JP2000094378A - Disassembling tool for fastening member - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a disassembling member of a fastening member capable of cutting a fastening part of a fastening member fastened to a base material by relatively low cutting force and having good separation of a flange part after cutting. SOLUTION: In this disassembling tool for a fastening member, for detaching a blind rivet 10 connected to base materials 1, 2 by a body part 11b and a flange part 11c from the base materials, the body part 11b and the flange part 1c are cut along a boundary range in the body part axial direction between the body part and the flange part by a cylindrical cutting edge into approximately cylindrical shapes, and the flange part 11c is radially divided and cut into a plural parts by a radial cutting edge 600. Therefore, load to be applied to the cylindrical cutting edge in cutting is reduced, and cutting force to be applied to the cylindrical cutting edge is low. Moreover, since the flange part 11c is divided into plural parts and separated, the flange part 11c is not caught in the cylindrical cutting edge, and separating performance of the flange part 11c is improved.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a disassembly tool for a fastening member, and more particularly, to disassembling a fastening portion of a fastening member fastened to a base material by mechanical fastening and removing the fastening member from the base material. The present invention relates to a disassembly tool for a fastening member.

[0002]

2. Description of the Related Art Joining techniques for joining base materials such as steel plates and plastics or other members to the base material include welding, bonding, and mechanical fastening. The above-mentioned welding has a problem that large and expensive equipment and a space for ensuring safety are required. The above-mentioned bonding is relatively inexpensive and has the advantage that work can be performed in a small space. However, it is necessary to fix the posture of the base material until the adhesive is solidified and bonding is completed. Time-consuming. In addition, in such welding and bonding, when a base material is bonded, a poor connection occurs and the connection is re-used, or when the base material is recycled, the bonded portion can be disassembled without damaging the base material. Impossible.

On the other hand, the mechanical fastening includes screw fastening,
There are pin fastening, rivet fastening, and the like, which are widely used in various fields. As is well known, the screw is fastened by using a wrench or a screwdriver, such as a bolt 3 and a nut 4 as shown in FIG. 14A or a tapping screw 5 as shown in FIG. 14B. Is the base material 1,
This is a fastening method in which the base materials 1 and 2 are mechanically joined by being screwed into the two fastening holes 1a and 2a.

As shown in FIG. 15A, a pin 6 as a fastening member is inserted into the fastening holes 1a and 2a of the base materials 1 and 2 by using a swaging machine or a swaging tool. This is a fastening method of mechanically joining the base materials 1 and 2 by attaching them. Here, as shown in FIG. 15B, when the shaft 7 is caulked to the base material 1, the pin is also fastened, and the shaft 7 is regarded as a fastening member.

[0005] The above rivet is fastened to a solid rivet 8 as shown in Fig. 16 (a), a tubular rivet 9 as shown in Fig. 16 (b), and Fig. 16 (c) using a riveting machine or riveting tool. A fastening member such as a blind rivet 10 as shown in FIG.
As shown in (e) and (f), fastening holes 1 in base materials 1 and 2
This is a fastening method for mechanically joining the base materials 1 and 2 by fastening to the base materials 1 and 2a.

The above blind rivet 10 is shown in FIG.
As shown in (c), the rivet body 11 is composed of a mandrel (core shaft) 12 inserted into a shaft hole 11a of the rivet body 11, for example, as shown in FIG.
The base materials 1 and 2 are fastened to the fastening holes 1a and 2a in the procedures shown in (b), (c) and (d). That is, in the blind rivet 10, first, as shown in FIG. 17A, the body 11b of the rivet body 11 is inserted into the fastening holes 1a and 1b of the base materials 1 and 2. Then, FIG.
As shown in (b), the riveting tool 13 is set on the mandrel 12 of the blind rivet 10.
Then, as shown in FIG. 17C, the rivet body 1
When the trigger of the riveting tool 13 is pulled while the nose piece 13a of the riveting tool 13 is in close contact with the first flange portion 11c, the mandrel 12 of the blind rivet 10 is grasped by the jaw 13b of the riveting tool 13 and pulled up. Can be As a result, the portion of the body 11b of the rivet body 11 projecting from the base material 2 is plastically deformed by the mandrel head 12a of the mandrel 12 like drawing, and is caulked to the base material 2. In this state, when the mandrel 12 is further pulled up by the jaw 13b, FIG.
As shown in (d), the broken portion 12b of the mandrel 12
In FIG. 16C, the mandrel 12 is broken, and the fastening of the base materials 1 and 2 by the blind rivet 10 is completed. This blind rivet 10 is shown in FIG.
As is clear from (a), (b), (c) and (d), fastening work to the base materials 1 and 2 without supporting the body 11b side (the back side of the base materials 1 and 2). So, for example, the base material 1,
2 is suitable for fastening at places where the hands are not accessible on the back side.

[0008] As another fastening method, as shown in FIG. 18, a fastening portion 1 b formed in advance integrally with one base material 1 is caulked to a fastening hole 2 a of the other base material 2. A fastening method called burring caulking for mechanically joining the base materials 1 and 2 is known. Here, the fastening portion 1b of the base material 1 fastened by this burring caulking
Are also regarded as the above-mentioned fastening members.

In such a mechanical fastening, the fastening member can be removed from the base material by disassembling the fastening portion of the fastening member fastened to the base material. In comparison, in a little space,
There is an advantage that refastening of the fastening member to the base material and recycling of the base material can be performed easily at low cost.

However, since the fastening members used for mechanical fastening such as pin fastening, rivet fastening, and burring caulking described above are fastened to the base material by plastic deformation of the body, When a fastening failure occurs when fastening the fastening member to the base material and re-fastening is performed, or when the base material is recycled, when the fastening member is removed from the base material, the fastening portion of the fastening member is removed. It has to be destroyed, and it takes time and effort to disassemble it and damages the base material during disassembly.

That is, as a general method of disassembling this type of fastening member, for example, as shown in FIG.
The fastening portion (the flange portion 11c) of the fastening member (here, the blind rivet 10) was cut by a drill 14 rotated by a drill (not shown), and the fastening portion of the fastening member was removed from the body portion 11b. Thereafter, the body 11b is hit from the cutting portion side to remove the fastening members from the base materials 1 and 2. In such a conventional disassembly method, the preparation and selection of the drill and drill 14 and It takes time to set up cutting work and the like. Further, in this conventional disassembly method, as shown in FIG.
In the cutting of c), the tip of the drill 14 reaches the base material 1,
The fastening hole 1a of the base material 1 may be cut.
As described above, when the fastening hole 1a of the base material 1 is cut, the base material 1 cannot be recycled,
Even if the fastening member (blind rivet 10) is refastened to the base material 1, there is a problem that a sufficient fastening force cannot be secured.

Further, in the method of disassembling the fastening member using such a drill, when the fastening portion of the fastening member is cut, the drill 1 is removed.
In some cases, the rotation of the fastener 4 caused the fastening member to rotate, causing the base material to be scratched or the fastening part to be unable to be cut. Here, when the base material damaged by the rotation of the fastening member constitutes the exterior surface of the product, the commercial value of the product is significantly reduced, and the product itself may be defective. Is high.

In the case where the fastening member is rotated by the rotation of the drill 14 during cutting of the fastening portion of the fastening member, the flange of the fastening member is usually provided as shown in FIG. A method is adopted in which the part 11c and the body part 11b are gripped by a gripping tool 15 such as pliers or pliers to prevent the fastening member from rotating around. However, it is difficult and dangerous to perform this work alone. , Needs multiple workers.

In particular, when the flange portion 11c of the fastening member is formed in a dish shape and it is impossible to grip the flange portion 11c with the gripping tool 15 (see FIG. 24).
Or, when the fastening member is fastened to a place where the hand cannot enter the body 11b side, the body 1 of the fastening part
Since it is difficult to hold the 1b with the gripping tool 15 and prevent the fastening member from rotating, it is extremely difficult to cut the fastening member using a drill as described above.

In the case of the screw fastening as shown in FIGS. 14A and 14B, the bolts and nuts 3 and 4 and the tapping screws 5 as fastening members are relatively easily formed from the base materials 1 and 2. Can be removed in many cases, but in this case,
For example, the threaded portions of the bolts and nuts 3 and 4 and the tapping screw 5 are rusted and fixed, or the thread is damaged, and the bolts and nuts 3 and 4 and the tapping screw 5 rotate idly with respect to the base materials 1 and 2. Wrench or fastening tool (spanner or screwdriver)
When the engaging portion is damaged, it is very difficult to remove the bolts / nuts 3, 4 and the tapping screw 5.

The inventor of the present invention, for example, as shown in FIG. 21 or FIG.
a, has a small diameter of the cutting edge 103 than the inner diameter d ₁ of 2a, and the boundary between the body portion 11b and the flange portion 11c of the blind rivet 10 as a substantially parallel the fastening member on the inner peripheral surface of the fastening hole 1a A substantially cylindrical cutting edge 104 along the region
, A cutting blade support 200 that supports the cutting blade 102 so as to be able to advance and retreat along the central axis direction of the fastening hole 1a of the base material 1, and a center of the fastening hole 1a of the base material 1. The cutting edge 102 of the cutting blade 102 is cut into the flange 11c along the axial direction, and the blind rivet 1 is cut.
Cutting force applying means 300 for applying to the cutting blade 102 a cutting force for cutting the fastening portion of the blind rivet 10 along a boundary region between the body portion 11b and the flange portion 11c.
And disassembled tools 100A and 100B having the following.
The detailed configuration of the disassembly tools 100A and 100B will be described later.

[0016]

However, in the above disassembled tools 100A and 100B, when the thickness of the fastening portion of the fastening member to be cut is large or when the material of the fastening member is hard, A large cutting force is required to cut the fastening portion of the fastening member. For this reason, the disassembly tool 100A, 1 is configured such that the fastening portion as described above can disassemble a thick fastening member or a hard fastening member.
00B, a large cutting force applying means 3 is provided so that a large cutting force can be applied to the cutting blade 102.
Since 00 is required, there is a problem that the disassembly tool itself becomes large and its operability is reduced.

Further, in the disassembly tools 100A and 100B, since the fastening portion of the fastening member is cut into a ring shape by the cutting blade 102, the flange portion 11c separated from the body 11b of the fastening member by the cutting. However, there is a problem in that the flange 11c is easily entangled with the cutting blade 102 and the separability of the flange portion 11c from the cutting blade 102 deteriorates.

The present invention has been made in view of the above problems, and an object of the present invention is to cut a fastening portion of a fastening member fastened to a base material with a relatively small cutting force. Further, an object of the present invention is to provide a disassembly tool for a fastening member having good separability of a flange portion after cutting.

[0019]

In order to achieve the above object, according to the present invention, there is provided a body which is inserted into a fastening hole of a base material and the body which is pressed against a peripheral edge of the fastening hole. By a substantially integral flange portion, a fastening member fastened to the base material is removed from the base material by a disassembling tool of the fastening member. Along with, a cylindrical cutting blade that cuts the trunk portion and the flange portion into a substantially cylindrical shape, and a radial cutting blade that cuts the flange portion of the fastening member substantially radially with respect to the axial center of the fastening member,
It is characterized by having.

In this disassembly tool, along the body axial direction boundary region between the body and the flange of the fastening member,
The fastening portion of the fastening member is cut into a cylindrical shape by the cylindrical cutting blade, and the flange portion of the fastening member is radially cut by the radial cutting blade, whereby the flange portion is separated from the trunk portion. Then, the fastening member fastened to the base material is removed from the base material. Therefore, in the disassembly tool, unlike the disassembly method using the conventional drill, when the fastening member is disassembled, the fastening member does not run idle or the base material is not damaged. The fastening member can be easily and quickly removed. Here, the boundary region in the body axial direction between the body and the flange of the fastening member is, for example, the body 1 of the rivet body 11 of the blind rivet 10 as the fastening member shown in FIG.
It is a cylindrical region substantially parallel to the outer peripheral surface of the body portion 11b, which is a boundary between the flange portion 1b and the flange portion 11c and is indicated by a broken line A in FIG. In this disassembly tool, the flange portion of the fastening member is radially divided into a plurality of pieces and cut by the radial cutting blade, so that the load applied to the cylindrical cutting blade when the fastening portion of the fastening member is cut is reduced. Thus, the cutting force applied to the cylindrical cutting blade can be reduced. Also,
The fastening portion of the fastening member is cut into a cylindrical shape by the cylindrical cutting blade, and the flange portion of the fastening member is radially cut by the radial cutting blade. Since the portion is divided into a plurality of parts and separated, the flange portion does not become entangled with the cylindrical cutting blade after the cutting, and the separability of the flange portion is improved.

According to a second aspect of the present invention, in the disassembly tool of the first aspect, the cutting edge of the radial cutting blade is inclined so as to protrude toward the axis center.

In this disassembly tool, since the cutting edge of the radial cutting blade is inclined so as to protrude toward the center of the shaft, the cutting edge of the fastening member is cut by the radial cutting blade. The cutting edge of the radial cutting blade gradually bites from the axial center side of the flange portion toward the outer peripheral side. Thereby, the load applied to the radial cutting blade when cutting the flange portion of the fastening member is reduced, and the cutting force applied to the radial cutting blade can be reduced.

The invention of claim 3 is the invention of claim 1 or 2
In the above disassembly tool, the cylindrical cutting blade and the first radial cutting blade are integrally formed.

In this disassembly tool, since the cylindrical cutting blade and the radial cutting blade are integrally formed, the boundary between the trunk portion and the flange portion of the fastening member by the cylindrical cutting blade. The cutting of the area and the cutting of the flange portion of the fastening member by the radial cutting blade are performed substantially simultaneously by a single cutting operation. Thereby, the operation of the disassembling tool is facilitated, and the time required for disassembling the fastening member is reduced.

According to a fourth aspect of the present invention, there is provided the disassembly tool according to the first, second, or third aspect, further comprising rotating means for rotating the radial cutting blade by a predetermined angle around the axis center as a rotation center. It is characterized by the following.

In this disassembly tool, the radial cutting blade can be rotated by a predetermined angle about the axis center by the rotating means. This allows the radial cutting blade to cut the flange portion of the fastening member more finely, so that the load applied to the cylindrical cutting blade when cutting the fastening portion of the fastening member is further reduced, and the cylindrical cutting blade is further reduced. The cutting force applied to the cutting blade can be smaller.

According to a fifth aspect of the present invention, in the disassembly tool according to the first, second, third or fourth aspect, the cylindrical cutting blade and the radial cutting blade are fastened to the cylindrical cutting blade along the body axis direction. A cutting force applying means for applying a cutting force for cutting a fastening portion of the member is provided.

In this disassembly tool, a cutting force is applied to the cylindrical cutting blade and the radial cutting blade by the cutting force applying means regardless of an external impact. The boundary region between the body and the flange of the member is cut, and the radial cutting blade cuts the flange of the fastening member.

According to a sixth aspect of the present invention, in the disassembly tool according to the fifth aspect, the cutting force applied by the cutting force applying means causes the cutting edges of the cylindrical cutting blade and the radial cutting blade to have at least the cutting edges. The cylindrical cutting blade and the cutting blade stopping means for stopping the movement of the radial cutting blade in a state substantially reaching the boundary surface between the flange portion of the fastening member and the base material. Things.

In this disassembly tool, the cutting blade stopping means causes the cutting edges of the cylindrical cutting blade and the radial cutting blade to reach at least the boundary surface between the flange portion of the fastening member and the base material. In this state, the movement of the cylindrical cutting blade and the radial cutting blade is stopped, so that damage to the base material by the cylindrical cutting blade and the radial cutting blade is reliably avoided. Here, the state in which the cutting edge of the cylindrical cutting blade has almost reached the boundary surface between the flange portion of the fastening member and the base material means that the trunk portion and the flange portion of the fastening member are completely separated. Or a connected state while leaving a slight meat portion. Further, the state in which the cutting edge of the radial cutting blade has substantially reached the boundary surface between the flange portion of the fastening member and the base material is a state in which the flange portion of the fastening member is completely divided and cut, or Any of the connected states except for a slight meat portion may be used.

According to a seventh aspect of the present invention,
In the disassembly tool described in 4, 5, or 6, when cutting the fastening portion of the fastening member by fitting into a shaft hole formed in a flange portion of the fastening member which is substantially coaxial with the body of the fastening member. And a cutting blade positioning member for positioning a cutting position of the cylindrical cutting blade and the radial cutting blade.

In this disassembly tool, when the cutting blade positioning member is fitted into the shaft hole of the flange portion to cut the fastening portion of the fastening member, the cylindrical cutting blade and the radial cutting blade are used. Since the cutting position is determined, the cutting position of the cylindrical cutting blade and the radial cutting blade does not shift when cutting the fastening portion of the fastening member, and the flange portion is reliably separated from the body. it can.

The invention according to claim 8 is based on claims 1, 2, 3,
In the disassembly tool described in 4, 5, 6, or 7, the radial cutting blade is arranged so as to be movable and adjustable in the cutting direction with respect to the cylindrical cutting blade.

In this disassembly tool, since the radial cutting blade is disposed so as to be movable in the cutting direction with respect to the cylindrical cutting blade, for example, the cylindrical cutting blade or the radial cutting blade can be used. Even if the relative positional relationship in the cutting direction of the cutting edge between the cylindrical cutting blade and the radial cutting blade changes due to the polishing of the cutting edge of the cylindrical cutting blade, the radial cutting blade is moved relative to the cylindrical cutting blade. By adjusting the movement along the cutting direction, it is possible to adjust the relative positional relationship between the cutting edges of the cylindrical cutting blade and the radial cutting blade in the cutting direction to be an appropriate positional relationship. Further, without replacing the cylindrical cutting blade and the radial cutting blade, the cylindrical cutting blade and the radial cutting blade are adapted to fit the dimensions of the fastening portion and the flange portion of the fastening member to be disassembled. The relative positional relationship between the cutting edge and the cutting direction can be changed.

[0035]

Embodiments of the present invention will be described below. Note that the disassembly tool for the fastening member according to the present embodiment may be any type of fastening member as long as it is a fastening member used for mechanical fastening such as pin fastening, rivet fastening, and burring swaging described above. However, for convenience of explanation, FIG.
The blind rivet 10 as shown in FIG.

First, the above-described disassembly tools 100A and 100B shown in FIGS. 21 and 22 will be described. As described above, these disassembly tools 100A and 100B
It has a fastening hole 1a, the small diameter of the cutting edge 103 than the inner diameter d ₁ of 2a above base materials 1 and 2, and the blind rivet 10 as a substantially parallel the fastening member on the inner peripheral surface of the fastening hole 1a
A cutting blade 102 having a substantially cylindrical cutting edge 104 along a boundary region between the body 11b and the flange 11c, and a cutting blade 1 along the central axis direction of the fastening hole 1a of the base material 1.
The cutting blade support 200 for supporting the back and forth freely and the cutting edge 102 of the cutting blade 102 are cut into the flange portion 11c along the central axis direction of the fastening hole 1a of the base material 1 so as to form the blind. The blind rivet 1 extends along a boundary area between the body 11b and the flange 11c of the rivet 10.
And a cutting force applying means 300 for applying a cutting force for cutting the fastening portion of No. 0 to the cutting blade 102.

The cutting force applying means 300 of the disassembly tool 100A shown in FIG. 21 is constituted by, for example, a hydraulic cylinder or an air cylinder, and is provided with oil or oil through a pressure path 200a provided in the cutting blade support 200. When the air enters and exits, the cutting blade 102 moves forward and backward along the direction of arrow a. Here, as a supply means of oil or air which is a drive source of the cutting force applying means 300, oil or air which is a drive source of the jaw 13b of the riveting tool 13 for fastening the blind rivet 10 to the base materials 1 and 2 is used. Can be used as it is. Further, the cutting blade support 200
For example, it is desirable that the shape is provided with a grip portion such as a pistol type so that the operator can easily operate the disassembling tool 100B with one hand.

Using the disassembly tool 100A, the base materials 1, 2
To disassemble the blind rivet 10 fastened to
First, as shown in FIG.
03 is a blind rivet 10 as the fastening member.
Of the body 11b and the flange 11c. Next, in this state, for example, the cutting force applying means 300 urges the cutting blade 102 with a cutting force in the cutting direction.

As a result, as shown in FIG. 23, the cutting edge portion 104 of the cutting blade 102 of the disassembling tool 100A cuts along the boundary region between the body portion 11b and the flange portion 11c of the blind rivet 10 to form the blind. Rivet 1
0 is cut off, and the flange portion 11c is separated from the body portion 11b.

On the other hand, the disassembly tool 100B shown in FIG.
A cutting force applying unit 300 is provided so that a cutting force can be applied to the cutting blade 102 without using an external drive source such as an oil or air supply unit. That is, the cutting force applying means 300 of the disassembling tool 100B includes an extensible coil spring 303 as a cutting force urging means for urging the cutting blade 102 with a cutting force in a cutting direction, and the coil spring 303 A stopper 304 serving as a cutting blade locking means for locking the cutting blade 102 at a position where the urging force of the cutting blade 102 in the cutting direction is accumulated in the cutting direction (a position where the coil spring 303 is contracted), and the stopper 304 The cutting blade 1
And a release button 305 as a cutting blade locking release means for releasing the locking of the blade 02.

Using the disassembly tool 100B, the base materials 1, 2
To disassemble the blind rivet 10 fastened to
First, as in the case of the disassembly tool 100A, the cutting edge 103 of the cutting blade 102 faces the boundary region between the body 11b and the flange 11c of the blind rivet 10, and in this state, the disassembly tool 100B Cutting blade support 200
Is pressed against the blind rivet 10. As a result, the cutting blade 102 is
3 is pushed into the cutting blade support 200 while contracting the coil spring 303 against the extension force of the coil spring 303.

Then, the position of the cutting blade 102 pushed into the cutting blade support 200 is caused by the contraction of the coil spring 303 so that the urging force of the cutting blade 102 in the cutting direction, that is, When the position where the stretching force is sufficiently accumulated is reached, the cutting blade 102
The stopper 304 is provided on the outer periphery of the stopper so as to be able to move forward and backward.
Is pushed out and engaged by a resilient force of a spring 306 into a locking hole 200b formed in an inner peripheral portion of the cutting blade support 200, and the cutting blade 102 is It is locked to the cutting blade support 200.

In this state, the release button 305 provided on the outer periphery of the cutting blade support 200 so as to be able to advance and retreat is
When pushed into the cutting blade support 200 against the elasticity of the spring 307, the release pin 305 of the release button 305 is released.
As a result, the stopper 304 engaged with the locking hole 200b causes the cutting blade 1 to resist the elasticity of the spring 306.
02, the cutting blade 102 is released from the engagement with the cutting blade support 200.

When the engagement of the cutting blade 102 with the cutting blade support 200 is released, the tension of the coil spring 303 causes the cutting blade 1 to move.
02, a cutting force in the cutting direction is urged. Thereby, as in the case shown in FIG.
The cutting edge portion 104 of the cutting blade 102 of B cuts in along the boundary region between the body portion 11b of the blind rivet 10 and the flange portion 11c, the fastening portion of the blind rivet 10 is cut, and the flange portion is cut from the body portion 11b. The part 11c is separated. In this disassembly tool 100B, a cutting force can be applied to the cutting blade 102 without using an external drive source such as an oil or air supply means. It is suitable when performing.

In the disassembly tools 100A and 100B, as shown in FIG.
03 cuts the fastening portion of the blind rivet 10 by moving linearly substantially in parallel with the central axes of the fastening holes 1a and 2a of the base materials 1 and 2, as in the disassembly method using the conventional drill. In addition, when the blind rivet 10 is disassembled, the blind rivet 10 does not run idle, and the base materials 1 and 2 are not damaged by the idle rotation and the like.
2, the blind rivet 10 can be easily and quickly removed.

The blind rivet 10 fastened to the base materials 1 and 2 using the disassembly tools 100A and 100B
When disassembling, as shown in FIG. 19, the flange 11c and the body 11b of the blind rivet 10 are
There is no need to hold and fix with a gripping tool 15 such as pliers or pliers. Therefore, this disassembly tool 100A, 1
According to 00B, for example, as shown in FIG. 24, the shape of the flange portion 11c of the blind rivet 10 is formed in a dish shape, and the flange surface of the flange portion 11c bites into the base material 1 or the blind It is difficult to grip the flange portion 11c or the body portion 11b of the blind rivet 10 with the gripping tool 15 such as pliers or pliers, because the caulking portion of the body portion 11b of the rivet 10 bites into the base material 2. Even in this case, the fastening portion of the blind rivet 10 is cut by the cutting blade 102 and the body 1 is cut.
The flange portion 11c can be separated from 1b.

The cutting stroke of the disassembling tools 100A and 100B when the cutting blade 102 cuts the fastening member is determined by the cutting force applied to the cutting blade 102 by the cutting force applying means 300 as shown in FIG. The cutting edge 103 of the cutting blade 102 reaches at least near the boundary surface between the flange 11c of the blind rivet 10 and the base material 1, and the cutting edge 1 of the cutting blade 102
It is desirable that the setting is made such that the movement of the cutting blade 102 is stopped in a state where the outer peripheral surface of the cutting blade 04 is located near the edge of the fastening hole 1a of the base material 1.

Therefore, the above-mentioned disassembly tools 100A, 100A
21B, the step 105 formed on the outer peripheral surface of the cutting blade 102 is engaged with the step 208 formed on the inner peripheral surface of the cutting blade support 200, as shown in FIGS. By doing so, the movement of the cutting blade 102 is stopped at the above-mentioned predetermined position.

As a result, as shown in FIG. 25, the cutting force causes the cutting edge 103 of the cutting blade 102 to move at least to the flange portion 11c of the blind rivet 10.
And the outer peripheral surface of the cutting edge portion 104 of the cutting blade 102 is fixed to the fastening hole 1 of the base material 1.
a, the movement of the cutting blade 102 can be stopped in a state of being located near the edge of the base material 1 by the cutting blade 102.
Can be reliably avoided.

However, the disassembly tool 1 having the above-described structure is used.
In 00A and 100B, as described above, blind rivets 10 as fastening members to be cut are used.
When the thickness of the fastening portion is large, or when the material of the blind rivet 10 is hard, a large cutting force is required to cut the fastening portion. For this reason, when the disassembling tools 100A and 100B are configured such that the above-described fastening portion can disassemble a thick fastening member or a hard fastening member, a large cutting force can be applied to the cutting blade 102. In this case, a large cutting force applying means 300 is required, which causes a problem that the disassembly tool itself becomes large and its operability is reduced.

In the disassembling tools 100A and 100B, the cutting rivet 1 is
Since the flange portion 11c is cut into a ring shape, the flange portion 11c separated from the body portion 11b of the tightening blind rivet 10 is easily entangled with the cutting blade 102, and the flange portion with respect to the cutting blade 102 is cut. 11c
There is a problem that the separability of is deteriorated.

Therefore, in the disassembly tool according to the embodiment of the present invention, in order to solve the above-mentioned problems, the body 11
A cylindrical cutting blade for cutting the body 11b and the flange 11c into a substantially cylindrical shape along a boundary region of the body 11b and the flange 11c in the body axis direction, and the flange 11c with respect to the axis center. And a radial cutting blade for cutting substantially radially.

FIGS. 1A and 1B show an example of the cylindrical cutting blade 500. FIG. This cylindrical cutting blade 500 is similar to that shown in FIG.
As shown in (a), the cutting edge 503 of the cylindrical blade 502
Are disassembled tools 100A, 10A shown in FIGS.
In a manner similar to the cutting edge 103 of the cutting blade 102 of OB, it may be formed by a single ring-shaped blade, or
As shown in FIG. 1B, the cutting edge 503 may be formed of a plurality of (four in the figure) divided blades.

Here, as in the former case, in the case of the cylindrical cutting blade 500 in which the cutting edge 503 is formed by a single blade,
There is an advantage that the fastening portion of the blind rivet 10 can be cut without changing the contact position of the cutting edge 503 with the blind rivet 10. Further, as in the latter case, in the case of the cylindrical cutting blade 500 in which the cutting edge 503 is formed by a plurality of divided blades, the cylindrical blade 502 is rotated by rotating means described later, and the cutting edge 503 of the cutting edge 503 is cut. Although it is necessary to cut the fastening portion of the blind rivet 10 while changing the contact position, there is an advantage that the cutting force when cutting the fastening portion is small.

2 (a), 2 (b) and 2 (c) show an example of the radial cutting blade 600 used for cutting the flange portion 11c of the blind rivet 10 substantially radially. The illustrated radial cutting blade 600 is used as a cutting blade positioning member for positioning the cutting position of the radial cutting blade 600 by fitting into the shaft hole 11a of the blind rivet 10 when cutting the flange portion 11c of the blind rivet 10. The radial blades 602 are arranged on the centering shaft 400 of FIG.

Here, the radial blade 602 may be formed integrally with the centering shaft 400, or may be integrated with the centering shaft 400 detachably. Good. In addition, the radial blade 602 may be a single one, or, as shown in FIG.
As shown in (b), there may be a plurality. Further, the shape of the radial blade 602 may be a plate having a substantially uniform thickness as shown in FIGS. 2A and 2B, or FIG.
As shown in (c), the centering shaft 400 may have a wedge shape with an increased thickness. When a plurality of the radial blades 602 are provided, the cutting edges 603 of the respective radial blades 602 are cut so that the flange portions 11c of the blind rivets 10 are cut substantially equally by the cutting edges 603 of the respective radial blades 602. Are preferably arranged at substantially equal intervals, whereby the load on the radial blade 602 applied when the flange portion 11c is cut is substantially equalized.

In order to cut the flange portion 11c of the blind rivet 10 using the radial cutting blade 600, first, as shown by a solid line in FIG. The blind rivet 10 is fitted into the shaft hole 11a. Thereby, the cutting edge 603 of each radial blade 602 of the radial cutting blade 600 is
The flanges 11c of the blind rivet 10 are positioned (centered) at appropriate cutting positions.

Next, a cutting force in the cutting direction (direction of arrow a) is applied to the radial cutting blade 600 in a state where the fitting portion 400a of the centering shaft 400 is fitted into the shaft hole 11a of the blind rivet 10. . Thereby, as shown by a chain line in FIG. 3, the cutting edge 603 of each radial blade 602 of the radial cutting blade 600 is
Of the flange 11c, and the flange 11c is cut into a plurality of divided parts. For example, FIG.
When the flange portion 11c of the blind rivet 10 is cut using the radial cutting blade 600 having the four radial blades 602 shown in FIG. 4A, as shown in FIG. The flange portion 11c
It is cut into four parts.

In this disassembly tool, the fastening portion of the blind rivet 10 is cylindrically attached by the cylindrical cutting blade 500 along the boundary region in the body axial direction between the body portion 11b and the flange portion 11c of the blind rivet 10. The flange portion 11c of the blind rivet 10 is radially cut by the radial cutting blade 600, so that the flange portion 11c is cut from the body portion 11b.
Is separated into a plurality of parts, and the blind rivet 10 fastened to the base materials 1 and 2 is removed from the base materials 1 and 2.

Therefore, in this disassembly tool, the flange portion 11c of the blind rivet 10 is radially divided into a plurality of pieces and cut by the radial cutting blade 600. The load applied to the cylindrical cutting blade 500 is reduced,
The cutting force applied to the cylindrical cutting blade 500 can be small, and the disassembling tool can be downsized. Further, the flange portion 11c of the blind rivet 10 is radially cut by the radial cutting blade 600, so that the flange portion 11b of the blind rivet 10 is removed from the flange portion 11b.
Since c is divided into a plurality of pieces and separated, the flange portion 11c does not become entangled with the cylindrical cutting blade 500 after the cutting, and the separability between the disassembling tool and the flange portion 11c is improved.

Here, the cutting edge 603 of each radial blade 602 of the radial cutting blade 600 protrudes toward the center of the fitting portion 400a of the centering shaft 400 as shown by an angle θ in FIG. It is desirable to be inclined.

As described above, the cutting edge 603 of each radial blade 602 of the radial cutting blade 600 is connected to the centering shaft 4.
When the flange 11c of the blind rivet 10 is cut by the radial cutting blade 600, the cutting edge 603 of the radial blade 602 is inclined by projecting toward the axial center of the fitting portion 400a. The flange portion 11c gradually bites from the axial center side toward the outer peripheral side. Therefore, in the disassembly tool formed as described above, the load on the radial cutting blade 600 at the time of cutting the flange portion 11c of the blind rivet 10 can be reduced, so that the cutting force applied to the radial cutting blade 600 is small. As a result, the cutting operation of the flange portion 11c by the radial cutting blade 600 is facilitated.

The cylindrical cutting blade 500 and the radial cutting blade 600 may be integrally formed as in a disassembly tool 100C shown in FIG. In the disassembly tool 100C in which the cylindrical cutting blade 500 and the radial cutting blade 600 are integrally formed, the body 1 of the blind rivet 10 by the cylindrical cutting blade 500 is used.
Since the cutting of the boundary region between the flange portion 11b and the flange portion 11c and the cutting of the flange portion 11c of the blind rivet 10 by the radial cutting blade 600 can be performed substantially simultaneously by one cutting operation, the operation of the disassembling tool is performed. Becomes easier,
The time required for disassembling the blind rivet 10 can be reduced.

The disassembly tool 100C is provided with a cutting force applying means 300 configured similarly to the disassembly tool 100B shown in FIG. 22 to apply a cutting force to the cylindrical cutting blade 500 and the radial cutting blade 600. Is provided, and the cylindrical cutting blade 50 is used without using other tools such as a hammer.
It is configured such that a cutting force can be applied to the radial blade 602 of the zero cylindrical blade 502 and the radial cutting blade 600. Note that, in this disassembly tool 100C, members and parts with the same reference numerals as those of the disassembly tool 100B shown in FIG. 22 have the same configuration and function as the members and parts of the disassembly tool 100B. It is omitted.

Further, the disassembly tool 100C shown in FIG.
The cutting force applied by the cutting force applying means 300 causes the cylindrical cutting blade 500 and the radial cutting blade 60
In a state where the 0 blade edges 503, 603 have reached at least substantially the boundary surface between the flange portion 11c of the blind rivet 10 and the base material 1, the disassembly tool 10 shown in FIG.
As in the case of OB, the step 505 formed at the base of the cylindrical cutting blade 500 is engaged with the step 208 formed on the inner peripheral surface of the cutting blade support 200, whereby the cylindrical cutting is performed. The movement of the blade 500 and the radial cutting blade 600 is stopped.

Thus, the cutting edges 503, 603 of the cylindrical cutting blade 500 and the radial cutting blade 600 reach the vicinity of the boundary surface between the flange portion 11c of the blind rivet 10 and the base material 1, and Since the outer peripheral surface of the cutting blade 500 is stopped near the edge of the fastening hole 1a of the base material 1, damage to the base material 1 by the cylindrical cutting blade 500 and the radial cutting blade 600 is ensured. To be avoided.

Here, the cutting edge 5 of the cylindrical cutting blade 500
03 is the flange 11 of the blind rivet 10
The state where the boundary surface between the base member 1 and the base material 1 has been substantially reached means that the body 11b and the flange 11c of the blind rivet 10
May be in a completely separated state or in a state where they are connected while leaving a slight meat portion. Further, the state in which the cutting edge 603 of the radial cutting blade 600 has almost reached the boundary surface between the flange portion 11c of the blind rivet 10 and the base material 1 means that the flange portion 11c of the blind rivet 10 is completely divided. It may be either a cut state or a connected state with a slight meat portion left.

Further, this disassembly tool 100C fits into the shaft hole 11a through which the mandrel 12 formed in the body 11b of the blind rivet 10 is inserted, and cuts the fastening portion of the blind rivet 10. It has a movable centering shaft 400 as a cutting blade positioning member for positioning the cutting positions of the cylindrical cutting blade 500 and the radial cutting blade 600 with respect to the fastening portion.

As shown in FIG. 5, the centering shaft 400 can be advanced and retracted substantially along the axial direction of the shaft hole 11a of the blind rivet 10 into the hollow portion of the cylindrical blade 502 of the cylindrical cutting blade 500. And between the centering shaft 400 and the cylindrical blade 502, an extensible coil spring 401 as moving force urging means for urging a moving force with respect to the centering shaft 400 is provided. It is arranged. Further, the centering shaft 400 is formed so that the flat portion of the centering shaft 400 is exposed by the extension force of the coil spring 401 so that the fitting portion 400 a projects beyond the cutting edge 103 of the cylindrical cutting blade 500.

As shown in FIG. 5, when the fastening portion of the blind rivet 10 is cut, the fitting portion 400a of the centering shaft 400 fits into the shaft hole 11a of the flange portion 11c of the blind rivet 10. By doing so, the cylindrical cutting blade 500 and the radial cutting blade 600
Position the cutting position of. Thereby, when cutting the fastening portion, the cylindrical cutting blade 500 and the radial cutting blade 600
Is not shifted, the flange portion 11c can be reliably separated from the body portion 11b of the blind rivet 10, and the generation of burrs can be extremely reduced. The centering shaft 400 is connected to the cylindrical cutting blade 5.
Since the cylindrical cutting blade 500 is provided so as to be able to advance and retreat in a direction substantially along the axial direction of the shaft hole 11a with respect to the cylindrical blade 502, The cylindrical cutting blade 5 is moved by the centering shaft 400.
00 is not hindered from moving in the cutting direction, and the fastening portion can be reliably cut. Further, the coil spring 401
As a result, the moving force in the direction of fitting into the shaft hole 11a is urged against the centering shaft 400, so that the fitting operation of the fitting portion 400a of the centering shaft 400 to the shaft hole 11a is facilitated. Can be done.

It is preferable that the radial cutting blade 600 is disposed so as to be movable and adjustable in the cutting direction with respect to the cylindrical cutting blade 500. Disassembly tool 1 shown in FIG.
00D is formed by screwing the radial cutting blade 600 to the cylindrical cutting blade 500,
0 is configured to be movable and adjustable in the cutting direction with respect to the cylindrical cutting blade 500.

In the disassembly tool 100D, the radial cutting blade 600 is screwed to the cylindrical cutting blade 500 so as to be movable and adjustable in the cutting direction. Cutting edge 5 of radial cutting blade 600
03, 603, etc., the cylindrical cutting blade 500
Even when the relative positional relationship in the cutting direction between the cutting edges 503 and 603 with the radial cutting blade 600 changes, the radial cutting blade 600 is moved along the cutting direction with respect to the cylindrical cutting blade 500. By moving and adjusting, the cutting edges 503, 6 of the cylindrical cutting blade 500 and the radial cutting blade 600 are adjusted.
03 can be adjusted so that the relative positional relationship in the cutting direction becomes an appropriate positional relationship. Further, by adopting such a configuration, without replacing the cylindrical cutting blade 500 and the radial cutting blade 600, the dimensions of the fastening portion and the flange portion 11c of the fastening member to be disassembled can be matched.
The relative positional relationship between the cutting edges 503 and 603 of the cylindrical cutting blade 500 and the radial cutting blade 600 in the cutting direction can be changed.

FIG. 7 shows a disassembly tool 100E provided with a rotating means for rotating the cylindrical cutting blade 500 and the radial cutting blade 600 by a predetermined angle around the axis thereof.
An example is shown below. In this disassembling tool 100E, the radial cutting blade 600 can be rotated by a predetermined angle about the axis of the shaft by the rotating means, so that the radial cutting blade 600 allows the flange portion 11c of the blind rivet 10 to be rotated. Can be cut into smaller pieces. Therefore, in the disassembling tool 100E, the load applied to the cylindrical cutting blade 500 when cutting the fastening portion of the blind rivet 10 can be further reduced, and the cutting force applied to the cylindrical cutting blade 500 can be further reduced.

In this disassembly tool 100E,
While rotating the cylindrical cutting blade 500 by a predetermined angle about the axis of the shaft by the rotating means, the cylindrical rivet 10 is rotated by the cylindrical cutting blade 500.
Can be cut. Therefore, this disassembly tool 10
In 0E, the fastening portion of the blind rivet 10 can be cut using the cylindrical cutting blade 500 having the divided cutting edge 503 as shown in FIG. The cutting force applied to the 500 can be made smaller.

As shown in FIG. 7, the disassembly tool 100E is connected to a compressed air generator 25 by an air hose 24, and is configured to operate by compressed air. The cylindrical structure 21, which is a main part of the disassembly tool 100E, includes pistons 26 and 30, a spring 27,
31, packing 28, joint 29, holding rod 32, convex 33 fixed to piston 30, attachment 4
0, a cylindrical cutting blade 500, a radial cutting blade 600, and the like.

The compressed air passes through the air hoses 24a and 24b by the switching operation of the air valve 24v.
The power is supplied to the piston chambers 51 and 52.
The air valve 24v is provided inside the disassembly tool 100E, and switches its operation in conjunction with an operation button (not shown). At the tip of the piston 30, the cylindrical cutting blade 500 and the radial cutting blade 60 are provided.
0 is attached. It is desirable that the cylindrical cutting blade 500 and the radial cutting blade 600 be replaceable instead of being integrated with the piston 30 in consideration of replacement at the time of wear.

A linear groove and a spiral groove are formed on the inner peripheral surface of the cylindrical structure 21, and the piston 30 moves intermittently at the same angle when the protrusion 33 moves along the groove. It is designed to rotate. This rotation operation will be described later in detail.

FIG. 8 (a) shows the piston 26 and the holding rod 3
2 shows a detailed view before assembling a joint 29 with the second embodiment. Piston 2
A ball portion 35 is formed at the tip of 6. A hemispherical hole 41 is formed at the upper end of the holding rod 32, so that the sphere 35 of the piston 26 enters. The two joints 36 are set so as to sandwich the upper part of the sphere 35 while the sphere 35 is in the hemispherical hole 41. After that, the joint 26 and the pressing rod 32 are connected by the connecting plate 37 and the screw 38, so that the piston 26 and the pressing rod 32 are rotatably connected. FIG. 8B shows the joint 29 after assembly.
Is shown.

FIG. 9A shows a view of the cutting edge 503 of the piston 30 and the cylindrical cutting blade 500 and the cutting edge 603 of the radial cutting blade 600 as viewed from the direction of arrow G in FIG. As shown in FIG. 9 (a), for example, the cylindrical cutting blade 500 has a cutting edge 503 corresponding to a central angle of 45 degrees on a circumference of 4.8 mm in diameter, spaced 45 degrees apart from each other on the circumference. Are arranged in four. The diameter of the cylindrical blades 502 arranged on the circumference is 4.8 mm, which is smaller than the hole diameter of the fastening hole 1 a of the base material 1 4.9 mm so as not to damage the base material 1.

The radial cutting blade 600 is similar to that shown in FIG.
As shown in (a), for example, four cutting edges 603 corresponding to a central angle of 45 degrees are radially arranged at intervals of 90 degrees from a circumference of 4.8 mm in diameter.

Next, the body 11b of the blind rivet 10 and the flange 1
An operation of cutting the fastening portion of the blind rivet 10 and an operation of cutting the flange portion 11c along the boundary region in the trunk portion axial direction with the flange portion 1c will be described.

In FIG. 7, when the operation button is first pressed, the compressed air enters the piston chamber 52 through the air hose 24b by the switching operation of the air valve 24v. Since the piston chamber 52 is sealed by the packing 28, the piston 30 is moved by the force of the compressed air in FIG.
Extruded in the direction. The piston 30 moves until it hits the stoppers D1, D2 on the inner surface of the attachment 40. Then, when the pressing of the operation button 22 is released,
The switching operation of the air valve 24v causes the piston chamber 5
2 compressed air passes through the air hose 24b and exhaust port 2
Exit from 4c. Therefore, the piston 30 returns to the position where it hits the stoppers C1 and C2 by the force of the spring 31.

Here, the equiangular intermittent rotation operation of the piston 30 will be described. FIG. 10 is a developed view of the inner surface of the cylindrical structure 21. On the inner surface of the cylindrical structure 21, a groove having a width slightly larger than the outer diameter of the columnar projection 33 provided on the outer peripheral surface of the piston 30 is formed. Eight linear grooves 53a to 53h are formed at 45-degree intervals, and spiral grooves 54a to 54h are formed so as to connect these linear grooves 53a to 53h. Also, the branch point 4 between the linear grooves 53a to 53h and the spiral grooves 54a to 54h
Leaf springs 39a to 39h are provided in 2a to 42h, respectively. Since the convex portion 33 is fixed to the piston 30, the piston 33 is intermittently rotated at the same angle as the convex portion 33 moves along the linear grooves 53a to 53h and the spiral grooves 54a to 54h. Can be done.

The operation of moving the projection 33 and the piston 30 supporting the projection 33 along the linear grooves 53a to 53b will be described with reference to FIGS. 7 and 10. FIG. First, when the operation button is pressed, the piston chamber 5 is pressed.
2 is applied with air pressure, and the piston 30 is inserted into the linear groove 53a.
Extrude straight along. At this time, the branch point 42a
Is directed downstream with respect to the direction in which the projection 33 passes, so that the leaf spring 39a is elastically deformed when the projection 33 passes. As a result, the protrusion 3
3 passes through the branch point 42a as it is. And the piston 30 is provided with stoppers D1, D on the inner surface of the attachment 40.
Move until you hit 2. Thus, when the operation button is pressed, the piston 30 is pushed straight out without rotating.

When the operation button is released,
The piston 30 is pushed back by the spring 31.
At this time, the movement of the projection 33 is regulated by the leaf spring 39a disposed at the branch point 42a, moves in the X direction in FIG. 10, and enters the spiral groove 54a. The protrusion 33 is the piston 3
Since it is fixed at 0, the piston 30 is rotated along the spiral groove 54a. When the piston 30 is further pushed back, the projection 33 enters the linear groove 53b. By such an operation, the piston 30 is moved into the linear groove 53.
Rotate by an angle corresponding to a and 53b. That is, it rotates 45 degrees. Thereafter, each time the operation button is repeatedly pressed and released, the piston 30 is pushed out and returned to 4 times.
Rotate 5 degrees. Accordingly, the cylindrical cutting blade 500 and the radial cutting blade 60 attached to the tip of the piston 30
Zero also rotates.

Next, the operation of the holding bar 32 for removing the body 11b and the flange 11c of the blind rivet 10 from the base materials 1, 2 will be described with reference to FIG. When the operation button is pressed, the compressed air enters the piston chamber 51 through the air hose 24a by the switching operation of the air valve 24v. Thus, the piston 26 is pushed out in the direction F in FIG. The piston 26 moves until it hits the stoppers B1, B2 on the inner surface of the cylindrical structure 21. In addition, the piston 26 is connected to a pressing rod 32 penetrating through the center of the piston 30 via a joint 29. Therefore, when the operation button 23 is pressed, the pressing rod 32 also moves in the F direction in conjunction with the piston 26. When the operation button is released, the piston chamber 51 is released.
Is discharged from the air hose 24a to the exhaust port 24c, so that the piston 26 moves the stoppers A1, A2 on the inner surface of the cylindrical structure 21 by the force of the spring 27.
Return to position 2. Pressing rod 3 in conjunction with piston 26
2 also returns to the original position.

The pressing rod 32 and the piston 30 are
In particular, since tightness is required on the piston chamber 52 side,
A packing 28 such as an O-ring is provided. Due to the structure of the disassembly tool 100E, the packing 28 must have good sealing performance for movement in the thrust direction, but the holding rod 32 can rotate freely together with the piston 30 by the joint 29, and the packing 28 Since no force in the rotating direction is applied, the reliability of the packing 28 is improved.

Next, the operation of disassembling the blind rivet 10 using the disassembly tool 100E will be described. FIG. 11 shows the fastening portion of the blind rivet 10 by the cylindrical cutting blade 500 and the radial cutting blade 600 of the disassembling tool 100E along the boundary region in the body axial direction between the flange portion 11c and the body portion 11b of the blind rivet 10. 2 shows a cross-sectional view of a state in which is cut.

The inner diameter of the opening of the attachment 40 of the disassembly tool 100E is, for example, 9.7 mm, which is slightly larger than the outer diameter of the flange 11c of the blind rivet 10 of 9.6 mm. First, as shown in FIG.
The disassembly tool 100E is set by pressing down from above so that the flange portion 11c enters the attachment 40. Then, when the operation button is pressed, the piston 30 is pushed out by the compressed air, and the cylindrical cutting blade 500 and the radial cutting blade 600 attached to the tip of the piston 30 partially cut the flange portion 11c at equal intervals. . Here, since the stroke of the piston 30 is regulated by the stoppers D1 and D2, the base materials 1 and 2 are not damaged.

After the end of the first cutting, the pressing of the operation button is released. Thus, the cylindrical cutting blade 500 and the radial cutting blade 600 return while rotating by 45 degrees. Further, when the operation button is pressed, the cylindrical cutting blade 500 and the radial cutting blade 600 are moved 45 degrees from the first cutting position.
Cut off the shifted part. As described above, by repeatedly pressing and releasing the operation button at least twice, the circumferential cutting portion 504 and the radial cutting portion 604 corresponding to the cylindrical cutting blade 500 and the radial cutting blade 600 on the flange portion 11c. Is formed, and the flange portion 11c and the body portion 11 are formed.
b is cut.

FIG. 12 (a) shows four circumferential cutting portions 504 and a radial cutting portion 604 cut group formed on the flange portion 11c by one operation of the operation button with the disassembling tool 100E. It is a top view showing a state. FIG.
2B is a plan view showing that a ring-shaped circumferential cutting portion 504 and eight radial cutting portions 604 are formed on the flange portion 11c by operating the operation button at least twice. It is.

Thus, the ring-shaped circumferential cut portion 504 is formed on the flange portion 11c,
The flange 11c and the body 11b are cut and separated. Further, since the radial cutting portion 604 is formed on the flange portion 11c, the flange portion 11c is cut into a plurality of divided portions.

Here, since the body 11b normally stays in a form of being pressed against the through holes 1a, 2a of the base materials 1, 2, after the flange 11c is separated as described above, It is necessary to forcibly remove the body 11b from the base materials 1 and 2. FIG. 13 is an explanatory view showing a state in which the body 11b is removed from the base materials 1 and 2 by the holding rod 32 of the disassembly tool 100E.

As shown in FIG. 12B, when the operation button is pressed after the circumferential cut portion 504 and the radial cut portion 604 are formed on the flange portion 11c, the pressing rod 3
2 is extruded and applies a force to the trunk 11b. Then, the body 11b and the mandrel 12a are removed by the pressing force of the pressing rod 32, while leaving the flange 11c.

[0095]

According to the first to eighth aspects of the present invention, the flange portion of the fastening member is radially divided into a plurality of pieces and cut by the radial cutting blade. The load applied to the cylindrical cutting blade is reduced, and the cutting force applied to the cylindrical cutting blade can be reduced.
Further, the fastening portion of the fastening member is cut into a cylindrical shape by the cylindrical cutting blade, and the flange portion of the fastening member is radially cut by the radial cutting blade,
Since the flange portion is divided into a plurality of portions from the body of the fastening member and separated, the flange portion does not become entangled with the cylindrical cutting blade after the cutting, and the separability of the flange portion is improved. There is an excellent effect.

In particular, according to the second aspect of the present invention, since the cutting edge of the radial cutting blade is inclined so as to protrude toward the axial center, the flange of the fastening member is formed by the radial cutting blade. When cutting, the cutting edge of the radial cutting blade gradually bites from the axial center side of the flange portion toward the outer peripheral side, whereby the load applied to the radial cutting blade when cutting the flange portion of the fastening member And the cutting force applied to the radial cutting blade is reduced.

According to the third aspect of the present invention, since the cylindrical cutting blade and the radial cutting blade are integrally formed, the cylindrical cutting blade and the body of the fastening member formed by the cylindrical cutting blade are integrated. The cutting of the boundary region with the flange portion and the cutting of the flange portion of the fastening member by the radial cutting blade can be performed substantially simultaneously by a single cutting operation, so that the operation of the disassembly tool is facilitated, and There is an excellent effect that the time required for disassembling members can be reduced.

According to the fourth aspect of the present invention, the radial cutting blade can be rotated by a predetermined angle about the axis center as the rotation center by the rotating means. Can be cut more finely and the load applied to the cylindrical cutting blade at the time of cutting the fastening portion of the fastening member can be further reduced, and the cutting force applied to the cylindrical cutting blade can be reduced. There is an excellent effect.

In particular, according to the fifth aspect of the present invention, by applying a cutting force to the cylindrical cutting blade and the radial cutting blade by the cutting force applying means irrespective of an external impact, the cylindrical cutting blade is provided. There is an excellent effect that the boundary region between the trunk portion and the flange portion of the fastening member is cut by the blade, and the flange portion of the fastening member can be cut by the radial cutting blade.

According to the sixth aspect of the present invention, the cutting blade stopping means causes the cutting edges of the cylindrical cutting blade and the radial cutting blade to be at least between the flange portion of the fastening member and the base material. Since the cylindrical cutting blade, and the movement of the radial cutting blade are stopped in a state of substantially reaching the boundary surface,
There is an excellent effect that damage to the base material by the cylindrical cutting blade and the radial cutting blade can be reliably avoided.

In particular, according to the invention of claim 7, the cutting blade positioning member fits into the shaft hole of the flange portion, so that when cutting the fastening portion of the fastening member, the cylindrical cutting blade, And, since the cutting position of the radial cutting blade is determined, the cutting position of the cylindrical cutting blade and the radial cutting blade does not shift when cutting the fastening portion of the fastening member, and the flange is removed from the trunk portion. There is an excellent effect that the parts can be reliably separated.

According to the eighth aspect of the present invention, the radial cutting blade is disposed so as to be movable in the cutting direction with respect to the cylindrical cutting blade. Or even by polishing the cutting edge of the radial cutting blade, even if the relative positional relationship of the cutting direction of the cutting edge of the cylindrical cutting blade and the radial cutting blade changes, relative to the cylindrical cutting blade, By moving and adjusting the radial cutting blade along the cutting direction, the relative positional relationship of the cutting edge between the cylindrical cutting blade and the radial cutting blade in the cutting direction is adjusted to be an appropriate positional relationship. it can. Further, without replacing the cylindrical cutting blade and the radial cutting blade, the cylindrical cutting blade and the radial cutting blade are adapted to fit the dimensions of the fastening portion and the flange portion of the fastening member to be disassembled. There is an excellent effect that the relative positional relationship between the cutting edge and the cutting direction can be changed.

[Brief description of the drawings]

FIGS. 1A and 1B are schematic perspective views showing a cylindrical cutting blade of a disassembling tool for a fastening member according to an embodiment of the present invention.

FIGS. 2A, 2B and 2C are schematic perspective views showing a radial cutting blade of a disassembling tool for a fastening member according to an embodiment of the present invention.

FIG. 3 is a schematic cross-sectional view showing a state where a flange portion of a blind rivet is cut by the radial cutting blade.

FIG. 4 is a schematic perspective view showing a flange portion of a blind rivet cut by the radial cutting blade.

FIG. 5 is a disassembly tool 1 for a fastening member according to the embodiment of the present invention.
Schematic sectional view showing 00C.

FIG. 6 is a schematic sectional view showing a disassembly tool 100D for a fastening member according to another embodiment of the present invention.

FIG. 7 is a configuration diagram of a main part of a disassembling tool 100E for a fastening member according to still another embodiment of the present invention.

FIG. 8 is a detailed view of a joint portion of the disassembly tool 100E.

FIGS. 9A and 9B are explanatory views showing the configuration of the cutting edges of a cylindrical cutting blade and a radial cutting blade of the disassembly tool 100E.

FIG. 10 is an inner developed view of the cylindrical structure of the disassembly tool 100E.

FIG. 11 is an explanatory view showing a state in which a fastening member is being cut by the disassembly tool 100E.

FIGS. 12A and 12B show the disassembly tool 100E.
Explanatory drawing of the process which cuts a fastening member according to FIG.

FIG. 13 is an explanatory view showing a state where the body of the fastening member is removed by the disassembly tool 100E.

14A and 14B are cross-sectional views of a main part for describing screw fastening.

FIGS. 15A and 15B are cross-sectional views of main parts for describing pin fastening.

16 (a), (b), (c), (d), (e),
(F) is an important section sectional view for explaining rivet fastening.

17 (a), (b), (c) and (d) are process diagrams showing a procedure for fastening a blind rivet to a base material.

FIG. 18 is a sectional view of a main part for describing a tubular rivet.

FIG. 19 is a schematic cross-sectional view for explaining a conventional method for disassembling a fastening member.

FIG. 20 is a schematic cross-sectional view for explaining a problem of a conventional disassembling method of a fastening member.

FIG. 21 is a schematic sectional view showing the configuration of a disassembly tool 100A in which the present invention is implemented.

FIG. 22 is a schematic sectional view showing the configuration of another disassembly tool 100B in which the present invention is implemented.

FIG. 23 shows the disassembly tool 100A (or 100B).
FIG. 4 is a schematic cross-sectional view showing a state in which a flange portion of a fastening member is cut by the method.

FIG. 24 shows the disassembly tool 100A (or 100B).
The schematic sectional drawing which shows the state which cut the dish-shaped flange part of the fastening member by the.

FIG. 25 shows the disassembly tool 100A (or 100B).
Sectional drawing which shows the state of the flange part of the fastening member cut | disconnected by the cutting blade of FIG.

[Explanation of symbols]

 1, 2 Base metal 1a, 2a Base material fastening hole 10 Blind rivet 11a Blind rivet shaft hole 12 Blind rivet mandrel 11b Blind rivet body 11c Blind rivet flange 21 Cylindrical structure 24, 24a, 24b Air Hose 24c Exhaust port 25 Compressed air generator 26, 30 Piston 27, 31 Spring 28 Packing 29 Joining part 32 Holding rod 33 Convex part 35 Ball part at the tip of piston 26 Joint 37 Joint plate 38 Screw 39a-39h Leaf spring 40 Attachment 41 Hemispherical holes 42a to 42h at the upper end of the holding rod 42 Branch point 43 Circular cutting part 51, 52 Piston chamber 100C, 100D, 100E Disassembly tool 200 Cutting blade support 300 Cutting force applying means 400 Centering shaft 4 Edge of radial cutting blade 603 radially cutting blade of the stepped portion 600 disassembling tool cutting edge 505 cylindrical cutting edge of the cylindrical cutting blade 503 cylindrical cutting blade fitting portion 500 decomposition tool 0a centering shaft

Claims (8)

[Claims] 1. A fastening member fastened to a base material by a body portion inserted into a fastening hole of the base material and a flange portion substantially integral with the body portion pressed into contact with a peripheral portion of the fastening hole. In a disassembling tool for a fastening member for removing a member from the base material, a cylindrical shape that cuts the body and the flange into a substantially cylindrical shape along a boundary region in the body axial direction between the body and the flange. A disassembly tool for a fastening member, comprising: a cutting blade; and a radial cutting blade for cutting a flange portion of the fastening member substantially radially with respect to an axial center of the fastening member. 2. The disassembly tool for a fastening member according to claim 1, wherein the cutting edge of said radial cutting blade is inclined so as to protrude toward said axial center. 3. The disassembly tool for a fastening member according to claim 1, wherein said cylindrical cutting blade and said radial cutting blade are integrally formed. tool. 4. A disassembly tool for a fastening member according to claim 1, further comprising a rotating means for rotating said radial cutting blade by a predetermined angle around said axis center as a center of rotation. Disassembly tool for fastening members. 5. The disassembly tool for a fastening member according to claim 1, 2, 3, or 4, wherein said cylindrical cutting blade and said radial cutting blade are attached to said fastening member along said body axis direction. A disassembly tool for a fastening member, comprising cutting force applying means for applying a cutting force for cutting a fastening portion. 6. The disassembly tool for a fastening member according to claim 5, wherein the cutting force applied by the cutting force applying means causes at least the cutting edges of the cylindrical cutting blade and the radial cutting blade to have at least the fastening member. The cylindrical cutting blade and the cutting member stopping means for stopping the movement of the radial cutting blade in a state of substantially reaching the boundary surface between the flange portion and the base material. Disassembly tool. 7. The disassembly tool for a fastening member according to claim 1, 2, 3, 4, 5, or 6, wherein a shaft formed on a flange portion of the fastening member substantially coaxial with a body of the fastening member. Fitting the hole, when cutting the fastening portion of the fastening member, the cylindrical cutting blade, and has a cutting blade positioning member that positions the cutting position of the radial cutting blade. Disassembly tool for fastening members. 8. The method of claim 1, 2, 3, 4, 5, 6, or
7. The disassembly tool for a fastening member according to 7, wherein the radial cutting blade is arranged so as to be movable and adjustable in a cutting direction with respect to the cylindrical cutting blade.