KR20160092369A - Bidirectional processing jig device according to the rotational axis - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bidirectional processing jig apparatus to which a rotary shaft is applied.
A handle configured to be mounted on both sides of the base plate and configured to be moved by the user to carry the base plate and configured to be in the center of the base plate, A rotary cylinder which is formed on the rear surface of the binding portion and which generates physical energy for rotating the binding portion and which is located on both sides of the binding portion with reference to the binding portion and can perform linear motion by using air pressure, The present invention relates to a bi-directional processing jig device to which a rotary shaft including a pneumatic cylinder configured to be machined is applied.

Description

TECHNICAL FIELD [0001] The present invention relates to a bidirectional processing jig device using a rotary shaft,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bidirectional processing jig apparatus to which a rotary shaft is applied. More particularly, the present invention relates to a method of manufacturing a work machine by forming a stationary support on an upper end of a rotating shaft capable of rotating 180 degrees and engaging with a workpiece, generating power by a rotary cylinder, rotating the rotary shaft, first machining the workpiece with a primary pneumatic cylinder And a rotary shaft for secondarily machining the workpieces with the secondary pneumatic cylinder constructed on the right side when rotated to the right.

Generally, a factory that mass-produces a product and a machine that processes it are produced by pressing or partially cutting a product through vertical motion.

Accordingly, Japanese Laid-Open Patent Application No. 2010-0133250 (hereinafter referred to as "Prior Art Document 1") has filed a vertical turning apparatus for both drilling and tapping.

The drilling machine 8 and the tapping machine 10 are installed on the fixed plate 6 on the work table 4 and are provided with two columns each having a handle 14a and 14b, The brackets 12a and 12b are structured so that the support shaft 16a of the drilling machine 8 and the support shaft 16b of the tapping machine 10 can be lifted and lowered and the two column brackets 12a and 12b, A linear slide 32 with a table 34 rotatable about its axis is extended to the left and right and a linear slide 32 is connected to a rod 38a of the operation cylinder 38 .

However, there is a disadvantage in that when the processed product is processed, the production process is somewhat complicated, the cost of components constituting the production line is increased, and the cost competitiveness is negatively affected, .

(Patent 0001) Korean Patent Publication No. 2010-0133250

In order to solve the problems of the related art, the present invention is a rotary pneumatic cylinder comprising a fixed support at an upper end of a rotating shaft capable of rotating 180 degrees, coupled with a workpiece, generating a power by a rotary cylinder, The present invention provides a bidirectional machining jig device to which a rotary shaft for secondary machining a work piece with a secondary pneumatic cylinder constructed on the right side is applied after the workpiece is first machined by the first machining.

Another object of the present invention is to provide a bi-directional processing jig device in which unnecessary components are excluded and an actuator and a cylinder necessary for machining the workpiece are constituted to simplify the production process.

It is another object of the present invention to provide a bidirectional processing jig device using a rotary shaft that can reduce the manufacturing cost of the jig device by simplifying the components of the jig device.

According to a first aspect of the present invention, there is provided a bidirectional working apparatus for a rotary shaft, comprising: a base plate; a handle configured to be carried by both sides of the base plate, A rotary cylinder which is formed in the center of the binding portion and which is configured to be able to process the workpiece by rotating it by a maximum of 180 degrees and which is formed on the rear portion of the binding portion and generates physical energy for rotating the binding portion; And a bidirectional machining jig device using a rotary shaft including a pneumatic cylinder disposed on both sides of the binding portion with respect to the binding portion and capable of performing linear motion using air pressure and configured to process the workpiece through linear motion.

The coupling unit may include a support member configured to receive the workpiece, a rotary member configured to rotate the workpiece bound to the support member to a maximum of 180 degrees, and a connection unit configured to transmit power to the rotary member, And a bidirectional working jig device to which a rotary shaft including a member is applied.

In addition, the supporting member may be a bi-directional working jig device to which a rotating shaft is further applied, which is not separated from the workpiece, and which further includes fixing means for preventing fine movement when the workpiece is processed and manufactured, .

Further, the rotary member may include a bidirectional processing jig device to which a rotary shaft is further applied, the rotary device being configured to rotate the support member by a maximum of 180 degrees in response to a rotary motion generated in the rotary cylinder .

The rotary cylinder further includes a bi-directional processing jig device which is coupled to a side surface of the rotary cylinder, and which includes a pneumatic compressor configured to generate compressed air and to be transferred to the rotary cylinder .

The pneumatic cylinder may further include a bi-directional processing jig device coupled to a front portion of the pneumatic cylinder and configured to apply a rotation axis that further includes a model frame configured differently according to a model of a workpiece to be processed by a user.

As described above, an object of the present invention is to provide a method and a device for assembling a workpiece by forming a stationary support on an upper end of a rotating shaft capable of rotating 180 degrees and being coupled to a workpiece, generating power by a rotary cylinder, rotating the rotary shaft, After the first machining, rotate to the right and apply the second axis machining to the second pneumatic cylinder on the right.

Further, the present invention excludes unnecessary components, and the actuator and the cylinder necessary for machining the workpiece can be constituted, so that the production process can be simplified.

Further, the present invention simplifies the constituent elements of the jig device, thereby reducing the manufacturing cost of the jig device.

1 is a perspective view showing a conventional vertical drilling and tapping machine,
2 is a perspective view showing a bidirectional processing jig apparatus to which a rotary shaft of the present invention is applied,
3 is an exploded perspective view showing a bidirectional working jig apparatus to which a rotary shaft of the present invention is applied,
4 is a front view showing an operating state of the bidirectional working jig apparatus to which the rotary shaft of the present invention is applied.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It should be understood that various equivalents and modifications are possible.

2 is a perspective view showing a bidirectional processing jig apparatus to which a rotary shaft of the present invention is applied, and FIG. 3 is a perspective view illustrating a bidirectional processing jig apparatus to which the rotary shaft of the present invention is applied. FIG. 4 is a front view showing an operation state of a bidirectional processing jig apparatus to which the rotary shaft of the present invention is applied. FIG.

As shown in FIG. 2 or 3, the bidirectional processing jig apparatus 100 to which the rotary shaft is applied includes a base plate 110, a handle 130 configured to be moved by a user carrying the base plate 110, The binding unit 150 is coupled to the rear surface of the binding unit 150 and rotates the binding unit 150 to rotate the binding unit 150, And a pneumatic cylinder 190 positioned on both sides with reference to a rotary cylinder 170 and binding portion 150 generating energy and configured to process the workpiece 200.

The base plate 110 is equipped with all the components constituting the jig apparatus 100 and a plurality of fixing grooves 112 are formed on both sides of the base plate 110 so that the jig apparatus 100 and the work table are fixed .

The knob 130 is configured to allow the user to easily move the jig apparatus 100 and is formed between the fixing grooves 112 formed on both sides and has a screw- .

The binding unit 150 is a component that rotates by receiving the rotary motion generated from the rotary cylinder 170 by fixing the workpiece 200. The binding unit 150 has a function of preventing fine movement when the workpiece 200 is fixed, A rotating member 154 configured to rotate the workpiece 200 bound to the receiving member 152 up to a maximum of 180 degrees and a rotary member 170 connected to the rotary cylinder 170 to transmit power And a connecting member 156 for connecting the connecting members 156 to each other.

The support member 152 is configured to receive the workpiece 200 and includes a fixing means 152a that is fixed to the support member 152 so that the workpiece 200 does not generate a fine movement when the workpiece 200 is processed .

The fixing means 152a constitutes a projection on a certain portion of the supporting member 152 so that the workpiece 200 is fixed to the supporting member 152 so as to be formed in the same line as the groove formed in the workpiece 200. [

In addition, the fixing means 152a may be formed of one protrusion or a plurality of protrusions, and is constituted by one fixing means 152a in the present invention.

The rotary member 154 formed at the lower end of the support member 152 has a plurality of grooves formed at the outer portion thereof to be coupled with the base plate 110 and is coupled by binding means such as screws or bolts, It is preferable that grooves having a predetermined thickness are formed so that the rotating means 154a is inserted into the rotary member 154 so as to be rotated.

The rotating means 154a is a component that is coupled to the groove formed in the rotating member 154 and connected to the connecting member 156 to be described later to transfer the physical energy generated by the rotary cylinder 170 to convert the rotating energy into rotational motion .

The rotating means 154a is configured such that the thickness of the groove formed in the rotating member 154 and the rotating means 154a coincide with each other to transmit the rotating force to the rotating member 154, It is preferable that the rotating member 154 is rotated in the same manner when the rotating means 154a is rotated.

The connecting member 156 formed on the rear portion of the coupling unit 150 is connected to the rotary unit 154a on one side and the rotary cylinder 170 on the other side, And is configured to efficiently transfer the physical energy generated from the rotary cylinder 170 to the rotating means 154a.

The rotary cylinder 170 coupled to the coupling unit 150 converts the linear movement of the coupling unit 150 into a linear movement or a linear movement and transmits the converted movement to the coupling unit 150 In the present invention, it is configured to convert from linear motion to rotational motion.

The rotary cylinder 170 includes CRB1, CRB2, MSU, and CRBU of the pay-in type and CRA1, CRQ, MSUB, and MSQ of the rack and pinion type. Type MSQ rotary cylinder 170 as shown in FIG.

The pneumatic compressor 172 arranged on the left side of the rotary cylinder 170 compresses the air to generate rotary motion of the rotary cylinder 170 and the pneumatic pressure is transmitted to the rotary cylinder 170.

The rotary cylinder 170, which has received compressed air from the pneumatic compressor 172, generates a rotary motion using a rack and a pinion therein. The generated rotary motion is transmitted to the rotary unit 170 154a in a predetermined direction.

Specifically, the air compressed by the pneumatic compressor 172 is moved in a predetermined direction of the rack, and the rack and the pinion are meshed with each other such as a clockwheel. Thus, the pinion coupled with the rack allows the rack to move linearly And is rotated in a predetermined direction.

At this time, it is preferable to additionally configure a separate control device so that the rotation direction of the rotary cylinder 170 can be controlled. In the present invention, a separate control device is provided in the rotary cylinder 170, However, the present invention is not limited to this, and it is needless to say that a separate control device can be formed outside the rotary cylinder 170.

The rotary cradle 170 and the rotary cradle 174 which are combined with the coupling unit 150 to adjust the position thereof are formed in a "C" shape so that the rotary cylinder 170 is supported so as not to be tilted back, So that the cylinders 170 are aligned on the same line.

The height of the pedestal 174 may be adjusted according to a position where the rotary pedestal 174 is engaged with the binding portion 150.

The pneumatic cylinder 190 formed on both sides of the binding portion 150 is a device configured to process the workpiece 200 coupled with the binding portion 150. The pneumatic cylinder 190 has a pneumatic cylinder 190 A pneumatic pedestal 192 configured to be positioned on the same line as the binding portion 150 and the binding portion 150 is combined with a model frame 300 configured to process the workpiece 200 in the front portion.

In addition, the pneumatic cylinder 190 transmits a linear motion to the model frame 300 to process the workpiece 200.

More specifically, the pneumatic cylinder 190 transmits the linear motion generated by the air pressure to the model frame 300, and the model frame 300, which receives the linear movement from the pneumatic cylinder 190, And the workpiece 200 is configured to be processed due to the pressure exerted by the mold frame 300.

Here, the model frame 300 is a device manufactured to process the workpiece 200 and is processed by pressing the workpiece 200 through a linear movement of the pneumatic cylinder 190, The model of the workpiece 200 is determined.

The model frame 300 includes a plurality of model frames 300 that are different from each other so that the model frame 300 can be changed according to the model of the workpiece 200 to be created by the user. ) Can be used in place of course.

The mold frame 300 is pressed by the linear movement of the pneumatic cylinder 190 to process the workpiece 200. However, the present invention is not limited thereto, and a cutting tool such as a cutter blade may be provided in the mold frame 300 It is also possible to process the workpiece 200 by mounting the workpiece 200 or to melt a part of the workpiece 200 by using heat energy.

The operation sequence of the bidirectional processing jig apparatus 100 to which the rotary shaft is applied is such that the workpiece 200 to be processed is engaged with the receiving member 152 of the binding unit 150 and the receiving member 152 So that the workpiece 200 is not detached from the supporting member 152. [0064] As shown in FIG.

After the workpiece 200 is mounted with the support member 152, the rotary member 154 coupled to the support member 152 is supplied with rotational motion from the rotary cylinder 170 for rotation, .

At this time, the rotary cylinder 170 generates air of constant pressure generated in the pneumatic compressor 172 and transfers it to the rotary cylinder 170, and the rotating direction of the rotary member 154 is present in the rotary cylinder 170 Lt; RTI ID = 0.0 > controller. ≪ / RTI >

The rotary member 154 is rotated to the left based on the rotary motion generated in the rotary cylinder 170 and the model frame 300 coupled with the pneumatic cylinder 190 is rotated by the linear movement of the pneumatic cylinder 190, (FIG. 4B).

The first processed workpiece 200 is rotated to the right using the rotary motion of the rotary cylinder 170 to perform the second machining of the workpiece 200 using the pneumatic cylinder 190 and the model frame 300 constructed on the right side (Fig. 4C).

At this time, the model frame 300 for the first machining and the model frame for the second machining are different model frames 300, which are configured to double-process the workpiece 200.

Here, it is described that the jigs are used for the secondary processing on the right side after the primary processing on the left side. However, the present invention is not limited to this, and it is needless to say that it is possible to perform the secondary processing on the left side after the primary processing on the right side .

Although the present invention has been described in connection with the preferred embodiments thereof with reference to the accompanying drawings, it is to be understood that the present invention is not limited thereto, It is to be understood that various modifications and changes may be made without departing from the scope of the appended claims.

100: jig device 110: base plate
112: fixing groove 130: handle
150: binding portion 152: receiving member
152a: fixing means 154: rotating member
154a: rotating means 156: connecting member
170: Rotary cylinder 172: Pneumatic compressor
174: Rotary pedestal 190: Pneumatic cylinder
192: Pneumatic pedestal 200: Finished product
300: Models

Claims (6)

Base plate;
A handle configured on both sides of the base plate, the handle configured to allow a user to carry and move the base plate;
A binding portion which is formed in the center of the base plate and binds the workpieces and is configured to be able to process the workpieces by being rotated at maximum 180 degrees;
A rotary cylinder which is formed on a rear portion of the binding portion and generates physical energy for rotating the binding portion; And
A pneumatic cylinder positioned on both sides with respect to the binding portion and capable of linear motion using air pressure and configured to process the workpiece through linear motion;
Wherein the rotation axis is inclined with respect to the rotation axis.
The method according to claim 1,
The binding portion
A support member configured to receive a workpiece;
A rotating member configured to be able to rotate the workpiece bound to the receiving member up to 180 degrees; And
A connecting member connected to the rotary cylinder and configured to transmit power to the rotating member;
Wherein the rotation axis is inclined with respect to the rotation axis.
3. The method of claim 2,
The support member
Wherein the rotary shaft is further provided with fixing means for preventing fine movement when the workpiece is processed and manufactured without being separated from the workpiece and having a protruding portion formed at the upper end of the support member.
3. The method of claim 2,
The rotating member includes:
And a rotation unit configured to rotate the support member by 180 degrees at maximum to receive the rotation motion generated in the rotary cylinder.
The method according to claim 1,
In the rotary cylinder,
Further comprising a pneumatic compressor coupled to a side portion of the rotary cylinder and configured to generate compressed air and to be transferred to the rotary cylinder.
The method according to claim 1,
The pneumatic cylinder includes:
And a rotating shaft coupled to the front portion of the pneumatic cylinder and further including a model frame configured differently according to a model of a workpiece to be processed by a user.

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