KR20130134253A - Rivet tool - Google Patents

Abstract

The present invention relates to a rivet tool which can handle a rivet for coupling frames (46) composing a toy robot. In the rivet tool (10), first and second pick-up parts (14, 24) are formed in both ends of a tool body (12). A pair of first protruded plates (16) is extended from the first pick-up part (14) at a right angle to a direction extended from the tool body (12). A first opening part (18) is formed between the pair of first protruded plates (16) in the direction extended from the tool body (12). A first hanging rib (20) is formed on the inner surface of the first protruded plate (16) which is the end of the first opening part (18). The first hanging rib (20) is hung on a separable hanging sill (53) or a second hanging sill (56) of the rivet. The second pick-up part (24) is extended from the opposite side of the first pick-up part (14) in the opposite direction to the extended direction of the first pick-up part (14). A pair of second protruded plates (26) is extended from the second pick-up part (24) in parallel. A second opening part (28) is extended between the pair of second protruded plates (26) in the direction extended from the tool body (12). A spacer plate (32) is formed in the middle of the second opening part (28) in parallel to the second protruded plates (26). A second hanging rib (30) is formed on the inner surface of the second protruded plates (26). According to the present invention, the rivet can be easily separated from coupling holes (48) of the frames (46) using the rivet tool (10) as a lever.

Description

Rivet tool

The present invention relates to a rivet tool, and more particularly, to a rivet tool for mounting and detaching the rivet to the frame to combine the frame constituting the robot toy.

In order to increase the precision of the robot toy, the size of the frame should be small, and thus, the size of the coupling holes formed in the frame should be smaller, and the size of the rivets installed through the coupling holes to couple the frames together should be smaller.

In this way, the size of the rivet decreases, but the strength of the coupling must be kept above a certain value. Therefore, it is very difficult for the operator to hold the rivet by hand and insert it into the joining hole of the frame, or to hold and remove the rivet inserted into the joining hole by hand. It's hard and cumbersome. In particular, when the operator separates the rivets mounted on the joining hole by hand, the operator must hold the small rivet by hand and apply force. There was a problem.

In order to solve such a problem, a prefabricated toy, as shown in the prior art document, uses a separate tool, which is not applicable to all rivets due to the variety of types of rivets joining the frame. There is. Therefore, in the related art, assembly and disassembly of a robot toy are possible only by providing various kinds of tools.

Republic of Korea Patent Publication 10-2011-0133313

The present invention is to solve the conventional problems as described above, it is to be able to insert and remove the rivets to combine the frame with each other in one touch.

According to a feature of the present invention for solving the above problems, the present invention is a rivet tool for mounting and detaching the rivet in the coupling hole formed in the frame, the tool body, and the tool body at one end of the tool body A first catching portion extending in a direction orthogonal to an extending direction and hooked on a separating hook jaw or an end hook jaw formed on the rivet to separate the rivet from the coupling hole, and the first hook on the other end of the tool body; The second pull-out part which protrudes in the opposite direction to the subtracting part and is provided with a spacer plate at the inner center thereof is hooked to the end hook jaw with the spacer plate inserted into the elastic slit formed in the rivet to separate the rivet from the coupling hole. Include.

The first catching portion corresponds to a first protruding plate having a pair extending from the tool body side by side and penetrating therebetween to form a first opening through the tool body in an extending direction of the tool body, and an end portion of the first opening through the tool body. A first hook rib is formed around the inner surface of the first protruding plate, the hook hanger or the end hook of the rivet being formed, and the distance from the first hook rib is greater than the thickness of the hook hanger or the end hook. It includes a stop rib formed on the off.

The first catching portion is provided with a support end to protrude in a direction opposite to the extending direction of the first protrusion plate.

The second catching portion corresponds to a second protruding plate having a pair extending from the tool body side by side and penetrating therebetween to form a second open through portion in an extension direction of the tool body, and an end portion of the second open through portion. A second hook rib is formed around the inner surface of the second protruding plate to be hooked to the second hooking jaw or the end hooking jaw of the rivet, and a spacer plate positioned between the second protruding plates is disposed on the elastic slit formed in the rivet. do.

One side of the tool body is formed with a push-out portion for pushing out the rivets are inserted into the coupling hole of the frame, the push-in portion is inserted into the inside of the rivet to the stop end formed integrally protruding from the tool body inside the rivet A push rod is formed to push the diaphragm.

The fitting portion protrudes so as to protrude in the same direction as the pushing portion, and the fitting portion is formed with a fitting rod that is press-fitted into the rivet at a base end formed integrally with the tool body.

The pushing part and the fitting part extend in the same direction, and are formed to protrude in opposite directions to those of the first pushing part or the second pushing part.

In the rivet tool according to the present invention, the following effects can be obtained.

The rivet tool of the present invention has a configuration that can be mounted to the coupling hole of the frame and a structure that can be separated from the coupling hole, and also can be applied to various types of rivets, so that the assembly and disassembly work of the robot toy is more There is an effect that becomes easy.

Particularly, in the present invention, since the small rivets are hooked to the rivet tool and the rivet tool is operated using the principle of the lever, the operation of separating the rivet from the coupling hole of the frame is relatively easy.

1 is a perspective view showing the configuration of a preferred embodiment of the rivet tool according to the present invention.
Figure 2 is a perspective view showing in detail the configuration of the first pull-out portion constituting an embodiment of the present invention.
Figure 3 is a perspective view showing the configuration of the second catching portion, the pressing portion and the extracting portion constituting an embodiment of the present invention.
Figure 4 is a perspective view showing the appearance of the double riveting process and the process of coupling the two-stage rivet to the coupling hole of the frame using the rivet tool of the embodiment of the present invention.
Figure 5 and Figure 6 is an operating state showing the process of separating the two-stage rivets or three-stage rivets in the frame using an embodiment of the present invention.
7 and 8 is an operational state showing the separation of the double rivets in the frame using the embodiment of the present invention.
Figure 9 and Figure 10 is an operating state showing that the rivet pushed out using the embodiment of the present invention.

Hereinafter, preferred embodiments of the rivet tool according to the present invention will be described in detail with reference to the accompanying drawings. For reference, in the following description, the term "rivet" without a separate reference numeral refers to a two-stage rivet 50, a double-rivet 60, and a three-stage rivet collectively. And since the three-stage rivet is only longer than the two-stage rivet 50, if you use two-stage rivet 50 without any special explanation it can be seen that even three-stage rivets are included.

As shown in the drawings, the rivet tool 10 of the embodiment of the present invention is formed by extending the tool body 12 in one direction. The torso 12 is in the present embodiment is a bar shape having a rectangular cross-section that is empty inside and one side is open, it can be made in various forms such as rod-shaped. The tool body 12 may have a length enough to be held by a worker. The tool body 12 is made by injection molding a synthetic resin material.

One end of the tool body 12 is provided with a first catching portion 14. The first catching portion 14 is formed integrally with the tool body 12. The first protruding plate 16 extends at a predetermined interval in the first catching portion 14. The first protruding plate 16 extends side by side in a direction substantially perpendicular to the extending direction of the tool body 12. A first opening part 18 is formed between the first protrusions 16. The first opening part 18 is formed so as to pass between the first protrusion plate 16 and is also open toward the tip end of the first protrusion plate 16.

A first hook rib 20 is formed to surround the inner surface of the first opening portion 18, that is, the inner surface of the first protrusion plate 16. The first hook rib 20 is formed along an almost end of the first opening portion 18. The first hook rib 20 has an overall semicircular shape.

Stop ribs 22 are formed on the inner surfaces of both side first protruding plates 16 in the first opening portion 18. Each of the stop ribs 22 is formed at a predetermined distance from the first hook rib 20, and the first hook rib 20 is larger than the length of the separation hook 53 of the rivet 50, which will be described below. And the width between the stop rib 22 is formed a little wider. The stop rib 22 serves to prevent the rivet separated from the frame 46 does not randomly escape from the first catching portion 14.

A support end 23 is formed to protrude from the opposite side of the first protrusion plate 16 of the first hook-out portion 14. The support end 23 serves as a support point when the rivets having a relatively long length are separated, that is, three-stage rivets.

On the opposite side of the tool body 12, that is, the end of the opposite tool body 12 in which the first catching portion 14 is formed, a second catching portion 24 is provided. The second catching portion 24 is used to separate the double rivet 60 from the frame 46 to be described below. The second catching portion 24 is also provided with a pair of second protrusions 26 to protrude in a direction substantially perpendicular to the longitudinal direction of the tool body 12. An extension direction of the second protrusion plate 26 may be opposite to an extension direction of the first protrusion plate 16. A second open through portion 28 is formed in the extending direction of the tool body 12 through the second protrusion plate 26. A second hook rib 30 is formed on the inner surface of the end portion of the second opening portion 28, that is, on the inner surface of the second protrusion plate 26. The second hook rib 30 is a portion on which the end hook jaw 64 of the double rivet 60 is hooked.

The spacer plate 32 is provided between the second protrusions 26 in the second opening portion 28. When the spacer plate 32 is inserted into the elastic slit 66 of the double rivet 60 to separate the double rivet 60 from the frame 46, the end hanger jaw 64 of the double rivet 60 is The second hook rib 24 serves to maintain the state of being engaged.

Next, at one side of the middle portion of the tool body 12, the pushing portion 34 is formed to protrude. In the present embodiment, the pushing portion 34 is formed adjacent to the second catching portion 24, and thus, the tool body (to protrude in the opposite direction from which the second catching portion 24 protrudes) 12) is formed. The pusher part 34 is formed integrally with the tool body 12 so that the push bar 38 protrudes from the tip of the stop end 36 protruding from the tool body 12. The push rod 38 is inserted into the rivet and contacts the diaphragm 59 to apply a force in a direction in which the rivet is separated from the frame 46. Here, the plate 59 is formed at about the middle of the inner space of the rivet refers to partitioning the inner space to both sides.

The outer diameter of the push bar 38 is smaller than the inner diameter of the rivet made in a tubular shape. This is for the push bar 38 to easily enter the interior of the rivet. The stop end 36 is spaced between the tool body 12 and the push bar 38 to prevent the tool body 12 from interfering with another frame 46 and the like. It serves to see the tip relatively well. Of course, the stop end 36 is supported at the inlet edge of the engagement hole 48 of the frame 46 after the rivet is removed, and serves to prevent the push rod 38 from moving forward.

The fitting portion 40 is provided adjacent to the pushing portion 34. The fitting portion 40 is formed to protrude in the opposite direction on the opposite side of the second catching portion 24 in the present embodiment. The fitting portion 40 has a similar configuration to the pushing portion 34. That is, the fitting rod 44 extends from the base end 42 integrally protruding from the tool body 12. The fitting rod 44 is made in a rod shape and has an outer diameter larger than that of the pressing rod 38. The outer diameter of the fitting rod 44 is formed slightly larger than the inner diameter of the rivet so as to be pressed into the inner diameter of the rivet. The rivet is inserted into the coupling hole 48 of the frame 46 in a state where the rivet is fitted to the fitting rod 44.

Next, the configuration of the frame 46, the two-stage rivet 50, and the double rivet 60 will be described with reference to FIG. First, the frame 46 is generally made in a plate shape, and may be generally made of a rectangular plate or a plate of various shapes. A plurality of coupling holes 48 are drilled in the frame 46. A plurality of the coupling holes 48 are formed in a row in the frame 46 in a horizontal and vertical direction. A locking jaw 49 is formed at both sides of the inlet of the coupling hole 48. The locking jaw 49 is a portion in which the first and second hooking jaws 54 and 56 or the end hooking jaws 64 of the two-stage rivet 50 and the double rivet 60 to be described below are hooked. Two or three such frames 46 overlap and are joined by rivets.

Next, look at the configuration of the two-stage rivet 50 with reference to FIG. Figure 4 also shows a cross-sectional configuration of the two-stage rivet 50 for reference. As described above, the two-stage rivet 50 is different from the three-stage rivet and has the same configuration. The body portion 52 forms a skeleton of the two-stage rivet 50. The body portion 52 is made of a cylindrical shape, one end is formed with a separation hook jaw (53). The separation hook jaw 53 is formed to protrude in a circular shape surrounding the outer surface of one end of the body portion 52. The separation hook jaw 53 is positioned to protrude out of the coupling hole 48 of the frame 46.

A first hanger jaw 54 is formed adjacent to the separating hanger jaw 53 and surrounds the outer surface of the body part 52. The first hooking jaw 54 is a portion that is hooked to the hooking jaw 49 of the frame 46, and an outer diameter formed by the first hooking jaw 54 is larger than an inner diameter formed by the hooking jaw 49. Is formed. Of course, the outer diameter formed by the first hook jaw 54 is smaller than the outer diameter formed by the separation hook jaw 53.

A second hook jaw 56 is provided at the end of the body portion 52 on the opposite side on which the separation hook jaw 53 is formed. The second hanging jaw 56 has the same dimensions and shape as the first hanging jaw 54 but is divided into several parts by the elastic slit 48. The elastic slit 48 serves to make the end portion of the body portion 52 relatively elastic deformation compared to other portions of the body portion 52. The elastic slit 48 is preferably formed symmetrically to the body portion (52). In this embodiment, a total of four elastic slits 48 are formed. The elastic slit 48 extends in the longitudinal direction of the body portion 52 and is formed to one end of the body portion 52. For reference, the three-stage rivet has a length longer than the two-stage rivet 50 of the body portion 52. There is a diaphragm 59 in the body portion 52 of the two-stage rivet 50. The diaphragm 59 serves to partition the inside of the body portion 52 to both sides.

Next, the structure of the double rivet 60 is demonstrated. The body portion 62 forms a skeleton of the double rivet 60. The body portion 60 is also cylindrical. End hanger jaws 64 are formed at both ends of the body portion 62, respectively. In the double rivet 60, elastic slits 66 are formed up to both ends of the body part 62. That is, except for a predetermined section of the middle portion of the body portion 62, the elastic slit 66 is formed to both ends of the body portion 62, respectively. The elastic slit 66 is also formed to be symmetrical to those formed at both ends of the body portion 62.

Hereinafter, the rivet tool according to the present invention having the configuration as described above will be used in detail.

First, referring to FIG. 4, the rivet is inserted into the coupling hole 48 of the frame 46. At this time, the rivet is inserted into the fitting rod 55 of the fitting portion 40. The insertion rod 55 is inserted into the rivet. At this time, in the case of the two-stage rivet 50, the fitting rod 55 is fitted to the side where the elastic slit 58 is not formed. In the case of the double rivet 60, since the elastic slit 66 is formed at both ends, the elastic slit 66 has no choice but to fit in the portion where the elastic slit 66 is formed.

When the rivet is inserted into the coupling hole 48 of the frame 46 in such a state, the end portions of the body parts 52 and 62 are lifted up by the elastic slits 58 and 66 of the rivet, and the locking jaw is closed. Pass (49) and enter inside. In the case of the two-stage rivet 50, the two frames 46 are coupled to each other so that they are hooked to the engaging jaw 49 of the coupling hole 48 of the frame 46 on the opposite side. In the case of a three-stage rivet, the three frames 46 are coupled to each other, so that they are hooked to the engaging jaw 49 of the coupling hole 48 of the most opposite frame 46. The state in which the two-stage rivet 50 couples the two frames 46 can be seen in FIG. 5.

The double rivet 60 is hooked to the engaging jaw 49 on the opposite side of the coupling hole 48 of the frame 46. As such, the state in which the double rivet 60 is coupled to one frame 46 can be seen in FIG. 7.

Next, the separation of the two-stage rivet 50 from the frame 46 will be described with reference to FIGS. 5 and 6. The first catching portion 14 of the rivet tool 10 is hooked to the separating hook jaw 53 of the two-stage rivet 50. That is, the end of the tool body 12 in which the first catching portion 14 is formed is moved along the surface of the frame 46 so that the first hook rib 20 is separated from the hooking jaw 53 and the frame. Position it between (46). In such a state, when the tool body 12 is tilted in the direction shown in FIG. 6, the two-stage rivet 50 is coupled to the first hook rib 20 while pushing up the separation hook jaw 53. Omit at 48. That is, the end of the elastic slit 58 of the two-stage rivet 50 is elastically deformed by the force applied by the rivet tool 10, so that the second hooking jaw 56 is removed from the locking end 49. . In this case, as shown in FIG. 6, the two-stage rivet 50 is pulled out of the coupling hole 48.

When the two-stage rivet 50 suddenly occurs in the process of falling out of the coupling hole 48, the two-stage rivet 50 may protrude upward through the first opening portion 18. Prevented by the stop rib 22. Of course, the first opening portion 18 is also open toward the tip of the first projection plate 16, so that the two-stage rivet 50 may be pulled out. This can be prevented when the operator places the thumb on the tip of the first protrusion 16.

On the other hand, in the case of a three-stage rivet, the length of the body portion is longer and is installed over three frames 46, so it must pass through two locking jaws 49. Thus, the support end 23 is required. That is, when passing through the first locking step 49, the bottom of the end of the tool body 12 is sufficient, but when passing through the second locking step 49, the support end 23 is the frame 46 It must be a point supported by the prize to act as a lever.

Next, referring to FIGS. 7 and 8, the double rivet 60 is separated from the coupling hole 48 of the frame 46.

As shown in FIG. 7, the tip of the first protruding plate 26, which is the tip of the second catching part 24 of the rivet tool 10, is inserted into the coupling hole 48 of the frame 46. Half of which is adjacent to the double rivet 60, which protrudes. In this case, the tip of the spacer plate 32 is positioned at a position corresponding to the elastic slit 66. In this state, when the second catching portion 24 is advanced, the second hook rib 30 is engaged with the end hook jaw 64, and the spacer plate 32 is connected to the elastic slit 66. Will enter. As the spacer plate 32 enters the elastic slit 66, the end portion of the body portion 62 in which the elastic slit 66 is formed is not elastically deformed and is engaged with the second catching portion 24. Can be maintained. Therefore, the force exerted by the rivet tool 10 can be transmitted to the double rivet 60 well, and the end hook jaw 64 opposite to the second hooking portion 24 is coupled to the coupling hole ( A force capable of escaping from the locking jaw 49 of the 48 may be provided to the double rivet 60. 7 illustrates a state in which the double rivet 60 is hooked to the second catching part 24.

As such, when the second riveting part 24 is inclined to the rivet tool 10 while being engaged with the double rivet 60, the double rivet 60 is engaged in the coupling hole 48 of the frame 46. , As shown in FIG. 8.

Next, referring to FIGS. 9 and 10, the rivet is separated from the coupling hole 48 of the frame 46 by using the pusher 34. The use of the pusher 34 is a case where the rivet is inserted into the coupling hole 48 of one frame 46. In this case, since it is difficult to use the lever principle by hanging the rivets to the first and second catching portions 14 and 24, the rivet is pushed out of the frame 46 using the pushing portion 34. will be. This is possible because the diaphragm 59 is formed in the inner center of the rivet as described above.

As shown in FIG. 9, when the rivet is installed in the coupling hole 48 of one frame 46, the pressing rod 38 of the pusher part 34 is inserted into the rivet and pressed. The tip of the rod 38 touches the diaphragm 59 and continues to push the rivet out of the coupling hole 48. At this time, while the rivet is released from the coupling hole 48, the push rod 38 can also continue to advance in the direction in which the rivet is released, the stop end 36 is the coupling hole of the frame 46 (48) Contact the entrance so that no further advancement is made. Thus, the process of separating the rivets from the frame 46 with the pusher 34 is shown sequentially in FIGS. 9 and 10.

The scope of the present invention is not limited to the embodiments described above, but may be defined by the scope of the claims, and those skilled in the art may make various modifications and alterations within the scope of the claims It is self-evident.

For example, in the illustrated embodiment, all of the first catching part 14, the second catching part 24, the pushing part 34, and the fitting part 40 are formed in one rivet tool 10. Yes, but not necessarily. Only one of these may be formed in the rivet tool 10. However, in order to increase the versatility of the rivet tool 10, it is preferable that at least the first and second latching portions 14 and 24 are located at both ends of the tool body 12, respectively. In addition, the pusher part 34 and the fitting part 40 may be all or selectively employed.

In the illustrated embodiment, the pushing portion 34 and the fitting portion 40 are formed in a direction opposite to the protruding direction of the second catching portion 24, but the first catching portion 14 is disposed on the side thereof. The pushing portion 34 and the fitting portion 40 may be formed to protrude in a direction opposite to the protruding direction of the first catching portion 14.

10: rivet tool 12: tool body
14: first subtraction unit 16: the first protrusion
18: 1st opening penetration part 20: 1st hook rib
22: stop rib 24: second catching portion
26: 2nd projection board 28: 2nd opening part
30: second hook rib 32: spacer plate
34: Push-out part 36: Stop end
38: push rod 40: fitting
42: base end 44: fitting rod
46: frame 48: coupling hole
49: jaw 50: two-stage rivet
52: body 53: separation hook jaw
54: first hook jaw 56: second hook jaw
58: elastic slit 59: diaphragm
60: double rivet 62: body portion
64: end hook jaw 66: elastic slit

Claims (7)

In the rivet tool for mounting and detaching the rivets in the coupling hole formed in the frame,
Tool body,
A first catching portion extending in a direction perpendicular to an extension direction of the tool body at one end of the tool body and hooked on a separation hook or end hook chin formed in the rivet to separate the rivet from the coupling hole;
The other end of the tool body extends to protrude in a direction opposite to the first catching portion and is provided with a spacer plate at an inner center thereof so that the spacer plate is inserted into an elastic slit formed in the rivet so as to hang on the end hook jaw. A rivet tool comprising a second catching portion separated from the coupling hole.
The first projection plate according to claim 1, wherein the first catching portion extends in parallel with each other in the tool body and passes therebetween, wherein the first protrusion plate has a first opening through the tool body in an extending direction of the tool body, and the first opening part. A first hook rib is formed to surround the inner surface of the first protruding plate corresponding to the end of the through part, and the hook hook or the hook hook of the rivet is hooked, and the hook hook or the hook hook from the hook hook is formed on the first hook rib. A rivet tool comprising a stop rib formed at a greater distance than the thickness of the.
3. The rivet tool of claim 2, wherein the first catching portion is provided with a supporting end to protrude in a direction opposite to the extending direction of the first protruding plate.
According to any one of claims 1 to 3, wherein the second pulling portion is a second pair extending from the tool body side by side and penetrating therebetween the second opening through which the second opening is formed in the extension direction of the tool body; A second hook rib is formed around the inner surface of the protruding plate and the second protruding plate corresponding to the end of the second opening through which the second hook jaw or the end hook jaw of the rivet hangs. Rivet tool provided with a spacer plate positioned between the elastic slit formed in the rivet between.
According to claim 4, One side of the tool body is formed with a push-out portion for pushing apart the rivets fitted in the coupling hole of the frame, the push-out portion of the rivet to the stop end formed integrally protruding from the tool body Rivet tool that is formed by being inserted into the push bar to push the diaphragm inside the rivet.
According to claim 5, The fitting portion is formed to protrude in the same direction as the push-out portion, wherein the fitting portion is formed in the base end formed by protruding integrally to the tool body is formed with a fitting rod is pressed into the inside of the rivet Rivet tool.
The riveting tool of claim 6, wherein the pushing portion and the fitting portion extend in the same direction, and the riveting tool is formed to protrude in a direction opposite to the one of the first and second pushing portions.

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