KR101234296B1 - Drill for operating implant - Google Patents

Abstract

The present invention relates to a drill for implant surgery, and more particularly, is inserted into the alveolar bone while rotating along the axis of rotation, in the implant procedure drill for forming a hole for placement of the implant fixture in the alveolar bone,
The bag portion, the side cutting portion and the tip portion are sequentially arranged along the rotation axis direction, and the bag portion has a structure connected to the dental rotating mechanism, and the side cutting portion extends along the rotation axis direction to fracture the bone tissue in the alveolar bone. It comprises a land portion having a plurality of teeth, and a flute groove extending along the rotation axis direction to guide the bone tissue to discharge the bone tissue fractured by the land portion to the outside,
The tip is for an implant procedure drill having a polygonal pyramid shape.

Description

Drill for implant surgery

The present invention relates to a drill for implant treatment, and more particularly, to an implant treatment drill, which can easily and easily form a hole for implant treatment at a desired placement position even when the alveolar bone requiring the implant treatment is inclined or thin. will be.

Implants are originally meant to be a substitute for recovery when tissue is lost, but in dentistry, implants are made of artificial teeth. To replace the lost root (root), a root made of titanium or the like which does not have a rejection reaction to the human body is planted in the alveolar bone that has passed through the tooth, and then the tooth is restored by fixing the artificial tooth. In the case of general prosthetics or dentures, the surrounding teeth and bones are damaged over time, but the implants do not damage the surrounding dental tissues, and they have the advantage that they can be used semi-permanently because they have the same function or shape as natural teeth and do not cause tooth decay.

The implant procedure is completed by drilling a placement position using a predetermined drill, implanting the implant into the alveolar bone, fusion fusion to the bone, joining the abutment to the implant, and then applying the final prosthesis to the abutment.

These implants enhance the function of dentures, improve the aesthetics of dental prosthetic restorations, as well as dissipate excessive stress on surrounding supportive bone tissue, as well as single missing restorations. And also helps stabilize the dentition.

Specifically, the implant placement is important to secure a sufficient insertion space by using a drill in advance, the drill used is a lance drill (hole drill) to form a hole in the bone for easy initial drilling, and the marking formed by the lance drill Inserted around the groove is divided into a twist drill (Twist drill) to form a hole for placement. The lance drill can determine the bone density through drilling to improve the corrosion resistance and wear resistance by applying a tin coating on the outer surface. 1 and 2, the lance drill 100, the bag portion 110 is connected to the dental appliance, the body portion 120 extending in the rotation axis direction from the bag portion, and the body portion It is formed in the cutting portion 130 extending in the rotation axis direction from the sharp edge in the circumferential direction at equal intervals. The cutting edge 131 has a sharp shape in the direction of the rotation axis in order to accurately mark the desired position. The twist drill 200, the bag portion 210, the body portion 220 and the cutting portion 230 is formed with a cutting blade formed on the outer peripheral side. The cutting blade is formed along the direction of the axis of the cutting blade to dig into the alveolar bone to form a groove for placement.

In general, when the alveolar bone is flat in the procedure, it is possible to form a hole using only a lance drill, but as shown in FIG. 3, when the alveolar bone is inclined and thin, it is easy to form a hole in the alveolar bone with only the lance drill 100. I never do that. That is, in the process of forming the first hole in the alveolar bone, after placing the lance drill 100 in a direction perpendicular to the surface (see FIG. 3 (a)), the lance drill 100 is rotated to form a marking groove. (See FIG. 3 (b)), the drill drill for hole formation should be performed by standing the lance drill 100 in the direction in which the actual placement should be made. (FIG. 3 (c)) However, FIGS. Likewise, when the lance drill 100 is inserted between the thin alveolar bones with the lance drill 100 set up, since the sawtooth-shaped blade is not formed on the outer circumferential surface of the lance drill 100, the alveolar bone may collapse. There is concern.

Accordingly, as shown in FIG. 3 (d, e), a hole is formed in the portion where the marking groove is formed by the lance drill 100 by using a twist drill 200 having a sawtooth-shaped blade formed on the outer circumferential surface thereof. . At this time, since the twist drill 200 has a tooth-shaped blade formed on the outer circumferential surface of the twist drill 200, the twist drill 200 can be easily inserted without a great influence on the surrounding bone tissue.

On the other hand, although it may be considered to form a hole in the alveolar bone using a twist drill rather than a lance drill from the beginning, it is not appropriate to use the twist drill from the beginning. The reason is that in the case of the twist drill, the tip portion is not sharp and has a blunt shape, and thus, when the marking groove is not formed in the alveolar bone by the lance drill, the hole cannot be accurately formed in a desired position. In particular, when the twist drill is positioned on the inclined surface, the twist drill may easily move in the drilling process due to the shape of the tip of the twist drill.

Therefore, when the alveolar bone is inclined or thin, there is an inconvenience of using a lance drill and a twist drill together, which not only makes the overall treatment condition uncomfortable, but also increases the procedure cost as the procedure time is delayed. .

The present invention was created in order to solve the above-mentioned problems, and in more detail, it is possible to form the hole for implant treatment easily and conveniently even when the alveolar bone is inclined or thin by being able to mark and lateral cut the implantation position with a single drill. An object of the present invention is to provide a drill for implant treatment.

In the implant treatment drill of the present invention for achieving the above object is inserted into the alveolar bone while rotating along the rotation axis, in the implant procedure drill for forming a hole for placement of the implant fixture in the alveolar bone,

The bag, the side cutting part and the tip part are arranged in sequence along the rotation axis direction,

The bag portion,

Has a structure that is connected to the dental rotary mechanism,

The side cutting portion,

A land portion having a plurality of teeth extending along the rotation axis direction to fracture the bone tissue in the alveolar bone, and to guide the bone tissue to discharge to the outside the bone tissue extending along the rotation axis direction and fractured by the land portion to the outside Including flute groove,

The tip portion,

It is preferable to have a polygonal pyramid shape.

In the implant treatment drill,

It is preferable that the said tip part is a triangular pyramid or a square pyramid.

In the implant treatment drill,

It is preferable that the corner angle of the said tip part is 10 degrees-45 degrees.

In the implant treatment drill,

It is preferable that the length of the front-end | tip part in the rotating shaft direction is 4 mm or less.

In the implant treatment drill,

Preferably, the flute groove is provided with two to four at equal intervals along the circumferential direction of the side cutting portion.

In the implant treatment drill,

It is preferable that the vertical distance from each vertex of the teeth of the land portion to the valley is 1.0 mm or less.

In the implant treatment drill,

In the land portion of the side cutting portion,

It is preferable to include the smooth part which a tooth is not provided.

In the implant treatment drill,

It is preferable that a stopper portion having an outer diameter larger than the side cutting portion is provided between the bag portion and the side cutting portion.

In the implant treatment drill of the present invention for achieving the above object is inserted into the alveolar bone while rotating along the rotation axis, in the implant procedure drill for forming a hole for placement of the implant fixture in the alveolar bone,

The bag, the side cutting part and the tip part are arranged in sequence along the rotation axis direction,

The bag portion,

Has a structure that is connected to the dental rotary mechanism,

The side cutting portion,

A land portion having a plurality of teeth extending along the rotation axis direction to fracture the bone tissue in the alveolar bone, and to guide the bone tissue to discharge to the outside the bone tissue extending along the rotation axis direction and fractured by the land portion to the outside Including flute groove,

The tip portion,

It includes a plurality of corners having a sharp end and extending along the rotation axis direction from the end, the corner angles, which are angles between the adjacent corners, may be 10 ° to 45 °.

In the implant treatment drill,

The length of the tip portion in the rotation axis direction may be 4 mm or less.

The drill for implant surgery according to the present invention has the advantage of overcoming the limitations of existing lance drills or twist drills, even when the alveolar bone is inclined or thin, forming an implant procedure hole in the alveolar bone with only a single drill.

In particular, the convenience of the procedure is made by forming a hole at a desired position using an implant treatment drill without additional work such as separate alveolar bone flattening operation, removal of septal bone, and movement of the position of the hole. In this case, the implant can be placed where the operator wants to take the form of the final prosthesis as the operator thinks, thereby increasing the long-term stability of the prosthesis.

1 is a view showing a drill for an implant procedure according to the prior art.
Figure 2 is a front view of Figure 1;
3 is a view showing a groove forming process using the drill for implant treatment of FIG.
Figure 4 is a view showing a drill for the implant procedure according to an embodiment of the present invention.
Fig. 5 is a front view of Fig. 4; Fig.
6 is a perspective view of FIG. 4.
Figure 7 is a view showing the formation of a hole for the implant procedure in the alveolar bone using FIG.
8 is a view showing a drill for implant surgery according to another embodiment of the present invention.
9 is a perspective view of FIG. 8;
10 is a view showing a drill for implant surgery according to another embodiment of the present invention.

Hereinafter, a drill for an implant procedure according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Drill for implant surgery according to an embodiment of the present invention is a drill for forming a hole for insertion of the implant fixture in the alveolar bone while rotating along the axis of rotation.

Such an implant treatment drill 10 includes a bag portion 20, a side cutting portion 30, and a tip portion 40, and the bag portion 20, the side cutting portion 30, and the tip portion 40 are sequentially formed. Are arranged along the axial direction.

The bag portion 20 has a structure connected to the dental rotary mechanism, and forms an upper portion of the drill 10 for the implant procedure. The bag 20 has a shape that can be inserted into a motor for automatically rotating the implant 10 for an implant procedure or a driver for manually rotating the implant 10.

The side cutting portion 30 extends from the bag portion 20 and includes a land portion 31 and a flute groove 32.

The land portion 31 has a plurality of teeth 31a extending along the rotation axis direction in order to fracture bone tissue in the alveolar bone. The tooth 31a is preferably a height (e.g., the shortest distance from the vertex to the bone in the direction perpendicular to the rotation axis; h1) that is a vertical distance from each vertex to the valley, and more preferably 0.1 mm or less. It is good to be ~ 0.8 mm. If the height of the teeth 31a is too low, it is not easy to be easily inserted into the alveolar bone. If the height of the teeth 31a is too high, the torque for drilling should be large and damage to the periphery of the inserted alveolar bone may occur. Is not desirable.

 Three such land portions 31 are formed at equal intervals along the circumferential direction, and each land portion 31 may extend along the rotation axis direction in a spiral manner, but is not limited thereto. It can be changed and formed in the side cutting portion 30, the number can be expanded and reduced as needed.

The flute groove 32 is disposed between the adjacent land portions 31 and formed to be inwardly facing the rotation axis. The flute groove 32 extends along the rotation axis direction and guides the broken bone tissue to be discharged to the outside of the broken bone tissue by the land portion 31. Three flute grooves 32 are formed at equal intervals along the circumferential direction, but are not limited thereto, and the flute groove 32 may be formed on the side cutting part 30 by a person skilled in the art by changing the design if necessary. It is possible to increase or decrease.

The tip portion 40 is formed to extend along the rotation axis direction from the side cutting portion 30 to form an end portion of the drill 10 for the implant procedure. The tip portion 40 has a pointed end shape and the flat surface 42 extends along the circumferential direction. Where each face 42 meets a straight edge 41 is formed so that the tip portion 40 has a polygonal pyramid shape as a whole. In the present exemplary embodiment, the tip portion 40 is illustrated as having a triangular pyramid shape, but is not limited thereto.

The angle of the corner angle θ between the corners at the point where the face 42 and the face 42 meet each other at the tip portion 40 may be 10 to 45 °, and preferably 15 to 30 °. If the corner angle θ is too small, it easily breaks into the drill 10 for implant treatment, which is not preferable in terms of overall durability. If the corner angle is too large, a marking groove of sufficient depth is not formed on the surface of the inclined alveolar bone. It is not desirable to do so.

The length l1 of the tip portion 40 in the rotation axis direction may be 4 mm or less, and preferably 1 to 3 mm. If the length l1 of the tip portion 40 is too short, not only is it difficult to form a groove of sufficient depth on the surface of the alveolar bone, but there is a fear that the overall durability is degraded, and when the length of the tip portion 40 is too long, the teeth 31a are formed. Since the tip portion 40 is not deeply inserted into the alveolar bone, the load applied to the alveolar bone becomes large, and in the case of the thin alveolar bone, the alveolar bone may collapse before the side cutting portion 30 is inserted. .

The implant 10 drill according to an embodiment of the present invention operates as follows.

First, referring to FIG. 7, the drill 10 for the implant procedure is disposed perpendicular to the surface of the alveolar bone as a hole formed position. (See FIG. 7 (a)).

Thereafter, while rotating the drill for the implant procedure (10) to form a marking groove of a predetermined depth on the surface of the alveolar bone. (See FIG. 7 (b)).

Thereafter, the implant 10 is rotated to rotate to the position where the hole for the fixture is to be formed by rotating the drill 10. (See FIG. 7 (c)).

Subsequently, the hole for inserting the implant fixture is formed in the alveolar bone while digging into the alveolar bone while rotating the implant 10 for drilling the implant (see FIG. 7 (d)).

At this time, in Figure 7 (b) has a polygonal pyramid shape having a pointed tip end portion 40 serves to form a groove on the surface of the alveolar bone, in Figure 7 (d) once the groove is formed to some extent As the side cutting portion 30 is inserted in the fixed state, the teeth 31a of the side cutting portion 30 are broken around the alveolar bone so that the drill 10 can be inserted into the alveolar bone. On the other hand, the bone tissue of the alveolar bone fractured from the side cutting portion 30 is to escape to the upper side along the flute groove 32 disposed between the land portion (31).

The drill for implant surgery according to one embodiment of the present invention has the following effects.

First, in the prior art, in order to form a hole in the slanted alveolar bone inclined by using an implant treatment drill, the land drill 100 is a groove for marking in the state of preparing the lance drill 100 and twist drill 200, respectively. It is formed in the alveolar bone and then formed into a groove in which the fixture can be inserted while being inserted into the groove marked by the lance drill 100 using the twist drill 200 separately provided, but as described above, It was inconvenient and cumbersome in that two drills 100 and 200 should be used.

On the contrary, in the present embodiment, as a single implant treatment drill 10, while forming a groove for marking in the alveolar bone, it is possible to proceed to form a hole in the alveolar bone through the groove, thereby simplifying the procedure and saving overall procedure time. It will be helpful.

In particular, the implant 10 drill 10 is because the corner angle of the tip portion 40 is small, so that the marking can be easily performed without slipping against the inclined surface, and the land portion 31 of the side cutting portion 30 has a sawtooth ( 31a) has the advantage that it can be easily inserted into the alveolar bone.

The drill for implant surgery according to one embodiment of the present invention may be modified as follows.

First, as shown in FIGS. 8 and 9, the teeth 31a are not extended to the side cutting part 30 along the rotation axis direction, but a part of the side cutting parts 30 is formed by the teeth 31a. A portion 33 that is not formed may also be provided. For example, a tooth 31a is formed at a portion of the side cutting portion 30 at the tip portion 40 side so that the drill 10 can be easily inserted into the alveolar bone, and at the portion 33 adjacent to the bag 20. Since the teeth 31a are not formed, the bone tissue, once broken from the portion where the teeth 31a are formed, can be easily taken out to the outside along the flute groove 32.

In addition, the stopper 50 may be formed as shown in FIG. 10. The stopper 50 is disposed between the bag portion 20 and the side cutting portion 30, and is formed to have an outer diameter larger than that of the side cutting portion 30. As such, when the stopper 50 is formed, the drill 10 is not inserted beyond the desired depth, thereby increasing the precision. That is, when the drill 10 is inserted, the stopper 50 abuts against the alveolar bone so that the drill 10 is no longer inserted into the alveolar bone so that a hole having a desired depth can be formed by the operator.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, .

10 ... implant drill 20 ... sack
30 Side cutting 31 Land part
31a ... tooth 32 ... flute groove
40.Front end 41 ... Corner
42 ... cotton 50 ... stopper

Claims (11)

In the implant for drilling the implant is inserted into the alveolar bone while rotating along the axis of rotation, to form a hole for placement of the implant fixture in the alveolar bone,
The bag, the side cutting part and the tip part are arranged in sequence along the rotation axis direction,
The bag portion,
Has a structure that is connected to the dental rotary mechanism,
The side cutting portion,
A land portion having a plurality of teeth extending along the rotation axis direction to fracture the bone tissue in the alveolar bone, and to guide the bone tissue to discharge to the outside the bone tissue extending along the rotation axis direction and fractured by the land portion to the outside Including flute groove,
Wherein,
Drill for implant treatment, characterized in that it has a polygonal pyramid shape is provided with a single vertex at the tip to make point contact with the surface of the alveolar bone. The method of claim 1,
The tip portion is an implant treatment drill, characterized in that the triangular pyramid or square pyramid. The method according to claim 1 or 2,
The corner angle of the tip portion, the implant for drill, characterized in that 10 ° ~ 45 °. The method according to claim 1 or 2,
The length of the tip end portion in the direction of the rotation axis is an implant treatment drill, characterized in that 1 ~ 4mm. The method of claim 1,
The flute groove is an implant treatment drill, characterized in that provided with two to four at equal intervals along the circumferential direction of the side cutting portion. The method of claim 1,
Drill for implant treatment, characterized in that the vertical distance from each vertex of the teeth of the land portion to the bone is 0.1 ~ 1.0mm. The method of claim 1,
In the land portion of the side cutting portion,
Drill for implant treatment, characterized in that it includes a smooth portion that is not provided with teeth. The method of claim 1,
An implant treatment drill, characterized in that a stopper portion having an outer diameter larger than that of the side cutting portion is provided between the bag portion and the side cutting portion. In the implant for drilling the implant is inserted into the alveolar bone while rotating along the axis of rotation, to form a hole for placement of the implant fixture in the alveolar bone,
The bag, the side cutting part and the tip part are arranged in sequence along the rotation axis direction,
The bag portion,
Has a structure that is connected to the dental rotary mechanism,
The side cutting portion,
A land portion having a plurality of teeth extending along the rotation axis direction to fracture the bone tissue in the alveolar bone, and to guide the bone tissue to discharge to the outside the bone tissue extending along the rotation axis direction and fractured by the land portion to the outside Including flute groove,
Wherein,
And a plurality of edges having a sharp end and extending along the rotation axis direction from the ends thereof, wherein the corner angles between the adjacent edges are 10 ° to 45 °. 10. The method of claim 9,
The length of the tip end portion in the direction of the rotation axis is an implant treatment drill, characterized in that 1 ~ 4mm. 10. The method of claim 9,
The corner is a drill for implant treatment, characterized in that the straight line.

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