KR101884889B1 - jig assembly for chamfering process of an hexahedron type blocks - Google Patents

Abstract

The present invention provides a jig assembly for a chamfering process of hexahedron type blocks, which comprises a table, a fixing side support block, a moving side support block, a drive unit, and avoidance grooves. More specifically, each of the avoidance grooves is formed with a portion in which each edge portion of a circumferential side of a product such as a hexahedron block and a base material gripped by each support block is placed, and a chamfering process can be continuously performed after cutting each surface of a relevant product. Therefore, a chamfering process with respect to each edge can be performed along with a surface cutting process, and can be performed through an automated process.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a jig assembly for chamfering a hexahedron product,

The present invention relates to a jig assembly, and more particularly, to a jig assembly, in particular a hexahedron block type, which can be chamfered to each corner of the hexahedron block, To a jig assembly for chamfering a product.

In general, when machining a block-shaped product having a hexahedron shape, each surface is completely machined, and the chamfering operation is performed on each corner of the corresponding hexahedrally-shaped product to complete the manufacture.

However, in the case of the above-mentioned hexahedral block type product, after the primary machining is carried out while holding two opposing surfaces, the surface machining is completed by re-machining the two grinding surfaces, During the surface processing of the two surfaces during the progress of each surface machining, scratches may be generated during the surface machining of the machined surfaces on the jig or chuck. Therefore, The above-described general process is not suitable for the manufacture of parts such as products which should not have surface scratches.

Accordingly, in the past, when machining of each surface of the hexahedral block-shaped product has been completed, additional polishing has to be performed using a separate surface polishing apparatus. In this regard, in the related arts, Patent Registration No. 10-1530518, Registered Utility Model No. 20 -0285926, Registration Utility Model No. 20-0229938, and Registration No. 10-0340604.

Particularly, the above-described conventional techniques merely provide only a technique for additional surface polishing. Therefore, when chamfering each corner of the surface-polished hexahedral block-shaped product, surface damage due to grasping the corresponding hexahedral block- If the chamfering is performed before performing the surface polishing, there is a further problem that sharp edges of the corners must be generated again in the surface polishing process.

Conventionally, in the case of a hexahedral block type product, machining of each surface is performed, surface polishing is performed using a polishing apparatus, and then chamfering is performed manually to manufacture a hexagonal block type product without surface scratches In fact, there is a disadvantage that it is not suitable for mass production because the working efficiency is extremely low.

Registration No. 10-1530518 Registration Practical Utility Model No. 20-0285926 Registration Utility Model No. 20-0229938 Patent No. 10-0340604

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a method and apparatus for chamfering chamfered chamfering chambers, And to provide a jig assembly for chamfering of a hexagonal block type product according to a new shape.

According to an aspect of the present invention, there is provided a jig assembly for chamfering of a hexahedral block type product, comprising: a table having a top surface and providing a working area; A fixed-side support block fixed to an upper surface of the table and supporting at least one peripheral surface of a product having a hexahedral block shape; A movable-side support block installed horizontally on the surface of the table and brought into close contact with a circumferential surface of the product opposite to the circumferential surface supported by the fixed-side support block and closely contacting the fixed-side support block; And an avoidance groove formed to have a size such that a circumferential edge portion of a product gripped by the fixed-side support block and a movement-side support block is located, .

Here, an interference preventing groove is formed at a portion of the upper surface of the table that coincides with the avoidance groove of each of the receiving blocks to prevent the interference of the facing tool.

In addition, the avoidance groove is rounded in a circular or semicircular shape so that the facing tool can be rotated.

The bottom surface of the fixed-side supporting block and the moving-side supporting block are provided to be in contact with the surface of the table, and the height of the fixed-side supporting block and the moving-side supporting block is formed to be lower than the height of the hexahedron block .

In addition, each of the support blocks is formed to support at least two sides of the product.

As described above, the jig assembly for chamfering of the hexahedral block type product of the present invention has a configuration according to the avoidance groove and a configuration in which each support block is formed at a height different from that of the product. Therefore, The work can be performed automatically, so that the chamfering operation can be performed by an automated process rather than a manual chamfering operation. In addition, the corners of each support block and the corners of the product are mutually misaligned, It can be prevented.

In addition, the jig assembly for chamfering of the hexahedral block-shaped product of the present invention further includes interference preventing grooves at portions corresponding to the avoidance grooves of the respective support blocks among the upper surfaces of the table, So that it is possible to prevent the occurrence of interference during the chamfering process.

In addition, since the jig assembly for chamfering of the hexahedral block type product of the present invention is configured such that the avoidance groove is circular or semicircular so as to be rounded, it is possible to rotate the facing tool within the avoidance groove, .

In addition, the jig assembly for chamfering of the hexahedron block type product of the present invention may be configured such that the jig assembly is not tightly fixed to the fixed-side support block while pushing any one side of the product, The edge of the product can be accommodated in the recessed portion of the product.

1 is a perspective view illustrating a general structure of a fitting joint;
2 and 3 are plan views for explaining the operation state of the jig assembly for the surface machining of the hexahedral block type product according to the embodiment of the present invention
FIG. 4 is a front view of a hexagonal block-shaped product according to an embodiment of the present invention,
FIGS. 5 to 10 are diagrams illustrating states of the product of each process according to a method of processing a hexahedral block-shaped product according to an embodiment of the present invention.
11 and 12 are plan views for explaining an operation state for machining a simple hexahedron block using a jig assembly for machining a hexagonal block type product according to an embodiment of the present invention

Hereinafter, preferred embodiments of a method for processing a hexahedral block-shaped product of the present invention will be described with reference to FIGS. 2 to 12 attached hereto.

Prior to the description, the hexagonal block-shaped product processed by the processing method of the present invention includes a body portion 11 made of a hexahedron block type, and a connecting pipe (not shown) projecting from the peripheral surface of the body portion 11, Which is a fitting joint 10 of Fig.

In the description of the embodiment, the material and the raw material provided for the machining of the fitting joint 10 are all of the same configuration, except that only the shapes varying according to the machining order are all different. .

2 and 3 are plan views illustrating an operation state of a jig assembly for chamfering of a hexahedron block type product according to an embodiment of the present invention, FIG. 4 is a sectional view of a hexagonal block type product according to an embodiment of the present invention, Fig. 2 is a front view showing a jig assembly for chamfering.

The jig assembly (hereinafter, referred to as a "jig assembly") of a hexahedral block type product according to an embodiment of the present invention includes a table 210, a fixed-side support block 220, The movable base support block 230 and the driving unit 240 and the avoidance grooves 261 and 262. The respective avoidance grooves 261 and 262 are formed by the products (hexahedral block, And the chamfered corner portions of the product 100 are positioned, chamfering can be continuously performed after each surface of the product 100 is finished.

This will be explained in more detail for each configuration.

First, the table 210 is an area provided for proceeding a processing operation for machining a product (a raw material provided for machining a fitting joint) 10 while being placed on the table.

The table 210 includes a base plate, which is provided on an upper surface of a base frame (not shown) to provide an upper surface of the base plate.

Next, the fixed-side supporting block 220 is a portion provided to support one side edge of the product 100.

The fixed-side support block 220 is fixed to one side of the upper surface of the table 210.

In particular, the fixed-side bearing block 220 is provided with a fixed-side corner groove (not shown) having two bearing surfaces 222 and 223 for supporting a part of two wall surfaces adjacent to each other starting from the corner of the product 100, (Not shown). At this time, the fixed side edge groove 221 is positioned on the movement direction side of the product 100.

In addition, the bottom of the fixed-side supporting block 220 is disposed to be in contact with the surface of the table 210, and the height of the fixed-side supporting block 220 is lower than the height of the product 100 .

That is, when the product 100 is held by the fixed-side support block 220 and the movable-side support block 230, the upper surface and a part of the periphery thereof are simultaneously exposed to the upper side of the two support blocks 220 and 230 So that not only the upper surface of the product 100 but also the upper surface of the product 100 can be chamfered.

Next, the movable-side support block 230 is a portion provided to support the other side edge of the product 100 (the edge opposite to the side edge supported by the fixed-side support block).

The movement-side supporting block 230 is movably installed on one side of the upper surface of the table 100.

In particular, the movable-side bearing block 230 is provided with a movable-side corner groove (not shown) having two bearing surfaces 232 and 233 to support a part of two wall surfaces adjacent to each other from the other corner of the product 100, (231). At this time, the moving side edge groove 231 is located on the side opposite to the fixed side corner receiving portion 221 of the fixed side receiving block 220 so as to face each other, and the moving direction is also the moving side edge groove 231 are moved toward the fixed side edge groove 221.

In addition, the bottom of the moving-side supporting block 230 is disposed to be in contact with the surface of the table 210, and the height of the moving-side supporting block 230 is lower than the height of the product 100 .

That is, by allowing the upper surface and a part of the periphery thereof to be simultaneously exposed upward while the product 100 is gripped by the fixed-side supporting block 220 and the moving-side supporting block 230, As well as chamfering of the periphery of the upper surface where the machining is performed.

Next, the driving unit 240 is provided to move the movement-side supporting block 230.

The driving unit 240 may have a variety of structures. In the embodiment of the present invention, the driving unit 400 may be a pneumatic cylinder.

The moving side edge groove 231 of the movable side supporting block 230 is moved horizontally accurately toward the fixed side edge groove 221 of the fixed side receiving block 220 by driving the driving unit 240 including the pneumatic / So that it can be grasped securely, while allowing quick operation.

Next, the avoidance grooves 261 and 262 are grooves through which a surface taking tool 250 provided for chamfering each corner portion of the finished product 100 with respect to each wall surface is passed.

The escape grooves 261 and 262 include a fixed side avoiding groove 261 formed to penetrate vertically through the fixed side edge groove 221 of the fixed side supporting block 220, Side slip grooves 262 formed so as to penetrate up and down at the corners of the side edge grooves 231. Particularly, the slip grooves 261, 262 described above are formed in such a manner that the rotation of the surface- And is formed in a round or semicircular shape so as to be prevented from being generated.

Of course, each of the avoidance grooves 261 and 262 also serves to prevent the corners of the product 100 from contacting the corners of the fixed-side support block 220 and the movable-side support block 230.

That is, when the product 100 is moved by receiving the pressing force of the movable-side supporting block 230, the edge of the product 100 and the edges of the fixed-side supporting block 220 and the movable- It is possible to prevent damage to the edge of the product 100 due to the additional formation of the avoidance groove 224, So that damage can be prevented in advance.

Particularly, in the embodiment of the present invention, interference preventing grooves 211 and 212 (not shown) are formed in areas of the top surface of the table 100 that coincide with the avoidance grooves 261 and 262 of the respective receiving blocks 220 and 230, ) Are further formed.

In other words, chamfering from the upper end to the lower end with respect to each peripheral edge of the product 100 can be performed through the additional formation of the interference preventing grooves 211, 212 described above.

At this time, the interference preventing grooves 211 and 212 are formed to have the same shape as the avoidance grooves 261 and 262 and only to a depth enough to insert only a part of the surface taking tool 250.

Hereinafter, the operation of the jig assembly according to the embodiment of the present invention described above will be described in more detail.

Prior to the description, the fitting joint 10 constituting the hexahedron block type product according to the embodiment of the present invention includes the product 100 (shown in FIGS. 5 to 7) ) And then provided with the primary processing through the lathe processing.

The primary processing is an indexing process on a CNC lathe while grasping two retroreflective surfaces 111 and 112 symmetrical to each other in the body part 11 of the product 100, All the remaining surfaces except for the two gripping surfaces 111 and 112 gripped by the above process are formed within the tolerance range. This is as shown in FIGS. 8 to 10 attached hereto. 9 is a front view, and Fig. 10 is a bottom view.

And, the primary processed product 100 as described above is fixedly mounted to the jig assembly according to the embodiment of the present invention.

2, the operator places the first processed product 100 between the fixed-side supporting block 220 and the movable-side supporting block 230 on the table 210.

In this state, the moving-side supporting block 230 is moved by driving the pneumatic / hydraulic cylinder, which is the driving unit 240, and the product 100 is moved to the fixed-side supporting block 230 220 and the movable-side supporting block 230, respectively.

At this time, the four sides of the product 100 are in surface contact with the two supporting surfaces 222 and 223 of the fixed-side supporting block 220 and the two supporting surfaces 232 and 233 of the moving-side supporting block 230, do.

 In particular, since the movable side bearing block 231 is moved toward the fixed side edge groove 221 of the fixed side bearing block 220, the movable side bearing block 230 is fixed to the movable side bearing block 230 Even if the product 100 is inserted between the side support blocks 220 irrespective of the directionality, the two corners of the product 100 that are diagonally opposite to each other can be accurately positioned in the corner grooves 221 and 231 of the respective support blocks 220 and 230 .

Further, since the escape grooves 261 and 262 are formed in the corner grooves 221 and 231 of the respective receiving blocks 220 and 230, when the gripping of the product 100 by the respective receiving blocks 220 and 230 is performed, The occurrence of damage to each corner portion of the substrate 100 is prevented.

By the above-described process, the product 100 can be stably fixed to the jig assembly, and the machining center can then move the machining tool (not shown) in each direction by a pre-input operation control program One of the gripping surfaces 111 exposed upward in the unprocessed state of the product 100 is precisely machined.

Particularly, chamfering of the peripheral edge of the holding surface 111 is also carried out at the time of machining the holding surface 111, and the chamfering process is performed such that the product 100 moves from the respective receiving blocks 220 and 230 As shown in FIG.

That is, the peripheral edge of the holding surface 111 is moved along the edge along the edge of the surface-applying tool 250 in such a manner that the surface-applying tool 250 is brought into contact with the peripheral edge of the gripping surface 111 of the exposed product 100 250) are moved to perform chamfering.

After the chamfering of the gripping surface 111 and the peripheral edge thereof is completed as described above, the chamfering tool 250 is inserted into each of the avoidance grooves 261, Chamfering is also performed on each peripheral edge of the product 100 that has been provided.

When the process is completed, the product 100 is released through the movement of the movable-side supporting block 230 through the operation control of the driving unit 240, and then the unprocessed another gripping surface 112 of the product 100 And then the movable block 230 is moved forward by the re-operation of the driving unit 240. Then, the product is further restrained by the forward movement of the movable-side supporting block 230, 112 are machined.

Accordingly, all the precision machining of the circumferential surface and the two gripping surfaces 111 and 112 of the product 100 is completed through each of the above-described processes. Even if the machining of these surfaces is completed, There is no trace for the fitting joint 10, and thus one fitting joint 10 is completed.

As a result, the jig assembly for chamfering of the hexahedral block type product according to the present invention has a configuration according to the avoidance grooves 261 and 262 and a configuration in which the respective support blocks 220 and 230 are formed at a height different from the product 100, The chamfering operation for each corner of the support blocks 100 and 220 can also be performed automatically so that the chamfering operation can be performed by an automated process rather than a manual chamfering operation, It is possible to prevent the occurrence of damage due to the contact where the corner portions of the product 100 are misaligned with each other.

The jig assembly for chamfering of the hexahedral block type product of the present invention further includes interference preventing grooves 211 and 212 formed on portions of the upper surface of the table 210 that coincide with the avoidance grooves 261 and 262 of the respective support blocks 220 and 230 It is possible to prevent the occurrence of interference during chamfering of each peripheral edge of the product 100 by the faceting tool 250.

Further, since the jig assembly for chamfering of the hexahedral block type product of the present invention has the avoidance grooves 261 and 262 rounded in a circular or semicircular shape, it is possible to rotate the faceting tool 250 in the avoidance grooves 261 and 262, It is possible to perform chamfering processing.

In addition, the jig assembly for chamfering of the hexahedral block type product of the present invention may be configured such that the jig assembly for pressing the product 100 simultaneously pushes the two adjacent sides of the product 100 Side edges of the product 100 can be accommodated in the fixed-side corner groove 221 of the fixed-side support block 220, thereby preventing the mounting defect of the product 100.

On the other hand, the jig assembly for chamfering of the hexahedral block type product of the present invention is not limited to being used only for the purpose of machining the fitting joint 10 as in the above-described embodiment.

For example, as shown in FIGS. 11 and 12, the present invention can be used for various machining and chamfering operations on a simple hexahedral block type product.

10. Fitting joint 11. Body part
12. Connectors 100. Products
111, 112. The retracted surface 210. The table
211, 212. Interference prevention groove 220. Fixed-side support block
221. Fixed side edge groove 230. Moving side base block
231. Moving side edge grooves 222, 223, 232, 233. Bearing surface
240. Driving part 250. Cottoning tool
261, 262. Avoidance home

Claims (5)

A table having a top surface of the plane and providing a working area;
A fixed-side support block fixed to an upper surface of the table and supporting at least one peripheral surface of a product having a hexahedral block shape;
A movable-side support block installed horizontally on the surface of the table and brought into close contact with a circumferential surface of the product opposite to the circumferential surface supported by the fixed-side support block and closely contacting the fixed-side support block;
And an avoidance groove formed to have a size such that a circumferential edge portion of a product gripped by the fixed-side support block and a movement-side support block is located, Wherein the jig assembly comprises: The method according to claim 1,
Wherein an interference preventing groove is formed in a portion of the upper surface of the table that coincides with the avoidance groove of each of the support blocks to prevent interference of the tool for facing the jig. The method according to claim 1,
Wherein the avoidance groove is rounded in a circular or semicircular shape so as to allow rotation of the facing tool. The method according to claim 1,
The bottom surface of the fixed-side supporting block and the moving-side supporting block are provided so as to be in contact with the surface of the table,
Wherein the height of the fixed-side supporting block and the movable-side supporting block is lower than the height of the hexahedron block. The method according to claim 1,
Wherein each of the support blocks is formed to support at least two sides of the product. ≪ RTI ID = 0.0 > 15. < / RTI >

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