KR20190010996A - Drill for dental surgery - Google Patents

Abstract

The present invention relates to a drill for a dental procedure and, more specifically, to a drill for a dental procedure which easily aligns the center to a drilling position of an alveolar bone, and reduces friction heat produced in the alveolar bone. The drill for a dental procedure comprises a body unit, a drill blade unit, a guide, and a stopper. The drill blade unit has a drill blade extended from one end of the body unit to cut an alveolar bone. The guide protrudes from one end of the body unit in a radial direction to be inserted into a guide ring to be slid to guide the drill blade unit in an axial direction of the guide ring to guide a drilling position of the alveolar bone, and has a flow passage groove formed on the outer circumferential surface thereof to supply water to the drill blade unit through the guide ring. The stopper protrudes from the outer circumferential surface of the body unit in the radial direction to prevent the drill blade unit from being inserted into the alveolar bone deeper than a prescribed depth by coming in contact with an upper end of the guide ring, and has a groove to inject water into the guide ring. According to the present invention, the guide is inserted into the guide ring to guide a drilling position of the alveolar bone to slide to easily align the center of the drill during a drilling job. Water can be injected into the groove formed on the stopper to supply water to the drill blade unit to reduce friction heat produced in the alveolar bone. Also, according to the present invention, the drill blade is formed in multiple steps to have a diameter becoming smaller towards the end thereof to simultaneously drill grooves with different diameters in accordance with the depths in machining grooves for implanting fixtures. Therefore, drilling work time can be reduced.

Description

Drill for dental surgery

The present invention relates to a dental drill, and more particularly, to a dental drill capable of easily aligning the center of the drill with the drilling position of the alveolar bone and reducing frictional heat generated in the alveolar bone.

When the implant is performed, a drill is used to drill the alveolar bone to be implanted, and the screw is screwed into the groove. When the screw is screwed into the groove, the screw is screwed into the groove. After the abutment is attached to the upper part of the fixture fastened to the alveolar bone and the final restoration is put on the abutment, the implant operation is completed.

Drilling of the alveolar bone is an important task for determining the position, depth and direction of the implant. In the past, a drill was inserted into a guide ring for guiding the drill so as to fit the insertion direction and angle of the fixture, Were drilled. At this time, frictional heat is generated in the alveolar bone in contact with the cutting edge of the drill due to the rotation of the drill, and when the drill is rotated at a high speed, the alveolar bone is damaged.

In addition, since the drilling operation is performed through various steps while enlarging the diameter of the drilling using drills having different diameters, there is a problem that the drilling operation takes a long time due to the process of replacing the drill.

Registration No. 10-0946344 (Registered on Mar. 3, 2010) Registration No. 10-1066987 (Registration date September 16, 2011) Registration No. 10-0893287 (Registered on Apr. 4, 2009)

The present invention is intended to solve the above problems. An object of the present invention is to provide a dental treatment drill which can easily align the center of the bone with the drilling position of the alveolar bone and reduce the heat of friction occurring in the alveolar bone.

It is another object of the present invention to provide a drill for drilling a dental prosthesis which is capable of perforating a groove having a different diameter according to the depth at a time.

The dental treatment drill according to the present invention includes a body portion, a drill portion, a guide, and a stopper. The drill bit portion extends from one end of the body portion to form a drill blade for cutting the alveolar bone. Wherein the guide is inserted into the guide ring so as to be guided in an axial direction of a guide ring for guiding the drilling position of the alveolar bone and is radially protruded from one end of the body so as to be slidable, A channel groove through which water can be supplied is formed by the drill bit portion. The stopper is in contact with an upper end of the guide ring and protrudes in a radial direction from the outer circumferential surface of the body so that the drill bit is not inserted into the alveolar bone beyond a certain depth, and a groove into which water can be injected is formed in the guide ring .

In the dental drill described above, it is preferable that the guide is formed of a contact portion, a first taper portion, and a second taper portion. The contact portion is in contact with the inner circumferential surface of the guide ring. The first tapered portion is tapered so that the diameter becomes smaller toward the upper side along the axial direction at the contact portion so as to form 0 to 10 degrees with the inner circumferential surface of the guide ring. The second tapered portion is tapered so as to have a smaller diameter along the axial direction at the contact portion so as to form 0 to 10 degrees with the inner circumferential surface of the guide ring.

In the above dental drill, it is preferable that the flow path groove is connected to the valley of the drill bit portion.

Alternatively, in the dental treatment drill described above, it is preferable that the drill bit is formed in a multi-stage so that the diameter becomes smaller toward the end.

In the dental drill, it is preferable that each end of the drill bit has a larger diameter as it goes to the end.

According to the present invention, since the guide is inserted into the guide ring guiding the drilling position of the alveolar bone to slide, the center of the drill can be easily aligned during the drilling operation, water can be supplied to the groove formed in the stopper, Thereby reducing the friction heat generated in the alveolar bone.

In addition, according to the present invention, since the drill bit is formed in a multi-stage so that the diameter becomes smaller toward the end, grooves having diameters different from each other can be drilled at one time in the groove machining for fitting the fixture. So drilling time can be reduced.

1 is a sectional view of an embodiment of a drill for dental treatment according to the present invention.
2 is a plan view of the embodiment shown in Fig.

An embodiment of a dental drill according to the present invention will be described with reference to Figs. 1 and 2. Fig.

A dental treatment drill 1 according to the present invention includes a body 10, a guide 20, a stopper 30, and a drill blade 40.

The body 10 is fixedly coupled to a driving device for driving the drill 1 for dental procedures.

The guide 20 guides the drill bit 40 along a guide ring (not shown) such that it is perforated in accordance with the insertion direction and angle of the fixture when grooving to fix the fixture. For this purpose, the guide 20 is inserted into a guide ring for guiding the perforation position of the alveolar bone and protrudes in a radial direction from one end of the body 10 so as to be able to slide. At this time, the guide 20 is formed of the contact portion 22, the first tapered portion 24 and the second tapered portion 26, and the water can be supplied to the drilled blade portion 40 through the guide ring, Grooves 21 are formed. The contact portion 22 preferably has a diameter equal to the inner diameter of the guide ring so as to be in contact with the inner circumferential surface of the guide ring. The first tapered portion 24 is tapered so that its diameter becomes smaller toward the upper side along the axial direction in the contact portion 22. When the guide 20 is realized by only the contact portion 22, there is a lot of friction with the guide ring, so that sliding in the axial direction may not be smooth. So that the upper portion of the guide 20 tapers to reduce friction. At this time, it is preferable that the first tapered portion 24 is tapered to form 0 to 10 degrees with the inner peripheral surface of the guide ring. This is because when the inclination angle of the first tapered portion 24 is too large, the drill 1 can be pivoted in the right and left direction instead of sliding directly in the guide ring in the axial direction. The second tapered portion 26 is tapered so as to have a smaller diameter toward the bottom along the axial direction at the contact portion 22 so as to form 0 to 10 degrees with the inner peripheral surface of the guide ring. The second tapered portion 26 also reduces the friction with the guide ring like the first tapered portion 24 and is inclined so as to reduce the diameter of the lower portion so that the drill 1 can be easily inserted have. The channel groove 21 is formed on the outer circumferential surface of the guide 20 so that water supplied into the guide ring can be supplied to the drill bit 40. At this time, the flow path groove 21 is connected to the valley of the drill bit portion 40. Since the contact portion 22 is in close contact with the guide ring, water is not supplied to the drill portion 40 even if water is supplied from the outside of the guide ring unless the flow groove 21 is formed. In order to prevent this, the flow path groove 21 is formed so that water can be supplied to the outer circumferential surface of the guide 20.

The stopper 30 serves to prevent the drill bit portion 40 from being inserted into the alveolar bone beyond a predetermined depth. For this purpose, the stopper 30 protrudes in the radial direction from the outer circumferential surface of the body portion 10 so as to come into contact with the upper end of the guide ring. At this time, the stopper (30) is formed with a groove (31) for supplying water to the inside of the guide ring from the outside. It is preferable that a plurality of grooves 31 are formed to facilitate injection of water. During drilling, the alveolar bone is overheated due to the friction with the drill, so if the drill rotates at high speed, the alveolar bone is damaged. When water is supplied from the outside to the groove 31, the water moves to the drill bit 40 along the channel groove 21 formed on the outer circumferential surface of the guide 20, thereby preventing the alveolar bone from being overheated.

The drill blade portion 40 is formed with a drill blade 41 extending from one end of the body portion 10 to cut the alveolar bone. At this time, the drill blade 41 is formed in a multi-stage so that the diameter becomes smaller toward the end. The ends of the drill blades 41 are formed so as to have a larger diameter. That is, the step 42 is formed such that the lower diameter a is larger than the upper diameter b. Therefore, the drill can cut the alveolar bone better. In the conventional case, the drilling operation is performed through various steps while enlarging the diameter of the perforation using drills having different diameters, which takes a long time due to the process of replacing the drill. If the drill blades 41 are formed in a multi-step manner so that their diameters decrease toward the end portions, grooves having diameters different from each other can be drilled at one time, thereby reducing drilling operation time.

1: drill for dental treatment 10:
20: Guide 21: Euro home
22: contact portion 24: first taper portion
26: second tapered portion 30: stopper
31: groove 40: drill blade
41: drill blade 42: stage

Claims (5)

A body portion,
A drill blade portion extending from one end of the body portion and having a drill blade for cutting the alveolar bone,
Wherein the drill bit is inserted into the guide ring so as to be guided in an axial direction of a guide ring for guiding the drilling position of the alveolar bone and is radially protruded from one end of the body portion so as to be slidable, A guide formed with a flow path groove through which water can be supplied,
And a stopper protruding in a radial direction from an outer circumferential surface of the body so as not to be inserted into the alveolar bone by a predetermined depth or more in contact with an upper end of the guide ring and having a groove into which water can be injected into the guide ring, Wherein the drill is a dental drill. 2. The apparatus of claim 1, wherein the guide
A contact portion contacting the inner circumferential surface of the guide ring,
A first tapered portion tapered to have a smaller diameter toward the upper side along the axial direction at the contact portion so as to form 0 to 10 degrees with the inner peripheral surface of the guide ring,
And a second tapered portion tapered to have a smaller diameter along the axial direction at a lower portion of the contact portion so as to form an angle of 0 to 10 with the inner circumferential surface of the guide ring. 3. The method of claim 2,
And the channel groove is connected to the valley of the drill bit portion. 4. The method according to any one of claims 1 to 3,
Wherein the drill bit is formed in a multi-stage so that the diameter becomes smaller toward the end. 5. The method of claim 4,
Wherein each end of the drill bit is formed to be larger in diameter as it goes to the end.

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