KR101354655B1 - Drawing plugs for polycrystalline diamond and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a drawing plug for polycrystalline diamond used to a drawing process. The drawing plug for polycrystalline diamond comprises: a connection part having one side connected to a mandrel; a processing part formed of polycrystalline diamond (PCD) and connected to the other side of the connection part; and a coupling part for coupling the connection part and the processing part.

Description

Drawing plugs for polycrystalline diamond and manufacturing method

The present invention relates to a polycrystalline diamond sintered plug.

In general, wire drawing is a method of drawing through a die when making wire rods, pipes, and the like.

In the processing of the tube, the conical plug 20 supported by the mandrel 30 is inserted into the tube P. At this time, the plug 20 is located concentrically between the drawing die 100 and the pipe P. The pipe P located between the plug 20 and the drawing die 100 is processed while being deformed along the conical inclined portion 11a of the drawing die 100 and the conical taper 21 of the plug 20. do.

As the inner diameter of the pipe P was in contact with the taper 21 portion of the plug 20, the taper 21 portion of the plug 20 was worn. As the taper 21 portion of the plug 20 was worn, the inner diameter portion of the pipe P could not be precisely processed. In addition, since the worn plug 20 has to be replaced frequently, maintenance costs are incurred and economic efficiency is reduced.

Publication No. 10-2012-0097397 (2012.09.03.) Patent Registration No. 10-0938008 (2010.01.13.)

The present invention provides a polycrystalline diamond sintered drawing plug and a method of manufacturing the same, which can maintain a long life without abrasion.

The polycrystalline diamond sintered drawing plug according to an embodiment of the present invention includes a connection part, a processing part formed of a polycrystalline diamond sintered body and connected to the connection part, and a connection part for coupling the connection part and the processing part, wherein the connection part,
And a fastening groove formed in the processing part and the connecting part and a bolt inserted into the fastening groove of the processing part and the connecting part to couple the processing part and the connecting part.
A mandrel may be connected to one side of the connection part.

The polycrystalline diamond sintered plug may further include a flow path formed inside the connection part and the processing part.

The overlapping part may include a fastening groove formed in the processing part and the connecting part and a bolt coupled to the fastening groove of the processing part and the connecting part.

The flow path may include a connection flow path formed in the connection part and a bolt flow path formed in the bolt and connected to the connection flow path.

The coupling part may include a welding hole penetrating through an interior of any one selected from the processing part or the connecting part, a first bead located between the connecting part and the processing part, and a second bent part located in the welding through hole and connected to the first bead. May comprise beads.

A groove and a recess may be formed on a surface in which the processing unit and the connection unit face each other, and the first bead may be positioned between the recess and the recess.

The connection part may be any one selected from the group consisting of steel, carbon steel, special steel, stainless steel, cast iron, nonferrous metal, and combinations thereof.

The processing portion may be spaced apart from the first straight portion, the first straight portion, and the second straight portion having a diameter greater than the diameter of the first straight portion, and connecting the first straight portion and the second straight portion. The second linear portion may include an inclined portion having a smaller cross-sectional area from the second straight portion to the second straight portion.

According to an embodiment of the present invention, a method of manufacturing a polycrystalline diamond sintered plug may include: processing a connecting part, processing a processing part using a material made of a polycrystalline diamond sintered body, and joining the connecting part and the processing part, The connection portion and the processing portion are coupled by bolt coupling or welding. The processing unit may be processed by a discharger or an ultrasonic processing machine.

The connecting part processing step may include forming a coupling groove on one side of the connecting part and forming a first coupling groove on the other side of the connecting part, and the processing part processing step may include an inside of the processing part using a discharger. Forming a second fastening groove in the, and in the step of coupling, can be fastened to the first fastening groove and the second fastening groove using a bolt.

In the connecting part processing step, a connection flow path connected to the first fastening groove may be formed in the connection part, and a bolt flow path connected to the connection flow path may be formed on the bolt before the bolt is coupled to the fastening groove. .

The connecting part machining step and the processing part machining step may further include forming a connection flow path between the connection part and the processing part.

It is possible to weld between the connecting portion and the processing portion.

The connecting part processing step may further include forming a coupling groove on one side of the connecting part and forming a conical groove on the other side of the connecting part, and the processing part processing step may be performed by using a discharger. It may further comprise the step of forming a conical concave portion corresponding to the groove of the conical shape on one side of the processing portion, in the coupling step, it is possible to weld between the groove and the recess.

In any one of the connecting part processing step or the processing part processing step, it is possible to form a welding through-hole penetrating the inside of the connecting portion or the processing unit, and in the step of combining, the connecting portion and the machining inside the welding through-hole It is possible to form a second bead connected to the first bead between the portions.

After the coupling, the connecting part may further include forming a connection flow passage through the first bead connecting the processing part and the connection part and the processing part.

Polycrystalline diamond sintered compact drawing plug manufacturing method according to an embodiment of the present invention, which is used in the drawing process, forming a coupling groove in a predetermined depth on one side and processing the outer diameter to process the connection portion, polycrystalline diamond sintered body Processing the formed material with a discharger, processing an outer diameter with an ultrasonic processing machine, and processing a processing unit; and coupling the connection unit and the processing unit.

In the coupling step, the connection portion and the processing portion may be coupled by bolt coupling or welding.

The polycrystalline diamond sintered body drawing plug manufacturing method may further include forming a flow path passing through the connection part and the inside of the processing part.

According to the embodiment of the present invention, the processing portion portion of the polycrystalline diamond sintered drawing plug for substantially processing the tube is made of the polycrystalline diamond sintered body and is not damaged from the pressure and thermal shock generated when the tube comes into contact with the processing portion. As a result, the processing portion can improve the processing quality of the pipe. And since the processing part is safe from pressure and thermal shock, it does not break and there is no replacement cost due to breakage.

According to an embodiment of the present invention, a vacuum pressure is generated inside the tube when the tube is pulled to draw the tube. The drawing die or the polycrystalline diamond sintered drawing plug may be damaged by the impact of the vacuum pressure being momentarily opened when the end of the tube drawn out under the vacuum pressure exits the polycrystalline diamond sintered drawing plug and the drawing die. However, as the interior of the tube communicates with each other by a connection flow passage penetrating the inside of the polycrystalline diamond sintered compact drawing plug, no vacuum pressure is generated inside the tube. Thereby, since a vacuum pressure does not generate | occur | produce in the inside of a pipe | tube, the damage of a polycrystalline diamond sintered compact drawing plug and a drawing die by a vacuum pressure can be prevented.

1 is a conventional drawing plug installation state.
Figure 2 is a state diagram using a polycrystalline diamond sintered plug according to an embodiment of the present invention.
3 is a cross-sectional view of the polycrystalline diamond sintered compact drawing plug shown in FIG. 2;
4 is an exploded cross-sectional view of the polycrystalline diamond sintered compact drawn plug shown in FIG. 3;
5 is a cross-sectional view showing a state in which the connecting portion and the processing unit shown in FIG. 2 are joined by welding.
6 is a cross-sectional view showing a state in which the connecting portion and the processing unit shown in FIG. 2 are joined by welding.
7 is a process chart for producing a polycrystalline diamond sintered plug according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated with like reference numerals throughout the specification.

Next, a polycrystalline diamond sintered drawing plug according to an embodiment of the present invention will be described with reference to FIGS. 2 to 4.

FIG. 2 is a state diagram of using a polycrystalline diamond sintered compact plug according to an embodiment of the present invention, FIG. 3 is a cross-sectional view of the polycrystalline diamond sintered compact drawing plug shown in FIG. 2, and FIG. It is a cross section.

2 to 4, the polycrystalline diamond sintered compact according to the present embodiment, the polycrystalline diamond sintered compact drawing plug 100 is located at the center of the processing hole 11 formed in the drawing die 10. The machining hole 11 consists of a straight part 11b and the inclination part 11a. The inclined portion 11a and the straight portion 11b are connected to each other. The cross-sectional area of the inclined portion 11a gradually increases as it moves away from the straight portion 11b.

On the other hand, the inner diameter of the processing hole 11 and the outer diameter of the polycrystalline diamond sintered compact plug 100 are spaced apart from each other. The pipe P to be processed passes between the outer diameter of the polycrystalline diamond sintered compact plug 100 and the inner diameter of the processing hole 11. At this time, the polycrystalline diamond sintered body drawing plug 100 processes the inner diameter of the tube P, and the drawing die 100 processes the outer diameter of the tube P.

The polycrystalline diamond sintered drawing plug 100 for processing the inner diameter of the pipe P includes a connecting portion 110, a processing portion 120, and a coupling portion 130.

The connecting portion 110 allows the polycrystalline diamond sintered body drawing plug 100 to be positioned at the center of the processing hole 11 of the drawing die 100 while allowing the outer diameter to be spaced apart from the inner diameter of the processing hole 11. At this time, the connecting portion 110 is located on the concentric circle of the machining hole (11).

One side of the connection portion 110 is formed with a coupling groove 111 is coupled to the mandrel (MANDREL) for supporting the polycrystalline diamond sintered plug 100 is located on the concentric circle of the processing hole (11). However, the coupling groove 111 may be omitted. The outer circumferential surface of the connecting portion 110 is smoothly processed.

The connection unit 110 may be made of any one selected from the group consisting of steel, carbon steel, special steel, cast iron, nonferrous metals, and combinations thereof.

In addition, the connection part 110 is a special-purpose special steel, corrosion resistance and mechanical properties, good electrical resistance, low thermal conductivity, and can be made of stainless steel (STAINLESS STEEL) excellent workability compared to hardness.

The processing unit 120 is coupled to the other side of the connection unit 110 and processes the inner diameter of the pipe (P) passing through the processing hole (11). The machining unit 120 includes a first straight portion 122, a second straight portion 123, and an inclined portion 124.

The first straight portion 122 and the second straight portion 123 are spaced apart from each other. The diameter of the first straight portion 122 is smaller than the diameter of the second straight portion 123. In addition, the diameter ratio of the first straight portion 122 and the second straight portion 123 is 1: 1.3. The ratio of the diameters of the first straight portion 122 and the second straight portion 123 may vary depending on the machining hole 114 of the drawing die 10.

The inclined portion 124 connects the first straight portion 122 and the second straight portion 123 having different diameters. Accordingly, as the inclined portion 124 proceeds from the second straight portion 123 to the first straight portion 122, its cross-sectional area gradually decreases. The outer shape of the processing unit 120 is formed in various shapes. In the present embodiment, the shape of the processing unit 120 is not limited. The first straight portion 122 faces the straight portion 11b of the machining hole 11 and the inclined portion 124 faces at least a portion of the inclined portion 11a of the machining hole 11.

The processing unit 120 for processing the inner diameter of the pipe (P) may be made of a polycrystalline diamond sintered body (Poly Crystalline Diamond (PCD)) excellent in cohesion.

The processing unit 120 made of the polycrystalline diamond sintered body has a low friction coefficient, and the corrosion resistance fine hardness, the wear resistance, the cohesion (COHESION) and the adhesion (ADHESION) of the coating are improved.

Although the processing unit 120 is illustrated as having a shape having first and second straight portions and inclined portions in the accompanying drawings, the shape of the processing unit 120 is not limited thereto. The processing unit 120 may be formed in various forms.

The coupling part 130 connects the processing part 120 and the connection part 110 and includes a fastening groove and a bolt 131.

The fastening groove includes a first fastening groove 112 and a second fastening groove 121.

The first fastening groove 112 is formed at the other side of the connecting portion 110. In this case, the first fastening groove 112 does not penetrate the inside of the connecting portion 110 and is formed at least in part. A screw is formed in the circumferential surface of the first fastening groove 112.

The second fastening groove 121 is formed in the processing unit 120. At this time, the second fastening groove 121 penetrates inside the processing part 120. A screw is formed on the circumferential surface of the second fastening groove 121. However, a screw may not be formed on the circumferential surface of the second fastening groove 121. The second fastening groove 121 and the first fastening groove 112 are positioned on the same line and connected to each other.

The bolt 131 is coupled to the second fastening groove 121 and the first fastening groove 112 in the processing unit 120 direction. When no screw is formed on the circumferential surface of the second fastening groove 121, the bolt 131 passes through the second fastening groove 121 and is fastened to the first fastening groove 112.

In addition, the head of the bolt 131 is in close contact with the end of the processing unit 120. The head of the bolt 131 may be formed in a hexagonal shape or in a circular shape having a hexagonal groove. An anti-loosening washer (not shown) may be positioned between the head of the bolt 131 and the end of the processing unit 120 to prevent the bolt 131 from being screwed in the fastening groove. However, irregularities are formed in the bolts 131 and the processing unit 120 that are in contact with each other, so that the bolts 131 may not turn away.

As the bolt 131 is fastened to the second fastening groove 121 and the first fastening groove 112, the processing part 120 and the connection part 110 may be detachably connected.

On the other hand, the flow path is formed inside the connection portion 110 and the processing portion 120. The flow path includes a connection flow passage 113 and a bolt flow passage 132.

The connection passage 113 penetrates in one direction from the first fastening groove 112 in the connection portion 110. The connection passage 113 penetrated in one direction of the connection unit 110 is connected to the coupling groove 111. However, the connection flow passage 113 may penetrate in the circumferential direction instead of penetrating in one direction of the connection unit 110.

The bolt flow passage 132 penetrates through the inside of the bolt 131 coupled to the second fastening groove 121. The bolt flow passage 132 is connected to the connection flow passage 113.

As the polycrystalline diamond sintered drawing plug 100 is positioned inside the pipe P, the inside of the pipe P is blocked, and the pipe P is connected by a connection flow path penetrating the inside of the polycrystalline diamond sintered drawing plug 100. Inside both sides of the communication with each other may allow air to flow in the interior of the pipe (P).

Tube P passes between the processing hole 11 and the polycrystalline diamond sintered drawing plug 100 while the polycrystalline diamond sintered drawing plug 100 is located in the processing hole 11 of the drawing die 100. At the time, the outer diameter portion of the pipe P is in contact with the inclined portion 11a and the straight portion 11b of the processing hole 11, and the inner diameter portion of the pipe P is the inclined portion 124 and the first straight portion 122. It is processed while touching.

Tube P is gradually smaller in diameter as it passes between the inclined portion 124 and the inclined portion 11a, and becomes smaller in diameter when passing between the first straight portion 122 and the straight portion 11b. As P passes through the same diameter, a tube P having a predetermined diameter is formed.

On the other hand, when the tube P is pulled to draw the tube P, a vacuum pressure is generated inside the tube. The drawing die or the polycrystalline diamond sintered drawing plug is opened by the impact of the vacuum pressure being momentarily opened when the end of the tube P drawn out under the vacuum pressure is released from the polycrystalline diamond sintered drawing plug 100 and the drawing die 10. Can be damaged.

However, as the interior of the pipe P communicates with each other by the connection flow passage 113 penetrating the inside of the polycrystalline diamond sintered compact drawing plug 100, no vacuum pressure is generated inside the pipe P. Thereby, since a vacuum pressure does not generate | occur | produce inside the pipe | tube P, the damage of the polycrystal diamond sintered compact drawing plug 100 and the drawing die 10 by a vacuum pressure can be prevented.

In addition, the portion of the processing portion 120 of the polycrystalline diamond sintered drawing plug 100 which substantially processes the tube P is made of a polycrystalline diamond sintered body, and the pressure and thermal shock generated when the tube P comes into contact with the processing portion 120. It is not damaged from. Accordingly, the processing unit 120 may improve the processing quality of the pipe (P). And since the processing unit 120 is safe from pressure and thermal shock does not break does not occur replacement cost due to breakage.

Figure 5 shows a polycrystalline diamond sintered drawing plug according to another embodiment of the present invention. In accordance with another embodiment of the present invention it may have the features according to Figs.

According to another embodiment of the present invention, the polycrystalline diamond sintered drawing plug 200 includes a connection part 110, a processing part 120, and a coupling part 130.

The connecting portion 110 and the processing portion 120 of the polycrystalline diamond sintered plug 100 according to the present embodiment have the same structure and effect as those of the connecting portion and the processing portion shown in the embodiment of FIGS. 2 to 4. However, the coupling part 130 according to the present embodiment has a structure different from that of the coupling part shown in the embodiment of FIGS. 2 to 4. Accordingly, detailed descriptions of the connection part 110 and the processing part 120 of the present embodiment that are the same as the embodiment connection part and the processing part of FIGS. 2 to 4 will be omitted and only the description of the coupling part 130 will be described in detail.

Coupling portion 130 according to the present embodiment combines the connecting portion 110 and the processing unit 120 by a welding method. Welding method according to the present embodiment is made of a high temperature sintering (sintering) method using a metal powder. Metal powder is a material that forms a metal powder according to a material and uses the powder powder space connected by sintering in a vacuum furnace at high temperature and high pressure by a sintering method as a filtering space. These metal powders are excellent in breathability, filterability, and strength. In addition, the metal powder has excellent regeneration ability and is suitable for filtering heat resistant, corrosion resistant and high viscosity media.

In this way, the welding unit includes a first bead 134 and a second bead 135 that use a metal powder.

The first bead 134 is located between the connecting portion 110 and the processing portion 120 in contact with each other. The first bead 134 connects the surface where the connecting portion 110 and the processing portion 120 face each other.

The welding through hole 133 penetrates through the inside of the processing unit 120. However, the welding through hole 133 may penetrate the inside of the connection unit 110 without passing through the processing unit 120.

The second bead 135 is formed in the welding through hole 133 and is connected to the first bead 134. The second bead 135 forms a wide cross-sectional area of the first bead 134 to improve the coupling force between the connection part 110 and the processing part 120.

In addition, a connection flow path (not shown) is formed in the connection part 110, the processing part 120, and the first bead 134.

In other configurations, the configuration of the embodiment of FIGS. 2 to 5 may be applied as it is.

Another embodiment of the present invention shown in FIG. 6 has most of the components of the embodiment described with reference to FIG. 5. However, in the present embodiment, the groove 114 and the recess 125 are formed between the connecting portion 110 and the processing portion 120 facing each other. The recess 114 and the recess 125 are formed in the shape of a cone corresponding to each other. As the grooves 114 and the recesses 125 are formed in the shape of cones, the cross-sections facing the connecting portion 110 and the processing portion 120 are formed to be wide. The groove 114 and the recess 125 are not limited to the conical shape. It is irrelevant as long as the cross-sectional area of the portion in which the connecting portion 110 and the processing portion 120 face each other is formed.

Accordingly, the first bead 134 is formed between the groove 114 and the recess 125 between the connecting portion 110 and the processing portion 120 to form a wide area of the first bead 134. The first bead 134 having a wide area is more firmly coupled to the connection portion 110 and the processing portion 120. The first bead 134 according to the present embodiment is also connected to the second bead 135 located in the welding through hole 133 to form a wider cross-sectional area of the first bead 134. Accordingly, the coupling force between the connection part 110 and the processing part 120 may be enhanced.

Other configurations may be applied as the configurations of the embodiments of FIGS. 2 to 5 and 6.

Next, a method for producing a polycrystalline diamond sintered compact plug according to another embodiment of the present invention will be described.

Referring to FIG. 7, the method for manufacturing a polycrystalline diamond sintered compact plug includes a connecting part machining step S1, a processing part machining step S2, and a bonding step S3. Reference numerals described below refer to FIGS. 2 to 4.

The connecting part processing step (S1) processes the connecting part with a material made of any one selected from the group consisting of steel, carbon steel, special steel, stainless steel, cast iron, nonferrous metals, and combinations thereof. The connection part 110 has a predetermined length. At this time, the connecting portion 110 is processed into a dedicated machine tool suitable for the material and processing purposes.

This, the connection processing step (S1) comprises a coupling groove forming step and the first fastening groove forming step.

In the coupling groove forming step, the coupling groove 111 having a predetermined length in the inward direction from one side of the connecting portion 110 is formed. In the first fastening groove forming step, the first fastening groove 112 having a predetermined length is formed in the inward direction from the other side of the connection part 110. At this time, a screw is formed on the circumferential surface of the first fastening groove 112.

In addition, the connection flow path 113 is processed in the direction of the coupling groove 111 in the first fastening groove 112. However, the connection flow passage 113 may be processed in the circumferential direction of the connection portion 110 in the first fastening groove 112. And the outer peripheral surface of the connecting portion 110 is processed. At this time, the surface roughness of the outer peripheral surface of the connecting portion 110 has a low value.

Machining part Machining step S2 processes the process part with the raw material which consists of a polycrystal diamond sintered compact. At this time, the processing unit is processed by a discharger.

The machining part machining step S2 includes a second fastening groove machining step and a surface machining step.

In the second fastening groove processing step, the second fastening groove 121 is formed inside the processing unit 120 using a discharger. At this time, a screw is formed on the circumferential surface of the second fastening groove 121. However, a screw is not formed on the circumferential surface of the second fastening groove 121 and may be formed in a simple through shape.

In the surface machining step, the outer circumferential surface of the machining unit 120 is processed using a discharger. In this case, the first straight portion 122, the second straight portion 123, and the inclined portion 124 are processed. In addition, the circumferential surfaces of the first straight portion 122, the second straight portion 123, and the inclined portion 124 are polished using an ultrasonic processing machine. At this time, the outer circumferential surface roughness value of the processing unit 120 is processed to a very low value.

In the step of combining (S3), the processed connecting portion 110 and the processing unit 120 are in contact with each other and the connecting portion 110 and the processing unit 120 are coupled to each other using a bolt 131. In this case, the bolt 131 is coupled to the second fastening groove 121 and the first fastening groove 112 to couple the connection part 110 and the processing part 120. The head of the bolt 131 is in close contact with the end of the first straight portion 122 of the processing unit 120.

On the other hand, when a screw is not formed in the second fastening groove 121, the bolt 131 passes through the second fastening groove 121 and is fastened to the first fastening groove 112.

And before the bolt 131 is coupled to the fastening groove, the bolt 131 is formed with a bolt flow path 132 penetrating therein. The bolt passage 132 is connected to the connection passage 113 of the connection unit 110 when the bolt 131 is fastened to the coupling groove.

As such, the bolt 131 couples the connection part 110 and the processing part 120 so that the connection part 110 and the processing part 120 may be firmly fixed, and thus the processing part 120 may be replaced.

The method for manufacturing a polycrystalline diamond sintered plug according to another embodiment of the present invention may have the features according to FIG. 7 without limitation as described below.

According to another embodiment of the present invention, the polycrystalline diamond sintered drawing plug manufacturing method includes a joint machining step, a machining part machining step, and a bonding step.

The connection part processing step and the processing part processing step of the polycrystalline diamond sintered compact drawing plug manufacturing method according to the present embodiment have the connection part processing step and the processing part processing step of FIG. 7 as they are. However, the coupling step according to the present embodiment has a structure different from the coupling step shown in the embodiment of FIG.

Accordingly, detailed descriptions of the connection part machining step and the machining part machining step of the embodiment, which are identical to the embodiment connection part machining step and the machining part machining step of FIG. 7, will be omitted and only the description of the coupling step will be described in detail. Reference numerals described below refer to FIG. 5.

The joining step according to the present embodiment is to join the connecting part 110 formed in the connecting part machining step and the processing part 120 formed in the processing part machining step by welding, and the connecting part 110 and the processing part 120 are in contact with each other. In the state, the first bead 134 is formed between the connection part 110 and the processing part 120 to couple the connection part 110 and the processing part 120 to each other.

In addition, the connection flow path penetrating the interior of the connection part 110, the processing part 120, and the first bead 134 in a state where the connection part 110 and the processing part 120 are coupled to each other by the first bead 134. And form 113.

In other configurations, the configuration of the embodiment of FIG. 7 may be applied as it is.

Next, a method for producing a polycrystalline diamond sintered compact plug according to still another embodiment of the present invention will be described.

Yet another embodiment of the present invention has the manufacturing method of the embodiment described with reference to FIG. However, in the present embodiment, the groove 114 is formed in the connection part 110 in the connecting part machining step, and the recessed part 125 is formed in the processing part 120 in the processing part machining step. The recess 114 and the recess 125 are formed in a cone shape. In the present embodiment, the groove 114 and the recess 125 are not limited to the cone shape.

In the coupling step, the recess 125 is positioned in the recess 114 to form a first bead 134 therebetween. Accordingly, the first bead 134 is formed between the groove 114 and the recess 125 between the connecting portion 110 and the processing portion 120 to form a wide area of the first bead 134. The first bead 134 having a wide area is more firmly coupled to the connection portion 110 and the processing portion 120. The first bead 134 according to the present embodiment is also connected to the second bead 135 located in the welding through hole 133 to form a wider cross-sectional area of the first bead 134. Accordingly, the coupling force between the connection part 110 and the processing part 120 may be enhanced.

In other configurations, the configuration of the embodiment of FIG. 7 may be applied as it is.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of right.

P: tube
10: drawing die 11: machining hole
11a: inclined portion 11b: straight portion
20: Plug 21: Taper
30: mandrel
100: polycrystalline diamond sintered plug
110: connecting portion 111: coupling groove
112: first fastening groove 113: connection flow path
114: groove 120: machining
121: second fastening groove 122: first straight portion
123: second straight portion 124: inclined portion
125: main portion 130: coupling portion
131: bolt 132: bolt euro
133: welding through hole 134: first bead
135: second bead

Claims (9)

In being used for drawing processing,
Connection,
A processing part formed of a polycrystalline diamond sintered body and connected to the connection part, and
Coupling part for coupling the connection part and the processing part
Including;
The coupling portion
Fastening grooves formed in the processing part and the connecting part;
A bolt inserted into the coupling groove of the processing unit and the connection unit to couple the processing unit and the connection unit;
Containing
Polycrystalline Diamond Sintered Drawing Plug. In claim 1,
And a flow path formed in the connection portion and the processing portion. delete 3. The method of claim 2,
The flow path further comprises a connection flow path formed in the connection portion and a bolt flow path formed in the bolt and connected to the connection flow path. Connection,
A processing part formed of a polycrystalline diamond sintered body and connected to the connection part, and
Coupling part for coupling the connection part and the processing part
Including;
The coupling portion
Welding through hole penetrating the inside of any one selected from the processing portion or the connecting portion,
A first bead located between the connecting portion and the processing portion, and
A second bead located in the weld aperture and connected to the first bead
Containing
Polycrystalline Diamond Sintered Drawing Plug. The method of claim 5,
A groove having a recess and a recess formed on a surface of the processing portion and the connecting portion facing each other, wherein the first bead is positioned between the recess and the recess. In being used for drawing processing,
Machining the connection,
Processing the processed portion from a material made of a polycrystalline diamond sintered body, and
Combining the connection part and the processing part;
Including;
And the connecting portion and the processing portion are bolted or welded to each other. delete In claim 7,
And forming a flow path passing through the connection part and the inside of the processing part.

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