[0001]The present invention relates to an automobile door.
　The present application claims priority based on Japanese Patent Application No. 2019-004038 filed in Japan on January 15, 2019, the contents of which are incorporated herein by reference.
Background technology
[0002]
　Conventionally, for example, in Patent Document 1 below, there is a technique that assumes that a door structure for an automobile that can achieve high-level vibration suppression and tension rigidity improvement of a door outer panel while suppressing weight increase and cost increase is provided. Have been described.
Prior art literature
Patent documents
[0003]
Patent Document 1: Japanese Patent Application Laid-Open No. 2003-205741
Outline of the invention
Problems to be solved by the invention
[0004]
　In the technique described in Patent Document 1, one strut extending in the vehicle height direction of the door and a door outer waist reinforcement and a guard bar extending in the vehicle length direction of the door are provided. Of these, struts extending in the vehicle height direction of the door are provided to improve the tension rigidity of the panel, and shock absorption due to a collision is carried out by the guard bar extending in the vehicle length direction.
[0005]
　However, shock absorbing members such as guard bars are installed so as to cross the door. The end portion of the shock absorbing member is fixed, and the shock absorbing member absorbs the impact by bending on the central side of the fixed portion. However, the present inventors have found that if the shock absorbing member is easily bent, there is a problem that the performance of the shock absorbing member cannot be fully exhibited.
[0006]
　Further, since the strut provided with only one is provided for improving the tension rigidity, it is not possible to absorb the impact around the strut. Furthermore, the present inventors have found that it is necessary to provide a sturdy guard bar in order to absorb the impact, which causes a problem of increasing the weight of the door.
[0007]
　Therefore, the present invention has been made in view of the above problems, and an object of the present invention is to provide a new and improved automobile door capable of more reliably absorbing an impact.
Means to solve problems
[0008]
(1) The automobile door according to one aspect of the present invention includes a first shock absorbing member that crosses the automobile door so as to extend over both end regions in the vehicle height direction, and both ends of the automobile door in the vehicle length direction. A second shock absorbing member, an exterior material, and a belt line reinforcement that traverses the area so as to extend are provided, and the second shock absorbing member is adjacent to the exterior material and the first shock absorbing member. The member and the second shock absorbing member intersect at the intersection, the first shock absorbing member and the second shock absorbing member come into contact with each other at the intersecting portion, and the second shock absorbing member is the exterior material. The first shock absorbing member extends between the first shock absorbing member and the first shock absorbing member in a portion other than the both end regions in the vehicle height direction, the both end regions in the vehicle length direction, and the intersection. The bending rigidity of the cross section perpendicular to the current direction in the vehicle width direction is larger than the bending rigidity of the cross section perpendicular to the extending direction of the second shock absorbing member in the vehicle width direction, and the belt line reinforcement is the first. The window side end of the shock absorbing member is supported by a support portion, and the belt line reinforcement is arranged on the passenger compartment side of the first shock absorbing member in the extending direction of the belt line reinforcement in the support portion. The bending rigidity of the vertical cross section in the vehicle width direction is larger than the bending rigidity of the cross section perpendicular to the extending direction of the first shock absorbing member at the intersection in the vehicle width direction.
(2) In the automobile door according to (1) above, at the intersection of the first shock absorbing member and the second shock absorbing member, the first shock absorbing member and / or the second impact The thickness of the absorbing member in the vehicle width direction may be reduced.
(3) In the automobile door according to (1) above, at the intersection, the flexural rigidity of the cross section perpendicular to the extending direction of the first shock absorbing member in the vehicle width direction is the second shock absorbing member. It may be larger than the flexural rigidity of the cross section perpendicular to the extending direction of the member in the vehicle width direction.
(4) In the automobile door according to any one of (1) to (3) above, the second shock absorbing member may be joined to the first shock absorbing member.
(5) In the automobile door according to any one of (1) to (4) above, in the cross section perpendicular to the extending direction of the first shock absorbing member, the width in the vehicle width direction is the vehicle length. It may be greater than or equal to the width of the direction.
(6) In the automobile door according to any one of (1) to (5) above, in the cross section perpendicular to the extending direction of the second shock absorbing member, the width in the vehicle width direction is the vehicle height. It may be greater than or equal to the width of the direction.
The invention's effect
[0009]
　As described above, according to the present invention, it is possible to provide an automobile door capable of more reliably absorbing an impact.
A brief description of the drawing
[0010]
FIG. 1 is a perspective view showing a structure of an automobile according to an embodiment of the present invention.
FIG. 2 is a schematic view showing a door structure according to the present embodiment.
FIG. 3 is a schematic view showing a cross section along the alternate long and short dash line I-I'shown in FIG.
FIG. 4 is a schematic view showing a state in which the exterior panel according to the present embodiment is viewed from the back side (inside of an automobile).
FIG. 5 is a schematic perspective view showing an example of the configuration of the shock absorbing member according to the present embodiment.
FIG. 6 is a schematic schematic view showing a portion where the first shock absorbing member and the beltline reinforcement according to the present embodiment are connected.
FIG. 7 is a schematic perspective view showing in detail an example of an intersection of a first shock absorbing member and a second shock absorbing member according to the present embodiment.
FIG. 8 is a schematic view showing a door structure according to a comparative example.
FIG. 9 is a schematic view showing a cross section along the alternate long and short dash line II-II'shown in FIG.
FIG. 10 shows the relationship between the stroke of the indenter and the load received by the indenter when the exterior panel of the door is pushed by the indenter with respect to the configuration of the present embodiment shown in FIG. 2 and the configuration of the comparative example shown in FIG. It is a characteristic diagram.
Mode for carrying out the invention
[0011]
　Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the present specification and the drawings, components having substantially the same functional configuration are designated by the same reference numerals, so that duplicate description will be omitted.
[0012]
　In recent years, application of high-strength steel sheets to automobile exteriors has been studied. When a high-strength steel plate is applied, the thickness of the steel plate becomes thin, and the weight of the exterior material of the automobile can be reduced. For example, when a high-strength steel plate is applied to an exterior material having a conventional plate thickness of 0.7 mm, it is expected that even if the plate thickness is 0.4 mm, dent resistance equivalent to that of the conventional plate thickness of 0.7 mm can be obtained. can. However, since the tension rigidity of the exterior material depends on the plate thickness, if the plate thickness is reduced, the tension rigidity becomes insufficient. In other words, if the plate thickness is reduced, the exterior material is easily deformed when the exterior material is pushed by hand. On the other hand, in International Publication No. 2018/021422, the present inventors disclosed shock absorbing members arranged vertically and horizontally inside the exterior panel, and even if the thickness of the exterior material was reduced, the tension rigidity and impact resistance were increased. The weight has been reduced without degrading the performance. On the other hand, the present application achieves further weight reduction of the exterior material of the automobile.
[0013]
　FIG. 1 is a perspective view showing the structure of an automobile 1000 according to an embodiment of the present invention. As shown in FIG. 1, the automobile 1000 includes components such as a body 500, a door 600 (front door and / or rear door), a bonnet 700, a fender 800, and a boot lid 900. In the present embodiment, the structure of the automobile 1000, particularly in the vicinity of the door 600, will be described. The present invention can be applied to a sliding door as well as a door attached to the vehicle body via a hinge.
[0014]
　Normally, the door 600 and the body 500 refer to the door 600 with respect to the body 500 via a door hinge (or a door hinge provided on the B pillar 530) provided on the A pillar 510 (also referred to as a front pillar) of the body 500. They are connected so that they can rotate.
[0015]
　FIG. 2 is a schematic view showing the structure of the door 600, showing a state in which the door 600 is viewed from the outside of the automobile 1000. For convenience of explanation, in FIG. 2, only the impact absorbing member 120 of the exterior panel 100, which will be described later, is shown, and the exterior material 110 is not shown. Further, FIG. 3 is a schematic view showing a cross section along the alternate long and short dash line I-I'shown in FIG. The position of the alternate long and short dash line I-I'shown in FIG. 2 corresponds to the position of the alternate long and short dash line I-I'shown in FIG.
[0016]
　When the door 600 is a door (front door) on the front seat side of the automobile, the lower end 610 thereof is adjacent to the side sill 520 of the body 500 via the side panel in the closed state with respect to the body 500, and the front seat side of the automobile. The rear end 620 of the door 600 is adjacent to the B-pillar 530 (also referred to as the center pillar) of the body 500 via the side panel. The A pillar 510 and the B pillar 530 are also collectively referred to as pillars.
[0017]
　As shown in FIG. 3, the door 600 includes an exterior panel 100. The exterior panel 100 is a panel whose front side is exposed to the outside of the automobile 1000. The front surface of the exterior panel 100 is painted according to the color of the automobile 1000.
[0018]
　The exterior panel 100 is composed of an exterior material 110 and a shock absorbing member 120. As an example, the exterior material 110 is made of a steel plate having a thickness of about 0.4 to 0.7 mm. As an example, the exterior material 110 is curved so that the front side becomes a convex surface. That is, the exterior material 110 is curved in a cross section perpendicular to the vehicle length direction.
[0019]
　FIG. 4 is a schematic view showing a state in which the exterior panel 100 is viewed from the back side (inside of the automobile). The shock absorbing member 120 is a first shock absorbing member 122 arranged across the exterior panel 100 so as to extend over both end regions in the vehicle height direction of the exterior panel 100, and the vehicle length direction of the exterior panel 100. Includes a second shock absorbing member 124 arranged across the exterior panel 100 so as to extend over both end regions of the vehicle.
　Here, the "regions at both ends of the exterior panel 100 in the vehicle height direction" mean regions of up to 20% inward from both ends of the exterior panel 100 in the vehicle height direction.
　Further, the "regions at both ends of the exterior panel 100 in the vehicle length direction" mean regions of up to 10% inward from both ends of the exterior panel 100 in the vehicle length direction.
[0020]
　It is desirable that the first shock absorbing member 122 is curved according to the shape of the exterior material 110. The second shock absorbing member 124 extends substantially linearly and parallel to the vehicle length direction. However, when the exterior material 110 is curved in a cross section perpendicular to the vehicle height direction, it is desirable that the second shock absorbing member 124 has a shape that follows the curved shape of the exterior material 110. The first shock absorbing member 122 and the second shock absorbing member 124 can be in close contact with the exterior material 110 as long as they have a shape following the exterior material 110, and are preferably bonded (adhered) to the exterior material 110. Because it can be done. When the first shock absorbing member 122 or the second shock absorbing member 124 and the exterior material 110 are joined, the exterior material 110 is deformed when the first shock absorbing member 122 or the second shock absorbing member 124 is deformed. resist. That is, it is more preferable because the exterior material 110 can contribute to shock absorption.
[0021]
　A door inner panel 200 is provided inside the exterior panel 100. As an example, the door inner panel 200 is made of steel plate. Further inside of the door inner panel 200 faces the passenger compartment, and an interior material made of leather or a resin material is usually provided. In the vehicle width direction, a third shock absorbing member 126 is interposed between the first shock absorbing member 122 and the door inner panel 200.
[0022]
　FIG. 5 is a perspective view showing an example of the configuration of the shock absorbing member 120. The basic configurations of the first shock absorbing member 122 and the second shock absorbing member 124 can be the same. FIG. 5 also shows a cross-sectional configuration orthogonal to the longitudinal direction of the shock absorbing member 120. In the example shown in FIG. 5, the shock absorbing member 120 has a hollow rectangular cross section. The shock absorbing member 120 is manufactured by bending the plate material 130. Further, the shock absorbing member 120 may be manufactured of a hollow tubular member or a solid rod-shaped member. Further, the shock absorbing member 120 may have a hollow or solid trapezoidal cross section. Further, in the cross section of the first shock absorbing member 122 arranged in the vehicle height direction, the width in the vehicle width direction is equal to or larger than the width in the vehicle length direction, and the second shock absorbing member arranged in the vehicle length direction. In the cross section of 124, the width in the vehicle width direction is preferably equal to or larger than the width in the vehicle height direction. In the example shown in FIG. 5, the shock absorbing member 120 has a rectangular cross-sectional shape, and one side thereof has a long side H of about 6 to 20 mm and a short side D of about 6 to 16 mm. Further, the plate thickness of the plate material 130 constituting the shock absorbing member 120 is, for example, about 0.6 to 1.2 mm. As the plate material 130, a steel plate can be used. The tensile strength of the first shock absorbing member 122 and the second shock absorbing member 124 is preferably 980 MPa or more, more preferably 1470 MPa or more. Further, when the first impact absorbing member 122 and the second impact absorbing member 124 are formed from the steel sheet by press forming, cold forming may be used, or hot stamping may be adopted depending on the strength of the steel sheet.
[0023]
　As shown in FIG. 5, a predetermined gap may be provided between the end portion 130a and the end portion 130b of the bent plate member 130. On the other hand, the end portion 130a and the end portion 130b may be in close contact with each other. Further, the end portion 130a and the end portion 130b may be joined by welding, adhesion or the like. The cross section of the shock absorbing member 120 does not have to be continuous rectangular, annular or trapezoidal, and may be discontinuous due to the presence of gaps. Further, when an end portion is present in the cross section of the shock absorbing member 120, the end portions may be in close contact with each other, or the end portions may be joined by welding, adhesion, or the like.
　The shock absorbing member 120 is arranged so that the surface on which the ends 130a and 130b are located or the surface opposite to the surface on which the ends 130a and 130b are located is in close contact with the exterior material 110. Preferably, the surface on which the ends 130a and 130b are located or the surface opposite to the surface on which the ends 130a and 130b are located is joined to the exterior material 110.
[0024]
　As shown in FIG. 2, the door 600 is provided with a window frame 630. The end of the first shock absorbing member 122 on the window frame 630 side is supported by the beltline reinforcement 300. That is, the upper end of the first shock absorbing member 122 extending in the vehicle height direction is connected to the beltline reinforcement 300. The end portion of the first shock absorbing member 122 on the window frame 630 side is arranged outside the vehicle with respect to the beltline reinforcement 300.
[0025]
　In the present embodiment, the beltline reinforcement 300 has a function as a collision-resistant member that absorbs a load generated by a collision or the like. A general beltline reinforcement is provided in the vicinity of the window frame of the door on either or both of the passenger compartment side and the vehicle exterior side with the position of the window glass as a boundary. At this time, a beltline reinforcement with high material strength and bending rigidity is provided as a collision-resistant member on the vehicle interior side where it is easy to secure space, and relatively strong to reinforce the opening where the window glass enters and exits on the outside of the vehicle. It is common to have a low beltline reinforcement.
[0026]
　More specifically, in general, the beltline reinforcement includes a beltline inner reinforcement arranged on the vehicle interior side of the window glass and a beltline outer reinforcement arranged on the vehicle outside of the window glass. As the beltline inner reinforcement, a member having high strength and rigidity (for example, a pipe) is used to protect the occupants. Further, the beltline outer reinforcement is provided to reinforce the opening which is the entrance for the window glass to enter and exit. In order to reduce the weight, a high-rigidity member is not used as the beltline outer reinforcement, and for example, a metal plate having a plate thickness of about 0.6 mm is often used. Further, it is difficult to integrate the beltline inner reinforcement and the beltline outer reinforcement because the opening through which the window glass enters and exits cannot be reinforced.
[0027]
　The beltline reinforcement 300 according to the present embodiment corresponds to the beltline outer reinforcement because it supports the first shock absorbing member 122 in the vehicle height direction arranged outside the window glass. Then, in the present embodiment, the beltline reinforcement having a relatively high strength, which was conventionally arranged inside the window glass of the door 600, is arranged outside the vehicle than the window glass of the door 600, thereby causing the door 600. The collision resistance performance in the vicinity of the window frame 630 is improved. In other words, the beltline reinforcement 300 according to the present embodiment collides with the beltline reinforcement 300, which is different from the conventional beltline reinforcement only for reinforcing the opening, which is arranged outside the window glass of the door 600. It functions as a shock absorbing member that absorbs the shock of time.
[0028]
　Then, in the present embodiment, the upper end of the first shock absorbing member 122 extending in the vehicle height direction is connected to the beltline reinforcement 300, and the end of the first shock absorbing member 122 on the window frame 630 side is connected. By connecting the portion to the outside of the vehicle from the beltline reinforcement 300, the load applied from the outside of the door 600 is supported by the beltline reinforcement 300.
[0029]
　Further, by crossing the first shock absorbing member 122 and the second shock absorbing member 124 extending in the vehicle length direction, the collision resistance performance of the door 600 as a whole is improved. Hereinafter, the shock absorbing function of the beltline reinforcement 300, the first shock absorbing member 122, and the second shock absorbing member 124 will be described in detail.
[0030]
　As shown in FIG. 3, the beltline reinforcement 300 is composed of a sheet metal 310 having a shape along the exterior material 110 and a hat material 320 provided on the vehicle interior side of the sheet metal 310. By joining the hat material 320 to the sheet metal 310, the beltline reinforcement 300 has a tubular shape having an axis in the vehicle length direction, and the bending rigidity against a load from the outside of the door 600 is enhanced. ing.
[0031]
　The beltline reinforcement 300 according to the present embodiment is arranged in a narrow space inside the door 600, and high bending rigidity is required. Therefore, as the beltline reinforcement 300, a closed cross-section member as shown in FIG. 3, a solid material, a plate material thicker than other members, a member in which the closed cross-section member is filled with a filler, and the like are used. It is desirable to configure. The cross-sectional shape of the beltline reinforcement 300 shown in FIG. 3 is an example, and the cross-sectional shape of the beltline reinforcement 300 may be another shape. Further, the beltline reinforcement 300 may be composed of only the sheet metal 310 as long as the flexural rigidity can be ensured. As the material of the belt line reinforcement 300, various materials such as steel plate, stainless steel, aluminum, aluminum alloy, and CFRP (carbon fiber reinforced plastic) can be used.
[0032]
　FIG. 6 is a schematic view showing a portion where the first shock absorbing member 122 and the beltline reinforcement 300 are connected, and shows a region A1 surrounded by a chain double-dashed line in FIG. FIG. 6 shows a state in which the beltline reinforcement 300, the first shock absorbing member 122, and the second shock absorbing member 124 are viewed from the outside (exterior material 110 side) of the vehicle, and the exterior material 110 and the door inner. The panel 200 is not shown.
[0033]
　As shown in FIG. 6, the upper end of the first shock absorbing member 122 in the vehicle height direction is located outside the beltline reinforcement 300 and overlaps with the beltline reinforcement 300. Then, at the portion where the first shock absorbing member 122 and the beltline reinforcement 300 overlap, the first shock absorbing member 122 is joined to the beltline reinforcement 300 at the joint portion 122b. In other words, the first shock absorbing member 122 is joined to the beltline reinforcement 300 from the outside of the vehicle.
[0034]
　According to such a configuration, when the door 600 collides, the load due to the impact applied to the first impact absorbing member 122 is applied to the beltline reinforcement 300 from the outside of the vehicle toward the vehicle interior. Become. Since the first shock absorbing member 122 overlaps the beltline reinforcement 300 from the outside, the load can be reliably transmitted to the beltline reinforcement 300, and the load is applied by the beltline reinforcement 300. Can support.
[0035]
　As described above, the load due to the collision is transmitted from the first shock absorbing member 122 to the beltline reinforcement 300. Next, a configuration for transmitting the load due to the collision from the second impact absorbing member 124 to the first impact absorbing member 122 will be described.
[0036]
　The second shock absorbing member 124 extending in the vehicle length direction and the first shock absorbing member 122 extending in the vehicle height direction intersect at the intersection. At the intersection, the first shock absorbing member 122 and the second shock absorbing member 124 are in contact with each other. Here, "contact" includes not only direct contact but also joining via an adhesive such as mastic. FIG. 7 is a perspective view schematically showing an example of an intersection of the first shock absorbing member 122 and the second shock absorbing member 124. FIG. 7 schematically shows a state in which the first shock absorbing member 122 and the second shock absorbing member 124 are viewed from the outside (exterior material 110 side) of the vehicle. At the intersection, the second shock absorbing member 124 is located in the outer direction (exterior material 110 side) of the vehicle with respect to the first shock absorbing member 122. As shown in FIG. 7, the first shock absorbing member 122 may be provided with the recess 122a, and the second shock absorbing member 124 may be provided with the recess 124a. In other words, at the intersection of the first shock absorbing member 122 and the second shock absorbing member 124, the thickness of the first shock absorbing member 122 and / or the second shock absorbing member 124 in the vehicle width direction is increased. It may be decreasing. As a result, the first shock absorbing member 122 and the second shock absorbing member 124 are arranged in the same plane.
[0037]
　Since the second shock absorbing member 124 is located in the outer direction of the vehicle (on the side of the exterior material 110) with respect to the first shock absorbing member 122, another structure collides with the exterior panel 100 of the door 600. In this case, the load is transmitted from the exterior material 110 to the second shock absorbing member 124. The second shock absorbing member 124 is arranged in the vehicle length direction, and one second shock absorbing member 124 intersects the plurality of first shock absorbing members 122 at a plurality of intersections. Therefore, the load applied to one second shock absorbing member 124 is transmitted from the plurality of intersections to the plurality of first shock absorbing members 122. The plurality of first shock absorbing members 122 are arranged in the vehicle height direction, and the end portion of the door 600 on the window frame 630 side is supported by the beltline reinforcement 300, so that the load is the beltline reinforcement 300. Distributed to. Since the beltline reinforcement 300 is a shock absorbing member, has high collision resistance, and has high bending rigidity, the load due to collision can be received by the beltline reinforcement 300, and the impact can be absorbed more reliably. It will be possible. In particular, as shown in FIG. 2, the beltline reinforcement 300 extends not only within the range of the entrance of the window glass of the door 600 but also over the entire length of the door 600, and extends in the direction of the vehicle length of the beltline reinforcement 300. Both ends are installed so that the load can be transmitted to the A pillar 510 side and the B pillar 530 side. Therefore, the load due to the collision can be absorbed more reliably.
[0038]
　Here, the bending resistance of the member can be defined by the flexural rigidity of the member (Young's modulus × moment of inertia of area). In the present embodiment, the magnitude relation of the bending rigidity of the first impact absorbing member 122, the second impact absorbing member 124, and the beltline reinforcement 300 is optimally adjusted, and the second impact absorbing member 124 and the first impact are adjusted. By increasing the bending rigidity in the order of the absorbing member 122 and the beltline reinforcement 300, the impact absorbing performance of the door 600 is significantly improved. Hereinafter, the flexural rigidity of the first shock absorbing member 122, the second shock absorbing member 124, and the beltline reinforcement 300 according to the present embodiment will be described in detail.
[0039]
　As described above, the second impact absorbing member 124 in the vehicle length direction has a function of transmitting an impact load to the first impact absorbing member 122 in the vehicle height direction. Then, the impact load is mainly absorbed by the first impact absorbing member 122 in the vehicle height direction. First, in the portion excluding the both end regions in the vehicle height direction, the both end regions in the vehicle length direction, and the intersection, the cross section of the first shock absorbing member 122 extending in the vehicle height direction (in the vehicle width direction). The bending rigidity (around the axis in the vehicle length direction) is larger than the bending rigidity (around the axis in the vehicle height direction) in the vehicle width direction of the cross section of the second shock absorbing member 124 extending in the vehicle length direction. In particular, the flexural rigidity of the cross section of the first impact absorbing member 122 in the vehicle width direction is preferably 1.5 times or more larger than the bending rigidity of the cross section of the second shock absorbing member 124 in the vehicle width direction. It is more preferably twice or more larger, and even more preferably 10 times or more.
　Further, even at the intersection, the bending rigidity of the cross section of the first shock absorbing member 122 in the vehicle width direction is preferably larger than the bending rigidity of the cross section of the second shock absorbing member 124 in the vehicle width direction. In this case as well, it is preferably 1.5 times or more larger, and more preferably 10 times or more larger, as described above.
　Further, the flexural rigidity of the cross section of the first shock absorbing member 122 at the intersection in the vehicle width direction is the cross section of the second shock absorbing member 124 at the portion excluding both end regions and the intersection in the vehicle length direction. It may be larger than the flexural rigidity in the vehicle width direction. In this case as well, it may be 1.5 times or more larger, and further 5 times or more larger, as described above.
　The cross section means a cross section perpendicular to the extending direction of the shock absorbing member.
[0040]
　The reason why the bending rigidity of the first shock absorbing member 122 is made larger than that of the second shock absorbing member 124 is as follows. The door 600 of an automobile is often configured so that the length in the vehicle length direction is longer when the vehicle length direction and the vehicle height direction are compared. In the case of a shock absorbing member having the same cross-sectional shape, when both ends thereof are supported, the longer one is more likely to be deformed when a load is applied to the center. Therefore, comparing the second shock absorbing member 124 that crosses the vehicle length direction and the first shock absorbing member 122 that crosses the vehicle height direction, the first impact that crosses the vehicle height direction in the case of the same cross-sectional shape. The absorbing member 122 is stronger. Further, when comparing the vehicle length direction and the vehicle height direction of the exterior material 110 of the automobile door 600, the shape of the cross section perpendicular to the vehicle length direction in the vehicle height direction has a curvature that the outside in the vehicle width direction is convex. Is often large. Considering the case where the shock absorbing member 120 has a shape along the exterior material 110, when the shock absorbing member 120 receives a load toward the inside in the vehicle width direction, that is, when a collision load is applied to the side surface of the automobile 1000, Since the axial force of compression acts on the first impact absorbing member 122 having a large curvature that is convex on the outside in the vehicle width direction, the deformation inward in the vehicle width direction is further suppressed. That is, the first shock absorbing member 122 can withstand a larger load than the second shock absorbing member 124. In other words, the first shock absorbing member 122 extending in the vehicle height direction has higher shock absorbing performance. Therefore, in order to improve the impact absorption performance of the door 600 more efficiently, it is better to increase the bending rigidity of the first impact absorbing member 122 than that of the second impact absorbing member 124.
[0041]
　In order to transmit the impact load applied to the second shock absorbing member 124 in the vehicle length direction to the first shock absorbing member 122 in the vehicle height direction, the second shock absorbing member 124 in the vehicle length direction is the second in the vehicle height direction. It is arranged on the outside of the vehicle (exterior material side) from the shock absorbing member 122 of 1. At this time, since the main role of the second shock absorbing member 124 is to transmit the load to the first shock absorbing member 122, the impact of the door 600 is caused by reducing the bending rigidity of the second shock absorbing member 124. The effect on the absorption performance is smaller than the effect of reducing the bending rigidity of the first impact absorbing member 122. Since the flexural rigidity is reduced when the cross section of the shock absorbing member 120 is reduced or the thickness of the constituent plate material is reduced, the bending rigidity of the first shock absorbing member 122 is relatively large, and the second shock absorbing member is absorbed. By setting the flexural rigidity of the member 124 to be relatively small, it is possible to efficiently improve the impact absorption performance of the door 600 without increasing the weight excessively.
[0042]
　If the bending rigidity of the cross section of the second shock absorbing member 124 in the vehicle width direction is larger than the bending rigidity of the cross section of the first shock absorbing member 122 in the vehicle width direction, the second impact is more than necessary. The weight of the absorbing member 124 becomes large, which does not meet the purpose of reducing the weight of the door 600 intended by the present embodiment.
[0043]
　Next, the bending rigidity of the first shock absorbing member 122 and the beltline reinforcement 300 will be described. As described above, the end portion of the first shock absorbing member 122 in the vehicle height direction on the window frame 630 side is supported by the beltline reinforcement 300. At the location (supporting portion) where the beltline reinforcement 300 supports the end of the first shock absorbing member 122 or in the vicinity thereof, the flexural rigidity of the cross section of the beltline reinforcement 300 in the vehicle width direction is the first. It is larger than the flexural rigidity of the cross section of the shock absorbing member 122 in the vehicle width direction. In particular, the flexural rigidity of the cross section of the beltline reinforcement 300 in the vehicle width direction is preferably twice or more larger than the flexural rigidity of the cross section of the first shock absorbing member 122 in the vehicle width direction, and is 10 times or more larger. Is more preferable, and it is further preferable that it is 20 times or more larger.
[0044]
　As described above, the first shock absorbing member 122 overlaps the beltline reinforcement 300 from the outside, and the support portion of the beltline reinforcement 300 supports the load applied from the first shock absorbing member 122. The load due to the impact is transmitted from the second impact absorbing member 124 to the first impact absorbing member 122, and is finally received by the beltline reinforcement 300. Therefore, by making the flexural rigidity of the cross section of the beltline reinforcement 300 in the vehicle width direction larger than the flexural rigidity of the cross section of the first shock absorbing member 122 in the vehicle width direction, the beltline reinforcement 300 can be used. The load can be reliably received.
[0045]
　If the bending rigidity of the cross section of the first shock absorbing member 122 in the vehicle width direction is larger than the bending rigidity of the cross section of the beltline reinforcement 300 in the vehicle width direction, the first shock absorbing member in the vehicle height direction is used. Since the beltline reinforcement 300 is deformed before the 122 sufficiently absorbs the impact load, the object of the impact absorption according to the present embodiment is not met. Further, in this case, since the weight of the first shock absorbing member 122 in the vehicle height direction becomes heavier than necessary, the purpose of reducing the weight of the door 600 intended by the present embodiment is not met. The flexural rigidity of the first shock absorbing member 122 and the bending rigidity of the belt line reinforcement 300 are compared with the bending rigidity of the cross section in the vehicle width direction at the intersection of the first shock absorbing member 122 and the belt line rain. This is a comparison with the flexural rigidity of the cross section of the support portion of the first shock absorbing member 122 of the force 300 in the vehicle width direction. The first shock absorbing member 122 may not have a uniform cross-sectional shape in the longitudinal direction. Especially at the intersection, in order to arrange the first shock absorbing member 122 and the second shock absorbing member 124 in the same plane as described above, the first shock absorbing member 122 and the second shock absorbing member 124 When the recesses 122a and 124a are provided, the thickness of the recesses 122a and 124a decreases in the vehicle width direction. Flexural rigidity may be smaller than at locations other than intersections. Therefore, the flexural rigidity of the first shock absorbing member 122 for comparison with the bending rigidity of the beltline reinforcement 300 may be smaller than that of other parts in the first shock absorbing member 122. The flexural rigidity of the cross section in the vehicle width direction at a certain intersection.
[0046]
　Next, a comparative example of the above-described embodiment of the present invention will be described with reference to FIGS. 8 and 9. FIG. 8 is a schematic view showing the structure of the door 600 according to the comparative example, and shows a state in which the door 600 is viewed from the outside of the automobile 1000 as in FIG. Further, FIG. 9 is a schematic view showing a cross section along the alternate long and short dash line II-II'shown in FIG. The position of the alternate long and short dash line II-II'shown in FIG. 8 corresponds to the position of the alternate long and short dash line I-I'shown in FIG.
[0047]
　The comparative example shown in FIGS. 8 and 9 includes the above-mentioned beltline inner reinforcement 360 arranged on the vehicle interior side of the window glass and the beltline outer reinforcement 350 arranged on the vehicle outside of the window glass. Corresponds to. As described above, the beltline outer reinforcement 350 is provided for reinforcing the opening which is the entrance / exit of the window glass, and is composed of a metal plate. Since the beltline outer reinforcement 350 is only responsible for reinforcing the opening, it is not a member having collision resistance and high material strength and bending rigidity. Further, since the beltline outer reinforcement 350 is only responsible for reinforcing the opening, it is not arranged over the entire length of the door 600 as shown in FIG. 8, but is arranged only in the range of the entrance of the window glass. ing. That is, since both ends of the beltline outer reinforcement 350 in the vehicle length direction are not installed so as to be able to transmit the load to the A pillar 510 side and the B pillar 530 side, the load due to the collision cannot be sufficiently absorbed. .. On the other hand, the beltline inner reinforcement 360 is a collision-resistant member, and is composed of a member having high material strength and bending rigidity. As shown in FIG. 9, the beltline inner reinforcement 360 is composed of a cylindrical member extending in the vehicle length direction.
[0048]
　In the configuration of the comparative example shown in FIGS. 8 and 9, the first shock absorbing member 122 is connected to the beltline outer reinforcement 350.
[0049]
　In the configuration of the comparative example shown in FIGS. 8 and 9, the weight of the door 600 is considered to be the same. In the configuration of the present embodiment shown in FIGS. 2 and 3, and the configuration of the comparative example shown in FIGS. 8 and 9, the belt line reinforcement 300 of the present embodiment is the belt line outer reinforcement 350 and the belt line inner of the comparative example. The difference is that it replaces the Reinforce 360 ​​and the first shock absorbing member 122 is connected to the belt line outer reinforcement 350, and the other configurations are basically the same including the weight. ..
[0050]
　FIG. 10 shows the configuration of the embodiment of the present invention shown in FIGS. 2 and 3 and the configuration of the comparative example shown in FIGS. 8 and 9 with the center of the exterior panel 100 of the door 600 as the axis in the vehicle height direction having a radius of 20 mm. It is a characteristic diagram obtained by simulation the relationship between the stroke of the indenter and the load received by the indenter from the door 600, assuming the case of pushing with the columnar indenter held in the door 600. As shown in FIG. 10, in the case of the same stroke, the load characteristics of the present embodiment are improved as compared with the comparative example, and the difference is remarkable when the stroke is 20 mm or more. As described above, the weights of the doors of the present embodiment and the comparative examples are the same. Therefore, according to the configuration of the present embodiment, it can be seen that the shock absorption performance is remarkably higher than that of the comparative example in which the weight reduction equivalent to that of the present embodiment is achieved. Therefore, it can be understood that the impact absorption performance can be significantly improved by the configuration of the present embodiment.
[0051]
　In the above description, the case where each member such as the first shock absorbing member 122, the second shock absorbing member 124, the third shock absorbing member 126, and the door inner panel 200 is made of a steel plate has been illustrated. These members may be composed of other materials such as aluminum, aluminum alloy, and CFRP (carbon fiber reinforced plastic).
[0052]
　As described above, according to the present embodiment, the beltline reinforcement 300 supports the window side end portion of the first shock absorbing member 122, and the beltline reinforcement 300 is closer to the passenger compartment side than the first shock absorbing member 122. It was configured to be placed in. Further, the flexural rigidity of the cross section of the beltline reinforcement 300 in the vehicle width direction is made larger than the flexural rigidity of the cross section of the first shock absorbing member 122 in the vehicle width direction. As a result, when a load is applied to the door 600, the load transmitted from the first shock absorbing member 122 to the beltline reinforcement 300 can be more reliably supported.
[0053]
　Therefore, when the exterior material is made stronger and thinner for the purpose of weight reduction, the tension rigidity of the exterior material can be improved and the impact resistance performance at the time of collision can be ensured. Become.
[0054]
　Although the preferred embodiments of the present invention have been described in detail with reference to the accompanying drawings, the present invention is not limited to such examples. It is clear that a person having ordinary knowledge in the field of technology to which the present invention belongs can come up with various modifications or modifications within the scope of the technical idea of ​​the present invention. Naturally, it is understood that it belongs to the technical scope of the present invention.
[0055]
　The present invention can be applied to the front door and the rear door of an automobile. Further, the present invention can be applied not only to doors arranged on the side of an automobile but also on doors (also referred to as tailgates) arranged on the rear of an automobile. When the present invention is applied to a door arranged at the rear of an automobile, the inner panel of such a door intersects the vehicle length direction, so that the vehicle length direction described in the above embodiment is read as the vehicle width direction. The vehicle width direction may be read as the vehicle length direction.
Industrial applicability
[0056]
　The present invention has high industrial applicability because it can provide an automobile door capable of more reliably absorbing an impact.
Code description
[0057]
　122 First shock absorbing member
　124 Second shock absorbing member
　300 Beltline Reinforce
　520 Side sill
　600 Door
　1000 Automobile

WE CLAIMS

A first shock absorbing member which is an
　automobile door and crosses the automobile door so as to extend over both end regions in the vehicle height direction, and the automobile door so as to extend over both end regions in the vehicle length direction. A second shock absorbing member, an
　exterior material, and a
　belt line reinforcement
　are provided, and
　the second shock absorbing member is adjacent to the exterior material, and
　the first shock absorbing member and the second shock absorbing member are provided. The members intersect at the intersection,
　the first shock absorbing member and the second shock absorbing member come into contact at the crossing, and
　the second shock absorbing member is the exterior material and the first shock absorbing member. A
　vehicle having a cross section perpendicular to the extending direction of the first shock absorbing member in a portion other than the both end regions in the vehicle height direction, the both end regions in the vehicle length direction, and the intersection. The bending rigidity in the width direction is larger than the bending rigidity in the vehicle width direction of the cross section perpendicular to the extending direction of the second shock absorbing member, and the
　belt line reinforcement is the window side end portion of the first shock absorbing member.
　Is supported by a support portion, the belt line reinforcement is arranged on the vehicle interior side from the first shock absorbing member, and the
　vehicle width direction of the cross section perpendicular to the extending direction of the belt line reinforcement in the support portion. The bending rigidity of the automobile door is larger than the bending rigidity in the vehicle width direction of the cross section perpendicular to the extending direction of the first shock absorbing member at the intersection.
[Claim 2]
　At the intersection of the first shock absorbing member and the second shock absorbing member, the thickness of the first shock absorbing member and / or the second shock absorbing member in the vehicle width direction is reduced. The automobile door according to claim 1.
[Claim 3]
　At the intersection, the flexural rigidity of the cross section perpendicular to the extending direction of the first shock absorbing member in the vehicle width direction is the vehicle width direction of the cross section perpendicular to the extending direction of the second shock absorbing member. The
automobile door according to claim 2, wherein the automobile door is larger than the flexural rigidity of the above.
[Claim 4]
　The automobile door according to any one of claims 1 to 3, wherein the second shock absorbing member is joined to the first shock absorbing member.
[Claim 5]
　The automobile door according to any one of claims 1 to 4, wherein the width in the vehicle width direction is equal to or larger than the width in the vehicle length direction in a cross section perpendicular to the extending direction of the first shock absorbing member.
[Claim 6]
　The automobile door according to any one of claims 1 to 5, wherein the width in the vehicle width direction is equal to or larger than the width in the vehicle height direction in a cross section perpendicular to the extending direction of the second shock absorbing member.