JP7570263B2 - Vehicle bumper unit - Google Patents

Description

The present invention relates to a vehicle bumper unit. In particular, it relates to a vehicle bumper unit that is attached to a front side frame provided at the front of the vehicle.

For example, the following Patent Document 1 describes a front body structure for a vehicle equipped with a gusset as a technology for improving vehicle safety, particularly safety during an offset collision in which the vehicle partially collides with an obstacle, oncoming vehicle, or other colliding object. In this body structure, a gusset is connected to the outer surface in the vehicle width direction of the front side frames provided on both sides of the vehicle in the vehicle width direction. The gusset extends forward while spreading outward in the vehicle width direction, and faces the rear surface of the bumper beam.

In the front body structure of Patent Document 1, when an object strikes the portion of the bumper beam that is on the outer side in the vehicle width direction (hereinafter referred to as the "outer portion") of the bumper beam that is attached to the front side frame (hereinafter referred to as the "fixed portion"), the collision load is not only transmitted from the fixed portion of the bumper beam to the front side frame, but also transmitted to the front side frame via the gusset that abuts against the rear surface of the outer portion due to the impact of the collision. Note that hereinafter, a collision in which a collision load is applied to the outer portion of the bumper beam as described above is referred to as an "SOL (small overlap) collision."

JP 2019-172108 A

To improve vehicle safety during a side-on collision, it is necessary to efficiently transmit the collision load applied to the bumper beam to the front side frame. In the above structure, when a load is applied to the bumper beam in the vehicle width direction more inward than the position facing the gusset during a side-on collision, part of the collision load is transmitted to the outside of the bumper beam in the vehicle width direction, and then transmitted to the front side frame via the gusset abutting the rear surface of the bumper beam. Here, while the collision load is applied in a direction from the front to the rear of the vehicle, the gusset extends while inclining at a certain angle relative to the front-to-rear direction of the vehicle. If the load traveling from the bumper beam to the front side frame can be transmitted along a path that is more in line with the front-to-rear direction of the vehicle than the extension direction of the gusset, it is expected that the load transmission efficiency will be improved.

This technology was developed based on the above circumstances, and aims to provide a vehicle bumper unit with excellent collision resistance, in particular a vehicle bumper unit that exhibits excellent load transmission efficiency during a single-side collision.

The vehicle bumper unit according to the technology disclosed in this specification has the following configuration.
(1) A vehicle bumper unit to be attached to a vehicle including front side frames provided on both sides in a vehicle width direction so as to extend in a vehicle front-rear direction, and gussets extending forward from outer surfaces located on the outer sides of the front side frames in the vehicle width direction while expanding outward in the vehicle width direction, the outer parts located on the outer sides of the front side frames in the vehicle width direction have a shape that inclines rearward as it goes outward, the bumper unit including a bumper beam fixed directly or indirectly to a front end of the front side frames so as to extend in the vehicle width direction, and a clamp on the rear side of the bumper beam. The load transfer member comprises: a rear wall attached to face the front end of the gusset with a clearance, and having a gusset facing area facing the front end of the gusset; a front wall arranged along the outer portion and configured to be wider in the vehicle width direction than the gusset facing area when viewed from the front of the vehicle; and a front-to-rear connecting wall connected to an inner edge portion located on the inside of the vehicle width direction of the gusset facing area, extending in a direction such that the angle between the gusset facing area and the vehicle fore-and-aft direction is smaller than the angle between the extension direction of the gusset and the vehicle fore-and-aft direction, connecting the gusset facing area and the front wall.

(2) In the above (1), the front-rear connecting wall is connected to the front wall at a position forward of the inner edge in the vehicle front-rear direction or at a position inward in the vehicle width direction from the forward position in the vehicle front-rear direction.

(3) In the above (1) or (2), the load transmission member is an aluminum hollow member having a cavity that extends in the vertical direction when the bumper beam is fixed to the front side frame, and further includes an inclined connecting wall that is perpendicular to the front wall and connects the gusset facing area to the front wall.

(4) In the above (3), the inclined connecting wall is connected to the outer edge portion located on the outer side in the vehicle width direction of the gusset facing area.

(5) In the above (3) or (4), the load transmitting member further includes front and rear middle walls that extend between the front and rear connecting walls and the inclined connecting walls in a direction such that the angle between the front and rear direction of the vehicle is smaller than the angle between the extension direction of the gusset and the front and rear direction of the vehicle, connecting the gusset facing area to the front wall.

(6) In the above (5), the thickness of the front and rear middle walls is smaller than the thickness of the front and rear connecting walls.

(7) In any of (3) to (6) above, the load transmission member further includes an inclined middle wall between the front and rear connecting walls and the inclined connecting wall, which is perpendicular to the front wall and connects the gusset facing area and the front wall.

(8) In the above (7), the thickness of the inclined middle wall is greater than the thickness of the inclined connecting wall.

(9) In any of the above (1) to (8), the rear wall is provided with a guide portion that extends rearward on the vehicle width direction outer side of the gusset facing area.

(10) In any of (1) to (9) above, the clearance is set to be smallest between the inner edge portion located on the inner side in the vehicle width direction of the gusset facing area and the front end of the gusset.

In this specification, the terms "vehicle longitudinal direction," "vehicle width direction," and "up-down direction" generally refer to these directions, and some deviation is acceptable as long as it does not deviate from the gist of this disclosure. Additionally, "perpendicular" and "parallel" include those that are approximately perpendicular and those that are approximately parallel.

This technology makes it possible to provide a vehicle bumper unit with excellent collision performance, in particular a vehicle bumper unit that exhibits excellent load transmission efficiency during a single-side collision.

FIG. 1 is a perspective view showing a schematic configuration of a vehicle bumper unit according to an embodiment of the present invention attached to a front side frame. FIG. 2 is a plan view of the vehicle bumper unit as viewed from above. FIG. 3 is a plan view of the load transmitting member. FIG. 4 is an elevational view showing a configuration in the vicinity of a fixing portion of a vehicle bumper unit as viewed from the front of the vehicle. FIG. 5 is a schematic diagram showing how a collision load is transmitted after the vehicle bumper unit of FIG. 2 is subjected to a SOL collision. FIG. 6A is a plan view of a load transmitting member according to a first modified example. FIG. 6B is a plan view of the load transmitting member according to the second modification. FIG. 6C is a plan view of a load transmitting member according to the third modification. FIG. 7A is a plan view of a vehicle bumper unit according to a fourth modified example, as viewed from above. FIG. 7B is a plan view of the vehicle bumper unit according to the fifth modified example, as viewed from above.

<Embodiment>
An embodiment of a vehicle bumper unit according to the technology disclosed in this specification will be described below with reference to Figures 1 to 5. Note that the present technology is not limited to these examples, but is indicated by the claims, and is intended to include all modifications within the meaning and scope equivalent to the claims. Note that the arrows in the lower left part of each figure indicate the front (F), left (L), and upper (U) of the vehicle. In addition, for multiple identical members, some members may be labeled with a reference number, and the reference numbers of other members may be omitted.

(Vehicle side structure)
First, the structure of a vehicle 200 to which a vehicle bumper unit 100 of the present embodiment is attached will be described with reference to FIGS. 1 and 2. FIG.
The vehicle bumper unit 100 according to this embodiment is attached to a front side frame 20 extending along the vehicle front-rear direction of the vehicle 200. As shown in Fig. 1 and Fig. 2, a gusset 10 is connected to an outer surface 20S located on the outer side in the vehicle width direction of the front side frame 20. The front side frames 20 are provided on both sides of the vehicle 200 in a pair on the left and right, but Fig. 1 and the like only show the left front side frame 20. The vehicle bumper unit according to this embodiment and the structure of the mounting portion thereof are substantially the same (symmetrical) on the left and right sides of the vehicle 200, so in the following description, the structure on the left side will be described, and a description of the structure on the right side will be omitted unless necessary.

(Front side frame)
The front side frame 20 is, for example, a member made of a steel plate and having a rectangular closed cross section. The front side frame 20 is provided on both sides of the vehicle 200 so as to extend in the vehicle front-rear direction at the front of the vehicle 200, and vehicle equipment such as a radiator and an engine are disposed on the inner side of the pair of left and right front side frames 20 in the vehicle width direction. As shown in Figs. 1 and 2, a shock absorber mounting portion 21 having a substantially planar shape perpendicular to the vehicle front-rear direction is provided at the front end of the front side frame 20, and a mounting portion 41 of the shock absorber 40 described later is fixed to the shock absorber mounting portion 21. The shock absorber mounting portion 21 protrudes in the vertical direction and the vehicle width direction from the main body portion of the front side frame 20, and is formed so that the vertical and vehicle width dimensions are slightly larger than the corresponding dimensions of the main body portion of the shock absorber 40.

(Gusset)
1 and 2, the gusset 10 is connected to an outer surface 20S of the front side frame 20 so as to extend forward while spreading outward in the vehicle width direction. The method of connecting the gusset 10 to the front side frame 20 is not particularly limited, and the gusset 10 can be fixed, for example, by welding or fasteners. The extension length of the gusset 10 from the front side frame 20 is set to a length such that a front end 10T, which is the extension end of the gusset 10, faces a rear surface 30S of a bumper beam 30 (described later) with a predetermined clearance C therebetween.

As shown in Figs. 1 and 2, a gusset support member 19 is fixed near the front end 10T of the gusset 10 according to this embodiment, and the inner surface of the gusset 10 on the inner side in the vehicle width direction near the front end 10T is supported by the front side frame 20 via the gusset support member 19. The gusset support member 19 may be made of, for example, a steel plate. As shown in Figs. 1 and 2, the gusset support member 19 according to this embodiment is bent in a substantially stepped shape when viewed from above. The gusset support member 19 is fixed to the front side frame 20 and supports the front end of the gusset 10.

(Vehicle bumper unit)
Next, a vehicle bumper unit 100 according to this embodiment will be described with reference to Fig. 1 to Fig. 5. The vehicle bumper unit 100 includes a bumper beam 30 fixed to the front end of the front side frame 20 so as to extend in the vehicle width direction, and a load transmission member 50 attached to a rear surface 30S of the bumper beam 30. The vehicle bumper unit 100 according to this embodiment further includes an impact absorber 40 attached to the rear surface 30S of the bumper beam 30.

The bumper beam 30, the shock absorber 40, and the load transmission member 50 constituting the vehicle bumper unit 100 according to this embodiment are all hollow members made of aluminum alloy. The vehicle bumper unit, which was conventionally made of steel, is made of aluminum alloy to reduce its weight. As described later, this technology provides the effect of improving the load transmission efficiency and reducing the deformation of the bumper beam, and thus it is possible to use a member that is generally lighter than the conventional steel bumper beam but has low strength, such as an aluminum alloy hollow member. In order to obtain the advantage of reducing the weight while exhibiting sufficient strength, it is preferable to use an aluminum alloy with excellent strength, particularly for the bumper beam 30 and the load transmission member 50. Although not limited to these, from the viewpoints of strength and corrosion resistance, 6000 series (Al-Mg-Si type) and 7000 series (Al-Zn-Mg type) aluminum alloys can be preferably used as the aluminum alloy. In particular, it is preferable to use a 7000 series aluminum alloy with excellent strength.

(Bumper beam)
The bumper beam 30 is, for example, a long member having a rectangular closed cross section with a void (hollow portion) extending in the longitudinal direction. For the purpose of reinforcement, a concave portion or a convex portion may be formed on the wall of the bumper beam 30, or a rib wall may be arranged inside. The bumper beam 30 extends along the vehicle width direction as a whole. As shown in Figs. 1 and 2, an impact absorber 40 and a load transmission member 50 are attached to the rear surface 30S of the bumper beam 30. If the part of the bumper beam 30 to which the impact absorber 40 is attached is defined as a fixed part 31 and the part located outside the fixed part 31 in the vehicle width direction is defined as an outer part 33, the bumper beam 30 has a shape in which the fixed part 31 is located forward of the outer part 33 and the outer part 33 is inclined backward as it moves toward the outside in the vehicle width direction. The outer part 33 may be flat or curved, and may be either linearly inclined or curvedly inclined (curved) when viewed from above. Furthermore, the shape of the central portion located between the left and right fixing portions 31 and extending in the vehicle width direction is not particularly limited, and for example, the central portion may be partially or entirely curved. The rear surfaces of the fixing portions 31 and the outer portion 33 are made up of the rear surface 30S of the bumper beam. Therefore, hereinafter, the rear surface of the fixing portion 31 or the outer portion 33 may be referred to as the "rear surface 30S."

The bumper beam 30 is indirectly connected and fixed to the front side frame 20 via the shock absorber 40, as described below. The vertical dimension (height) of the bumper beam 30 is made larger than the same dimension of the main body of the front side frame 20. When the vehicle bumper unit 100 is attached to the vehicle, the fixed portion 31 of the bumper beam 30 is supported by the front side frame 20 via the shock absorber 40, and the outer portion 33 is arranged in a cantilever shape with the outer end in the vehicle width direction as the free end.

(Shock absorber)
The shock absorber 40 is, for example, a member having a rectangular closed cross section, and is arranged so that the void extends in the vehicle front-rear direction. As shown in Figs. 1 and 2, the shock absorber 40 is interposed between the shock absorber mounting portion 21 provided at the front end of the front side frame 20 and the rear surface 30S of the bumper beam 30. The vertical dimension (height) of the main body of the shock absorber 40 is slightly smaller than the vertical dimension (height) of the bumper beam 30 and larger than the vertical dimension of the main body of the front side frame 20. The vehicle width direction dimension of the main body of the shock absorber 40 is also larger than the vertical dimension of the main body of the front side frame 20. The shock absorber 40 according to this embodiment functions as a so-called crash box that absorbs collision energy by being crushed in the axial direction (vehicle front-rear direction) when a collision load F is applied from the front of the vehicle 200, as will be described later with reference to Fig. 5.

The front end of the impact absorber 40 is fixed to the fixed portion 31 of the bumper beam 30 by welding or the like. In addition, the rear end of the impact absorber 40 is provided with an attachment portion 41 that protrudes in the vertical direction and the vehicle width direction from the main body of the impact absorber 40, and is fixed to the impact absorber attachment portion 21.

(Load transmission member)
In the vehicle bumper unit 100 according to the present embodiment, a load transmission member 50 is attached to the outer portion 33 of the bumper beam 30. The gusset 10 does not directly face the rear surface of the bumper beam as in the conventional structure (for example, the front body structure described in Patent Document 1), but faces the load transmission member 50 attached to the rear surface 30S of the bumper beam 30, so that the collision load during the SOL collision can be transmitted more efficiently from the bumper beam 30 to the front side frame 20. In addition, if the gusset made of a steel plate directly faces the bumper beam made of a hollow member made of an aluminum alloy, there is a possibility that the front end of the gusset will bite into the rear surface of the bumper beam during the SOL collision and damage the bumper beam, but in the present embodiment, such a situation can be suppressed by interposing the load transmission member 50 between the two members. For example, a hollow member having a closed cross section is used as the load transmission member 50, and the void is arranged so as to extend in the vertical direction. The shape and dimensions of the load transmission member 50 will be described in detail with reference to FIG. 3 and FIG. 4.

As shown in FIG. 3, the load transfer member 50 according to this embodiment has a horizontal cross-sectional outer shape that is a substantially rectangular shape combining a substantially trapezoid and a substantially triangle (a shape combining a substantially trapezoid consisting of the front and rear connecting walls 53, the front and rear middle walls 55, the rear wall 51, and a portion of the front wall 52, which will be described later, and a substantially triangle consisting of the front and rear middle walls 55, the inclined connecting walls 54, and a portion of the front wall 52). As shown in FIG. 4, the vertical dimension of the load transfer member 50 is slightly smaller than the same dimension (height) of the bumper beam 30 and larger than the same dimension of the front end 10T of the gusset 10.

3 and 4, the load transmission member 50 includes a rear wall 51 having a gusset facing region 51R, a front wall 52 arranged along the rear surface 30S of the outer portion 33 of the bumper beam 30, and a front-rear connecting wall 53 extending in the vehicle front-rear direction to connect the gusset facing region 51R and the front wall 52. The gusset facing region 51R is a region having a certain area, and faces the front end 10T of the gusset 10 with a clearance C in the rear wall 51, and is a region against which the front end 10T abuts during a SOL collision. As shown in FIG. 4, in this embodiment, the dimension of the rear wall 51 in the vehicle width direction as viewed from the front of the vehicle is approximately equal to the same dimension of the front end 10T of the gusset 10, and the gusset facing region 51R extends over approximately the entire length of the rear wall 51 in the vehicle width direction. Also, as shown in FIG. 4, in this embodiment, the vertical dimension (height) of the rear wall 51 as viewed from the front of the vehicle is greater than the vertical dimension of the front end 10T of the gusset 10, and the height direction is set so that the gusset facing region 51R occupies a portion of the rear wall 51.

3, the rear wall 51 faces the front end 10T of the gusset 10 with the gusset facing region 51R facing the front end 10T of the gusset 10 with a predetermined clearance C. The clearance C can be set taking into consideration the magnitude and location of the collision load expected in the SOL collision, the strength of each wall constituting the load transmission member 50, the strength of the gusset 10 and the gusset support member 19, etc. It is preferable to set the clearance C so that it is smallest between the inner edge located on the inner side of the gusset facing region 51R in the vehicle width direction and the front end 10T. In this embodiment, the front end 10T is slightly inclined rearward as it moves toward the outer side in the vehicle width direction, while the gusset facing region 51R extends in the vehicle width direction, so that the clearance C is set to be smaller on the inner side in the vehicle width direction than on the outer side in the vehicle width direction.

As shown in FIG. 3, the front wall 52 is disposed along the rear surface 30S of the outer portion 33 of the bumper beam 30. In this embodiment, the entire front surface of the front wall 52 is disposed in contact with the rear surface 30S of the outer portion 33. Also, as shown in FIG. 4, in this embodiment, the dimension in the vehicle width direction of the front wall 52 that contacts the rear surface 30S is larger than the same dimension of the gusset facing region 51R (the same dimension as the rear wall 51 in this embodiment). Also, in this embodiment, the dimension in the vertical direction of the front wall 52 (the same dimension as the rear wall 51 in this embodiment) is larger than the same dimension of the gusset facing region 51R. In this way, when viewed from the front of the vehicle, the front wall 52 is set to have a larger area than the rear wall 51 and the gusset facing region 51R.

3, the front-rear connecting wall 53 is connected to the inner edge of the gusset facing region 51R in the rear wall 51, i.e., the end of the rear wall 51 on the inner side in the vehicle width direction. As a result, when the outer portion 33 of the bumper beam 30 is displaced rearward during a SOL collision and the gusset facing region 51R abuts against the front end 10T of the gusset 10, the collision load transmitted from the front-rear connecting wall 53 to the inner edge of the gusset facing region 51R is transmitted to the front side frame 20 mainly through the inner side of the gusset 10 in the vehicle width direction (the front side frame 20 side).
In this embodiment, the front-rear connecting wall 53 extends in the vehicle front-rear direction and is connected to the front wall 52 in front of the inner edge of the gusset facing region 51R. Since the front-rear connecting wall 53 extends in the vehicle front-rear direction, the collision load applied to the bumper beam 30 along the vehicle front-rear direction and transmitted to the front wall 52 can be efficiently transmitted to the gusset facing region 51R via the front-rear connecting wall 53. It is particularly preferable that the front-rear connecting wall 53 extends in the vehicle front-rear direction as in this embodiment, but it is not necessary to extend strictly in the vehicle front-rear direction. The front-rear connecting wall 53 can be set to extend in a direction that forms a slight angle with respect to the vehicle front-rear direction, for example, an angle of -7° or more and +7° or less, preferably -5° or more and +5° or less, more preferably -3° or more and +3° or less. If the extension direction of the front-rear connecting wall 53 is in such a range, the collision load can be transmitted sufficiently efficiently from the front wall 52 to the gusset facing region 51R.

In addition, the front and rear connecting walls 53 are connected to the front wall 52 at a position closer to the inside in the vehicle width direction than the intersection line between the extension surface of the inner side of the gusset 10 and the bumper beam 30, i.e., closer to the fixed part 31 of the bumper beam 30. When the gusset facing area 51R abuts against the front end 10T of the gusset 10 due to an SOL collision, the bumper beam 30 is deformed while being supported from the rear by the fixed part 31 with the front side frame 20 and the connection part with the front wall 52 of the front and rear connecting walls 53. In this embodiment, the connection part with the front wall 52 of the front and rear connecting walls 53 is located on the inside in the vehicle width direction, i.e., closer to the initial contact point during a SOL collision and the fixed part 31 with the front side frame 20, so that deformation of the bumper beam 30 during a SOL collision is reduced compared to the conventional configuration in which the rear surface of the bumper beam 30 directly faces the gusset.

3, the load transfer member 50 according to this embodiment further includes an inclined connecting wall 54 that is perpendicular to the front wall 52 and connects the gusset facing region 51R and the front wall 52. The inclined connecting wall 54 according to this embodiment connects the outer edge of the gusset facing region in the rear wall 51, i.e., the outer end of the rear wall 51 in the vehicle width direction, and the outer end of the front wall 52 in the vehicle width direction. As a result, the cross section of the load transfer member 50 has a closed cross section with a rectangular outer shape as described above. The inclined connecting wall 54 does not need to be strictly perpendicular to the front wall 52, and may extend in a direction that forms a slight angle (for example, an angle of -7° to +7°, preferably -5° to +5°, more preferably -3° to +3°) with respect to the normal line of the front wall 52 within the scope of the present disclosure.

3, the load transmission member 50 according to this embodiment further includes a front-rear middle wall 55 between the front-rear connecting wall 53 and the inclined connecting wall 54, which extends in the front-rear direction of the vehicle and connects the front wall 52 and the rear wall 51. The front-rear middle wall 55 is located on the outer side of the front-rear connecting wall 53 in the vehicle width direction, and is arranged in a space having a closed rectangular cross section formed by the rear wall 51, the front wall 52, the front-rear connecting wall 53, and the inclined connecting wall 54 so as to divide the space in the front-rear direction of the vehicle. The front-rear middle wall 55 does not need to extend strictly in the front-rear direction of the vehicle, as does the front-rear connecting wall 53, and may extend in a direction that forms a slight angle with respect to the front-rear direction of the vehicle, as long as it does not deviate from the gist of this disclosure. In addition, the front-rear middle wall 55 does not need to be parallel to the front-rear connecting wall 53, and may extend in a direction that forms a slight angle with respect to the front-rear connecting wall 53.

3, the load transmission member 50 according to this embodiment further includes an inclined middle wall 56 between the front-rear connecting wall 53 and the inclined connecting wall 54, which is perpendicular to the front wall 52 and connects the front wall 52 and the rear wall 51. The inclined middle wall 56 is located inward in the vehicle width direction from the inclined connecting wall 54 and the front-rear middle wall 55, and is arranged in a space having a closed rectangular cross section formed by the rear wall 51, the front wall 52, the front-rear connecting wall 53, and the front-rear middle wall 55 so as to divide the space in a downward diagonal direction from the vehicle front-rear direction. The inclined middle wall 56, like the inclined connecting wall 54, does not need to be strictly perpendicular to the front wall 52, and may extend in a direction that forms a slight angle with respect to the normal line of the front wall 52, as long as it does not deviate from the gist of this disclosure. The inclined middle wall 56 does not need to be parallel to the inclined connecting wall 54, and may extend in a direction that forms a slight angle with respect to the inclined connecting wall 54.

As shown in FIG. 3, in the load transfer member 50 according to the present embodiment, the front and rear middle walls 55 and the front and rear connecting walls 53, the inclined middle walls 56 and the inclined connecting walls 54 are arranged parallel to each other. In the load transfer member 50 according to the present embodiment, the walls arranged parallel to each other are formed so that the walls located on the inner side in the vehicle width direction (front and rear connecting walls 53, inclined middle walls 56) have a greater thickness than the walls located on the outer side in the vehicle width direction (front and rear middle walls 55, inclined connecting walls 54). Specifically, if the thickness of the front and rear connecting walls 53 is 53W and the thickness of the front and rear middle walls 55 is 55W, the thickness 53W is greater than the thickness 55W. Also, if the thickness of the inclined middle wall 56 is 56W and the thickness of the inclined connecting wall 54 is 54W, the thickness 56W is greater than the thickness 54W. Although it depends on the arrangement, dimensions, shape, and material of the front side frame 20 and the bumper beam 30, and the dimensions and shapes of the rear wall 51 and the front wall 52 of the load transfer member 50, it is preferable that the cross-sectional shape of the load transfer member 50 in a plan view is set so as not to deform easily. For example, it is preferable that the thickness 53W is 1.2 times or more the thickness 55W, and the thickness 56W is 1.2 times or more the thickness 54W, and more preferably 1.5 times or more each. By setting the thickness of each wall within the above range, the load transfer member 50 can be made lightweight while ensuring sufficient strength, and the collision load during a SOL collision can be efficiently transmitted to the front side frame 20 from the inside in the vehicle width direction.

(Manufacturing of vehicle bumper units)
The vehicle bumper unit 100 having the above structure can be manufactured, for example, as follows.
First, the above-mentioned aluminum alloy is molded into the above-mentioned dimensions and shapes by a known method to manufacture the bumper beam 30, the shock absorber 40, and the load transmission member 50. The load transmission member 50 and the like can be molded preferably by extrusion molding, or can be molded, for example, by machining. After each member is molded, the shock absorber 40 and the load transmission member 50 are fixed to predetermined positions on the rear surface 30S of the bumper beam 30. The shock absorber 40 and the load transmission member 50 can be fixed by a known method such as welding or fastening using fasteners.

The manufactured vehicle bumper unit 100 is attached to both the left and right sides of the vehicle 200 by fixing the shock absorber attachment portion 21 provided at the front end of the front side frame 20 to the attachment portion 41 of the shock absorber 40, for example as described above.

(SOL collision)
An example of the transmission of a collision load F when a vehicle 200 equipped with the vehicle bumper unit 100 as described above collides with a collision object B such as a barrier in a SOL collision will be described with reference to Figures 2 and 5. Note that the effect of the collision load applied to the vehicle bumper unit 100 due to the collision of the vehicle 200 varies depending on the positional relationship between the fixing portion 31 (the mounting portion of the shock absorber 40) and the load portion where the collision load is applied to the bumper beam 30. In the following, a case will be described in which the collision load F due to the SOL collision with the collision object B is applied to the end portion (near the fixing portion 31) on the inner side in the vehicle width direction of the outer portion 33 of the bumper beam 30 as shown in Figure 2.

When a collision load F is applied to the above-mentioned position of the bumper beam 30 due to a SOL collision with a colliding object B, a part of the collision load F is transmitted to the front side frame 20 via the shock absorber 40, for example as shown by the arrows A1 and A2 in FIG. 5. As the collision load F is transmitted in this manner, the shock absorber 40 gradually collapses, and the bumper beam 30 is displaced rearward relative to the vehicle 200, and the bumper beam 30 and the front side frame 20 approach each other.

On the other hand, another part of the collision load F is transmitted from the load transmission member 50 to the gusset 10 and further to the front side frame 20, as shown by the arrows B1, B2, and B3 in FIG. 5. Specifically, the transmission of the collision load F via the load transmission member 50 and the gusset 10 proceeds as follows.

When a collision load F is applied to the outer portion 33 arranged in a cantilever shape, a portion of the collision load F is transmitted from the front wall 52 abutting against the rear surface 30S of the bumper beam 30 to the load transmission member 50, as shown by the arrow B1 in FIG. 5. Most of the collision load F applied to the bumper beam 30 on the inner side in the vehicle width direction from the mounting position of the load transmission member 50 is transmitted from the inner edge in the vehicle width direction of the front wall 52 through the front-rear connecting wall 53 to the rear wall 51, as shown by the arrow B2 in FIG. 5.

When a collision load F is applied to the outer portion 33 arranged in a cantilever shape, the bumper beam 30 deforms, and the end of the outer portion 33 on the vehicle width direction outer side moves toward the rear of the vehicle with the boundary with the fixed portion 31 as the center of rotation. Due to such deformation of the bumper beam 30 and the relative displacement of the bumper beam 30 caused by the crushing of the impact absorber 40 described above, the load transmission member 50 approaches the gusset 10, and the gusset facing area 51R, which faces the front end 10T with a clearance C, abuts against the front end 10T. When the gusset facing area 51R abuts against the front end 10T, the load transmitted to the rear wall 51 of the load transmission member 50 is transmitted from the load transmission member 50 to the gusset 10 in the gusset facing area 51R. Then, as shown by the arrow B3 in FIG. 5, the load is transmitted to the front side frame 20 through the gusset 10.

<Effects of this embodiment>
As described above, according to the vehicle bumper unit 100 according to this embodiment, the following advantageous effects can be obtained.

In the load transmission member 50 according to this embodiment, the front-rear connecting walls 53 extend in the vehicle front-rear direction in which the collision load F due to the SOL collision is applied, and connect the gusset facing region 51R of the rear wall 51 to the front wall 52. Therefore, the collision load F transmitted from the bumper beam 30 to the front wall 52 can be transmitted very efficiently to the gusset facing region 51R by the front-rear connecting walls 53.

In addition, in the load transmission member 50 according to this embodiment, the front and rear connecting walls 53 are connected to the inner edge located on the vehicle widthwise inner side of the gusset facing region 51R. Therefore, the collision load F transmitted to the front wall 52 of the load transmission member 50 is transmitted to the inner edge of the gusset facing region 51R by the front and rear connecting walls 53. As a result, when the gusset facing region 51R abuts against the front end 10T due to deformation or displacement of the bumper beam 30, the load transmitted from the load transmission member 50 to the gusset 10 is transmitted mainly to the vehicle widthwise inner side of the gusset 10, that is, to the side close to the front side frame 20. In this way, the collision load F of the SOL collision can be transmitted to the front side frame 20 more efficiently and via a shorter path.

In addition, in the load transmission member 50 according to this embodiment, the front wall 52 is provided so as to be larger in the vehicle width direction than the gusset facing region 51R of the rear wall 51. Therefore, the collision load F applied to the outer portion 33 of the bumper beam 30 is transmitted to the front wall 52 arranged over a wide range, and is transmitted to the gusset facing region 51R via the load transmission member 50. As a result, when the gusset facing region 51R abuts against the front end 10T due to deformation or displacement of the bumper beam 30, the collision load F applied to the outer portion 33 of the bumper beam 30 due to the collision is efficiently transmitted to the gusset 10 via the load transmission member 50 and transmitted to the front side frame 20. In this embodiment, the vertical dimension of the front wall 52 is also larger than the same dimension of the gusset facing region 51R (the same dimension of the rear wall 51 in this embodiment), so that the collision load F is transmitted from the front wall 52 to the load transmission member 50 over a wider range.

In addition, in the load transmission member 50 according to this embodiment, the front-rear connecting wall 53 is connected to the front wall at the front of the inner edge of the gusset facing region 51R in the vehicle longitudinal direction. Therefore, compared to the conventional configuration in which the gusset 10 directly faces the rear surface of the bumper beam 30, it is possible to reduce deformation of the outer portion 33 when a collision load is applied to a position of the outer portion 33 near the fixed portion 31 during a SOL collision.

The load transfer member 50 according to this embodiment is a hollow aluminum member having a void that extends in the vertical direction when the bumper beam 30 is fixed to the front side frame 20, and further includes an inclined connecting wall 54 that is perpendicular to the front wall 52 and connects the gusset facing region 51R to the front wall 52. Therefore, while the load transfer member 50 is formed to be lightweight, the cross-sectional rigidity of the load transfer member 50 made of a hollow member is improved by the inclined connecting wall 54, thereby suppressing deformation and crushing.

In addition, in the load transmission member 50 according to this embodiment, the inclined connecting wall 54 is connected to the outer edge portion located on the vehicle widthwise outer side of the gusset facing region 51R. In other words, the inclined connecting wall 54 is disposed on the outermost side in the vehicle widthwise direction. Therefore, the collision load F applied to the bumper beam 30 can be transmitted from a wide area of the outer portion 33 to the front wall 52, and can be transmitted to the front side frame 20 while suppressing the crushing of the load transmission member 50.

In addition, the load transfer member 50 according to this embodiment further includes front and rear middle walls 55 that extend in the vehicle front-rear direction between the front and rear connecting walls 53 and the inclined connecting walls 54 and connect the gusset facing region 51R and the front wall 52. By including the front and rear middle walls 55, the cross-sectional rigidity of the load transfer member 50 can be improved, and the load transfer member 50 can be prevented from collapsing.

In addition, in the load transfer member 50 according to this embodiment, the thickness 55W of the front and rear middle walls 55 is smaller than the thickness 53W of the front and rear connecting walls 53. The front and rear middle walls 55 only need to be thick enough to prevent the load transfer member 50 from collapsing. By making the front and rear middle walls 55 thinner than the front and rear connecting walls 53, the weight of the load transfer member 50 can be reduced.

The load transfer member 50 according to this embodiment further includes an inclined middle wall 56 that is between the front and rear connecting walls 53 and the inclined connecting wall 54 and perpendicular to the front wall 52 to connect the gusset facing region 51R and the front wall 52. By including the inclined middle wall 56, the cross-sectional rigidity of the load transfer member 50 can be improved, and deformation (crushing) of the load transfer member 50 can be suppressed.

In addition, in the load transfer member 50 according to this embodiment, the thickness 56W of the inclined middle wall 56 is greater than the thickness 54W of the inclined connecting wall 54. The inclined middle wall 56 only needs to be thick enough to prevent the load transfer member 50 from collapsing. By making the inclined connecting wall 54 thinner than the inclined middle wall 56, the weight of the load transfer member 50 can be reduced.

In addition, in the vehicle bumper unit 100 according to this embodiment, the clearance C between the load transmission member 50 and the gusset 10 is set to be smallest between the inner edge of the gusset facing region 51R located on the inner side in the vehicle width direction and the front end 10T of the gusset 10. With this configuration, when the load transmission member 50 is displaced relative to the front side frame 20 or the like due to a SOL collision, the gusset facing region 51R of the rear wall 51 first abuts against the front end 10T of the gusset 10 at its inner edge. Therefore, the load transmitted from the load transmission member 50 to the gusset 10 is first transmitted to the inner side of the gusset 10 in the vehicle width direction, i.e., to the side close to the front side frame 20. As a result, the collision load F can be transmitted to the front side frame 20 more efficiently over a short path.

<Modifications of the embodiment>
Modified examples of the load transmission member 50 constituting the vehicle bumper unit 100 will be described with reference to Figures 6A to 6C, 7A and 7B. The load transmission members 150, 250, 350, 450, and 550 according to the following modified examples can be hollow members having a closed cross section made of, for example, an aluminum alloy, as in the load transmission member 50 according to the embodiment. The load transmission members 150, 250, 350, 450, and 550 are attached to the rear surface 30S of the outer part 33 of the bumper beam 30 so that the voids extend in the vertical direction, as in the load transmission member 50. In the following, the same components as those of the load transmission member 50 are given the same reference numerals as in the embodiment, and the description thereof will be omitted, and the description of the same functions and effects as those of the embodiment will also be omitted.

(Variation 1)
6A is a plan view of a load transfer member 150 according to Modification 1 as viewed from above. The load transfer member 150 according to this modification differs from the load transfer member 50 according to the above embodiment in that, in a space defined by the rear wall 51, the front wall 52, the front-rear connecting walls 53, and the inclined connecting walls 54, the load transfer member 150 only has an inclined middle wall 156 perpendicular to the front wall 52, and does not have a wall corresponding to the front-rear middle wall 55 of the embodiment. The inclined middle wall 156 is disposed outside the inclined middle wall 56 of the load transfer member 50 in the vehicle direction, i.e., closer to the inclined connecting wall 54, and is formed to be thicker than the inclined connecting wall 54.

(Effects of Modification 1)
The load transmission member 150 according to this modification has a simpler structure than the load transmission member 50, and is therefore advantageous in terms of weight reduction and cost reduction. In addition, a relatively thick inclined middle wall 156 is disposed in the cavity of the load transmission member 150 so as to divide the cavity into roughly equal parts, so that the load transmission member 150 is less likely to be crushed even without the front and rear middle walls 55, and the collision load can be efficiently transmitted to the front side frame 20.

(Variation 2)
6B is a plan view of the load transfer member 250 according to the modified example 2 as viewed from above. The load transfer member 250 according to the modified example is different from the load transfer member 50 according to the above embodiment in that a guide portion 251G1 extending rearward, i.e., toward the gusset 10, is formed at the end portion of the rear wall 251 on the outer side in the vehicle direction. The guide portion 251G1 is formed by bending rearward an end portion of the rear wall 251 on the outer side in the vehicle direction than the gusset facing region 251R.

(Effects of Modification 2)
In the load transmission member 250 according to this modification, a guide portion 251G1 is provided on the rear wall 251, which extends rearward on the vehicle width direction outer side of the gusset facing region 251R. When the gusset expands due to a SOL collision and the front end of the gusset slides outward in the vehicle width direction, the front end may not be firmly abutted against the gusset facing region of the load transmission member, and the collision load may not be transmitted well from the load transmission member to the gusset. By providing the guide portion 251G1, the movement of the front end 10T of the gusset 10 outward in the vehicle width direction is restricted. As a result, the front end 10T is firmly abutted against the gusset facing region 251R, and the collision load F can be reliably transmitted from the load transmission member 250 to the gusset 10 and further to the front side frame 20.

(Variation 3)
6C is a plan view of the load transmission member 350 according to the third modification seen from above. The load transmission member 350 according to this modification is different from the load transmission member 50 according to the above embodiment in that an outer guide portion 351G1 and an inner guide portion 351G2 extending rearward, i.e., toward the gusset 10, are formed at both ends of the rear wall 351 in the vehicle direction. The outer guide portion 351G1 is formed by bending an end portion of the rear wall 351 that is more outer in the vehicle direction than the gusset facing region 351R rearward, and the inner guide portion 351G2 is formed by bending an end portion of the rear wall 351 that is more inner in the vehicle direction than the gusset facing region 351R in the direction along the extension direction of the gusset 10.

(Effects of Modification 3)
When the gusset falls inward due to a SOL collision and the front end of the gusset slides inward in the vehicle width direction, the front end may not be firmly abutted against the gusset facing area of the load transmission member, and the collision load may not be transmitted well from the load transmission member to the gusset. In addition, the connection portion between the gusset and the front side frame may be damaged. According to the above configuration, the outer guide portion 351G1 restricts the movement of the front end 10T of the gusset 10 outward in the vehicle width direction, and the inner guide portion 351G2 restricts the movement of the front end 10T of the gusset 10 inward in the vehicle width direction, so that the front end 10T is reliably guided to a position substantially directly facing the gusset facing area 351R. As a result, the front end 10T is firmly abutted against the gusset facing area 351R, and the collision load F can be more reliably transmitted from the load transmission member 350 to the gusset 10 and further to the front side frame 20.

(Variation 4)
7A is a plan view of the load transmission member 450 according to the fourth modification attached to the rear surface 30S of the bumper beam 30, viewed from above. The load transmission member 450 according to this modification is different from the load transmission member 50 according to the above embodiment in that the front-rear connecting wall 453 is formed to extend in a direction D453 in which the angle between the front-rear direction DFR of the vehicle is θ1 when attached to the bumper beam 30. The angle θ1 is set so that θ1<α is satisfied with respect to the angle α between the extension direction DG1 of the gusset 10 and the front-rear direction DFR of the vehicle. In consideration of the deformation of the bumper beam 30 and the impact absorber 40 when the rear wall 51 contacts the front end 10T of the gusset 10 during a SOL collision, the extension direction of the front-rear connecting wall 453 at the time of such contact is arranged to be within the above range also falls within the scope of the present disclosure. As shown in FIG. 7A, in the load transmission member 450 of this modified example, the front wall 452 is formed shorter than the front wall 52 of the first embodiment, and the front-rear connecting walls 453 extend in a direction expanding outward in the vehicle width direction as they move toward the front of the vehicle.

(Effects of Modification 4)
In the load transmission member 450 according to this modification, the direction D453 in which the front-rear connecting wall 453 extends is set to be along (close to) the vehicle front-rear direction DFR in which the collision load F due to the SOL collision is applied, compared to the extension direction DG1 of the gusset 10. Therefore, compared to the conventional configuration in which the front end 10T of the gusset 10 directly faces the rear surface 30S of the bumper beam 30, the collision load F transmitted from the bumper beam 30 to the front wall 452 can be efficiently transmitted to the gusset facing region 51R by the front-rear connecting wall 453. In addition, the front-rear connecting wall 453 is connected to the front wall 452 on the vehicle width direction inner side of the intersection line between the extension surface of the vehicle width direction inner surface of the gusset 10 and the rear surface 30S of the bumper beam 30. Therefore, compared to the conventional configuration, deformation of the outer portion 33 when a collision load is applied to a position near the fixed portion 31 in the outer portion 33 during the SOL collision is reduced. As a result, a bumper unit including the load transmitting member 450 can exhibit higher collision resistance than a bumper unit having a conventional configuration.

(Variation 5)
7B is a plan view of the load transmission member 550 according to the fourth modification attached to the rear surface 30S of the bumper beam 30, viewed from above. As shown in FIG. 7B, in the load transmission member 550 according to this modification, the front wall 552 is formed longer than the front wall 52 according to the first embodiment, and the front-rear connecting wall 553 extends in a direction D553 inclined inward in the vehicle width direction toward the front of the vehicle. The angle θ2 between the direction D553 in which the front-rear connecting wall 553 extends and the vehicle front-rear direction DFR is set so that θ2<α is satisfied with respect to the angle α between the extension direction DG1 of the gusset 10 and the vehicle front-rear direction. That is, as shown in FIG. 7B, if the direction that is linearly symmetrical to the extension direction DG1 in the vehicle front-rear direction DFR is defined as the symmetric direction DG2, the direction D553 is a direction along the vehicle front-rear direction DFR more than the symmetric direction DG2.

(Effects of Modification 5)
In the load transmission member 550 according to this modification, the extension direction of the front-rear connecting wall 553 is set to be along the vehicle front-rear direction in which the collision load F due to the SOL collision is applied, compared to the extension direction of the gusset 10. Therefore, compared to the conventional configuration in which the front end 10T of the gusset 10 directly faces the rear surface 30S of the bumper beam 30, the collision load F transmitted from the bumper beam 30 to the front wall 552 can be efficiently transmitted to the gusset facing region 51R by the front-rear connecting wall 553. In addition, the front-rear connecting wall 553 is connected to the front wall 552 on the vehicle width direction inner side of the intersection line between the extension surface of the vehicle width direction inner side surface of the gusset 10 and the rear surface 30S of the bumper beam 30, and further on the vehicle direction inner side of the front of the inner edge of the gusset facing region 51R. Therefore, even compared to the first embodiment, the deformation of the outer portion 33 when a collision load is applied to a position near the fixed portion 31 in the outer portion 33 during the SOL collision is further reduced. As a result, the bumper unit including the load transmitting member 550 can exhibit high collision resistance.

<Other embodiments>
The technology disclosed in this specification may be subject to various changes, modifications, improvements, etc. based on the knowledge of a person skilled in the art, as long as such changes, modifications, improvements, etc. do not deviate from the spirit of the present invention. For example, the following embodiments are also included in the technical scope of the technology disclosed in this specification.

(1) In the above embodiment, the case where the entire front surface of the front wall 52 abuts against the rear surface 30S of the outer portion 33 before the SOL collision is exemplified. This is preferable because the collision load F can be transmitted from the entire front surface of the front wall 52 to the load transmission member 50 while suppressing deformation and damage of the bumper beam 30 during a SOL collision or the like. However, the present invention is not limited to this embodiment, and it is sufficient that the front wall 52 is arranged along the outer portion 33, and that at least a partial area (preferably the entire area) of the rear surface 30S abuts against the front surface of the front wall 52 when a load is applied to the bumper beam 30 from the front. For example, the front wall 52 may be formed flat with respect to the curved outer portion 33. Note that, in the above embodiment, the case where both the outer portion 33 and the front wall 52 are formed linearly when viewed from above is described, but both members may be curved.

(2) In the above embodiment, the gusset facing region 51R extends in the vehicle width direction with respect to the front end 10T, which is inclined rearward as it approaches the outside in the vehicle width direction, so that the clearance C is set to be smallest at the inner edge of the gusset facing region 51R. However, this is not limited to this. For example, the rear wall 51 may be formed in a shape such that the gusset facing region 51R inclines rearward as it approaches the inside in the vehicle width direction with respect to the front end 10T extending in the vehicle width direction, or both the front end 10T and the gusset facing region 51R may be inclined with respect to the vehicle width direction. Alternatively, one or both of the inner edges of the gusset facing region 51R and the front end 10T may be partially protruded toward the other.

(3) In the above embodiment, the bumper beam 30 is indirectly fixed to the front side frame 20 via the shock absorber 40, but this is not limited to the above. Vehicle bumper units that do not include a shock absorber and have a configuration in which the bumper beam is directly fixed to the front side frame are also included in the scope of this disclosure.

(4) In the above modification 1, a load transfer member 150 is described that does not have a middle wall corresponding to the front and rear middle walls 55 of the embodiment, and has an inclined middle wall 156, but is not limited to this. A load transfer member that does not have a middle wall corresponding to the inclined middle wall 56 of the embodiment, and has only a middle wall corresponding to the front and rear middle walls 55, can also achieve the same effect by simplifying the structure, etc. Furthermore, it is also possible to form the load transfer member into a rectangular closed cross-sectional shape without a middle wall, or to form the cross-sectional shape into a substantially C-shaped or I-shaped cross-section in which the front wall and rear wall are connected by a front and rear connecting wall.

(5) In the above modification 4 and modification 5, the front and rear connecting walls 453, 553 extend in directions D453, D553 in which the angles θ1, θ2 with the vehicle fore-and-aft direction DFR are smaller than the angle α between the extension direction DG1 of the gusset 10 and the vehicle fore-and-aft direction DFR. Similarly, for example, the front and rear middle walls 55 in the embodiment may be formed so that they extend in a direction in which the angle with the vehicle fore-and-aft direction DFR is smaller than the angle α between the extension direction DG1 of the gusset 10 and the vehicle fore-and-aft direction DFR.

100...vehicle bumper unit, 200...vehicle, 10...gusset, 10T...front end, 19...gusset support member, 20...front side frame, 20S...outer surface, 21...shock absorber mounting portion, 30...bumper beam, 30S...rear surface, 31...fixing portion, 33...outer portion, 40...shock absorber, 41...mounted portion, 50, 150, 250, 350, 450, 550...load transmission member, 51, 251, 351...rear wall, 51R, 251R, 351R...gusset facing area, 52, 452, 552...front wall, 53, 453, 553...front and rear connecting walls, 54...inclined connecting wall, 55...front and rear middle walls, 56, 156...inclined middle wall, 251G1...guide portion, 351G1...outer guide portion, 351G2...inner guide portion B: Collision object, C: Clearance, F: Collision load

Claims (10)

A vehicle bumper unit to be attached to a vehicle, the vehicle comprising: front side frames provided on both sides in a vehicle width direction so as to extend in a vehicle front-rear direction; and gussets extending forward while expanding outward in the vehicle width direction from outer surfaces located on the outer sides of the front side frames in the vehicle width direction,
a bumper beam that is fixed directly or indirectly to a front end of the front side frame so as to extend in the vehicle width direction, and has an outer portion that is located outer than a fixed portion to the front side frame and has a shape that inclines rearward as it goes outward;
A bumper beam is attached to the rear side of the bumper beam so as to face the front end of the gusset with a clearance therebetween,
a rear wall having a gusset facing area facing a front end of the gusset;
A front wall is disposed along the outer portion and is provided so as to be wider in a vehicle width direction than the gusset facing region when viewed from the front of the vehicle;
a front-to-rear connecting wall connected to an inner edge portion located on the vehicle widthwise inside of the gusset opposing area, extending in a direction such that the angle between the gusset and the vehicle fore-and-aft direction is smaller than the angle between the extension direction of the gusset and the vehicle fore-and-aft direction, and connecting the gusset opposing area and the front wall. The vehicle bumper unit according to claim 1, wherein the front-rear connecting wall is connected to the front wall at a position forward in the vehicle front-rear direction of the inner edge portion or at a position inward in the vehicle width direction from the forward position in the vehicle front-rear direction of the inner edge portion. The load transmitting member is
A hollow member made of aluminum having a void extending in the up-down direction when the bumper beam is fixed to the front side frame,
3. The vehicle bumper unit according to claim 1, further comprising an inclined connecting wall that is perpendicular to the front wall and connects the gusset facing region and the front wall. The vehicle bumper unit according to claim 3, wherein the inclined connecting wall is connected to an outer edge portion located on the vehicle width direction outer side of the gusset facing area. The vehicle bumper unit according to claim 3 or 4, wherein the load transmission member further includes front and rear middle walls extending between the front and rear connecting walls and the inclined connecting walls in a direction such that the angle between the front and rear direction of the vehicle is smaller than the angle between the extension direction of the gusset and the front and rear direction of the vehicle, connecting the gusset facing area to the front wall. The vehicle bumper unit according to claim 5, wherein the thickness of the front and rear middle walls is smaller than the thickness of the front and rear connecting walls. The vehicle bumper unit according to any one of claims 3 to 6, wherein the load transmission member further includes an inclined middle wall between the front and rear connecting walls and the inclined connecting wall, the inclined middle wall being perpendicular to the front wall and connecting the gusset facing area to the front wall. The vehicle bumper unit according to claim 7, wherein the thickness of the inclined middle wall is greater than the thickness of the inclined connecting wall. The vehicle bumper unit according to any one of claims 1 to 8, wherein the rear wall is provided with a guide portion extending rearward on the vehicle width direction outer side of the gusset facing area. 10. The vehicle bumper unit according to claim 1, wherein the clearance is set to be smallest between an inner edge portion located on the vehicle widthwise inner side of the gusset opposing area and the front end of the gusset.

Images