KR101332697B1 - Fixing jig for tooling implant abutment - Google Patents

Abstract

The present invention relates to a jig for fixing the material for abutment processing during abutment processing of a custom implant, more specifically, a fixing jig for fixing the material for abutment processing formed with a thread for coupling with the jig. . Looking at the configuration of the present invention, the working body is a hollow body formed therein, and the mounting screw which is installed in the working space to be movable and corresponding to the threaded portion of the abutment processing material is formed at one end and the cam hole is formed at the interruption An eccentric cam is provided at a position coupled to the moving member, the cam hole and corresponding to the cam hole, and one end is exposed to the outside of the main body, and a lever coupled to one end of the shaft.
According to the configuration of the present invention described above, when operating the lever after screwing the abutment processing material to the moving member, the moving member is moved by the eccentric cam provided on the shaft and the abutment processing The material is brought into close contact with the body or spaced apart from the body. That is, according to the present invention, the abutment processing material screwed to the moving member of the fixing jig can be fixed only by lever operation, so that the abutment processing material can be easily installed and removed.

Description

Fixing jig for implant abutment processing {FIXING JIG FOR TOOLING IMPLANT ABUTMENT}

The present invention relates to a jig for fixing the material for abutment processing during abutment processing of a custom implant, more specifically, easy to install and remove the material for abutment processing, to securely secure the material for abutment processing By preventing the slip with the jig during processing, and not only can easily check the processing position, but also relates to the fixing jig for implant abutment processing that can always fix the material for abutment processing in a certain position.

Dental implant (dental implant) is a method of implanting artificial tooth structure or artificial tooth structure formed by planting artificial tooth root at the site of tooth defect or tooth extraction and adhering to alveolar bone and fixing the prosthetic tooth to the artificial tooth root Means. These implants can be performed only on the missing area without damaging adjacent teeth or surrounding tissue around the missing tooth, supporting bone tissue, delaying the absorption of bone tissue and providing the same chewing power as natural teeth. It can, however, form aesthetics almost identical to natural teeth.

Looking at the structure of the implant, the artificial root (fixture) to be placed in the alveolar bone, the abutment fixed on the artificial root, the abutment screw (fixing the abutment to the artificial root) And prosthesis, a prosthesis that is an artificial tooth secured to the abutment.

However, the abutment of the above-described configuration serves to transfer the load applied through the artificial tooth to the artificial tooth root, that is, the load to the jawbone. For this purpose, the size, shape, and contour of the artificial tooth should be taken into account when processing the abutment. Should reflect all.

For this reason, abutments tend to prefer customized products that are made according to the oral environment of each patient rather than ready-made mass produced in uniform size.

Republic of Korea Patent Publication No. 2011-0012568 (2011.02.09)

The present invention is for fixing the abutment processing material during the processing of the custom abutment, the mounting and removal of the abutment processing material is easy, the material is securely fixed to the abutment processing material and slip with the jig during processing The purpose of the present invention is to provide a fixing jig for implant abutment processing, which can prevent the cutting position and can easily check the processing position as well as fixing the abutment processing material at a constant position at all times.

Implant abutment processing jig according to the present invention for achieving the above object is a jig for fixing the material for abutment processing is formed threaded for coupling with the jig.

Looking at the fixing jig for implant abutment processing according to the present invention, the hollow body formed therein and the mounting screw movably installed in the working space, the mounting screw corresponding to the threaded portion of the abutment processing material at one end A movable member having a cam hole formed at a stop thereof, coupled to penetrate the cam hole, and having an eccentric cam at a position corresponding to the cam hole, one end of which is exposed to the outside of the main body, and a lever coupled to one end of the shaft It includes.

According to the above-described configuration, when operating the lever after screwing the abutment processing material to the moving member, the moving member is moved by the eccentric cam provided on the shaft and the abutment processing material is Close to the body or spaced apart from the body.

On the other hand, the abutment processing material may be formed of a small diameter portion inserted into the inside of the main body when the screw coupling with the moving member, and a large diameter portion formed with a larger diameter than the small diameter portion. In addition, a positioning groove or a positioning protrusion may be formed in the small diameter portion.

The present invention for fixing the abutment processing material described above is configured to further include a fixing block in close contact with the small diameter portion inserted into the body. The fixing block is installed at one end of the working space, the first guide hole is formed so that one end of the moving member can penetrate. In addition, one surface of the fixing block is formed with a positioning projection or positioning groove corresponding to the positioning groove or positioning projection of the abutment processing material.

According to the above configuration, when the abutment processing material is moved to the main body side, the small diameter part is in close contact with the fixed block, and the large diameter part is in close contact with the main body. In particular, a positioning groove (or positioning protrusion) formed in the small diameter portion of the abutment processing material is inserted into the positioning protrusion (or positioning groove) formed in the fixed block.

According to the present invention configured as described above, the abutment processing material screwed to the moving member of the jig can be fixed only by lever operation, and the abutment processing material can be easily installed and removed.

In addition, the present invention is a structure in which the large diameter portion and the small diameter portion of the abutment processing material are in close contact with the main body of the jig and the fixed block, respectively, while the abutment processing material is fixed to the jig. Therefore, the material for abutment processing can be securely fixed and the processing center of the abutment processing material can be easily aligned.

Further, in the present invention, the positioning groove (or positioning projection) formed in the small diameter portion of the abutment processing material and the positioning protrusion (or positioning groove) formed in the fixing block of the jig are formed in a shape corresponding to each other. Therefore, during the processing of the abutment processing material, it is possible to prevent slip between the abutment processing material and the jig, not only to easily check the processing position, but also to always fix the abutment processing material at a constant position. .

1 is a perspective view of a fixing jig for implant abutment processing according to an embodiment of the present invention.
Figure 2 is a partial cross-sectional perspective view of the fixing jig for implant abutment processing according to an embodiment of the present invention.
Figure 3 is an exploded perspective view of the fixing jig for implant abutment processing according to an embodiment of the present invention.
4 and 5 are a cross-sectional view taken along line AA and BB of FIG.
6 to 9 is an operating state of the fixing jig for implant abutment processing according to an embodiment of the present invention.
10 is a perspective view of a fixing jig for implant abutment processing according to another embodiment of the present invention.
Figure 11 is a partial cross-sectional perspective view of the fixing jig for implant abutment processing according to another embodiment of the present invention.
12 to 15 is an operating state of the fixing jig for implant abutment processing according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring to the accompanying drawings, embodiments of the present invention will be described in detail. In the following description of embodiments according to the present invention, and in adding reference numerals to the components of each drawing, the same reference numerals are added to the same components as much as possible even though they are shown in different drawings.

Implant abutment processing jig (100, hereinafter referred to as jig) according to an embodiment of the present invention is a small abutment processing material (300 of Figure 6, hereinafter referred to as 'material') shelf, It is a special tool that can be easily installed in a machine tool such as milling, and to accurately set the machining position of the material (300).

Referring to the jig 100 with reference to Figures 1 to 5, the operating space 118 is formed in the main body 110, the moving member 120 is installed to be movable in the operating space 118, the moving member Mounting screw 130 coupled to one end of the 120, the fixed block 140 installed on one end of the working space 118, the guide ring 150 provided on the other end of the working space 118, and a moving member ( A shaft 160 coupled through the 120, a lever 170 coupled to an upper end of the shaft 160, a rolling means 180 coupled to the main body 110 to support the shaft 160, and moving; It is configured to include a spring (S) and the stopper 190 to elastically support the member 120 to the other end side of the main body 110.

The main body 110 is formed in a multi-stage cylindrical shape consisting of a small diameter portion 112, a middle diameter portion 114, and a large diameter portion 116. An operating space 118 is formed inside the main body 110, and the operating space 118 extends toward the center of the main body 110.

At one end of the main body 110, that is, the small diameter portion 112, a close contact surface 112a is formed to be in close contact with the large diameter portion 310 of the material 300, and a small portion of the material 300 is formed at the center of the close contact surface 112a. The mounting hole 112b into which the neck portion 320 is inserted is formed, and the directional groove 119 is formed around the mounting hole 112b of the close contact surface 112a. At this time, the mounting hole (112b) is connected to the working space 118, the fixed block 140, the small diameter portion 320 of the material 300 inserted through the mounting hole (112b) is installed at one end of the working space 118. To close contact with the In addition, the directional groove 119 is a means for confirming the position of the positioning projection 146 to be described later from the outside, it may be made in a pair to display all of the pair of positioning projections 146. .

A through hole 114a through which the shaft 160 penetrates is formed in an upper portion of the outer circumferential surface of the middle diameter portion 114 of the main body 110, and a coupling hole in which a rolling means 180 supporting the shaft 160 is coupled to a lower portion thereof. 114b is formed. The through hole 114a and the coupling hole 114b should be positioned in a straight line so as to prevent bending of the shaft 160.

A large number of fixing holes 116a are formed radially in the large diameter portion 116 of the main body 110, which fixes the jig 100 including the main body 110 to a machine tool such as a lathe, milling, or the like. The fixing screw (not shown) for fixing is a part to be coupled.

The moving member 120 is a means for moving the material 300 coupled to the mounting screw 130 to be movable in the working space 118. The moving member 120 includes a body 122 having a cam hole 124, a coupling protrusion 126 formed at one end of the body 122, and a guide part 128 provided at the other end of the body 122. .

Body 122 is formed of a flat plate having a predetermined thickness, both sides are formed to be curved to move in the cylindrical working space 118. The cam hole 124 formed in the body 122 is a portion through which the shaft 160 for moving the moving member 120 passes, and more specifically, the eccentric cam 164 formed at the middle of the shaft 160 is positioned. It is a part. That is, when the eccentric cam 164 rotates, the moving member 120 is moved to one end or the other end side of the main body 110 by pushing the wall surface of the cam hole 124.

Coupling protrusion 126 is a portion to which the mounting screw 130 is coupled. Coupling protrusion 126 is a pipe shape protruding from one end of the body 122, the female screw 127 is formed therein so that the mounting screw 130 can be coupled. In this embodiment, the mounting screw 130 is illustrated as a structure that is detachably coupled to the moving member 120, which can adjust the protruding length of the mounting screw 130, and when the mounting screw 130 is broken This is to allow replacement.

The guide part 128 is a part for guiding the movement of the moving member 120 together with the body 122. The guide portion 128 is formed in a multi-stage cylindrical shape protruding from the other end of the body 122, the male screw 129 is formed on the other end outer peripheral surface of the guide portion 128 so that the stopper 190 can be screwed.

The moving member 120 having the above-described structure guides the movement of the moving member 120 by contacting the inner wall of the working space 118 with the guide portion 128 at the other end of the working space 118. It is supported by the guide ring 150 installed in the guide the movement of the moving member 120. Therefore, there is no fear that the moving direction of the moving member 120 is shifted, thereby preventing malfunction of the moving member 120.

The mounting screw 130 is a part to which the material 300 is coupled. Mounting screw 130 is a rod-shaped having a predetermined length, the thread is formed on the outer peripheral surface as a whole. That is, the mounting screw 130 is a computer bolt having a predetermined length. The mounting screw 130 is coupled to and fixed to the coupling protrusion 126 of the moving member 120, one end of which is exposed to the outside through the fixing block 140 and the main body 110.

The fixed block 140 is formed in a multi-stage disc shape. A first guide hole 142 through which the mounting screw 130 penetrates is formed at the center of the fixing block 140, and one surface of the fixing block 140 is in close contact with the small diameter portion 320 of the material 300. 144 is formed. In addition, a pair of positioning protrusions 146 are formed on the contact surface 144, which is a material when the small diameter portion 320 of the material 300 is in close contact with the fixed block 140. A portion inserted into the positioning groove 330 formed in the small diameter portion 320 of (300).

Here, the above-mentioned fixing block 140 is fixed to the inside of the body 110 through the fixing screw 148, which is to allow the fixing block 140 to be replaced when the positioning projection 146 is broken. For sake.

The guide ring 150 has a disc shape having a predetermined thickness, and a second guide hole 152 through which the guide part 128 penetrates is formed therein. In addition, a male screw 154 is formed on the outer circumferential surface of the guide ring 150 so that the guide ring 150 can be coupled to the other end of the working space 118. The guide ring 150 guides the movement of the movable member 120 by supporting the guide unit 128.

The shaft 160 includes a rotation shaft 162 having a predetermined length and an eccentric cam 164 formed at the middle of the rotation shaft 162. The upper end of the rotation shaft 162 penetrates through the through hole 114a formed in the main body 110, and the lower end is inserted into the rolling means 180 coupled to the main body 110. At this time, the eccentric cam 164 is located in the cam hole 124 formed in the body 122 of the moving member 120, the eccentric cam 164 is rotated when the shaft 160 is rotated by operating the lever 170. The moving member 120 is moved by pushing the inner wall of the cam hole 124.

The lever 170 is an operation means for rotating the shaft 160. Since the lever 170 has the same structure as a conventional rod-shaped handle for rotating the shaft, a detailed description thereof will be omitted.

The rolling means 180 is formed in a disk shape having a flange 182 formed at the bottom thereof. The upper surface of the rolling means 180 is formed with an insertion groove 184 is inserted into the lower end of the rotary shaft 162 of the shaft 160, the outer peripheral surface of the male screw to be coupled to the coupling hole (114b) of the main body 110 ( 186 is formed. At this time, the insertion groove 184 of the rolling means 180 coupled to the coupling hole 114b should be located in line with the through hole 114a so as to prevent bending of the shaft 160. In addition, when a bearing (not shown) is added to the insertion groove 184 and the through hole 114a, the shaft 160 may be smoothly rotated.

The stopper 190 is a means for elastically supporting the moving member 120 to the other end side of the main body 110 together with the spring (S). The stopper 190 is formed in a C shape having a cutout 192 formed at one side thereof, and an internal thread 194 is formed therein so that the stopper 190 can be screwed to the other end of the guide 128. . In addition, both ends of the stopper 190 is coupled with a fixing screw 196 for fixing in close proximity to both ends spaced by the incision 192.

The spring S is positioned between the guide ring 150 and the stopper 190 to elastically support the moving member 120 to the other end side of the main body 110. At this time, in the present embodiment, a plurality of plate springs are used as the spring S, but the present invention is not limited thereto and various springs may be applied according to the needs of the user.

6 to 9, the process of mounting and removing the material 300 using the jig 100 according to the present embodiment will be described.

Looking at the material 300 mounted on the jig 100 according to the present embodiment, the material 300 is formed in a multi-stage cylindrical shape consisting of a large diameter portion 310 and a small diameter portion 320. At one end of the material 300 (the end on which the small diameter portion 320 is formed), a screw portion 340 corresponding to the mounting screw 130 of the jig 100 is formed. A positioning groove 330 is formed in the small diameter portion 320 of the material 300 so that the positioning protrusions 146 of FIGS. 2 and 4 can be inserted into the fixing block 140 of the jig 100. In addition, the confirmation groove 350 is formed in the large diameter portion 310 so that the position of the positioning groove 330 can be checked from the outside in the state where the material 300 is mounted on the jig 100.

6 and 7 illustrate the process of mounting the material 300 to the jig 100. As shown in FIGS. 6 and 7, the lever 170 is rotated in a clockwise direction, and the moving member 120 is moved to one end of the main body 110 so that a part of the mounting screw 130 may be removed. It protrudes outward. In this state, since the mounting screw 130 protrudes to the outside of the main body 110, the material 300 can be easily coupled to the mounting screw 130.

First, the material 300 is screwed to the mounting screw 130 protruding to the outside of the main body 110. That is, the screw portion 340 of the material 300 is positioned to abut one end of the mounting screw 130, and then the material 300 is rotated and screwed. At this time, the small diameter portion 320 of the material 300 is inserted into the body 110 through the mounting hole 112b and then rotated so as to be inserted to a predetermined depth.

When the material 300 is inserted to a predetermined depth, the material 300 is rotated in the forward or reverse direction, and the position of the material 300 is adjusted so that the positioning groove 330 and the positioning protrusion (146 in FIGS. 2 and 4) coincide with each other. Adjust. At this time, when matching the identification groove 350 formed in the material 300 and the directional groove 119 formed in the main body 110 of the positioning groove 330 and the positioning projections (146 of FIGS. 2 and 4). The position is matched.

Then, when the lever 170 is rotated in the direction of the arrow of FIG. 6 in a state where the positioning groove 330 and the positioning protrusion 146 coincide with each other, the rotation shaft 162 and the eccentric cam 164 of the shaft 160 are rotated. It rotates and presses the wall surface of the cam hole 124, the moving member 120 is guided by the operating space 118 and the guide ring 150 to move to the other end side of the main body 110. As a result, the material 300 coupled to the mounting screw 130 is also moved and fixed in close contact with the main body 110.

In this process, the large diameter portion 310 of the material 300 is in close contact with the contact surface 112a of the small diameter portion 112 of the main body 110, and the small diameter portion 320 of the material 300 is fixed block 140. It is in close contact with the contact surface 144 of. In addition, the positioning protrusion 146 formed in the fixed block 140 is inserted into the positioning groove 330 formed in the small diameter portion 320 of the material 300 (see FIGS. 8 and 9).

Here, the moving member 120 pulling the material 300 is elastically supported to the other end side of the main body 110 by a spring S positioned between the guide ring 150 and the stopper 190, even if an external force is applied. The material 300 mounted on the jig 100 is not easily spaced apart or removed.

On the other hand, since the removal process of the material 300 mounted on the jig 100 is in the reverse order of the mounting process, a detailed description thereof will be omitted.

According to this embodiment described above, the material 300 screwed to the jig 100 can be reliably fixed only by operating the lever 170. Therefore, the installation and removal of the material 300 is easy and can reduce the time required for mounting and removal work is very efficient.

In addition, the contact surface 112a having the large diameter portion 310 and the small diameter portion 320 of the material 300 formed on the main body 110 and the fixed block 140 in a state in which the material 300 is fixed to the jig 100. 144) so that the processing center of the material 300 can be easily matched.

In addition, since the positioning protrusion 146 formed in the fixed block 140 is inserted into the positioning groove 330 formed in the small diameter portion 320 of the material 300, the material 300 in the process of processing the material 300 Slip between the 300 and the jig 100 can be prevented, and not only the processing position can be easily confirmed, but also the material 300 can be fixed at a constant position at all times.

10 and 11 are a perspective view and a partial cross-sectional perspective view of a fixing jig for implant abutment processing according to another embodiment of the present invention, with reference to FIGS. 10 and 11 to the jig 200 according to another embodiment of the present invention. Let's look at the following.

The jig 200 according to the present embodiment includes a main body 210, a moving member 220 installed to be movable within the main body 210, and a mounting screw 230 coupled to one end of the moving member 220. And, the fixed block 240 installed in the inner end of the main body 210, the guide ring 250 installed in the other end of the inner body 210, the shaft 260 coupled through the moving member 220, The lever 270 coupled to the upper end of the shaft 260, the rolling means (not shown) coupled to the main body 210 to support the shaft 260, and the moving member 220 to the other end side of the main body 110. It is configured to include a spring (S) and the stopper 290 to elastically support.

Among the components constituting the jig 200 of the present embodiment, other components 220 to 290 and S except for the main body 210 are the same as the corresponding components 120 to 190 and S of the above-described embodiment. The description will be omitted.

The main body 210 is formed in a cylindrical shape having a plurality of stages having different outer diameters, and an operating space 218 is formed therein. At one end of the main body 210 having a relatively small outer diameter, a contact surface 212a is formed in which the large diameter portion 310 of the material 300 is in close contact, and a small diameter portion of the material 300 is formed at the center of the contact surface 212a. The mounting hole 212b into which the 320 is inserted is formed. In addition, a mounting groove 212c is formed at an inner upper portion and a lower portion of the mounting hole 212b, and a positioning protrusion 219 is inserted into the mounting groove 212c, and the positioning protrusion 219 is a bolt (B). Is fixed by. At this time, the mounting hole 212b is connected to the working space 218, the small block 320 of the material 300 inserted through the mounting hole 212b fixed block 140 is installed at one end of the working space 218. To close contact with the

Meanwhile, referring to FIG. 12, the material 300 mounted on the jig 200 according to the present embodiment will be described. The material 300 has a multi-stage cylindrical shape including a large diameter part 310 and a small diameter part 320. Is formed. At one end of the small diameter portion 320 side of the material 300, a threaded portion 340 corresponding to the mounting screw 230 of the jig 200 is formed, and the large diameter portion 310 is formed on the main body 210 of the jig 200. The positioning groove 330 into which the combined positioning protrusion 219 is inserted is formed.

12 and 13 illustrate a process of mounting the material 300 on the jig 200, and screwing the material 300 to the mounting screw 230 protruding to the outside of the main body 210. That is, the screw portion 340 of the material 300 is positioned to abut one end of the mounting screw 230, and then the material 300 is rotated and screwed. At this time, the small diameter portion 320 of the material 300 is rotated to be inserted to a predetermined depth after being inserted into the inside of the main body 210 through the mounting hole (212b).

When the material 300 is inserted to a predetermined depth, the material 300 is rotated in the forward or reverse direction, and the position of the material 300 is adjusted to match the positioning groove 330 and the positioning protrusion 219. At this time, the positioning groove 330 is formed in the large diameter portion 310 of the material 300, and the positioning protrusion 219 protrudes out of the main body 210, so that the positioning groove 330 and the positioning protrusion ( The position of 219 can be more accurately and easily matched.

Then, when the lever 270 is rotated in the direction of the arrow in FIG. 12 while the positioning groove 330 and the positioning protrusion 219 are aligned, the rotation shaft 262 and the eccentric cam 264 of the shaft 260 Rotate and press the wall surface of the cam hole 224, the moving member 220 is guided by the operating space 218 and the guide ring 250 to move to the other end side of the main body 210, coupled to the mounting screw 230 The material 300 is moved and adhered to and fixed to the main body 210.

In this process, the large diameter portion 310 of the material 300 is in close contact with the contact surface 212a of the main body 210, and the small diameter part 320 of the material 300 is in close contact with the fixed block 240. In addition, a positioning protrusion 219 coupled to the main body 210 is inserted into the positioning groove 330 formed in the material 300 (see FIGS. 14 and 15).

In the jig 200 and the material 300 according to the present embodiment, the positioning protrusion 219 protrudes to the outside of the main body 210, and the positioning groove 330 is the large diameter portion of the material 300. It is formed in 310, the operator can visually check this, so that the positioning groove 330 and the positioning projection 219 can be more accurately and easily matched. In addition, since the positioning protrusion 219 is inserted into the positioning groove 330, it is possible to prevent the slip between the material 300 and the jig 200 in the process of processing the material 300.

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Those skilled in the art will understand. Therefore, the scope of protection of the present invention should be construed not only in the specific embodiments but also in the scope of claims, and all technical ideas within the scope of the same shall be construed as being included in the scope of the present invention.

100: jig 110: main body
112: small neck 114: middle neck
116: large neck 118: operating space
120: moving member 122: body
124: cam hole 128: guide portion
130: mounting screw 140: fixed block
142: first guide 144: close contact
146: positioning protrusion 150: guide ring
152: second guide hole 160: shaft
162: rotation axis 164: eccentric cam
170: lever 180: rolling means
190: stopper 192: incision
S: Spring 300: Material
310: large diameter part 320: small diameter part
330: positioning groove 340: screw portion
350: confirmation

Claims (12)

In the fixing jig for fixing the material for abutment processing having a threaded portion at one end,
A hollow body having an operating space formed therein;
A movable member which is installed to be movable in the working space, the mounting screw corresponding to the threaded portion of the abutment processing material is formed at one end, and a cam hole is formed at the stop;
A shaft coupled to penetrate the cam hole, an eccentric cam is provided at a position corresponding to the cam hole, and one end of which is exposed to the outside of the main body; And
A lever coupled to one end of the shaft,
When the lever is manipulated after screwing the abutment processing material to the moving member, the moving member is moved by the eccentric cam provided on the shaft, and the abutment processing material is brought into close contact with the main body or the main body. Fixing jig for implant abutment processing, characterized in that spaced apart from. The method according to claim 1,
The abutment processing material is composed of a small diameter portion inserted into the inside of the main body when the screw is coupled to the moving member, and a large diameter portion formed with a larger diameter than the small diameter portion,
A fixing block is installed at one end of the working space, and the fixing block has a first guide hole through which the mounting screw passes.
When the abutment processing material is moved to the main body side, the small diameter portion is in close contact with the fixing block, the large diameter part is in contact with the main body fixed jig for implant abutment processing. The method according to claim 2,
Positioning grooves or positioning projections are formed in the small diameter portion of the abutment processing material,
The fixing block jig for implant abutment processing, characterized in that the positioning projection or positioning groove corresponding to the positioning groove or positioning projection is formed in the fixed block. The method according to claim 2,
A positioning groove is formed in the large diameter portion of the abutment processing material,
Fixing jig for implant abutment, characterized in that the main body is provided with a positioning projection corresponding to the positioning groove. The method according to any one of claims 1 to 4,
The movable member includes a body in which the cam hole is formed, a mounting screw provided at one end of the body, and a guide part provided at the other end of the body,
Implant abutment fixing jig characterized in that the guide ring for supporting the guide portion is installed at the other end of the operating space. The method according to claim 5,
The mounting screw is a threaded screw threaded to the body, the fixing jig for implant abutment processing, characterized in that the female thread formed on one end of the body. The method according to claim 5,
A stopper is coupled to the other end of the guide portion, and a fixing jig for implant abutment processing is installed between the guide ring and the stopper to elastically support the moving member to the other end side of the main body. The method of claim 7,
The stopper is formed in a C-shape surrounding the other end of the guide portion, the fixing jig for implant abutment processing, characterized in that both ends of the stopper is fastened by a fixing screw. The method according to claim 8,
A male screw is formed on the outer circumferential surface of the other end of the guide portion, and a female screw is formed on the inner circumferential surface of the stopper. The method according to any one of claims 1 to 4,
The main body is formed in multiple stages having different diameters of the outer circumferential surface, one end of the main body is formed in close contact with one end of the abutment processing material, the interruption is formed through holes through which one end of the shaft is formed A fixed jig for implant abutment processing. The method of claim 10,
Implant abutment processing jig characterized in that the directional groove is formed on the contact surface. The method of claim 10,
Implant abutment fixing jig, characterized in that the rolling means for supporting the lower end of the shaft is installed in the middle of the main body.

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