KR20210042645A - A oral model and a method for the same - Google Patents

Abstract

The present invention relates to an oral model which can be used for education on tooth extraction procedures, and a manufacturing method thereof. According to the technology, it is possible to reproduce an excessive tooth impacted in the oral cavity similarly to the real one, the effect of practice of the operation to remove the excess tooth can be increased, and the clinical skill can be improved. In addition, by utilizing computer programs such as CAD and 3D printing technology, it is possible to economically and easily produce a customized oral model for each patient. The oral model comprises: a main body in the shape of the maxilla or mandible of the oral cavity, which has an impact space; a tooth to be removed located inside the impact space and disposed at a predetermined distance from the inner surface of the impact space; and a support part supporting the tooth to be removed in the impact space of the main body.

Description

Oral model and its manufacturing method {A ORAL MODEL AND A METHOD FOR THE SAME}

The present technology relates to an oral model that can be used for teaching tooth extraction procedures and a method of manufacturing the same.

The oral model is used for practice in dental education institutions, hospitals, and seminars. These oral models are mainly used for practice before trainees perform actual procedures in the dental treatment curriculum such as implants, tooth extraction, orthodontics, and treatment of gum disease.

On the other hand, the supernumerary tooth refers to a tooth that occurs more than a predetermined number of each type of tooth, such as incisors, canines, and molars. The excess teeth generated during the indwelling may interfere with the eruption of the permanent teeth, and there may be insufficient space for the teeth to be arranged in the mouth, which may lead to malocclusion, such as a rectum. In addition, it may absorb the roots of adjacent teeth or form cysts, and may be inserted into the nasal cavity, maxillary sinuses, or hard palate, or may cause perceptual abnormalities by compressing nerves. Therefore, it is desirable to remove it before complications occur due to excess values.

However, currently, there is a problem that the surgery to remove the ambushed excess teeth is only a method of being skilled through a lot of clinical experience for actual patients, but this has a problem that it is difficult to proceed easily due to ethical issues as well as difficulty in recruiting patient groups.

Such. To solve the problem, a method of using an oral model can be considered, but the conventional oral model can be mainly applied only to the practice of procedures such as implants or simple extractions, and the excess teeth that are ambushed in proximity to the permanent anterior teeth are similar to the real one. It is difficult to reproduce, and there is a problem that it is not suitable for use in practice of surgery to remove excess teeth.

Domestic registered utility model No. 20-0422578, educational implant tooth model

One object of the present technology is to provide an oral model that can be used to practice tooth extraction in the oral cavity.

In addition, another object of the present technology is to provide a method for manufacturing the oral cavity model.

The present technology is an ambush space is formed, the upper or lower body of the oral cavity; A tooth to be removed located inside the ambush space and disposed at a predetermined distance from the inner surface of the ambush space; And a support part for supporting the tooth to be removed in the ambush space of the main body.

In addition, the present technology includes the steps of (S1) forming an ambush space surrounding the tooth to be removed and the tooth to be removed at a predetermined distance; (S2) arranging the teeth to be removed surrounded by the ambush space in the upper or lower body of the oral cavity; (S3) arranging a support for connecting the tooth to be removed and the inner surface of the ambush space; (S4) generating data of a three-dimensional oral cavity model; And (S5) manufacturing an oral cavity model through mechanical processing using the generated 3D oral cavity model data.

According to one aspect of the present technology described above, it is possible to reproduce the excess teeth ambushed in the oral cavity in a similar way to the actual one, it is possible to increase the practical effect of the surgery to remove the excess teeth, and it is possible to improve clinical proficiency. In addition, using computer programs such as CAD and 3D printing technology, it is possible to economically and easily produce individual patient-customized oral models.

1 is a view showing the external shape of the oral cavity model according to the present technology.
2 is a cross-sectional view showing a surface cut along the line AA′ of the oral cavity model of FIG. 1.
3 is a real photograph of the oral model according to the present technology.

The oral model according to the present technology includes a body of the upper or lower jaw shape of the oral cavity in which an ambush space is formed; A tooth to be removed located inside the ambush space and disposed at a predetermined distance from the inner surface of the ambush space; And a support portion for supporting the tooth to be removed in the ambush space of the main body.

The separation distance is preferably 0.01 to 2.0 mm, more preferably 0.05 to 1.5 mm, even more preferably 0.1 to 1.0 mm.

The ambush space and a plurality of teeth to be removed may be present.

The oral model according to the present technology may further include a communication path for discharging the fluid in the ambush space to the outside of the body.

The method of manufacturing an oral cavity model according to the present technology includes the steps of: (S1) forming an ambush space surrounding the tooth to be removed and the tooth to be removed at a predetermined distance from the tooth to be removed; (S2) arranging the teeth to be removed surrounded by the ambush space in the upper or lower body of the oral cavity; (S3) arranging a support for connecting the tooth to be removed and the inner surface of the ambush space; (S4) generating data of a three-dimensional oral cavity model; And (S5) manufacturing an oral cavity model through mechanical processing using the generated 3D oral cavity model data.

The separation distance is preferably 0.01 to 2.0 mm, more preferably 0.05 to 1.5 mm, even more preferably 0.1 to 1.0 mm.

The step (S3) may further include arranging a communication path for discharging the fluid in the ambush space to the outside of the body.

The steps (S1) to (S4) may use a CAD program.

The machining of step (S5) may be performed using a 3D printer.

Hereinafter, preferred embodiments of the present technology will be described in more detail with reference to the accompanying drawings.

Prior to the description of the present technology, the following specific structure or functional descriptions are exemplified only for the purpose of describing embodiments according to the concept of the present technology, and embodiments according to the concept of the present technology may be implemented in various forms. , It should not be construed as being limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present technology can make various changes and have various forms, specific embodiments will be illustrated in the drawings and described in detail in the present specification. However, this is not intended to limit the embodiments according to the concept of the present technology to a specific form of disclosure, and it should be understood that all modifications, equivalents, and substitutes included in the spirit and scope of the present technology are included.

As shown in Figures 1 to 2, the oral model 10 according to the present technology is the body 100 of the upper or lower jaw shape of the oral cavity in which the ambush space 120 is formed; A tooth to be removed 140 located inside the ambush space 120 and disposed to be spaced apart from the inner surface of the ambush space 120 at a predetermined interval; And it is preferable to be configured to include a support portion 150 for supporting the removal target tooth 140 in the ambush space 120 of the body 100.

The main body 100 of the oral cavity model 10 according to the present technology is a shape of the upper or lower jaw of the human oral cavity. The body 100 may have an alveolar bone portion 110 and an ambush space 120 formed therein.

The alveolar bone portion 110 is a portion of the body 100 where the teeth 130 are located. The alveolar bone portion 110 may be formed separately and coupled to the main body 100 or may be integrally formed with the main body. The alveolar bone portion 110 is formed along an arc, inside the body 100 at a predetermined distance from the arc-shaped side edge. As shown in FIG. 2, the alveolar bone portion 110 and the tooth 130 may be formed integrally with the body 100, or may be individually formed and combined. When formed individually, the alveolar bone portion 110 may be formed with a groove so that the teeth 130 can be coupled.

The ambush space 120 is a space in which the teeth 140 to be removed are disposed, and may be freely located inside the main body 100 according to a required practice condition.

The teeth 130 are coupled to the alveolar bone portion 110 of the main body 10, and may be implemented in various forms such as incisors, canines, premolar teeth, and molar teeth according to the coupling position in order to reproduce a shape similar to the oral structure of the human body. have.

The tooth to be removed 140 refers to an impingement tooth or an excess tooth buried in the oral mucosa or jaw without erupting even after the time to erupt into the mouth. In the oral model according to the present technology, the removal target tooth 140 may be a subject of practice in removing surgery. The teeth to be removed 140 are located inside the ambush space 120 of the main body 100 and are arranged to be spaced apart from the inner surface of the ambush space 140 by a predetermined distance. When the separation distance is too long, the tooth 140 to be removed can be easily extracted just by opening the ambush space 120, so the practical effect may be reduced, and when the separation distance is too short, the main body ( 100) and the tooth to be removed 140 may be in direct contact with each other, so extraction of the tooth to be removed 140 may not be well performed during practice.

The separation distance may be preferably 0.01 to 2.0 mm, more preferably 0.05 to 1.5 mm, even more preferably 0.1 to 1.0 mm. In this way, by separating the target tooth 140 from the inner surface of the ambush space 120 at a predetermined interval, the body 100 and the tooth to be removed 140 are directly coupled to each other so that the extraction of the tooth to be removed 140 during practice is It prevents it from being done properly and allows it to function similar to doing clinical practice for real patients.

The ambush space 120 and the tooth to be removed 140 may be configured in plural according to a required practice condition.

The support part 150 is a member that fixes the teeth 140 to be removed to the body 100, but is not limited thereto, but may be in the form of a column having a circle, a triangle, a square, a pentagon, etc., and may be formed in plural. I can. It is preferable that the support part 150 is formed by minimizing the cross-sectional area within a required range. If the cross-sectional area of the support part 150 is large, the tooth 140 to be removed from the oral model 10 is strongly coupled to the body, so that the practical effect may be degraded, such as not being able to properly extract teeth during practice.

The support part 150 may be integrally manufactured with the body 100 and the tooth 140 to be removed using a single material, but may be separately manufactured and combined.

The body 100, the tooth 130, the tooth to be removed 140, and the support part 150 of the oral cavity model 10 according to the present technology are, but are not limited to, a soft synthetic resin, plastic, resin, having elasticity, It may be produced by using a single material or a mixture of materials such as rubber and silicone.

The oral model 10 according to the present technology may further include a communication path 160 for discharging the fluid in the ambush space 120 to the outside of the body. When manufacturing the oral cavity model 10 using a material such as synthetic resin, resin, silicon, etc., the material or impurities remaining in the empty space between the ambush space 120 and the tooth to be removed 140 can be cleaned with a cleaning solution. It is to do.

On the other hand, the manufacturing method of the oral cavity model 10 according to the present technology includes the steps of (S1) forming an ambush space 120 surrounding the tooth to be removed 140 and the tooth to be removed 140 at a predetermined distance; (S2) arranging the teeth 140 to be removed surrounded by the ambush space 120 on the main body 100 having the shape of the upper or lower jaw of the oral cavity; (S3) arranging a support part 150 connecting the tooth to be removed 140 and the inner surface of the ambush space 120; (S4) generating data of a three-dimensional oral cavity model; And (S5) manufacturing the oral cavity model 10 through mechanical processing using the generated 3D oral cavity model data.

In the step (S1), the target tooth 140 to be removed, which is a subject of practice, is formed, and the ambush space is removed in the form of a film structure or capsule at a location spaced apart from the surface of the target tooth 140 to be removed by a predetermined distance. This is a step of forming so as to surround the target tooth 140. The tooth to be removed 140 may directly design a shape of a tooth, use a shape of an impingement or excess tooth obtained from oral information of a patient to be actually treated, or may use a previously designed shape.

The separation distance may be preferably 0.01 to 2.0 mm, more preferably 0.05 to 1.5 mm, even more preferably 0.1 to 1.0 mm. In this way, by separating the target tooth 140 from the inner surface of the ambush space 120 at a predetermined interval, the body 100 and the tooth to be removed 140 are directly coupled to each other so that the extraction of the tooth to be removed 140 during practice is It prevents it from being done properly and allows it to function similar to doing clinical practice for real patients.

The step (S2) is a step of arranging the teeth 140 to be removed surrounded by the ambush space 120 on the main body 100. The main body 100 is a shape of the upper or lower jaw of the oral cavity of the human body, and may be in a shape including a tooth 130 and an alveolar bone 110, and, like the tooth to be removed 140, directly designed or The shape of the maxillary or mandible obtained from the oral information of the patient to be treated may be used, or a previously designed shape may be used.

The step (S3) is a step of disposing a support part 150 connecting the tooth to be removed 140 and the inner surface of the ambush space 120. The support part 150 serves to fix the teeth 140 to be removed to the main body 100, and is not limited thereto, but may be in the form of a column having a circular, triangular, square, pentagonal cross section, and arranged in a plurality of Can be. It is preferable that the support part 150 is formed by minimizing the cross-sectional area within a required range. When the cross-sectional area of the support part 150 is large, the tooth 140 to be removed from the manufactured oral model 10 is strongly coupled to the body, so that the practical effect may be degraded, such as not being able to properly extract teeth during practice.

By arranging the teeth 140 to be removed surrounded by the ambush space 120 in the main body 100 using the support unit 150, it is possible to design an oral model with an ambush tooth or an excess tooth similar to the actual one.

The step (S3) may further include arranging a communication path for discharging the fluid in the ambush space 120 to the outside of the body. When manufacturing the oral cavity model 10 using a material such as synthetic resin, resin, silicon, etc., the material or impurities remaining in the empty space between the ambush space 120 and the tooth to be removed 140 can be cleaned with a cleaning solution. It is to do.

The step (S4) is a step of generating 3D data of the oral model 10 designed through the steps (S1) to (S3). The steps (S1) to (S4) may be performed using a computer-aided design (CAD) program, and shape information of the oral model 10 may be designed and manufactured as digital data.

The step (S5) is a step of manufacturing the oral cavity model 10 through mechanical processing using the generated 3D oral cavity model 10 data. The body 100, the tooth 130, the tooth to be removed 140, and the support part 150 of the oral model 10 are, but are not limited to, a soft synthetic resin, plastic, resin, rubber, silicone, etc. having elasticity. It may be produced by using single or mixed materials.

Meanwhile, the mechanical processing is not limited thereto, but may be performed using a 3D printer. In the case of using a 3D printer, the oral cavity model 10 is formed by a 3D printer using the generated 3D oral cavity model data. The 3D printer molds the oral cavity model 10 by laminating the above denture base materials one by one, based on the input data of the oral cavity model 10. The 3D printer may employ any of a stereolithography method, a powder sinter lamination method, a heat melting lamination method, and an inkjet method.

In the case of forming the oral cavity model 10 using a 3D printer, the body 100, the alveolar bone part 110, the ambush space 120, the tooth 130, the tooth to be removed 140, and the support part 150 are included. Thus, the entire oral model 10 can be molded only with a 3D printer.

As a result, the process of shaping or correcting the impact space 120, the tooth to be removed 140, etc. by hand or the like can be eliminated, or can be minimized.

In particular, the oral model 10 of the present technology has a separate internal space 120 when placing the tooth 140 to be removed in the body 100 so that the tooth to be removed 140 is spaced apart from the body 100, By designing that only a part is connected to the support part 150, in the case of using a 3D printer, even if it is molded using only a single material, in this way, since the main body 100 and the tooth to be removed 140 are formed in a separate structure, Mouth models with impact or excess teeth can be made suitable for practice.

The technical task of the present technology is achieved by the technical configuration as described above, and although it has been described by the limited embodiments and drawings, the present technology is not limited thereto, and the present technology is by a person having ordinary knowledge in the technical field to which the present technology belongs. It goes without saying that various modifications and variations are possible within the scope of the technical idea and the scope of the claims to be described below.

10-oral model 100-main body
110-alveolar bone 120-ambush space
130-tooth 140-tooth to be removed
150-support 160-communication path

Claims (9)

The body of the maxillary or mandibular shape of the oral cavity is formed with an ambush space;
A tooth to be removed located inside the ambush space and disposed at a predetermined distance from the inner surface of the ambush space; And
A support part for supporting the tooth to be removed in the ambush space of the main body;
Containing, oral model. The method of claim 1,
The constant separation distance is characterized in that 0.1 to 2.0 mm, oral model. The method of claim 1,
The oral model, characterized in that the ambush space and the teeth to be removed are plural. The method of claim 1,
It characterized in that it further comprises a communication path for discharging the fluid in the ambush space to the outside of the body, oral model. (S1) forming an ambush space surrounding the tooth to be removed and the tooth to be removed at a predetermined distance from the tooth to be removed;
(S2) arranging the teeth to be removed surrounded by the ambush space in the upper or lower body of the oral cavity;
(S3) arranging a support for connecting the tooth to be removed and the inner surface of the ambush space;
(S4) generating data of a three-dimensional oral cavity model; And
(S5) manufacturing an oral model through mechanical processing using the generated three-dimensional oral model data; method of manufacturing an oral cavity model comprising. The method of claim 5,
The separation distance is characterized in that 0.1 to 2.0 mm, the method of manufacturing an oral model. The method of claim 5,
The step (S3) further comprises arranging a communication path for discharging the fluid in the ambush space to the outside of the main body. The method of claim 5,
The steps (S1) to (S4) are characterized in that using a CAD program, the method of manufacturing an oral model. The method of claim 5,
The mechanical processing of the step (S5) is a method of manufacturing an oral model, characterized in that using a 3D printer.

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