JPH07156831A - Floor structure of electric vehicle - Google Patents

Abstract

PURPOSE:To prevent an outer wall from being fallen to the inner side of a room by transmitting the input load to be applied to a side sill in the side crush of a vehicle from an outrigger to a side member, and also transmitting the load to an outer wall of a battery frame from an extended part of the outrigger. CONSTITUTION:A side member 3 to form a closed section structure part is mounted on the lower surface of a side part of a floor panel 1, and a side sill 9 is mounted on a side edge of the floor panel 1. The side sill 9 is connected to the side member 3 by an outrigger 8. In addition, a battery frame 10 where a plurality of batteries 17 are arranged is mounted on the side member 3 in an attachable/detachable manner. In this floor structure, an extended part 8A extending downward is formed to the lower part of the outrigger 8. The extended part 8A is arranged opposite to the outer wall of the battery frame 10. This constitution transmits the input load to be applied to the side sill 9 in the side crush of a vehicle also to the battery frame 10.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a floor structure of an electric vehicle.

[0002]

2. Description of the Related Art An electric vehicle requires a large number of batteries as a drive source. For example, as shown in Japanese Unexamined Patent Publication No. 52-16733, this battery has a plurality of batteries under the vehicle body floor. Some are attached as a pack (here, the motor and the like are also integrated). This type of floor structure is advantageous in that it is not necessary to dispose a battery that undergoes a chemical change inside the vehicle interior, and the battery can be mounted more easily than when it is mounted inside the vehicle compartment.

[0003]

However, in the above conventional floor structure of an electric vehicle, the center of gravity of the battery pack is below the vehicle body floor because the battery pack is below the vehicle body floor. At the time of collision, the inertial force of the battery pack is generated at a position offset downward with respect to the input load applied from the barrier to the side sill on the side of the main body floor.

Therefore, a moment is generated between the battery pack and the vehicle body floor, the battery pack is likely to be displaced outward, and this displacement prevents the internal battery from colliding with the side wall of the battery pack and being damaged. There is a problem in that the strength and rigidity must be increased, and the weight of the vehicle body is increased.

Therefore, the present invention provides a floor structure of an electric vehicle capable of sufficiently protecting the battery and sufficiently absorbing energy in the case of a side collision of a vehicle without causing a significant increase in vehicle body weight. .

[0006]

Means for Solving the Problems A side member forming a closed cross-section structure portion is attached to a lower surface of a side portion of a floor panel, a side sill is attached to a side edge of the floor panel, and the side sill and the side member are connected by an outrigger. In the floor structure of an electric vehicle in which a battery frame in which a plurality of batteries are arranged is detachably attached to a side member, an extension portion extending downward is formed at a lower portion of the outrigger. The portion is disposed adjacent to the outer wall of the battery frame. Further, a bracket is attached to a corner portion formed by the inner side surface of the outer wall of the battery frame and the upper surface of a lateral member provided in the battery frame along the vehicle width direction,
The mounting height of this bracket to the outer wall of the battery frame may be set to overlap the position of the extension of the outrigger.

[0007]

When a load is input to the side sill during a side collision of the vehicle, the input load acts on the side member via the outrigger and also acts on the battery frame via the extension portion of the outrigger.

Therefore, the moment resulting from the inertial force of the battery frame to the outside of the vehicle compartment immediately after the collision is weakened by the input load acting on the battery frame from the extension portion of the outrigger, and the displacement of the battery frame, especially the outer wall Prevents the battery from being damaged by preventing it from falling inward.

When a bracket is provided at the corner portion between the lateral member of the battery frame and the outer wall,
It is possible to reliably prevent the outer wall of the battery frame from collapsing at the time of a side collision of the vehicle.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings.

In FIG. 3, reference numeral 1 denotes a floor panel, and a floor member 2 is joined to the back side of the floor panel 1. The floor member 2 is provided on both sides with a hat-shaped cross-sectional side member 3 provided along the front-rear direction, and three cross-members 4 having a hat-shaped cross-section along the vehicle width direction, which are mounted between the side members 3. , 6, specifically, a cross member 4 on the front side of the passenger compartment, a cross member 5 on the rear side of the passenger compartment, and a cross member 3 adjacent to the cross member 4. An L-shaped sub-member 7 having a hat-shaped cross section is provided between the cross member 5 and the side member 3.

A side sill 9 is attached to the outer side wall of the side member 3 at a predetermined interval via four outriggers 8 having a hat-shaped cross section.

The floor panel 1 is joined to the floor member 2 thus constructed, and a closed cross-section structure portion is formed in the side member 3, the cross members 4, 5, 6, the sub member 7, and the outrigger 8. .

On the other hand, in FIG. 3, reference numeral 10 denotes a battery frame, which is detachably attached to the side member 3 and the cross members 4 and 6 as shown in FIG.

As shown in FIG. 3, the battery frame 10 is provided with side frames 11 on both sides as outer walls along the front-rear direction, and a front frame 12 and a rear frame 13 are provided on the front and rear parts, respectively, along the vehicle width direction. And
A sub-frame 14 connected to the rear frame 13 is provided at the rear end of each side frame 11.

A lateral frame 15 as a lateral member is provided between the side frames 11 in the vehicle width direction. The lateral frame 15 is vertically spaced between the lateral frames 15 and between the rear frame 13 and the lateral frame 15. A frame 16 is provided. The horizontal frames 15 and the vertical frames 16 arranged in a lattice form compartments 18 for a plurality of batteries 17, and two batteries 17 are fixed to each compartment 18 by a mounting bracket 19. It has become.

The side frame 11, the front frame 12, and the rear frame 13 are larger in height than the horizontal frame 15 and the vertical frame 16.

Here, as shown in FIG.
Is formed as an extending portion 8A whose lower portion extends downward and is adjacent to the outer wall of the side frame 11 of the battery frame 10.

Specifically, as shown in FIG. 2, the outrigger 8 is composed of a front side wall 8a, a rear side wall 8b, a bottom wall 8c inclined toward the vehicle interior side, and an inner side wall 8d, and an upper edge flange 8e of the inner side wall 8d. On the lower surface of the lower wall of the side member 3, the front and rear side walls 8
The upper edge flange 8e of a and 8b is joined to the back surface of the floor panel 1. Therefore, the inner wall 8d of the outrigger 8 is adjacent to and faces the outer surface of the side frame 11 of the battery frame 10. In addition, F
R indicates the front side.

A bracket 20 having a U-shaped cross section is attached by welding to a corner portion between an upper surface of an end portion of the lateral frame 15 of the battery frame 10 and an inner side surface of the side frame 11. The bracket 20 is formed such that the upper wall 20a rises toward the outer side, and the mounting height of the bracket 20 to the side frame 1 is such that the bracket 20 overlaps the extending portion 8A of the outrigger 8 in the vertical direction. Is set to.

In FIG. 2, reference numeral 21 is a mounting hole for the battery frame 10 and the side member 3, and 22 is a mounting hole for the mounting bracket 19 for mounting on the battery 17.

According to the structure of the above embodiment, when the barrier B collides with the side surface of the side sill 9 shown in FIG. 1 during a side collision of the vehicle, the input load applied to the side sill 9 is transmitted to the side member 3 via the outrigger 8. At the same time, it is directly transmitted to the side frame 11 of the battery frame 10 via the extending portion 8A of the outrigger 8.

Here, the moment M caused by the inertial force A of the battery frame 10 to the outside of the vehicle compartment generated immediately after the collision.
Is weakened by the input load B acting on the side frame 11 of the battery frame 10 via the extending portion 8A.

As a result, the force for tilting the side frame 11 of the battery frame 10 is minimized,
In addition, the upper surface of the end portion of the horizontal frame 15 and the side frame 11
The tilt of the side frame 11 is restricted by the bracket 20 attached to the corner portion formed by the inner surface of the outer wall of the battery, and the input load B is supported by the lateral frame 15 in the width direction of the battery frame 10.

At this time, since the extending portion 8A of the outrigger 8 and the bracket 20 are provided at the vertically overlapping position, the input load acting on the extending portion 8A of the outrigger 8 is not lost and the bracket 20 is not lost. Be transmitted to.

That is, for example, if the extension portion 8A is not provided on the outrigger 8, the input load X acts on the side member 3 from the outrigger 8 at the beginning of the collision as shown in FIG. Inertial force Y works. Therefore, the moment M acts on the Z portion of the outer wall of the side frame 11 in FIG. Therefore,
The side frame 1 of the battery frame 10 as shown in FIG.
Since the lower portion of the side frame 11 is displaced outward with the upper portion of 1 as an axis, the upper portion of the side frame 11 falls toward the vehicle interior side, and the corner portion of the battery 17 on the outermost side is the side frame 1.
It will make a collision with 1. Therefore, a force is applied from the extending portion 8A of the outrigger 8 to the portion Z of the outer wall of the side frame 11 to cancel the moment M.

Therefore, the outrigger 8 and the bracket 20 prevent the side frame 11 of the battery frame 10 from falling toward the passenger compartment side, and therefore the side frame 11 tilts to collide with the battery 17 and damage the battery 17. There is no. Further, it is not necessary to increase the rigidity or reinforce the side frame 11 itself of the battery frame 10, and the weight of the vehicle body is not increased.

In this way, at the time of a side collision of the vehicle, the side sills 9 and the outriggers 8 and the like are crushed and deformed to absorb the impact energy while preventing the battery 17 from being damaged due to the side frame 11 of the battery frame 11 falling. is there.

The present invention is not limited to the above embodiment, and the side frame 11 can be sufficiently prevented from falling down even if the bracket 20 is not provided.

[0030]

As described above, according to the invention described in claim 1, not only the input load to the side sill acting at the time of a side collision of the vehicle is transmitted from the outrigger to the side member, but also by the extension portion of the outrigger. It can be transmitted to the outer wall of the battery frame. Therefore, it is possible to weaken the moment caused by the inertial force of the battery frame which is generated immediately after the collision toward the outside of the vehicle compartment, and as a result, the tilting of the outer wall of the battery frame to the inside of the vehicle compartment, which is a major factor, is caused. Can be prevented.

According to the invention described in claim 2,
The bracket can surely prevent the outer wall of the battery frame from inclining to the vehicle interior side, and the bracket is arranged so as to vertically overlap the extension portion of the outrigger, so that the extension of the outrigger is prevented. The input load acting from the outlet can be transmitted to the bracket without loss.

[Brief description of drawings]

FIG. 1 is a sectional view of an essential part taken along the line AA of FIG. 3 of an embodiment of the present invention.

FIG. 2 is an exploded perspective view of the relevant part.

FIG. 3 is an exploded perspective view of the same.

FIG. 4 is a cross-sectional view corresponding to FIG. 1 when the outrigger has no extending portion.

FIG. 5 is an explanatory view of a crushed state when the outrigger has no extending portion.

[Explanation of symbols]

 1 ... Floor panel 3 ... Side member 8 ... Outrigger 8A ... Extension part 9 ... Side sill 10 ... Battery frame 11 ... Side frame (outer wall) 15 ... Horizontal floor panel (lateral member) 20 ... Bracket

Claims (2)

[Claims] 1. A side member forming a closed cross-section structure portion is attached to a lower surface of a side portion of a floor panel, a side sill is attached to a side edge of the floor panel, and the side sill and the side member are connected by an outrigger. In a floor structure of an electric vehicle to which a battery frame in which a plurality of batteries are arranged is detachably attached, an extension portion that extends downward is formed in a lower portion of the outrigger, and the extension portion is the battery frame. The floor structure of an electric vehicle, which is arranged adjacent to the outer wall of the vehicle. 2. A bracket is attached to a corner portion formed by an inner surface of an outer wall of the battery frame and an upper surface of a lateral member provided along the vehicle width direction on the battery frame, and a battery of the bracket is attached. 2. The floor structure for an electric vehicle according to claim 1, wherein the mounting height of the frame to the outer wall is set to overlap the position of the extension of the outrigger.