KR20240099611A - swaging tool - Google Patents

Abstract

The present invention relates to a swaging tool. According to the present invention, the swaging tool comprises: a support means to be supported by an object or a bearing member; and a pressing means provided on one side of the support means, and rotated while pressing a portion of the bearing member mounted on the support means to enable the bearing member and the object to be coupled. According to the present invention, damage to the bearing member is prevented in the swaging process.

Description

Swaging tool {swaging tool}

The present invention relates to a swaging tool, and more specifically, the pressing means is configured to locally contact the bearing member, and the swaging of the bearing member is achieved by gradually swaging the bearing member through rotation of the pressing means. It is about a swaging tool that prevents damage during the process.

In general, swaging refers to a type of plastic processing that seeks to achieve a goal through deformation of an object.

Conventionally, it is used to enable bonding between two objects through swaging.

In this regard, in Korean Patent No. 10-1803842, the structure includes a first metal material on which a hole portion is formed, and a second metal material on which a vertical flange is formed while being inserted into the hole portion, and the second metal material is used on the hole portion. A swaging structure of a metal material that allows coupling of a first metal material and a second metal material by swaging a vertical flange after insertion into a metal material, and a bus bar using this swaging structure are disclosed.

However, in the metal swaging structure according to the prior art and the bus bar using this swaging structure, excessive load is applied to the swaging device when pressure is applied to the entire area in the process of swaging the vertical flange. Alternatively, there was a problem of damage to the vertical flange.

Korea Registered Patent No. 10-1803842

Therefore, the purpose of the present invention is to solve the problems of the prior art as described above, and the pressing means is configured to locally contact the bearing member, and the swaging of the bearing member is gradually reduced through rotation of the pressing means. The aim is to provide a swaging tool that prevents damage during the swaging process of bearing members.

According to the features of the present invention for achieving the above-described object, a support means for supporting an object or a bearing member is provided on one side of the support means and a part of the bearing member seated on the support means is pressed. It is characterized by including a pressing means that allows the bearing member and the object to be coupled by rotation.

The support means includes a support body that has an external shape and provides an area for supporting an object or a bearing member, and is formed on one surface of the support body and is seated on the bearing member and the support body, so that the bearing member and the support body It is characterized by including a prevention groove to prevent interference.

The pressing means includes a pressing body that has an external shape and has a first engaging groove that allows insertion of a key on one side and a second engaging groove that allows insertion of a rotating shaft on the other side, and the pressing A coupling portion provided on one side of the body and having at least one through hole through which the rotation axis can pass and a coupling hole through which a pressing member can be installed, and a coupling portion provided on one side of the coupling portion and having the coupling portion formed on one side of the pressing body. A rotating shaft that can be rotatably supported, a fixing part provided on the outer ring of the rotating shaft and a part of which is inserted into the interior of the bearing member, and a fixed portion provided on the other side of the pressing body and the rotating shaft can be coupled inside the pressing body. It is characterized by comprising a key that presses the bearing member and a pressing member provided inside the coupling hole.

The coupling hole is characterized in that it is formed at an angle.

The pressing member is characterized in that it is rotatably installed inside the coupling hole.

The swaging tool according to the present invention has the following effects.

In the present invention, as the pressing member is installed at an angle, the bearing housing is guided to be swaged in an outward direction, which has the advantage of preventing defects in the rotation angle of the ball bearing.

In the present invention, the pressure members are individually rotatable, thereby reducing friction, and this has the advantage of reducing damage to the bearing member due to heat generation.

In the present invention, the pressing member is provided to contact a portion of the guide groove, and the entire guide groove can be swaged through rotation, so there is an advantage in that damage to the bearing member due to excessive load can be reduced.

1 is an exploded view showing the configuration of a preferred embodiment of the swaging tool according to the present invention.
Figure 2 is a cross-sectional view showing an application example of a preferred embodiment of the swaging tool according to the present invention.
Figure 3 is an upper perspective view showing the configuration of a support means constituting a preferred embodiment of the swaging tool according to the present invention.
Figure 4 is a bottom perspective view showing the configuration of the pressing means constituting a preferred embodiment of the swaging tool according to the present invention.
Figure 5 is a cross-sectional view showing swaging according to a preferred embodiment of the swaging tool according to the present invention.

First, the object 100 and bearing member 200 to which the swaging tool according to the present invention is applied will be described.

The object 100 corresponds to a lock link used in an aircraft landing gear, and is a portion where an insertion hole 110 for inserting the bearing member 200 is formed.

Of course, the object 100 may correspond to an unspecified product used in various areas, and is characterized by the formation of an insertion hole 110 for inserting the bearing member 200.

The insertion hole 110 is formed to penetrate the object 100, and as shown in FIG. 2, the upper or lower end is formed to be expanded, so that when swaging of the bearing member 200 is performed, the insertion hole 110 is formed to penetrate the object 100. ) and the insertion hole 110 may be preferably configured to be combined.

Meanwhile, as shown in FIG. 2, the bearing member 200 includes a bearing housing 210 that accommodates a ball bearing 220, and a ball bearing that is rotatably accommodated inside the bearing housing 210. (220) and the like.

Here, a guide groove 211 is formed in the bearing housing 210 to guide swaging by the swaging tool according to the present invention.

The guide groove 211 is formed on the upper or lower surface of the bearing housing 210 to facilitate swaging by the pressing means 400 of the present invention.

It is preferable that the guide groove 211 is recessed inward from the upper or lower surface of the bearing housing 210 and has a ring shape.

Additionally, the guide groove 211 may preferably be formed in a shape similar to a 'v' shape.

Of course, it is preferable that the guide groove 211 is formed close to the outer ring side on the upper or lower surface of the bearing housing 210.

Meanwhile, for example, the ball bearing 220 has a height longer than the height of the insertion hole 110.

That is, in the process of the pressing means 400 pressurizing the guide groove 211, the outer ring of the bearing housing 210 is expanded, and through this, the bearing member 200 and the object 100 can be coupled. .

In addition, the ball bearing 220 is made in a shape similar to a ring whose circumferential surface is similar to a sphere.

Here, as the ball bearing 220 has a shape similar to a ring, a penetrating portion is formed, and a portion of the support means 300 and the pressing means 400 may be inserted into this penetrating portion.

Hereinafter, a preferred embodiment of the swaging tool according to the present invention will be described with reference to the drawings.

1 to 5 show one embodiment of a swaging tool according to the present invention. That is, Figure 1 shows an exploded view showing the configuration of a preferred embodiment of the swaging tool according to the present invention, and Figure 2 shows a cross-sectional view showing an application example of the preferred embodiment of the swaging tool according to the present invention. 3 shows a top perspective view showing the configuration of the support means constituting a preferred embodiment of the swaging tool according to the present invention, and Figure 4 shows the configuration of the pressing means constituting a preferred embodiment of the swaging tool according to the present invention. A bottom perspective view is shown, and Figure 5 shows a cross-sectional view showing swaging according to a preferred embodiment of the swaging tool according to the present invention.

As shown in these drawings, the swaging tool according to the present invention includes support means 300 for supporting the object 100 or bearing member 200, and one side of the support means 300. It is configured to include a pressing means 400 that presses and rotates a portion of the bearing member 200 mounted on the support means 300 so that the bearing member 200 and the object 100 can be coupled.

The support means 300 includes a support body 310 that has an external shape and provides an area for supporting the object 100 or the bearing member 200, and is formed on one surface of the support body 310. When the bearing member 200 is seated on the support body 310, it includes a prevention groove 320 to prevent interference between the bearing member 200 and the support body 310.

The support body 310 forms the outer shape of the support means 300 and has a shape similar to a circular pillar.

Of course, the support body 310 may have a different pillar shape, and the pillar shape is intended to allow the object 100 to be positioned away from the ground or the pedestal.

A prevention groove 320 is formed on the upper surface of the support body 310 (in FIG. 3).

The prevention groove 320 is recessed in the downward direction from the upper surface of the support body 310, and when the bearing member 200 is seated on the support body 310, the bearing member 200 and the support body 310 This is an area to prevent interference.

It would be desirable for the prevention groove 320 to be recessed into a ring shape.

In this way, as the prevention groove 320 is formed, the central portion of the upper surface of the support body 310 is formed to protrude in the shape of a circular column, and the outer ring portion of the upper surface is formed to protrude in a ring shape.

Here, as the prevention groove 320 is formed, the ball bearing 220 is inserted into the portion that protrudes in a circular column shape from the central portion of the upper surface of the support body 310, and the outer ring of the upper surface of the support body 310 The bearing housing 210 and the object 100 are seated on the portion that protrudes in a ring shape from the portion.

In addition, as the prevention groove 320 is formed, the upper outer ring portion of the upper surface of the support body 310 that protrudes in a cylindrical shape from the center is formed to have a gradually narrower diameter inward, thereby facilitating the insertion of the ball bearing 220. It is desirable to configure it so that it can be easily accomplished.

In addition, at least one open groove 330 may be formed on one surface of the support body 310 to allow confirmation of whether the bearing member 200 is seated from the outside.

The open groove 330 is recessed downward from the upper surface of the support body 310 (in FIG. 3), and is a portion that allows confirmation from the outside whether the bearing member 200 is seated.

It would be desirable for the opening groove 330 to be connected to the prevention groove 320 and the outer ring of the support body 310.

That is, the open groove 330 has a shape penetrating from the outer ring of the support body 310 in the inner and upper directions.

The bearing member 200 and the object 100 can be seated by the support means 300 configured in this way.

Meanwhile, a pressing means 400 is provided to enable swaging of the bearing member 200 mounted on the support means 300.

The pressing means 400 has an external shape and has a first coupling groove 411 formed on one side to allow insertion of the key 450, and a first coupling groove 411 that allows insertion of the rotation shaft 430 on the other side. 2 A pressing body 410 in which a coupling groove 412 is formed, a through hole 421 and a pressing member 460 provided on one side of the pressing body 410 through which the rotating shaft 430 can pass are installed. A coupling portion 420 having at least one coupling hole 422 formed on one side of the coupling portion 420, and the coupling portion 420 being rotatable on one side of the pressing body 410. A rotating shaft 430 that can be supported, a fixing part 440 provided on the outer ring of the rotating shaft 430 and a part of which is inserted into the bearing member 200, and a fixed portion 440 on the other side of the pressing body 410. A key 450 is provided so that the rotating shaft 430 can be coupled inside the pressing body 410, and a pressing member 460 is provided inside the coupling hole 422 and presses the bearing member 200. It is composed including, etc.

The pressing body 410 forms the external shape of the pressing means 400 and is a portion for supporting a plurality of components.

This pressing body 410 is combined with a device such as a drilling machine that allows vertical movement while applying rotational force, and has a shape similar to a circular pillar.

In addition, a groove may be further formed on the bottom of the pressing body 410 to prevent interference with the pressing member 460.

Additionally, a chucking portion 413 may be formed to protrude on the upper surface of the pressing body 410 so that it can be coupled to a drilling machine, etc.

The chucking portion 413 is formed to protrude upward from the upper surface of the pressing body 410 (in FIG. 4), and is a portion that has a smaller diameter than the pressing body 410 and is located on the same center line.

It can be combined with a drilling machine, etc. through the chucking part 413.

And, a second coupling groove 412 is formed on the bottom of the pressing body 410 (in FIG. 2).

The second coupling groove 412 is recessed from the bottom of the pressing body 410 upward, and is a portion where the rotation shaft 430 can be inserted.

Of course, it would be desirable for the second coupling groove 412 to be located on the center line of the pressing body 410.

At the same time, a first coupling groove 411 is formed on the side of the pressing body 410.

The first coupling groove 411 is recessed in the inner direction from the side of the pressing body 410, and is formed by the rotation shaft 430 inserted into the inside of the pressing body 410 through the second coupling groove 412. This is the area where the key 450 for fixation can be inserted.

It would be preferable that the first coupling groove 411 be connected to the second coupling groove 412 for contact between the rotating shaft 430 and the key 450.

Accordingly, a rotation shaft 430 inserted into the second coupling groove 412 and a key 450 inserted into the first coupling groove 411 are provided.

The rotation shaft 430 is inserted into the second coupling groove 412 formed in the pressing body 410, and the coupling portion 420 can rotate on the lower side of the pressing body 410 (in FIG. 2). This is the part that allows it to be supported.

The rotation shaft 430 has a shape similar to a circular pillar with a long length up and down (in FIG. 2) and a narrow diameter, and the lower end is expanded to form a coupling portion 420 or a fixing portion ( 440) is configured to prevent it from deviating in the downward direction.

In addition, the key 450 is inserted into the first coupling groove 411 formed in the pressing body 410, so that the rotation axis 430 can be fixed inside the second coupling groove 412. This is the part where

For this, the key 450 will have to be fixed inside the first coupling groove 411.

That is, screws may be formed on the outer ring of the key 450 and the inside of the first coupling groove 411, and through this, the key 450 can be fixed inside the first coupling groove 411. .

Meanwhile, a coupling portion 420 is provided on the outer ring of the rotating shaft 430.

The coupling portion 420 has a shape similar to a circular plate, and is a portion where the through hole 421 and the coupling hole 422 are formed.

Here, the through hole 421 is formed through the central portion of the coupling portion 420 in the up and down direction (in FIG. 2) and is a portion through which the rotating shaft 430 can be inserted.

Through this through hole 421, the rotation shaft 430 can be inserted into the second coupling groove 412 while penetrating the coupling portion 420.

That is, the coupling portion 420 is coupled to the rotating shaft 430 through the through hole 421 and is located on the lower side of the pressing body 410 (in FIG. 2).

In addition, at least one coupling hole 422 is formed in the coupling portion 420.

The coupling hole 422 is formed downwardly from the upper surface of the coupling part 420, and is formed at least one at a position spaced a predetermined distance outward from the center of the coupling part 420.

At this time, it would be desirable for the plurality of coupling holes 422 to be arranged in a ring shape.

And, the coupling hole 422 is formed to be inclined.

This is so that the pressing member 460 installed inside the coupling hole 422 can be positioned at an angle.

That is, since the pressing member 460 is installed at an angle, swaging of the bearing housing 210 is more easily performed in the outer direction of the bearing housing 210.

This means that, when swaging the bearing housing 210 through the pressing member 460, if the bearing housing 210 is not swaged in the outward direction based on the guide groove 211 formed in the bearing housing 210, but is swaged in the inward direction, This is because the rotation angle of the ball bearing 220 provided inside the bearing housing 210 may be limited.

To explain once more, as the pressing member 460 is formed to be inclined, swaging in the outward direction can be induced based on the guide groove 211 formed in the bearing housing 210, and through this, the ball bearing 220 A sufficient rotation angle can be obtained.

Of course, it is preferable that the direction in which the coupling hole 422 is inclined is such that the pressing member 460 installed in the coupling hole 422 moves away from the center of the coupling portion 420 from the top to the bottom.

A pressing member 460 is provided inside the coupling hole 422.

The pressing member 460 is provided inside the coupling hole 422 and has a shape similar to a circular pillar.

In this way, the pressing member 460 has a shape similar to a circular pillar and is configured to press the bearing housing 210 through the lower peripheral surface.

This pressing member 460 is a part that is inserted into the guide groove 211 formed in the bearing housing 210 and allows swaging to occur.

That is, the bearing housing 210 is swaged by the pressing member 460 pressing the bearing housing 210 .

Of course, the pressing member 460 is installed at an angle as the coupling hole 422 is formed at an angle.

Such a plurality of pressing members 460 may be provided as the plurality of coupling holes 422 are formed, and the plurality of pressing members 460 press along the guide groove 211 in the process of rotation. .

That is, instead of pressurizing the entire guide groove 211, local pressure is applied by the press member 460, and swaging of the entire guide groove 211 is performed through rotation.

Accordingly, the load applied to the bearing housing 210 can be greatly reduced, and along with this, damage to the bearing housing 210 is also greatly reduced.

In addition, the pressing member 460 may be rotatably installed inside the coupling hole 422.

That is, the pressing member 460 may be installed inside the coupling hole 422 using a bearing (not shown), and may be individually rotatable inside the coupling hole 422 through this.

In this way, when the pressing member 460 is rotatably provided inside the coupling hole 422, the friction force can be reduced in the process of pressing the guide groove 211 formed in the bearing housing 210, and thus Accordingly, heat generation is greatly reduced.

To explain one more time, since the pressing member 460 is rotatable, heat generated during the swaging process is greatly reduced, and damage to the bearing housing 210 is also greatly reduced.

Meanwhile, a fixing part 440 is provided on the outer ring of the rotating shaft 430.

The fixing part 440 is coupled to the outer ring of the rotating shaft 430 and has a shape similar to a ring shape.

Accordingly, the fixing part 440 may be penetrated by the rotating shaft 430.

Here, the rotation shaft 430 preferably passes through the fixing part 440, the coupling part 420, and the second coupling groove 412 in order so that the fixing part 440 can be positioned at the bottom.

In addition, it is desirable that the diameter of the fixing part 440 corresponds to the inner ring of the ball bearing 220, so that it can provide an origin when inserted into the inner ring of the ball bearing 220.

That is, by inserting the fixing part 440 into the inner ring of the ball bearing 220, the pressing member 460 may be positioned at a position corresponding to the guide groove 211.

Swaging of the bearing member 200 can be performed by the pressing means 400 configured in this way.

That is, in the swaging tool according to the present invention, as the pressing member is installed at an angle, the bearing housing is guided to be swaged in the outward direction, thereby preventing defects related to the rotation angle of the ball bearing.

In addition, in the swaging tool according to the present invention, the pressure members are individually rotatable, thereby reducing the friction force, thereby reducing damage to the bearing member due to heat generation.

In addition, in the swaging tool according to the present invention, the pressing member is provided to contact a part of the guide groove, and the entire guide groove can be swaged through rotation, so that damage to the bearing member due to excessive load can be reduced. It has been done.

The scope of the present invention is not limited to the embodiments illustrated above, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

100. Object 110. Insertion hole
200. Bearing member 210. Bearing housing
211. Guide groove 220. Ball bearing
300. Support means 310. Support body
320. Prevention groove 330. Open groove
400. Pressurizing means 410. Pressurizing body
411. First coupling groove 412. Second coupling groove
413. Chucking part 420. Joining part
421. Through hole 422. Coupling hole
430. Rotating shaft 440. Fixed part
450. Height 460. Pressure member

Claims (5)

A support means capable of being supported with an object or bearing member;
A swaging tool comprising: a pressing means provided on one side of the support means and rotating while pressing a portion of the bearing member seated on the support means so that the bearing member and the object can be coupled. According to claim 1,
The support means is,
A support body that forms an external shape and provides an area for supporting an object or bearing member;
A swaging tool comprising a prevention groove formed on one surface of the support body and preventing interference between the bearing member and the support body when seated on the bearing member and the support body. According to claim 1,
The pressurizing means is,
A press body that has an external shape and has a first coupling groove on one side through which a key can be inserted and a second coupling groove on the other side through which a rotating shaft can be inserted;
a coupling portion provided on one side of the pressing body and having at least one through hole through which a rotating shaft can pass and at least one coupling hole through which a pressing member can be installed;
a rotation shaft provided on one side of the coupling portion and allowing the coupling portion to be rotatably supported on one side of the pressing body;
a fixing part provided on the outer ring of the rotating shaft and part of which is inserted into the bearing member;
a key provided on the other side of the pressing body and allowing the rotation axis to be coupled inside the pressing body;
A swaging tool, characterized in that it includes a pressing member provided inside the coupling hole and pressing the bearing member. According to claim 3,
The swaging tool is characterized in that the coupling hole is formed inclinedly. According to claim 3,
A swaging tool, characterized in that the pressing member is rotatably installed inside the coupling hole.

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