KR101271396B1 - Device for forging self piercing rivet - Google Patents

Abstract

PURPOSE: A self-piercing rivet forging apparatus is provided to penetrate the upper plate of self-piercing connecting objects and to make the upper plate of the penetrating portion not to be completely sheared in the process of pressing in a lower plate, thereby reinforcing the connecting strength of the upper plate and lower plate by the penetrating portion. CONSTITUTION: A self-piercing rivet forging apparatus includes a first die member(20), a first fin member(30), a second die member(50), a second fin member(60), a third die member(80), and a third fin member(90). A cylindrical billet(101) is inserted into the first die member. The first fin member is inserted into the first die member and molds a centering groove(103) at the insertion end part of the billet. A reserve molding product, on which the centering groove is formed, is inserted into the second die member, and a plurality of protrusion parts(55) for molding a slit(5) are included in the inner side surface of the second die member. The second fin member is inserted into the second die member, is coupled to the protrusion parts, and extrudes and molds a shank part(3). The extrusion molding, in which the shank part is formed, is inserted into the third die member, and the head molding groove(85) for molding the head unit(1) is included in the third die member. The third fin member is insertably installed at the third die member and supports the extrusion molding.

Description

Self Piercing Rivet Forging Forming Equipment {DEVICE FOR FORGING SELF PIERCING RIVET}

Embodiment of the present invention relates to a self-piercing rivet forging molding apparatus, and more particularly to a self-piercing rivet forging molding apparatus for forging a self-piercing rivet that can be bonded through two or more pieces of the bonding object.

In the automobile industry, the use of aluminum alloys and plastic materials to improve fuel efficiency due to environmental problems has been aimed at reducing the weight of the vehicle body.

For this purpose, in the automobile industry, a joining method capable of replacing conventional spot welding for assembling a vehicle body is being studied.

Recently, a self piercing rivet joining method using a self piercing rivet system has been adopted as a joining method meeting these expectations.

The self-piercing rivet jointing method is different from the conventional riveting method in which a hole for riveting is formed on a joining object such as a steel plate and a rivet is inserted into the hole and then the head is molded to join the object to be joined. Or the rivet is subjected to plastic deformation by press-fitting the rivet into the object to be bonded by air pressure to join the object to be bonded.

In the above self-piercing rivet joining method, a self-piercing rivet consisting of a head and a partially hollow cylindrical shank is used to fasten a joining object such as, for example, sheet metal.

For example, the self-piercing rivet is joined by the punch of the setting tool, the shank penetrates the upper plate of the joining object, is supported by the die, and spreads outward, and the shank is press-fitted into the lower plate with the head portion supporting the upper plate. The upper and lower plates of can be joined.

By the way, since the shank is terminated by the annular piercing edge of the prior art, the through portion of the upper plate can be completely sheared by the annular edge portion of the shank during the penetration of the upper plate of the object to be joined and pressed into the lower plate.

This acts as a factor to lower the bonding strength of the joining object because the through portion of the upper plate sheared by the shank remains a dead metal that cannot be utilized for mechanical interlock formation of the upper and lower plates. .

Therefore, in the prior art, when joining a joining object using a single rivet, since the rivet does not play a role of restraining the upper and lower plates with a certain strength by the dead metal as described above, the upper and lower plates are rotated. This problem is disadvantageous in terms of bonding properties and bonding strength.

Thus, in the prior art, various methods have been tried to prevent the rotation of the bonding object, but the situation is preventing rotation by bonding the bonding object using a plurality of rivets in a conventional manner.

Using a plurality of rivets to join the joining objects as described above may cause problems such as a decrease in productivity due to complexity of the joining process, a cost increase due to the joining process and an increase in the number of parts.

In addition, in the prior art, since the shank portion of the rivet terminates with an annular piercing edge, there is also a problem that the joining load increases because the shank portion shears through the top plate of the joining object in an annular shape.

Embodiments of the present invention improve the shape of the shank so that the through portion of the joining object is not sheared, the self-piercing rivet forging molding apparatus for forging a self-piercing rivet that the through portion can reinforce the bonding strength of the joining object To provide.

In addition, embodiments of the present invention can prevent the rotation of the bonding object even if a single number of rivets are applied to the bonding object by using a through portion that is not sheared by the shank, and can improve the bonding strength of the bonding object. A self-piercing rivet forging apparatus for forging a piercing rivet is provided.

In addition, embodiments of the present invention to provide a self-piercing rivet forging molding apparatus for forging a self-piercing rivet that can increase the bonding strength of the bonding object while reducing the bonding load on the bonding object.

In addition, embodiments of the present invention is to provide a self-piercing rivet forging molding apparatus that the overall molding process of the self-piercing rivet is simple, good dimensional accuracy and formability, and can reduce the punch load.

Self-piercing rivet forging apparatus according to an embodiment of the present invention, for forging a self-piercing rivet including a head portion and a shank portion formed with a plurality of slits, iii) a first die into which a cylindrical billet is inserted A member, ii) a first pin member installed to be inserted into the first die member corresponding to the insertion end of the billet, and forming a centering groove at the insertion end of the billet; A second die member having a plurality of protrusions formed on an inner side thereof to insert a molded product, and (i) be inserted into the second die member corresponding to an insertion end of the preform, A second pin member coupled to the protrusions and extruding the shank portion; and iii) an extruded article formed with the shank portion is inserted therein, and the head portion is inserted. A third die member having a head forming groove for molding; and iii) a third pin member installed to be inserted into the third die member corresponding to the insertion end of the extruded article and supporting the extruded article. can do.

In addition, the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the first punch unit is provided to correspond to the first die member and presses the billet inserted into the first die member, and the second die member A second punch unit provided to correspond to the second die member and pressing the preformed product inserted into the second die member, and a third punch provided to correspond to the third die member and pressurizing the extruded article inserted into the third die member. It may include a unit.

In addition, the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the first pusher for supporting the first pin member and pushing the first pin member from the first die member, and the second pin member And a second pusher for supporting and pushing the second pin member from the second die member, and a third pusher for supporting the third pin member and pushing the third pin member from the third die member. have.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the first die member may include a cylindrical first die body having a first insertion hole for inserting the billet.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the first pin member may include a conical pin protrusion for forming the centering groove at the insertion end of the billet.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the protrusion may be integrally protruded to the inner surface of the second die member with a length corresponding to the slit.

Further, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the protrusion may be disposed radially toward the inner center from the inner surface of the second die member.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the protrusion may be formed in the form that the cross-sectional width gradually decreases from the inner surface of the second die member toward the inner center.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the protrusion portion may be formed in the form of the end corresponding to the insertion end of the preform.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the second die member may include a cylindrical second die body having a second insertion hole in which the preform can be inserted.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the second pin member is inserted into the second insertion hole and can be slidably coupled to the protrusion.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the second pin member is formed between the inner surface of the second die member to form a space corresponding to the shank portion and engaging with the protrusion portion One portion and an outer diameter corresponding to the inner diameter of the second die member may be composed of a second portion integrally connected with the first portion and coupled to the protrusion.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the first portion may be integrally connected with the second portion as an outer diameter corresponding to the inner space of the shank portion.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the second pin member may include a coupling groove connected to the second portion from the first portion and slidably coupled to the protrusion. .

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the first portion may be made of a relatively smaller outer diameter than the second portion.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the first portion may be integrally connected to the second portion through a tapered first support surface.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the third die member may include a cylindrical third die body having a third insertion hole through which the extruded article can be inserted.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the third pin member is inserted into the shank portion of the extrusion molded product, and the end of the shank portion integrally connected to the insertion portion It may be made of a support for supporting.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the insertion portion may be made of a relatively smaller outer diameter than the support portion.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the insertion portion may be integrally connected to the support portion through the second support surface of the tapered form.

In addition, the self-piercing rivet forging apparatus according to the embodiment of the present invention is for forging a self-piercing rivet including a head portion and a shank portion formed with a plurality of slits. 1 die member, ii) a first pin member installed to be inserted into the first die member corresponding to the insertion end of the billet, and forming a centering groove at the insertion end of the billet; A second die member having a plurality of protrusions formed on an inner side thereof, the preform formed being inserted therein; and i) being installed so as to be inserted into the second die member corresponding to an insertion end of the preform. A second pin member coupled to the protrusions and extruding the shank portion; and iii) an extruded article having the shank portion is inserted therein. A third die member having a head forming groove for molding the die portion, and iii) a third pin member installed to be inserted into the third die member corresponding to the insertion end of the extruded article and supporting the extruded article. The second pin member includes a first portion which forms a space corresponding to the shank portion between inner surfaces of the second die member and engages with the protrusion, and corresponds to an inner diameter of the second die member. An outer diameter may include a coupling groove integrally connected with the first portion and coupled to the protrusion, and coupled to the protrusion from the first portion to the second portion, and coupled to the protrusion in a slidable manner.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the protrusion is formed in the form that the cross-sectional width gradually decreases toward the inner center from the inner surface of the second die member is coupled to the coupling groove Can be.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the protrusion may be formed spaced 120 degrees apart on the inner surface of the second die member.

In addition, in the self-piercing rivet forging molding apparatus according to an embodiment of the present invention, the third pin member is inserted into the shank portion of the extrusion molded product, and the end of the shank portion integrally connected to the insertion portion It consists of a support for supporting, the support jaw may be formed on the edge end of the support.

In addition, the self-piercing rivet forging apparatus according to the embodiment of the present invention, forging a self-piercing rivet for joining the bonding objects of the same kind and different materials.

The self-piercing rivet forging apparatus according to an embodiment of the present invention is for forging a self-piercing rivet including a head portion and a shank portion having a plurality of slits, and includes a centering groove at one end of the billet. An extrusion molding unit including a die having a preform formed therein and having a plurality of protrusions formed on an inner side thereof for forming the slit, and a pin coupled to the protrusions and extruding the shank portion, ii) the extrusion molded article And a head forming unit including a die inserted therein and having a head forming groove for forming the head, and a pin inserted into the die and supporting the extruded article.

In addition, the self-piercing rivet forging apparatus according to an embodiment of the present invention includes a pre-forming unit including a die into which the billet is inserted and a pin inserted into the die to form the centering groove at the end of the billet. can do.

An embodiment of the present invention forms a self-piercing rivet that penetrates the upper plate of the self-piercing joining objects and prevents the through portion of the upper plate from being completely sheared in the process of being pressed into the lower plate. can do.

In addition, in an embodiment of the present invention, the piercing portion of the upper plate that is not sheared may be utilized to form a self-piercing rivet that prevents rotation of the upper and lower plates as a single number and improves the bonding strength of the upper and lower plates.

Moreover, in the Example of this invention, the self-piercing rivet which can increase the joint strength of a joining object can be shape | molded, reducing the joining load with respect to the joining object of a lower board.

In addition, in the embodiment of the present invention, the self-piercing rivets with slits formed in the shank portion may be formed by a simple process of preforming, forward extrusion, and head forming, so that the billet upsetting, head forming, forward extrusion, Unlike the general process of forming rivets with a back extrusion (bottom forming) process, the entire molding process of the self-pierce rivets can be shortened.

Therefore, in the embodiment of the present invention, since the entire molding process of the self-piercing rivet in which the slits are formed in the shank part is simple, productivity may be improved and manufacturing cost may be reduced.

In addition, in the embodiment of the present invention, since the centering groove is formed in the billet through the preforming unit, the centering position and the centering of the preform for the second pin member can be achieved in the process of forming the shank portion in the preform through the extrusion molding unit. can do.

Therefore, in the embodiment of the present invention, it is possible to plan and center the preformed part with respect to the second fin member in the forward extrusion process, thereby minimizing the occurrence of burrs due to the intersection of the die and the pin, dimensional accuracy and Self-piercing rivets with good moldability can be produced.

In addition, according to the embodiment of the present invention, as the end portion of the mountain form is formed on the protrusions of the second die member, the moldability is good by easily inducing forward extrusion of the preformed parts to the protrusions, The punch load of the second punch unit can be reduced.

In addition, in the embodiment of the present invention, since the centering groove is formed at the end of the preform and the head is formed last through the head forming unit, the punch load of the second punch unit with respect to the second pin member can be further reduced. .

In addition, in the embodiment of the present invention, the second pin member of the extrusion molding unit has a tapered first support surface connecting the first portion and the second portion, and the insertion portion is provided on the third pin member of the head molding unit. Since the taper-shaped 2nd support surface which connects a support part is provided, the dimensional precision in a front extrusion molding process and a head part molding process can be improved further.

Since these drawings are for reference in describing exemplary embodiments of the present invention, the technical spirit of the present invention should not be construed as being limited to the accompanying drawings.
1 is a perspective view illustrating a self-piercing rivet forged by a self-piercing rivet forging molding apparatus according to an embodiment of the present invention.
2 is a cross-sectional view illustrating a self-piercing rivet forged by a self-piercing rivet forging molding apparatus according to an embodiment of the present invention.
3 is a view schematically showing a self-piercing rivet forging apparatus according to an embodiment of the present invention.
4 is an exploded perspective view showing a preforming unit applied to a self-piercing rivet forging apparatus according to an embodiment of the present invention.
Figure 5 is a plan view showing an extrusion molding unit applied to the self-piercing rivet forging apparatus according to an embodiment of the present invention.
6 is a partially cutaway exploded perspective view illustrating an extrusion molding unit applied to a self-piercing rivet forging apparatus according to an exemplary embodiment of the present invention.
7 is an exploded perspective view illustrating a head forming unit applied to a self-piercing rivet forging apparatus according to an embodiment of the present invention.
8A to 8G are views illustrating a process of forging a self-piercing rivet using a self-piercing rivet forging molding apparatus according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

Such drawings are for reference only to specifically and clearly describe preferred embodiments of the present invention and technical spirit or features, and thus it may be known that the drawings may be different from actual product or facility design specifications.

In addition, since the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of description, the present invention is not necessarily limited to those shown in the drawings, and is shown by enlarging the thickness in order to clearly express various parts and regions. It was.

In the following detailed description, the names of the components are denoted by the first, second, and so on in order to distinguish them from each other in terms of the same names, and are not necessarily limited to those in the following description.

1 is a perspective view illustrating a self-piercing rivet forged by a self-piercing rivet forging molding apparatus according to an embodiment of the present invention, Figure 2 is a cross-sectional view of FIG.

1 and 2, first, before describing the self-piercing rivet forging apparatus according to the embodiment of the present invention, the self-piercing rivet 200 formed by the forging molding apparatus for convenience of description below. Let's introduce).

The self piercing rivet 200 formed by the forging molding apparatus may be applied to a self piercing rivet system (not shown in the drawing) which integrally fastens at least two or more joining objects.

The self-piercing rivet system presses the self-piercing rivet 200 (hereinafter referred to as "rivet" except in exceptional cases) with respect to the bonding objects overlapped with each other at a predetermined pressure, and plastic deformation of these bonding objects and the rivet 200 It consists of a structure that can join the bonding objects as.

For example, the self-piercing rivet system basically includes a C-type frame mounted on the arm of the robot, a punch unit configured on the upper side of the frame, and an anvil unit configured on the lower side of the frame corresponding to the punch unit. Can be.

Since such a self-piercing rivet system is made of a self-piercing rivet device of known art well known in the art, a more detailed description of the configuration will be omitted herein.

Here, the bonding objects bonded by the rivet 200 may include a material such as plastic, rubber, aluminum sheet, steel sheet. Examples of the metal include high tensile steel and aluminum materials having low elongation.

Such joining objects may be plates of the same type of material, or plates of different types of materials.

The rivet 200 as described above is made of a structure that penetrates the upper plate of the bonding objects and does not completely shear the through portion of the upper plate in the process of being pressed into the lower plate so that the penetrating portion can reinforce the bonding strength of the upper and lower plates.

In addition, the rivet 200 is made of a structure that can prevent the rotation of the upper and lower plates as a single number by utilizing the through portion of the upper plate that is not sheared, and can improve the bonding strength of the upper and lower plates.

The rivet 200 has a structure capable of increasing the bonding strength of the bonding object while reducing the bonding load of the upper and lower plates.

The self-piercing rivet 200 applied to the embodiment of the present invention for this purpose basically includes a head portion 1 and a hollow shank portion 3.

The head portion 1 may be formed of a circular plate having a predetermined thickness as a portion receiving the punching pressure of the self-piercing rivet system.

The shank portion 3 penetrates the upper plate by a predetermined punch load, is pressed into the lower plate along the shaping bone of the anvil unit, and deformed outward, and is integrally connected to the head portion 1, Two (two or more) slits 5 are formed.

The opposite end of the shank portion 3 connected to the head portion 1 may be defined as a free end, and the space between the free end and the head portion 1 may be defined as an inner space.

Here, the slits 5 may be formed to have the same length as the entire length of the shank portion 3, may be formed to have a length smaller than the entire length, and an arc based on the inner center of the shank portion 3. It is arranged at equal intervals along the direction.

For example, three slits 5 are provided along the arc direction with respect to the inner center of the shank part 3, and may be spaced apart at intervals of 120 degrees along the arc direction.

The arrangement angle of these slits 5 is set by a simulation test on the basis of the strength range in which buckling does not occur when the shank portion 3 penetrates the upper plate.

The shank portion 3 as described above has a shank body 7 which is integrally connected with the head portion 1 and disposed between the slits 5.

Since the shank body 7 is a part press-fitted into the joining objects, the shank body 7 is generally referred to as the shank portion 3 except for exceptional cases.

Hereinafter, with reference to the accompanying drawings the configuration of the forging apparatus 100 according to an embodiment of the present invention for forming a self-piercing rivet 200 provided with slits 5 in the shank portion 3 as described above It will be described in detail.

3 is a view schematically showing a self-piercing rivet forging apparatus according to an embodiment of the present invention.

Referring to FIG. 3, the self-piercing rivet forging apparatus 100 according to the embodiment of the present invention basically includes a preforming unit 10, an extrusion molding unit 40, and a head forming unit 70. If this is described by configuration, it is as follows.

In the above, the preforming unit 10, the extrusion molding unit 40 and the head forming unit 70 may be installed in the die body 201 which can be moved back and forth and / or as an example.

However, the preforming unit 10, the extrusion molding unit 40 and the head forming unit 70 is not necessarily limited to being installed in all of the die body 201 that can be moved forward and backward and / or liftable, the die body 201 May be configured to be able to move forward and backward and / or move up and down in the die body 201 in a fixed state.

In the embodiment of the present invention, the preforming unit 10 is for preforming the billet (billet 101) cut to a predetermined length as a material for forming the self-piercing rivet 200.

That is, the preforming unit 10 is for molding the centering groove 103 at one end of the billet (101).

The reason why the centering groove 103 is formed at the end of the billet 101 is to attain the precise position and centering of the molding material in a later step, and to reduce the molding load (punch load) in the later step.

4 is an exploded perspective view showing a preforming unit applied to a self-piercing rivet forging apparatus according to an embodiment of the present invention.

3 and 4, the preforming unit 10 according to the embodiment of the present invention includes a first die member 20 and a first pin member 30.

The preforming unit 10 may be configured of the first die member 20 and the first pin member 30 in the die body 201 as mentioned above.

The first die member 20 includes a cylindrical first die body 21 into which the billet 101 can be inserted. A first insertion hole 23 into which the billet 101 may be inserted is formed at the center of the first die body 21.

In the said billet 101, the edge part into which the insertion is made into the 1st insertion hole 23 is called "insertion edge part" below.

The first pin member 30 is for forming the centering groove 103 at the insertion end of the billet 101 by the first punch unit 301 which will be described later.

The first pin member 30 may be installed to be inserted into the first insertion hole 23 corresponding to the insertion end of the billet 101.

In this case, the first pin member 30 has an outer diameter corresponding to the inner diameter of the first insertion hole 23. The first pin member 30 constitutes a conical pin protrusion 31 for forming the centering groove 103 at the insertion end of the billet 101.

The pin protrusion 31 may be formed to protrude in a conical form at the end of the first pin member 30 corresponding to the insertion end of the billet (101).

On the other hand, the first punch unit 301 is provided as a header for pressing (punching) the billet 101 inserted into the first die member 20, the header body 401 corresponding to the first die member 20 Can be configured.

Here, the header body 401 may be provided to move forward and backward with respect to the die body 201, and the first punch unit to the header body 401 with the header body 401 fixed 301 may be provided so that forward and backward and / or lifting is possible.

In addition, the first pin member 30 is installed in the die main body 201 so as to be movable forward and backward corresponding to the first die member 20.

That is, the first pin member 30 supports the billet 101 pressurized by the first punch unit 301 while being inserted into the first die member 20 and has a centering groove ( 103).

And the 1st pin member 30 can push out the billet 101 (preform below) from the 1st insertion hole 23 of the 1st die member 20. As shown in FIG.

To this end, a first pusher 501 is installed on the die body 201 to support and press the first pin member 30 and to push the first pin member 30 from the first die member 20. do.

The first pusher 501 is in contact with the first pin member 30, it may be composed of a known cam means that is rotatably installed in the die body 201.

The centering groove 103 is formed at the insertion end of the billet 101 by the first die member 20, the first pin member 30, the first punch unit 301, and the first pusher 501. Bars having the centering grooves 103 formed at the ends of the billets 101 are referred to as "preformed articles" in the following.

In the embodiment of the present invention, the extrusion molding unit 40 is for molding the shank portion 3 of the self-piercing rivet 200 by extruding the preform 111.

That is, the extrusion molding unit 40 may form the shank portion 3 on which the slits 5 are formed by extruding the preform 111.

5 is a plan view showing an extrusion molding unit applied to the self-piercing rivet forging apparatus according to an embodiment of the present invention, Figure 6 is an extrusion applied to the self-piercing rivet forging molding apparatus according to an embodiment of the present invention A partially cutaway exploded perspective view of a molding unit.

5 and 6 together with FIG. 3 described above, the extrusion molding unit 40 according to the embodiment of the present invention includes a second die member 50 and a second pin member 60, The second die member 50 and the second pin member 60 may be configured in the die body 201.

The second die member 50 includes a cylindrical second die body 51 into which the preform 111 may be inserted.

A second insertion hole 53 into which the preform 111 may be inserted is formed at the center of the second die body 51.

In the said preform 111, the edge part inserted into the 2nd insertion hole 53 of the 2nd die body 51 is called "insertion edge part" below.

In an embodiment of the present invention, a plurality of protrusions 55 are formed on the inner side (inner circumferential surface) of the second die body 51 to form the slits 5 on the shank portion 3.

The protrusions 55 protrude integrally with the inner surface of the second die body 51 in a length corresponding to the slit 5 of the shank portion 3.

The protrusion 55 is radially disposed toward the center of the second insertion hole 53 at the inner side of the second die body 51 and corresponds to the slit 5 of the shank portion 3. The inner circumferential surface of the body 51 is formed spaced apart by 120 degrees.

In this case, the protrusion part 55 may have a shape in which the cross-sectional width gradually decreases toward the center of the second insertion hole 53 from the inner surface of the second die body 51.

The reason why the protrusions 55 are configured in this manner is to improve strength problems such as breaking of the protrusions 55 due to the punch load of the second punch unit 302.

In addition, the protrusion part 55 may have an end portion (an upper end portion when referring to the drawing) corresponding to the insertion end of the preform 111 in the form of a mountain.

That is, the ends of the protrusions 55 form oblique oblique sides inclined in both directions with respect to the center.

The reason why the end portion of the protrusion part 55 is formed in the form of a mountain as described above facilitates the forward extrusion of the preform 111 to the protrusion part 55, and the punch load of the second punch unit 302 which will be described later. This is to reduce the

 In an embodiment of the present invention, the second pin member 60 is for molding the shank portion 3 to the preform 111 by the second punch unit 302.

The second pin member 60 is installed to be inserted into the second insertion hole 53 of the second die body 51 corresponding to the insertion end of the preform 111.

In this case, the second pin member 60 is inserted into the second insertion hole 53 of the second die body 51, coupled to the protrusions 55 of the second die body 51, and the shank portion. (3) can be extrusion-molded.

The second pin member 60 is inserted into the second insertion hole 53 of the second die body 51 and slidably coupled to the protrusions 55. The second pin member 60 includes a first portion 61 and a second portion 62 integrally connected to the first portion 61.

The first portion 61 is integrally connected with the second portion 62 as an outer diameter corresponding to the inner space of the shank portion 3, and thus the shank portion 3 is formed between the inner surfaces of the second die body 51. It forms a space (S) corresponding to) and can be combined with the protrusions (55).

In addition, the second portion 62 may be integrally connected to the first portion 61 as an outer diameter corresponding to the inner diameter of the second die body 51 and may be coupled to the protrusions 55.

That is, since the first portion 61 has an outer diameter corresponding to the inner space of the shank portion 3, and the second portion 62 has an outer diameter corresponding to the inner diameter of the second die body 51, The first portion 61 has a smaller outer diameter than the second portion 62.

Here, the first portion 61 and the second portion 62 may be integrally connected through the tapered first support surface 64.

The first support surface 64 supports an end portion of the shank portion 3 and has an outer diameter gradually decreasing from the second portion 62 to the first portion 61.

The second fin member 60 according to an embodiment of the present invention is connected from the first portion 61 to the second portion 62, and slidable to the protrusions 55 of the second die body 51. It includes a coupling groove 66 to be coupled.

At this time, the protrusions 55 may be coupled to the coupling groove 66 with a cross-sectional portion corresponding to the inner center of the second die body 51 with respect to the first portion 61, and the second portion 62. ), The entire protrusion thickness may be coupled to the coupling groove 66.

On the other hand, the second punch unit 302 is provided as a header for pressing (punching) the preform 111 inserted into the second die member 50, the header body corresponding to the second die member 50 401 may be configured.

Here, the second punch unit 302 may be provided in the header body 401 provided to be able to move forward and backward with respect to the die body 201, the header body 401 is fixed The header body 401 may be provided forward and backward and / or liftable.

In addition, the second pin member 60 is installed in the die main body 201 so as to be movable forward and backward corresponding to the second die member 50.

That is, the second pin member 60 supports the preform 111 pressurized by the second punch unit 302 while being inserted into the second die member 50 and extrudes the preform 111. The crochet part 3 can be shape | molded.

In addition, the second pin member 60 may push out the preform 111 (the extruded article below) from the second insertion hole 53 of the second die member 50.

To this end, a second pusher 502 is installed on the die body 201 to support and press the second pin member 60 and to push the second pin member 60 out of the second die member 50. do.

The second pusher 502 is in contact with the second pin member 60, it may be composed of a cam means of a conventional technique rotatably installed in the die body 201.

In the above, the preform 111 is extruded through the second die member 50, the second pin member 60, the second punch unit 302, and the second pusher 502 to form the shank portion 3. Now, what the shank part 3 was shape | molded in this way is called "extrusion molding article" below.

In the embodiment of the present invention, the head molding unit 70 is for molding the head portion 1 of the self-piercing rivet 200 to the extrusion molded article 121 extruded from the extrusion molding unit 40.

7 is an exploded perspective view illustrating a head forming unit applied to a self-piercing rivet forging apparatus according to an embodiment of the present invention.

3 and 7, the head forming unit 70 according to the embodiment of the present invention includes a third die member 80 and a third pin member 90, and thus, a third die member 80. ) And the third pin member 90 may be configured in the die body 201.

The third die member 80 includes a cylindrical third die body 81 into which the extruded article 121 may be inserted.

A third insertion hole 83 into which the extruded article 121 may be inserted is formed at the center of the third die body 81.

In the extruded molded article 121, an end inserted into the third insertion hole 83 of the third die body 81 is referred to as an "insertion end" below.

Here, at one end of the third die body 81, that is, the insertion portion of the extruded article 121, a head forming groove 85 for molding the head portion 1 at an end opposite to the insertion end of the extruded article 121. ) Is formed.

The head forming groove 85 is formed to be inclined outward from the edge of the third insertion hole (83).

In the embodiment of the present invention, the third pin member 90 is for molding the head portion 1 to the extruded article 121 by the third punch unit 303 which will be described later, the extruded article 121 The insertion end of the third die body 81 is inserted into the third insertion hole 83 so as to correspond to the insertion end.

In this case, the third pin member 90 may be inserted into the third insertion hole 83 of the third die body 81 to support the extruded article 121.

The third pin member 90 is composed of an insertion portion 91 and a support portion 92. The insertion portion 91 is a portion to be inserted into the shank portion 3 of the extrusion molded article 121, and the support portion 92 ) Is a portion that is integrally connected to the insertion portion 91 and supports the end of the shank portion (3).

In the insert 91 is made of an outer diameter corresponding to the inner diameter of the shank portion 3, the support 92 is made of an outer diameter corresponding to the inner diameter of the third die body 81, the insertion portion 91 Has an outer diameter relatively smaller than the support portion 92.

Here, the insertion portion 91 and the support portion 92 may be integrally connected through the tapered second support surface 94.

The second support surface 94 supports the end of the shank portion 3, and the outer diameter of the second support surface 94 gradually decreases from the support portion 92 to the insertion portion 91.

At the edge end of the support part 92 connected to the second support surface 94, a support jaw 96 is formed to substantially support the end of the shank part 3.

On the other hand, in the above, the third punch unit 303 is provided as a header for pressing (punching) the extruded article 121 inserted into the third die member 80, the header body corresponding to the third die member 80 401 may be configured.

Here, the third punch unit 303 may be provided in the header body 401 provided to be able to move forward and backward with respect to the die body 201, and the header body 401 is fixed The header body 401 may be provided forward and backward and / or liftable.

In addition, the third pin member 90 is installed in the die body 201 so as to be able to move forward and backward in correspondence with the third die member 80.

That is, the third pin member 90 supports the extruded article 121 pressurized by the third punch unit 303 while being inserted into the third die member 80 and extrudes the extruded article 121 to the head. The part 1 can be shape | molded.

In addition, the third pin member 90 may push out the extruded article 121 from the third insertion hole 83 of the third die member 80.

To this end, a third pusher 503 is installed on the die body 201 to support and press the third pin member 90 and to push the third pin member 90 from the third die member 80. do.

The third pusher 503 is in contact with the third pin member 90, it may be composed of a cam means of the known art rotatably installed in the die body 201.

Hereinafter, with reference to the accompanying drawings a forging process of the self-piercing rivets using the forging apparatus 100 according to an embodiment of the present invention configured as described above will be described in detail.

8A to 8G are views illustrating a process of forging a self-piercing rivet using a self-piercing rivet forging molding apparatus according to an embodiment of the present invention.

First, according to the embodiment of the present invention, as shown in FIG.

Then, the billet 101 is preformed, the billet 101 in a state in which the first pin member 30 is set in the first insertion hole 23 of the first die member 20 as shown in Figure 8b Is inserted into the first insertion hole (23).

At this time, the first pusher 501 (see FIG. 3 below) supports the first pin member 30 and has a conical shape at the end of the first pin member 30 corresponding to the insertion end of the billet 101. The pin protrusion 31 is provided.

Subsequently, in the embodiment of the present invention, the billet 101 (see FIG. 8B) is pressurized (punched) through the first punch unit 301 as shown in FIG. 8C.

Then, the insertion end of the billet 101 may be pressed to the pin protrusion 31 of the first pin member 30 to form the centering groove 103 at the insertion end thereof.

After the centering groove 103 is formed in the billet 101 as described above, the first pusher 501 presses the first pin member 30, whereby the first pin member 30 is formed at the end thereof. The preform 111 formed with the 103 is pushed out of the first insertion hole 23 of the first die member 20.

The next process is a forward extrusion process, in which the second pin member 60 is set in the second insertion hole 53 of the second die member 50 as shown in FIG. 8D.

Referring to the setting process of the second die member 50 and the second pin member 60 as described above in detail, in the embodiment of the present invention, the second pin member 60 to the second insertion hole (53) In the inserting process, the coupling groove 66 of the second pin member 60 is coupled to the protrusions 55 of the second die member 50.

Accordingly, the second pin member 60 is slidably coupled to the protrusions 55 to form a space (S: see FIG. 5 below) between the inner surfaces of the second die body 51 except for the protrusions 55. do.

Then, the preform 111 is moved from the first die member 20 to the second die member 50, and the preform 111 is inserted into the second insertion hole 53 of the second die member 50. do.

Accordingly, the preform 111 maintains a state in which the centering groove 103 is in the state facing the first portion 61 of the second pin member 60 and spans the protrusions 55, and the second pusher ( 502: see FIG. 3 hereinafter) supports the second fin member 60.

Next, in the exemplary embodiment of the present invention, the preform 111 (see FIG. 8D) is pressurized (punched) through the second punch unit 302 as shown in FIG. 8E.

Then, as the preform 111 is pressed by the second punch unit 302, the shank portion is extruded forward into the space S except for the second pin member 60 and the protrusions 55 (refer to FIG. 8D). (3) is formed.

In this process, since the centering groove 103 is formed at the end of the preform 111, the preform 111 is formed by the first portion of the second fin member 60 through the centering groove 103. 61 in position, it is possible to maintain the centering on the first portion (61).

In addition, since the centering groove 103 is formed at the end of the preform 111, the punch load of the second punch unit 302 with respect to the second pin member 60 may be further reduced.

Here, in the process where the preform 111 is extruded by the second punch unit 302, a plurality of slits 5 are formed in the shank part 3 by the protrusions 55.

In this case, by forming the end of the protrusions 55 in the form of a mountain, it is possible to easily guide the front extrusion of the preform 111 to the protrusions (55).

In addition, in the embodiment of the present invention, since the first portion 61 and the second portion 62 of the second fin member 60 are integrally connected through the tapered first support surface 64, 1 While the support surface 64 supports the shank portion 3, the dimensional accuracy of the shank portion 3 can be increased.

Furthermore, in the embodiment of the present invention, since the protrusions 55 gradually take the form of the cross-sectional width gradually decreasing from the inner side of the second die member 50 toward the center of the second insertion hole 53, the second Strength problems such as cracking of the protrusion part 55 by the punch load of the punching unit 302 can be improved.

After the preform 111 is thus extruded forward to form the shank portion 3, the second pusher 502 presses the second fin member 60, and the second fin member 60 is the shank portion ( The extruded molded article 121 formed with 3) is pushed out from the second insertion hole 53 of the second die member 50.

Next, in the embodiment of the present invention, the head portion 1 is molded to the extruded article 121 as shown in FIGS. 8F and 8G.

In the head forming process described above, first, the third pin member 90 is set in the third insertion hole 83 of the third die member 80 as shown in FIG. 8F.

Then, the extruded article 121 is moved from the second die member 50 toward the third die member 80 and the extruded article 121 is inserted into the third insertion hole 83.

Thus, the insertion portion 91 of the third pin member 90 is inserted into the shank portion 3 of the extruded article 121, and the end of the shank portion 3 is supported by the support portion 92. Maintain the state supported by (96). In this case, the third pusher 503 (see Fig. 3 hereinafter) supports the third pin member 90.

Next, in the embodiment of the present invention is pressed (punching) the extrusion molded article 121 through the third punch unit 303 as shown in Figure 8g.

Then, the portion opposite to the insertion end side of the extruded molded article 121 is pressed by the third punch unit 303, compressively deformed along the head forming groove 85 of the third die member 80, and the head portion 1. ) Will be molded.

Here, in the embodiment of the present invention, since the insertion portion 91 and the support portion 92 of the third pin member 90 are integrally connected through the second support surface 94 having a tapered shape, the second support surface While the 94 supports the shank portion 3, the dimensional accuracy due to the molding of the extruded article 121 can be improved.

Therefore, the forging molding apparatus 100 according to the embodiment of the present invention forging the self-piercing rivet 200 formed with a plurality of slits 5 in the shank portion 3 through a series of operation process as described above. You can do it.

According to the self-piercing rivet forging apparatus 100 according to the embodiment of the present invention as described above, by forming the centering groove 103 in the billet 101 through the preforming unit 10, the extrusion molding unit The shank portion 3 may be molded into the preform 111 through 40, and the head portion 1 may be molded into the extruded article 121 through the head molding unit 70.

Therefore, in the embodiment of the present invention, the self-piercing rivet 200 in which the slits 5 are formed in the shank portion 3 may be formed by a simple process of preforming, forward extrusion, and head forming. Unlike the general process of forming rivets by upsetting, head forming, front extrusion, and back extrusion (low molding) processes, the entire forming process of the self-piercing rivets can be shortened.

Thus, in the embodiment of the present invention, since the entire molding process of the self-piercing rivet 200 in which the slits 5 are formed in the shank portion 3 is simple, productivity may be improved and manufacturing cost may be reduced.

On the other hand, according to the self-piercing rivet forging apparatus 100 according to an embodiment of the present invention, since the centering groove 103 is formed in the billet 101 through the preforming unit 10, the extrusion molding unit 40 Through the forming of the shank portion (3) in the preform 111 through the second pin member 60 can be positioned in the correct position and the centering.

Therefore, in the embodiment of the present invention, it is possible to plan and center the preform 111 relative to the second fin member 60 in the forward extrusion process, thereby minimizing the occurrence of burrs due to the intersection of the die and the pin. It is possible to manufacture a self-piercing rivet 200 having good dimensional accuracy and formability.

In addition, according to the embodiment of the present invention, as the end portion of the mountain form is formed in the protrusions 55 of the second die member 50, the front extrusion of the preform 111 to the protrusions 55 is easily induced. As a result, the moldability is good, and the punch load of the second punch unit 302 against the second pin member 60 can be reduced.

In addition, in the embodiment of the present invention, since the centering groove 103 is formed at the end of the preform 111, and the head part 1 is formed later through the head forming unit 70, the second pin member 60 is formed. It is possible to further reduce the punch load of the second punch unit 302 relative to).

In the embodiment of the present invention, the tapered first support surface 64 connecting the first portion 61 and the second portion 62 to the second pin member 60 of the extrusion molding unit 40 is provided. And a tapered second support surface 94 that connects the insertion portion 91 and the support portion 92 to the third pin member 90 of the head forming unit 70, thereby forward extrusion molding process and The dimensional accuracy in the head molding process can be further improved.

On the other hand, since the self-piercing rivet 200 formed by the forging molding apparatus 100 as described above forms a plurality of slits 5 in the shank portion 3, the self-piercing rivet 200 penetrates into the lower plate while penetrating the upper plate of the joining objects. By preventing the through portion of the upper plate from shearing completely during the process, the through portion can reinforce the bonding strength of the upper and lower plates.

In addition, the self-piercing rivet 200 may prevent the rotation of the upper and lower plates as a single number by utilizing the through portion of the upper plate that is not sheared, and may improve the bonding strength of the upper and lower plates.

The self-piercing rivet 200 may increase the bonding strength of the bonding object while reducing the bonding load of the upper and lower plates to the bonding object.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And it goes without saying that the invention belongs to the scope of the invention.

1 ... head 3 ... shank
5 ... slit 7 ... shank body
10 ... preforming unit 20 ... first die member
21 ... 1st die body 23 ... 1st insertion hole
30 ... First pin member 31 ... Pin protrusion
40 ... extrusion molding unit 50 ... second die member
51 ... 2nd die body 53 ... 2nd insert hole
55 ... protrusion 60 ... second pin member
61 ... First Part 62 ... Second Part
64 ... 1st support surface 66 ... Engagement groove
70 ... head forming unit 80 ... third die member
81 ... 3rd die body 83 ... 3rd insertion hole
85 Head molding groove 90 Third pin member
91 ... Insert 92 ... Support
94. 2nd support surface 96 ... Supporting jaw
101 ... Billet 103 ... Centering Home
111 ... Preform 121 ... Extrusion
200 ... Self Piercing Rivet 201 ... Die Body
301 ... First Punch Unit 302 ... Second Punch Unit
303 ... 3rd Punch Unit 401 ... Header Body
501 ... the first pusher 502 ... the second pusher
503 ... Third Pusher

Claims (21)

A self-piercing rivet forging molding apparatus for forging a self-piercing rivet including a head portion and a shank portion having a plurality of slits,
A first die member into which a cylindrical billet is inserted;
A first pin member installed to be inserted into the first die member corresponding to the insertion end of the billet and forming a centering groove at the insertion end of the billet;
A second die member into which the preformed product having the centering groove is inserted, and having a plurality of protrusions formed on the inner side for forming the slit;
A second pin member installed to be inserted into the second die member corresponding to the insertion end of the preform, the second pin member coupled to the protrusions and extruding the shank portion;
A third die member into which the shank portion is formed, into which an extrusion molded article is inserted, and which has a head forming groove for forming the head portion; And
A third pin member installed to be inserted into the third die member corresponding to an insertion end of the extruded article and supporting the extruded article
Self-piercing rivet forging molding apparatus comprising a. The method according to claim 1,
A first punching unit provided corresponding to the first die member and pressing the billet inserted into the first die member;
A second punch unit provided corresponding to the second die member and for pressing the preform inserted into the second die member;
A third punching unit provided corresponding to the third die member to press the extruded article inserted into the third die member;
Self piercing rivet forging molding apparatus comprising a. The method according to claim 1,
A first pusher supporting the first pin member and pushing the first pin member away from the first die member;
A second pusher that supports the second pin member and pushes the second pin member away from the second die member;
A third pusher that supports the third pin member and pushes the third pin member away from the third die member
Self-piercing rivet forging molding apparatus comprising a. The method according to claim 1,
The first die member includes a cylindrical first die body having a first insertion hole into which the billet can be inserted.
The first pin member is a self-piercing rivet forging molding apparatus including a conical pin projection for forming the centering groove at the insertion end of the billet. The method according to claim 1,
The protruding portion
Protruding integrally with the inner surface of the second die member as a length corresponding to the slit,
Self-piercing rivet forging apparatus disposed radially from the inner side of the second die member toward the inner center. The method according to claim 1,
The protruding portion
Self-piercing rivet forging molding device formed in the form that the cross-sectional width gradually decreases toward the inner center from the inner side of the second die member. The method according to claim 1,
The protruding portion
A self-piercing rivet forging molding apparatus in which an end portion corresponding to an insertion end of the preform is formed in an acid form. The method according to claim 1 or 4,
The second die member may include a second die body having a cylindrical shape having a second insertion hole into which the preform may be inserted.
The second pin member is inserted into the second insertion hole and the self-piercing rivet forging molding device is slidably coupled to the protrusion. The method according to claim 1,
The second pin member,
A first portion forming a space corresponding to the shank portion between inner surfaces of the second die member and engaging with the protrusion portion;
A second portion integrally connected with the first portion and coupled with the protrusion as an outer diameter corresponding to an inner diameter of the second die member;
Self-piercing rivet forging molding device consisting of. 10. The method of claim 9,
The first portion,
Self-piercing rivet forging molding apparatus is integrally connected to the second portion as the outer diameter corresponding to the inner space of the shank portion. 10. The method of claim 9,
The second pin member,
Self-piercing rivet forging apparatus is connected to the first portion from the second portion, including a coupling groove slidably coupled to the projection. 10. The method of claim 9,
The first portion,
Self-piercing rivet forging molding device having an outer diameter relatively smaller than the second portion, and is integrally connected to the second portion through a tapered first support surface. The method of claim 8,
The third die member may include a third die body having a cylindrical shape having a third insertion hole into which the extruded article may be inserted.
The third pin member is a self-piercing rivet forging molding device comprising an insertion portion inserted into the shank portion of the extruded product and a support portion integrally connected to the insertion portion and supporting the end portion of the shank portion. The method of claim 13,
The insertion unit,
Self-piercing rivet forging molding device is made of a relatively smaller outer diameter than the support portion, and is integrally connected to the support portion through a tapered second support surface. A self-piercing rivet forging molding apparatus for forging a self-piercing rivet including a head portion and a shank portion having a plurality of slits,
A first die member into which a cylindrical billet is inserted;
A first pin member installed to be inserted into the first die member corresponding to the insertion end of the billet and forming a centering groove at the insertion end of the billet;
A second die member into which the preformed product having the centering groove is inserted, and having a plurality of protrusions formed on the inner side for forming the slit;
A second pin member installed to be inserted into the second die member corresponding to the insertion end of the preform, the second pin member coupled to the protrusions and extruding the shank portion;
A third die member into which the shank portion is formed, into which an extrusion molded article is inserted, and which has a head forming groove for forming the head portion; And
A third pin member installed to be inserted into the third die member corresponding to an insertion end of the extruded article and supporting the extruded article,
The second pin member is:
A first portion which forms a space corresponding to the shank portion between inner surfaces of the second die member and engages with the protrusion, and is integrally connected to the first portion as an outer diameter corresponding to an inner diameter of the second die member; And a second portion engaging with the protrusion;
Self-piercing rivet forging apparatus is connected to the first portion from the second portion, including a coupling groove slidably coupled to the projection. The method of claim 15,
The protruding portion
Self-piercing rivet forging apparatus is formed in the form of the cross-sectional width gradually decreases toward the inner center from the inner side of the second die member is coupled to the coupling groove. 17. The method of claim 16,
The protruding portion
Self-piercing rivet forging molding apparatus is formed on the inner surface of the second die member spaced 120 degrees apart. 17. The method according to claim 15 or 16,
The third pin member,
An insertion portion inserted into the shank portion of the extruded article and a support portion integrally connected to the insertion portion and supporting an end portion of the shank portion,
Self-piercing rivet forging molding device that the support jaw is formed on the edge end of the support. The method according to claim 1 or 15,
Self-piercing rivet forging apparatus for forging a self-piercing rivet for joining joining objects of the same or different materials. A self-piercing rivet forging molding apparatus for forging a self-piercing rivet including a head portion and a shank portion having a plurality of slits,
An extruded molding including a die having a centering groove formed at one end of the billet and having a plurality of protrusions formed on an inner side thereof for forming the slit, and a pin coupled to the protrusions and extruding the shank portion. unit; And
A head forming unit including a die into which the extruded article is inserted and provided with a head forming groove for forming the head part, and a pin inserted into the die to support the extruded article
Self piercing rivet forging molding apparatus comprising a. 21. The method of claim 20,
A preforming unit including a die into which the billet is inserted and a pin inserted into the die and forming the centering groove at an end of the billet
Self piercing rivet forging molding apparatus comprising a.

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