JP2017217278A - Dental drill and perforation method for dental implantation using the dental drill - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a dental drill and a perforation method for dental implantation using the dental drill which prevents a necrosis of a gnathic bone by friction heat.SOLUTION: A drill including two cut blades formed symmetrically with respect to a rotational axis and has a tip portion which is thinned. When viewed from the tip portion side, the cut blades includes: a thinning cut blade extending in a shape including a curve toward a drill outer circumferential side from a chisel edge; and a main cut blade extending from an end of the thinning cut blade to the drill outer circumferential edge. The drill includes: a first drill in which a thinning face formed by the thinning cut blade is formed in a substantially parabolic shape which inclines in a drill shaft direction when viewed from a drill front side; and second and third drills in which a diameter of the tip portion is smaller than a drill diameter, an inclined part is provided, a relief angle β is provided only on an outer circumference, outer circumferential grooves are provided on both sides of the two cut blades, and a drill diameter is larger than the first dental drill.SELECTED DRAWING: Figure 17

Description

  The present invention relates to a dental drill and a drilling method for embedding a dental implant using the dental drill.

  Regarding the application of a drill to dental treatment, in particular, the implantation of a dental implant in the jawbone, Patent Document 1 discloses that the dental implant (ie, an artificial tooth support that is surgically fixed to the jawbone) to the body. It is disclosed to leave unhealed and unhealed for a predetermined time to ensure acceptance. During the placement of the dental implant, an accurate surgical placement of the dental implant is performed. This dental implant site is prepared using a dental drill that drills bone at a low speed, prepares the patient's jawbone, and accepts a generally cylindrical dental implant having a predetermined diameter. The diameter of the drill bit or bar used with the drill is gradually increased so that a site can be provided.

  In Patent Document 1, surgical drilling is extremely important for the success of dental implant implantation, and for this success, the biological surface of the dental implant, that is, the biomedical surface, is applied to the bone. One major reason for the need for osseointegration or osseointegration, dental implant implantation failure and rejection is to prepare the dental implant In the meantime, it is said that the bone is overheated, and it has been disclosed by numerous studies that bone cells cannot survive when subjected to temperatures of 47 ° C or higher for 1 minute. Has been.

  In the invention of Patent Document 1, in a temperature measuring instrument assembly of a surgical drill of the type having a surgical head to which a drill bar is detachably attached, the drill bar having a through hole extending to the tip of the drill bar Temperature sensor means receivable in the drill bar through-hole for detecting and measuring the temperature at the tip of the drill bar; and for indicating the temperature at the tip of the drill bar By providing a temperature measuring means coupled to the temperature sensor means, the bone is prevented from reaching a temperature of 47 ° C. or higher.

  Also, in Patent Document 2, when forming a hole for insertion into a jaw bone of a dental implant, if a drill with a large diameter is drilled from the beginning, the contact area between the drill and the jaw bone increases, and frictional heat due to rotation of the drill is increased. To increase frictional heat and increase the risk of necrosis of the jawbone, to avoid frictional heat and necrosis of the jawbone, implant hole drilling into the jawbone of the dental implant is first embedded with a small diameter drill A dental implant is formed by forming a pilot hole to a depth corresponding to the length of the dental implant, then drilling to the same depth with a drill slightly larger in diameter than the pilot hole, and repeating this process It is disclosed that it is necessary to gradually increase the diameter to match the outer diameter size.

  Patent Document 3 provides a step drill that can penetrate through the jawbone at a location that is very accurately implanted and fit locally to ensure the correct location of the implant and the subsequent denture, as perforated by a dental drill In order to achieve this object, a pilot drill for preparing an implant bed for accommodating a dental implant as a pouched stepped hole to be provided in the jawbone, and a stepped hole in advance To enlarge the pouched pilot hole provided in the jawbone (ie, to enlarge the existing stepped hole relative to a further enlarged stepped hole as a containment for a dental implant) ), A step drill, a second step drill, and a third step drill.

  In Patent Document 3, the stepped guide has a length in the range of 2.0 mm, the step drill is formed in three blades, and each has three tip blades, a polishing portion, a guide blade, a spiral groove, an oblique angle, and so on. Having a surface and a stepped blade, the drill neck has a length of at least the insertion depth of the implant (transplanted tissue) to be used, the stepped guides of the second and third step drills are 2.0 mm, 2 These first, second and third drill necks have an associated diameter in the range of 2.8 mm, 3.5 mm or 4.3 mm. It is disclosed that the tip angle located between the tip blades is greater than 90 °, particularly in the range of 120 °.

  Moreover, in patent document 4, this inventor can reduce cutting resistance significantly as a drill for general industries, and can perform the drilling operation by human power using a hand drill, a drilling machine, etc. easily. We are proposing drills that can be used widely in general industries.

  The drill described in Patent Document 4 is a drill having two cutting edges formed symmetrically about the rotation axis and having a thinned tip, and the cutting blade is viewed from the drill tip side. And a thinning cutting edge extending from the chisel edge toward the outer periphery of the drill in a shape including a curve and a main cutting edge extending from the end of the thinning cutting edge to the outer periphery of the drill, and the thinning formed by the thinning cutting edge When viewed from the front side of the drill, the surface is formed in a substantially parabolic shape inclined with respect to the drill axis direction.

Special Table 9-502911 Japanese Unexamined Patent Publication No. 2016-30090 JP-T-2006-519642 Japanese Patent No. 5051801

The dental drills disclosed in the above-mentioned Patent Documents 2 and 3 incorporate the idea of a general industrial step drill to suppress frictional heat due to the rotation of the drill, but the configuration of the drill tip is scooped. Since the angle is not specified, heat is induced when the jawbone is drilled.
Patent Document 4 does not describe application as a step drill as disclosed in Patent Documents 2 and 3.
Accordingly, the present invention provides a dental drill that appropriately defines the rake angles of the main cutting edge and the thinning cutting edge of the drill tip so that the jawbone does not become necrotic due to frictional heat accompanying the rotation of the drill, and the dental drill An object of the present invention is to provide a drilling method for embedding a dental implant using a dental drill.

The invention according to claim 1 is a dental drill having two cutting blades formed symmetrically with respect to the rotation axis and having a thinned tip portion, the cutting blade viewed from the drill tip side. And a thinning cutting edge extending from the chisel edge toward the outer periphery of the drill in a shape including a curve and a main cutting edge extending from the end of the thinning cutting edge to the outer periphery of the drill, and the thinning formed by the thinning cutting edge When the ridgeline at the boundary with the chip discharge groove on the surface is viewed from the front side of the drill, which is the opening side of the chip discharge groove, the thinning cutting edge side as it goes from the drill tip side to the base end side with respect to the drill axis direction The rake angle θ ₁ formed by the main cutting edge and the rake angle θ ₂ formed by the thinning cutting edge are formed in a substantially U shape inclined in the direction of transition from the main cutting edge to the main cutting edge side. Chisel Except below, for the first dental drill and satisfies the _{θ 1> θ 2> 0 °} .

The invention according to claim 2 is a dental drill having two cutting blades formed symmetrically about the rotational axis and having a thinned tip, and the cutting blade is seen from the drill tip side. And a thinning cutting edge extending from the chisel edge toward the outer periphery of the drill in a shape including a curve and a main cutting edge extending from the end of the thinning cutting edge to the outer periphery of the drill, and the thinning formed by the thinning cutting edge When the ridgeline at the boundary with the chip discharge groove on the surface is viewed from the front side of the drill, which is the opening side of the chip discharge groove, the thinning cutting edge side as it goes from the drill tip side to the base end side with respect to the drill axis direction The rake angle θ1 formed by the main cutting edge and the rake angle θ2 formed by the thinning cutting edge are formed in a chisel shape. straight Except below, θ1>θ2> 0 ° is satisfied, the diameter of the tip is smaller than the drill diameter, an inclined portion is provided between the tip and the outer diameter of the drill diameter, and the clearance angle β _outer Is provided only on the outer periphery of the inclined portion, the outer peripheral groove is provided on both sides of the two cutting blades, and the drill diameter is larger than that of the first dental drill.

  According to a third aspect of the present invention, in the second dental drill according to the second aspect, the drill diameter is further larger than that of the second dental drill according to the second aspect. For drills.

  According to a fourth aspect of the present invention, when an extension line obtained by extending a line extending along the deepest portion of the thinning surface in the drill tip direction is viewed from the front side of the drill, the heel of the drill is not intersected with the center portion of the drill tip. The first to third dental drills according to any one of claims 1 to 3, wherein the first to third dental drills are shifted to a side or a cutting edge side.

  The invention according to claim 5 relates to the first to third dental drills according to claim 4, wherein the width of the deviation is within 10% of the drill diameter.

  The invention according to claim 6 relates to the first to third dental drills according to claim 4 or 5, wherein the extension line is shifted toward the heel side of the drill.

  The invention according to claim 7 relates to the first to third dental drills according to claim 4 or 5, wherein the extension line is shifted toward the cutting edge side of the drill.

  The invention according to claim 8 is characterized in that an extension line obtained by extending a line extending along the deepest portion of the thinning surface in the drill tip direction intersects with a drill tip center portion when viewed from the drill front side. It is related with the 1st thru | or 3rd dental drill as described in any one of Claims 1 thru | or 3.

  The invention according to claim 9 is characterized in that a rake angle is formed in a portion including a portion directly below the chisel of the thinning cutting edge, according to any one of claims 4 to 6. Relates to dental drills.

  The invention according to claim 10 is characterized in that a rake angle is formed in a portion immediately below the chisel of the thinning cutting edge and not including the portion immediately below. The first to third dental drills according to any one of the above.

The invention according to claim 11 is characterized in that the clearance angle β _outer is 0 ° <β _outer <20 °, or the second or third dental according to any one of claims 2 to 10 For drills.

  The invention according to claim 12 is characterized in that the outer peripheral grooves are provided alternately with respect to the outer periphery of the two-blade, according to any one of claims 2 to 11. Relates to dental drills.

  The invention according to claim 13 is characterized in that the outer peripheral groove is provided at the same position with respect to the outer periphery of the two-blade, and the second or second according to any one of claims 2 to 11 3 relates to a dental drill.

  The invention according to claim 14 relates to the first dental drill according to any one of claims 1 or 4 to 10, wherein the drill diameter is 1.5 mm to 3.5 mm.

  The invention according to claim 15 relates to a second dental drill according to any one of claims 2 or 4 to 13, characterized in that the drill diameter is 3.0 mm to 5.0 mm.

  The invention according to claim 16 relates to a third dental drill according to any one of claims 3 to 13, characterized in that the drill diameter is 4.0 mm to 6.0 mm.

  The invention according to claim 17 is the first dental drill according to any one of claims 1, 4 to 10, or 14, and any one of claims 2, 4 to 13, or 15. A dental drill set comprising the second dental drill according to claim 3 and the third dental drill according to any one of claims 3 to 13 or 16.

  According to an eighteenth aspect of the present invention, (1) a first dental drill is used to drill a cortex of a jawbone at a predetermined position of the jawbone by a diameter of the first drill by the first drill tip. The first pilot hole is then drilled, and a depth measurement gauge is introduced into the first pilot hole drilled in the jawbone to control the first pilot hole to an accurate depth. And (2) inserting and drilling a second dental drill having a diameter larger than the diameter of the first dental drill into the first pilot hole to drill the second pilot hole; Introducing a depth measuring gauge corresponding to the second pilot hole drilled in the jawbone to control the second pilot hole to an accurate depth; and (3) the second dental drill. A third dental drill having a diameter greater than the diameter of the second pie A third pilot hole is formed by inserting into the pilot hole and drilling to introduce a depth measurement gauge corresponding to the third pilot hole drilled in the jawbone. And (4) a drilling method for implanting a dental implant using a dental drill, including the step of screwing an implant into the third pilot hole.

According to the first dental drill of the first aspect of the present invention, there is provided a dental drill capable of greatly reducing cutting resistance as compared with a conventional dental drill and capable of easily performing bone drilling. Can be provided. In addition, since the cutting resistance is reduced, the drilling accuracy is improved, the drilling time is shortened, the work efficiency is improved, and the drill life can be greatly extended. Furthermore, since the cutting resistance is greatly reduced, the processing heat at the time of bone drilling can be suppressed and necrosis of the jawbone can be suppressed.
In addition, the rake angle θ ₁ formed by the main cutting edge and the rake angle θ ₂ formed by the thinning cutting edge satisfy θ ₁ > θ ₂ except for the position immediately below the chisel, so that the apparent rake angle is reduced. It becomes smaller and less bites into the jawbone, making it easier to cut the jawbone. Further, by setting θ ₂ > 0 °, there is no problem when θ ₂ is changed from 0 ° to minus (the cutting resistance increases and the sharpness is deteriorated).

According to the second dental drill of the invention of claim 2, in addition to the effect of the first dental drill described above, since the inclined portion is provided between the tip portion and the outer diameter portion, A second pilot hole that is larger than the first pilot hole that conforms to the shape of the implant can be formed.
In addition, since the clearance angle β _outer is provided only on the outer periphery of the inclined portion and not on the outer periphery of the outer diameter portion, the first pilot hole opened using the dental drill of the first aspect is expanded. When making the diameter, a large cutting force can be given to the inclined portion which is a main cutting place. In addition, after the drill tip reaches the bottom of the first pilot hole, the cutting force and stability of the tip are taken into account and the drilling is promoted. Further, since the clearance angle β _outer is not provided in the outer diameter portion, the outer diameter portion proceeds along the cylindrical first pilot hole formed by the tip portion and the inclined portion, and the outer diameter portion is the cylindrical first pilot hole. Therefore, extremely stable cutting (drilling) is possible.
Furthermore, since the outer peripheral grooves are provided on both sides of the two cutting blades, the outer peripheral grooves serve as a brake, so that excessive cutting of the jaw bone can be prevented when drilling the jaw bone.

  According to the third dental drill of the invention of claim 3, in addition to the effect of the second dental drill described above, since the inclined portion is provided between the tip portion and the outer diameter portion, A third pilot hole can be formed that is larger than the second pilot hole that matches the shape of the implant.

  According to the 1st thru | or 3rd dental drill which concerns on invention of Claim 4, when the extension line which extended the line extended along the deepest part of a thinning surface to a drill tip direction is seen from a drill front side, a drill Because it is shifted to the heel side or cutting edge side of the drill without crossing the center of the tip, it is clear from the chisel to the cutting edge (some heels) or from the vicinity of the chisel to the cutting edge except directly under the chisel. A rake portion can be formed. This sharply improves the sharpness.

  According to the 1st thru | or 3rd dental drill which concerns on invention of Claim 5, since the width | variety of the said shift | offset | difference is less than 10% of a drill diameter, it was excellent in being able to reduce cutting resistance more reliably. A sharpness can be obtained.

According to the first to third dental drills of the invention of claim 6, since the extension line is shifted to the heel side of the drill, it is clear from the chisel to the cutting edge (some heel portions). A rake portion can be formed. As a result, a clear cutting edge is formed from the chisel portion to the cutting edge portion, and sharpness is dramatically improved.
Further, the rake angle is relatively large, and the cutting force is maximized as compared with the case where the extension line is displaced toward the cutting edge of the drill and the case where the extension line intersects the center of the drill tip.

  According to the first to third dental drills according to the invention of claim 7, since the extension line is shifted to the cutting blade side of the drill, it is clear from the vicinity of the chisel to the cutting blade except directly under the chisel. A scoop is obtained. There is no scoop directly under the chisel, but the chisel width is narrower than when the extension line is shifted toward the heel (case 1), and is substantially the same as when the extension line intersects the center of the drill tip (case 2). In addition, since the thinning portion can be made large, cutting resistance is reduced, and even if there is no scoop directly under the chisel, a sharpness equivalent to or better than the above two cases (cases 1 and 2) can be obtained.

  According to the 1st thru | or 3rd dental drill which concerns on invention of Claim 8, when the extension line which extended the line extended along the deepest part of a thinning surface to a drill front end direction is seen from a drill front side, a drill Since it intersects with the center of the tip, a clear cutting edge is formed from the vicinity of the chisel to the cutting edge except for the portion directly below the chisel, and sharpness is dramatically improved. In addition, since the chisel width is minimized, the cutting resistance is decreased, and the same cutting force as that obtained when the extension line is shifted to the heel side can be obtained.

  According to the first to third dental drills of the ninth aspect of the invention, since the rake angle is formed in the portion including the portion directly below the chisel of the thinning cutting blade, the jawbone is brought into contact with the cutting blade immediately below the chisel. A rake angle is formed in all the parts, and all of them act as cutting edges, so that there is an advantage that the cutting force becomes large (see FIG. 11A described later).

  According to the first to third dental drills according to the invention of claim 10, since the rake angle is formed in a portion of the thinning cutting blade near the chisel and not including the undercut, the chisel is formed. Except directly below, the part in contact with the jawbone acts as a cutting blade. As a result, a cutting force equivalent to the case where the rake angle is formed in the portion including the portion directly below the chisel of the thinning cutting edge (case 3) is obtained, but since the chisel tip becomes narrow, the cutting resistance of the chisel tip is reduced. The sharpness equivalent to the case 3 is obtained (refer to FIGS. 11B and 11C described later).

According to the second or third dental drill according to the invention of claim 11, since the relief angle β _outer provided on the outer periphery of the inclined portion is 0 ° <β _outer <20 °, A large cutting force can be given to the cutting edge while maintaining the stability of cutting.

  According to the 2nd or 3rd dental drill which concerns on invention of Claim 12, since the outer periphery groove | channel is provided alternately with respect to the outer periphery of a two-blade, the situation where a cutting blade always contacts the jawbone to cut. It can be ensured, the braking force can be increased, and the jawbone can be prevented from being cut excessively.

  According to the 2nd or 3rd dental drill which concerns on invention of Claim 13, since the outer periphery groove | channel is provided in the same position with respect to the outer periphery of a two-blade, the location where a cutting blade does not contact with the jawbone to cut. Therefore, the cutting force can be appropriately suppressed, and the jawbone can be prevented from being cut too much.

  According to the first dental drill of the fourteenth aspect of the invention, since the drill diameter is 1.5 mm to 3.5 mm, the depth is adjusted to the length of the dental implant to be embedded without damaging other than the target site. Thus, the first pilot hole can be formed.

  According to the 2nd dental drill which concerns on invention of Claim 15, since a drill diameter is 3.0 mm-5.0 mm, expanding the diameter of the 1st pilot hole drilled with the 1st dental drill. Can do.

  According to the third dental drill of the invention of claim 16, since the drill diameter is 4.0 mm to 6.0 mm, the diameter of the first pilot hole drilled by the second dental drill is expanded. Can do.

  According to the dental drill set according to the invention of claim 17, it is possible to provide a dental drill set having the effects of the first to third dental drills described above, which has a large cutting force and suppresses processing heat. Accordingly, it is possible to prevent the death of jaw bone cells and the like, and to safely form the third pilot hole that matches the shape of the dental implant of an appropriate size without excessively cutting the jaw bone.

  According to the drilling method for implanting a dental implant using the first to third dental drills according to the invention of claim 18, the first to third dental drills having a large cutting force are used. In this way, the processing heat is suppressed, the cell death of jaw bone cells and the like is prevented, and the jaw bone is not cut too much, and the third pilot hole that conforms to the shape of an appropriately sized dental implant is formed safely. Can provide a way to do.

It is a figure which shows the drill which concerns on 1st embodiment of this invention, Comprising: (a) is a top view (figure which looked at the drill from the front end side), (b) is a front view of a front-end | tip part. It is the figure which looked at the drill which concerns on this invention from the slightly left direction rather than FIG.1 (b). It is a figure which defines a clearance angle. It is a figure which shows the angle which applies a drill to a grindstone at the time of thinning formation. It is a figure which shows the angle of a thinning. (A) is a figure which shows a cross section orthogonal to a thinning part, (b) is a figure which shows the cross-section site | part (AA cross section) of (a). It is a figure which shows another example of the edge part shape of a rake face. It is a figure which shows the drill of 2nd embodiment of this invention, Comprising: (a) is a top view (figure which looked at the drill from the front end side), (b) is a front view of a front-end | tip part. It is a figure which shows the drill of 3rd embodiment of this invention, Comprising: (a) is a top view (figure which looked at the drill from the front end side), (b) is a front view of a front-end | tip part. It is a figure which shows the drill of 4th embodiment of this invention, Comprising: (a) is a top view (figure which looked at the drill from the front end side), (b) is a front view of a front-end | tip part. It is sectional drawing which cut | disconnected the drill which concerns on this invention to the vertical direction (drill length direction) along the chisel, (a) is the drill of 2nd embodiment, (b) is the drill of 3rd embodiment, ( c) is the drill of the fourth embodiment. It is a figure which shows the example of the grindstone shape for creation of the thinning cutting blade in the drill which concerns on this invention, and has shown the rotation end part (outer peripheral part) of the grindstone. It is a figure which shows the example of the grindstone shape for creation of the thinning cutting blade in the drill which concerns on this invention, and has shown the rotation end part (outer peripheral part) of the grindstone. It is a figure which shows the drill of 6th embodiment of this invention, Comprising: (a) is a side view, (b) is sectional drawing of an inclination part and an outer peripheral part. It is a side view of the drill of 7th embodiment of this invention. It is explanatory drawing of the outer periphery groove | channel provided in the dental drill which concerns on this invention, Comprising: (a) is the shape where the outer periphery groove | channel was provided alternately with respect to the outer periphery of a two-blade, and the entrance of the outer periphery groove | channel inclined toward the drill front end side. , (B) is a shape in which the outer peripheral groove is provided at the same position with respect to the outer periphery of the two-blade and the inlet of the outer peripheral groove is inclined toward the drill tip side, (c) is the outer peripheral groove alternately with respect to the outer periphery of the two-blade. (D) is a shape in which the inlet of the outer peripheral groove is inclined toward the handle, and (d) is a shape in which the outer peripheral groove is provided at the same position with respect to the outer periphery of the two-blade and the inlet of the outer peripheral groove is inclined toward the handle, The outer peripheral groove is provided alternately with the outer periphery of the two-blade blade, and the inlet of the outer peripheral groove is substantially V-shaped when viewed from the side, with both the drill tip side and the handle side inclined, and (f) has two outer peripheral grooves. (G) is a substantially V-shaped shape in side view, provided at the same position with respect to the outer periphery of the blade, and the inlet of the outer peripheral groove is inclined to both the drill tip side and the handle side. (H) shows a substantially U-shaped outer circumferential groove, and (i) shows a partial region (X) of the outer circumferential groove having a substantially rectangular side view in (g). (J) is an enlarged view of a partial region (Y) of an outer circumferential groove that is substantially U-shaped in side view in (h). It is a figure which shows a mode that bone drilling is carried out in steps using the dental drill which concerns on this invention. It is a drawing substitute photograph which shows the test piece used for the cutting performance test, and the measurement position of temperature and cutting resistance.

Hereinafter, a preferred embodiment of a dental drill according to the present invention will be described with reference to the drawings.
1A and 1B are views showing a first embodiment of a dental drill according to the present invention, wherein FIG. 1A is a top view (a view of the drill viewed from the tip side), and FIG. 1B is a front view of the tip portion. .

The dental drill according to the present invention has two cutting edges formed symmetrically with respect to the rotational axis, and the tip is thinned.
The cutting blade is a thinning cutting blade (1) extending in a shape including a curve from the chisel edge toward the outer periphery of the drill when viewed from the drill tip side, and a main extending from the end of the thinning cutting blade (1) to the outer periphery of the drill It consists of a cutting blade (2). In the illustrated example, the main cutting edge (2) extends linearly from the end of the thinning cutting edge (1) to the outer peripheral edge of the drill, but may extend in a curved line, It may extend linearly including a curved portion. This is common to all embodiments of the present invention.
In the figure, (3) is a flank, (4) is a chisel, (5) is a rake face formed by the main cutting edge (2), (6) is a new rake face formed by thinning, (W) Is the chisel width.

In the dental drill of the first embodiment, the length of the main cutting edge (2) is (A) and the length of the thinning cutting edge (1) is the cutting edge length in the extending direction of the main cutting edge (2). When (B), 0 <A ≦ B is satisfied.
By setting the length (B) of the thinning cutting edge (1) to be equal to or longer than the length (A) of the main cutting edge (2), compared with the conventional dental drill where A> B It may be possible to greatly reduce the cutting resistance.
However, in the present invention, A> B may be satisfied, as shown in the embodiments described later (see FIGS. 8 and 10).

  In the dental drill of the first embodiment, the cutting resistance is reduced as the ratio (B / (A + B)) of the length (B) of the thinning cutting edge (1) to the entire cutting edge length (A + B) is larger. Therefore, it is preferable to lengthen the length (B) of the thinning cutting edge (1) as much as possible and shorten the length (A) of the main cutting edge (2). However, when the length (A) of the main cutting edge (2) becomes 0, the surface accuracy of the drilled hole is lowered, so that 0 <A is necessary. Preferably, it is set so as to satisfy R × 0.1 ≦ A with respect to the drill radius (R).

FIG. 2 is a view of the dental drill of the first embodiment as seen from the left slightly from the front.
And rake angle formed by the main cutting edge (2) (θ _1), rake angle formed by the thinning cutting edge (1) (θ ₂₎ is, θ _1> θ _2> 0 satisfy °. However, just below the chisel (4), θ ₂ ≈0 ° (θ ₂ <0 ° close to 0 °).
The rake angle (θ ₂ ) formed by the thinning cutting edge (1) is smaller than the rake angle (θ ₁ ) formed by the main cutting edge (2). Means that it becomes smaller (relaxes).
In the present invention, by forming the thinning cutting edge (1) so as to satisfy θ ₁ > θ ₂ , the apparent rake angle is reduced, the amount of biting into the work piece is reduced, and it can be easily cut. .

The reason why θ ₂ > 0 ° is that when the rake angle (θ ₂ ) formed by the thinning cutting edge (1) is changed from 0 ° to minus, the cutting resistance is increased and the sharpness is worsened. Incidentally, the conventional drill is thinned so that the rake angle becomes negative because the cutting edge is easily chipped if there is a rake at the center.

The twist angle of the drill varies depending on the type of drill, but is set to approximately 30 °. However, the cutting resistance increases at this angle.
There is a method to reduce the cutting resistance by reducing the rake angle by reducing the torsion angle, but it can be seen only by thinning as in the present invention without changing the conventional torsion angle rather than making a drill by changing the torsion angle. The method of changing the rake angle has the great advantage that it can be performed very easily.

Included angle formed by the main cutting edge (2) and (alpha _1), the cutting edge angle formed by the thinning cutting edge (1) (alpha ₂₎ is, α ₁ <α ₂ <satisfy 90 ° (Note, alpha ₍ Refer to FIG. 6 for ₁ and α ₂ ).

Here, a supplementary explanation of the rake angle and the edge angle will be given.
The rake angle inherent to the drill (rake angle before thinning formation) is too sharp and the cutting edge bites into the workpiece like a wedge, so that the cutting resistance increases.
By performing thinning, the rake angle is reduced and the edge angle is increased, thereby improving the sharpness (cutting resistance is reduced). In particular, according to the thinning applied to the dental drill according to the present invention, a gentle rake angle and a large cutting edge angle suitable for work are created.

The clearance angle (β) is set so as to satisfy 0 ° <β <8 °. Preferably, it is set so as to satisfy 0 ° <β ≦ 4 °.
In general, it is thought that a sharp cutting edge can be obtained by increasing the rake angle and increasing the rake angle, so that the sharpness can be obtained. have.
In the present invention, by setting the clearance angle (β) as small as 0 ° <β ≦ 4 °, the amount of biting into the workpiece is reduced and the workpiece can be cut easily.

Here, the clearance angle (β) is defined by the following (A) or (B).
(B) The center of the drill tip is aligned with the horizontal center line of the grinding wheel outer periphery with a radius of 50 mm or more, the cutting edge of the drill tip is applied parallel (= horizontal) to the grinding wheel horizontal center line, and the rear end of the drill Is an angle formed by the grindstone horizontal center line and the drill center axis when the drill is lowered from the grindstone horizontal center line around the drill tip (see FIG. 3A).
(B) Align the center of the drill tip with the grindstone horizontal center line on the side of the grindstone (vertical plane), place the cutting edge of the drill tip parallel to the grindstone horizontal center line (= horizontal), and place the rear end of the drill The angle formed by the grindstone horizontal center line and the drill center axis when lowered from the grindstone horizontal centerline around the drill tip (see FIG. 3B).

However, in (A) and (B), the angle produced by the grinding wheel radius shown in FIG. 3A and the distance from the drill center to the cutting edge: 1/2 W (W: core thickness) (grinding wheel radius) When the thickness (W) is 50 mm at 50 mm, a difference of about 0.573 °, about 0.286 ° at a radius of 100 mm, and about 0.191 ° at a radius of 150 mm occurs.
Therefore, when calculating | requiring by (A), it is preferable to make into a clearance angle what added this difference. In other words, the clearance angle is preferably obtained as in the following formula.
(A) (FIG. 3A): clearance angle = β + tan ⁻¹ ((1−cos (sin ⁻¹ 0.5 W / R)) R ÷ 0.5 W)
(B) (FIG. 3B): clearance angle = β
For example, the actual clearance angle of a drill having a diameter of 10 mm and a core thickness of 2 mm polished with a grinding wheel having a clearance angle of 3 ° and a radius (R) of 50 mm is about 3.573 °.

  The chisel width (W) (see FIG. 1A) is preferably set to be small so that the workpiece can be cut easily. Specifically, it is preferably set to 10% or less of the drill diameter. For example, when the drill diameter φ is 2 to 13 mm, the chisel width (W) is set to be increased or decreased in the range of 0.1 to 0.8 mm according to the increase or decrease of the drill diameter.

In the present invention, the thinning angle is set smaller than that of a conventional drill.
In the conventional thinning, in order to give priority to the strength and rigidity of the drill itself, the angle (θ) at which the drill is applied to the grindstone at the time of thinning formation is increased (see FIG. 4A).
If the angle (θ) is reduced as much as possible and the center of the drill is brought close to the grinding surface tangent of the grindstone, the resistance of the portion called the web at the center of the drill is not received, so the cutting resistance is greatly reduced (FIG. 4B). reference).

Therefore, in the present invention, it is preferable to set the thinning angle so as to satisfy the following (I) and (II).
(I) The angle (θ in FIG. 4) formed by the drill center axis with respect to the vertical center line of the grindstone to be thinned is 0 to 20 °.
(II) The angle formed by the drill center axis with respect to the center line in the width direction of the grindstone for thinning is 20 to 35 ° (see FIG. 5)
However, the range of the thinning angle (II) is obtained when the tip angle is 118 ° and the twist angle is 30 °, and is not necessarily suitable for all drills. Theoretically, the upper limit value of the thinning angle in the above (II) is set to a range up to a half angle (59 ° in the case of 118 °) of a position parallel to the cutting edge of the drill (= tip angle). be able to.

Next, the shape of the thinning will be described.
Fig.6 (a) is a figure which shows the cross section (AA cross section of FIG.6 (b)) at right angles to the thinning part of a drill.
In the example shown in FIG. 6A, the edge of the rake face (6) formed by thinning (the boundary with the rake face (5) formed by the main cutting edge (2)) is the radius of the thinning ( R ₂ ) is formed in an arc shape. Note that (R ₁ ) is the radius of the drill groove.
As shown, the main cutting edge (2) rake angle formed by the (theta _1), rake angle formed by the thinning cutting edge (1) (theta ₂₎ is, θ _1> θ _2> a 0 ° Fulfill.
Moreover, the main cutting edge angle formed by the (2) (α _1), the cutting edge angle formed by the thinning cutting edge (1) (α ₂₎ satisfy the _{α 1 <α 2 <90 °} .

In the present invention, the edge shape of the rake face is not limited to an arc shape, but may be a shape combining an arc and a straight line (see FIG. 7).
The inventors of the present invention have the same sharpness when the edge shape of the rake face is an arc shape (FIG. 6A) and when the edge shape is a combination of an arc and a straight line (FIG. 7). Experiments have confirmed that there is no difference in resistance.

When the ridgeline of the boundary with the chip discharge groove of the thinning surface (8) formed by the thinning cutting edge (1) is seen from the front side of the drill, the dental drill according to the present invention has a drill axis direction (C). It is formed in a substantially parabolic shape (substantially U-shaped) that is inclined with respect to (see FIG. 2). In the present invention, the “front side of the drill” refers to the opening side of the chip discharge groove.
As shown in the figure, the direction of the inclination is the direction of transition from the thinning cutting edge (1) side to the main cutting edge (2) side as it goes from the drill tip side to the base end side (downward diagonally downward in front view). It is. The same applies to later-described embodiments.
The angle of inclination (γ) is set in the range of 20 to 35 ° (for example, 27.5 °). As described above, this angle setting is performed by setting the angle formed by the drill center axis with respect to the center line in the width direction of the grindstone to be thinned to be 20 to 35 ° (see FIG. 5). it can. When thinning is performed, the angle at which the center of the grindstone (see the alternate long and short dash line (L) in FIG. 1A) is tilted with respect to the center axis in the longitudinal direction of the drill is determined by taking into account the twist angle of the drill. It is preferable to set in the range of ° to twist angle + 10 °. However, theoretically, this angle can be set from a twist angle of −10 ° to a half of the tip angle on the cutting edge side.
These configurations (the shape of the thinning cutting edge, the direction of inclination, and the angle of inclination) are common to the drills of all the embodiments of the present invention.

8A and 8B are views showing a dental drill according to a second embodiment of the present invention, in which FIG. 8A is a top view (a view of the drill viewed from the distal end side), and FIG. 8B is a front view of the distal end portion.
The dental drill of the second embodiment has a substantially parabolic shape in which the thinning surface (8) formed by the thinning cutting edge (1) is inclined with respect to the drill axial direction (C) when viewed from the drill front side. It is formed in a (substantially U shape) (see FIG. 8B).
An extension line (D) extending along the deepest part (the deepest part scraped off by thinning) of the thinning surface (8) formed by the thinning cutting edge (1) extends in the direction of the drill tip is the front side of the drill When viewed from the top, it is shifted to the heel side of the drill without intersecting with the center (7) of the drill tip.
The deviation amount (d) is preferably within 10% of the drill diameter. This is because if it exceeds 10%, the cutting resistance increases and the sharpness decreases.

A rake angle is formed at a portion of the thinning cutting edge (1) including the portion directly below the chisel (4). In FIG. 8A, the rake face forming the rake angle is indicated by reference numeral (10).
Since the rake angle is formed in the portion including directly under the chisel (4), a portion (9) in which the width in the direction parallel to the chisel is narrower than the chisel width (W) is formed immediately under the chisel (4). ing. (See Fig. 11 (a))

In the dental drill of the second embodiment, the length of the main cutting edge (2) is (A) and the length of the thinning cutting edge (1) is the cutting edge length in the extending direction of the main cutting edge (2). When (B), A> B.
And rake angle formed by the main cutting edge (2) (θ _1), rake angle formed by the thinning cutting edge (1) (θ ₂₎ satisfies the _{θ 1> θ 2> 0 °} . The same is true immediately below the chisel (4).

9A and 9B are views showing a dental drill according to a third embodiment of the present invention, in which FIG. 9A is a top view (a view of the drill viewed from the tip side), and FIG. 9B is a front view of the tip portion.
The dental drill of the third embodiment also has a substantially parabolic shape in which the thinning surface (8) formed by the thinning cutting edge (1) is inclined with respect to the drill axial direction (C) when viewed from the drill front side. It is formed in a (substantially U shape) (see FIG. 9B).
An extension line (D) extending in the drill tip direction from a line extending along the deepest part of the thinning surface (8) formed by the thinning cutting edge (1) is the center of the drill tip ( 7) Misaligned to the cutting edge side of the drill.
The deviation amount (d) is preferably within 10% of the drill diameter. This is because if it exceeds 10%, the cutting resistance increases and the sharpness decreases.

  A rake angle is formed in a portion of the thinning cutting edge (1) in the vicinity immediately below the chisel (4) and not including the direct bottom. More specifically, a rake angle is formed on the main cutting edge (2) side from directly below the chisel (4) of the thinning cutting edge (1). In FIG. 9A, the rake face forming the rake angle is indicated by reference numeral (10).

In the dental drill of the third embodiment, the length of the main cutting edge (2) is (A) and the length of the thinning cutting edge (1) is the cutting edge length in the extending direction of the main cutting edge (2). When (B), 0 <A ≦ B is satisfied.
And rake angle formed by the main cutting edge (2) (θ _1), rake angle formed by the thinning cutting edge (1) (θ ₂₎ is, θ _1> θ _2> 0 satisfy °. However, just below the chisel (4), θ ₂ ≈0 ° (θ ₂ <0 ° close to 0 °).

10A and 10B are views showing a dental drill according to a fourth embodiment of the present invention, wherein FIG. 10A is a top view (a view of the drill viewed from the tip side), and FIG. 10B is a front view of the tip portion.
The dental drill of the fourth embodiment also has a substantially parabolic shape (substantially U) when the thinning surface formed by the thinning cutting edge (1) is inclined with respect to the drill axis direction (C) when viewed from the front side of the drill. (Refer to FIG. 10B).
An extension line (D) extending in the drill tip direction from a line extending along the deepest part of the thinning surface (8) formed by the thinning cutting edge (1) is the center of the drill tip ( 7)

  A rake angle is formed in a portion of the thinning cutting edge (1) in the vicinity immediately below the chisel (4) and not including the direct bottom. More specifically, a rake angle is formed on the main cutting edge (2) side from directly below the chisel (4) of the thinning cutting edge (1). In FIG. 10A, the rake face forming the rake angle is indicated by reference numeral (10).

In the dental drill of the fourth embodiment, the cutting edge length in the extending direction of the main cutting edge (2) is the length of the main cutting edge (2) (A) and the length of the thinning cutting edge (1). When (B), A> B.
And rake angle formed by the main cutting edge (2) (θ _1), rake angle formed by the thinning cutting edge (1) (θ ₂₎ is, θ _1> θ _2> 0 satisfy °. However, just below the chisel (4), θ ₂ ≈0 ° (θ ₂ <0 ° close to 0 °).

  The dental drill of the fifth embodiment has the characteristics of any of the dental drills of the first to fourth embodiments described above, and has a drill diameter of 1.5 mm to 3.5 mm, preferably 1.5 mm to 2. 5 mm dental drill. By using the above-described drill diameter, the first pilot hole can be formed to a depth corresponding to the length of the dental implant to be embedded. Moreover, by providing any of the features of the dental drill according to the first to fourth embodiments, cutting resistance is lower than that of the conventional dental drill, and processing heat during bone drilling can be suppressed. .

In the dental drill of the sixth embodiment, the diameter (11) of the drill tip is smaller than the drill diameter (12), and the inclined portion (15) is provided between the tip (13) and the outer diameter (14). The clearance angle (β _outer ) is provided only on the outer periphery of the inclined portion (15) (see FIG. 14B), and the outer peripheral groove (16) is provided on both sides of the two cutting edges (FIG. 14). (See (a)). The drill diameter is 3.0 mm to 5.0 mm, preferably 3.0 mm to 4.0 mm. The dental drill according to the sixth embodiment has any of the characteristics of the dental drill according to the first to fourth embodiments except for the characteristics described above. By being said drill diameter, the 1st pilot hole vacated with the dental drill of 5th embodiment can be expanded.
Since the dental drill according to the present invention has different diameters in the groove length (17), the drill diameter (12) in this specification refers to the largest diameter in the groove length (17).
Moreover, in this specification, the outer peripheral part of the site | part which has a drill diameter (12) is called outer-diameter part (14).

In the dental drill of the sixth embodiment, since the diameter (11) of the drill tip is smaller than the drill diameter (12), the inclined portion (15) is provided between the tip (13) and the outer diameter (14). It is formed. Since the cutting for expanding the diameter of the first pilot hole is mainly performed at the inclined portion (15), a clearance angle (β _outer ) is provided only on the outer periphery of the inclined portion (15), and the inclined portion (15 ) Give the cutting blade a large cutting force.
The clearance angle (β _outer ) of the inclined portion (15) is set so as to satisfy 0 ° <β _outer <20 °. Preferably, it is set to satisfy 0 ° <β _outer ≦ 15 °, more preferably 0 ° <β _outer <8 °.
In addition, it is preferable not to provide a clearance angle (β _outer ) in the _outer diameter portion (14). Thereby, when expanding the diameter of the 1st pilot hole vacated using the dental drill of 5th embodiment, it cuts with the cutting edge of an inclination part (15) mainly, and a front-end | tip part (13) is 1st. After reaching the bottom of one pilot hole, the cutting force and stability of the tip (13) are taken into account to promote drilling. Further, since the clearance angle (β _outer ) is not provided in the _outer diameter portion (14), the outer diameter portion (14) proceeds along the cylindrical pilot hole formed by the tip portion (13) and the inclined portion (15). 14) is supported by a cylindrical pilot hole, and extremely stable cutting (drilling) is possible.
Since the dental drill of the sixth embodiment has the inclined portion (15), the second pilot hole that matches the shape of the dental implant can be formed by performing bone drilling using the dental drill. .

In the dental drill of the sixth embodiment, outer peripheral grooves (16) are provided on both sides of the two cutting edges. By providing the outer circumferential groove (16), the outer circumferential groove (16) can act as a brake during cutting, preventing overcutting of the jawbone.
As shown in FIG. 16, the outer peripheral grooves (16) are provided alternately with respect to the outer periphery of the two-blade, or are provided at the same position with respect to the outer periphery of the two-blade. Moreover, an outer peripheral groove | channel (16) may be alternately arrange | positioned in a certain location with respect to the outer periphery of a 2 blade, and may be arrange | positioned in the same location in a certain location. By alternately providing the outer periphery of the two blades, it is possible to ensure that the cutting blades are always in contact with the pilot holes to be cut. Moreover, by providing in the same position with respect to the outer periphery of 2 blades, since the location where a cutting blade does not contact with the pilot hole to cut is made, cutting force is suppressed.

  As shown in FIGS. 16 (a) to 16 (f), the shape of the inlet of the outer peripheral groove (16) is inclined to the drill tip side, inclined to the handle side, and inclined to both the drill tip side and the handle side. The side view is generally V-shaped, the side view is substantially rectangular as shown in FIG. 16G, or the side view is substantially U-shaped as shown in FIG. 16 (i) is an enlarged view of a partial region (X) of the outer peripheral groove having a substantially rectangular shape in side view in FIG. 16 (g), and FIG. 16 (j) is a schematic view U in side view in FIG. 16 (h). It is an enlarged view of the partial area | region (Y) of a character-shaped outer periphery groove | channel. By having an inclination at the inlet of the outer peripheral groove, the braking force at the time of cutting can be further increased.

The dental drill of the seventh embodiment has the same features as the dental drill of the sixth embodiment described above, and only the drill diameter is different (see FIG. 15). The diameter of the dental drill of the seventh embodiment is 4.0 mm to 6.0 mm, preferably 4.0 mm to 5.0 mm. By using the above-mentioned drill diameter, the diameter of the second pilot hole formed by the dental drill of the sixth embodiment can be increased, and the third pilot hole having an appropriate size and shape can be formed. it can.

In the dental drills of the second to seventh embodiments, as in the case of the dental drill of the first embodiment, when the thinning cutting edge (1) is viewed from the front side of the drill, the drill axis direction ( It is characterized by being formed in a substantially parabolic shape (substantially U-shaped) inclined with respect to C).
Thereby, even if 0 <A ≦ B is not satisfied, the load applied to the chisel is reduced, and the chisel width can be narrowed. Specifically, the chisel width after thinning can be reduced to about 3 to 5% of the drill diameter. Therefore, cutting resistance can be reduced and an excellent sharpness can be obtained, which exerts a great effect on bone drilling.

The first to seventh embodiments according to the present invention have been described above, but when forming the pilot hole for the implant, the three dental drills of the fifth to seventh embodiments should be used as a set. Is desirable. However, the dental drill of the first to seventh embodiments may be used alone or in combination.
Moreover, the material of the dental drill according to the present invention is preferably a material determined for medical use such as stainless steel or titanium alloy.

Hereinafter, the shape of the grindstone for creating the thinning cutting edge (1) in the drill according to the present invention will be described. 12-13 is a figure which shows the example of a grindstone shape, and has shown the rotation edge part (outer peripheral part) of the grindstone.
The grindstone is a grindstone having one or more radii of curvature at the rotating end.
One of the curvature radius of the grindstone and R _1, to the R ₁ primarily radius for thinning cutting edge created across the cutting edge. Next adjacent to the R ₁ to the radius of curvature R ₂ that forms a curved surface smoothly connected to the R _1, mainly provided to strike the heel.

The _{R 1} and the two radii of curvature of the combination of _{R 2} to the basic, depending on the ratio of the diameter and web thickness of the drill, as shown in FIG. 13, the magnitude relation of _{R 1} and _{R 2 (R} 1 = _{R 2} , R ₁ <R ₂ , R ₁ > R ₂ ), a larger R ₃ between R ₁ and R ₂ to accommodate a thick drill, or a larger radius of curvature for the wheel width Therefore, small R ₄ and R ₅ are formed at the grindstone corner.
A grindstone that combines one or more radii of curvature may also be used.
Further, as shown in FIG. 13, thinning may be performed by including a straight portion between the R portions or by inclining the side surfaces.

  Below, the bone cutting method for the implant using the dental drill of 5th to 7th embodiment is described as an example (refer FIG. 17). In addition, bone drilling may be performed by a combination of the embodiments other than the above-described combinations or by use alone, and a commonly used method may be used as a drilling method.

Bone drilling consists of steps (1) to (4).
Step (1): In this step, the first dental drill (DR1) is used to place the cortex of the jawbone at a predetermined position of the jawbone according to the diameter of the first dental drill. A first pilot hole (PO1) is formed by drilling with a drill tip, and a depth measuring gauge is introduced into the first pilot hole (PO1) drilled in the jawbone, thereby the first pilot. Control the hole to the correct depth.
Step (2): In this step, a second dental drill (DR2) having a diameter larger than the diameter of the first dental drill (DR1) is inserted into the first pilot hole (PO1) and drilled. The second pilot hole (PO2) is drilled, and a depth measurement gauge corresponding to the second pilot hole (PO2) drilled in the jawbone is introduced to introduce the second pilot hole (PO2). To the correct depth.
Step (3): In this step, a third dental drill (DR3) having a diameter larger than the diameter of the second dental drill (DR2) is inserted into the second pilot hole (PO2) and drilled. The third pilot hole (PO3) is drilled, and a depth measurement gauge corresponding to the third pilot hole (PO3) drilled in the jawbone is introduced to introduce the third pilot hole (PO3). To the correct depth.
Step (4): In this step, the implant is screwed into the third pilot hole (PO3).
The first, second, and third dental drills can be those of the fifth to seventh embodiments described above, but are not limited thereto.

  By the above method, the third pilot hole that prevents cell death such as jaw bone cells at the time of cutting and that does not cut the jaw bone excessively and conforms to the shape of an appropriately sized dental implant can be formed. Can do.

Cutting performance tests were performed using the dental drills of the examples of the present invention and the comparative examples.
(Test method)
A test piece with a model bone cut into a ring is attached to an NC milling machine, and cutting is performed with a total of 4 types × 3 types of dental drills of Comparative Example and Example 1-3, and the temperature generated during each cutting and the vertical direction The cutting resistance generated in each was measured, and the performance of each drill due to heat generation and sharpness was compared (see FIG. 18).
Each type of drill is divided into three stages (1st to 3rd) and enlarged sequentially, and the final shape (third pilot hole) can be formed in the third stage (3rd).
Cutting with various drills was performed under the following conditions.
Temperature: 16 ° C
Model bone (test piece) surface temperature: 12 ° C
Number of revolutions: 8.33 s ^-1
Feed rate: 0.1 mm / rev.
The outer peripheral grooves of the 2nd and 3rd drills of Example 1-3 are formed such that the outer peripheral grooves are alternately provided with respect to the outer periphery of the two-blade and the inlet of the outer peripheral groove is inclined toward the drill tip side ((a) of FIG. 16 Used).
Table 1 below shows the presence or absence of the outer peripheral groove of Example 1-3.

(Test results)
Table 2 shows the measured values of the temperature generated during cutting with various drills and the cutting resistance generated in the vertical direction.
Table 3 shows the characteristics of Example 1-3 obtained from the cutting performance test.

In the 2nd and 3rd drills of the comparative examples, the temperature generated during the cutting exceeded 47 ° C. at which bone cells could be necrotized and reached 50 ° C., but in all of the drills of Example 1-3, the temperature was less than 47 ° C. It was temperature.
Further, the cutting resistance was 3.4 to 5.5 kg in the comparative example, but 1.1 to 2.0 kg in the example.
In addition, by providing grooves in the inclined part and outer peripheral part of the 2nd and 3rd drills, the cutting resistance slightly increases, but it becomes possible to improve the operability while keeping the generated temperature at the time of cutting low. Can be prevented and overcutting can also be prevented.
As described above, the dental drill of the present invention can greatly reduce the cutting resistance as compared with the conventional dental drill, and can prevent the necrosis of the jawbone by suppressing the temperature rise during the cutting. Furthermore, by providing the groove in the inclined portion and / or the outer peripheral portion, the groove becomes a stopper, and it is possible to prevent overcutting.

  The dental drill according to the present invention is suitably used as a drill for drilling into a jaw bone for implanting a dental implant into the jaw bone.

DESCRIPTION OF SYMBOLS 1 Thinning cutting edge 2 Main cutting edge 3 Relief face 4 Chisel 5 Rake face formed by main cutting edge 6 Rake face formed by thinning 7 Drill tip center part 8 Thinning face formed by thinning cutting edge 9 Parallel to chisel The width 10 in the narrow direction is narrower than the chisel width 10 The rake face forming a rake angle 11 The diameter of the drill tip 12 The drill diameter 13 The tip 14 The outer diameter 15 The inclined part 16 The outer peripheral groove 17 The groove length A Length B Thinning blade length C Drill axial direction D Extension line DR1 extending along the deepest part of the thinning surface in the drill tip direction First dental drill DR2 Second dental drill DR3 First 3 dental drill d displacement PO1 first pilot hole PO2 second pilot hole PO3 third pilot hole R drill radius X of the outer peripheral groove having a substantially rectangular shape in side view Min region Y side view the U-shaped peripheral groove subregion theta ₁ main cutting edge angle formed by the rake angle alpha ₁ major cutting edge formed by the rake angle theta ₂ thinning cutting edge formed by the cutting edge alpha ₂ radius W chisel width to form the rake face by a radius R ₂ thinning to form the rake surface by an inclination angle R ₁ main cutting edge clearance angle γ thinned face of the cutting angle beta clearance angle beta _outer inclined portion formed by thinning the cutting edge θ Angle at which the drill hits the grinding wheel during thinning

Claims (18)

A dental drill having two cutting edges formed symmetrically about the rotational axis and having a thinned tip.
When the cutting blade is viewed from the drill tip side, a thinning cutting blade extending in a shape including a curve from the chisel edge toward the drill outer peripheral side, and a main cutting blade extending from the end of the thinning cutting blade to the drill outer peripheral end Become
When the ridgeline at the boundary between the thinning surface and the chip discharge groove formed by the thinning cutting edge is viewed from the front side of the drill, which is the opening side of the chip discharge groove, the base from the drill tip side with respect to the drill axis direction. As it goes to the end side, it is formed in a substantially U-shape inclined in the direction of transition from the thinning cutting edge side to the main cutting edge side,
The rake angle θ ₁ formed by the main cutting edge and the rake angle θ ₂ formed by the thinning cutting edge satisfy θ ₁ > θ ₂ > 0 °, except directly below the chisel. 1 dental drill. A dental drill having two cutting edges formed symmetrically about the rotational axis and having a thinned tip.
When the cutting blade is viewed from the drill tip side, a thinning cutting blade extending in a shape including a curve from the chisel edge toward the drill outer peripheral side, and a main cutting blade extending from the end of the thinning cutting blade to the drill outer peripheral end Become
When the ridgeline at the boundary between the thinning surface and the chip discharge groove formed by the thinning cutting edge is viewed from the front side of the drill, which is the opening side of the chip discharge groove, the base from the drill tip side with respect to the drill axis direction. As it goes to the end side, it is formed in a substantially U-shape inclined in the direction of transition from the thinning cutting edge side to the main cutting edge side,
The rake angle θ1 formed by the main cutting edge and the rake angle θ2 formed by the thinning cutting edge satisfy θ1>θ2> 0 °, except under the chisel,
The diameter of the tip is smaller than the drill diameter,
An inclined part is provided between the tip part and the outer diameter part of the drill diameter,
The clearance angle β _outer is provided only on the outer periphery of the inclined portion,
Outer circumferential grooves are provided on both sides of the two cutting edges,
A second dental drill having a drill diameter larger than that of the first dental drill.   3. The second dental drill according to claim 2, wherein the drill diameter is larger than that of the second dental drill according to claim 2.   When the extension line extending in the direction of the drill tip extends from the line extending along the deepest portion of the thinning surface when viewed from the front side of the drill, the extension line shifts to the heel side or the cutting edge side of the drill without intersecting the drill tip center portion. The 1st thru | or 3rd dental drill as described in any one of Claim 1 thru | or 3 characterized by the above-mentioned.   5. The first to third dental drills according to claim 4, wherein a width of the shift is within 10% of a drill diameter.   The first to third dental drills according to claim 4 or 5, wherein the extension line is shifted toward a heel side of the drill.   The first to third dental drills according to claim 4 or 5, wherein the extension line is shifted to a cutting edge side of the drill.   The extension line which extended the line extended along the deepest part of the said thinning surface to the drill front-end | tip direction crosses a drill front-end | tip center part, when it sees from the said drill front side. The 1st thru | or 3rd dental drill as described in one.   The first to third dental drills according to any one of claims 4 to 6, wherein a rake angle is formed in a portion including a portion directly below the chisel of the thinning cutting edge.   9. The rake angle is formed in a portion of the thinning cutting blade in the vicinity immediately below the chisel and not including the direct bottom, 9. Thru third dental drill. The second or third dental drill according to any one of claims 2 to 10, wherein the clearance angle β _outer is 0 ° <β _outer <20 °.   The second or third dental drill according to any one of claims 2 to 11, wherein the outer circumferential grooves are provided alternately with respect to the outer circumference of the two-blade.   The second or third dental drill according to any one of claims 2 to 11, wherein the outer peripheral groove is provided at the same position with respect to the outer periphery of the two-blade.   The first dental drill according to any one of claims 1 or 4 to 10, characterized in that the drill diameter is between 1.5 mm and 3.5 mm.   14. A second dental drill according to any one of claims 2 or 4 to 13, characterized in that the drill diameter is between 3.0 mm and 5.0 mm.   The third dental drill according to any one of claims 3 to 13, characterized in that the drill diameter is 4.0 mm to 6.0 mm. A first dental drill according to any one of claims 1, 4 to 10, or 14;
A second dental drill according to any one of claims 2, 4 to 13, or 15;
A dental drill set comprising the third dental drill according to any one of claims 3 to 13 or 16. (1) Using a first dental drill, a first pilot hole is formed by drilling the cortex of the jawbone with the first drill tip at a predetermined position of the jawbone according to the diameter of the first drill. Drilling and introducing a depth measurement gauge into the first pilot hole drilled in the jawbone to control the first pilot hole to an accurate depth;
(2) A second dental drill having a diameter larger than the diameter of the first dental drill is inserted into the first pilot hole and drilled to form a second pilot hole, so that the inside of the jaw bone Introducing a depth measuring gauge corresponding to the second pilot hole drilled in to control the second pilot hole to an accurate depth;
(3) A third dental drill having a diameter larger than that of the second dental drill is inserted into the second pilot hole and drilled to form a third pilot hole. Introducing a depth measurement gauge corresponding to the third pilot hole drilled in to control the third pilot hole to an accurate depth;
(4) A drilling method for implanting a dental implant using a dental drill including the step of screwing the implant into the third pilot hole.

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