JP6340634B2 - Rear body structure of the vehicle - Google Patents

Description

  The present invention relates to a rear body structure of a vehicle, and more particularly to a rear body structure of a vehicle including a rear side frame and a rear subframe.

  In a vehicle such as an automobile, a crash can is interposed between a rear bumper rain extending in the vehicle width direction and a rear side frame extending in the vehicle longitudinal direction at the rear of the vehicle body, and an impact load acts from the rear of the vehicle body at the time of a rear collision (rear collision). Sometimes, a crush can is crushed and deformed so as to be folded to absorb energy.

  Further, there is known a rear subframe disposed at the rear of the vehicle body for improving the energy absorption performance at the time of rear collision. For example, in Patent Document 1, a rear subframe is disposed below the rear side frame. In such a vehicle, when an impact load is applied from the rear of the vehicle body at the time of a rear-end collision, an energy absorbing performance is improved by transmitting the load through the rear subframe in addition to the rear side frame.

JP 2016-43829 A

  In recent years, in vehicles such as automobiles, in order to improve the safety of passengers in the passenger compartment at the time of a rear impact, it has been required to further improve the energy absorption performance at the time of the rear impact, and a rear side frame is arranged at the rear of the vehicle body. Even in a vehicle in which a rear subframe is disposed below the rear side frame, it is required to improve energy absorption performance when an impact load is applied from the rear of the vehicle body at the time of a rear collision.

  Therefore, the present invention provides a rear vehicle body structure that can improve the energy absorption performance at the time of a rear collision and improve the safety of passengers in the vehicle interior in a vehicle including a rear side frame and a rear subframe. This is the issue.

  In order to solve the above problems, the present invention is configured as follows.

First, the invention according to claim 1 of the present application is arranged along a pair of left and right rear side frames that extend in the longitudinal direction of the vehicle body at the rear of the vehicle body, and below the pair of left and right rear side frames and along the pair of left and right rear side frames. A rear body structure of a vehicle including a rear subframe extending in the longitudinal direction of the vehicle body, the rear subframe being provided on the rear side of the vehicle body and allowing the rear subframe to be crushed and deformed when an impact load is applied from the rear of the vehicle body. A crushing deformation allowing portion and a crushing deformation non-allowing portion provided on the front side of the vehicle body of the crushing deformation allowing portion, and the rear end portion of the rear side frame and the rear end portion of the rear subframe are interposed via a plate member. The frame is connected to the front side of the vehicle body from the rear end portion of the rear side frame and the front side of the vehicle body from the rear end portion of the rear subframe. Connection part is provided, wherein the frame connecting portion, said provided so as to connect the rear side frames and the crush deformation unacceptable portion of the rear sub-frame, the rear side frame, from the rear side of the vehicle body is provided on the rear side of the vehicle body A crush deformation allowing portion that allows crush deformation when an impact load is applied, and a crush deformation not-permitted portion provided on the vehicle body front side of the crush deformation allowing portion, and the frame connecting portion includes the rear side frame. The crushing deformation non-permissible part and the crushing deformation non-permissible part of the rear subframe are connected to suppress separation of the rear side frame and the rear subframe. An upper horizontal frame extending substantially horizontally in the vehicle longitudinal direction along the rear side frame, and downward from the front end of the upper horizontal frame A vertical frame extending in the vertical direction; and a lower horizontal frame connected to a lower end portion of the vertical frame and extending in a substantially horizontal direction on the front side of the vehicle body. The upper horizontal frame is on the vehicle body rear side and vehicle body upper side from the battery. It is provided in .

The invention according to claim 2, wherein the billing in the invention described in claim 1, before Symbol upper horizontal bridge portion connecting the vehicle body lower side of the upper end of the vertical frame and the rear side of the vehicle body from the front end portion of the frame Is provided.

The invention of claim 3 is the invention according to claim 1 or claim 2, the battery frame for supporting the battery on the vehicle body front side of the front Symbol rear subframe is provided, the rear sub-frame The vehicle body front side is connected to the battery frame.

The invention according to claim 4, wherein in the invention according to claims 1 to any one of claims 3, the rear end of the vehicle body front side of the rear end of the rear side frame the rear sub-frame A plurality of frame connecting portions for connecting the front side of the vehicle body to each other; and the plurality of frame connecting portions are arranged at a substantially constant interval in a longitudinal direction of the vehicle body, and at least one of the frame connecting portions includes the rear side frame and the It is provided so as to connect to the crush deformation non-permitted portion of the rear subframe.

  According to the invention described in claim 1 of the present application, the rear sub-frame disposed below the rear side frame is provided with the crush deformation allowable portion on the rear side of the vehicle body and the crush deformation non-permissible portion on the front side of the vehicle body. The rear end portion of the rear side frame and the rear end portion of the rear subframe are connected via a plate member, and the vehicle body front side from the rear end portion of the rear side frame and the vehicle body front side from the rear end portion of the rear subframe. The frame connection portion is provided so as to connect the rear side frame and the crushed deformation non-permissible portion of the rear subframe.

  As a result, the frame connection part connects the rear side frame and the crushed deformation non-permissible part of the rear subframe when a load is input to the rear side frame and the rear subframe when an impact load is applied from the rear of the vehicle body at the time of a rear collision. Therefore, it is possible to prevent the rear side frame and the rear sub frame from being separated by the frame connecting portion and to deform the rear side frame and the rear sub frame from the rear side of the vehicle body. Energy absorption performance can be improved and the safety of passengers in the passenger compartment can be increased.

Also, Li Ya side frame is provided with a collapsing deformation unacceptable portion of the vehicle body rear side crushing deformation allowing portion and the vehicle front side, the frame connections, the collapse deformation nonpermissive portion and the rear sub-frame of the rear side frame crush deformation It is provided so as to connect the non-permitted portion to suppress separation of the rear side frame and the rear subframe.

As a result, when a rear collision occurs, when a load is applied to the rear side frame and the rear sub frame when an impact load is applied from the rear of the vehicle body, the frame connecting portion is subjected to the deformation deformation non-permitted portion of the rear side frame and the rear sub frame. Since it is provided so as to connect the non-permitted portion, the rear side frame and the rear sub frame can be prevented from being separated by the frame connecting portion, and the rear side frame and the rear sub frame can be crushed and deformed from the rear side of the vehicle body. It is possible to improve the energy absorption performance at the time of a rear collision and improve the safety of passengers in the passenger compartment.
The rear sub-frame includes an upper horizontal frame, a vertical frame extending downward from the front end portion of the upper horizontal frame, and a lower horizontal frame connected to the lower end portion of the vertical frame and extending forward of the vehicle body. By providing the frame on the rear side of the vehicle body and on the upper side of the vehicle body from the battery, the above-described effects can be effectively obtained.

Further, according to the invention described in claim 2, the bridge portion connecting the vehicle body lower side of the upper end portion of the vehicle body rear side and the vertical frame of the front end of the upper side horizontal frame is provided.

  As a result, when a load is input to the rear sub-frame when an impact load is applied from the rear of the vehicle during a rear impact, the load input to the upper horizontal frame is transmitted from the upper horizontal frame to the vertical frame through the bridge portion. Therefore, it is possible to reduce the load transmitted through the corner between the upper horizontal frame and the vertical frame and to prevent the corner between the upper horizontal frame and the vertical frame from being deformed. it can.

According to the third aspect of the present invention, the battery frame is disposed on the vehicle body front side of the rear sub-frame, and the vehicle body front side of the rear sub-frame is connected to the battery frame, so that the rear sub-frame at the time of a rear collision. The load input to the battery frame can be transmitted to the battery frame and dispersed, so that the above-described effect can be achieved more effectively.

According to the fourth aspect of the present invention, there are provided a plurality of frame connecting portions that connect the vehicle body front side from the rear end portion of the rear side frame and the vehicle body front side from the rear end portion of the rear subframe, The frame connecting portions are arranged at substantially constant intervals in the longitudinal direction of the vehicle body, so that the separation of the rear side frame and the rear subframe by the plurality of frame connecting portions can be effectively suppressed, and the above effect is more effective. Can get to.

1 is a bottom view of a vehicle body to which a rear vehicle body structure according to an embodiment of the present invention is applied. 1 is a side view of a vehicle body to which a rear vehicle body structure according to an embodiment of the present invention is applied. FIG. 2 is a bottom view of the vehicle body shown in FIG. 1 with a rear subframe and a battery frame removed. It is a perspective view which shows the principal part of the vehicle body of FIG. It is sectional drawing of the vehicle body along the Y5-Y5 line in FIG. It is a perspective view of a rear subframe. It is a perspective view of the vehicle body which shows the A section of FIG. It is sectional drawing of the vehicle body which shows the frame connection part which connects a rear side frame and a rear sub-frame. FIG. 6 is a cross-sectional view of a vehicle body showing a modified example of a frame connecting portion that connects a rear side frame and a rear subframe. It is sectional drawing of the vehicle body which shows the frame connection part which connects a rear sub-frame and a battery frame. It is sectional drawing of the vehicle body which shows the frame connection part which connects a battery frame and a front floor frame.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

  1 is a bottom view of a vehicle body to which a vehicle rear body structure according to an embodiment of the present invention is applied. FIG. 2 is a side view of a vehicle body to which the vehicle rear body structure according to the embodiment of the present invention is applied. 1 is a bottom view of the vehicle body shown in FIG. 1 with the rear subframe and the battery frame removed, FIG. 4 is a perspective view showing the main part of the vehicle body of FIG. 3, and FIG. 5 is taken along the line Y5-Y5 in FIG. It is sectional drawing of a vehicle body. In FIG. 1, a drive motor as a drive source is omitted.

  A vehicle body 1 to which a rear body structure of a vehicle according to an embodiment of the present invention is applied is a vehicle body such as an electric vehicle. As shown in FIGS. 1 to 5, a pair of left and right rear sides extending in the longitudinal direction of the vehicle body at the rear portion of the vehicle body. A frame 2 and a rear subframe 70 extending in the longitudinal direction of the vehicle body along the left and right rear side frames 2 are disposed below the pair of left and right rear side frames 2.

  As shown in FIG. 3, the rear part of the vehicle body also has a rear floor panel 3 installed on the pair of left and right rear side frames 2, and extends in the vehicle width direction on the lower surface side of the rear floor panel 3. No. 2 installed between the rear side frames 2 of each. 4 Cross member 4 and No. 4 5 and a cross member 5 are disposed.

  No. The four cross members 4 are provided so as to connect the left and right rear side frames 2 to the vehicle body front side. No. 5. The cross member 5 is provided so as to connect the vehicle body front-rear direction center sides of the left and right rear side frames 2 and is disposed on the lower surface side of the spare tire storage portion 3a that is provided in the rear floor panel 3 and that is recessed downward. .

  The rear side frame 2 is formed in a substantially U-shaped cross section, is attached to the lower surface side of the rear floor panel 3, and forms a closed cross section that extends in the longitudinal direction of the vehicle body in cooperation with the rear floor panel 3. No. 4 Cross member 4 and No. 4 Each of the five cross members 5 is formed in a substantially hat-shaped cross section and is attached to the lower surface side of the rear floor panel 3 to form a closed cross section extending in the vehicle width direction in cooperation with the rear floor panel 3.

  The rear end portions of the left and right rear side frames 2 are respectively attached to crash cans 7 mounted at both ends of a rear bumper rain 6 provided in a rear bumper (not shown) extending in the vehicle width direction at the rear of the vehicle body. The crash can 7 is crushed and deformed so as to be folded when an impact load is applied from the rear of the vehicle body at the time of a rear collision, and absorbs energy.

  A front end portion of the rear side frame 2 is overlapped and connected to a rear end portion of the kick-up frame 10 that is inclined outward in the vehicle width direction and downward of the vehicle body from the vehicle body rear side toward the vehicle body front side. The front end of the front is overlapped and connected to the rear end of the front floor frame 11 extending in the longitudinal direction of the vehicle body.

  Centered on the left and right kick-up frames 10 are center floor panels 13 that are provided on the front side of the vehicle body from the rear floor panel 3 and incline downward from the vehicle body rear side toward the vehicle body front side. A front floor panel 14 provided on the front side of the vehicle body from the center floor panel 13 is installed. In the vehicle body 1, a vehicle compartment is provided on the front floor panel 14.

  The kick-up frame 10 is formed in a substantially hat-shaped cross section, is attached to the lower surface side of the center floor panel 13, and forms a closed cross section that cooperates with the center floor panel 13 and extends in the longitudinal direction of the vehicle body. The front floor frame 11 is formed in a substantially hat-shaped cross section and is attached to the lower surface side of the front floor panel 14, and forms a closed cross section that cooperates with the front floor panel 14 and extends in the longitudinal direction of the vehicle body.

  A plurality of cross members 15 extending in the vehicle width direction and spaced apart from each other in the vehicle body front-rear direction and extending between the left and right front floor frames 11 are attached to the lower surface side of the front floor panel 14.

  As shown in FIG. No. 4 between the left and right front floor frames 11 on the vehicle body front side of the cross member 4. Three cross members 15 are installed. No. The three cross members 15 are formed in a substantially hat-shaped cross section, are attached to the lower surface side of the front floor panel 14, and form a closed cross section extending in the vehicle width direction in cooperation with the front floor panel 14. For other cross members installed between the left and right front floor frames 11, no. It is formed in the same manner as the three cross member 15.

Next, the rear side frame 2 and the rear subframe 70 of the vehicle body 1 according to the present embodiment will be described.
As shown in FIGS. 4 and 5, the rear side frame 2 includes a lower surface portion 2a and side surface portions 2b on both sides of the lower surface portion 2a extending in a direction substantially perpendicular to the lower surface portion 2a. Is formed. The rear side frame 2 is also provided with flange portions 2c on both sides that extend outward from the rear side frame 2 on the side surface portions 2b on both sides, and the flange portions 2c on both sides are attached to the rear floor panel 3.

  In the present embodiment, the rear side frame 2 is configured to be divided in the vehicle front-rear direction by a front frame 20 disposed on the front side of the vehicle body and a rear frame 30 disposed on the vehicle body rear side of the front frame 20. The rear end portion of the frame 20 and the front end portion of the rear frame 30 are overlapped and joined.

  Each of the front frame 20 and the rear frame 30 includes lower surface portions 21, 31 and side surface portions 22, 32 on both sides of the lower surface portions 21, 31 extending in a direction substantially orthogonal to the lower surface portions 21, 31. It is formed in a substantially U-shaped cross section. Further, the front frame 20 and the rear frame 30 are provided with flange portions 23 and 33 on both sides extending to the outside of the rear side frame 2 on the side portions 22 and 32 on both sides, respectively, and the flange portions 23 and 33 on both sides are formed on the rear floor. It is attached to the panel 3.

  As shown in FIG. 5, the rear end portion of the front frame 20 and the front end portion of the rear frame 30 are overlapped with the front end portion of the rear frame 30 inserted inside the rear end portion of the front frame 20. The overlapping portion 41 of the rear end portion of the front frame 20 and the front end portion of the rear frame 30 is joined and attached by welding or the like.

  In the present embodiment, the rear frame 30 is formed by, for example, pressing the rear frame 30 using a steel plate having a thickness of 1.4 mm and press-molding the front frame 20 using a steel plate having a thickness of 1.6 mm. It is formed using a steel plate that is thinner than the front frame 20, and has a lower strength against axial compression than the front frame 20.

  The rear frame 30 is formed by, for example, forming the rear frame 30 using a 590 MPa class high strength steel plate having a tensile strength of 590 MPa or more and press forming the front frame 20 using a 780 MPa class high strength steel plate having a tensile strength of 780 MPa or more. For example, a steel plate having a different tensile strength that has a correlation with the strength against compression in the axial direction is used, and a steel plate having a tensile strength lower than that of the front frame 20 is used to set the strength against compression in the axial direction lower than that of the front frame 20. Alternatively, it may be formed using a steel plate having a thickness smaller than that of the front frame 20 and a lower tensile strength, and the strength against axial compression may be set lower than that of the front frame 20.

  As described above, no. 5 Cross member 5 is installed. As shown in FIGS. 4 and 5, the 5 cross member 5 is connected to an overlapping portion 41 of the rear end portion of the front frame 20 and the front end portion of the rear frame 30 in the rear side frame 2. The left and right rear side frames 2 are formed in the same manner. 5 Cross member 5 has both ends connected to overlapping portion 41 of one rear side frame 2 and overlapping portion 41 of the other rear side frame 2, respectively.

  In the vehicle body 1, as described above, the rear subframe 70 is disposed at the rear of the vehicle body, and the rear subframe 70 supports the drive motor 61 as a drive source as shown in FIGS. Is provided. A battery frame 100 that supports a battery 62 that stores electric power to be supplied to the drive motor 61 is also disposed on the front side of the vehicle body from the rear subframe 70.

  FIG. 6 is a perspective view of the rear subframe. As shown in FIGS. 1, 2, and 6, the rear sub-frame 70 includes an upper horizontal frame 71 that extends substantially horizontally in the vehicle longitudinal direction along the rear side frame 2, and a lower side from the front end of the upper horizontal frame 71. A vertical frame 74 extending in a substantially vertical direction and a lower horizontal frame 75 connected to the lower end portion of the vertical frame 74 and extending in a substantially horizontal direction on the front side of the vehicle body are provided.

  The upper horizontal frame 71 connects the left and right upper frame portions 72 extending in the vehicle body longitudinal direction along the left and right rear side frames 2 and the vehicle body longitudinal direction center side of the left and right upper frame portions 72 extending in the vehicle width direction. Thus, an upper cross portion 73 is provided between the left and right upper frame portions 72.

  Between the upper horizontal frame 71 and the vertical frame 74, a front end portion of the upper horizontal frame 71, specifically, a vehicle body rear side from the front end portion of the upper frame portion 72 and a vehicle body lower side from the upper end portion of the vertical frame 74. A bridging portion 80 to be connected is provided, and the bridging portion 80 is connected to the upper frame portion 72 at substantially the same position in the longitudinal direction of the vehicle body as the portion to which the upper cross portion 73 is connected. The bridging portion 80 is formed of a plate-like member, and is provided so as to incline to the vehicle body lower side as it goes to the vehicle body front side.

  The lower horizontal frame 75 is connected to the lower ends of the left and right vertical frames 74 and extends in the vehicle width direction, and two lower frame portions 77 extending from the lower rear cross portion 76 to the vehicle body front side. The lower frame portion 77 is connected to the lower frame portion 77 and the lower frame portion 77 and the lower frame portion 77 is connected to the front end portions of the two lower frame portions 77 and extends in the vehicle width direction. And a cross portion 79.

  In the rear sub-frame 70, the upper horizontal frame 71, the vertical frame 74, and the lower horizontal frame 75 are each configured to have a closed cross section having the same plate thickness using a metal material, and the bridging portion 80 is formed in a plate shape using the metal material. The upper horizontal frame 71, the vertical frame 74, the lower horizontal frame 75, and the bridge portion 80 are joined to each other. In addition, you may make it the bridge | crosslinking part 80 comprise in a closed cross section.

  In the rear sub-frame 70 configured in this manner, as shown in FIG. 2, a crush deformation allowing portion 85 that is provided on the rear side of the vehicle body and allows crushing deformation when an impact load from the vehicle body rear side is applied, A crushing deformation non-permissible portion 86 provided on the front side of the vehicle body of the crushing deformation allowing portion 85 is provided, and the crushing deformation allowing portion 85 is from a portion where the upper cross portion 73 and the bridging portion 80 in the upper horizontal frame 71 are connected. The crushing deformation non-permissible portion 86 is formed by a portion on the vehicle body front side from a portion where the upper cross portion 73 and the bridging portion 80 in the upper horizontal frame 71 are connected.

  In the present embodiment, the rear sub-frame 70 has an upper horizontal frame 71, a vertical frame 74, and a lower horizontal frame 75 each having a closed cross section with the same plate thickness. 85 may be configured to have a closed cross-section with a plate thickness thinner than the crush deformation non-permissible portion 86 of the rear subframe 70, and the crush deformation permissible portion 85 and the crush deformation non-permissible portion 86 of the rear subframe 70 may be formed. . Further, the crushing deformation allowable portion 85 of the rear subframe 70 is formed in a closed cross section using a steel plate having a lower tensile strength than the crushing deformation non-permissible portion 86 of the rear subframe 70, and the crushing deformation allowable portion 85 of the rear subframe 70 is configured. It is also possible to form the crushing deformation non-permissible portion 86.

  FIG. 7 is a perspective view of the vehicle body showing a portion A of FIG. 2, and in FIG. 7, the rear floor panel 3 installed on the rear side frame 2 is omitted. Similar to the rear end portion of the rear side frame 2, the rear end portion of the rear sub frame 70 is attached to the crash cans 7 that are respectively attached to both end portions of the rear bumper rain 6.

  As shown in FIG. 7, a first plate member 8 extending in a direction substantially orthogonal to the longitudinal direction of the vehicle body is fixed to the front end portion of the crash can 7 by welding or the like, and the first plate member 8 is formed in a substantially rectangular shape. In addition, four bolt insertion holes are formed in the peripheral portion.

  On the other hand, a second plate member 52 extending in a direction substantially orthogonal to the longitudinal direction of the vehicle body is fixed to the rear end portion of the rear side frame 2 by welding or the like, and the second plate member 52 is approximately half the size of the first plate member 8. Now, two bolt insertion holes are formed on both sides of the portion which is formed in a substantially rectangular shape and fixed to the rear side frame 2.

  Further, a third plate member 53 extending in a direction substantially orthogonal to the longitudinal direction of the vehicle body is fixed to the rear end portion of the rear subframe 70 by welding or the like, and the third plate member 53 is substantially half of the first plate member 8. Two bolt insertion holes are formed on both sides of the portion fixed to the rear sub-frame 70 and having a substantially rectangular shape.

  The second plate member 52 and the third plate member 53 are in contact with the first plate member 8 in a state where they are arranged vertically, and the first plate member 8 and the second plate member 52 are inserted into the bolt insertion holes. The first plate member 8 and the third plate member 53 are fastened by using the bolt B2 and the nut that are inserted into the bolt insertion hole.

  As a result, the crash can 7 and the rear side frame 2 are coupled, the crash can 7 and the rear subframe 70 are coupled, and the rear end portion of the rear side frame 2 and the rear end portion of the rear subframe 70 are connected to the plate member 8. , 52, 53.

  FIG. 8 is a cross-sectional view of the vehicle body showing a frame connecting portion that connects the rear side frame and the rear subframe. FIG. 8 shows a cross-section of the vehicle body taken along line Y8-Y8 in FIG. As shown in FIG. 2, in the vehicle body 1, the rear end portion of the rear side frame 2 and the rear end portion of the rear subframe 70 are coupled, and the vehicle body front side and the rear subframe 70 are connected to the rear end portion of the rear side frame 2. A frame connecting portion that connects the vehicle body front side with respect to the rear end portion, in this embodiment, three frame connecting portions 54, 55, and 56 are provided.

  As shown in FIG. 8, in the frame connection portion 54 that connects the rear side frame 2 and the rear subframe 70, the rear side frame 2 has a bolt insertion hole 2d formed in the lower surface portion 2a and corresponds to the bolt insertion hole 2d. The nut N3 is fixed to the upper surface side of the lower surface portion 2a by welding or the like.

  On the other hand, the upper horizontal frame 71 of the rear subframe 70, specifically, the upper frame portion 72, includes a first frame member 81 having an upper surface portion 81a and side surface portions 81b on both sides and formed in a substantially U-shaped cross section. The second frame member 82 includes a lower surface portion 82a and side surface portions 82b on both sides and is formed in a substantially U-shaped cross section. The side surface portions 81b and the second frame member 82 on both sides of the first frame member 81 are formed. The side portions 82b on both sides of the two are joined by welding or the like to form a closed cross section.

  The upper frame portion 72 has an upper surface portion formed by the upper surface portion 81 a of the first frame member 81, a lower surface portion formed by the lower surface portion 82 a of the second frame member 82, side surface portions 81 b on both sides of the first frame member 81, and The side portions on both sides are formed by the side portions 82b on both sides of the second frame member 82, and are formed in a substantially rectangular cross section.

  A cylindrical member 83 which is formed in a substantially cylindrical shape and through which a bolt is inserted is fixed to the upper frame portion 72 by welding or the like. The cylindrical member 83 includes a base portion 83a provided on one end side, and a tip portion 83b provided on the other end side and having an outer diameter and an inner diameter smaller than the base portion 83a, and includes a base portion 83a and a tip portion 83b. A step portion 83c is provided between them.

  In the upper frame portion 72, a circular opening 81c through which the distal end portion 83b of the cylindrical member 83 is inserted is formed in the upper surface portion 81a, and a bolt insertion hole 82c is formed in the lower surface portion 82a. The cylindrical member 83 has a base 83a disposed in the upper frame portion 72 with respect to the upper frame portion 72, and a step portion 83c is welded to the upper surface portion 81a in a state where the tip portion 83b protrudes from the opening 81c. It is fixed by.

  Then, as shown in FIG. 8, the bolt B3 is screwed onto the nut N3 from the lower side of the upper frame portion 72 in a state where the tip 83b of the cylindrical member 83 is in contact with the lower surface portion 2a of the rear side frame 2. The rear side frame 2 and the rear sub frame 70 are connected.

  The frame connecting portions 55 and 56 are also formed in the same manner as the frame connecting portion 54, and the three frame connecting portions 54, 55, and 56 are arranged at substantially constant intervals in the longitudinal direction of the vehicle body as shown in FIG. . The frame connecting portions 54, 55, and 56 are provided to connect the vehicle body front side, the vehicle body front-rear direction center side, and the vehicle body rear side of the upper frame portion 72 to the rear side frame 2, respectively. In the overlapping portion 41, the rear side frame 2 and the rear subframe 70 are connected.

  As described above, the rear sub-frame 70 is provided on the rear side of the vehicle body and allows the deformation to be crushed and deformed when an impact load is applied from the rear of the vehicle body. And a crushing deformation non-permissible portion 86 provided on the surface.

  The rear side frame 2 is also provided on the rear side of the vehicle body and is allowed to be crushed and deformed when an impact load is applied from the rear of the vehicle body, and the crushed material is provided on the front side of the crushed deformation allowable portion 87. A deformation non-permissible portion 88 is provided, the crush deformation allowable portion 87 is formed by the rear frame 30 excluding the overlapping portion 41, and the crush deformation non-permissible portion 88 is formed by the front frame 20 including the overlapping portion 41. Has been.

  As shown in FIG. 2, the frame connecting portion 54 is provided so as to connect the crush deformation non-permissible portion 88 of the rear side frame 2 and the crush deformation non-permissible portion 86 of the rear subframe 70. The crush deformation allowable portion 87 of the rear side frame 2 and the crush deformation non-permissible portion 86 of the rear subframe 70 are connected to each other, and the frame connecting portion 56 is connected to the crush deformation allowable portion 87 of the rear side frame 2 and the rear subframe 70. Is provided so as to be connected to the crushing deformation allowable portion 85.

  As described above, the frame connecting portion 54 is provided so as to connect the rear side frame 2 and the crush deformation non-permissible portion 86 of the rear subframe 70. Specifically, the crush deformation non-permissible portion 88 of the rear side frame 2 and It is provided so as to connect to the crushing deformation non-permissible portion 86 of the rear subframe 70.

  FIG. 9 is a cross-sectional view of the vehicle body showing a modification of the frame connecting portion that connects the rear side frame and the rear subframe. In the frame connecting portion 54 'shown in FIG. 9, a protruding portion 2a' protruding downward is provided on the lower surface portion 2a of the rear side frame 2, and a bolt insertion hole 2d is formed in the protruding portion 2a 'and the bolt insertion hole 2d. Nut N3 is welded correspondingly.

  On the other hand, in the upper frame portion 72 of the rear subframe 70, a bolt insertion hole 81c 'is formed in the upper surface portion 81a and a bolt insertion hole 82c is formed in the lower surface portion 82a. A cylindrical member 83 ′ is fixed to the upper surface portion 81 a of the upper frame portion 72.

  Then, as shown in FIG. 9, with the protrusion 2 a ′ provided on the lower surface 2 a of the rear side frame 2 in contact with the rear subframe 70, the bolt B 3 is inserted from the lower side of the upper frame 72 to the nut. The rear side frame 2 and the rear subframe 70 are connected to each other by being screwed to N3.

  In this manner, a bolt and a nut are fastened in a state where a part of the lower surface portion 2 a of the rear side frame 2 protrudes downward and is in contact with the rear subframe 70, and the front side of the vehicle body from the rear end portion of the rear side frame 2 is fastened. It is also possible to connect the side and the vehicle body front side from the rear end portion of the rear subframe 70.

  FIG. 10 is a cross-sectional view of the vehicle body showing a frame connecting portion that connects the rear subframe and the battery frame, and is a cross-sectional view of the vehicle body taken along line Y10-Y10 in FIG. As shown in FIG. 10, the lower horizontal frame 75 of the rear sub-frame 70, specifically, the lower frame portion 77 is also provided with an upper surface portion 91a and side portions 91b on both sides, and is formed in a substantially U-shaped cross section. The first frame member 91, and the second frame member 92 having a lower surface portion 92 a and side surface portions 92 b on both sides and having a substantially U-shaped cross section are formed. The portion 91b and the side surface portions 92b on both sides of the second frame member 92 are joined together by welding or the like to form a closed cross section.

  The lower frame portion 77 has an upper surface portion formed by the upper surface portion 91 a of the first frame member 91, a lower surface portion formed by the lower surface portion 92 a of the second frame member 92, and side surface portions 91 b on both sides of the first frame member 91. And the side part of both sides is formed by the side part 92b of the both sides of the 2nd frame member 92, and the cross section is formed in the substantially rectangular shape.

  As shown in FIG. 1, the battery frame 100 includes a front frame (not shown) that is disposed on the vehicle body front side and extends in the vehicle width direction, a rear frame 100a that is disposed on the vehicle body rear side and extends in the vehicle width direction, Side frames 100b on both sides extending in the longitudinal direction of the vehicle body are provided by connecting both sides in the vehicle width direction of the frame and both sides in the vehicle width direction of the rear frame 100a.

  As shown in FIG. 10, the front frame, the rear frame 100a, and the side frames 100b on both sides are respectively an upper surface portion 101a and side surface portions 101b on both sides of the upper surface portion 101a extending in a direction substantially orthogonal to the upper surface portion 101a. The first frame member 101 having both side flange portions 101c extending outward from the side surface portions 101b on both sides and having a substantially hat-shaped cross section, and the second frame member 102 formed in a flat plate shape. The flange portions 101c on both sides of the first frame member 101 are overlapped with the second frame member 102 and joined by welding or the like to form a closed cross section.

  In the frame connection portion 57 that connects the rear subframe 70 and the battery frame 100, a bolt insertion hole 101d is formed in the flange portion 101c of the first frame member 101 in the battery frame 100, specifically, the rear frame 100a. In addition, a nut N4 is fixed to the upper surface side of the flange portion 101c by welding or the like corresponding to the bolt insertion hole 101d, and a bolt insertion hole 102a is formed in the second frame member 102.

  On the other hand, in the lower horizontal frame 75 of the rear subframe 70, specifically, the lower frame portion 77, a bolt insertion hole 91c is formed in the upper surface portion 91a, and a bolt insertion hole 92c is formed in the lower surface portion 92a. A cylindrical member 103 that is formed in a substantially cylindrical shape and into which a bolt is inserted is fixed to the upper surface portion 91 a of the lower frame portion 77.

  As shown in FIG. 10, with the second frame member 102 of the battery frame 100 in contact with the lower frame portion 77 of the rear subframe 70, the bolt B <b> 4 is moved from the lower side of the lower frame portion 77. The rear sub frame 70 and the battery frame 100 are connected to each other by screwing onto the nut N4. Similarly, the other lower frame portion 77 of the rear sub-frame 70 is connected to the vehicle body rear side of the battery frame 100.

  FIG. 11 is a cross-sectional view of the vehicle body showing a frame connecting portion that connects the battery frame and the front floor frame, and is a cross-sectional view of the vehicle body taken along line Y11-Y11 in FIG. The battery frame 100, specifically, the side frame 100 b is disposed along the lower side of the front floor frame 11 and connected to the front floor frame 11.

  As shown in FIG. 11, the front floor frame 11 includes a lower surface portion 11a, side surface portions 11b extending in a direction substantially orthogonal to the lower surface portion 11a on both sides of the lower surface portion 11a, and outward from the side surface portions 11b on both sides. The flange portions 11 c on both sides are formed to have a substantially hat-like cross section, and the flange portions 11 c on both sides are coupled and attached to the lower surface side of the front floor panel 14.

  In the frame connecting portion 58 that connects the battery frame 100 and the front floor frame 11, the front floor frame 11 is formed with a bolt insertion hole 11d in the lower surface portion 11a and the lower surface portion 11a corresponding to the bolt insertion hole 11d. A nut N5 is fixed to the upper surface side by welding or the like.

  On the other hand, the battery frame 100, specifically the side frame 100b, has a bolt insertion hole 101e formed in the upper surface portion 101a of the first frame member 101 and a bolt insertion hole 102b formed in the second frame member 102, A cylindrical member 113 that is formed in a cylindrical shape and through which a bolt is inserted is fixed to the upper surface portion 101 a of the first frame member 101.

  Then, as shown in FIG. 11, with the upper surface portion 101 a of the first frame member 101 of the battery frame 100 in contact with the lower surface portion 11 a of the front floor frame 11, the bolt B5 is connected from the lower side of the battery frame 100. The battery frame 100 and the front floor frame 11 are connected to each other by screwing onto the nut N5.

  In the present embodiment, a plurality of frame connection portions 58 that connect the battery frame 100, specifically, the side frame 100b and the front floor frame 11, are provided apart from each other in the vehicle body front-rear direction. Note that the front frame of the battery frame 100 is connected to a vehicle body member such as a front side frame via a front subframe disposed on the vehicle body front side, for example.

  When an impact load is applied to the vehicle body 1 configured in this way from the rear of the vehicle body, when the load is input to the rear side frame 2 after the crush can 7 is crushed and deformed, the rear side frame 2 is crushed and deformed non-permitted. Before being deformed by crushing, the crushing deformation allowing portion 87 is crushed and deformed from the rear side of the vehicle body to absorb energy.

  In the vehicle body 1, after the crash can 7 is crushed and deformed, a load is input to the rear subframe 70. When a load is input to the rear subframe 70, the crushed deformation non-permissible portion 86 is crushed and deformed. Before being deformed, the crushing deformation allowing portion 85 is crushed and deformed, and is crushed and deformed from the rear side of the vehicle body to absorb energy.

  When an impact load is applied to the vehicle body 1 from the rear of the vehicle body, the separation of the rear side frame 2 and the rear subframe 70 is also suppressed by the frame connecting portions 54, 55, 56 in the vehicle body 1.

  As described above, in the rear vehicle body structure of the vehicle according to the present embodiment, the rear subframe 70 disposed below the rear side frame 2 has a crush deformation allowable portion 85 on the rear side of the vehicle body and a crush deformation non-removable portion on the front side of the vehicle body. And a rear end portion of the rear side frame 2 and a rear end portion of the rear subframe 70 are connected via plate members 8, 52, 53, and the vehicle body is connected to the vehicle body from the rear end portion of the rear side frame 2. A frame connecting portion 54 is provided to connect the front side to the front side of the vehicle body from the rear end portion of the rear subframe 70. The frame connecting portion 54 connects the rear side frame 2 and the crush deformation non-permissible portion 86 of the rear subframe 70. Provided to connect.

  As a result, when a load is input to the rear side frame 2 and the rear subframe 70 when a shock load is applied from the rear of the vehicle body at the time of a rear collision, the frame connecting portion 54 is not deformed by the deformation of the rear side frame 2 and the rear subframe 70. Since it is provided so as to connect to the allowance portion 86, the rear side frame 2 and the rear sub frame 70 are prevented from being separated by the frame connection portion 54, and the rear side frame 2 and the rear sub frame 70 are separated from the rear side of the vehicle body. It can be crushed and deformed, and the energy absorption performance at the time of rear-end collision can be enhanced to improve the safety of passengers in the vehicle interior.

  The rear side frame 2 includes a crush deformation allowing portion 87 on the rear side of the vehicle body and a crush deformation not allowing portion 88 on the front side of the vehicle body, and the frame connecting portion 54 includes a crush deformation not allowing portion 88 on the rear side frame 2 and a rear sub It is provided so as to connect the crush deformation non-permissible portion 86 of the frame 70.

  As a result, when a load is input to the rear side frame 2 and the rear subframe 70 when an impact load is applied from the rear of the vehicle body at the time of a rear collision, the frame connection portion 54 is connected to the crush deformation non-permissible portion 88 of the rear side frame 2 and the rear Since it is provided so as to connect the crush deformation non-permissible portion 86 of the sub frame 70, the rear side frame 2 and the rear sub frame 70 are prevented from being separated by the frame connecting portion 54. The frame 70 can be crushed and deformed from the rear side of the vehicle body, and the energy absorption performance at the time of rear-end collision can be enhanced to improve the safety of passengers in the vehicle interior.

  The rear sub frame 70 includes an upper horizontal frame 71, a vertical frame 74 extending downward from the front end of the upper horizontal frame 71, and a lower horizontal frame 75 connected to the lower end of the vertical frame 74 and extending forward of the vehicle body. And a bridging portion 80 that connects the vehicle body rear side from the front end portion of the upper horizontal frame 71 and the vehicle body lower side from the upper end portion of the vertical frame 74 is provided.

  Thereby, when a load is input to the rear sub-frame 70 in the event of an impact load from the rear of the vehicle body at the time of a rear collision, the load input to the upper horizontal frame 71 is vertically transmitted from the upper horizontal frame 71 through the bridge portion 80. Since it can be transmitted to the frame 74 and dispersed, the load transmitted through the corner between the upper horizontal frame 71 and the vertical frame 74 is reduced, and the corner between the upper horizontal frame 71 and the vertical frame 74 is reduced. Can be prevented from being deformed.

  Further, the battery frame 100 is disposed on the vehicle body front side of the rear subframe 70, and the vehicle body front side of the rear subframe 70 is connected to the battery frame 100, so that a load input to the rear subframe 70 at the time of a rear collision is obtained. It can be transmitted to the battery frame 100 and dispersed.

  A plurality of frame connection portions 54, 55, 56 are provided for connecting the vehicle body front side from the rear end portion of the rear side frame 2 and the vehicle body front side from the rear end portion of the rear subframe 70. , 55 and 56 are arranged at substantially constant intervals in the longitudinal direction of the vehicle body, thereby effectively preventing the rear side frame 2 and the rear subframe 70 from being separated by the plurality of frame connecting portions 54, 55 and 56. Can do.

  The present invention is not limited to the illustrated embodiments, and various improvements and design changes can be made without departing from the scope of the present invention.

  As described above, according to the present invention, in the rear body structure of a vehicle including a rear side frame and a rear subframe, it is possible to improve the energy absorption performance at the time of a rear collision and improve the safety of passengers in the vehicle interior. Therefore, it may be suitably used in the manufacturing industry of this type of vehicle.

DESCRIPTION OF SYMBOLS 1 Car body 2 Rear side frame 8,52,53 Plate member 54,54 ', 55,56 Frame connection part 62 Battery 70 Rear sub-frame 71 Upper horizontal frame 74 Vertical frame 75 Lower horizontal frame 80 Bridging part 85 Collapse of rear sub-frame Deformation permitting portion 86 Rear subframe crushing deformation non-permissible portion 87 Rear side frame crushing deformation allowing portion 88 Rear side frame crushing deformation nonpermissible portion 100 Battery frame

Claims (4)

A vehicle comprising a pair of left and right rear side frames extending in the longitudinal direction of the vehicle body at a rear portion of the vehicle body, and a rear subframe disposed below the pair of left and right rear side frames and extending in the longitudinal direction of the vehicle body along the pair of left and right rear side frames. The rear body structure,
The rear sub-frame is provided on the rear side of the vehicle body to allow the deformation to be crushed and deformed when an impact load is applied from the rear of the vehicle body, and the crushed deformation provided on the front side of the vehicle body of the crushed deformation permission portion. With non-allowable parts,
A rear end portion of the rear side frame and a rear end portion of the rear subframe are connected via a plate member, and a vehicle body front side from the rear end portion of the rear side frame and a vehicle body from the rear end portion of the rear subframe. A frame connecting part that connects the front side is provided,
The frame connecting portion is provided to connect the rear side frame and a crush deformation non-permissible portion of the rear subframe ,
The rear side frame is provided on the rear side of the vehicle body and is allowed to be crushed and deformed when an impact load is applied from the rear of the vehicle body. With an allowance part,
The frame connecting portion is provided so as to connect the crush deformation non-permissible portion of the rear side frame and the crush deformation non-permissible portion of the rear sub frame to suppress separation of the rear side frame and the rear sub frame. And
The rear sub-frame includes an upper horizontal frame extending in a substantially horizontal direction in the vehicle longitudinal direction along the rear side frame, a vertical frame extending in a substantially vertical direction downward from a front end portion of the upper horizontal frame, and a lower end of the vertical frame A lower horizontal frame connected to the front portion and extending in a substantially horizontal direction on the front side of the vehicle body,
The upper horizontal frame is provided on the vehicle body rear side and the vehicle body upper side from the battery,
A vehicle body structure for a rear portion of a vehicle. Before SL bridge portion connecting the vehicle body lower side of the upper end of the vertical frame and the rear side of the vehicle body from the front end of the upper horizontal frame is provided,
The rear body structure of the vehicle according to claim 1 . A battery frame that supports the battery is disposed on the vehicle body front side of the rear subframe,
A vehicle body front side of the rear sub-frame is connected to the battery frame;
The rear body structure of a vehicle according to claim 1 or 2 , characterized in that A plurality of frame connecting portions for connecting the vehicle body front side from the rear end portion of the rear side frame and the vehicle body front side from the rear end portion of the rear subframe;
The plurality of frame connecting portions are arranged at substantially constant intervals in the longitudinal direction of the vehicle body,
At least one of the frame connection portions is provided to connect the rear side frame and the crush deformation non-permissible portion of the rear subframe;
The rear body structure of a vehicle according to any one of claims 1 to 3 , wherein the vehicle body structure is a rear body structure.

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