KR102513046B1 - A orthodontic devices that are supported in close contact with the tooth surface - Google Patents

Abstract

The present invention relates to an orthodontic device which is closely attached and supported by teeth of a patient who will receive orthodontic care without a gap. Specifically, the present invention relates to an orthodontic device closely attached and supported by teeth surface, wherein the orthodontic device which covers the surface of teeth of a patient who will receive orthodontic care. The orthodontic device comprises: a labial surface (10), a buccal surface (20), a lingual surface (30), and an occlusal surface (40) corresponding to the teeth surface. An opening part (55) is formed in the occlusal surface (40) so that the volume of the buccal surface (20) is the same as the volume of the lingual surface (30) corresponding to the buccal surface (20), or a reduction in the thickness of the occlusal surface (40) interferes with contraction during coagulation. According to the present invention, the orthodontic device can be perfectly attached to the teeth surface of a patient who will receive orthodontic care by inhibiting the progression of coagulation and contraction.

Description

Orthodontic devices that are supported in close contact with the tooth surface {A orthodontic devices that are supported in close contact with the tooth surface}

The present invention relates to an orthodontic device that is tightly supported with a tooth surface by preventing shrinkage or reducing a shrinkage rate in the process of curing and solidifying a liquid material during 3D printing.

In general, teeth and oral and maxillofacial parts do not grow properly in place due to bad habits, genetics, or the environment, and facial protrusion occurs due to uneven dentition, malocclusion, and the like.

Such abnormal occlusion not only causes masticatory dysfunction, pronunciation disorder, and temporomandibular joint dysfunction, but also causes dental caries and periodontal disease.

In order to prevent disorders due to malocclusion, orthodontic treatment is a treatment that applies physical correction force to teeth or jawbones to change their position and improve them to normal occlusion.

By performing this orthodontic treatment, we achieve the goals of improving the position of individual teeth, improving the upper and lower relationship of the dental arch, improving maxillofacial abnormalities and functions, eliminating various disorders caused by malocclusion, preventing oral diseases, and improving the health of tissues around the oral cavity. can do.

As devices applied for such orthodontic treatment, a fixed appliance that is fixed in the oral cavity and can be attached and detached only by a dental specialist and a removable appliance that can be directly pulled out of the oral cavity by the person to be corrected. there is

In general, a fixed orthodontic device uses a bracket and a wire. After attaching the bracket to the surface of the tooth, inserting the wire into the slot of the bracket and pushing or pulling the wire gradually changes the position of the tooth. It treats crooked teeth or uneven teeth.

In addition, the removable orthodontic appliance is an orthodontic appliance in which an orthodontic wire is fixed to the base, and an orthodontic appliance that can be inserted or removed by the person subject to correction in the oral cavity, and includes an active appliance and a passive appliance ( It is classified as a passive appliance).

Since the various orthodontic devices described above are made of metal wires, the orthodontic subject has the inconvenience of having to attach brackets and wires that are not aesthetically pleasing during a long-term orthodontic treatment period.

In order to solve this problem, a transparent aligner providing correction power in the form of a mouthpiece that maintains the color and shape of teeth has been developed. Transparent aligners are a procedure that corrects the dentition by replacing the temperature variable orthodontic device with a transparent material that changes step by step from the state of teeth before correction to the state of teeth to be corrected.

Accordingly, a representative transparent orthodontic device is a conventional orthodontic device using a thermoplastic film under the name of Invisalign and a manufacturing method using the same, and the technology is disclosed in US Patent Nos. 5,975,893 and 6,217,325.

To manufacture orthodontic devices, Invisalign first manufactures a tooth model step by step, places a transparent thermoplastic film on the tooth model, applies predetermined heat, and then applies a vacuum pressure molding device called Omni Bag. Former) to make orthodontic devices

In this vacuum adsorption method, when heat is applied to the thermoplastic resin covering the entire tooth model and the inside of the molding device is maintained in a vacuum, the thermoplastic resin wraps the tooth model. Since relatively much heat is applied to the center of the film paper, Therefore, since the occlusal surface of the teeth becomes relatively thicker than the gum side, the overall orthodontic device cannot obtain a uniform thickness, making it difficult to adhere completely to the tooth surface, so that uniform and efficient force can be transmitted to all surfaces of the teeth. There is a disadvantage that it is difficult to fine-tune the teeth.

Due to the above reasons, since the tooth transparent orthodontic device using Invisalign has a space between the tooth surface and the inner surface of the orthodontic device, the orthodontic device is not well seated and desirable tooth movement is difficult. In addition, since Invisalign orthodontic devices have a hard property due to the hard material characteristics of transparent orthodontic devices, when the tooth movement distance is artificially increased during treatment with these devices, the force applied to the teeth at the initial stage of device installation is physiologically acceptable. If it exceeds the limit of 0.1 mm, it causes pain or sometimes causes resorption of the tooth root. Therefore, in order to achieve the purpose of treatment, it must be subdivided into many steps, which not only increases the cost of treatment but also causes the disadvantage of extending the treatment period. there is.

In order to solve the problem of manufacturing a tooth model for each orthodontic stage, which is the above problem, and the problem of the space between the manufactured orthodontic device and the teeth, a variable temperature shape memory polymer is used, and the target orthodontic tooth of the orthodontic subject Technologies for implementing on a computer and directly producing it with a 3D printer have been developed (Patent Publication No. 10-2022-0112393, photocurable composition for 3D printer and method for manufacturing the same; prior art 1).

The 3D printing technology exhibits a continuous and weak elasticity even at an oral body temperature of 36.5 ° C., which is lower than the glass transition temperature of 50 ° C. to 70 ° C., which is a glass transition temperature that exhibits a shape memory effect known as a material. A well-known thermoplastic shape-memory polymer that is photocurable that exhibits an effect is used, and in the known 3D printing method, one of the additive manufacturing methods using photocurability is mainly used.

However, since the 3D printing technology undergoes a process of curing and solidifying the axing material, shrinkage of the material occurs during the solidification process.

That is, the orthodontic device in the form of a mouthpiece is mainly composed of a lingual side in contact with the tongue in the oral cavity, a labial side in contact with the lips, and a buccal side corresponding to the cheek. A phenomenon in which the near part is separated from the tooth surface occurs.

The cause for this is that the horizontal direction of the orthodontic appliance is an integral structure in which the lingual and labial surfaces are connected, and the root portion corresponding to the lower part in the vertical direction of the orthodontic appliance is in an open state, so the orthodontic appliance is in an open state. Since the sides of the device are connected to each other in the process of contraction as a whole, the contraction in the lateral direction is the extent to which the device is contracted as a whole, but since the lower end of the orthodontic appliance is open in the vertical direction, which is the vertical direction, A phenomenon in which the lower end, which is the closest part, is separated from the tooth surface occurs, and it can be said that it appears remarkably compared to the horizontal direction.

Another cause is that premolars and molars in orthodontic devices have a relatively large area due to the occlusal surface compared to canines and incisors without an occlusal surface, and the shrinkage rate during solidification is greater in areas with a larger area, It occurs mainly on the buccal surfaces of premolars and molars.

Summarizing the above, a phenomenon in which the inner surface of the orthodontic appliance is separated from the tooth surface mainly occurs in the part corresponding to the root of the premolar and molar teeth, which are the buccal surfaces.

As a related technology, Patent Publication 2019-00056931 (May 27, 2019) relates to a denture base resin for 3D printing, and the main component of the resin substrate is a combination of dimethacrylate to increase the polymerization degree and increase the mechanical properties while increasing polymerization shrinkage. It has been developed in a small direction (prior art 2).

In addition, Patent Publication 2020-0054946 (2020. 5. 20.) UV light curing device for improving the curing performance of a three-dimensional laminate and Patent Publication 2021-0045951 (2021. 4. 27.) 3D printing dental output In the technique disclosed in the vacuum and air post-curing device, an attempt was made to improve the shrinkage rate by irradiating ultraviolet rays composed of different wavelengths using a plurality of LEDs on the outer surface of the three-dimensional laminate (Prior Art 3 and 4).

However, the prior art 1 does not disclose the contents of the shrinkage rate of the material in the manufacturing process of the mouthpiece-type orthodontic device, and the prior invention 2 is the development of the material, and the prior inventions 3 and 4 are light sources during the manufacturing process. Through the improvement of the irradiation method of the information on the shrinkage rate is disclosed.

Among these prior inventions, in particular, prior inventions 3 and 4 require additional equipment for additional measures such as attaching a separate irradiation device or adjusting the wavelength of a light source in the existing 3D printing equipment, so additional equipment costs and operation, etc. It can be seen that there are additional disadvantages to this.

Therefore, in the case of 3D printing of orthodontic devices using conventionally known photocurable temperature changeable polymers, a means to solve the problem of shrinkage of the material economically during the solidification and hardening process without any change or addition of equipment is sought. The need to become is urgently raised.

Publication No. 2022-0112393 (May 11, 2022), photocurable composition for 3D printer and method for producing the same Patent Publication 2019-00056931 (2019. 5. 27.) Denture base resin for 3D printing Publication of Patent Publication 2020-0054946 (May 20, 2020) UV light curing device for improving curing performance of 3-dimensional laminate Publication of Patent Publication 2021-0045951 (2021. 4. 27.) Vacuum and air post-curing device for 3D printed dental output

An object of the present invention is to suppress the progress of coagulation contraction to provide an orthodontic appliance in perfect contact with the tooth surface of a person to be orthodontic.

Another object of the present invention is to provide an orthodontic appliance in perfect contact with the tooth surface of a person to be orthodontic by controlling the coagulation shrinkage rate.

Another object of the present invention is to provide a method of manufacturing an orthodontic device that is in perfect contact with the tooth surface of a person to be orthodontic by suppressing the progress of coagulation shrinkage or controlling the coagulation shrinkage rate.

In order to achieve the technical problem of the present invention,

In the orthodontic device for covering the surface of the teeth of a person to be orthodontic, the orthodontic device has a labial side surface 10, a buccal side surface 20, a lingual side surface 30 and an occlusal surface 40 corresponding to the tooth surface, In the buccal side surface 20, there is an opening 51 of the buccal side surface that hinders shrinkage during hardening and solidification, or a corresponding lingual side surface 30' of the buccal side surface 20 has a lingual side surface that hinders the progress of shrinkage during hardening and solidification. An opening 52 is formed to provide an orthodontic device characterized in that it prevents shrinkage during solidification.

At this time, the buccal side surface 20 has openings 51 and 52 of the buccal side that hinder the progress of shrinkage during curing and solidification, and the corresponding lingual side surface 30' of the buccal side surface 20 has a design that prevents shrinkage during curing and solidification. Both side openings 51 and 52 are formed to provide an orthodontic device characterized in that it prevents contraction during solidification.

At this time, the openings 51 and 52 are formed in a form in which a part of the buccal side surface 20 or the corresponding lingual side surface 30' of the buccal side surface 20 is removed, such as a rectangle, a cross shape, a circle, an ellipse, etc. To provide an orthodontic device characterized in that to interfere with contraction during solidification.

In addition, in the orthodontic device covering the surface of the teeth of the person to be corrected, the orthodontic device has a labial side surface 10, a buccal side surface 20, a lingual side surface 30 and an occlusal surface 40 corresponding to the tooth surface An opening 55 is formed in the occlusal surface 40 so that its volume is smaller than that of the buccal side surface 20 and the lingual side surface 30' corresponding to the buccal side surface 20, respectively. It is to provide an orthodontic device, characterized in that for preventing contraction.

At this time, in the orthodontic device covering the surface of the teeth of the person to be corrected, the orthodontic device has a labial side surface 10, a lingual side surface 20, a lingual side surface 30 and an occlusal surface 40 corresponding to the tooth surface The occlusal surface 40 has a difference in thickness so that its volume is smaller than that of the buccal side surface 30 and the lingual side surface 30' corresponding to the buccal side surface 20, respectively, preventing shrinkage during solidification. To provide an orthodontic device characterized in that to do.

At this time, in the thickness, the occlusal surface 40 is thinner than the buccal side surface 30 and the corresponding lingual side surface 30 'of the buccal side surface 20, characterized in that to prevent contraction during solidification. corrector will be provided.

In addition, the surfaces 10, 20, 30, and 40 exhibit continuous and weak elasticity even at 36.5° C., which is lower than the oral body temperature of 50° C. to 70° C., which is the glass transition temperature of silicon or the most effective shape memory effect. It is formed of a thermoplastic shape memory polymer material that can exhibit a shape memory effect that is restored to the original shape stored in the memory, and is transparent, or a pigment or antibacterial material for color expression can be further added. To provide a dental orthodontic device.

The orthodontic device as described above includes the steps of scanning the teeth of the person to be orthodontic using a 3D scanner (S10); Obtaining the current oral condition of the person to be corrected as data through the data scanned in the step (S10) of scanning the tooth to be corrected (S20); A correction target setting step (S30) of setting a correction target based on the data acquired in the step (S20) of acquiring the current oral condition as data; Subdividing the steps from the current oral state to the orthodontic target according to the orthodontic target set in the orthodontic target setting step (S30) according to the standard of the amount of tooth movement (S40); Designing orthodontic devices based on each subdivided data according to each subdivision step set in the subdivision step (S40) (S50); And 3D printing the orthodontic device using the completed design of the orthodontic device designed in the step of designing the orthodontic device (S50) (S60); and solidifying the orthodontic device formed by 3D printing using a curing machine (S70).

At this time, in the step of designing the orthodontic device (S50), the type, size, and formation position of the openings 51, 52, and 55 are determined according to the orthodontic target set by the person to be corrected, and the occlusal surface 40 and the buccal side surface 20 ) and the thickness of the lingual side surface 30' corresponding to the buccal side surface 20, etc. are designed.

In addition, the material used in the 3D printing step (S60) exerts a continuous and weak elastic force even at 36.5 ° C, which is lower than the glass transition temperature of 50 ° C to 70 ° C, which is the most effective shape memory effect, and the body temperature in the oral cavity. It is a photocurable temperature variable-shape memory polymer that can exhibit a shape memory effect that is restored to its original shape, and in the known 3D printing method, one of the additive manufacturing methods using photocurability is mainly used. The purpose of the invention can be achieved better.

According to the present invention, by providing an orthodontic device that is supported in close contact with the tooth surface by reducing shrinkage during coagulation and a method for manufacturing the same, the orthodontic device is in perfect contact with the tooth surface without lifting the root portion of the orthodontic device. By this, not only can you feel psychological stability, but there is an effect that there is no need to frequently remove and manage from the teeth, such as the orthodontic device in which the lower end is lifted as in the prior art.

1 to 9 are perspective views for illustrating a structure according to an embodiment of the present invention.
10 and 11 are perspective views for illustrating a structure according to still another embodiment of the present invention.
12 to 15 are perspective views for illustrating a structure according to another embodiment of the present invention.
16 is an exemplary view of the upper jaw of the tooth model to which the present invention is applied.
17 is an exemplary view of a general orthodontic device.

The terms or words used in the specification and claims of the present invention should not be construed as being limited to ordinary or dictionary meanings, and the inventors may properly define the concept of terms in order to best describe their invention. It should be interpreted as a meaning and concept consistent with the technical spirit of the present invention based on the principle that it can be.

Therefore, the embodiments described in the specification of the present invention and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention, so they can be replaced at the time of filing of the present invention. It should be understood that there may be many equivalents and variations.

In general, since shrinkage occurs when a liquid material solidifies, it is common to mold larger than the desired shape or size in consideration of the shrinkage. A major feature is that orthodontic devices that are supported in perfect contact with the tooth surface have been invented by preventing the progress of contraction or selectively adjusting the volume of each surface.

Hereinafter, prior to description with reference to the drawings, matters that are not necessary to reveal the gist of the present invention, that is, known configurations that can be added obviously by those skilled in the art, are not shown or described in detail. reveal

First, referring to FIG. 16, the dentition gradually increases in number from number 1 to number 7 or 8 as it moves toward the rear with respect to the center of the front teeth, and the left and right sides are symmetrical with respect to the center. Since it has, for convenience, only one side will be described with reference numerals.

In addition, since the number 8 tooth is referred to as a conventional "wisdom tooth", it is clarified in advance that in the case where the number 8 mark is not described on the attached drawing, the tooth is shown as an example of an extracted state.

Here, the dentition is usually called the labial side in contact with the lips according to the part in contact with the surrounding body parts, especially the part in contact with the cheek part of the labial side is called the buccal side, and the part in contact with the tongue is called the lingual side, and the upper and lower teeth are in contact with each other. The part is called the occlusal surface, and among the teeth, only the premolars and molars have the occlusal surface.

Therefore, the orthodontic device of the present invention will use the name referring to each of the teeth as it is.

That is, as shown in FIG. 17, since the orthodontic appliance is formed according to the alignment of the teeth on one side of the labial side surface (A), the buccal side surface (B), the lingual side surface (C), and the occlusal surface (D), the entire row of teeth is Since it consists of a structure corresponding to the tooth arrangement on one side and a tooth arrangement structure on the other side corresponding to the tooth arrangement structure on the one side, and the upper jaw and the lower jaw also consist of the same tooth arrangement structure, in the present invention, the structure on one side of the upper or lower jaw to be explained as a basis.

Hereinafter, the orthodontic device of the present invention will be described in detail with reference to the accompanying drawings.

1 to 11 for illustrating the structure of the present invention, the orthodontic device of the present invention is formed in the form of a mouthpiece that can be put on the teeth of a person to be corrected, and on one side of the orthodontic device Openings 51 and 52 are formed to prevent shrinkage during solidification.

At this time, the openings 51 and 52 may be located in various places of the orthodontic device, and may be formed in various positions such as the buccal side (B) and the lingual side (C) of the orthodontic device.

Here, the openings 51 and 52 are installed in the direction in which contraction proceeds so that when the orthodontic appliance is hardened and solidified after 3D printing, the orthodontic appliance can perform a buffering role to prevent contraction of the orthodontic appliance.

More specifically, in the step of hardening and solidifying the orthodontic device after the 3D printing of the openings 51 and 52 as described above, solidification and shrinkage occurs as occurs in all materials, but shrinkage in the horizontal direction Since the labial side surface 10 and the lingual side surface 30 are connected to each other in the form of a row of teeth, the entire orthodontic appliance tends to shrink in the horizontal direction, but in the vertical direction, the lower end of the orthodontic appliance is open Therefore, the lower part, which is the part closest to the tooth root, is separated from the tooth surface due to contraction, which is remarkably compared to the horizontal direction.

In addition, the openings 51 and 52 may be selectively applied in various shapes.

Therefore, in order to reduce the shrinkage of the orthodontic appliance in the vertical direction to some extent, the buccal side surfaces 20 contacting the tooth side surfaces 20 and the lingual side surfaces 30 'corresponding to the buccal side surfaces are formed by opening the openings 51 and 52 in the direction in which the contraction occurs. ), since the direction of the force to be contracted in the vertical direction is dispersed and alleviated by the openings 51 and 52, consequently, the lower end of the orthodontic device is spaced apart from the surface near the root of the tooth, which is the lower end of the teeth. phenomenon is prevented.

The openings 51 and 52 of the orthodontic device of the present invention are formed on the buccal side surface 20 of the orthodontic device or the lingual side surface 30 'corresponding to the buccal side surface 20 and It can be formed in various shapes on both the side surface 20 and the lingual side surface 30 '.

Here, whether the openings 51 and 52 are formed on the buccal side surface 20 of the orthodontic appliance, or whether they are formed on the lingual side surface 30' corresponding to the buccal side surface 20, or all of the above surfaces 20 , 30 ') is determined according to the shape or condition of the teeth corresponding to the orthodontic device in which the openings 51 and 52 of the person to be orthodontic are formed and the doctor's opinion.

In addition, the openings 51 and 52 may be formed in a form in which the buccal side surface 20 or a portion of the lingual side surface 30 'corresponding to the buccal side surface 20 is removed, such as a rectangle, a cross shape, a circle, an ellipse, or the like. .

Here, in the case of the direct shooting type, it is effective when contraction in the vertical direction is large, but in the case of a person with a larger mouth than normal, the size of the teeth is also larger, so shrinkage in the horizontal direction must be considered. It should be.

That is, in the case of considering even the shrinkage in the horizontal direction, in the case of forming the vertically long rectangular, that is, cross-shaped openings 51 and 52 together with the rectangular openings 51 and 52 formed horizontally as described above, the vertical direction and Together, it is possible to reduce the contraction in the horizontal direction as well as simultaneously.

As described above, the openings 51 and 52 can be designed in various shapes, such as the intersection of circular and elliptical shapes at right angles.

For these openings 51 and 52, several forms are described as examples in the present invention, but it is not limited thereto, and it is revealed that various forms can be applied.

In addition, in the installation position of the openings 51 and 52, the present invention can be applied to a portion in contact with the tooth surface of the intermediate portion based on the height of the tooth, for example, in the case of FIG. 1, it is preferable in the horizontal direction. contains the central 1/3 point in the form where the tooth surface passes, and its width is a position that does not exceed 1/2 of the length of the crown, which is the distance from the boundary of the gum to the tip of the tooth. It can be limited to a location that includes the /3 point and does not exceed 2/3 of the crown length.

Here, as a reason for limiting to the central 1/3, the teeth are divided into 3 parts in height based on the gum, and are commonly referred to as 1/3 of the alveolar 1/3, 1/3 of the center, and 1/3 of the occlusion from the lower side. Since the 1/3 part is the part where the teeth protrude the most to the side, the openings 51 and 52 can be stably supported, so the central 1/3 part must be included.

In addition, in the case of including 1/3 of the alveolus, it is located close to the lower end of the orthodontic device, and has the advantage of effectively reducing shrinkage during solidification to maintain the overall shape of the orthodontic device as designed. In the piece-type orthodontic appliance, the supporting force of the lower portion is reduced, and in the case of including the occlusal 1/3, the disadvantage that contraction continues to occur from the lower portion of the orthodontic appliance to the occlusal surface appears as it is.

In addition, the size of the openings 51 and 52 is a degree to which the attachment can be inserted to provide support, as one of the orthodontic methods is to attach attachments to the tooth surface for indentation, extrusion, or rotational correction. size is preferred.

Therefore, the openings 51 and 52 can be applied to one of orthodontic methods such as indentation, extrusion, or rotation.

Each of the above cases considers the size or shape of a general tooth or the height of a tooth protruding into the gum, and since the above conditions are all different for each person to be orthodontic, the orthodontic device among the orthodontic device manufacturing methods described later In the design step (S50), it is designed on which surface and in what shape the openings 51 and 52 are to be formed.

At this time, the buccal side surface 20 and the lingual side surface 30 corresponding to the buccal side surface 20 are expected to correspond to molars or premolars, but in the case of incisors and canines, compared to the labial side surface 10, the labial side surface Since the surface area corresponding to the lingual side surface 30 corresponding to is smaller, a difference in shrinkage due to a difference in volume naturally occurs in the orthodontic device in the surface portion.

Therefore, as shown in FIGS. 10 and 11, even in the case of the incisors and canines, the openings 53 and 54 having the same shape as the openings 51 and 52 are installed on the labial side surface 10 or corresponding to the labial side surface 10. Each or both of the side surfaces 30 may be formed.

As another embodiment of the present invention, when described in detail with reference to FIGS. 12 to 15, the orthodontic device is in the form of a mouthpiece that is used by covering the teeth, and has an opening 55 in the occlusal surface 40 of the orthodontic device formed or the thickness of the occlusal surface 40 is formed thinner than that of both side surfaces 20 and 30'.

The reason for this is that the occlusal surface 40 of conventional premolars and molars has a larger surface area than the buccal surface 20 and the lingual surface 30' corresponding to the buccal surface, so its volume is also relatively large, so the occlusal surface Coagulation shrinkage occurs significantly compared to both sides.

As a result, since the orthodontic device has a large tendency to shrink in the transverse direction, it corresponds to the lower end of the orthodontic device corresponding to the end of the buccal side surface 20 and the corresponding lingual side surface 30 'that are open in the transverse direction on both sides Lifting away from the tooth surface often occurs near the root of the tooth.

That is, in the previous embodiment, the openings 51 and 52 are formed in the direction in which the shrinkage proceeds to prevent the progress of the shrinkage, but in another embodiment, the rate of shrinkage is controlled by adjusting the volume occupied by each surface. is to do

In addition, since the volume of the occlusal surface 40 is reduced as described above, it is possible to form the thickness of the buccal side surface 20 and the corresponding lingual side surface 30', which are both sides, relatively thin. This is so that the both side parts 20 and 30' can adhere better to teeth or gums when wearing orthodontic appliances.

To this end, as shown in FIGS. 12 to 14, openings 55 of various shapes are formed in the occlusal surface 40 to reduce the volume of the occlusal surface 40, and as shown in FIG. 15, both side surfaces 20, 30') is molded thinner.

For example, in the case of 3D printing each surface (10, 20, 30, 40) with the same thickness, When the area of the occlusal surface 40 of one molar is set to be 1, the relative ratio of the buccal surface 20 is about 0.8, and the area of the lingual surface 30' is about 0.6.

Therefore, since the average area of both sides is 0.7, it is possible to form the size of the opening 55 to be about 30% of the area of the occlusal surface 40.

In addition, in the case of reducing the volume of the occlusal surface 40, a method of 3D printing by lowering the thickness of the occlusal surface 40 or increasing the thickness of both side surfaces 20 and 30' on the contrary can be devised. .

Here, the case where the thickness of both side surfaces 20 and 30' is increased is described as an example,

In general, when the thickness of the occlusal surface 40 is 3D printed at 0.5t, the buccal side surface 20 has a relative ratio of about 0.8, so it can be manufactured at 0.625t (1: 1/0.8 = 0.5t: x).

In addition, since the relative ratio of the lingual side surface 30' corresponding to the buccal side surface 20 is about 0.6 compared to the occlusal surface 40, it can be manufactured with 0.83t (1: 1/0.6 = 0.5t: x). .

15 shows that the thickness of the occlusal surface 40 is 3D printed with a thickness of 0.5t, and both side surfaces 20 and 30 are printed with a thickness of 0.6t. Although shown, in the case of adjusting the thickness ratio of the parts forming the boundary with each other, it is possible to manufacture an orthodontic device in which the stepped portion 60 does not exist.

In addition, each of the above cases is determined in consideration of the size or shape of a general tooth or the height of a tooth that protrudes into the gum, and since the above conditions are all different for each person to be orthodontic, the method for manufacturing an orthodontic device to be described later In the step of designing the orthodontic device (S50), which opening (51, 52, 53, 54, 55) is to be formed or the occlusal surface 40, the buccal side surface 20 and the buccal side surface 20 corresponding to It is decided how to 3D print each thickness of the lingual side surface 30 '.

Here, the orthodontic device as described above is formed of silicone or thermoplastic shape memory polymer according to an embodiment, and the thermoplastic shape memory polymer uses a known photocurable composition.

The silicone or temperature tunable-shape-memory polymer is basically formed of a transparent material, but a pigment may be further added to express color.

For example, pigments of various colors may be additionally added, such as adding a white pigment to aesthetically show a whitening effect or adding a pigment having a color similar to that of the primary teeth of the person to be corrected.

In addition, when the orthodontic subject wears the orthodontic tooth for a long time, an antibacterial substance capable of sterilizing various bacteria that may occur in the oral cavity may be further added.

The antibacterial material is usually antibacterial, and any ingredient harmless to the human body may be used, and examples thereof may include various materials such as silver (Ag), copper (Cu), charcoal, and ocher.

The steps of manufacturing the orthodontic appliance are as follows.

Scanning the teeth to be corrected using a 3D scanner (S10), acquiring the current oral condition of the subject of correction as data through the scanned data in the step (S10) of scanning the teeth to be corrected (S10) Step (S20), a correction target setting step (S30) of setting a correction target based on the data obtained in the step (S20) of acquiring the current oral condition as data, to the correction target set in the correction target setting step (S30) According to the step of subdividing the steps from the current conception state to the orthodontic target according to the standard of tooth movement amount (S40), designing orthodontic devices based on each subdivided data according to each subdivision step set in the subdivision step (S40). 3D printing of the orthodontic device using the completed design of the orthodontic device designed in step (S50) and designing the orthodontic device (S50) (S60) and curing the 3D printed orthodontic device It consists of step (S70).

1. Step of scanning the self to be corrected (S10)

The step of scanning the tooth to be orthodontic (S10) refers to a process of acquiring the structure and position of the teeth before treatment as 3D data by scanning the teeth of the upper or lower jaw with a 3D scanner.

Here, the 3D data on the structure and position of the teeth before orthodontic treatment is used to obtain the current oral condition of the subject for orthodontic treatment and to set the orthodontic direction and orthodontic target.

At this time, the 3D scanner can be anything as long as it can be scanned in 3D, but it is preferable to use a 3D scanner for dentistry.

2. Acquiring the current oral condition of the subject for correction as data (S20)

The step of acquiring the current shape state of the person to be corrected as data (S20) is to obtain information on the current oral condition of the person to be corrected based on the 3D data obtained in the step (S10) of scanning the teeth to be corrected.

More specifically, information such as the shape of the mouth of the person to be corrected, the occlusion of the upper and lower jaws, and the arrangement of teeth is obtained as 3D image information including graphics, and each unique image information is obtained based on the obtained image information. Characteristic information about the part is also obtained.

3. Calibration target setting step (S30)

The correction target setting step (S30) is to set a correction target based on the data obtained in the step (S20) of acquiring the current oral condition as data.

More specifically, based on the information obtained in the step of acquiring the current oral condition of the person to be corrected as data (S20), the final orthodontic treatment goal of the person to be corrected is set.

4. Segmentation step (S40)

The subdividing step (S40) is to subdivide the steps from the current oral state to the orthodontic target according to the amount of tooth movement according to the orthodontic target set in the orthodontic target setting step (S30).

More specifically, according to the correction target set in the correction target setting step (S30), the amount of tooth movement at the front and/or rear end of the portion requiring correction is set to 0.2 to 0.3 mm per 1STEP.

For example, assuming that the extraction portion of a tooth requiring correction is 1.5 cm, the segmentation process is set to a total of 60 STEP (when the average moving distance is 0.25 mm).

5. Designing dental braces (S50)

In the step of designing the orthodontic device (S50), the shape of each surface of the orthodontic device is designed for each step based on the data subdivided for each step set in the subdividing step (S40).

At this time, the design of the orthodontic device is preferably designed using a 3D modeling program, but is not limited thereto.

In addition, the type, size and position of the openings 51, 52, 53, 54, 55 of the orthodontic appliance or the occlusal surface 40, the buccal side surface 20, and the lingual side surface 30 corresponding to the buccal side surface 20 ') to design the relative thickness.

6. 3D printing step (S60)

Using the completed design of the orthodontic device designed in the step of designing the orthodontic device (S50), the orthodontic device is 3D printed for each STEP.

7. Hardening the 3D printed orthodontic device (S70)

The orthodontic device printed in the 3D printing step (S60) is solidified using a hardener.

There are differences in the method and time of solidification and curing depending on the type of 3D printer and the type of photocurable polymer used, but in general, orthodontic devices, which are the result of 3D printing, are placed in a machine irradiated with ultraviolet rays (UV) and solidified and hardened.

Through this process, solidification and hardening, which were insufficient during 3D printing, are completely completed.

As the method used here, any one of the additive manufacturing methods using photocurability is applied to the known additive manufacturing method of 3D printing.

In addition, a material that can be applied to a 3D printing method in the medical field for a tooth model may be used, and preferably, a photocurable resin that is cured using ultraviolet (UV) light may be used as the material, but is not limited thereto. don't

On the other hand, in the present invention, when the orthodontic device is laminated with a 3D printer, a photocurable temperature-changeable thermoplastic shape memory polymer is used. Either one can be mainly used.

The basic principle of well-known 3D printing is to design a model to be made on a computer using a 3D design program and then save it in the form of STL (Standard Triangle Language) data, but it can be selected as a specific file format required by the 3D printer, , After that, the designed 3D drawing is divided into thin layers as if differentiating layer by layer, and finally, a three-dimensional print can be obtained only by stacking the thin layers one by one from the bottom and going through the process of integration. At this time, since the thickness of the layer is about 0.05 to 0.1 mm, which is thinner than a sheet of paper, it is possible to create an elaborate three-dimensional model.

In addition, the above photocurable temperature-changeable shape-memory polymer (thermoplastic shapememory polymer) has a continuous and weak elasticity even at 36.5 ° C, which is the oral body temperature lower than the glass transition temperature of 50 ° C to 70 ° C, which exhibits the most efficient shape memory effect. and can show the shape memory effect of recovering to the original shape that was memorized.

Here, a known photocurable composition is used as the temperature-variable-shape-memory polymer.

In addition, a selection step in which the user selects a color may be included before printing.

If the user does not selectively select a color, a transparent material is used as a default.

What has been described using the drawings above is only the main points of the present invention, and it is obvious that the present invention is not limited to the configuration of the drawings as various designs are possible within the technical scope.

10: Labial aspect
20: buccal side
30: lingual side
30 ': lingual surface corresponding to the buccal surface 20
40: occlusal surface
51: opening on the buccal side
52: opening on the lingual side corresponding to the buccal side
53: opening on the labial side of canines and incisors
54: opening on the canine and incisor lingual side
55: opening of the occlusal surface
60: stepped part
100A: orthodontic device
100B: orthodontic device
100C : Orthodontic device
100D: orthodontic device
100E: orthodontic device

Claims (2)

In the orthodontic device for covering the surface of the teeth of the person to be orthodontic,
The orthodontic device has a labial side surface 10, a buccal side surface 20, a lingual side surface 30, and an occlusal surface 40 corresponding to the tooth surface, and the occlusal surface 40 includes a buccal side surface 20 Orthodontics supported in close contact with the tooth surface, characterized in that the opening 55 is formed to be equal to the average value of the volume of the lingual side surface 30 corresponding to the buccal side surface 20 to prevent shrinkage during solidification Device.
In the orthodontic device for covering the surface of the teeth of the person to be orthodontic,
The orthodontic device has a labial side surface 10, a buccal side surface 20, a lingual side surface 30, and an occlusal surface 40 corresponding to the tooth surface, and the occlusal surface 40 corresponds to the buccal side surface 20 By reducing the thickness of the occlusal surface 40 to be equal to the average value of the volume of the lingual surface 30 corresponding to the buccal surface 20, it is supported in close contact with the tooth surface, characterized in that it prevents shrinkage during solidification orthodontic appliance.

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