KR102276544B1 - Guide drill assembly for implant - Google Patents

Abstract

The present invention includes: a guide drill made of a single metal body and including a handpiece coupling part, a first shaft part, a stoppering part, a second shaft part, a third shaft part, and a drill part; It consists of a single metal body and can be fitted in the second and third shafts of the guide drill, and includes a cylindrical part having a diameter corresponding to the mesio-distal diameter of a tooth requiring implantation, a cylindrical protrusion, a cone part, and an extension part and a hollow sleeve passing through the center of the cylindrical protrusion, extension, cylinder and cone portion, a plurality of slits imparting elasticity to the cylindrical protrusion and extension in a radial direction, and protruding from the inner peripheral end of the cylindrical protrusion toward the hollow sleeve a stopper including a stepped portion to be formed, and when the stopper is inserted into the guide drill from the drill portion, the step portion of the stopper is spread in the radial direction by the elasticity of the plurality of slits to contact the outer surface of the third shaft. It provides a guide drill assembly for implant surgery, characterized in that fitted to the outer surface of the shaft.

Description

Guide drill assembly for implant procedure {GUIDE DRILL ASSEMBLY FOR IMPLANT}

The present invention relates to a guide drill assembly for implant surgery, and more particularly, a guide drill for implant surgery comprising a guide drill used for drilling alveolar bone to fix a fixture for implant placement, and a stopper inserted therein to help drilling. It's about assembly.

Recently, implants to replace missing teeth have become common. This implant treatment method is a series of processes in which the alveolar bone hole is formed through drilling in the alveolar bone, the fixture is fixed, various abutments are fixed with the fixture, and finally the prosthesis is fixed with the fixture.

A variety of tools and methods are used for this series of operations, and the present invention relates to a tool necessary for a procedure required in the process of incising the gingiva for implant placement and drilling the alveolar bone to fix the fixture.

Currently, a drilling set sold under the trade name of 'BonePen' by Acrodent Co., Ltd. is known as the instrument used for this procedure, and the technology of this drilling set is disclosed in Korean Patent Publication No. 10-1159560. In the process of drilling the guide drill, the technology disclosed in this patent publication has a pen spring interposed inside the cup that surrounds the guide drill, and the elastic force of the spring causes the cup to reciprocate between teeth during the drilling process of the guide drill. Although the function of assisting the centering of the guide drill is disclosed, there is a problem that a lot of mechanisms are required to interpose the pen spring inside the cup, which affects the rigidity of the guide drill or interferes with the smooth operation of the guide drill.

That is, as described above, the space for the dentist who is the operator to drill the alveolar bone in the mouth of the patient who is the recipient is very narrow, and the guide drill, which is a device for this, has to be made in a very small size. In order to insert and assemble many structures in order to secure the centering of the structure, the size of the structure is very small, so not only the assemblyability is deteriorated, but also the possibility of defects is increased. All these reasons are inevitably the cause of the increase in the cost of the guide drill assembly. do.

Registered Patent Publication No. 10-1159560

Accordingly, an object of the present invention is to provide a guide drill assembly for implant surgery that can ensure the rigidity of the guide drill while ensuring the centering of the guide drill with a simpler structure.

To this end, the present invention is made of a single metal body, a handpiece coupling portion, a first shaft portion having a first length and a first diameter, a stoppering portion having a diameter greater than the first diameter, and the first A second shaft portion having a second length smaller than the first diameter and a second diameter larger than the first diameter and smaller than the stoppering diameter, a third length smaller than the second length, and a third diameter larger than the second diameter and smaller than the stoppering diameter A third shaft portion having a, a guide drill including a drill portion, and a single metal body can be fitted to the second shaft and the third shaft of the guide drill, corresponding to the mesio-distal diameter of the tooth requiring implant treatment. A cylindrical portion having a diameter, a cylindrical projection integrally projecting with the cylindrical portion above the cylindrical portion, a cone portion extending integrally with the cylindrical portion below the cylindrical portion, and a cylindrical portion integrally provided between the cylindrical portion and the cylindrical projection An extension, a cylindrical protrusion, a hollow sleeve passing through the center of the cylindrical and cone portions, and a plurality of slits formed in the longitudinal direction on the outer periphery of the cylindrical protrusion to impart elasticity to the cylindrical protrusion and the extension in a radial direction; , a stopper including a stepped portion protruding from the inner peripheral end of the cylindrical protrusion toward the hollow sleeve, the inner diameter of the stopper hollow sleeve is greater than the third diameter of the third shaft, and the inner diameter of the stopper stepped portion is smaller than the diameter of the stopper ring while being smaller than the third diameter of the third shaft and larger than the second diameter of the second shaft, when the stopper is inserted into the guide drill from the drill part, the step portion of the stopper is spread radially due to the elasticity of the plurality of slits, and the 3 It provides a guide drill assembly for implant surgery, characterized in that fitted to the outer surface of the second shaft while contacting the outer surface of the shaft.

Here, the slit may preferably include a plurality of slits formed on the cylindrical protrusion.

In addition, a plurality of slits may be formed in the extension portion.

In this case, more preferably, the slit of the extension is locally reduced in thickness of the extension.

Here, the height of the stopper may correspond to the sum of the second length and the third length to limit the maximum insertion depth of the drill part.

The guide drill is preferably made of a single body by machining a martensitic stainless steel rod.

The stopper is preferably made of a single body by machining a titanium alloy rod.

According to the present invention, it is possible to provide a guide drill assembly for implant surgery that can ensure the rigidity of the guide drill while ensuring the centering of the guide drill with a simpler structure.

1 shows a perspective view of a guide drill and a stopper constituting a guide drill assembly according to the present invention in a separated state.
Figure 2 shows a cross-sectional view of a state in which the guide drill and the stopper constituting the guide drill assembly according to the present invention are combined.
Figures 3a and 3b are virtual views assuming a case of operating the guide drill assembly according to the present invention, Figure 3a shows a state in which the drilling of the guide drill is not sufficiently made, Figure 3b is the drilling of the guide drill is sufficient shows the status of
4 is a virtual view assuming a state in which a guide pin that can be provided separately in the alveolar bone hole is inserted after the drilling operation is completed by the guide drill assembly according to the present invention.
5A and 5B are a perspective view and a cross-sectional view illustrating the configuration of the guide pin shown in FIG. 4 .
6 is a view schematically showing a process for determining a three-dimensional position of a target tooth using the guide drill assembly according to the present invention.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings are provided for the purpose of helping the understanding of the present invention, the scope of which will be defined by the claims.

Of the accompanying drawings, Figure 1 shows a perspective view of a state in which a guide drill and a stopper constituting the guide drill assembly according to the present invention are separated, Figure 2 is a guide drill and a stopper constituting the guide drill assembly according to the present invention Shows a cross-sectional view of the assembled state

As shown in the drawings, the guide drill assembly according to the present invention consists of a guide drill 100 and a stopper 200 . Each of these members is characterized in that it is obtained by machining a single metal body. That is, it is made by cutting a rod-shaped round bar metal material with a CNC lathe, and then heat-treating it in a post-process, and grinding or electrolytic polishing may be performed on the surface. In any case, since the round bar metal is manufactured through machining, rigidity can be guaranteed.

More specifically, the guide drill 100 of the present invention is made of a single metal body, preferably by machining a round bar made of martensitic stainless steel to form the guide drill 100. However, according to a preferred embodiment of the present invention, a trimrite material was used. The round bar of this material was manufactured by machining the guide drill 100 shown in the drawing through CNC machining, that is, by cutting it. It can be replaced by CNC lathes as well as machining centers depending on machining demands. Therefore, sufficient rigidity and stability or biocompatibility for drilling alveolar bone can be secured.

The guide drill 100 includes a handpiece coupling part 110 that can be coupled to an electric drill (not shown), a first shaft part 120 having a first length 122 and a first diameter, and a first diameter. A stoppering portion 130 having a larger diameter, a second length 142 smaller than the first length 122, and a second shaft portion 140 having a second diameter larger than the first diameter and smaller than the stopper ring diameter and , a third shaft portion 150 having a third length 152 smaller than the second length 142 and a third diameter greater than the second diameter and smaller than the stopper ring 130 diameter, and a drill portion 160 . do.

In addition, a stopper 200 that can be fitted from the lower part of the guide drill 100 is provided to configure the guide drill assembly according to the present invention, and the stopper 200 is also made of a single metal body like the guide drill 100 . is done Preferably, the stopper 200 may be formed by machining a round bar made of titanium alloy, and according to a preferred embodiment of the present invention, ELI material is used. The round bar of this material was manufactured by machining the stopper 200 shown in the drawing through CNC machining, that is, by cutting it. As described above, the CNC lathe may be replaced by a machining center or the like depending on the machining demand. Likewise, sufficient rigidity and stability or biocompatibility may be secured.

The stopper 200 is made of a single metal body and can be inserted into the second shaft 140 and the third shaft 150 of the guide drill 100, the mesio-distal view of the tooth requiring implant surgery (to be described later). A cylindrical portion 210 having a diameter corresponding to , a cylindrical projection 240 integrally projecting with the cylindrical portion 210 above the cylindrical portion 210, and the cylindrical portion 210 integrally extending below the cylindrical portion The cone 220 and the cylindrical portion 210 and the cylindrical portion 210 and the extension portion 270 provided integrally with the cylindrical portion between the protrusion 240, the cylindrical projection 240, the extension portion 270, the cylinder The hollow sleeve 230 penetrating through the center of the portion 210 and the cone portion 220, and formed in the longitudinal direction on the outer periphery of the cylindrical projection 240, the cylindrical projection 240 and the extension portion 270 in the radial direction elastic It includes a plurality of slits 250 and 252 for giving a , and a stepped portion 260 protruding from the inner peripheral end of the cylindrical protrusion 240 toward the hollow sleeve 230 .

Here, the inner diameter of the stopper 200, the hollow sleeve 230 is greater than the third diameter of the third shaft 150, the stopper stepped portion 260, the inner diameter is smaller than the diameter of the stopper ring 130, the third shaft 150 smaller than the third diameter of the second shaft 140 and larger than the second diameter of the second shaft 140, when inserting the stopper 200 into the guide drill 100 from the drill part 160 side, the plurality of slits 250 and 252 Due to the elasticity of the stopper, the stepped portion 260 of the stopper is spread in the radial direction and is fitted to the outer surface of the second shaft while contacting the outer surface of the third shaft 150 .

The slit is a plurality of slits 250 formed by removing a portion of the cylindrical protrusion 240 in the longitudinal direction at equal intervals along the circumferential direction of the cylindrical protrusion 240, and the extension 270 at equal intervals along the circumferential direction. It may include an extension slit 252 formed of . As shown in the drawing, the extension slit 252 may be formed by locally reducing the thickness of the extension. Due to the presence of these slits 250 and 252, the cylindrical protrusion 240 has elasticity in the radial direction, and as a result, a stepped portion 260 formed to protrude from the inner peripheral end of the cylindrical protrusion 240 toward the hollow sleeve 230. In this radial direction, it is elastic and can be opened.

When the stopper 200 is fitted under the drill part 160 of the guide drill 100 as described above by having such a structure, the stepped part 260 is slightly spread while contacting the surface of the third shaft 150 When it is fitted and reaches the second shaft 140 , the inner diameter of the stepped portion 260 returns to its original position and has a size capable of smoothly moving on the surface of the second shaft 140 , so in the state fitted to the second shaft 140 , Even if a relatively large force is not applied, there is no difficulty in moving up and down on the second shaft 140 . Alternatively, once the stopper 200 is fitted up to the second shaft 140 , it does not come down on the third shaft 150 and does not fall out unless a force is applied in the downward direction. In addition, since the inner diameter of the hollow sleeve 230 is very finely large in correspondence with the third diameter of the third shaft 150 , the hollow sleeve 230 while the stepped portion 260 moves up and down along the second shaft 140 . ) while in contact with the outer surface of the third shaft 150 serves to guide it.

According to a preferred embodiment of the present invention, the length of the handpiece coupling unit 110 is approximately 2 mm, the first length 122 is approximately 11 mm, and the thickness of the stoppering unit 130 is less than 1 mm, and the second The length 142 is approximately 5 mm, the third length 152 is approximately 3 mm, and the length of the drill portion 160 is approximately 9 mm so that the overall drill guide assembly height is approximately 30 mm. The diameter of the drill part is about 2 mm, and the diameter of the stoppering part 130 is about 6 mm.

It is preferable that the standard of the guide drill 100 be unified into one standard as described above in consideration of the convenience of manufacture, but the diameter of the cylindrical part of the stopper 200 is a size corresponding to the mesio-distal diameter of the lost tooth, so it is 6 mm , 7 mm, 8 mm, 9 mm, 10 mm, etc., should be prepared in several sizes, and a stopper 200 of a different size may be fitted and used according to the mesio-distal diameter of the lost tooth, that is, the tooth to be implanted. It is possible to use a stopper 200 of a different size in one guide drill 100, but a stopper 200 of a different size is provided in one kit with a stopper 200 of a different size inserted into the guide drill 100. It would be good for the convenience of the operator to configure to use the guide drill 100 fitted with the stopper 200 according to the size of the heart diameter.

The total height of the stopper 200 will be the sum of the cylindrical protrusion 240 , the extended portion 270 , the cylindrical portion 210 , and the cone portion 220 , which is the second length 142 and the third length 152 . It is preferable to correspond to the sum of According to one preferred embodiment described above, it may be approximately 8 mm. That is, when the stopper 200 rises to the highest position, the lower end of the stoppering unit 130 and the upper end of the cylindrical protrusion 240 come into contact, and in that state, the lower end of the cone unit 220 is the lower end of the third shaft 150 . and the stopper 200 will completely cover the second shaft 140 and the third shaft 150 .

Figures 3a and 3b are virtual views assuming a case of operating the guide drill assembly according to the present invention, Figure 3a shows a state in which the drilling of the guide drill is not sufficiently made, Figure 3b is the drilling of the guide drill is sufficient shows the status of

In the process of drilling to place the implant fixture on the lost tooth, a stopper 200 corresponding to the mesio-distal diameter of the lost tooth is selected, and the stopper is inserted into the guide drill 100 to insert the cylindrical protrusion 240 step ( Drilling is started in a state in which the 260 is inserted up to the second shaft 140 . When drilling is performed in the direction of the arrow shown in FIG. 3A, it becomes possible to form an alveolar bone hole at the exact center of the mesio-distal diameter of the consequently lost tooth. The process of drilling the alveolar bone hole is not performed once with an electric drill, but the guide drill reciprocates up and down several times while drilling. In this process, the stepped part 260 of the cylindrical protrusion 240 is first 2 The shaft 140 is relatively moved along the outer surface, and as described above, the hollow sleeve 230 is also moved relative to the third shaft 150 along the outer surface of the guide drill 100. Centered at the exact center of the mesiodistal mirror will guide the formation of the alveolar bone hole. Figure 3b shows a state in which the drilling of the guide drill 100 is sufficiently made through this process, and the drill part 160 of the guide drill 100 forms an alveolar bone hole to a desired depth in the alveolar bone.

Thereafter, the guide drill assembly is removed, the guide pin 300 provided separately is inserted into the alveolar bone hole, and a subsequent procedure can be performed accordingly. The guide pin 300 has the shape shown in FIGS. 5A and 5B , and is manufactured by machining one body like the stopper. The guide pin 300 may be formed by machining a round bar made of a titanium alloy, which is the same material as the stopper 200 , and according to a preferred embodiment of the present invention, ELI material is used. The round bar of this material was manufactured by machining the guide pin 300 shown in the drawing through CNC machining, that is, by cutting it. As described above, the CNC lathe may be replaced by a machining center or the like depending on the machining demand. Likewise, sufficient rigidity and stability or biocompatibility may be secured.

As shown in the drawing, the rod extension 340 that can be fitted into the alveolar bone hole formed by drilling, the crown 310 that can correspond to the lost teeth, the sealing connection 320 for preventing separation of the operation part, and there It has a hole 330 formed therein. The length of the rod extension part 340 is about 9 mm corresponding to the length of the drill part 340, the height of the crown part 310 is about 5 mm, and the height of the sealing connection part 320 is about 2 mm. , the total height of the guide pin 300 is approximately 16 mm. The diameter of the rod extension part 340 is about 1.9 mm in consideration of the diameter of the drill part 160 being 2 mm, and the diameter of the crown part 310 of the guide pin 300 corresponds to the mesio-distal diameter of the lost tooth. It is preferable to be prepared in several sizes, such as 6 mm, 7 mm, 8 mm, 9 mm, 10 mm, etc. like the stopper 200 .

In FIGS. 3A and 3B , it has been described assuming that there is only one missing tooth. However, when two or more adjacent teeth are lost and an implant needs to be operated, one tooth is removed using the guide drill assembly according to the present invention. After inserting the guide pin 300 into the alveolar bone hole after forming the alveolar bone hole, the procedure of forming the alveolar bone hole for the implantation of the implant fixture using the guide drill assembly according to the present invention also in the adjacent position will step on These series of procedures are already in progress, and detailed descriptions thereof will be omitted.

A process of determining a three-dimensional position of a target tooth using the guide drill assembly according to the present invention will be described with reference to FIG. 6 .

First, assuming that the patient's adjacent teeth (T0) exist and the target teeth (T1, T2) adjacent thereto are lost and implantation is performed, the ideal dentition arrangement targeted by 'D1', the mesio-distal view of T1 It can be easily obtained through the above method, and when the stopper standard closest to the mesiodistal diameter 'T1' is selected and the stopper is positioned close to the adjacent tooth T0, the center of the target tooth is determined in the mesiodistal direction. Next, the user can identify the center in the buccal and lingual directions from the alveolar bone that appears by incising the gingiva by visual or tactile sense. can Accordingly, the user can very simply and conveniently determine the center of the mesio-distal direction and the buccal direction of the target tooth (refer to 'C1' in the drawing) by using the guide drill assembly according to the present invention.

By determining the size of the stopper 200 corresponding to the determined mesio-distal diameter and inserting the drilling into the guide drill 100, it is possible to drill the alveolar bone hole by accurately centering it at the center position of the target tooth.

According to the present invention, it is possible to provide a guide drill assembly for implant surgery that can ensure the rigidity of the guide drill while ensuring the centering of the guide drill with a simpler structure.

100: guide drill
110: handpiece coupling part
120: first shaft
130: stoppering unit
140: second shaft
150: third shaft
160: drill part
200: stopper
210: cylindrical part
220: Konbu
230: hollow sleeve
240: cylindrical protrusion
250, 252: slit
260: stepped portion
270: extension
300: guide pin

Claims (7)

Consisting of a single metal body, a handpiece coupling portion, a first shaft portion having a first length and a first diameter, a stoppering portion having a diameter greater than the first diameter, a second length smaller than the first length, A second shaft portion having a second diameter greater than the first diameter and smaller than the stoppering diameter, a third shaft portion having a third length smaller than the second length and a third diameter greater than the second diameter and smaller than the stoppering diameter; , and a guide drill including a drill part,
It consists of a single metal body and can be fitted to the second and third shafts of the guide drill, and a cylindrical part having a diameter corresponding to the mesio-distal diameter of a tooth requiring implantation, and the cylindrical part on the upper side of the cylindrical part integrally A protruding cylindrical portion, a cone portion extending integrally with the cylindrical portion below the cylindrical portion, an extension provided integrally with the cylindrical portion between the cylindrical portion and the cylindrical portion, and the cylindrical portion, the extension, the cylindrical portion and the center of the cone portion It consists of a stopper including a hollow sleeve passing through, a plurality of slits formed in the longitudinal direction on the cylindrical protrusion, and a stepped portion protruding from the inner peripheral end of the cylindrical protrusion toward the hollow sleeve,
The inner diameter of the stopper hollow sleeve is larger than the third diameter of the third shaft, and the inner diameter of the stopper step is smaller than the diameter of the stopper ring, smaller than the third diameter of the third shaft and larger than the second diameter of the second shaft, so that the stopper is drilled When inserted into the guide drill from the side, the step portion of the stopper is spread in the radial direction by the elasticity of the plurality of slits, and the guide for implant surgery, characterized in that it is fitted to the outer surface of the second shaft while contacting the outer surface of the third shaft drill assembly.
According to claim 1,
The plurality of slits is a guide drill assembly for implant surgery, characterized in that the cylindrical protrusion is formed by partially removing the cylindrical protrusion in the longitudinal direction at equal intervals along the circumferential direction.
3. The method of claim 2,
Guide drill assembly for implant surgery, characterized in that it further comprises a plurality of extension slits formed to correspond to the plurality of cylindrical protrusion slits.
4. The method of claim 3,
The extension slit is a guide drill assembly for implant surgery, characterized in that the thickness of the extension is locally reduced.
5. The method according to any one of claims 1 to 4,
A guide drill assembly for implant surgery, characterized in that the height of the stopper corresponds to the sum of the second length and the third length.
5. The method according to any one of claims 1 to 4,
The guide drill is a guide drill assembly for implant surgery, characterized in that it consists of a single body by machining a martensitic stainless steel rod.
5. The method according to any one of claims 1 to 4,
The stopper is a guide drill assembly for implant surgery, characterized in that it consists of a single body by machining a titanium alloy rod.

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