RU2487811C1 - Vehicle body - Google Patents

Abstract

FIELD: transport.

SUBSTANCE: invention relates to automotive industry. Vehicle body comprises front suspension element and two subframes. Front suspension element is secured to vehicle body to prop up front wheel axle. Subframes are secured to front suspension element to extend therefrom. Every subframe is secured by its top side to front suspension element relative to centroid of every subframe.

EFFECT: efficient impact absorption.

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Description

The present invention relates to a vehicle body structure and, in particular, to a mounting structure of a subframe connecting the front suspension element to the front of the body.

The front lower body of a vehicle, such as a car, has a front suspension element that extends laterally in the vehicle and supports the front wheels. The front suspension element is attached to the body part (front element) in the left and right positions, for example, its rear end portion.

For such a vehicle, a technology was developed in which, in a frontal collision of a vehicle, the front of the body collapses to absorb impact energy and the fixing part of the front suspension element and the body are destroyed, preventing the transfer of impact energy from the front suspension element to the rear of the body (see JP 10-119825 A).

It is also known a vehicle in which there are subframes connecting the front suspension element to the body to increase stiffness. Each of the subframes has the shape of a square tube. The subframes are located in the left and right positions and extend longitudinally between the front of the body and the front end portion of the front suspension element.

As described above, in a vehicle having subframes, in a frontal collision of a vehicle, impact energy applied to the front of the body is transmitted to the rear of the body through the subframes and the front suspension element. Accordingly, even if the front of the body can collapse, the ability to absorb impact energy by the entire vehicle during a head-on collision as a whole can be reduced.

Thus, we consider a way to reduce the strength of the subframes, which will allow the subframes to actively crumple. However, in the case of the subframes described above, in a frontal collision of a vehicle, the subframes create traction directed backward and, under the influence of the impact energy applied to the front of the vehicle, bend. As a result, there is a high probability that, as a result of bending, the subframes will take a V-shape in the central part in the longitudinal direction. If the subframes bend and take a V-shape, with continued impact from the front, most of the impact energy of the subframes will not be absorbed. That is, despite the fact that the subframes can absorb impact energy at an early stage of a head-on collision of a vehicle, the effect of absorption of impact energy can be immediately reduced.

In addition, we consider a method in which the fastening part of the front suspension element and the body can be made destructible, as described in JP 10-119825 A. However, in this design, since the impact energy is not absorbed by the subframes, the front part of the vehicle must be shaped to sufficiently absorb impact energy. Thus, the degree of freedom of designers is reduced.

The present invention addresses the above problems. An object of the present invention is to provide a vehicle body structure capable of sufficiently absorbing the impact energy of the subframes and having a high ability to absorb impact energy of the entire vehicle as a whole in the event of a head-on collision.

To solve this problem, according to the present invention, there is provided a vehicle body structure comprising: a front suspension element attached to a vehicle body and supporting a front wheel suspension; and a pair of subframes attached to the front suspension element and extending forward from the front suspension element, each of the subframes attached to the front suspension element on the upper side of the centroid of each of the subframes.

Each of the subframes can be formed so that its cross section in the vertical direction decreases from the front of the vehicle to the rear.

Each of the subframes may be provided with a reinforcing element that extends along the subframe in the longitudinal direction of the vehicle, and an incised portion may be made on the reinforcing element.

An incised portion may have a plurality of notches, and incisions of the plurality may be spaced apart from one another in the longitudinal direction of the vehicle.

According to one aspect of the present invention, each of the subframes is attached to the front suspension element on the upper side of the centroid of each of the subframes. Accordingly, when the subframe bends under the influence of a shock applied to the front of the vehicle body and directed towards the rear of the vehicle during a head-on collision, the subframe bends so as to protrude downward near the attachment point of the subframe to the front suspension element. Therefore, it is possible to control the position or direction of the bending of the subframe during the bending of the subframe and, thereby, sufficiently absorb the impact energy on the subframe during a head-on collision, thereby increasing the ability of the entire vehicle to absorb shock.

A design in which “each of the subframes is attached to the front suspension element above the centroid of each subframe” means that the subframe and the front suspension element are attached to each other in a position above the line passing through the centroid of the subframe and parallel to the longitudinal direction of the subframe.

According to one aspect of the present invention, since the subframe is shaped so that its vertical cross section decreases from the front of the vehicle to the rear, the portion closer to the rear of the vehicle bends more easily than the portion closer to the front of the vehicle. Therefore, even when the shock load is continuously transmitted from the front of the vehicle towards the rear, the subframe bends so that it continuously curls in a circle from the part closer to the rear of the vehicle. Thus, the shock load continues to be absorbed.

According to one aspect of the present invention, since the subframe is prone to bending in a notched portion of the reinforcing member, it is possible to easily and accurately set the position in which the subframe bends when warped.

According to one aspect of the present invention, since there are many notches in the longitudinal direction of the vehicle on the subframe, it is possible to arbitrarily set the position in which the subframe is bent, and to gradually bend the subframe in different positions during a head-on collision, thereby continuing to absorb impact energy.

The invention will now be described in more detail with reference to the accompanying drawings, in which:

FIG. 1 is a side view of a body structure according to an illustrative embodiment of the invention;

FIG. 2 is a bottom view showing a body structure of a front part of a vehicle;

FIG. 3 is a side view showing a stretcher mounting portion of a subframe to a front suspension element; and

FIG. 4 is an illustration of changes in the deformation state of a subframe during a head-on collision of a vehicle.

The following is a description of an illustrative embodiment of the invention with reference to the drawings.

In FIG. 1 is a side view of the structure of a body 2 (vehicle body) of a front part of a vehicle according to an illustrative embodiment of the invention.

As shown in FIG. 1 and 2, the vehicle 1 according to an illustrative embodiment has a front suspension element 4 that supports the suspension of the front wheels 3 in the front lower body 2. The front suspension element 4 has a thick plate configuration of a substantially rectangular shape that extends in the transverse direction of the vehicle 1 The four corner parts of the front suspension element 4 protrude forward, backward, to the right and to the left, respectively.

The front suspension element 4 is attached to the body 2 by bolts 5 in the two rear end portions 4a that protrude backward, and the front suspension element 4 is also attached to the lower surface of the body 2 by uprights 4b that protrude upward in the left and right positions relative to the central part in the longitudinal direction vehicle 1.

In addition, the vehicle is equipped with two subframes 10 that connect the front end portion 4c of the front suspension element 4 to the front part 2a of the body 2. The subframe 10 is square in cross-section of the column, which is formed by welding into an element having a L-shaped section, a reinforcing element 11, which extends longitudinally along the subframe 10. The subframes 10 are arranged so as to extend backward from the front 2a of the body 2 to the front end 4c of the front suspension element 4.

In addition, the body 2 has such a structure that the front of the joints in which the body 2 is attached to the front suspension element 4 has a tendency to relative warping compared to the rear of the joint. When an impact load acts on the front part 2a of the body 2 during a head-on collision, the front part of the body 2 is crushed to absorb impact energy to prevent the shock from spreading to the rear of the body 2.

In FIG. 3 is an enlarged side view illustrating a structure of a mounting portion of a subframe 10 and a front suspension element 4.

As shown in FIG. 3, the rear end portion of the subframe 10 and the front end portion 4c of the front suspension element 4 are fastened with a bolt 12. The rear end portion of the subframe 10 is formed so that the upper wall 10a of the subframe 10 protrudes backward. A nut 13 is welded and attached to the protruding portion 10b of the upper wall 10a.

At the same time, the front end portion 4c of the front suspension element 4 has a plate-shaped protrusion 4d that extends forward. A bolt hole is formed in the protrusion 4d of the front suspension element 4. The protrusion 4d of the front suspension element 4 and the protrusion 10b of the subframe 10 are stacked one on the other in the vertical direction and then the bolt 12 is screwed into the nut 13 to fasten the front suspension element 4 and the subframe 10 to each other.

In particular, in this illustrative embodiment, the protrusion 10b of the rear end portion of the subframe 10 projects backward from the upper wall 10a of the subframe 10, and the position of the protrusion 10b of the subframe 10, i.e., the position in which the subframe 10 is attached to the front suspension element 4, is shifted upward centroid C subframe 10.

More specifically, the protrusion 4d of the front suspension element 4 and the protrusion 10b of the subframe 10 are attached to each other in a position that is offset upward from a line (dash-dotted line in FIG. 3) that passes through the centroid C of the subframe 10 and which is parallel to the longitudinal direction of the subframe 10, i.e., the direction along the upper wall 10a of the subframe 10 shown in FIG. 3.

In addition, the subframe 10 is formed so that its vertical section decreases from the front of the vehicle to its rear. Further, in the reinforcing member 11 provided on the subframe 10, there are a plurality of notches (notched portion) 15 spaced apart from each other in the longitudinal direction of the vehicle 1. The number of notches 15 is not limited to a plurality, there may be a single notch.

According to this illustrative embodiment, due to the above-described structure, when a load directed to the rear part acts on the front of the body 2, this load is transmitted through the body 2 itself, as well as through the subframes 10 and the front suspension element 4, to the rear of the body. Thus, when a shock load occurs and the front of the body 2 collapses, as, for example, in a head-on collision, the shock also acts on the subframes 10, from their front to the rear, so that the subframes 10 also wrinkle and bend. Therefore, since the impact energy is absorbed not only by the front of the body 2, but also by the subframes 10, shock transmission to the rear of the body 2 is prevented. As a result, crushing of the rear of the body 2 can be prevented and therefore protect the passenger inside the vehicle 1 in its back.

In FIG. 4 shows the changing strain states of the subframe 10 during a head-on collision.

As described above, in this illustrative embodiment, the mounting position of the subframe 10 to the front suspension element 4 is located above the centroid C of the subframe 10 in the vertical direction. Therefore, when the shock load acts in the rearward direction from the front part 2a of the body 2 to the subframe 10, the subframe bends as shown in FIG. four.

More specifically, under the action of a shock load applied from the front part 2a of the body 2, the subframe 10 bends at the rear end portion, i.e., in a position adjacent to the fastening position in which the subframe 10 is attached to the front suspension element 4 so that protrude down. Due to this, it is possible to control the position in which a bend occurs, or the direction of bending of the subframe. Therefore, it is possible to shape the subframe 10 so that the impact energy is effectively absorbed by the subframe during a head-on collision of the vehicle, thereby increasing the ability of the entire vehicle to absorb impact energy.

In particular, since the subframe 10 is formed so that its vertical section decreases from the front of the vehicle to its rear, the rear of the vehicle is more prone to bending than the front of the vehicle. Accordingly, when the shock load continuously acts on the front part 2a of the body 2, the subframe 10 is bent so that it continuously twists down from its rear end portion, as shown in FIG. 4. In this way, he continues to absorb the energy of the impact.

In addition, since notches 15 are made in the reinforcing element 11 provided on the subframe 10, the subframe 10 tends to bend at the positions of the notches 15. Therefore, it is possible to easily and accurately set the position in which the subframe 10 is bent. In particular, if there are many notches 15 spaced in the longitudinal direction of the vehicle 1, it is possible to arbitrarily set the bending position of the subframe 10 and gradually bending the subframe 10 in different positions during a head-on collision. Thus, it is possible to further continue to absorb impact energy.

The invention is not limited to the described illustrative embodiment. The invention can be widely applied to vehicles in which subframes 10 connect the front part 2a of the body 2 to the front suspension element 4.

Claims (4)

1. A vehicle body structure comprising a front suspension element attached to a vehicle body and supporting a front wheel suspension; and a pair of subframes attached to the front suspension element and extending forward from the front suspension element, characterized in that each of the subframes is attached to the front suspension element with an upper side relative to the centroid of each of the subframes. 2. The construction according to claim 1, characterized in that each of the subframes is formed so that its cross section in the vertical direction decreases from the front of the vehicle to the rear of the vehicle. 3. The construction according to claim 1 or 2, characterized in that each subframe is provided with a reinforcing element extending along the subframe in the longitudinal direction of the vehicle, and the reinforcing element is formed with a notched portion. 4. The construction according to claim 3, characterized in that the notched section contains many cuts, and cuts of many cuts are spaced from each other in the longitudinal direction of the vehicle.

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