KR102594314B1 - custom angled abutment and its fabrication method - Google Patents

Abstract

A custom angled abutment is disclosed, which is formed with a structure including a through hole (2) having a central axis (C1) that coincides with the central axis of a fixture and allows passage of a screw part of a first fixing screw fastened to the fixture, and a blind screw hole (4) having a central axis (C2) that is fastened to the screw part of a second fixing screw for bonding with an artificial tooth, wherein the central axis (C1) of the through hole (2) and the central axis (C2) of the blind screw hole (4) do not coincide and can be set at various angles. The disclosed custom angled abutment comprises: a fitting part (10) formed with a polygonal cross-section to be inserted into the upper polygonal hole of the fixture; a gum contact part (20) formed on an upper side of the fitting part (10) and touching the gums of a patient; a base part (30) formed on an upper side of the gum contact part (20); and a post part (40) formed on the upper part of the base part (30) and on which an artificial tooth is fixed. The base part (30) includes an upper inclined surface (32) formed to be inclined with respect to the X-axis or the Y-axis and forming a first angle (A) with respect to the X-axis and a second angle (B) with respect to the Y-axis, and the post part (40) is formed in a direction perpendicular to the upper inclined surface (32).

Description

Custom angled abutment and its manufacturing method {custom angled abutment and its fabrication method}

The present invention relates to dental implant technology, and more specifically, to a customized angled abutment and a method of manufacturing the same.

In general, implant prosthetic treatment refers to treatment that restores the function and aesthetics of teeth using an implant system including artificial teeth when teeth or tissues surrounding teeth are damaged. Typically, an implant includes a fixture that is installed on the patient's teeth, an abutment that is fastened to the fixture with, for example, a screw, and the upper part protrudes beyond the gums, and an artificial tooth that is coupled to the upper part of the abutment. . In implant prosthetic treatment, a fixture is installed in the alveolar bone at the location where the tooth is missing, then fused with bone tissue, and then the abutment is fastened to the fixture with a screw, and then the artificial tooth is coupled to the abutment.

Meanwhile, in some patients, especially elderly patients, it is often difficult to place an implant (specifically, a fixture) due to insufficient alveolar bone height or width due to bone resorption and the presence of the inferior alveolar nerve canal. For patients with bone recession in the posterior region, the ALL-ON-4 implant system can be very useful. The ALL-ON-4 implant system can achieve sufficient success by installing only four implants in the anterior part of the upper and lower jaw, where implant treatment is easy and the success rate is high.

On the other hand, when there is a limitation in the height or width of the alveolar bone due to bone recession in the posterior region, there is a need to install the fixture at an angle. Additionally, in order to install artificial teeth to enable mastication of food under such limited conditions, the existing general This is not possible with a vertical abutment.

In response to this, an angled abutment has been proposed in the past, in which the angle of the crown, that is, the conical post portion that allows attachment of the artificial prosthesis, is inclined at a certain angle with respect to the central axis of the coupling portion that coincides with the center of the fixture.

However, although it was used limitedly in the conventional ALL-ON-4 implant system, the angled abutment has a post inclination angle of only 17 degrees or 30 degrees, so it can satisfy the various conditions of patients with bone recession in the posterior teeth. It was difficult. In addition, in the conventional angled abutment, the central axis of the coupling portion and the central axis of the post portion always exist on the same plane, and the angle between them exists on the same plane, which also supports various oral conditions of the patient. This makes it difficult to meet the requirements, and a complicated configuration must be added separately to avoid interference between the first fixing screw that connects the fixture and the angled abutment and the second fixing screw that secures the angled abutment and the crown. There were problems such as:

Patent registration number 10-2378801 (registration date March 22, 2022) Patent registration number 10-2039010 (registration date October 25, 2019)

The problem that the present invention aims to solve is to solve the problems of the prior art. It has a structure in which the central axis of the coupling part coupled to the fixture and the central axis of the post coupled to the crown are inclined and staggered on different planes to accommodate various patients' oral conditions. We provide customized angled abutments manufactured to suit.

According to one aspect of the present invention, a through hole (2) has a central axis (C1) that coincides with the central axis of the fixture and allows passage of the threaded portion of the first fixing screw fastened to the fixture, and a through hole (2) for coupling with an artificial tooth. It is fastened to the threaded part of the second fixing screw and is formed in a structure including a blind screw hole (4) having a central axis (C2), and the central axis (C1) of the through hole (2) and the blind screw hole (4) A customized angled abutment is provided that can be set at various angles without matching the central axis (C2), and the customized angled abutment has a fitting portion formed with a polygonal cross-section to be inserted into the upper polygonal hole of the fixture. (10); A gum contact part 20 formed on the upper side of the fitting part 10 and in contact with the patient's gums; A base portion 30 formed on the upper part of the gum contact portion 20; and a post part 40 formed on the upper part of the base part 30 and on which the artificial tooth is seated, and the base part 30 is formed to be inclined with respect to the It includes an upper inclined surface 32 that forms one angle (A) and a second angle (B) with respect to the Y axis, and the post portion 40 is formed in a direction perpendicular to the upper inclined surface 32.

The upper inclined surface 32 is formed to be inclined with respect to both the The point where the central axis (C1) of 2) passes is at a position spaced apart from the center of the upper inclined surface (32), and the central axis (C1) of the through hole (2) is completely spaced from the blind screw hole (4). The post portion 40 is formed rotationally symmetrically around the central axis C2 of the blind screw hole 4, and the post portion 40 has a circumferential conical surface and an upper ring surface 42. It includes, and the central axis (C2) of the blind screw hole (4) and the central axis (C1) of the through hole (2) do not meet each other.

The central axis C1 of the through hole 2 passes a point completely outside the upper inclined surface 32, and the post portion 40 has a circumferential conical surface and an upper ring surface 42 on the upper inclined surface 32. ), and a cutout portion 2a is formed in the upper part of the through hole 2 to receive a side portion of the head portion of the first fixing screw when the first fixing screw is inserted, and the cutout portion 2a is formed in the upper part of the through hole 2. (2a) is formed outside the ring surface 42.

The customized angled abutment according to the present invention has the advantage of being manufactured to suit the oral conditions of various patients in a structure in which the central axis of the coupling part coupled to the fixture and the central axis of the post coupled to the crown are inclined and staggered on different planes. has

Figure 1 is a perspective view showing a customized angled abutment according to a first embodiment of the present invention, with the main parts not visible shown in silver lines.
Figure 2 is a plan view showing a customized angled abutment according to the first embodiment of the present invention, and is a view showing the main parts that are not visible with a silver line;
Figure 3 is a front view showing a customized angled abutment according to the first embodiment of the present invention, and is a view showing the main parts that are not visible with a silver line;
Figure 4 is a side view showing a customized angled abutment according to the first embodiment of the present invention, with the main parts not visible shown in silver lines;
Figure 5 is a perspective view showing a customized angled abutment according to a second embodiment of the present invention, and is a view showing the main parts that are not visible with a silver line;
Figure 6 is a plan view showing a customized angled abutment according to a second embodiment of the present invention, with the main parts not visible shown in silver lines;
Figure 7 is a front view showing a customized angled abutment according to a second embodiment of the present invention, with the main parts not visible shown in silver lines.
Figure 8 is a side view showing a customized angled abutment according to a second embodiment of the present invention, with the main parts not visible shown in silver lines.
Figure 9 is a perspective view showing a customized angled abutment according to a third embodiment of the present invention, and is a view showing the main parts that are not visible with a silver line;
Figure 10 is a diagram for explaining a method of manufacturing a customized angled customized abutment.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. The invention may be implemented in many different forms and is not limited to the embodiments described herein.

In explaining the present invention, the size or shape of components shown in the drawings may be exaggerated or simplified for clarity and convenience of explanation.

Additionally, terms specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. These terms should be interpreted as meanings and concepts consistent with the technical idea of the present invention based on the content throughout this specification.

In order to clearly explain the present invention, descriptions of parts unrelated to the technical idea of the present invention have been omitted, and identical or similar components are assigned the same reference numerals throughout the specification.

Additionally, in various embodiments, components having the same configuration will be described using the same symbols only in the representative embodiment, and in other embodiments, only components that are different from the representative embodiment will be described.

Throughout the specification, when a part is said to be “connected” to another part, this includes not only “directly connected” but also “indirectly connected” through another member. Additionally, when a part "includes" a certain component, this may mean that it further includes other components rather than excluding other components, unless specifically stated to the contrary.

[First Example]

Referring to Figures 1 to 4, the customized angled abutment (1) according to the first embodiment of the present invention constitutes an implant together with a fixture, a first fixing screw, a second fixing screw, and a crown. As is well known, the fixture is installed in the alveolar bone and may be made of titanium or titanium alloy material. The fixture includes a screw hole, and a hole with a polygonal cross-section into which the customized angled abutment (1) is seated is formed at the top of the screw hole. The first set screw is used to secure the custom angled abutment to the fixture, and the second set screw is used to fix the crown and the custom angled abutment.

The customized angled abutment 1 of this embodiment is, for example. It is custom-made from titanium or an alloy material containing titanium, and is advantageously used to fix artificial teeth to a fixture that is installed at an angle to the patient's jawbone at an angle due to the patient's oral conditions, and is the center of the fixture. A through hole (2) that includes a main central axis (C1) coincident with the axis and allows passage of the threaded portion of the first fixing screw fastened to the fixture, and is fastened to the threaded portion of the second fixing screw for coupling with the artificial tooth. It is formed in a structure including a blind screw hole (4).

More specifically, the customized angled abutment 1 of this embodiment includes a fitting portion 10 formed with a polygonal cross-section to be inserted into the upper polygonal hole of the fixture, and a fitting portion 10 formed on the upper side of the fitting portion 10 to be inserted into the upper polygonal hole of the fixture. A gum contact portion 20 that is in contact with the gum contact portion 20 and has a truncated cone shape, a base portion 30 formed on an upper portion of the gum contact portion 20, and an artificial tooth formed on the upper portion of the base portion 30, on which the artificial tooth is seated. It integrally includes a conical post portion 40 of the lower body.

The base portion 30 forms a boundary with the gum contact portion 30, and is a lower horizontal surface composed of a horizontal plane that intersects at a right angle to the central axis C1 of the fixture and the through hole 2, that is, the main central axis C1. (31) and an upper inclined surface 32 that is inclined with respect to both the X and Y axes parallel to the lower horizontal plane, forming a first angle (A) with respect to the Includes. At this time, the central axis C1 of the through hole 2, that is, the main central axis C1, passes through the area of the upper inclined surface 32, and the location where the main central axis C1 passes is the upper inclined surface 32. It is located at a considerable distance from the center of. In addition, the main central axis C1 passes through the peripheral side wall of the post part 40, that is, the conical surface, but is completely spaced apart from the blind screw hole 4 formed in the center of the post part 40.

In the case of a conventional angled abutment, the surface formed at the top of the base is inclined at 17 degrees or 30 degrees with respect to only one of the X and Y axes and is always parallel to the other axes, which is used to fix artificial teeth. 2 The central axis of the fixing screw was always tilted at only 17 or 30 degrees to one axis, making it difficult to satisfy the oral conditions of various patients. On the other hand, according to this embodiment, although there may be a difference in the angle of the upper inclined plane, it is allowed to be inclined at the first and second angles with respect to both the can be satisfied.

The post portion 40 is formed in a roughly truncated cone shape on the upper inclined surface 32 of the base portion 30, and the center of the blind screw hole 4 is perpendicular to the upper inclined surface 32 in all directions. It is formed to be approximately rotationally symmetrical about the axis C2. At this time, the post portion 40 includes a peripheral conical surface and an upper ring surface 42, and the blind screw hole 4 is formed to pass through the center of the ring surface 42.

At this time, the central axis C2 of the blind screw hole 4 and the central axis C1 of the through hole 2 do not meet each other. In addition, the blind screw hole 4 and the through hole 2 are also formed so as not to meet each other. In this structure, the center of the first fixing screw and the center of the through hole (2) are aligned from the time the end of the threaded portion of the first fixing screw is inserted into the through hole (2) until the threaded portion of the first fixing screw is fastened to the fixture. Fastening work is possible in a consistent state, and the inconvenience and inconvenience in work can be eliminated by the structure for introducing the first fixing screw at an angle with respect to the central axis of the through hole to avoid conventional interference. A cutout portion 2a is formed in the upper part of the through hole 2 to loosely accommodate the side portion of the head portion when the first fixing screw is inserted. The inner surface of the cut part 2a may include an arc-shaped curved surface over the entire height. In this case, the head side of the first fixing screw is made into a smooth circular side, so that the inner surface of the cut part 2a can be slid. If possible, it can act as a guide surface that guides smooth entry of the first fixing screw. The first fixing screw, which is inclinedly fastened due to the inclined fixture, can be fastened to the fixture in a well-aligned state despite the inclination.

At this time, the cut portion 2a is formed to delete part of the inclined upper surface 32 and the conical surface of the base portion 30, and its height is set below the above-described ring surface 42, so that the ring surface 42 is The incision 2a is formed as an intact circular ring surface that does not span. Since the ring surface 42 is formed as a completely circular ring-shaped surface completely spaced from the incision 2a, the second fixing screw is fastened to the closed screw hole 4 to fix the artificial tooth to the abutment, making an incision. The part (2a) does not have any effect on the blocked screw hole (4) or its surroundings, ensuring reliable fastening.

[Second Embodiment]

5 to 8, the customized angled abutment 1 according to the second embodiment of the present invention includes a fitting portion 10 formed with a polygonal cross-section to be inserted into the upper polygonal hole of the fixture, and the fitting portion 10. A gum contact portion 20 formed on the upper side of (10), in contact with the patient's gums, and formed in the shape of a truncated cone of the lower quadrant, a base portion 30 formed on the upper side of the gum contact portion 20, and the base portion 30 ) and integrally includes a conical post portion 40 in the shape of a cone in which the artificial tooth is seated.

The base portion 30 forms a boundary with the gum contact portion 20, and is a lower horizontal surface composed of a horizontal plane that intersects at a right angle with the central axis C1 of the fixture and the through hole 2, that is, the main central axis C. (31) and an upper inclined surface 32 formed to be inclined with respect to both the X and Y axes parallel to the lower horizontal surface 31, forming a first angle with respect to the . At this time, the second angle may be a minute angle close to 0 degrees, and further, the second angle may be 0 degrees.

At this time, the central axis C1 of the through hole 2, that is, the main central axis C1, does not pass through the upper inclined surface 32. It passes a point completely off the upper slope 32. This allows the post portion 40 formed on the upper inclined surface 32 and the blind screw hole 4 formed in the post portion 40 to deviate from the through hole 2 more completely and reliably.

The post portion 40 is formed in a roughly truncated cone shape on the upper inclined surface 32 of the base portion 30, and the center of the blind screw hole 4 is perpendicular to the upper inclined surface 32 in all directions. It is formed rotationally symmetrically around the axis C2. At this time, the post portion 40 includes a peripheral conical surface and an upper ring surface 42, and the blind screw hole 4 is formed to pass through the center of the ring surface 42.

As described above, since the central axis C1 of the through hole 2 does not pass through the upper inclined surface 32 on which the post part 40 is formed, the blind screw hole 4 passing through the center of the post part 40 is It is far away from the through hole (2). A cutout portion 2a is formed in the upper part of the through hole 2 to accommodate the side portion of the head portion when the first fixing screw is inserted. The inner surface of the cut part 2a may include an arc-shaped curved surface over the entire height. In this case, the head side of the first fixing screw is made into a smooth circular side, so that the inner surface of the cut part 2a can be slid. If possible, it can act as a guide surface that guides smooth entry of the first fixing screw.

In the case of the previous embodiment, the cut portion 2a was formed to remove a significant height of the conical surface as well as the upper inclined surface 32, but in the present embodiment, the central axis C1 of the through hole 2 is formed at the post portion. Due to the structure that does not pass through the upper inclined surface 32 on which (40) is formed, the cut portion 2a is hardly formed on the conical surface. In the drawing, the boundary of the incision 2a slightly exceeds the lower part of the conical surface, but note that the incision 2a and the conical surface can be formed to be completely spaced apart. The ring surface 42 is also formed as an intact circular ring surface without the cutout 2a. Since the ring surface (2a) and the conical surface are substantially formed as intact surfaces completely spaced apart from the incision part (2a), the second fixing screw is fastened to the blind screw hole (4) to fix the artificial tooth to the abutment, making an incision. The part 2a does not have any influence on the screw hole or its surroundings, ensuring reliable fastening and improving the durability of the abutment.

[Third Embodiment]

Referring to FIG. 9, the customized angled abutment 1 according to the third embodiment of the present invention includes a fitting portion 10 formed with a polygonal cross-section to be inserted into the upper polygonal hole of the fixture, and the fitting portion 10. A gum contact portion 20 formed on the upper side of the gum contact portion 20, which is in contact with the patient's gums and has a truncated cone shape of the lower lateral canal, a base portion 30 formed on the upper portion of the gum contact portion 20, and an upper portion of the base portion 30. It is formed in and integrally includes a conical post portion 40 in which the artificial tooth is seated.

The base portion 30 forms a boundary with the gum contact portion 20, and is formed to be inclined with respect to both the X-axis and the Y-axis, forming a first angle with respect to the Includes (32).

The post portion 40 is formed in a roughly truncated cone shape on the upper inclined surface 32 of the base portion 30, and the central axis of the blind screw hole 4 is perpendicular to the upper inclined surface 32 in all directions. It is formed rotationally symmetrically with (C2) as the center. At this time, the post portion 40 includes a peripheral conical surface and an upper ring surface 42, and the blind screw hole 4 is formed to pass through the center of the ring surface 42.

When the first fixing screw is inserted, a cutout portion 2a is formed in the upper part of the through hole 2 to accommodate the side portion of the head portion of the first fixing screw. The inner surface of the cutout portion 2a may include an arc-shaped curved surface over the entire height.

The cut portion 2a is formed to remove not only the upper inclined surface 32 of the base portion 30 but also a portion of the conical surface. In contrast, the ring surface 42 is formed as an intact circular ring surface without the cutout 2a. Since the ring surface 42 is formed as an intact surface completely spaced apart from the incision 2a, the second fixing screw is fastened to the closed screw hole 4 to fix the artificial tooth to the abutment, and the incision 2a It does not have any effect on the screw hole or its surroundings, ensuring reliable fastening.

[Manufacturing method]

Figure 10 is a diagram for explaining a custom abutment manufacturing method according to an embodiment of the present invention.

Referring to Figure 10, the custom angled abutment manufacturing method according to an embodiment of the present invention includes a step (S1) of acquiring an STL file of a custom angled abutment design, and converting the data of the STL file into NC data. A step of converting to (S2), a step of correcting the NC data so that the dimensions of the STL file and the dimensions of the CNC-processed customized abutment result are substantially 1:1, and a step of correcting the customized abutment using the corrected NC data. It includes a step (S4) of CNC milling a titanium round bar material to produce an angled abutment. At this time, the round bar material is CNC milled while being held in a jig that rotates and moves back and forth and left and right to produce a customized angled abutment.

The STL file may be an STL file in which a dental laboratory designs a customized abutment and delivers it to a customized abutment processing company.

To design a customized angled abutment, the dentist installs a fixture in the alveolar bone at the patient's tooth loss site, fastens the scan body to the fixture after a certain period of time, and then digitally scans the oral cavity. The scan data is sent to the dental laboratory, and the dental laboratory uses the scan data to design a virtual tooth, and from the virtual tooth, a customized angled abutment and artificial tooth are designed together. At this time, it is possible to create an oral plaster using oral scan data and design customized angled abutments and artificial teeth using data obtained by scanning the oral plaster.

In step (S1), the STL file created by designing the customized angled abutment and artificial tooth is delivered to the processing company. The STL file includes the design of the aligned angled abutment as well as the design of the corresponding artificial tooth.

The processing and production of artificial teeth based on the artificial tooth design are performed in a dental laboratory, and the manufacturing of customized abutments based on the customized angled abutment design through CNC milling is performed at a processing company.

In step S2, converting the data of the STL file into NC data is performed using a CAM. The STL file is based on point data, and by inputting NC data whose dimensions have not been corrected in the STL file received from the dental laboratory, a round bar clamped to a jig that rotates and moves in a CNC machine is cut and processed to create a customized abutment. When manufacturing, the actual dimensions of the resulting custom abutment will be longer (larger) than the dimensions of the STL file.

Therefore, a step (S3) of correcting the NC data is performed so that the dimensions of the STL file and the dimensions of a specific part of the finished product are substantially 1:1. The step (S3) may be performed depending on previously accumulated data.

When an artificial tooth and a customized angled abutment are designed together, extracted as an STL file, and then processed based on this, in most cases, the dimensions of the customized abutment are larger than the actual result and do not fit the crown well. For this reason, separate additional processing to partially remove the inner thickness of the artificial tooth was previously required, but the present invention allows the customized angled abutment to be processed without additional processing by correcting the dimensions before CNC milling. It can fit perfectly into the machined crown.

In step S4, the round bar is CNC milled to produce a customized angled abutment using the corrected NC data.

As a CNC milling tool, a ball end mill is used instead of a bite type with a sharp tip commonly used in making existing custom abutments. Ball end mills are suitable for round processing.

Above, the above content merely exemplifies a preferred embodiment of the present invention, and those skilled in the art should be aware that modifications and changes can be made to the present invention without changing the gist of the present invention.

10: Fitting portion 20: Gum contact portion
30: base part 40: post part
2: Through hole 4: Blind screw hole

Claims (3)

A through hole (2) has a central axis (C1) that coincides with the central axis of the fixture and allows passage of the threaded portion of the first fixing screw fastened to the fixture, and is fastened to the threaded portion of the second fixing screw for coupling with an artificial tooth. It is formed of a structure including a blind screw hole (4) having a central axis (C2), and the central axis (C1) of the through hole (2) and the central axis (C2) of the blind screw hole (4) coincide with each other. It is a customized angled abutment that can be set at various angles without
A fitting portion 10 formed with a polygonal cross-section to be inserted into the upper polygonal hole of the fixture;
A gum contact part 20 formed on the upper side of the fitting part 10 and in contact with the patient's gums;
A base portion 30 formed on the upper part of the gum contact portion 20; and
It is formed on the upper part of the base part 30 and integrally includes a post part 40 on which the artificial tooth is seated,
The base portion 30 is formed to be inclined with respect to the X-axis or Y-axis and includes an upper inclined surface 32 forming a first angle (A) with respect to the The post portion 40 is formed in a direction perpendicular to the upper inclined surface 32,
The upper inclined surface 32 is formed to be inclined with respect to both the The point where the central axis (C1) of 2) passes is at a position spaced apart from the center of the upper inclined surface (32), and the central axis (C1) of the through hole (2) is completely spaced from the blind screw hole (4). The post portion 40 is formed rotationally symmetrically around the central axis C2 of the blind screw hole 4, and the post portion 40 has a circumferential conical surface and an upper ring surface 42. A customized angled abutment, characterized in that the central axis (C2) of the blind screw hole (4) and the central axis (C1) of the through hole (2) do not meet each other. delete delete