KR101076379B1 - Auto-stop drill for implant surgery - Google Patents

Abstract

An implant treatment drill used to form a hole in the maxillary sinus having a mucosa therein, the drill being connected to an external driving source and having a protruding pin formed on an outer circumferential surface; A power transmission cap having a recess into which the protruding pin can be inserted; A main drill coupled to the power transmission cap and capable of rotating with the secondary drill through the power transmission cap; During the drilling, the tip of the sub drill does not protrude forward than the tip of the main drill. At the moment of drilling, the tip of the sub drill protrudes forward than the tip of the main drill while being compressed by the pressing force applied by the operator. A spring for urging the sub drill and the main drill in opposite directions to each other; The cutting edge of the main drill has a shape that narrows toward the tip side so that the cutting edge of the main drill does not protrude toward the mucosa, even when the maxilla is perforated in a circular shape, and is applied to the pressing force applied by the operator. Only the secondary drill protrudes toward the mucosa so that the protruding pin is separated from the concave portion so that the rotational force of the secondary drill is not transmitted to the main drill so that the main drill is automatically stopped. .

Implant, Drill, Drill, Main Drill, Secondary Drill, Automatic Stop

Description

Automatic Stop Drill for Implant Procedures {AUTO-STOP DRILL FOR IMPLANT SURGERY}

The present invention relates to a drill used in an implant procedure used to recover a patient's lost tooth, and more particularly, an automatic stop drill that can be stopped at the same time as the maxillary sinus puncture and the mucous membrane inside the maxillary sinus during damage to the maxillary sinus. It is about.

In the skull of the human body, there are empty spaces such as maxillary sinus, frontal sinus and sphenoid sinus that play a role of weight reduction and sound resonance. Membrane is present between this empty space and the skull. The presence of such mucosa acts as a cause of difficulty in the procedure when approaching the maxillary sinus and placing the implant.

Problems during the procedure occur when a hole is formed to implant a bone into an empty space of the maxillary sinus. That is, the maxillary sinus mucosa can be easily torn when the drill's blade touches the mucosa or the surgeon exerts excessive force during the rotation of the drill during the drilling of the maxillary sinus. Because tearing of the mucosa can cause problems such as infection of the maxillary sinus, the operator should always be careful to avoid tearing as much as possible.

During the drilling operation by rotating the drill in the oral cavity, the operator mostly judges the perforation of the maxillary sinus by the operator's fingertips. The thickness of the maxilla is confirmed by X-ray or CT secondly, but the depth of the maxillary sinus is not flat and there are various types of septum. Therefore, the surgeon is under pressure that the mucosa may be perforated. Done.

In order to reduce the burden on the operator, conventionally, the end of the drill is blunted so that the mucous membrane does not stick even when the rotating drill blade touches the mucosa, or a small particle of diamond grit is attached to the tool so that the bone A drill to squeeze out is proposed.

However, such conventional drills require a stopper, which is an ancillary mechanism, or a drill bit is not sharply formed in order to avoid tearing of the mucosa.

And the ejection and cutting of the cut bone chip is not made smoothly, and the bone part being cut is partially heated by friction heat with the drill, or the operator exerts excessive force. The problem is that there is a risk of perforating the mucous membranes.

The present invention for solving the conventional problems, the operator can intuitively check the perforation of the maxillary sinus during the operation of the maxillary sinus and do not damage the mucous membrane inside the maxillary sinus, the automatic stop drill that can be stopped at the same time as the perforation of the maxillary sinus It is to provide.

According to an aspect of the present invention for achieving the above object, a drill used in the implant procedure, and a secondary drill that can be rotated connected to an external drive source; A main drill rotatable with the secondary drill; A clutch mechanism for limiting transmission of rotational force from the sub-drill to the main drill when the object on which the drilling operation is performed is drilled; It is provided with an automatic stop drill comprising a.

The automatic stop drill preferably includes a power transmission cap that is fastened to the main drill to allow the main drill to rotate with the secondary drill.

The secondary drill has a cylindrical secondary drill body, a connection portion formed at one end of the secondary drill body to be connected to the external drive source to receive power, and a secondary cutting edge formed at the other end of the secondary drill body for cutting. It is preferable to include.

The main drill has a main cutting body formed at the distal end of the main drill body for cutting a bone together with a hollow main drill body having an empty inside to surround the outside of the sub drill and a sub cutting edge formed in the sub drill. It is preferable to include the blade.

The clutch mechanism includes a spring for urging the sub drill and the main drill in opposite directions, at least one protruding pin protruding from the sub drill, and an inner circumferential surface of the power transmission cap fastened to the main drill. At least one recess is formed to be concave, wherein the projecting pin is preferably able to be maintained in the recess by the pressing force of the spring.

A female screw portion is formed in the main drill body of the main drill, and a male screw portion is formed in the power transmission cap, and the power transmission cap is preferably fastened to the main drill by screwing the female screw portion and the male screw portion.

The secondary cutting edges are preferably arranged in a circle with at least two blades spaced apart at regular angular intervals.

The main cutting edge is formed to be thicker than the thickness of the main drill body, preferably projecting inward from the inner circumferential surface of the main drill body and outward from the outer circumferential surface of the main drill body, respectively.

The main cutting edge has three or more discharge grooves, and is preferably arranged in an annular shape to have at least two blades in one discharge groove.

It is preferable that the cross section of the tip end of each blade included in the main cutting edge and arranged in an annular shape has a triangular shape in which the outer inclined surface has a slope larger than the inner inclined surface.

The screw direction of the female screw portion and the male screw portion is preferably the same direction as the rotation direction during the operation of the automatic stop drill.

Preferably, the main cutting edge of the main drill includes a larger number of blades than the sub cutting edge of the sub drill.

According to another aspect of the present invention for achieving the above object, as an implant procedure drill used to form a hole in the maxillary sinus having a mucous membrane therein, it is connected to an external drive source can be rotated and formed on the outer surface A secondary drill having a protruding pin; A power transmission cap having a recess into which the protruding pin can be inserted; A main drill coupled to the power transmission cap and capable of rotating with the secondary drill through the power transmission cap; During the drilling, the tip of the sub drill does not protrude forward than the tip of the main drill. At the moment of drilling, the tip of the sub drill protrudes forward than the tip of the main drill while being compressed by the pressing force applied by the operator. A spring for urging the sub drill and the main drill in opposite directions to each other; The cutting edge of the main drill has a shape that narrows toward the tip side so that the cutting edge of the main drill does not protrude toward the mucosa, even when the maxilla is perforated in a circular shape, and is applied to the pressing force applied by the operator. Only the secondary drill protrudes toward the mucosa so that the protruding pin is separated from the concave portion so that the rotational force of the secondary drill is not transmitted to the main drill so that the main drill is automatically stopped. .

The cutting edge of the secondary drill has a lower cutting force than the cutting edge of the main drill, and at the moment when the maxilla is drilled in a circular shape by the main drill, a disk-shaped bone fragment is placed in front of the secondary drill and the cutting edge of the secondary drill. It is preferable to remain between the mucosa and the secondary drill does not directly contact the mucosa.

According to the present invention as described above, it is possible to provide an automatic stop drill including an external main drill and an internal secondary drill and the rotation of the main drill can be stopped at the same time as the drilling of the maxillary sinus.

According to the automatic stop drill of the present invention, the operator during the maxillary sinus procedure can intuitively check the perforation of the maxillary sinus, thereby reducing the burden on the procedure.

In addition, according to the automatic stop drill of the present invention, it is possible to prevent damage to the mucosa by preventing a part of the bone to be cut at the moment when the maxillary sinus is punctured in the shape of a disc to prevent direct contact with the mucosa of the secondary drill that continues to rotate. Will be.

In addition, according to the automatic stop drill of the present invention, the cutting edge of the main drill is projected radially from the outer peripheral surface of the main drill to form a space between the bone to be cut and the outer peripheral surface of the main drill to smoothly discharge the cut bone fragments In addition, the cutting edge of the main drill does not need to be blunt to prevent mucosal damage, thereby reducing the time and effort required for the procedure and reducing the pain and burden of the patient.

EMBODIMENT OF THE INVENTION Hereinafter, the automatic stop drill for implant procedures which concerns on preferable embodiment of this invention is demonstrated in detail with reference to drawings.

1 and 2 are a perspective view and a cross-sectional view of the automatic stop drill according to a preferred embodiment of the present invention, Figures 3 to 5 a main drill included in the automatic stop drill according to a preferred embodiment of the present invention, A perspective view of the secondary drill and power transmission cap is shown, respectively. 6 is a view for explaining the operation of the automatic stop drill according to a preferred embodiment of the present invention.

As shown in Figure 1 and 2, the automatic stop drill for the implant procedure of the present invention, the secondary drill 10 that can be rotated in connection with an external drive source such as a motor, and the outside of the secondary drill 10 The main drill 20, which can be rotated together with the secondary drill 10, and the rotational force of the secondary drill 10, are transmitted to the main drill 20 so that the main drill 20 can rotate together with the secondary drill 10. It includes a power transmission cap 30 to enable.

As shown in FIGS. 1, 2 and 4, the secondary drill 10 includes an approximately cylindrical secondary drill body 11 and one end of the secondary drill body 11 connected to an external drive source to receive power. The connection part 12 which is formed in the and the secondary cutting edge 13 which is formed in the other end of the secondary drill body 11 to cut the bone.

At least one protruding pin 14 is formed in the middle of the sub drill body 11, and the sub drill 10 can transmit rotational force to the main drill 20 by the protruding pin 14. At the other end on which the secondary cutting edge 13 of the secondary drill 10 is formed, a stepped portion 15 formed by reducing the diameter of the secondary drill body 11 is formed. Further, an annular projection 16 protruding in a circle is formed in the sub drill body 11 on the side of the sub cutting edge 13 from the protruding pin 14.

As shown in FIGS. 1 to 3, the main drill 20 is a hollow main drill body 21 having an empty inside to surround the outside of the sub drill 10, and a combination of the sub drill 10. The main drill body for cutting the bone together with the female threaded portion 22 formed on one inner circumferential surface of the main drill body 21 and the secondary cutting edge 13 so that the power transmission cap 30 interposed at the time may be fastened. It comprises a main cutting edge 23 formed at the other end of the 21.

The main cutting edge 23 is formed to be thicker than the thickness of the main drill body 21, and protrudes inward from the inner circumferential surface of the main drill body 21 and outward from the outer circumferential surface of the main drill body 21, respectively. The main cutting edge 23 protruding inward from the inner circumferential surface of the main drill body 21 forms a first internal step 24.

In addition, a second internal step 25 is formed on the inner circumferential surface of the main drill body 21 to cooperate with the annular projection 16 of the sub-drill 10 to interpose the spring 40 therein. have.

The spring 40 is a coil spring, in which the secondary cutting edge 13 and the main cutting edge 23 can be located on substantially the same plane by the elastic force of the spring 40. At the same time, the spring 40 can maintain the connection state between the sub drill 10 and the main drill 20 through the power transmission cap 30 as described below.

As shown in Figs. 1, 2 and 5, the power transmission cap 30 includes a cap body 31 having a through hole 32 formed to penetrate the sub drill 10, and a main drill. The cap body (33) is formed on the outer circumferential surface of the cap body (31) and the protruding pin (14) of the sub drill (10) to be screwed into the female screw portion (22) of the cap body ( And a concave portion 34 formed on the inner circumferential surface 31.

Hereinafter, the operation of the automatic stop drill of the present invention configured as described above with reference to Figures 6 (a) and (b).

As shown in Fig. 2 and 6 (a), the automatic stop drill of the present invention is the secondary cutting edge 13 and the main cutting edge 23 by the spring 40 during the normal or bone cutting operation. It is configured to be located on approximately the same plane.

At this time, one end of the spring 40 is in contact with the annular projection 16 of the secondary drill 10, and the other end of the spring 40 is in contact with the second internal step 25 of the main drill 20. Accordingly, the sub drill 10 and the main drill 20 are pressed in opposite directions by the pressing force of the spring 40.

However, since the protruding pin 14 of the secondary drill 10 is inserted into the recess 34 of the power transmission cap 30 to limit further movement, the main drill 20 is removed from the secondary drill 10. Departure can be prevented. In addition, the main drill 20 can thus rotate together when the sub drill 10 rotates.

As described above, since the main cutting edge 23 protrudes radially outwardly of the main drill body 21, the hole formed by the main cutting edge 23 has a diameter larger than that of the main drill body 21. . Therefore, as shown in FIG. 6A, bone fragments broken during the bone cutting operation may be smoothly discharged to the outside through a space existing between the outer circumferential surface of the main drill 20 and the inner circumferential surface of the cut bone. have.

As shown in Fig. 2 and 6, the cross section of the tip of each blade included in the main cutting edge 23 and arranged in an annular shape is formed to have a substantially triangular shape, the outer inclined surface has a slope larger than the inner inclined surface . Between each blade there is formed a flute (Flute) through which the cut pieces of bone can be discharged. The main cutting edge 23 has at least three discharge grooves, and is preferably made to have two or more blades in one discharge groove.

In addition, each of the edges included in the secondary cutting edge 13 and arranged in an annular shape is formed of at least two or more, and each of the edges is spaced apart from each other at a constant angular interval. Accordingly, the center of gravity of the secondary cutting edge 13 may be coincident with the center of rotation when the secondary drill 10 rotates, so that eccentricity or vibration does not occur. Discharge grooves through which the cut bone fragments are discharged are also formed between the respective edges of the secondary cutting edge 13.

As shown in Figs. 1 to 4, the sub cutting edge 13 has a smaller number of blades and a smaller inclination angle than the main cutting edge 23. Accordingly, at the moment when the maxillary sinus is punctured as described later with reference to FIG. 6B, circular drilling is performed by the main cutting edge 23 before the sub cutting edge 13, and the sub cutting edge 13 is performed. In front of the) is approximately a disk (Disk) bone fragment (D) remains.

In addition, the sub drill 10 continues to be pressurized in the puncturing direction by the pressure applied by the operator during the procedure, and the sub drill 10 is in a state of being subjected to resistance of the bone to be cut. However, since the resistance to the sub-drill 10 disappears at the moment of circular drilling by the main cutting edge 23, the sub-drill 10 momentarily protrudes forward while pressing the disc-shaped bone fragments D. do.

Since the bone fragment D exists between the sub cutting edge 13 and the mucosa M of the sub-drill 10, the sub cutting edge 13 does not directly contact the mucosa M, so that the mucosa M is Not damaged.

On the other hand, the main cutting edge 23 of the main drill 20 at the moment of drilling, since the outer inclined surface is being resisted by the bone B, the main drill 20 moves forward together with the sub-drill 10. can not do.

As such, when the sub drill 10 is momentarily moved forward than the main drill 20, the protruding pins 14 of the sub drill 10 are recessed in the power transmission cap 30 while the spring 40 is compressed. It exits from 34 and the rotation of the main drill 20 is automatically stopped.

Movement of the secondary drill 10 may be limited by the step 15 contacting the first internal step 24 of the main drill 20.

The operator can recognize the perforation of the maxillary sinus by detecting the instantaneous advancement of the secondary drill 10 and the automatic stop of the main drill 20, thereby stopping the advancing of the drill and ending the drilling operation.

In FIG. 6B, for convenience of illustration, the auxiliary drill 10 exaggerates the length of the protrusion while pushing the mucosa M, but it is preferable that the protrusion length is actually designed to be about 0.5 to 4 mm. .

As described above, according to the present invention, the protruding pin 14 of the secondary drill 10, the recess 34 of the power transmission cap 30 coupled with the main drill 20, and the spring 40 It may function as a clutch means for transmitting or disconnecting power between the drill 10 and the main drill 20.

In addition, the inner diameter of the main cutting edge 23 and the outer diameter of the secondary cutting edge 13 preferably have the same dimensions so that the bone fragments generated during the drilling operation do not enter the inside of the drill. Similarly, the inner diameter of the through hole 32 of the power transmission cap 30 preferably has the same dimensions as the outer diameter of the secondary drill body 11.

In addition, the thread direction between the female threaded portion 22 of the main drill 20 and the male threaded portion 33 of the power transmission cap 30 is preferably the same as the rotational direction of the drill to prevent accidental loosening of the screw. . That is, the right screw is used if the drill rotates to the right during the procedure, the left screw is used if the drill rotates to the left.

As described above, the automatic stop drill for the maxillary sinus procedure according to the present invention has been described with reference to the illustrated drawings, but the present invention is not limited to the embodiments and drawings described above, and the present invention belongs to the claims. Of course, various modifications and variations can be made by those skilled in the art.

1 and 2 are a perspective view and a cross-sectional view of the automatic stop drill according to the present invention,

3 is a perspective view of the main drill included in the automatic stop drill according to the present invention;

4 is a perspective view of a secondary drill included in an automatic stop drill according to the present invention;

5 is a perspective view of a power transmission cap included in an automatic stop drill according to the present invention, and

6 is a view for explaining the operation of the automatic stop drill according to the present invention.

Description of the Related Art

10: part drill 11: part drill body

12 connection part 13 sub cutting edge

14: protruding pin 15: stepped portion

16: annular projection 20: main drill

21: main drill body 22: female thread

23: main cutting edge 24: first internal step

25: second internal step portion 30: power transmission cap

31 cap body 32 through-hole

33: male thread portion 34: recessed portion

40: spring B: goal

D: bone fragment (disc) M: mucosa

Claims (14)

It is a drill used in the implant procedure, A secondary drill which can be rotated in connection with an external drive source; A main drill rotatable with the secondary drill; A clutch mechanism for limiting transmission of rotational force from the secondary drill to the main drill when the object to which the drilling operation is performed is drilled; A power transmission cap fastened to the main drill to allow the main drill to rotate together with the sub drill; Automatic stop drill, characterized in that it comprises a. delete The method according to claim 1, The secondary drill has a cylindrical secondary drill body, a connection portion formed at one end of the secondary drill body to be connected to the external drive source to receive power, and a secondary cutting edge formed at the other end of the secondary drill body for cutting. Automatic stop drill, characterized in that it comprises a. The method according to claim 1, The main drill has a main cutting body formed at the distal end of the main drill body for cutting a bone together with a hollow main drill body having an empty inside to surround the outside of the sub drill and a sub cutting edge formed in the sub drill. Automatic stop drill characterized by including a blade. The method according to claim 1, The clutch mechanism includes a spring for urging the sub drill and the main drill in opposite directions, at least one protruding pin protruding from the sub drill, and an inner circumferential surface of the power transmission cap fastened to the main drill. At least one recess formed concave, And the protruding pin can be held in the recess by the pressing force of the spring. The method according to claim 1, A female screw portion is formed in the main drill body of the main drill, and a male screw portion is formed in the power transmission cap, and the power transmission cap is fastened to the main drill by screwing the female screw portion and the male screw portion. Stop drill. The method of claim 3, The secondary cutting edge is an automatic stop drill, characterized in that the at least two blades are arranged in a circle spaced apart at regular angular intervals. The method according to claim 4, The main cutting edge is formed thicker than the thickness of the main drill body, it is projected inward from the inner circumferential surface of the main drill body and outward from the outer circumferential surface of the main drill body, respectively. The method according to claim 4, The main cutting edge has three or more discharge grooves, the automatic stop drill, characterized in that arranged in an annular so as to have at least two blades in one discharge groove. The method according to claim 4, The end face of each of the blades included in the main cutting edge arranged in an annular shape is an automatic stop drill, characterized in that the outer inclined surface is a triangular shape having a slope larger than the inner inclined surface. The method according to claim 6, The female screw thread and the male screw thread direction of the automatic stop drill, characterized in that the same direction as the rotation direction during the operation of the automatic stop drill. The method according to claim 1, And the main cutting edge of the main drill includes a greater number of blades than the sub cutting edge of the sub drill. An implant treatment drill used to form a hole in the maxillary sinus where mucous membranes are present, A secondary drill connected to an external drive source and rotatable, the secondary drill having a protruding pin formed on an outer circumferential surface thereof; A power transmission cap having a recess into which the protruding pin can be inserted; A main drill coupled to the power transmission cap and capable of rotating with the secondary drill through the power transmission cap; During the drilling, the tip of the sub drill does not protrude forward than the tip of the main drill. At the moment of drilling, the tip of the sub drill protrudes forward than the tip of the main drill while being compressed by the pressing force applied by the operator. A spring for urging the sub drill and the main drill in opposite directions to each other; Including; The cutting edge of the main drill has a shape that becomes narrower toward the tip side, so that the cutting edge of the main drill does not protrude toward the mucosa, even when the maxilla is perforated in a circular shape, but only by the pressing force applied by the operator. And the protruding pin is separated from the concave portion by protruding toward the mucosa, so that the main drill is automatically stopped because the rotational force of the sub drill is not transmitted to the main drill. 14. The method of claim 13, The cutting edge of the secondary drill has a lower cutting force than the cutting edge of the main drill, and at the moment when the maxilla is drilled in a circular shape by the main drill, a disk-shaped bone fragment is placed in front of the secondary drill and the cutting edge of the secondary drill. Remaining between the mucosa and the secondary drill does not directly contact the mucosa.

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