JP6130509B2 - Body front structure - Google Patents

Description

  The present invention relates to an improved technique for a front bulkhead and its surroundings in a front part of a vehicle body such as a passenger car.

  In a general vehicle, as in the vehicle body front structure known from Patent Document 1, the left and right front side frames that are located at the front of the vehicle body and extend in the vehicle front-rear direction, and the left and right front side frames The front bulkhead provided between the front end portions of the main component is a main component. In many cases, a power unit including an engine is disposed in a space surrounded by the left and right front side frames and the front bulkhead.

  The power unit is one of the most important functional parts, and is generally disposed at a relatively low position in the front part of the vehicle body. When the vehicle travels on a substantially horizontal flat road surface and enters a steep uphill from the flat road surface, the power unit may be in contact with the road surface, that is, rubbed. However, it is not preferable that an important functional component such as a power unit contacts the road surface from the viewpoint of vehicle protection. On the other hand, it is conceivable to increase the installation height of the power unit. However, there is a limit because the center of gravity of the vehicle body goes up. It is also conceivable to significantly increase the strength of the lower surface of the power unit. However, since the weight of the power unit is greatly increased, there is room for improvement.

JP 2013-032038 A

  This invention makes it a subject to provide the technique which can protect the power unit arrange | positioned at the front part of a vehicle body easily from the outside.

According to the first aspect of the present invention, the left and right front side frames located in the front portion of the vehicle body and extending in the longitudinal direction of the vehicle body and the front bulkhead provided between the front end portions of the left and right front side frames are provided. In the vehicle body front structure in which a power unit including an engine can be disposed in the enclosed space, a lower end portion of the front bulkhead is configured by a bulkhead lower member extending in the vehicle width direction, and the front bulkhead Left and right side portions of the head are constituted by left and right bulkhead side members extending upward from left and right ends of the bulkhead lower member, and left and right projecting members projecting downward on the lower surface of the bulkhead lower member And the left and right projecting members are the left and right bulkheads in the lower surface of the bulkhead lower member. In the vicinity just below the lower end of Idomenba, located respectively, the left and right reinforcing member for reinforcing the left and right bulkhead side member, further comprising, the left and right reinforcements along the left and right bulkhead side members The left and right bulkhead side members are joined to the left and right bulkhead side members, and at least part of the lower ends of the left and right reinforcing members are joined to the bulkhead lower members together with the left and right projecting members, The bulkhead side member includes vertical plate-shaped left and right wall portions whose plate surfaces face the vehicle width direction and extend in the vertical direction, and the left and right reinforcing members are joined to the vehicle width direction inner surfaces of the left and right wall portions. There is provided a vehicle body front structure comprising left and right inner surface reinforcing members and left and right outer surface reinforcing members joined to outer surfaces in the vehicle width direction of the left and right wall portions .

  As described in claim 2, preferably, the bottom surfaces of the left and right projecting members are set to a height that can be positioned lower than the lowest end of the power unit.

  Preferably, the front part of the bottom surfaces of the left and right projecting members is inclined upward toward the front of the vehicle body.

As described in claim 4, preferably, the left and right projecting member includes a left and right bottom plate consists of a left and right side plates extending upwardly from the edge of the left and right of the bottom plate, at least one lower end of the left and right side plates The portion is spaced apart from the upper surfaces of the left and right bottom plates by a certain height and overlaps the left and right bottom plates when viewed from the bottom. The constant height is such that the edges of the left and right bottom plates are upward. When deformed, it is set in a range where it can hit the lower ends of the left and right side plates.

As described in claim 5 , preferably, the left and right projecting members are each constituted by a bent product of one plate material.

As described in claim 6 , preferably, work holes are respectively formed on the bottom surfaces of the left and right projecting members.

As described in claim 7 , preferably, the power unit can be mounted, and a subframe attached to the left and right front side frames, and left and right underload paths extending from the subframe toward the front of the vehicle body. The front end portions of the left and right underload paths are attached in the vicinity of the left and right projecting members in the lower surface of the bulkhead lower member.

As described in claim 8, preferably, be capable of mounting the power unit, and the sub-frame attached to the left and right front side frames, left and right of the under load path extending from said subframe to the vehicle front And the front end portions of the left and right underload paths are positioned in the vicinity of the left and right projecting members in the lower surface of the bulkhead lower member, and the bulkhead lower and the left and right reinforcing members. It is attached to the member.

  In the invention according to claim 1, the front bulkhead, which is a kind of strength member located at the front end of the vehicle body, is effectively used. Left and right projecting members projecting downward are joined to the lower surface of the bulkhead lower member. When the vehicle travels on a substantially horizontal flat road surface and enters a steep uphill from the flat road surface, the lowermost end of the power unit approaches the road surface. However, the reaction force from the road surface can be absorbed by at least one of the left and right protruding members contacting the road surface prior to the power unit. Therefore, the power unit can be easily and sufficiently protected from the outside. In addition, since the left and right projecting members simply project downward from the lower surface of the bulkhead lower member, an increase in the weight of the vehicle body can be suppressed as much as possible.

Further, in the invention according to claim 1, the left and right projecting members are located in the lower surface of the bulkhead lower member and immediately below the lower ends of the left and right bulkhead side members. For this reason, when at least one of the left and right projecting members comes into contact with the road surface, the reaction force from the road surface can be transmitted from the projecting member to the lower end of the bulkhead side member via the lower surface of the bulkhead lower member. . The reaction force can also be received by the bulkhead side member. Therefore, since the front bulkhead can absorb the reaction force without being greatly deformed, it can be sufficiently protected so that the reaction unit does not affect the power unit.
In the invention according to claim 1, the left and right bulkhead side members are reinforced by the left and right reinforcing members. The left and right reinforcing members are joined to the left and right bulkhead side members. At least a part of the lower end portions of the left and right reinforcing members are joined to the lower surface of the bulkhead lower member together with the left and right protruding members. For this reason, a large reaction force from the road surface can be transmitted from the protruding member to both the lower end of the bulkhead side member and the lower end of the reinforcing member via the lower surface of the bulkhead lower member. Therefore, the large reaction force can be received by both the bulkhead side member and the reinforcing material. As a result, the front bulkhead can sufficiently absorb the large reaction force without being greatly deformed.
Further, in the invention according to claim 1, the left and right bulkhead side members include vertical plate-shaped left and right wall portions extending in the vertical direction with the plate surfaces facing the vehicle width direction. The left and right reinforcing members are composed of left and right inner surface reinforcing members and left and right outer surface reinforcing members. The left and right inner surface reinforcing members and the left and right outer surface reinforcing members reinforce the left and right bulkhead side members by sandwiching both surfaces of the left and right wall portions. Accordingly, the large reaction force transmitted from the protruding member via the lower surface of the bulkhead lower member can be received by the bulkhead side member, the inner surface reinforcing member, and the outer surface reinforcing member. As a result, the front bulkhead can more sufficiently absorb the large reaction force without being greatly deformed.

  In the invention which concerns on Claim 2, the height of the bottom face of the left and right protrusion members is located lower than the lowest end of the power unit. For this reason, the reaction force from the road surface can be further absorbed by at least one of the bottom surfaces of the left and right protruding members coming into contact with the road surface before the lowermost end of the power unit.

  In the invention which concerns on Claim 3, the front part in the bottom face of a right and left protrusion member inclines upward toward the vehicle body front. When the vehicle enters a steep uphill, the front and lower corners of the left and right protruding members may contact the slope. In this case, in the invention according to claim 3, it is possible to make an inclined surface inclined forward and upward rather than the front and lower corners of the left and right projecting members contact the slope, so-called surface contact. Because of the surface contact, the reaction force (ground load) received by the left and right projecting members from the road surface of the slope can be dispersed. Since the distributed load is transmitted to the vehicle body, it is possible to sufficiently protect the power unit from being affected by the reaction force while ensuring the maximum strength of the vehicle body.

In the invention according to claim 4 , the left and right projecting members include left and right bottom plates and left and right side plates extending upward from the edges of the left and right bottom plates. At least a part of the lower ends of the left and right side plates are separated from the upper surfaces of the left and right bottom plates by a certain height, and overlap the left and right bottom plates as viewed from the bottom. When receiving a large reaction force from the road surface, the edge of the bottom plate is greatly deformed upward and hits the lower end of the side plate. That is, the projecting member can absorb the small reaction force only by the bottom plate when receiving a small reaction force, and can absorb the large reaction force by the bottom plate and the side plate when receiving a large reaction force. Therefore, the projecting member can protect the power unit from being affected by the reaction force by efficiently absorbing the reaction force from the road surface.

In the invention according to claim 5 , the left and right projecting members are each formed by a bent product of one plate material. For this reason, the member for protecting a power unit from the reaction force of a road surface can be manufactured with few parts and a simple structure.

In the invention which concerns on Claim 6 , the hole for work is formed in the bottom face of the right and left protrusion member, respectively. Generally, when assembling a front bulkhead, the positioning member (positioning jig) provided on the assembly table is fitted into the positioning hole of the bulkhead lower member, thereby positioning the bulkhead lower member on the assembly table. To be done. In the invention which concerns on Claim 6 , a positioning member can be fitted to a positioning hole through this work hole.

  That is, depending on the difference in the specifications of the power unit (difference in the size of the power unit), there are cases where the left and right protruding members are necessary and unnecessary. For example, when a small power unit is mounted on a vehicle body of the same size, it may be possible to increase the height of the lowermost end of the power unit. In that case, since the grounding measures of the power unit are not required, the left and right protruding members are unnecessary, and it is only necessary to provide positioning holes in the bulkhead lower member. On the other hand, when left and right projecting members are required, the positioning holes of the same size are provided at the same position of the bulkhead lower member, and work holes are provided on the bottom surfaces of the left and right projecting members.

Thus, in the invention according to claim 6 , it is only necessary to provide positioning holes of the same size at the same position of the bulkhead lower member regardless of whether or not there is a grounding countermeasure. For this reason, it is possible to use the same positioning member (positioning jig) regardless of the presence or absence of grounding measures. Therefore, since the same positioning member can be used for alignment at the same position of the bulkhead lower member, efficient assembly work can be performed.

In the invention according to claim 7 , the left and right underload paths extend from the sub-frame mounting the power unit toward the front of the vehicle body. The front end portions of the left and right underload paths are attached in the vicinity of the left and right projecting members in the lower surface of the bulkhead lower member. Therefore, when the lowermost end of the power unit approaches the road surface, at least one of the left and right projecting members and the left and right underload paths contacts the road surface and absorbs the reaction force from the road surface before the power unit. can do. Therefore, the power unit can be more reliably protected from the outside. For example, even if the left and right protruding members are deformed upward by contacting the road surface many times, the power unit can be protected by the left and right underload paths.

In the invention according to claim 8 , the left and right underload paths extend from the sub-frame mounting the power unit toward the front of the vehicle body. The front end portions of the left and right underload paths are located in the vicinity of the left and right projecting members in the lower surface of the bulkhead lower member, and are attached to the bulkhead lower member together with the left and right reinforcing members that are strength members. . As described above, the fixing portions of the front end portions of the left and right underload paths, the left and right reinforcing members, and the bulkhead lower member can be made high in strength. Therefore, for example, when a collision load acts on the front of the vehicle from the front, so-called front collision, the collision load is sufficiently transmitted from the bulkhead lower member to the subframe via the left and right underload paths and dispersed. Can do. The left and right underload paths and the subframe can efficiently absorb the collision load.

It is a left view of the front part of the vehicle body concerning the present invention. It is the perspective view which looked at the front part of the vehicle body shown in FIG. 1 from the left front. It is the perspective view which looked at the lower left part and left protrusion member of the front bulkhead shown by FIG. 2 from the left back. It is the perspective view which looked at the lower left part and left protrusion member of the front bulkhead shown by FIG. 3 from the front. FIG. 5 is a cross-sectional view taken along line 5-5 in FIG. It is the perspective view which looked at the lower left part and left protrusion member of the front bulkhead shown by FIG. 2 from the front lower part. FIG. 7 is a cross-sectional view taken along line 7-7 in FIG. FIG. 7 is an exploded view of a lower left portion and a left protruding member of the bulkhead lower member shown in FIG. 6. FIG. 9 is a bottom view of the left protruding member shown in FIG. 8. FIG. 10 is a developed view of the left protruding member shown in FIG. 9. It is sectional drawing along the 11-11 line of FIG. FIG. 3 is a perspective view of a connection configuration between a lower left portion and a left underload path of the front bulkhead shown in FIG. 2 as viewed from the front upper side. It is the figure which looked at the connection structure of the lower left part of a bulkhead lower member shown by FIG. 12, and the left underload path | pass from the downward direction.

  EMBODIMENT OF THE INVENTION The form for implementing this invention is demonstrated below based on an accompanying drawing.

  A vehicle body front structure according to an embodiment will be described with reference to the drawings.

  As shown in FIGS. 1 and 2, a vehicle body 11 of a vehicle 10 such as a passenger car is formed of a monocoque body, and substantially extends with respect to a vehicle width center line CL that extends in the vehicle longitudinal direction through the center of the vehicle 10 in the vehicle width direction. Therefore, it is formed symmetrically.

  The vehicle body 11 includes left and right front side frames 12 and 12 that are positioned at the front portion of the vehicle body 11 and extend in the longitudinal direction of the vehicle body, and a front bulkhead provided between the front end portions of the left and right front side frames 12 and 12. 13 and a bumper 14 disposed in front of the front bulkhead 13

  The left and right front side frames 12 and 12 are configured to have a substantially U-shaped cross section when viewed from the front, or a substantially rectangular cross section when viewed from the front.

  The front bulkhead 13 is a frame member having a substantially rectangular shape when viewed from the front, and includes a bulkhead lower member 21 extending in the vehicle width direction, and left and right bulkhead side members 22 erected from both ends of the bulkhead lower member 21. 22 and a bulkhead upper member 23 spanned between the upper ends of the left and right bulkhead side members 22 and 22.

  Thus, the lower end portion of the front bulkhead 13 is constituted by the bulkhead lower member 21 extending in the vehicle width direction. The left and right side portions of the front bulkhead 13 are constituted by left and right bulkhead side members 22, 22 extending upward from the left and right ends of the bulkhead lower member 21. The left and right bulkhead side members 22, 22 are joined to the inner surfaces in the vehicle width direction of the front end portions of the left and right front side frames 12, 12 at substantially center portions in the height direction.

  The left and right bulkhead side members 22 and 22 are configured to have a substantially U-shaped cross section in plan view with the vehicle width direction outer side opened. More specifically, the left and right bulkhead side members 22 and 22 include left and right front walls 22a and 22a facing the front of the vehicle body, and left and right rear walls 22b positioned rearwardly from the left and right front walls 22a and 22a. , 22b, and left and right inner walls 22c, 22c connecting the left and right front walls 22a, 22a and the left and right rear walls 22b, 22b. That is, the vehicle width direction inner ends of the left and right front walls 22a, 22a and the vehicle width direction inner ends of the left and right rear walls 22b, 22b are integrally formed by the left and right inner walls 22c, 22c. The left and right bulkhead side members 22, 22 are configured in a substantially U-shaped cross section in plan view with the vehicle width direction outer side opened.

  The left and right front walls 22a and 22a and the left and right rear walls 22b and 22b are vertical plate-like wall portions extending in the vertical direction with the plate surfaces facing the vehicle body longitudinal direction. The left and right inner walls 22c, 22c are vertical plate-shaped left and right wall portions extending in the vertical direction with the plate surfaces facing the vehicle width direction. That is, the left and right bulkhead side members 22 and 22 include left and right front walls 22a and 22a, left and right rear walls 22b and 22b, and left and right wall portions 22c and 22c.

  The bumper 14 includes left and right bumper brackets 31 and 31 attached to the front surfaces of the left and right front walls 22a and 22a, and a bumper beam 32 spanned between the left and right bumper brackets 31 and 31 and bolted thereto. .

  A power unit 62 (see FIG. 1) can be disposed in a space 61 surrounded by the left and right front side frames 12 and 12 and the front bulkhead 13. The power unit 62 includes a traveling engine 63 and a transmission 64.

  A subframe 65 (see FIG. 1) is attached to the left and right front side frames 12 and 12 from below. The subframe 65 can mount the power unit 62.

  As shown in FIG. 3, the bulkhead lower member 21 has a substantially U-shaped cross section in a side view with the top thereof released. More specifically, the bulkhead lower member 21 includes a front wall 21a facing the front of the vehicle body, a rear wall 21b positioned rearward from the front wall 21a, and the front wall 21a and the rear wall 21b. It consists of the bottom wall 21c to connect. That is, the lower end of the front wall 21a and the lower end of the rear wall 21b are integrally formed by the bottom wall 21c, so that the bulkhead lower member 21 is configured to have a substantially U-shaped cross section when viewed from the side. Yes.

  Further, the bulkhead lower member 21 is integrally formed with a front flange 21d extending forward from the upper end of the front wall 21a and a rear flange 21e extending rearward from the upper end of the rear wall 21b. Each of the members 21a to 21e is formed in a substantially flat plate shape. The lower surface 21f of the bulkhead lower member 21, that is, the lower surface 21f of the bottom wall 21c is formed on a substantially horizontal flat surface.

  In this embodiment, a front bulkhead 13 which is a kind of strength member located at the front end of the vehicle body 11 is effectively used. That is, as shown in FIGS. 1 to 3, left and right projecting members 70, 70 projecting downward are joined to the lower surface 21 f of the bulkhead lower member 21. The bottom surfaces 71a and 71a of the left and right projecting members 70 and 70 are formed on a substantially horizontal flat surface. The bottom surfaces 71a and 71a of the left and right projecting members 70 and 70 are so-called bottom members set to a height H1 that can be positioned lower than the lowest end 62a (see FIG. 1) of the power unit 62. . For example, the bottom surfaces 71 a and 71 a of the left and right projecting members 70 and 70 are positioned lower than the lowest front end 62 a of the power unit 62 by the height H 1.

  When the vehicle 10 travels on a substantially horizontal flat road surface and enters a steep uphill from the flat road surface, the lowermost end 62a of the power unit 62 approaches the road surface. However, the reaction force from the road surface can be absorbed by at least one of the bottom surfaces 71a and 71a of the left and right projecting members 70 and 70 contacting the road surface prior to the lowermost end 62a of the power unit 62. Therefore, the power unit 62 can be easily and sufficiently protected from the outside. Moreover, since the left and right projecting members 70 and 70 project downward from the lower surface 21f of the bulkhead lower member 21, an increase in the weight of the vehicle body 11 can be suppressed as much as possible.

  As shown in FIGS. 1, 4, and 5, the left and right protruding members 70, 70 are located immediately below the lower ends of the left and right bulkhead side members 22, 22 in the lower surface 21 f of the bulkhead lower member 21. Respectively. Therefore, when at least one of the bottom surfaces 71a and 71a of the left and right projecting members 70 and 70 is in contact with the road surface, a reaction force from the road surface is transmitted from the projecting members 70 and 70 to the lower surface 21f of the bulkhead lower member 21. Thus, it can be transmitted to the lower ends of the bulkhead side members 22 and 22. The reaction force can also be received by the bulkhead side members 22 and 22. Therefore, since the front bulkhead 13 can absorb the reaction force without being greatly deformed, the front bulkhead 13 can be sufficiently protected so that the power unit 62 is not affected by the reaction force.

  Hereinafter, the left protruding member 70 will be described in detail. The right projecting member 70 has the same configuration as the left projecting member 70, and a description thereof will be omitted.

  As shown in FIGS. 5 to 8, the left protruding member 70 is formed in a box shape having a substantially rectangular shape when viewed from the bottom and having an open top, and includes a left bottom plate 71, a left bottom plate 71 and a left bottom plate 71. The left side plate 72 extends upward from the edge 71b. The bottom plate 71 has a substantially rectangular shape in a bottom view, and has a substantially horizontal flat bottom surface 71a. The bottom surface 71a forms the bottom surface of the protruding member 70 as described above. The bottom surface 71a of the bottom plate 71 is referred to as “the bottom surface 71a of the protruding member 70” as appropriate.

  The side plate 72 is formed in a frame shape extending upward from the edge 71b so as to surround the edge 71b of the bottom plate 71 over substantially the entire circumference. Hereinafter, the side plate 72 is referred to as “the left vertical frame 72” as appropriate. The left vertical frame 72 includes a front plate 81 facing the front of the vehicle body, a rear plate 82 positioned away from the front plate 81 rearward, an outer plate 83 facing outward in the vehicle width direction, and a vehicle width direction. It consists of an inner plate 84 facing inward.

  A front flange 85, a rear flange 86, an outer flange 87, and an inner flange 88 are integrally formed on the upper edge of the vertical frame 72. The front flange 85 is an elongated flat plate extending upward from the front end of the upper edge of the left vertical frame 72 (the upper end of the front plate 81). The rear flange 86 is an elongated flat plate extending upward from the rear end of the upper edge of the vertical frame 72 (the upper end of the rear plate 82). The outer flange 87 is a flat plate that extends outward in the vehicle width direction from the outer side in the vehicle width direction (the upper end of the outer plate 83) in the upper edge of the vertical frame 72. The inner flange 88 is a flat plate extending inward in the vehicle width direction from the inner side in the vehicle width direction (the upper end of the inner plate 84) in the upper edge of the vertical frame 72.

  The upper end of the vertical frame 72 is overlaid on the lower surface 21 f of the bulkhead lower member 21. The front flange 85 is overlapped and joined to the front wall 21a. The rear flange 86 is overlapped and joined to the rear wall 21b. The outer flange 87 and the inner flange 88 are overlapped and joined to the bottom wall 21c. As a result, the left projecting member 70 is joined to the bulkhead lower member 21 and projects downward from the lower surface 21 f of the bulkhead lower member 21.

  5 to 7, at least a part of the lower end of the side plate 72, that is, the lower ends 81a and 82a of the front plate 81 and the rear plate 82 are fixed with respect to the upper surface 71c of the bottom plate 71. While being separated by a height H2, it overlaps the bottom plate 71 in a bottom view (see FIG. 7). The constant height H2 is set in a range in which the lower edge 81a, 82a of the side plate 72 can be hit when the edge 71b of the bottom plate 71 is deformed upward. More specifically, the lower ends 81a and 82a of the front plate 81 and the rear plate 82 of the vertical frame 72 are spaced apart from the upper surface 71c of the bottom plate 71 by a height H2. Moreover, the lower ends 81 a and 82 a of the front plate 81 and the rear plate 82 are positioned on the edge 71 b of the upper surface 71 c of the bottom plate 71.

  For this reason, when the edge 71b of the bottom plate 71 receives a large reaction force from the road surface, the edge 71b is greatly deformed upward, whereby the lower ends 81a and 82a of the side plate 72 (each of the front plate 81 and the rear plate 82). It hits the lower end 81a, 82a). That is, the left protruding member 70 absorbs the small reaction force only by the bottom plate 71 when receiving a small reaction force, and the large reaction force by the bottom plate 71 and the side plate 72 when receiving a large reaction force. Can absorb power. Therefore, the protruding member 70 can protect the power unit 62 (see FIG. 1) from being affected by the reaction force by efficiently absorbing the reaction force from the road surface.

  As shown in FIGS. 1, 2, 6, and 7, the front portions of the bottom surfaces 71 a and 71 a of the left and right projecting members 70 and 70 are inclined upward toward the front of the vehicle body 11. That is, forwardly rising inclined surfaces 71d and 71d are formed in front portions of the bottom surfaces 71a and 71a. The inclination angle of the inclined surfaces 71d and 71d with respect to the substantially horizontal bottom surfaces 71a and 71a is α. The inclination angle α is set to an optimum value for each vehicle type of the vehicle 10 in consideration of the relationship between the vehicle body 11 and the power unit 62, preferably in the range of 5 ° to 15 °, particularly preferably 10 °. Is set.

  When the vehicle 10 travels on a substantially horizontal flat road surface and enters a steep uphill, the front and lower corners of the left and right projecting members 70 and 70 may contact the slope. In this case, in the present embodiment, the inclined surfaces 71d and 71d inclined forward and upward, not the front and lower corners, of the left and right protruding members 70 and 70 can be brought into contact with the slope, so-called surface contact. . Because of the surface contact, the reaction force (ground load) received by the left and right projecting members 70, 70 from the road surface of the slope can be dispersed. Since the distributed load is transmitted to the vehicle body, it is possible to sufficiently protect the power unit 62 from being affected by the reaction force while ensuring the maximum strength of the vehicle body 11.

  As shown in FIGS. 2, 5, and 6, circular work holes 73 (only the left are shown) are formed in the bottom surfaces 71 a and 71 a of the left and right projecting members 70 and 70, respectively.

  In general, when the front bulkhead 13 is assembled, a positioning member (positioning jig) (not shown) provided on an assembly table (not shown) is attached to the left and right positioning holes 74 (only the left side) of the bulkhead lower member 21. The bulkhead lower member 21 is positioned on the assembly table by fitting to the assembly table. On the other hand, in this embodiment, the positioning member can be fitted into the positioning hole 74 through the work hole 73.

  That is, depending on the difference in the specifications of the power unit 62 shown in FIG. 1 (difference in the size of the power unit 62), there are cases where the left and right protruding members 70, 70 are necessary and unnecessary. For example, when a small power unit 62 is mounted on the vehicle body 11 of the same size, there is a possibility that the height of the lowermost end 62a of the power unit 62 can be increased. In that case, since the grounding measures of the power unit 62 are not necessary, the left and right projecting members 70 are not necessary, and the bulkhead lower member 21 only needs to be provided with the positioning hole 74. On the other hand, when left and right projecting members are required, the positioning holes 74 and 74 having the same size are provided at the same position of the bulkhead lower member 21, and the bottom surfaces 71a and 71a of the left and right projecting members 70 and 70 are provided. Work holes 73 and 73 are provided.

  As described above, in this embodiment, the positioning holes 74 and 74 having the same size may be provided at the same position of the bulkhead lower member 21 regardless of the presence or absence of grounding measures. For this reason, it is possible to use the same positioning member (positioning jig) regardless of the presence or absence of grounding measures. Therefore, since the same positioning member can be used to align the bulkhead lower member 21 at the same position, efficient assembly work can be performed.

  As shown in FIGS. 8 to 10, the left projecting member 70 is configured by a bent product of one plate material. For this reason, the member for protecting the power unit 62 (see FIG. 1) from the reaction force of the road surface can be manufactured with a small number of parts and a simple configuration. The right protruding member 70 is the same as the left protruding member 70.

  A configuration in which the left protruding member 70 is developed is shown in FIG. As shown in FIG. 10, a substantially H-shaped blank 90 (blanks, also referred to as a metal piece or a blank material) is taken from a plate material, and the blank 90 is bent and processed as shown in FIG. 8 and FIG. 9. A box-shaped protruding member 70 can be obtained.

  The broken line La shown in FIG. 10 is a mountain fold line, and the imaginary line Lb is a valley fold line. By bending the blank 90, the H-shaped central portion 91 (the portion 91 corresponding to the central position of the H-shape) becomes the bottom plate 71 of the left protruding member 70 shown in FIG. Similarly, the first right piece 92 on the right side of the central portion 91 becomes an outer plate 83. The second right piece 93 further right adjacent to the first right piece 92 becomes an outer flange 87. A first left piece 94 adjacent to the left of the central portion 91 serves as an inner plate 84. The second left piece 95 adjacent to the left of the first left piece 94 is an inner flange 88.

  The upper right extension piece 92a extending upward from the upper end of the first right piece 92 and the upper left extension piece 94a extending upward from the upper end of the first left piece 94 are bent, overlapped and joined. Thus, the front plate 81 of the protruding member 70 is configured.

  A lower right extension piece 92b extending downward from the lower end of the first right piece 92 and a lower left extension piece 94b extending downward from the lower end of the first left piece 94 are bent, overlapped and joined. Thus, the rear plate 82 of the projecting member 70 is configured.

  The upper right piece 92c extending rightward from the upper right extension piece 92a serves as the front flange 85. The lower right piece 92d extending rightward from the lower right extension piece 92b serves as a rear flange 86.

  As shown in FIGS. 2 and 5, the left and right bulkhead side members 22, 22 are reinforced by left and right reinforcing members 100, 100. That is, the left and right reinforcing members 100, 100 extend in the vertical direction along the left and right bulkhead side members 22, 22, and are joined to the left and right bulkhead side members 22, 22. Further, at least a part of the lower ends of the left and right reinforcing members 100, 100 are joined to the bulkhead lower member 21 together with the left and right protruding members 70, 70.

  Therefore, a large reaction force from the road surface is applied to the lower ends of the bulkhead side members 22 and 22 and the lower ends of the reinforcing members 100 and 100 from the protruding members 70 and 70 via the lower surface 21f of the bulkhead lower member 21. , Can tell both. Therefore, the large reaction force can be received by both the bulkhead side members 22 and 22 and the reinforcing members 100 and 100. As a result, the front bulkhead 13 can sufficiently absorb the large reaction force without being greatly deformed.

  As shown in FIGS. 2, 3, 5 and 11, the left and right reinforcing members 100, 100 are joined to the outer surfaces in the vehicle width direction of the left and right inner walls 22c, 22c (left and right wall portions 22c, 22c). Left and right outer surface reinforcing members 101, 101 and left and right inner surface reinforcing members 111, 111 joined to inner surfaces in the vehicle width direction of the left and right inner walls 22c, 22c. The left and right outer surface reinforcing members 101 and 101 and the left and right inner surface reinforcing members 111 and 111 reinforce the left and right bulkhead side members 22 and 22 by sandwiching both surfaces of the left and right inner walls 22c and 22c. .

  Hereinafter, the relationship between the lower left of the front bulkhead 13, the left protruding member 70, and the left reinforcing member 100 will be described in detail with reference to FIGS. 3, 4, 5, and 11. Since the relationship between the lower right of the front bulkhead 13, the right protruding member 70, and the right reinforcing member 100 is the same as that of the lower left of the front bulkhead 13, the description thereof is omitted.

  The lower end portion of the left bulkhead side member 22 is sandwiched between the front wall 21 a and the rear wall 21 b of the bulkhead lower member 21.

  The left outer surface reinforcing member 101 is formed in a substantially U-shaped cross section in plan view with the vehicle width direction outer side opened. More specifically, the left outer surface reinforcing member 101 includes a left front wall 102 facing the front of the vehicle body, a left rear wall 103 positioned rearward from the left front wall 102, and the left front wall 102. It consists of a left inner wall 104 connecting the wall 102 and the left rear wall 103.

  The left outer surface reinforcing member 101 is sandwiched between the front wall 22 a and the rear wall 22 b of the left bulkhead side member 22.

  The upper half of the left outer reinforcing member 101 has the inner wall 104 overlapped with the inner wall 22c of the left bulkhead side member 22, the front wall 102 is joined to the front wall 22a of the left bulkhead side member 22, and the rear wall. 103 is joined to the rear wall 22 b of the left bulkhead side member 22.

  The lower half of the left outer surface reinforcing member 101 is inclined so as to fall away from the inner wall 22c outward in the vehicle width direction. As shown in FIG. 11, in the lower half of the left outer surface reinforcing member 101, the front wall 21a, the front wall 22a, and the front wall 102 are joined together, and the rear wall 21b and the rear wall are joined together. 22b and the rear wall 103 are joined together.

  As shown in FIGS. 5 and 11, a lower flange 105 is formed at the lower end of the left outer surface reinforcing member 101 from the inner wall 104 toward the outer side in the vehicle width direction. The lower flange 105 is overlapped on the bottom wall 21c of the bulkhead lower member 21 and joined to the bottom wall 21c together with the outer flange 87 of the left protruding member 70.

  On the other hand, as shown in FIGS. 5, 11 and 12, the left inner surface reinforcing member 111 is a vertically long and slender vertical plate-like member, and its edge in the longitudinal direction of the vehicle body is slightly folded. The left inner reinforcing member 111 is overlapped with the inner wall 22c of the left bulkhead side member 22, and is joined to the inner wall 22c together with the inner wall 104 of the upper half of the left outer reinforcing member 101.

  A lower flange 112 directed inward in the vehicle width direction is formed at the lower end of the left inner surface reinforcing member 111. The lower flange 112 is overlaid on the bottom wall 21c of the bulkhead lower member 21 and joined to the bottom wall 21c together with the inner flange 88 of the left protruding member 70.

  As described above, as shown in FIG. 2, the left and right reinforcing members 100, 100 are composed of left and right outer surface reinforcing members 101, 101 and left and right inner surface reinforcing members 111, 111. Accordingly, the large reaction force transmitted from the left and right projecting members 70, 70 via the lower surface of the bulkhead lower member 21 is applied to the left and right bulkhead side members 22, 22 and the left and right outer surface reinforcing members 101, 101 and the left and right inner surface reinforcing members 111, 111. As a result, the front bulkhead 13 can absorb the large reaction force more sufficiently without being greatly deformed.

  Further, as shown in FIGS. 1 and 2, the vehicle body 11 includes left and right underload paths 120, 120 extending from the subframe 65 toward the front of the vehicle body. Front end portions 121 and 121 (see FIG. 12) of the left and right underload paths 120 and 120 are attached in the vicinity of the left and right projecting members 70 and 70 in the lower surface 21 f of the bulkhead lower member 21.

  Hereinafter, the left underload path 120 will be described in detail with reference to FIGS. 1, 6, 12, and 13. The right underload path 120 has the same configuration as that of the left underload path 120, and a description thereof will be omitted.

  The front end portion 121 of the left underload path 120 is located in the lower surface 21f of the bulkhead lower member 21 in the vicinity of the left protruding member 70, together with the left reinforcing member 100 (particularly the left inner surface reinforcing member 111). The bulkhead lower member 21 is attached by bolts 122. A rear end portion 123 of the left underload path 120 is attached to the subframe 65 with a bolt 124.

  The bottom surfaces 125, 125 of the left and right underload paths 120, 120 are set to a height H3 that can be positioned lower than the lowermost end 62a of the power unit 62. For example, the bottom surfaces 125, 125 of the left and right underload paths 120, 120 are positioned lower than the lowest front end 62a in the power unit 62 by the height H3.

  Therefore, when the lowermost end 62a of the power unit 62 approaches the road surface, the bottom surfaces 71a and 71a of the left and right projecting members 70 and 70 and the left and right underload paths 120, before the lowermost end 62a of the power unit 62, At least one of the bottom surfaces 125 of the 120 is in contact with the road surface, and the reaction force from the road surface can be absorbed. Therefore, the power unit 62 can be more reliably protected from the outside. For example, even when the bottom surfaces 71a and 71a of the left and right projecting members 70 and 70 are deformed upward by contacting the road surface many times, the power unit 62 is protected by the left and right underload paths 120 and 120. Can do.

  Further, as described above, the left and right underload paths 120, 120 extend from the subframe 65 on which the power unit 62 is mounted toward the front of the vehicle body. The front end portions 121 and 121 of the left and right underload paths 120 and 120 are positioned in the vicinity of the left and right projecting members 70 and 70 in the lower surface 21f of the bulkhead lower member 21, and are strengthened to the left and right as strength members. Along with the materials 100 and 100, the bulkhead lower member 21 is attached.

  In this way, the fixing portions of the front end portions 121, 121 of the left and right underload paths 120, 120, the left and right reinforcing members 100, 100, and the bulkhead lower member 21 can be made high in strength. Therefore, for example, when a collision load acts on the front of the vehicle 10 from the front, so-called front collision, the collision load is sufficiently applied to the subframe 65 from the bulkhead lower member 21 via the left and right underload paths 120 and 120. Can be distributed to. The left and right underload paths 120 and 120 and the subframe 65 can absorb the collision load efficiently.

  The vehicle body front structure of the present invention is suitable for use in a configuration having a sub-frame 65 on which a power unit 62 is mounted and an underload path 120 in a vehicle body 11 of a vehicle 10 such as a passenger car.

DESCRIPTION OF SYMBOLS 10 Vehicle 11 Vehicle body 12 Front side frame 13 Front bulkhead 21 Bulkhead lower member 21f Lower surface of bulkhead lower member 22 Bulkhead side member 22c Wall portion (inner wall) of bulkhead side member
61 Space 62 Power unit 62a Bottom end of power unit 63 Engine 65 Subframe 70 Projection member 71 Bottom plate 71a Bottom surface of projection member 71b Edge of bottom plate 71c Top surface of bottom plate 71d Inclined surface 72 Side plate (vertical frame)
73 Work hole 74 Positioning hole 81a Lower end of side plate 82a Lower end of side plate 100 Reinforcement material 101 Outer surface reinforcement member 111 Inner surface reinforcement member 120 Underload path 125 Bottom surface of underload path H1 Height from bottom surface of projecting member to bottom end of power unit H3 Height from the bottom of the underload path to the lowest end of the power unit α Inclination angle of the inclined surface

Claims (8)

The engine is contained in a space enclosed by the left and right front side frames that are positioned in the front part of the vehicle body and extend in the longitudinal direction of the vehicle body, and the front bulkhead provided between the front end portions of the left and right front side frames. In the vehicle body front structure where the power unit can be placed,
The lower end portion of the front bulkhead is constituted by a bulkhead lower member extending in the vehicle width direction,
The left and right sides of the front bulkhead are configured by left and right bulkhead side members extending upward from left and right ends of the bulkhead lower member,
Left and right projecting members projecting downward are joined to the lower surface of the bulkhead lower member,
The left and right projecting members are respectively located in the lower surface of the bulkhead lower member, just below the lower ends of the left and right bulkhead side members ,
Left and right reinforcing members for reinforcing the left and right bulkhead side members,
The left and right reinforcing members extend in the vertical direction along the left and right bulkhead side members, and are joined to the left and right bulkhead side members,
At least a part of the lower ends of the left and right reinforcing members are joined to the bulkhead lower member together with the left and right protruding members,
The left and right bulkhead side members include left and right wall portions in the form of vertical plates whose plate surfaces extend in the vertical direction facing the vehicle width direction,
The left and right reinforcing members include left and right inner surface reinforcing members joined to the inner surfaces in the vehicle width direction of the left and right wall portions, and left and right outer surface reinforcing members joined to the outer surfaces in the vehicle width direction of the left and right wall portions. A vehicle body front structure characterized by that.   The vehicle body front part structure according to claim 1, wherein bottom surfaces of the left and right projecting members are set to a height that can be positioned lower than a lowermost end of the power unit.   The vehicle body front part structure according to claim 1, wherein a front part of the bottom surfaces of the left and right projecting members is inclined upward toward the front of the vehicle body. The left and right projecting members include left and right bottom plates and left and right side plates extending upward from the edges of the left and right bottom plates,
At least a part of the lower ends of the left and right side plates are spaced apart from the upper surfaces of the left and right bottom plates by a certain height, and overlap the left and right bottom plates in a bottom view,
2. The vehicle body front structure according to claim 1, wherein the certain height is set in a range in which when the edges of the left and right bottom plates are deformed upward, they can hit the lower ends of the left and right side plates.   The vehicle body front part structure according to claim 1, wherein the left and right projecting members are each formed by a bent product of one plate material.   The vehicle body front part structure according to claim 1, wherein work holes are respectively formed on the bottom surfaces of the left and right projecting members. The power unit can be mounted, and a subframe attached to the left and right front side frames;
Left and right underload paths extending from the subframe toward the front of the vehicle body,
The vehicle body front part structure according to claim 1, wherein front end portions of the left and right underload paths are attached in the vicinity of the left and right projecting members in a lower surface of the bulkhead lower member. The power unit can be mounted, and a subframe attached to the left and right front side frames;
Left and right underload paths extending from the subframe toward the front of the vehicle body,
Front end portions of the left and right underload paths are located in the vicinity of the left and right projecting members in the lower surface of the bulkhead lower member, and are attached to the bulkhead lower member together with the left and right reinforcing members. The vehicle body front part structure according to claim 1 .

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