JPWO2017013774A1 - rivet - Google Patents

Abstract

Provided is a rivet that can reduce or eliminate design distortion stamped on the outer surface of the base. The rivet (1) includes a disc-shaped base (10) having an inner surface (10b) and an outer surface (10a), and a post (20) extending from the center of the inner surface (10b) of the base (10). Prepare. A concave design (30) is imprinted on the outer surface (10a) of the base (10). The rivet (1) has an annular projection (16) provided along the circumferential direction on the inner surface (10b) side of the base (10). The total volume of the annular protrusion (16) is at least a part of the design (30) existing radially outward from the annular protrusion (16) on the outer surface (10a) of the base (10). It is set to be larger than the total volume. The base (10) includes a constant thickness region (10B) having a substantially constant thickness outward in the radial direction and an outer region (10C) in which the thickness increases from the constant thickness region (10B) to the radially outer side. The annular convex portion (16) is provided in the constant thickness region (10B).

Description

  The present invention relates to a rivet, and more particularly to a rivet that is a stopper for attaching a button such as a bar to a fabric.

  In jeans, a decorative button made of metal called a bar is generally attached by a rivet serving as a fastener for reinforcing a can against the end of a pocket or the like or for decoration. Such bars and rivets are disclosed in, for example, Japanese Patent Application Laid-Open No. 2005-204911, International Publication WO2013 / 042232, and the like. The rivet is made of an aluminum alloy, a copper alloy, or the like, and includes a disk-shaped base and a post extending from the center of the base. When the bar is attached to a fabric such as jeans, the bar is fixed to the fabric by causing the post of the rivet to penetrate the fabric and then plastically deforming the shape of the post inside the bar (see FIG. 9). With the bar attached to the fabric, the outer surface of the rivet base (the surface opposite the post) is visible to the user on the back side of the fabric. Therefore, a concave design such as a logo made up of characters, figures, symbols, etc. is generally engraved on the outer surface of the rivet base. Such a design engraving on the outer surface of the base of the rivet is performed by a die used when one side of a bar-shaped intermediate material to be a rivet is crushed into a disk shape by cold forging (FIGS. 5 and 6). reference). At this time, since one side of the intermediate material is deformed into a base shape while being plastically flowed, there may be a phenomenon in which the design on the die side or the concavo-convex shape forming a part thereof flows in the metal moving direction and is distorted. FIG. 13 is a photograph showing a distorted state in which a particularly radially outer portion of the design flows radially outward on the outer surface of a conventional rivet base. When the design is distorted in this way, the design becomes unsightly and there is still room for improvement.

JP 2005-204911 A International Publication No. WO2013 / 042232

  The present invention has been made in view of the above problems, and it is an object of the present invention to provide a rivet that can reduce or eliminate the distortion of the design stamped on the outer surface of the base.

  In order to solve the above-described problem, according to the present invention, a disk-shaped base having an inner surface and an outer surface opposite to the inner surface, and a post extending from the center of the inner surface of the base, A rivet in which a concave design is engraved on the outer surface of the base, the inner surface of the base having an annular protrusion provided continuously or discontinuously along the circumferential direction, There is provided a rivet characterized in that the total volume is larger than the total volume of a part of the design existing radially outward from the annular projection on the outer surface of the base.

  The concave design for the outer surface of the rivet base is generally imprinted by a die during forging of the rivet. At this time, it has been found that a portion of the design that is radially outward on the outer surface of the rivet base flows outwardly in the radial direction and is easily distorted. Such distortion in the radially outer portion of the design was particularly noticeable in the portion where the thickness of the rivet increases (see the outer region 10C with respect to the intermediate region 10B in FIG. 4). About this cause, the present inventor found the following points. The base metal material flows radially outward during forging and forms the base (see FIGS. 5 and 6). At this time, the metal material is applied to a particularly thick portion on the radially outer side of the base. A flow pressure becomes low and a metal material becomes easy to flow. For this reason, the flow rate of the metal material radially outward increases, and the radially outer portion of the design flows more than expected toward the radially outer side.

  In this invention, the part corresponding to the cyclic | annular convex part of a base becomes thick partially by providing an annular convex part to the inner surface of a base continuously or discontinuously along the circumferential direction. For this reason, the base once becomes thicker at the annular protrusion outward in the radial direction, and then returns to a thinner thickness again. Therefore, the metal material that becomes the base that flows outward in the radial direction at the time of forging molding is thickened at the portion corresponding to the annular convex portion of the base, the flow pressure is once lowered, and then passed through the annular convex portion. Immediately after that, the thickness decreases and the flow pressure increases. As a result, the flow rate of the metal material decreases from the portion corresponding to the annular convex portion to the radially outer side, so that a part of the design that is radially outward from the annular convex portion is distorted to the radially outer side. It becomes difficult.

  In the present invention, the total volume of the annular convex portion is larger than the total volume of a part of the design existing on the outer side surface of the base on the outer side in the radial direction than the annular convex portion. Here, when the whole design comes radially outward from the annular protrusion, the total volume of the annular protrusion is designed to be larger than the total volume of the entire design. The volume of the annular protrusion is the volume of the annular protrusion that protrudes from the inner surface of the base. The volume of the design is the volume that is recessed from the outer surface of the base due to the concave design. In the present invention, the total volume of the annular protrusion is designed to be larger than the total volume of the design portion that is finally arranged radially outward from the annular protrusion, thereby coming outside in the radial direction from the annular protrusion. The distortion of the design part can be reduced or eliminated.

  In the present invention, the annular convex portion is provided continuously or discontinuously along the circumferential direction on the inner side surface of the base. When the annular convex portion is continuously provided along the circumferential direction, the annular convex portion extends continuously without being interrupted along the circumferential direction. As an example of the case where the annular convex portion is provided discontinuously along the circumferential direction, the annular convex portion is formed by a plurality of convex portions extending along the circumferential direction, and there are a plurality of discontinuous portions, or a spot shape This is a case where an annular convex portion is formed by arranging the convex portions in the circumferential direction. As long as the condition of the total volume of the annular protrusion is satisfied, the annular protrusion may be continuous or discontinuous, and there may be a plurality of annular protrusions (for example, the first radially inner first). The second annular convex portion and the second annular convex portion on the radially outer side).

  In the present invention, the rivet is made of metal such as aluminum, aluminum alloy, copper, copper alloy, steel, stainless steel, but is not limited thereto.

  In the present invention, the concave design imprinted on the outer surface of the base consists of characters, figures, symbols, etc., for example, a logo or the like.

  In one embodiment of the present invention, the base includes a constant thickness region having a substantially constant thickness outward in the radial direction, and an outer region in which the thickness increases from the constant thickness region outward in the radial direction. The convex portion is provided in the constant thickness region. In this case, when the rivet is forged, the base metal material flows from the constant thickness region to the thicker outer region. And the radially outer portion of the design tends to be distorted radially outward. In this embodiment, by providing an annular convex portion in the constant thickness region of the base, the thickness of the portion corresponding to the annular convex portion in the constant thickness region is increased. As a result, after the flow pressure drops momentarily at the portion corresponding to the annular convex portion in the constant thickness region and the flow velocity increases momentarily, the metallic pressure increases and the fluid pressure increases to the outside in the radial direction. The flow rate of the drops. This reduces or eliminates the distortion of the design thickness region and the outer region of the base, especially the design portion radially outward from the annular projection, radially outward.

  In one embodiment of the present invention, the total volume of the annular convex portion is larger than the total volume of a part of the design existing in the constant thickness region. The present inventor sets the total volume of the annular convex portion to be larger than the total volume of the design portion arranged in the constant thickness region of the design on the outer surface of the base of the rivet, so that the radially outer portion of the design Has been found to flow out to the outside in the radial direction and to be distorted or almost distorted. This is because the metal material that flows outward in the radial direction at the time of forging of the rivet, particularly the base, is an annular convex portion, and immediately after the flow pressure is lowered, the flow pressure is increased and the flow rate is lowered, thereby moving toward a thicker outer region. This is probably because the flow rate of the metal material is suppressed.

  In one embodiment of the present invention, an inner region whose thickness decreases toward the constant thickness region is included inside the constant thickness region in the radial direction. In this case, the base of the rivet becomes thinner in the inner region to the constant thickness region on the outer side in the radial direction, the thickness is almost constant in the constant thickness region, and the thickness in the outer region on the outer side in the radial direction from the constant pressure region. Becomes thicker.

  In one embodiment of the present invention, the base has an inner inclined surface extending obliquely outward and downward in the radial direction from the lower end of the post on the inner surface side, and radially outward from the lower end of the inner inclined surface. An intermediate horizontal plane extending substantially horizontally; an outer inclined surface extending obliquely outward and upward in a radial direction from a radially outer end of the intermediate horizontal plane; and substantially horizontally from a radially outer end of the outer inclined surface to a radially outer side. An extending outer horizontal surface is provided, and the annular convex portion is formed on the intermediate horizontal surface. In this case, the base becomes thicker from the radially outer end of the intermediate horizontal surface where the annular convex portion is formed to the radially outer side. For this reason, once the flow pressure drops and the flow speed rises momentarily at the portion corresponding to the annular projection during forging, the flow pressure rises after passing the annular projection, and the outer side in the radial direction of the intermediate horizontal plane The flow velocity from the edge outward in the radial direction decreases. This reduces or eliminates design distortion from the intermediate horizontal surface of the base radially outward.

  In one embodiment of the present invention, the outer surface of the base includes a circular horizontal bottom surface, and an inclined bottom surface extending radially outward and upward from a radially outer end of the horizontal bottom surface, the radial direction of the horizontal bottom surface An outer end is located radially outward from a radially outer end of the intermediate horizontal plane, and a design is formed between a radial outer end of the horizontal bottom surface and a radially outer end of the intermediate horizontal plane of the horizontal bottom surface. Being done. In this case, at least a part (design part) of the design is between the radially outer end of the horizontal bottom surface on the outer surface of the base and the position corresponding to the radially outer end of the intermediate horizontal surface on the outer surface of the base. Exists. Such a design portion existing on the outer side in the radial direction of the horizontal bottom surface tends to be distorted by flowing toward the outer side in the radial direction, especially during forging, but this can be reduced or eliminated by providing an annular convex portion.

  In the present invention, an annular convex portion that extends in the circumferential direction is provided on the inner surface side of the base of the rivet, and the design portion in which the total volume of the annular convex portion exists radially outward from the annular convex portion on the outer surface of the base. It is set larger than the total volume. As a result, when the metal material as the base flows outward in the radial direction during the forging of the rivet, the flow pressure increases immediately after the flow pressure once decreases at the portion corresponding to the annular convex portion. Since the flow rate of the material outward in the radial direction is reduced, the design portion of the base that is present on the radially outer side than the annular protrusion is hardly distorted outward in the radial direction.

FIG. 1 is a top view of a rivet according to an embodiment of the present invention. 2 is a cross-sectional view taken along line AA in FIG. FIG. 3 is a bottom view of the rivet. FIG. 4 is a partially enlarged view of FIG. FIG. 5 is a cross-sectional view showing a rivet forging process, which shows a base before forging. FIG. 6 is a cross-sectional view showing a rivet forging process, in which a base after forging is represented. FIG. 7 is a bottom view of the base of the rivet showing another example of the design. FIG. 8 is a bottom view of the rivet base showing yet another example of the design. FIG. 9 is a cross-sectional view showing a state in which the bar is fixed to the fabric using rivets. FIG. 10 is a cross-sectional view showing an example of a button that can be fixed to the fabric with rivets. FIG. 11 is a cross-sectional view showing another example of a button that can be fixed to a fabric with rivets. FIG. 12 is a side view showing a second embodiment of the rivet according to the present invention. FIG. 13 is a photograph showing a distorted state in which the design flows radially outward on the outer surface of the base of the conventional rivet.

  Several embodiments of the present invention will be described below with reference to the drawings. However, the present invention is not limited to such embodiments, and can be modified within the scope of the claims and equivalents. It is. FIG. 1 is a top view of a rivet 1 according to an embodiment of the present invention, and FIG. 2 is a cross-sectional view taken along line AA of FIG. FIG. 3 is a bottom view of the rivet 1. FIG. 4 is a partially enlarged view of FIG. Hereinafter, the vertical direction of the rivet 1 is based on the paper surface of FIG. 2 unless otherwise specified. The rivet 1 is a forged molded product made of a metal such as an aluminum alloy or a copper alloy, and has a disk shape having an inner side surface (upper surface) 10b and an outer side surface (bottom surface) 10a opposite to the inner side surface 10b. And a solid post 20 extending concentrically with the base 10 from the center of the inner side surface 10b of the base 10 to the upper side. As shown in FIG. 3, as an example of the concave design 30, a logo consisting of 16 alphabet letters YKKSNAPFASTENERS is arranged on the bottom surface 10 a that is the outer surface of the base 10 in the circumferential direction. A reference number 31 in FIG. 3 is a design different from the design 30, and the design 31 is composed of three circumferentially elongated sectors arranged radially inward of the design 30 along the circumferential direction. The designs 30 and 31 are engraved on the bottom surface 10a by the lower die 90 (see FIGS. 5 and 6) when the rivet 1 is forged, and are slightly recessed upward from the bottom surface 10a. This forging will be described later.

  The post 20 has a base 21 extending substantially the same diameter upward from the base 10 and a horizontal section extending horizontally from the base 21 (horizontal means a plane perpendicular to the rivet 1 or the axis of the post 20). Is provided with an upper portion 22 that extends while being gradually reduced, and a tip portion 23 that slightly protrudes upward from the upper portion 22. The upper surface 24 of the tip 23, that is, the upper surface 24 of the post 20 is a surface that extends horizontally, and has a substantially oval shape that is long in the left-right direction based on the paper surface of FIG. 1. The horizontal cross section of the distal end portion 23 also has a substantially oval shape that gradually reduces to the upper surface 24. The horizontal section of the upper portion 22 is circular at the lower end in contact with the base portion 21 and is substantially oval at the upper end in contact with the tip portion 23. The rate at which the horizontal cross section shrinks upward is slightly larger at the tip portion 23 than at the upper portion 22.

  The base 10 has an inner inclined surface 11 extending obliquely outward and downward in the radial direction from the lower end of the post 20 on the upper surface (inner surface) 10b side, and extends substantially horizontally from the lower end of the inner inclined surface 11 to the radially outer side. An intermediate horizontal surface 12, an outer inclined surface 13 extending obliquely outward and upward in the radial direction from the radially outer end of the intermediate horizontal surface 12, and an outer surface extending substantially horizontally from the radially outer end of the outer inclined surface 13 radially outward And a horizontal plane 14. The inner inclined surface 11, the intermediate horizontal surface 12, the outer inclined surface 13, and the outer horizontal surface 14 constitute an upper surface 10 b that is an inner surface of the base 10. The inclination angle of the inner inclined surface 11 with respect to the horizontal is slightly smaller than that of the outer inclined surface 13, that is, the inner inclined surface 11 is slightly less inclined than the outer inclined surface 13. The position of the outer horizontal surface 14 in the vertical direction (the axial direction of the rivet 1) is substantially the same as the lower end of the post 20. It can be said that the inner inclined surface 11, the outer inclined surface 13, and the intermediate horizontal surface 12 are annularly recessed downward with respect to a virtual extension horizontal surface from the outer horizontal surface 14 to the lower end of the post 20. An annular convex portion 16 that is convex upward is provided at a substantially intermediate portion in the radial direction of the intermediate horizontal surface 12 so as to be continuous in the circumferential direction. The annular convex portion 16 is represented by a thick black line for easy understanding in FIG. The annular protrusion 16 does not necessarily have to be continuous in the circumferential direction as long as the condition relating to the total volume of the annular protrusion 16 described later is satisfied. For example, a plurality of protrusions elongated in the circumferential direction are annularly arranged along the circumferential direction. Alternatively, a large number of spot-like convex portions can be arranged in the circumferential direction to form an annular convex portion. As shown in an enlarged view in FIG. 4, the annular convex portion 16 has a substantially arc shape in the longitudinal section along the radial direction. That is, the annular protrusion 16 gradually rises from the inner side in the radial direction to the outer side in the radial direction and reaches the apex in the intermediate horizontal plane 12, and then gradually decreases in height toward the outer side in the radial direction. Of the design 30 provided on the bottom surface 10 a of the base 10, the portion that exists on the outer side in the radial direction from the annular convex portion 16 is the design portion that exists on the outer side in the radial direction from the radial outer end 16 a of the annular convex portion 16. 30a. In other words, the design portion 30a is present on the outer side in the radial direction from the virtual line 17 at the same position in the radial direction as the radial outer end 16a of the annular convex portion 16 on the bottom surface 10a of the base 10. In the present embodiment, it can be seen from FIG. 3 that almost half of each of the 16 alphabetic characters that make up the design 30 exists radially outside the virtual line 17.

  The bottom surface 10a of the base 10 includes a circular horizontal bottom surface 10c and an inclined bottom surface 10d extending radially outward and upward from the radially outer end of the horizontal bottom surface 10c. The inclination angle of the inclined bottom surface 10d with respect to the horizontal is slightly smaller than that of the outer inclined surface 13 on the upper surface side. There is a peripheral side surface 15 between the radially outer end of the inclined bottom surface 10d and the radially outer end of the outer horizontal surface 14 on the upper surface side. The peripheral side surface 15 extends along the vertical direction (axial direction). The designs 30 and 31 imprinted on the bottom surface 10a are designed to be within the range of the horizontal bottom surface 10c. More preferably, the designs 30 and 31 imprinted on the bottom surface 10a are not in contact with the radially outer end of the horizontal bottom surface 10c, and the outermost portion of the designs 30 and 31 and the radius of the horizontal bottom surface 10c. Between the outer ends in the direction, there is an annular horizontal surface with no irregularities. The radial position of the boundary between the horizontal bottom surface 10c and the inclined bottom surface 10d corresponds to the middle in the radial direction of the outer inclined surface 13 on the upper surface 10b side. The thickness along the vertical direction between the top surface 10b side and the bottom surface 10a excluding the thickness of the base 10, that is, the depressions of the designs 30 and 31, is as follows. Referring to FIG. 4, the inner region 10 </ b> A corresponding to the inner inclined surface 11 becomes gradually thinner outward in the radial direction. In the intermediate region (constant thickness region) 10B corresponding to the intermediate horizontal surface 12 radially outward from the inner region 10A, the thickness is substantially constant. In the outer region 10C corresponding to the outer inclined surface 13 radially outward from the intermediate region 10B, the thickness gradually increases toward the outer side in the radial direction. In the region corresponding to the outer horizontal surface 14 radially outward from the outer region 10C, the thickness gradually decreases toward the radially outer end (circumferential side surface 15) of the base 10. The inner region 10A is surrounded by first and second virtual extension surfaces 10l and 10m extending in the vertical direction (axial direction) from the radially inner end and the radially outer end of the inner inclined surface 11 in the base 10, respectively. An annular region. The intermediate region 10B is an annular region of the base 10 surrounded by the second virtual extension surface 10m and the third virtual extension surface 10n extending in the vertical direction from the radially outer end of the intermediate horizontal surface 12. Further, the outer region 10C is an annular region of the base 10 surrounded by the third virtual extension surface 10n and the fourth virtual extension surface 10o extending from the radially outer end of the outer inclined surface 13 along the upward direction. is there.

  In the present embodiment, the design 30 on the bottom surface 10a of the base 10 is based on FIG. 4, about 1/4 of the radially inner portion 30c is present in the inner region 10A, and the remaining about 3/4 of the design portion. It is assumed that 30a exists in the intermediate region 10B. The radially outer end of the design 30 is located radially outside the imaginary line 17 from the radially outer end 16a of the linear annular protrusion 16 and slightly radially inward from the third virtual extension surface 10n. To do. Hereinafter, a portion of the design 30 that exists on the outer side in the radial direction from the virtual line 17 is referred to as a “design portion 30b”. In this example, the design portion 30b is a part of the design portion 30a in the intermediate region 10B (30b <30a). The total volume of the annular convex portion 16 provided on the intermediate horizontal surface 12 of the base 10 of the rivet 1 is set to be greater than or equal to the total volume of the design portion 30a of the intermediate region 10B, that is, the total volume of the concavely recessed portion corresponding to the design portion 30a. Is done. Further, the total volume of the annular convex portion 16 is larger than the design portion 30 b on the outer side in the radial direction from the virtual line 17. In addition, the total volume of the annular convex part 16 should just be larger than the design part 30b of radial direction outer side than the virtual line 17, and the total volume of the annular convex part 16 is larger than the total volume of the design part 30a of the intermediate | middle area | region 10B. May be less. The volume of the design portions 30a and 30b in the intermediate area 10B is the space volume of the space recessed from the surface of the horizontal bottom surface 10c, and the total volume is the sum of the space volumes.

  In the case of a conventional rivet having a configuration substantially similar to that of the rivet 1 except that the annular convex portion 16 is not provided, a metal material is used when the design is engraved on the bottom surface (outer surface) of the base when the rivet is forged. Flows from the intermediate region (10B) to the outer region (10C). At this time, since the thickness of the base increases from the intermediate region (10B) to the outer region (10C), the metal material moves radially outward. Flow pressure is reduced, thereby increasing the flow rate. For this reason, the design portion in the vicinity of the radially outer end of the intermediate region (10B) may flow radially outward to cause distortion (see the photograph in FIG. 13). On the other hand, in the rivet 1 according to the present invention, since the annular convex portion 16 is provided on the intermediate horizontal surface 12 of the intermediate region 10B, the thickness of the base 10 (in the intermediate horizontal surface 12) is the portion corresponding to the annular convex portion 16. Become thicker. Therefore, the metal material forming the rivet 1 that flows radially outward during forging molding temporarily decreases the flow pressure radially outward at the portion corresponding to the annular protrusion 16, and then the annular protrusion 16 As soon as it passes, the thickness of the rivet 1 is reduced again to the thickness of the intermediate horizontal surface 12 without the annular convex portion 16, so that the flow pressure radially outward increases. Due to such a change in the flow pressure, the flow rate of the metal material toward the outer side in the radial direction is decreased on the outer side in the radial direction with respect to the annular protrusion 16 in the intermediate region 10B. As a result, the design portions 30a and 30b rarely extend outward in the radial direction. In addition, since the design 31 which consists of three sectors exists in the inner side area | region 10A, there is almost no unsightly distortion like the conventional rivet. In addition, the total volume of the annular convex portion 16 is larger than the total volume of the design portion 30b. Preferably, the total volume of the annular convex portion 16 is larger than the total volume of the design portion 30a. Since it is possible to forge-mold with pressure and flow rate, the design 30 can be molded neatly. The circular horizontal bottom surface 10c is designed to be as large as possible with respect to the entire bottom surface 10a from the viewpoint of formability. On the other hand, the inner side surface 10b of the base 10 has a shape as in the first embodiment as a whole in order to make it possible to firmly attach to the fabric 50. For example, the radially outer end of the horizontal bottom surface 10c is located outside the third virtual extension surface 10n. This is because part of the design 30 may be radially outward from the third virtual extension surface 10n, and the flow pressure is weaker outside the third virtual extension surface 10n. As a result, the design is easily distorted, but even with such a configuration, the presence of the annular convex portion 16 hardly distorts unsightly like a conventional rivet.

  Next, the forging process of the rivet 1 will be described. The rivet 1 is obtained by cold forging molding in which a rod-shaped intermediate material 1D is plastically deformed using an upper die 80 and a lower die 90. FIG. 5 shows a state in which the upper part of the intermediate material 1D is molded into the post 20 by the upper die 80. FIG. FIG. 5 shows a lower portion of the intermediate material 1D, that is, a base 10D before forging. The upper die 80 has an upper cavity 82 that is recessed upward from the lower surface 81 and that has a shape that matches the irregular shape of the inner surface 10 b of the base 10. The upper cavity 82 includes an annular recess 83 corresponding to the annular protrusion 16. On the other hand, the lower die 90 has a lower cavity 92 that is recessed downward from its upper surface 91 and has a shape that matches the outer surface 10 a of the base 10. The lower cavity 92 includes minute protrusions 93 for imprinting the designs 30 and 31 on the outer side surface 10a of the base. From the state of FIG. 5, the upper die 80 is lowered toward the lower die 90. Accordingly, as shown in FIG. 6, the base 10D before forging of the intermediate material 1D is radially compressed while being compressed in the axial direction between the upper cavity 82 of the upper die 80 and the lower cavity 92 of the lower die 90. The base 10 having the upper surface 10b and the bottom surface 10a described above is formed. At the time of this forging, the metal material that becomes the base 10 of the rivet 1 flows outward in the radial direction, the flow pressure radially outward decreases temporarily in the annular recess 83 corresponding to the annular protrusion 16, and then As soon as the annular recess 83 is passed, the thickness of the rivet 1 is reduced, so that the flow pressure outward in the radial direction is increased. Due to such a change in the flow pressure, the flow rate of the metal material to the outer side in the radial direction is lower than the annular recess 83 in the radial direction. As a result, the designs 30 and 31 hardly distort by flowing radially outward.

  FIG. 7 is a bottom view showing another example (designs 32 and 33) of the design to be engraved on the bottom surface 10a of the base 10 of the rivet 1, and other than the designs 32 and 33 are the same as the rivet 1 described above. Use the same reference numbers. In this example, the design 32 is made up of three alphabet letters YKK and the design 33 is made up of a rectangular frame substantially surrounding the design 32. The bold portion of YKK, which is the design 32, is recessed in a concave shape, and the design 33 has a rectangular shape. The formed line is depressed. Also in this example, the total volume of the annular protrusions 16 (not shown in FIG. 7) provided on the upper surface side of the base 10 is the second virtual extension surface 10m and the third virtual extension surface 10n of the designs 32 and 33. It is set to be equal to or greater than the total volume of the portion existing in the intermediate region 10B. The total volume of the annular convex portion 16 is larger than the total volume of the portions of the designs 32 and 33 that exist radially outside the annular convex portion 16, that is, radially outside the virtual line 17. Therefore, the radially outer portions of the designs 32 and 33 are hardly distorted radially outward.

  FIG. 8 is a bottom view showing still another example (design 34) of the design imprinted on the bottom surface 10a of the base 10 of the rivet 1. Since the parts other than the design 34 are the same as those of the rivet 1 described above, the same reference numerals are used. Use. The design 34 is a geometric pattern composed of a plurality of regular hexagons having different sizes, and a line forming each regular hexagon is recessed in a concave shape. In the design 34, the next largest regular hexagon 34b is arranged radially inward of the largest regular hexagon 34a so that each vertex of the regular hexagon 34b is in contact with the midpoint of each side of the regular hexagon 34a. Similarly, the next largest regular hexagon is arranged radially inward of the regular hexagon 34b so that each vertex of the next largest regular hexagon touches the midpoint of each side of the regular hexagon 34b, and this is the smallest regular hexagon 34c. Repeat until. Also in this example, the total volume of the annular protrusions 16 (not shown in FIG. 8) provided on the upper surface side of the base 10 is set between the second virtual extension surface 10m and the third virtual extension surface 10n in the design 34. It is set to be equal to or greater than the total volume of the portion existing in the intermediate region 10B. The total volume of the annular convex portion 16 is larger than the total volume of the portion of the design 34 that exists radially outside the annular convex portion 16, that is, radially outside the imaginary line 17. As a result, the radially outer portion of the design 34 is hardly distorted radially outward.

  FIG. 9 is a cross-sectional view showing a state in which the bar 40 as an example of the bar is fixed to the dough 50 using the rivet 1 described above. The bar 40 is a decorative button made of metal used for fastening a jeans or the like, and includes a central dome portion 41 and a flange portion 42 that extends upward from the lower end of the dome portion 41 and then spreads radially outward. . When the bar 40 is attached to the dough 50, the post 20 of the rivet 1 is passed through the dough 50 using a button attaching machine (not shown), and then, as shown in FIG. The bar 40 is fixed to the dough 50 by caulking.

  The rivet 1 other than the bar 40 or the like can be used when fixing the buttons 60 and 70 of the type to be put in and out of the button hole illustrated in FIGS. 10 and 11 to the cloth. The button 60 shown in FIG. 10 is formed by drawing a metal plate or the like, and includes a body portion 61 and a head portion 62 whose diameter is increased at the upper end of the body portion 61. An opening 64 for receiving the post 20 of the rivet 1 when fixed to the dough is formed in the bottom 63 of the body 61 so as to enter the inside of the body 61 from the bottom 63. The button 60 is fixed to the dough by the rivet 1 by crimping the post 20 of the rivet 1 received from the opening 64 with a punch (not shown) inside the body portion 61. The button 70 in FIG. 11 includes a body portion 71 and a head portion 72 whose diameter is increased at the upper end of the body portion 71. The button 70 is made of a metal button body 70a that forms the body portion 71 and the lower surface portion of the head portion 72, and a metal body that is integrally assembled by covering the lower surface portion corresponding to the head portion 72 of the button body 70a from above. The cap 70b. The bottom portion 73 of the body portion 71 is formed so as to be recessed upward in the radial direction, and a small hole 74 is opened at the center thereof. When the button 70 is fixed to the fabric, the post 70 of the rivet 1 penetrating the fabric is received inside the trunk portion 71 so as to break through the bottom portion 73 from the small hole 74, and then the button 70 is crimped by tightening the post 20. Fixed to the dough. As described above, since the annular convex portion 16 is attached to the surface facing the fabric 50, the design is prevented from being distorted, and the attachment strength to the fabric 50 is improved. From the viewpoint of preventing distortion of the design, the total volume of the annular protrusions 16 only needs to be larger than the total volume of a part of the design existing radially outward from the annular protrusions 16 on the outer surface of the base. It is preferable to set the size so that the attachment strength to the fabric 50 does not decrease.

  FIG. 12 is a side view showing a second embodiment of the rivet 101 according to the present invention. The rivet 101 is a forged product made of a metal such as an aluminum alloy or a copper alloy, and includes a disk-shaped base 110 and a solid post 120 extending concentrically with the base 110 upward from the center of the base 110. Prepare. A concave design (not shown) is imprinted on the bottom surface 110a, which is the outer surface of the base 110 opposite to the post 120, during forging. An upper surface 110b that is an inner surface of the base 110 is horizontal. The bottom surface 110a of the base 110 includes a circular horizontal bottom surface 110c, and an inclined bottom surface 110d extending radially and upward from the radially outer end of the horizontal bottom surface 110c. There is a peripheral side surface 115 between the radially outer end of the inclined bottom surface 110d and the radially outer end of the upper surface 110b. A concave design (not shown) is provided on the horizontal bottom surface 110c. In the rivet 101, an annular convex portion 116 is provided in the middle between the lower end of the post 120 and the peripheral side surface 115 on the upper surface 110 b of the base 110. The total volume of the annular convex portion 116 is set to be at least larger than the design portion existing radially outside the virtual line 117 at the same position in the radial direction as the radial outer end of the annular convex portion 116 in the design. Is done. As a result, there is almost no possibility that the radially outer portion of the design provided on the bottom surface 110a of the base 110 is distorted radially outward. As with the rivet 1, the rivet 101 can be used to fix the bar 40, the buttons 60, 70, etc. to the fabric.

1, 101 Rivet 1D Intermediate material 10, 110 Base 10A Inner area 10B Intermediate area (constant thickness area)
10C outer region 10a, 110a Base bottom surface (outer surface)
10b, 110b Upper surface (inner surface) of the base
10c horizontal bottom surface 10d inclined bottom surface 10l first virtual extension surface 10m second virtual extension surface 10n third virtual extension surface 10o fourth virtual extension surface 11 inner inclined surface 12 intermediate horizontal surface 13 outer inclined surface 14 outer horizontal surface 16, 116 annular convex portion 17, 117 Virtual line 20, 120 Post 30, 31, 32, 33, 34 Design 30a Design part 30b present in the middle area (constant thickness area) 30b Present radially outside the annular convex part 16 (virtual line 17) Design part 40 Bar 50 Fabric 60, 70 Button 80 Upper die 90 Lower die

Claims (7)

A disc-shaped base (10, 110) having an inner surface (10b, 110b) and an outer surface (10a, 110a) opposite to the inner surface (10b, 110b); and the base (10, 110) And a post (20, 120) extending from the center of the inner surface (10b, 110b), and a concave design (30, 31, 32, 33, 34) on the outer surface (10a, 110a) of the base (10, 110). ) (1, 101) engraved with
The inner surface (10b, 110b) of the base (10, 110) has an annular protrusion (16, 116) provided continuously or discontinuously along the circumferential direction,
The design in which the total volume of the annular protrusions (16, 116) exists radially outside the annular protrusions (16, 116) on the outer surfaces (10a, 110a) of the base (10, 110). A rivet characterized in that it is larger than the total volume of a part of 30, 31, 32, 33, 34).   The base (10) includes a constant thickness region (10B) having a substantially constant thickness outward in the radial direction and an outer region (10C) in which the thickness increases from the constant thickness region (10B) to the radially outer side. The rivet according to claim 1, wherein the annular convex portion (16) is provided in the constant thickness region (10B).   The rivet according to claim 2, wherein the total volume of the annular convex part (16) is larger than the total volume of the design (30) existing in the constant thickness region (10B).   The rivet according to claim 2 or 3, comprising an inner region (10A) whose thickness is reduced toward the constant thickness region (10B) on the radially inner side of the constant thickness region (10B).   The rivet according to claim 1, wherein the rivet (1, 101) is made of metal.   The base (10) includes, on the inner surface (10b) side, an inner inclined surface (11) extending obliquely outward and downward in the radial direction from a lower end of the post (20), and an inner inclined surface (11). An intermediate horizontal surface (12) extending substantially horizontally from the lower end to the radially outer side, an outer inclined surface (13) extending obliquely outward and upward in the radial direction from the radially outer end of the intermediate horizontal surface (12), and the outer surface The outer horizontal surface (14) extending substantially horizontally from the radially outer end of the inclined surface (13) to the radially outer side is provided, and the annular protrusion (16) is formed on the intermediate horizontal surface (12). Rivet as described in.   The outer surface (10a) of the base (10) includes a circular horizontal bottom surface (10c) and an inclined bottom surface (10d) extending radially outward and upward from a radially outer end of the horizontal bottom surface (10c). The radially outer end of the horizontal bottom surface (10c) is radially outward from the radially outer end of the intermediate horizontal surface (12), and the radius of the horizontal bottom surface (10c) of the horizontal bottom surface (10c). A rivet according to claim 6, wherein a design (30) is formed between a laterally outer edge and a radially outer edge of the intermediate horizontal surface (12).

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