JP5862554B2 - Auto body structure - Google Patents

Description

  The present invention relates to an automobile body structure in which a bumper beam extension made of FRP is disposed between a body frame extending in the front-rear direction and a bumper beam extending in the vehicle width direction.

  An inner bumper beam extension and an outer bumper beam extension made of steel plates bent into a polygonal cylinder are arranged between the bumper beam and the connecting plate, and the front side frame is connected to the rear end of the inner bumper beam extension with the connecting plate interposed therebetween, Japanese Patent Application Laid-Open No. H11-228707 discloses a structure in which an upper member is connected to a rear end of an outer bumper beam extension with a connecting plate interposed therebetween.

JP 2012-35703 A

  However, since the bumper beam extension is made of a steel plate, the one described in Patent Document 1 not only increases the weight, but the thickness of one steel plate is constant, so that it corresponds to the input collision load. Therefore, it is difficult to freely set the intensity distribution of each bumper beam extension, and the degree of freedom in layout is low because the impact load is supported not only by the front side frame but also by the upper member.

  The present invention has been made in view of the above circumstances, and aims to optimize the shock absorbing performance of the bumper beam extension according to the distribution of the magnitude of the input collision load while reducing the weight of the bumper beam extension. And

  To achieve the above object, according to the first aspect of the present invention, a vehicle body of an automobile in which a bumper beam extension made of FRP is disposed between a body frame extending in the front-rear direction and a bumper beam extending in the vehicle width direction. The bumper beam extension comprises a main impact absorbing portion and a secondary impact absorbing portion which are formed of groove-like recesses that are separated in the vehicle width direction and extend in the front-rear direction, and have a plate thickness of the secondary impact absorbing portion. Is set to be smaller than the plate thickness of the main impact absorbing portion.

  According to the invention described in claim 2, in addition to the configuration of claim 1, the bumper beam extension includes a main closed cross-sectional portion configured by combining a pair of the main impact absorbing portions into a closed cross-section, A vehicle body structure for an automobile is provided, comprising a sub-closed cross-section portion configured by combining a pair of sub-impact absorbers to form a closed cross-section.

  According to the invention described in claim 3, in addition to the configuration of claim 1 or claim 2, the main impact absorbing portion is formed by laminating discontinuous fiber reinforced resin layers on both the inner and outer surfaces of the continuous fiber reinforced resin layer. A vehicle body structure for an automobile is proposed in which the sub-impact absorber is configured by laminating a discontinuous fiber reinforced resin layer only on the outer surface of the continuous fiber reinforced resin layer.

  According to the invention described in claim 4, in addition to the configuration of any one of claims 1 to 3, discontinuous fibers are formed on the outer surfaces of the main impact absorbing portion and the secondary impact absorbing portion. Ribs made of thermoplastic resin are formed in the front-rear direction, and ribs made of discontinuous fibers made of thermoplastic resin are formed on the inner surface of the main impact absorbing portion in a direction inclined with respect to the front-rear direction. A vehicle body structure characterized by the above is proposed.

  According to the invention described in claim 5, in addition to the configuration of any one of claims 1 to 4, the bumper beam extension is bent in a direction intersecting the input direction of the collision load. A vehicle body structure is proposed which includes a flange in which discontinuous fibers are hardened with a thermoplastic resin, and the bumper beam is connected to the flange.

  According to the invention described in claim 6, in addition to the configuration of claim 3, the continuous fibers of the continuous fiber reinforced resin layer of the main impact absorbing portion have a first direction which is an input direction of a collision load. A vehicle body structure is proposed in which the main shock absorbing portion is oriented in a second direction perpendicular to the first direction, and the main impact absorbing portion includes a ridge line that forms a corner portion along the input direction of the collision load.

  According to the invention described in claim 7, in addition to the configuration of claim 2, the sub closed cross-section portion is provided continuously outside the main closed cross-section portion in the vehicle width direction, and the main closed cross-section portion is A vehicle body structure for an automobile is proposed in which the vehicle body frame is linearly connected to an outer end in the front-rear direction of the body frame, and the sub-closed cross section is connected to a side surface of the body frame via a brace member.

  According to the invention described in claim 8, in addition to the configuration of claim 7, the front-rear direction outer end of the sub-closed cross-section portion is located on the front-rear direction inner side than the front-rear direction outer end of the main closed cross-section portion. A vehicle body structure is proposed which is characterized by

  The front side frame front portion 14 of the embodiment corresponds to the vehicle body frame of the present invention, and the first sub impact absorbing portion 18b and the second sub impact absorbing portion 18c of the embodiment are included in the sub impact absorbing portion of the present invention. Correspondingly, the first sub-closed cross-section portion 23 and the second sub-closed cross-section portion 24 of the embodiment correspond to the sub-closed cross-section portion of the present invention, and the front fastening flanges 51b and 52b of the embodiment are flanges of the present invention. The first reinforcing ribs 51h and 52h and the second reinforcing ribs 51i and 52i in the embodiment correspond to the ribs of the present invention.

  According to the configuration of the first aspect, the bumper beam extension made of FRP is disposed between the vehicle body frame and the bumper beam. The bumper beam extension is integrally provided with a main impact absorbing portion and a secondary impact absorbing portion made of a groove-like recess extending in the front-rear direction and spaced apart in the vehicle width direction, and the thickness of the secondary impact absorbing portion is set to the plate of the primary impact absorbing portion. Since it is set smaller than the thickness, the main shock absorbing part is the main shock absorbing area with relatively high shock absorbing capacity, and the sub shock absorbing part is the sub shock absorbing area with relatively low shock absorbing capacity. The shock absorbing performance of the bumper beam extension can be optimized according to the distribution of the magnitude of the input collision load. Further, since the bumper beam extension is made of FRP, it is lighter than that made of steel plate, and the weight can be further reduced by reducing the thickness of the sub impact absorbing portion.

  According to the second aspect of the present invention, the bumper beam extension includes a main closed cross-sectional portion configured by combining a pair of main impact absorbing portions to form a closed cross-section and a pair of sub-impact absorbing portions configured by a closed cross-section. Therefore, the impact absorbing performance can be enhanced by suppressing the opening of the main impact absorbing portion and the sub impact absorbing portion by closing the main impact absorbing portion and the sub impact absorbing portion.

  According to the configuration of claim 3, the main impact absorbing portion is formed by laminating discontinuous fiber reinforced resin layers on both the inner and outer surfaces of the continuous fiber reinforced resin layer, and the secondary impact absorbing portion is formed outside the continuous fiber reinforced resin layer. Since the discontinuous fiber reinforced resin layer is laminated only on the surface, it is easy to set the plate thickness of the sub impact absorbing portion smaller than the plate thickness of the main impact absorbing portion. Moreover, when a collision load is input to the main impact absorbing portion, the continuous fiber reinforced resin layer supports the tensile load, and the discontinuous fiber reinforced resin layers on both the inner and outer surfaces support the compressive load. In addition to improving the shock absorption performance by suppressing delamination, the continuous fiber reinforced resin layer supports the tensile load and compresses the discontinuous fiber reinforced resin layer on the outer surface when a collision load is input to the secondary shock absorber. By supporting the load, delamination of the continuous fiber reinforced resin layer can be suppressed and the shock absorbing performance can be enhanced.

  According to the fourth aspect of the present invention, since the ribs formed by discontinuous fibers hardened with the thermoplastic resin are formed in the front-rear direction on the outer surfaces of the main impact absorbing portion and the secondary impact absorbing portion, the ribs support the compressive load. As a result, delamination of the continuous fiber reinforced resin layer can be suppressed more reliably, and ribs made of discontinuous fibers hardened with thermoplastic resin on the inner surface of the main impact absorbing portion are inclined with respect to the front-rear direction. Therefore, even if a collision load of an oblique collision is input, delamination of the continuous fiber reinforced resin layer can be suppressed.

  According to the fifth aspect of the present invention, the bumper beam extension is provided with a flange which is bent in a direction crossing the input direction of the collision load and the discontinuous fibers are hardened with the thermoplastic resin, and the bumper beam is connected to the flange. Therefore, when a collision load is input from the bumper beam to the bumper beam extension, the flange with a large pressure receiving area is triggered (triggering to cause destruction), and the bumper beam extension is sequentially crushed in the front-rear direction to improve shock absorption performance. Can be increased.

  According to the configuration of claim 6, the continuous fibers of the continuous fiber reinforced resin layer of the main impact absorbing portion are oriented in the first direction which is the input direction of the collision load and the second direction orthogonal thereto. And since the main impact absorbing portion includes a ridge line that forms a corner portion along the input direction of the collision load, when the ridge line that forms the corner portion is deformed so as to spread radially outward by the collision load, the main shock absorbing portion is oriented in the second direction. The formed continuous fiber can be stretched to increase the amount of shock absorption.

  According to the seventh aspect of the present invention, the auxiliary closed cross-section portion is connected to the outer side in the vehicle width direction of the main closed cross-section portion, and the main closed cross-sectional portion is linearly connected to the outer end in the front-rear direction of the vehicle body frame. Since the cross-section is connected to the side of the body frame via a brace member, it is possible not only to ensure impact absorption performance while reducing the longitudinal dimension of the front part of the body, but also to efficiently handle the collision load at the time of offset collision Can be absorbed into.

  According to the configuration of the eighth aspect, since the front-rear outer end of the sub-closed cross-section is located on the inner side in the front-rear direction than the front-rear outer end of the main closed cross-section, The shock absorption performance can be improved by inputting the input to the outer end in the front-rear direction of the closed cross-section and triggering the crushing to sequentially collapse the bumper beam extension in the front-rear direction.

The perspective view of the vehicle body front part of a motor vehicle. (First embodiment) FIG. 2 is a two-direction arrow view of FIG. 1. (First embodiment) The perspective view of a bumper beam. (First embodiment) FIG. 4 is an enlarged view of part 4 of FIG. 1. (First embodiment) FIG. 5 is an enlarged view of part 5 of FIG. 2. (First embodiment) FIG. 6 is a sectional view taken along line 6-6 of FIG. (First embodiment) FIG. 7 is a cross-sectional view taken along line 7-7 of FIG. (First embodiment) The exploded perspective view of a bumper beam extension. (First embodiment) 9 (A)-9 (D) direction arrow directional view of FIG. (First embodiment) Explanatory drawing of the manufacturing method of a bumper beam extension. (First embodiment) Action | operation explanatory drawing at the time of the input of a collision load. (First embodiment) Action | operation explanatory drawing at the time of the input of a collision load. (First embodiment) Action | operation explanatory drawing at the time of the input of a collision load. (First embodiment) Action | operation explanatory drawing of the weak part of a bumper beam extension. (First embodiment) The figure corresponding to FIG. (Second Embodiment)

First embodiment

  Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. In the present specification, the front-rear direction (impact load input direction), the left-right direction (vehicle width direction), and the up-down direction are defined with reference to the passenger seated in the driver's seat.

  As shown in FIGS. 1 and 2, the vehicle body of the embodiment includes a cabin 11 integrally formed in a bathtub shape with FRP such as CFRP (carbon fiber reinforced resin), and a dash panel 12 standing from its front end. A pair of left and right suspension support members 13, 13 that are die-cast with an aluminum alloy are fixed to the front surface. The suspension support members 13 and 13 include damper housings 13a and 13a that support upper ends of suspension dampers (not shown), and front side frame rear portions 13b and 13b that are connected to lower portions of the damper housings 13a and 13a and extend forward. A pair of left and right front side frame front parts 14, 14 made of an aluminum extruded material or a steel plate press material are connected to the front ends of the front side frame rear parts 13b, 13b. A pair of left and right FRP side members 16, 16 are connected to front ends of a pair of left and right FRP upper members 15, 15 extending forward from the left and right upper portions of the dash panel 12.

  A front bulkhead 17 made of FRP formed in a rectangular frame shape in front view is fixed to the front ends of the front side frame front portions 14, 14, and the front ends of the side members 16, 16 are located on the upper left and right sides of the front bulkhead 17. Connected. A pair of left and right FRP bumper beam extensions 18, 18 are fixed to the front ends of the front side frame front portions 14, 14, and an FRP bumper beam 19 extending in the vehicle width direction at the front ends of the bumper beam extensions 18, 18. Is fixed. The front surface of the bumper beam 19 is covered with a bumper face 20. An FRP shroud 21 formed in a rectangular frame shape when viewed from the front is disposed at a position surrounded by the front bulkhead 17, the bumper beam 19, and the pair of left and right bumper beam extensions 18, 18. Further, cooling system components (not shown) such as an engine cooling radiator, an air conditioning condenser, and a battery cooling radiator are overlapped and supported in the front-rear direction.

  Next, the structure of the bumper beam 19 is demonstrated based on FIG. 3 and FIG.

  The bumper beam 19 made of FRP includes a rear body portion 31 and front initial load absorbing portions 32. The main body 31 includes a pair of U-shaped cross-sections 33, 33 that have an upper wall 33a, a lower wall 33b, and a bottom wall 33c and that open toward the front. The upper flange 33d and the lower flange 33e of the upper U-shaped section 33 are overlapped in the front-rear direction and welded together to form a substantially W-shaped section. Inside the U-shaped cross-section 33, a plurality of vertical ribs 33f that extend in the vertical direction and connect the upper wall 33a, the lower wall 33b, and the bottom wall 33c are separated by a predetermined distance in the longitudinal direction of the bumper beam 19. Formed. The upper flange 33d of the upper U-shaped cross section 33 and the lower flange 33e of the lower U-shaped cross section 33 are formed with a plurality of pins 33g projecting forward. A plurality of fastening collars 34 are inserted into the bottom wall 33c of the U-shaped cross section 33.

  The initial load absorbing portions 32 are divided into three in the longitudinal direction of the bumper beam 19, and each has substantially the same structure. Each initial load absorbing portion 32 includes a flat connecting wall 32a, and a plurality of vertical ribs 32b and a plurality of horizontal ribs 32c formed on the front surface of the connecting wall 32a. The vertical ribs 32b extending in the vertical direction and the horizontal ribs 32c extending in the left-right direction intersect with each other in a lattice shape. Pin holes 32d, into which the pins 33g of the main body 31 can be fitted, are formed on the upper and lower edges of the connecting wall 32a. The initial load absorbing portion 32 is coupled to the main body portion 31 by fitting the pins 33g of the main body portion 31 into the pin holes 32d of the initial load absorbing portion 32 and melting the pins 33g with a vibration tool.

  Next, the structure of the bumper beam extension 18 will be described with reference to FIGS.

  The bumper beam extension 18 is configured by connecting the upper member 51 and the lower member 52, and the planar shape thereof is a trapezoidal shape or a triangular shape. That is, the inner end in the vehicle width direction of the bumper beam extension 18 extends linearly in the front-rear direction, the inner end (rear end) in the front-rear direction extends linearly in the vehicle width direction, and the outer end (front end) in the front-rear direction extends in the vehicle width direction. The outer side is inclined to the inner side in the front-rear direction (rear side). Therefore, the front-rear width of the bumper beam extension 18 is the largest at the inner end in the vehicle width direction and the smallest at the outer end in the vehicle width direction. Since the upper member 51 and the lower member 52 of the bumper beam extension 18 have a substantially plane symmetrical structure, the structure will be described below with the upper member 51 as a representative.

  The upper member 51 includes an inner layer portion made of continuous fiber reinforced resin, and an outer layer portion made of discontinuous fiber reinforced resin that covers the entire outer surface and a part of the inner surface of the inner layer portion. The inner layer portion is displayed in a dark color in FIGS. 8 and 9, and the outer layer portion is displayed in a light color in FIGS. 8 and 9.

  The upper member 51 in which the continuous fiber reinforced resin and the discontinuous fiber reinforced resin are laminated is manufactured as follows. As shown in FIG. 10A, a mold 55 for press-molding the upper member 51 of the bumper beam extension 18 includes a female die 56 having a concave cavity 56a for molding the outer surface of the upper member 51, and the upper member 51. Are formed in the cavity 56a and the core 57a, and grooves 56b, 57b,... Are formed in the cavity 56a and the core 57a. With the mold 55 opened, a first prepreg 58 of discontinuous fiber reinforced resin, a second prepreg 59 of continuous fiber reinforced resin, and a third discontinuous fiber reinforced resin are formed on the cavity 56a of the female mold 56. The prepreg 60 is disposed in a preheated state.

  The second prepreg 59 is composed of two layers of carbon fiber continuous fibers UD (sheets of continuous fibers aligned in one direction) laminated in two directions at 0 ° and 90 °, and the first and third prepregs. 58 and 60 are made of carbon fiber discontinuous fiber mats as reinforcements, and are impregnated with a thermoplastic resin (nylon 6, nylon 66, polypropylene, etc.). A plurality of preheated prepregs are inserted into a mold in a laminated state and subjected to pressure molding, and then cooled to obtain a fiber reinforced resin product.

  The length of the discontinuous fibers of the first prepreg 58 and the third prepreg 60 of the discontinuous fiber reinforced resin is 0.9 mm to 100 mm, but is preferably about 50 mm from the viewpoint of impact absorption performance. In order to achieve both cost and impact absorption performance, the fiber of each prepreg 58, 59, 60 is preferably glass fiber, and the thermoplastic resin is preferably nylon 6 or nylon 66.

  When the male mold 57 is lowered with respect to the female mold 56, the second prepreg 59 is pressed by the cavity 56a of the female mold 56 and the core 57a of the male mold 57, and the upper member 51 is molded. At this time, since the first and third prepregs 58 and 60 using the discontinuous fiber as a reinforcing material can be easily deformed, the first prepreg 58 sandwiched between the second prepreg 59 and the cavity 56a of the female die 56 is It flows into the grooves 56b of the cavity 56a, and the ribs and the like on the outer surface of the upper member 51 are simultaneously formed and laminated in a thin film shape along the entire outer surface of the upper member 51. Similarly, the third prepreg 60 sandwiched between the second prepreg 59 and the core 57a of the male mold 57 flows into the grooves 57b of the core 57a, and simultaneously molds ribs and the like on the inner surface of the upper member 51, The upper member 51 is laminated in a thin film shape along a part of the inner surface of the upper member 51 (part forming a closed cross section). And the upper member 51 is completed by cut | disconnecting the excess part of the outer periphery of the product taken out from the metal mold | die 55. FIG.

  As shown in an enlarged circle in FIG. 8, among the continuous fibers 61 of the second prepreg 59, one continuous fiber 61 is oriented in the front-rear direction, and the other continuous fiber 62 is the vehicle width. Oriented in the direction. Further, the discontinuous fibers 63 of the first and third prepregs 58 and 60 are entangled randomly.

  A continuous fiber reinforced resin having a long fiber UD as a reinforcing material has a relatively high strength. However, since there is a limit to the amount of deformation of the UD, the moldability is low, and it is difficult to mold thin and high ribs. It is. On the other hand, discontinuous fiber reinforced resin having short fibers that are randomly intertwined as a reinforcing material has a relatively low strength, but because the fibers are easily deformed, the moldability is high, and thin and high ribs are formed. Easy to do. Therefore, by laminating the discontinuous fiber reinforced resin on the continuous fiber reinforced resin and molding the upper member 51, the strength and formability of the upper member 51 can be compatible.

  The upper member 51 formed as described above includes a main body 51a extending in the vehicle width direction while being bent into a corrugated plate shape in a substantially trapezoidal or substantially triangular shape in plan view, and upward from the front edge of the main body 51a. The front fastening flange 51b to be bent, the rear fastening flange 51c to be bent upward from the rear edge of the main body 51a, and the four joints 51d to 51g extending in the vehicle width direction on the inner surface of the main body 51a in the front-rear direction. With. First reinforcing ribs 51h... Intersecting in three directions at intervals of 60 ° are formed on the inner surface between the two joining portions 51d and 51e with at least two discontinuous fiber reinforced resins in the front-rear direction (the first reinforcing ribs in FIG. 8). 52h), the second reinforcing ribs 51i that extend in the front-rear direction and connect the front fastening flange 51b and the rear fastening flange 51c on the outer surface of the main body 51a are also discontinuous fiber reinforced resin. Formed with. Further, three nuts 64 are inserted into the front fastening flange 51b of the discontinuous fiber reinforced resin, and three fastening holes 51j are formed in the rear fastening flange 51c of the discontinuous fiber reinforced resin (FIG. 8). reference). Furthermore, a slit 51n that extends linearly in the front-rear direction from the vicinity of the front fastening flange 51b to the vicinity of the rear fastening flange 51c is formed in the joint 51e (see FIGS. 5 and 8).

  Since the lower member 52 has the same shape that is substantially plane-symmetric with the upper member 51 described above, the same subscript as the subscript of each part of the upper member 51 is added to the reference numeral 52 of the lower member 52 so as to overlap. Description is omitted. The only difference between the upper member 51 and the lower member 52 is that the lower member 52 includes a plurality of pins 52k that protrude upward from the four joint portions 52d to 52g, whereas the upper member 51 includes the pins 52k. It is a point provided with a plurality of pin holes 51m which can be fitted (see FIG. 8).

  As apparent from FIGS. 4 and 7, the main closed cross-section portion 22 of the bumper beam extension 18 is formed by vertically coupling the main impact absorbing portions 18a and 18a having a square cross-sectional shape of the upper member 51 and the lower member 52. The first sub-closed cross-section portion 23 and the second sub-closed cross-section portion 24 of the bumper beam extension 18 are composed of a first sub-impact absorbing portion in which the upper member 51 and the lower member 52 form a groove shape having a circular arc cross section. 18b, 18b and the second sub-impact absorbers 18c, 18c are connected vertically.

  9 and 10B, the main closed cross-section 22 of the bumper beam extension 18 includes a first prepreg 58 of discontinuous fiber reinforced resin, a second prepreg 59 of continuous fiber reinforced resin, and discontinuous fibers. The third prepreg 60 made of a reinforced resin has a three-layer structure. The first sub-closed cross-section portion 23 and the second sub-closed cross-section portion 24 of the bumper beam extension 18 are formed by disposing the third prepreg 60 made of discontinuous fiber reinforced resin. A discontinuous fiber reinforced resin first prepreg 58 and a continuous fiber reinforced resin second prepreg 59 and a laminated two-layer structure are not included.

  Accordingly, the outer surfaces of the upper member 51 and the lower member 52 are all covered with the first prepreg 58 made of discontinuous fiber reinforced resin, and the inner surfaces of the upper member 51 and the lower member 52 are partially made of the continuous fiber reinforced resin. The second prepreg 59 is exposed, and the other part is covered with the third prepreg 60 of discontinuous fiber reinforced resin. The plate thickness T2 of the first sub-closed section 23 and the second sub-closed section 24 of the two-layer structure is smaller than the plate thickness T1 of the main closed section 22 of the three-layer structure (FIG. 10B )reference).

  The upper member 51 and the lower member 52 having the above-described shapes are configured such that the pins 52k of the lower member 52 are fitted into the pin holes 51m of the upper member 51 so that the joint portions 51d to 51g and 52d to 52g are brought into contact with each other. In this state, the tips of the pins 52k... Are melted together by a vibrating tool from the upper member 51 side (see FIG. 7). In this state, the rear fastening flanges 51c and 52c of the upper member 51 and the lower member 52 are linearly aligned in the vertical direction, but the front fastening flanges 51b and 52b of the upper member 51 and the lower member 52 are tilted forward. (See FIG. 6).

  The bumper beam extension 18 in which the upper member 51 and the lower member 52 are coupled to each other includes a rectangular cylindrical main closed cross-sectional portion 22 that is located on the inner side in the vehicle width direction and extends in the front-rear direction, and an elliptic cylindrical shape adjacent to the outer side in the vehicle width direction. The first sub closed section 23 and an elliptic cylindrical second sub closed section 24 adjacent to the outside in the vehicle width direction are provided (see FIG. 7). The cross-sectional areas of the first and second sub closed cross-section portions 23 and 24 are equal to each other and smaller than the cross-sectional area of the main closed cross-section portion 22. Further, the width in the front-rear direction of the substantially triangular bumper beam extension 18 in plan view is gradually narrowed from the inner side to the outer side in the vehicle width direction, so that the main closed cross section 22 is the longest in the front-rear direction, and then The first sub closed section 23 is long and the second sub closed section 24 is the shortest (see FIG. 5).

  The front side frame front portion 14 is disposed behind the first sub impact absorbing portion 18b (first sub closed cross-section portion 23) and the second sub impact absorbing portion 18c (second sub closed cross-section portion 24) of the bumper beam extension 18. The front surfaces of the front wheels 65 located on the outer side in the vehicle width direction face each other (see FIGS. 2 and 5).

  Next, the mounting structure of the bumper beam extension 18 to the front bulkhead 17 and the bumper beam 19 will be described with reference to FIGS.

  A mounting plate 81 made of a metal plate is welded to the front end of the front side frame front portion 14, and a bracing member 82 made of a metal plate is attached to the vehicle width direction outer end of the mounting plate 81 and the vehicle width direction outer surface of the front side frame front portion 14. Are welded. Then, six bolts 83 that pass through the rear fastening flanges 51c and 52c of the bumper beam extension 18 from front to rear are screwed into weld nuts 84 provided on the rear surface of the mounting plate 81, so that the bumper beam extension 18 and the front are fixed. The bulkhead 17 is fastened together with the mounting plate 81.

  Further, bolts 85 penetrating through the fastening collars 34 inserted into the main body 31 of the bumper beam 19 from the front to the rear are screwed into nuts 64 inserted into the front fastening flanges 51 b and 52 b of the bumper beam extension 18. The bumper beam 19 is fastened to the front ends of the bumper beam extensions 18 and 18.

  Next, the operation of the embodiment of the present invention having the above configuration will be described.

  The collision load input from the bumper beam 19 to the bumper beam extension 18 due to the frontal collision of the vehicle is transmitted to the front side frame front part 14 via the mounting plate 81 and the bracing member 82, so that the collision load is transmitted to the front side frame front part. 14 can be efficiently transmitted.

  At this time, the bumper beam extension 18 is integrally provided with a main shock absorbing portion 18a and first and second sub shock absorbing portions 18b and 18c which are separated in the vehicle width direction and extend in the front-rear direction, and first and second sub shock absorbing portions. Since the plate thickness T2 of the portions 18b and 18c is smaller than the plate thickness T1 of the main shock absorbing portion 18a, the main shock absorbing portion 18a is a main shock absorbing region having a relatively high shock absorbing capacity, and the first and second sub By making the shock absorbing portions 18b and 18c a sub shock absorbing region having a relatively low shock absorbing capability, the shock absorbing performance of the bumper beam extension 18 is optimized according to the distribution of the magnitude of the input collision load. Can do. Further, by making the bumper beam extension 18 made of FRP, it is lighter than that made of steel plate, and the weight of the first and second sub-impact absorbers 18b, 18c is further reduced by further reducing the thickness. Can do.

  In particular, the bumper beam extension 18 is formed by coupling a pair of main impact absorbing portions 18a to form a closed main section 22 and a pair of first and second auxiliary impact absorbing portions 18b and 18c. Since the first and second sub-closed cross-section portions 23 and 24 configured in a cross section are provided, the main impact absorbing portion 18a and the first and second sub-impact absorbing portions 18b and 18c are closed to suppress opening. The shock absorption performance can be improved.

  The main impact absorbing portion 18a is configured by laminating discontinuous fiber reinforced resin layers on both the inner and outer surfaces of the continuous fiber reinforced resin layer, and the first and second sub impact absorbing portions 18b and 18c are formed outside the continuous fiber reinforced resin layer. Since the discontinuous fiber reinforced resin layer is laminated only on the surface, the plate thickness T2 of the first and second secondary shock absorbers 18b and 18c is set smaller than the plate thickness T1 of the main shock absorber 18a. Becomes easier.

  As shown in FIG. 11, when a collision load is input to the main impact absorbing portion 18a, the continuous fiber reinforced resin layer supports the tensile load, and the discontinuous fiber reinforced resin layers on both the inner and outer surfaces support the compressive load. The continuous fiber reinforced resin layer suppresses delamination of the continuous fiber reinforced resin layer to enhance the impact absorbing performance, and when the collision load is input to the first and second sub impact absorbing portions 18b and 18c, the continuous fiber reinforced resin layer has a tensile load. Since the discontinuous fiber reinforced resin layer on the outer surface supports the compressive load while supporting the above, delamination of the continuous fiber reinforced resin layer can be suppressed and the shock absorbing performance can be enhanced.

  As shown in FIG. 12, the second reinforcing ribs 51i, 52i,..., 52i, which are made of discontinuous fibers hardened with a thermoplastic resin are formed on the outer surfaces of the main impact absorbing portion 18a and the first and second auxiliary impact absorbing portions 18b, 18c. Are formed in the front-rear direction, so that the second reinforcing ribs 51i... 52i can support the compressive load and thereby more reliably suppress delamination of the continuous fiber reinforced resin layer. The first reinforcing ribs 51h... 52h... In which discontinuous fibers are hardened with a thermoplastic resin are formed on the inner surface of 18a in a direction inclined with respect to the front-rear direction. Even if it exists, the delamination of a continuous fiber reinforced resin layer can be suppressed.

  As shown in FIG. 13, the bumper beam extension 18 includes front fastening flanges 51b and 52b which are bent in a direction crossing the input direction of the collision load and the discontinuous fibers are hardened with a thermoplastic resin. Since the bumper beam 19 is connected to the fastening flanges 51 b and 52 b, when a collision load is input from the bumper beam 19 to the bumper beam extension 18, the front fastening flanges 51 b and 52 b having a large pressure receiving area are triggered (trigger to cause destruction). ) And the bumper beam extension 18 is sequentially crushed in the front-rear direction, so that the shock absorbing performance can be enhanced.

  The continuous fibers of the continuous fiber reinforced resin layer of the main impact absorbing portion 18a are oriented in the front-rear direction, which is the input direction of the collision load, and in the vehicle width direction and the up-down direction perpendicular thereto, and have a square cross section. 18a is provided with a ridge line that forms a corner along the input direction (front-rear direction) of the collision load (see FIGS. 7 and 8), and is deformed so that the ridge line that forms the corner spreads radially outward by the collision load. In some cases, the continuous fibers oriented in the vehicle width direction and the vertical direction can be stretched to increase the amount of shock absorption.

  Further, the first and second sub closed cross-section portions 23 and 24 are continuously provided on the outer side in the vehicle width direction of the main closed cross-section portion 22, and the main closed cross-section portion 22 is linearly formed at the front-rear direction outer end of the front side frame front portion 14. Since the first and second sub closed cross-section portions 23 and 24 are connected to the side surface of the front side frame front portion 14 via the brace member 82 (see FIG. 5), the front-rear direction dimension of the front portion of the vehicle body is reduced. It is possible not only to secure impact absorption performance while reducing the load, but also to efficiently absorb the collision load at the time of offset collision.

  Further, since the front ends of the first and second sub closed cross-section portions 23 and 24 are located behind the front end of the main closed cross-section portion 22 (see FIG. 5), the collision load of the frontal collision is first the front end of the main closed cross-section portion 22. , And the bumper beam extension 18 can be sequentially crushed in the front-rear direction as a trigger for crushing to improve the shock absorbing performance.

  In particular, when a collision load is intensively input to the end in the vehicle width direction of the bumper beam 19 due to a narrow offset frontal collision, the bumper beam extension 18 has a trapezoidal shape or a triangular shape whose width in the front-rear direction is smaller toward the outer side in the vehicle width direction. The main impact absorbing portion 18a formed on the inner side in the vehicle width direction is aligned in the front-rear direction with respect to the front side frame front portion 14, and the first and second auxiliary impact absorbing portions 18b, 18c on the outer side in the vehicle width direction are front wheels. Since the first and second auxiliary impact absorbing portions 18b and 18c come into contact with the front wheel 65 due to a collision load, the bumper beam extension 18 moves backward without tilting. As a result, the collision load input from the bumper beam 19 is reliably supported by the front side frame front portion 14 to effectively crush the main impact absorbing portion 18a of the bumper beam extension 18, and the collision load is supported by the front wheel 65. By effectively crushing the first and second sub impact absorbing portions 18b and 18c of the bumper beam extension 18, the impact absorbing effect can be enhanced.

  At this time, since the first and second auxiliary impact absorbing portions 18b and 18c smaller than the main impact absorbing portion 18a are juxtaposed in the vehicle width direction, the first and second auxiliary impact absorbing portions 18b and 18c are curved in the vehicle width direction. The front wheel 65 can be brought into contact with the entire peripheral surface to exert the maximum shock absorbing performance. In addition, since the first and second sub-impact absorbing portions 18b and 18c include a plurality of second reinforcing ribs 51i, 52i, which are formed of discontinuous fiber reinforced resin layers and extend in the front-rear direction, the contact area with the front wheel 65 Can increase the shock absorbing performance.

  The bumper beam extension 18 includes slits 51n and 52n that extend in the front-rear direction and can be easily broken between the main shock absorbing portion 18a and the first and second sub shock absorbing portions 18b and 18c. The first and second sub-impact absorbers 18b and 18c separated from the main impact absorber 18a by breaking 51n and 52n are brought into contact with the front wheel 65 at an early stage (see FIG. 14), and the main impact absorber 18a and the first The shock absorption performance can be further enhanced by crushing both of the second sub shock absorbing portions 18b and 18c independently.

Second embodiment

  Next, a second embodiment of the present invention will be described with reference to FIG.

  Although the rear end of the bumper beam extension 18 of the first embodiment extends linearly in the vehicle width direction, the rear end of the bumper beam extension 18 of the second embodiment is located at a portion facing the front wheel 65. An extension 18d that protrudes rearward is provided. By forming the extension 18d, the left and right ends of the front bulkhead 17 and the mounting plate 81 are also bent in a crank shape.

  By forming the extension 18d in the bumper beam extension 18, the distance between the rear end of the bumper beam extension 18 and the front end of the front wheel 65 is reduced, and the bumper beam extension 18 is immediately attached when a collision load of frontal collision is input. The bumper beam extension 18 can be further improved in impact absorbing performance by preventing it from inclining by being brought into contact with the front wheel 65.

  The embodiments of the present invention have been described above, but various design changes can be made without departing from the scope of the present invention.

  For example, the bumper beam extension and bumper beam of the present invention are not limited to those on the front side of an automobile, and may be those on the rear side.

  Further, the vehicle body frame of the present invention is not limited to the front side frame front portion 14 of the embodiment, and may be a frame disposed in the front-rear direction at the vehicle body front portion or the vehicle body rear portion.

  The FRP of the present invention is not limited to the CFRP (carbon fiber fiber reinforced resin) of the embodiment, and may be another type of FRP such as a glass fiber fiber reinforced resin or an aramid fiber fiber reinforced resin.

  The number of sub-impact absorbers 18b and 18c provided in each bumper beam extension 18 is not limited to two in the embodiment, and may be one or three or more.

14 Front side frame front (body frame)
18 Bumper beam extension 18a Main shock absorber 18b First sub shock absorber (sub shock absorber)
18c 2nd sub shock absorption part (sub shock absorption part)
19 Bumper beam 22 Main closed section 23 First sub closed section (sub closed section)
24 2nd sub closed section (sub closed section)
51b Front fastening flange (flange)
51h First reinforcing rib (rib)
51i Second reinforcing rib (rib)
52b Front fastening flange 52h First reinforcing rib (rib)
52i Second reinforcing rib (rib)
82 Bracing members

Claims (8)

A vehicle body structure in which an FRP bumper beam extension (18) is disposed between a vehicle body frame (14) disposed in the front-rear direction and a bumper beam (19) disposed in the vehicle width direction,
The bumper beam extension (18) is integrally provided with a main impact absorbing portion (18a) and sub impact absorbing portions (18b, 18c) made of groove-shaped recesses that are separated in the vehicle width direction and extend in the front-rear direction. A vehicle body structure for an automobile, characterized in that a plate thickness of the shock absorbing portion (18b, 18c) is set smaller than a plate thickness of the main shock absorbing portion (18a).   The bumper beam extension (18) includes a main closed cross-section portion (22) configured to have a closed cross-section by connecting a pair of main impact absorption portions (18a), and a pair of sub-impact absorption portions (18b, 18c). The vehicle body structure according to claim 1, further comprising: a sub-closed cross-section portion (23, 24) coupled to form a closed cross-section.   The main impact absorbing portion (18a) is formed by laminating discontinuous fiber reinforced resin layers on both the inner and outer surfaces of the continuous fiber reinforced resin layer, and the auxiliary impact absorbing portions (18b, 18c) are formed outside the continuous fiber reinforced resin layer. The automobile body structure according to claim 1 or 2, wherein a discontinuous fiber reinforced resin layer is laminated only on the surface.   Ribs (51i, 52i) in which discontinuous fibers are hardened with a thermoplastic resin are formed in the front-rear direction on the outer surfaces of the main impact absorbing portion (18a) and the secondary impact absorbing portion (18b, 18c). The ribs (51h, 52h) in which discontinuous fibers are hardened with a thermoplastic resin are formed on the inner surface of the absorption part (18a) in a direction inclined with respect to the front-rear direction. Item 4. The vehicle body structure according to any one of items 3 to 4.   The bumper beam extension (18) includes flanges (51b, 52b) which are bent in a direction crossing the input direction of the collision load and in which discontinuous fibers are hardened with a thermoplastic resin, and the flanges (51b, 52b) are provided. The vehicle body structure according to any one of claims 1 to 4, characterized in that the bumper beam (19) is connected.   The continuous fibers of the continuous fiber reinforced resin layer of the main impact absorbing portion (18a) are oriented in a first direction which is an input direction of a collision load and a second direction perpendicular thereto, and the main impact absorbing portion. The vehicle body structure according to claim 3, wherein (18a) includes a ridge line that forms a corner along the input direction of the collision load.   The sub closed cross section (23, 24) is connected to the outer side in the vehicle width direction of the main closed cross section (22), and the main closed cross section (22) is arranged at the outer end in the front-rear direction of the body frame (14). The automobile according to claim 2, characterized in that it is connected in a straight line and the sub-closed cross section (23, 24) is connected to the side surface of the body frame (14) via a brace member (82). Car body structure.   The automobile according to claim 7, wherein an outer end in the front-rear direction of the sub-closed section (23, 24) is located on an inner side in the front-rear direction than an outer end in the front-rear direction of the main closed section (22). Car body structure.

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