KR20120100250A - Bone scrapper - Google Patents

Abstract

PURPOSE: A bone scrapper is provided to supply a bond crushing function and a bond collecting function with a simple structure, thereby increasing the efficiency of an implant operation. CONSTITUTION: An empty tubular object is formed in a tubular rotator(110). The tubular rotator includes a columnar cutter(111a). A drill type rotator includes a drill plate unit(131) and a drill pin(132). The drill plate unit is inserted into the tubular rotator. The drill pin is connected to the drill plate unit. A pair of first inclined intervals and a first straight interval are formed on the surface of a section of the drill plate unit.

Description

Bone Scraper

The present invention relates to a bone harvester, and more particularly, to a bone harvester having a simple and simple structure, which can provide both a grinding function and a harvesting function of the bone, thereby improving the efficiency and reliability of the implant procedure. It is about.

Implant means a substitute that recovers when human tissue is lost. However, in dentistry, implantation of artificial teeth is called implant. In other words, implants made of titanium (titanium), which are not rejected by the human body, are implanted in the alveolar bone where the teeth fall out to replace the lost roots (roots), and the implant is fixed to restore the function of the teeth. do.

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 uses a predetermined drill to drill the position of the implantation (positioning), then implants the fixture into the alveolar bone, fused the bone to the bone, and then attaches the abutment to the fixture. This is done by putting the final prosthesis on the abutment.

This implant procedure improves the function of dentures, improves the aesthetic aspects of dental prosthetic restorations, as well as disperses excessive stresses on surrounding supportive bone tissue, as well as single missing restorations. It also helps to stabilize the teeth.

On the other hand, in the above-described implant procedure, when the alveolar bone is inherently or acquired, or depressed so much that it is insufficient to fix the fixture, artificial bones or synthetic bones are implanted into the lacking joints to raise the alveolar bone, and then drilling The implant procedure will be performed.

However, in the case of artificial bone or synthetic bone, it may cause biotrouble with the alveolar bone, or the tissue may not be transplanted well due to the wrong tissue. Therefore, various instruments for collecting autologous bone, that is, bone extractors, have been researched and developed in implant procedures.

However, the bone harvester known to date has a structure for collecting bone, but does not perform a function of grinding a relatively solid bone is required for efficient structural improvement.

SUMMARY OF THE INVENTION An object of the present invention is to provide a bone harvester having a simple and simple structure, which can provide both a grinding function and a harvesting function of bone, thereby improving the efficiency and reliability of an implant procedure.

The object is a tubular rotary body provided with a hollow inside (pipe) and the cylindrical cutter is formed along the circumferential direction at the end; And a drill rotator having a drill plate part coupled to be partially inserted into the tubular rotator, and a drill pin connected to the drill plate and having an end portion exposed to the outside of the tubular rotator. And, the end surface of the drill plate portion to which the drill pin is connected is achieved by a bone harvester, both sides are formed symmetrically with each other with the drill pin interposed, and having a non-linear shape.

An end surface of the drill plate portion may include a pair of first inclined sections formed to be inclined toward both sides of the drill pin at both sides of the drill plate portion; And a first straight section provided in a straight line between the pair of first inclined sections to which the drill pin is connected.

The drill pin may have a shape in which the width gradually narrows from the connection region of the drill plate to the exposed end.

At least one coupling protrusion may be provided at any one of the tubular rotating body and the drill-type rotating body, and the other protrusion may have a protrusion groove to which the coupling protrusion is detachably coupled.

The drill-shaped rotating body may further include a handle partially connected to the shank portion.

The end surface of the drill plate portion may have an arc shape.

An end surface of the drill plate portion may include a pair of second inclined sections formed to be inclined toward both sides of the drill pin at both sides of the drill plate portion; A pair of second straight sections provided in a straight line toward the drill pin at the point where the pair of second inclined sections ends; A pair of third inclined sections formed to be inclined toward the drill pin at a point where the pair of second straight sections ends; And a third straight section provided in a straight line between the pair of third inclined sections to which the drill pin is connected.

According to the present invention, while having a simple and simple structure, the bone grinding function and the collecting function can be provided together, thereby improving the efficiency and reliability of the implant procedure.

1 is a perspective view of a bone harvester according to a first embodiment of the present invention,
Fig. 2 is an exploded perspective view of Fig. 1,
3 is a front view of FIG. 1,
4 is an enlarged view of area A of FIG. 3,
5 is an enlarged view of main parts of a bone extractor according to a second embodiment of the present invention;
6 is an enlarged view of main parts of a bone harvester according to a third embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

1 is a perspective view of a bone harvester according to a first embodiment of the present invention, FIG. 2 is an exploded perspective view of FIG. 1, FIG. 3 is a front view of FIG. 1, and FIG. 4 is an enlarged view of region A of FIG. 3.

Referring to these drawings, the bone harvester of the present embodiment largely includes a tubular rotary body 110, a drill-shaped rotary body 130, and a handle 150.

The tubular rotating body 110 may have a hollow tubular body, that is, a pipe shape. At the end of the tubular rotary body 110, as shown in FIG. 1, a cylindrical cutter 111a is formed along the circumferential direction.

The cylindrical cutter 111a serves to grind or drill the bone while digging a relatively hard bone.

The spiral cutter 111b is further formed on the outer side of the tubular rotating body 110. The spiral cutter 111b allows the tubular rotary body 110 to dig into the valley. An insertion depth display portion 111c is further formed on the outer surface of the tubular rotating body 110 to visually check the insertion depth of the tubular rotating body 110.

Thus, when the cylindrical cutter 111a is formed at the end of the tubular rotating body 110, and the tubular rotating body 110 has a pipe shape, and there is no drill-shaped rotating body 130, the collected bone is approximately It may have a cylindrical shape.

However, since the drill-shaped rotating body 130 is operated together to crush the bone, the collected bone may have various shapes including a cylindrical shape.

The drill-type rotating body 130 is coupled to the tubular rotating body 110 serves to crush the bone.

The drill-shaped rotating body 130 is connected to the drill plate 131 and the drill plate 131 coupled to be partially inserted into the tubular rotating body 110, the end of the tubular rotating body 110 The drill pin 132 is provided to be exposed to the outside.

At this time, the end surface of the drill plate 131 to which the drill pin 132 is connected is formed symmetrically with both sides with the drill pin 132 therebetween, and has a non-linear shape.

This will be described in detail with reference to FIG. 4. In this embodiment, the end surface of the drill plate 131 is a pair of first inclined section 131a which is formed to be inclined toward the drill pin 132 on both sides of the drill plate 131, a pair of first inclination A straight line is provided between the sections 131a and includes a first straight section 131b to which the drill pin 132 is connected.

Thus, the end surface of the drill plate 131 has a non-linear shape consisting of a pair of the first inclined section 131a and the first straight section 131b, the drill pin 132 in the first straight section (131b) By having a structure that is connected, the grinding efficiency of the bone can be increased.

In other words, the crushing efficiency of the bone can be increased because of its large surface area and the crushing of the bone in contact with the bone in any angular direction that is not straight.

The drill pin 132 has, for example, an awl shape in which the width gradually narrows from the connection region of the drill plate 131, that is, the first straight section 131b to the exposed end. The cross section of the drill pin 132 may be circular but may be polygonal. The exposed length of the drill pin 132 may be appropriately designed. This drill pin 132 serves to guide the initial drilling position.

On the other hand, the tubular rotating body 110 and the drill-shaped rotating body 130 is coupled only in use, it should be separated in normal or wash. To this end, coupling protrusions 135 and protrusion grooves 115 are formed in the tubular rotary body 110 and the drill-shaped rotary body 130, respectively.

Coupling protrusion 135 is formed to protrude radially outward from the outer surface of the body portion 134 of the drill-shaped rotating body 130. Coupling protrusion 135 is provided in pairs on both sides of the body portion 134 of the drill-shaped rotating body 130.

And the projection groove 115 is provided in the form of a non-linear groove on both sides of the outer surface of the tubular rotating body 110 is utilized as a place where the coupling projection 135 is coupled.

Since the protrusion groove 115 is provided in the form of a non-linear groove, the coupling protrusion 135 is inserted into the protrusion groove 115 when the tubular rotating body 110 and the drill rotating body 130 are coupled to each other. By rotating the drill-shaped rotor 130, the tubular rotor 110 and the drill-type rotor 130 may be coupled to each other.

The drill-shaped rotary body 130 is provided with a shank portion 138 on the opposite side of the drill plate portion 131 based on the body portion 134. The shank portion 138 is a portion that is connected to a tool such as, for example, a dental hand piece. In this embodiment, the handle 150 is connected to the shank portion 138.

The handle 150 includes a connection part 151 connected to the shank part 138 and a grip part 152. The gripping portion 152 is provided with a slip prevention pattern 152a as shown. The anti-slip pattern 152a may be an uneven pattern or a rubber pad.

Between the body portion 134 and the shank portion 138 of the drill-shaped rotating body 130, a flange portion 139 is formed larger than the diameter of the body portion 134 is formed.

As described above, the shank portion of the drill-shaped rotating body 130 after the tubular rotating body 110 and the drill-shaped rotating body 130 are coupled using the coupling protrusion 135 and the protrusion groove 115. Connect the handle 150 to (138), and then crush or collect the bone while rotating the handle 150.

As such, according to the present embodiment, while having a simple and simple structure, the bone grinding function and the collecting function can be provided together, thereby improving the efficiency and reliability of the implant procedure.

5 is an enlarged view of main parts of a bone harvester according to a second embodiment of the present invention.

Referring to this figure, the end surface 231a of the drill plate portion 231 of the drill-shaped rotating body 230 has an arc shape.

As such, even if the end surface 231a of the drill plate 231 has an arc shape, the crushing efficiency of the bone may be improved because the end surface 231a forms a wide contact surface with the bone during the grinding operation.

6 is an enlarged view of main parts of a bone harvester according to a third embodiment of the present invention.

Referring to this figure, the end surface of the drill plate 331 of the drill-shaped rotating body 330 is a pair of second inclined section formed to be inclined toward the drill pin 332 from both sides of the drill plate 331. 331a, a pair of second straight sections 331b provided in a straight line toward the drill pin 332 at the point where the pair of second inclined sections 331a end, and a pair of second straight sections The drill pin 332 is provided in a straight line between the pair of third inclined sections 331c and the pair of third inclined sections 331c which are formed to be inclined toward the drill pin 332 at the point at which the 331b ends. The third straight section 331d is connected thereto.

Even though the end surface of the drill plate 331 has a shape as shown in FIG. 6, the grinding surface of the drill plate 331 may increase the grinding efficiency of the bone because the end surface of the drill plate 331 forms a wide contact surface with the bone.

Although the present embodiment has been described in detail with reference to the drawings, the scope of the present invention is not limited to the above-described drawings and descriptions.

In the above-described embodiment, the coupling protrusion 135 is provided on the drill-type rotating body 130, and the protrusion groove 115 is provided on the tubular rotating body 110, but vice versa. In other words, the coupling protrusion 135 may be provided in the tubular rotary body 110, and the protrusion groove 115 may be provided in the drill-type rotary body 130.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

110: tubular rotating body 111a: cylindrical cutter
115: engaging projection 130: drill type rotating body
131: drill plate 131a: first inclined section
131b: first straight section 132: drill pin
135: projection groove 138: shank portion
150: handle

Claims (7)

A tubular rotary body provided with a hollow tubular body and having a columnar cutter formed along the circumferential direction at an end thereof; And
And a drill-type rotating body having a drill plate part coupled to be partially inserted into the tubular rotating body, and a drill pin connected to the drill plate part and having an end portion exposed to the outside of the tubular rotating body. ,
An end surface of the drill plate portion to which the drill pin is connected is formed on both sides symmetrically with the drill pin interposed, but having a non-linear shape, bone harvester.
The method of claim 1,
The end surface of the drill plate portion,
A pair of first inclined sections formed to be inclined toward both sides of the drill pin at both sides of the drill plate; And
A bone extractor comprising a first straight section provided in a straight line between the pair of first inclined section is connected to the drill pin.
The method of claim 1,
The drill pin is a bone harvester having a shape that gradually narrows in width from the connection region of the drill plate toward the exposed end.
The method of claim 1,
At least one coupling protrusion is provided on any one of the tubular rotary body and the drill-shaped rotary body, and the other is a bone harvester, characterized in that a protrusion groove is formed to be detachably coupled to the coupling protrusion.
The method of claim 1,
The bone harvester further comprises a handle that is partially connected to the shank portion to the drill-like rotating body.
The method of claim 1,
And the end surface of the drill plate portion has an arc shape.
The method of claim 1,
The end surface of the drill plate portion,
A pair of second inclined sections formed to be inclined toward both sides of the drill pin on both sides of the drill plate;
A pair of second straight sections provided in a straight line toward the drill pin at the point where the pair of second inclined sections ends;
A pair of third inclined sections formed to be inclined toward the drill pin at a point where the pair of second straight sections ends; And
A bone extractor comprising a third straight section provided in a straight line between the pair of third inclined section is connected to the drill pin.

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