KR100759261B1 - Drill for operating implant - Google Patents

Abstract

A drill for an implant operation is provided to suppress overheating on boring to thus prevent a necrosis of an alveolar bone and to reduce the count number of boring an alveolar bone, thereby reducing the amount of time for the implant operation. A drill(100) for an implant operation comprises: a drill body(111) which has a space(121) for holding the bones of the alveolar bones inside while boring a hole in the alveolar bones; plural cutters(115) which are formed on the end of the drill body in order to bore the alveolar bones when the drill body rotates; plural outlets(117) for the bone pieces, which are concaved on the surface of the drill body at a torsion angle to the circumference of the main body, and which guide the drain for the bone pieces generated on boring the alveolar bones.

Description

DRILL FOR OPERATING IMPLANT}

1 is a partially exploded front view of a drill for an implant procedure according to a first embodiment of the present invention.

Fig. 2 is a side view of Fig. 1 showing a main section.

3A and 3B are diagrams illustrating one use state of the implant for drills of FIGS. 1 and 2, respectively.

4 is a front view of a drill for implant surgery according to a second embodiment of the present invention.

5 is a side view of FIG. 4.

6 is a partially exploded front view of a drill for implant surgery according to a third embodiment of the present invention.

Fig. 7 is a side view of Fig. 6 showing a main section.

8 is an exploded view of main parts of a drill for implant surgery according to a fourth embodiment of the present invention.

FIG. 9 is an assembled front view of the implant treatment drill of FIG. 8 in use. FIG.

10 is a cross-sectional view of FIG. 9.

* Explanation of symbols for the main parts of the drawings

5: alveolar bone 7,7 ': hole

100 ~ 400: drill for implant treatment 111: drill body

115: cutting edge 117: bone discharge furnace

121: bone receiving part 125: bone supplement receiving ball

131: shank portion 135: stopper

The present invention relates to a drill for implant surgery, and more specifically, a simple structure, by preventing excessive heat generation during drilling to prevent the necrosis of the alveolar bone while reducing the number of puncture operations of the alveolar bone during implantation procedure implantation time The present invention relates to a drill for implant procedures that can be shorter than before and that implant procedures can be made easier than before.

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.

The implant procedure is completed by drilling a placement position using a predetermined drill, placing the implant in the alveolar bone, fusion fusion to the bone, then 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.

On the other hand, since the implant is placed after drilling the alveolar bone of the patient using a drill or the like, drilling of the alveolar bone is also very important.

Here, for example, briefly described with respect to the drilling operation of the drill for implantation as follows. Such a drilling operation as an example may be a variety of drilling operations, of course.

First, the placement position of the implant on the surface of the alveolar bone is determined using a round drill as an initial drill.

Next, after cutting the upper portion of the alveolar bone at the site where the tooth is lost and opening it slightly, a guide drill is attached to a predetermined device to supply a water to the alveolar bone to drill a hole having a predetermined depth.

Then, the hole is expanded while supplying water to the alveolar bone by replacing with a first drill, and then expanding the upper end of the hole while supplying water to the alveolar bone by replacing with a pilot drill.

Subsequently, the lower end of the hole is expanded while supplying water to the alveolar bone by replacing with a final drill.

Subsequently, a thread is formed in the hole while supplying water to the alveolar bone by replacing with a tap drill.

Then, after the fixture is coupled to the screw hole in which the thread is formed by using a predetermined mechanism, the abutment is fastened to the fixture to fix the artificial tooth to the abutment using an adhesive.

However, conventionally, in order to implant a fixture during implantation, a plurality of drills should be drilled by changing several types of drills in order, and therefore, many pilot drills should be used in order to install a large diameter fixture. Too many times of puncture operation, the procedure time is long, there is a problem that causes the inconvenience of the patients.

Therefore, it is possible to consider a method of reducing the number of drilling operations by drilling a large diameter hole at one time. In this case, excessive heat is generated when the bones of the alveolar bones cut during drilling are not discharged to the outside smoothly. It is not easy to reduce the number of drilling operations because there is a problem that causes.

Accordingly, the present applicant omits the drilling of the first drill, the pilot drill, and the final drill, thereby reducing the number of punctures of the alveolar bone, minimizing the inconvenience of patients, and developing an implant procedure drill that can shorten the implant procedure time. It came to the following.

An object of the present invention, as a simple structure, to prevent excessive heat generation during drilling to prevent the necrosis of the alveolar bone, while reducing the number of puncture operation of the alveolar bone during the implant procedure can shorten the implant procedure time than the conventional and also implant procedures It is to provide a drill for implant surgery that can be easier than conventional.

Another object of the present invention is to provide an implant treatment drill that can limit the depth of the hole to be drilled when drilling a hole in the alveolar bone and can be stably drilled in response to the shape and position of various alveolar bones.

The object is, according to the present invention, when drilling a hole in the alveolar bone drill body which is formed inside the bone receiving portion is accommodated bone of the alveolar bone; A plurality of cutting edges formed at the end of the drill body to drill holes in the alveolar bone when the drill body is rotated; And a plurality of bone discharge paths having a torsion angle on the outer circumference of the drill body and recessed from the surface of the drill body, for guiding the discharge of the bone fragments of the alveolar bone generated when the alveolar bone is drilled. It is achieved by a drill for implant treatment.

Here, the front end of the plurality of bone discharge path, may be processed in the form of a blade so as to puncture the alveolar bone together with the plurality of cutting edges.

It may include at least one bone support receiving hole is formed through the drill body to communicate with the bone receiving portion.

The bone support hole may have a shape of a long hole formed in parallel with the longitudinal direction of the drill body.

The surface of the drill body may be formed to be symmetrical with each other and a pair of incision surface cut vertically along the longitudinal direction of the drill body, the bone support hole is to be formed on each of the pair of incision surface Can be.

At least one insertion depth display pattern displaying the insertion depth of the drill body inserted into the alveolar bone may be further formed on the surface of the drill body.

The at least one insertion depth display pattern may have a band shape surrounding an outer surface of the drill body.

Removably coupled to the drill body, it may further include a stopper for limiting the depth of the hole to be punctured when drilling the hole in the alveolar bone.

The stopper is detachably coupled to an upper end portion of an inner wall surface of the drill body via the bone accommodating portion, and either one of the stopper and an upper end portion of the inner wall surface of the drill body is provided with a male screw portion, and the male screw portion is screwed on the other. Female threads to be fastened may be formed.

The male screw portion may be formed at the stopper, and the female screw portion may be formed at an upper end portion of an inner wall surface of the drill body.

The stopper may include a shaft portion having the male screw portion formed on an outer surface thereof; And a head portion connected to the shaft portion and having a larger diameter than the shaft portion, and a tool insertion groove may be further formed in the head portion.

The cutting edge may have an angle of 0 degrees to 45 degrees with respect to the axis of the drill body.

It may further include a shank portion coaxial with the drill body and extending in the longitudinal direction from one end of the drill body.

The bone support hole may be formed on the path of the bone discharge path, the bone support hole may be formed in a radial direction with respect to the axis of the drill body.

The width of the short side of the bone support hole may be larger than the width of the bone discharge passage.

The upper end of the drill body may be formed in the removable groove recessed from the outer surface, the stopper may be provided with a engaging portion detachably coupled to the removable groove of the drill body.

The catching part may include: a plurality of balls installed in a radial direction on an inner circumference of the stopper; And it may include a plurality of springs for elastically supporting the ball to the stopper.

On the other hand, according to the present invention, when drilling a hole in the alveolar bone, the drill body is formed therein the bone receiving portion is accommodated in the bone of the alveolar bone; A plurality of cutting edges formed at the end of the drill body to drill holes in the alveolar bone when the drill body is rotated; And is detachably coupled to the drill body, it is also achieved by an implant treatment drill, characterized in that it comprises a stopper for limiting the depth of the hole to be drilled when drilling the hole in the alveolar bone.

Here, the stopper is detachably coupled to the upper end of the inner wall surface of the drill body via the bone accommodating portion, one of the stopper and the upper end of the inner wall surface of the drill body is formed with a male screw portion, the other of the male screw A female screw portion to which the additional screw is fastened may be formed.

The male screw portion may be formed on the stopper, and the female screw portion may be formed on an upper end portion of an inner wall surface of the drill body.

The stopper may include a shaft portion having the male screw portion formed on an outer surface thereof; And a head portion connected to the shaft portion and having a larger diameter than the shaft portion, and a tool insertion groove may be further formed in the head portion.

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

1 is a partially exploded front view of a drill for an implant procedure according to a first embodiment of the present invention, FIG. 2 is a side view of FIG. 1 showing a main portion cross section, and FIGS. 3A and 3B are implants of FIGS. 1 and 2, respectively. It is a state of use of the drill for the procedure.

As shown in these figures, the implant 100 for the implant procedure according to the present embodiment is formed in the drill body 111, the drill body 111 by the rotation of the drill body 111, the alveolar bone (5, 3A and 3B) and a plurality of cutting edges 115 for drilling holes in the hole, and a predetermined depth is formed in one end portion of the drill body 111 in the longitudinal direction to drill holes in the alveolar bone 5. When the bone receiving portion 121 is accommodated bone of the alveolar bone (5), a plurality of bone discharge passage 117 for guiding the discharge of bone fragments of the alveolar bone (5) during drilling, and the bone receiving portion 121 and At least one bone auxiliary receiving hole 125 formed to penetrate the drill body 111 to be in communication with the drill body 111 is detachably coupled to the depth of the hole to be drilled when drilling a hole in the alveolar bone 5, again In other words, the drill body 111 is provided with a stopper 135 for limiting the depth (D) is inserted.

The drill body 111 has a cylindrical shape but has a hollow shape up to a predetermined height by providing a bone accommodating portion 121 recessed in a longitudinal direction from an end portion thereof in a longitudinal direction. The drill body 111 is rotated when drilling about the longitudinal axis. The internal threaded portion 111a is formed at the upper end of the inner wall surface of the drill body 111. A male screw portion 137a formed on the outer surface of the shaft portion 137 of the stopper 135 to be described later is screwed into the female screw portion 111a.

Cutting edge 115 is formed at a predetermined interval on one end of the drill body (111). The cutting edge 115 may be provided in various ways, but in the present embodiment, the cutting edge 115 may be provided at an angle of 0 degrees to 45 degrees with respect to the axis of the drill body 111.

The bone accommodating part 121 is formed in the one end of the drill body 111 in a predetermined depth recessed in the longitudinal direction. The bone receiving portion 121 is the bone of the alveolar bone 5 is received during the drilling by the rotation of the drill body 111, the drill body 111 is separated from the alveolar bone 5 after the drilling of the alveolar bone 5 The bone is separated from the alveolar bone 5 in a state accommodated in the bone accommodating part 121. That is, since the cutting edge 115 cuts only the portion of the alveolar bone 5 corresponding to the thickness of the cutting edge 115, the bone of the alveolar bone 5 is accommodated in the bone accommodating portion 121 during drilling. When the drill body 111 is separated from the alveolar bone 5, the bone of the alveolar bone 5 accommodated in the bone accommodating part 121 during the puncturing is almost in a state in which a coupling relationship with the adjacent bone is released. It is separated from the alveolar bone 5 in a state accommodated in the receiving portion 121 and exits together with the drill body 111. Therefore, a hole of a relatively larger diameter is formed in the alveolar bone 5 than in the prior art.

As such, the bone of the alveolar bone 5 accommodated in the bone accommodating part 121 is an auxiliary tool as the bone assisting hole 125 of the drill 100 after the drill body 111 is separated from the alveolar bone 5 after the drilling operation. Inserted (not shown) is removed by applying an external force to the bone of the alveolar bone 5 accommodated in the bone receiving portion 121.

The bone discharge passage 117 has a predetermined twist angle at the drill body 111 and is formed to be recessed a predetermined depth from the surface of the drill body 111. The bone discharge path 117 serves as a plurality of discharge paths through which bone fragments of the alveolar bone 5 to be discharged are discharged. Thus, the bone discharge path 117 smoothly discharges the bone of the alveolar bone 5 which is cut at the time of drilling to the outside, not only to prevent excessive heat from occurring during the puncture, but also to prevent necrosis of the alveolar bone 5 due to excessive heat. Do it. Therefore, unlike conventional, it is possible to perforate a relatively large diameter at a time while suppressing excessive heat generation. Although the reference numeral is not given, the tip of the bone discharge passage 117 is sharply processed in the form of a blade in this embodiment. As the tip of the bone discharge path 117 is processed in the form of a blade, the bone discharge path 117 smoothly discharges the bone of the alveolar bone 5 to the outside, as well as the plurality of cutting edges 115 and the alveolar bone 5 ) To assist in drilling work.

Bone support receiving hole 125 is formed through the drill body 111. In the present embodiment, the bone support hole 125 has the shape of a long hole formed in parallel with the longitudinal direction of the drill body 111. On the other hand, in the present embodiment, the bone support hole 125 is formed on the incision surface 112 formed on the surface of the drill body 111. That is, a pair of incision surfaces 112 are formed on the surface of the drill body 111 to be symmetrical with each other and vertically cut along the length direction of the drill body 111. Such a pair of incision surfaces 112 Bone secondary accommodation hole (125) is penetrated in the form of a long hole. Thus, by forming a pair of incision surface 112 on the surface of the drill body 111, and by forming the bone auxiliary accommodation hole (125) here because the opening area of the bone auxiliary accommodation hole 125 can be increased After the drilling operation, there is an advantage that the bone accommodated in the bone accommodating part 121 can be easily removed by a predetermined tool inserted through the bone support accommodating hole 125.

The bone auxiliary receiving ball 125 is a bone fragment of the alveolar bone 5 when the hole is drilled in the alveolar bone 5 is discharged through the bone discharge passage 117, the bone of the alveolar bone 5 in the bone auxiliary receiving ball 125 Pieces can be accommodated. Therefore, in the conventional drilling, bone fragments of the alveolar bone 5 may be caught in the drill and friction may occur, thereby suppressing a phenomenon in which excessive heat is generated. As described above, the bone of the alveolar bone 5 accommodated in the bone accommodating part 121 during the drilling is easily removed from the bone accommodating part 121 by a predetermined tool inserted through the bone auxiliary accommodating ball 125 after the drilling operation. Can be.

The other end of the drill body 111, that is, the opposite end of the bone receiving portion 121 of the drill body 111, for example, is connected to a tool such as a dental hand piece (drill hand piece) A shank portion 131 for operating 111 is provided. The shank portion 131 is provided coaxially with the drill body 111 and extends in the longitudinal direction from one end of the drill body 111.

On the other hand, the stopper 135 is detachably coupled to the drill body 111 to limit the depth of the hole to be drilled when drilling the hole in the alveolar bone (5). In other words, the depth D into which the drill body 111 is inserted is limited.

The stopper 135 includes a shaft portion 137 having a male screw portion 137a formed on an outer surface thereof, and a head portion 136 connected to the shaft portion 137 and having a larger diameter than the shaft portion 137. The head 136 is further formed with a tool insertion groove 136a. In the present embodiment, the tool insertion groove 136a is a hexagon wrench groove. However, since the scope of the present invention is not limited thereto, a cross or straight groove may be formed in addition to the hexagon wrench groove.

Accordingly, after inserting a separate tool into the tool insertion groove 136a, the male screw portion 137a formed on the shaft portion 137 of the stopper 135 by rotating the stopper 135 is provided at the upper end of the inner wall surface of the drill body 111. The stopper 135 can be easily coupled to the drill body 111 by being screwed to the formed female thread 111a, whereby the stopper 135 can limit the depth of the hole to be drilled. For reference, the stopper 135 may have a size of about 1 to 7 Φ but in the present embodiment has a diameter of 2.5 Φ, which is an implant diameter 100 for all implant procedures having an inner diameter of about 4 to 7 Φ This is to be used in common.

By this configuration, briefly described the drilling operation of the drill for placing the implant in the missing tooth as follows.

First, the placement position of the implant on the surface of the alveolar bone 5 is determined using a round drill (not shown) as an initial drill.

Next, after cutting the upper portion of the alveolar bone 5 of the site where the tooth is lost and opening it slightly, a guide drill (not shown) is attached to a predetermined device to supply water to the alveolar bone 5 while supplying water to the alveolar bone 5. Drill the hole 7.

3A and 3B, while replacing the drill 100 according to the present invention and supplying water to the alveolar bone 5, the upper and lower ends of the first hole 7 are expanded and drilled, that is, the alveolar bone A second hole 7 'is formed in (5). At this time, the bone of the perforated alveolar bone 5 as the drill body 111 of the drill 100 according to the present embodiment is rotated is accommodated in the bone accommodating portion 121 and the bone fragment of the alveolar bone 5 at the time of drilling It is discharged to the bone discharge path (117). In addition, the bone fragments of the alveolar bone 5 discharged to the bone discharge path 117 may be partially accommodated in the bone support receiving hole 125 while being discharged to the bone discharge path 117. Thus, in the alveolar bone 5 of the missing tooth, the second hole 7 ′ in which the implant is to be implanted is recessed to a predetermined depth while suppressing excessive heat generation.

On the other hand, the bone accommodated in the bone accommodating portion 121 is inserted into the predetermined tool through the bone auxiliary receiving hole 125 after the drilling operation, it can be easily removed from the bone accommodating portion 121.

Subsequently, a thread is formed in the second hole 7 'while supplying water to the alveolar bone 5 by replacing it with a tap drill (not shown).

Then, using a tool such as a dental hand piece, a fixture (not shown) is coupled to the threaded threaded hole and bone fused for a period of time, and then the abutment (not shown) is attached to the fixture (not shown). By fastening the artificial tooth to the abutment using an adhesive, the implant procedure is completed.

As such, a plurality of cutting edges 115 for drilling holes in the alveolar bone 5 are formed by the rotation of the drill body 111 in the drill body 111, and the holes are drilled in the alveolar bone 5. When the bone receiving portion 121 in which the bone of the alveolar bone 5 is received is formed at a predetermined depth in the longitudinal direction at one end of the drill body 111, and discharge of the bone fragments of the alveolar bone 5 generated during drilling Drilling the alveolar bone 5 in accordance with the implant procedure by forming a plurality of bone drainage path 117 to guide the recessed body in a predetermined depth from the surface of the drill body 111 with a predetermined twist angle on the outer periphery of the drill body 11 By eliminating the drilling of the first drill, the pilot drill and the final drill, the simple structure prevents excessive heat generation during drilling to prevent necrosis of the alveolar bone 5 while reducing the number of drilling operations of the alveolar bone 5 during implantation. It is possible to shorten implant procedure time than before In addition, the implant procedure can be made easier than before.

And by detachably coupled to the drill body 111, by providing a stopper 135 for limiting the depth of the drill to be drilled, it is possible to stably drill in response to the shape and position of the various alveolar bone (5) .

FIG. 4 is a front view of an implant procedure drill according to a second embodiment of the present invention, and FIG. 5 is a side view of FIG.

A plurality of insertion depths indicating the insertion depth of the drill body 211 is inserted into the alveolar bone (see 5, 2a and 2b) on the surface of the drill body 211 in the implant 200 for the implant procedure Display patterns 211a to 211e are further formed. The insertion depth display patterns 211a to 211e have a band shape surrounding the outer surface of the drill body 211.

As shown in the present embodiment, when the insertion depth display patterns 211a to 211e are formed on the surface of the drill body 211, the depths D1 to D5 at which the drill body 211 is inserted for drilling the alveolar bone 5 are illustrated. (See 4) has the advantage of making drilling easier.

For reference, in the present embodiment, five insertion depth display patterns 211a to 211e are formed, but since the scope of the present invention is not limited thereto, the number of insertion depth display patterns 211a to 211e is appropriately changed. It can be. In addition, in forming the insertion depth display patterns 211a to 211e, a separate anodizing method may be applied.

FIG. 6 is a partially exploded front view of an implant procedure drill according to a third embodiment of the present invention, and FIG. 7 is a side view of FIG.

In the case of the drill 300 for the implant procedure according to the present embodiment, the bone discharge passage 117 (see FIGS. 1 and 2) of the first embodiment is not formed on the outer surface of the drill body 311.

However, as shown in FIGS. 6 and 7, even when the drill 300 for the implant procedure in which the bone discharge path 117 (see FIGS. 1 and 2) is not formed is drilled when the hole is drilled in the alveolar bone 5. The stopper 335 may be provided to limit the depth of the hole, that is, the depth into which the drill body 111 is inserted.

As described above, the stopper 335 of the present embodiment is also detachably coupled to the drill body 311, and is connected to the shaft portion 337 and the shaft portion 337 having the male thread portion 337a formed thereon. And a head 336 having a diameter larger than that of the shaft 337. The head 336 is further formed with a tool insertion groove 336a.

Accordingly, after inserting a separate tool into the tool insertion groove 336a, the male screw portion 337a formed on the shaft portion 337 of the stopper 335 by rotating the stopper 335 is provided at the upper end of the inner wall surface of the drill body 311. The stopper 335 can be easily coupled to the drill body 311 by being screwed to the formed female thread portion 311a, whereby the stopper 335 can limit the depth of the hole to be drilled.

FIG. 8 is an exploded view of main parts of an implant procedure drill according to a fourth embodiment of the present invention, FIG. 9 is an assembled front view of the implant procedure drill of FIG. 8, and FIG. 10 is a cross-sectional view of FIG. 9.

As shown in these figures, the implant 400 for the implant procedure according to the present embodiment is almost the same as the implant procedure drill 100 (refer to FIG. 1 and FIG. 2) described in the first embodiment, and thus redundant description will be omitted. Hereinafter, only parts different from the drill 100 of the first embodiment will be described.

In this embodiment, the upper and lower portions of the drill body 411 is formed with a removable groove 445 recessed from the outer surface to a predetermined depth along the outer circumference. The detachable groove 445 is engaged with the engaging portion 437, which will be described later, of the stopper 435.

The bone discharge path 417 is formed in the drill body 411 with a predetermined torsion angle and is recessed a predetermined depth from the surface of the drill body 411. The bone discharge passage 417 serves as a plurality of discharge passages through which bone fragments of the alveolar bone to be drilled (see FIGS. 2, 2A and 2B) are discharged, and simply form a groove shape.

The bone support receiving hole 425 formed through the drill body 411 has a long hole shape, and is formed radially with respect to the axis of the drill body 411. In addition, the bone auxiliary receiving hole 425 is formed on the path of the bone discharge path 417, so that when the hole in the alveolar bone 5, the bone fragments of the alveolar bone 5 are discharged through the bone discharge path 417 A bone fragment of the alveolar bone 5 may be accommodated in the bone support hole 425. At this time, the width of the short side of the bone support hole 425 is formed larger than the width of the bone discharge passage (417).

On the other hand, the stopper 435 of the present embodiment has a structure different from the previous embodiments. That is, the stopper 435 is formed to have a smaller length than the drill body 411 to limit the depth of the drill 400 to be drilled, by combining the stopper 435 of various lengths can be drilled to the desired depth . The stopper 435 has a hollow pipe shape to surround the outer peripheral area of the drill body 411.

A locking portion 437 for attaching and detaching the stopper 435 to the drill body 411 is provided on the inner circumference of the stopper 435. Although the locking portion 437 may be provided in various ways, in the present embodiment, the locking portion 437 includes a plurality of balls 439 and a ball (439) which are installed to be movable in a radial direction on the inner circumference of the stopper 435. A plurality of springs 441 for elastically supporting the 439 is provided.

The ball 439 has a spherical shape, and one region protrudes from the inner circumference of the stopper 435. The spring 441 is accommodated in the inner circumference of the stopper 435 to elastically support one side of the ball 439. On the other hand, the ball 439 of the locking portion 437 is engaged with the removable groove 445 formed in the drill body 411 during the drilling operation. The detachable groove 445 has a cross-sectional shape of a semicircle corresponding to the cross-sectional shape of the ball 439.

Thus, the ball 439 of the engaging portion 437 is held in the removable groove 445 of the drill body 411, the stopper 435 is mounted to the drill body 411, in particular, the ball 439 is drilled It is installed to be movable toward the removable groove 445 of the body 411 so that the stopper 435 can be easily attached to the drill body 411. In addition, the implant operator can selectively mount the stopper 435 of various lengths to the drill 400 according to the present invention in accordance with the shape and position of the various alveolar bone 5 to stably perforate.

In the fourth embodiment described above, the locking portion is formed on the inner circumference of the stopper, and the removable groove is formed on the outer circumference of the drill body, but the removable groove is formed on the inner circumference of the stopper, and the locking portion is formed on the outer circumference of the drill body. It may be formed.

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.

As described above, according to the present invention, it is possible to reduce the number of puncture operations of the alveolar bone during the implantation procedure while preventing the necrosis of the alveolar bone by preventing excessive heat generation during the puncture, thereby shortening the implant procedure time. In addition, the implant procedure can be made easier than before. This can also minimize the discomfort of the patient.

In addition, by being detachably coupled to the drill body, and having a stopper for limiting the depth of the hole to be drilled when drilling the hole in the alveolar bone, it can be stably drilled in response to the shape and position of the various alveolar bone.

Claims (21)

A drill body in which a bone accommodating part is accommodated to accommodate the bone of the alveolar bone when a hole is drilled in the alveolar bone; A plurality of cutting edges formed at the end of the drill body to drill holes in the alveolar bone when the drill body is rotated; And A plurality of bone discharge passages having a torsion angle on the outer circumference of the drill body and recessed from the surface of the drill body, for guiding discharge of the bone fragments of the alveolar bone generated when the alveolar bone is drilled; And The drill for implant treatment, characterized in that it is formed through the drill body so as to communicate with the bone receiving portion, the bone receiving hole having a shape of a long hole formed parallel to the longitudinal direction of the drill body. The method of claim 1, The end of the plurality of bone discharge passage, the drill for the implant procedure, characterized in that the processing is in the form of a blade so as to puncture the alveolar bone together with the plurality of cutting edges. delete delete The method of claim 1, On the surface of the drill body is formed a symmetrical mutually and a pair of incision surface formed vertically cut along the longitudinal direction of the drill body, The bone support hole is implant implant, characterized in that each formed on the pair of incision surface. The method of claim 1, The drill for implant treatment, characterized in that the insertion depth display pattern for displaying the insertion depth of the drill body to be inserted into the alveolar bone is further formed on the surface of the drill body. The method of claim 6, The insertion depth display pattern is a drill for implant treatment, characterized in that having a band shape surrounding the outer surface of the drill body. The method of claim 1, Removably coupled to the drill body, the drill for implant treatment, characterized in that it further comprises a stopper for limiting the depth of the hole to be punctured when drilling the hole in the alveolar bone. The method of claim 8, The stopper is detachably coupled to the upper end of the inner wall surface of the drill body via the bone receiving portion, Any one of the upper end of the inner wall surface of the stopper and the drill body is formed with a male thread, and the other is a female thread drill, characterized in that the female threaded portion is formed screwed. The method of claim 9, The male screw portion is formed in the stopper, and the female screw portion is formed in the upper end of the inner wall surface of the drill body drill for implant treatment. The method of claim 10, The stopper is, A shaft portion having an external thread formed on an outer surface thereof; And A head portion connected to the shaft portion and larger in diameter than the shaft portion, Drill for implant treatment, characterized in that the head is further formed with a tool insertion groove. The method of claim 1, The cutting edge is an implant treatment drill, characterized in that having an angle of 0 degrees to 45 degrees with respect to the axis of the drill body. The method of claim 1, And a shank portion extending coaxially with the drill body and extending in a longitudinal direction from one end of the drill body. A drill body in which a bone accommodating part is accommodated to accommodate the bone of the alveolar bone when a hole is drilled in the alveolar bone; A plurality of cutting edges formed at the end of the drill body to drill holes in the alveolar bone when the drill body is rotated; And A plurality of bone discharge passages having a torsion angle on the outer circumference of the drill body and recessed from the surface of the drill body, for guiding discharge of the bone fragments of the alveolar bone generated when the alveolar bone is drilled; And An implant treatment drill, characterized in that it is formed on the path of the bone discharge path, and includes a bone auxiliary hole formed radially with respect to the axis of the drill body. The method of claim 14, The width of the short side of the bone auxiliary accommodation hole is implant drill, characterized in that larger than the width of the bone discharge passage. The method of claim 8, The upper end of the drill body is formed with a removable groove recessed from the outer surface, The stopper is a drill for implant operation, characterized in that the engaging portion is provided detachably coupled to the removable groove of the drill body. The method of claim 16, The locking portion, A plurality of balls installed in a radial direction on an inner circumference of the stopper; And And a plurality of springs elastically supporting the ball on the stopper. A drill body in which a bone accommodating part is accommodated to accommodate the bone of the alveolar bone when a hole is drilled in the alveolar bone; A plurality of cutting edges formed at the end of the drill body to drill holes in the alveolar bone when the drill body is rotated; And Removably coupled to the drill body, the drill for implant treatment, characterized in that it comprises a stopper for limiting the depth of the hole to be drilled when drilling the hole in the alveolar bone. The method of claim 18, The stopper is detachably coupled to the upper end of the inner wall surface of the drill body via the bone receiving portion, Any one of the upper end of the inner wall surface of the stopper and the drill body is formed with a male thread, and the other is a female thread drill, characterized in that the female threaded portion is formed screwed. The method of claim 19, The male screw portion is formed in the stopper, and the female screw portion is formed in the upper end of the inner wall surface of the drill body drill for implant treatment. The method of claim 20, The stopper is, A shaft portion having an external thread formed on an outer surface thereof; And A head portion connected to the shaft portion and larger in diameter than the shaft portion, Drill for implant treatment, characterized in that the head is further formed with a tool insertion groove.

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