JP2020137956A - Arranging method of shape data of dental technology material and cutting machine used therefor - Google Patents

Abstract

To provide an arranging method of shape data of a dental technology material that eliminates the need of considering the position direction in installing a workpiece and can be easily used at a plurality of different devices, and a cutting machine used therefor.SOLUTION: An arranging method of shape data of a dental technology material includes: imaging the shape of a workpiece 2 by an imaging device in the state in which the workpiece is mounted on a holding jig 1 which can be mounted on a cutting machine and the mounting direction of which is physically defined, to obtain shape data of the workpiece; and arranging shape data of a target dental technology material at an arbitrary position in the shape data of the workpiece.SELECTED DRAWING: Figure 1

Description

The present invention relates to a method for arranging shape data of a dental technician and a cutting machine used for the method. More specifically, the present invention relates to a method of arranging the shape data of a dental technician at an optimum position in the shape data of a workpiece and a cutting machine.

In the field of dentistry, there is known a method of manufacturing a dental restoration by carving out a work piece by using CAD / CAM technology. In recent years, using this CAD / CAM technology, a plurality of dental restorations have been cut from a workpiece.

Furthermore, from the viewpoint of cost reduction, more dental restorations have been newly cut from the partially chipped workpiece remaining after cutting the dental restoration. At that time, on the CAD software, it is possible to avoid the cut portion so that the dental restoration can be cut at the uncut portion of the workpiece. Further, when using CAD / CAM technology, for example, when cutting out a dental restoration from a disk-shaped workpiece (dental mill blank), the position information of the workpiece is read once on CAM software and the shape is formed. Need to get as data. When reusing a work piece that has been machined once, it is necessary to match the position direction of the shape data of the work piece with the position direction of the work piece that has the cut part installed in the CAM. It was. Therefore, conventionally, in order to reuse a work piece that has been machined once, shape data is required each time, and it is necessary to manage the consumption amount of the work piece, and the work piece is not cut. The part was saved in the CAM software as shape data.

However, when a work piece having a cut part is installed in the CAM, the work piece is cut because the direction in which the work piece having the cut part was installed at the time of the previous cutting process is unknown. There was a problem that it could not be easily installed so that the dental restoration could be cut in the unfinished part.

To solve this problem, a technique is known in which a positioning notch is provided to a work piece so that the position direction of the shape data of the uncut portion of the work piece and the position direction of the work piece match. (See Patent Document 1).

In addition, if the shape data including the position direction information installed at the time of the previous cutting is lost, or the previous shape data is used by using a cutting machine in a place different from the CAD / CAM system that was cut last time. When the position direction of the shape data is unknown due to circumstances such as the inability to do so, for example, for a dental mill blank disc having a cut portion, a method of acquiring the disc arrangement data has been proposed (see Patent Document 2). ).

Japanese Patent No. 6344808 Japanese Unexamined Patent Publication No. 2018-171312

However, the method disclosed in Patent Document 1 is effective because shape data cannot be used when the portion remaining after cutting the workpiece is used in a cutting machine different from that at the time of the previous machining. There was a problem that it was not a good method. Further, the method disclosed in Patent Document 2 is such that the image data is corrected after the imaging step in order to determine the direction of the workpiece because the direction installed at the time of the previous cutting process is unknown. It is complicated to have a plurality of steps of the above, and it is necessary to use the program disclosed in Patent Document 2. Further, the method of Patent Document 2 has a problem that the object from which data can be obtained is limited to a cylindrical disk.

The present invention is a method for arranging shape data of a dental technician that can be easily used by a plurality of different devices without having to consider the positional direction when installing the workpiece, and a cutting machine used for the method. The purpose is to provide.

As a result of diligent studies on the above problems, the present inventors have found that the above problems can be solved by a specific method and a cutting machine.

That is, the present invention includes the following inventions.
[1] The shape of the workpiece by the imaging device in a state where the workpiece is mounted on a holder that can be mounted on the cutting machine and whose mounting direction on the cutting machine is physically defined. The dental technician has a step of photographing and acquiring the shape data of the work piece and a step of arranging the shape data of the target dental work piece at an arbitrary position in the shape data of the work piece. How to arrange shape data.
[2] The method according to [1], wherein the holder includes at least one mark indicating position information.
[3] The method according to [2], wherein the mark has position information in a two-dimensional coordinate system.
[4] The method according to any one of [1] to [3], wherein the imaging device is a digital camera.
[5] The method according to any one of [1] to [4], wherein the holder includes an auxiliary tool for fixing the workpiece.
[6] The shape of the workpiece by the imaging device in a state where the workpiece is mounted on a holder that can be mounted on the cutting machine and whose mounting direction on the cutting machine is physically defined. A method of acquiring shape data of a work piece, which comprises a step of taking a picture of the work piece and acquiring the shape data of the work piece.
[7] The method according to [6], wherein the holder includes an auxiliary tool for fixing the workpiece.
[8] The shape of the workpiece by the imaging device in a state where the workpiece is mounted on a holder that can be mounted on the cutting machine and whose mounting direction on the cutting machine is physically defined. The process of acquiring the shape data of the work piece, the process of arranging the shape data of the target dental technician at an arbitrary position in the shape data of the work piece, and the work piece. A method for manufacturing a dental technician, which comprises a step of cutting and acquiring the dental technician.
[9] An imaging unit that captures an image of a workpiece that can be mounted on a cutting machine and that is mounted on a holder whose mounting direction on the cutting machine is physically defined, and a target dental technician. A cutting machine provided with a processing unit that arranges the shape data of the work piece at an arbitrary position in the shape data of the workpiece.
[10] An acquisition unit that acquires the position of a mark included in the holder from an image taken by the image pickup unit, a storage unit that stores a predetermined position where the mark is attached to the cutting machine, and the holding unit. The cutting machine according to [9], further including a compositing unit for synthesizing a mark position provided by the tool and a predetermined position of the mark stored in the storage unit.
[11] The cutting machine according to [10], wherein the mark has position information in a two-dimensional coordinate system.
[12] The cutting machine according to any one of [9] to [11], which has a digital camera as the imaging unit.
[13] The cutting machine according to [12], which has a light source device such as laser light or striped light as a light source corresponding to the digital camera.
[14] A CAD / CAM system including the cutting machine according to any one of [9] to [13].

According to the present invention, it is not necessary to consider the positional direction when installing the workpiece, and the workpiece can be easily used in a plurality of different devices. Therefore, even when a new dental technician is cut from the work piece after cutting the dental technician, the shape data of the work piece can be easily acquired, and the target is included in the shape data of the work piece. It becomes possible to appropriately arrange the shape data of the dental technician. Further, according to the present invention, when a special work material (for example, a rectangular parallelepiped or the like) having a shape different from that of a columnar (disk shape) is used in a new state, the work piece can be easily processed. The shape data can be acquired, and the shape data of the target dental technician can be appropriately arranged in the shape data of the workpiece.

A holder according to an embodiment of the present invention. It is a work piece attached to the holder and the auxiliary tool according to the embodiment of the present invention.

In one embodiment of the present invention, an imaging device is used in a state where an object is mounted on a holder that can be mounted on a cutting machine and whose mounting direction on the cutting machine is physically defined. The process of photographing the shape of the work piece and acquiring the shape data of the work piece and the step of arranging the shape data of the target dental technology at an arbitrary position in the shape data of the work piece. A method of arranging the shape data of the dental technique to be provided can be mentioned.

The holder in the present invention is used to attach a work piece to a predetermined position of a cutting machine. The mounted workpiece is fixed in place on the cutting machine. The holder can be attached to a cutting machine and is used in combination with a predetermined cutting machine. Further, the holder is physically defined in the mounting direction to the cutting machine. The physical definition of the mounting direction on the cutting machine means that the holder is fixed to the cutting machine in a certain direction, or the shape of the holder is used for cutting. Includes those that have a defined mounting direction on the machine and can only be mounted in a certain direction. As the holder, a commercially available product can be used as long as it has the above configuration. The shape of the holder is not limited as long as it can be mounted in a predetermined place of the cutting machine and the mounting direction to the cutting machine is physically defined.

An example of the holder and the workpiece used in the present invention is shown in FIG. In FIG. 1, the workpiece 2 is cylindrical (disk-shaped). In FIG. 1, the workpiece 2 is mounted on the rotating shaft 5 of the cutting machine. The holder used in the present invention includes at least one mark indicating position information. The mark preferably has the position information of the two-dimensional coordinate system, and may have the position information of the three-dimensional coordinate system. The mark is not limited as long as the information in the XY direction can be read, and may be, for example, a grid-like label, a quadrangular pyramid, or the like. The position where the mark is provided in the holder 1 is not particularly limited as long as it can be recognized. In FIG. 1, the holder 1 includes one mark 4 indicating position information. Further, the holder used in the present invention includes a fixing portion for fixing to the cutting machine. The fixed portion may also serve as a mark indicating position information. As the holder used in the present invention, a commercially available product may be used. When a commercially available holder is used, for example, it is preferable to attach a mark having the position information of the two-dimensional coordinate system to the commercially available product.

In the present invention, since the mounting direction of the holder on the cutting machine is physically defined in advance, it is not necessary to determine the direction of the workpiece. Therefore, the present invention is different from Patent Document 2 in which shape data is acquired only by the workpiece on the premise that the direction of the workpiece is unknown, and is different from Patent Document 2 in that it is before cutting as in Patent Document 2. It is not necessary to acquire the outline of the entire workpiece of the work piece, and it is not necessary to acquire a plurality of image data or to correct and correspond the image data, and the auxiliary tool is used as the holder. By using them in combination, the shape of the workpiece is not limited.

The holder used in the present invention may include an auxiliary tool for fixing the work piece. By providing the auxiliary tool, the workpiece can be fixed to the holder even if it has an arbitrary shape, and can be attached to the cutting machine together with the holder. The auxiliary tool is not particularly limited as long as it can fix and hold the workpiece and can be attached to the holder of the present invention. The shape of the auxiliary tool is not particularly limited as long as it has a fixing portion for fixing the workpiece and can be attached to the holder, and is, for example, a shape as shown in FIG. May be good.

An example of a holder provided with an auxiliary tool is shown in FIG. In FIG. 2, the auxiliary tool 3 is attached to the holder 1 while holding the work piece 2 having a square columnar shape. The auxiliary tool 3 includes a fixing portion for fixing the workpiece 2 to the auxiliary tool 3 and a fixing portion for fixing the auxiliary tool 3 to the holding tool 1. The number of fixing portions for fixing the workpiece 2 and the holder 1 is not limited. The fixing portion may be a bolt, a nut, a screw or the like. The material of the auxiliary tool 3 is not particularly limited and may be resin, porcelain, metal, alloy or the like, but from the viewpoint of strength, metal, alloy or the like is preferable.

Further, in FIG. 2, the auxiliary tool 3 includes one mark 4 indicating position information. The auxiliary tool 3 is preferably provided with at least one mark 4 indicating position information. The mark 4 preferably has position information in a two-dimensional coordinate system, and may have position information in a three-dimensional coordinate system. The mark 4 is not limited as long as the information in the XY direction can be read, and may be, for example, a grid-like label, a quadrangular pyramid, or the like. The position where the mark 4 is provided in the auxiliary tool 3 is not particularly limited as long as it can be recognized.

The method of the present invention includes a step of photographing the shape of the work piece with an imaging device and acquiring shape data of the work piece while the work piece is attached to the holder. The image pickup device is not limited as long as it can appropriately image the shape of the workpiece, but it is preferable to use, for example, a digital camera from the viewpoint that the captured image can be easily captured in the CAM software. The digital camera may be any as long as it can capture a still image and can acquire the still image as image data, and may capture a moving image. The number of pixels of the digital camera is not particularly limited as long as it can capture the shape of the workpiece, and may be, for example, 100,000 pixels or more. The digital camera may be, for example, a digital single-lens reflex camera, a compact digital camera, or the like, such as a camera built in a mobile phone, a mobile information terminal (PDA Personal Digital Assist), a camera built in a smartphone, or a digital camera. Examples include single-lens reflex cameras and compact digital cameras. Commercially available digital cameras can be used. As the light source corresponding to the image pickup device, natural light may be used, laser light or striped light may be used, or a light source device for generating these may be used in combination. The shape data of the work piece is input into the CAM software, and the operator can recognize the shape and position information of the portion remaining after cutting the work piece in the CAM software.

In the method of the present invention, the shape data of the dental technician is used. The shape data of the dental technician is data output from CAD software, and is input to CAM software for use. The shape data of the dental technician is data prepared in advance.

The CAD software used in the present invention is not particularly limited, and commercially available products can be used. Commercially available CAD software includes, for example, DWOS series such as "DWOS-CNB", "DWOS-PFW", "DWOS-FDM", "DWOS-IMP", "DWOS-OAR", and "DWOS-BSP" Dental Wings) and the like.

The CAM software used in the present invention is not particularly limited, and commercially available products can be used. Examples of commercially available CAM software include open CAM software "WorkNC Dental" (manufactured by Vero) and "GO2dental" (manufactured by Go2cam).

In another embodiment of the present invention, imaging is performed in a state where the workpiece is mounted on a holder that can be mounted on a cutting machine and whose mounting direction on the cutting machine is physically defined. An example thereof includes a method of acquiring shape data of a work piece, which comprises a step of photographing the shape of the work piece by an apparatus and acquiring the shape data of the work piece. The process in this method is the same as the process of the method of arranging the shape data of the dental technician.

The method of the present invention includes a step of arranging the shape data of the dental technician at an arbitrary place in the shape data of the workpiece by the operator's judgment using CAM software.

Performing an arithmetic operation of converting the shape data of the dental technician placed in the shape data of the work piece obtained as described above into NC (Numerical Control) data for processing in the CAM software. Can be done. Cutting can be performed using the NC data obtained by the calculation work.

In another embodiment of the present invention, imaging is performed in a state where the workpiece is mounted on a holder that can be mounted on a cutting machine and whose mounting direction on the cutting machine is physically defined. The process of photographing the shape of the work piece by the device and acquiring the shape data of the work piece, and the shape data of the target dental technician are arranged at arbitrary positions in the shape data of the work piece. Examples thereof include a method for manufacturing a dental technician, which comprises a step and a step of cutting the workpiece to obtain the dental technician. The process of acquiring the shape data of the workpiece and the step of arranging the shape data of the dental technician in this method are the same as the steps of the method of arranging the shape data of the dental technician. The cutting process can be performed using NC data as described above.

As a device for executing the above method, the cutting machine of the present invention is mounted on a holder that can be mounted on the cutting machine and whose mounting direction on the cutting machine is physically defined. It includes an imaging unit that photographs the work piece, and a processing unit that arranges the shape data of the target dental technician at an arbitrary position in the shape data of the work piece.

The imaging device corresponding to the imaging unit may be provided in the cutting machine of the present invention, but may be independent of the cutting machine. When the image pickup apparatus is independent of the cutting machine, it is preferable that the holder is provided with at least one mark indicating position information. The shape of the work piece is photographed with the work piece attached to the holder. After photographing the shape of the workpiece, the holder is mounted on the cutting machine, and the mounting direction of the holder can be defined on the shape data in the CAM software based on the mark. As a result, the installation direction of the workpiece in the cutting machine is determined on the shape data, and the operator can recognize the shape and position information of the workpiece in the CAM software.

When the imaging device is independent, the position of the mark provided by the holder is acquired from the image taken by the imaging unit from the viewpoint of the operator recognizing the shape and position information of the workpiece in the CAM software. A storage unit that stores a predetermined position (a holder mounting position on the rotation axis of the cutting machine) at which the mark is mounted on the cutting machine, a mark position provided by the holder, and the storage. It is preferable to further include a synthesis unit that synthesizes a predetermined position of a mark stored in the unit.

The acquisition unit acquires the position information of the mark included in the holder from the image captured by the imaging unit. The acquisition unit is not particularly limited as long as it has a scanning function capable of reading the position information of the mark provided in the holder, and a scanner can be used.

The storage unit stores a predetermined position (position where the holder is mounted on the rotation axis of the cutting machine) at which the mark is mounted on the cutting machine, in addition to the position information of the mark acquired by the acquisition unit. The storage unit is not particularly limited as long as it is a storage device that can store the position information data of the mark, and can be used. The storage device may be a main storage device or an external storage device. Examples of the main storage device include RAM such as DRAM and SRAM, and volatile semiconductor memory such as registers and cache memory. Examples of the external storage device include storage media such as hard disks, flexible disks, SSDs, CDs, DVDs, SD memory cards, and USB memory. As the position information data of the mark provided in the storage unit, those previously stored in the storage device can be used.

In the synthesis unit, the position of the mark provided by the holder acquired by the acquisition unit and the predetermined position of the mark stored in the storage unit are combined, that is, the positions of both are aligned. By synthesizing, it is possible to take a picture by the imaging unit even when the holder is not attached to the cutting machine.

Examples of the cutting machine used in the present invention include a desktop processing machine, a large-scale machining center (general-purpose machining machine), and the like, depending on the workpiece. Examples of cutting machines include desktop processing machines "DWX-50", "DWX-4", "DWX-4W", "DWX-52D", and "DWX-52DCi" (manufactured by Roland DG Co., Ltd.). And so on.

In the method and the cutting machine of the present invention, the shape of the work piece is photographed and the shape data of the work piece is acquired by using a holder in which the mounting direction to the cutting machine is physically defined in advance. , The shape data of the work piece can be acquired by simply installing the work piece in the cutting machine and taking a picture, and the operator can easily recognize the shape and position information of the work piece in the CAM software. it can. Therefore, the remaining work piece after cutting the dental work can be reused. In addition, by using an auxiliary tool, even if the work piece is in a new state and is a special work material having a shape different from that of a columnar shape (for example, a disk shape) (for example, a rectangular parallelepiped shape or the like). Well, any shape of work material can be used. In addition, another embodiment of the present invention includes a CAD / CAM system including the cutting machine.

When the workpiece has a shape other than a columnar shape, the mounting direction to the cutting machine can be physically determined by using an auxiliary tool (adapter) in combination with the holder. When an auxiliary tool is used, the workpiece is attached to the cutting machine in a state of being attached to the auxiliary tool and the holder. The shape of the workpiece attached to the holder via the auxiliary tool is photographed by the imaging device, and the shape data of the workpiece is acquired. After that, the shape data of the target dental technician can be arranged at an arbitrary position in the shape data of the work piece. The shape data of the target dental technician can be selected and arranged by the operator in the CAM software while appropriately confirming the optimum position in an arbitrary range in the shape data of the work piece.

Examples of dental technicians in the present invention include dental restorations (crowns, bridges, inlays, onlays, veneers, etc.), dentition models, orthodontic appliances (mouthpieces, etc.), denture beds, artificial teeth, and the like.

1 Holder 2 Work piece 3 Auxiliary tool 4 Mark indicating position information 5 Rotating shaft

Claims (14)

The shape of the workpiece is photographed by an imaging device with the workpiece mounted on a holder that can be mounted on the cutting machine and whose mounting direction on the cutting machine is physically defined. The shape data of the dental technician, which comprises a step of acquiring the shape data of the work piece and a step of arranging the shape data of the target dental technician at an arbitrary position in the shape data of the work piece. Placement method. The method according to claim 1, wherein the holder includes at least one mark indicating position information. The method according to claim 2, wherein the mark has position information in a two-dimensional coordinate system. The method according to any one of claims 1 to 3, wherein the imaging device is a digital camera. The method according to any one of claims 1 to 4, wherein the holder includes an auxiliary tool for fixing the workpiece. The shape of the workpiece is photographed by an imaging device with the workpiece mounted on a holder that can be mounted on the cutting machine and whose mounting direction on the cutting machine is physically defined. , A method for acquiring shape data of a work piece, which comprises a step of acquiring shape data of the work piece. The method of claim 6, wherein the holder comprises an auxiliary tool for fixing the workpiece. The shape of the work piece is photographed by an imaging device with the work piece mounted on a holder that can be mounted on the cutting machine and whose mounting direction on the cutting machine is physically defined. , The process of acquiring the shape data of the work piece, the step of arranging the shape data of the target dental technician at an arbitrary position in the shape data of the work piece, and cutting the work piece. A method for manufacturing a dental technician, which comprises a step of acquiring the dental technician. An image pickup unit that captures an image of a workpiece that can be mounted on a cutting machine and that is mounted on a holder whose mounting direction on the cutting machine is physically defined, and shape data of the target dental technician. A cutting machine provided with a processing unit for arranging the device at an arbitrary position in the shape data of the workpiece. The holder includes an acquisition unit that acquires the position of a mark included in the holder from an image taken by the image pickup unit, a storage unit that stores a predetermined position where the mark is attached to the cutting machine, and a storage unit. The cutting machine according to claim 9, further comprising a compositing unit that combines the position of the mark and the predetermined position of the mark stored in the storage unit. The cutting machine according to claim 10, wherein the mark has position information in a two-dimensional coordinate system. The cutting machine according to any one of claims 9 to 11, which has a digital camera as the imaging unit. The cutting machine according to claim 12, further comprising a light source device such as laser light or striped light as a light source corresponding to the digital camera. A CAD / CAM system comprising the cutting machine according to any one of claims 9 to 13.

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