KR100946344B1 - An Implant Drill - Google Patents

Abstract

The present invention relates to a dental implant drill, and more particularly, to an implant drill that can be drilled from a small diameter to a large diameter without changing the drill blade when drilling the alveolar bone to easily operate the implant.

In the implant drill of the present invention for achieving the above object, a cutting groove is formed on the outer peripheral surface of the cylindrical body, a central axis having a shank portion is provided in the implant drill mounted on a dental general handpiece, the cutting groove is formed cylindrical The diameter of the body is increased in stages, the entire body is characterized in that the multi-stage shape.

Implants, Implant Drills, Pilot Drills

Description

Implant Drills {An Implant Drill}

The present invention relates to a dental implant drill, and more particularly, to an implant drill that can be drilled from a small diameter to a large diameter without changing the drill blade when drilling the alveolar bone to easily operate the implant.

In recent years, dental implants are rapidly being used to implant artificial teeth.

In this implantation technique, the implant is drilled through the alveolar bone to implant the implant, and the artificial tooth is firmly fixed to the alveolar bone by fixing the artificial tooth to the implant.

However, the drilling of the alveolar bone in such an implant technique is a very cumbersome operation, usually performed in the following steps.

First, use a small diameter drill to drill down to the middle depth. If the drilling direction is correct by checking in the middle, drill it completely to the depth required for implant placement.

Next, the drill blade is replaced to prepare the drilling of the large diameter drill by using a pilot drill. The pilot drill has a small diameter at the beginning of the insertion, but gradually increases in diameter to drill a small depth. It serves to fit the drill into the drilled part.

Next, the drill blade is replaced again, and the drill diameter is drilled again by using a large-diameter drill to enlarge the drill diameter to the extent that the implant can be placed.

And if the implant of the large diameter is to be implanted, it is necessary to replace it again with the corresponding large diameter drill to increase the drilling diameter once more.

At this time, it is not possible to drill using a large diameter drill from the beginning, and the continuous replacement of the drill blade from a small diameter to a large diameter like this is a serious problem that cannot be reversed if the drilling direction is wrong when drilling using a large diameter drill from the beginning. Because it happens.

Therefore, in order to properly secure the direction of drilling, it was necessary to replace the drill blades several times, and the implant procedure was very cumbersome due to the replacement of the drill blades.

On the other hand, alveolar bone powder secured during the drilling process is re-injected during implant implantation to fix the implant due to hardening of the bone powder, so it is necessary and if necessary, a separate expensive bone powder should be used. In order to prevent the loss of bone powder, the replacement of the drill blades remains a bigger problem because they are largely lost during the continuous blade replacement.

The present invention has been made in view of the above situation, when drilling the alveolar bone can be drilled once from a small diameter to a large diameter without replacing the drill blade to easily implant the implant, as well as in the process of drilling The purpose is to provide an implant drill that can be secured sufficiently without fear of loss of autologous bone powder.

In the implant drill of the present invention for achieving the above object, a cutting groove is formed on the outer peripheral surface of the cylindrical body, a central axis having a shank portion is provided in the implant drill mounted on a dental general handpiece, the cutting groove is formed cylindrical The diameter of the body is increased in stages, the entire body is characterized in that the multi-stage shape.

At this time, the portion in which the diameter of the body increases is characterized in that the pilot drill blade structure.

At this time, the cutting groove is characterized in that the depth and width increases toward the shank portion.

And, the cutting groove is characterized in that the two penetrating spiral between the cutting grooves facing each other.

The present invention as described above can be drilled from small diameter to large diameter without replacing the drill blade when drilling the alveolar bone to easily implant the implant, as well as secure enough without fear of loss of autologous bone powder during the drilling process On the other hand, the alveolar bone is naturally compressed in the drilling direction during the drilling process, there is an effect that does not require a separate bone compression (condensing).

In addition, since the alveolar bone is perforated in the shape of a multi-stage by the implant drill of the present invention, in the process of implantation of a simple cylindrical shape, the deep portion is naturally compressed in the transverse direction to obtain the effect of additional bone compression (condensing). Will be.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the implant drill D according to the present invention is largely divided into a connection part 10 and a drill part 20.

The connecting portion 10 is provided with a central axis 12 having the shank portion 11 to fix the implant drill (D) to the dental handpiece, having an outer diameter larger than the diameter of the body portion 20 A circular catch frame 13 is provided to prevent the drill blade from being drilled to too wide a depth.

Referring to FIG. 2, the drill part 20 has a circular cross section having a smaller diameter than the hook frame 13, and the circular diameter is from a small diameter (a) to a large diameter (b) and a large diameter (c). Step by step increase the whole body consists of a multi-stage cylindrical.

At this time, the body is provided with a cutting groove 21 as a whole to allow drilling of the alveolar bone B in accordance with the rotation of the drill portion 20, wherein the cutting groove 21 is caught from the end of the body portion 20 ( 13) it is preferable that the bone powder (BP) separated from the alveolar bone B can be moved along the cutting groove 21 to be gathered at the rear end where the hook frame 13 is located.

More preferably, the cutting groove 21 is to increase the depth and width toward the rear end direction in which the hook frame 13 is located so that the bone powder (BP) bone powder collecting groove 22 More cumulative

On the other hand, in the multi-stage drill portion 20, the diameter increasing portion from the small diameter (a) to the large diameter (b), and the large diameter (b) to the large diameter (c) has the same structure as the pilot drill It is desirable that the diameter of the perforated portion is naturally expanded by an already inserted drill blade at an acute angle at a predetermined angle in the plane perpendicular to the drilling direction.

Looking at the process of drilling the alveolar bone (B) through the present invention as described above in detail.

First, the shank portion 11 of the connecting portion 10 is mounted on the dental handpiece driving unit so that the entire implant drill D can rotate when the power is applied, as shown in FIG. ) Make the tip close to the treatment area.

In the above state, when the operator applies force, the tip of the drill part 20 is brought into close contact with the treatment part, and then the power is applied to the handpiece to rotate the implant drill D. First, the drill blade having a small diameter (a) Alveolar bone (B) will be perforated.

If it is determined that the direction of the perforation is correct in the process of sufficiently inserting the drill blade having the small diameter (a), the operator further applies a force to the cutting groove 21 of the portion increasing from the small diameter (a) to the large diameter (b). The diameter of this naturally perforated part is expanded, and the drilling of the large diameter (b) is performed sequentially to finish the drilling of the large diameter (b) to the alveolar bone (B). The perforated portion is expanded as shown in FIG. 4.

As such, when the drilling is completed using the drill according to the present invention, the bone powder (BP) separated from the alveolar bone (B) during the drilling process is naturally pushed back and collected in the bone powder collecting groove 22 at the rear end, and the drill (D). After removing from the alveolar bone (B) by separating the collected bone powder (BP) in the bone powder collection groove 22 it is possible to naturally collect the bone powder (BP).

The implanted alveolar bone B may be selectively implanted after undergoing pretapping. In this case, it is also possible to trim the perforated part using a separate drill blade.

At this time, the drill according to the present invention is further formed through the drill body in the longitudinal direction long through the drill body irrespective of the cutting groove, as shown in Figure 5, the heat generated during the drilling process is easily released and bone powder It is also possible to accumulate in this through groove.

On the other hand, the implant drill according to the present invention, regardless of the number of multi-stage, it is obvious that the larger the number of the multi-stage, the larger the desired drilling diameter, but if only the large diameter of the large diameter after the small diameter and only two stages of large diameter You will only have a structure.

In other words, the implant drill according to the present invention is selected and used in accordance with the size of the implant to be placed in a variety of forms, such as for the second stage large diameter, the third stage large diameter, the fourth stage oversized diameter, starting from a small diameter It is possible to.

1 is a perspective view of an implant drill according to the present invention in a three-stage embodiment.

2 is a side view of an implant drill according to the invention in a three stage embodiment.

3 is a use state showing the initial drilling process of the implant drill according to the present invention of the three-stage embodiment.

4 is a use state showing the subsequent drilling process of the implant drill according to the present invention of the three-stage embodiment.

5 is a side view of an implant drill according to the present invention of an embodiment having a through groove.

<Description of the symbols for the main parts of the drawings>

D: Implant Drill

B: Alveolar bone B.P: Bone powder

10: connection part 11: shank part

12: center axis 13: hang frame

20: drill portion 21: cutting groove

22: bone meal collecting groove 23: through groove

a: small diameter

b: large diameter

c: invitation size

Claims (4)

An implant drill in which a cutting groove is formed on an outer circumferential surface of a cylindrical body and a central shaft having a shank portion is provided and mounted on a general dental handpiece. The diameter of the cylindrical body in which the cutting groove is formed is increased in stages, so that the entire body is configured in a multistage shape. Implant drill, characterized in that the through groove is provided in the body along the longitudinal direction The method according to claim 1, Implant drill, characterized in that the increase in the diameter of the body is a pilot drill blade structure. The method according to claim 2, The cutting groove is an implant drill, characterized in that the depth and width increases toward the shank portion. delete

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