阅读说明：本技术 车辆下部结构 (Vehicle lower structure ) 是由 佐伯浩治 于 2019-12-20 设计创作，主要内容包括：一种车辆下部结构,与以往相比能够抑制电池组的上下振动。电池组的前端固定于地板横梁(240)。地板横梁具备横梁上部(250)及横梁下部(260)。在横梁上部及横梁下部中的一方的前方凸缘(254、264)设置有延长部(258),该延长部从该前方凸缘的前端弯折并且向前下方延伸设置,且前端连接于前地板面板(210)。在延长部安装有加强构件(290)。加强构件具备加强凸缘(292)及肋板(294)。加强凸缘从前方凸缘跨及延长部地弯折并重叠,从而固定于该前方凸缘及该延长部。肋板插入延长部与横梁下部之间的间隙并沿车辆前后方向延伸设置。(A vehicle lower structure is capable of suppressing vertical vibration of a battery pack as compared with the conventional structure. The front end of the battery pack is fixed to a floor cross member (240). The floor cross member is provided with a cross member upper part (250) and a cross member lower part (260). An extension (258) is provided to one of the front flanges (254, 264) of the beam upper portion and the beam lower portion, the extension being bent from the front end of the front flange and extending forward and downward, and the front end being connected to the front floor panel (210). A reinforcing member (290) is attached to the extension portion. The reinforcing member is provided with a reinforcing flange (292) and a rib (294). The reinforcement flange is folded and overlapped from the front flange across the extension portion, and is fixed to the front flange and the extension portion. The rib is inserted into a gap between the extension and the lower portion of the cross member and extends in the front-rear direction of the vehicle.)

1. A vehicle lower section structure having a battery pack disposed on a floor panel, wherein,

the front end of the battery pack is fixed to a cross member as a framework member extending in the vehicle width direction,

the cross member includes a cross member upper portion as an upper member and a cross member lower portion as a lower member,

the upper beam portion includes a hat-shaped upper convex cap portion that opens downward when viewed in the vehicle width direction,

the lower portion of the cross member is provided with a hat-shaped lower convex cap portion which opens upward when viewed from the vehicle width direction,

the front flanges and the rear flanges of the visor parts of the lower and upper hat parts are fixed to each other to form a closed cross-sectional structure,

an extension portion that is bent from a front end of the front flange and extends forward and downward, and a front end of which is connected to a floor panel, is provided on the front flange on one of the lower portion and the upper portion of the cross member,

a reinforcing member is attached to the extension portion,

the reinforcing member includes:

a reinforcement flange that is bent and overlapped from the front flange of the lower beam portion and the upper beam portion so as to straddle the extension portion, and is fixed to the front flange and the extension portion; and

and a rib plate inserted into a gap between the extension portion and the lower portion of the cross member and extending in the vehicle front-rear direction.

2. The vehicle lower structure according to claim 1, wherein,

the plurality of reinforcement members are provided at equal intervals in the vehicle width direction of the cross member.

Technical Field

The present disclosure particularly relates to a lower structure of a vehicle in which a battery pack is disposed on a floor panel.

Background

A hybrid vehicle or an electric vehicle using a rotating electric machine as a drive source is equipped with a battery pack as a power source. For example, in japanese patent application laid-open No. 2016 and 199105, a battery pack is mounted below a rear seat and above a floor panel.

The battery pack as a heavy object is fixed to a frame member of the vehicle. For example, referring to fig. 7, the front end of the battery pack 500 is fixed to a floor cross member 510. The floor cross member 510 is a framework member extending in the vehicle width direction, and includes a cross member upper portion 512 as an upper member and a cross member lower portion 514 as a lower member.

The beam upper portion 512 is formed in a hat shape that is convex upward when viewed in the vehicle width direction, and the beam lower portion 514 is formed in a hat shape that is convex downward when viewed in the vehicle width direction. The front flanges 516 and 517 and the rear flanges 518 and 519 are fixed to each other by welding or the like, thereby forming a closed cross-sectional structure.

One of the beam upper portion 512 and the beam lower portion 514 is provided with an extension portion 520 extending further forward from the front end thereof. In the example of fig. 7, the extension 520 extends from the front flange 516 of the beam upper portion 512. The extension 520 is connected to the front floor panel 530.

For example, the bottom surface of the beam lower portion 514 is set so as to be substantially aligned with the height position of the front floor panel 530. Accordingly, the front floor panel 530 is disposed at a position lower than the front flange 516 of the cross member lower portion 514. The extension 520 connecting both ends is bent from the front end of the front flange 516 and extends forward and downward to the front floor panel 530.

Disclosure of Invention

However, although the closed cross-section structural portion where the beam upper portion 512 and the beam lower portion 514 overlap has high rigidity, the rigidity of the extension portion 520 (which is a single piece) existing only in one of the portions is low. Therefore, when the floor cross member 510 supports the battery pack 500, the extension portion 520 may be deformed.

For example, during traveling on a bad road, the floor cross member 510 and the battery pack 500 vibrate up and down as indicated by broken lines in fig. 7 and 8, where the bending points 522 and 524 of the extension portion 520 serve as deformation starting points.

It is therefore an object of the present disclosure to provide a vehicle lower portion structure that can suppress vertical vibration of a battery pack as compared with the related art.

The present disclosure relates to a vehicle lower portion structure including a battery pack disposed on a floor panel. The front end of the battery pack is fixed to a cross member as a framework member extending in the vehicle width direction. The cross member includes a cross member upper portion as an upper member and a cross member lower portion as a lower member. The beam upper portion includes a hat-shaped upper convex cap portion that opens downward when viewed in the vehicle width direction. The lower portion of the cross member includes a hat-shaped lower convex cap portion that opens upward when viewed in the vehicle width direction. The closed cross-sectional structure is formed by fixing the front flanges and the rear flanges of the visor portion, which are the lower and upper hat portions, to each other. An extension portion is provided on one of the front flanges of the lower portion and the upper portion of the cross member, the extension portion being bent from a front end of the front flange and extending forward and downward, and the front end being connected to the floor panel. A reinforcement member is attached to the extension portion. The reinforcing member includes a reinforcing flange and a rib. The reinforcement flange is bent and overlapped from the front flange of the lower portion of the cross member and the upper portion of the cross member over the extension portion, and is fixed to the front flange and the extension portion. The rib is inserted into a gap between the extension and the lower portion of the cross member and extends in the front-rear direction of the vehicle.

According to the above configuration, the reinforcing flange is overlapped (lined) along the bent shape of the extended portion, and the bent point of the extended portion which may become a deformation starting point is reinforced. Further, the rib is inserted into the gap between the extension and the lower portion of the cross member, so that deformation of the shape of the gap portion is suppressed.

In the above disclosure, a plurality of reinforcing members may be provided at equal intervals in the vehicle width direction of the cross member.

According to the above configuration, the respective reinforcing members are arranged uniformly, whereby the deformation of the extension portion is suppressed uniformly.

According to the present disclosure, vertical vibration of the battery pack can be suppressed compared to the conventional art.

Drawings

Fig. 1 is an exploded perspective view illustrating a lower structure of a vehicle according to the present embodiment.

Fig. 2 is a sectional view a-a of fig. 1.

Fig. 3 is a perspective view of a single body exemplifying the reinforcing member.

Fig. 4 is an enlarged view of the periphery of the reinforcing member of fig. 2.

Fig. 5 is a perspective view of another example of the reinforcing member.

Fig. 6 is a view showing an example in which an extension is provided at a lower portion of a cross member.

Fig. 7 is a diagram illustrating a conventional vehicle lower portion structure, and is a diagram illustrating vertical vibration of the battery pack.

Fig. 8 is a diagram illustrating a conventional vehicle lower portion structure, and is another diagram illustrating vertical vibration of the battery pack.

Detailed Description

Fig. 1 illustrates an example of a vehicle lower portion structure according to the present embodiment. In addition, a cross-sectional view a-a of fig. 1 is illustrated in fig. 2. In fig. 1 to 6, the vehicle longitudinal direction is indicated by an axis denoted by symbol FR, the vehicle width direction is indicated by an axis denoted by symbol RW, and the vehicle vertical direction is indicated by an axis denoted by symbol UP. The vehicle front-rear axis FR takes the vehicle front direction as the positive direction. The vehicle width axis RW has the right width direction as the positive direction. The vehicle UP-down axis UP is a forward direction. The three axes are orthogonal to each other.

The vehicle lower portion structure according to the present embodiment is mounted on, for example, a hybrid vehicle or an electric vehicle that uses a rotating electric machine as a drive source.

The vehicle lower portion structure according to the present embodiment includes a battery pack 100. The battery pack 100 is disposed in the battery housing space 200 formed below the rear seat 350 and above the rear floor panel 220.

Referring to fig. 1 and 2, battery housing space 200 is a portion of rear floor panel 220, and is provided so as to be sandwiched between floor cross member 240 and fastening plate 230 in the vehicle front-rear direction.

Referring to fig. 2, the front end of the rear floor panel 220 is joined to the rear end of the floor cross member 240. In fig. 2 and the like, the welding points are indicated by X marks. The rear floor panel 220 is a floor behind the vehicle, and a kick portion 222 that is inclined upward toward the rear is provided around the rear wheel 300 in order to secure a space for a suspension mechanism of the rear wheel 300. The space between the kick portion 222 and the floor cross member 240 becomes the battery housing space 200.

Referring to fig. 1, battery pack 100 includes battery module 110, cooling fans 120A and 120B, and control unit 130, and these are housed in case 150 (see fig. 2). Battery module 110 is disposed closer to rear wheel 300 than cooling fans 120A and 120B and control unit 130.

Cooling fans 120A and 120B send cooling air into battery module 110. For example, the cooling fans 120A and 120B are provided on both sides in the vehicle width direction with the control unit 130 interposed therebetween. The cooling fans 120A and 120B are constituted by sirocco fans, for example.

Further, intake ports 122 are provided at vehicle width direction end portions of cooling fans 120A and 120B. Air in the vehicle interior is sucked through the suction port 122 and sent as cooling air to the battery module 110.

The control unit 130 manages the power of the battery module 110. The control unit 130 is constituted by a computer, for example, and may be a so-called battery ECU (electronic control unit). The control unit 130 performs, for example, charge/discharge management and temperature management of the battery module 110.

The battery module 110 includes a stack in which a plurality of unit cells, also referred to as single cells, are stacked. For example, the single battery may be a lithium ion secondary battery or a nickel metal hydride secondary battery, or may be an all-solid-state battery.

The battery pack 100 is detachably fastened to a vehicle cabin floor by bolts, nuts, or the like. Specifically, referring to fig. 2, the front end of battery pack 100, i.e., front end flange 152A of case cover 152 and front end flange 154A of case tray 154, is fastened and fixed to beam upper portion 250 of floor beam 240. The rear end flange 152B of the case cover 152 and the rear end flange 154B of the case tray 154 are fastened and fixed to the fastening plate 230. Further, a substantially central portion in the vehicle front-rear direction of the case tray 154 is fastened and fixed to a battery cross portion (cross)270 as a framework member extending in the vehicle width direction.

Referring to fig. 2, a fastening plate 230 is provided at the bent-up portion 222 that is inclined in a side view. The fastening plate 230 is formed in a stepped shape, for example, so as to provide a horizontal fastening surface around the kick portion 222. The rear end flange 152B of the case cover 152 and the rear end flange 154B of the case tray 154 of the battery pack 100 are detachably fastened to the stepped horizontal portion by bolts, nuts, or the like. The front end of the fastening plate 230 is coupled to the bent-up portion 222. Further, the rear end of the fastening plate 230 is joined to a rear cross portion 280, which is a framework member extending in the vehicle width direction.

Referring to fig. 1, a pair of sills 310, which are framework members extending in the vehicle longitudinal direction, are provided at both ends (both side ends) in the vehicle width direction of the vehicle interior. Both ends of floor cross member 240 in the vehicle width direction are fixed to the pair of rocker panels 310, 310.

Referring to fig. 2 and 4, the floor cross member 240 is a framework member including a cross member upper portion 250 as an upper member and a cross member lower portion 260 as a lower member. The beam lower portion 260 includes a lower convex cap portion 262. The lower convex cap 262 has a cap shape that opens upward, and includes a front flange 264 and a rear flange 266 as the visor portion.

The beam upper part 250 includes an upper convex cap part 252 and an extension part 258. The upper hat portion 252 has a hat shape that opens downward when viewed in the vehicle width direction, and includes a front flange 254 and a rear flange 256 as a visor portion thereof.

The front flange 254 of the beam upper portion 250 and the front flange 264 of the beam lower portion 260 overlap and are joined to each other, and the rear flange 256 of the beam upper portion 250 and the rear flange 266 of the beam lower portion 260 overlap and are joined to each other, thereby forming a closed cross-sectional structure based on the upper and lower hat portions 252, 262.

The front end flange 152A of the case cover 152 and the front end flange 154A of the case tray 154 of the battery pack 100 are detachably fastened to the top portion 252A of the upper convex cap portion 252 of the beam upper portion 250 having the closed cross-sectional structure by bolts, nuts, or the like.

An extension 258 is provided further forward from the front end of the front flange 254 of the beam upper portion 250. Extension 258 is a portion that connects floor cross member 240 to front floor panel 210 in front of it.

Extension 258 may be provided to extend from one of beam upper portion 250 and beam lower portion 260. For example, although the extension 258 is provided from the front end of the front flange 254 of the beam upper portion 250 in fig. 4, the extension 258 may be provided from the front end of the front flange 264 of the beam lower portion 260 as shown in fig. 6.

The configuration and the like will be described below with reference to the form of fig. 4, that is, with reference to an example in which extension 258 is provided in beam upper portion 250, but the description is also applicable to a case in which extension 258 is provided in beam lower portion 260.

As illustrated in fig. 4, the front flange 254 is offset from the front floor panel 210 in the vehicle height direction, and the front flange 254 is disposed at a high position with respect to the front floor panel 210. Therefore, the extending portions 258 connecting both sides are bent from the front ends of the front flanges 254 and extend forward and downward, and the front ends thereof are connected to the front floor panel 210.

As illustrated in fig. 4, extension 258 has a bent structure including a plurality of bending points 258A, 258B. Further, the bending points 258A and 258B extend (independently) without overlapping the beam lower portion 260. Therefore, the bending points 258A and 258B have lower rigidity than the peripheral structures thereof, and when the battery pack 100 is biased in the vertical direction, the bending points 258A and 258B may serve as deformation starting points and the battery pack 100 may vibrate vertically.

Therefore, in the vehicle lower portion structure according to the present embodiment, reinforcement member 290 is provided in extension portion 258. The reinforcing member 290 is also called a "wall portion (bulk)" and includes a reinforcing flange 292, a rib 294, and a substrate 297 (see fig. 3). The reinforcing member is obtained by press molding a metal material such as aluminum.

A perspective view of the reinforcing member 290 is illustrated in fig. 3. For example, in the reinforcing member 290, a pair of ribs 294, 294 are provided in the vehicle width direction, and both lower ends are connected to the substrate 297.

The base plate 297 has a front flange 292A formed on the front side thereof and a rear flange 292B formed on the rear side thereof. The front end flange 292A is joined to the front floor panel 210 together with the front end flange 258C of the extension 258 (see fig. 4). The rear end flange 292B is joined to the cap bottom 262A of the beam lower portion 260.

The reinforcement flange 292 is bent from the front flange 254 of the beam upper portion 250 over the front end flange 258C of the extension 258, overlaps the front flange 254 and the extension 258, and is fixed to the front flange 254 and the extension 258.

The reinforcing flange 292 is bent from the front flange 254 of the beam upper portion 250 and the front flange 264 of the beam lower portion 260 further rearward along the shape of the lower boss portion 262 of the beam lower portion 260 and is fixed to the lower boss portion 262 so as to overlap (line).

As illustrated in fig. 4, the reinforcement flange 292 is joined to the aforementioned members at five points, namely, the front end flange 258C, the extension side 258D, the front flange 264, the cap side 262B, and the cap bottom 262A. The bend points 258A, 258B of extension 258 are reinforced by reinforcing flange 292. That is, deformation starting from the bending points 258A and 258B is suppressed.

Referring to fig. 3, a relief portion 295 is formed at the corner portion of the reinforcing flange 292 corresponding to the bending points 258A and 258B. This is to avoid deformation of the metal near the corner during press forming (bending). However, from the viewpoint of reinforcing the bending points 258A and 258B, the amount of metal removed in the escape portion 295 is preferably as small as possible, and the minimum amount of metal removed is sufficient to prevent the above-described distortion.

Referring to fig. 4, rib 294 is provided to extend in the vehicle front-rear direction and is inserted into the gap between extension 258 and beam lower portion 260. Specifically, rib 294 is formed in the same shape as a trapezoidal gap defined by extension portion 258D, front flange 254, and cap portion 262B, and is inserted into the gap.

Thus, when a load such as deformation of the gap is applied to the extension portion 258 and the beam lower portion 260, the rib 294 is supported against the load, and deformation of the shape of the gap is suppressed.

In this manner, in the present embodiment, the reinforcement flange 292 is lined with the extension portion 258, the rib 294 is inserted into the gap between the extension portion 258 and the beam lower portion 260, and the front floor panel 210 and the cap bottom portion 262A are coupled by the reinforcement member 290. With such a configuration, deformation starting from the bending point 258A and deformation around the reinforcing member 290 are suppressed. As a result, the amplitude of the vertical vibration of the assembled battery 100 is suppressed as compared with the conventional vehicle lower portion structure in which no reinforcing member is provided.

Referring to fig. 1, as indicated by broken lines in the floor cross member 240, a plurality of reinforcing members 290 are provided at equal intervals in the vehicle width direction of the floor cross member 240. By arranging reinforcing members 290 uniformly, deformation of extension 258 is suppressed uniformly.

< Another example of reinforcing Member >

Fig. 5 shows another example of the reinforcing member 290. Although the pair of ribs 294 and the pair of reinforcing flanges 292 are provided in fig. 3, only one rib 294 and one reinforcing flange 292 are provided in the example of fig. 5. With this configuration, since the reinforcing flange 292 is lined in the extension portion 258 similarly, the rib 294 is inserted into the gap between the extension portion 258 and the beam lower portion 260 similarly, and the front floor panel 210 and the cap bottom portion 262A are connected by the reinforcing member 290 similarly, deformation starting from the bending points 258A and 258B and deformation around the reinforcing member 290 are suppressed.

< Another example of the extension section >

In fig. 4, an extension 258 is provided from the front flange 254 of the beam upper portion 250, but the vehicle lower portion structure according to the present embodiment is not limited to this form. In short, the extension 258 may be provided from one of the front flanges 254 and 264 of the beam upper portion 250 and the beam lower portion 260, and the extension 258 may be provided from the front flange 264 of the beam lower portion 260 as illustrated in fig. 6, for example.

As illustrated in fig. 6, the front flange 264 is disposed at a high position with respect to the front floor panel 210. Extending portions 258 for connecting both sides are bent from the front ends of front flanges 264 and extend forward and downward, and the front ends thereof are connected to front floor panel 210.

Extension 258 is reinforced by reinforcing member 290 as in figure 4. Reinforcing flange 292 is bent from front flange 264 of beam lower portion 260 over front end flange 258C of extension portion 258, overlaps (is lined) front flange 264 and extension portion 258, and is fixed to front flange 264 and extension portion 258.

Rib 294 of reinforcement member 290 extends in the vehicle front-rear direction and is inserted into the gap between extension 258 and beam lower 260. The reinforcing structure such as the reinforcing flange 292 and the rib 294 suppresses deformation starting from the bending points 258A and 258B and deformation around the reinforcing member 290. As a result, the amplitude of the vertical vibration of the assembled battery 100 is suppressed as compared with the conventional vehicle lower portion structure in which no reinforcing member is provided.

The present disclosure is not limited to the above-described embodiments, and includes all changes and modifications without departing from the technical scope or spirit defined by the scope of the claims.