Invention name: Front pillar outer
Technical field
[0001]
　The present invention relates to a front pillar outer that constitutes a front pillar.
Background technology
[0002]
　The body of the car includes the front pillars. The front pillar is composed of a combination of a front pillar inner, a front pillar outer, and the like. From the viewpoint of improving the collision safety of automobiles, it is desirable that the front pillars have high strength. Further, from the viewpoint of improving running stability, it is desirable that the front pillar has high rigidity. Therefore, the front pillars are required to have improved strength and rigidity.
[0003]
　The vehicle body parts having improved strength are described in, for example, Japanese Patent Application Laid-Open No. 2014-11809 (Patent Document 1), Japanese Patent Application Laid-Open No. 5-310147 (Patent Document 2), and Japanese Patent Application Laid-Open No. 2016-2781 (Patent Document 3). Has been done.
[0004]
　Patent Document 1 describes a front pillar lower provided with a reinforcing component. The reinforcing component described in Patent Document 1 includes a vertical surface portion facing the front wheel and a high-strength horizontal surface portion. When a vehicle collides head-on, the front wheels move to the rear of the vehicle. The vertical surface limits the movement of the front wheels to the rear of the vehicle. The horizontal surface portion absorbs the collision energy loaded on the vertical surface portion. It is described in Patent Document 1 that the deformation of the front pillar lower due to the collision can be suppressed by this.
[0005]
　The vehicle body component disclosed in Patent Document 2 includes a first structure having a closed cross section and a second structure having a closed cross section and welded to the first structure. Therefore, the vehicle body component includes a region composed of only the first structure and a region composed of the first structure and the second structure. In short, the body parts include areas of two different plate thicknesses. It is described in Patent Document 2 that this enhances the ability to absorb the collision energy of the vehicle body parts.
[0006]
　The vehicle body parts disclosed in Patent Document 3 include a U-shaped first part and a U-shaped second part. Slits are provided at the ends of the first component and the ends of the second component, respectively. The slit of the first component is arranged so as to overlap the slit of the second component, and the first component and the second component are welded to each other. Therefore, since the two parts overlap in a part of the vehicle body parts, the strength is increased. It is described in Patent Document 3 that the strength of the vehicle body parts is high even if the reinforcing plate or the like of another member is not provided.
[0007]
　In addition to Patent Documents 1 to 3, as a technique for improving strength and rigidity, the material of the front pillar may be a tailored welded blank (hereinafter, also referred to as "TWB") or a tailored rolled blank (hereinafter, "TRB"). It is also possible to make it.). It is also conceivable to attach a reinforcing plate to a part of the front pillar.
[0008]
　TWB is a material in which a plurality of metal plates having different materials or plate thicknesses are combined by welding. Parts molded from TWB have partial plate thickness differences, strength differences, or both.
[0009]
　TRB is a metal plate formed by special roll rolling, and is a material whose plate thickness changes continuously. Parts molded from TRB have partial plate thickness differences, strength differences, or both.
Prior art literature
Patent documents
[0010]
Patent Document 1: Japanese Patent Application Laid-Open No. 2014-11809
Patent Document 2: Japanese Patent Application Laid-
Open No. 5-310147 Patent Document 3: Japanese Patent Application Laid-Open No. 2016-2781
Outline of the invention
Problems to be solved by the invention
[0011]
　However, it cannot be said that the above-mentioned conventional technique can sufficiently improve the strength contributing to the collision characteristics and the rigidity contributing to the running stability in the front pillar outer.
[0012]
　An object of the present invention is to provide a front pillar outer with high strength and high rigidity.
Means to solve problems
[0013]
　The front pillar outer according to the embodiment of the present invention includes a glass surface side flange portion, a door side flange portion, and a main body portion connecting the glass surface side flange portion and the door side flange portion. The front pillar outer includes a first member and a second member. The plate thickness of the second member is the same as or larger than the plate thickness of the first member.
[0014]
　The first member extends longitudinally from the front end to the rear end of the front pillar outer. The first member includes a first glass surface side flange portion, a first door side flange portion, and a first main body portion connecting the first glass surface side flange portion and the first door side flange portion. The first glass surface side flange portion constitutes a part of the glass surface side flange portion. The first door-side flange portion constitutes a part of the door-side flange portion. The first main body portion constitutes a part of the main body part.
[0015]
　The second member extends longitudinally from the rear end to the front end of the front pillar outer. The second member includes a second glass surface side flange portion, a second door side flange portion, and a second main body portion connecting the second glass surface side flange portion and the second door side flange portion. The second glass surface side flange portion constitutes a part of the glass surface side flange portion. The second door-side flange portion constitutes a part of the door-side flange portion. The second main body forms a part of the main body.
[0016]
　The rear end of the first door side flange portion is located behind the rear end of the first glass surface side flange portion and the rear end of the first main body portion. The front end of the second glass surface side flange portion is located in front of the front end of the second door side flange portion and the front end of the second main body portion. The first door side flange portion and the second door side flange portion overlap each other in a region from the rear end of the first door side flange portion to the front end of the second door side flange portion. The first glass surface side flange portion and the second glass surface side flange portion overlap each other in a region from the rear end of the first glass surface side flange portion to the front end of the second glass surface side flange portion. The first main body and the second main body overlap each other in a region from the rear end of the first main body to the front end of the second main body.
[0017]
　The overlapping region between the first door side flange portion and the second door side flange portion, the overlapping region between the first glass surface side flange portion and the second glass surface side flange portion, and the first main body portion and the second main body portion. In the overlapping region, the first member and the second member are joined to each other.
The invention's effect
[0018]
　The front pillar outer according to the embodiment of the present invention has high strength and high rigidity.
A brief description of the drawing
[0019]
FIG. 1 is a perspective view showing an example of a front pillar outer according to the present embodiment.
FIG. 2 is a cross-sectional view of the front pillar in lines II-II of FIG.
FIG. 3 is a cross-sectional view of the front pillar in lines III-III of FIG.
FIG. 4 is an exploded perspective view of the front pillar outer shown in FIG. 1.
FIG. 5 is a perspective view showing a front pillar outer when a collision load is applied.
FIG. 6 is a schematic view showing a part of a vehicle body structure including a front pillar outer.
FIG. 7 is a perspective view showing a front pillar outer when the vehicle is running.
FIG. 8 is a perspective view showing another example of the front pillar outer according to the present embodiment.
FIG. 9 is a schematic diagram showing analysis conditions of Examples.
FIG. 10 is a schematic diagram showing analysis conditions of Examples.
Embodiment for carrying out the invention
[0020]
　Hereinafter, embodiments of the present invention will be described. In the following description, embodiments of the present invention will be described with reference to examples, but the present invention is not limited to the examples described below. In the following description, specific numerical values ​​and specific materials may be exemplified, but the present invention is not limited to these examples.
[0021]
　The front pillar outer according to the present embodiment includes a glass surface side flange portion, a door side flange portion, and a main body portion connecting the glass surface side flange portion and the door side flange portion. The front pillar outer includes a first member and a second member. The plate thickness of the second member is the same as or larger than the plate thickness of the first member.
[0022]
　The first member extends longitudinally from the front end to the rear end of the front pillar outer. The first member includes a first glass surface side flange portion, a first door side flange portion, and a first main body portion connecting the first glass surface side flange portion and the first door side flange portion. The first glass surface side flange portion constitutes a part of the glass surface side flange portion. The first door-side flange portion constitutes a part of the door-side flange portion. The first main body portion constitutes a part of the main body part.
[0023]
　The second member extends longitudinally from the rear end to the front end of the front pillar outer. The second member includes a second glass surface side flange portion, a second door side flange portion, and a second main body portion connecting the second glass surface side flange portion and the second door side flange portion. The second glass surface side flange portion constitutes a part of the glass surface side flange portion. The second door-side flange portion constitutes a part of the door-side flange portion. The second main body forms a part of the main body.
[0024]
　The rear end of the first door side flange portion is located behind the rear end of the first glass surface side flange portion and the rear end of the first main body portion. The front end of the second glass surface side flange portion is located in front of the front end of the second door side flange portion and the front end of the second main body portion. The first door side flange portion and the second door side flange portion overlap each other in a region from the rear end of the first door side flange portion to the front end of the second door side flange portion. The first glass surface side flange portion and the second glass surface side flange portion overlap each other in a region from the rear end of the first glass surface side flange portion to the front end of the second glass surface side flange portion. The first main body and the second main body overlap each other in a region from the rear end of the first main body to the front end of the second main body.
[0025]
　The overlapping region between the first door side flange portion and the second door side flange portion, the overlapping region between the first glass surface side flange portion and the second glass surface side flange portion, and the first main body portion and the second main body portion. In the overlapping region, the first member and the second member are joined to each other.
[0026]
　As described above, in the front pillar outer portion of the present embodiment, the flange portion on the first door side and the flange portion on the second door side are joined in the overlapping region of each other. Further, the flange portion on the first glass surface side and the flange portion on the second glass surface side are joined in an overlapping region with each other. As a result, the first member and the second member that overlap each other are integrated to form the front pillar outer. That is, the front pillar outer of the present embodiment is composed of the first member and the second member.
[0027]
　When a collision load is applied to the front pillar outer of the present embodiment, the front pillar outer is curved. As a result, compressive strain is applied to a part of the region of the flange portion on the door side in the longitudinal direction. In the present specification, the region to which this compression strain is applied is also referred to as a “door-side compression portion”. On the other hand, tensile strain is applied to a part of the flange portion on the glass surface side in the longitudinal direction. In the present specification, the region to which this tensile strain is applied is also referred to as a “glass surface side tensile portion”. Further, compressive strain is applied to a part of the other region in the longitudinal direction of the flange portion on the glass surface side. In the present specification, the region to which this compression strain is applied is also referred to as a “glass surface side compression portion”. The door side compression part and the glass surface side compression part are also collectively referred to as "compression strain part". The tensile parts on the glass surface side are also collectively referred to as "tensile strain parts". At the time of collision, the compression strain site tends to buckle.
[0028]
　In the front pillar outer of the present embodiment, the first door side flange portion and the second door side flange portion overlap each other at the door side compression portion. In this overlapping region, the flange portion on the first door side and the flange portion on the second door side are joined to each other. Further, in the compression portion on the glass surface side, the flange portion on the first glass surface side and the flange portion on the second glass surface side overlap each other. In this overlapping region, the flange portion on the first glass surface side and the flange portion on the second glass surface side are joined to each other. In short, the materials are doubly stacked in both the door side compression portion and the glass surface side compression portion.
[0029]
　Here, the collision characteristic of the compression strain portion is proportional to the product of the strength of the material and the plate thickness of the material to the third power. Therefore, increasing the plate thickness of the material at the compression strain site greatly contributes to the improvement of the collision characteristics. This collision characteristic is called buckling resistance. In the front pillar outer of the present embodiment, the materials are doubly stacked at the compression strain portion (door side compression portion and glass surface side compression portion), and the plate thickness is substantially increased. Therefore, the buckling resistance of the compression strain portion is greatly improved. This makes it possible to increase the strength of the front pillar outer.
[0030]
　In the front pillar outer of the present embodiment, the glass surface side tension portion does not overlap the materials and is composed of only the second member of a single material. Here, the collision characteristic of the tensile strain portion is proportional to the product of the strength of the material and the plate thickness of the material. Therefore, increasing the plate thickness of the material at the tensile strain portion does not contribute to the improvement of the collision characteristics as much as increasing the plate thickness of the material at the compression strain portion. In order to improve the collision characteristics of the tensile strain site, the strength of the material may be increased. If the strength of the material is increased, the collision characteristics of the compression strain site are further improved. In the front pillar outer of the present embodiment, the plate thickness of the tensile strain portion does not increase. Therefore, the increase in weight is suppressed, and the weight of the front pillar outer can be reduced by increasing the strength of the material.
[0031]
　However, compressive stress and tensile stress repeatedly act on the glass surface side tensile portion of the front pillar outer when the vehicle is running. If the rigidity of the tension portion on the glass surface side is low, the running stability is impaired. Therefore, it is necessary to increase the rigidity of the tension portion on the glass surface side.
[0032]
　In the case of the front pillar outer of the present embodiment, the glass surface side tension portion is composed of only the second member, but the plate thickness of the second member is not smaller than the plate thickness of the first member. That is, the plate thickness of the second member is the same as or larger than the plate thickness of the first member. Therefore, the rigidity of the tension portion on the glass surface side is improved. This enhances running stability.
[0033]
　When the vehicle is running, the same repeated stress as that of the glass surface side tension portion acts on the door side compression portion. In the front pillar outer of the present embodiment, as described above, the materials are doubly stacked at the compression portion on the glass surface side, and the plate thickness is substantially increased. Therefore, not only the buckling resistance but also the rigidity is greatly improved at the compression portion on the glass surface side. This further enhances running stability.
[0034]
　The order in which the first member and the second member overlap is not particularly limited. Specifically, the first member may be superposed on the second member, or the first member may be superposed under the second member.
[0035]
　In the front pillar outer of the present embodiment, when the length of the flange portion on the glass surface side is L, the overlapping region between the flange portion on the first door side and the flange portion on the second door side is the glass surface on the flange portion on the door side. It is preferably provided in a part or the entire range between the position corresponding to the rear end of the side flange portion and the position corresponding to the rear end of the glass surface side flange portion to the position of L × 2/3.
[0036]
　In many cases, when a collision load is applied to the front pillar outer, a large compressive strain is likely to occur on the door-side flange portion of the curved region near the rear end of the front pillar outer. That is, the door-side compression portion is likely to be arranged near the rear end of the front pillar outer. Therefore, if the flange portion on the first door side and the flange portion on the second door side overlap each other in a part or all of such a range, the buckling of the front pillar outer can be further suppressed.
[0037]
　In the front pillar outer of the present embodiment, when the length of the glass surface side flange portion is L, the overlapping region between the first glass surface side flange portion and the second glass surface side flange portion is the glass surface side flange portion. It is preferably provided in a part or the entire range between the position of L × 1/8 from the front end and the position of L × 2/3 from the front end of the glass surface side flange portion.
[0038]
　When a collision load is applied to the front pillar outer, a large compressive strain is likely to occur on the glass surface side flange portion in the region near the front end of the front pillar outer. That is, the compression portion on the glass surface side is likely to be arranged near the front end of the front pillar outer. Therefore, if the first glass surface side flange portion and the second glass surface side flange portion overlap each other in a part or all of such a range, the buckling of the front pillar outer can be further suppressed. ..
[0039]
　In the above front pillar outer, the plate thicknesses of the first member and the second member are not particularly limited as long as the plate thickness of the second member is not smaller than the plate thickness of the first member. Practically, the plate thickness is preferably 0.60 mm or more and 1.60 mm or less. The lower limit of the plate thickness is more preferably 0.85 mm. The upper limit of the plate thickness is more preferably 1.05 mm. The plate thickness of the second member may be the same as the plate thickness of the first member, or may be larger than the plate thickness of the first member.
[0040]
　Further, the tensile strength (strength of the material) of the first member and the second member is preferably 800 MPa or more. The lower limit of the tensile strength is more preferably 1200 MPa. The tensile strength of the first member may be the same as the tensile strength of the second member, or may be different from the tensile strength of the second member. From the viewpoint of running stability, that is, from the viewpoint of increasing the rigidity of the tension portion on the glass surface side, the tensile strength of the second member is preferably higher than the tensile strength of the first member.
[0041]
　The method of joining the overlapping region between the flange portion on the first door side and the flange portion on the second door side is not particularly limited. Similarly, the method of joining the overlapping region between the first glass surface side flange portion and the second glass surface side flange portion is not particularly limited. The joining method thereof is, for example, welding. The welding method is laser welding, spot welding, or the like. The joining method may be mechanical fastening, bonding with an adhesive, or the like. These joining methods can also be used together.
[0042]
　In this case, the front pillar outer is suitable for the front pillar outer for automobiles.
[0043]
　In the present specification, each direction of the front pillar outer means a direction in which the front pillar outer is mounted on an automobile. For example, each direction of "front", "rear", "left", "right", "upper", and "lower" coincides with each direction of the automobile. The symbols "F", "Re", "Le", "R", "U" and "D" in the drawings mean the front, rear, left, right, top and bottom of the vehicle, respectively. Further, in the present specification, unless otherwise specified, the "longitudinal direction" means a direction along the front end to the rear end of the front pillar outer. "Cross section" means a cross section perpendicular to the longitudinal direction of the front pillar outer.
[0044]
　Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The same or corresponding parts in the drawings are designated by the same reference numerals and the description thereof will not be repeated.
[0045]
　[Overview of Front Pillar Outer 1]
　FIG. 1 is a perspective view showing an example of the front pillar outer 1 of the present embodiment. FIG. 2 is a cross-sectional view of the front pillar 101 in line II-II of FIG. FIG. 2 shows a cross section in the vicinity of the rear end 1re of the front pillar outer 1. The cross section shown in FIG. 2 includes a door-side compression portion A1. FIG. 3 is a cross-sectional view of the front pillar 101 in line III-III of FIG. FIG. 3 shows a cross section in the vicinity of the front end 1fe of the front pillar outer 1. The cross section shown in FIG. 3 includes a glass surface side compression portion A2 and a door side compression portion A1. FIG. 4 is an exploded perspective view of the front pillar outer 1 shown in FIG. 1 to 4 show a front pillar outer 1 arranged on the left side of two front pillar outers mounted on an automobile. In FIG. 4, the contour of the front pillar outer 1 is shown by an imaginary line (dashed-dotted line) in each of the first member 11 and the second member 21.
[0046]
　First, with reference to FIGS. 2 and 3, the front pillar 101 supports the windshield 102. Strictly speaking, the front pillar 101 here is a front pillar upper that constitutes the skeleton of the vehicle body. One of the members constituting the front pillar upper is the front pillar outer 1.
[0047]
　The front pillar 101 includes a side panel 104, a front pillar inner 105, and a front pillar outer 1. The side panel 104 is arranged outside the front pillar inner 105 and the front pillar outer 1. A closed cross section is formed by the side panel 104 and the front pillar inner 105. The front pillar outer 1 is arranged inside the closed cross section. The front pillar outer 1 plays a role of reinforcing the front pillar 101.
[0048]
　With reference to FIGS. 1 to 4, the front pillar outer 1 includes a glass surface side flange portion 2, a door side flange portion 3, and a main body portion 4. The main body portion 4 is arranged between the glass surface side flange portion 2 and the door side flange portion 3 in the width direction of the front pillar outer 1. The main body 4 connects the glass surface side flange portion 2 and the door side flange portion 3.
[0049]
　Here, the front pillar outer 1 is composed of a first member 11 and a second member 21, which will be described in detail later. In the front pillar outer 1, the glass surface side flange portion 2 is partially overlapped with each other from the first glass surface side flange portion 12 of the first member 11 and the second glass surface side flange portion 22 of the second member 21. It is composed. The door-side flange portion 3 is composed of a first door-side flange portion 13 of the first member 11 and a second door-side flange portion 23 of the second member 21, which are partially overlapped with each other. The main body 4 is composed of a first main body 14 of the first member 11 and a second main body 24 of the second member 21, which are partially overlapped with each other.
[0050]
　In short, in the front pillar outer 1 of the present embodiment, the glass surface side flange portion 2 is a portion composed of the first glass surface side flange portion 12 and the second glass surface side flange portion 22. The door-side flange portion 3 is a portion composed of a first door-side flange portion 13 and a second door-side flange portion 23. The main body portion 4 is a portion composed of a first main body portion 14 and a second main body portion 24.
[0051]
　The glass surface side flange portion 2 of the front pillar outer 1 is joined to the side panel 104 and the front pillar inner 105 by welding or the like. The glass surface side flange portion 2 includes a region that directly or indirectly supports the side edge of the windshield 102. The glass surface side flange portion 2 supports the side edge of the windshield 102 together with the side panel 104 and the front pillar inner 105.
[0052]
　The door side flange portion 3 is joined to the side panel 104 and the front pillar inner 105 by welding or the like. The door-side flange portion 3 includes a region directly or indirectly facing the upper edge of the door 103. The door-side flange portion 3 faces the upper edge of the door 103 together with the side panel 104 and the front pillar inner 105. The cross-sectional shape of the front pillar outer 1 is a hat shape.
[0053]
　With reference to FIGS. 1 to 4, the door-side flange portion 3 includes a door-side compression portion A1. The door-side compression portion A1 is a partial region in the longitudinal direction of the door-side flange portion 3. A compression strain is applied to the door-side compression portion A1 when a collision load is applied to the front pillar outer 1. Further, compressive stress and tensile stress repeatedly act on the door-side compression portion A1 when the vehicle is running.
[0054]
　The glass surface side flange portion 2 includes the glass surface side compression portion A2. The glass surface side compression portion A2 is a partial region in the longitudinal direction of the glass surface side flange portion 2. A compression strain is applied to the compression portion A2 on the glass surface side when a collision load is applied to the front pillar outer 1.
[0055]
　Further, the glass surface side flange portion 2 includes a glass surface side tension portion B. The glass surface side tension portion B is a part of the glass surface side flange portion 2 in the longitudinal direction. A tensile strain is applied to the glass surface side tensile portion B when a collision load is applied to the front pillar outer 1. Further, compressive stress and tensile stress repeatedly act on the tension portion B on the glass surface side when the vehicle is running.
[0056]
　The door-side compression portion A1 is arranged near the rear end 1re of the front pillar outer 1. The glass surface side compression portion A2 is arranged near the front end 1fe of the front pillar outer 1. The glass surface side tension portion B is located behind the glass surface side compression portion A2. The glass surface side tension portion B is adjacent to the glass surface side compression portion A2 and exists up to the rear end 2re of the glass surface side flange portion 2.
[0057]
　Here, the first member 11 and the second member 21 constituting the front pillar outer 1 will be described.
[0058]
　[First member 11]
　The first member 11 extends in the longitudinal direction from the front end 1fe of the front pillar outer 1 toward the rear end 1re. The first member 11 includes a first glass surface side flange portion 12, a first door side flange portion 13, and a first main body portion 14. The first glass surface side flange portion 12 constitutes a part of the glass surface side flange portion 2. The first door-side flange portion 13 constitutes a part of the door-side flange portion 3. The first main body portion 14 constitutes a part of the main body portion 4, and connects the first glass surface side flange portion 12 and the first door side flange portion 13.
[0059]
　The first door side flange portion 13 extends in the longitudinal direction from a position corresponding to the front end 1fe of the front pillar outer 1. In the example shown in FIGS. 1 and 4, the first door side flange portion 13 is provided in the entire area between the position corresponding to the front end 1fe of the front pillar outer 1 and the position corresponding to the rear end 1re. .. In this case, in the longitudinal direction of the front pillar outer 1, the region of the first door side flange portion 13 coincides with the region of the door side flange portion 3. In the longitudinal direction of the front pillar outer 1, the first door side flange portion 13 includes the door side compression portion A1.
[0060]
　The first glass surface side flange portion 12 extends in the longitudinal direction from a position corresponding to the front end 1fe of the front pillar outer 1. However, the flange portion 12 on the first glass surface side does not extend to the position corresponding to the rear end 1re of the front pillar outer 1. In other words, the first glass surface side flange portion 12 is provided in a region between a position corresponding to the front end 1fe of the front pillar outer 1 and a position at a predetermined distance from the position corresponding to the front end 1fe. In the longitudinal direction of the front pillar outer 1, the first glass surface side flange portion 12 includes the glass surface side compression portion A2. However, the first glass surface side flange portion 12 does not include the glass surface side tension portion B. In this case, the first glass surface side flange portion 12 does not exist in the portion near the rear end 2re of the glass surface side flange portion 2.
[0061]
　The first main body portion 14 is arranged between the first glass surface side flange portion 12 and the first door side flange portion 13 in the width direction of the front pillar outer 1. The first main body portion 14 extends in the longitudinal direction from a position corresponding to the front end 1fe of the front pillar outer 1. However, similarly to the first glass surface side flange portion 12, the first main body portion 14 does not extend to the position corresponding to the rear end 1re of the front pillar outer 1. In other words, the first main body portion 14 is provided in a region between a position corresponding to the front end 1fe of the front pillar outer 1 and a position at a predetermined distance from the position corresponding to the front end 1fe. In the longitudinal direction of the front pillar outer 1, the region of the first main body portion 14 coincides with the region of the flange portion 12 on the first glass surface side. In this case, the first main body portion 14 does not exist in the portion near the rear end 4re of the main body portion 4.
[0062]
　From the above, in the first member 11, the rear end 13re of the first door side flange portion 13 is located behind the rear end 12re of the first glass surface side flange portion 12 and the rear end 14re of the first main body portion 14. ..
[0063]
　[Second member 21]
　The second member 21 extends in the longitudinal direction from the rear end 1re of the front pillar outer 1 toward the front end 1fe. The second member 21 includes a second glass surface side flange portion 22, a second door side flange portion 23, and a second main body portion 24. The second glass surface side flange portion 22 constitutes a part of the glass surface side flange portion 2. The second door-side flange portion 23 constitutes a part of the door-side flange portion 3. The second main body portion 24 constitutes a part of the main body portion 4, and connects the second glass surface side flange portion 22 and the second door side flange portion 23.
[0064]
　The second glass surface side flange portion 22 extends in the longitudinal direction from a position corresponding to the rear end 1re of the front pillar outer 1. However, the second glass surface side flange portion 22 does not extend to a position corresponding to the front end 1fe of the front pillar outer 1. In other words, the second glass surface side flange portion 22 is provided in the region between the position corresponding to the rear end 1re of the front pillar outer 1 and the position at a predetermined distance from the position corresponding to the rear end 1re. There is. In the longitudinal direction of the front pillar outer 1, the second glass surface side flange portion 22 is provided at the glass surface side tension portion B and the glass surface side compression portion A2. In this case, the second glass surface side flange portion 22 does not exist in the portion of the glass surface side flange portion 2 near the front end 2fe.
[0065]
　The second door side flange portion 23 extends in the longitudinal direction from a position corresponding to the rear end 1re of the front pillar outer 1. However, the second glass surface side flange portion 22 does not extend to a position corresponding to the front end 1fe of the front pillar outer 1. In other words, the second door side flange portion 23 is provided in the area between the position corresponding to the rear end 1re of the front pillar outer 1 and the position at a predetermined distance from the position corresponding to the rear end 1re. .. In the longitudinal direction of the front pillar outer 1, the second door-side flange portion 23 is provided at the door-side compression portion A1. In this case, the second door-side flange portion 23 does not exist in the portion of the door-side flange portion 3 near the front end 3fe.
[0066]
　The second main body portion 24 is arranged between the second glass surface side flange portion 22 and the second door side flange portion 23 in the width direction of the front pillar outer 1. The second main body portion 24 extends in the longitudinal direction from a position corresponding to the rear end 1re of the front pillar outer 1. However, similarly to the second door side flange portion 23, the second main body portion 24 does not extend to a position corresponding to the front end 1fe of the front pillar outer 1. In other words, the second main body portion 24 is provided in the region between the position corresponding to the rear end 1re of the front pillar outer 1 and the position at a predetermined distance from the position corresponding to the rear end 1re. In the longitudinal direction of the front pillar outer 1, the region of the second main body portion 24 coincides with the region of the second door side flange portion 23. In this case, the second main body portion 24 does not exist in the portion of the main body portion 4 near the front end 4fe.
[0067]
　From the above, in the second member 21, the front end 22fe of the second glass surface side flange portion 22 is located in front of the front end 23fe of the second door side flange portion 23 and the front end 24fe of the second main body portion 24.
[0068]
　[Front pillar outer 1 composed of the first member 11 and the second member 21]
　The first door side flange portion 13 and the second door side flange portion 23 are mutually connected to each other at the rear end 13re of the first door side flange portion 13. It overlaps in the region from the second door side flange portion 23 to the front end 23fe. That is, the first door side flange portion 13 and the second door side flange portion 23 overlap each other in the region of the door side compression portion A1. In this overlapping region, the first door side flange portion 13 and the second door side flange portion 23 are joined to each other by welding.
[0069]
　Further, the first glass surface side flange portion 12 and the second glass surface side flange portion 22 are mutually from the rear end 12re of the first glass surface side flange portion 12 to the front end 22fe of the second glass surface side flange portion 22. Overlapping in areas. That is, the first glass surface side flange portion 12 and the second glass surface side flange portion 22 overlap each other in the region of the glass surface side compression portion A2. In this overlapping region, the first glass surface side flange portion 12 and the second glass surface side flange portion 22 are joined to each other by welding.
[0070]
　Further, the first main body portion 14 and the second main body portion 24 overlap each other in a region from the rear end 14re of the first main body portion 14 to the front end 24fe of the second main body portion 24. In this overlapping region, the first main body portion 14 and the second main body portion 24 are joined to each other by welding.
[0071]
　As described above, in the front pillar outer 1 of the present embodiment, the first member 11 and the second member 21 are integrated by joining the first member 11 and the second member 21 in the mutual overlapping region. As a result, the front pillar outer 1 is established.
[0072]
　In the entire area of ​​the door side compression portion A1, the materials are doubly stacked by the first door side flange portion 13 and the second door side flange portion 23 joined to each other. As a result, the plate thickness of the entire area of ​​the door-side compression portion A1 is substantially increased. Therefore, the buckling resistance of the compression portion A1 on the door side is greatly improved. Thereby, the strength of the front pillar outer 1 can be increased.
[0073]
　In the example shown in FIGS. 1 to 4, the first member 11 is superposed under the second member 21. The overlapping region O1 between the first door side flange portion 13 and the second door side flange portion 23 coincides with the range of the door side compression portion A1. In the present specification, this overlapping region O1 is also referred to as a “door-side overlapping region”. The range of the door side compression portion A1 is the position corresponding to the rear end 2re of the glass surface side flange portion 2 in the door side flange portion 3 and the glass surface side when the length of the glass surface side flange portion 2 is L. It is a range between the position corresponding to the rear end 2re of the flange portion 2 and the position of L × 2/3. Therefore, the door-side overlapping region O1 is provided over the entire range of the door-side compression portion A1. However, the door-side overlapping region O1 may be provided in a part of the range of the door-side compression portion A1. For example, the compression strain may be small in the region near the rear end 3re of the door side flange portion 3. In this case, the first member 11 may not be present in the region near the rear end 3re of the door-side flange portion 3.
[0074]
　In the glass surface side compression portion A2, the materials are doubly stacked by the first glass surface side flange portion 12 and the second glass surface side flange portion 22 joined to each other. As a result, the plate thickness of the entire area of ​​the compression portion A2 on the glass surface side is substantially increased. Therefore, the buckling resistance of the compression portion A2 on the glass surface side is greatly improved. Thereby, the strength of the front pillar outer 1 can be increased.
[0075]
　In the example shown in FIGS. 1 to 4, the first member 11 is superposed under the second member 21. The overlapping region O2 between the first glass surface side flange portion 12 and the second glass surface side flange portion 22 coincides with the range of the glass surface side compression portion A2. In the present specification, this overlapping region O2 is also referred to as a “glass surface side overlapping region”. The range of the glass surface side compression portion A2 is the position of L × 1/8 from the front end 2fe of the glass surface side flange portion 2 and the glass surface side flange portion 2 when the length of the glass surface side flange portion 2 is L. It is a range between the front end 2fe and the position of L × 2/3. Therefore, the glass surface side overlapping region O2 is provided in the entire range of the glass surface side compression portion A2. However, the glass surface side overlapping region O2 may be provided in a part of the range of the glass surface side compression portion A2.
[0076]
　The first member 11 does not exist in the tension portion B on the glass surface side. That is, the glass surface side tension portion B is composed of only the second member 21. As a result, the increase in weight can be suppressed, and the weight of the front pillar outer 1 can be reduced by increasing the strength of the material. Further, the plate thickness of the second member 21 is the same as or larger than the plate thickness of the first member 11. Therefore, the rigidity of the tension portion B on the glass surface side is improved. This enhances running stability.
[0077]
　[Relationship between the deformation behavior of the front pillar outer 1 at the time of collision and the compression strain portion and the tensile strain portion]
　As described above, in the door side overlapping region O1 corresponding to the door side compression portion A1, the materials are doubly stacked. .. In the glass surface side overlapping region O2 corresponding to the glass surface side compression portion A2, the materials are doubly stacked. On the other hand, the glass surface side tension portion B is made of a single material. Therefore, the plate thickness of the compression strain portion (door side compression portion A1 and the glass surface side compression portion A2) is substantially thicker than that of the tensile strain portion (glass surface side tension portion B) and other regions. Therefore, the collision characteristics of the compressive strain site are higher than those of the tensile strain site and other regions.
[0078]
　FIG. 5 is a perspective view showing the front pillar outer 1 when a collision load is applied. With reference to FIG. 5, in a state where the front pillar outer 1 is mounted on an automobile, the front end 1fe of the front pillar outer 1 is arranged at a position lower than the rear end 1re. When a vehicle collides head-on, the collision load P is applied to the front end 1fe of the front pillar outer 1. The front pillar outer 1 has a shape that is convexly curved upward from the front end 1fe to the rear end 1re. When a collision load P is applied to the front pillar outer 1, stress is concentrated on the curved portion of the front pillar outer 1, and the curved portion tends to bend upward. Therefore, compressive stress acts on the door-side flange portion 3 to apply compressive strain. On the other hand, tensile stress acts on the flange portion 2 on the glass surface side, and tensile strain is applied. Compressive strain is applied to the glass surface side flange portion 2 by the compressive stress acting on the door side flange portion 3 and the tensile stress acting on the glass surface side flange portion 2.
[0079]
　When the compressive strain becomes excessively large, the front pillar outer 1 buckles and bends upward. When the front pillar outer 1 buckles, the collision energy absorption capacity of the front pillar outer 1 is significantly reduced. Therefore, in order to improve the collision characteristics of the front pillar outer 1, it is necessary to suppress the buckling of the front pillar outer 1.
[0080] [0080]
　In order to suppress the buckling of the front pillar outer 1, it is effective to enhance the collision characteristic of the region where the compression strain is applied, that is, the door side compression portion A1 in the door side flange portion 3. In the glass surface side flange portion 2, enhancing the collision characteristic of the region where the compression strain is applied, that is, the glass surface side compression portion A2 also contributes to the suppression of buckling of the front pillar outer 1.
[0081]
　In the case of the front pillar outer 1, the curvature of the door side flange portion 3 is large in the region S shown in FIGS. 1, 2 and 5. Compressive strain is applied to this region S. This region becomes the door side compression portion A1. Further, compressive strain is also applied to a part of the flange portion 2 on the glass surface side. This region becomes the compression portion A2 on the glass surface side.
[0082]
　In the glass surface side flange portion 2, tensile strain is applied to the region behind the glass surface side compression portion A2. This region becomes the glass surface side tension portion B.
[0083]
　Here, the collision characteristic (buckling resistance) of the front pillar outer 1 largely depends on the plate thickness of the material at the compression strain site. The plate thickness of the material at the tensile strain portion does not affect the collision characteristics of the front pillar outer 1 as much as the plate thickness of the material at the compression strain portion. Therefore, the plate thickness of the material at the glass surface side tension portion B may be thinner than the substantial plate thickness of the material at the door side compression portion A1 and the glass surface side compression portion A2.
[0084]
　FIG. 6 is a schematic view showing a part of the vehicle body structure including the front pillar outer 1. In FIG. 6, the side panel of the front pillar is not shown. With reference to FIG. 6, the rear end of the front pillar is joined to the roof 106 of the vehicle. The roof 106 is provided approximately horizontally with respect to the ground. On the other hand, the windshield 102 of the vehicle is arranged obliquely with respect to the ground. Therefore, the front pillar curves near its rear end. Along with this, the front pillar outer 1 also curves in the vicinity of its own rear end 1re.
[0085]
　When a collision load is applied to the front pillar outer 1, a large compression strain is likely to occur on the door-side flange portion 3 of the curved region S near the rear end 1re of the front pillar outer 1. The shape of the front pillar outer 1 differs depending on the vehicle model. Therefore, the portion where a large compressive strain is generated differs depending on the vehicle model. However, in many cases, the region to which the compressive strain is applied is defined within a certain range. Specifically, as shown in FIG. 6, in the door side flange portion 3, the position R1 corresponding to the rear end 2re of the glass surface side flange portion 2 and the position corresponding to the rear end 2re of the glass surface side flange portion 2 Compressive strain is applied in the range between R1 and the position of L × 2/3. In short, this range is the range of the door-side compression portion A1. Here, L means an arc length (length in the longitudinal direction) along the door side edge of the glass surface side flange portion 2 of the front pillar outer 1. The position R1 corresponds to the rear end 3re of the door side flange portion 3.
[0086]
　Therefore, as shown in FIG. 1, the door side overlapping region O1 has a position R1 corresponding to the rear end 2re of the glass surface side flange portion 2 and the rear end 2re of the glass surface side flange portion 2 in the door side flange portion 3. It is provided in at least a part of the range between the position R1 corresponding to the position R1 and the position L × 2/3. That is, the door-side overlapping region O1 is provided in a part or the entire range of the door-side compression portion A1. FIG. 1 shows an example in which the door-side overlapping region O1 is provided over the entire range of the door-side compression portion A1.
[0087]
　[Deformation Behavior of Front Pillar Outer 1 During Vehicle Travel]
　FIG. 7 is a perspective view showing the front pillar outer 1 during vehicle travel. When the automobile is traveling, a load Pv in the vertical direction is repeatedly applied to the front pillar outer 1 from the front wheels through the suspension and the like. This repeated load Pv is applied to the front end 1fe of the front pillar outer 1. As a result, the front pillar outer 1 bends in the vertical direction with its rear end 1re as a fulcrum. Therefore, in the front pillar outer 1, the compressive stress and the tensile stress repeatedly act on the glass surface side tensile portion B.
[0088]
　If the tension portion B on the glass surface side on which repeated stress acts is low, the front pillar outer 1 greatly bends in the vertical direction when the vehicle is running. In this case, running stability is impaired. Therefore, it is necessary to increase the rigidity of the tension portion B on the glass surface side. In order to increase the rigidity of the glass surface side tension portion B, it is effective to increase the plate thickness of the material constituting the glass surface side tension portion B, that is, the second member 21.
[0089]
　FIG. 8 is a perspective view showing another example of the front pillar outer 1 of the present embodiment. In the front pillar outer 1 shown in FIG. 8, the compression strain applied at the time of collision is small in the region near the rear end 3re of the door side flange portion 3. In this case, the first member 11 (first door-side flange portion 13) does not exist in the region near the rear end 3re of the door-side flange portion 3. Along with this, the first door-side flange portion 13 does not exist in the portion near the rear end 3re of the door-side flange portion 3. That is, FIG. 8 shows an example in which the door-side overlapping region O1 is provided in a part of the door-side compression portion A1. In this case, the rear end 13re of the first door side flange portion 13 is located in front of the rear end 1re of the front pillar outer 1.
[0090]
　With reference to FIG. 1, when a collision load is applied to the front pillar outer 1, a large compressive strain is likely to occur on the glass surface side flange portion 2 in the vicinity of the front end 1fe of the front pillar outer 1. This compressive strain is caused by the compressive stress acting on the door side flange portion 3 and the tensile stress acting on the glass surface side flange portion 2. In many cases, the region to which this compressive strain is applied is defined within a certain range. Specifically, as shown in FIG. 1, in the glass surface side flange portion 2, the position of L × 1/8 from the front end 2fe of the glass surface side flange portion 2 and the front end 2fe to L of the glass surface side flange portion 2 Compressive strain is applied in the range between the position of × 2/3. In short, this range is the glass surface side compression portion A2. Here, L means an arc length (length in the longitudinal direction) along the door side edge of the glass surface side flange portion 2 of the front pillar outer 1.

The scope of the claims
[Claim 1]
　A front pillar outer including a glass surface side flange portion, a door side flange portion, a main body portion connecting the glass surface side flange portion and the door side flange portion,
　from the front end to the rear end of the front pillar outer. A first member extending in the longitudinal direction toward the surface, a first glass surface side flange portion forming a part of the glass surface side flange portion, and a first door side flange forming a part of the door side flange portion. A first member including a first main body portion that connects the portion, the first glass surface side flange portion, and the first door side flange portion to form a part of the main body portion, and
　after the front pillar outer. A second member extending in the longitudinal direction from one end to the front end, the second glass surface side flange portion forming a part of the glass surface side flange portion, and the second member constituting the door side flange portion. A second member including a second main body portion that connects the second door side flange portion, the second glass surface side flange portion, and the second door side flange portion to form a part of the main body portion is provided. The plate thickness of
　the second member is the same as or larger than the plate thickness of the first member, and
　the rear end of the first door side flange portion is the rear end of the first glass surface side flange portion and the first. 1
　The front end of the second glass surface side flange portion is located behind the rear end of the main body portion, and the front end of the second door side flange portion is located in front of the front end of the second door side flange portion and
　the front end of the second main body portion. The first door side flange portion and the second door side flange portion overlap each other in a region from the rear end of the first door side flange portion to the front end of the second door side flange portion.
　The first glass surface side flange portion and the second glass surface side flange portion overlap each other in a region from the rear end of the first glass surface side flange portion to the front end of the second glass surface side flange portion.
　The first main body and the second main body overlap each other in a region from the rear end of the first main body to the front end of the second main body, and
　the first door side flange portion and the second door are overlapped with each other. In the overlapping region with the side flange portion, the overlapping region between the first glass surface side flange portion and the second glass surface side flange portion, and the overlapping region between the first main body portion and the second main body portion, the first A front pillar outer in which one member and the second member are joined to each other.
[Claim 2]
　In the front pillar outer according to claim 1,
　when the length of the glass surface side flange portion is L,
　the overlapping region between the first door side flange portion and the second door side flange portion is described above. One of the range between the position corresponding to the rear end of the glass surface side flange portion and the position corresponding to the rear end of the glass surface side flange portion to the position of L × 2/3 in the door side flange portion. Front pillar outer provided in the part.
[Claim 3]
　In the front pillar outer according to claim 1,
　when the length of the glass surface side flange portion is L,
　the overlapping region between the first door side flange portion and the second door side flange portion is described above. In the door side flange portion, the entire range between the position corresponding to the rear end of the glass surface side flange portion and the position corresponding to the rear end of the glass surface side flange portion to the position of L × 2/3. Front pillar outer that is installed in.
[Claim 4]
　The front pillar outer according to any one of claims 1 to 3,
　when the length of the glass surface side flange portion is L,
　the first glass surface side flange portion and the second glass surface side. The overlapping region with the flange portion is one of the range between the position of L × 1/8 from the front end of the glass surface side flange portion and the position of L × 2/3 from the front end of the glass surface side flange portion. Front pillar outer provided in the part.
[Claim 5]
　The front pillar outer according to any one of claims 1 to 3,
　when the length of the glass surface side flange portion is L,
　the first glass surface side flange portion and the second glass surface side. The overlapping region with the flange portion is the entire range between the position of L × 1/8 from the front end of the glass surface side flange portion and the position of L × 2/3 from the front end of the glass surface side flange portion. Front pillar outer that is installed in.