KR20200069744A - trephine drill for implant - Google Patents

Abstract

The present invention provides a trephine drill for an implant to form a perforation for implantation of a fixture to improve the precision of the procedure. The trephine drill for an implant includes: a shank portion having a mounting portion on one side end thereof to be coupled to a dental handpiece; a guide rod portion extending and protruding from an inner end of the shank portion and having a diameter corresponding to a cylindrical alignment hole formed by an initial drill in an alveolar bone corresponding to a fixture implant area to be inserted into and guided into the alignment hole; and a rotation cutting portion rotating while being connected to the shank portion, wherein the rotation cutting portion has an inner diameter larger than the outer diameter of the guide rod portion, so that a bone piece accommodation space is formed between an outer periphery of the guide rod portion to allow a bone cut piece to be induced, and the rotation cutting portion is formed with a plurality of cutting blades on an edge of an end in a circumferential direction.

Description

Trephine drill for implants

The present invention relates to a trepine drill for implants, and more particularly, to a trepine drill for implants with improved procedure precision.

In general, an implant refers to a substitute that can replace human tissue when the original human tissue is lost, but in dentistry, means to implant an artificial tooth. In other words, it is a treatment method to fix the artificial teeth after planting a fixture made of titanium or the like that has no rejection to the human body to replace the lost root, and fix the artificial teeth to restore the function of the teeth.

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 are no secondary decay factors. In addition, since the implant has the same structure as a natural tooth, there is no pain and foreign body sensation in the gums, and it can be used semi-permanently if it is well managed.

1 is a flow chart showing a conventional implant procedure.

As shown in FIG. 1, the conventional implant procedure is a primary procedure (s1, s2, s3, s4) in which a fixture is placed in the alveolar bone, and a time (3-6 months) when the fixture is bone-fused to the alveolar bone. ), and then fixing the final prosthesis (s5, s6).

First, the first procedure is a gum removal step (s1) to open the gums of the tooth-defected part, a multi-step drilling step (s2) to form a perforation where the fixture is to be placed, and a fixture placement step (s3), the placed fixation It consists of a step (s4) of combining the temporary teeth with the chur.

In detail, in the gum removal step (s1), the gum is removed through a tissue punch or the like and the alveolar bone at the position where the fixture is placed is exposed. Then, through the multi-step drilling step (s2) to the exposed portion of the alveolar bone to form a perforation for the fixture.

At this time, the multi-step drilling step (s2) may be made of a step of forming an initial hole, a step of expanding the hole, a step of forming a thread inside the hole, and a step of removing the residual alveolar bone inside the hole, and the like. It can be made in various ways depending on the type of drilling and drilling method used.

In addition, the first procedure is completed when the fixture is placed in the perforation formed through the multi-stage drilling step (s2) (s3) and the temporary tooth is combined with the placed fixture (s4). Here, the fixture placed in the perforation serves as the root of the artificial tooth. Therefore, in order to provide a fast and stable recovery process in which the alveolar bone forms a bone fusion with the fixture, and to provide a stable coupling force between the bone and the bone after bone fusion, it is very important to form an accurate perforation in the multi-stage drilling step (s2), The completeness of artificial tooth formation through implant surgery will be influenced.

On the other hand, the maxillary sinus is a space filled with air on the upper part of the molar roots on both sides of the maxilla. Therefore, when the teeth of the maxillary sinus were extracted and the fixture was placed, there was a problem that it could not be firmly placed. In order to solve this problem, after performing a bone graft to reinforce the residual bone on the inner surface of the alveolar bone of the maxillary sinus, a fixture is placed.

At this time, inside the maxillary sinus, there is a maxillary sinus membrane that is associated with a respiratory system to control humidity in the nasal cavity and to control resonance during speech. If the maxillary sinus membrane is torn during the drilling operation to install the fixture, the inside of the maxillary sinus is exposed to pathogens and a fatal secondary infection may occur in the maxilla and respiratory tract, so careful work is required.

On the other hand, the conventional maxillary sinus implant placement is performed in the following process.

First, through CT imaging, the alveolar bone thickness of the fixture placement position is measured, and a stopper capable of limiting the insertion depth of the drill in response to the measured alveolar bone is provided on the outer periphery of the drill and then drilled to form a perforation. Subsequently, a water or lifting tool is inserted through the perforation to lift the maxillary sinus membrane from the inner surface of the maxillary sinus bone. In addition, when the maxillary sinus membrane is raised from the inner surface of the alveolar bone, a graft bone layer having a sufficient thickness and density to implant a fixture may be formed as the bone graft material is injected and fused to the inside.

However, when the stopper is in direct contact with the gum, which is a soft tissue, the gap between the end of the stopper and the alveolar bone changes while the gum is pressed by the force pressing the drill. Due to this, since the insertion depth of the drill is not accurately limited, there is a serious problem in that the maxillary sinus membrane is torn due to the direct contact of the drill end with the maxillary sinus membrane.

In addition, when the gum is cut and the stopper is in contact with the outer surface of the exposed alveolar bone, the gap between the stopper end and the alveolar bone may be fixed, but the stopper slides along the rounded profile of the alveolar bone and the drilling position is disengaged from the preset position. Due to this, the placement position of the fixture is not preferable, so the accuracy of the overall implant placement is deteriorated, and there is a problem that the maxillary sinus membrane is brought into contact with the drill end where the position is moved, causing tearing. Moreover, the recovery period is increased due to the large incision area of the gums, the appearance of the gums is deformed after recovery, and the blood supply through the gums is not smooth, resulting in an increase in the recovery time consumed for fusion and stabilization of the graft.

In order to solve the above problems, a part of an auxiliary device called a surgical guide was used to guide the insertion depth and the drilling position of the drill. In the surgical guide, at least one guide hole penetrates in correspondence with the placement position and direction of the fixture, and the accuracy of the drilling operation is improved as it substantially matches the inside of the oral cavity. Further, as the stopper is supported on the outer surface of the surgical guide, the drill position can be guided stably.

However, due to the fluidity of the periodontal tissue or the operator's carelessness, the maxillary sinus membrane may be damaged by drilling beyond the limited insertion depth through the surgical guide. Accordingly, the inside of the maxillary sinus was exposed to pathogens, and a fatal secondary infection occurred in the maxillary sinus and the respiratory tract, resulting in a decrease in procedure precision and procedure safety.

And, in the related art, a thread is formed on the outer circumference of the shank and the inner circumference of the drill cutting edge so that the longitudinal position of the drill cutting edge is selectively adjusted, and a separate position fixing unit for fixing the drill cutting edge is further provided.

However, the conventional position fixing unit has a problem in that it is difficult to use with a surgical guide through a hole formed on the side of a drill cutting blade and is difficult to use with a surgical guide, so that the precision of the procedure decreases rapidly as the drill has a lower bearing capacity.

Moreover, when the pressure of the conventional position fixing unit is released during the drilling operation, since the drill cutting edge is disengaged in the longitudinal direction, there is a problem in that the safety of the procedure is rapidly reduced.

Korean Registered Patent No. 10-0619145

In order to solve the above problems, the present invention is to solve the problem of providing a trepine drill for implants with improved treatment precision.

In order to solve the above problems, the present invention, in the trepine drill for implants to form a perforation for the placement of a fixture, the shank portion formed with a mounting portion coupled to the dental handpiece at one end; A guide rod portion protruding from the inner end of the shank portion, and having a diameter corresponding to the alignment hole to be guided by being inserted into a cylindrical alignment hole formed by an initial drill in the alveolar bone corresponding to the fixture placement area; And connected to the shank portion is rotated at the same time, the inner diameter is formed larger than the outer diameter of the guide rod portion to form a bone fragment receiving space to induce a bone cutting between the outer portion of the guide rod portion, the circumferential direction on the edge of the end Accordingly, there is provided a trepine drill for an implant including a rotary cutting part in which a plurality of cutting edges are formed.

Here, the length of the rotary cutting unit is formed to be less than or equal to a preset interval range based on the end of the guide rod to prevent cutting of the maxillary sinus membrane by limiting the puncture depth by the guide rod unit. It is preferably formed below the depth of the ball.

And, the end of the guide rod portion is formed to be rounded to prevent cutting of the alignment hole when the guide rod portion is inserted into the alignment hole, the cutting edge is inclined cutting surface is formed inclined in one surface portion corresponding to the rotation direction And a stepped surface formed to be stepped perpendicular to the cutting target surface from the end of the cutting slope to the other surface portion corresponding to the rotational opposite direction, wherein the cutting slope and the stepped surface are circumferentially formed at the edge of the rotary cutting portion. It is preferable to be provided alternately in sequence.

In addition, at least one or more bone discharging holes are formed along the longitudinal direction so that the bone cutting material introduced into the bone fragment receiving space is discharged on the side portion of the rotary cutting part, and the length of the bone discharging holes in the longitudinal direction exceeds the thickness of the guide hole. It is preferably formed.

In addition, a stopper step extending radially outward along a circumferential direction is integrally formed in the central portion of the shank portion, and the rotary cutting portion is preferably connected to an inner end of the stopper step.

Through the above solution, the present invention provides the following effects.

First, since the guide rod portion protruding from the inner end of the shank portion is inserted into the alignment hole pre-formed in the alveolar bone by the initial drill, the drilling direction for fixing the fixture during drilling can be guided, thereby significantly improving the treatment precision.

Second, the rotary cutting part connected to the shank part is rotated and supported by the guide hole of the surgical guide, and at the same time, the guide rod part is inserted into the alignment hole and guided. Since it is possible to form a precise perforation corresponding to the diameter, the procedure precision can be significantly improved.

Third, since the end portion of the guide rod portion inserted into the alignment hole formed in the alveolar bone is guided to guide the drilling direction, cutting of the inner circumferential surface of the alignment hole guiding the drilling direction is prevented before the rotation of the guide rod portion, thereby maintaining a strong support force. Procedure safety and procedure precision can be significantly improved.

Fourth, since the length of the rotary cutting portion is formed below a predetermined distance range based on the end of the guide rod inserted into the alignment hole, the depth of the perforation is limited, so the cutting of the maxillary sinus membrane is prevented beforehand, and the safety of the operation can be significantly improved. have.

Fifth, unlike the conventional method in which the longitudinal position of the cutting edge is variable and fixed by the position fixing unit, since the rotary cutting part is integrally fixed and rotated by the shank part, the support force during cutting is increased to improve the procedure precision, and the cutting The longitudinal direction of the blade can be prevented beforehand to improve the safety of the procedure.

1 is a flow chart showing a conventional implant procedure.
Figure 2 is a perspective view showing a trepine drill for implants according to an embodiment of the present invention.
Figure 3 is a side view showing a trepine drill for implants according to an embodiment of the present invention.
Figure 4 is a cross-sectional view showing a trepine drill for implants according to an embodiment of the present invention.
Figure 5 is an exemplary use of a trepine drill for implants according to an embodiment of the present invention.
Figure 6 is a usage example showing a first modification of the trepine drill for implants according to an embodiment of the present invention.
7 is a usage example showing a second modification of the trepine drill for implants according to an embodiment of the present invention.

Hereinafter, a trepine drill for an implant according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view showing a trepine drill for an implant according to an embodiment of the present invention, and FIG. 3 is a side view showing a trepine drill for an implant according to an embodiment of the present invention. And, Figure 4 is a cross-sectional view showing a trepine drill for implants according to an embodiment of the present invention, Figure 5 is an exemplary use of a trepine drill for implants according to an embodiment of the present invention.

1 to 5, the trepine drill 100 for an implant according to an embodiment of the present invention includes a shank portion 10, a guide rod portion 20, and a rotary cutting portion 30 .

Here, the trepine drill 100 for the implant is used in a multi-stage drilling procedure that forms a perforation for the placement of a fixture during the implant procedure, and is drilled in the alveolar bone 4 at a position where the fixture is placed in the oral cavity. It is a device for cutting and removing the alveolar bone 4 so that it is formed.

In addition, in one embodiment of the present invention, an example is illustrated and described as an example in which the trepine drill 100 for implant is used for the maxilla where the maxillary sinus membrane (membrane, 5) is present, but is equally applicable to the mandible. It is desirable to understand.

The trepine drill 100 for such an implant has a guide rod portion 20 to be described later inserted into a cylindrical alignment hole 6 formed by an initial drill (not shown) in the alveolar bone 4 corresponding to the fixture placement area, and is drilled. It is preferred that the direction is guided. At the same time, the outer peripheral of the rotary cutting part 30 to be described later is inserted into the guide hole 2 of the surgical guide 1 that guides the implant placement position of the trepine drill 100 for implantation. Can be.

Here, the alignment hole 6 may be formed by the initial drill (not shown) separately provided in the initial stage of the multi-stage drilling step of forming a perforation to be fixed. Here, the alignment hole 6 is preferably formed to a depth smaller than the depth from the surface of the gum 3 to the maxillary sinus membrane 5, between the inner end of the alignment hole 6 and the maxillary sinus membrane 5 It is preferred that they are formed to be spaced apart at predetermined intervals.

For example, when the total depth of the alveolar bone 4 at the position of the fixture placed measured by CT imaging, that is, the depth from the surface of the gum 3 to the maxillary sinus membrane 5 is 8.0 mm, the alignment hole 6 ) May be formed to a depth of 5.0 mm from the surface of the gum 3.

On the other hand, the shank portion 10 is preferably formed with a mounting portion 11 coupled to a dental handpiece (not shown) at one end. Here, the dental handpiece (not shown) is a hand drill device used to provide rotational force to the trepine drill 100 for the implant.

In addition, the mounting portion 11 is provided with one surface portion in a decut shape, and the other surface side end portion may be extended to be stepped radially outward. Accordingly, when the mounting portion 11 is coupled to the dental handpiece (not shown), as the rotational force of the handpiece (not shown) is transmitted to the shank portion 10, the shank portion 10 is integrally formed. Can be rotated.

In addition, the shank portion 10 is connected to the guide rod portion 20 and the rotary cutting portion 30, the guide rod portion 20 and the rotational force generated in the dental handpiece (not shown) It can be transferred to the rotary cutting unit 30.

At this time, the shank portion 10 may be formed independently of the diameter of the guide rod portion 20 and the rotary cutting portion 30, but is provided with a diameter smaller than the diameter of the rotary cutting portion 30 desirable. In addition, the shank portion 10 is preferably provided with a larger diameter than the diameter of the guide rod portion 20.

In addition, the shank portion 10 may be provided in a cylindrical shape, it may be provided in a metal material such as stainless steel. Accordingly, the shank portion 10 can be firmly connected to and supported by the guide rod portion 20 and the rotary cutting portion 30 during high-speed rotation.

Through this, damage such as warping or twisting that may occur when the shank portion 10 is rotated is prevented, and durability can be improved, and the precision of drilling can be prevented from being reduced due to vibration caused by rotational damage. have.

On the other hand, it is preferable that the stopper step 12 extending radially outward along the circumferential direction is integrally formed in the longitudinal center portion of the shank portion 10. Here, the stopper step 12 is preferably formed integrally extending radially outward along the circumferential direction on the outer periphery of the longitudinal central portion adjacent to the other end of the shank portion 10. At this time, the stopper step 12 may be manufactured by a method such as SUS welding.

In detail, it is preferable that the stopper step 12 is formed with a flat seating portion perpendicular to the longitudinal direction so that one end portion of the rotary cutting portion 30 is supported. In addition, an inclined portion having a diameter that decreases toward the side of the shank portion 10 from the seating portion may be formed.

Here, it is preferable that the seating portion protrudes to extend radially outward along the circumferential direction from a body adjacent to the other end side of the longitudinal center portion of the shank portion 10. At this time, the diameter of the stopper stepped 12 seating portion is preferably formed to be more than the diameter of the rotary cutting portion (30).

Accordingly, since the one end of the rotary cutting unit 30 is supported by the stopper step 12 during drilling for drilling, the lengthwise departure of the rotary cutting unit 30 is prevented beforehand, so that the precision and operation of the procedure are prevented. Safety can be significantly improved.

In addition, a cylindrical coupling portion 13 may be formed at the other end of the shank portion 10 so that the rotary cutting portion 30 is fixed. Here, the outer diameter of the coupling portion 13 may be formed to correspond to the inner diameter of the rotary cutting portion 30.

On the other hand, the guide rod 20 is integrally protruding along the longitudinal direction from the inner end of the coupling portion 13 of the shank portion 10 is provided in a cylindrical shape, integral when the shank portion 10 is rotated Can be rotated to Here, the guide rod portion 20 may be provided with a metal material such as stainless steel, or in some cases, may be provided with titanium having excellent biocompatibility.

In addition, the guide rod portion 20 is most preferably formed integrally with the shank portion 10, but in some cases, the guide rod portion 20 is provided separately from the shank portion 10, the shank portion It may be detachably coupled to the inner end of the coupling portion 13 of (10). Accordingly, since the guide rod portion 20 is separated from the shank portion 10 and is easy to clean, the convenience of use can be improved.

In addition, the guide rod portion 20 is preferably provided with a diameter corresponding to the alignment hole 6 so that the end of the guide rod portion 20 is inserted into the alignment hole 6 to guide the drilling direction. . For example, when the diameter w1 of the alignment hole 6 is formed to be 1.5 mm or 2.0 mm by the initial drill (not shown), the diameter w2 of the guide rod portion 20 is the alignment hole ( It may be provided in 1.5mm or 2.0mm corresponding to the diameter of 6).

Accordingly, the guide rod portion 20 protruding from the inner end of the shank portion 10 is inserted into the alignment hole 6 formed in advance by the initial drill (not shown) to rotate the rotating portion during rotation. The perforation direction of 30 can be guided.

Through this, unlike the conventional in which the alignment hole 6 is not formed and the alveolar bone 4 is cut by a drill, the guide rod portion 20 is inserted into the alignment hole 6 to drill the fixture for fixation. Since the direction is guided, the procedure precision can be significantly improved.

And, the length of the guide rod 20 is preferably provided in excess of the length of the alignment hole (6). In addition, at the end of the guide rod portion 20, the round portion 21 is rounded so as to prevent cutting of the alignment hole 6 when the guide rod portion 20 inserted in the alignment hole 6 is rotated. It is preferably formed.

In detail, as the rotation of the guide rod portion 20 is rotated, the end edge of the guide rod portion 20 where a substantial external force is applied to the alignment hole 6 may be rounded. That is, the diameter of the rim of the round portion 21 may be reduced to a predetermined radius reduction rate toward the end.

Accordingly, since the end portion of the guide rod portion 20 is formed to be rounded, cutting of the inner circumferential surface of the alignment hole 6 that guides the drilling direction when the guide rod portion 20 is rotated can be prevented. Through this, since the rigid support force of the alignment hole 6 guiding the drilling direction is maintained, the procedure safety and the procedure precision can be significantly improved.

Meanwhile, the rotary cutting part 30 is preferably connected to the shank part 10 so as to be rotated simultaneously with the shank part 10. In detail, the rotary cutting part 30 may be provided with a metal material such as a hollow cylindrical stainless steel, and one end may be connected to an inner end of the seating part of the stopper step 12. At this time, a recess groove 34 that is recessed in a radially inner direction along a circumferential direction may be formed at one end side edge of the rotary cutting part 30.

Further, the rotary cutting part 30 is most preferably fixed integrally with the shank part 10 so as to be rotated at the same time when the shank part 10 is rotated, but may be provided separately and fixed to each other.

Therefore, unlike the conventional method in which the longitudinal position of the drill cutting edge is variable and fixed by the position fixing unit, the rotating cutting part 30 is integrally fixed to the shank part 10 and rotated, thereby increasing the supporting force during cutting. As a result, the procedure precision can be significantly improved.

Moreover, since the rotary cutting part 30 is integrally fixed and rotated on the shank part 10, the longitudinal direction of the cutting edge 31 is prevented beforehand, so that the safety of the operation can be significantly improved.

In addition, it is preferable that the rotary cutting unit 30 is provided with a plurality of different lengths to be used sequentially for each procedure of multi-stage drilling, and is integrally fixed to the shank portion 10. That is, it is preferable that the plurality of rotary cutting parts 30 provided in different lengths are integrally set and provided with the shank part 10.

Accordingly, since a plurality of trepine drills for the implant having the rotary cutting unit 30 having a length required in each procedure of multi-stage drilling are provided, it is possible to rapidly perform the procedure and to improve work efficiency and safety of the procedure. .

In addition, the length of the rotary cutting unit 30 is preset based on the end of the guide rod 20 so that the depth of puncture is limited by the guide rod unit 20 to prevent cutting of the maxillary sinus membrane 5. It is preferably formed in the interval range h2 or less.

Here, the predetermined interval range (h2) is preferably formed below the depth (h1) of the alignment hole (6). At this time, the alignment hole 6 is formed with a depth h1 smaller than the length from the surface of the gum 3 to the maxillary sinus membrane 5, but the inner end of the alignment hole 6 and the maxillary sinus membrane 5 It is preferable to understand that the gap is formed by being spaced apart.

For example, when the depth h1 of the alignment hole 6 is formed to be 5.0 mm, and the length of the guide rod 20 is 17.0 mm, the length of the rotary cutting portion 30 is 14.0 mm. It may be provided. That is, the length of the rotary cutting unit 30 may be formed to be 3.0 mm smaller than the end of the guide rod 20. Of course, the length of the rotary cutting portion 30 may be provided longer than the length of the guide rod portion 20, detailed description will be described later.

Accordingly, when the guide rod portion 20 is inserted into the alignment hole 6 and rotated, the alveolar bone 4 is equal to the difference in the preset interval range h2 from the depth h1 of the alignment hole 6 This cut can be used to form perforations. At this time, when the length of the rotary cutting part 30 is smaller than the length of the guide rod part 20 as in one embodiment of the present invention, the alveolar bone 4 is cut by a depth smaller than the target drilling depth to be cut. It is desirable to understand.

Through this, when the length of the rotary cutting portion 30 is provided smaller than the length of the guide rod portion 20 inserted into the alignment hole 6, the depth of the drilling is limited and cutting of the maxillary sinus membrane 5 is possible. Since it is prevented beforehand, the operation safety can be significantly improved. That is, since the rotary cutting part 30 is rotated while the guide rod part 20 of the present invention is inserted into the alignment hole 6, the drilling direction is guided and the drilling depth for fixing the fixture is limited. The configuration is significantly different from the conventional technology.

Therefore, since the length of the rotary cutting part 30 is formed below a predetermined interval range h2 based on the end of the guide rod 20, the depth of the puncture is limited, so that the cutting of the maxillary sinus membrane 5 is unforeseen. Since it is prevented, the surgical safety can be significantly improved.

And, the inner diameter of the rotary cutting portion 30 is formed larger than the outer diameter of the guide rod portion 20, the outer diameter of the rotary cutting portion 30 is preferably formed to correspond to the inner diameter of the guide hole (2) Do.

Here, the rotary cutting part 30 is provided with an outer diameter corresponding to the inner circumference of the guide hole 2 so as to be inserted into and supported by the guide hole 2 of the surgical guide 1 that guides the position of the fixture. This is preferred.

In detail, in the implant procedure, when forming the perforation where the fixture is placed, it is difficult to determine the exact position and direction to be performed, so an auxiliary device called the surgical guide 1 is used. Here, the surgical guide 1 is formed of a profile inside the oral cavity. In addition, the surgical guide 1 is fixed by wrapping the teeth and gums of teeth and gums of a patient with teeth or edentulous teeth, and a plurality of guide holes 2 are formed at each position where an implant is required.

Further, the guide hole 2 is preferably provided as a cylindrical hole, and is provided to guide the drill device inserted in the inside while rotating and guiding up and down. At this time, the rotary cutting part 30 is inserted into the inner periphery of the guide hole 2 and is guided by being slid in the longitudinal direction, and is supported by the user because it is rotated inside the guide hole 2. Easily remove the gums of the correct part.

In addition, the guide hole 2 may be provided with various diameters according to the type of natural teeth to be replaced with an implant. For example, the fixture that becomes the root of an artificial tooth is provided with a diameter of 3.5mm, 4.0mm, 4.5mm, 5.0mm, and the like. In addition, the outer diameters of the guide hole 2 and the rotary cutting part 30 may be formed to be about 3.0 mm, 3.5 mm, 4.0 mm, 4.5 mm, etc. in correspondence with the eccentricity of the fixture. That is, the guide hole 2 may be selected and provided in a size corresponding to the diameter of the fixture, and the rotary cutting part 30 may be provided corresponding to the diameter of the guide hole 2. At this time, the rotary cutting part 30 is preferably provided with an outer diameter that is slightly smaller than the inner periphery of the guide hole 2 so that it can be inserted into and rotated inside the guide hole 2.

Accordingly, the rotary cutting unit 30 is rotationally supported by the guide hole 2 and at the same time, the guide rod unit 20 is inserted into the alignment hole 6 and is provided with a double alignment support structure. Therefore, since the precise perforation corresponding to the diameter of the fixture can be formed in the alveolar bone 4 on the side of the fixture placement region, the procedure precision can be remarkably improved.

Moreover, referring to FIG. 5, an auxiliary stopper 40 for adjusting the insertion depth of the rotary cutting unit 30 may be further provided. The auxiliary stopper 40 may be standardized to a unit length and provided in plural.

Here, the auxiliary stopper 40 may be selectively provided with a length at which one end is in contact with the seating portion of the stopper step 12 and the other end is in contact with one end of the guide hole 22. In addition, the auxiliary stopper 40 may be disposed to surround one outer surface of the rotary cutting unit 30.

Through this, abrasion or tearing of the maxillary sinus membrane 5 due to the end of the cutting edge portion 30 contacting the maxillary sinus membrane 5 while the perforation of the alveolar bone 4 is formed at the correct position can be prevented. Can be.

In addition, the inner diameter of the rotary cutting unit 30 is formed to be larger than the outer diameter of the guide rod unit 20, so that the rotary cutting unit 30 is spaced apart from the guide rod unit 20 by a predetermined interval. It is preferably provided with.

And, between the inner circumference of the rotary cutting portion 30 and the outer circumference of the guide rod portion 20, it is preferable that a bone fragment receiving space 32 through which a bone cutting material is induced is formed. In addition, at the side of the rotary cutting part 30, at least one or more bone discharging holes 33a and 33b are formed along the longitudinal direction in communication with the outside so that the bone cutting material introduced into the bone fragment receiving space 32 is discharged. This is preferred.

At this time, the bone fragment receiving space 32 may be introduced into the bone cutting material generated in the drilling process, the bone cutting material is preferably understood to mean the alveolar bone removed from the implant placement position.

In addition, the bone cutting material may be discharged to the outside through the bone discharge holes 33a and 33b communicating with the bone fragment receiving space 32. At this time, the length of the longitudinal direction of the bone discharge hole (33a, 33b) is preferably formed in excess of the thickness of the guide hole (2).

Due to this, the rotating cutting part 30 is inserted into the inner periphery of the guide hole 2 to remove the alveolar bone 4 in a rotationally supported state, and when inserted, the lengthwise ends of the bone discharging holes 33a, 33b are inserted. At least one side may be exposed to the outside of the guide hole (2).

Accordingly, the bone cutting material introduced into the bone fragment receiving space 32 is not accumulated inside the bone fragment receiving space 32 and can be smoothly discharged to the outside through the bone discharge holes 33a and 33b. . Moreover, the accumulation of the bone cutting material and the flow thereof may prevent the bone cutting material from sticking to the gums or alveolar bones, which are not subject to removal. Therefore, the alveolar bone of the implant placement position can be smoothly and accurately removed, and additional work is not required such as removing and scraping the entangled bone cutting material through a separate tool or procedure, so work efficiency can be significantly improved.

In addition, it is preferable that a plurality of cutting edges 31 are formed along the circumferential direction to cut the alveolar bone 4 in the fixture placement position on the edge of the rotary cutting unit 30. In detail, the end of the rotary cutting unit 30 is opened to communicate with the bone fragment receiving space 32, and the cutting edge 31 may be formed along the edge of the rotary cutting unit 30. At this time, it is most preferable that the cutting knuckle 31 is integrally provided with the rotary cutting part 30, and may be separately provided and combined depending on the case.

Here, it is preferable that the cutting edge 31 is formed on one surface portion corresponding to the rotational direction, but includes a plurality of cutting inclined surfaces that are formed to increase in length along the circumferential direction and be inclined. In addition, the cutting edge 31 is preferably formed on the other surface portion corresponding to the opposite direction of rotation, but includes a plurality of stepped surfaces formed to be stepped perpendicular to the cutting target surface from the end of the cutting slope. At this time, the cutting target surface is preferably understood as the cutting surface of the alveolar bone 4 that is cut in correspondence with the fixture placement region.

In addition, it is preferable that each of the cutting inclined surfaces and each of the stepped surfaces is alternately provided along the circumferential direction on the edge of the rotary cutting part 30. Accordingly, the cutting edge 31 is in direct contact with the alveolar bone 4 between the positions of the fixtures, thereby cutting the alveolar bone 4 during rotation. At this time, the alveolar bone 4 contacted by the cutting edge 31 may be cut and flow into the bone receiving space 32.

Then, the cutting edge 31 is inserted into the alveolar bone 4 and cut the alveolar bone 4 to separate it from the entire tissue. At this time, the rotary cutting unit 30 pushes the alveolar bone 4 outside the cutting edge 31 as the cutting edge 31 is inserted toward the alveolar bone 4, and the outer surface is outside the cutting edge 31. It is in close contact with the alveolar bone (4).

Accordingly, the alveolar bone (4) separated from the entire tissue through the cutting edge (31) and the bone debris decomposed by friction due to the rotation of the cutting edge (31) to the outside of the rotary cutting unit (30) Without leaking, it can flow smoothly toward the bone receiving space 32 side.

On the other hand, Figure 6 is a usage example showing a first modification of the trepine drill for implants according to an embodiment of the present invention. The trepine drill 100A for implants according to the first modification of the present invention has the same basic configuration as the above-described embodiment except for the length of the rotary cutting unit 30A, so a detailed description of the same configuration will be omitted.

As shown in Figure 6, the length of the rotary cutting portion (30A) is guided to form a perforation for the placement of the fixture as the alveolar bone (4) is cut by a depth corresponding to the alignment hole (6) It is preferably formed corresponding to the length of the rod portion 20.

For example, when the depth h1 of the alignment hole 6 is formed to be 5.0 mm, and the length of the guide rod 20 is 17.0 mm, the length of the rotary cutting portion 30A is 17.0 mm. It may be provided. Accordingly, when the guide rod portion 20 is inserted into the alignment hole 6 and rotated, the alveolar bone 4 is cut by the depth h1 of the alignment hole 6 to form a perforation.

Here, it is understood that the trepine drill 100A for implants according to the first modification of the present invention is inserted into the perforation of the fixture placement region cut first by the trepine drill 100 for implants of the above-described embodiment. desirable. That is, it is preferable to understand that the alveolar bone 4 of the fixture placement region is cut step by step at a predetermined depth by a plurality of trepine drills for implants having different lengths of the rotating cutting parts.

On the other hand, Figure 7 is a usage example showing a second modification of the trepine drill for implants according to an embodiment of the present invention. The trepine drill 100B for implants according to the second modification of the present invention has the same basic configuration as the above-described embodiment except for the length of the rotary cutting unit 30B, so a detailed description of the same configuration will be omitted.

7, the length of the rotary cutting unit 30B is preferably formed to exceed a predetermined length h3 from the length of the guide rod unit 20. At this time, the predetermined length is preferably formed smaller than the depth between the maxillary sinus membrane (5) at the inner end of the alignment hole (6) to prevent cutting of the maxillary sinus membrane (5).

For example, when the depth from the surface of the gum 3 to the maxillary sinus membrane 5, that is, the entire depth of the alveolar bone 4 is 8.0 mm, the depth h1 of the alignment hole 6 is formed to be 5.0 mm. Can be. Accordingly, the depth between the maxillary sinus membrane 5 at the inner end of the alignment hole 6 may be set to 3.0 mm. In addition, when the length of the guide rod 20 is provided to be 17.0 mm, the length of the rotary cutting portion 30B may be formed to be greater than 17.0 mm and less than 20.0 mm. That is, the length of the rotary cutting portion 30B is less than the length corresponding to the depth between the length of the guide rod 20 and the maxillary sinus membrane 5 at the inner end of the alignment hole 6 It can be formed in length.

Here, it is understood that the trepine drill 100B for implants according to the second modified example of the present invention is inserted into the perforation of the fixture placement area cut second by the trepine drill 100A for the implant of the first modified example described above. This is preferred. That is, it is preferable to understand that the alveolar bone 4 of the fixture placement region is cut step by step at a predetermined depth by a plurality of trepine drills for implants having different lengths of the rotating cutting parts.

Accordingly, the length of the rotary cutting part 30B may be provided longer than the length of the guide rod part 20. In addition, the difference between the end of the guide rod portion 20 facing the alveolar bone 4 and the end portion of the rotary cutting portion 30B is the depth between the maxillary sinus membrane 5 at the inner end of the alignment hole 6. It can be formed smaller. Through this, when the alveolar bone 4 of the fixture placement region is cut, the precision of the procedure can be remarkably improved since it is possible to perform a precise operation as long as the cutting of the maxillary sinus membrane 5 is prevented.

Therefore, since the length of the rotary cutting portion 30B is formed below a predetermined interval range based on the end of the guide rod 20, the drilling depth is limited and cutting of the maxillary sinus membrane 5 is prevented beforehand. Safety can be significantly improved.

At this time, the terms "include", "compose" or "prepare" as described above means that the corresponding component can be intrinsic, unless specifically stated otherwise, excluding other components. It should not be interpreted as being able to further include other components. All terms, including technical or scientific terms, have the same meaning as generally understood by a person skilled in the art to which the present invention pertains, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted as being consistent with the contextual meaning of the related art, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in the present invention.

As described above, the present invention is not limited to each of the above-described embodiments, and it is possible to be modified by a person skilled in the art to which the present invention pertains without departing from the scope of the claims of the present invention. The implementation of such modifications is within the scope of the present invention.

100,100A,100B: Trepine drill for implant 1: Surgical guide
2: Guide hole 3: Gum
4: alveolar bone 5: maxillary sinus membrane
6: Sorter 10: Shank part
11: Mounting part 12: Stopper step
13: extension 20: guide rod
21: round part 30,30A,30B: rotary cutting part
31: cutting edge 32: bone receiving space
33a, 33b: bone discharge hole 34: recessed groove
40: auxiliary stopper

Claims (5)

In the trepine drill for implants that form a perforation for the placement of a fixture,
A shank portion in which an attachment portion coupled to the dental handpiece is formed at one end portion;
A guide rod portion extending from the inner end of the shank portion, and having a diameter corresponding to the alignment hole to be guided by being inserted into a cylindrical alignment hole formed by an initial drill in the alveolar bone corresponding to the fixture placement area; And
Connected to the shank portion and rotated at the same time, the inner diameter is formed larger than the outer diameter of the guide rod portion, so that a bone receiving space is formed to induce a bone cutting between the outer circumference of the guide rod portion, along the circumferential direction at the edge of the end. A trepine drill for an implant including a rotary cutting part in which a plurality of cutting edges are formed. According to claim 1,
The length of the rotary cutting unit is formed to be less than or equal to a predetermined interval range based on the end of the guide rod so that the drilling depth is limited by the guide rod portion to prevent cutting of the maxillary sinus membrane.
The preset interval range is a trepine drill for implants, characterized in that formed below the depth of the alignment hole. According to claim 1,
The end portion of the guide rod portion is formed to be round to prevent cutting of the alignment hole when the guide rod portion is inserted into the alignment hole,
The cutting edge includes a cutting slope formed obliquely on one surface portion corresponding to the rotational direction, and a stepped surface formed perpendicular to the cutting target surface from an end of the cutting slope portion on the other surface corresponding to the rotational direction,
The cutting plane for the implant, characterized in that the cutting inclined surface and the stepped surface are alternately provided along the circumferential direction on the edge of the rotary cutting unit. According to claim 1,
At least one bone discharging hole is formed along the longitudinal direction so that the bone cutting material introduced into the bone fragment receiving space is discharged from the side portion of the rotary cutting unit,
The lengthwise length of the bone discharge hole is a trepine drill for implant, characterized in that formed in excess of the thickness of the guide hole. According to claim 1,
The central portion of the shank portion is formed integrally with a stopper step extending radially outward along a circumferential direction, wherein the rotary cutting part is connected to an inner end of the stopper step, a trepine drill for an implant.

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