JPH08168926A - Feeder device for rivet - Google Patents

Abstract

PURPOSE: To align push type rivets quickly and accurately in a target attitude and supply them continuously. CONSTITUTION: A screw track 16 having the width a little larger than the outside diameter of a head part 9 of a pus type rivet 1 is upward formed into a spiral shape along the reverse truncated cone-shaped peripheral surface from a part supplying part on the center part on the bottom part, and a straight track 18 is connected to the terminal part of the screw track, so as to constitute a ball feeder 14. A guide groove 19 gradually inclined downward, and whose terminal width is set larger than the outside diameter of a rivet main body 2 of the push-type rivet 1, and smaller than the outside diameter of a flange part 8 is formed on the terminal of the screw track 16, and a wide groove 22 having the same width as the terminal of the guide groove 19 is formed on the straight track 18.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rivet parts feeder, and more particularly to a feeder device for aligning a push-type rivet, which comprises a rivet body and a headed pin for driving the rivet body to push open the leg pieces. Regarding

[0002]

2. Description of the Related Art A push-type rivet arranged by a feeder device according to the present invention has a structure as shown in FIG. 1 is a push rivet type bed made of a synthetic resin, and a cylindrical rivet body 2 having a bottom 3.
And a pin 5 inserted into the hollow portion 4 of the rivet body 2. In the rivet main body 2, a plurality of vertically split grooves 6 are radially inserted from the bottom portion 3 thereof to form a plurality of elastic leg-opening pieces 7, and a flange portion is formed on the outer periphery of the upper end portion. 8 is provided.

[0003] The pin 5 has a total length longer than the entire length of the hollow portion 4 of the rivet body 2, and a head 9 having a diameter larger than the outer diameter of the pin 5 is provided at the upper end thereof.
On the lower surface of the head 9, a recess 9a is formed in which the flange 8 of the rivet main body 2 can be immersed. Then, the rivet main body 2 and the pin 5 with the head 9 are inserted into the hollow portion 4 of the rivet main body 2 from the tip end thereof to the state shown in FIG.

In the method of using the push type rivet 1, when the head 9 of the pin 5 is strongly pressed in the direction of the arrow from the state shown in FIG. 8, the tip of the pin 5 descends and the bottom 3 of the rivet body 2 is pushed. By penetrating the vertical split groove 6 formed in the above, and expanding the plurality of opening leg pieces 7 outwardly around the rear surface of the mounting hole 12, the two plates 10 and 11 are opened with the flange portion 8 of the rivet body 2. The legs 7 sandwich the legs from above and below and fasten them together.

[0005]

The above-mentioned problems were solved by hand, but since the length of this push-type rivet is as small as 20 mm or less, the work efficiency is poor. In order to mechanically perform the rivet setting operation with a push gun or the like, it has been desired to develop a device for aligning and delivering the push type rivet 1 so as to face a certain direction.

[0006]

The present invention has been made based on the above demands, and its gist is to provide a cylindrical rivet body having a flange portion on the outer circumference of the upper end portion. And a headed pin assembled by being inserted into the hollow portion of the rivet body, and by pushing in the headed pin, a plurality of open leg pieces formed in the lower portion of the rivet body expand outwardly. In a feeder for aligning push-type rivets configured to fix two members, a portion slightly larger than the outer diameter of the head of the push-type rivet along the peripheral surface of the inverted frustoconical shape from the component supply portion at the bottom center. When the screw track is formed in a spiral shape facing upward, a straight track is connected to the terminal end of the screw track to form a ball feeder, and the screw track is formed at the end of the screw track. When a guide groove is formed which is gradually inclined downward and whose end width is set to be larger than the outer diameter of the rivet body and smaller than the outer diameter of the flange portion, the straight track has the same width as the end width of the guide groove. A rivet feeder is characterized in that a wide groove is formed.

[0007]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in FIGS. 1 to 7. In the drawings, 14 is a ball feeder for aligning the push rivets 1 having the structure shown in FIG. As shown in FIG. 2, the screw track 16 is formed in a spiral shape upward from the flat part supply part 15 at the center of the bottom along the inner peripheral surface of the inverted truncated cone shape. Guide walls 17 are provided on both sides of the. Here, the width of the screw track 16 is set to be slightly larger than the outer diameter of the head 9 of the push-type rivet 1, and the straight track 18 is provided at the end of the ball feeder 14 to form the ball feeder 14. Fixed in a straight line in the tangential direction of.

At the end of the screw track 16, there is formed a guide groove 19 which is gradually inclined downward toward the straight track 18 and has an arc-shaped bottom surface. The length is substantially the same as the entire length of the push-type rivet 1, and the width at the end of the guide groove 19 is set to be larger than the outer diameter of the rivet body 2 of the push-type rivet 1 and smaller than the diameter of the flange portion 8, In addition, the depth at the end of the guide groove 19 is set to about の of the outer diameter of the rivet body 2.

The straight track 18 connected to the end of the ball feeder 14 has a wide groove 22 and a narrow groove 2 from its starting end 20 toward its terminating end (outlet) 21.
3 are continuously formed. And the wide groove 22
Is set to have the same width as the end width of the guide groove 19 and the length and depth of about the entire length of the push-type rivet 1, and the narrow groove 23 is slightly smaller than the outer diameter of the pin 5 of the push-type rivet 1. The width is wide and the thickness is smaller than the distance between the upper surface of the flange portion 8 and the lower surface of the head portion 9 of the push-type rivet 1. The wide groove 22 and the narrow groove 2
Numerals 3 are connected by an inclined wall 24 so that the push type rivet 1 can move smoothly.

Further, a head restraint 25 of the push-type rivet 1 is provided directly above the narrow groove 23,
The lower surface of the head restraint 25 and the straight track 18
Is set slightly larger than the height of the head 9 of the push-type rivet 1.

Reference numeral 26 denotes an escape unit (a unit for supplying the push type rivet 1 to the next device),
The push-type rivet 1 is supplied to a predetermined place (the above-mentioned push gun) one by one from the outlet 21 of 8.
That is, a deep groove 28 is formed in the fixed base 27 installed at the delivery port 21 of the straight track 18 by right and left side walls 29 in a direction orthogonal to the delivery direction of the straight track 18. The slide body 30 is a pneumatic cylinder and is arranged so as to reciprocate vertically in the drawing.

Then, on the slide body 30,
A catcher arm 31 is rotatably pivoted by a stop screw 32 at a base end thereof, and a spring 3 stretched between the slide body 30 and the catcher arm 31.
3, it is urged in the left rotation direction in the figure. On the right side of the catcher arm 31, a hook 34 is provided at a position corresponding to the outlet 21 of the straight truck 18 for receiving and suspending one push-type rivet 1.

Although not shown, the slide body 3 is also provided.
0 has a circular hole in which the push type rivet 1 can be dropped at a position corresponding to the hook portion 34, and the hook of the catcher arm 31 when the slide body 30 moves is formed. Part 34 and slide body 3
A guide tube 35 on which the push-type rivet 1 falls is provided at the forward position of the circular hole 0, and the guide tube 35 is connected to the above-mentioned push gun via a flexible pipe.

On the surface of the free end of the catcher arm 31, a stopper 36 having the same width as the width of the groove 28 of the fixed base 27 is rotatably pivotally mounted by a set screw 37. And catcher arm 31
Are biased in the counterclockwise direction by a spring 38 stretched between them, and are stopped by a stopper pin 39 standing upright from the catcher arm 31.

Reference numeral 40 denotes a flat cam fixed on the left side wall 29 of the fixed base 27, the upper end of which is formed as an acute angle portion 40a. In normal times, the catcher arm 31 has the left end of the stopper 36 as the flat cam. By abutting against the right side surface of the spring 40, the hook portion 34 resists the elasticity of the spring 33, and the hook portion 34 of the straight track 18 is delivered.
1 and the left end of the stopper 36 is moved to the acute angle portion 40 a of the flat cam 40 by the advance of the slide body 30.
The catcher arm 31 is set so as to rotate counterclockwise by the elastic force of the spring 33 when it is disengaged from.

Reference numeral 41 denotes a stopper fixed to the slide body 30 for closing the delivery port 21 of the straight track 18 and stopping the subsequent push type rivet 1 from being discharged when the slide body 30 advances. belongs to.

Next, the operation of the above embodiment will be described. When a large amount of push-type rivets 1 are put into the component supply section 15 of the ball feeder 14 and a magnetic vibration is applied to the ball feeder 14, the component supply section will be described. From 15, the push-type rivets 1 enter one by one toward the entrance 16 </ b> A of the screw truck 16. At this time, the push-type rivet 1 is transported in tandem with the screw track 16 toward the terminal end with either the rivet body 2 or the head 9 facing forward.

At the end of the screw track 16, the rivet body 2 of the push-type rivet 1 is reached.
3, the rivet body 2 is introduced into the guide groove 19, falls into the wide groove 22 of the straight track 18, and stands upright, as shown in FIG. In this state, it enters the narrow groove 23 and is conveyed in tandem toward the terminal end (outlet) 21.

The head 9 of the push type rivet 1
When the end of the ball feeder 14 is directed forward, as shown in FIG.
The peripheral edge of the head portion 9 moves while sliding on the left and right side edges of the guide groove 18 of the ball feeder 14 and the left and right side edges of the wide groove 22 of the straight track 18, so that the rivet body 2 moves into the wide groove 22 of the straight track 18. When dropped, it becomes upright. Subsequent operations are the same as those in the above embodiment.

Here, the straight track 18 is
Although it vibrates together with the screw track 16, the vibration mode is different due to the difference in shape between the two, so that the traveling speed of the push type rivet 1 entering the straight track 18 decreases, and the push-type rivet 1 of the ball feeder 14 moves on the screw track 16. The traveling speed of the mold rivet 1 is fast. Due to this difference in speed, the straight track 18
When the periphery of the head 9 of the push type rivet 1 immediately after enters the lower surface of the head 9 of the push type rivet 1 that has entered, the entanglement of the front and rear push type rivets 1 occurs, which hinders the subsequent parts supply work. May be caused.

However, the push-type rivet 1 which has fallen into the wide groove 22 of the straight track 18 and is in an upright state enters the narrow groove 23 in this state, and thereby the flange 8 of the push-type rivet 1 is formed. The push-type rivet 1 is moved forward and backward in the traveling direction by the presence of the narrow groove 23 between the upper surface of the head 9 and the lower surface of the head holder 25 immediately above the head 9 of the push-type rivet 1. When the jump is prevented without swinging, the push rivet 1 is not pushed up immediately.

The push-type rivet 1 is suspended from the delivery port 21 of the straight track 18 to the hook portion 34 of the catcher arm 31 of the one-piece escape portion 26 and the circular hole of the slide body 30. Then, the slide body 30 is moved forward by the pneumatic cylinder in the direction of the arrow in the figure, and the hook portion 34 of the catcher arm 31 and the circular hole of the slide body 30 become the guide cylinder 35
Right above, the left end of the stopper 36 comes off the right side surface of the flat cam 40, and the catcher arm 31 rotates counterclockwise about the stop screw 32 by the contraction force of the spring 33. As a result, the push type rivet 1 separates from the hook portion 34 of the catcher arm 31 and
It drops to 5 and is sent to a push gun.

[0023]

As described above, the rivet feeder according to the present invention has a cylindrical rivet body having a flange on the outer periphery of the upper end, and a head inserted and assembled into the hollow portion of the rivet body. A push-type rivet for aligning a push-type rivet, wherein the plurality of leg pieces formed at the lower portion of the rivet body are expanded outwardly by the insertion of the pin with the head and the two members are fixed. In the above, a screw track slightly larger than the outer diameter of the head of the push-type rivet is formed spirally from the component supply portion at the bottom center along the peripheral surface of the inverted frustoconical shape, facing upward. A straight track is connected to the end of the screw track to form a ball feeder, and the end of the screw track is gradually lowered and inclined to reduce the end width. A guide groove having a diameter larger than the outer diameter of the main body and smaller than the outer diameter of the flange portion is formed, and a wide groove having the same width as the end width of the guide groove is formed in the straight track. Therefore, the push-type rivet conveyed on the screw track is surely aligned in the desired posture by the guide groove and the wide groove regardless of the posture. In addition, when the narrow groove is connected to the wide groove of the straight track toward the delivery port, the narrow groove is slightly wider than the outer diameter of the pin, and the gap between the upper surface of the flange and the lower surface of the head is small. The push-type rivet that has entered the narrow groove straight track has a narrow width because it is formed to have a smaller thickness and a head restraint is provided directly above the narrow groove at the height position of the head. There are various effects such that the groove and the head restraint prevent jumping out, and the subsequent push-type rivet allows smooth transportation without being pushed up.

[Brief description of drawings]

FIG. 1 is a plan view of a rivet feeder device according to the present invention.

FIG. 2 is an enlarged plan view of a main part of the feeder device.

FIG. 3 is a main part side view for explaining the operation of the feeder device.

FIG. 4 is a main part side view for explaining different operations of the feeder device.

FIG. 5 is an enlarged perspective view of a main part of the feeder device.

FIG. 6 is a plan view of a supply unit connected to a delivery port of the feeder device.

FIG. 7 is a plan view of the supply section during operation.

FIG. 8 is a partial vertical cross-sectional view showing a tightened state of the push-type rivet used in the present invention.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 push type rivet 2 rivet main body 4 hollow part 5 pin 7 open leg piece 8 flange part 9 head 14 ball feeder 15 parts supply part 16 screw track 16A entrance 17 guide wall 18 straight track 18A upper surface 19 guide groove 20 start end 21 feed Exit 22 Wide groove 23 Narrow groove 25 Head holding

Claims (2)

[Claims] 1. A rivet body having a cylindrical portion having a flange on the outer periphery of an upper end portion, and a pin with a head inserted and assembled into a hollow portion of the rivet body. In a feeder for arranging a push type rivet configured such that a plurality of open leg pieces formed at a lower portion of a rivet body expand outward and fix two members, an inverted truncated conical shape is formed from a component supply portion at a bottom center. A screw track slightly larger than the outer diameter of the head of the push type rivet is formed spirally upward along the peripheral surface, and at the end of the screw track, a straight track is connected to connect a ball. A feeder is formed, and the end of the screw track is gradually lowered and inclined so that the end width is larger than the outer diameter of the rivet body and larger than the outer diameter of the flange portion. A rivet feeder device characterized in that a narrow guide groove is formed and a wide groove having the same width as the end width of the guide groove is formed in the straight track. 2. The narrow groove is connected to the wide groove of the straight track toward the delivery port, and the narrow groove is slightly wider than the outer diameter of the pin, and the upper surface of the flange portion and the lower surface of the head portion. 2. The rivet feeder device according to claim 1, wherein the rivet feeder is formed to have a thickness smaller than a distance between the head and the head, and a head restraint is provided at a height position of the head just above the narrow groove.