KR100671442B1 - Bonding apparatus for manufacture of diamond bite - Google Patents

Abstract

The present invention relates to a manufacturing apparatus and a manufacturing method, and more particularly, to a new diamond bite manufacturing method and a manufacturing apparatus for the same, so that the process for the production of diamond bite can be as simple as possible and the degradation of diamond can be minimized. .

To this end, the present invention comprises the steps of preparing a single crystal diamond tip of the raw stone state; Confirming the orientation of the diamond tip for selecting a crystal plane; Fixing the diamond tip of the gemstone state to a holder portion of the grinding device for suction-fixing the diamond tip by vacuum adsorption, and then grinding the upper and lower reference planes with respect to the selected crystal surface; Joining the diamond tip to the shank by welding using electrical resistance; Sequentially grinding inclined surfaces and upper surfaces of the diamond tip bonded to the shank and at least one clearance surface using two or more grinding wheels; In addition, a step of performing a final inspection of the angle and dimensions and roughness of the diamond tip is provided, the diamond bite manufacturing method characterized in that the progress is sequentially performed.

Diamond Bite, Manufacturing Device, Grinding Device, Holder, Welding Device

Description

Bonding apparatus for manufacture of diamond bite

1 is a perspective view showing a typical diamond bite

Figure 2 is a flow chart showing the manufacturing process of the conventional diamond bite

3 is a perspective view schematically showing a grinding device for a diamond bite manufacturing process according to an embodiment of the present invention

Figure 4 is a side cross-sectional view showing in more detail the holder portion of the configuration constituting the grinding device of FIG.

5 is a front view of the holder part of FIG.

Figure 6 is a block diagram showing a block welding device for diamond bite manufacturing process according to an embodiment of the present invention

7 is a plan view for explaining the internal structure of the chamber portion constituting the welding device of FIG.

8 is a flow chart showing a diamond bite manufacturing process using the diamond bite manufacturing apparatus according to an embodiment of the present invention.

9 is a perspective view for explaining a diamond bite produced by the manufacturing method according to an embodiment of the present invention

<Description of Symbols for Major Parts of Drawings>

100.Diamond Bite 110.Shank

130. Diamond tip 131. Inclined surface

132. Clearance 200. Grinding device

210. Grinding section 211. Grinding wheel

220. Byte holder 230. Holder

231. Vacuum force generating unit 232. Vacuum block

233. Clamp Chuck 234. Clamp

235. Clamp adjustment screw 240. Coupling

300. Welding device 310. Chamber part

320. Shank holder 331. Plus electrode

332. Negative electrodes 340. Current supply

350. Power Supply Unit 360. Position Control Unit

361.Pressure members 362.Support blocks

363. Moving part 371. Camera part

372. Monitor section 373. Control computer

380. Controls

The present invention relates to a cutting tool having a diamond tip, and more particularly to a method for manufacturing a cutting tool having a diamond tip and an apparatus used therefor.

A cutting tool, generally called a bite, is a cutting tool mainly used for metal cutting in lathes and planers.

This bite is largely composed of a shank 11 and a cutting edge portion 12 as shown in FIG. 1.

At this time, the shank 11 is a portion to be mounted on a bite holder such as a lathe, and the cutting edge portion 12 is a portion for performing normal cutting.

The bite may be formed entirely of high-speed steel, but in this case, since the unit price is expensive, the shank 11 is usually formed of a general metal, but the tip of the cemented carbide or the like is attached to the cutting edge part 12 by soldering or And the tip 13 such as diamond are brazed or vacuum-welded and used.

At this time, the bite having the diamond tip 13 is an aluminum, copper, acrylic resin cutting, V groove cutting of a light guide panel (LGP) of LCD, or ultra precision machining bite used for aspheric lens and lens mold processing As the tip 13 itself is quite expensive, it requires precision in its manufacturing operation.

2 is a flowchart illustrating a manufacturing process of the bite having the diamond tip 13 (hereinafter referred to as "diamond bite"), and the manufacturing process of the conventional diamond bite will be described with reference to the following. same.

First, in order to manufacture a diamond bite, after preparing the diamond tip 13 in the state of the gemstone, the crystal face of the diamond tip 13 is checked and the crystal surface is selected.

Subsequently, polishing (grinding) operation is performed to remove the chipped portion or the defective portion of the diamond tip 13.

Then, the diamond tip 13, which has been polished, is brazed to the auxiliary shank (not shown).

At this time, the auxiliary shank is a rough working shank for roughing the diamond tip (13).

Then, roughness is made by roughing the diamond tip 13 welded to the auxiliary shank with a grinding machine (not shown), and then a primary directional test is performed to inspect the crystal surface of the diamond tip 13 after roughing is completed. do.

Subsequently, the diamond tip 13 having passed the primary directionality test is separated from the auxiliary shank and then washed.

At this time, the cleaning process is a process of removing the foreign matter (brazing) on the surface when grinding the diamond tip (13).

When the cleaning is completed, the diamond tip 13 is welded to the cutting edge portion 12 of the final shank 11.

At this time, the final shank 11 is the shank that makes up the actual diamond bite.

And the inclined surface 13a which is the upper surface of the diamond tip 13 of the state welded to the said final shank 11, and the clearance surface 13b which is the front surface are ground with a grinding machine, and a precise shape is completed.

Thereafter, a second directional test is performed to check the crystal direction of the diamond tip 13 again, and then the diamond bite is completed through the final test.

However, the above-described series of processes for manufacturing the conventional diamond bite cause various problems as described below.

First, the diamond tip 13 of the gemstone state used in the diamond bite is a single crystal diamond, not a state of uniformly selected gemstones, and since it is a sweet potato shape, it is difficult to fix it with a conventional general clamp, and thus, there is no difficulty in working. .

Therefore, the diamond tip 13 was forced to use the auxiliary shank as described above, which caused a problem that the cost increases due to the additional provision of the auxiliary shank.

Second, in general, diamond has a small thermal expansion coefficient, but also has a strong advantage in thermal shock, but because the heat resistance is weak, high temperature degradation occurs when exposed to high temperature has a disadvantage that the wear resistance is deteriorated.

Nevertheless, the above-described conventional manufacturing process of the diamond bite is performed by welding the diamond tip 13 to the auxiliary shank, removing the diamond tip 13 from the auxiliary shank, and the diamond on the final shank 11. Since a plurality of welding processes are repeatedly performed, such as a process of welding the tip 13, the diamond tip 13 has a problem in that the wear resistance is greatly degraded by the high temperature deterioration of the diamond tip 13.

Particularly, in the related art, the diamond tip 13 is welded to have only a bonding strength that is merely attached to the shank 11 in consideration of the above-described deterioration in wear resistance. In this case, the diamond tip 13 is held on the shank. The strength present only results in no gaps at the interface and quality depends on the deformation resistance of the small alloy.

Third, since the method of joining the diamond tip 13 to the shank 11 in the conventional diamond bite manufacturing process was performed through melting of the solvent by vacuum welding, the diamond tip 13 was welded to the shank 11 during the welding. When the diamond tip 13 was not bonded to the correct position due to the flow of the diamond tip 13 and the diamond tip 13 was generated due to the vibration caused by the welding during the welding, the rework was eventually performed. Occurred frequently.

The present invention has been made to solve the above-mentioned conventional problems, the object of the present invention is to manufacture a new diamond bite so that the process for the production of the diamond bite can be as simple as possible, the degradation of the diamond tip can be minimized It is to provide a method and a manufacturing apparatus for the same.

It is also an object of the present invention to provide a new diamond bite manufacturing apparatus that can be stably grinding the diamond tip performed during the manufacturing process of the diamond bite.

According to the diamond bite manufacturing method of the present invention for achieving the above object, (A) preparing a single crystal diamond tip of the gemstone state; (B) checking the directivity of the diamond tip for selecting a crystal plane; (C) grinding the upper and lower reference surfaces with respect to the selected crystal surface after fixing the diamond tip of the gemstone state to a holder portion of the grinding device for adsorption fixing the diamond tip by vacuum suction; (D) joining the diamond tip to the shank by welding using electrical resistance; (E) sequential grinding of the inclined surface, which is the upper surface of the diamond tip bonded to the shank, and the relief surface, which is the front surface, using two or more grinding wheels; And, (f) performing a final inspection of the angle and dimension and roughness of the diamond tip: characterized in that the progress.

In addition, according to the apparatus for grinding the reference surface of the diamond tip during the manufacturing process of the diamond bite has a vacuum force generating unit for providing an air suction force, and a vacuum flow path for receiving the air suction force from the vacuum force generator, A vacuum block having a concave indentation while the front face is rounded for accommodation, and an inner circumferential surface of the vacuum block are formed stepwise so that the vacuum block is accommodated, and the front end thereof selectively surrounds a diamond tip of a gemstone state accommodated in the front of the vacuum block. A plurality of clamps formed to correspond to the shape of the outer circumferential surface of the vacuum block to clamp, a clamp chuck on which each of the clamps are mounted, and a plurality of clamps passing through the clamp chucks to engage with each of the clamps. Optionally toward the center or outward direction in the clamp chuck It includes a number of clamping the adjustment screw to adjust so that the movement is provided with the holder portion of the grinding apparatus consisting of a diamond byte manufacturing process.

In addition, according to the device for bonding the diamond tip to the shank during the manufacturing process of the diamond bite chamber unit for forming a working space; A shank holder provided on the working space in the chamber part for holding the shank forming a diamond bite; A positive electrode and a negative electrode which are provided on both sides of the shank holder in the working space in the chamber, respectively, and allow a current to pass through the shank held in the shank holder and an upper surface of the shank in front of the shank and the solder and diamond tips. ; A current supply unit provided outside the chamber unit and supplying current to each electrode; A power supply unit provided outside the chamber unit and supplying power to the current supply unit; And, provided on the working space in the chamber portion, and adjusts the position of the diamond tip placed on the upper surface of the shank, and also to adjust the position of the diamond tip that can be generated during the process of the position adjustment unit: includes A welding device for a diamond bite manufacturing process is provided.

Hereinafter, a preferred embodiment of the diamond bite manufacturing method and a manufacturing apparatus therefor according to the present invention described above will be described with reference to FIGS. 3 to 8.

First, the apparatus for manufacturing the diamond bite 100 according to the embodiment of the present invention is largely configured to include a grinding device 200 for the diamond bite manufacturing process, and a welding device 300 for the diamond bite manufacturing process.

Here, the grinding device 200 for the diamond bite manufacturing process as shown in Figure 3 attached to the diamond tip 130 and / or the shank 110 in the state of gemstone while rotating the grinding wheel 211. And a grinding portion 210 for grinding the tip 130, a bite holder 220 for fixing the diamond bite 100, and a holder 230 for fixing the diamond tip 130, and the bite holder 220 And a coupling part 240 to which the holder part 230 is selectively coupled.

In this case, the grinding wheel 211 is provided with at least two or more so as to selectively perform roughing, that is, rough grinding or precision grinding, and is detachable to the grinding unit 210.

In addition, the bite holder 220 is formed to fix the shank 110 of the diamond bite 100.

The holder 230 is a device for fixing the diamond tip 130 when the grinding process is performed.

The holder portion 230 of the grinding apparatus according to the embodiment of the present invention described above is configured to secure the diamond tip 130 of the gemstone state by a vacuum suction force so that a stable clamping can be made.

Hereinafter, the structure of the holder part 230 will be described in more detail with reference to FIGS. 4 and 5, and a series of grinding the diamond tip 130 in the state of gemstone using the holder part 230 will be described. The process will be described in more detail.

First, the holder 230 is largely comprised of a vacuum force generating unit 231, a vacuum block 232, a clamp chuck 233, a clamp 234, and a clamp adjustment screw 235. .

The vacuum force generating unit 231 is preferably composed of a conventional vacuum pump or the like to provide an air suction force.

In addition, the vacuum block 232 has a vacuum flow path that receives the air suction force from the vacuum force generating unit 231, the front surface is formed to be concave round to accommodate the diamond tip 130 of the gemstone state.

At this time, on the surface of the front of the vacuum block 232 to accommodate the diamond tip 130 is formed on the surface of the microchip to prevent the slip of the diamond tip 130 to form a rough surface most desirable.

Of course, by attaching a separate friction member (for example, rough paper surface) to the concave portion may be configured to prevent the slip of the diamond tip 130.

The clamp chuck 233 is a chuck on which the clamp 234 is mounted.

In addition, the clamp 234 serves as a jaw of the clamp chuck 233, and an inner circumferential surface thereof is stepped to accommodate the vacuum block 232, and the front end thereof is the vacuum block. It is formed to correspond to the shape of the outer peripheral surface of the vacuum block 232 to selectively clamp the circumference of the diamond tip 130 accommodated in the front of the (232).

At this time, the clamp 234 is a plurality, in particular provided by one each on the left and right and up and down side clamping for the symmetric four directions of the diamond tip 130 regardless of the shape of the diamond tip 130 is made smoothly Most desirable.

In addition, the clamp adjusting screw 235 serves to adjust the clamp 234 is selectively moved toward the center side direction or the outer direction in the clamp chuck 233 by the rotation, the clamp Pass through the chuck 233 is coupled to each of the clamp 234, respectively.

Therefore, if the diamond tip 130 is to be mounted on the holder part 230 to perform the grinding operation on the diamond tip 130 in the rough state, the diamond tip 130 is placed on the front surface of the vacuum block 232. In addition to the housing, the vacuum force generating unit 231 is driven to vacuum suction the diamond tip 130 to the vacuum block 232.

Subsequently, by operating each clamp adjusting screw 235 so that each clamp 234 is clamped to the circumferential surface of the diamond tip 130, the mounting of the diamond tip 130 is completed, and the grinding portion 210 continues. It is enough to drive as much as necessary to drive the required area.

As a result, the single crystal diamond tip 130 in the rough state is stably ground by the holder 230 according to the embodiment of the present invention.

On the other hand, Figure 6 attached is a welding device for a diamond bite manufacturing process of the diamond bite manufacturing apparatus according to an embodiment of the present invention.

As can be seen through this, the welding device 300 according to the embodiment of the present invention is largely the chamber 310, the shank holder 320, a pair of electrodes (331,332), the current supply unit 340, It is configured to include a power supply unit 350 and the position adjusting unit 360.

The chamber 310 is a chamber that forms a working space where a welding operation is substantially performed, and is configured to selectively receive argon (Ar) gas and hydrogen (H 2) gas.

In this case, the chamber 310 allows welding to be performed in a vacuum state, and the above gases can be made into the atmosphere to prevent oxidation inside the chamber 310.

In addition, the shank holder 320 is provided on the working space in the chamber 310 and is a holder for holding the shank 110 forming the diamond bite 100.

The pair of electrodes 331 and 332 may include a positive electrode 331 and a negative electrode 332, respectively.

In this case, the electrodes 331 and 332 are provided at both sides of the shank holder 320 in the working space in the chamber 310, respectively, and the shank 110 held in the shank holder 320 and its front upper surface. The electric resistance welding is performed by passing a current through a solder (not shown) and the diamond tip 130 is mounted.

The current supply unit 340 is provided outside the chamber 310 and serves to supply current to the electrodes 331 and 332.

In addition, the power supply unit 350 is provided outside the chamber unit 310 and serves to supply power to the current supply unit 340.

In addition, the position adjusting unit 360 is provided on the working space in the chamber 310, and may be generated during the process while adjusting the position of the diamond tip 130 placed on the upper surface of the shank 110. It serves to prevent the position variation of the diamond tip 130.

At this time, the position adjusting unit 360 is configured to include a pair of pressing members 361, a pair of support blocks 362 and the moving unit 363 as shown in FIG.

The pair of pressing members 361 are positioned at opposite ends of the diamond tip 130, respectively, of the front both sides of the diamond bite 100, and the diamond tips 130 are moved in the diagonal direction. It selectively serves to pressurize).

In addition, the pair of support blocks 362 may serve to support the respective pressing members 361 in the chamber 310, and may rotate in a clockwise or counterclockwise direction. ) Angle is adjustable.

At this time, the pressing member 361 is supported through the support block 362, the corresponding surface between the pressing member 361 and the support block 362 is spirally coupled.

In addition, the moving part 363 is configured to move the pressing member 361 in the diagonal direction.

At this time, the moving part 363 is a motor configured to rotate the pressing member 361, and the pressing member 361 is rotated by the pressing member 361 based on the support block 362. Allow it to move forward or backward.

Reference numeral 380 is a controller for controlling the operation of the position adjusting unit 360.

On the other hand, in the welding device for a diamond bite manufacturing process according to an embodiment of the present invention having a series of the above-described structure reads whether the diamond tip 130 of the diamond bite 100 is correctly seated at the set position of the shank 110 It is preferable that a series of configuration is further provided.

This is because the welding work is performed in the chamber part 310 which is blocked from the external environment, so that the work is difficult.

Accordingly, in the embodiment of the present invention, it is proposed that the camera unit 371, the monitor unit 372, and the control computer 373 are further provided.

At this time, the camera portion 371 serves to photograph the position of the diamond tip 130 placed on the shank 110 of the diamond bite 100, and is composed of a microscope that can be enlarged at a magnification of about 100 times or more. This is preferred.

In addition, the monitor 372 serves to receive and display an image photographed by the camera 371.

The control computer 373 also controls the camera unit 371 and the monitor unit 372.

In this case, the control computer 373 may be configured to perform the role of the control unit 380, that is, to control the operation of the position adjusting unit 360 constituting the welding device 300.

Hereinafter, a process of bonding the diamond tip 130 to the shank 110 by the above-described welding apparatus 300 will be described.

First, the worker places the diamond tip 130 on the shank 110 in a state where the shank 110 is fixed to the shank holder 320 in the chamber 310.

Subsequently, the operator controls the operation of the position adjusting unit 360 by controlling the control unit 380 while checking the image captured by the camera unit 371 through the monitor unit 372 on the surface of the shank 110. The diamond tip 130 is placed so that it can be accurately positioned in the set position.

When the position adjustment of the diamond tip 130 is completed by the above process, the current supply unit 340 is controlled to provide a positive current and a negative current to the pair of electrodes 331 and 332 so as to provide a front upper surface of the shank 110. The current passes through the solder existing between the diamond tips 130.

Thus, the diamond tip 130 is fixed while being bonded on the surface of the shank 110 while brazing by electrical resistance is performed.

As a result, since the diamond tip 130 and the shank 110 are bonded by the electric resistance welding using the welding device, deterioration of the diamond tip 130 is prevented, thereby reducing the wear resistance and at the same time the diamond tip 130 ) Can be bonded in the correct position.

On the other hand, the above-described diamond bite manufacturing apparatus according to the embodiment of the present invention is characterized by the holder portion 230 and the welding device, respectively, but if the diamond bite 100 is manufactured using the above-described devices, conventional diamond bite manufacturing Compared to the process, a considerable amount of work can be reduced, and process time can be saved.

Of course, the manufacture of the diamond bite 100 using each of the devices described above should proceed with the optimum process sequence.

Accordingly, the embodiment of the present invention described below provides a new diamond bite manufacturing method using each of the above devices to shorten the process time and minimize the defects can be produced.

Hereinafter, a detailed description of a method of manufacturing a diamond bite according to a preferred embodiment of the present invention will be described in detail with reference to the flowchart of FIG. 8 and the perspective view of FIG. 9.

First, the operator decides the desired tool shape, precision grade, processing purpose and use, and then prepares a single crystal diamond tip 130 in the state of gemstone for manufacturing the diamond bite 100 (S110), and then continues to select the crystal surface. Check the directivity of the diamond tip 130 for (S120).

The above-described series of processes are the same as those of preparing the raw stone and confirming the directionality of the conventional general diamond bite.

Then, when the confirmation of the directionality for the selection of the crystal plane is completed by the above-described process, the process of grinding the upper and lower reference planes for the selected crystal plane (S130).

In this case, the grinding of the upper and lower reference planes uses the grinding apparatus 200 for the diamond bite manufacturing process according to the embodiment of the present invention described above, and the reference plane grinding process of the diamond tip 130 using the same is the operation process of the aforementioned grinding device. Same as the description in the embodiment for.

In other words, the diamond tip 130 is fixed to the holder part 230 which sucks and fixes the diamond tip 130 by vacuum adsorption, and then the upper and lower reference surfaces of the selected crystal surface are ground by the grinding part.

Of course, a sawing operation may be performed to remove the lumped portion or the defective portion of the diamond tip 130 before the grinding process.

When the reference surface grinding of the diamond tip 130 in the gemstone state is completed, a bonding process of joining the diamond tip 130 to the shank 110 is performed.

At this time, the joining process uses the welding device 300 for the diamond bite manufacturing process according to the embodiment of the present invention described above, the joining process between the diamond tip 130 and the shank 110 using the same also described above embodiment Same process as in.

That is, the diamond tip 130 is bonded to the shank 110 by welding using an electrical resistance (S140) to prevent deterioration of the diamond tip 130 to prevent abrasion resistance deterioration in advance and the diamond tip 130. ) And the shank 110 is to be smoothly bonded.

In particular, during the bonding process described above, it is preferable that the inclined surface 131 of the final diamond bite 100 as shown in FIG. 9 can be selected.

At this time, the selection of the inclined surface 131 of the diamond bite 100 refers to the angle of inclination of the top surface of the diamond tip 130, the adjustment thereof is the welding device 300 for the diamond bite manufacturing process according to an embodiment of the present invention. It is preferable to proceed through the control of the position adjusting unit 360 of.

That is, by operating each pressing member 361 through the control of the position adjustment unit 360 to adjust the inclination of the top surface of the diamond tip 130. That is, in the step of joining the diamond tip to the shank by welding using electrical resistance, the pair of pressing members 361 support the both ends of the front surface of the diamond tip 130 placed on the surface of the shank 110, the pressing member After adjusting the inclination of the upper surface of the diamond tip 130 in accordance with the movement of the diamond tip 130 is bonded to the shank using an electrical resistance.

When the diamond tip 130 is bonded to the shank 110, the diamond tip 130 bonded to the shank 110 is ground with one or more grinding wheels 211.

The grinding process is a process of forming the diamond tip 130 to serve as a bite, and proceeds rough roughing and precision grinding sequentially.

At this time, the roughing process is performed with a grinding wheel for rough grinding, the precision grinding process is performed with a grinding wheel for precision grinding.

That is, roughing the diamond tip 130 with the grinding wheel for rough grinding (S150), and when the roughing process is completed, replace the grinding wheel with the grinding wheel for the precision grinding (S160) and then precision grinding process By proceeding to precisely grind (S170) the inclined surface 131 and the clearance surface 132 of the diamond tip 130.

At this time, the grinding of the inclined surface 131 of the diamond tip 130 is a process of grinding inclined downward at a predetermined angle as the upper surface of the diamond tip 130 toward the rear side, the clearance surface 132 of the diamond tip 130 Grinding is a process in which the front surface of the diamond tip 130 is inclined toward the rear side at a set angle toward the lower side.

In addition, when precision grinding of the inclined surface 131 and the clearance surface 132 of the diamond tip 130 is completed, the blade tip edge portion 133 of the diamond tip 130 is formed to form a very fine round.

At this time, the round radius is in the range of approximately 1 μm to 300 μm.

When the series of grinding processes as described above are completed, the directionality of the diamond tip 130 is finally inspected (S180) to check the inclined surface 131 and the clearance surface 132 of the diamond tip 130.

If it is confirmed that the inclined surface 131 and the clearance surface 132 of the diamond tip 130 are ground incorrectly, the above-described grinding process is repeated.

In addition, if it is confirmed that the inclined surface 131 and the clearance surface 132 of the diamond tip 130 are accurately ground by the above-described process, the final inspection for the angle, the dimension, and the roughness of the diamond tip 130 is performed (S190). By doing so, the diamond bite 100 is completed.

As described above, the manufacturing process according to the embodiment of the present invention performs the design of the diamond crystal surface and the crystal direction from the diamond tip 130 of the original gemstone state, so that the grinding process is the final shank (shank determined as the actual product) 110. In order to proceed continuously in the state bonded to the) it is to be able to prevent the change of the direction in advance.

In other words, the present invention is to check the directionality of the single crystal diamond so as not to have a defect from the beginning to be maintained to the end in the state in which the crystal surface is selected, so that the blade tip strength of the diamond tip 130 may be unstable.

In particular, the welding process is to prevent the wear resistance by reducing the diamond tip is provided with a minimum of heat during welding, and to prevent oxidation by using an atmosphere gas while maintaining a low temperature vacuum.

As described above, due to the diamond bite manufacturing apparatus and the diamond bite manufacturing method using the same according to the present invention, various effects as described below can be obtained.

First, since the manufacturing process can be achieved in a batch production system, the number of processes, the number of workers and defects can be reduced.

Second, the desired final tool shape can be designed, processed and welded from the first raw stone, thereby reducing the manufacturing time of the diamond bite.

Third, by using the shank to be used as the final tool in the welding process or the grinding process, it is possible to prevent defects due to directional mismatches in advance.

That is, since the diamond tip is no longer separated in the welded state, the change in the directionality cannot be made, and the defect due to the change in the direction can be prevented in advance.

Fourth, the process of welding the diamond tip to the shank is made of electrical resistance, and it is possible to maintain the exact position of the diamond tip during the welding process, thereby preventing a reduction in wear resistance due to deterioration of the diamond tip. The welding defect has an effect that can be prevented.

Claims (4)

A chamber part forming a working space; A shank holder provided on the working space in the chamber part for holding the shank forming a diamond bite; A positive electrode and a negative electrode which are provided on both sides of the shank holder in the working space in the chamber, respectively, and allow a current to pass through the shank held in the shank holder and an upper surface of the shank in front of the shank and the solder and diamond tips. ;  A current supply unit provided outside the chamber unit and supplying current to each electrode; A power supply unit provided outside the chamber unit and supplying power to the current supply unit; And, It is provided on the working space in the chamber portion, and adjusts the position of the diamond tip placed on the upper surface of the shank, and also includes a position adjusting unit for preventing a change in the position of the diamond tip that may be generated during the process. Welding device for diamond bite manufacturing process characterized in. The method of claim 1, The position adjusting unit A pair of pressing members each of which is positioned at opposite ends of each of the diamond tips of each of the front portions of the diamond bite, and selectively presses the diamond tips while moving in the diagonal direction; A pair of support blocks for supporting the pressing members in the chamber and configured to adjust the angle; Welding device for a diamond bite manufacturing process characterized in that it comprises a moving part for moving the pressing member in the diagonal direction. The method of claim 2, The pressing member is supported through the support block, but the corresponding surface is coupled to each other spirally, The moving part of the position adjusting unit is a welding device for a diamond bite manufacturing process, characterized in that the motor is made to rotate the pressing member to move forward or backward based on the support block. The method of claim 1, A camera unit for checking the position of the diamond tip placed on the shank, A monitor unit displaying an image photographed through the camera unit; Welding device for the diamond bite manufacturing process, characterized in that the control unit for controlling the camera unit, the monitor unit and the position adjusting unit is further provided.

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