KR101166161B1 - Drill for the milling of surgical template - Google Patents

Abstract

The present invention relates to a drill for drilling an intraoral surgical procedure induction attachment, and more particularly to a surgical drill used for drilling an alveolar bone for surgical implantation in an oral cavity, An instrument for inserting an induction bushing in an impression model and a drill for forming holes for the installation of a prosthetic analog, wherein the drilling can be used to continuously form multiple holes of different diameters. For drilling drills.
A drilling drill for the treatment of an intraoral surgical procedure induction attachment of the present invention is a drill for drilling an intraoral surgical procedure induction attachment, A bushing fixing pin for fixing the induction bushing or a second drill part for drilling a hole for insertion of a prosthetic analog, a first drill part for drilling a hole for installation of the induction bushing, And a third drill portion for grinding the upper portion.
According to the drilling drill for drilling of an intraoral surgical procedure guiding fixture of the present invention, a drilling operation for inducing drilling in an oral drilling operation is performed in a hole and an oral impression model to be machined in a guiding fixture, The hole for analog insertion can be accurately and efficiently machined by one drilling.

Description

[0001] Description [0002] Drill for the milling of surgical template [0003]

The present invention relates to an intraoral oral surgical induction fitting, particularly a drill for drilling a functional part provided in a fitting, and a surgical guiding device for precisely guiding a drilling device to guide the direction of drilling in an oral cavity drilling operation The present invention relates to a drill for drilling a functional part such as a hole for installing a functional part such as a bushing or a fixing body for induction on an induction-inducing installation.

When performing the operation of performing the implant, generally, a drilling operation is performed on the alveolar bone using the drill to immobilize the fixture. In this case, the specific procedure for placing the implant is different from patient to patient. Considering various factors such as the state of the patient's teeth, the position of the tooth requiring the implant treatment, and the state of the alveolar bone of the patient, As well. Therefore, there is a characteristic that it is difficult to perform the drilling operation for perforating the alveolar bone according to the position, direction, and depth of the implant, which is customized to each individual patient, in a predetermined standardized manner.

Because of these characteristics, drilling of the alveolar bone, which should be performed by a customized and optimized plan according to each patient, is not easy for the beginner and the experienced person to accurately measure the depth and direction of the perforation.

If the practitioner performs a drilling operation by performing a drilling operation, it can not accurately determine to what extent the drilling operation has been performed at present. If the drilling operation exceeds the predetermined depth, the drill may damage the nerve in the alveolar bone.

On the other hand, if the drilling operation is completed before the predetermined drilling depth is reached, the depth of the drilled groove is shallow, and excessive force is required to fix the fixture, which may damage the thread around the groove. Also, since the fixture can not be completely fixed, there is a possibility that the re-operation will be performed later.

In order to alleviate the difficulty of the alveolar bone, an auxiliary device called a dental jig for precision guided surgery has been developed to derive various treatment tools including a drill in the correct position and direction to perform the drilling operation There must be inserted a derivative such as an induction bushing to guide the direction of the procedure, including the direction of drilling. A hole for inserting a derivative such as a bushing, a pinhole for fixing a derivative for fixing a derivative or a hole for inserting an analogue for coupling with an abutment during manufacture of a prosthesis is formed in an intraoral impression model And a plurality of holes are formed.

However, in the conventional hole machining, drilling is performed several times for machining the holes having different diameters, which requires a long processing time, and there is a problem that a clearance is generated between the holes by separate drilling.

In addition, implant prosthesis is inevitably made after implantation with a surgical induction complex. In the past, it was cumbersome to reconstruct an oral cavity model for prosthesis using a fitting.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide an oral cavity surgical procedure induction fitting capable of forming holes having different diameters to be formed in a surgical procedure induction field complex or the like by a single drilling operation In particular, it is an object of the present invention to provide a drill for drilling a functional part provided in an intraoral surgical procedure induction device and for forming a hole for a prosthesis into which a prosthesis can be inserted.

In order to achieve the above-mentioned object, the drill for drilling the intraoral surgical procedure induction fitting and the oral impression model according to the present invention is a drill for guiding an intraoral surgical induction fitting and an oral impression model A joint drill comprising: a first drill portion for drilling a hole for installation of an induction bushing or fixture for inducing drilling in a drilling operation in the surgical procedure induction attachment; and a bushing fixing pin or prosthesis for fixing the induction bushing A second drill section for drilling a hole for insertion of a fixing pin for an analog or fixed body for use in a surgical procedure, and a surgical instrument such as a drill or handpiece head used in an intraoral puncturing operation on the above- And a third drill for machining a hole or a step for ensuring the precision of the drilling operation, such as forming an accurate geometric relationship with the accessor or the functional part.

The first drill part, the second drill part, and the third drill part are integrally formed in one body to continuously process the holes processed by the drill parts.

Further, the drilling drill is made of a plurality of twisted blades, and each of the twisted blades is provided with a step for machining three different diameters.

The three diameters that can be machined by the twist blade correspond to the diameters of the holes processed by the first drill, the second drill, and the third drill, respectively, and the second drill, The first drill portion, and the third drill portion are sequentially arranged in this order.

Further, the third drill portion includes a flat blade portion for machining a hole for forming an accurate geometric relationship with the easy access or function portion.

Further, the flat blade portion has a flat bottom surface, and a spiral drill blade for a flat surface is formed on the bottom surface.

Further, the flat blade portion has a flat bottom surface, and a flat surface having a roughness for a flat surface is formed on the bottom surface.

The outer diameter of the third drill portion is equal to or larger than the diameter of the head portion of the drilling machine used in the drilling operation in the oral cavity.

Further, the outer diameter of the first drill portion is a size capable of accommodating the maximum outer diameter portion of the guide bushing so that the functional component can be inserted.

The first drill is characterized in that the hole machined by the first drill is an inclined blade having a predetermined inclination.

The first drill is a stepped structure having a diameter different from that of the first drill so that a stop part for adjusting the insertion depth of the functional part is formed in the hole to be machined.

The outer diameter of the second drill is a size that can accommodate the maximum outer diameter of the bushing fixing pin or the analog or fixed pin for prosthesis.

The present invention having the above-described structure can be formed by drilling a hole for a functional part such as a bushing to be inserted into a surgical procedure induction attachment and a hole for a hole for fabricating the corresponding mouthplant prosthesis have.

In addition, machining time can be remarkably reduced by machining a plurality of holes with one drill.

In addition, since a plurality of holes are formed by one drill, there is an effect that the positional relationship between the holes can be precisely adjusted.

Further, it is possible to simultaneously perform the hole processing necessary for the post-processing of the precision-guided mounting object.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a front view of a drill for drilling an intraoral surgical induction mount and an intraoral impression model according to an embodiment of the present invention,
FIG. 2 is a front view of a drill portion for a drill comprising a third drill portion and a flat blade portion,
FIG. 3 is a rear perspective view of the drill drill shown in FIG. 2,
FIG. 4 is a view showing an inclined blade drill for machining an inductive bushing insertion hole in a drill for drilling a surgical procedure induction mount and an in-mouth impression model according to an embodiment of the present invention,
FIG. 5 is a view showing a stepped structure drill for machining an induction bushing insertion hole in a drill for drilling an intraoral surgical procedure induction mount and an intraoral impression model according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a drill for drilling of an intraoral surgical induction fitting and an in-mouth impression model according to the present invention will be described in detail with reference to the drawings.

1 is a front view of a drill for drilling an intraoral surgical induction mount and an intraoral impression model according to an embodiment of the present invention.

The drill for drilling of the intraoral surgical procedure induction attachment and the oral impression model according to the present invention may be used for drilling in a surgical procedure including an oral puncture procedure or for the installation of a structure for inducing a surgical direction Surgical procedure induction fittings, for example, drilling guides for mounting in the oral cavity, fixing pins for fixing the induction bushing, analog for abutment fastening, etc. can be installed in the oral impression model, Is used to form a hole capable of receiving the diameter of the head portion on the top of the in-mouth procedure induction fitting or the like in order to facilitate the accessibility of the head portion of the processing machine.

As described above, the implant is a dental operation in which an artificial tooth is fixed to the alveolar bone by cutting the gums (gums), perforating the alveolar bone, fixing the prosthesis by inserting the fixture, and fixing the artificial tooth to the alveolar bone. When performing such an implant, the depth, direction, and position of the perforation for the implant are determined after confirming the dental structure of the patient, the shape of the alveolar bone, the location of the neural tube, etc. through CT images, etc. If the operation is performed without inducing drilling Because of the difficulty in correcting the procedure, a surgical procedure induction mount is mounted to induce drilling for perforation. The bushing for inducing drilling is installed in such a fitting. The in-mouth procedure induction mount is manufactured on the model of the patient's mouth, and a hole capable of accommodating the maximum diameter of the induction bush is mounted directly on the in- Or it may be manufactured by using a material having fluidity after the bushing fixing pin is installed on the in-mouth impression model.

The perforation of the alveolar bone is usually performed using a drilling machine including a drill, but it is also possible to perform perforation without rotating the machine by using a laser or the like. In this case, since the induction bushing is unnecessary, It may also be drilled into the induction mount.

Also, for the preparation of the prosthesis, an analogue to be connected to the prosthesis abutment should be inserted into the oral impression model. These analogs are used to fix the restorations to be installed in the oral cavity in consideration of the occlusal relationship with the existing teeth in the in-mouth impression model.

In addition, the lower portion of the intraoral instru- ment-inducing fitting is made to fit the dentition structure of the patient, but the upper portion is not flat as the upper portion is finished without special processing. Since the upper part of the intraoral treatment induction attachment is not flat, the induction of the induction bushing causes interference between the head part of the drilling machine and the mechanical part for the surgical operation, There is a problem such that the processing can not be performed. Therefore, there is a need to flatten the upper portion of the intraoral implantation guiding fixture provided with the guide bushing.

In order to perform the implant treatment as described above, it is necessary to form a plurality of holes in the intraoral surgical procedure induction attachment and the oral cavity impression model, but since the diameters of the holes are different, There is a problem that a large amount of holes are required and the positional relationship between the formed holes must be matched within a small tolerance but it is formed by several drilling operations and the machining tolerance is very large.

Referring to FIG. 1, a drill for drilling a surgical procedure induction fitting and an in-mouth impression model according to an embodiment of the present invention will be described in detail. Guiding bushing or intraoral surgical procedure in the oral cavity, a first drill part (200) for forming a hole for the installation of a fixture for fixing the fixture in the mouth, and a bushing fixing pin or prosthesis for fixing the induction bushing to the intraoral impression model A second drill part 300 for forming a hole (a pore hole or a pore hole) for insertion of a fixing pin for an analog or fixed body for use in a surgical procedure and a head part of a drilling machine at the top of a surgical procedure induction attachment And a third drill part (100) for forming a hole for forming the hole.

The first drill portion 200 is a drill portion including a drill bit for inserting the bushing. The drill portion includes an induction bushing for inducing drilling in the surgical procedure induction fitting or a fixture for fixing the intraoral surgical induction fitting in the oral cavity To form a hole for the installation of a drillable edible function or an induction of a mechanical part for a surgical procedure. The induction bushing is preferably fixed to the hole formed in the surgical procedure induction fitting so that the induction bushing is machined to have an inclination in the up-and-down direction of the hole so as not to create a clearance along the upper and lower sides of the hole or to process the stop portion according to a specific positional relationship. For this, as shown in FIG. 3 and FIG. 4, the first drill 200 may be formed with a stepped portion such that a beveled edge is formed on the first drill portion 200 or a stop portion is formed like B, It is preferable to process it to form a hole.

The outer diameter of the first drill part 200 should be large enough to accommodate the guide bushing or the fixture. Since the guide bushing is formed in a substantially circular shape, the first drill part 200 has the same size as the outer diameter of the guide bushing, . In order to prevent rotation of the induction bushing, when the induction bushing has an elliptical shape, it is preferable that the induction bushing has a size capable of accommodating a maximum outer diameter portion (directing the major axis).

The second drill portion 300 processes the hole for insertion of the guide bushing fixing pin or the fixing pin for the prosthesis analog or the fixing body into the in-mouth impression model. Therefore, it is desirable to have a size within tolerance that is equal to the diameter of the maximum outer diameter portion of the fixing pin or the analog or the position stability is ensured so as to accommodate the guide bushing fixing pin or the analog for prosthesis. The shape of the drill of the second drill part 300 is the same as that of the first drill part 200 described above.

The third drill unit 100 may include a functional part such as a surgical instrument and a guide bushing for drilling the hole of the drilling machine in the upper part of the surgical procedure induction attachment mounted in the mouth, The hole or the step is machined to ensure the precision of the drilling process. It is preferable that the hole machined by the third drilling portion 100 is formed to be capable of receiving the head portion of the boring drill. The hole machined by the third drill part 100 is preferably a hole formed up to the upper portion of the guide bushing rather than a through hole. For this purpose, a flat bottom surface is provided with a flat blade edge However, it is difficult to form the flat portion 160 on the drill body. In addition, a flat surface having a predetermined roughness is formed for the purpose of planarization, and holes may be formed by rotation of the flat surface. Of course, the shape of the hole forming the hole for receiving the head part is irrelevant.

The first drill unit 200, the second drill unit 300, and the third drill unit 100 described above are integrally formed in one drill body so that a plurality of holes different from each other can be machined by a single drilling operation . However, considering the positional relationship of the guide bushing and the depth of the analogue in the surgical procedure induction fitting according to the characteristics such as the depth of the drilling operation, the first drill part 200, the second drill part 300, The positional relationship between the parts 100 should be determined.

The first drill part 200, the second drill part 300 and the third drill part 100 are integrally formed in a single drill body, The second drill unit 300, and the third drill unit 100, it is easy to manufacture. The torsion blade 110 is inclined at a predetermined inclination to the drill body. Steps 112 and 114 are formed on the torsion blade 110 so that each drill can process all holes to be machined. Steps 112 and 114 are formed on the single torsion blade 110 so that the first drill part 200, the second drill part 300 and the third drill part 100 are machined There is an advantage that the number of air holes is reduced and manufacturing is easy in manufacturing a drill bit.

Third drill section: 100
Flat blade: 150
First drill section: 200
Second drill section: 300
Torsion blade: 110

Claims (12)

A drill for drilling of an intraoral surgical implant induction or intraoral implant model,
A hole for installation of a surgical functioning portion including an induction bushing or a fixation body for inducing a surgical operation including a piercing operation in the surgical operation induction attachment, or a first drill for drilling a hole for guiding the surgical operation Wealth,
A bushing fixation pin for fixing the inductive bushing to the surgical procedure induction mount or an in-mouth impression model, or for inserting a fixation pin for an analog or fixation prosthesis or for accessing the oral tissue of the mechanical section for the surgical procedure A second drill portion for drilling the hole,
And a third drill for machining a hole or a step for securing an accuracy of the surgical procedure or an easy approach of the mechanical part for the surgical operation to the upper part of the surgical procedure induction attachment,
Wherein the drilling drill comprises a plurality of twist blades, each of the twist blades having a stepped portion for machining three different diameters,
The three diameters that can be machined by the twist blade correspond to the diameters of the holes processed by the first drill, the second drill, and the third drill, respectively, and the second drill, Wherein the first drill part and the third drill part are sequentially arranged in the order of the first drill part, the first drill part, and the third drill part.
In claim 1,
Wherein the first drill part, the second drill part, and the third drill part are integrally formed in one body to continuously process the holes processed by the respective drill parts. Drill drills for machining impression models in the mouth.
delete delete In claim 1,
Wherein the third drill includes a flat blade for machining the hole or the stepped portion, and the drill for drilling the intraoral surgical procedure induction fitting and the oral impression model.
In claim 5,
Wherein the flat blade portion has a flat bottom surface and a helical drill blade for a flat surface is formed on the bottom surface. The drill for drilling a surgical procedure induction fitting and an oral impression model.
In claim 5,
Wherein the flat blade portion has a flat bottom surface and a flat surface having a roughness for a flat surface is formed on the bottom surface of the flat blade portion. A surgical drill for inducing an intraoral surgical procedure and a drill for drilling of an intraoral impression model .
In claim 1,
Wherein an outer diameter of the third drill portion is equal to or larger than a diameter of a head portion of a drilling machine including a drill used in a drilling operation in an oral cavity, Common drill.
In claim 1,
Wherein an outer diameter of the first drill is of a size capable of accommodating a maximum outer diameter of the guide bushing to allow insertion of the guide bush or capable of receiving a maximum outer diameter of the mechanical portion for the surgical procedure. Drilling drills for the machining of surgical procedure induction fittings and intraoral impressions.
In claim 1,
Wherein the first drill comprises an inclined blade such that the hole machined by the first drill has a predetermined degree of inclination. ≪ RTI ID = 0.0 > [10] < / RTI >
In claim 1,
Wherein the first drill is a stepped structure having a different diameter so that a stop portion for adjusting the insertion depth of the guide bushing or the mechanical portion for surgical operation is formed in the hole to be drilled. Drill drills for machining impression models in the mouth.
In claim 1,
Wherein an outer diameter of the second drill is a size capable of accommodating a maximum outer diameter of the bushing fixation pin or the prosthesis analogue, and a drill for drilling a surgical procedure induction attachment and an oral impression model.

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