KR20220045909A - A system that can analyze the arch shape and occlusion pattern based on big data cloud that classifies the arch shape and occlusion pattern of the maxillary and mandibular dentition, and the maxillary and mandibular dentition can be merged into the anatomical position - Google Patents

Abstract

The present invention relates to a system that can analyze an arch shape and occlusion pattern based on a big data cloud that classifies the arch shape and occlusion pattern of upper and lower dentition, and can merge the upper and lower dentition in an anatomically ideal position. The system includes: a reference unit; an analysis unit; a tooth model unit; a control unit; and a cloud server unit. The present invention has an effect of enabling good mastication and pronunciation.

Description

A system that can analyze the arch shape and occlusion pattern based on a big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition, and can merge the maxillary and mandibular dentition in an ideal anatomical position. {A SYSTEM THAT CAN ANALYZE THE ARCH SHAPE AND OCCLUSION PATTERN BASED ON BIG DATA CLOUD THAT CLASSIFIES THE ARCH SHAPE AND OCCLUSION PATTERN OF THE MAXILLARY AND MANDIBULAR DENTITION, AND THE MAXILLARY AND MANDIBULAR DENTISITION CAN BE MERGED INTO THE ANATOM

The present invention relates to a system that can analyze the arch shape and occlusion pattern based on a big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition, and can merge the maxillary and mandibular dentition into an ideal anatomical position. , and more specifically, it is possible to quickly and accurately analyze the shape of the jaw and the occlusal aspect in the process of modularization with the baseline that allows the digital three-dimensional tooth model to be placed in the ideal anatomical position for the design of digital dental prosthetics. It is possible to analyze the arch shape and occlusal pattern based on a big data cloud that classifies the arch shape and occlusal pattern of the upper and lower jaws that form a digital three-dimensional dental model to be interlocked with each other to improve mastication and pronunciation. It relates to a system in which upper and lower teeth can be merged in an ideal position.

In general, for humans, teeth are deeply related to extremely important functions such as feeding, vocalization, and expression in the oral cavity, and therefore, tooth loss becomes a fatal problem that harms them.

Reconstructing the structure of the oral cavity that has lost teeth in this way is called dental prosthesis.

At this time, as a method of manufacturing artificial teeth, a method of using an oral scanner, which is a type of 3D scanner, has been widely used in recent years.

The three-dimensional tooth model is produced through a three-dimensional printer and a three-dimensional processing machine through a process of scanning teeth and gums with an oral scanner, a type of 3D scanner.

That is, the patient's teeth and gums are created using an oral scanner or a dental model scanner to create virtual 3D dental model data, and the three-dimensional data is output to an artificial tooth design program and artificial teeth are designed based on this. The artificial teeth designed in the artificial tooth design program are processed with a three-dimensional processing machine to reproduce the shape of the artificial teeth. The artificial teeth manufactured in this way must be adjusted to fit the tooth model and adjusted to fit well with the opposing teeth to function in the oral cavity. A three-dimensional artificial tooth design CAD program is required for this process, and this process is called digital prosthetic design.

The three-dimensional dental prosthesis designed in this way is designed to be placed in a unique anatomical position in the human body.

Therefore, the process of digitizing teeth and gums using the digital tooth design CAD program is a very important process, and it is necessary to accurately reproduce the position and shape of the tissues and teeth in the oral cavity required for the production of artificial teeth.

However, the conventional digital dental design CAD program has an inconvenient problem of adjusting the positions of each of the upper and lower 28 upper and lower jaws one by one without being placed in the ideal anatomical position.

In addition, if the upper and lower teeth are misaligned in the process of moving 28 teeth one by one, an ideal occlusion cannot be formed. There are also problems that may arise.

In addition, when manufacturing artificial teeth by referring to the shape of the face or the maxilla and the mandible that are photographed with a dental city or X-ray and output as an image, the above-mentioned

The same problem may occur.

Therefore, in the prior art, in the process of designing artificial teeth using a CAD program, there is no reference point that can position the teeth at an ideal anatomical position, so it is difficult to align them to an accurate position, and it takes a long time because the teeth are arranged one by one. there is.

As related prior art, Registered Patent Publication No. 10-1805003 (Title of the invention: Dental CAD system, driving method and recording medium thereof, registration date: November 29, 2017) and Registered Patent Publication No. 10-0583183 (invention) Name of: Orthodontic data provision method, registration date: May 18, 2006) is there.

The present invention was created to solve the problems of the prior art as described above, and the shape and occlusion of the jaw arch in the process of being modularized with the reference line so that the digital three-dimensional tooth model required for the design of a digital dental prosthesis can be placed in an ideal anatomical position. Based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition, it forms a digital three-dimensional dental model to fit in an anatomically ideal position quickly and accurately because it is easy to analyze the aspect, so that you can write and pronounce it well. The purpose of this system is to analyze the shape of a single arch and the occlusal pattern, and to merge the upper and lower teeth at the ideal anatomical position.

Other objects of the present invention can be understood through the characteristics of the present invention, can be seen more clearly through the embodiments of the present invention, and can be realized by means and combinations indicated in the claims.

In order to achieve the problems to be solved by the present invention as described above, the present invention has the following technical features.

The system that can analyze the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and can merge the maxillary and mandibular dentition into an anatomically ideal position, a reference unit that receives data of a patient's dental model scanned from a dental model scanner that generates virtual 3D dental model data, and includes a line or surface in a shape capable of vertical and horizontal analysis; an analysis unit for analyzing a tooth model suitable for the data of the scanned tooth model received from the reference unit; The tooth model analyzed by the analysis unit consists of a maxillary tooth model (gum model) and a mandibular tooth model (gum model) designed in a digital tooth design program, and the maxillary tooth model and the mandibular tooth model are the reference unit and Tooth model unit composed of one modularization, respectively; a control unit connected to the reference unit, the analysis unit, and the tooth model unit, respectively, and control the reference unit, the analysis unit, and the tooth model unit automatically or manually by artificial intelligence, but at the same time modularize or selectively modularize and control; and a cloud server unit including the reference unit, the analysis unit, the tooth model unit, and the control unit, wherein data related to occlusion positivity, dental arch shape, and tooth model are provided and can be used through connection; is made including

In a system capable of analyzing the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and in which the maxillary and mandibular dentition can be merged into an ideal anatomical position, , The reference unit can be moved and positioned on the patient tooth model output as an image to a three-dimensional modeling program, and is located on the remaining teeth and landmarks included in the patient tooth model, and the obtained patient tooth model and the reference The negative three-dimensional coordinates move the patient tooth model through the control unit to the reference three-dimensional coordinate origin.

In a system capable of analyzing the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and in which the maxillary and mandibular dentition can be merged into an ideal anatomical position, , The line or plane that can analyze the horizontal and vertical of the reference part is made horizontal and vertical with the occlusal plane or anatomical reference plane of the skull or face output as an image.

In a system capable of analyzing the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and in which the maxillary and mandibular dentition can be merged into an ideal anatomical position, , The reference part is a reference body that crosses a vertical and horizontal line or surface to become a reference body, a linkage connected to the center of intersection of the reference body in a bar shape, a hemisphere shape, a question body, an upper question body, a submuneum Consisting of a sieve and connected to the other end corresponding to one end of the linkage connected to the reference body, the maxillary and mandibular gums of the toothless patient, or the remaining maxillary and mandibular teeth of the patient in which the teeth are partially bound, are bitten. and a scan protrusion formed to protrude in the direction of the reference plane or to protrude in plurality around the outer circumferential surface of the question body.

In a system capable of analyzing the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and in which the maxillary and mandibular dentition can be merged into an ideal anatomical position, , the analysis unit includes a plurality of arch shapes, lines, and planes, each contains text and logos that can indicate characteristics of the arch, the reference unit and the tooth model are mutually controlled through the control unit, and the The arch shape and occlusal aspect of the patient's tooth model are analyzed and output to the three-dimensional modeling area.

In a system capable of analyzing the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and in which the maxillary and mandibular dentition can be merged into an ideal anatomical position, , The analysis unit, a reference body that intersects with vertical and horizontal lines or planes as a reference body, a facial center body that is connected to the reference body and is disposed in the center of the face that is a landmark of a toothless patient or a patient with a partial tooth loss, the face The occlusal plane is disposed in the center of the arch, which is a landmark of a toothless patient or a patient with a partial tooth loss by intersecting with the centrosome, and is disposed in the lower part of the occlusal plane adjacent to the reference part from the condyle of the patient to the mandibular incisor. An angle body for measuring the distance, at least one or more condylar centroids intersecting with the occlusal plane and disposed in the condyle center of the patient, at least one or more condylar centroids adjacent to the condylar centrosome, connected to both sides of the occlusal plane, the patient It is composed of a gradient regulator that adjusts the inclination due to overwork.

In a system capable of analyzing the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and in which the maxillary and mandibular dentition can be merged into an ideal anatomical position, , The analysis unit is formed in the shape of a plurality of arches, and is classified into an occlusal aspect, an arch shape, and a tooth shape based on tooth anatomy and human anatomy, and is formed to include letters, lines, and surfaces that can indicate features and sizes, and the criteria The position is stored in the same three-dimensional coordinates as the negative three-dimensional coordinates, and a tooth model suitable for the patient's tooth model can be suggested, and artificial intelligence or manually analyzes and proposes a maxillary and mandibular tooth model suitable for the patient's tooth model.

In a system capable of analyzing the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and in which the maxillary and mandibular dentition can be merged into an ideal anatomical position, , The tooth model part is made of a tooth model or a model upper and lower jaw model including teeth and gums, and includes a line, plane or sphere, and a cylindrical solid shape having the same shape as the reference part, and indicates the characteristics of each arch. It contains text and logo that can be used, is mutually controlled through the reference unit and the control unit, and the arch shape and occlusal aspect of the patient's tooth model are analyzed and output as a three-dimensional modeling area.

In a system capable of analyzing the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and in which the maxillary and mandibular dentition can be merged into an ideal anatomical position, , the reference part, the analysis part, and the tooth model part are mutually controlled with the patient's tooth model, analyze the left and right distances of the maxillary and mandibular molars, the distance between the labial surface of the anterior part and the distal surface of the posterior part, the arch line shape of the anterior part, the anterior part to the posterior part The average angle to be implemented is analyzed through artificial intelligence included in the controller or manual mouse control, and the most similar arch is selected and outputted from among a plurality of arches included in the analysis unit.

In a system capable of analyzing the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and in which the maxillary and mandibular dentition can be merged into an ideal anatomical position, , the reference unit, the analysis unit, and the tooth model unit include components having the same shape as each other, so that the three-dimensional coordinates of each component can be controlled or analyzed through the control unit.

In a system capable of analyzing the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and in which the maxillary and mandibular dentition can be merged into an ideal anatomical position, , the reference unit, the analysis unit, and the tooth model unit are stored in the specified coordinate origin of the 3D digital tooth design program.

In a system capable of analyzing the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and in which the maxillary and mandibular dentition can be merged into an ideal anatomical position, , When the patient tooth model is output as an image to a modeling program, it is output including shape information and position information, and when the remaining teeth are included in the patient tooth model, the positions of the upper, lower, left, and right remaining teeth are included in the reference unit. It is output based on a position similar to the position of the model, and in the case of edentulous jaws, it is output on the image based on the occlusal plane included in the reference unit at the center of the distance between the maxillary and mandibular remaining alveolar ridges, and the landmark of the patient's tooth model and the The control unit controls the output as an image at the same location as the landmark included in the analysis unit.

The present invention can easily analyze the shape of the jaw and the occlusal aspect in the process of modularization with the baseline that allows the digital three-dimensional dental model necessary for designing a digital dental prosthesis to be placed in an ideal anatomical position through the means for solving the above problems. Therefore, it is effective to quickly and accurately form a digital three-dimensional tooth model to engage in an ideal anatomical position so that the masturbation and pronunciation can be improved.

In addition, the present invention can improve the accuracy of dental prostheses set in the oral cavity because the size and position of teeth can be analyzed quickly and accurately because the upper and lower 28 teeth can be easily viewed simultaneously with the face or skull image through the tooth analysis plate. There is an effect.

Other effects of the present invention can be understood through the characteristics of the present invention, can be seen more clearly through the embodiments of the present invention, and can be exhibited by means and combinations shown in the claims.

1 is a view of an embodiment of a digital three-dimensional dental model according to the prior art;
2 is a diagram in which the arch shape and occlusion pattern can be analyzed based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and the maxillary and mandibular dentition can be merged into an anatomically ideal position. the flow chart of the system,
3 is a view that can analyze the arch shape and occlusion pattern based on a big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to FIG. detailed drawings of the system;
Figure 4 is a view showing the separated state of the reference unit according to Figure 2;
5 is a view showing a state in which the reference unit according to FIG. 2 is mounted in an ideal anatomical position of a toothless patient;
Figure 6 is a view showing the analysis unit according to Figure 2;
7 is a view showing a state in which the analysis unit according to FIG. 2 is mounted in an ideal anatomical position of a toothless patient;
8 is a view showing a state in which the analysis unit and the patient tooth model according to FIG. 2 are controlled to fit an anatomically ideal position;
9 is a view showing a state in which the analysis unit and the patient tooth model according to FIG. 2 are aligned to an anatomically ideal position;
10 is a view showing a state in which the coordinates of the analysis unit and the patient tooth model bundle according to FIG. 2 coincide with each other;
11 and 12 are views showing a training set provided with a plurality of tooth models according to FIG. 2;
13 is a view showing a state in which the patient's remaining teeth according to FIG. 2 are controlled using a reference unit;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The detailed description of the invention that follows refers to the accompanying drawings, which show by way of illustration specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the present invention. It should be understood that various embodiments of the present invention are different but need not be mutually exclusive. For example, specific shapes, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the present invention in relation to one embodiment. In addition, it should be understood that the position or arrangement of individual components in each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the following detailed description is not intended to be taken in a limiting sense, and the scope of the present invention is limited only by the appended claims, along with all scopes equivalent to those claimed. In the drawings, like reference numerals refer to the same or similar functions throughout the various aspects.

2 is a diagram in which the arch shape and occlusion pattern can be analyzed based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and the maxillary and mandibular dentition can be merged into an anatomically ideal position. It is a flowchart of the system, and FIG. 3 is a big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to FIG. This is a detailed view of a system that can be combined, FIG. 4 is a view showing a separated state of the reference unit according to FIG. 2, and FIG. 5 is a state in which the reference unit according to FIG. 2 is mounted at an ideal anatomical position of the toothless patient. 6 is a view showing the analysis unit according to FIG. 2, FIG. 7 is a view showing a state in which the analysis unit according to FIG. 2 is mounted in an ideal anatomical position of a toothless patient, and FIG. 8 is a view showing the analysis unit according to FIG. It is a view showing a state in which the analysis unit and the patient tooth model are controlled to fit an anatomically ideal position, FIG. 9 is a view showing a state in which the analysis unit and the patient tooth model according to FIG. is a view showing a state in which the coordinates of the analysis unit and the patient dental model bundle according to FIG. 2 coincide with each other, FIGS. 11 and 12 are views showing a training set provided for a plurality of dental models according to FIG. 2 , and FIG. 13 FIG. 2 is a diagram illustrating a state in which the patient's remaining teeth according to FIG. 2 are controlled using a reference unit.

The system 100 that can analyze the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition according to the present invention, and can merge the maxillary and mandibular dentition into an anatomically ideal position (100). ), as shown in FIGS. 2 to 13 , includes a reference unit 110 , an analysis unit 120 , a tooth model unit 130 , a control unit 140 , and a cloud server unit 150 .

The reference unit 110 receives data of a patient's dental model scanned by a dental model scanner that generates virtual 3D dental model data, and is made of a line or surface in a form capable of vertical and horizontal analysis.

More specifically, the reference unit 110 includes a line or surface of a shape capable of vertical and horizontal analysis, includes a portion capable of diagnosing the shape and size of the arch of the patient's tooth model, and a digital tooth design program The upper and lower jaw tooth model bundles designed in . are combined and the three-dimensional coordinates of the patient's tooth model, the upper and lower teeth model, and the multiple jaw arch analysis unit can be controlled and directed in the three-dimensional space of the three-dimensional modeling program.

The reference unit 110 may be moved and located on the patient tooth model output as an image to the three-dimensional modeling program, and is located on the remaining teeth and landmarks included in the patient tooth model, and the acquired patient tooth model and the reference unit ( The three-dimensional coordinates of 110) move the patient tooth model through the control unit 140 to the three-dimensional coordinate origin of the reference unit.

When the patient tooth model is output as an image to the modeling program, it is output including shape information and location information. When the patient tooth model includes the remaining teeth, the position of the upper, lower, left, and right remaining teeth is included in the reference unit 110. Tooth model It is output based on a position similar to the position of The control unit 140 controls the output as an image at the same location as the landmark included in the analysis unit 120 to be described.

A line or plane capable of analyzing the horizontal and vertical of the reference unit 110 is formed horizontally and vertically with the occlusal plane or anatomical reference plane of the skull or face output as an image.

The reference unit 110 acquires data acquired with a facial scanner, three-dimensional data acquired with a dental city (CT), and digital three-dimensional data acquired by scanning teeth of a plaster model, respectively.

The reference unit 110 automatically (artificial intelligence, AI) or manually coordinates the patient's three-dimensional (3D) tooth model in the three-dimensional area.

The reference unit 110 includes a reference body 111 , a link body 112 , a question body 113 , and a scan protrusion 114 .

The reference body 111 becomes a reference by crossing vertical and horizontal lines or planes.

Specifically, the reference body 111 is formed in a vertical and horizontal, that is, a criss-cross shape, and is provided in a state of maintaining a constant distance from the questioning body 113 to be bitten by a toothless patient.

The reference body 111 is an anatomically ideal position so that the reference unit 110 including the linkage body 112, the question body 113, and the scan protrusion 114 can be quickly and accurately positioned even if it moves to another location. always the standard.

Conventionally, there is a disadvantage in that it takes a lot of time and inconvenient work when placed in an ideal anatomical position without a separate standard to acquire the tooth height or tooth distance of a toothless patient or a patient with a partial tooth loss.

The reference unit 110 is merged through the reference body 111 of the reference unit 110 and the reference body 111 of the analysis unit 120 so as not to deviate from each other when merging with the analysis unit 120 to be described below.

In the present invention, the reference body 111 is formed in a crisscross shape and is exemplified as a reference so that the reference body 110 including the reference body 111 can be quickly and accurately positioned, but the reference body 111 is used as a reference body. If the included reference unit 110 becomes a reference that can be quickly and accurately positioned, it can be transformed into other shapes.

The linkage body 112 is connected to the cross center of the reference body 111 in a bar shape.

Specifically, the linkage body 112 is formed in a rectangular bar shape, so that one end is linked to the center of intersection of the reference body 111 , that is, the center of the cross.

The linkage body 112 is formed in a rectangular bar shape, and as long as it can maintain the distance between the reference body 111 and the question body 113, it may be deformed into other shapes such as a cylindrical shape.

The linkage body 112 maintains the distance between the reference body 111 and the question body 113, and the length can be adjusted in multiple steps to suit a toothless patient or a patient with a partial tooth loss, such as the reference body 111. It may be possible to adjust the distance between the and the question body 113 .

The question body 113 has a hemispherical shape, and is composed of a question body 113a, an upper question body 113b, and a lower question body 113c, and at one end of the linkage body 112 connected to the reference body 111 . It is connected to the corresponding other end to bite the maxillary and mandibular gums of the toothless patient, or the remaining maxillary and mandibular teeth of the patient whose teeth are partially bonded.

The question body 113 is formed in a hemispherical shape. Among the hemispherical shapes, the round part is positioned on the lip of a toothless patient or a patient with a partially missing tooth, and the straight part is positioned in the patient's mouth.

Grooves are formed on the upper and lower surfaces of the questioning body 113 , respectively, so that when the patient bites the questioning body 113 , a filling material such as silicone, which is harmless to the human body, is introduced into the groove.

The question body 113a is a part to which the other end corresponding to one end of the linkage body 112 connected to the reference body 111 is connected, and the upper question body 113b is located on the upper part of the question body 113a based on the question body 113a. , the lower question body 113c is coupled to the lower portion, respectively.

The upper jaw body 113b and the lower jaw body 113c are used to provide an appropriate shape because the shape, size, and tooth shape of the jaw are different for each edentulous patient or a patient with partially bonded teeth.

The scan protrusion 114 is formed to protrude in plurality around the outer circumferential surface of the question body 113 or to protrude in the direction of the reference body 111 .

In detail, the scan protrusions 114 are formed to protrude in plurality around the outer peripheral surface of the hemispherical question body 113 , that is, the round portion, or protrude in plurality in the direction of the reference body 111 .

Among the scan protrusions 114, one end of the scan protrusions protruding in the direction of the reference body 111 is exposed out of the patient's mouth and scanned accurately.

The scan protrusion 114 is formed in a cylindrical shape or a quadrangular prism shape, and a plurality of hemispherical protrusions are formed around an outer peripheral surface of the cylindrical or quadrangular prism shape.

Conventionally, when scanning using a scanner, that is, an oral scanner, it was made of a flat surface and could not be accurately scanned.

Accordingly, in the present invention, a hemispherical protrusion is formed around the outer circumferential surface of the scan protrusion 114 so that a scan can be performed accurately.

In the present invention, the scan protrusions 114 are exemplified as being arranged in different shapes, such as a cylindrical shape, a quadrangular prism shape, and the like, but in some cases, they may be arranged only in a cylindrical shape or only in a quadrangular prism shape, that is, only in the same shape.

The vertical protrusion 115 is included in the reference unit 110, and is formed vertically in front of the upper surface of the questioning body 113 to which the maxillary gums of a toothless patient or the remaining maxillary teeth of a patient with a partial loss of teeth are bitten. It should fit the center line of the patient's face.

The vertical protrusion 115 is formed in a cylindrical shape on the upper surface of the question body 113 and comes into contact with the portion where the maxillary gum first comes into contact.

The vertical protrusion 115 is formed on the upper surface of the questioning body 113 to fit the center line of the patient's face, and may be formed on the lower surface of the questioning body 113 in some cases.

When a toothless patient or a patient with a partial loss of teeth bites the reference unit 110, silicone and harmless to the human body are placed in the empty space between the remaining teeth of the toothless patient or the patient with a partial tooth loss and the reference portion 110. The same filler is filled.

The analysis unit 120 analyzes a tooth model suitable for the data of the scanned tooth model transmitted from the reference unit 110 .

The analysis unit 120 includes a plurality of arch shapes, lines, and surfaces, and includes text and logos that can indicate the characteristics of each arch, and the reference unit 110 and the tooth model unit 130 include the control unit ( 140), and the arch shape and occlusal aspect of the patient's tooth model are analyzed and output to the three-dimensional modeling area.

The analysis unit 120 includes a reference body 121 , a facial central body 122 , an occlusal plane 123 , an angle body 124 , a condyle central body 125 , and an inclination control body 126 .

The reference body 121 is a reference by crossing vertical and horizontal lines or planes.

Specifically, the reference body 121 is vertically and horizontally, that is, formed in a crisscross shape, so that the facial central body 122, the occlusal plane 123, the angle body 124, and the condylar central body 125 are located in an ideal anatomical position. , even if the analysis unit 120 including the inclination control body 126 moves to another position, it is always a reference so that it can be placed in a fast and accurate position.

In the present invention, the reference body 121 is formed in a crisscross shape and is exemplified as a reference so that the analysis unit 120 including the reference body 121 can be placed in a fast and accurate position. If the included analysis unit 120 is a standard that can be quickly and accurately placed, it can be transformed into other forms.

The reference body 121 has a shape that can analyze the landmarks in the patient's oral cavity, and can analyze the occlusal plane, the vertical center line of the face, and the horizontal line connecting the pupil of the eye outside the oral cavity of the human body's facial skin or skull and mandible. include

The facial central body 122 is connected to the reference body 121 and is disposed in the facial center, which is a landmark of a toothless patient or a patient with a partial tooth loss.

The facial central body 122 is formed in a 'C' and one end is disposed in the center of the face (mid line), which is a landmark of a toothless patient or a patient with a missing tooth.

The occlusal plane 123 intersects with the facial central body 122 and is disposed in the center of the arch, which is a landmark of a toothless patient or a patient with a missing tooth.

The occlusal plane body 123 is formed in a rectangular shape, and the facial central body 122 intersects at an orthogonal angle to the center.

The angle body 124 is disposed under the occlusal plane 123 adjacent to the reference unit 110 to measure the distance from the condyle of the patient to the mandibular incisors.

At least one condyle center body 125 is intersected with the occlusal plane 123 and is disposed at the condyle center of the patient.

The inclination control body 126 is connected to both sides of the occlusal plane 123 adjacent to the condylar center body 125 by at least one or more to adjust the overwork inclination of the patient.

The analysis unit 120 is formed in a plurality of arch shapes, and is classified into an occlusal aspect, an arch shape, and a tooth shape based on tooth anatomy and human anatomy, and includes characters, lines, and surfaces that can indicate features and sizes, The location is stored in the same three-dimensional coordinates as the three-dimensional coordinates of the reference part, and a tooth model suitable for the patient's tooth model can be suggested, and artificial intelligence or manually analyzes and proposes a maxillary and mandibular tooth model suitable for the patient's tooth model.

The tooth model unit 130 is a tooth model analyzed by the analysis unit 120 and consists of a maxillary tooth model (gum model) and a mandibular tooth model (gum model) designed in a digital tooth design program, and a maxillary tooth model and a mandibular tooth The model is composed of the reference unit 110 and each one modularized.

The tooth model unit 130 is manufactured as a tooth model or a model upper and lower jaw model including teeth and gums, and includes a line, surface or sphere, and a cylindrical solid shape of the same shape as the reference unit 110, and each of the It contains text and logos that can indicate features, is mutually controlled through the reference unit 110 and the control unit 140, and analyzes the arch shape and occlusal aspect of the patient's tooth model and outputs it as a three-dimensional modeling area.

In the tooth model unit 130, the reference unit 110 and the analysis unit 120 are mutually controlled with the patient tooth model together with the tooth model unit 130. Analyze, analyze the arch line shape of the anterior region, and the average angle transitioning from the anterior region to the posterior region through artificial intelligence included in the control unit 140 or manual mouse control, and the most Select a similar arch and print it.

The tooth model unit 130 is a training set provided with a plurality of tooth models, and may consist of upper and lower dentition together, or may be composed of maxillary and mandibular dentition.

The reference unit 110 and the analysis unit 120 together with the tooth model unit 130 control the three-dimensional coordinates of each component through the control unit 140, which will be described below, since they include components of the same shape as each other. can be analyzed.

In the tooth model unit 130, the reference unit 110 and the analysis unit 120 together with the tooth model unit 130 are stored at the specified coordinate origin of the 3D digital tooth design program.

The control unit 140 is connected to the reference unit 110, the analysis unit 120, and the tooth model unit 130, respectively, and the reference unit 110, the analysis unit 120, and the tooth model unit 130 are artificially intelligent ( It is controlled by 人工知能, AI (Artificial Intelligence), but at the same time modularized or selectively modularized to control.

The control unit 140 temporarily controls the modularization to adjust the movement due to an unexpected event in the process of moving the reference unit 110 , the analysis unit 120 , and the tooth model unit 130 to an anatomically ideal position.

The cloud server unit 150 includes a reference unit 110 , an analysis unit 120 , a tooth model unit 130 , and a control unit 140 , and is provided with big data related to occlusion positivity, dental arch shape, and tooth model and is connected. It can be used through

Specifically, the cloud server unit 150 is equipped with big data related to occlusion training, dental arch shape, and tooth model, etc., and various occlusal orientations, dental arch shape, tooth model, etc. are provided through online access based on the Internet. Big data can be used in the right place.

In the above, the present invention has been described based on a preferred embodiment, but the technical spirit of the present invention is not limited thereto, and it is possible to carry out modifications or changes within the scope described in the claims. It will be apparent to the person concerned, and such modifications or changes shall fall within the scope of the appended claims.

100: A system that can analyze the arch shape and occlusion pattern based on a big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition, and can merge the maxillary and mandibular dentition into an anatomically ideal position
110: reference part
111: reference body
112: linkage
113: question body
114: scan projection
115: vertical projection
120: analysis unit
121: reference body
122: facial central body
113: occlusal plane
114: angle font
115: condyle centrosome
116: inclination control body
130: tooth model part
140: control unit
150: cloud server unit

Claims (12)

a reference unit that receives data of a patient's dental model scanned from a dental model scanner that generates virtual 3D dental model data, and includes a line or surface in a form capable of vertical and horizontal analysis;
an analysis unit for analyzing a tooth model suitable for the data of the scanned tooth model received from the reference unit;
The tooth model analyzed by the analysis unit consists of a maxillary tooth model (gum model) and a mandibular tooth model (gum model) designed in a digital tooth design program, and the maxillary tooth model and the mandibular tooth model are the reference unit and Tooth model unit composed of one modularization, respectively;
a control unit connected to the reference unit, the analysis unit, and the tooth model unit, respectively, and control the reference unit, the analysis unit, and the tooth model unit automatically or manually by artificial intelligence, but at the same time modularize or selectively modularize and control; and
a cloud server unit including the reference unit, the analysis unit, the tooth model unit, and the control unit, and having data related to occlusion positivity, dental arch shape, and tooth model available through connection; It is possible to analyze the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition, characterized in that it includes system there. The method of claim 1,
The reference unit can be moved and located on the patient tooth model output as an image to a three-dimensional modeling program, and is located on the remaining teeth and landmarks included in the patient tooth model, and the obtained patient tooth model and the reference unit The three-dimensional coordinates are based on the big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition, characterized in that the patient tooth model is moved through the control unit to the three-dimensional coordinate origin of the reference unit. A system in which the maxillary and mandibular dentition can be merged in an anatomically ideal position. The method of claim 1,
Classify the arch shape and occlusal aspect of the maxillary and mandibular dentition, characterized in that the line or plane that can analyze the horizontal and vertical of the reference part is horizontal and vertical to the occlusal plane or anatomical reference plane of the skull or face output as an image A system that can analyze the shape of the arch and occlusion based on a big data cloud, and can merge the upper and lower teeth in an ideal anatomical position. According to claim 1,
The reference part is
A reference body that intersects vertical and horizontal lines or planes as a reference;
Linkage connected to the center of intersection of the reference body in a bar shape,
It has a hemispherical shape, and is composed of a question body, an upper question body, and a lower question body, and is connected to the other end corresponding to one end of the linkage connected to the reference body, so that the maxillary gum, mandibular gum or teeth of the toothless patient are part The remaining maxillary and mandibular teeth of the bound patient,
A maxillary arch shape based on a big data cloud classifying the arch shape and occlusal aspect of the maxillary and mandibular dentition, characterized in that it consists of a plurality of protrusions around the outer circumferential surface of the question body or scan protrusions protruding in the direction of the reference plane, A system that can analyze the occlusal pattern and merge the upper and lower teeth at the ideal anatomical position. The method of claim 1,
The analysis unit includes a plurality of arch shapes, lines, and planes, and includes texts and logos that can indicate characteristics of each arch, and the reference unit and the dental model unit are mutually controlled through the control unit, and the patient It is possible to analyze the arch shape and occlusion pattern based on a big data cloud that classifies the arch shape and occlusal pattern of the maxillary and mandibular dentition, characterized in that it is output as a three-dimensional modeling area by analyzing the arch shape and occlusal aspect of the tooth model. A system in which the upper and lower teeth can be merged in an anatomically ideal position. According to claim 1,
The analysis unit,
A reference body that intersects vertical and horizontal lines or planes as a reference;
A facial central body that is connected to the reference body and is disposed in the center of the face, which is a landmark of a toothless patient or a patient with a partial tooth loss,
The occlusal plane intersected with the facial central body and disposed at the center of the arch, which is a landmark of a toothless patient or a patient with a partial tooth loss,
An angle body disposed under the occlusal plane adjacent to the reference part to measure the distance from the condyle of the patient to the mandibular anterior teeth;
At least one condylar centrosome intersecting with the occlusal plane and disposed at the condyle center of the patient;
Big data cloud that classifies the arch shape and occlusal aspect of the maxillary and mandibular dentition, characterized in that at least one or more inclination adjusters are connected to both sides of the occlusal plane adjacent to the condylar centrosome to adjust the patient's overexertion inclination. A system that can analyze the arch shape and occlusal pattern based on According to claim 1,
The analysis unit is formed in a plurality of arch shapes, and is classified into an occlusal aspect, a jaw shape, and a tooth shape based on tooth anatomy and human anatomy, and is formed to include letters, lines, and surfaces that can indicate features and sizes, and the reference portion The upper and lower jaws are stored in the same three-dimensional coordinates as the three-dimensional coordinates, and a tooth model suitable for the patient's tooth model can be suggested, and artificial intelligence or manually analyzing and suggesting a maxillary and mandibular tooth model suitable for the patient's tooth model. A system that can analyze the arch shape and occlusal pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the dentition, and can merge the upper and lower dentition in an ideal anatomical position. The method of claim 1,
The tooth model part is made of a tooth model or a model upper and lower jaw model including teeth and gums, and includes a line, surface or sphere, and cylindrical solid shape having the same shape as the reference part, and can indicate the characteristics of each arch maxillary and mandibular dentition, characterized in that it contains text and a logo, which are mutually controlled through the reference unit and the control unit, and are output to a three-dimensional modeling area by analyzing the arch shape and occlusal aspect of the patient's tooth model A system that can analyze the shape of the arch and occlusion based on the big data cloud that classifies the shape and occlusal pattern, and can merge the upper and lower teeth in an ideal anatomical position. According to claim 1,
The reference part, the analysis part, and the tooth model part are mutually controlled with the patient's tooth model, and the left and right distances of the upper and lower molars, the distance between the labial surface of the anterior part and the distal surface of the posterior part are analyzed, and the arch line shape of the anterior part, transition from the anterior part to the posterior part The shape and occlusion of the maxillary and mandibular dentition, characterized in that the average angle is analyzed through artificial intelligence or manual mouse control included in the control unit, and the most similar arch among a plurality of arches included in the analysis unit is selected and output. A system that can analyze the shape of the arch and occlusion based on the big data cloud that classifies the aspects, and can merge the upper and lower jaws at the ideal anatomical position. The method of claim 1,
The reference unit, the analysis unit, and the tooth model unit include components having the same shape as each other, so that the three-dimensional coordinates of each component can be controlled or analyzed through the control unit. A system that can analyze the shape of the arch and occlusion pattern based on the big data cloud that classifies the occlusal pattern, and can merge the upper and lower jaws in an ideal anatomical position. According to claim 1,
The reference unit, the analysis unit, and the tooth model unit are stored in the specified coordinate origin of the three-dimensional (3D) digital tooth design program. A system that can analyze the shape of a single arch, occlusal pattern, and merge the upper and lower teeth in an ideal anatomical position. The method of claim 1,
When the patient tooth model is output as an image to the modeling program, it is output including shape information and position information, and when the patient teeth model includes the remaining teeth, the positions of the upper, lower, left, and right remaining teeth are included in the reference unit. It is output based on a position similar to the position of It is possible to analyze the arch shape and occlusion pattern based on the big data cloud that classifies the arch shape and occlusal aspect of the upper and lower teeth, characterized in that the controller controls the output as an image at the same location as the landmark included in the appendix. A system in which the upper and lower teeth can be merged in an anatomically ideal position.

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