JP2016030090A - Dental implant drill - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a dental implant drill for expanding a pilot hole, having a function to reduce a risk of perforating a site more than intended depth by mistake, without installing a stopper to the drill.SOLUTION: A columnar dental implant drill DRL with a central axis AX expands a pilot hole 3 formed on a jawbone for implanting a dental implant in the jawbone. One end of the columnar body is a shank 1 to be mounted on a drive device, and the other end of the columnar body is a perforation part 2 perforating the jawbone. The perforation part 2 includes: a distal surface 21 having no cutting blade at the tip; a first tapered surface continued from the distal surface 21, extending in the direction of the shank 1, and having a first angle forming an acute angle relative to the central axis AX, and a first cutting blade; a second tapered surface continued from the first tapered surface, extending in the direction of the shank 1, and having a second angle forming an acute angle relative to the central axis AX, and a second cutting blade; and a body surface continued from the second tapered surface and extending in the direction of the shank 1.SELECTED DRAWING: Figure 1

Description

The present invention relates to a dental implant drill for enlarging a pilot hole formed in a jaw bone for embedding a dental implant in the jaw bone.

The dental implant treatment is one of the dental treatments performed on a tooth defect site lost due to caries, periodontal disease, or trauma.

Usually, dental implants are made of pure titanium or titanium alloy with excellent biocompatibility. They are embedded in the tooth defect site as an alternative to the tooth root, function as an artificial tooth root, and serve as an abutment above the dental implant. Oral function is restored by attaching an abutment and fixing various prosthetic devices there.

Dental implants generally have a screw shape. Therefore, the embedding method in the jawbone uses a drill or other cutting tool attached to the drive device to form an embedding hole in the jawbone at the tooth defect site, insert the dental implant there, and form the screw shape. It is common to use and fix to bone.

In addition, dental implants are prepared in a plurality of types having different outer diameter sizes and lengths in order to cope with different jaw bone widths and heights for each patient. Therefore, it is necessary to form the embedding hole according to the outer diameter size and length of each dental implant.

As a precaution in forming the embedding hole, drilling with a large-diameter drill from the beginning increases the contact area between the drill and the jawbone, increases frictional heat due to rotation, and increases the risk of necrosis of the jawbone.

To avoid this, the insertion hole is first formed to a depth that matches the length of the dental implant to be inserted with a small-diameter drill, followed by a diameter slightly larger than the diameter of the preparation hole. By drilling to the same depth with a drill and repeating this, it is necessary to gradually increase the diameter to match the outer diameter size of the dental implant to be embedded.

In addition, drilling beyond the depth appropriate for the dental implant to be implanted may damage nerve tissue and blood vessels, leading to a serious accident. For this reason, careful attention is paid to the control of the drilling depth during the treatment.

Patent Document 1 describes a technique in which a mark such as a line indicating a distance from the tip is provided on the drill surface, and the depth is controlled while the mark is visually confirmed to perform drilling.

However, if the surgeon accidentally gives the drill more force than necessary, there is no means to forcibly regulate it, and the drill may be drilled beyond the intended depth. I could not say.

Patent Document 2 describes means for forcibly regulating the drilling depth by attaching a stopper to a drill.

However, as described above, since it is essential to gradually expand the formation of the embedding hole, the drilling work is required a plurality of times. Therefore, there is a problem that stoppers must be attached to all the drills, which causes inconvenience in attaching / detaching work.

Japanese Patent No. 4420423 JP 2013-66665 A

An object of the present invention is to provide a dental implant drill for enlarging a pilot hole having a function of reducing the risk of accidentally drilling beyond the intended depth without attaching a stopper to the drill. .

As a result of intensive research, a columnar dental implant drill (DRL) having a central axis (AX) that expands a prepared hole (3) formed in the jawbone in order to implant the dental implant in the jawbone, One end of the columnar shape is a shank portion (1) to be attached to the drive device, the other end of the columnar shape is a perforated portion (2) for perforating the jawbone, and the perforated portion (2) has a cutting edge at the tip. The first angle (α) and the first angle (α), which are acute with respect to the central axis (AX) extending in the direction of the shank portion (1), continuous to the front end surface (21). A first tapered surface (22) having a cutting edge (221), and an acute angle with respect to the central axis (AX) extending in the direction of the shank portion (1) continuously to the first tapered surface (22). A second tapered surface (23) having a second angle (β) and a second cutting edge (231), and the front It was clarified that the above-mentioned problem can be solved by a dental implant drill characterized by comprising a body surface (24) extending in the direction of the shank portion (1) continuously to the second tapered surface (23). It is.

In the dental implant drill (DRL) of the present invention, the drilling resistance is significantly increased by the tip surface (21) having no cutting edge when the drilled portion (2) comes into contact with the pilot hole tip (32). . Thereby, even when an operator accidentally applies more force than necessary, the risk of drilling beyond the depth of the lower hole (3) is reduced.
In addition, since the drilling resistance is significantly increased, the surgeon can know that the drill tip has reached the lower hole tip (32), which is an index for completing the drilling operation.

Furthermore, as long as the pilot hole (3) of the required depth is formed in the jawbone using any known technique, the subsequent diameter expansion can be achieved only with the dental implant drill (DRL) of the present invention. Can be controlled. Therefore, it is not necessary to attach a stopper or the like, and the treatment can be simplified.

The above effect can be obtained regardless of the length of the drilled portion of the dental implant drill (DRL).

1 is a front view of one preferred embodiment of a dental implant drill (DRL) of the present invention. FIG. It is an enlarged view of one perforation part tip of a preferred embodiment of a dental implant drill (DRL) of the present invention. 1 is a plan view of one preferred embodiment of a dental implant drill (DRL) of the present invention. FIG. 1 is a perspective view of one preferred embodiment of a dental implant drill (DRL) of the present invention. FIG. It is a front view when the dental implant drill (DRL) of this invention is inserted in a prepared hole. It is a front enlarged view when the dental implant drill (DRL) of the present invention reaches the tip of the prepared hole. It is a front enlarged view of the drilling part for demonstrating the back taper of the dental implant drill (DRL) of this invention. It is one front view of a suitable embodiment of the 1st drill and the 2nd drill when a plurality of dental implant drills (DRL) of the present invention are prepared. It is an enlarged view of one perforation part tip of a preferred embodiment of the second drill of the dental implant drill (DRL) of the present invention. It is a top view of one drilling part tip of a suitable embodiment of the second drill of the dental implant drill (DRL) of the present invention. It is a front view of the enlarged hole formed with the 1st drill of the dental implant drill (DRL) of this invention. It is a front view when further expanding an enlarged hole with the 2nd drill of the dental implant drill (DRL) of this invention. It is a front enlarged view when the 2nd drill of the dental implant drill (DRL) of this invention arrives at the expansion hole front-end | tip. 1 is a front view of one preferred embodiment of a pilot hole drill (DRLF) and drill stopper (DRLS) for use in combination with a dental implant drill (DRL) of the present invention. FIG. It is one front view of suitable embodiment when a drill stopper (DRLS) is mounted | worn with the prepared hole formation drill (DRLF) shown in FIG.

Dental implant drill (DRL)
Shank (1)
Perforated part (2)
Tip surface (21)
First taper surface (22)
First blade (221)
Second taper surface (23)
Second cutting edge (231)
Body surface (24)
First transition part (25)
Second transition part (26)
Third transition part (27)
Groove (28)
Center axis (AX)
First diameter (d1)
Second diameter (d2)
Third diameter (d3)
Body surface angle (θ)
First angle (α)
Second angle (β)

Pilot hole (3)
Pilot hole edge (31)
Pilot hole tip (32)
Pilot hole side (33)
Pilot hole diameter (B)
Pilot hole tip angle (γ)

Expansion hole (4)
Enlarged hole edge (41)
Expansion hole tip (42)
Expanded hole side (43)
Expanded hole taper surface (44)
Pilot hole remaining surface (45)

Drill hole drill (DRLF)
Drill stopper (DRLS)

The present invention may include arbitrary components not shown in the following drawings.
Further, the dental implant drill (DRL) of the present invention does not include a tap drill that imparts the screw shape of the dental implant to the embedding hole. The tap drill is a tool for forming a shape suitable for the screw shape of a dental implant on the side surface of a pre-formed embedding hole. This is because the drilling depth is easily controlled and the risk of accidentally drilling beyond the intended depth is extremely low.

The dental implant drill (DRL) of the present invention comprises a columnar shank portion (1) to be mounted on a drive device and a columnar drilling portion (2) for drilling a jawbone. (FIGS. 1 to 4)

The shank part (1) has one of the shaft shapes described in Japanese Industrial Standards JIS T5504-1: 2001 Dental Rotating Instruments-Shaft-Part 1: Made of Metal, and matches the specifications of the drive device to be mounted. Can have different sizes and shapes.

The perforated part (2) is connected to the front end surface (21) having no cutting edge at the front end and the central axis (AX) extending in the direction of the shank part (1) continuously to the front end surface (21). The first taper surface (22) having a first angle (α) that is an acute angle and the first blade (221), and the first taper surface (22) are continuous with the shank portion (1). A second tapered surface (23) having a second angle (β) and a second cutting edge (231) that are acute with respect to the central axis (AX) extending in the direction, and continuous to the second tapered surface (23). And a body surface (24) extending in the direction of the shank portion (1).

Further, the perforated part (2) is provided with a groove (28) from the tip surface (21) toward the shank part (1).
The groove (28) preferably has a spiral shape with the central axis (AX) as the central axis in order to efficiently eject bone fragments excised by drilling in the direction of the shank portion (1). Three is preferred, but it may be either two or four.
In addition, the length of the groove (28) in the central axis (AX) direction is preferably longer than the depth of the embedding hole necessary for the dental implant to be implanted. Thereby, when it drills to the depth of a required embedding hole, a bone piece can be discharged | emitted more efficiently from a groove | channel (28).

The first tapered surface (22) has a first blade (221) along the groove (28), and the second tapered surface (23) has a second cutting edge (231) along the groove (27). Have
It is preferable that the number of the first blades (221) and the second cutting blades (231) is equal to the number of the grooves (28) so that the bone fragments are efficiently discharged from all the grooves efficiently when drilling.

The perforated part (2)
A first transition portion (25) adjacent to the tip surface (21) and the first taper surface (22) having the first diameter (d1);
A first transition surface (26) adjacent to the first taper surface (22) and the second taper surface (23) to be the second diameter (d2);
It has the 2nd taper surface (23) used as a 3rd diameter (d3), and the 3rd transition part (27) to which a body surface (24) adjoins.
For the pilot hole diameter (B) of the pilot hole (3),
It is preferable to set within a range of 1.0 mm ≦ (d1) <(d2) <(B) <(d3).
Thereby, when the perforated part (2) is inserted into the lower hole (3), the second tapered surface (23) having the second cutting edge (231) contacts the edge edge (31) of the lower hole inlet. .
When drilling is started toward the lower hole tip (32), the lower hole side surface (33) is cut by the second cutting edge (231) and enlarged to the diameter (d3) of the third transition portion (27). (Fig. 5)

As the drilling progresses, the first transition portion (25) eventually comes into contact with the lower hole tip (32). (Fig. 6)
At this time, since the tip surface (21) has no cutting edge, the perforation resistance is significantly increased.
As a result, even if the surgeon accidentally applies more force than necessary, it is possible to obtain an effect of reducing the risk of drilling beyond the depth of the lower hole (3).
Further, since the drilling resistance is significantly increased, the operator can grasp that the dental implant drill (DRL) of the present invention has reached the tip of the lower hole (32). It becomes.

Moreover, when the first diameter (d1) is 1.0 mm ≦ (d1), when the first transition portion (24) comes into contact with the lower hole tip (32), an effect of increasing perforation resistance is appropriate. To be demonstrated.

FIG. 5 and FIG. 6 show an example of the pilot hole (3) formed by a cutting tool whose tip is tapered.
At this time, when the pilot hole tip angle (γ) with respect to the central axis (AX) of the pilot hole tip (32) is smaller than the first angle (α) with respect to the central axis (AX) of the first tapered surface (22), Until the first transition portion (25) comes into contact with the lower hole tip (32), the lower hole tip (32) is cut off by the first blade (221) of the first tapered surface (22).
However, even in this case, since the tip surface (21) having no cutting edge always comes into contact with the tip of the lower hole (32), the effect of increasing the punching resistance can be obtained similarly.
This is the same whether the shape of the tip of the pilot hole (32) is flat or round.
That is, in the dental implant drill (DRL) of the present invention, the above effect can be obtained in the same manner regardless of the shape of the tip of the prepared hole (32).
The tip surface (21) is more preferably a plane that is perpendicular to the central axis (AX). Thereby, the above-mentioned effect is appropriately exhibited in any shape of the pilot hole tip (32).

As described above, the pilot hole (3) needs to be gradually enlarged. That is, the third diameter (d3) is preferably set in the range of (B) +0.2 mm ≦ (d3) ≦ (B) +1.0 mm with respect to the pilot hole diameter (B).
Thereby, the frictional heat which generate | occur | produces when a pilot hole side surface (33) and a 2nd taper surface (23) contact at the time of drilling can be suppressed, and the risk of bone necrosis can be reduced.

The second angle (β) of the second taper surface (24) with respect to the central axis (AX) is preferably set in a range of 10 ° ≦ (β) ≦ 20 °.
Accordingly, when the dental implant drill (DRL) of the present invention is inserted into the prepared hole (3), the second tapered surface (23) serves as a guide for the prepared hole side surface (33). Therefore, it is possible to start drilling smoothly.

The body surface (24) has a tapered shape called a back taper in the direction of the shank (1), and the body surface angle (θ) with respect to the central axis (AX) is 0 ° <(θ). It is preferable to set in the range of ≦ 0.5 °. (Fig. 7)
Thereby, when the dental implant drill (DRL) of the present invention is drilled in the pilot hole (3), unnecessary contact between the body surface (24) and the pilot hole side surface (33) is avoided, and unnecessary frictional heat is generated. Occurrence can be suppressed.
In FIG. 7, for convenience of explanation, the illustration of the groove (28) is omitted, and the body surface angle (θ) is also shown outside the above-mentioned preferred setting range.

It is preferable that a plurality of dental implant drills (DRL) of the present invention are prepared so that a plurality of dental implants having different outer diameter sizes can be formed.
Below, when the dental implant drill (DRL) of this invention is prepared in multiple numbers, one of the suitable embodiment which forms an embedding hole using this is demonstrated.
For convenience of description, the one used for enlarging the lower hole (3) is distinguished from the “first drill”, and the one used for further enlarging the enlarged hole (4) formed by the first drill is distinguished from the “second drill”. To do. (Fig. 8)
The second drill is the same as that of the dental implant drill (DRL) of the present invention, that is, the first drill, in the preferred embodiment. Add distinction. (Fig. 9, 10)
However, the description regarding the components of the second drill is not limited to the second drill, and can be applied to all dental implant drills (DRL) of the present invention.

The enlarged hole (4) formed by the first drill has an enlarged hole tip (42), an enlarged hole side surface (43), an enlarged hole tapered surface (44), and a lower hole remaining surface (45). (Fig. 11)
The enlarged hole side surface (43) is enlarged by the second tapered surface (23) of the first drill, and its diameter is equal to the third diameter (d3) of the third transition portion (27).
The enlarged hole taper surface (44) is a surface formed by the second taper surface (23) when the first drill abuts the pilot hole tip (32), and the second angle (β) of the first drill. Is equal to
The lower hole remaining surface (45) is a surface in which the lower hole side surface (32) is left behind because the first drill satisfies 1.0 mm ≦ (d1) <(d2) <(B) <(d3). , Equal to the pilot hole diameter (B).

Here, the second drill can be easily explained by treating the enlarged hole (4) as a pilot hole (3) for the second drill.
That is, in the drilling part (2a) of the second drill, the first diameter (d1a), the second diameter (d2a), and the third diameter (d3a) are:
For the enlarged hole diameter (d3) of the enlarged hole (4),
By setting within the range of 1.0 mm ≦ (d1a) <(d2a) <(d3) <(d3a), the effect when drilling in the lower hole (3) with the first drill is expanded with the second drill. The same effect can be obtained when inserted in (4).
In addition, it is more preferable that (d1) ≦ (d1a), (d2) <(d2a), and (d3) <(d3a).

However, as described above, the enlarged hole (4) has an enlarged hole tapered surface (44) formed by the second tapered surface (23) of the first drill and the remaining surface of the lower hole, which is not in the lower hole (3). (45).
However, like the first drill, the second drill has a first angle (αa) that is an acute angle with respect to the central axis (AXa) extending in the direction of the shank portion (1a) and the first blade (221a). A first taper surface (22a), a second angle (βa) that is continuous with the first taper surface (22a), and an acute angle with respect to the central axis (AXa) extending in the direction of the shank portion (1a) and Since the second transition portion (26a) reaches the enlarged hole taper surface (44), the second blade (221a) can be used. Since the enlarged hole taper surface (44) and the lower hole remaining surface (45) are excised by the second cutting edge (231a), the drilling can be continued as it is. (Fig. 12)

At this time, in order to efficiently cut the enlarged hole taper surface (44),
The length (h1a) parallel to the central axis (AXa) from the distal end surface (21a) to the second transition portion (26a) is set in a range of 0.1 mm ≦ (h1a) ≦ 0.6 mm, The first angle (αa) with respect to the central axis (AXa) of the one tapered surface (22a) is preferably set from the range of 55 ° ≦ (αa) ≦ 65 °.
The above configuration can be applied to all dental implant drills (DRL) of the present invention.

When the tip surface (21a) of the second drill reaches the enlarged hole tip (42), the first transition portion (25a) comes into contact with the enlarged hole tip (42). (Fig. 13)
At this time, since the tip surface (21a) has no cutting edge like the first drill, the drilling resistance is significantly increased. That is, the same effect as when the first drill reaches the tip of the pilot hole (32) can be obtained.

Moreover, when it is necessary to prepare the 3rd drill which expands further the expansion hole (4) formed with the 2nd drill, the expansion hole (4) formed with the 2nd drill is prepared for the pilot hole (3) of the 3rd drill. By using the preferred embodiment in the above description, the third drill can achieve the same effects as the first drill and the second drill.

Thus, when the dental implant drill (DRL) of the present invention is used in combination with any dental implant, the diameter of the third transition portion (27) of each drill is suitable for the dental implant to be implanted. By matching with the diameter of the embedding hole, it can be used as a dental implant kit suitable for the dental implant to be implanted.

When preparing a dental implant drill kit for implanting any dental implant, including the dental implant drill (DRL) of the present invention, a pilot hole (3) having a pilot hole diameter (B) is formed. It is preferable to combine the pilot hole forming drill (DRLF) with a drill stopper (DRLS) that can be attached to the pilot hole forming drill (DRLF) and forcibly restricts the drilling depth of the pilot hole forming drill (DRLF).
Accordingly, it is possible to appropriately and easily form the insertion hole of the dental implant with the minimum number of products and operations. (Fig. 14)

As one of the preferred embodiments of the pilot hole forming drill (DRLF) and the drill stopper (DRLS), the drill stopper (DRLS) is detachable from the pilot hole forming drill (DRLF) manually without using a tool or the like. It is preferable that (Fig. 15)

In addition, it is preferable that the depth of the prepared hole (3) formed by the prepared hole forming drill (DRLF) with the drill stopper (DRLS) is matched with the length necessary for embedding the dental implant. Therefore, for example, if there are a plurality of types of dental implants to be embedded, it is preferable to prepare the same type of drill stopper (DRLS) accordingly.

According to the dental implant drill (DRL) of the present invention, it is possible to perform the operation more safely and with simplified operations in forming an embedding hole for embedding a dental implant in a jawbone. Further, it can be appropriately adjusted to an arbitrary outer diameter size of the dental implant, and the application range is wide.
Therefore, the present invention can be widely used in the field of dental implant treatment.

Claims (9)

A columnar dental implant drill (DRL) having a central axis (AX) for enlarging a pilot hole (3) formed in the jawbone for embedding a dental implant in the jawbone, wherein one end of the columnar shape is It is a shank part (1) to be mounted on the driving device, and the other end of the columnar shape is a perforated part (2) for perforating the jawbone. The perforated part (2) has a distal end surface (21 having no cutting edge at the front end). ), A first angle (α) that is an acute angle with respect to the central axis (AX) extending in the direction of the shank portion (1) and the first blade (221). A first taper surface (22) having a second angle that is continuous with the first taper surface (22) and is acute with respect to the central axis (AX) extending in the direction of the shank portion (1) ( β) and a second tapered surface (23) having a second cutting edge (231), and the second tapered surface ( 23) A dental implant drill characterized by comprising a body surface (24) extending in the direction of the shank portion (1) continuously to 23). The perforated part (2)
A first transition portion (25) adjacent to the tip surface (21) and the first taper surface (22) having a first diameter (d1);
A second transition portion (26) adjacent to the first tapered surface (22) and the second tapered surface (23) having a second diameter (d2);
The second tapered surface (23) having a third diameter (d3) and the third transition portion (27) adjacent to the body surface (24);
For the pilot hole diameter (B) of the pilot hole (3),
The dental implant drill according to claim 1, wherein 1.0 is set in a range of 1.0 mm ≤ (d1) <(d2) <(B) <(d3). The third diameter (d3) is set in a range of (B) +0.2 mm ≦ (d3) ≦ (B) +1.0 mm with respect to the pilot hole diameter (B). The dental implant drill according to 2. The dental implant drill according to any one of claims 1 to 3, wherein the distal end surface (21) is a plane perpendicular to the central axis (AX). The dental implant drill according to any one of claims 1 to 4, wherein the second angle (β) is set in a range of 10 ° ≤ (β) ≤ 20 °. The body surface (24) tapers in the direction of the shank portion (1), and the body surface angle (θ) with respect to the central axis (AX) is 0 ° <(θ) ≦ 0.5. The dental implant drill according to any one of claims 1 to 5, wherein the dental implant drill is set within a range of °. The said dental implant drill (DRL) is comprised from the at least 2 or more multiple types from which said 2nd diameter (d2) and said 3rd diameter (d3) differ. The dental implant drill according to any one of the above. A length (h1) parallel to the central axis (AX) from the first transition part (25) to the second transition part (26) is set in a range of 0.1 mm ≦ (h1) ≦ 0.6 mm. The dental implant drill according to any one of claims 1 to 7, wherein the first angle (α) is set in a range of 55 ° ≦ (α) ≦ 65 °. The dental implant drill (DRL) can be attached to a prepared hole forming drill (DRLF) that forms the prepared hole (3) having the prepared hole diameter (B), and the prepared hole forming drill (DRLF). The dental implant drill according to any one of claims 1 to 8, wherein the dental implant drill is used in combination with a drill stopper (DRLS) that forcibly regulates a drilling depth of the pilot hole forming drill (DRLF).