JP7479775B2 - Vehicle battery fixing structure - Google Patents

Description

The present invention relates to a structure for fixing a battery mounted on a vehicle.

As described in Patent Document 1, conventionally, automobiles are used in which a battery is disposed at the rear of the automobile. Patent Document 1 discloses a structure in which a battery and a fuel tank are disposed between the underside of a floor panel and a rear chassis module. Patent Document 1 discloses that the above structure prevents damage to the battery and fuel tank by dividing the load generated during a rear collision into a vehicle body side load path and a chassis side load path.

JP 2020-117208 A

Conventionally, automobiles have been used in which a seat is provided so as to be able to slide in the fore-and-aft direction of the vehicle along a slide rail. The slide rail is attached to a floor panel disposed below the seat. In an automobile equipped with such a slide rail, if the slide rail is disposed forward of the battery, the battery may be damaged by the slide rail in the event of a rear-end collision. For example, depending on the layout of the automobile's components, the rear end of the slide rail may be disposed so as to overlap the front of the battery in order to place the main muffler or the like below the floor panel. In this case, it is conceivable that the rear end of the slide rail may come into contact with the battery in the event of a rear-end collision. Such contact may damage the battery. For this reason, it is desirable to avoid such contact.

Therefore, one of the objects of the present invention is to provide a vehicle battery fixing structure that can prevent the battery from being damaged by the slide rail during a rear-end collision.

A battery fixing structure for a vehicle according to one embodiment of the present invention comprises a step-shaped floor panel, a seat slide rail attached to a high step portion of the floor panel, a battery attached to a low step portion of the floor panel, and a belt portion attached to the underside of the floor panel.
The floor panel includes a connecting portion connecting the higher step portion and the lower step portion, an upper corner portion connecting the higher step portion and the connecting portion, and a lower corner portion connecting the lower step portion and the connecting portion.
The high step portion and the low step portion are provided so that a rear end portion of the seat slide rail is disposed at a middle position in front of the battery in the vehicle up-down direction.
The band portion is disposed so as to extend in the front-rear direction of the vehicle from the high stage portion through the connecting portion to the low stage portion, and includes a mountain fold portion disposed to face the upper corner portion, a valley fold portion disposed to face the lower corner portion, and a straight portion disposed on the low stage portion so as to span the underside of the battery.

The vehicle battery fixing structure described above has a portion between the seat slide rail and the battery that is relatively prone to deformation in the event of a rear-end collision. In particular, the mountain fold of the belt portion is deformable so as to push the upper corner of the floor panel relatively upward and toward the rear of the vehicle. As a result, the rear end of the seat slide rail is displaced relatively upward in the vehicle and moves away from the battery. Therefore, even if the rear end of the seat slide rail is positioned so as to overlap the front of the battery, the rear end of the slide rail is prevented from coming into contact with the battery in the event of a rear-end collision. Details will be described later.

1 is a bottom view of a vehicle battery fixing structure according to a first embodiment, seen from below the vehicle. FIG. 1 is an explanatory diagram showing a cross section of a vehicle battery fixing structure according to a first embodiment taken along a plane parallel to the vehicle front-rear direction and the vehicle up-down direction, illustrating a normal state; 1 is an explanatory diagram showing a cross section of a battery fixing structure for a vehicle according to a first embodiment, taken along a plane parallel to the vehicle front-rear direction and the vehicle up-down direction, illustrating an initial state during a rear-end collision. FIG. 1 is an explanatory diagram showing a cross section of a battery fixing structure for a vehicle according to a first embodiment, taken along a plane parallel to the vehicle front-rear direction and the vehicle up-down direction, illustrating a later state during a rear-end collision. FIG.

[Embodiment 1]
Hereinafter, a battery fixing structure for a vehicle according to the present invention will be specifically described with reference to Figs.
The same symbols in the figures indicate the same objects. In the figures, "FR" indicates the front of the vehicle, "RR" indicates the rear of the vehicle, "LH" indicates the left side of the vehicle, "RH" indicates the right side of the vehicle, "UP" indicates the top of the vehicle, and "LWR" indicates the bottom of the vehicle. In the following description, they will simply be referred to as the front, rear, etc.
1 corresponds to the vehicle width direction. The left-right direction in FIG. 1 corresponds to the vehicle front-rear direction. The vehicle front-rear direction corresponds to the vehicle length direction.
2 to 4 corresponds to the vehicle up-down direction, and the left-right direction in Fig. 2 to 4 corresponds to the vehicle front-rear direction.
In the following description, the surface of each component facing upward on the vehicle is called the top surface, and the surface facing forward on the vehicle is called the front surface, etc. The length of each component is the length along the vehicle front-rear direction. The width of each component is the length along the vehicle width direction. The height of each component is the length along the vehicle up-down direction.
FIG. 2 is a cross-sectional view taken along line AA shown in FIG.

(overview)
The vehicle battery fixing structure 1 according to the first embodiment is used to fix a battery 6 (FIG. 2) to a vehicle body 2 shown in FIG. 1. The battery 6 supplies power to on-board electrical equipment (not shown). The battery 6 is disposed at the rear of the vehicle.

More specifically, the vehicle body 2 shown in FIG. 1 comprises a floor panel 3, a side member 21, and a cross member 22. The side member 21 and the cross member 22 are attached to the underside of the floor panel 3. The side member 21 is a reinforcing member that extends in the front-to-rear direction. A pair of side members 21 are arranged on either side of the floor panel 3 with a gap in the vehicle width direction. The cross member 22 is a reinforcing member that extends in the vehicle width direction, and is arranged so as to span both side members 21.

The floor panel 3 has a two-step shape with a high step portion 31 and a low step portion 33. A connecting portion 32 is disposed between the high step portion 31 and the low step portion 33. As shown in FIG. 2, a seat slide rail 7 is attached to the high step portion 31. A battery 6 is attached to the low step portion 33. The high step portion 31 is mainly disposed forward of the low step portion 33. Therefore, the seat slide rail 7 is disposed forward of the battery 6.

The vertical positions of the high step portion 31 and the low step portion 33 are adjusted so that the rear end portion 7b of the seat slide rail 7 and the front surface 6a of the battery 6 overlap in the vertical direction. That is, the front surface 6a of the battery 6 is disposed facing the rear end portion 7b of the seat slide rail 7. In this arrangement, it is considered that the rear end portion 7b of the seat slide rail 7 and the battery 6 will come into contact with each other in the event of a rear collision. The vehicle battery fixing structure 1 of the first embodiment has a configuration for avoiding the above-mentioned contact. Specifically, the vehicle battery fixing structure 1 of the first embodiment has a belt portion 4. The belt portion 4 is attached to the lower surface of the floor panel 3. The belt portion 4 is also disposed so as to extend in the front-rear direction from the high step portion 31 through the connecting portion 32 to the low step portion 33 (see also FIG. 1). Furthermore, the belt portion 4 has a mountain fold portion 46, a valley fold portion 48, and a straight portion 43. Since the belt portion 4 has a specific shape and is disposed in a specific manner, the seat slide rail 7 and the battery 6 can be displaced so as not to come into contact with each other in the event of a rear collision.
Each component will be described below, with the band portion 4 being particularly described in detail.

(Floor panel)
As described above, the floor panel 3 is a component of the vehicle body 2, and separates the vehicle interior from the exterior at the rear of the vehicle. As described above, the battery 6 and the seat slide rails 7 are attached to the upper surface of the floor panel 3, which faces the interior of the vehicle. The fuel tank 9 and a main muffler (not shown), etc. are attached to the lower surface of the floor panel 3, which faces the exterior of the vehicle.

The floor panel 3 includes a high step 31, a connecting portion 32, a low step 33, an upper corner 36, and a lower corner 38. The high step 31 is arranged so as to be generally parallel to the front-rear direction and the vehicle width direction and generally perpendicular to the up-down direction. The low step 33 is also arranged so as to be generally parallel to the front-rear direction and the vehicle width direction and generally perpendicular to the up-down direction. The high step 31 is arranged so as to be located higher than the low step 33. In addition, most of the high step 31 is arranged so as to be located forward of the low step 33. In detail, as shown in FIG. 1, the part of the floor panel 3 that is arranged in the front is rectangular in a plan view. A part of the part of the floor panel 3 that is arranged in the rear protrudes downward. The bottom of this protruding part is the low step 33. The rear part of the floor panel 3 includes a part that is U-shaped in a plan view and the low step 33. This U-shaped part and the front part of the floor panel 3 described above are the high step 31. The front part of the high step 31 is arranged forward of the low step 33. The rear portion of the high step 31 is provided to surround the low step 33, except for the rear end of the low step 33. In this example, the low step 33 has a polygonal shape in a plan view. The maximum width of the low step 33 is smaller than the width of the front portion of the high step 31.

As shown in FIG. 2, the high stage 31 and the low stage 33 are provided so that the height h of the step between the high stage 31 and the low stage 33 is smaller than the height H of the battery 6.

The connecting portion 32 connects the high stage portion 31 and the low stage portion 33, which are arranged with a vertical offset. Therefore, the connecting portion 32 is arranged so as to cross in the vertical direction. In this example, the connecting portion 32 is C-shaped in a plan view as shown in FIG. 1, corresponding to the above-mentioned U-shaped portion of the high stage portion 31 (FIG. 1). In detail, the connecting portion 32 has a front wall portion 32a and a pair of side wall portions. The front wall portion 32a is a portion of the connecting portion 32 arranged to face forward. The front wall portion 32a connects the rear end edge of the above-mentioned front portion of the high stage portion 31 and the front end edge of the low stage portion 33. Each side wall portion is arranged rearward of the front wall portion 32a. In addition, each side wall portion is arranged on both sides of the front wall portion 32a so as to face generally to the side. In addition, as shown in FIG. 2, the fuel tank 9 is arranged in the lower space surrounded by the above-mentioned front portion of the high stage portion 31 and the front wall portion 32a of the connecting portion 32.

The upper corner 36 is a ridgeline portion that connects the high step 31 and the connecting portion 32. The lower corner 38 is a ridgeline portion that connects the low step 33 and the connecting portion 32. In this example, the ridgeline portion that connects the high step 31 and the front wall portion 32a of the connecting portion 32 at the upper corner 36 is arranged generally along the vehicle width direction (Figure 1). This ridgeline portion is located forward among the ridgelines that make up the upper corner 36. The ridgeline portion that connects the low step 33 and the front wall portion 32a of the connecting portion 32 at the lower corner 38 is arranged generally along the vehicle width direction (Figure 1). This ridgeline portion is located forward among the ridgelines that make up the lower corner 38. Therefore, in the following description, the ridgelines that are located forward as described above at the upper corner 36 and the lower corner 38 are referred to as forward ridgelines.

(Slide rail for seats)
The seat slide rail 7 is a metal member that slides the seat 70 arranged on the high step portion 31 of the floor panel 3 in the front-rear direction. A pair of seat slide rails 7 are attached to the high step portion 31 along the front-rear direction. The seat slide rails 7 are arranged at a predetermined interval in the vehicle width direction. In this example, the rear end portion 7b of each seat slide rail 7 is arranged rearward of the front ridge portion of the upper corner portion 36 of the floor panel 3. In FIG. 2, the seat 70 is virtually shown by a two-dot chain line. The seat 70 is not shown in FIG. 3 and FIG. 4, which will be described later.

(Battery)
The battery 6 is typically rectangular. In this example, the battery 6 is attached to the lower stage 33 of the floor panel 3 by a bracket (not shown) so that one of the six faces of the battery 6 faces forward. The one face of the battery 6 is the front surface 6a. The lower surface 6b of the battery 6 is the surface that is attached to the lower stage 33. The battery 6 is arranged on the lower stage 33 as follows.
The front surface 6 a faces the front wall portion 32 a of the connecting portion 32 of the floor panel 3 .
One side of the front surface 6a is disposed substantially along the vehicle width direction.
The front surface 6a is disposed close to the front ridge of the lower corner 38 of the floor panel 3. Therefore, the distance in the front-rear direction between the rear end 7b of the seat slide rail 7 and the front surface 6a of the battery 6 is relatively small. Here, the distance is shorter than the length of the battery 6.

The height H of the battery 6 is greater than the height h of the step between the high stage 31 and the low stage 33. Therefore, the upper surface of the battery 6 attached to the low stage 33 is located higher than the upper surface of the high stage 31. In addition, the rear end 7b of the seat slide rail 7 is located at the middle position in the vertical direction on the front surface 6a of the battery 6.

(Belt section)
The belt portion 4 is attached to the underside of the floor panel 3 so as to extend in the front-rear direction (see FIG. 1). In this example, the belt portion 4 is located at the center of the underside of the floor panel 3 in the vehicle width direction. More specifically, the belt portion 4 is located roughly along a center line that bisects the underside of the floor panel 3 in the vehicle width direction. Note that the state in which the belt portion 4 is "positioned so that it extends in the front-rear direction" here refers to a state in which the longitudinal direction of the belt portion 4 coincides or substantially coincides with the front-rear direction.

The length of the belt portion 4 is adjusted to satisfy the following two conditions: The length of the belt portion 4 is the size along the longitudinal direction of the belt portion 4. The longitudinal direction of the belt portion 4 is the left-right direction in FIG.
The front end of the band 4 is located near the front ridge of the upper corner 36 of the floor panel 3. More specifically, the front portion of the band 4 is located in front of and behind the front ridge of the upper corner 36 so as to cross over the front ridge of the upper corner 36.
The rear end of the belt portion 4 reaches the rear end of the low step portion 33 of the floor panel 3 .
The width of the belt portion 4 is shorter than the length of the belt portion 4. The width of the belt portion 4 is a size along a direction perpendicular to the longitudinal direction of the belt portion 4. The direction perpendicular to the longitudinal direction of the belt portion 4 is the up-down direction in FIG.
The thickness of the band portion 4 can be appropriately selected.
In this example, the belt portion 4 has a hat-shaped cross section formed by pressing a metal plate. More specifically, the belt portion 4 has a gutter-shaped main body and flange portions extending from both sides of the main body. The flange portions of the belt portion 4 are fixed to the floor panel 3 or the like. The main body of the belt portion 4 is disposed with a small gap from the underside of the floor panel 3 as shown in FIG. 2.

The belt portion 4 has an outer shape that generally follows the outer shape of the portion of the floor panel 3 where the belt portion 4 is attached. The belt portion 4 is arranged so as to extend from the front ridge portion of the high stage portion 31 through the front wall portion 32a of the connecting portion 32 and the front ridge portion of the low stage portion 33 in that order to the rear end portion of the low stage portion 33. The belt portion 4 comprises, from the front, a flange portion 41, a mountain fold portion 46, an inclined portion 42, a valley fold portion 48, and a straight portion 43. The front end portion of the belt portion 4 is the front end portion of the flange portion 41. The rear end portion of the belt portion 4 is the rear end portion of the straight portion 43.

The flange portion 41 is attached to the high step portion 31. In this example, the flange portion 41 is not directly attached to the high step portion 31, but is attached to the bottom surface of the cross member 22 attached to the underside of the high step portion 31. The straight portion 43 is attached to the low step portion 33. The flange portion 41 is arranged so as to be roughly parallel to the front-rear direction and the vehicle width direction and roughly perpendicular to the up-down direction. Most of the straight portion 43 is also arranged so as to be roughly parallel to the front-rear direction and the vehicle width direction and roughly perpendicular to the up-down direction.

In this example, the length of the straight portion 43 is longer than the length of the flange portion 41. The straight portion 43 is also disposed over the entire length of the central portion in the vehicle width direction of the low stage portion 33 of the floor panel 3 (see FIG. 1). Therefore, the straight portion 43 is disposed in the low stage portion 33 so as to span the lower surface 6b of the battery 6. More specifically, the straight portion 43 is disposed over the entire length from the front edge to the rear edge of the lower surface 6b of the battery 6. Such a straight portion 43 functions as a member that increases the rigidity of the portion of the floor panel 3 where the battery 6 is disposed. In other words, the straight portion 43 functions as a reinforcing member that supports the battery 6 from below.

The inclined portion 42 connects the flange portion 41 and the straight portion 43, which are arranged offset in the vertical direction. Therefore, the inclined portion 42 is arranged to intersect in the vertical direction, similar to the connecting portion 32 of the floor panel 3.

The mountain fold 46 is a ridgeline portion that connects the flange portion 41 and the inclined portion 42. The mountain fold 46 is arranged to face the upper corner 36 of the floor panel 3. The mountain fold 46 has a shape that is easily deformed when a predetermined load is applied so that the angle of the inner angle of the mountain fold 46 on the vehicle exterior side becomes smaller. When such deformation occurs, the above arrangement allows the mountain fold 46 to push the upper corner 36 upward from below. The valley fold 48 is a ridgeline portion that connects the straight portion 43 and the inclined portion 42. The valley fold 48 is arranged to face the lower corner 38 of the floor panel 3. The valley fold 48 has a shape that is easily deformed when a predetermined load is applied so that the angle of the inner angle of the valley fold 48 on the vehicle interior side becomes smaller.

In this example, the belt portion 4 is an integral body formed by joining two belt materials by welding or the like. The two belt materials are a front belt material arranged in the front and a rear belt material arranged in the rear. The front belt material constitutes the flange portion 41, the mountain fold portion 46, and most of the inclined portion 42. The rear belt material constitutes the remaining portion of the inclined portion 42, the valley fold portion 48, and the straight portion 43. Since the belt portion 4 is composed of two belt materials, it is easy to change the material, thickness, etc. of each belt material. For example, the material of the rear belt material including the straight portion 43 is a material having a higher rigidity than the front belt material. Or, for example, the thickness of the rear belt material is thicker than the thickness of the front belt material. Such a rear belt material has a higher rigidity than the front belt material. Therefore, the straight portion 43 composed of the rear belt material can further increase the rigidity of the location where the battery 6 is arranged in the low stage portion 33 of the floor panel 3. On the other hand, the front belt material has a relatively low rigidity. Therefore, the mountain folds 46 and other parts made of the front belt material are more likely to deform than the straight sections 43 when subjected to an external load.

In addition, in this example, the belt portion 4 is positioned as follows: In a plan view from the top and bottom, an imaginary line extending the belt portion 4 in the front-to-rear direction does not overlap with each of the seat slide rails 7 attached to the high stage portion 31 of the floor panel 3. In other words, the seat slide rails 7 and the belt portion 4 are positioned offset in the vehicle width direction.

(Rigidity Relationship)
The location where the seat slide rail 7 is attached in the high stage 31 of the floor panel 3 is more rigid than the upper corner 36 and the lower corner 38 of the floor panel 3. The location where the battery 6 is attached in the low stage 33 of the floor panel 3 is more rigid than the upper corner 36 and the lower corner 38. The location where the battery 6 is arranged in the low stage 33 is also highly rigid because the straight portion 43 of the belt portion 4, which has high rigidity, is attached thereto as described above. On the other hand, the upper corner 36 and the lower corner 38 have relatively low rigidity. Therefore, it can be said that the upper corner 36 and the lower corner 38 are more easily deformed than the attachment location of the seat slide rail 7 in the high stage 31 and the attachment location of the battery 6 in the low stage 33 when subjected to an external load. The connecting portion 32 of the floor panel 3 also has a relatively low rigidity. Therefore, it can be said that the connecting portion 32 is also relatively easily deformed. It can be said that the vehicle battery fixing structure 1 of the first embodiment has a portion between the seat slide rail 7 and the battery 6 that is relatively prone to deformation when subjected to an external load.

(Behavior during rear-end collisions)
Hereinafter, the behavior of the battery fixing structure 1 for a vehicle in the first embodiment during a rear-end collision will be described with reference to mainly Fig. 3 and Fig. 4. In Fig. 2 to Fig. 4, a back door disposed behind the rear end of the floor panel 3 is virtually shown by a two-dot chain line.
<Normal>
The normal condition when no rear collision occurs is as described above, see FIG.

<Rear-end collision: initial stage>
As shown in Figure 3, when a rear-end collision occurs and the load associated with the rear-end collision is received, the low step 33 of the floor panel 3 and the straight portion 43 of the band portion 4, which have relatively high rigidity, are relatively displaced forward. This narrows the gap between the low step 33 and the straight portion 43 and the attachment point of the seat slide rail 7 on the high step 31, which has relatively high rigidity. Therefore, the relatively low rigidity member sandwiched between these two high rigidity members is deformed as follows.

The straight portion 43 of the belt portion 4 is displaced relatively from the rear to the front, so that the mountain fold 46 of the belt portion 4 is deformed so that the inner angle of the mountain fold 46 on the vehicle exterior side becomes smaller. With this deformation, the mountain fold 46 is displaced relatively upward. With this displacement, the mountain fold 46 pushes the upper corner 36 of the floor panel 3 relatively upward. Therefore, the upper corner 36 is also deformed so that the inner angle of the upper corner 36 on the vehicle exterior side becomes smaller. With this deformation, the upper corner 36 is also displaced relatively upward. With the above-mentioned displacement of the upper corner 36, the front ridge of the high step 31 connected to the upper corner 36 and the portion nearby are displaced relatively upward. Therefore, the rear end 7b of the seat slide rail 7 attached to the high step 31 is also displaced relatively upward.

In addition, as the straight portion 43 of the belt portion 4 is relatively displaced from the rear toward the front, the lower corner 38 of the floor panel 3 is deformed so that the interior angle of the lower corner 38 on the passenger compartment side becomes smaller. The valley fold 48 of the belt portion 4 is also deformed so that the interior angle of the valley fold 48 on the passenger compartment side becomes smaller.

<Rear-end collision: later stage>
As shown in FIG. 4, in the later stage when the maximum load is applied, the low step 33 of the floor panel 3 and the straight portion 43 of the band 4 are restrained from relatively displacing forward. Therefore, the load is mainly used for the deformation of the upper corner 36 and the mountain fold 46 and the deformation of the lower corner 38 and the valley fold 48. As the upper corner 36 and the mountain fold 46 are relatively displaced upward by the deformation, the connecting portion 32 of the floor panel 3 and the inclined portion 42 of the band 4 connected thereto are also relatively displaced upward. On the other hand, the straight portion 43 is difficult to deform. Therefore, the lower corner 38 and the valley fold 48 try to deform so that the above-mentioned inner angle becomes smaller, and the rear end of the low step 33 and the rear end of the straight portion 43 are relatively displaced downward. As a result of this displacement, the front and upper corner of the battery 6 is relatively displaced backward. In other words, the front and upper corner of the battery 6 is displaced so as to move away from the rear end 7b of the seat slide rail 7. Therefore, a gap is generated between the rear end portion 7 b of the seat slide rail 7 that has been relatively displaced upward as described above and the front surface 6 a of the battery 6 .

(Major Effects)
In the vehicle battery fixing structure 1 of the first embodiment, the rear end 7b of the seat slide rail 7 is arranged to overlap the front surface 6a of the battery 6. However, as described above, the rear end 7b of the seat slide rail 7 does not come into contact with the battery 6 during a rear collision. Such a vehicle battery fixing structure 1 of the first embodiment can prevent the battery 6 from being damaged by the rear end 7b of the seat slide rail 7 during a rear collision.

In addition, in this example, a towing hook 8 is attached to the rear end of the straight portion 43 of the belt 4. Such a belt 4 also functions as a member for attaching the hook 8 to the floor panel 3. As described above, the straight portion 43 has a relatively high rigidity, so it can adequately withstand the load during towing.

The present invention is not limited to these examples, but is defined by the claims, and is intended to include all modifications within the meaning and scope of the claims.
For example, the band portion 4 may be attached to the lower step portion 33 of the floor panel 3 so as to satisfy the following conditions.
In a plan view from the top and bottom, an imaginary line extending the belt portion 4 in the front-rear direction overlaps with the seat slide rail 7 attached to the high stage portion 31 of the floor panel 3. In other words, the seat slide rail 7 and the belt portion 4 are arranged in series in the front-rear direction without being misaligned in the vehicle width direction.

[0023] 1 Vehicle battery fixing structure 2 Vehicle body 21 Side member 22 Cross member 3 Floor panel 31 High step portion 32 Connection portion 33 Low step portion 36 Upper corner portion 38 Lower corner portion 32a Front wall portion 4 Belt portion 41 Flange portion 42 Inclined portion 43 Straight portion 46 Mountain fold portion 48 Valley fold portion 6 Battery 6a Front surface 6b Underside 7 Seat slide rail 7b Rear end portion 70 Seat 8 Hook 9 Fuel tank H, h Height

Claims (1)

Step-shaped floor panels,
a seat slide rail attached to a high stage portion of the floor panel;
a battery attached to a lower stage portion of the floor panel;
A band portion attached to the underside of the floor panel,
The floor panel is
A connecting portion connecting the high stage portion and the low stage portion;
An upper corner portion connecting the high step portion and the connecting portion;
A lower corner portion connecting the lower step portion and the connecting portion,
The high step portion and the low step portion are provided such that a rear end portion of the seat slide rail is disposed at a middle position in a front surface of the battery in a vehicle up-down direction,
The band portion is
The lower end portion is disposed so as to extend in a vehicle front-rear direction from the higher end portion through the connecting portion to the lower end portion,
A mountain fold portion disposed to face the upper corner portion;
A valley fold portion arranged to face the lower corner portion;
A straight portion is disposed on the lower stage portion so as to cross the lower surface of the battery.
A vehicle battery fixing structure.

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