KR102052693B1 - Initial Drill with tissue punching function - Google Patents

Abstract

The present invention relates to an initial drill for dental implant surgery, and more particularly, the process of cutting and removing the gingiva using a tissue punch during the conventional fixture placement procedure through a second cutting blade of a subcutaneous narrowing form is omitted. The second cutting blade partially crushes the gingiva, which shortens the recovery time of the gingiva and prevents scars from being cut and removed by using a tissue punch. In accordance with the present invention relates to an initial drill having a tissue punching function that can be performed in the correct direction without drilling in the position where the fixture within the alveolar bone is to be placed to improve the reliability of the fixture placement procedure.
To this end, the present invention is formed in the mounting portion coupled to the rotary tool for the implant and extending in the axial direction from the lower end of the mounting portion is extended to the guide support portion and the guide support portion that is rotated through the guide hole of the guide stent, It includes an inclined portion is formed in the inclined surface and the cutting edge portion extending to the bottom of the inclined portion to perform drilling at the position where the fixture in the alveolar bone is to be placed, wherein the inclined portion of the alveolar bone at the position where the fixture is placed The second cutting blade to be broken is formed.

Description

Initial Drill with Tissue Punching Function

The present invention relates to an initial drill for dental implants, and more particularly, a tissue that partially drills a gingival at a position where a fixture is to be placed while drilling is performed at a precise depth and direction without slipping at a position where the fixture in the alveolar bone is to be placed. It relates to an initial drill having a punching function.

In general, an implant means a substitute that can replace human tissue when the original human tissue is lost, but in the dentist, an implanted artificial tooth is implanted. In the case of a general prosthesis or denture, the surrounding teeth and bones are damaged over time, but the implant can prevent damage to the surrounding dental tissue and can be used stably because there is no secondary decay factor. In addition, since the implant has the same structure as the natural teeth, there is no pain and foreign body feeling of the gums, and there is an advantage that can be used semi-permanently if you manage well.

Briefly describing the method of implantation, the alveolar bone is exposed by exposing the gingival of the patient to be implanted first. Next, the position of the implant to be inserted among the exposed alveolar bone is determined and a portion of the alveolar bone is deleted by using a drilling tool such as a drill at the position to form a recess for implanting the implant. In general, when implanting the gingival to expose the alveolar bone during the implantation procedure and then drill directly on it, it is difficult to accurately determine the exact position and direction to perform the drilling operation. Use a separate drilling tool that is inserted into the guide hole of the guide stent to be rotated and supported.

The drilling tool is a tissue punch to remove the gingival at the position where the fixture is to be placed before the drilling operation, and a reamer and an insertion position for cutting the inner surface of the guide hole to form a groove to a size substantially equal to or slightly smaller than the diameter of the fixture. Drill set and fixture consisting of a plurality of drills according to the diameter and depth are drilled by gradually increasing the diameter size according to the diameter and the depth of implantation of the initial drill to be drilled and the initial drill after drilling the initial drill An end side is inserted into the groove portion formed on the upper surface of the fixture to include a fixture driver to rotate. When the groove is formed, the implant including the fixture and the abutment is implanted in the groove and the implant is completed by covering the gingiva.

1 is a view showing a conventional initial drill, Figure 2 is a view showing a state of drilling the alveolar bone 50 using a conventional initial drill.

Referring to FIG. 1, the initial drill is inserted into the cutting part 2 and the guide hole of the guide stent for drilling to form a groove in the alveolar bone, and a guide part 3 which is rotated and supported along the inner circumferential surface of the guide hole. Regardless of the diameter of the cutting part 2 and the diameter of the guide part 3 and the inclined part 6 and the drill diameter, the same shape and dimensions correspond to the drill mounting part of the rotary tool for implants. It consists of a mounting portion (4) formed by.

 The rotational tool for the implant here comprises a ball bearing handpiece or an air bearing handpiece or an electric slow micromotor handpiece or an air slow micromotor handpiece or a contra-angle or straight handpiece.

In addition, the cutting portion includes a tip portion 5 for performing drilling in contact with the surface to be cut, and is discharged to the outside so that the born chip generated during the drilling process does not remain in the buried groove formed for implantation of the fixture. It includes a chip discharge groove (9).

In general, the tip portion 5 is formed at the tip of the drill to be in contact with the rotating shaft, the chisel portion 8 and the blade that is first contacted with the surface to be cut and the thrust is most received at the tip during the drilling process for forming the groove groove It includes a cutting edge (7) which is the intersection of the inclined plane and the clearance plane to form the tip.

Referring to FIG. 2, the conventional initial drill is sharply formed in front of the guide hole H even when the shape of the alveolar bone 50 is inclined or curved when the fixture F is placed. Therefore, the tip of the cutting edge slips when contacting the gingiva, which causes a problem that the groove is formed by leaving the desired point.

In addition, when the gingival was precisely punched out using a tissue punch, there was a problem that the wound was hardly healed and the scars remained after recovery.

Republic of Korea Utility Model Registration 20-0467202 (2013.05.27.)

SUMMARY OF THE INVENTION The present invention has been made to solve various problems including the above problems, and an object of the present invention is to shorten the recovery time of the gingiva and scars than when the second cutting blade is partially cut and removed using a tissue punch. It is to provide an initial drill having a tissue punching function that does not remain.

In addition, the object of the present invention is that the cutting edge of the cutting edge portion is made in a round shape so that the drilling is performed in the correct direction without slipping in the position where the fixture in the alveolar bone is to be implanted to improve the reliability of the tissue implantation procedure Branches provide initial drills.

The present invention has the following features to achieve the above object.

The present invention is inserted into the guide hole of the guide stent formed to surround a portion of the teeth or gingiva, and is rotated and supported, so that the fixture in the alveolar bone can be implanted as the drilling is performed precisely in the desired position An initial drill comprising: a mounting portion coupled to the implant rotary tool; and a guide counterpart extending in the axial direction from the lower end of the mounting portion and being rotatably supported through the guide hole of the guide stent; and an extension formed at the bottom of the guide counterpart. And an inclined portion having an inclined surface in the form of an ordinary light subsoil; and a cutting edge portion which is formed at the bottom of the inclined portion to perform drilling at a position where the fixture in the alveolar bone is to be placed; A second cutting blade for partially crushing the alveolar upper gingiva is formed.

In addition, the guide corresponding part is formed to have a diameter larger than the diameter of the guide portion and the guide portion that is accommodated in the guide hole and the rotation of the guide portion is mounted on the upper outer surface of the upper guide hole when the initial drill is inserted into the guide hole Accordingly, the initial drill is characterized in that it comprises a stepped portion so that it is no longer drawn in the desired depth.

In addition, the cutting edge is characterized in that the front end surface is formed in a round shape so that drilling is carried out to the correct position without slipping at the position where the fixture is to be placed, the inclined surface of the inclined portion has a pi (α) with a horizontal line of 1 ° to It is characterized by being formed at 89 °.

According to the present invention, the process of cutting and removing the gingiva using a tissue punch during the conventional fixture placement procedure is omitted through the second cutting blade in the form of a subcutaneous strait, thereby reducing the procedure time, and the second cutting blade is the gingiva. Partial crushing has the effect of shortening the recovery time of the gingiva and leaving no scars than cutting and removing the tissue using a punch.

In addition, since the cutting edge of the cutting edge is formed in a round shape, drilling is performed in the correct direction without slipping at the position where the fixture in the alveolar bone is to be placed, thereby improving the reliability of the fixture placement procedure.

1 is a view showing a conventional initial drill.
2 is a view showing a state of drilling the alveolar bone 50 using a conventional initial drill.
3 is a view showing the initial drill 100 having a tissue punching function according to an embodiment of the present invention.
4 is a view showing a second cutting blade 41 of the inclined portion 40 according to an embodiment of the present invention.
FIG. 5A is a view showing a state in which the gingiva is partially crushed using the second cutting blade 41 according to the embodiment of the present invention.
Figure 5 (b) is a view showing a state of punching the gingiva using a tissue punch.
6 is a view showing the front end surface 31 of the cutting edge portion 30 according to an embodiment of the present invention.
7 is a view showing a state of drilling the alveolar bone 50 using the initial drill 100 having a tissue punching function according to an embodiment of the present invention.

In order to explain the present invention, the operational advantages of the present invention, and the object achieved by the practice of the present invention, the following describes exemplary embodiments of the present invention and looks at it with reference thereto.

First, the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention, and singular forms may include plural forms unless the context clearly indicates otherwise. Also in this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof described on the specification, one or more other It is to be understood that the present invention does not exclude the possibility of the presence or the addition of features, numbers, steps, operations, components, parts, or a combination thereof.

In describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

3 is a view showing an initial drill 100 having a tissue punching function according to an embodiment of the present invention, Figure 4 is a second cutting edge 41 of the inclined portion 40 according to an embodiment of the present invention 5 (a) is a view showing a partial fracture of the gingiva using the second cutting blade 41 according to an embodiment of the present invention, Figure 5 (b) is a tissue punch FIG. 6 is a view showing a state in which a gingival is punched using, FIG. 6 is a view showing a front end surface 31 of a cutting edge portion 30 according to an embodiment of the present invention, and FIG. FIG. 4 is a view illustrating a state in which the alveolar bone 50 is drilled using the initial drill 100 having a tissue punching function.

 Implant procedures are largely divided into flap implant surgery and flapless implant surgery. Flap implant surgery is a wide incision in the gingival before placing the fixture (F) in the alveolar bone (50), exposing the alveolar bone (50) by widening the flap composed of the periosteum and gum tissue, and then drilling The operation of the alveolar bone (50) through the operation to remove the internal bone to form a groove for implantation (F) after implantation of the fixture (F), and then re-collect the gingival to complete the implant surgery first, In flapless implant surgery, the alveolar bone is not exposed to the outside, that is, while the gingiva covers the alveolar bone 50, the drill passes through the gingiva 40 to delete the alveolar bone, and the groove is formed. Through the fixture (F) refers to the method of implantation in the alveolar bone (50).

 In the implant procedure, a guide stent (G) may be used that assists to perform stable drilling without shaking as much as a desired depth at an accurate position of the alveolar bone.

The guide stent (G) is formed in the housing surrounding the buccal, lingual and occlusal side of the at least one tooth is formed with a guide hole (H) for placing the fixture (F), the housing is a model that mimics the teeth of the subject It is produced by applying a resin of a transparent material so as to surround the gingiva and the appropriate number of teeth lost teeth and curing it.

Here, a sleeve may be inserted into an upper side of the guide hole H of the guide stent G to prevent deformation of the guide stent G due to heat generated when the drill is rotated.

Referring to the drawings, the initial drill 100 having a tissue punching function according to an embodiment of the present invention is formed extending in the axial direction from the mounting portion 10 and the lower portion of the mounting portion 10 coupled to the rotary tool for the implant and the guide The inclined portion 40 and the inclined portion extending from the guide counterpart 20 and the guide counterpart 20 which are rotated and supported through the guide hole H of the stent G, and the inclined surface is formed in the form of a light beam underneath. It is extended to the lower end portion includes a cutting edge 30 for drilling in the position where the fixture (F) in the alveolar bone 50 is to be placed.

Here, the mounting portion 10 may be formed in the same shape and dimensions corresponding to the drill mounting portion of the drill apparatus irrespective of the diameter of the drill. The mounting portion 10 is formed with a smaller diameter than the guide counterpart 20, the upper end is formed with a fixing groove formed along the circumference, the end is formed in a substantially D-cut shape is fixedly coupled to the rotary tool.

Meanwhile, the guide counterpart 20 includes a stepped part 22 and a guide part 21.

The stepped portion 22 is formed by forming a larger than the diameter of the guide hole (H) and the guide portion 21 so as not to be accommodated in the guide hole (H) of the guide stent (G) on the upper end of the guide corresponding portion (20) Preferably, the stepped portion 22 is a stopper for the initial drill 100 to be seated on the upper outer surface of the guide hole (H) of the guide stent (G) and to prevent the initial drill 100 from entering at a desired depth. The guide portion 21 is formed in a cylindrical shape at the lower side of the stepped portion 22 and is accommodated in the guide hole H and slides back and forth, and the cutting is performed along the forming direction of the guide hole F. It serves to guide the blade 30.

In addition, the guide portion 21 is rotated in the guide hole (H) to support the inside of the drilling process through the rotation of the cutting portion 30 in the drilling position of the desired fixture (F) without departing from the position of the mounting position shakes at the correct position Can be stably rotated to form a buried groove.

Meanwhile, an inclined portion 40 having an inclined surface in the form of an ordinary light narrow is formed between the guide portion 20 and the cutting edge portion 30 by the difference between the diameter of the guide portion 20 and the diameter of the cutting edge portion 30. The smaller the diameter of the blade 30 is, the smaller the pi is alpha. The inclined surface of the inclined portion 40 is formed with a bridge (α) of 1 ° to 89 ° with a horizontal line, more preferably may be formed of 40 ° to 70 °.

In addition, the inclined portion 40 may form a second cutting edge 41 along the inclined surface. Referring to Figure 4 (a, b) to cut and remove the upper gingiva of the target alveolar bone 50 before the drilling operation in the conventional fixture (F) implantation implants through the second cutting blade 41 of the upper and lower strait type The tissue punching operation is omitted, and the procedure time can be shortened. The second cutting blade 41 partially crushes the upper gingiva of the alveolar bone 50, thereby reducing the loss of gingiva than when the tissue punch is cut and removed. It is effective in shortening the recovery time and preventing scars.

In addition, by forming the pier (α) of the inclined portion 40 at a desired angle, the range of the upper gingiva loss portion of the alveolar bone 50 may be adjusted when drilling for fixing the fixture F is performed.

Meanwhile, the cutting edge part 30 includes a front end surface 31 having a round shape at the front end portion. In the present specification, the "round" shape is a concept including both a shape having a mixed shape of a curved section and a straight section or a semi-ellipse, such as a rounded corner. After the chisel portion of the cutting edge portion 30 first touches the surface of the alveolar bone 50, a groove is formed until the front end surface 31 contacts the surface of the alveolar bone 50, and the front end surface 31 is the alveolar bone ( When it comes into contact with 30, the cutting starts and the front end surface 31 completes the formation of the recess groove for placing the fixture (F).

The conventional initial drill described above is recessed or recessed even when the shape of the alveolar bone 50 at the position where the fixture F is to be inclined or curved is supported while being rotated inside the guide hole H, thereby leaving the desired point. This can be formed.

On the other hand, referring to Figure 7, the initial drill 100 of the present invention is rotated at a low speed as the front end surface 31 has a round shape and the chisel portion length of the front end surface 31 is extended compared to the cutting edge of the conventional initial drill When the torque increases and the area in which the chisel portion contacts the alveolar bone 50 becomes large, it is possible to prevent a misalignment of the groove in the drilling process.

 In addition, the thrust received by the drill is increased due to the extension of the chisel, which causes fluctuations up and down about the rotation axis when drilling. This is because the guide portion 20 of the initial drill 100 is inside the guide hole H. Rotational support in the groove does not affect the groove groove malformation.

As described above, the present invention has been described with reference to one embodiment shown in the drawings, but this is merely exemplary, and those skilled in the art may realize various modifications and other equivalent embodiments therefrom. Will understand.

Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

10: mounting part 20: guide counterpart
21: guide portion 22: step
30: cutting edge 31: end surface
40: inclined portion 41: second cutting blade
50: alveolar bone 100: initial drill
F: fixture G: guide stent
H: guide hole

Claims (4)

It is inserted into the guide hole (H) of the guide stent (G) formed to surround the teeth or gingival is rotated, the fixture in the alveolar bone (50) as the drilling is performed accurately in the desired position in combination with the rotary tool for implants In the initial drill 100 to allow (F) to be implanted,
The initial drill 100 is
A mounting portion 10 coupled to the rotating tool for implants;
A guide counterpart 20 extending in an axial direction from a lower end of the mounting part 10 and being rotatably supported through the guide hole H of the guide stent G;
An inclined portion 40 formed at a lower end of the guide counterpart 20 and having an inclined surface in a form of a light beam;
A cutting edge portion 30 extending from the bottom of the inclined portion 40 to perform drilling at a position where the fixture F in the alveolar bone 50 is to be placed;
The inclined portion 40 is inclined surface of the second cutting edge 41 for partially crushing the upper gingiva of the alveolar bone 50 at the position where the fixture (F) is implanted, the pier with the horizontal line (α) 40 ° to 70 ° Initial drill having a tissue punching function, characterized in that formed along the.
The method of claim 1,
The guide counterpart 20
A guide part 21 accommodated in the guide hole H to be rotated and supported;
It is formed to have a diameter larger than the diameter of the guide portion 21 on the upper side of the guide portion 21 when the initial drill 100 is inserted into the guide hole (H) in the upper outer surface of the guide hole (H) Initial drill having a tissue punching function, characterized in that it comprises a stepped portion 22 so that the initial drill 100 is no longer drawn in the desired depth as it is seated.
The method of claim 1,
The cutting edge portion 30 is
Initial drill having a tissue punching function, characterized in that the front end surface 31 is formed in a round shape so that drilling is performed to an accurate position without slipping at the position where the fixture (F) is to be placed.
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