Technical field
[0001]
The present disclosure relates to an automobile skeleton member that exhibits high energy absorption efficiency, for example, in the event of an automobile collision.
Background technology
[0002]
In recent years, fuel efficiency regulations have become stricter all over the world, and there is a demand for improved collision performance and weight reduction of automobile bodies. However, simply replacing the material of the automobile skeleton member with a material with high strength and thin plate thickness may cause early buckling at the time of collision due to a decrease in rigidity depending on the shape of the skeleton member, and the energy absorption efficiency is not necessarily high. Is not always obtained. The energy absorption performance increases as the number of parts where the skeleton member undergoes plastic deformation increases, but if buckling occurs early at the time of collision, many parts that do not undergo plastic deformation remain, and even if the material strength is increased, the energy absorption performance becomes higher. The degree of improvement is small. For this reason, studies are underway on skeletal members that can utilize the original strength of the material so that buckling does not occur at an early stage during a collision. Further, in electric vehicles, the development of a vehicle body structure in which a large-capacity battery is mounted under the floor is being promoted, and the skeletal members such as side sills are being improved.
[0003]
As a technique for improving energy absorption performance, Patent Document 1 discloses that a bulkhead having a substantially U-shaped cross section is provided between a side sill and a cross member. The bulkhead of Patent Document 1 is composed of a front portion, a rear side surface portion, and a flange, and has recesses in the front surface portion and the rear side surface portion. Patent Document 2 discloses a shock absorbing member in which a bellows-shaped deformation promoting means is provided in the hollow member. In the shock absorbing member of Patent Document 2, when a bending load due to an impact is applied, the bellows-shaped deformation promoting means buckles, thereby converting the bending load into a compression load in the longitudinal direction and suppressing cross-sectional collapse. There is. Patent Document 3 discloses a metal absorber in which a concave or convex bead is formed on a vertical wall of a hat member.
Prior art literature
Patent documents
[0004]
Patent Document 1: Japanese Unexamined Patent Publication No. 2006-205977
Patent Document 2: Japanese Unexamined Patent Publication No. 2006-207679
Patent Document 3: Japanese Unexamined Patent Publication No. 2008-265738
Outline of the invention
Problems to be solved by the invention
[0005]
Since the vehicle body structure of Patent Document 1 is not a structure aimed at suppressing buckling of the side sill itself, there is room for improvement from the viewpoint of improving energy absorption performance by utilizing the material strength. Further, when the present inventor carried out a simulation of the impact absorbing member of Patent Document 2, many parts of the impact absorbing member did not undergo plastic deformation, and the viewpoint of improving the energy absorption performance by utilizing the material strength. Then there is room for improvement. The absorber of Patent Document 3 is intended to protect the legs of a pedestrian in the event of a collision between a pedestrian and an automobile, and there is room for improvement in terms of improving the energy absorption performance on the vehicle body side.
[0006]
The present disclosure has been made in view of the above problems, and an object thereof is to improve the energy absorption efficiency (mass efficiency of absorbed energy) of the automobile frame member.
Means to solve problems
[0007]
One aspect of the present disclosure that solves the above problems is an automobile skeleton member, which comprises a hat member and a closing plate, wherein the hat member includes a top plate, two vertical walls, and two flanges. The two vertical walls are respectively between the top plate and the flange, the two vertical walls face each other, the two flanges are each joined to the closing plate, and the two vertical walls are each the said. The groove comprises a plurality of grooves extending in a direction perpendicular to the longitudinal direction of the hat member, the groove having a bottom surface and two side surfaces, the two side surfaces facing each other, and the two side surfaces being on both sides of the bottom surface. The width a of the groove and the depth b of the groove in the cross section parallel to the top plate and the height c of the vertical wall in the direction perpendicular to the top plate are 0.2 ≦ a / c ≦ 0. 3. It is characterized in that the relationship of 0.2 ≦ b / c ≦ 0.3 is satisfied.
[0008]
Another aspect of the present disclosure is an automobile skeleton member, comprising a hollow member, the hollow member comprising a top plate and two vertical walls, the two vertical walls each comprising the top plate. Adjacent to, the two vertical walls face each other, each of which comprises a plurality of grooves extending in a direction perpendicular to the longitudinal direction of the hollow member, the grooves having a bottom surface and two side surfaces. The two side surfaces face each other, and the two side surfaces are on both sides of the bottom surface, and the width a of the groove portion and the depth b of the groove portion in a cross section parallel to the top plate are perpendicular to the top plate. The height c of the vertical wall in the above direction is characterized in that it satisfies the relationship of 0.2 ≦ a / c ≦ 0.3 and 0.2 ≦ b / c ≦ 0.3.
The invention's effect
[0009]
It is possible to improve the energy absorption efficiency of automobile skeleton members.
A brief description of the drawing
[0010]
FIG. 1 is a perspective view showing a schematic configuration of an automobile skeleton member according to a first embodiment.
FIG. 2 is a diagram showing a cross section of an automobile skeleton member that is perpendicular to the longitudinal direction of the member in a portion where a groove is not provided.
[Fig. 3] Fig. 3 is a diagram showing the periphery of a side sill in a cross section perpendicular to the vehicle height of an electric vehicle.
FIG. 4 is a plan view of the vicinity of a groove forming portion of a hat member.
[Fig. 5] Fig. 5 is a side view of the vicinity of a groove forming portion of a hat member.
6 is a cross-sectional view taken along the line AA in FIG.
FIG. 7 is a diagram showing an example of a deformation mode (out-of-plane bending mode) of an automobile skeleton member.
8 is a cross-sectional view taken along the line BB in FIG. 7. FIG.
FIG. 9 is a diagram showing an example of a deformation mode (in-plane bending mode) of an automobile skeleton member.
FIG. 10 is a diagram showing an example (shaft crushing mode) of a deformation mode of an automobile skeleton member.
11 is a cross-sectional view taken along the line CC in FIG.
FIG. 12 is a perspective view showing a schematic configuration of an automobile skeleton member according to a second embodiment.
FIG. 13 is a diagram corresponding to a cross section taken along the line AA in FIG. 5 of the automobile skeleton member according to the second embodiment.
FIG. 14 is a diagram corresponding to a cross section taken along the line AA in FIG. 5, showing an example of the shape of the groove portion.
FIG. 15 is a diagram corresponding to a cross section taken along the line AA in FIG. 5 of the automobile skeleton member according to the third embodiment.
FIG. 16 is a view corresponding to the AA cross section in FIG. 5 of an automobile skeleton member having grooves in both the first hat member and the second hat member.
FIG. 17 is a perspective view showing a schematic configuration of an automobile skeleton member according to a fourth embodiment.
FIG. 18 is a diagram corresponding to a cross section taken along the line AA in FIG. 5 of the automobile skeleton member according to the fourth embodiment.
[Fig. 19] Fig. 19 is a diagram showing an example of the shape of a groove portion.
[Fig. 20] Fig. 20 is a diagram showing an example of the shape of a groove portion.
FIG. 21 is a diagram showing an example of the shape of a groove portion.
[Fig. 22] Fig. 22 is a diagram showing an analysis model in a collision simulation.
FIG. 23 is a load-stroke diagram in simulation (1).
[Fig. 24] Fig. 24 is a diagram showing an analysis model in a collision simulation.
FIG. 25 is a load-stroke diagram in simulation (2).
FIG. 26 is a diagram showing the relationship between a / c, b / c, and energy absorption efficiency in simulation (3).
FIG. 27 is a diagram showing the relationship between a / c, b / c, and a deformation mode in simulation (3).
FIG. 28 is a diagram showing the relationship between e / c in simulation (4) and energy absorption efficiency.
FIG. 29 is a diagram showing the relationship between the groove spacing d in simulation (5) and the energy absorption efficiency.
FIG. 30 is a diagram showing the relationship between a / c, b / c, and energy absorption efficiency in simulation (6).
Embodiment for carrying out the invention
[0011]
Hereinafter, one embodiment according to the present disclosure will be described with reference to the drawings. In the present specification and the drawings, the elements having substantially the same functional configuration are designated by the same reference numerals, so that duplicate description will be omitted.
[0012]

FIG. 1 is a diagram showing a schematic configuration of an automobile skeleton member 1 in the first embodiment. The automobile skeleton member 1 is a member that receives a bending load such as a side sill or a bumper beam. The automobile skeleton member 1 of the first embodiment has a hat member 10 having a hat-shaped cross section perpendicular to the member longitudinal direction (Y direction in FIG. 1) and a flat plate-shaped bottom plate joined to the hat member 10. Has a closing plate 20 and. The X, Y, and Z directions shown in FIG. 1 are perpendicular to each other. When the automobile frame member 1 is, for example, a member constituting a side sill, the X direction is the vehicle height direction and the Y direction is the vehicle length. The direction and the Z direction are the vehicle width directions. Further, when the automobile frame member 1 is, for example, a member constituting a bumper beam, the X direction is the vehicle height direction, the Y direction is the vehicle width direction, and the Z direction is the vehicle length direction.
[0013]
As shown in FIG. 2, the hat member 10 has a top plate 11, two vertical walls 12 connected to the top plate 11, and two flanges 13 connected to the vertical wall 12. The two vertical walls 12 are located between the top plate 11 and the flange 13, respectively, and the two vertical walls 12 face each other. In the first embodiment, the automobile skeleton member 1 is configured by joining the two flanges 13 of the hat member 10 and the closing plate 20. The hat member 10 is formed of, for example, a steel material having a tensile strength of 440 to 1500 MPa, but the material of the hat member 10 is not particularly limited, and may be, for example, an aluminum alloy member, a magnesium alloy member, or the like. Similarly, the closing plate 20 is formed of, for example, a steel material having a tensile strength of 440 to 1500 MPa, but the material of the closing plate 20 is not particularly limited, and may be, for example, an aluminum alloy member, a magnesium alloy member, or the like.
[0014]
When the automobile skeleton member 1 is attached to the vehicle body, the top plate 11 of the hat member 10 may be arranged on the outside of the vehicle or on the inside of the vehicle with respect to the closing plate 20. Especially in the case of the side sill, it is preferable that the top plate 11 is arranged on the outside of the vehicle with respect to the closing plate 20. This is because if the flange of the hat member is on the outside of the vehicle, the flange and the door interfere with each other and the door does not close. It is also preferable to apply this disclosure to electric vehicles. This is because the side sill absorbs the impact to prevent damage to the battery placed inside the vehicle than the side sill. FIG. 3 is a diagram showing the periphery of the side sill 41 in a cross section perpendicular to the vehicle height direction of the electric vehicle 40. As shown in FIG. 3, when the automobile skeleton member 1 is a member constituting the side sill 41, the closing plate 20 is adjacent to the battery 42 mounted on the floor panel (not shown), and the top plate 11 is the vehicle. Of the outside and the inside of the car, it is preferable that the car is arranged on the outside of the car. In this embodiment and the embodiments described later, the top plate 11 is arranged on the outside of the vehicle, whichever is outside the vehicle or inside the vehicle.
[0015]
As shown in FIGS. 1 and 4 to 6, the hat member 10 of the first embodiment has a groove portion 31 extending in a direction perpendicular to the longitudinal direction of the member. From the viewpoint of effectively improving the energy absorption efficiency, the groove portion 31 extends from the ridge line portion 14 to the ridge line portion 15 as shown in FIGS. 1 and 4 to 6, that is, the vehicle inner end portion of the vertical wall 12. It is preferable that it is formed from the outer end of the vehicle. Grooves 31 are provided on both of the pair of vertical walls 12. The forming method of the groove portion 31 is not particularly limited, and for example, the forming is performed by repeatedly performing press working after forming the hat member 10 and gradually increasing the depth of the groove portion 31. In the present specification, the portion where the groove portion 31 as shown in FIG. 4 is formed is referred to as a “groove forming portion 30”. Further, as shown in FIG. 6, in the present specification, the top plate 11 at the groove forming portion 30 is referred to as a “groove top plate 32”, and the vertical wall 12 at the groove forming portion 30 is referred to as a “groove vertical wall 33”. The flange 13 at the groove forming portion 30 is referred to as a “groove flange 34”.
[0016]
The groove top plate 32 is located in the same plane as the top plate 11 in the portion other than the groove forming portion 30, and the groove flange 34 is located in the same plane as the flange 13 in the portion other than the groove forming portion 30. There is. As shown in FIG. 4, the groove vertical wall 33 of the first embodiment has a bottom surface 31a of the groove 31 which is a plane parallel to the vertical wall 12 of a portion other than the groove forming portion 30, and a groove forming portion 30 other than the bottom surface 31a. It has a pair of flat side surfaces 31b connecting the vertical wall 12 of the portion and the bottom surface 31a of the groove portion 31. That is, the groove portion 31 includes a bottom surface 31a and two side surfaces 31b, and the two side surfaces 31b face each other and are located on both sides of the bottom surface 31a.
[0017]
A plurality of groove forming portions 30 are provided at intervals along the member longitudinal direction of the hat member 10. That is, the two vertical walls 12 are provided with a plurality of groove portions 31 along the member longitudinal direction of the hat member 10. In the first embodiment, the region where the groove forming portion 30 exists is only the central portion in the member longitudinal direction of the hat member 10, but the groove forming portion 30 covers, for example, the entire area of ​​the hat member 10 in the member longitudinal direction. It may be provided. The vertical wall 12 located between the adjacent groove forming portions 30 has a shape that protrudes from the bottom surface 31a of the groove portion 31 due to the provision of a plurality of groove forming portions 30.
[0018]
The automobile skeleton member 1 of the first embodiment is configured as described above. In the automobile skeleton member 1, a load is partially applied from the Z direction at the time of a collision, and a moment is generated to cause bending deformation. In the case of the automobile skeleton member 1 of the first embodiment, the groove portion 31 of the hat member 10 is not only the vertical wall 12, but also the ridge line portion 14 between the vertical wall 12 and the top plate 11 and between the vertical wall 12 and the flange 13. By being provided on the ridge line portion 15, the surface rigidity of the top plate 11 is increased and the load required for deformation of the automobile skeleton member 1 is increased as compared with the case where the groove portions 31 are not provided on the ridge line portions 14 and 15. be able to. Further, since the groove portion 31 has three flat surfaces, that is, a shape having a bottom surface 31a of the groove portion 31 and two side surfaces 31b, the surface rigidity of the top plate 11 can be further increased, and the automobile skeleton member 1 is deformed. The load required for this can be further increased. In the automobile skeleton member 1 of the first embodiment, the energy absorption performance can be improved by their action. Further, since the automobile skeleton member 1 of the first embodiment does not have a structure in which a reinforcing member is newly added, the mass efficiency related to the energy absorption performance can be improved.
[0019]
When the automobile skeleton member 1 is deformed, one of the following deformation modes occurs.
[0020]
(Out-of-plane folding mode)
As shown in FIGS. 7 and 8, the out-of-plane bending mode is a mode in which the main deformation is a deformation in which the vertical wall 12 of the hat member 10 bends in the out-of-plane direction in a cross section perpendicular to the longitudinal direction of the member.
(In-plane folding mode)
As shown in FIG. 9, in the in-plane bending mode, the main deformation is the deformation in which the vertical wall 12 of the hat member 10 is bent along the longitudinal direction of the member, and the deformation is in the out-of-plane direction in the cross section perpendicular to the longitudinal direction of the member. This is a mode in which the deformation of the vertical wall 12 is small.
(Axial crush mode)
As shown in FIGS. 10 and 11, the axial crushing mode is a mode in which the vertical walls 12 of the hat member 10 are crushed at short intervals in a cross section perpendicular to the longitudinal direction of the member, and a bellows-like deformation occurs as a whole.
[0021]
In order to stably increase the load required for deformation from the early stage of the collision to the late stage of the collision, it is preferable that the automobile skeleton member 1 is deformed in the axial crushing mode.
[0022]
Here, as shown in FIG. 4, the width of the groove portion 31 in the cross section parallel to the top plate 11 of the hat member 10 is defined as “a”, and the depth of the groove portion 31 is defined as “b”, which is shown in FIG. As described above, the height of the vertical wall 12 in the direction perpendicular to the top plate 11 of the hat member 10 is defined as “c”. The width a of the groove portion 31 is the distance between the side surfaces 31b of the hat member 10 facing each other in the member longitudinal direction (Y direction). The depth b of the groove portion 31 is the cross section parallel to the top plate 11 of the hat member 10 from the vertical wall 12 to the bottom surface 31a of the groove portion 31 in the direction perpendicular to the member longitudinal direction of the hat member 10 (X direction). The length. The height c of the vertical wall 12 is the length from the flange 13 to the top plate 11 in the direction (Z direction) perpendicular to the member longitudinal direction of the hat member 10. In the first embodiment, the height c of the vertical wall 12 is equal to the height from the groove flange 34 to the groove top plate 32.
[0023]
In order to facilitate the deformation of the axial crushing mode in the automobile frame member 1, the width a of the groove portion 31, the depth b of the groove portion 31, and the height c of the vertical wall 12 of the hat member 10 are 0.2. It is preferable that the relationship of ≦ a / c ≦ 0.3 and 0.2 ≦ b / c ≦ 0.3 is satisfied. When this numerical range is satisfied, the deformation of the automobile skeleton member 1 tends to be in the axial crushing mode as shown in the examples described later, and the load required for the deformation is stably increased from the early stage of the collision to the late stage of the collision. Thereby, the energy absorption performance can be further improved.
[0024]
Further, the distance d between the adjacent groove portions 31 is preferably 50 mm or less. When the distance d between the groove portions 31 is 50 mm or less, the shaft crushing mode is likely to be deformed, and the energy absorption efficiency can be improved. The smaller the distance d between the groove portions 31, the more the energy absorption efficiency can be improved. However, from the viewpoint of moldability of the hat member 10 having the groove portion 31, the distance d between the groove portions 31 may be 10 mm or more. preferable. Further, in order to more easily induce the deformation of the axial crushing mode, the angle θ 1 formed by the bottom surface 31a of the groove portion 31 and the side surface 31b of the groove portion 31 is preferably 90 to 95 degrees, and is vertically vertical. More preferred. Further, in order to more easily induce deformation in the axial crushing mode, the angle θ 2 formed by the groove vertical wall 33 and the groove flange 34 is preferably 90 to 100 degrees as shown in FIG. 6, and is vertical. Is more preferable.
[0025]

As shown in FIGS. 12 and 13, in the automobile skeleton member 1 of the second embodiment, the groove portion 31 does not extend to the ridgeline portion 14 of the hat member 10. That is, in the automobile skeleton member 1 of the second embodiment, although one end of the groove 31 extends to the inner end of the vertical wall 12 (the ridge line 15 in the example of FIG. 14), the other end of the groove 31 Does not extend to the outer end of the vertical wall 12 (the ridge 14 in the example of FIG. 14). Even in the groove portion 31 having such a shape, the width a of the groove portion 31, the depth b of the groove portion 31, and the height c of the vertical wall 12 of the hat member 10 are 0.2 ≦ a / c ≦ 0. By satisfying the relationship of 3 and 0.2 ≦ b / c ≦ 0.3, the shaft crushing mode is likely to be deformed, and the energy absorption efficiency can be improved.
[0026]
FIG. 14 is a diagram showing a shape example of the groove portion 31. Unlike the example of FIG. 13, the automobile skeleton member 1 in the example of FIG. 14 has a groove portion while one end of the groove portion 31 extends to the vehicle outer end portion of the vertical wall 12 (the ridge line portion 14 in the example of FIG. 14). The other end of 31 has a structure that does not extend to the inner end portion of the vertical wall 12 (the ridgeline portion 15 in the example of FIG. 14). The automobile skeleton member 1 having the structure as shown in FIG. 13 can improve the energy absorption efficiency as compared with the automobile skeleton member 1 having the structure as shown in FIG. When an impact load is input to the automobile skeleton member 1, the buckling region expands toward the inner end of the vertical wall 12 starting from the first buckled portion of the vertical wall 12. Therefore, it is advantageous in terms of improving the energy absorption efficiency that the first buckling point is on the outside of the vehicle of the vertical wall 12. There are two reasons. First, the closer the first buckling point is to the outer end of the vertical wall 12, the more the area deformed in a bellows shape. Secondly, if the inside of the vertical wall 12 buckles first, the deviation between the extending direction of the groove 31 on the outside of the vehicle and the impact input direction becomes large, and the deformation of the shaft crushing mode is less likely to occur. That is, it is desirable that the groove portion 31 extends to the inner end portion of the vertical wall 12. The first place to buckle is the place without the groove 31. The reason for first buckling without the groove 31 is that the deformation resistance is small without the groove 31. In the case of the automobile skeleton member 1 of FIG. 13, the groove portion 31 extends to the vehicle inner end portion of the vertical wall 12 (the ridge line portion 15 in the example of FIG. 13), and the groove portion 31 extends to the vehicle outer end portion of the vertical wall 12 (in the example of FIG. 13). The groove portion 31 is not formed in the ridge line portion 14). Therefore, the automobile skeleton member 1 of FIG. 13 tends to buckle in the vicinity of the vehicle outer end portion (ridge line portion 14 in the example of FIG. 13) of the vertical wall 12 when an impact load is input. On the other hand, the automobile skeleton member 1 of FIG. 14 tends to buckle in the vicinity of the vehicle inner end portion (ridge line portion 15 in the example of FIG. 14) of the vertical wall 12. Therefore, the automobile skeleton member 1 having the structure shown in FIG. 13 can secure a large area of ​​deformation in a bellows shape as compared with the automobile skeleton member 1 having the structure shown in FIG. 14, and improves the energy absorption efficiency. Can be done.
[0027]
Further, according to the automobile skeleton member 1 of the second embodiment, since the groove portion 31 is not formed in one of the ridgeline portions 14 and the ridgeline portions 15, the automobile of the first embodiment. Compared to the skeleton member 1, the hat member 10 is easier to mold. That is, the automobile skeleton member 1 of the second embodiment is a member capable of achieving both energy absorption efficiency and moldability at a high level.
[0028]
When the groove portion 31 extends to the vehicle inner end portion (ridge line portion 15 in the example of FIG. 13) of the hat member 10 as in the second embodiment, the groove portion 31 in the direction perpendicular to the top plate 11 of the hat member 10 The length e is preferably 80% or more of the height c of the vertical wall 12 of the hat member 10. As a result, deformation of the shaft crushing mode is likely to occur when an impact load is input, and energy absorption efficiency can be improved. The length e of the groove portion 31 is the length from the flange 13 to the R stop on the groove portion 31 side of the vertical wall 12 at the groove forming portion 30. From the viewpoint of further improving the energy absorption efficiency, the length e of the groove portion 31 is more preferably 90% or more of the height c of the vertical wall 12, and further preferably 95% or more. preferable.
[0029]

In the automobile skeleton member 1 in the first embodiment, the mating member of the hat member 10 was the closing plate 20. In the automobile skeleton member 1 of the second embodiment shown in FIG. 15, the mating member is also a hat member. In the following description, the hat member (upper member in FIG. 15) described in the first embodiment is referred to as a "first hat member 10a", and a hat member (a hat member serving as a mating member of the first hat member 10a). The lower member in FIG. 15) is referred to as a "second hat member 10b". Like the first hat member 10a, the second hat member 10b also has a top plate 11, a pair of vertical walls 12 connected to the top plate 11, and a flange 13 connected to the vertical wall 12. The automobile skeleton member 1 is configured by joining the first hat member 10a and the second hat member 10b with each other by a flange 13. Also in the automobile skeleton member 1 of the second embodiment, the groove portion 31 of the first hat member 10a has a bottom surface 31a and a pair of side surfaces 31b when viewed from a direction perpendicular to the top plate 11 as shown in FIG. The groove portion 31 is provided from the ridge line portion 14 to the ridge line portion 15 as shown in FIG. Therefore, the energy absorption efficiency can be improved.
[0030]
Further, as shown in FIG. 16, the second hat member 10b may also be provided with the groove portion 31 in the same manner as the first hat member 10a. This makes it possible to further improve the energy absorption efficiency. When the groove portion 31 is provided in the second hat member 10b, the width a of the groove portion 31 and the sum c of the height c 1 of the first hat member 10a and the height c 2 of the second hat member 10b are used. The ratio (a / c) is 0.2 to 0.3, and the depth b of the groove portion 31 and the height c 1 of the first hat member 10a and the height c 2 of the second hat member 10b. The ratio (b / c) of the above to the sum c is preferably 0.2 to 0.3. Further, the angle θ 1 formed by the bottom surface 31a of the groove portion 31 and the side surface 31b of the groove portion 31 is preferably 90 to 95 degrees, and more preferably vertical. Further, the angle θ 2 formed by the groove vertical wall 33 and the groove flange 34 is preferably 90 to 100 degrees, and more preferably vertical. Is preferable.
[0031]
Further, when both the first hat member and the second hat member 10b have the groove forming portion 30, the height c 2 of the second hat member 10b and the height c 1 of the first hat member 10a The ratio (c 2 / c 1) is preferably 0.25 or less. When this numerical range is satisfied, the deformation of the axial crushing mode is more likely to be induced, and the energy absorption efficiency can be improved as compared with the case where c 2 / c 1 exceeds 0.25. c 2 / c 1 is more preferably 0.2 or less, and further preferably 0.1 or less. That is, the smaller the c 2 / c 1, the more preferable.
[0032]

The automobile skeleton member 1 of the first to third embodiments described above was configured by joining a plurality of members to each other, whereas the automobile skeleton member 1 of the fourth embodiment is shown in FIGS. 17 and 18. As shown in, it is composed of a square tubular hollow member 2. The hollow member 2 has a top plate 11, two vertical walls 12 connected to the top plate 11, and a bottom plate 16 connected to the two vertical walls 12. The two vertical walls 12 are located between the top plate 11 and the bottom plate 16, respectively, and the two vertical walls 12 face each other. The top plate 11 and the bottom plate 16 also face each other. The material of the hollow member 2 is not particularly limited, and is, for example, a steel material, an aluminum alloy member, a magnesium alloy member, or the like. When the automobile skeleton member 1 of the fourth embodiment is, for example, a member constituting the side sill 41 of the electric vehicle 40, the bottom plate 16 of the hollow member 2 is a floor panel (not shown) as in the example of FIG. Adjacent to the battery 42 mounted on.
[0033]
Similar to the first to third embodiments, the automobile skeleton member 1 of the fourth embodiment has a plurality of groove portions 31 extending in a direction perpendicular to the member longitudinal direction of the hollow member 2. From the viewpoint of effectively improving the energy absorption efficiency, the groove portion 31 is formed so as to extend from the ridgeline portion 14 to the ridgeline portion 17, that is, from the vehicle inner end portion to the vehicle outer end portion of the vertical wall 12. Is preferable. Grooves 31 are provided on both of the pair of vertical walls 12. The forming method of the groove portion 31 is not particularly limited, and for example, after forming a square tubular hollow member by extrusion molding, the pressing process is repeated and the depth of the groove portion 31 is gradually increased to form the groove portion 31. Will be. Further, for example, the groove portion 31 may be formed by hydroforming.
[0034]
A plurality of groove forming portions 30 are provided along the member longitudinal direction of the hollow member 2. That is, the two vertical walls 12 are provided with a plurality of groove portions 31 along the member longitudinal direction of the hollow member 2. In the present specification, the top plate 11 at the groove forming portion 30 is referred to as "groove top plate 32", the vertical wall 12 at the groove forming portion 30 is referred to as "groove vertical wall 33", and the bottom plate 16 at the groove forming portion 30 is referred to as "groove vertical wall 33". It is referred to as "groove bottom plate 35". The groove top plate 32 is located in the same plane as the top plate 11 in the portion other than the groove forming portion 30, and the groove bottom plate 35 is located in the same plane as the bottom plate 16 in the portion other than the groove forming portion 30. There is. The shape of the groove 31 in a plan view is the same as that of the first to third embodiments. That is, in the automobile skeleton member 1 of the fourth embodiment as in the case of FIG. 4, the groove portion vertical wall 33 is a bottom surface 31a of the groove portion 31 which is a plane parallel to the vertical wall 12 of the portion other than the groove forming portion 30. And a side surface 31b which is a pair of planes connecting the vertical wall 12 of the portion other than the groove forming portion 30 and the bottom surface 31a of the groove portion 31. That is, the groove portion 31 includes a bottom surface 31a and two side surfaces 31b, and the two side surfaces 31b face each other and are located on both sides of the bottom surface 31a.
[0035]
The automobile skeleton member 1 of the fourth embodiment is configured as described above. Also in the automobile skeleton member 1 of the fourth embodiment, the width a of the groove portion 31 (FIG. 4), the depth b of the groove portion 31 (FIG. 4), and the height c of the vertical wall 12 of the hollow member 2 (FIG. 18). ) Satisfies the relationship of 0.2 ≦ a / c ≦ 0.3 and 0.2 ≦ b / c ≦ 0.3. Therefore, the energy absorption efficiency can be improved as in the automobile skeleton member 1 of the first to third embodiments. The height c of the vertical wall 12 of the hollow member 2 is the length from the bottom plate 16 to the top plate 11 in the direction perpendicular to the longitudinal direction of the member (Z direction). Further, the height c of the vertical wall 12 of the hollow member 2 of the fourth embodiment is equal to the height from the groove bottom plate 35 to the groove top plate 32.
[0036]
The distance d (FIG. 4) between the adjacent groove portions 31 is preferably 50 mm or less as in the first to third embodiments. As a result, the shaft crushing mode is likely to be deformed, and the energy absorption efficiency can be improved. From the viewpoint of moldability of the hollow member 2 having the groove portion 31, the distance d between the groove portions 31 is preferably 10 mm or more. Further, in order to more easily induce deformation in the axial crushing mode, the angle θ 1 (FIG. 4) formed by the bottom surface 31a of the groove portion 31 and the side surface 31b of the groove portion 31 is preferably 90 to 95 degrees, and is vertical. Is more preferable. Further, in order to more easily induce deformation in the axial crushing mode, the angle θ 3 formed by the groove vertical wall 33 and the groove bottom plate 35 is preferably 80 to 90 degrees as shown in FIG. 18, and is vertical. Is more preferable.
[0037]
Similar to the case of the second embodiment shown in FIG. 12, even when the automobile skeleton member 1 is composed of the hollow member 2, the groove portion 31 is the vehicle inner end portion of the vertical wall 12 as shown in FIG. In the example of FIG. 19, it does not have to be formed over the entire area from the ridge line portion 17) to the outer end portion of the vehicle (ridge line portion 14 in the example of FIG. 19). When the groove portion 31 is not formed up to the outer end portion of the vehicle as shown in FIG. 19, the length e of the groove portion 31 in the direction perpendicular to the top plate 11 of the hollow member 2 is the height of the vertical wall 12 of the hollow member 2. It is preferably 80% or more of the length c. As a result, it is possible to achieve both energy absorption efficiency and moldability at a high level, as in the case of the automobile skeleton member 1 of the second embodiment as shown in FIG. From the viewpoint of further improving the energy absorption efficiency, the length e of the groove portion 31 is more preferably 90% or more of the height c of the vertical wall 12, and further preferably 95% or more. preferable. The length e of the groove portion 31 when the automobile skeleton member 1 is composed of the hollow member 2 is from the bottom plate 16 of the hollow member 2 to the R stop on the groove portion 31 side of the vertical wall 12 at the groove forming portion 30. Is the length of.
[0038]
Although the embodiment according to the present disclosure has been described above, the present disclosure is not limited to such an example. It is clear that a person skilled in the art can come up with various modifications or amendments within the scope of the technical ideas described in the claims, and of course, these are also the technical scopes of the present disclosure. It is understood that it belongs to.
[0039]
For example, in the above embodiment, the shape of the groove 31 with respect to the vertical wall 12 is concave, but it may be convex as shown in FIG. 20 or FIG. 21. Even in this case, the width a of the groove portion 31, the depth b of the groove portion 31, and the height c of the vertical wall 12 are 0.2 ≦ a / c ≦ 0.3 and 0.2 ≦ b. If the relationship of / c ≦ 0.3 is satisfied, the shaft crushing mode is likely to be deformed, and the energy absorption efficiency can be improved. Further, even in the case of the convex groove portion 31, the length e of the groove portion 31 is preferably 80% or more of the height c of the vertical wall 12, as in the above-described embodiment. Further, even in the case of the convex groove portion 31, the distance d between the groove portions 31 is preferably 50 mm or less, as in the above-described embodiment.
Example
[0040]

As an example of the automobile skeleton member according to the present disclosure, an analysis model (structure 1) as shown in FIG. 22 was created, and a simulation simulating a pole side collision was carried out. The analysis model of FIG. 22 has a configuration equivalent to that of the automobile skeleton member shown in FIG. 1, and is composed of a hat member 10 and a closing plate 20. The material of the hat member 10 and the closing plate 20 is a steel material having a tensile strength of 1180 MPa and a plate thickness of 1.6 mm. A plurality of groove forming portions 30 are provided in the central portion of the hat member 10 in the longitudinal direction of the member. The total length of the hat member 10 is 1500 mm, and the height c (length in the Z direction) of the vertical wall 12 and the width (length in the X direction) of the top plate 11 are 100 mm, respectively. The width a and the depth b of the groove portion 31 are 20 mm, respectively. That is, the above-mentioned values ​​of a / c and b / c are 0.2, respectively. The distance between the grooves is 20 mm.
[0041]
The simulation is carried out by pressing a columnar impactor 50 with a radius of 127 mm against the closing plate 20 and displacing the impactor 50 at a speed of 1.8 km / h. In this simulation, a rigid wall is arranged on the top plate 11. Further, as a comparative example, an analysis model (structure 2) having no groove in the hat member was created, and the same simulation as the above conditions was carried out.
[0042]
FIG. 23 is a load-stroke diagram in simulation (1). The arrow direction in FIG. 23 is the input direction. As shown in FIG. 23, the structure 1 has a larger load than the structure 2 having no groove portion, and the energy absorption performance is improved.
[0043]

As shown in FIG. 24, a rigid wall was placed under the closing plate 20, and a simulation was performed using an analysis model in which the impactor 50 was applied to the top plate 11 of the hat member 10. The other simulation conditions are the same as in the simulation (1).
[0044]
FIG. 25 is a load-stroke diagram in simulation (2). The arrow direction in FIG. 25 is the input direction. As shown in FIG. 25, the structure 1 has a larger load than the structure 2 having no groove portion, and the energy absorption performance is improved. According to the results of the simulations (1) and (2), it can be seen that the effect of improving the energy absorption performance can be obtained regardless of whether the top plate 11 is arranged on the outside of the vehicle or on the inside of the vehicle.
[0045]

Next, the ratio of the width a of the groove (FIG. 4) to the height c of the vertical wall (FIG. 6) and the ratio of the depth b of the groove b (FIG. 4) to the height c of the vertical wall (FIG. 6) are different. Multiple analysis models were created, and simulations were performed with each analysis model. The other simulation conditions are the same as in the simulation (1).
[0046]
Figure 26 summarizes the relationship between a / c, b / c, and energy absorption efficiency in simulation (3). The “suitable range” shown in FIG. 26 is a range in which the energy absorption efficiency (absorption energy / mass) is 5.0 [kN * mm / kg] or more. As shown in FIG. 26, when a / c is 0.2 to 0.3 and b / c is 0.2 to 0.3, the energy absorption efficiency is particularly high. As shown in FIG. 27, in this simulation, when a / c is 0.2 to 0.3 and b / c is 0.2 to 0.3, the automobile skeleton member is used. Deformation of the axial crushing mode occurred.
[0047]

Next, in a structure as shown in FIG. 13 in which the groove portion 31 does not extend to the ridgeline portion 14 on the top plate 11 side of the vertical wall 12, an analysis model in which the ratio of the groove portion length e and the vertical wall height c is different is obtained. Multiple pieces were created and simulations were performed with each analysis model. The other simulation conditions are the same as in the simulation (2).
[0048]
FIG. 28 is a diagram showing the relationship between e / c in simulation (4) and energy absorption efficiency. As shown in FIG. 28, when e / c is 0.8 or more, the energy absorption efficiency is dramatically improved as compared with the case where e / c is less than 0.8. Under the conditions of this simulation, when e / c was 0.8 and 1.0, the automobile skeleton member was deformed in the axial crushing mode. That is, when the length e of the groove portion is 80% or more of the height c of the vertical wall, the shaft crushing mode is likely to be deformed, and the energy absorption efficiency can be effectively improved.
[0049]

Next, multiple analysis models with different groove spacing d (Fig. 4) were created, and simulations were performed with each analysis model.The other simulation conditions are the same as in the simulation (2).
[0050]
FIG. 29 is a diagram showing the relationship between the groove spacing d in the simulation (5) and the energy absorption efficiency. As shown in FIG. 29, under the conditions of this simulation, when the distance d between the grooves is 50 mm or less, the shaft crushing mode is deformed and the energy absorption efficiency is improved.
[0051]

Next, an analysis model was created in which the automobile skeleton member was composed of the first hat member and the second hat member, and the simulation was carried out. The material of the first hat member and the second hat member is a steel material having a tensile strength of 1180 MPa. The first hat member and the second hat member are each provided with a groove portion as shown in FIG. In this simulation, the ratio (c 2 / c 1) of the height c 2 of the second hat member to the height c 1 of the first hat member is 0.25. The shape of the groove portion is the same for the first hat member and the second hat member except for the difference in the height of the hat member. Other simulation conditions are the same as in simulation (1). The simulation is carried out in a plurality of analysis models in which the width a of the groove and the depth b of the groove are different.
[0052]
Figure 30 summarizes the relationship between a / c, b / c, and energy absorption efficiency in simulation (6). “C” is the sum of the height c 1 of the first hat member and the height c 2 of the second hat member. The “suitable range” shown in FIG. 30 is a range in which the energy absorption efficiency is 5.0 [kN * mm / kg] or more. Similar to the simulation (3), when a / c is 0.2 to 0.3 and b / c is 0.2 to 0.3, the automobile skeleton member is deformed in the axial crushing mode. As a result, the mass efficiency of energy absorption performance has improved. In this simulation, the deformation mode of the automobile skeleton member when a / c is less than 0.2 and b / c is 0.2 to 0.3 is the in-plane deformation mode. The energy absorption efficiency was 5.0 [kN * mm / kg] or more. The reason for such a result is that the load is increased by the vertical wall between the grooves coming into contact with the adjacent vertical wall when the automobile skeleton member is deformed.
Industrial applicability
[0053]
The technology related to this disclosure can be used for automobile side sills, bumper beams, etc.
Description of the sign
[0054]
1 Automobile skeleton member
2 Hollow member
10 Hat member
10a 1st hat member
10b Second hat member
11 Top plate
12 Vertical wall
13 Flange
14 Ridge line
15 Ridge line
16 Bottom plate
17 Ridge line
20 Closing plate
30 Groove formation location
31 Groove
31a Bottom of the groove
31b Side surface of groove
32 Groove top plate
33 Groove vertical wall
34 Groove flange
35 Groove bottom plate
40 Electric vehicle
41 Side sill
42 battery
50 Impactor
a Width of the groove
b Depth of the groove
c Height of vertical wall
d. Spacing of grooves
e. Length of groove
θ 1 Angle between the bottom of the groove and the side of the groove
θ 2 Angle between the groove vertical wall and the groove flange
θ 3 Angle between the vertical wall of the groove and the bottom plate of the groove

The scope of the claims
[Claim 1]
Equipped with a hat member and a closing plate,
The hat member has a top plate, two vertical walls, and two flanges.
The two vertical walls are located between the top plate and the flange, respectively.
The two vertical walls face each other,
The two flanges are joined to the closing plate, respectively.
Each of the two vertical walls is provided with a plurality of grooves extending in a direction perpendicular to the longitudinal direction of the hat member.
The groove has a bottom surface and two side surfaces.
The above two sides face each other,
The two sides are on both sides of the bottom surface,
The width a of the groove and the depth b of the groove in the cross section parallel to the top plate and the height c of the vertical wall in the direction perpendicular to the top plate are 0.2 ≦ a / c ≦ 0.3. And, an automobile skeleton member satisfying the relationship of 0.2 ≦ b / c ≦ 0.3.
[Claim 2]
The groove extends to the inner end of the vertical wall,
The automobile skeleton member according to claim 1, wherein the length e of the groove portion in the direction perpendicular to the top plate is 80% or more of the height c of the vertical wall.
[Claim 3]
The automobile skeleton member according to claim 1 or 2, wherein the groove d is 50 mm or less.
[Claim 4]
Equipped with a hollow member
The hollow member includes a top plate, a bottom plate, and two vertical walls.
The top plate and the bottom plate face each other,
The two vertical walls are located between the top plate and the bottom plate, respectively.
The two vertical walls face each other,
Each of the two vertical walls is provided with a plurality of grooves extending in a direction perpendicular to the longitudinal direction of the hollow member.
The groove has a bottom surface and two side surfaces.
The above two sides face each other,
The two sides are on both sides of the bottom surface,
The width a of the groove and the depth b of the groove in the cross section parallel to the top plate and the height c of the vertical wall in the direction perpendicular to the top plate are 0.2 ≦ a / c ≦ 0.3. And, an automobile skeleton member satisfying the relationship of 0.2 ≦ b / c ≦ 0.3.
[Claim 5]
The groove extends to the inner end of the vertical wall,
The automobile skeleton member according to claim 4, wherein the length e of the groove portion in the direction perpendicular to the top plate is 80% or more of the height c of the vertical wall.
[Claim 6]
The automobile skeleton member according to claim 4 or 5, wherein the groove d is 50 mm or less.
[Claim 7]
A side sill provided with the automobile skeleton member according to any one of claims 1 to 3 and a battery are provided.
An electric vehicle in which the closing plate is adjacent to the battery and the top plate is arranged on the outside of the vehicle in a cross section perpendicular to the vehicle height direction.
[Claim 8]
A side sill provided with the automobile skeleton member according to any one of claims 4 to 6 and a battery are provided.
The bottom plate is adjacent to the battery in a cross section perpendicular to the vehicle height direction.
The top plate is an electric vehicle located on the outside of the vehicle.