JP2009255705A - Front part structure of automobile - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a front part structure of an automobile capable of transmitting an impact load applied to the body forefront to the rear part of the body etc. through a front tire in good performance and dispersing even if the front tire retreating in the event of a head-on collision makes also a relative movement upward with respect to the body. <P>SOLUTION: The front part structure of automobile is equipped with a front hinge pillar 3 installed behind each front tire W, an apron reinforcement 4 extending forward from the upper part of the front hinge pillar 3, and a coupling member 61 to couple together the front hinge pillar 3 and the apron reinforcement 4 in a part over behind the tire W in the diagonally crossing arrangement. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a shock absorbing structure for a front portion of a vehicle body of an automobile, and belongs to the technical field of the vehicle body structure.

  Conventionally, when an impact load is input to the front part of the vehicle body due to a front collision or the like, this load may be configured to be absorbable by an axial crash of the front side frame extending in the vehicle front-rear direction at the vehicle body front part. . In order to increase the shock absorbing capacity, it is necessary to increase the cross-sectional area and the crush stroke of the front side frame, and in either case, the vehicle body becomes large.

  For example, in Patent Document 1, the front end portion of the vehicle body recedes and comes into contact with the front portion of the front tire in the case of a front collision, while avoiding such an increase in the size of the vehicle body. Focusing on the fact that the tire also retreats along with this, a plate member extending upward from the front end along the inner surface of the rear part of the wheel house is attached to the front end of the side sill constituting the vehicle body behind the front tire. The rear part of the tire and the plate member are in contact with each other when the tire is retracted, whereby the impact load input to the front end of the vehicle body is transmitted and distributed to the side sill via the front tire and the plate member. What has been made is disclosed.

Japanese Patent Laid-Open No. 06-16154

  By the way, at the time of a front collision, a so-called nose dive in which the front end of the vehicle body sinks downward may occur. In this case, the front tire moves backward relative to the vehicle body while moving backward. Therefore, the rear portion of the front tire mainly comes into contact with a portion of the plate member located above the side sill, and there is a possibility that the impact load is not sufficiently transmitted and distributed to the side sill.

  Therefore, even when the front tire moves backward relative to the vehicle body at the time of the front collision, the present invention applies the impact load input to the vehicle front end portion to the rear side of the vehicle via the front tire. It is an object of the present invention to provide a front structure of an automobile that can be satisfactorily transmitted and dispersed in a vehicle body.

  In order to solve the above-described problems, the present invention is configured as follows.

  First, the invention according to claim 1 of the present application includes a front hinge pillar provided at the rear of the front tire, an apron reinforcement extending forward from an upper portion of the front hinge pillar, and the front front of the front A connecting member for connecting the hinge pillar and the apron reinforcement in a brace form is provided.

  According to a second aspect of the present invention, in the vehicle front structure according to the first aspect, the connection member has a closed cross-sectional structure.

  According to a third aspect of the present invention, there is provided the front structure of the automobile according to the first or second aspect, wherein the front hinge pillar and the apron reinforcement are in the vicinity of the connection portion and the length of the connecting member. A reinforcing member is provided to connect the substantially middle portion in the direction.

  According to a fourth aspect of the present invention, in the front structure of the automobile according to the third aspect, a front pillar extends rearward and upward from an upper end portion of the front hinge pillar, and the reinforcing member It arrange | positions so that it may be located substantially on the extension line of a pillar, It is characterized by the above-mentioned.

  According to a fifth aspect of the present invention, in the front structure of the automobile according to any one of the first to fourth aspects, the front hinge pillar has a closed cross-sectional structure extending vertically. In the internal space, a connecting portion of the connecting member is provided with a node that partitions the space up and down.

  According to a sixth aspect of the present invention, there is provided the front structure of the automobile according to any one of the first to fifth aspects, wherein the front tire extends in the vehicle longitudinal direction inside the front tire in the vehicle width direction. A side frame is provided, and the front side frame is provided with a bent portion for bending the frame toward the outside of the vehicle when an impact load is applied from the front of the vehicle body. The scheduled portion is provided in front of the damper so that when the front side frame is bent toward the outside of the vehicle, the frame comes into contact with the damper of the suspension for the front tire from the front. To do.

  According to a seventh aspect of the present invention, there is provided a vehicle front structure according to any one of the first to sixth aspects, wherein the movable member is movably provided on the connecting member or the reinforcing member. When the impact load is input to the vehicle body from approximately the front of the vehicle body, there is provided a movement holding means for moving the moving member forward and downward toward the rear portion of the front tire and holding the moving member at this moving position. It is characterized by that.

  Next, the effect of the present invention will be described.

  First, according to the first aspect of the present invention, a connecting member for connecting the front hinge pillar and the apron reinforcement in a brace form is provided on the rear upper side of the front tire. Thus, when the front tire moves backward relative to the vehicle body while retracting, the front tire comes into contact with the connecting member. In that case, since the connecting member is provided between the front hinge pillar and the apron reinforcement, which are usually high in rigidity, the front tire that is to move rearward and upward can be reliably received by the connecting member. Become. Therefore, the impact load input to the front tire from the front end side of the vehicle body at the time of the front collision is transmitted and distributed to the apron reinforcement and the front hinge pillar via the connecting member. In addition, this apron reinforcement and the front hinge pillar are also transmitted and distributed to the vehicle body behind the apron reinforcement (for example, the front pillar and the side sill). Hereinafter, the apron reinforcement, the front hinge pillar, and the like including the rear vehicle body will be referred to as appropriate.

  If no nose dive occurs, the front tire moves rearward and directly contacts the front end of the front hinge pillar. In this case, the impact load is directly distributed and transmitted to the front hinge pillar. As a result, the same effect as in the prior art can be obtained.

  In addition, the provision of the connecting member improves the vehicle body rigidity at the normal time of the front part of the vehicle body and improves running stability and the like, and also improves the impact resistance of the front part of the vehicle body at the time of a front collision. Can also be obtained.

  Further, according to the invention described in claim 2, since the connecting member has a closed cross-sectional structure, the rigidity of the member increases, and the effect can be obtained more reliably.

  According to the invention of claim 3, there is provided a reinforcing member for connecting the vicinity of the connecting portion between the front hinge pillar and the apron reinforcement and the substantially intermediate portion in the longitudinal direction of the connecting member. The impact load is transmitted and distributed to the front hinge pillar, the apron reinforcement and the like through the reinforcing member.

  According to the invention described in claim 4, the reinforcing member is arranged so as to be substantially located on the extension line of the front pillar, so that the load input to the reinforcing member is also efficiently applied to the front pillar. It will be transmitted and distributed.

  According to the invention described in claim 5, the front hinge pillar has a closed cross-sectional structure extending vertically, and a node for partitioning the space up and down is formed at a connection portion of the connecting member in the internal space. Since it is provided, the rigidity of the connecting portion of the connecting member in the front hinge pillar increases, and as a result, the load input to the front hinge pillar through the connecting member is reliably received by the pillar.

  Further, in the invention described in claim 6, the front side frame extending in the vehicle longitudinal direction inside the front tire in the vehicle width direction is folded toward the vehicle outer side when an impact load is applied from the front of the vehicle body. A bent portion to be bent is provided, and the bent portion is arranged so that when the front side frame is bent to the outside of the vehicle, the frame comes into contact with the damper of the suspension from the front. It is provided in front of the damper. In this case, when the front side frame comes into contact with the damper, a large impact load from the front of the vehicle body is input from the front side frame to the front tire via the damper. According to the present invention, this large load is applied. It is possible to effectively transmit and disperse to the front hinge pillar, apron reinforcement and the like through the connecting member.

  According to the seventh aspect of the present invention, when an impact load is input substantially from the front of the vehicle body, the moving member movably provided on the connecting member or the reinforcing member is directed toward the rear portion of the front tire. Since the front tire moves rearward and upward, the tire comes into contact with the moving member earlier than the contact with the connecting member or the reinforcing member. It will be. Therefore, the impact load input to the front end of the vehicle body is faster than the case where no moving member is provided, and the front hinge pillar, apron reinforcement, etc. are passed through the front tire, the moving member, the connecting member or the reinforcing member. Will be transmitted and distributed.

  Further, the contact between the tire and the moving member restricts further upward movement of the tire, and as a result, the tire moves rearward toward the front hinge pillar and hits the lower side of the connecting member and the front hinge pillar. You will be in touch. Therefore, it is possible to efficiently transmit and disperse the impact load to the front hinge pillar.

  Here, when the tires are retracted, the left and right tires may be inclined in a letter C shape (the rear side becomes wider) in a plan view, and in this case, the rear part of the tire abuts the front part of the front hinge pillar from the front. In this embodiment, the rear part of the tire and the moving member abut against each other at an early stage after the front collision, so that the rear part of the tire is constrained by the moving member, and the left and right tires have a square shape as described above. It will be suppressed to open in the shape. Therefore, the rear portions of the left and right tires are in good contact with the front hinge pillar, and the impact load is transmitted from the tire to the front hinge pillar.

  Further, even when the space between the rear portion of the front tire and the front end portion of the front hinge pillar is narrow, the moving member can be disposed using the connecting member or the reinforcing member.

  Hereinafter, a front structure of an automobile according to an embodiment of the present invention will be described.

  As shown in FIG. 1, a dash panel 2 that partitions an engine room Z1 in which an engine is housed and a passenger compartment Z2 in which an occupant is boarded is provided at the front of the vehicle body 1 according to the present embodiment.

  Front and rear pillars 3 (only one of which is shown) that extend in the vertical direction and pivotally support a front door (not shown) are provided at both left and right ends of the dash panel 2. The front hinge pillar 3 has a closed cross-sectional structure extending vertically.

  A pair of left and right apron reinforcements 4 and 4 extend forward from the upper end side of the left and right hinge pillars 3.

  A pair of left and right front side frames 5 and 5 extend in the longitudinal direction of the vehicle body at a position substantially parallel to the apron reinforcements 4 and 4 in a plan view and spaced inward in the vehicle width direction.

  A wheel house 6 for a front tire is provided between the apron reinforcement 4 and the front side frame 5 in the vehicle width direction.

  A flat plate 7 is attached to the front end portions of the front side frame 5 and the apron reinforcement 4 across the front side frame 5 and the apron reinforcement 4. A bumper reinforcement 9 extending in the vehicle width direction is attached between the left and right plates 7 and 7 via crush cans 8 and 8. The crash cans 8, 8 are configured to compress and deform in the longitudinal direction of the vehicle body when an impact load in the longitudinal direction of the vehicle body is input.

  The lower portion of the dash panel 2 is curved rearward, and the lower end portion is joined to the front end portion of the floor panel 10. The lower portion of the dash panel 2 and the floor panel 10 are provided with a tunnel portion 11 that extends in the front-rear direction at the approximate center in the vehicle width direction and bulges upward.

  The rear side of the front side frame 5 is curved downward on the side of the wheel house 6, and the rear end is connected to the front end of the floor frame 12 that extends in the vehicle longitudinal direction on the lower surface side of the floor panel 10. ing. The floor frame 12 has a hat-like cross section, and forms a closed cross section that extends in the vehicle longitudinal direction with the floor panel 10.

  A side sill 13 extends rearward from the lower end of the front hinge pillar 3. The side sill 13 has a closed cross-sectional structure extending in the longitudinal direction of the vehicle body.

  A front pillar 17 extends rearward and upward from the upper end of the front hinge pillar 3. The front pillar 17 has a closed cross-sectional structure extending rearward and upward.

  The lower and upper front hinge pillars 3, 3 are connected to the lower side and the upper side of the dash panel 2, and the lower dash cross member 14 that forms a closed section extending in the vehicle width direction with the panel 2, and the upper dash cross A member (not shown) is provided.

  The wheel house 6 is formed by causing the rear side of the apron panel 19 to bulge upward in an arch shape. The apron panel 19 has an outer end in the vehicle width direction joined to the apron reinforcement 4 and an inner end in the vehicle width direction joined to the front side frame 5. A suspension tower portion 6a is formed on the upper portion of the wheel house 6 by causing the apron panel 19 to bulge upward in a tower shape.

  A cowl portion 40 extending in the vehicle width direction is provided on the upper portion of the dash panel 2.

  Next, the front suspension 30 for the front tire 30 and its mounting structure will be described with reference to FIGS. A suspension support frame 20 is provided below the front side frame 5. The suspension support frame 20 has a substantially rectangular frame shape in plan view, and left and right side portions 20a and 20a extend back and forth substantially below the front side frames 5 and 5, respectively. And, the front end side of the left and right side portions 20a, 20a is at the lower part near the front end part of the front side frames 5, 5, and the rear side from the middle in the front-rear direction is below the curved parts 5a, 5a of the front side frames 5, 5. The rear end side is attached to a cross member (not shown) provided on the front end side of the floor panel 10 via a bracket, a mount rubber or the like.

  The front suspension 30 is of a double wishbone type, and includes a wheel support 31 (not shown in FIG. 2) that rotatably supports the front tire W, and an upper arm 32 and a lower arm 33 that are spaced apart from each other in the vertical direction. And a shock absorber 34.

  Suspension support members 37 and 38 are attached to the surface of the apron panel 19 on the side opposite to the engine room Z1 of the suspension tower portion 6a.

  The upper arm 32 has an A shape, and its inner ends 32a and 32a in the vehicle width direction are attached so as to be rotatable about shaft members 32A and 32A that are supported by brackets 37 and 38 and extend in the longitudinal direction of the vehicle body. ing. On the other hand, the vehicle width direction outer end portions 32b and 32b are attached to the upper end portion of the upward extending portion 31a formed on the wheel support 31 via a ball joint.

  Like the upper arm 32, the lower arm 33 has an A shape, and inner ends 33a, 33a in the vehicle width direction are formed on the support walls provided on the side portions 20a, 20a of the suspension support frame 20 in the vehicle longitudinal direction. The shaft members 33A and 33A that extend are attached so as to be rotatable. On the other hand, the vehicle width direction outer end portions 33b and 33b are attached to the lower end portion of the downward extension portion 31b formed on the wheel support 31 via a ball joint.

  The shock absorber 34 includes a damper 35 and a coil spring 36. The damper 35 has an upper end fixed to the top portion 6a 'of the suspension tower 6a, and a lower end attached to the middle portion in the vehicle width direction of the lower arm 33 so as to be swingable about a shaft member 35A extending in the longitudinal direction of the vehicle body. ing. The coil spring 36 is attached to the damper 35 so as to be extendable and contractible.

  A suspension attachment portion reinforcing member 23 that reinforces the attachment portion of the shock absorber 34 is provided on the top surface of the top portion 6a ′ of the suspension tower portion 6a.

  Next, the structures of the front hinge pillar 3, the apron reinforcement 4, and the front side frame 5 will be described in order.

  As shown in FIG. 4, the front hinge pillar 3 has a closed cross section extending in the vertical direction by connecting an outer member 31 bulging outward in the vehicle width direction and an inner member 32 bulging inward in the vehicle width direction. It is configured as a structure. The front pillar 17 has substantially the same structure as the front hinge pillar 3.

  As can be seen from FIGS. 1 and 2, the apron reinforcement 4 is composed of a portion 4A in front of the suspension tower 6a and a rear portion 4B. The front portion 4A and the rear portion 4B have a closed cross-sectional structure that extends continuously in the longitudinal direction of the vehicle body.

  For example, as shown in FIG. 3, the rear portion 4B is composed of an apron outer panel 41 that constitutes the outer surface of the upper portion of the wheel house 6 and an apron rain member 42 having a hat-shaped cross section that bulges outward in the vehicle width direction. A closed cross section extending in the direction is formed. Further, the rear portion 4B has a greater load resistance against the impact load from the front of the vehicle body than the front portion 4A.

  As can be seen from FIG. 3, the front side frame 5 is formed by joining a cross-sectional hat-shaped outer member 51 bulging outward in the vehicle width direction and a cross-sectional hat-shaped inner member 52 bulging inward in the vehicle width direction. Thus, a hollow closed cross section having a substantially rectangular cross section extending in the longitudinal direction of the vehicle body is formed.

  As can be seen from FIGS. 1 and 2, the front side frame 5 is composed of a front part 5A and a rear part 5B with respect to the suspension tower 6a. Different materials are used for the front portion 5A and the rear portion 5B. For example, the front portion 5A can be compressed and deformed in a bellows shape when an impact load is input while maintaining the required rigidity during normal operation. Thus, for example, it is formed using materials, such as a high tension material. on the other hand. The rear portion 5B is configured such that, for example, by increasing the thickness of the material, the load resistance against an impact load from the front of the vehicle body is greater than that of the front portion 5A, and compression deformation is less likely to occur.

  The outer member 51 and the inner member 52 of the front portion 5A are respectively formed with concave beads 5e and 5f extending in the longitudinal direction of the vehicle body. Here, the beads 5e and 5f are provided to increase the amount of absorption of impact energy when the front portion 5A of the front side frame 5 is compressed and deformed in the longitudinal direction of the vehicle body.

  Further, as can be seen from FIG. 2, the rear end position of the beads 5e, 5f is located behind the bead 5f on the inner side in the vehicle width direction. Accordingly, when an impact load is applied from the front of the vehicle body, the rear portion of the front side frame 5 is easily bent outward in the vehicle width direction due to the difference in rigidity between the inside and outside of this portion. That is, the front side frame 5 is formed with the planned bending portion T1 in the vicinity of the rear end of the front portion 5A.

  As can be seen from FIG. 1 and FIG. 2, the side surface portion 5b on the inner side in the vehicle width direction of the rear portion 5B of the front side frame 5 (hereinafter, the side surface portion 5b on the inner side in the vehicle width direction is referred to as the inner side surface portion 5b, On the side of the suspension tower 6a, a bead 5g extending in the vertical direction is formed on the side surface 5a on the outer side in the direction. As can be seen from FIG. 5 (a), the bead 5g is recessed outward in the vehicle width direction, and when an impact load is applied to the front side frame 5 from the front of the vehicle body, the bead 5g starts from the bead 5g. It bends to protrude. That is, the bend scheduled portion T2 is configured by the bead 5g. The planned bending portion T2 is provided at a position ahead of the damper 35 by a predetermined amount so as to come into contact with the damper 35 of the front suspension 30 from the front when the front side frame 5 is bent outward. .

  Further, as can be seen from FIG. 2, a bead 5h extending in the vertical direction is formed in the middle of the curved portion 5w on the side surface portion 5a of the front side frame 5 on the outer side in the vehicle width direction. As can be seen from FIG. 5 (b), the bead 5h is recessed inward in the vehicle width direction. When an impact load is applied to the front side frame 5 from the front of the vehicle body as will be described later, the bead 5h is the starting point. As a result, the front portion is bent outward in the vehicle width direction. That is, the bend 5h constitutes the scheduled bending portion T3.

  Further, as can be seen from FIGS. 1 and 3, there is a bracing between the inner side surface portion 5b of the curved portion 5w of the front side frame 5 and the vicinity of the connecting portion of the lower dash cross member 14 to the front side frame 5. A reinforcing member 18 is provided. The reinforcing member 18 is provided in order to prevent the vicinity of the planned bending portion T3 of the frame 5 from being displaced inward in the vehicle width direction when the front side frame 5 is bent. An engine is disposed between the left and right front side frames 5 and 5 at the front bending portion T1 side, and the engine is fixed to the portion near the bending portion T1 in the frame 5. Thus, it is possible to suppress the vicinity of the planned bending portion T1 of the frame 5 from being displaced inward in the vehicle width direction.

  Here, in the present embodiment, as shown in FIGS. 1 to 3, a connecting member 61 that connects the front hinge pillar 3 and the apron reinforcement 4 in a brace manner is provided in the rear upper part of the front tire W. It has been.

  As shown in FIGS. 6 and 7, the connecting member 61 is a hat having a cross-sectional shape, and is attached to the outer surface of the apron outer panel 41 in the vehicle width direction, and forms a closed cross-sectional structure with the surface. . The rear end portion of the apron outer panel 41 is overlapped and joined to the joining flange portion between the outer member 31 and the inner member 32 of the front hinge pillar 3. The rear end portion (lower end portion) of the connecting member 61 is abutted against and joined to the front surface portion of the outer member 31. Further, as can be seen from FIG. 2, the front end portion (upper end portion) of the connecting member 61 is abutted against and joined to the lower surface portion of the apron rain member 42.

  Moreover, in this Embodiment, as shown in FIGS. 1-3, the reinforcement member which connects the connection part of the front hinge pillar 3 and the apron reinforcement 4, and the longitudinal direction substantially intermediate part of the connection member 61 62 is provided.

  The reinforcing member 62 is provided so as to be positioned substantially on the extension line of the front pillar 17. Further, as can be seen from FIGS. 6 and 7, the hollow closed cross-section member has a substantially rectangular cross section, and the lower portion penetrates the connecting member 61 and is joined to the edge of the through opening.

  Further, in the present embodiment, as shown in FIGS. 2 and 4, a node member 63 that forms a node that divides the space up and down is formed at a connection portion of the connecting member 61 in the internal space of the front hinge pillar 3. Is provided.

  Next, functions and effects of the front-rear structure of the automobile according to the present embodiment will be described.

  That is, for example, when a frontal collision between the automobile 1 and the obstacle M occurs and an impact load is input to the bumper reinforcement 9 from the front, the impact is applied to the front side frames 5 and 5 via the crash cans 8 and 8. Load is input.

  Then, as shown in FIG. 8, the crash cans 8, 8 are compressed and deformed in the longitudinal direction of the vehicle body. Further, the front side frame 5 is compressed and deformed in the front-rear direction of the vehicle body at the front portion 5A, and is bent in the vehicle width direction at each of the planned bending portions T1, T2, T3 at the rear portion 5B. Specifically, the bending is performed so that the planned bending portion T2 (front and rear position P3) protrudes outward in the vehicle width direction between the planned bending portions T1 and T3 in the front side frame 5. And a part of impact load is absorbed by this compression deformation and bending.

  In this case, since the planned bending portion T2 is positioned a predetermined amount ahead of the damper 35 of the suspension 30, the portion between the planned bending portions T2 and T3 in the front side frame 5 is the damper 35. It will contact from the front.

  Therefore, the damper 35 (particularly the lower side) is pushed rearward by the abutting front side frame 5 and moves rearward, that is, the tire W moves rearward. When the nose dive occurs, the tire W moves upward relative to the vehicle body while moving backward. Therefore, it is difficult to contact the front hinge pillar 3 and the front end of the side sill 13, or the contact may be delayed.

  However, in the present embodiment, a connecting member 61 that connects the front hinge pillar 3 and the apron reinforcement 4 in a brace form is provided on the rear upper side of the front tire W. When the vehicle moves backward with respect to the vehicle body, the front tire W comes into contact with the connecting member 61 as shown in FIG. In this case, since the connecting member 61 is provided between the front hinge pillar 3 and the apron reinforcement 4, which are usually high in rigidity, the front tire W trying to move rearward and upward is more reliably secured by the connecting member 61. Will be accepted. Therefore, the impact load input to the front tire from the front side frame 5 via the damper 35 (from the front end side of the vehicle body) at the time of the front collision is transmitted to the apron reinforcement 4 and the front hinge pillar 3 via the connecting member 61. , Distributed. Further, it is transmitted and distributed to the vehicle body behind the apron reinforcement 4 and the front hinge pillar 3 (for example, the front pillar 17 and the side sill 13).

  In this case, since the connecting member 61 has a closed cross-sectional structure, the rigidity of the member 61 increases, and the above-described effect can be obtained more reliably.

  Further, since a reinforcing member 62 is provided to connect the vicinity of the connecting portion between the front hinge pillar 3 and the apron reinforcement 4 and the substantially intermediate portion in the longitudinal direction of the connecting member 61, as described above, The load is transmitted and distributed to the front hinge pillar 3, the apron reinforcement 4, and the like through the reinforcing member 62.

  Further, since the reinforcing member 62 is arranged so as to be positioned substantially on the extension line of the front pillar 17, the load input to the reinforcing member 62 is efficiently transmitted and distributed to the front pillar 17. .

  The front hinge pillar 3 has a closed cross-sectional structure extending vertically, and a node member 63 that forms a node that divides the space up and down is provided at a connection portion of the connecting member 61 in the internal space. Therefore, the rigidity of the connecting portion of the connecting member 61 in the front hinge pillar 3 is increased, and as a result, the load input to the front hinge pillar 3 through the connecting member 61 is reliably received by the pillar 3. Become.

  Further, in the present embodiment, the front side frame 5 is provided with the planned bending portion T2 as described above, and the front side frame 5 is bent outside the vehicle. In some cases, the frame 5 is provided so as to come into contact with the damper 35 of the suspension 30 from the front. In this case, when the front side frame 5 comes into contact with the damper 35, the front side frame 5 passes through the damper 35. A large impact load from the front of the vehicle body is input to the tire W. According to the present invention, this large load is applied to the front hinge pillar 3 and the apron reinforcement via the connecting member 61 and the reinforcing member 62. 4 can be effectively transmitted and dispersed.

  In the above description of the operation, the case where nose dive has occurred has been described. However, when no nose dive has occurred, the tire W moves rearward and mainly moves to the front end of the front hinge pillar 3 or the side sill 13. In this case, the impact load is directly dispersed and transmitted to the front hinge pillar 3 and the side sill 13, and the same effect as in the conventional case is obtained.

  Further, since the connecting member 61 and the reinforcing member 62 are provided, the vehicle body rigidity at the normal time of the vehicle body front portion is improved, the running stability is improved, and the front portion of the vehicle compartment Z2 at the time of the front collision. An effect of improving the collision resistance of the nearby vehicle body is also obtained.

  Next, the front structure of the automobile according to the second embodiment of the present invention will be described. In addition, about the component similar to 1st Embodiment, detailed description is abbreviate | omitted and the same code | symbol is used when it is necessary to quote.

  In the second embodiment, in addition to the configuration of the first embodiment, as shown in FIG. 10, the second member moves into the space at the lower end of the reinforcing member 62 (also the internal space of the connecting member 61). The member 80 is disposed, and when the impact load is input to the vehicle body from approximately the front of the vehicle body, the moving member 80 is moved toward the rear portion of the front tire W along the longitudinal direction of the reinforcing member 62. In addition, a movement holding mechanism 81 for holding at this movement position is provided.

  The movement holding mechanism 81 includes a cylinder device 82 and a gas generation device 83 provided on the rear upper side of the moving member 80 in the internal space of the reinforcing member 62 (also inside the connecting member 61), and an input of an impact load to the vehicle body. And a ECU 85 that outputs a gas generation signal to the gas generator 83 when an impact load detection signal is input from the G sensor 85.

  The cylinder 86 of the cylinder device 82 is fixed to the inner surface of the connecting member 61, and the moving member 80 is fixed to the tip of the rod 87 a of the piston 87. In addition, a communication hole 86 a is formed on the bottom surface of the cylinder 86 to introduce the gas generated by the gas generator 83 into the space in the cylinder 86 through the connecting pipe 88.

  Further, the stroke S of the piston 87 is set so that the moving member 80 can move to a position where it comes into contact with the rear portion of the front tire W that moves substantially rearward by an impact load.

  According to the second embodiment, for example, when a front collision or the like occurs in the automobile 1, the impact load is detected by the G sensor 84, and gas is generated from the gas generator 83. Then, this gas flows into the space in the cylinder 86, and the piston 87 moves along the longitudinal direction of the reinforcing member 62 as indicated by an imaginary line. That is, the moving member 80 moves by the stroke S toward the rear portion of the front tire W along the longitudinal direction of the reinforcing member 62. The moving member 80 is held at this moving position by the gas pressure.

  When the front tire W moves upward and rearward as described in the first embodiment, the rear portion of the front tire W contacts the connecting member 61 and the reinforcing member 62 as shown in FIG. It will abut against the moving member 80 earlier than it abuts. Therefore, the impact load input to the front end of the vehicle body is faster than the case where the moving member 80 is not provided, and the front hinge pillar 3 passes through the front tire W, the moving member 80, the connecting member 61, and the reinforcing member 62. And transmitted to the apron reinforcement 4 and the like.

  Further, due to the contact between the tire W and the moving member 80, the tire W is restricted from further upward movement. As a result, the tire W moves rearward toward the front hinge pillar 3, and the lower side of the connecting member 61 and It will contact the front hinge pillar 3. Therefore, it is possible to efficiently transmit and disperse the impact load to the front hinge pillar 3 and the side sill 13 having relatively high rigidity in the vehicle body.

  Here, when the tire W is retracted, the left and right tires W, W may be inclined in a letter C shape (the rear side becomes wider) in plan view. In this case, the rear portion of the tire W is in front of the front hinge pillar 3. In this embodiment, the rear part of the tire W and the moving member 80 are brought into contact with each other at an early stage after the front collision, so that the rear part of the tire W is restrained by the moving member 80 and left and right. The tires W, W are prevented from opening in a C shape as described above. Therefore, the rear portions of the left and right tires W are in good contact with the front hinge pillar 3, and the impact load is transmitted from the tire W to the front hinge pillar 3.

  Even if the space between the rear portion of the front tire W and the front end portion of the front hinge pillar 3 (the space between the rear portion of the front tire W and the front end portion of the side sill 13) is narrow, the front hinge pillar 3 and the apron rain The moving member 80 and the moving holding mechanism 81 can be arranged using the space near the connection portion with the force 4, more specifically, the internal space of the reinforcing member 62 (also the internal space of the connecting member 61). .

  Even when the front tire moves backward relative to the vehicle body while retreating at the time of a front collision, the present invention applies the impact load input to the vehicle front end to the vehicle body behind the vehicle via the front tire. An automobile front structure that can be transmitted and dispersed well can be provided, and can be widely used in the automobile industry.

1 is a perspective view from the front of a vehicle body showing a front structure of an automobile according to an embodiment of the present invention. It is a side view of the vehicle body front right part of the automobile. It is AA sectional drawing of FIG. It is BB sectional drawing of FIG. It is CC sectional drawing ((a) figure) of FIG. 2, DD sectional drawing ((b) figure). It is EE sectional drawing of FIG. It is FF sectional drawing of FIG. It is explanatory drawing of an effect | action (the 1). It is explanatory drawing of an effect | action (the 2). It is a figure equivalent to FIG. 6 about the front part structure of the motor vehicle which concerns on the 2nd Embodiment of this invention. It is explanatory drawing of an effect | action.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Car 3 Front hinge pillar 4 Apron reinforcement 17 Front pillar 30 Suspension 35 Damper 61 Connecting member 62 Reinforcement member 63 Node member (node)
80 moving member 81 moving holding mechanism (moving holding means)
T2 Folding planned part W Front tire

Claims (7)

A front hinge pillar provided behind the front tire;
An apron reinforcement extending forward from the top of the front hinge pillar;
A front structure of an automobile, characterized in that a connecting member for connecting the front hinge pillar and the apron reinforcement in a brace form is provided at a rear upper side of the tire. The front structure of an automobile according to claim 1,
The front structure of an automobile, wherein the connecting member has a closed cross-sectional structure. In the front structure of the automobile according to claim 1 or 2,
A front structure of an automobile, comprising a reinforcing member that connects a vicinity of a connecting portion between the front hinge pillar and an apron reinforcement and a substantially intermediate portion in a longitudinal direction of the connecting member. In the front structure of the automobile according to claim 3,
A front pillar extends rearward and upward from the upper end of the front hinge pillar,
The front structure of an automobile, wherein the reinforcing member is disposed so as to be generally located on an extension line of the front pillar. In the front part structure of the automobile according to any one of claims 1 to 4,
The front hinge pillar has a closed cross-sectional structure extending vertically.
A front structure of an automobile, wherein a node for vertically dividing the space is provided at a connection portion of the connecting member in the internal space. In the front structure of the automobile according to any one of claims 1 to 5,
A front side frame that extends in the vehicle longitudinal direction inside the front tire in the vehicle width direction is provided,
The front side frame is provided with a planned bending portion that bends the frame toward the outside of the vehicle when an impact load is input from the front of the vehicle body.
In addition, the bent portion is provided in front of the damper so that when the front side frame is bent outward, the frame comes into contact with the damper of the front tire suspension from the front. A front structure of an automobile, characterized in that In the front structure of the automobile according to any one of claims 1 to 6,
A moving member movably provided on the connecting member or the reinforcing member;
When an impact load is input to the vehicle body from approximately the front of the vehicle body, there is provided a moving holding means for moving the moving member forward and downward toward the rear portion of the front tire and holding the moving member at this moving position. The front structure of an automobile characterized by

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