KR200476682Y1 - guide stent for placing dental implants - Google Patents

Abstract

In order to improve the convenience and accuracy of the fixture placement and restoration of the fixture, the present invention provides a method and apparatus for guiding the placement of the fixture and the perforation for placement of the fixture during the implant procedure, A guide stand for a dental implant, which is formed with a profile and is coupled to a stance fixed and wrapped around a periodontal tissue to guide a fixture placement position, the stance body comprising: a staple body having a fixture hole formed at the fixture mounting position; A hollow bushing portion inserted into and coupled to the coupling hole and having a guide hole through which an implant drill is rotatably supported on an inner periphery of the hollow bushing portion; and a guide protrusion protruding from one side of the outer circumference of the hollow bushing portion, The guide stent for a dental implant is characterized in that it includes a sleeve including a sleeve.

Description

Guide stent for placing dental implants "

The present invention relates to a guide stand for a dental implant, and more particularly, to guide a placement position of a fixture and a perforation for positioning the fixture during an implant procedure, and to provide a fixture for a fixture and a prosthesis, The present invention relates to a guide stand for a dental implant.

Generally, an implant refers to a substitute for replacing a human tissue when the original human tissue is lost, but refers to implanting an artificial tooth in the dentistry. To replace the missing tooth root, a fixture made of titanium or the like which has no rejection to the human body is planted in the alveolar bone that has been taken out of the tooth, and then the tooth is restored by fixing the artificial tooth.

In the case of general prostheses or dentures, the surrounding teeth and bones are damaged over time, but the implants can prevent damage to the surrounding dental tissues and can be used stably because there is no secondary cause of tooth decay. In addition, since the implant has the same structure as the natural teeth, there is no pain or foreign body sensation of the gums, and it is advantageous that the implant can be used semi-permanently.

1 is a flowchart illustrating a conventional implant procedure.

As shown in FIG. 1, the conventional implant procedure includes a primary procedure (s1, s2, s3, s4) of placing a fixture in the alveolar bone and a time ) And fixing the final prosthesis (s5, s6).

First, the primary procedure includes a gum removal step (s1) for opening the gum of a tooth-missing part, a multistage drilling step (s2) for forming a perforation where the fixture is to be placed, a fixture placement step (s3) And a step (s4) of binding temporary teeth to the tooth tip.

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

At this time, the multi-step drilling step (s2) may include forming an initial hole, expanding a hole, forming a thread in a hole, and removing a remaining alveolar bone in the hole. Depending on the type of drill and the drilling method used, it can be varied.

Then, the fixture is placed on the perforations formed through the multi-step drilling step (s2) (s3), and the temporary teeth are coupled to the fixture placed (s4), thereby completing the primary procedure.

Here, the fixture placed in the perforation serves as the root of the artificial tooth. Therefore, it is very important to form an accurate hole in the multi-step drilling step (s2) in order to provide a stable and fast restoration process in which the alveolar bone forms osseointegration with the fixture and provides a stable bonding force between the alveolar bone and the fixture after the osseointegration. And the completeness of artificial tooth formation through implant treatment is determined.

At this time, the temporary tooth includes a healing abutment and a cover screw. Here, the healing abutment and the cover screw are inserted into the fixture while the inserted fixture is osseointegrated to the alveolar bone, preventing gums and foreign substances from being introduced into the fixture and damaging the inside of the fixture .

Then, the temporary tooth is coupled to the fixture, and after waiting for the alveolar bone to be restored for a period of about 3 to 6 months, the temporary tooth is removed and the abutment is engaged (s5). Finally, when the final prosthesis is coupled to the abutment portion, the implant procedure can be completed (s6).

On the other hand, it is very difficult for a novice as well as an experienced person to form a perforation in an exact depth and direction at a position where the fixture is to be placed in the above-described procedure. Therefore, in the drilling operation for forming the perforation, the operation is performed using a surgical guide tool called a stance.

Here, the stent acquires the shape of the alveolar bone in the oral cavity through the CT scan, and acquires the shape of the teeth and the gum through the gypsum model formed in accordance with the profile in the oral cavity. Then, it implements the image matching, plans the implant operation through simulation, and creates a stand that can guide the operation according to the plan.

At this time, the staple is formed with a guide hole for guiding the placement position of the fixture corresponding to the implant treatment plan in a state of being fixed in the oral cavity. The inner circumference of the guide hole rotatably supports the outer circumference of the drill used in the formation of the perforation so that the perforation can be guided in a precise direction and depth in the drilling process.

However, since the guide hole is easily deteriorated by the drill being rotated at a high speed, there is a problem in that the rotation of the drill can not be stably provided when the drill is formed. Accordingly, the accuracy of the drill formed is reduced, .

In addition, a fixture is placed on the perforations formed through the drilling step. A hexa hole is formed on the inside of the fixture, and a temporary tooth (healing abutment / cover screw) or a portion of the abutment A hexahedron is inserted and fixed. At this time, an adhesive is interposed and fixed in the hexa hole. The hexa holes and the hexa projections are provided in a honeycomb shape favorable to pressure dispersion, and the hexa projections can be accurately inserted into the hexa hole when inserted in a predetermined direction.

However, conventionally, since the arrangement angle of the hexa holes on the inside of the fixture is not uniformly aligned, the insertion angle of the temporary tooth or the abutment portion is changed according to the angle at which the fixture is placed.

The cover screw of the provisional teeth prevents the food from infiltrating into the empty space inside the fixture to cause infection or reduce the bonding force between the fixture and the alveolar bone due to the inflow of the gums and the healing abutment serves as the cover screw And to regenerate the shape of the gums that are regenerated with.

In this case, when the angle of placement of the fixture is different from the placement angle of the healing abutment according to the implant procedure plan, it is necessary to insert and remove the fixture through trial and error several times in order to correct the placement angle of the fixture, The alveolar bone is damaged or the bone loss is increased, thereby increasing the recovery period.

Further, on the upper side of the abutment portion, there is formed a polygonal projection to which the final prosthesis is coupled, the direction of the polygonal projection being changed according to the insertion angle of the abutment portion. Accordingly, when the final prosthesis is manufactured, it is necessary to manufacture the final prosthesis in accordance with the orientation of the zone after the fixture is placed, so that the preparation period and the manufacturing period are prolonged.

Korean Patent No. 10-0920727

In order to solve the above-mentioned problems, a guiding stand for a dental implant, which guides the placement of the fixture and the perforation for positioning the fixture in the implant procedure, and improves the convenience and accuracy of the fixture placement and restoration, As a solution to the problem.

In order to solve the above problems, the present invention provides a guide stand for dental implants which is formed into a profile set through three-dimensional image acquisition data in the oral cavity and which is coupled to a stand that is wrapped around a periodontal tissue to guide a fixture placement position A staple body having a fitting hole formed at the fixture mounting position; A hollow bushing portion inserted into and coupled to the coupling hole and having a guide hole through which an implant drill is rotatably supported on an inner periphery of the hollow bushing portion; and a guide protrusion protruding from one side of the outer circumference of the hollow bushing portion, The guide stent for a dental implant is characterized in that it includes a sleeve including a sleeve.

Here, the guide protrusions may be arranged at predetermined arrangement angles so that the hexahedrons of the abutments formed in the hexa holes of the fixture are aligned corresponding to the arrangement angles of the crowns manufactured according to the three-dimensional image acquisition data, And is preferably fixed to the edge of the coupling hole.

The circumferential width of the guide protrusion is adjusted so that the hexahedron of the abutment formed in the hexa hole of the fixture is aligned with the arrangement angle of the crown manufactured according to the three-dimensional image acquisition data, Is preferably corresponded to the guide surface width of the guide surface.

In addition, in order to align the hexahedron of the abutment formed in the hexa hole of the fixture corresponding to the arrangement angle of the crown manufactured according to the three-dimensional image acquisition data, It is preferable that an alignment groove portion into which the guide projection is inserted is formed.

At this time, the guide protrusions are protruded to a single point on the outer periphery of the hollow bushing, and the guide protrusions are formed on the guide surface formed on the abutment and the guide surface formed on the abutment corresponding to the arrangement angle of the crown manufactured according to the three- And a rough surface is formed along the circumferential direction on the outer circumferential surface of the hollow bushing portion.

Through the above-mentioned solution, the guide stent for dental implants according to the present invention provides the following effects.

First, since the guide protrusions are assembled in correspondence with the arrangement angles of the crowns manufactured according to the three-dimensional image acquisition data, the claws are arranged at the guide protrusions by aligning the fixture / abutment at the guide protrusions, It can be accurately combined with the abutment.

Therefore, it is possible to manufacture the crown by not only preparing the crown corresponding to the angle of fixture but also setting the crown arrangement angle when preparing the guide stance. Therefore, it is possible to prepare the implant procedure and significantly reduce the time for manufacturing various prostheses And can provide an infrastructure device capable of completing gum removal, fixture hole drilling, fixture placement, and abutment / crown installation with a single procedure.

Second, the circumferential width of the guide protrusion corresponds to the guide surface width of the abutment. When the practitioner aligns the guide surface with the guide protrusion, the hexa hole of the fixture and the hexa projection of the abutment are automatically So that the alignment time can be reduced.

Thirdly, the alignment groove formed in the upper edge of the coupling hole of the guide stand can accurately insert and fix the guide protrusion corresponding to the arrangement angle of the crown manufactured according to the three-dimensional image acquisition data. Therefore, the fixture and abutment The accuracy of alignment can be improved and the crown manufactured at the time of guiding the stent can be precisely bonded to the oral cavity in accordance with the implant procedure plan.

Fourthly, the sleeve is fixed so that the guide projection portion is inserted into the alignment groove portion of the engagement hole and is not rotated, and the release prevention protrusion protruding from the inner circumferential surface of the engagement hole is inserted into the release prevention groove portion of the hollow bushing portion, And the guide protrusions are automatically aligned to the predetermined positions, so that the assemblability of the product can be improved.

1 is a flowchart showing a conventional implant procedure.
2 is an exemplary view of a guide stand for a dental implant according to one embodiment of the present invention;
FIG. 3 is a perspective view showing a sleeve of a guide stand for a tooth implant according to an embodiment of the present invention; FIG.
4 is a plan view showing a sleeve of a guide stand for a tooth implant according to an embodiment of the present invention;
FIG. 5A is a schematic view showing the use of a guide stand for a tooth implant according to an embodiment of the present invention; FIG.
Fig. 5B is a projection sectional view showing a hexa-hole of the fixture and a hexa-projection of the abutment projected on the AA cross-section of Fig. 5A. Fig.
FIG. 5c is a perspective view showing the abutment and the fixture aligned by the guide protrusion according to the embodiment of the present invention; FIG.

Hereinafter, a guide stand for a dental implant according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a perspective view of a sleeve of a guide stand for a tooth implant according to an embodiment of the present invention, and FIG. 4 is a perspective view of a guide stand for a tooth implant according to an embodiment of the present invention. FIG. 5A is a schematic view illustrating the use of the guide stent for dental implants according to one embodiment of the present invention, FIG. 5B is a cross- FIG. 5C is a sectional view of the hexa-hole of the fixture and the abutment of the abutment projected on the hexa-hole of the fixture. FIG. 5C is a cross-sectional view showing the abutment and the fixture by the sleeve of the guide stand for dental implant according to one embodiment of the present invention Which is shown in FIG.

As shown in FIGS. 2 to 5C, the guide stand 100 for dental implants according to an embodiment of the present invention includes a stent body 10 and a sleeve 20. Here, the guide stand 100 for a dental implant is formed into a profile set with three-dimensional image acquisition data obtained through three-dimensional information and image information inside the oral cavity, and serves to guide the various implant procedures to be performed thereafter .

In detail, the three-dimensional image acquisition data is used to obtain three-dimensional information about the alveolar bone and teeth in the oral cavity by performing a CT scan of the patient, and to obtain the three-dimensional information of the patient's periodontal tissues such as teeth, gums and the like through oral scanning, Dimensional image and the image information, and then matching the three-dimensional information and the image information.

In addition, an implant procedure plan can be established after the simulation considering the patient's anatomical prosthesis relationship according to the three-dimensional image acquisition data.

At this time, the stent body 10 of the guide stall 100 is formed with a profile set to have the shape of the periodontal tissue according to the three-dimensional image acquisition data, and the stent body 10 is provided with the implant There is provided a sleeve 20 for guiding the fixture placement position according to the treatment plan and guiding the drilling for forming the perforation at the fixture placement position.

2, an outer surface of the stent body 10 is formed with a profile set through the three-dimensional image acquisition data, so that the periodontal tissue can be jointed and inserted and fixed.

At this time, the anchor holes 12 may be provided on the side of the stent body 10. The anchor pin 12 is inserted into the anchor hole 12, and the anchor pin is inserted and fixed to the patient's gums and alveolar bone, so that the stanchion body 10 can be fixed in the oral cavity.

Accordingly, the staple body 10 can stably guide the various implant procedures including the drilling operation in a fixed state. In the stent body 10, a coupling hole 11 is preferably formed corresponding to the number of implants to be placed along the position where the fixture is to be placed.

2 to 3, the sleeve 20 is inserted into and coupled to the respective coupling holes 11 and includes a hollow bushing 23 and a guide protrusion 21. Here, the coupling hole 11 is formed corresponding to the fixture placement position, and the hollow bushing 23 has a guide hole 22 through which the drill for an implant is rotatably supported along the inner periphery.

The guide hole 22 rotatably supports a drill for forming a hole through which the fixture is to be inserted, and the guide hole 22 guides the depth, forming direction, diameter, and the like of the hole.

Therefore, it is preferable that the guide hole 22 has a diameter that can be guided in contact with the outer peripheral surface of the drill, and the upper edge of the guide hole 22 is formed in a height range in which the insertion depth of the drill can be adjusted .

In addition, the hollow bushing 23 may be made of brass. Therefore, it is possible to firmly support the stress due to the high-speed rotation of the drill, reduce frictional force during rotation to reduce frictional heat generation, and prevent deformation of the guide hole 22 due to stress or frictional heat.

Accordingly, by precisely and stably guiding the drill to improve the precision of the drilling, it is possible not only to perform a more complete implant treatment, but also to prevent vibration or damage of the drill due to the deformation.

2 to 4, the guide protrusion 21 protrudes from one side of the outer periphery of the hollow bushing 23, and is fixed to one side of the coupling hole 11. As shown in FIG. Here, the guide protrusion 21 can prevent rotation of the slit part 20 when the slit part 20 is inserted from the inside of the coupling hole 11 and fixed.

That is, since the inner circumferential surface of the hollow bushing portion 23 abuts against the outer circumferential surface of the drill, a force for rotating the hollow bushing portion 23 together by the rotation of the drill is applied. Is fixed to one side of the coupling hole (11) of the guide stand (10), thereby preventing rotational flow of the hollow floating part (23) and thus separation and separation of the hollow floating part (23).

The guide protrusion 21 prevents the accuracy of the drill guide from being reduced by rotating the hollow bushing 23 along the drill, thereby providing a stable guide performance.

The outer peripheral surface of the hollow bushing 23 may be formed with a rough surface 232b along the circumferential direction. Accordingly, when the hollow bushing 23 and the coupling hole 11 are coupled with an adhesive or the like, the coupling force can be improved as the contact area is increased.

Of course, on the outer circumferential surface of the hollow bushing 23, a separation preventing groove 23a may be formed along the circumferential direction. At this time, the separation preventing protrusion formed along the circumferential direction may be inserted into the release preventing groove portion 23a and fixed to the inner circumferential surface of the coupling hole 11.

Therefore, the sleeve 20 is fixed so as not to be rotated by the guide protrusion 21, and the separation preventing groove 23a and the separation preventing protrusion can be coupled to each other and fixed to the coupling hole 11 , Not only is it firmly connected by simply inserting and fitting the direction, but also the guide protrusion is automatically aligned to the set position, so that the assembling property of the product can be improved.

The guide protrusions 21 are arranged in a predetermined arrangement angle so that the hexahedrons of the abutments formed in the hexa holes of the fixture are aligned corresponding to the arrangement angles of the crowns manufactured according to the three- And is fixed to the rim of the coupling hole 11.

5a to 5b, a hexa hole 3a is formed inside the fixture 3 and a hexa projection 4a of the abutment 4 is formed in the hexa hole 3a, And can be fixed by an adhesive.

The hexa holes 3a and the hexa projections 4a may be formed in a honeycomb shape so as not to be damaged by the pressure applied during chewing of the teeth. Can be completely inserted into the inside of the main body 3a.

In addition, the abutment 4 may be formed with a guide surface 4b provided in parallel with one surface of the hexahedron 4a.

Here, when the three-dimensional image acquisition data is obtained, the guide protrusions 21 are formed in a shape corresponding to the arrangement angles at which the crown, which is the final prosthesis, is coupled into the oral cavity, and the abutment 4 and the abutment 4 is fixed to the edge of the coupling hole 11 at a predetermined placement angle so that the fixture 3 is aligned.

That is, the guide protrusion 21 serves as a reference for aligning the hexa hole 3a of the fixture 3, so that the guide protrusion 21 can be fixed to the fixture 3 in accordance with the direction of the guide protrusion 21. [ The butt 4 can be aligned and the crown can be coupled into the mouth to fit the three-dimensional image acquisition data.

Accordingly, the crown can be manufactured together with the guide stance 100 at the time when the three-dimensional image acquisition data is acquired through the CT photographing and the oral scan, and the time required for the operation can be drastically reduced.

In other words, if the angle of placement of the fixture 3 to be placed on the perforation is determined, the crown is not manufactured corresponding to the arrangement angle of the fixture 3, but the step of manufacturing the guide stand 100 The placement angle of the crown can be set, so that it is possible to prepare the implant procedure and significantly reduce the time for manufacturing various prostheses.

Accordingly, it is possible to provide an infrastructure device capable of completing gum removal, fixture hole drilling, fixture placement, and abutment / crown installation with a single operation.

At this time, it is preferable that an alignment groove 11a is formed in the upper edge of the coupling hole 11 of the guide stand 100. The alignment groove 11a is formed in the hexa-convex shape of the abutment 4, which is formed in the hexa hole 3a of the fixture 3, corresponding to the arrangement angle of the crown manufactured according to the three- The guide protrusion 21 can be inserted at a predetermined placement angle so that the guide protrusions 4a are aligned.

In detail, an implant procedure plan is established in the guide stance 100 according to the three-dimensional image acquisition data, and a joint hole 11 is formed corresponding to a position where the fixture 3 is placed according to the implant procedure plan do.

A sleeve 20 guiding the direction and diameter of the perforation for fixing the fixture 3 is inserted and fixed to the coupling hole 11 and the guide projection 21 of the sleeve 20 is inserted into the coupling hole 11. [ May be inserted into the alignment groove 11a formed in the substrate 11 and aligned and fixed at a predetermined placement angle.

When the three-dimensional image acquisition data is acquired in the guide stall 100, the alignment groove 11a is formed in the coupling hole 11 corresponding to the angle at which the crown is to be arranged, The guide protrusion 21a is inserted and fixed.

The hexa holes 3a of the fixture 3 are aligned in correspondence with the positions of the guide protrusions 21 and the abutments 4 are formed in the hexa holes 3a of the fixture 3, The crowns manufactured at the time of manufacturing the guide stent 100 can be accurately inserted into the oral cavity in accordance with the implant procedure plan.

The circumferential width of the guide protrusion 21 may correspond to the width of the guide surface 4b and the width of the guide surface 4b may be equal to the circumferential width of the guide protrusion 21 .

5c, the practitioner can adjust the hexagonal protrusions 4a of the abutment 4 only by aligning the width of the guide surface 4b in the circumferential direction of the guide protrusion 21, And the hexa holes 3a of the fixture 3 inserted and joined so that the hexa projections 4a are engaged with each other can be automatically aligned.

Accordingly, the operator can easily align the fixture 3 and the abutment 4 in accordance with the arrangement angles of the previously manufactured crown, thereby reducing the procedure time.

Of course, when placing the fixture 3, the practitioner can arrange the fixture 3 in alignment with the guide protrusion 21 while looking at the direction of the hexa hole 3a.

When the orientation of the hexa hole 3a is not directly confirmed, the abutment 4 is inserted into the fixture 3 so that the hexa projection 4a is formed in the hexa hole 3a The direction of the fixture 3 can be adjusted so that the guide surface 4b is aligned with the guide protrusion 21 when inserted.

Since the guide surface 4b is formed on the outer surface of the abutment 4 and is parallel to one surface of the hexa-shaped protrusion 4a, the guide surface 4b is formed on the guide protrusion 21 So that the hexa projections 4a can be aligned.

In other words, the practitioner aligns any one of the guide surface 4b of the abutment, the hexa boss 4a, or the hexa hole 3a of the fixture with reference to the guide projection 21, You can sort. Also, as the abutments 4 are aligned, crown manufactured according to the three-dimensional image acquisition data can be combined at an accurate placement angle.

That is, the practitioner can easily align the width of the guide surface 4b so as to correspond to the circumferential width of the guide projection 21, so that the operation time can be reduced and the fixture 3 / So that the manufactured crown can be assembled at an accurate arrangement angle, so that the convenience and precision of the procedure can be improved.

Of course, the fixture 3 may be provided with a mark corresponding to the hexa hole 3a on the upper edge of the fixture 3 so that the orientation of the hexa hole 3a inside the fixture 3 can easily be confirmed from the outside. Thus, the practitioner can easily confirm the direction of the fixture 3 and the orientation of the abutment 4 coupled to the fixture 3.

The outer surface 21a of the guide protrusion 21 corresponds to the guide surface 4b formed on the abutment 4 and the guide surface 4b corresponding to the arrangement angle of the crown manufactured according to the three- The hexa holes 4a are arranged in parallel to one surface of the hexa holes 4a. At this time, it is preferable that the outer surface 21a of the guide protrusion 21 is plane.

That is to say, the practitioner can adjust the hexahedron 3a of the fixture 3 in parallel with the outer surface 21a of the guide protrusion 21 or the abutment 4 hexahedron 3a formed in the hexa hole 3a 4a of the hexahedron 4a or the guide surface 4b parallel to one surface of the hexahedral protrusion 4a are aligned with each other so that the abutment 4 can be aligned and joined according to the arrangement angle of the crown.

The crown is not manufactured according to the arrangement angle of the abutment 4 after the abutment 4 is coupled to the fixture 3 mounted on the perforation, Since the placement angle of the crown can be set in the manufacturing step, it is possible to prepare the implant procedure and to significantly reduce the time required to manufacture various prostheses.

Accordingly, when an abutment / crown is manufactured, it is possible to provide an infrastructure device capable of completing the gum removal, fixture hole drilling, fixture placement, and abutment / crown installation with a single operation .

The guide protrusions 21 protrude from a single location on the outer periphery of the hollow bushing 23. Accordingly, the guide protrusion 21 can accurately guide the placement angle of the fixture and the placement angle of the abutment according to the predetermined arrangement angle of the crown.

As described above, the present invention is not limited to the above-described embodiments, but can be modified by a person having ordinary skill in the art to which the present invention belongs without departing from the scope of claims of the present invention And such modifications are within the scope of the present invention.

100: guide stance 1: gums
2: alveolar bone 3: fixture
3a: Hexa Hall 4: Abutment
4a: hexagonal projection 4b: guide face
10: stand body 11: engaging hole
11a: alignment groove portion 12: anchor hole
20: Sleeve 21: Guide protrusion
22: guide hole 23: hollow bushing portion

Claims (5)

A guide stand for dental implants, which is formed as a profile set through three-dimensional image acquisition data in an oral cavity and is coupled to a stance that is wrapped around a periodontal tissue to guide a fixture placement position,
A staple body having a fitting hole formed at the fixture mounting position; And
A hollow bushing portion inserted and coupled to the coupling hole and having a guide hole through which an implant drill is rotatably supported on an inner periphery thereof and a guide protrusion protruding from one side of the outer circumference of the hollow bushing portion and fixed to one side of the coupling hole Lt; RTI ID = 0.0 >
The guide protrusions are aligned with predetermined arrangement angles so that the hexahedrons of the abutments formed in the hexa holes of the fixture are aligned corresponding to the arrangement angles of the crowns manufactured according to the three-dimensional image acquisition data, Wherein the guide stent is fixed to the rim. delete A guide stand for dental implants, which is formed as a profile set through three-dimensional image acquisition data in an oral cavity and is coupled to a stance that is wrapped around a periodontal tissue to guide a fixture placement position,
A staple body having a fitting hole formed at the fixture mounting position; And
A hollow bushing portion inserted and coupled to the coupling hole and having a guide hole through which an implant drill is rotatably supported on an inner periphery thereof and a guide protrusion protruding from one side of the outer circumference of the hollow bushing portion and fixed to one side of the coupling hole Lt; RTI ID = 0.0 >
The circumferential width of the guide protrusion is adjusted so that the hexagonal protrusion of the abutment formed in the hexa hole of the fixture corresponds to the arrangement angle of the crown manufactured according to the three- And the width of the guide stent corresponds to the width of the surface of the tooth. A guide stand for dental implants, which is formed as a profile set through three-dimensional image acquisition data in an oral cavity and is coupled to a stance that is wrapped around a periodontal tissue to guide a fixture placement position,
A staple body having a fitting hole formed at the fixture mounting position; And
A hollow bushing portion inserted and coupled to the coupling hole and having a guide hole through which an implant drill is rotatably supported on an inner periphery thereof and a guide protrusion protruding from one side of the outer circumference of the hollow bushing portion and fixed to one side of the coupling hole Lt; RTI ID = 0.0 >
Wherein the hexagon protrusion of the abutment formed in the hexa hole of the fixture is aligned with the arrangement angle of the crown manufactured according to the three-dimensional image acquisition data, Wherein the alignment guide groove is formed in the guide groove. A guide stand for dental implants, which is formed as a profile set through three-dimensional image acquisition data in an oral cavity and is coupled to a stance that is wrapped around a periodontal tissue to guide a fixture placement position,
A staple body having a fitting hole formed at the fixture mounting position; And
A hollow bushing portion inserted and coupled to the coupling hole and having a guide hole through which an implant drill is rotatably supported on an inner periphery thereof and a guide protrusion protruding from one side of the outer circumference of the hollow bushing portion and fixed to one side of the coupling hole Lt; RTI ID = 0.0 >
The guide protrusion is protruded at a single point on the outer periphery of the hollow bushing,
Wherein the guide protrusion is disposed at a position aligned in parallel with a guide surface formed in the abutment and a surface of the hexa hole corresponding to the guide surface corresponding to an arrangement angle of the crown manufactured according to the three-
Wherein a rough surface machined surface is formed on an outer circumferential surface of the hollow bushing along a circumferential direction.

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