KR101122133B1 - Drill for operating implant - Google Patents

Abstract

Disclosed is a drill for implant treatment. Drill for implant treatment of the present invention, the drill body; A pressure head portion provided at one end of the drill body for cutting the alveolar bone or pressing the bone graft material implanted in the alveolar bone; And a stopper part detachably coupled to the drill body, the stopper part reciprocating in the longitudinal direction of the drill body to limit the depth into which the pressure head part is drawn. According to the present invention, not only can cut the maxillary alveolar bone to form a hole, but also can press the bone graft material implanted between the maxillary alveolar alveolar bone and the maxillary sinus lining, and can control the depth of infusion during cutting and pressing.

Description

DRILL FOR OPERATING IMPLANT}

The present invention relates to a drill for implant surgery, and more particularly, to a drill for implant surgery that can pressurize the bone graft material when the bone graft material is hardened when cutting the alveolar bone or implanted bone graft material in the cut alveolar bone.

Implants are originally meant to be a substitute for recovery when tissue is lost, but in dentistry, implants are made of artificial teeth. In order to replace the lost root (root), a tooth root made of titanium (titanium), which is not rejected by the human body, is planted in the alveolar bone where the tooth falls out, and the artificial tooth is fixed to restore the function of the 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.

Implants also enhance the function of dentures and improve the aesthetic aspects of dental prosthetic restorations, as well as in single brace restorations, as well as in partial and complete teeth. Furthermore, it disperses excessive stress on surrounding supportive bone tissue and helps stabilize teeth.

On the other hand, the implant success rate in the maxillary posterior part is known to be relatively low compared to the success rate in other parts, for example, the mandibular posterior part during such implantation procedure, because the maxillary posterior part is relatively weak in bone and has the maxillary sinus inside. This is because it is not easy to implant.

In other words, the maxillary sinus, which is located between the upper molar and, more precisely, the upper molar and the side of the nose, is a space surrounded by the mucous membrane and expands downward when the tooth is lost physiologically. As a result of the bone absorption, the amount of bone that can be implanted is insufficient due to the downward expansion, which makes it difficult to implant the implant into the maxillary posterior molar.

In this case, after forming a space by elevating the maxillary sinus lining, a bone graft material is implanted in the secured space, and implantation is implanted therein. Such methods include a vertical approach and a lateral approach.

First, the vertical approach is a method of securing a certain amount of residual bone in the implant site, and tapping the maxilla several times with a device called a chisel and hammer-shaped osteotomes to prevent damage to the maxillary sinus lining. Then, a little bit of bone graft material through the hole.

However, when using such a vertical approach, because the maxillary sinus lining cannot be seen directly during the procedure, the procedure takes a long time because the operation is performed very carefully while checking the process by X-rays.

Next, the lateral approach is a method when the remaining bone of the implant site is very insufficient, forming a hole on the side of the maxillary sinus, elevating the lining of the maxillary sinus, and implanting a bone graft material through the hole. By the way, this method has the advantage that the procedure can be faster than the vertical approach, there is a concern that the edema may occur in the treatment site as well as the operation itself is difficult.

Therefore, in order to solve these problems, in recent years, maxillary sinus elevation using a general implant drill has been studied, and furthermore, it is actually applied.

However, the cutting drill used in the treatment of the maxillary sinus elevation is not easy to clean due to the diamond particles coated on the drill surface, and the cutting surface of the cutting drill wears, thus reducing the cutting force and thus shortening the service life. .

In addition, by coating the cutting surface with diamond particles, there is a problem that quality stabilization is difficult and product cost increases.

In the case of maxillary sinus elevation, after cutting the maxillary alveolar bone with a cutting drill, a pressure drill is required to press bone graft material into the space generated by elevating the maxillary sinus lining. There is a problem that requires a lot of drill.

Therefore, it is necessary to develop an implant procedure drill capable of performing the role of a pressure drill for pressing the bone graft material that is implanted between the alveolar bone and the maxillary sinus lining after cutting the maxillary alveolar bone while supplementing the problem of the cutting drill.

An object of the present invention, the cutting drill for cutting the maxillary alveolar alveolar bone and can perform all the functions of the pressure drill for pressing the bone graft material implanted between the maxillary alveolar alveolar bone and the maxillary sinus lining, cutting and bone of the alveolar bone It is to provide a single implant treatment drill with a stopper function to prevent the implant from pressing beyond the depth required.

The above object, according to the present invention, a drill body; A pressure head portion provided at one end of the drill body to cut alveolar bone or pressurize a bone graft material implanted in the alveolar bone; And a stopper part detachably coupled to the drill body, the stopper part reciprocating in the longitudinal direction of the drill body to limit the depth into which the pressure head part is drawn.

The stopper unit may include a stopper body formed in a cylindrical shape; A rotation induction part provided at one end of the stopper body to rotate the stopper body; A rotation limit ring coupled to an outer circumferential surface of the stopper body and limiting rotation of the stopper body when the drill body rotates; And a release prevention jaw provided at the other end of the stopper body symmetrical with the rotation guide part and preventing the rotation restriction ring from being separated from the stopper body.

In the central region of the stopper body may be formed through the drill body coupling hole is formed in the longitudinal direction of the drill body coupled to the drill body.

The stopper body may have at least one through hole communicating with the drill body coupling hole, and the rotation restriction ring may contact the drill body through the through hole.

A stopper female screw may be formed in the circumferential direction on the inner circumferential surface of the drill body coupler.

The drill body may be a drill body male screw is formed along the longitudinal direction of the drill body to be fastened to the stopper female screw.

One region of the outer circumferential surface of the drill body may be provided with a cutting surface for cutting one surface formed with the drill body male screw in the longitudinal direction of the drill body.

The cutting surface may be provided with a pull-in depth display unit capable of adjusting the pull-out depth of the pressing head portion, and the pull-in depth display unit may be formed of a plurality of pull-in depth display lines.

A protrusion may be formed along the circumferential direction on the outer circumferential surface of the rotation guide portion.

The pressing head portion is formed to extend from one end of the drill body, one end of the pressing head portion symmetrical with the drill body may be formed in a hemispherical shape.

The pressure head part may have a plurality of grooves formed along a length direction of the pressure head part.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings.

According to the present invention, it is possible to cut the maxillary alveolar bone to form a hole as well as to press the bone graft material implanted between the maxillary alveolar alveolar bone and the maxillary sinus lining, and to control the depth of infusion during cutting and pressing.

1 is a perspective view of a drill for implant surgery according to an embodiment of the present invention.
2 is a partial perspective view according to an embodiment of FIG. 1.
3 is a perspective view of a stopper part according to an embodiment of FIG. 1.
4 is a front view of the stopper part according to FIG. 3.
5 is a side view of the stopper part according to FIG. 3.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, the present invention will be described in detail by explaining preferred embodiments of the present invention with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

1 is a perspective view of a drill for implant operation according to an embodiment of the present invention, Figure 2 is a partial perspective view according to one embodiment of Figure 1, Figure 3 is a perspective view of the stopper portion according to an embodiment of Figure 1, 4 is a front view of the stopper part according to FIG. 3, and FIG. 5 is a side view of the stopper part according to FIG. 3.

As shown in these figures, the implant 100 for the implant procedure according to the present embodiment, the drill body 110, the hole is provided at one end of the drill body 110 to form the hole by cutting the alveolar bone or formed The pressure head 130 and the drill head 110 that can press the bone graft material implanted between the maxillary alveolar alveolar bone and the maxillary sinus lining are detachably coupled to the reciprocating movement in the longitudinal direction of the drill body 110 It includes a stopper 200 that can limit the depth of implantation of the pressing head 130.

The size of the pressure head 130 may be formed in various sizes according to the size of the alveolar bone of the individual, the size of the drill body 110 may be formed in an appropriate size in proportion to the size of the pressure head 130.

Drill body 110 is formed in the shape of a cylinder, the other end of the drill body 110, that is, the drill rod 125 is provided at the side end opposite to the one end is provided with the pressing head 130, the drill The shank portion 120 is provided at an end of the rod 125 opposite to the side where the drill body 110 is provided, so as to be connected to a dental hand piece capable of rotating the drill body 110.

Drill rod 125 is generally formed that the circumferential size of the outer peripheral surface is smaller than the circumferential size of the outer peripheral surface of the drill body (110). And the drill body male screw 113 is formed along the longitudinal direction of the drill body 110 on the outer peripheral surface of the drill body (110).

The drill body male thread 113 may be formed as a left screw or a right screw, and the direction in which the drill body male thread 113 is formed is formed in a direction opposite to the rotation direction of the drill body 110 connected to the handpiece. In this embodiment, since the direction of rotation of the drill body 110 connected to the handpiece is right, the drill body male screw 130 is formed of a left screw.

Although the drill body male screw 130 may have various pitch intervals, the pitch interval of the drill body male screw 130 may be accurately adjusted so that the user stops the stopper part 200 reciprocating on the drill body 110 according to the depth of insertion. Form. Therefore, in the present embodiment, the stopper 200 is formed to have a pitch interval of 0.5 so as to easily stop in accordance with the inlet depth.

 On the other hand, the cutting surface 115 is formed in one area of the outer circumferential surface of the drill body 110, since the drill body male thread 113 is formed on the outer circumferential surface of the drill body 110, the cutting surface 115 is a drill body male screw ( 113 is provided by cutting the formed surface.

The cutting surface 115 is parallel to the imaginary surface including the central axis of the drill body 110, the stopper portion 200 reciprocating on the drill body 110 is drawn in the depth of the cutting surface 115 A retraction depth display unit 150 is formed to fit in the.

If there is no cutting surface 115, the inlet depth display unit 150 is to be formed on the drill body male screw 113, in this case the stopper limiting the depth to which the press head portion 130 is drawn in the drill body 110 Since the part 200 is coupled and reciprocated, the cutting depth display part 150 may be worn and removed due to frequent reciprocating movement of the stopper part 200, so that the cutting surface is partially cut on the outer circumferential surface of the drill body 110. If the depth 115 is formed on the cutting surface 115 by forming the 115, the pulling depth display 150 of the cutting surface 115 is not removed even by the reciprocating movement of the stopper 200.

The draw depth display unit 150 is formed of a plurality of draw depth display lines, and the thickness and spacing of the draw depth display line may be formed to have various thicknesses and gaps so as to correspond to various types of holes.

On the other hand, one end of the drill body 110 is formed by cutting the alveolar bone of the maxillary sinus to form a hole or through the formed hole pressurizing head portion 130 that can press the bone graft material implanted between the maxillary alveolar alveolar bone and the maxillary sinus lining Prepared.

Pressing head 130 is an end portion that is opposite to the side that is connected to the drill body 110 to the cylindrical body 131 of the circumference of the outer peripheral surface is larger than the circumference of the outer peripheral surface of the drill body 110, that is, the pressing head portion One end 133 of the 130 is formed in a hemispherical shape to facilitate pressing the bone graft material.

And grooves 133a which are symmetrical with each other based on the central axis of the pressing head 130 are formed extending from the one end 133 to the body 131 along the longitudinal direction of the pressing head 130. And the edge (130a) formed in the pressure head 130 due to the groove 133a serves as a cutting edge that can cut the maxillary alveolar bone.

On the other hand, the stopper portion 200 coupled to the drill body 110 to reciprocate and limit the depth to which the pressure head 130 is drawn, the stopper body 210 and the stopper body 210 is formed in a cylindrical shape Rotation guide portion 230 that is provided at one end of the) to rotate the stopper body 210, and is fitted to the outer peripheral surface of the stopper body 210 to limit the rotation of the stopper body 210 when the drill body 110 is rotated The rotation limiting ring 250 and the other end of the stopper body 210, that is, the end of the stopper body 210 is provided at the end opposite to the end of the stopper body 210 is provided with the rotation limiting ring 250 is a stopper body And a departure prevention jaw 270 that prevents the departure from the 210.

The stopper body 210 is formed in a cylindrical shape as described above, but the drill body coupling hole 211 penetrated along the longitudinal direction of the drill body 110 is formed in the central region of the stopper body 210.

The stopper body 210 is coupled to the drill body 110 through the drill body coupler 211 to reciprocate along the length direction on the drill body 110. In addition, a stopper female screw 213 corresponding to the male screw 113 of the drill body 110 is formed along the longitudinal direction of the drill body 110 on the inner circumferential surface of the drill body coupler 211.

As a result, the stopper female screw 213 formed on the drill body coupler 211 is fastened to the drill body male screw 113 formed on the outer circumferential surface of the drill body 110, so that the stopper part 200 is along the length direction on the drill body 110. Reciprocating movement is possible.

Meanwhile, some areas of the outer circumferential surface of the stopper body 210 are symmetrically cut with respect to the center axis of the stopper body 210, and the thickness of the cutting body is cut from the outer circumferential surface of the stopper body 210. It is to be cut by the thickness (T) to the inner peripheral surface to be formed.

 As such, when some spaced apart areas of the outer circumferential surface of the stopper body 210 are cut, the stopper body 210 has a through hole 215 penetrating through the stopper body 210 and communicating with the drill body coupler 211. .

As a result, when the stopper part 200 is coupled to the drill body 110, the drill body male screw 113 is exposed through the through hole 215. When the rotation limit ring 250 is fitted to the outer circumferential surface of the stopper body 210, the rotation limit ring 250 comes into contact with the drill body male screw 113 exposed through the through hole 215.

As such, when the rotation limit ring 250 comes into contact with the drill body male screw 113, the stopper part 200 may obtain a friction force capable of preventing rotation of the drill body 110.

Therefore, when the drill body 110 connected to the handpiece rotates to form a hole in the maxillary alveolar bone, the rotation limit ring 250 in contact with the drill body male thread 113 is applied to the moment of inertia of the stopper part 200 by the frictional force. When the drill body 110 rotates with respect to the stopper 200 may be prevented from being rotated.

Here, the rotation limit ring 250 is generally provided with an elastic material having an elastic material. In this embodiment, the rotation limit ring 250 is applied with an O-ring.

At one end of the stopper body 210, the stopper body 210 is rotated to determine the position of the stopper part 200 according to a depth at which the pressure head 130 provided at one end of the drill body 110 is inserted. Rotational induction part 230 is provided.

The rotation guide portion 230 is formed to have an outer circumferential size larger than the circumferential size of the outer circumferential surface of the stopper body 210. The size of the circumference of the outer circumferential surface of the rotary induction portion 230 is larger than that of the outer circumferential surface of the pressure head 130. When the operator grasps and rotates the rotation induction part 230 to determine the position of the stopper part 200, the operator does not come into contact with the pressure head part 130.

In addition, a plurality of protrusions 231 are formed along the circumferential direction on the outer circumferential surface of the rotation induction part 230. The plurality of protrusions 231 are formed along the circumferential direction with a plurality of protrusions 231 having the same size at regular intervals, and the operator uses the stopper body 230 to determine the position of the stopper portion 200 by the stopper body. It is provided to prevent slipping by the smooth surface when rotating 210.

On the other hand, the end opposite to one end of the stopper body 210, which is provided with the rotation guide 230, that is, the other end of the stopper body 210 is separated from the outer peripheral surface circumference size larger than the outer peripheral surface size of the stopper body 210 Bump 270 is provided.

The release prevention jaw 270 is fitted to the outer circumferential surface of the stopper body 210 so that the rotation limit ring 250 that restricts the rotation of the stopper 200 when the drill body 110 rotates is separated from the stopper body 210. Is provided to prevent that.

Since the release prevention jaw 270 is provided to prevent the release of the rotation limiting ring 250 fitted to the outer circumferential surface of the stopper body 210, the rotation limiting ring 250 is inserted into the outer circumferential surface of the stopper body 210. It is provided to have a circumference sufficient to prevent separation of the ring 250.

Hereinafter, a method of using an implant treatment drill according to the present invention will be described with reference to maxillary sinus elevation, which is one of the implant procedures.

First, a thin hole is formed using a guide drill (not shown) in a position where the implant is to be placed, for example, the maxillary sinus alveolar bone, and the center of the formed hole is indicated. In other words, a guide drill (not shown) is used to form shallow holes from the maxillary sinus lining to approximately 3 mm adjacent locations.

Subsequently, a hole is formed using a drilling drill (not shown) to a position approximately 1 mm from the maxillary sinus lining. At this time, the center of the drilling drill should be aligned with the center of the hole indicated by the guide drill.

On the other hand, when the drilling drill forms a hole in the alveolar bone from the maxillary sinus lining to approximately 2 mm adjacent to the alveolar bone, the hole is formed by using the rotational force of the handpiece, and then the operator directly rotates the drilling drill to the approximately 1 mm adjacent position. Run

That is, when rotating the drill for drilling with the handpiece can not accurately control the drilling operation of the drill for drilling, but if the operator directly rotates the drilling drill to form a hole of the alveolar bone to the desired depth.

Subsequently, the drill 100 for implant surgery according to an embodiment of the present invention is inserted into the hole of the alveolar bone, and the drilling operation is performed until one end portion 133 formed in the hemispherical shape of the pressure head 130 is in contact with the maxillary sinus lining. Proceed.

In the drilling operation, the edge 130a by the groove 133a formed from the one end 133 formed in the hemispherical shape of the pressing head 130 to the body 131 of the pressing head 130 serves as a cutting edge. The alveolar bone is cut and drilled. On the other hand, the cut bones of the alveolar bone may be discharged through the groove 133a formed in the pressing head 130. In this case, the maxillary sinus lining may be slightly elevated by the hemispherical one end portion 133 of the pressure head 130.

Next, a maxillary sinus elevation instrument (not shown) is introduced into the hole of the alveolar bone to elevate the partially exposed maxillary sinus lining.

Then, after filling the bone graft material (not shown) in the space formed by the maxillary sinus lining operation, using the hemisphere one end portion 133 of the pressure head 130 in the implant treatment drill 100 of the present invention. Pressurize the bone graft material. One end 133 of the pressing head 130 is formed convexly in a hemispherical shape can be uniformly and densely pressed between the maxillary sinus lining and the alveolar bone.

On the other hand, the drill body 110 is connected to the pressing head 130 is coupled to the stopper 200 for limiting the depth to which the pressing head 130 is drawn. The stopper part 200 may reciprocate in the longitudinal direction of the drill body 110 on the drill body 100 so that the operator determines the position of the stopper part 200 according to the depth into which the pressure head 130 is inserted.

Therefore, when cutting the maxillary alveolar bone using the stopper part 200 or pressing the bone graft material between the maxillary sinus lining and the alveolar bone, the pressing head 130 may be prevented from being introduced deeper.

As described above, according to the drill for the implant procedure of the present invention, the cutting drill and the pressure drill, which had to be separately provided in order to pressurize the bone graft material implanted between the alveolar bone and the alveolar bone and the maxillary sinus lining, the implant of the embodiment of the present invention It can be replaced by a single drill, which can reduce the cost.

In addition, by removing the diamond particle coating is made in the conventional cutting drill, and simplifying the product production and quality can be stabilized.

In addition, by providing a stopper 200 that is not provided in the conventional cutting drill and the pressurized drill, it is possible to prevent the depth of the drill depth to be adjusted by adjusting the depth of penetration depending only on the working ability of the operator.

As described above, the present invention is not limited to the described embodiments, and various modifications and changes can be made without departing from the spirit and scope of the present invention, which will be apparent to those skilled in the art. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

100: implant treatment drill 110: drill body
113: drill body male thread 115: cutting surface
120: shank portion 125: drill rod
130: pressure head 133a: groove
200: stopper portion 210: stopper body
211: Drill Body Coupling 213: Stopper Female Thread
230: rotation guide portion 250: rotation limit ring
270: dropping jaw

Claims (11)

Drill body;
A pressure head portion provided at one end of the drill body to cut alveolar bone or pressurize a bone graft material implanted in the alveolar bone; And
Removably coupled to the drill body, and includes a stopper portion for reciprocating in the longitudinal direction of the drill body to limit the depth to which the pressing head portion is drawn,
The stopper part,
A stopper body formed in a cylindrical shape;
A rotation induction part provided at one end of the stopper body to rotate the stopper body;
A rotation limit ring coupled to an outer circumferential surface of the stopper body and limiting rotation of the stopper body when the drill body rotates; And
And a separation prevention jaw provided at the other end of the stopper body symmetrical to the rotation guide part and preventing the rotation restriction ring from being separated from the stopper body. delete The method of claim 1,
Drill in the central region of the stopper body is formed in the longitudinal direction of the drill body coupled to the drill body engaging hole coupled to the drill body is implant treatment. The method of claim 3,
The stopper body is formed with at least one through-hole communicating with the drill body coupling hole, the rotation restriction ring is implant drill, characterized in that in contact with the drill body through the through hole. The method of claim 3,
An implant treatment drill, characterized in that a stopper female screw is formed in the circumferential direction on the inner circumferential surface of the drill body coupler. The method of claim 5,
The drill body is an implant treatment drill, characterized in that the drill body male thread is formed along the longitudinal direction of the drill body to be fastened to the stopper female screw. The method of claim 6,
And a cutting surface for cutting one surface of the drill body male thread formed along a longitudinal direction of the drill body in one region of the outer circumferential surface of the drill body. The method of claim 7, wherein
The cutting surface is provided with a draw depth display for adjusting the pull depth of the pressing head portion,
The insertion depth display unit is implant drill, characterized in that formed with a plurality of depth input line. The method of claim 1,
Drill for implant treatment, characterized in that the protrusion is formed in the circumferential direction on the outer circumferential surface of the rotation guide portion. The method of claim 1,
The pressing head portion is formed extending from one end of the drill body, one end of the pressing head portion is for implant treatment, characterized in that formed in a hemispherical shape. The method of claim 10,
The pressing head portion is a drill for implant treatment, characterized in that a plurality of grooves are formed along the longitudinal direction of the pressing head portion.

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