KR102034995B1 - Abutment for Implant and Method for making the same - Google Patents

Abstract

According to an embodiment of the present invention, an implant abutment, which is installed to connect a fixture implanted to a bone tissue in a preset first direction with dentures, comprises: an attachment having a lower portion inserted into a fixture, an upper portion upwardly extending from the lower portion, and a through hole penetrating the inside thereof; a fastening screw fastened to lower portions of the fixture and the attachment; a ball having a lower portion inserted into the through hole of the attachment, having a rotatable spherical shape, and having a ball recess part formed at the center thereof; a cylinder coupled to an upper portion of the ball, and having a cylinder through hole aligned in the ball recess part; and a cylinder screw fastened to the ball recess part and the cylinder through hole. The ball includes a plurality of cut holes formed on an outer circumferential surface of the ball to be elastically deformed when the cylinder screw is fastened. Also, an extension line passing through the center of the ball recess part slantly extends with respect to the first direction.

Description

Abutment for Implant and Method for making the same

The present invention relates to an implant abutment and a method of manufacturing the same.

In general, denture is a prosthesis with artificial teeth, which can be attached to or detached from the gums. When the food is ingested, it is worn on the gums and stored separately when used to sleep. Dentures can be divided into partial dentures and full dentures. Partial dentures are applied when there are parts of natural teeth missing, and full dentures when no natural teeth remain in the maxilla or mandible.

In addition, the implant is implanted in the alveolar bone where the tooth is made of a material that is not rejected to the human body so that it can replace the root of the missing tooth, and then bonded and fixed the artificial tooth together with the connection column to restore the original function of the tooth It is a procedure to recover.

Implants as described above have the disadvantage that the cost is increased to exponentially when the cost of the implant is formed at a high cost to supplement the teeth by the implant procedure in a state where a large number of natural teeth are lost.

In addition, dentures are less expensive than implants, but if they are not worn correctly on the gums, they can cause pain in the gums, or if the dentures are not organized systematically, the dentures are lost and their function is lost. There is a disadvantage of causing damage.

Recently, the development of an artificial prosthesis (overdenture) combining an implant and a denture has been made to compensate for such a disadvantage.

1 is a state diagram of use of a denture using an implant.

Referring to Figure 1, the prosthesis (overdenture), at least two or more implants (1) are implanted in the lower jaw or upper alveolar bone (B), the implant (1) of the denture (2) receptor (3) ) To be mounted on the structure.

However, when implanting the implant into the alveolar bone as described above, there was a problem that the implant can not be placed vertically according to the condition of the patient. In the case of patients using dentures, there is a problem that the implantation of the implant is relatively easy because the alveolar bone condition is more likely to be worsened.

That is, although the plurality of implants are implanted in the alveolar bone of the patient, the implantation angle is different, there may be a problem that the compatibility is lower when the denture is mounted on the implant.

In order to solve this problem, registered utility model publication No. 20-0471489 discloses an abutment of a ball joint type. The abutment of the ball joint type compensates for the inclination angle of the fixture during the procedure.

However, the abutment of the ball joint type also has a problem in that the rotation range of the ball joint is limited because there is a limit on the compensable angle, so that it is difficult to apply to patients with a large angle of placement of the alveolar bone.

In particular, even if the placement angle of any one or more of the two or more implants 1 is compensated for, if the other implant having a largely displaced angle is not sufficiently compensated for, the densities of the dentures may still be inferior.

In addition, if the denture is mounted without sufficiently compensating the implantation angle of the implant by the ball joint type abutment, there is a problem that the denture is easily twisted due to the chewing pressure when the patient is used, making it difficult to use for a long time.

When the consistency of the denture is inferior as described above, there is a problem that not only causes pain to the patient but also the denture is damaged and cannot be used continuously, and when it is necessary to perform reoperation, it is not only economical but also affects the health of the patient. There is this.

The present invention, in order to solve the above problems, when the fixture implanted in the patient's alveolar bone is placed in the left and right directions in a condition that should be implanted in the forward direction, for example vertical direction of the alveolar bone, the wrong angle of the fixture An object of the present invention is to provide an implant abutment that compensates for and improves the consistency with dentures.

In detail, an object of the present invention is to provide an abutment for an implant comprising an angled type attachment or an angled type cylinder having a shape inclined at a set angle to compensate for the twisted angle of the fixture.

Another object of the present invention is to provide an implant abutment including a ball body having a spherical ball shape that is inserted into a through hole of an attachment coupled to the fixture and is free to rotate freely.

In addition, when the twisted angle of the fixture is relatively large, by providing the angled attachment and the angled cylinder to increase the compensation angle efficiently, to provide an implant abutment capable of double angle compensation The purpose.

Another object of the present invention is to provide an implant abutment including a ball body having a rotation limiting portion so that the ball maintains a set angle when the ball is attached to the attachment.

Another object of the present invention is to provide an implant abutment including an attachment having an area portion in contact with a rotation limiting portion of the ball and facilitating maintaining a set angle of the ball when the ball is mounted on the attachment.

In addition, an object for providing an implant abutment comprising a ball having an incision hole to enable elastic deformation, so that the ball is stably coupled to the attachment and the cylinder when screwing the cylinder screw to the ball. do.

In addition, when the fixture is placed in the patient's alveolar bone is implanted, an object of the present invention is to provide an implant abutment manufacturing method for manufacturing a custom abutment reflecting the patient's alveolar bone condition.

Implant abutment according to an embodiment of the present invention, in the implant abutment is installed to connect the fixture and denture implanted in the first direction predetermined in the bone tissue, the lower portion inserted into the fixture Attachment having a through hole penetrating through the upper portion and the upper portion extending from the lower portion; A fastening screw fastened to the lower portion of the fixture and the attachment; A lower part inserted into a through hole of the attachment, the ball having a spherical shape that can be rotated, and a ball depression formed at a center thereof; A cylinder coupled to an upper portion of the ball and having a cylinder through hole aligned with the ball depression; And a cylinder screw fastened to the ball recess and the cylinder through hole, wherein the ball includes a plurality of cutout holes formed in an outer circumferential surface of the ball to be elastically deformable when the cylinder screw is fastened. An extension line passing through the center of the depression may extend inclined with respect to the first direction.

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According to the above solution, irrespective of the twisted angle of the fixture implanted in the alveolar bone of the patient, the angle can be compensated to increase the consistency with the denture.

In detail, an inclined shape inserted into the fixture or an inclined cylinder coupled to an upper side of the attachment may be provided to compensate for the twisted angle of the fixture.

In addition, even if the wrong angles of a plurality of fixtures placed in the maxilla or mandible of the patient for mounting the denture are different from each other, the denture receptor can be vertically coupled using the inclined attachment or cylinder. You can prevent the shaking.

In addition, since the ball is inserted into the through-hole of the attachment and coupled to the cylinder in a spherical shape, the angle can be freely rotated, so that the attachment and the cylinder may be mounted at an angle corresponding to the inclined shape of the attachment.

In addition, when the twisted angle of the fixture is relatively large, dual angle compensation is possible by combining an inclined attachment and an inclined cylinder.

In addition, the ball is provided with a rotation restriction on the outer surface is inserted into the attachment, the ball can be easily inserted to the attachment while maintaining the set angle can be easily coupled to the cylinder and the cylinder screw.

Further, when the cylinder screw is coupled to the ball inserted into the through hole of the attachment, the ball may be elastically deformed by the cutting hole of the ball, so that the screw of the cylinder screw may be easily coupled.

In addition, as the volume of the ball increases due to the elastic deformation of the ball, stable attachment of the attachment and the cylinder is possible.

In addition, a patient-specific design of attachments, balls, and cylinders capable of angular compensation required for each fixture implanted into the alveolar bone of the patient is possible, thereby preventing economic reoperations.

In addition, by preventing the reoperation of the patient, it is possible to increase the oral health of the patient and the ease of use of the denture.

1 is a state diagram of use of a denture using an implant.
2 is a perspective view of an implant according to a first embodiment of the present invention.
3 is a side view of the implant.
4 is an exploded view of the implant.
5 is a cross-sectional view taken along line 5-5 of FIG. 2.
6 is a perspective view of an attachment according to a first embodiment of the present invention.
7 is a side view of the attachment.
8 is a cross-sectional view taken along line 8-8 of FIG. 6.
9 is a perspective view of a ball according to a first embodiment of the present invention.
10 is a side view of the ball.
11 is a cross-sectional view taken along line 11-11 of FIG. 9.
12 is a perspective view of a cylinder according to the first embodiment of the present invention.
13 is a side view of the cylinder.
14 is a cross-sectional view taken along 14-14 of FIG. 12.
15 is a perspective view of an abutment according to a second embodiment of the present invention.
16 is a cross-sectional exploded view taken along 16-16 of FIG. 15.
17 is a perspective view of an attachment according to a second embodiment of the present invention.
18 is a cross-sectional view taken along line 18-18 of FIG. 17.
19 is a perspective view of a cylinder according to a second embodiment of the present invention.
20 is a cross-sectional view taken along line 20-20 of FIG. 19.
21 is a perspective view of an abutment according to a third embodiment of the present invention.
FIG. 22 is a cross-sectional exploded view taken along line 22-22 of FIG. 21;
23 is a perspective view of a ball according to a fourth embodiment of the present invention.
24 is a perspective view of the ball viewed from another side.
25 is a side view of the ball.
26 is a perspective view of an attachment according to a fourth embodiment of the present invention.
Fig. 27 is a plan view of the attachment as seen from above.
28 is a flow chart showing a method of manufacturing an implant abutment according to an embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail with reference to the accompanying drawings. In adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are assigned to the same components as much as possible even though they are shown in different drawings. In addition, in describing the embodiments of the present invention, when it is determined that the detailed description of the related well-known configuration or function interferes with the understanding of the embodiment of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are only for distinguishing the components from other components, and the nature, order or order of the components are not limited by the terms. When a component is described as being "connected", "coupled" or "connected" to another component, that component may be directly connected or connected to that other component, but between components It will be understood that may be "connected", "coupled" or "connected".

Figure 2 is a perspective view of the implant according to the first embodiment of the present invention, Figure 3 is a side view of the implant, Figure 4 is an exploded view of the implant, Figure 5 is a cross-sectional view taken along the 5-5 of FIG. .

2 to 5, the implant 100 according to the first embodiment of the present invention, the fixture is placed in the alveolar bone (B), the abutment coupled to the upper side of the fixture 110 The fastener may include a fastening screw 130 for coupling the abutment to the fixture 110.

In addition, the abutment, the attachment 200 is coupled to the fixture groove formed in the fixture 110, the ball 300 is coupled to the upper portion of the attachment 200 and the upper side of the ball 300 It may be coupled to and may include a cylinder 400 for fixing the denture (2).

The attachment 200 according to the first embodiment may be defined as an "angled type attachment" that is formed to be inclined in the left and right direction about an up and down reference, and the cylinder 400 is a "straight type" formed in the up and down direction. Cylinder ".

The implant 100 may further include a cylinder screw 150 for fixing the cylinder 400 to the ball 300.

The fixture 110 may be placed in the alveolar bone B and function as an artificial root. The fixture 110 may be implanted in the first direction d1 preset in the alveolar bone B. For example, the first direction d1 may be a direction in which an extension line extending along the center of the fixture 110 faces.

The fixture 110 may include a fixture body 111 extending in the first direction d1 and a thread 112 formed on an outer surface of the fixture body 111. Thread 112 of the fixture 110 may be screwed to the female thread (not shown) formed in the groove of the alveolar bone (B).

In addition, the fixture 110 may be formed with fixture grooves 114 and 116 extending downward from an upper end thereof. The attachment 200 and the fastening screw 130 may be inserted into the fixture grooves 114 and 116.

The fixture grooves 114 and 116 communicate with the first groove 114 and the first groove 114 into which the lower portion of the fastening screw 130 is inserted, and the second groove into which the lower portion of the attachment 200 is inserted. 116 may include. When the fastening screw 130 is fastened to the fixture 110 and the attachment 200, at least a part of the fastening screw 130 may be located in the first groove 114 and the second groove 116. have.

The second groove 116 may be provided to increase in diameter toward the top. The shape of the second groove 116 may be provided to correspond to the lower shape of the attachment 200 to be described later.

In addition, the first groove 114 may be provided smaller than the diameter of the second groove 116 to correspond to the shape of the fastening screw 130.

An upper portion of the first groove 114 may be provided to increase in diameter toward the upper side. Since the upper diameter of the first groove 114 is larger than the lower diameter of the first groove 114, the fastening screw 130 can easily enter the first groove 114.

In addition, the fixture 110 may further include a first seating portion 118 on which the lower end of the attachment 200 is seated. The first seat 118 may be positioned between the first groove 114 and the second groove 116. When the attachment 200 is inserted into the fixture 110, the lower surface of the attachment 200 may be stably supported by the upper surface of the first seating portion 118.

In addition, a thread 114a for fastening the fastening screw 130 may be formed on an inner circumferential surface of the first groove 114. The thread 114a may be screwed with the thread 135 of the fastening screw 130 to be described later.

The fastening screw 130 may include a head portion 131 on which a coupling groove 131a to which a tool is coupled may be formed, and a body portion 133 extending downward from the head portion 131. . The head part 131 and the body part 133 may be formed to correspond to the first direction d1.

The diameter of the head 131 may be larger than the diameter of the body 133. By the difference in diameter between the head 131 and the body 133, the head 131 may be seated on the second seating portion 221 of the attachment 200 to be described later.

The body portion 133 of the fastening screw 130 may include a thread 135 threaded to the thread 114a of the fixture 110. For example, the thread 114a of the fixture 110 constitutes a female thread, and the thread 135 of the fastening screw 130 constitutes a male thread.

The cylinder screw 150 may include a head portion 151 in which a coupling groove 151a to which a tool is coupled may be formed, and a body portion 153 extending downward from the head portion 151. . The head part 151 and the body part 153 may have a ball 300 to be described later corresponding to the second direction d2 inclined at a first angle a1 set in the first direction d1. It may be inserted into the cylinder 400.

The second direction d2 may be a direction in which an extension line perpendicular to the center of the cylinder 400 or the ball 300 to be described later is directed. For example, the first angle a1 may be formed in a range of 15 ° to 30 °.

In addition, the diameter of the head portion 151 of the cylinder screw 150 may be provided larger than the diameter of the body portion 153 of the cylinder screw 150. Due to the difference in diameter between the head part 151 and the body part 153 of the cylinder screw 150, the head part 153 of the cylinder screw 150 is a third seating portion of the cylinder 400 to be described later ( See, FIG. 14, 422.

In addition, the body portion 153 of the cylinder screw 150 may be inserted into the ball recessed portion (see Fig. 9, 305) of the ball 300 to be described later.

In addition, the cylinder screw 150 may further include a screw thread 153a formed in the body portion 153. The thread 153a may be screwed to the thread 320 of the ball 300 to be described later.

6 is a perspective view of an attachment according to a first embodiment of the present invention, FIG. 7 is a side view of the attachment, and FIG. 8 is a cross-sectional view taken along the line 8-8 of FIG.

6 to 8, the attachment 200 may include a body part 201, a part of which is inserted into the fixture groove.

The body portion 201 may be provided in a form inclined part.

In detail, the lower portion of the body portion 201 may be formed to extend in the first direction d1 to be inserted into the second groove 116 of the fixture 110. The upper portion of the body portion 201 is inclined in a second direction d2 inclined at a first angle a1 predetermined with respect to the first direction d1 as it goes upward from the lower portion of the body portion 201. Can be extended.

The inclined outer surface of the body portion 201 may be formed in a curved surface. In detail, the outer surface connecting the lower and upper portions of the body portion 201 may be formed in a curved surface. That is, in the state in which the attachment 200 is placed in the alveolar bone B, the gum and the like of the patient in contact with the attachment 200 may prevent pain and damage from occurring due to the curved surface.

The body portion 201 may be provided to decrease the outer diameter toward the lower portion. That is, due to the difference in the outer diameter of the body portion 201, only the lower portion of the body portion 201 is inserted into the second groove 116 of the fixture 110, the diameter larger than the second groove 116 An upper portion of the body portion 201 to be formed may be located above the fixture 110.

The body portion 201 may further include an upper surface 203 formed perpendicular to the second direction d2. A portion of the upper surface 203 may be formed to be open. The upper surface 203 of the body portion 201 may be in contact with the lower surface 416 of the cylinder 400 to be described later.

That is, the second direction d2 may be a direction in which an extension line penetrating the upper surface 203 vertically faces.

The upper surface 203 may include an upper groove 204 formed by recessing a portion thereof. The upper groove 204 may be located at the uppermost side of the upper surface 203. The fastening screw 150 can be easily inserted into the attachment 200 in the first direction d1 by the upper groove 204.

The body portion 201 may further include a rotation preventing portion 205 having a polygonal cross section. The anti-rotation part 205 may be located below the body part 201. For example, the anti-rotation part 205 may have a hexagonal cross section.

When the lower portion of the attachment 200 is inserted into the second groove 116 of the fixture 110, the attachment 200 is prevented because the rotation of the attachment 200 is prevented by the rotation preventing portion 205. It can be fixed stably.

The body portion 201 is connected to the first body portion 201a and the first body portion 201a extending in the second direction d2 downward from the upper surface 203 and in the first direction. a second body portion 201b extending to (d1) and connected to the first body portion 201a and the second body portion 201b and facing the rotation preventing portion 205 in the first direction d1; It may further include a third body portion 201c extending to.

The second body portion 201b may be located on the left side with reference to FIG. 7. In detail, the second body portion 201b may be positioned below the upper surface 203 positioned relatively above the upper surface 203 based on an extension line penetrating the attachment 200 vertically. In more detail, the second body portion 201b may be located below the upper surface 203 in which the upper groove 204 of the upper surface 203 is formed.

The first body portion 201a and the second body portion 201b may be connected to each other by different extending directions of the first body portion 201a and the second body portion 201b. According to the shape of the first body portion 201a and the second body portion 201b, the attachment 200 below the upper groove 204 of the attachment 200 may have a predetermined thickness.

That is, the attachment 200 can maintain a predetermined thickness while having the shape of the first through hole 210 and the second through hole 220 which will be described later, thereby reinforcing strength.

The third body portion 201c may have a rounded outer surface.

At least a portion of the third body portion 201c may be provided to have an outer diameter smaller toward the lower portion. Due to the difference in the outer diameter of the third body portion 201c, the lower portion of the attachment 200 may be inserted into the fixture 110.

The attachment 200 may further include through holes 210 and 220 into which the fastening screw 130 and the ball 300 to be described later are inserted.

The through holes 210 and 220 are located above the body part 201 and downward from the first through hole 210 and the first through hole 210 formed corresponding to the second direction d2. It may include a second through hole 220 extending and formed corresponding to the first direction (d1).

The first through hole 210 and the second through hole 220 may be in communication. The fastening screw 130 may be inserted through the opened upper surface of the body portion 210 and may be positioned in the second through hole 220 through the first through hole 210.

The first through hole 210 may have a rounded surface. In detail, the first through hole 210 may be provided as a spherical surface, a part of which is omitted. In more detail, the first through hole 210 may be formed to correspond to a part of the outer surface of the ball 300 to be described later.

The first through hole 210 may be in communication with the upper groove 204.

In addition, the second through hole 220 may be provided in a circumferential surface corresponding to the shape of the fastening screw 130. By the shape of the second through hole 220, the fastening screw 130 can be easily inserted into the second through hole (220).

The second through hole 220 may be formed in a size corresponding to the diameter of the head 131 of the fastening screw 130. Since the diameter of the second through hole 220 is larger than the diameter of the body portion 133 of the fastening screw 130, the inner circumferential surface of the attachment 200 is the body portion 133 of the fastening screw 130. It may be spaced apart from the exterior.

In addition, the diameter of the first through hole 210 may be larger than the diameter of the second through hole 220. Therefore, the fastening screw 130 can be easily inserted into the second through hole 220 through the first through hole 210.

In addition, the attachment 200 may include a screw thread 230 located in the second through hole 220 and a second seating portion 221 located on the upper side of the screw thread 230.

The upper and lower lengths of the second through holes 220 positioned above the screw thread 230 of the second through holes 220 may be longer than the head 131 of the fastening screw 130. That is, when the fastening screw 130 is inserted into the second through hole 220 of the attachment 200 and fastened, the head 131 of the fastening screw 130 is connected to the first through hole 210. It is positioned apart from the ball 300 is inserted.

The thread 230 of the attachment 200 may be formed to correspond to the thread 135 of the fastening screw 130. In other words, the thread of the attachment 200 may be formed in the same manner as the thread 114a of the fixture 110.

The fastening screw 130 may be coupled to the thread 114a of the fixture 110 by passing through the thread 230 of the attachment 200. In this case, the head 131 of the fastening screw 130 may be supported by the second seating portion 221.

9 is a perspective view of a ball according to a first embodiment of the present invention, FIG. 10 is a side view of the ball, and FIG. 11 is a cross-sectional view taken along the line 11-11 of FIG.

9 to 11, the ball 300 may have a spherical shape with a portion partially opened.

The ball 300 may include a ball body 301 coupled to the attachment 200 and the cylinder 400.

The ball body 301 may have a top surface 303 in which the opening is formed and a ball recess 305 in which the cylinder screw 150 is inserted. The ball recess 305 may be formed to extend below the opening of the ball body 301.

The ball 300 may include a cutting hole 310 formed in the outer circumferential surface of the ball body 301. The cutting hole 310 may be in communication with the ball recess 305.

The cutting hole 310 may be provided in plurality. The plurality of cutting holes 310 may be arranged at equal intervals. For example, six cutting holes 310 may be provided and arranged at equal intervals.

By the cutting hole 310, the cylinder screw 150 may be easily inserted into the ball recess 305 of the ball 300. That is, the ball body 301 is elastically deformed by the cutting hole 310 so that the cylinder screw 150 can be easily inserted.

The ball 300 may include a thread portion 320 formed on an inner surface of the ball 300 to correspond to the thread 153a of the cylinder screw 150. The screw part 320 may be located between a plurality of adjacent cutting holes 310.

For example, the screw part 320 may be a female screw, and the thread 153a of the cylinder screw 150 may be provided as a male screw.

At least a part of the ball 300 may be inserted into the through holes 210 and 220 of the attachment 200. Since the first through hole 210 and the second through hole 220 of the attachment 200 communicate with each other, a part of the ball 300 inserted into the attachment 200 is partially connected to the first through hole 210. ), And the other part is located above the first through-hole (220).

When the ball 300 is inserted into the through holes 210 and 220 of the attachment 200, the lower part of the ball 300 is inserted into the second through hole 220, and the head of the fastening screw 130 is fastened. 131 may be spaced apart. When the ball 300 is rotated by the spaced positions of the ball 300 and the fastening screw 130, interference by the fastening screw 130 may be prevented.

Referring to FIG. 10, the ball 300 is a virtual agent passing through a random point perpendicular to the second direction d2 and located farthest from the upper surface 303 of the outer surface of the ball body 301. The second extension line l1 may further include a virtual second extension line l2 parallel to the first extension line l1 and the first extension line l1 and passing through the center of the ball body 301.

The ball 300 is a virtual third extension line l3 parallel to the first extension line l1 and the second extension line l2 and passing through the upper surface 203 of the attachment 200 and the incision hole 310. It may further include a virtual fourth extension line (L4) passing through the bottom of.

The distance between the first extension line l1 and the second extension line l2 is the radius r of the ball body 301, and the distance between the first extension line l1 and the third extension line l3 is The ball 300 may be understood as the first height h1 inserted into the attachment 200.

The first height h1 may be larger than the radius r of the ball body 301. That is, the center of the ball body 301 may be located in the first through hole 210 of the attachment 200, and at least half of the ball 300 is the first through hole of the attachment 200. May be inserted at 210.

Since the ball 300 may be elastically deformed by the cutting hole 310, the ball 300 may be attached even if the first height h1 is larger than the radius r of the ball body 301. It can be easily inserted into the first through hole 210 of the (200).

In addition, after the ball 300 is inserted into the first through hole 210 of the attachment 200 by the first height h1, the cylinder screw 150 is fastened to elastically deform the ball 300. In this case, since the size of the ball 300 is increased, the ball 300 may be easily prevented from being detached from the attachment 200.

In addition, the distance from the first extension line l1 to the fourth extension line l4 may be understood as a second height h2 in which the cutting hole 310 of the ball body 301 is not formed.

The second height h2 may be smaller than the radius r of the ball body 301. For example, the second height h2 may be smaller than the radius r of the ball body 301 and greater than half of the radius r of the ball body 301.

By the second height (h2), as the cylinder screw 150 is fastened to the ball 300, the ball 300 can be elastically deformed and damage can be prevented.

In addition, when the ball 300 is inserted into the first through hole 210 of the attachments 200 and 250 or the third through hole 260 (see FIG. 17) to be described later, the ball 300 may be easily formed due to the shape of the ball 300. Rotatable.

The ball 300 may be rotated in a direction in which the first angle a1 increases or decreases based on the first direction d1 to achieve angle compensation. For example, the first angle a1 may be adjusted to a maximum of 30 degrees so that the position of the ball 300 may be adjusted, and accordingly, angle compensation of up to 60 degrees may be performed on both sides of the first direction d1. .

12 is a perspective view of a cylinder according to a first embodiment of the present invention, FIG. 13 is a side view of the cylinder, and FIG. 14 is a cross-sectional view taken along 14-14 of FIG. 12.

12 to 14, the cylinder 400 may include a first body 410 formed corresponding to a second direction d2 and a second body 414 inclinedly extending from the first body 410. ) May be included.

The first body 410 may have a cylindrical shape.

In addition, the first body 410 has an open upper surface, through which the cylinder screw 150 can enter.

In addition, the second body 410 may extend inclined in a direction perpendicular to the second direction d2 toward the lower side. In other words, the second body 410 may be formed such that its outer diameter increases toward the lower side.

In addition, the cylinder 400 is located on the outer surface of the first body 410 and is perpendicular to the second direction d2 from the lower end of the protrusion 412 and the second body 414 formed in the circumferential direction. It may further include a third body 416 extending in one direction.

A plurality of protrusions 412 may be provided. The plurality of protrusions 412 may be spaced apart from each other in the second direction d2 by a predetermined interval. The denture 2 can be easily mounted to the implant 100 by the protrusion 412.

In addition, the third body 416 extends outward from a lower end of the second body 414. The lower surface of the third body 416 may be provided to correspond to the upper surface 203 of the attachment 200.

When the cylinder 400 is coupled to the ball 300, the bottom surface of the third body 416 is in contact with the top surface 203 of the attachment 200.

In addition, the cylinder 400 may include a cylinder through hole 420 formed to penetrate in the vertical direction.

The cylinder through hole 420 may include a first cylinder through hole 421 extending downward from an open upper surface of the first body 410 and a second extending downward from the first cylinder through hole 421. It may include a third cylinder through hole 425 extending downward from the cylinder through hole 423 and the second cylinder through hole 423 and coupled to the upper portion of the ball 300.

The first cylinder through hole 421 and the second cylinder through hole 423 may be formed in a cylinder. That is, the inner surface of the cylinder 400 located in the first cylinder through hole 421 and the second cylinder through hole 423 may be configured as a circumferential surface.

The diameter of the first cylinder through hole 421 may be larger than the diameter of the second cylinder through hole 423. The diameter of the first cylinder through hole 421 is provided to correspond to the diameter of the head portion 151 of the cylinder screw 150, the diameter of the second cylinder through hole 423 is the cylinder screw 150 It may be provided to correspond to the diameter of the body portion 153 of the.

The third cylinder through-hole 425 may be provided in a shape corresponding to a portion of the outer surface of the ball 300 so that the upper portion of the ball 300 can be inserted.

The cylinder 400 may further include a third seating part 422 on which the head 151 of the cylinder screw 150 is supported. The third seating part 422 may be located between the first cylinder through hole 421 and the second cylinder through hole 423.

Therefore, when the cylinder screw 150 is inserted into the cylinder 400, the head 151 of the cylinder screw 150 is seated on the third seating portion 422.

As described above, when the abutment according to the first embodiment of the present invention is coupled to the fixture 110, the first angle preset from the first direction d1 in which the fixture 110 is placed. (a1) can be compensated.

Since various angle compensations are possible according to the inclined shape of the attachment 200, the implantation of the patient may be performed irrespective of the mounting angle of the fixture 110. That is, the denture of the patient can be stably coupled, the abutment can exert a stable and safe effect on the chewing activity of the patient.

Hereinafter, a second embodiment of the present invention will be described. Since the present embodiment differs only in the structure of the attachment and the cylinder from the first embodiment, the difference is mainly described. For the same parts as the first embodiment, the description and reference numerals of the first embodiment are used.

15 is a perspective view of an abutment according to a second embodiment of the present invention, FIG. 16 is a cross-sectional exploded view taken along 16-16 of FIG. 15, and FIG. 17 is an attachment of an attachment according to a second embodiment of the present invention. 18 is a cross-sectional view taken along 18-18 of FIG. 17, FIG. 19 is a perspective view of a cylinder according to a second embodiment of the present invention, and FIG. 20 is a cross-sectional view taken along 20-20 of FIG. 19. to be.

15 to 20, the abutment according to the second embodiment of the present invention includes an attachment 250 coupled to a fixture groove formed in the fixture 110 and an upper portion of the attachment 250. Coupled to the ball 300 and the upper side of the ball 300 may be coupled to include a cylinder 450 for fixing the denture (2).

The attachment 250 according to the second embodiment may be defined as a "straight type attachment" formed in the vertical direction, and the cylinder 450 is an "angled type formed to be inclined in the left and right direction about an up and down reference. Cylinder ".

The attachment 250 may include a body part 251, a part of which is inserted into the fixture groove.

The body part 251 may be formed to extend in the first direction d1.

In other words, an extension line extending vertically to the center of the attachment 250 may face the first direction d1.

The body portion 251 may be configured to reduce the outer diameter toward the lower side. In detail, only a lower portion of the body portion 251 is inserted into the second groove 116 of the fixture 110 due to a difference in the outer diameter of the body portion 251, and has a larger diameter than that of the second groove 116. The upper portion of the body portion 251 is formed may be located on the upper side of the fixture (110).

The outer surface of the body portion 251 may be formed in a curved surface. That is, in the state where the attachment 250 is placed in the alveolar bone B, the gum and the like of the patient contacting the attachment 250 may prevent pain and damage from occurring due to the curved surface.

The body portion 251 may further include an upper surface 253 which is formed perpendicular to the first direction d1. A portion of the upper surface 253 may be formed to be open. The upper surface 253 of the body portion 251 may be in contact with the lower surface 466 of the cylinder 450 to be described later.

In addition, the body portion 251 may further include a rotation preventing portion 255 having a polygonal cross section. The anti-rotation part 255 may be located under the body part 251. For example, the anti-rotation part 255 may have a hexagonal cross section.

When the lower portion of the attachment 250 is inserted into the second groove 116 of the fixture 110, the attachment 250 is prevented because the rotation of the attachment 250 is prevented by the rotation preventing portion 255. It can be fixed stably.

In addition, the attachment 250 may further include through holes 260 and 270 into which the fastening screw 130 and the ball 300 to be described later are inserted.

The through holes 260 and 270 extend downward from the opened upper surface 253 of the body part 251 and correspond to the third through hole 260 and the first through hole corresponding to the outer surface of the ball 300. And a fourth through hole 270 extending downward from 260.

The third through hole 260 and the fourth through hole 270 may be in communication. The fastening screw 130 may be inserted through the opened upper surface of the body portion 210 to pass through the third through hole 260 and be positioned in the fourth through hole 270.

The third through hole 260 may have a rounded surface. In detail, the third through hole 260 may be provided as a spherical surface with a part omitted. In more detail, the third through hole 260 may be formed to correspond to a part of the outer surface of the ball 300 to be described later.

In addition, the third through hole 260 may have a height corresponding to the first height h1 of the ball 300. When the ball 300 is inserted into the third through hole 260, the ball 300 has a ball body 301 corresponding to the first height h1 inserted into the attachment 250.

In addition, the fourth through hole 270 may be provided in a circumferential surface corresponding to the shape of the fastening screw 130. By the shape of the fourth through hole 270, the fastening screw 130 can be easily inserted into the fourth through hole (270).

The fourth through hole 270 may have a size corresponding to the diameter of the head 131 of the fastening screw 130. Since the diameter of the fourth through hole 270 is larger than the diameter of the body portion 133 of the fastening screw 130, the inner circumferential surface of the attachment 250 is the body portion 133 of the fastening screw 130. It may be spaced apart from the exterior.

In addition, the diameter of the third through hole 260 may be larger than the diameter of the fourth through hole 270. Therefore, the fastening screw 130 can be easily inserted up to the fourth through hole 270 through the third through hole 260.

In addition, the attachment 250 may include a screw thread 280 positioned in the fourth through hole 270 and a fourth seating portion 271 positioned above the screw thread 280.

The thread 280 of the attachment 250 may be formed to correspond to the thread 135 of the fastening screw 130. In other words, the thread 280 of the attachment 250 may be formed in the same manner as the thread 114a of the fixture 110.

The vertical length of the fourth through hole 270 positioned above the thread 280 of the fourth through hole 270 may be longer than the length of the head 131 of the fastening screw 130. .

When the fastening screw 130 and the ball 300 are inserted into the through holes 260 and 270 of the attachment 250 by the length of the fourth through hole 270, the ball 300 and the fastening screw The head 131 of the 130 may be spaced apart. That is, when the ball 300 rotates, interference by the head 131 of the fastening screw 130 may be prevented.

The fastening screw 130 may be screwed to the thread 114a of the fixture 110 by passing through the thread 280 of the attachment 250. In this case, the lower surface of the head 131 of the fastening screw 130 may be supported by the upper surface of the fourth seating portion 271.

The cylinder 450 may include a fourth body 460 formed corresponding to the second direction d2, a sixth body 466 formed perpendicularly to the first direction d1, and the fourth body 460. ) May include a fifth body 464 connecting the sixth body 466.

The second direction d2 may be a direction in which an extension line perpendicular to the center of the cylinder 450 or the ball 300 faces. For example, the first angle a1 may be formed in a range of 15 ° to 30 °.

The fourth body 460 may have a cylindrical shape.

In addition, the fourth body 460 has an open upper surface, and the cylinder screw 150 can enter through the open upper surface.

In addition, the fifth body 464 may extend inclined in a direction perpendicular to the second direction d2 toward the lower side. In other words, the fifth body 464 may be formed such that its outer diameter increases toward the lower portion thereof.

19 and 20, the fifth body 464 connects a sixth body 466 that is relatively close to the fourth body 460 from the lower end of the fourth body 460. It may include a first inclined portion 464a and a second inclined portion 464b connecting the sixth body 466 relatively far from the lower end of the fourth body 460 to the fourth body 460.

The outer diameter of the sixth body 466 may be larger than the outer diameter of the fifth body 464. In other words, the sixth body 466 extends outward from an end of the fifth body 464.

By the shapes of the fourth body 460, the fifth body 464, and the sixth body 466, the cylinder 450 may be understood as an inclined shape with respect to the sixth body 466. Can be.

In addition, the cylinder 450 may further include a protrusion 462 positioned on an outer surface of the fourth body 460 and formed in a circumferential direction.

The lower surface of the third body 466 may be provided to correspond to the upper surface 253 of the attachment 250. When the cylinder 450 is coupled to the ball 300, the bottom surface of the third body 466 is in contact with the top surface 253 of the attachment 250.

In addition, the cylinder 450 may include a cylinder through hole 470 formed to penetrate in the vertical direction.

The cylinder through hole 470 may include a fourth cylinder through hole 471 extending downward from the opened upper surface of the fourth body 460 and a fifth extending downward from the fourth cylinder through hole 471. It may include a sixth cylinder through hole 475 extending downward from the cylinder through hole 473 and the fifth cylinder through hole 473 and coupled to the upper portion of the ball 300.

The fourth cylinder through hole 471 and the fifth cylinder through hole 473 may be formed in a cylinder. That is, the inner surface of the cylinder 450 located in the fourth cylinder through hole 471 and the fifth cylinder through hole 473 may be configured as a circumferential surface.

The diameter of the fourth cylinder through hole 471 may be larger than the diameter of the fifth cylinder through hole 473. The diameter of the fourth cylinder through-hole 471 is provided to correspond to the diameter of the head portion 151 of the cylinder screw 150, the diameter of the fifth cylinder through-hole 473 is the cylinder screw 150 It may be provided to correspond to the diameter of the body portion 153 of the.

The sixth cylinder through hole 475 may be provided in a shape corresponding to a portion of the outer surface of the ball 300 so that the upper portion of the ball 300 can be inserted therein.

In detail, as illustrated in FIG. 20, the length of the arc formed by the sixth cylinder through hole 475 positioned on the first inclined portion 464a with respect to the bottom surface of the fifth cylinder through hole 473. Is smaller than the length of the arc of the sixth cylinder through-hole 475 located on the side of the second inclined portion 464b.

The cylinder 450 may further include a fifth seating portion 472 on which the head 151 of the cylinder screw 150 is supported. The fifth seating portion 472 may be positioned between the fourth cylinder through hole 471 and the fifth cylinder through hole 473.

Therefore, when the cylinder screw 150 is inserted into the cylinder 450, the head 151 of the cylinder screw 150 is seated on the fifth seating portion 472.

As described above, when the abutment according to the second embodiment of the present invention is coupled to the fixture 110, the first angle preset from the first direction d1 in which the fixture 110 is placed. (a1) can be compensated.

For example, the first angle a1 may be inclined so that the cylinder 450 may be up to 30 degrees, and the position of the ball 300 may be adjusted to match the shape of the cylinder 450. An angle compensation of up to 60 degrees may be performed on both sides of the first direction d1.

Since various angle compensations are possible according to the inclined shape of the cylinder 450, the implantation of the patient may be performed irrespective of the placement angle of the fixture 110. That is, the denture of the patient can be stably coupled, so that the abutment can exert a stable and safe effect on the chewing activity of the patient.

Hereinafter, a third embodiment of the present invention will be described. Since the present embodiment differs only in the combination of the attachment and the cylinder compared to the first and second embodiments, the difference will be mainly described. The same parts as those in the first and second embodiments will be described above. The description and reference numerals of the embodiment and the second embodiment are used.

21 is a perspective view of an abutment according to a third embodiment of the present invention, and FIG. 22 is a cross-sectional exploded view taken along the line 22-22 of FIG. 21.

21 and 22, the abutment according to the third embodiment of the present invention includes an attachment 200 coupled to a fixture groove formed in the fixture 110 and an upper portion of the attachment 200. Coupled to the ball 300 and the upper side of the ball 300 may be coupled to include a cylinder 450 for fixing the denture (2).

The attachment 200 according to the third embodiment is the “angled type attachment” that is formed to be inclined about an up and down standard, and the cylinder 450 is the “angled type cylinder that is formed to be inclined about an up and down standard. "to be.

When the attachment 200, the ball 300, and the cylinder 450 are coupled, an upper portion of the attachment 200 is inclined in the second direction d2, and the cylinder 450 is The second direction d2 may be formed to correspond to the third direction d3 inclined at a predetermined second angle a2.

In detail, an extension line extending vertically through the second through hole 220 of the attachment 200 faces the first direction d1 and is perpendicular to the upper surface 203 of the attachment 200. The extension line extending vertically may correspond to the second direction d2.

The extension line penetrating the ball recess 305 of the ball 300 according to the third embodiment or the extension line perpendicular to the center of the fourth body 451 of the cylinder 450 is directed to the third direction. (d3).

For example, the second angle a2 inclined from the second direction d2 to the third direction d3 may be formed in a range of 10 ° to 30 °.

As described above, when the abutment according to the third embodiment of the present invention is coupled to the fixture 110, the first angle preset from the first direction d1 in which the fixture 110 is placed. (a1) and the second angle a2 may be compensated for.

Since the dual compensation is possible at various angles according to the inclined shape of the attachment 200 and the cylinder 450, the patient's implantation can be performed irrespective of the mounting angle of the fixture 110. That is, the denture of the patient can be stably coupled, the abutment 100 can exhibit a stable and safe effect on the chewing activity of the patient.

In particular, even if the angle of the fixture 110 is relatively largely distorted due to a patient's alveolar bone injury, since the angle angle attachment 200 and the angled type cylinder 450 are used, double angle compensation is possible. The suitability of (2) can be improved.

Figure 23 is a perspective view of a ball according to a fourth embodiment of the present invention, Figure 24 is a perspective view of the ball from another side, Figure 25 is a side view of the ball, Figure 26 is a fourth embodiment of the present invention. It is a perspective view of the attachment, and FIG. 27 is a top view which looked at the attachment from the upper side.

In the following, a fourth embodiment of the present invention is signed. Since this embodiment differs only in some configurations of attachments and balls compared to the first embodiment and the second embodiment, the differences will be mainly described, and the same parts as in the first and second embodiments will be described above. The description and reference numerals of the first embodiment and the second embodiment are used.

23 to 27, the ball 300 according to the fourth embodiment of the present invention may further include a rotation limit unit 330 formed on the ball body 301.

The rotation restriction part 330 may be formed by cutting a part of the curved surface of the ball body 301. In detail, the rotation limit unit 330 may be formed to face.

The rotation limit unit 330 may be formed in a circular shape.

In addition, the rotation limit unit 330 may be located between the adjacent cutting holes 310 of the ball body 301. When the ball 300 is inserted into the attachment 250, the rotation of the ball 300 may be limited by the rotation limiting part 330.

In detail, the ball 300 forms the inclined setting angle with respect to the attachments 200 and 250 such that the ball recess 305 is aligned with the cylinder through holes 420 and 470 and the cylinder screw 150. When coupled to), the rotation limiting portion 330 may prevent the rotation of the ball (300). Since the rotation of the ball 300 is prevented, the ball 300 can maintain the set angle.

Therefore, as the ball 300 is maintained at the set angle, the coupling of the cylinder 400 and the cylinder screw 150 may be easily performed.

The rotation limit unit 330 may be provided in plurality. The plurality of rotation limit units 330 may be disposed to face each other. Rotation of the ball 300 is easily prevented by the plurality of rotation limiting units 330.

In addition, the ball 300 is a virtual fifth extension line l5 parallel to the first extension line l1 and passing through a point that is located farthest from the first extension line l1 among the rotation limiting portions 330. It may further include.

The distance from the first extension line l1 to the fifth extension line l6 may be defined as a third height h3.

The third height h3 may be larger than the second height h2 at which the ball 300 is inserted into the attachment 250. That is, only a part of the rotation limiting part 330 may be inserted into the attachment 250.

The attachment 250 may further include an extended surface 253a extending inwardly from the upper surface 253 and a planar portion 262 which is formed in a plane and forms part of the third through hole 260. Can be.

In detail, the upper surface 253 may be formed in a ring shape. The extension surface 253a may extend horizontally inward from a portion of the ring-shaped upper surface 253.

The extension surface 253a may be formed in plural to correspond to the plurality of rotation limiting parts 330. Similarly, the plurality of extension surfaces 253a may be positioned to face each other.

In addition, the planar portion 262 may be provided at a position corresponding to the extension surface 253a of the inner surface of the attachment 250 that forms the third through hole 260 and has a spherical shape.

The flat part 262 may be formed to face at least a portion of the rotation limiting part 330. For example, the planar portion 262 may have a circular shape with some omitted.

In addition, the planar portion 262 may be provided in plurality in correspondence with the plurality of rotation limiting portions 330 and the plurality of extension surfaces 253a.

When the ball 300 is inserted into the third through hole 260 of the attachment 250, a part of the rotation limiting part 330 is in contact with the flat part 262 to rotate the ball 300. Preventable.

Hereinafter, the manufacturing method of the abutment of the said invention is demonstrated.

28 is a flow chart showing a method of manufacturing an implant abutment according to an embodiment of the present invention.

In manufacturing the abutment according to the present invention, first, the fixture 110 is fastened to the fixture 110 with the scan body 500 in a state of being placed in the alveolar bone B of the patient ( S10).

In this case, the fixture 110 may be implanted at various angles according to the state of the maxilla or mandible of the patient. The fixture 110 is often not vertically buried in the maxilla or mandible, and the angle of the patient may be distorted a lot when the patient's condition is severe.

The oral cavity scan data scanned by the oral scanner 550 is stored in the computer using the scan body 500 fastened to the fixture 110 (S20). The scan body may be understood as a kind of scan adapter. Information about an implantation angle of the fixture 110 may be obtained through the oral cavity scan data.

The abutment may be designed in a dental program using the oral cavity scan data. For example, 3Shape, Exocad, or the like can be used as the dental program.

First, an angle a requiring compensation by the abutment may be determined based on an implantation angle of the fixture 110 (S30).

In detail, the oral cavity scan data may obtain information about the first direction d1 in which the fixture 110 is placed. Compensation is required by the abutment 100 by comparing the second direction d2 or the third direction d3 and the first direction d1 in which the cylinder 400 of the abutment is vertically positioned. The angle a can be obtained.

A kind of abutment capable of compensating the angle a may be determined according to the size of the angle a requiring compensation (S40).

When the size of the angle a is relatively small, the angled type attachment 200 and the straight type cylinder 400 or the straight type attachment 250 and the angled type cylinder 450 may be selected. have. At this time, the fixture 110 may be appropriately selected according to the implantation groove state of the alveolar bone B of the patient.

In detail, when the angled type attachment 200 and the straight type cylinder 400 are selected, the angle a is compensated by the angled type attachment 200 to compensate for the attachment 200 and the ball 300. The straight type cylinder 400 fastened to) may be vertically positioned.

In addition, when the straight type attachment 250 and the angled type cylinder 450 are selected, the angle type cylinder 460 is compensated by the angled type cylinder 450 to compensate for the angle a. It can be positioned vertically.

In addition, when the size of the angle a is relatively large, the angle a attachment 200 and the angle type cylinder 450 may be selected to compensate the angle a.

In detail, the angle-type attachment 200 is fastened to the first angle a1 by the angle type attachment 200 fastened to the fixture 110, and the angle fastened to the angle type attachment 200 and the ball 300. The second type a2 is compensated for by the de-type cylinder 450, thereby enabling dual angle compensation.

In other words, since the first angle a1 and the second angle a2 can be compensated for and finally the angle a can be compensated, the angled coupled to the receptor 3 of the denture 2. The type cylinder 450 may be positioned vertically.

Therefore, even when the angle of the fixture 110 placed in the alveolar bone B of the patient is relatively large, that is, even when the size of the angle a is relatively large, the angled type attachment 200 and the It is possible to mount a stable denture 2 by the abutment including the angled type cylinder 450.

Unlike the prior art, the abutment does not require reoperation even when the implantation angle of the fixture 110 is relatively large, thereby exerting an economic effect.

In addition, since it is possible to mount the appropriate abutment to the patient without reoperation, the patient's convenience may be increased.

The determined abutment may be processed (S50).

The processed abutment may be assembled to the fixture 110 placed in the alveolar bone B of the patient.

First, the attachments 200 and 250 of the processed abutment are inserted into the fixture 110, and fastened and fixed using the fastening screw 130 (S60).

The ball 300 is inserted into the attachments 200 and 250, and the processed cylinders 400 and 450 are coupled to each other and fastened and fixed using the cylinder screws 150 (S70). In detail, after inserting the processed ball 300 into the attachment (200, 250), the cylinder screw 150 is easily inserted into the cylinder through hole (420,470) and the ball recess 305 of the cylinder (400,450). Adjust the position of the ball 300.

By the rotation limiting portion 330 formed on the ball 300, the position of the adjusted ball 300 can be maintained, so that the coupling of the cylinders 400 and 450 and the fastening of the silan screw 150 are easy. can do.

When the cylinders 400 and 450 are coupled to the receptor 3 of the denture 2, the denture 2 may be stably mounted in the mouth of the patient.

In the embodiment of the present invention, the fixture 110 and the fastening screw 130 and the ball 300 and the cylinder screw 150 has been described as screwed, but the fixture 110 and the The attachment 200 and the ball 300 and the cylinder 400 may be changed to another fastening member that can be coupled.

In addition, in the embodiment of the present invention, the case in which the ball 300 having the rotation limiting portion 330 is inserted into the straight type attachment 250, but the ball having the rotation limiting portion 330 300 may be inserted into the angle type attachment 200. When inserted into the angled attachment 200, the rotation limiting unit 330 may be provided at a position corresponding to the flat part provided in the angled attachment 200.

In addition, although the attachment 200 or the cylinder 450 is shown to be inclined to the right in the figure of the present invention, it is clear that the direction of the inclination is not limited thereto.

Within the scope of the basic technical idea of the present invention, many modifications are possible to those skilled in the art, and the scope of the present invention should be interpreted based on the appended claims. will be.

1: implant 2: denture
100: abutment 110: fixture
130: tightening screw 150: cylinder screw
200,250: Attachment 300: Ball
400,450: cylinder

Claims (20)

In the implant abutment which is installed to connect the fixture and the denture implanted in the first predetermined direction in the bone tissue,
An attachment having a lower portion inserted into the fixture and a through hole penetrating through the upper portion and the upper portion extending upwardly from the lower portion;
A fastening screw fastened to the lower portion of the fixture and the attachment;
A lower part inserted into a through hole of the attachment, the ball having a spherical shape that can be rotated, and a ball depression formed at a center thereof;
A cylinder coupled to an upper portion of the ball and having a cylinder through hole aligned with the ball depression; And
And a cylinder screw fastened to the ball recess and the cylinder through hole,
The ball includes a plurality of incision holes formed in the outer circumferential surface of the ball so as to be elastically deformable when the cylinder screw is fastened,
An extension line passing through the center of the ball recess portion is inclined with respect to the first direction. The method of claim 1,
A lower portion of the attachment extends in the first direction,
An upper portion of the attachment extends in the second direction inclined at a predetermined first angle with respect to the lower portion of the attachment. The method of claim 2,
An extension line passing through the center of the ball depression is an implant abutment facing the second direction. The method of claim 2,
In the through hole of the attachment,
A first through hole formed in an upper portion of the attachment and into which a lower portion of the ball is inserted; And
An implant abutment formed under the attachment and including a second through hole in which the fastening screw is inserted. The method of claim 4, wherein
The first through hole has a shape corresponding to a portion of the spherical surface of the ball,
An implant abutment having a diameter of the first through hole is larger than a diameter of the second through hole. The method of claim 4, wherein
The center of the ball is the implant abutment located in the first through hole. The method of claim 4, wherein
An implant abutment is formed on the upper surface of the attachment, the upper groove is formed in communication with the first through-hole so that the fastening screw is inserted in the first direction. The method of claim 2,
The cylinder,
A first body connected to the denture and provided in a cylindrical shape;
A second body extending obliquely downward from the first body toward the outside; And
A third body extending perpendicularly to the second direction from the end of the second body toward the outside;
The lower surface of the third body is an implant abutment in contact with the upper surface of the attachment. The method of claim 8,
The cylinder through hole,
A first cylinder through hole through which the cylinder screw passes; And
A second cylinder through hole into which an upper portion of the ball into which the cylinder screw is fastened is inserted;
The second cylinder through-hole is implant abutment having a shape corresponding to the outer surface of the ball. The method of claim 2,
The ball,
A virtual first extension line (l1) perpendicular to the second direction and passing through a point located opposite to the cylinder with respect to the center of the sphere; And
And a virtual second extension line l4 parallel to the first extension line and passing through a lower end of the incision hole.
An implant abutment (h2) from the first extension line to the second extension line is half the length of the radius (r) of the ball. The method of claim 1,
The attachment extends in the first direction,
The cylinder through-hole is implant abutment is formed to be inclined at a predetermined first angle with respect to the attachment. The method of claim 11,
The cylinder,
A first body extending in a second direction;
A third body contacting the upper surface of the attachment and extending perpendicular to the first direction; And
A second body connecting the first body and the third body, the second body having a first inclined portion and a second inclined portion longer than the first inclined portion;
The second abutment is an implant abutment in the direction through the cylinder through-hole. The method of claim 11,
In the through hole of the attachment,
A first through hole formed in an upper portion of the attachment and into which a lower portion of the ball is inserted; And
An implant abutment formed under the attachment and including a second through hole in which the fastening screw is inserted. The method of claim 13,
The first through hole has a shape corresponding to a portion of the spherical surface of the ball,
An implant abutment having a diameter of the first through hole is larger than a diameter of the second through hole. The method of claim 2,
The cylinder through-hole is implant abutment formed to be inclined at a predetermined second angle with respect to the attachment. The method of claim 15,
The cylinder,
A first body extending in a third direction;
A third body contacting the upper surface of the attachment and extending perpendicular to the second direction; And
A second body connecting the first body and the third body, the second body having a first inclined portion and a second inclined portion longer than the first inclined portion;
The third abutment is an implant abutment in a direction passing through the cylinder through hole. The method of claim 11,
The ball,
An implant abutment including a rotational limiter provided with a portion of the outer surface facing to prevent rotation. The method of claim 17,
The attachment is,
It includes a flat portion provided facing the position corresponding to the rotation limit of the through hole,
An implant abutment in which the rotational restriction portion and the planar portion are in contact with the ball inserted into the through hole of the attachment. delete delete

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