JP2014168979A - Structure of suspension frame - Google Patents

Abstract

PROBLEM TO BE SOLVED: To absorb load from a front side or the like of a vehicle by deformation of a front end portion of a floor and efficiently transmit and distribute the load to a rear side or the like of the vehicle so as to reduce deformation of the floor.SOLUTION: The structure of a suspension frame comprises: a pair of left and right side members 5; and a suspension frame 10 for connecting the side members 5. The suspension frame 10 is provided with a rear side attachment part 16a and a front side attachment part 19a for the side members. A rear side arm 13 has a central portion in a vehicle width direction formed in a curved shape protruding toward the front side of the vehicle. On the rear side of the vehicle of the suspension frame 10 are arranged a pair of left and right inner gussets 20 extending obliquely forward from both left and right sides of a center tunnel portion provided at a central portion in the vehicle width direction of a vehicle body floor 8. Outer end portions in the vehicle width direction of the inner gussets 20 and the side members 5 are connected around the rear side attachment part 16a for the side members 5 positioned at both left and right end portions of the suspension frame 10.

Description

  The present invention relates to a structure of a suspension frame disposed between a pair of left and right side members extending in the vehicle front-rear direction.

Conventionally, in a vehicle such as a four-wheeled vehicle, a pair of left and right side members including a front side member, an apron side member, and a floor side member that extend along the vehicle front-rear direction are used as the vehicle body frame. It is arranged at intervals in the direction. A lower arm that constitutes a suspension mechanism is provided around the pair of left and right side members so that loads and vibrations from front tires and the like are input to the vehicle body via the lower arm when the vehicle is traveling. It has become.
Such loads and vibrations include, for example, vehicle longitudinal direction loads and vibrations during vehicle braking and acceleration, vehicle width direction loads and vibrations during vehicle turning, vehicle up-down loads due to road surface irregularities, and the like. Examples thereof include vibrations, loads and vibrations due to these loads and vibrational components. In some cases, an external load is directly applied to the vehicle body from the vehicle longitudinal direction or the vehicle width direction. Such loads and vibrations may reduce the running stability of the vehicle and cause vibration and noise in the passenger compartment.
Therefore, in order to cope with these problems, a suspension frame is suspended between the pair of left and right side members and the lower arm, and the suspension frame receives the above-described load and vibration and increases the rigidity of the vehicle body. I have to.

  Patent Document 1 is provided as an example of the structure of such a suspension frame. In Patent Document 1, a support member extending in the vehicle front-rear direction is disposed below a pair of left and right front side members, and a suspension lower arm is provided at a lower arm attachment portion provided at each of a front end portion and a rear end portion of the support member. Is installed. A suspension frame extending linearly along the vehicle width direction is suspended between the pair of support members, and both end portions of the suspension frame in the vehicle width direction are attached to intermediate portions of the support members in the vehicle front-rear direction. It has been. In addition, a front vehicle body attachment portion is provided along the vehicle vertical direction between the lower arm attachment portion on the vehicle front side of the support member and the suspension frame attachment portion of the support member, and on the vehicle rear side of the support member. A rear vehicle body attachment portion that protrudes outward in the vehicle width direction from the lower arm attachment portion is provided, and the support member is attached to the front side member by the front vehicle body attachment portion and the rear vehicle body attachment portion.

JP 2001-191945 A

However, in the conventional suspension frame structure described above, since the suspension frame extends linearly along the vehicle width direction, it is difficult to receive the load and vibration in the vehicle longitudinal direction by the suspension frame. There is a problem that the rigidity of the vehicle body against the load and vibration of the vehicle cannot be increased efficiently by the suspension frame.
In such a conventional suspension frame structure, when a large load is applied from the front of the vehicle to the front of the vehicle body, the bumper member, the front side member, etc. are deformed and absorb the load. At this time, members in the engine room such as the transmission move to the rear of the vehicle and come into contact with the dash panel or the like. In addition, since a torque rod that suppresses rocking during operation of the engine and transmission is attached to the suspension frame, a load is also applied to the vicinity of the center of the suspension frame. On the other hand, when the front part of the vehicle body is deformed by the load, the front wheel tire also moves to the rear of the vehicle, and a load is applied to both ends of the suspension frame in the vehicle width direction from the tire and the lower arm. These loads applied to the suspension frame cause the suspension frame to interfere with the vehicle body (floor side member and floor bottom) around the floor and cause deformation of the vehicle body. Moreover, there is a desire to secure the passenger space without deforming the floor, although the front part of the vehicle body is deformed to absorb the load.

  The present invention has been made in view of such a situation, and an object of the present invention is to absorb the load from the front of the vehicle applied to the front of the vehicle body by the deformation of the front end of the floor and efficiently to the rear of the vehicle. An object of the present invention is to provide a suspension frame structure that can be transmitted and dispersed to reduce floor deformation.

  In order to solve the above-described problems of the prior art, the present invention includes a front side member, an apron side member, and a floor side member that extend along the vehicle front-rear direction, and is arranged with an interval in the vehicle width direction. A pair of left and right side members, and a pair of left and right side members are connected to each other, and a suspension frame disposed at a distance in the vehicle front-rear direction with respect to the vehicle drive mechanism, along the vehicle front-rear direction The suspension frame includes a torque rod that connects the drive mechanism and the suspension frame by attaching one end of the suspension frame to a central portion of the suspension frame in the vehicle width direction. The suspension frame has an attachment portion to the vehicle body side. A suspension frame provided with a rear mounting portion and a front mounting portion on the side member In the structure, the suspension frame is formed in a curved shape in which a central portion in the vehicle width direction protrudes toward the front of the vehicle, and is provided at a central portion in the vehicle width direction of the vehicle body floor on the vehicle rear side of the suspension frame. A pair of left and right inner gussets extending diagonally forward from the left and right sides of the center tunnel portion are disposed, and the outer end portions of the inner gusset in the vehicle width direction and the side members are located at both left and right end portions of the suspension frame. The side member is connected to the periphery of the rear mounting portion.

  In the present invention, a side sill extending along the vehicle front-rear direction is disposed outside the side member in the vehicle width direction, and the side member and the side sill have an outer end in the vehicle width direction at the vehicle outer side. The outer gussets are connected by outer gussets obliquely rearward toward the vehicle, and the inner end portions of the outer gussets in the vehicle width direction are around the rear attachment portions to the side members located at the left and right ends of the suspension frame. Connected to the side member, the inner gusset and the outer gusset are arranged to have a mountain shape inclined toward opposite sides.

  Further, in the present invention, the apron side member is disposed so as to be inclined such that the front end portion is located on the vehicle outer side or the vehicle inner side with respect to the vehicle longitudinal axis.

  The present invention also includes a pair of left and right side members arranged at intervals in the vehicle width direction, including a front side member, an apron side member, and a floor side member extending along the vehicle longitudinal direction. Between the side members, a suspension frame disposed at a distance in the vehicle longitudinal direction with respect to the vehicle drive mechanism, and disposed along the vehicle longitudinal direction, with one end portion of the suspension frame A torque rod that connects the drive mechanism and the suspension frame by being attached to a central portion in the vehicle width direction, and the suspension frame has a rear attachment portion to the side member as an attachment portion to the vehicle body side; In the structure of the suspension frame provided with the front mounting portion, the suspension frame is provided. The rear arm is formed in a curved shape projecting toward the front of the vehicle around the center in the vehicle width direction to which one end of the torque rod is attached, and the torque in front of the rear arm. A front arm formed in a curved shape projecting toward the rear of the vehicle centering on a central portion in the vehicle width direction to which one end of the rod is attached, and the rear arm and the front arm include the suspension The frames are connected by frame gussets provided on both the left and right sides in the vehicle width direction, and the frame gussets are arranged so as to be inclined so that the front end portion is located on the vehicle outer side or the vehicle inner side with respect to the vehicle longitudinal axis. .

  In the present invention, the frame gusset is disposed so as to be inclined so that a front end portion is positioned on the vehicle outer side with respect to an axis in the vehicle longitudinal direction, and the apron side member is inclined in the same direction as the frame gusset. Are arranged.

  Further, in the present invention, the frame gusset is disposed at the same inclination as the normal direction of the rear arm at the connection portion with the rear arm, or the front end portion is at the rear portion at the connection portion with the rear arm. It is inclined and arranged so as to be located outside the vehicle with respect to the normal direction of the side arm.

  Further, in the present invention, the apron side member is a separate part from the vehicle body, and the front side member and the floor located at the front and rear are attachment portions to the side members located at the left and right ends of the suspension frame. It overlaps with the side member.

  And in this invention, the said floor side member is formed in the shape extended toward the vehicle outer side toward the vehicle rear.

As described above, the structure of the suspension frame according to the present invention includes a front side member, an apron side member, and a floor side member that extend along the vehicle front-rear direction, and a pair of left and right members arranged at intervals in the vehicle width direction. The side members and the pair of left and right side members are connected to each other, and are disposed along the vehicle front-rear direction with a suspension frame that is spaced from the vehicle drive mechanism in the vehicle front-rear direction. And a torque rod for connecting the drive mechanism and the suspension frame by attaching one end portion to a central portion of the suspension frame in the vehicle width direction. The suspension frame includes the side as an attachment portion to the vehicle body side. A rear mounting portion and a front mounting portion are provided on the member, and the suspension is The frame is formed in a curved shape with a center portion in the vehicle width direction protruding toward the front of the vehicle, and on the vehicle rear side of the suspension frame, the left and right sides of the center tunnel portion provided in the center portion in the vehicle width direction of the vehicle body floor A pair of left and right inner gussets extending diagonally forward from both sides are disposed, and the outer end portions of the inner gussets in the vehicle width direction and the side members are connected to the side members located at the left and right end portions of the suspension frame. It is connected around the rear mounting part.
Therefore, according to the structure of the present invention, the load applied to the central portion of the suspension frame from the drive mechanism (engine, transmission, etc.) in front of the vehicle, the load applied to the vehicle rear from the front side member, and the suspension frame from the front wheel tire via the lower arm. Since the load applied to the left and right ends of the vehicle is collected at the rear mounting portion to the side member via the suspension frame, the collected load can be efficiently transmitted to the rear of the vehicle and dispersed. . Then, due to the presence of the inner gusset, not only the floor side member but also the front end of the floor located in the area between the inner gusset and the center tunnel portion is deformed to absorb the load and distribute the load to the rear of the center tunnel portion. Therefore, deformation of the entire floor can be reliably reduced. Moreover, when a load is applied to the central portion of the suspension frame, the curved portion is deformed, and both left and right end portions move to the outside of the vehicle, which is not simply transmitted to the rear of the vehicle but converted to a load to the outside of the vehicle. Therefore, the deformation between the inner gusset and the center tunnel portion is induced so as to expand, and the desired deformation can be caused.

  In the present invention, a side sill extending along the vehicle front-rear direction is disposed outside the side member in the vehicle width direction, and the side member and the side sill have an outer end in the vehicle width direction at the vehicle outer side. The outer gussets are connected by outer gussets obliquely rearward toward the vehicle, and the inner end portions of the outer gussets in the vehicle width direction are around the rear attachment portions to the side members located at the left and right ends of the suspension frame. Since the inner gusset and the outer gusset are connected to the side member and are arranged in a mountain shape inclined toward opposite sides, the load absorption and load described above are made using the entire width of the floor. Distribution can be made. In addition, the load can be distributed to the side sill via the outer gusset, and the deformation of the floor can be further reduced.

  Further, in the present invention, the apron side member is disposed at the left and right end portions of the suspension frame before the front end portion is inclined so that the front end portion is positioned on the vehicle outer side or the vehicle inner side with respect to the vehicle longitudinal axis. The rear mounting portion to the positioned side member serves as a starting point of rigidity as a connecting set point of the rigid members, and the load can be absorbed by folding the apron side member portion by the load from the front of the vehicle. At this time, since the folding and deformation of the inner gusset and the outer gusset arranged in the front part of the floor are interlocked, the desired deformation can be reliably caused when a load is applied from the front of the vehicle.

Further, the structure of the suspension frame according to the present invention includes a pair of left and right sides including a front side member, an apron side member, and a floor side member extending along the vehicle front-rear direction and arranged at intervals in the vehicle width direction. A member and a pair of left and right side members, a suspension frame disposed at a distance in the vehicle longitudinal direction with respect to the vehicle drive mechanism, and disposed along the vehicle longitudinal direction; And a torque rod that connects the drive mechanism and the suspension frame by being attached to a central portion of the suspension frame in the vehicle width direction. The suspension frame is attached to the side member as an attachment portion to the vehicle body side. A rear mounting portion and a front mounting portion are provided. A rear arm formed in a curved shape projecting toward the front of the vehicle around a central portion in the vehicle width direction to which one end of the torque rod is attached, and the torque rod in front of the rear arm A front arm formed in a curved shape projecting toward the rear of the vehicle with a central portion in a vehicle width direction to which one end of the vehicle is attached as the center, and the rear arm and the front arm include the suspension frame. The frame gussets are arranged so as to be inclined so that the front end portions are located on the vehicle outer side or the vehicle inner side with respect to the vehicle longitudinal axis.
Therefore, according to the structure of the present invention, when a load is applied to the left and right end portions of the suspension frame from the front wheel tire via the lower arm, it is possible to induce the rear arm and the front arm to be folded and deformed. It is possible to absorb the load by the deformation, and to reduce the burden of the rear mounting portion on the side member. Further, when the front arm is folded with the above load, the front mounting portion to the side member moves obliquely rearward to the vehicle outer side, so that the front side member is deformed toward the vehicle outer side and the side member is deformed. Can be induced and load absorption performance can be improved.

  In the present invention, the frame gusset is disposed so as to be inclined so that a front end portion is positioned on the vehicle outer side with respect to an axis in the vehicle longitudinal direction, and the apron side member is inclined in the same direction as the frame gusset. Therefore, when the load from the front of the vehicle is applied to both left and right ends of the suspension frame, the frame gusset is folded and the front mounting part to the side member is inclined rearward toward the outside of the vehicle. It moves and is interlocked with the deformation of the front side member toward the outside of the vehicle, so that the deformation of the side member can be promoted and the load absorption performance can be improved.

  Further, in the present invention, the frame gusset is disposed at the same inclination as the normal direction of the rear arm at the connection portion with the rear arm, or the front end portion is at the rear portion at the connection portion with the rear arm. Since the frame gusset is positioned so as to be located outside the vehicle with respect to the normal direction of the side arm, the frame gusset is positioned so as to stretch in the normal direction with respect to the front arm. In addition to ensuring rigidity against vibration and load, the frame gusset has a smaller inclination angle with respect to the normal direction due to folding of the rear arm when the vehicle is deformed. be able to.

  Further, in the present invention, the apron side member is a separate part from the vehicle body, and the front side member and the floor located at the front and rear are attachment portions to the side members located at the left and right ends of the suspension frame. Since it is arranged overlapping with the side members, the rigidity of the front and rear mounting parts to the side members can be set higher than that of the front and rear front side members and floor side members, and the load from the front of the vehicle When a load is applied to both left and right end portions of the left and right apron side members, the apron side member falls while maintaining its shape, and the folding of the rear and front arms and gussets of the suspension frame can be promoted. Moreover, the rigidity between the suspension points of the front and rear suspension frames can be increased with respect to vibration and load during vehicle operation, and the running stability of the vehicle can be improved.

  And in the present invention, since the floor side member is formed in a shape that spreads outward from the vehicle toward the rear of the vehicle, when a load from the front of the vehicle is applied to both the left and right ends of the suspension frame, The fall due to the inclination of the inner gusset, the outer gusset and the frame gusset can be promoted, and the load absorption performance can be further improved.

It is the bottom view which looked at the vehicle body front part to which the structure of the suspension frame concerning the embodiment of the present invention was applied from the lower part. It is the bottom view which looked at the vehicle body side attaching part vicinity of the suspension frame which concerns on embodiment of this invention from the bottom in the state which removed the lower arm. It is the bottom view which looked at the suspension frame concerning the embodiment of the present invention from the lower part.

Hereinafter, the present invention will be described in detail based on illustrated embodiments.
1 to 3 show the structure of a suspension frame according to an embodiment of the present invention.

The vehicle according to the embodiment of the present invention is a four-wheel type automobile as shown in FIGS. 1 and 2, and this type of vehicle body front portion 1 has a vehicle skeleton as a part constituting the vehicle body skeleton in the vehicle longitudinal direction. A pair of left and right side members 5 including a front side member 2, an apron side member 3, and a floor side member 4 extending along the vehicle are disposed at intervals in the vehicle width direction. The front side member 2, the apron side member 3, and the floor side member 4 are arranged in this order from the vehicle front side to the vehicle rear side. The apron side member 3 includes the front and rear front side members 2 and the floor. It is arranged between the side members 4. And the side sill 6 extended along the vehicle front-back direction is arrange | positioned in the vehicle width direction outer side of the floor side member 4 among the pair of left and right side members 5.
The vehicle body front portion 1 is provided with a pair of left and right lower arms 7 constituting a suspension mechanism. These lower arms 7 are arranged below the side members 5 so as to straddle the apron side members 3 in the vehicle front-rear direction, and loads and vibrations from front tires and the like pass through the lower arms 7 when the vehicle travels. It is designed to be input to the car body. Further, the vehicle body floor 8 of the vehicle body front portion 1 is provided with a convex center tunnel portion 9 extending along the vehicle front-rear direction and projecting toward the vehicle interior side. The vehicle body floor 8 is disposed at the center in the vehicle width direction. 1 and 2, the arrow Fr direction indicates the front of the vehicle.

On the other hand, as shown in FIGS. 1 and 3, a suspension frame 10 connecting these side members 5 extends in the vehicle width direction between the pair of left and right side members 5 positioned on the vehicle front side in the vehicle body front portion 1. Are arranged. A vehicle drive mechanism (not shown) having an engine, a transmission, and the like is disposed on the vehicle front side of the suspension frame 10, and the side members 5 are provided on both left and right sides of the drive mechanism in the vehicle width direction. A front side member 2 is disposed. Therefore, the suspension frame 10 is arranged at an interval in the vehicle front-rear direction with respect to the drive mechanism.
Further, a torque rod 11 is provided in the vehicle body front portion 1, and the torque rod 11 is arranged along the vehicle front-rear direction. One end (rear end) of the torque rod 11 is attached to the center of the suspension frame 10 in the vehicle width direction, and the drive mechanism (not shown) and the suspension frame 10 are connected by the torque rod 11. .

  As shown in FIGS. 1 and 3, the suspension frame 10 of the present embodiment is provided with a central coupling body 12 positioned at the center in the vehicle width direction, and one end portion of the torque rod 11 is attached to the central coupling body 12. Installed. Moreover, the suspension frame 10 is positioned on the vehicle front side of the rear arm 13 and the rear arm 13 provided so as to extend from both ends of the central coupling body 12 in the vehicle width direction toward the vehicle outer side. The connecting body 12 has a front arm 14 provided so as to extend from both ends in the vehicle width direction toward the outside of the vehicle, and the rear arm 13 and the front arm 14 have a vehicle width of the suspension frame 10. They are connected to each other by frame gussets 15 provided on the left and right sides of the direction. For this reason, the frame gusset 15 is provided along the vehicle front-rear direction.

As shown in FIGS. 1 to 3, the rear arm 13 is provided with a rear suspension body 16 extending from both ends in the vehicle width direction toward the vehicle outer side. At the center of the side wall, a rear side mounting portion 16a to the floor side member 4 (side member 5) is provided as a mounting portion on the vehicle body side, and the rear side arm 13 has a rear side suspension in the rear side mounting portion 16a. The body 16 is attached to and suspended from the lower surface of the floor side member 4. Moreover, a reinforcing attachment body 17 extending toward the rear of the vehicle is provided at the rear end portion of the rear suspension body 16. A rear end portion 17 a of the reinforcing attachment body 17 is attached to the lower surface of the floor side member 4.
Further, a front suspension body 18 extending toward the vehicle outer side is provided at an outer end portion of the front arm 14 in the vehicle width direction, and a suspension arm 19 extending toward the vehicle outer side is provided on the front suspension body 18. Is provided. A front mounting portion 19a to the apron side member 3 (side member 5) is provided at the center of the vehicle outer end portion of the suspension arm 19 as a mounting portion on the vehicle body side. In the front mounting portion 19a, the front arm 14 is provided. The front suspension body 18 and the suspension arm 19 are attached to the lower surface of the apron side member 3 and suspended.

  The rear arm 13 of the present embodiment is located on the opposite side of the torque rod 11 in the vehicle front-rear direction, and the vehicle front is centered on the central coupling body 12 in the vehicle width direction to which one end of the torque rod 11 is attached. It is formed in a curved shape that protrudes toward. On the other hand, the front arm 14 is formed in a curved shape that protrudes toward the rear of the vehicle around the central coupling body 12 at the center in the vehicle width direction to which one end of the torque rod 11 is attached in front of the rear arm 13. ing. In other words, the rear arm 13 and the front arm 14 have arc shapes that are opposite to each other in plan view, and are disposed so as to overlap in the vehicle longitudinal direction at both ends in the vehicle width direction of the central coupling body 12.

As shown in FIG. 2, the frame gusset 15 of the present embodiment is disposed so as to be inclined so that the front end portion 15a is positioned on the vehicle outer side (or on the vehicle inner side) with respect to the axis C1 in the vehicle longitudinal direction. Further, the apron side member 3 located adjacent to the outside of the frame gusset 15 on the vehicle side is inclined in the same direction as the frame gusset 15. With this arrangement, when the load F from the front of the vehicle is applied to the left and right ends of the suspension frame 10, the frame gusset 15 is folded and the front mounting portion 19a to the apron side member 3 is provided. It moves to the vehicle outer side (arrow X direction) diagonally backward, and the deformation of the side member 5 including the apron side member 3 is promoted in conjunction with the deformation of the front side member 2 toward the vehicle outer side.
Moreover, the frame gusset 15 is disposed at the same inclination as the normal direction C2 of the rear arm 13 at the connecting portion with the rear arm 13, or the front end portion 15a is the rear arm at the connecting portion with the rear arm 13. It is inclined and arranged so as to be located outside the vehicle with respect to the 13 normal direction C2. Accordingly, the positional relationship is such that the frame gusset 15 stretches in the normal direction C2 with respect to the front arm 14, the rigidity against vibration and load from the front wheel tire is ensured during vehicle operation, and the rear arm 13 of the rear arm 13 is deformed when the vehicle body is deformed. Due to the folding, the inclination angle of the frame gusset 15 becomes small with respect to the normal direction C2, and it is possible to smoothly shift to the bending deformation.

Further, as shown in FIG. 2, the apron side member 3 of the present embodiment is a separate part from the vehicle body, and the front side attaching portion 19 a to the side member 5 whose front and rear end portions are located at both left and right end portions of the suspension frame 10. Further, the front side member 2 and the floor side member 4 positioned in the front-rear direction are overlapped with the rear attachment portion 16a. Therefore, the rigidity of the front side mounting part 19a and the rear side mounting part 16a to the side member 5 overlapping the front and rear end parts of the apron side member 3 is higher than the rigidity of the front and rear front side members 2 and the floor side member 4 itself. ing. Therefore, when a load from the front of the vehicle is applied to the left and right ends of the suspension frame 10, the apron side member 3 falls down while maintaining its shape, and the rear arm 13 and the front arm 14 of the suspension frame 10 and the like. The folding between the suspension points of the front and rear suspension frames 10 is enhanced with respect to vibrations and loads during vehicle operation.
In addition, the floor side member 4 is formed in the shape which spreads outside the vehicle toward the vehicle rear, that is, in a C shape in plan view. When the floor side member 4 has a square shape, when a load from the front of the vehicle is applied to the left and right ends of the suspension frame 10, an inner gusset 20, an outer gusset 21, and a frame gusset described later are used. The fall by the inclination of 15 is promoted.

Further, in the structure of the present embodiment, a pair of left and right sides extending obliquely forward from the left and right sides of the center tunnel portion 9 of the vehicle body floor 8 are provided on the vehicle rear side of the suspension frame 10 as shown in FIGS. 1 and 2. Inner gussets 20 are respectively arranged. That is, these inner gussets 20 are arranged so as to be in a front-opened V-shape in plan view together with the side surface portion of the center tunnel portion 9. In addition, the outer end of the inner gusset 20 in the vehicle width direction and the floor side member 4 of the side member 5 are rear attachment portions 16a to the side members 5 located at the left and right ends of the rear arm 13 of the suspension frame 10. It is connected around.
As a result, when a load is applied to the central portion and the left and right side portions of the suspension frame 10 from the front of the vehicle, the floor front end located not only in the floor side member 4 but also in the region between the inner gusset 20 and the center tunnel portion 9. The portion is deformed to absorb the load, and the load is distributed to the rear of the center tunnel portion 9. Moreover, when a load is applied to the central portion of the suspension frame 10, the curved portion of the rear arm 13 is deformed, the left and right end portions move to the outside of the vehicle, and are converted into a load to the outside of the vehicle. The region between the center tunnel portion 9 is deformed so as to expand.

Furthermore, in the structure of the present embodiment, the floor side member 4 and the side sill 6 of the side member 5 are disposed obliquely rearward with the outer end in the vehicle width direction toward the vehicle outer side, as shown in FIGS. The outer gussets 21 are connected to each other. The inner ends of the outer gussets 21 in the vehicle width direction are connected to the floor side member 4 around the rear attachment portions 16a to the side members 5 located at the left and right ends of the rear arm 13 of the suspension frame 10. Yes. That is, the inner gusset 20 and the outer gusset 21 have a mountain shape inclined toward opposite sides, and are arranged so as to be W-shaped in plan view by the left and right inner gussets 20 and the outer gusset 21. .
Thereby, load absorption and load distribution are performed using the entire width of the vehicle body floor 8, and load distribution is also performed to the side sill 6 via the outer gusset 21, so that deformation of the vehicle body floor 8 is reduced. It is like that.

Next, the operation and effect of the structure of the suspension frame 10 according to the embodiment of the present invention will be described.
The suspension frame 10 of the present embodiment includes a rear arm 13 formed in a curved shape that protrudes toward the front of the vehicle around a central portion in the vehicle width direction to which one end of the torque rod 11 is attached, and a rear arm. 13 and a front arm 14 formed in a curved shape projecting toward the rear of the vehicle centering on the same central portion, and the rear arm 13 and the front arm 14 are provided on the left and right sides in the vehicle width direction. The frame gusset 15 is connected to each other, and the front end portion 15a of the frame gusset 15 is disposed to be inclined with respect to the vehicle longitudinal axis C1. In addition, a pair of left and right inner gussets 20 extending diagonally forward from the left and right sides of the center tunnel portion 9 of the vehicle body floor 9 are disposed on the vehicle rear side of the suspension frame 10, and the outer end of the inner gusset 20 in the vehicle width direction is disposed. And the floor side member 4 of the side member 5 are connected to the side member 5 around the rear mounting portion 16a, and a side sill is arranged on the outer side of the floor side member 4 in the vehicle width direction. The side sill 6 is connected by an outer gusset 21 disposed obliquely rearward toward the vehicle outer side, and the inner end of the outer gusset 21 in the vehicle width direction is connected to the side member 5 around the rear mounting portion 16a. The inner gusset 20 and the outer gusset 21 are arranged so as to incline toward opposite sides.

Therefore, when the drive mechanism moves rearward due to an external load from the front of the vehicle and hits the center portion of the suspension frame 10, the rear arm 13 that curves convexly toward the front of the vehicle is deformed into a linear shape by the load. Therefore, the input load from the front of the vehicle is pushed and spread in the vehicle width direction via the rear arm 13, and the load direction changes. At this time, the presence of the outer gusset 21 arranged on the curved extension line of the rear arm 13 can absorb the input load from the rear mounting portion 16a to the side member 5 and can transmit the load to the side sill 6. Load distribution can be performed. Moreover, since the inner gusset 20 connected to the structural member of the center tunnel portion 9 supports the rear attachment portion 16a to the side member 5 from obliquely rearward, the input to the rear attachment portion 16a to the side member 5 is performed. The load can be absorbed and transmitted to the rear of the center tunnel portion 9.
Therefore, according to the structure of the suspension frame 10 of the present embodiment, the input load to the floor side member 4 and the like is compared with the conventional structure in which the side member 5 such as the floor side member 4 receives all the load from the front of the vehicle. The weight of the side members 5 such as the floor side member 4 can be reduced. The suspension frame 10 to which turning load, deceleration and acceleration load, vibration, etc. are applied from the front wheel tire via the lower arm 7 has a curved rear arm 13 and front arm 14 connected by a frame gusset 15, and Since the apron side member 3, the inner gusset 20, the outer gusset 21, and the like are connected to each other, the rigidity of the vehicle body floor 8 against the load and vibration in the vehicle front-rear direction and the like can be increased. Deformation can be suppressed, vehicle running stability can be improved, vibration and noise can be reduced, and driving operability and indoor comfort can be improved.

While the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications and changes can be made based on the technical idea of the present invention.
For example, in the above-described embodiment, the suspension frame 10 includes the rear arm 13 and the front arm 14, but depending on the application model, the center portion in the vehicle width direction protrudes toward the front of the vehicle. You may use the suspension frame comprised by the one back side arm 13 formed in the shape. In this case, both left and right end portions of the suspension frame are formed in a bifurcated shape branched in the vehicle front-rear direction, and two attachment portions to the side member 5 are provided on the front and rear sides as attachment portions on the vehicle body side.

DESCRIPTION OF SYMBOLS 1 Car body front part 2 Front side member 3 Apron side member 4 Floor side member 5 Side member 6 Side sill 7 Lower arm 8 Car body floor 9 Center tunnel part 10 Suspension frame 11 Torque rod 12 Central coupling body 13 Rear arm 14 Front arm 15 Frame gusset 16 Rear suspension body 16a Rear attachment portion to the side member 18 Front suspension body 19 Suspension arm 19a Front attachment portion to the side member 20 Inner gusset 21 Outer gusset C1 Center axis of the vehicle longitudinal direction C2 Normal direction of the rear arm

Claims (8)

A pair of left and right side members arranged at intervals in the vehicle width direction, including a front side member, an apron side member, and a floor side member extending along the vehicle front-rear direction, are connected to the pair of left and right side members. A suspension frame disposed at a distance in the vehicle front-rear direction with respect to the vehicle drive mechanism, and disposed along the vehicle front-rear direction, with one end portion being a central portion in the vehicle width direction of the suspension frame A torque rod connecting the drive mechanism and the suspension frame to each other, and the suspension frame is provided with a rear attachment portion and a front attachment portion to the side member as attachment portions on the vehicle body side. In the structure of the suspension frame that
The suspension frame is formed in a curved shape in which a central portion in the vehicle width direction protrudes toward the front of the vehicle, and a center tunnel portion provided at a central portion in the vehicle width direction of the vehicle body floor on the vehicle rear side of the suspension frame. A pair of left and right inner gussets extending obliquely forward from both left and right sides of the inner gusset are disposed, and the outer end portions of the inner gusset in the vehicle width direction and the side members are located at the left and right end portions of the suspension frame. A suspension frame structure characterized in that the suspension frame is connected in the vicinity of the rear mounting portion.   A side sill extending along the vehicle front-rear direction is disposed outside the side member in the vehicle width direction, and the side member and the side sill have an outer end in the vehicle width direction obliquely rearward toward the vehicle outer side. The outer end gussets are connected by the outer gussets, and the inner ends of the outer gussets in the vehicle width direction are connected to the side members around the rear attachment portions to the side members located at the left and right ends of the suspension frame. 2. The suspension frame structure according to claim 1, wherein the inner gusset and the outer gusset are arranged in a mountain shape inclined toward opposite sides.   2. The suspension frame structure according to claim 1, wherein the apron side member is disposed so as to be inclined such that a front end portion thereof is positioned on an outer side or an inner side of the vehicle with respect to an axis in a vehicle front-rear direction. A pair of left and right side members arranged at intervals in the vehicle width direction, including a front side member, an apron side member, and a floor side member extending along the vehicle front-rear direction, are connected to the pair of left and right side members. A suspension frame disposed at a distance in the vehicle front-rear direction with respect to the vehicle drive mechanism, and disposed along the vehicle front-rear direction, with one end portion being a central portion in the vehicle width direction of the suspension frame A torque rod connecting the drive mechanism and the suspension frame to each other, and the suspension frame is provided with a rear attachment portion and a front attachment portion to the side member as attachment portions on the vehicle body side. In the structure of the suspension frame that
The suspension frame includes a rear arm that is formed in a curved shape that protrudes toward the front of the vehicle around a central portion in the vehicle width direction to which one end of the torque rod is attached, and the front of the rear arm. Centered in the vehicle width direction to which one end of the torque rod is attached, and having a front arm formed in a curved shape protruding toward the rear of the vehicle, the rear arm and the front arm The suspension frames are connected by frame gussets provided on both the left and right sides in the vehicle width direction, and the frame gussets are arranged so as to be inclined so that the front end portions are located on the vehicle outer side or the vehicle inner side with respect to the vehicle longitudinal axis. The structure of the suspension frame characterized by   The frame gusset is disposed so as to be inclined so that a front end portion is positioned on the vehicle outer side with respect to an axis in the vehicle longitudinal direction, and the apron side member is disposed to be inclined in the same direction as the frame gusset. The structure of the suspension frame according to claim 4.   The frame gusset is disposed at the same inclination as the normal direction of the rear arm in the connecting portion with the rear arm, or the front end portion is in the normal direction of the rear arm in the connecting portion with the rear arm. The suspension frame structure according to claim 5, wherein the suspension frame is disposed so as to be inclined with respect to the vehicle.   The apron side member is a separate part from the vehicle body, and is an attachment portion to the side member located at both left and right ends of the suspension frame, overlapping the front side member and the floor side member located at the front and rear. The suspension frame structure according to any one of claims 3 to 6, wherein the suspension frame structure is disposed.   The structure of the suspension frame according to any one of claims 1 to 7, wherein the floor side member is formed in a shape that spreads outward from the vehicle toward the rear of the vehicle.

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