodiment.

The inner surface of the fifth flange 40 and the outer surface of the sixth flange 41 are joined (fixed) to each other by welding or the like. As the above-mentioned fixing method, a configuration similar to the configuration in which the first flange 31 and the second flange 34 are fixed to each other can be exemplified.

With the above configuration, the second flange unit 15 and the third flange unit 16 are not provided with a ridge line portion and an extension portion. In other words, the ridge line portions 32, 35 and the extension portions 33, 36 of the first flange unit 14 are not provided at any portion of the main body 13 other than the curved wall portion 23.

As described above, according to the present embodiment, the curved wall portion 23 is provided with a first flange 31 and a second flange 34 that protrude toward the inner peripheral side of the curved wall portion 23 and extend along the longitudinal direction L1. There is. Extension portions 33 and 36 are provided on at least one of these flanges 31 and 34 (both in the present embodiment). According to this configuration, out-of-plane deformation of the first flange 31 and the second flange 34, in other words, in a direction intersecting the plane P1 (see FIG. 5A) including the joint surface 37 of the flanges 31 and 34. The deformation of the first and second flanges 31, 34 of the above, in other words, the wavy deformation of the first and second flanges 31, 34 can be suppressed by the first and second extension portions 33, 36. .. By providing the first and second extension portions 33 and 36 in this way, the moment of inertia of area of the lower arm 2 with respect to the out-of-plane deformation of the first and second flanges 31 and 34 can be increased. Therefore, both the strength and the rigidity of the lower arm 2 can be made higher.

More specifically, the out-of-plane deformation will be described more specifically. When the tire 3 rides on the curb, or when the tire 3 collides with the curb, a large load is applied to the first connecting portion 25 of the lower arm 2. Especially impact load) may be applied. When such a large load is applied, a compressive load acts on the curved wall portion 23 of the lower arm 2 in a direction that shortens the distance between the first and third connecting portions 25 and 27. As a result, the first and second flanges 31, 34 of the first flange unit 14 generate high compressive stress and receive a deformation force that causes out-of-plane deformation. However, as described above, since the first and second extension portions 33 and 36 are provided, the occurrence of the above-mentioned out-of-plane deformation can be suppressed. Thereby, the bending strength and the compressive strength of the lower arm 2 can be increased. Further, the neutral surface P1 of the bending deformation when the above compression is applied exists between the curved wall portion 23 and the facing wall portion 24 in the closed cross section orthogonal to the longitudinal direction L1 in the lower arm 2. The first and second extension portions 33 and 36 are arranged at the positions farthest from the neutral surface P1 in the first flange unit 14. As a result, high bending rigidity can be realized with less material, so that the material placement efficiency with respect to the bending rigidity can be increased.

Further, according to the present embodiment, the first and second flanges 31, 34 and the first and second extension portions 33, 36 are connected via the first and second ridge line portions 32, 35 having a curved shape. There is. According to this configuration, stress concentration between the first and second flanges 31, 34 and the corresponding first and second extension portions 33, 36 can be relaxed.

Further, according to the present embodiment, in addition to the first flange 31, the second flange 34 is also provided on the curved wall portion 23. According to this configuration, the compressive load acting on the curved wall portion 23 can be jointly received by the two flanges 31 and 34. Therefore, the lower arm 2 can receive a higher load than the above-mentioned compressive load without out-of-plane deformation.

Further, according to the present embodiment, when viewed in the longitudinal direction L1, the first extension portion 33 extends toward the outer surface (upper side surface) side of the first flange 31, and the second extension portion 36 is the second flange. It extends to the outer side (lower side) side. According to this configuration, the first flange unit 14 is formed in a T shape when viewed in the longitudinal direction L1. In the lower arm 2 in which loads in various directions are input from the tire 3 and the vehicle body 4, the first flange unit 14 has such a shape, so that the curved wall portion 23 of the first flange unit 14 receives a compressive load. On the other hand, even when a load other than the compressive load is applied, the out-of-plane deformation suppressing effect can be sufficiently exhibited.

Further, according to the present embodiment, the first and second extension portions 33 and 36 are not provided in any portion of the main body 13 other than the curved wall portion 23. According to this configuration, out-of-plane deformation is suppressed by providing the first and second extension portions 33, 36 at the portions of the first to third flange units 14, 15 and 16 that are most likely to be bent and deformed by the compressive load. , No extension is provided in places where bending and deformation are difficult. As a result, it is not necessary to dispose more steel material than necessary in the places where the effect of providing the first and second extension portions 33 and 36 is weak, and the lower arm 2 can be made lighter. In particular, the effect of reducing the weight of the lower arm 2, which is the unsprung weight, can significantly improve the running performance improving effect, as compared with the effect of reducing the weight of the vehicle body 4, etc., which is the unsprung weight.

Further, according to the present embodiment, the plate thickness of at least a part (in the present embodiment) of the lower arm 2 is set to 2.5 mm or less. According to this configuration, the weight of the lower arm 2 can be reduced while suppressing the out-of-plane deformation of the flanges 31 and 34 in the curved wall portion 23.

Further, according to the present embodiment, at least a part (in the present embodiment) of the lower arm 2 is a member formed of a steel plate having a tensile strength of 980 MPa or more. By forming the lower arm 2 with such an ultra-high-strength steel plate, it is possible to increase the resistance (strength) of the lower arm 2 against impact while achieving weight reduction. If the lower arm is made of a low-strength material, the lower arm has a small elastic deformation region, and the difference in strength due to the presence or absence of the above-mentioned out-of-plane deformation is unlikely to occur in the first place. Therefore, by setting the tensile strength of the lower arm 2 to, for example, 980 MPa, the strength of the lower arm 2 can be further increased while sufficiently securing the elastic deformation region of the lower arm 2.

In the following, the points different from the configuration of the first embodiment will be mainly described, and the same components as those of the first embodiment may be designated by the same reference numerals and detailed description thereof may be omitted.

In the above-described embodiment, the first and second extension portions 33 and 36 of the first flange unit 14 extend in parallel with the first and second vertical wall forming portions 18 and 20 of the curved wall portion 23, as an example. explained. However, this does not have to be the case. For example, as shown in FIG. 6A as a first modification, the first and second extension portions 33, 36 may extend inward. More specifically, even if the first and second extension portions 33, 36 are formed so that the tips of the first and second extension portions 33, 36 are directed toward the first and second vertical wall forming portions 18, 20. Good. In this case, the first and second extension portions 33, 36 approach the corresponding vertical wall forming portions 18, 20 as the distance from the first and second flanges 31, 34 increases.

Further, for example, as shown in FIG. 6B as a second modification, the first and second extension portions 33 and 36 may extend outward. More specifically, the first and second extension portions 33, 36 are formed so that the tips of the first and second extension portions 33, 36 face away from the first and second vertical wall forming portions 18, 20. You may. In this case, the distances of the first and second extension portions 33 and 36 from the first and second vertical wall forming portions 18 and 20 increase as the distance from the first and second flanges 31 and 34 increases.

In the above-described embodiment, the embodiment in which the extension portions 33 and 36 corresponding to both the first and second flanges 31 and 34 of the first flange unit 14 are provided will be described as an example. However, this does not have to be the case. For example, as shown in FIG. 7A as a third modification, the first flange 31 is provided with the first ridge line portion 32 and the first extension portion 33, while the second flange 34 is provided with the second. The ridge line portion 35 and the second extension portion 36 may not be provided. At this time, the first ridge line portion 32 and the first extension portion 33 may extend to the first flange 31 side (upper side) or may extend to the second flange 34 side (lower side). Further, although not shown, the second flange 34 is provided with the second ridge line portion 35 and the second extension portion 36, while the first flange 31 is provided with the first ridge line portion 32 and the first extension portion 33. It does not have to be. In this case, the second extension portion 36 may extend toward the second flange 34 side or may extend toward the first flange 31 side.

In the above-described embodiment, the first and second flanges 31 and 34 of the first flange unit 14 extend in opposite directions to each other as an example, but this may not be the case. For example, as shown in FIG. 7B as a fourth modification, the first extension portion 33 may extend toward the second flange 34 side. In this case, the first extension portion 33 is overlapped with the second extension portion 36, and both the first extension portion 33 and the second extension portion 36 extend toward the outer surface (upper side surface) side of the second flange 34. ing. Although not shown, the first extension portion 33 and the second extension portion 36 may extend toward the first flange 31 side.

In the above-described embodiment, the embodiment in which the first and second extension portions 33 and 36 are integrally molded with the corresponding first and second flanges 31 and 34 has been described as an example, but this may not be the case. For example, as shown in FIG. 8A as a fifth modification, the extension portions 33, 36 integrally formed with the first and second flanges 31, 34 are omitted in the lower arm 2, and instead, the extension portions 33, 36 are omitted. A reinforcing plate 42 formed of a member different from the first and second flanges 31, 34 may be provided. In this case, the reinforcing plate 42 is provided on at least one of the first flange 31 and the second flange 34 (both in the fifth modification). The reinforcing plate 42 extends in a direction different from the extending direction of the first and second flanges 31, 34 when viewed in the longitudinal direction L1 (the direction perpendicular to the paper surface in FIG. 8A). The reinforcing plate 42 is formed in a flat plate shape, for example, and extends in the height direction Z.

The plate thickness t1 of the reinforcing plate 42 preferably has a relationship of t1 ≧ t2 with the maximum plate thickness t2 as the maximum value of the plate thicknesses of the flanges 31 and 34. In this fifth modification, the reinforcing plate 42 extends in parallel with the vertical wall forming portions 18 and 20 in the curved wall portion 23. The tips of the flanges 31 and 34 and the reinforcing plate 42 are fixed to each other by, for example, fillet welding. The reinforcing plate 42 extends upward with respect to the first flange 31 and downwards with respect to the second flange 34. The reinforcing plate 42 includes a first extension portion 33A and a second extension portion 36A.

In this fifth modification, the portion of the reinforcing plate 42 extending above the first flange 31 forms the first extension portion 33A. Further, a portion of the reinforcing plate 42 extending below the second flange 34 forms the second extension portion 36A. The main difference between the first extension portion 33 of the present embodiment and the first extension portion 33A is whether the first extension portions 33, 33A are integrally molded with the first flange 31 or the reinforcing plate 42. The point is that the first extension portion 33A is not provided with the first ridge line portion. Similarly, the main difference between the second extension portion 36 of the present embodiment and the second extension portion 36A is whether the second extension portions 36, 36A are integrally molded with the second flange 34 or the reinforcing plate 42. The point is that the second extension portion 36A is not provided with the second ridge line portion. Therefore, the detailed description of the first extension section 33A will be replaced with the description of the first extension section 33, and the detailed description of the second extension section 36A will be replaced with the description of the second extension section 36.

According to this fifth modification, the first and second extension portions 33A and 36A are formed by using the reinforcing plate 42 which is a member different from the flanges 31 and 34. As a result, a mold for integrally molding the first and second extension portions 33A and 36A with the first and second flanges 31 and 34 is unnecessary. Further, by setting the plate thickness t1 ≧ t2, the moment of inertia of area of the first and second extension portions 33A and 36A can be further increased. Further, the first and second extension portions 33A and 36A are integrally molded with each other. As a result, the moment of inertia of area of the first and second extension portions 33A and 36A can be further increased.

In the fifth modification, by omitting the upper half or the lower half of the reinforcing plate 42, either the first extension portion 33A or the second extension portion 36A may be omitted.

Further, in the above-described embodiment, the embodiment in which the first and second extension portions 33 and 36 are integrally molded with the corresponding first and second flanges 31 and 34 has been described as an example, but this may not be the case. .. For example, as shown as a sixth modification in FIG. 8B, in the lower arm 2, a member (flange 34B) different from the first and second flanges 31 and 34 provided on the main body 13 is attached to the lower arm 2. The two ridge line portion 35B and the second extension portion 36B may be provided. In the sixth modification, for example, a flange 34B different from the second flange 34, and the flange 34B joined to the first flange 31 is provided with the second ridge line portion 35B and the second extension portion 36B. This flange 34B is an example of the "second flange" of the present invention. The second extension 36B is used, for example, as a stay to which a stabilizer link (not shown) for connecting the left and right lower arms attached to the vehicle body 4 is attached.

[Second Embodiment]
Next, the second embodiment of the present invention will be described. FIG. 9 is a schematic side view showing a main part of the automobile suspension structure 1C according to the second embodiment of the present invention. FIG. 10A is a schematic cross-sectional view taken along the line XA-XA of FIG. 9, and the illustration behind the cross section along the line XA-XA is omitted. FIG. 10B is a schematic cross-sectional view taken along the line XB-XB of FIG. 9, and the illustration behind the cross section along the line XB-XB is omitted.

Explaining with reference to FIGS. 9, 10 (A) and 10 (B), the automobile suspension structure 1C is a multi-link suspension and has an upper arm 51 and a lower arm 52 as suspension arms.

In the present embodiment, the upper arm 51 is formed in a substantially V shape when viewed in the length direction X. In the present embodiment, the upper arm 51 is a hollow member having a closed cross section formed by pressing and welding one steel plate. The upper arm 51 may be a hollow member having a closed cross section, which is formed by joining a plurality of steel plates by welding or the like.

The steel plate constituting the upper arm 51 is the same steel plate as the steel plate forming the first half portion 11, and the plate thickness is set to be the same as the plate thickness of the steel plate forming the first half portion 11.

The upper arm 51 has a main body 13C, and a first flange unit 14C and a second flange unit 15C formed on the main body 13C.

The main body 13C has at least a part of a closed cross section (a cross section in which a cross section orthogonal to the width direction Y is closed). The main body 13C has a rectangular flat cross section in a cross section orthogonal to the width direction Y except for both ends in the width direction Y.

The main body 13C has a first upper plate 53 and a second upper plate 54 that form the upper plate of the main body 13C.

The first upper plate 53 and the second upper plate 54 extend along the substantially length direction X. The first upper plate 53 and the second upper plate 54 are arranged in the length direction X.

The main body 13C having the above configuration has one end portion 55, the other end portion 56, and a curved wall portion 57.

One end portion 55 of the main body 13C is a portion forming one end portion of the main body 13C in the width direction Y, and a first connecting portion 58 is formed. The first connecting portion 58 is a cylindrical portion extending in the length direction X. A bush (not shown) is press-fitted into the first connecting portion 58, and the upper arm 51 and the knuckle (not shown) are attached by using a bolt passed through the bush and a nut screwed to the bolt. It is connected. The knuckle is connected to the wheel and the tire 3. The other end 56 is a portion of the main body 13C that constitutes the other end in the width direction Y, and a second connecting portion 59 is formed. The second connecting portion 59 is a cylindrical portion extending in the length direction X. A bush (not shown) is press-fitted into the second connecting portion 59, and the upper arm 51 and, for example, a bracket of the vehicle body 4 are connected by using a bolt passed through the bush and a nut screwed to the bolt. Has been done.

In the present embodiment, when the upper arm 51 is attached to the vehicle body 4, the one end portion 55 is arranged outside the vehicle body 4 in the width direction and functions as the outer end portion of the upper arm 51. Further, when the upper arm 51 is attached to the vehicle body 4, the other end 56 is arranged inside the vehicle body 4 in the width direction and functions as an inner end portion of the upper arm 51. With the above configuration, the load from the tire 3 is input to the upper arm 51 from the first connecting portion 58 of the one end portion 55, and is transmitted to the vehicle body 4 via the second connecting portion 59 of the other end portion 56.

In the present embodiment, when the upper arm 51 is attached to the vehicle body 4, the curved wall portion 57 is arranged upward. The curved wall portion 57 is formed in a U shape when viewed from the length direction X, and is curved in a substantially arc shape. The longitudinal direction L1C of the curved wall portion 57 is a direction in which the curved wall portion 57 is curved and extends in a substantially arc shape when viewed from the length direction X.

The first upper plate 53 and the second upper plate 54 of the main body 13C having the above-described configuration are connected by two flange units 14C and 15C. The first flange unit 14C connects the first upper plate 53 and the second upper plate 54 in the curved wall portion 57 of the main body 13C to each other. The second flange unit 15C connects the first upper plate 53 and the second upper plate 54 of the main body 13C, which are arranged on the other end 56 side with respect to the curved wall portion 57, to each other.

The first flange unit 14C is a flange unit provided on the curved wall portion 57, and projects from the curved wall portion 57 to the inner peripheral side of the curved wall portion 57 (the curvature center point side of the curved wall portion 57).

The first flange unit 14C includes a first flange 31C, a first ridge line portion 32C and a first extension portion 33C provided on the first upper plate 53, and a second flange 34C and a second flange 34C provided on the second upper plate 54. It has a ridge line portion 35C and a second extension portion 36C.

The first flange 31C, the first ridge line portion 32C, and the first extension portion 33C extend along the longitudinal direction L1C of the curved wall portion 57 and face upward from the main body 13C when the lower arm 52 is attached to the vehicle body 4. Since it has substantially the same configuration as the corresponding first flange 31, the first ridge line portion 32, and the first extension portion 33 of the first embodiment except that it extends along the above, detailed description thereof will be omitted. To do. Similarly, the second flange 34C, the second ridge line portion 35C, and the second extension portion 36C extend along the longitudinal direction L1C of the curved wall portion 57, and the main body is in a state where the lower arm 52 is attached to the vehicle body 4. It has substantially the same configuration as the corresponding second flange 34, the second ridge line portion 35, and the second extension portion 36 of the first embodiment except that it extends upward from 13C. The description is omitted.

Further, in the second embodiment, the first ridge line portion 32C, the first extension portion 33C, the second ridge line portion 35C, and the second extension portion 36C are the same as those shown in the above-described modifications in the first embodiment. The configuration of may be adopted.

The above is the schematic configuration of the first flange unit 14C. Next, the configuration of the configuration of the second flange unit 15C will be described.

The second flange unit 15C has a third flange 38C provided on the first upper plate 53 and a fourth flange 39C provided on the second upper plate 54.

The third flange 38C extends in the width direction Y from the end of the first flange 31C near the other end 56 toward the other end 56. The third flange 38C extends along the width direction Y so that the flange height from the first upper plate 53 to the tip of the third flange 38 is substantially constant. The third flange 38C extends integrally with the first flange 31C, but does not have the first ridge line portion 32C and the first extension portion 33C. The fourth flange 39C extends in the width direction Y from the end of the second flange 34C near the other end 56 toward the other end 56. The fourth flange 39C extends along the width direction Y so that the flange height from the second upper plate 54 to the tip of the fourth flange 39 is substantially constant. The fourth flange 39C extends integrally with the second flange 34C, but does not have the second ridge line portion 35C and the second extension portion 36C. The third flange 38C and the fourth flange 39C are formed in a flat plate shape in the present embodiment.

The inner surface of the third flange 38C and the inner surface of the fourth flange 39C are joined (fixed) to each other by welding or the like. As the above-mentioned fixing method, a configuration similar to the configuration in which the first flange 31 and the second flange 34 are fixed to each other can be exemplified.

Due to the above configuration, the second flange unit 15C is not provided with a ridge line portion and an extension portion. In other words, the first and second ridge line portions 32C and 35C and the first and second extension portions 33C and 36C are not provided in the main body 13C except for the curved wall portion 57.

As described above, according to the present embodiment, the curved wall portion 57 is provided with a first flange 31C and a second flange 34C that project toward the inner peripheral side of the curved wall portion 57 and extend along the longitudinal direction L1C. There is. The first and second extension portions 33C and 36C are provided on at least one of the first and second flanges 31C and 32C (both in the present embodiment). According to this configuration, out-of-plane deformation of the first flange 31C and the second flange 34C, in other words, the first in the direction intersecting the plane P2C including the joint surface 37C of the first and second flanges 31C and 32C. And the deformation of the second flanges 31C and 32C, in other words, the wavy deformation of the first and second flanges 31C and 32C can be suppressed by the first and second extension portions 33C and 36C. By providing the first and second extension portions 33C and 36C in this way, the moment of inertia of area of the upper arm 51 with respect to the out-of-plane deformation of the first and second flanges 31C and 34C can be increased. Therefore, both the strength and the rigidity of the upper arm 51 can be made higher.

More specifically, the out-of-plane deformation will be described more specifically. When the tire 3 rides on the curb or when the tire 3 collides with the curb during the running of the automobile, a large load is applied to the first connecting portion 58 of the upper arm 51. (Especially impact load) may be applied. When such a large load is applied, a compressive load acts on the curved wall portion 57 of the upper arm 51 in a direction that shortens the distance between the first and second connecting portions 58 and 59. As a result, the first and second flanges 31C and 32C of the first flange unit 14C generate high compressive stress, and a deformation force such as out-of-plane deformation acts. However, as described above, since the first and second extension portions 33C and 36C are provided, the occurrence of the above-mentioned out-of-plane deformation can be suppressed.

The embodiments and modifications of the present invention have been described above. However, the present invention is not limited to the above-described embodiments and modifications. The present invention can be modified in various ways within the scope of the claims.

The present invention can be widely applied as a suspension arm and an automobile suspension structure.

1,1C Automotive suspension structure 2 Lower arm (suspension arm)
11 1st half 12 2nd half 13,13C Main body 23 Curved wall (curved)
31,31C 1st flange 32,32C 1st ridge line (ridge line)
33, 33A, 33C 1st extension (extension)
34, 34B, 34C Second flange 35, 35B, 35C Second ridge line (ridge line)
36, 36A, 36B, 36C 2nd extension (extension)
37, 37C Joint surface 42 Reinforcing plate 51 Upper arm (suspension arm)
57 Curved wall part (curved part)
L1, L1C Longitudinal direction of curved part

Claims (16)

The main body including the curved part and
A first flange that protrudes from the curved portion toward the inner peripheral side of the curved portion and extends along the longitudinal direction of the curved portion.
A second flange extending along the longitudinal direction and joined to the first flange,
A predetermined extension portion provided at at least one of the tip of the first flange and the tip of the second flange, which extends in a direction different from the extension direction of each flange when viewed in the longitudinal direction. When,
The suspension arm is equipped with. The suspension arm according to claim 1.
Further provided with a ridgeline portion connecting the predetermined extension portion and the flange provided with the extension portion.
The ridgeline portion is a suspension arm formed in a curved shape when viewed in the longitudinal direction. The suspension arm according to claim 1 or 2.
The second flange is a suspension arm that is provided on the curved portion, projects from the curved portion toward the inner peripheral side of the curved portion, and extends along the longitudinal direction of the curved portion. The suspension arm according to any one of claims 1 to 3.
A suspension arm provided with a first extension portion provided on the first flange and a second extension portion provided on the second flange as the predetermined extension portion. The suspension arm according to claim 4.
Each of the flanges has a joint surface between the two flanges and an outer surface opposite to the joint surface.
When viewed in the longitudinal direction, the first extension portion extends toward the outer surface side of the first flange, and the second extension portion extends toward the outer surface side of the second flange. arm. The suspension arm according to claim 4.
Each of the flanges has a joint surface between the two flanges and an outer surface opposite to the joint surface.
A suspension arm in which both the first extension portion and the second extension portion extend toward the outer surface side of the second flange when viewed in the longitudinal direction. The suspension arm according to any one of claims 1 to 3.
As the predetermined extension portion, the first extension portion is provided on the first flange.
A suspension arm in which the extension portion is not provided on the second flange. The suspension arm according to claim 7.
The first extension portion is a suspension arm extending toward the second flange side. The suspension arm according to any one of claims 1 to 8.
A reinforcing plate provided on at least one of the first flange and the second flange, further comprising a reinforcing plate formed of a member different from each of the flanges.
The reinforcing plate is a suspension arm including the extension portion. The suspension arm according to claim 9.
A suspension arm in which the relationship between the plate thickness t1 of the reinforcing plate and the maximum plate thickness t2 as the maximum value of the plate thickness at each of the flanges is t1 ≧ t2. The suspension arm according to any one of claims 1 to 10.
The main body is a plate-shaped first half portion provided with the first flange and a plate-shaped second half portion provided with the second flange, and cooperates with the first half portion. A suspension arm formed by using a second half portion that forms a closed cross section in at least a part of the longitudinal direction when viewed in the longitudinal direction. The suspension arm according to any one of claims 1 to 11.
The predetermined extension portion is a suspension arm that is not provided in a portion of the main body other than the curved portion. The suspension arm according to any one of claims 1 to 12.
A suspension arm in which the member constituting the suspension arm includes a member having a plate thickness of 2.5 mm or less. The suspension arm according to any one of claims 1 to 13.
A suspension arm in which the member constituting the suspension arm includes a member formed of a steel plate having a tensile strength of 980 MPa or more. The suspension arm according to any one of claims 1 to 14.
The suspension arm is a suspension arm which is a lower arm or an upper arm included in an automobile suspension structure. An automobile suspension structure comprising the suspension arm according to any one of claims 1 to 15.

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