JP4479299B2 - Lower body structure - Google Patents

Description

  The present invention relates to a lower body structure in a vehicle such as an automobile, and more particularly to a structure under a floor in a fuel cell vehicle.

Conventionally, under the floor of a vehicle such as a fuel cell vehicle or an electric vehicle, a side member extending in the vehicle front-rear direction and a plurality of cross members for connecting the side members to the left and right are provided. A unit, a fuel cell stack, and the like are disposed under the floor under the motor room or the seat (for example, see Patent Documents 1 and 2).
Japanese Patent Laid-Open No. 2003-123779 JP 2003-17107 A

 However, the conventional example has a problem in that twisting deformation is likely to occur at the boundary between the motor room and the passenger compartment where a heavy object such as a drive motor is disposed, during traveling of the vehicle.

  Accordingly, an object of the present invention is to provide a vehicle body lower structure that can maintain a high torsional rigidity of a vehicle body even in a vehicle in which a heavy object is mounted under the floor.

To achieve the above object, a vehicle body lower structure according to the present invention, the vehicle front, is disposed a drive chamber having a driving means for driving the vehicle, to the rear of the drive chamber, equipped with a heavy under the floor A vehicle body lower structure in which a guard bar is extended along the vehicle width direction at the front end under the floor of the passenger room, and extends from the drive chamber along the vehicle longitudinal direction on both left and right sides of the vehicle. A pair of left and right side members are extended over the passenger compartment, and both end portions of the guard bar are attached to the left and right side members, so that the side members are bridged by the guard bar, a suspension member is provided in front of the guard bar, The front end of the vehicle is formed along the vehicle width direction, the mounting portion extends from the guard bar toward the rear of the vehicle, and the mounting portion is fixed to the front end of the heavy object. When viewed from above, the mounting portion is orthogonal to both the guard bar and the front end portion of the heavy object, and the suspension member and the vehicle body are fixed to the rear end portion of the suspension member and both end portions of the guard bar. It is characterized by being connected via a mounting bracket .

 According to the vehicle body lower structure according to the present invention, since the guard bar is arranged along the vehicle width direction at the boundary between the drive chamber and the passenger compartment, the torsional rigidity of the vehicle body during vehicle travel can be improved. That is, driving means that are heavy items such as a drive motor and a high-power unit are arranged in the driving chamber, and heavy items such as a fuel cell unit are mounted under the floor of the passenger compartment. The boundary between the driving chamber and the passenger compartment is slightly less rigid than the driving chamber and the passenger compartment. Therefore, if a guard bar is provided at the boundary between the driving chamber and the passenger compartment, the torsional rigidity of the vehicle can be increased. In addition, according to this invention, it can be set as a fuel cell vehicle using the vehicle body structure of general vehicles, such as a gasoline vehicle, and can aim at cost reduction.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

 FIG. 1 is a bottom view of a front portion of a vehicle that employs a vehicle body lower structure according to an embodiment of the present invention as viewed from below.

 Schematically, a motor room 1 which is a driving chamber is provided on the front side of the vehicle (left side in FIG. 1), and a passenger compartment (on the right side in FIG. 1) of the motor room 1 is provided on the vehicle rear side. (Cabin) 3 is provided.

 Front tires 5 that are rotatably supported are disposed on the left and right sides of the motor room 1, and side members 7 that extend along the vehicle front-rear direction are disposed on the inner sides of the front tires 5 in the vehicle width direction. It is provided in a pair. The side member 7 extends from the front end of the motor room 1 to the passenger compartment 3, and an outrigger portion 7 a is formed at the front end portion of the passenger compartment 3 so as to branch outward in the vehicle width direction.

 Further, between the left and right side members 7 in the motor room 1, a high-power unit 9 and a suspension member 11 which are power consuming devices are disposed, and the high-power unit 9 is disposed on the front side of the vehicle. A suspension member 11 is disposed rearward. In the motor room 1, a drive motor and a high-power unit 9 (not shown) constituting drive means for driving the vehicle are disposed.

 On the other hand, on the passenger compartment 3 side, a mounting frame 15 for mounting a heavy fuel cell stack (power generation device) on the vehicle body is disposed. The center side of the front end portion 15a of the mounting frame 15 is formed in a substantially linear shape along the vehicle width direction.

 A guard bar 17 extends along the vehicle width direction at the boundary between the passenger compartment 3 and the motor room 1, specifically, at the front end of the passenger compartment 3 below the floor.

 As shown in FIG. 2, which is a cross-sectional view taken along the line AA of FIG. 1, the guard bar 17 extends substantially horizontally at the center in the vehicle width direction when viewed from the vehicle front-rear direction, and the left and right sides are oblique. The two ends 17a and 17a are bent and extended upward, and are bolted to the side member 7 via a gusset 19 which is a mounting bracket. The guard bar 17 bridges the left and right side members 7.

  FIG. 3 is a side view of the vicinity of the guard bar 17 as viewed from the side of the vehicle according to the embodiment of the present invention.

  A fuel cell stack 21 is mounted on a mounting frame 15 disposed under the floor on the passenger compartment 3 side, and a mounting portion 23 extends substantially horizontally from the guard bar 17 toward the rear of the vehicle. Yes. The mounting portion 23 has a rear end 23 a that is thin in the vertical direction, and the rear end 23 a is bolted to the lower portion of the mounting frame 15. The ground height Hg below the guard bar 17 is set to the same height as the ground height Hf of the mounting frame 15. The ground height Hg of the guard bar 17 may be set higher than the ground height Hf of the mounting frame 15. 1 to 3, the wire harness 25 is connected to the high voltage unit 9 from the fuel cell stack 21 through the guard bar 17 and the suspension member 11.

 FIG. 4 is an enlarged view showing the vicinity of the left end portion of the guard bar of FIG.

 As shown in FIG. 4, the gusset 19 whose outer shape is formed in a substantially triangular shape is provided with three attachment points P, Q, and R. Of these attachment points, the attachment point P is disposed on the outermost side in the vehicle width direction of the gusset 19, and both end portions of the guard bar 17 are bolted to the side member 7 together with the attachment point P. Further, the attachment point Q on the center side in the vehicle width direction is bolted to the side member 7, and the attachment point R is bolted to the rear end portion of the suspension member 11.

 FIG. 5 is an enlarged view of the periphery of the entire guard bar of FIG.

 From the rear surface of the guard bar 17, three attachment portions 23 are extended toward the rear of the vehicle at a predetermined interval in the vehicle width direction. These three attachment portions 23 are all arranged so as to be orthogonal to the guard bar 17, and the attachment portion 23 on the center side is also arranged so as to be orthogonal to the front end portion 15 a of the mounting frame 15.

 Hereinafter, a procedure for transmitting a collision load at the time of a vehicle collision will be briefly described.

 First, as shown in FIG. 1, when a collision load is input to the suspension member 11, it is transmitted from the rear end portion of the suspension member 11 to both end portions 17 a of the guard bar 17 through the gusset 19. However, since the guard bar 17 is connected to the mounting frame 15 via the mounting portion 23 and the mounting frame 15 is provided with the fuel cell stack 21, the guard bar 17 efficiently moves the suspension member 11 and the like backward. Can be suppressed.

 According to the embodiment of the present invention, the following effects are obtained.

 First, a pair of left and right side members 7 are extended from the motor room 1 to the passenger compartment 3 along the vehicle front-rear direction on both left and right sides of the vehicle, and both ends of the guard bar 17 are connected to the left and right side members 7, 7. By attaching, the side members 7 and 7 are bridged by the guard bar 17, so that the torsional rigidity of the vehicle body can be improved efficiently. Further, since both end portions 17a and 17a of the guard bar 17 are fixed to the highly rigid side member 7, the torsional rigidity in the rolling direction of the vehicle body can be particularly enhanced. In the above embodiment, both end portions 17a of the guard bar 17 are fixed to the side member 7 via the gusset 19. However, the present invention is not limited to this, and both end portions 17a of the guard bar 17 are directly fixed to the side member 7. You may do it.

  Further, since the motor room 1 includes a heavy drive motor (not shown), a high-power unit 9 and a suspension member 11, the motor room 1 itself is a highly rigid space. On the other hand, since the heavy fuel cell stack 21 is mounted under the floor of the passenger compartment 3, the passenger compartment side is also set to have high rigidity. The boundary portion between the high-rigidity motor room 1 and the passenger compartment 3 tends to be low in rigidity, particularly torsional rigidity. However, according to the present embodiment, the guard bar 17 is disposed at this boundary portion, so that the fuel Even in a battery vehicle or the like, the torsional rigidity of the entire vehicle can be improved.

 Further, the heavy objects are a fuel cell stack 21 and a mounting frame 15 which are power generation devices. In the motor room 1, a high-power unit 9 connected to the fuel cell stack 21 via a wire harness 25 is arranged. Since the wire harness 25 is arranged above the guard bar 17, the wire harness 25 can be reliably protected from obstacles on the road surface while the vehicle is traveling.

  Since the guard bar 17 is fixed to the mounting frame 15 on which the fuel cell stack 21 is mounted, the mounting strength of the guard bar 17 is further increased, and the wire harness 25 can be more reliably protected.

  Further, the suspension member 11 is provided in front of the guard bar 17, the front end portion 15a of the mounting frame 15 is formed along the vehicle width direction, and an attachment portion 23 is extended from the guard bar 17 toward the rear of the vehicle. By fixing the portion 23 to the front end portion 15a, the mounting member 23 is disposed perpendicular to the front end portion 15a of the mounting frame 15 when viewed from the vehicle vertical direction, so that the suspension member 11 can be viewed from the front of the vehicle. When a collision load is input to the guard bar 17, the guard bar 17 can reliably receive the collision load by the fuel cell stack 21 and the mounting frame 15, and the rearward movement of the suspension member 11 can be suppressed to a minimum. Therefore, it is possible to suitably prevent each component in the motor room 1 from entering the passenger compartment 3 at the time of a vehicle collision.

 Further, since the rear end portion of the suspension member 11 and both end portions 17a of the guard bar 17 are connected via the gusset 19, the collision load input to the suspension member 11 due to the vehicle collision is prevented via the gusset 19. 17, the amount of rearward movement of the suspension member 11 can be further suppressed. Further, since the suspension member 11 is not directly attached to the guard bar 17, even when the suspension member 11 swings up, down, left and right when the vehicle travels, the swing is not directly transmitted to the guide bar, so that the torsion of the vehicle body is efficiently performed. Can be prevented. Further, since the gusset 19 is provided in a normal vehicle, the increase in the number of parts can be minimized without changing the existing vehicle body structure.

 And since the attachment part 23 of the said guard bar 17 is arrange | positioned substantially horizontal toward the vehicle rear, when it sees from the vehicle side, without changing the direction of the collision load input into the guard bar 17 as it is. This can be transmitted directly to the mounting frame 15, and the amount of rearward movement of the suspension member 11 can be further suppressed.

 Further, since the lower portion of the guard bar 17 is disposed at a height higher than the lower surface of the mounting frame 15, air resistance during vehicle travel can be reduced.

1 is a bottom view of a vehicle that employs a lower body structure according to an embodiment of the present invention. It is sectional drawing by the AA line of FIG. It is the side view which looked at the guard bar vicinity part by embodiment of this invention from the vehicle side. It is an enlarged view which shows the left end part vicinity of the guard bar of FIG. It is an enlarged view of the peripheral part of the whole guard bar of FIG.

Explanation of symbols

1 ... Motor room (drive room)
3 ... Crew compartment (cabin)
7 ... Side member 9 ... High-power unit
11 ... Suspension member 15 ... Mounting frame (heavy)
15a ... front end 17 ... guard bar 17a ... both ends 19 ... gusset (mounting bracket)
21 ... Fuel cell stack (power generator, heavy object)
23 ... Mounting part 25 ... Wire harness

Claims (5)

A driving chamber having driving means for running the vehicle is disposed at the front of the vehicle , and a passenger compartment loaded with heavy objects is disposed under the floor behind the driving chamber , and a vehicle is disposed at the front end of the passenger compartment under the floor. A vehicle body lower structure with a guard bar extending along the width direction ,
A pair of left and right side members are extended from the drive chamber to the passenger compartment along the vehicle front-rear direction on both the left and right sides of the vehicle, and both ends of the guard bar are attached to the left and right side members. Bridging the
A suspension member is provided in front of the guard bar, a front end portion of the heavy object is formed along a vehicle width direction, an attachment portion is extended from the guard bar toward the rear of the vehicle, and the attachment portion is connected to the front end portion of the heavy object. By fixing to the vehicle, when viewed from the vehicle vertical direction, the mounting portion is orthogonal to both the guard bar and the front end portion of the heavy object,
A vehicle body lower structure characterized in that a rear end portion of the suspension member and both end portions of a guard bar are connected via a mounting bracket for fixing the suspension member and the vehicle body . The heavy object is a power generator, and a power consuming device connected to the power chamber via a wire harness is disposed in the driving chamber,
The vehicle body lower part structure according to claim 1 , wherein the wire harness is routed through above the guard bar. The vehicle body lower part structure according to claim 2 , wherein the power generation device is a fuel cell stack, and the power consumption device is a high-power unit. The vehicle body lower part structure according to any one of claims 1 to 3, wherein the mounting portion of the guard bar is disposed substantially horizontally toward the rear of the vehicle when viewed from the side of the vehicle. The vehicle body lower part structure according to any one of claims 1 to 4 , wherein a lower part of the guard bar is arranged at a height equal to or higher than a lower surface of a heavy object.

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