JP2012145167A - Blind rivet - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a blind rivet having superior water tightness.SOLUTION: The blind rivet 1 is composed of a mandrel 2 and a rivet 3. The mandrel is formed into a round rod shape as a whole, and has a head 12 larger in diameter than the other portion at one end. The river has a rivet body 15 which is cylindrical as a whole and closed at its one end, and a flange 16 which is continuous to the other end of the rivet body and expanded to the outside of the radial direction of the rivet body. Furthermore, the rivet accommodates the mandrel by making the head positioned at the closed one end and locking the head so as to be undrawable. The rivet body has a tapered part 21 which is gradually reduced in outside diameter as progressing toward one end side from a connecting portion with the flange.

Description

  The present invention relates to a blind rivet capable of performing, for example, a work of overlapping and fastening a plurality of plate-shaped members from one side.

A blind rivet is used as one of means for fastening a plurality of stacked plate members by work only from one side.
The blind rivet includes a cylindrical rivet that substantially fastens a plurality of plate members by being deformed, and a mandrel that protrudes from the rivet to both sides or one side thereof to deform the rivet in a fastening operation. There are two types of blind rivets. One is a type in which the head of a mandrel that deforms the rivet for fastening is housed in the rivet, and the remaining head of the mandrel is not exposed to the opposite side of the work side after fastening the plate (tentatively “closed type” (Patent Document 1). The other is a type in which the head of the mandrel is out of the rivet and the remaining head of the mandrel is exposed to the opposite side of the working side after fastening the plate (tentatively called “valve type”) (Patent Documents 2 and 3).

JP 2004-340334 A JP 2000-266019 A JP 2009-41699 A

In the closed type blind rivet described in Patent Document 1, only the rivet is exposed on the side opposite to the work side after the fastening, and therefore, generally, the rivet itself has an excellent liquid blocking property (referred to as “watertightness”). It is said that.
On the other hand, the valve-type blind rivets described in Patent Document 2 and Patent Document 3 both expose the remaining head of the mandrel together with the rivet on the side opposite to the working side after fastening. The liquid that has entered between the remaining head is likely to leak to the other side.

Thus, from the rivet fastening structure, it is considered that blind rivets are excellent in water tightness, but in reality, liquid leakage is likely to occur between the hole of the fastened plate material and the rivet, and the water tightness is not always sufficient. There was a problem that was not.
The present invention has been made in view of the above-described problems, and an object thereof is to provide a blind rivet that is excellent in water tightness.

  A blind rivet according to the present invention is a blind rivet comprising a mandrel and a rivet, and the mandrel has a round bar shape as a whole and has a head having a larger diameter than the other part at one end, and the rivet A rivet body that is cylindrical and closed at one end thereof, and a flange that is continuous with the other end of the rivet body and extends outward in the radial direction of the rivet body. The mandrel is housed so as not to be pulled out by being positioned and hooked, and the rivet body has a tapered portion whose outer diameter gradually decreases from the continuous portion with the flange toward the one end side. Have

  Preferably, in a cross section in which the flange includes the axis of the rivet body, a line passing through two points of the flange-side end point and the radially outer end of the tapered portion and the axis of the rivet body have an angle of 90. It is formed to intersect at a degree or less.

  ADVANTAGE OF THE INVENTION According to this invention, the blind rivet excellent in watertightness can be provided.

FIG. 1 is a front half sectional view of a blind rivet. FIG. 2 is an enlarged half sectional view around the rivet. FIG. 3 is a front half sectional view of a plate member fastened by a blind rivet. FIG. 4 is a sectional view of the blind rivet in the fastening process. FIG. 5 is a view in which the blind rivet after fastening is halved together with the plate material. FIG. 6 is a front half sectional view of another form of blind rivet. FIG. 7 is a front view of another form of blind rivet. FIG. 8 is a front half sectional view of another form of rivet.

FIG. 1 is a front half sectional view of the blind rivet 1, and FIG. 2 is an enlarged half sectional view around the rivet 3.
The blind rivet 1 includes a mandrel 2 and a rivet 3.
The mandrel 2 includes a mandrel body 11 and a head 12. The mandrel body 11 is a round bar as a whole. The mandrel body 11 has a planned break portion 13 having a smaller diameter than the other portions in the vicinity of one end. On the other end side of the mandrel main body 11 in the longitudinal direction, annular raised auxiliary rings 14,..., 14 are provided at equal intervals.

  The head 12 is a cylindrical portion having a larger diameter than the mandrel body 11. The head 12 is continuous with one end of the mandrel body 11 on the side where the planned fracture portion 13 is disposed. The mandrel main body 11 and the head 12 are made of a metal material harder than the rivet 3. In the mandrel 2, a head 12, a planned breaking portion 13 and a part of the mandrel body 11 are accommodated in the rivet 3.

The rivet 3 includes a rivet body 15 and a flange 16. The rivet body 15 is cylindrical and has one end closed. The flange 16 is a bowl-shaped part having a circular end edge that spreads outward in the radial direction of the released other end of the rivet body 15. The rivet 3 accommodates the mandrel 2 by bringing the head 12 into contact with the inner surface of the closed end of the rivet body 15.
The rivet body 15 is narrowed so that an inner diameter thereof is smaller than an outer diameter of the head 12 by a rolling process at a portion facing the head 12 of the mandrel 2 in the axial direction between the head 12 and the planned breaking portion 13. . The portion where the inner diameter is reduced is referred to as a throttle portion 17. The rivet 3 is integrated with the mandrel 2 by preventing the mandrel 2 from falling off by the narrowed portion 17.

In the rivet body 15, a portion having a constant length L inward in the axial direction from the end on the flange 16 side is a tapered portion 21 whose outer diameter gradually increases (continuously) toward the end. The length L in the axial direction of the tapered portion 21 is 20% or more of the rivet diameter D (in the rivet 1, the outer diameter D on the side where the head 12 is accommodated and closed).
Here, the end on the flange 16 side that defines the length L is the end on the flange 16 side of the bus bar of the tapered portion 21.

In the rivet 1 shown in FIG. 2, the angle θ formed by the generatrix of the outer surface of the tapered portion 21 and the axis is about 4 degrees. This angle θ decreases as the length L of the tapered portion increases, and varies depending on the length L of the tapered portion.
The flange 16 has a concave curved surface on the rivet body 15 side (referred to as “back surface 22”). Therefore, the back surface 22 is separated from the virtual surface orthogonal to the rivet body 15 by a distance S at the maximum on the radially inward side of the portion in contact with the surface.

In the blind rivet 1, both the mandrel 2 and the rivet 3 are made of stainless steel. The mandrel 2 and rivet 3 can be made of other metal materials, and the mandrel 2 and rivet 3 can also be made of different metal materials.
FIG. 3 is a front half sectional view of the plate members 51 and 52 fastened by the blind rivet 1.
The plate material is fastened with the blind rivet 1 by using a special tool and pulling out the mandrel 2 while pressing the flange 16 against the plate material 51. By this processing, the head 12 is prevented from moving in the rivet body 15 by the throttle 17 and compresses and deforms between the throttle 17 and the flange 16 in the rivet 3. As a result, the side of the rivet 3 that protrudes from the plate material 52 and accommodates the head 12 is greatly deformed so as to spread outward in the radial direction. When the force applied to the mandrel 2 exceeds the tensile strength of the material, the mandrel 2 breaks at the planned break portion 13. The plate members 51 and 52 are sandwiched between the flange 16 of the rivet 3 and a portion that is greatly deformed to expand radially outward, and are fastened firmly (FIG. 3).

Next, the water tightness of the blind rivet 1 will be described.
FIG. 4 is a cross-sectional view of the blind rivet in the fastening process, and FIG. 5 is a diagram (photograph) of the blind rivets 1 and 7 that have actually been fastened together with the plate material. 4 and 5, (a) is the blind rivet 1 having the tapered portion 21, and (b) is the blind rivet 7 having no tapered portion 21.

As for the blind rivets 1 and 7, when the mandrel 2 is pulled out from the rivets 3 and 8, the head 12 of the mandrel 2 is hooked on the hooking portion 23 formed by the throttle portion 17, and the rivet main bodies 15 and 71. Is compressed in the axial direction.
In the compressed rivet main bodies 15 and 71, the portion on the narrowed portion 17 side protruding from the plate material 52 expands in the radial direction (deformed portion P1). The portion in the rivet hole 53 that continues to this is curved in a wavy shape with respect to the axial direction in accordance with the deformation of the portion on the throttle portion 17 side that protrudes from the plate material 52, and this curvature is further on the side of the continuous flange 16. Propagate toward the part.

In the rivet holes 53 of the rivet bodies 15, 17, a reduction deformation in the radial direction is generated (deformation portion P <b> 2) that is continuous with the expansion deformation in the radial direction at the portion protruding from the plate material 52.
Since the rivet bodies 15 and 71 are prevented from being deformed in the radial direction by the flange 16 at the continuous portion with the flange 16, the portion slightly away from the flange 16 in the axial direction becomes the end point P3 of the reduction deformation in the radial direction. At the end point P3 of the reduction deformation in the radial direction, a force F is applied to the portion closer to the flange 16 than this in the direction of expanding the diameter by compression of the rivet bodies 15 and 71.

  The force F causes the rivet body 15 in the blind rivet 1 to have the entire taper portion 21 pushed and expanded to the inner surface side of the rivet hole 53 (see FIG. 4A). On the other hand, the rivet body 71 of the blind rivet 7 that does not have the taper portion 21 is in close contact with the inner surface of the rivet hole 53 due to enlargement deformation in the radial direction near the end point P3 of the reduction deformation. It moves away from the inner surface of the hole 53 (see FIG. 4B).

  In the blind rivet 1, the interval between the vicinity of the flange 16 of the rivet body 15 and the rivet hole 53 is narrowed by the tapered portion 21 before the fastening process. Therefore, after the fastening process, it is possible to increase the contact area (see symbol AR1) between the rivet body 15 and the inner surface of the rivet hole 53 in the vicinity of the flange 16. Due to this large contact area, the blind rivet 1 can obtain high water tightness after the fastening process.

The blind rivet 1 uses the fact that the vicinity of the flange 16 in the rivet body 15 is less likely to be deformed in the radial direction as compared with other parts, thereby improving the watertightness after the fastening process.
On the other hand, in the blind rivet 7 that does not have the taper portion 21, the contact area (see symbol AR2) between the rivet body 71 and the inner surface of the rivet hole 53 is small, and sufficient water tightness cannot be expected.

  The effect of improving the water tightness of the blind rivet 1 having the taper portion 21 depends on the degree of expansion deformation in the radial direction of the portion protruding from the plate material 52 in the rivet body 15 after the fastening process (the size of the diameter to be crushed and expanded). It can be obtained. That is, the taper portion 21 can be applied as long as it is a blind rivet having a cylindrical rivet body, and such a blind rivet can improve water tightness at a fastening portion.

FIG. 6 is a front half sectional view of another form of blind rivet 1B.
The blind rivet 1B includes a mandrel 2B and a rivet 3B.
The mandrel 2B includes a mandrel body 11 and a head 12. The mandrel body 11 is a round bar as a whole, although its shape is slightly different from the mandrel 2 in the blind rivet 1. The mandrel body 11 includes a planned fracture portion 13 and a gripped auxiliary ring. The configuration of the planned fracture portion 13 and the gripped auxiliary ring is substantially the same as that in the blind rivet 1, and the description thereof is omitted. The head 12 has substantially the same configuration as the head 12 in the blind rivet 1.

The rivet 3B includes a rivet body 15B and a flange 16. The rivet body 15B has a cylindrical shape with one end closed.
The rivet body 15B has an inner diameter smaller than the outer diameter of the head 12 by rolling at a corresponding axial position between the head 12 of the mandrel 2 accommodated in the rivet main body 15B and the planned fracture portion 13. A narrowed diaphragm portion 17 is provided. In the rivet 3 </ b> B, a portion of the length L from the narrowed portion 17 to the flange 16 is a tapered portion 21 </ b> B whose outer diameter gradually increases toward the flange 16. The length L in the axial direction of the tapered portion 21 greatly exceeds 20% of the rivet diameter D.

In the rivet 3B shown in FIG. 6, the angle θ formed by the generatrix of the outer surface of the tapered portion 21B and the axis is about 1.2 degrees. The angle θ depends on the length L of the tapered portion.
In the approximate center of the tapered portion 21B, a second throttle portion 25B is provided that is narrowed in the same manner as the throttle portion 17. The second narrowed portion 25B is for planning the position of the end point P3 of the reduction deformation in the radial direction of the blind rivet 1 during the fastening operation of the plate material.

The configuration, functions, and the like of the parts other than the above-described parts in the blind rivet 1B are the same as those in the blind rivet 1, and the description thereof is omitted. Further, the taper portion 21B of the blind rivet 1B in fastening the plate material is also the same as the taper portion 21 in the blind rivet 1.
FIG. 7 is a front view of another type of blind rivet 1C.

  The blind rivet 1C is caulked at four locations inward at 90 ° intervals in the circumferential direction of the rivet body 15C, and the head of the mandrel 2 is integrated with the rivet 3C. The caulked portion is referred to as a caulking portion 27. The caulking portions 27, 27, 27 hook the head 12 of the mandrel 2 by protruding inward of the rivet body 15C, and prevent the mandrel 2 from coming out of the rivet 3C. Further, the caulking portions 27, 27, 27 serve to hook the head 12 during the plate material fastening process and compress the rivet body 15C in the axial direction.

  The blind rivet 1 </ b> C has a tapered portion 21 </ b> C in which the outer diameter gradually increases toward the flange 16 from the vicinity of the flange 16 to the caulking portions 27, 27, 27 in the rivet main body 15 </ b> C. The operation of the blind rivet 1C during the fastening process of the tapered portion 21C, the operation related to the water tightness after the fastening, and the like are the same as those of the blind rivet 1 and 1B.

  In the above-described embodiment, the rivets 3, 3B, 3C and the mandrel 2 can have other shapes. For example, the flange 16 can have various forms as shown in FIG. FIG. 8A shows a rivet 3D in which the flange 16D forms an acute angle with the shaft center in a cross section including the shaft center of the rivet body 15, and its radial end edge is inclined toward the tapered portion 21 side. A back surface 22D of the flange 16D is a flat surface. FIG. 8B shows a rivet 3E in which the flange 16E is spread outward in the radial direction perpendicular to the axis of the rivet body 15 as a whole.

The blind rivet using the rivets 3D and 3E shown in FIG. 8 also functions as shown in FIG. 4A when fastening the plate material, and increases the contact area between the rivet body 15 and the inner surface of the rivet hole. And high water tightness can be obtained after the fastening process.
In the blind rivets 1, 1 </ b> B, 1 </ b> C, the flanges 16, 16 </ b> D, 16 </ b> E are radially outer end edges and end points on the flange side of the tapered portions 21, 21 </ b> B, 21 </ b> C in the section including the axis of the rivet bodies 15, 15 </ b> B, 15 </ b> C. It is preferable that an angle α at which a line AB passing through (refer to FIGS. 2 and 8) intersects the axis of the rivet bodies 15, 15 B and 15 C is 90 degrees or less.

  When the continuous portion of the rivet main body 15, 15B, 15C and the flange 16, 16D, 16E in the cross section including the axis of the rivet main body 15, 15B, 15C is continuous by the curved line, the radius of curvature of the curved line suddenly increases. The intersection of the tangent of the decreasing point and the extended line of the taper parts 21, 21B, 21C is defined as the flange side end point of the taper parts 21, 21B, 21C. The point where the radius of curvature of the curved line sharply decreases is the point where the slope of the tangent of each point of the curved line changes rapidly or discontinuously.

  In addition, each structure of the blind rivets 1, 1B, 1C and the blind rivets 1, 1B, 1C or the overall structure, shape, dimensions, number, material, and the like can be appropriately changed in accordance with the spirit of the present invention.

  INDUSTRIAL APPLICATION This invention can be utilized for the blind rivet which can perform the operation | work which piles up several plate-shaped members and fastens from one side.

1,1B, 1C Blind rivet 2 Mandrel 3, 3B-3E Rivet 12 Head 15, 15B, 15C Rivet body 16, 16D, 16E Flange 21, 21B, 21C Taper

Claims (2)

A blind rivet consisting of a mandrel and rivets,
The mandrel has a round bar shape as a whole and a head having a larger diameter than the other part at one end,
The rivet is
A rivet body that is generally cylindrical and closed at one end;
A flange extending continuously outwardly in a radial direction of the rivet body, the flange being extended radially outward of the rivet body, the head being positioned on one closed side and the head being hooked to hang the mandrel Is contained in an unextractable manner,
The rivet body has a taper portion whose outer diameter gradually decreases from the continuous portion with the flange toward the one end side. The flange is
In a cross section including the axial center of the rivet body, a line passing through two points of the flange side end point and the radially outer end edge of the tapered portion intersects the axial center of the rivet body at an angle of 90 degrees or less. The blind rivet according to claim 1 formed.