JP5571504B2 - Shock absorbing member for vehicle - Google Patents

Description

  The present invention relates to an impact absorbing member for a vehicle used as a crash box of an automobile bumper beam and the related technology.

 A bumper beam is provided inside a bumper provided at, for example, a front end of an automobile in order to absorb an impact at the time of a collision.

  The bumper beam has a bumper reinforcement arranged along the vehicle width direction and a pair of left and right crash boxes that support the bumper reinforcement on the vehicle structure, and absorbs collision energy by compressive plastic deformation of the crash box. ing.

  As such a shock absorbing crash box, those shown in the following Patent Documents 1 to 3 are well known.

  The crash box shown in Patent Documents 1 and 2 is integrally provided with a small-diameter pipe part constituting one half, a large-diameter pipe part constituting the other half, and a step part connecting both pipes. The impact energy is absorbed by immersing the small-diameter pipe part into the large-diameter pipe part while plastically deforming so that the step part of the part is continuously inserted inward.

  The crash box shown in Patent Document 3 absorbs collision energy by two-stage plastic deformation, ie, diameter reduction deformation and crushing deformation. That is, this crush box has a small-diameter pipe and a large-diameter pipe to which one end of the small-diameter pipe is press-fitted and fixed separately. When the small diameter pipe is press-fitted into the large diameter pipe, the large diameter pipe is crushed and deformed in a bellows shape to absorb the collision energy.

Japanese Patent No. 4436620 Special table 2007-503561 US Patent Application Publication No. 2010/00727764

  By the way, the crash box as the shock absorbing member is compressively deformed in the axial direction (vehicle longitudinal direction) and absorbs the collision energy. Therefore, when the compression deformation is finished, the crash box absorbs the impact energy. After that, the impact will be directly applied to the vehicle structure. Therefore, if the length of the crash box in the axial direction is increased to increase the amount of compression displacement (effective stroke length) at the time of collision, even large collision energy can be absorbed smoothly, improving the shock absorption characteristics. Can be made.

  However, since the crash box is arranged in a limited installation space between the bumper reinforcement and the vehicle structure, it is possible to ensure a sufficient axial length of the crash box. Have difficulty.

  Under such a technical background, for example, in the crash box shown in Patent Documents 1 and 2, since the small diameter pipe portion is immersed in the large diameter pipe portion, the effective stroke length is about half of the total length of the crash box. Thus, there is a problem that it is difficult to sufficiently secure the effective stroke length and it is difficult to improve the shock absorption characteristics.

  In the crash box shown in Patent Document 3, the impact absorption by the crash box is completed when the crushing deformation of the large-diameter pipe is completed. At that time, the collapsed bellows-like large-diameter pipe (crushed) The remaining part) remains between the bumper reinforcement and the vehicle structure. Since this remaining portion does not function as the effective stroke length, the effective stroke length is reduced correspondingly, and there is a problem that it is difficult to improve the shock absorption characteristics as described above.

  This invention is made in view of said subject, and it aims at providing the impact-absorbing member for vehicles which can ensure sufficient effective stroke length and can improve an impact-absorbing characteristic.

  In order to solve the above problems, the present invention comprises the following means.

[1] A vehicle impact absorbing member applied to a vehicle having a hollow side frame,
With the proximal end of the small-diameter pipe inserted into the distal end of the large-diameter pipe, the overlapping part of both pipes is expanded or contracted to form an overlapping convex part protruding in the outer diameter direction or inner diameter direction. By connecting the small diameter pipe and the large diameter pipe,
The large-diameter pipe is fixed to the side frame in a state where at least a part of the large-diameter pipe is accommodated in the distal end portion of the side frame, and the small-diameter pipe is arranged in a manner protruding from the distal end of the side frame,
Of the small-diameter pipe and large-diameter pipe, the pipe disposed on the protruding direction side of the overlapping convex part is a deformed pipe, and the remaining one pipe is a non-deformed pipe.
When an impact along the axial direction is applied to the small-diameter pipe from its distal end side, the peripheral wall of the deformable pipe is plastically deformed in the outer diameter direction or the inner diameter direction by the overlapping convex portion of the non-deformable pipe, and the small-diameter pipe The shock absorbing member for vehicles is characterized in that the impact energy is absorbed by being press-fitted into the large-diameter pipe, and at least the base end of the small-diameter pipe is accommodated in the side frame. .

[2] A substantially entire area excluding the axial tip of the large-diameter pipe is disposed in the side frame,
2. The impact absorbing member for a vehicle according to item 1, wherein substantially the entire area of the small-diameter pipe is configured to be press-fit into the large-diameter pipe.

  [3] The vehicle impact absorbing member according to item 1 or 2, wherein the overlapping convex portion is disposed in the side frame.

[4] The overlapping convex portion is constituted by an outward convex portion protruding in the outer diameter direction,
When an impact is applied to the small-diameter pipe, the outer convex portion of the small-diameter pipe is plastically deformed so that the peripheral wall of the large-diameter pipe forming the deformed pipe is expanded in the outer diameter direction. 4. The vehicle impact absorbing member according to any one of items 1 to 3.

[5] The overlapping convex portion is constituted by an inward convex portion protruding in the inner diameter direction,
The preceding item 1 in which, when an impact is applied to the small-diameter pipe, the inward convex portion of the large-diameter pipe is plastically deformed so that a peripheral wall of the small-diameter pipe forming the deformed pipe is pushed in an inner diameter direction. The shock absorbing member for a vehicle according to any one of?

  [6] The vehicle impact absorbing member according to any one of [1] to [5], wherein the overlapping convex portion is formed in a whole area in a circumferential direction of the small diameter pipe and the large diameter pipe.

  [7] The vehicle impact absorbing member according to any one of [1] to [5], wherein the overlapping convex portion is formed on a part of a circumferential direction of the small diameter tube and the large diameter tube.

  [8] The vehicle impact absorbing member according to any one of the aforementioned Items 1 to 7, wherein the overlapping convex portion is formed by tube expansion processing or contraction processing using a mold.

[9] An impact absorbing device applied to a vehicle having a hollow side frame extending in the front-rear direction on both sides of the vehicle,
A crash box configured by the vehicle impact absorbing member according to any one of the preceding items 1 to 8,
A bumper reinforcement attached to a tip of a small-diameter pipe in the crash box and disposed along a vehicle width direction.

  [10] A stay is attached to the distal end surface of the side frame, and the distal end of the large-diameter pipe is expanded in a state where the large-diameter pipe is inserted into a large-diameter pipe attachment hole provided in the stay. 10. The vehicle shock absorption according to claim 9, wherein the expanded diameter portion is press-engaged with a peripheral portion of the large diameter tube mounting hole of the stay so that the large diameter tube is attached to the side frame via the stay. apparatus.

  [11] A tip end portion of the small-diameter pipe is expanded in a state where the small-diameter pipe is inserted and arranged along the axial direction in a small-diameter pipe mounting hole provided in the bumper reinforcement. 11. The vehicle impact absorbing device according to item 9 or 10, wherein the bumper reinforcement is attached to the small-diameter pipe by being pressed and engaged with a peripheral part of the small-diameter pipe attachment hole of the reinforcement.

[12] A crash box that supports bumper reinforcements arranged along the vehicle width direction and absorbs collision energy applied to the bumper reinforcements,
While constituted by the vehicle impact absorbing member according to any one of the preceding items 1 to 8,
The crash box, wherein the bumper reinforcement is attached to a tip of the small-diameter pipe.

[13] Bumper reinforcements arranged along the vehicle width direction;
A crash box that supports the bumper reinforcement and absorbs collision energy applied to the bumper reinforcement;
The crash box is configured by the vehicle impact absorbing member according to any one of the preceding items 1 to 8,
The bumper beam is characterized in that the bumper reinforcement is attached to the tip of the small diameter tube.

  According to the vehicle impact absorbing member of the invention [1], at least a part of the large-diameter pipe into which the small-diameter pipe is press-fitted when absorbing the shock is accommodated in the side frame, and the base end portion of the small-diameter pipe when absorbing the shock. Since the frame is accommodated in the side frame, a long effective stroke length can be secured. In addition, the overlapping convex part of one of the small-diameter pipe and the large-diameter pipe continuously plastically deforms the peripheral wall of the other pipe in the radial direction to absorb the collision energy. The collision energy can be absorbed well, the collision energy can be absorbed smoothly immediately after the collision, and excellent shock absorption characteristics can be obtained.

  According to the vehicle impact absorbing member of the invention [2], the effective stroke length can be further increased, and the impact absorbing characteristics can be improved more reliably.

  According to the vehicle impact absorbing member of the invention [3], the effective stroke length can be further increased, and the impact absorbing characteristics can be improved more reliably.

  According to the vehicle impact absorbing member of the invention [4] or [5], the collision energy can be absorbed more reliably.

  According to the vehicle impact absorbing member of the invention [6], the amount of collision energy absorbed can be increased.

  According to the vehicle impact absorbing member of the invention [7], the amount of collision energy absorbed can be adjusted as appropriate.

  According to the impact absorbing member for a vehicle of the invention [8], it is possible to more reliably form the polymerization convex portion having excellent dimensional accuracy.

  According to the invention [9], it is possible to provide a vehicular shock absorbing device having the same effects as the vehicular shock absorbing member.

  According to the invention [10], the crash box can be easily and reliably attached to the side frame.

  According to the invention [11], the bumper reinforcement can be easily and reliably attached to the crash box.

  According to the invention [12], it is possible to provide a crush box having the same effects as the above-described vehicle impact absorbing member.

  According to the invention [13], it is possible to provide a bumper beam having the same effects as the above-described vehicle impact absorbing member.

FIG. 1 is a perspective view showing an automobile impact absorbing device to which a crash box according to an embodiment of the present invention is applied. FIG. 2 is a horizontal sectional view showing the shock absorbing device of the embodiment. FIG. 3 is an enlarged horizontal sectional view showing the vicinity of the crash box in the impact absorbing device of the embodiment. 4 is an enlarged horizontal sectional view of a portion surrounded by a two-dot chain line in FIG. 5 is an enlarged horizontal sectional view of a portion surrounded by a two-dot chain line in FIG. FIG. 6 is a horizontal cross-sectional view for explaining the behavior at the time of compressive deformation in the crash box of the embodiment. FIG. 7 is a graph showing the relationship between the load at the time of collision and the amount of displacement of the crash box in the shock absorber of the embodiment. FIG. 8 is an enlarged horizontal sectional view showing the periphery of a crash box in an automobile impact absorbing device which is a modification of the present invention. FIG. 9 is a graph showing the relationship between the load at the time of collision and the amount of displacement of the crash box in the conventional crush deformation type shock absorber.

 FIG. 1 is a perspective view showing an automobile impact absorbing device to which a crash box according to an embodiment of the present invention is applied, and FIG. 2 is a horizontal sectional view showing the impact absorbing device.

  As shown in both figures, the automobile impact absorbing device in this embodiment is provided at the front of the vehicle. A body of an automobile to which the shock absorbing device is applied has a pair of left and right side members 6 and 6 extending in the front-rear direction on both the left and right sides. The impact absorbing device of the present embodiment is configured by assembling the bumper beam 1 described below.

  The side member 6 constitutes a side frame as a vehicle structure, and has a hollow structure provided with a hollow portion 65 having a rectangular cross section and continuously extending in the length direction.

  As shown in FIG. 3, an inward flange 61 projecting inward is formed on the inner periphery of the front end of the side member 6.

  A stay 7 is provided on the front end surface of the side member 6. The stay 7 is formed in a rectangular shape corresponding to the opening shape of the front end of the side member 6 when viewed from the front of the vehicle (front view state), and has a crash box mounting hole (large diameter tube mounting hole) in the center. 75 is formed. The mounting hole 75 is formed in a circular shape corresponding to a large-diameter pipe 5 of the crash box 3 to be described later, and has a larger diameter than the large-diameter pipe 5 so that the large-diameter pipe 5 can be inserted. ing.

  With the stay 7 disposed so as to close the front end opening of the side member 6, the outer peripheral portion is fixed to the inward flange 61 of the side member 6 by fixing means such as bolting or welding.

  As shown in FIGS. 1 and 2, a bumper beam 1 according to the present embodiment is provided on a front end of an automobile along bumper reinforcements 2 arranged along the vehicle width direction, and on both sides of the bumper reinforcements 2. A crash box 3 for supporting the reinforcement 2 on the side member 6 is provided.

  As shown in FIGS. 2 and 3, the crash box 3 functions as an impact absorbing member, and has a small diameter tube 4 disposed on the front side (front end side), a rear side (base end side), and a small diameter. A large-diameter pipe 5 separate from the pipe 4 is provided.

  The small-diameter pipe 4 and the large-diameter pipe 5 are made of, for example, an extruded shape material or a drawn shape material made of aluminum or an alloy thereof.

  Both the small diameter pipe 4 and the large diameter pipe 5 have a circular cross section. The small-diameter pipe 4 has a smaller diameter than the large-diameter pipe 5 and is slightly smaller in size. The small-diameter pipe 4 can be inserted into the large-diameter pipe 5 while aligning the axis of each other.

  The large-diameter pipe is in a state where almost the entire area of the large-diameter pipe 5 of the crash box 3 except the front end (tip) is accommodated in the hollow portion 65 of the side member 6 via the crash box mounting hole 75 of the stay 7. The front end of 5 is fixed to the stay 7 by tube expansion processing (expanding processing). That is, as shown in FIG. 4, expanded pipe portions 55, 55 projecting in the outer diameter direction and continuing in the circumferential direction are formed on the front and rear sides of the crush box mounting hole 75 of the stay 7 at the front end of the large diameter pipe 5 by pipe expansion processing. Then, the large-diameter pipe 5 of the crash box 3 is connected and fixed to the stay 7 by press-engaging the expanded pipe portions 55 and 55 with the peripheral edge portion of the mounting hole 75 in the stay 7.

  In the present invention, the tube expansion method is not particularly limited, but a tube expansion method using a mold can be suitably employed. As the pipe expansion processing method using the mold, the push type that pushes the mandrel and the pull type that pulls the mandrel into the pipe expansion die installed in the pipe are well known. In the invention, any method can be suitably employed. Thus, by using the pipe expansion process using a metal mold, the pipe expansion part 55, the polymerization convex parts 41 and 51 and the pipe expansion part 45, which will be described later, can be accurately and reliably formed.

  Further, in the state where the rear end portion (base end portion) of the small diameter tube 4 in the crush box 3 is inserted into the front end portion (tip end portion) of the large diameter tube 5, a portion where the two tubes 4 and 5 overlap (overlapping portion). That is, the rear end (base end) of the small diameter tube 4 and the front end (tip end) of the large diameter tube 5 are fixed by the pipe expansion process. That is, as shown in FIG. 4, outward convex portions 41 and 51 as superposed convex portions protruding in the outer diameter direction are formed at the rear end of the small diameter tube 4 and the front end of the large diameter tube 5 by the same pipe expansion process as described above. The small-diameter tube 4 is connected to the large-diameter tube 5 by press-fitting the outer peripheral surface of the outward-convex portion 41 on the small-diameter tube 4 side to the inner peripheral surface of the outward-convex portion 51 on the large-diameter tube 5 side. It is fixed (fastened and fixed).

  In the present embodiment, the outward projecting portions 41 and 51 are formed over the entire circumference continuously in the circumferential direction of the small diameter tube 4 and the large diameter tube 5.

  Here, in the present embodiment, of the small diameter pipe 4 and the large diameter pipe 5, the large diameter pipe 5 is arranged on the protruding direction of the overlapping convex portions 41 and 51 (the outer diameter direction of the pipes 4 and 5). Therefore, while being configured as a deformed tube, the small-diameter tube 4 is arranged on the side opposite to the protruding direction of the overlapping convex portions 41 and 51 (inner diameter direction of the tubes 4 and 5). Composed.

  Further, in the present embodiment, the outward projecting portions 41 and 51 are arranged inside the stay 7, that is, inside the side member 6.

  As shown in FIGS. 1 and 2, the bumper reinforcement 2 is constituted by an extruded shape member, a plate member, a drawn shape member, or the like made of aluminum or an alloy thereof, a plate press product made of a steel material, or the like.

  The bumper reinforcement 2 is integrated in a cross-sectional shape between the outer peripheral wall 21 formed in a vertically long rectangular shape in the cross-sectional shape and the front and rear walls of the outer peripheral wall 21 at an intermediate position in the height direction of the outer peripheral wall 21. A horizontal reinforcing partition wall 22 (see FIG. 1) is formed, and is formed in a so-called “day” cross-sectional shape. The partition wall 22 is formed continuously in the length direction of the bumper reinforcement 2 except for a portion to which the crash box 3 is attached.

  Further, the bumper reinforcement 2 is formed so that the intermediate portion slightly protrudes forward by bending the both side portions in the vehicle width direction rearward in a plan view.

  Crash box mounting holes (small-diameter pipe mounting holes) 25 and 25 penetrating in the front-rear direction are formed in the front and rear walls of the outer peripheral wall 21 at both ends in the length direction (vehicle width direction) of the bumper reinforcement 2. Yes.

  As shown in FIGS. 2 and 5, the front portion (tip portion) of the small diameter tube 4 in the crash box 3 is inserted into the crash box mounting holes 25, 25 on both front and rear walls of the bumper reinforcement 2. Is fixed to the bumper reinforcement 2 by pipe expansion processing. That is, on the front and rear sides of the crash box mounting holes 25, 25 of the bumper reinforcement 2 at the front portion of the small-diameter tube 5, the expanded portions 45, 45 projecting in the outer diameter direction and continuing in the circumferential direction by the same expansion processing as described above. The small-diameter pipe 4 of the crash box 2 is connected and fixed to the bumper reinforcement 2 by forming the pipe expansion parts 45 and 45 and press-fitting the peripheral portions of the mounting holes 25 and 25 in the bumper reinforcement 2.

  In the shock absorbing device of the present embodiment, the assembly procedure is not particularly limited, but the large diameter tube 5 is preferably attached to the stay 7 before the small diameter tube 4 and the large diameter tube 5 are connected. .

  That is, after connecting the small-diameter pipe 4 and the large-diameter pipe 5, if the large-diameter pipe 5 is to be attached to the stay 7, only the large-diameter pipe 5 is provided with the inner-diameter pipe 4 disposed inside the large-diameter pipe 5. Needs to be expanded and attached to the stay 7, and the expansion may be difficult. Therefore, as described above, the large-diameter pipe 5 is preferably attached to the stay 7 before the small-diameter pipe 4 and the large-diameter pipe 5 are connected.

  The small diameter pipe 4 may be attached to the bumper reinforcement 2 at any stage. For example, the small diameter pipe 4 may be attached to the bumper reinforcement 2 and the small diameter pipe 4 and the large diameter pipe 5 may be connected simultaneously. Is possible.

  In the automobile impact absorbing device of the present embodiment having the above configuration, when an impact due to a collision is applied to the bumper reinforcement 2 in the state (initial state) shown by the solid line in FIG. Furthermore, the small-diameter pipe 4 in the crash box 3 is press-fitted into the large-diameter pipe 5 while being plastically deformed (expanded deformation) so as to push the peripheral wall of the large-diameter pipe 5 in the outer diameter direction by the outward convex portion 41. The collision energy is absorbed by the diameter expansion deformation at that time. In FIG. 6, the shape and size of the outward projecting portions 41 and 51 are shown differently from those in FIGS. 2 and 3 in order to facilitate understanding of the invention such as the behavior of pipe expansion deformation. .

  According to the impact absorbing device of the present embodiment having the above configuration, the peripheral wall of the large-diameter pipe 5 is continuously expanded and deformed by the outward convex portion 41 of the small-diameter pipe 4 in the crash box 3 to absorb the collision energy. Therefore, the shock absorbing characteristics can be remarkably improved as compared with a shock absorbing device having a conventional crash box.

  That is, a conventional crash box that performs two-stage plastic deformation, ie, a diameter-reducing deformation in which a small-diameter pipe is pressed into a large-diameter pipe while being deformed, and a crushing deformation in which the large-diameter pipe is deformed in a bellows shape after the diameter-reducing deformation ( In the impact absorbing device provided with the above Patent Document 3), as shown in FIG. 9, in the initial stage of the collision, the collision energy is absorbed by the reduced diameter deformation of the small diameter tube, and after the reduced diameter deformation is finished, the outer side Shifting to bellows-like crushing deformation by large-diameter pipe, and impact energy is absorbed by the crushing deformation, so the load (load necessary for plastic deformation) varies greatly depending on the amount of axial deformation. . For this reason, in the conventional shock absorbing device shown in FIG. 9, there is a large difference between the maximum load and the average load, and the collision energy cannot be stably absorbed in the entire axial direction, resulting in a reduction in shock absorbing characteristics. Will be. Furthermore, since the maximum load immediately after the transition from the reduced diameter deformation to the bellows-like crushing deformation becomes extremely large, the variation of the load with respect to the amount of displacement in the axial direction is further increased, and the shock absorption characteristics are further deteriorated.

  On the other hand, in the impact absorbing device of the present embodiment, the peripheral wall of the large-diameter pipe 5 is continuously expanded and deformed by the outward convex portion 41 of the small-diameter pipe 4 in the crash box 3, and therefore the solid line in FIG. As shown in Fig. 4, the load due to the expansion deformation (the load necessary for the expansion expansion) is almost constant regardless of the axial displacement, and the ratio of the average load to the maximum load (average load / maximum load) However, it is possible to obtain an ideal shock absorption characteristic exceeding 0.8, and it is possible to stably and stably absorb the collision energy in the entire axial direction. Moreover, in the crash box 3 of the present embodiment, the maximum load (initial load) at the initial stage of deformation is based on the deformation in the diameter increasing direction of the large diameter pipe 5 by the outward convex portion 41 of the small diameter pipe 4. Compared to the initial maximum load when the material is crushed and deformed, the initial load is reduced, the difference from the subsequent load is also reduced, and the collision energy can be absorbed smoothly immediately after the collision.

  Moreover, since the increase / decrease in energy absorption amount can be changed by changing the diameter expansion deformation amount, the absorption amount of collision energy can be easily adjusted as necessary. For example, an impact absorbing member having a shock absorbing characteristic for low speed collision as shown by a dashed line in FIG. 7 or a shock absorbing characteristic for high speed collision as shown by a solid line in FIG. It can be obtained easily and reliably.

  As described above, according to the crash box 3 of the present embodiment, the effective stroke length of the crash box is increased and the difference between the maximum load and the average load is increased as compared with the conventional crash box to be crushed and deformed (see FIG. 9). Therefore, it is possible to obtain an ideal shock absorption characteristic that the load hardly fluctuates regardless of the amount of displacement in the axial direction.

  In the crash box 3 of the present embodiment, since the entire length direction (axial direction) of the large-diameter pipe 5 into which the small-diameter pipe 4 is press-fitted when absorbing the collision energy is arranged in the side member 6, the small diameter The collision energy can be absorbed until the pipe 4 is pushed into the large-diameter pipe 5 (side member 6) and the bumper reinforcement 2 collides with the side member 6. In other words, there is no remaining crushing portion (small-diameter pipe 4) between the front end of the side member 6 and the bumper reinforcement 2, and the entire space can be used as the effective stroke length. For this reason, the crash box 3 of the present embodiment is, for example, a conventional crash box that is crushed and deformed into a bellows shape, or a crash box that is immersed while a small-diameter pipe portion is inserted into a large-diameter pipe portion and a step portion between the two is inwardly inserted. The effective stroke length can be increased as compared to the case in which the remaining crushing portion remains between the side member and the bumper reinforcement, as in (see Patent Documents 1 and 2).

  As described above, the crash box 3 of the present embodiment can utilize the entire length of the installation space as the effective stroke length even in a limited installation space. That is, according to the crash box 3 of the present embodiment, the effective stroke length can be set to the maximum, the amount of collision energy absorbed can be increased, and even more excellent shock absorption characteristics can be obtained.

  By the way, in the above embodiment, the large-diameter tube 5 is expanded and deformed to absorb the collision energy. However, the present invention is not limited to this, and in the present invention, the small-diameter tube is deformed and contracted to reduce the collision energy. May be absorbed.

  For example, as shown in FIG. 8, when the small diameter pipe 4 and the large diameter pipe 5 in the crush box 3 are connected, the overlapping portion of both the pipes 4 and 5 is reduced in the inner diameter direction by a contraction process using a mold. Inward convex portions 42 and 52 as protruding superimposing convex portions are formed, and the large diameter tube 5 is connected and fixed to the small diameter tube 4. In this modification, of the small-diameter pipe 4 and the large-diameter pipe 5, the small-diameter pipe 4 is disposed on the projecting direction side of the inward convex portion (the overlapping convex portions 42 and 52), and the large-diameter tube 5 is not projecting. It is arranged on the direction side. Therefore, in this modified example, unlike the above-described embodiment, the small diameter tube 4 is configured as a deformed tube, and the large diameter tube 5 is configured as a non-deformed tube which is the remaining one tube. In this modification, other configurations are the same as those in the above embodiment.

  In this modified example, when the small-diameter pipe 4 is press-fitted into the large-diameter pipe 5 at the time of a collision, plasticity is applied so that the peripheral wall of the small-diameter pipe 4 is pushed inward by the inward convex portion 52 of the large-diameter pipe 5. The collision energy is absorbed by deformation (constriction deformation).

  In the above embodiment, the entire circumference of the small-diameter pipe 4 and the large-diameter pipe 5 in the crush box 3 is provided with a polymerization convex portion that is continuous in the circumferential direction, but the invention is not limited thereto, and in the present invention, You may make it provide a superposition | polymerization convex part in at least one part of the circumferential direction. For example, two or more overlapping convex portions may be provided at intervals in the circumferential direction.

  Moreover, in this invention, the height (the amount of pipe expansion or the amount of contraction) of superposition | polymerization convex parts, such as an outward convex part and an inward convex part, is not specifically limited. That is, since the load (energy absorption amount) varies depending on the height of the superposition convex portion, the height of the superposition convex portion may be appropriately set according to the load required as the shock absorbing member (crash box). .

  Furthermore, in the said embodiment, although the thing with a circular cross section is used as the small diameter pipe 4 and the large diameter pipe 5, the cross-sectional shape of a small diameter pipe and a large diameter pipe is not specifically limited, Polygon shape, such as a quadrangle | tetragon Alternatively, a small diameter tube and a large diameter tube having an elliptical shape, an oval shape, or an irregular cross-sectional shape may be used. Furthermore, it is not necessary to form the small-diameter pipe and the large-diameter pipe in a similar shape. If the small-diameter pipe can be inserted into the large-diameter pipe, the small-diameter pipe and the large-diameter pipe should be formed in different cross-sectional shapes. Also good.

  In the above embodiment, almost the entire area of the large-diameter pipe of the crash box is accommodated in the side frame. However, the present invention is not limited to this, and in the present invention, at least a part of the large-diameter pipe is in the side frame. As long as it is housed in However, in order to increase the effective stroke length, it is preferable to accommodate the large-diameter pipe in the side frame as much as possible as in the above-described embodiment and the modified example of FIG.

  Further, in the present invention, in particular, when the overlapping convex portion is constituted by the inward convex portions 42 and 52 as in the modification of FIG. 8, the distal end portion of the large-diameter pipe 5 projects forward from the side frame. It is also possible to arrange the protrusions (in front of the side frame), and to form overlapping protrusions such as the inward protrusions 42 and 52 on the protrusions. However, in the case where the overlapping convex portions are configured by the outward convex portions 41 and 51 as in the above-described embodiment, the outward convex portions 41 and 51 are preferably formed inside the side frame. That is, by arranging the outwardly projecting portions 41 and 51 in the side frame, all the enlarged diameter deformed portions in the large diameter pipe 5 can be arranged in the side frame, so that the effective stroke length can be increased.

  In the above embodiment, the case where the crash box as the shock absorbing member of the present invention is applied to the bumper beam of the bumper provided at the front end of the automobile has been described as an example. However, the present invention is not limited to this. The shock absorbing member can be applied to a crash box for a front underrun protector of a large vehicle, and further to a crash box for protecting a pedestrian or a crew member.

  The impact absorbing member of the present invention can also be used for a bumper beam provided at the rear end of an automobile. When provided at the rear end, needless to say, the distal end side is the rear side, and the proximal end side is the front side.

  The vehicle impact absorbing member of the present invention can be applied to a bumper beam crash box for automobiles.

1: Bumper beam 2: Bumper reinforcement 25: Crash box mounting hole (small diameter tube mounting hole)
3: Crush box 4: Small diameter tube 41: Outward convex portion (overlapping convex portion)
42: Inward convex portion (overlapping convex portion)
45: Expanded pipe part 5: Large diameter pipe 51: Outward convex part (polymerization convex part)
52: Inward convex portion (overlapping convex portion)
55: Tube expansion part 6: Side member (side frame)
65: Hollow portion 7: Stay 75: Crash box mounting hole (large diameter tube mounting hole)

Claims (15)

A vehicle impact absorbing member applied to a vehicle having a hollow side frame,
With the proximal end of the small-diameter pipe inserted into the distal end of the large-diameter pipe, the overlapping part of both pipes is expanded or contracted to form an overlapping convex part protruding in the outer diameter direction or inner diameter direction. By connecting the small diameter pipe and the large diameter pipe,
The large-diameter pipe is fixed to the side frame in a state where at least a part of the large-diameter pipe is accommodated in the distal end portion of the side frame, and the small-diameter pipe is arranged in a manner protruding from the distal end of the side frame,
Of the small-diameter pipe and large-diameter pipe, the pipe disposed on the protruding direction side of the overlapping convex part is a deformed pipe, and the remaining one pipe is a non-deformed pipe.
When an impact along the axial direction is applied to the small-diameter pipe from its distal end side, the peripheral wall of the deformable pipe is plastically deformed in the outer diameter direction or the inner diameter direction by the overlapping convex portion of the non-deformable pipe, and the small-diameter pipe Is pressed into the large-diameter pipe, so that impact energy is absorbed, and at least the base end of the small-diameter pipe is accommodated in the side frame ,
Almost the entire area excluding the axial tip of the large-diameter tube is disposed in the side frame,
A vehicular shock absorbing member characterized in that substantially the entire area of the small-diameter pipe is configured to be press-fit into the large-diameter pipe . The vehicle impact absorbing member according to claim 1, wherein the overlapping convex portion is disposed in the side frame. A vehicle impact absorbing member applied to a vehicle having a hollow side frame,
With the proximal end of the small-diameter pipe inserted into the distal end of the large-diameter pipe, the overlapping part of both pipes is expanded or contracted to form an overlapping convex part protruding in the outer diameter direction or inner diameter direction. By connecting the small diameter pipe and the large diameter pipe,
The large-diameter pipe is fixed to the side frame in a state where at least a part of the large-diameter pipe is accommodated in the distal end portion of the side frame, and the small-diameter pipe is arranged in a manner protruding from the distal end of the side frame,
Of the small-diameter pipe and large-diameter pipe, the pipe disposed on the protruding direction side of the overlapping convex part is a deformed pipe, and the remaining one pipe is a non-deformed pipe.
When an impact along the axial direction is applied to the small-diameter pipe from its distal end side, the peripheral wall of the deformable pipe is plastically deformed in the outer diameter direction or the inner diameter direction by the overlapping convex portion of the non-deformable pipe, and the small-diameter pipe Is pressed into the large-diameter pipe, so that impact energy is absorbed, and at least the base end of the small-diameter pipe is accommodated in the side frame,
The above-mentioned superposition convex part is arranged in the above-mentioned side frame. The vehicle impact absorbing member according to any one of claims 1 to 3 , wherein the overlapping convex portion is formed in the entire region in the circumferential direction of the small diameter tube and the large diameter tube. The polymerization convex portion, the small diameter tube and the impact absorbing member for vehicle according to any one of claims 1 to 4 formed on a part of circumferential direction of the large diameter pipe. A vehicle impact absorbing member applied to a vehicle having a hollow side frame,
With the proximal end of the small-diameter pipe inserted into the distal end of the large-diameter pipe, the overlapping part of both pipes is expanded or contracted to form an overlapping convex part protruding in the outer diameter direction or inner diameter direction. By connecting the small diameter pipe and the large diameter pipe,
The large-diameter pipe is fixed to the side frame in a state where at least a part of the large-diameter pipe is accommodated in the distal end portion of the side frame, and the small-diameter pipe is arranged in a manner protruding from the distal end of the side frame,
Of the small-diameter pipe and large-diameter pipe, the pipe disposed on the protruding direction side of the overlapping convex part is a deformed pipe, and the remaining one pipe is a non-deformed pipe.
When an impact along the axial direction is applied to the small-diameter pipe from its distal end side, the peripheral wall of the deformable pipe is plastically deformed in the outer diameter direction or the inner diameter direction by the overlapping convex portion of the non-deformable pipe, and the small-diameter pipe Is pressed into the large-diameter pipe, so that impact energy is absorbed, and at least the base end of the small-diameter pipe is accommodated in the side frame,
The above-mentioned superposition convex part is formed in a part of peripheral direction of the above-mentioned small diameter pipe and the above-mentioned large diameter pipe. The overlapping convex portion is constituted by an outward convex portion protruding in the outer diameter direction,
When an impact is applied to the small-diameter pipe, the outer convex portion of the small-diameter pipe is plastically deformed so that the peripheral wall of the large-diameter pipe forming the deformed pipe is expanded in the outer diameter direction. The impact absorbing member for a vehicle according to any one of claims 1 to 6 . The overlapping convex portion is constituted by an inward convex portion protruding in the inner diameter direction,
When the impact is applied to the small-diameter pipe, the inward convex portion of the large-diameter pipe is plastically deformed so that a peripheral wall of the small-diameter pipe forming the deformed pipe is pushed in an inner diameter direction. The vehicle impact absorbing member according to any one of 1 to 6 . The vehicle impact absorbing member according to any one of claims 1 to 8 , wherein the overlapping convex portion is formed by tube expansion processing or contraction processing using a mold. An impact absorbing device applied to a vehicle having a hollow side frame extending in the front-rear direction on both sides of the vehicle,
With the proximal end of the small-diameter pipe inserted into the distal end of the large-diameter pipe, the overlapping part of both pipes is expanded or contracted to form an overlapping convex part protruding in the outer diameter direction or inner diameter direction. By connecting the small diameter pipe and the large diameter pipe, the large diameter pipe is fixed to the side frame in a state where at least a part of the large diameter pipe is accommodated in the distal end portion of the side frame. Of the small diameter pipe and the large diameter pipe, the pipe arranged on the projecting direction side of the overlapping convex part is a deformed pipe, and the other pipe is the non-deformed pipe. As described above, when an impact along the axial direction is applied to the small-diameter pipe from its distal end side, the peripheral wall of the deformable pipe is plastically deformed in the outer diameter direction or the inner diameter direction by the overlapping convex portion of the non-deformable pipe, A small diameter pipe is press-fitted into the large diameter pipe. The Rukoto, together with the impact energy is absorbed, and the crush box constituted by the vehicle impact absorbing member which is adapted at least a base end portion of the small diameter tube is accommodated in the side frame,
Attached to the tip of the small diameter pipe in the crash box, and e Bei a bumper reinforcement disposed along the vehicle width direction,
A stay is attached to the tip surface of the side frame, and the tip of the large diameter pipe is expanded in a state where the large diameter pipe is inserted and disposed in a large diameter pipe mounting hole provided in the stay. The vehicular shock absorbing device is characterized in that the large-diameter pipe is attached to the side frame via the stay by press-fitting and engaging the expanded pipe portion with the peripheral portion of the large-diameter pipe attachment hole of the stay . An impact absorbing device applied to a vehicle having a hollow side frame extending in the front-rear direction on both sides of the vehicle,
A crash box constituted by the impact absorbing member for a vehicle according to any one of claims 1 to 9 ,
A bumper reinforcement attached to a tip of a small-diameter pipe in the crash box and disposed along a vehicle width direction. A stay is attached to the tip surface of the side frame, and the tip of the large diameter pipe is expanded in a state where the large diameter pipe is inserted and disposed in a large diameter pipe mounting hole provided in the stay. 12. The vehicle impact absorbing device according to claim 11 , wherein the large diameter pipe is attached to the side frame via the stay by press-fitting and engaging the expanded pipe portion with the peripheral edge of the large diameter pipe attachment hole of the stay. The tip of the small-diameter pipe is expanded in a state where the small-diameter pipe is inserted and arranged along the axial direction in the small-diameter pipe mounting hole provided in the bumper reinforcement, and the expanded pipe is the small diameter of the bumper reinforcement. The impact absorbing device for a vehicle according to any one of claims 10 to 12 , wherein the bumper reinforcement is attached to the small-diameter pipe by being pressed and engaged with a peripheral portion of the pipe attachment hole. A crash box that supports bumper reinforcements arranged along the vehicle width direction and absorbs collision energy applied to the bumper reinforcements,
Together it is constituted by a vehicle impact absorbing member according to any one of claims 1 to 9
The crash box, wherein the bumper reinforcement is attached to a tip of the small-diameter pipe. Bumper reinforcements arranged along the vehicle width direction,
A crash box that supports the bumper reinforcement and absorbs collision energy applied to the bumper reinforcement;
The crush box, while being constituted by a vehicle impact absorbing member according to any one of claims 1 to 9
The bumper beam is characterized in that the bumper reinforcement is attached to the tip of the small diameter tube.

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