JP4120464B2 - Front body structure of the vehicle - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a front body structure of a vehicle.
[0002]
[Prior art]
  The following Patent Document 1 is known as a conventional technique related to a front body structure of a vehicle. As shown in FIG. 10, the structure disclosed in the document 1 is an apron member composed of a hood panel, a fender panel, a mounting flange made of a resin material, an apron member upper and an apron member lower. The fender panel has a vertical wall portion fixed to the vertical wall portion of the mounting flange by a rivet, and a lower wall portion of the mounting flange is fastened to the lower wall portion of the apron member upper by a bolt and a nut. It is a thing.
[0003]
  According to the above structure, the mounting flange is made of resin when a load is applied to the boundary between the hood panel and the fender panel from substantially upward to substantially downward. It is said that the lateral wall portion of the step portion breaks relatively easily, and energy can be absorbed during the breaking process.
[0004]
  However, as can be seen from FIG. 10, the structure of the literature 1 is provided with a thick portion filled with resin, and when a load is applied to the fender or the hood panel from the upper side to the lower side, the structure is directed downward. Even if it tries to deform, there is a problem that the deformation is inhibited by the thick portion, and as a result, the initial load that causes the lateral wall portion to break is increased.
[0005]
[Patent Document 1]
  JP-A-11-180350
[0006]
[Problems to be solved by the invention]
  As described above, an object of the present invention is to improve load energy absorption when a load is applied from the upper side to the lower side of a fender or a bonnet.
[0007]
[Means for Solving the Problems]
  In a first configuration related to the present invention, a wheel apron member constituting a side wall of an engine room provided in a front portion of the vehicle and a fender panel constituting a vehicle front side surface so as to cover the wheel apron member are made of a synthetic resin material. It is a front body structure of a vehicle that is connected by a connecting member, and the lower part of the connecting member is attached to a wheel apron member, while the upper part of the connecting member is attached to a flange part that hangs downward from the upper end of the fender panel. The mounting position to the flange portion is provided at a position offset outward in the vehicle width direction from the mounting position to the wheel apron member, and the offset width is adjacent to the mounting position to the flange portion. Extend approximately horizontally inward in the vehicle width direction.In addition, it extends in the front-rear direction at the lower part between the fender panel and the vehicle width direction side end part of the bonnet so as to be deformed when a load is applied to the bonnet covering the upper part of the engine room from above.The width of the first offset portion and the width in the vehicle width direction of the second offset portion inclined in the vehicle width direction outward and upward from the attachment position to the wheel apron member are set. .
[0008]
  According to the first configuration, the front structure of the vehicle in the present invention includes a wheel apron member, a fender panel, and a connecting member made of a synthetic resin material that connects them, and the lower part of the connecting member is a wheel. While being attached to the apron member, the upper portion holds the fender panel at a position offset outward in the vehicle width direction from the attachment position with the wheel apron member. Therefore, when a load of a predetermined amount or more is applied from the upper side to the lower side of the fender panel, the connecting member has a portion of the offset width in the vehicle width direction substantially downward with the attachment portion with the wheel apron member as a fulcrum. It can be easily deformed toward the head and the load energy absorption is improved.
[0009]
  In the first configuration, the offset width extends inward in the vehicle width direction substantially horizontally adjacent to the mounting position on the flange portion.In addition, it extends in the front-rear direction at the lower part between the fender panel and the vehicle width direction side end part of the bonnet so as to be deformed when a load is applied to the bonnet covering the upper part of the engine room from above.The width of the first offset portion and the width in the vehicle width direction of the second offset portion inclined in the vehicle width direction outward and upward from the attachment position to the wheel apron member are set. In other words, the first offset portion is located outward and in the vehicle width direction relative to the second offset portion, and when a load of a predetermined amount or more is applied from the upper side to the lower side of the fender panel or bonnet. First, the substantially horizontal first offset portion is deformed to absorb the initial load, and the load that could not be absorbed by the deformation alone is positioned below the first offset portion and on the inner side in the vehicle width direction. Can be configured to deform and absorb the load.Further, when a load of a predetermined amount or more is applied from the upper side to the lower side of the bonnet, the first offset portion is deformed to absorb the load energy, particularly the initial load.
[0010]
  In the second configuration according to the present invention, the flange portion is held by a holding portion provided at the upper portion of the connecting member, and the fender panel and the upper part of the engine room are disposed on the inner side in the vehicle width direction of the holding portion. A rain rail portion extending in the front-rear direction at the lower portion between the vehicle bonnet side end portion of the bonnet to be covered and having a concave cross section is formed. The width of the rain rail portion in the vehicle width direction is the width of the first offset portion. Is set as.
[0011]
  According to the second configuration, the rain rail portion provided on the inner side in the vehicle width direction of the holding portion can improve the appearance so that the inside of the engine room cannot be seen from the gap between the fender panel and the bonnet, and rain, In addition to the basic function of preventing intrusion of water into the engine room, the width in the vehicle width direction functions as the first offset portion because the cross section is concave, and therefore, from the top to the bottom of the fender panel. When a load of a predetermined amount or more is applied, the outer side in the vehicle width direction of the first offset portion is deformed downward from the inner side, and the absorbability of load energy, especially the initial load, is improved.
[0012]
  According to a third configuration of the present invention, the flange portion of the fender panel is supported by the upper end portion of the vertical wall on the outer side in the vehicle width direction constituting the rain rail portion.
[0013]
  According to the third configuration, the flange portion that hangs downward from the upper end portion of the fender panel supports the upper end portion of the vertical wall on the outer side in the vehicle width direction that constitutes the rain rail portion provided on the upper portion of the connecting member. It is. Therefore, when the attachment position of the apron panel member and the connecting member is used as a reference, the flange portion supporting position is a position offset outward in the vehicle width direction of the connecting member, and from the upper side of the fender panel toward the lower side. When a load of a predetermined amount or more is applied, not only the first offset portion but also the entire connecting member including the second offset portion is easily deformed, and load energy absorption is improved.
[0014]
  In a fourth configuration according to the present invention, a groove portion extending in the front-rear direction along the vertical wall on the outer side in the vehicle width direction is formed in the outer side corner portion in the rain rail portion.
[0015]
  According to the fourth configuration, since the groove portion extending in the front-rear direction along the vertical wall on the outer side in the vehicle width direction is formed in the outer side corner portion in the rain rail portion, it extends downward from the upper side of the fender panel. When a load exceeding a predetermined amount is applied, the groove part is likely to be the starting point of bending deformation, and the vertical wall on the outer side in the vehicle width direction can be easily displaced and deformed downward, improving the absorption of load energy. In particular, the energy absorption of the initial load is improved.
[0016]
  According to a fifth configuration of the present invention, a groove portion extending in the front-rear direction is formed at a corner portion on the lower surface side of the rain rail portion and on the inner side in the vehicle width direction.
[0017]
  According to the fifth configuration, since the groove portion extending in the front-rear direction is formed in the corner portion on the lower surface side of the rain rail portion and on the inner side in the vehicle width direction, a predetermined amount or more from the upper side of the fender panel downwards. When a load is applied, the rain rail on the outer side in the vehicle width direction can be easily displaced and deformed downward from this lower groove on the lower surface side, improving the absorption of load energy, Energy absorption of initial load is improved.
[0018]
  In a sixth configuration according to the present invention, the vertical wall portion on the inner side in the vehicle width direction of the rain rail portion is located below the bonnet.
[0019]
  According to the sixth configuration, since the vertical wall portion on the inner side in the vehicle width direction of the rain rail portion is located on the lower side of the bonnet, the effect of the basic function described in the second configuration is obtained, Furthermore, when a load of a predetermined amount or more is applied downward from above the bonnet, the bonnet is displaced downward while contacting the longitudinal wall portion on the inner side in the vehicle width direction of the rain rail portion. On the other hand, since the rain rail portion supports the flange portion at the upper end of the vertical wall on the outer side in the vehicle width direction, the inner side in the vehicle width direction is easily displaced downward. As a result, the rain rail portion The width in the width direction, that is, the first offset portion is deformed to absorb the load energy, particularly the initial load. Further, the load that cannot be absorbed only by the first offset portion is configured such that the second offset portion positioned inward in the vehicle width direction from the first offset portion is deformed to absorb the load energy. That is, according to the sixth configuration, when a load from the upper side to the lower side is applied to the bonnet or to the fender and the bonnet at the same time, the absorbability of the load energy can be improved.
[0020]
  The seventh configuration according to the present invention is a clip for fixing to a mounting flange that is suspended from the upper end portion of the fender panel and connected to the wheel apron member on the vertical wall on the outer side in the vehicle width direction of the rain rail portion. The part is provided.
[0021]
  According to the seventh configuration, the fender panel is provided with the mounting flange that hangs from the upper end portion thereof, and the clip member is provided on the vertical wall on the outer side in the vehicle width direction of the rain rail portion of the connecting member. Since it is fixed to the mounting flange, the fender panel, the connecting member, and the wheel apron member are integrated. Therefore, when a load is applied to the fender panel from the outside in the vehicle width direction, there is little collapse of the upper part of the fender panel to the engine room side, and the rigidity in the vehicle width direction can be secured. And since this structure is less resistant to the load applied from the upper side to the lower side of the fender panel or bonnet, its energy absorption is not impaired.
[0022]
【The invention's effect】
  As described above, the present invention can improve load energy absorption when a load is applied from the upper side to the lower side of the fender or bonnet.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, embodiments of the present invention will be described with reference to FIGS. In these drawings, FIG. 7 shows a second embodiment obtained by partially modifying the first embodiment shown in FIGS. 1 to 6 and 9, and is based on the present invention. The basic configuration, operation and effect are the same as in the first embodiment.
[0024]
  FIG. 1 is a perspective view showing a structure of a side portion of an engine room provided at a front portion of a vehicle according to the present invention. According to FIG. 1, the side part of the engine room ER includes a fender panel 1 disposed in the vehicle front-rear direction at the most side part of the vehicle body, and the vehicle front-rear side in the vehicle width direction inner side than the fender panel 1. It has the wheel apron member 7 (henceforth apron member 7) arrange | positioned in the direction, and the connection member 3 which consists of a synthetic resin material which connects the fender panel 1 and the apron member 7, for example, a polypropylene resin. The fender panel 1 and the apron member 7 are both steel plates.
[0025]
  Specifically, the fender panel 1 is provided with a plurality of strip-shaped mounting flanges 5a, 5b, and 5c that hang down in the vehicle front-rear direction, and is provided above the mounting flanges 5a, 5b, and 5c. The fender panel 1 and the connecting member 3 are connected by fitting the clip portion 3k (see FIG. 2) provided in the connecting member 3 into the mounting hole 1h (see FIG. 2).
[0026]
  On the other hand, a mounting hole 3h (see FIG. 2) is also provided in the lower part of the connecting member 3, and the fastening member T1 (see FIG. 2) is utilized by using the mounting hole 7h (see FIG. 2) provided in the lower part of the apron member 7. 2), the connecting member 3 and the apron member 7 are connected.
[0027]
  Furthermore, the upper portion of the apron member 7 has an upper flange portion 7b (see FIG. 2) that is bent substantially horizontally outward in the vehicle width direction, and substantially horizontally at the lower ends of the mounting flanges 5a, 5b, and 5c. The mounting surface 5d (see FIG. 2) bent toward the engine room side is connected by a fastening member T2.
[0028]
  In FIG. 1, the apron member 7 is provided with a notch recess 7 a, and this notch recess 7 a is for accommodating the suspension tower 9.
[0029]
  Further, the mounting flange will be described as an embodiment with a plurality of strip-shaped plate members as shown in FIG. 1, but the present invention is not limited to this, and the fender panel 1 is directed downward from above. When a load is applied, it is only necessary that the outer surface portion 1a can be easily deformed. For example, FIG. 8 shows another embodiment when the mounting flange is viewed from the engine room outward in the vehicle width direction, and a plurality of holes 25 (circle, corner, A punching metal 21 having an ellipse or the like is not limited in shape, and is fixed to a protruding portion 20d below the flange portion 20c hanging from the upper end portion 20b of the fender panel by welding or the like, as shown in FIG. A thin steel plate 31 having a thickness smaller than that of the fender panel outer surface portion 30a may be connected to the protruding portion 30d below the flange portion 30c. Note that the connecting member and the fender panel are attached to the protruding portion 20d and the punching metal 25 in FIG. 8A and the protruding portion 30d and the thin steel plate 31 in FIG. Mounting holes 23 and 33 are formed in a penetrating state.
[0030]
  The above-described connection structure of the plurality of strip-like mounting flanges 5a, 5b, and 5c, the connecting member 3, and the apron member 7 will be described in further detail with reference to FIG.
[0031]
  2, FIG. 2 (A) is an AA cross-sectional arrow view in FIG. 1, and FIG. is there. As shown in FIG. 2A, the fender panel 1 includes an outer surface portion 1a, a fender panel upper end portion 1b that is an end portion of the outer surface portion 1a that curves upward toward the engine room ER side, and a fender panel. It has a flange portion 1c that hangs down from the upper end portion 1b of the panel, and an inclined portion 1d (see FIG. 2B) that inclines downward from the flange portion 1c toward the inside of the engine room ER.
[0032]
  Above the engine room ER, a bonnet 10 including a bonnet panel outer 10a and a bonnet panel inner 10b is disposed to cover the engine room ER.
[0033]
  A connecting member 3 is provided below a side portion of the bonnet 10 in the vehicle width direction. An attachment hole 3h is provided in the lower part 3A of the connecting member 3, and the connecting member 3 has an attachment hole 3h and an attachment hole 7h provided in the vertical surface portion 7a of the apron member 7 described in FIG. After being aligned, the upper part of the apron member 7 is connected via the fastening member T1.
[0034]
  The apron member 7 has an upper flange portion 7b that is bent outward from the vertical surface portion 7a in the vehicle width direction.
[0035]
  On the other hand, from the flange part 1c of the fender panel 1, the attachment flange 5a which hangs down further via the inclination part 1d is provided. And the upper part of the attachment flange 5a is connected with the connection member 3 by the clip part 3k (refer FIG.2 (B)), Furthermore, the lower end part of the attachment flange 5a is provided with the attachment surface part 5d toward an engine room inner side, The upper flange portion 7b of the apron member 7 and the mounting flange 5a are connected by a fastening member T2.
[0036]
  From the above, the connecting member 3 is connected to the upper portion of the mounting flange 5a at the upper portion thereof, and is connected to the apron member 7 at the lower portion thereof, and the upper portion of the apron member 7 is connected to the lower portion of the mounting flange 5a. It will be connected. In other words, the fender panel 1, the connecting member 3, and the apron member 7 have a structure that is integrally connected, and the fender panel upper end 1b does not move even when a load is applied to the fender panel 1 from the lateral direction. Rigidity is secured so that it does not easily fall into the engine room ER side.
[0037]
  FIG. 2 shows a cross section of the portion including the mounting flange 5a, but the mounting flanges 5b and 5c described in FIG. 1 have the same structure.
[0038]
  Then, the structure of the connection member 3 is demonstrated based on FIG. 2 (A) and FIG. 2 (B). 2 (A) and 2 (B) are cross-sectional views taken along the line AA in FIG. 1, the explanation is added also in FIG. To be able to understand the structure of 3.
[0039]
  As shown in FIG. 2 (A), the connecting member 3 includes an inclined surface portion 3e extending from the lower portion 3A to the vehicle width direction and extending upward, and a vertical surface portion extending substantially vertically upward from the inclined surface portion 3e. 3B and a rain rail portion 3C at the top of the vertical surface portion 3B. The inclined surface portion 3e acts to absorb load energy as a second offset portion that will be described in detail later.
[0040]
  Further, as shown in FIG. 2 (B), the upper part of the connecting member 3 in the AA cross-section of FIG. 1 is an inner vertical wall in the vehicle width direction that extends continuously upward from the vertical surface 3B. Part 3f, rain rail bottom surface part 3g extending substantially horizontally from the lower part of vehicle width direction inner side vertical wall part 3f toward the vehicle width direction outward, and extending upward from the outer end part of rain rail bottom surface part 3g A vehicle width direction outer side vertical wall portion 3i and a support portion 3j extending outward in the vehicle width direction at the upper end portion of the vehicle width direction outer side vertical wall portion 3i and contacting the flange portion 1c and the inclined portion 1d. In addition, a clip portion 3k that protrudes outward in the vehicle width direction is provided at a lower portion of the vehicle width direction outer side vertical wall portion 3i. The rain rail bottom surface portion 3g acts to absorb load energy as a first offset portion which will be described in detail later.
[0041]
  The shape of the clip portion 3k is shown in a simplified manner in FIGS. 2 to 7, but a detailed shape is shown in FIG. According to FIG. 9, the clip portion 3 k includes a center member 3 ka and a plurality of umbrella-shaped members 3 kb and 3 kb extending from the distal end portion of the center member 3 ka toward the vehicle width direction outer side vertical wall portion 3 i. The umbrella-shaped members 3 kb and 3 kb are inserted into mounting holes 1 h (see FIG. 2B) provided in the upper part of the mounting flange 5 a while constricting the umbrella-shaped members 3 kb and 3 kb. As a result, the upper part of the connecting member 3 and the upper part of the mounting flange 5a, which is a constituent member of the fender panel 1, are connected.
[0042]
  In FIG. 2B, the connecting member 3 has three surfaces of the groove M formed by the vehicle width direction inner side vertical wall portion 3f, the rain rail bottom surface portion 3g, and the vehicle width direction outer side vertical wall portion 3i. A surrounding rail-shaped rain rail portion 3C is formed.
[0043]
  Two groove portions M1 and M2 are formed in the rainrail bottom surface portion 3g of the rainrail portion 3C so as to extend in the vehicle front-rear direction.
[0044]
  First, the groove part M1 is formed in the outer side corner | angular part in the rain rail part 3C, ie, the upper surface outward side edge part of the rain rail bottom face part 3g along the vehicle width direction outer side vertical wall part 3i. One groove portion M2 is formed along the vehicle outer side surface of the vertical surface portion 3B at the lower surface inner side end portion of the rain rail bottom surface portion 3g.
[0045]
  Next, the structure of the holding portion 3D of the connecting member 3 will be described with reference to FIG. 3 which is a cross-sectional view taken along the line BB in FIG.
[0046]
  In the BB cross section in FIG. 1, the mounting flange 5a, 5b or 5c is not formed, and it extends upward from the middle part in the height direction of the vertical wall 3i in the vehicle width direction to the support 3j. It differs from the AA cross section in FIG. 1 that the outer holding surface part which faces is provided. Therefore, overlapping of the parts described in FIG. 2 is avoided, and only the different points will be described.
[0047]
  In FIG. 3, an outer holding surface portion 3 n that extends upward and faces the support portion 3 j is provided from a middle portion in the height direction of the vertical wall portion 3 i on the outer side in the vehicle width direction of the holding portion 3 </ b> D. A flange holding portion 3p for holding a lower portion of the flange portion 1c of the fender panel 1 and an inclined portion 1d inclined downward from the engine room side is formed by the support portion 3j and the vertical wall portion 3i on the outer side in the vehicle width direction. Has been.
[0048]
  Based on the above, before specifically describing the absorbability of load energy when a load is applied from the top to the bottom of the fender or bonnet, the characteristics of the structure according to the present invention shown in this embodiment will be described. Keep it.
[0049]
  2 and 3, the lower part of the connecting member 3 is connected to the vertical surface portion 7a of the apron member, while the upper part of the connecting member 3 is the flange part 1 constituting the fender panel 1 and the inclined part 1d. The upper portion of the mounting flange 5a hanging from the inclined portion 1d is fixed by the clip portion 3k.
[0050]
  Here, the distance (the offset width) in the vehicle width direction between the upper fixing portion (the holding portion by the flange holding portion 3p and the fixing portion by the clip portion 3k) and the lower fixing portion (the connecting portion by the fastening member T1) of the connecting member 3 ) Is a width in the planar view vehicle width direction of the inclined surface portion 3e in the connecting member 3 (width of the second offset portion) and a width in the plane view vehicle width direction of the rain rail bottom surface portion 3g of the rain rail portion 3C (first offset). Part width). That is, when the lower fixing portion of the connecting member 3 is used as a reference, the upper fixing portion of the connecting member 3 is set at a position offset to the vehicle outer side, which is one feature of the structure according to the present invention. It is.
[0051]
  In addition, it is one feature of the structure according to the present invention that the rain rail bottom surface portion 3g of the rain rail portion 3C is formed with two grooves M1 and M2 extending in the vehicle front-rear direction.
[0052]
  Specifically, the groove portion M1 is formed at the outer side corner portion in the rain rail portion 3C, that is, on the upper outer side end portion of the rain rail bottom surface portion 3g along the vehicle width direction outer side vertical wall portion 3i. One groove portion M2 is formed along the vehicle outer side surface of the vertical surface portion 3B at the lower surface inner side end portion of the rain rail bottom surface portion 3g.
[0053]
  Further, the fender panel 1 and the apron member 7 are also connected, and the vehicle width from the mounting surface portion 5d extending toward the engine room ER at the lower portion of the strip-shaped mounting flange 5a of the fender panel 1 and the vertical surface portion 7a of the apron member 7 The upper flange portion 7b that is bent outward in the direction is connected. With this, when the lower fixing portion of the apron member 7 (the connecting portion by the fastening member T1) is used as a reference, the upper portion of the mounting flange 5a It is set at a position offset toward the side, which is also a feature of the structure according to the present invention.
[0054]
  Based on the above characteristics, the absorbability of load energy when a load is applied from the top to the bottom of the fender or bonnet according to the present invention will be described below in three cases.
[0055]
  The first is a case where a load is applied from above the fender panel, and energy absorption due to deformation of the fender panel and the connecting member at this time will be described with reference to FIG.
[0056]
  The second is a case where a load is applied from above so as to straddle the fender panel and the bonnet. The energy absorption due to the deformation of the fender panel, the bonnet, and the connecting member at this time will be described with reference to FIG. .
[0057]
  And the 3rd is a case where a load is applied to a bonnet from the upper part, The energy absorption property by a deformation | transformation of a bonnet, a fender panel, and a connection member at this time is demonstrated using FIG.
[0058]
  4 (A), FIG. 5 (A), and FIG. 6 (A) are all shown in FIG. 3 (A), that is, the BB cross-sectional perspective view in FIG. B), FIG. 5B, and FIG. 6B are all enlarged views of the holding portion 3D.
[0059]
  Also, the fender panel, the bonnet, and the connecting member described in FIGS. 4, 5, and 6 below are modified in the form of load energy, the angle of the direction in which the load is applied, and the width direction in which the load is applied. The position varies depending on the position of the object and the area of the object applied as a load. Therefore, in the present embodiment, one modified form when a load that deforms the connecting member or the like from the upper side to the lower side is applied will be described.
[0060]
  First, based on FIG. 4 (A), the energy absorption property by the deformation | transformation of a fender panel when a load is applied from the upper part of a fender panel and a connection member is demonstrated. In the figure, the alternate long and two short dashes line indicates the state before deformation, and the solid line indicates the state after deformation.
[0061]
  When a load F that deforms the fender panel 1 and the connecting member 3 is applied from above the fender panel 1, the fender panel 1 is deformed downward. That is, the outer surface portion 1a is greatly curved so as to fall to the engine room ER side, and the fender panel upper end portion 1b is also displaced downward accordingly.
[0062]
  Since the mounting flange 5a is integrally connected to the flange portion 1c hanging from the upper end portion 1b of the fender panel, the mounting flange 5a is also deformed while being displaced downward.
[0063]
  As described in the description of FIG. 1, the fender panel 1 (including the mounting flanges 5a, 5b, and 5c) and the apron member 7 are both steel plate materials, but the other shapes of the mounting flange 5a are strips. It is easy to be deformed with respect to the load from the side, and this ease of deformation is based on the lower fixing part of the apron member 7 (the connecting part by the fastening member T1). Since it is set at a position offset toward the side, it is more prominent. Therefore, it is set as the structure which can improve the absorbability of load energy in the process of deformation | transformation of the attachment flange 5a other accompanying the deformation | transformation of the outer surface part 1a in the fender panel 1. FIG.
[0064]
  In the present invention, the upper part of the connecting member 3 made of a synthetic resin material has been described as one of the structural features that the upper part of the connecting member 3 is offset to the vehicle outer side with respect to the lower part. When a load is applied to 1 and the fender panel upper end portion 1b is displaced downward, the holding portion 3D of the connecting member 3 holds the flange portion 1c hanging from the fender panel upper end portion 1b. The holding portion 3D is also displaced in substantially the same manner as the fender panel upper end portion 1b. Further, the vertical surface portion 3B and the inclined surface portion 3e (second offset portion) are also deformed as shown in FIG.
[0065]
  In this way, the connecting member 3 is deformed in accordance with the downward displacement of the fender panel upper end portion 1b from the effect of the width of the second offset portion, that is, the position attached by the apron member 7 and the fastening member T2. The inclined surface portion 3e inclined outward in the vehicle width direction and upward is easy to be displaced and deformed downward, whereby load energy can be absorbed in the process of deformation. It has become a thing.
[0066]
  Furthermore, as shown in FIG. 4B, the holding portion 3D can be greatly deformed so that the rain rail portion 3C is crushed.
[0067]
  This contributes to the formation of the grooves M1 and M2 and the length of the rain rail bottom surface portion 3g in the vehicle width direction, that is, the width of the first offset described as one of the features of the structure according to the present invention. That is, when the flange portion 1c is displaced so as to fall toward the engine room ER side, the vehicle width direction outer side vertical wall portion 3i and the outer holding surface portion of the holding portion 3D holding the flange portion 1c. 3n is also deformed because it is a synthetic resin material while being displaced to fall toward the engine room ER side. It is the groove portion M1 that facilitates this deformation, and the groove portion M1 has an effect as a notch, so that it is deformed so as to narrow its surface angle with respect to the rain rail bottom surface portion 3g. Easy.
[0068]
  On the other hand, since the vertical surface portion 3B is deformed and displaced so as to fall toward the vehicle outer side, the groove portion M2 is deformed so as to widen the surface angle between the rain rail bottom surface portion 3g and the vertical surface portion 3B.
[0069]
  As described above, the groove portions M1 and M2 each have a function of easily changing the surface angle between the rain rail bottom surface portion 3g and the vertical wall portion 3i on the vehicle width side of the holding portion 3D, and the rain rail bottom surface portion 3g and the vertical surface portion 3B. And has a predetermined width (first offset width) in the vehicle width direction so that the rain rail bottom surface portion 3g can be deformed, so that an initial load has been applied from above. The load is distributed and transmitted to the mounting flange 5a and the vertical surface portion 3B while the load energy is absorbed by deformation from the stage. That is, the load energy absorbability is improved by the grooves M1 and M2, and in particular, the initial load energy absorbability can be improved.
[0070]
  As described above, based on FIG. 4, the energy absorption by the deformation of the fender panel and the connecting member when a load is applied from above the fender panel has been described. Each of the characteristics of the structure described above is the effect of the present invention. It turns out that it is tied to.
[0071]
  Next, energy absorption by deformation of the fender panel, the hood, and the connecting member when a load is applied from above so as to straddle the fender panel and the bonnet will be described with reference to FIG. In the figure, the alternate long and two short dashes line indicates the state before deformation, and the solid line indicates the state after deformation.
[0072]
  When a load F that deforms the fender panel 1 and the connecting member 3 is applied from above so as to straddle the fender panel 1 and the bonnet 10, the vehicle width direction side end portion 10e of the fender panel 1 and the bonnet 10 is deformed downward. Displace. That is, in the fender panel 1, the outer surface portion 1a is greatly curved so as to fall to the engine room ER side, and the fender panel upper end portion 1b is also displaced downward accordingly.
[0073]
  Since the mounting flange 5a is integrally connected to the flange portion 1c hanging from the upper end portion 1b of the fender panel, the mounting flange 5a is also deformed while being displaced downward.
[0074]
  At this time, similarly to the case where the load is applied from above the fender panel described above, the mounting flange 5a and others are strip-shaped, and the lower fixing portion of the apron member 7 (the connecting portion by the fastening member T1). , The upper part of the mounting flange 5a is set at a position offset to the vehicle outer side, so that the ease of deformation with respect to the load from above is made more remarkable. Yes. Therefore, it is set as the structure which can improve the absorbability of load energy in the process of deformation | transformation of the attachment flange 5a other accompanying the deformation | transformation of the outer surface part 1a in the fender panel 1. FIG.
[0075]
  On the other hand, the deformation of the connecting member 3 is slightly different from the case where a load is applied from above the fender panel. The vehicle width direction side end portion 10e of the bonnet 10 and the fender panel upper end portion 1b are displaced downward at substantially the same height, and accordingly, the vehicle width direction side end portion 10e is displaced in the vehicle width direction of the holding portion 3D. It is a point which contact | abuts to the side vertical wall part 3f top part, and is deform | transformed so that the connection member 3 may be crushed below.
[0076]
  Specifically, a portion extending from the lower side of the vertical surface portion 3B to the inclined surface portion 3e (second offset portion) is bent in a substantially square shape. Such deformation is caused by the fact that the position of the upper end portion 1b of the fender panel to which the load is applied and the end portion 10e in the vehicle width direction of the bonnet 10 are outside the vehicle relative to the position of the lower fixing portion (fixing portion with the apron member 7) of the connecting member. Because it is offset towards. In particular, the vertical surface portion 3B and the inclined surface portion 3e are given a predetermined surface angle by the inclined surface portion 3e in advance, and the width of the second offset portion is given so that a moment acts. The character-shaped deformation is facilitated, whereby load energy can be absorbed during the deformation process.
[0077]
  The deformation of the holding portion 3D of the connecting member 3 is shown in FIG. 5B and is substantially the same as described in FIG. 4B, but the vehicle width direction side end portion 10e is the holding portion 3D. Since the vehicle width direction inner side vertical wall portion 3f is displaced downward while contacting the top of the vehicle width direction inner side vertical wall portion 3f, a load is applied to the vehicle width direction inner side vertical wall portion 3f from above the fender panel (FIG. 4 ( B)) is less inclined toward the outside of the vehicle.
[0078]
  However, since the groove portion M1 has an effect as a notch portion, the groove portion M1 is deformed so as to narrow its surface angle with respect to the rain rail bottom surface portion 3g, and the groove portion M2 is further perpendicular to the rain rail bottom surface portion 3g. The tendency to deform so as to widen the surface angle with 3B is the same. Further, the rain rail bottom surface portion 3g is also deformed because it has a width in the vehicle width direction (the width of the first offset). Accordingly, the grooves M1 and M2 and the rain rail bottom surface portion 3g are distributed from the initial stage where the load is applied from above and absorb the load energy, and distribute and transmit the load to the mounting flange 5a and the vertical surface portion 3B. Therefore, in particular, the energy absorption of the initial load can be improved.
[0079]
  As described above, based on FIG. 5, the energy absorption due to the deformation of the fender panel, the bonnet, and the connecting member when a load is applied from above so as to straddle the fender panel and the bonnet has been described. It turns out that each is connected with the effect of this invention.
[0080]
  Furthermore, based on FIG. 6, energy absorption by deformation of the bonnet, fender panel, and connecting member when a load is applied to the bonnet from above will be described. In the figure, the alternate long and two short dashes line indicates the state before deformation, and the solid line indicates the state after deformation.
[0081]
  When a load is applied to the bonnet 10 from above, the bonnet 10 is displaced downward, and its end 10e in the vehicle width direction is in contact with the top of the vertical wall 3f in the vehicle width direction of the holding portion 3D. Although the member 3 is pushed downward, the flange in which the vehicle width direction outer side vertical wall portion 3i and the outer holding surface portion 3n of the holding portion 3D of the connecting member 3 are suspended from the fender panel upper end portion 1b of the fender panel 1 Since the portion 1c is held, the displacement of the vehicle width direction outer side vertical wall portion 3i and the outer holding surface portion 3n in the holding portion 3D is smaller than that described with reference to FIGS. 4 and 5 (the outer surface portion 1a). And the deformation of the fender panel 1 including the mounting flange 5a is small). For this reason, the surface part from the vehicle width direction inner side vertical wall part 3f to the vertical surface part 3B and the inclined surface part 3e (second offset part) is easily deformed and displaced.
[0082]
  At this time, the mounting flange 5a is deformed as shown in the drawing. The mounting flange 5a and the like are strip-shaped, and the upper portion of the mounting flange 5a is offset to the vehicle outer side based on the lower fixing portion of the apron member 7 (the connecting portion by the fastening member T1). Since it is set, it is easy to deform. Accordingly, the structure is such that the load energy absorbability can be increased in the process of deformation of the mounting flange 5a and the like accompanying the downward deformation of the holding portion 3D in the vehicle width direction outer side vertical wall portion 3i.
[0083]
  On the other hand, the surface angle between the vertical surface portion 3B and the inclined surface portion 3e in the connecting member 3 is bent at a substantially right angle as shown in the figure. Such deformation is connected to the position of the vehicle width direction outer side vertical wall portion 3i holding the flange portion 1c and the outer holding surface portion 3n by the width of the first offset portion and the width of the second offset portion. This is because the width of the offset to the outside of the vehicle with respect to the position of the lower fixing portion of the member (fixing portion with the apron member 7) is set. In particular, the inclined surface portion 3e (second offset portion) gives a predetermined surface angle to the vertical surface portion 3B and the inclined surface portion 3e in advance, and the width of the second offset portion so that a moment acts. This facilitates deformation at a substantially right angle, so that load energy can be absorbed during the deformation process. Thus, it is one end of the effect of the present invention that the load energy absorbability can be adjusted in accordance with various automobiles by setting the angle of the inclined surface portion 3e and the offset width.
[0084]
  Further, as shown in FIG. 6B, the vertical surface portion 3B of the coupling member 3 and the longitudinal wall portion 3f in the vehicle width direction of the holding portion 3D are lowered while falling down toward the engine room ER side. Deform towards. At this time, since the vehicle width direction outer side vertical wall portion 3i and the outer holding surface portion 3n hold the flange portion 1c and have little displacement, the rain rail bottom surface portion 3g and the holding portion 3D are extended in the vehicle width direction outer side vertical direction. The surface angle of the wall portion 3i is expanded by the action of the groove portion 1, the surface angle between the rain rail bottom surface portion 3g and the vertical surface portion 3B tends to be slightly widened, and the rain rail bottom surface portion 3g also has a predetermined width ( The width of the first offset is deformed.
[0085]
  As described above, the groove portions M1 and M2 each have a function of easily changing the surface angle between the rain rail bottom surface portion 3g and the vertical wall portion 3i on the vehicle width side of the holding portion 3D, and the rain rail bottom surface portion 3g and the vertical surface portion 3B. Since the rain rail bottom surface portion 3g also has a predetermined width (the width of the first offset) in the vehicle width direction, a load is applied from above the bonnet 10 and the holding portion 3D When the vehicle width direction inner side vertical wall portion 3f is about to be displaced downward, the load is distributed and transmitted to the mounting flange 5a and the vertical surface portion 3B while deforming from the initial stage to absorb the load energy. That is, the load energy absorbability is improved by the width of the grooves M1 and M2 and the rain rail bottom surface portion 3g in the vehicle width direction, and in particular, the energy absorbability of the initial load can be improved.
[0086]
  As described above, based on FIG. 6, the energy absorbability due to the deformation of the fender panel, the bonnet, and the connecting member when a load is applied from above the bonnet has been described. Each of the features of the structure described above is the effect of the present invention. It turns out that it is tied to.
[0087]
  Next, the second embodiment will be briefly described. FIG. 7 shows the main part of the second embodiment at the BB cross-sectional position in FIG. According to FIG. 7, in the second embodiment, the cross-section of the top portion 3t of the outer holding surface portion 3n holding the flange portion 1c in the holding portion 3D has a predetermined curvature, and the curvature surface is It is in contact with the inner surface of the outer surface 1a near the upper end 1b of the fender panel.
[0088]
  In the case of the second embodiment, since the top cross section of the outer holding surface portion 3n has a predetermined curvature, the flange portion 1c is formed by the outer holding surface portion 3n and the vehicle width direction outer side vertical wall portion 3i. In addition to facilitating the insertion operation, the thickness of the top portion of the outer holding surface portion 3n is partially increased, and the length of the outer holding surface portion 3n is also increased, so the flange portion 1c. The retention of is increased. For this reason, even if the fender panel 1 and the holding portion 3D of the connecting member 3 are greatly deformed by the load from above, they will not fall off, and the effect of improving the load energy absorbability described in the first embodiment Can be exhibited stably.
[0089]
  Even in the case of the second embodiment, as described with reference to FIGS. 4, 5, and 6, the form of deformation of the fender and the connecting member according to the position where the load is applied, and the absorbability of the load energy Will not change.
[Brief description of the drawings]
FIG. 1 is a perspective view showing a front structure of a vehicle according to the present invention.
FIG. 2 is a cross-sectional view taken along the line AA in FIG.
3 is a cross-sectional view taken along the line BB in FIG.
FIG. 4 is a diagram showing deformation of the constituent member of the present invention when a load is applied from above the fender panel.
FIG. 5 is a view showing deformation of the constituent member of the present invention when a load is applied from above over the fender panel and the bonnet.
FIG. 6 is a diagram showing deformation of the constituent member of the present invention when a load is applied from above the bonnet.
FIG. 7 is a diagram showing a second embodiment based on FIG.
FIG. 8 shows another embodiment of a mounting flange
FIG. 9 is a detailed view of the clip part.
FIG. 10 is a diagram showing a conventional technique.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Fender panel 1b ... Fender panel upper end part
1c ... Flange part 3 ... Connecting member
3C: Rain rail part 3D: Holding part
3e: Inclined surface portion (second offset portion) 3f: Inner side vertical wall portion in the vehicle width direction
3g ... Rain rail bottom (first offset part)
3i: Vehicle width direction outer side vertical wall portion 3k: Clip portion
M1, M2 ... Groove 5a, 5b, 5c ... Mounting flange
7 ... Wheel apron member 10 ... Bonnet
ER engine room

Claims (7)

A wheel apron member (7) constituting a side wall of an engine room (ER) provided in a front portion of the vehicle and a fender panel (1) constituting a vehicle front side surface so as to cover the wheel apron member (7) are made of synthetic resin. A vehicle front body structure connected by a connecting member (3) made of a material,
The lower part of the connecting member (3) is attached to the wheel apron member (7), while the upper part of the connecting member (3) is a flange part (1c) that hangs downward from the upper end of the fender panel (1). The mounting position to the flange portion (1c) is provided at a position offset outward in the vehicle width direction from the mounting position to the wheel apron member (7), and the width of the offset is When a load is applied from above to the hood (10) extending substantially inward in the vehicle width direction adjacent to the attachment position to the flange portion (1c) and covering the upper part of the engine room (ER). as deformed, the fender panel (1), first offset portion extending in the front-rear direction at the lower portion between the vehicle width direction side end portion (10e) of the bonnet (10) (3 g And the width in the vehicle width direction of the second offset portion (3e) inclined in the vehicle width direction outward and upward from the attachment position to the wheel apron member (7). A vehicle body structure for a front portion of a vehicle. A wheel apron member (7) constituting a side wall of an engine room (ER) provided in a front portion of the vehicle and a fender panel (1) constituting a vehicle front side surface so as to cover the wheel apron member (7) are synthetic resin. A vehicle front body structure connected by a connecting member (3) made of a material,
The lower part of the connecting member (3) is attached to the wheel apron member (7), while the upper part of the connecting member (3) is a flange part (1c) that hangs downward from the upper end of the fender panel (1). The mounting position to the flange portion (1c) is provided at a position offset outward in the vehicle width direction from the mounting position to the wheel apron member (7), and the width of the offset is The width of the first offset portion (3g) extending inwardly in the vehicle width direction adjacent to the attachment position to the flange portion (1c) and the vehicle width from the attachment position to the wheel apron member (7) The width of the second offset portion (3e) inclined outward in the direction and upward is set in the vehicle width direction in plan view.
The flange portion (1c) is held by a holding portion provided at an upper portion of the connecting member (3), and the fender panel (1) and the engine are disposed on the inner side in the vehicle width direction of the holding portion. A rain rail portion (3C) having a concave cross section is formed at the lower portion between the vehicle width direction side end portion of the bonnet (10) covering the upper portion of the room (ER), and the rain rail portion (3C) is formed. front body structure of vehicles characterized in that the vehicle width direction of width is set as the width of the first offset portion (3 g) of part (3C).   The flange part (1c) of the fender panel (1) is supported by the upper end part of the vertical wall (3i) on the vehicle width direction outer side that constitutes the rain rail part (3C). Item 3. A front body structure of a vehicle according to Item 2.   A groove portion (M1) extending in the front-rear direction along the vertical wall (3i) on the outer side in the vehicle width direction is formed at an outer side corner portion in the rain rail portion (3C). A vehicle front body structure according to claim 2 or claim 3.   The groove part (M2) extended in the front-back direction is formed in the corner | angular part of the lower surface side of the said rain rail part (3C) and a vehicle width direction inner side, The Claim 2 or Claim 4 characterized by the above-mentioned. The front body structure of the vehicle.   The vertical wall portion (3f) on the inner side in the vehicle width direction of the rain rail portion (3C) is located on the lower side of the bonnet (10). A vehicle front body structure according to claim 1.   On the vertical wall (3i) on the outer side in the vehicle width direction of the rain rail part (3C), a mounting flange (hanging from the upper end of the fender panel (1) and connected to the wheel apron member (7)) The vehicle body structure for a front part of a vehicle according to any one of claims 2 to 6, characterized in that a clip part (3k) for fixing to 5a, 5b, 5c) is provided.

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