JP2020135355A - Status display device and status display system for dental processing machine - Google Patents

Abstract

To easily know the status of a plurality of dental processing machines.SOLUTION: A status display device 200 of a dental processing machine 100 comprises: a state acquisition unit 213 that acquires a processing state S1 for each of a plurality of dental processing machines 100; a state creation unit 215 that creates a state list SL1 indicating each processing state S1 of the plurality of dental processing machines 100 acquired by the state acquisition unit 213; an image acquisition unit 225 for acquiring an image M1 of a processing space 26 in which a workpiece 5 in one dental processing machine 100 selected by a user among the plurality of dental processing machines 100 is processed, and which is the image M1 captured by an imaging device 105; and a display processing unit 251 that displays the state list SL1 created by the state creation unit 215 and the image M1 acquired by the image acquisition unit 225.SELECTED DRAWING: Figure 6

Description

The present invention relates to a status display device and a status display system of a dental processing machine. More specifically, the present invention relates to a status display device for displaying the machining status of a plurality of dental processing machines, and a status display system including the status display device and an operation terminal for operating the dental processing machine.

For example, Patent Document 1 discloses a cutting machine that produces an object by cutting a workpiece molded from a predetermined material such as ceramic or resin into a desired shape (hereinafter referred to as processing). Has been done. The cutting machine disclosed in Patent Document 1 uses a rod-shaped machining tool to rotate the machining tool in the axial direction and change the relative position between the machining tool and the workpiece to be machined. Process things. As a result, a desired object can be produced.

JP-A-2015-120222

By the way, as an example of the above-mentioned cutting machine, there is a dental machine used in the dental field. Depending on the user, it is possible that multiple dental processing machines have been introduced. Multiple dental machines are not always located in the same room, and some dental machines may be located in remote locations. In such a case, it is difficult to manage all the states of the plurality of dental processing machines. In particular, when checking the condition of a dental processing machine located in a remote location, it was necessary to go directly to the remote location. Therefore, it was difficult to easily know the state of a plurality of dental processing machines.

The present invention has been made in view of this point, and an object of the present invention is to be able to know the state of dental processing machines arranged in remote locations and to easily know the state of a plurality of dental processing machines. It is to provide a status display device and a status display system of a dental processing machine capable of this.

The state display device of the dental processing machine according to the present invention includes a state acquisition unit, a state creation unit, an image acquisition unit, and a display processing unit. The state acquisition unit acquires the processing state for each of the plurality of dental processing machines. The state creation unit creates a state list showing each of the processing states of the plurality of dental processing machines acquired by the state acquisition unit. The image acquisition unit is an image of a processing space in which an object to be processed in one of the dental processing machines selected by the user is processed, and is captured by the photographing apparatus. Get an image. The display processing unit displays the state list created by the state creation unit and the image acquired by the image acquisition unit.

According to the state display device of the dental processing machine, a state list showing the processing states of a plurality of dental processing machines is displayed by the display processing unit. Therefore, the user can recognize at a glance which dental processing machine is operating by looking at the processing state of each dental processing machine displayed by the display processing unit. Therefore, the state of a plurality of dental processing machines can be easily known. Further, by looking at the image displayed by the display processing unit, it is possible to know the details of the processing of the dental processing machine selected by the user. Therefore, it is possible to know the processing state of the dental processing machine located at a remote location and to know the detailed state of processing of the dental processing machine located at a remote location. Therefore, it is easy to recognize the state of the dental processing machine located in a remote place.

According to the present invention, a state display device for a dental processing machine capable of knowing the state of a dental processing machine arranged in a remote place and easily knowing the state of a plurality of dental processing machines. Can be provided.

It is a conceptual diagram of the state display system which concerns on embodiment. It is a perspective view of a dental processing machine. It is a front view of the dental processing machine, and is the figure which shows the state which the cover is opened. It is a perspective view of a tool magazine, a rotation support member and a clamp. It is a block diagram of a state display system. It is a figure which shows an example of the display screen. It is a figure which shows the flow of data at the time of displaying a state screen on a display device.

Hereinafter, a state display system including a state display device of the dental processing machine according to the embodiment of the present invention will be described with reference to the drawings. It should be noted that the embodiments described here are, of course, not intended to particularly limit the present invention.

FIG. 1 is a conceptual diagram of the state display system 1 according to the present embodiment. The status display system 1 is a system that collectively manages and displays the status of a plurality of dental processing machines 100. Here, the state of the dental processing machine 100 is a state such as whether or not the dental processing machine 100 is being processed. First, an outline of the status display system 1 will be described.

As shown in FIG. 1, the status display system 1 includes a dental processing machine 100, a photographing device 105, an operation terminal 110, a server 120, and a status display device 200. The number of dental processing machines 100 according to this embodiment is not particularly limited. The number of dental processing machines 100 may be one or a plurality. The photographing device 105 captures an image of the processing space 26 (see FIG. 3), which is a space for processing the workpiece 5 in the dental processing machine 100. The photographing device 105 is paired with the dental processing machine 100, and the number of the photographing devices 105 is the same as the number of the dental processing machines 100. However, a plurality of photographing devices 105 may be provided for one dental processing machine 100. In this case, the number of photographing devices 105 is larger than the number of dental processing machines 100.

The operation terminal 110 is a terminal on which the user operates the dental processing machine 100. One or more dental processing machines 100 are communicably connected to the operation terminal 110. Further, one or a plurality of photographing devices 105 are communicably connected to the operation terminal 110. The number of operation terminals 110 according to this embodiment is also not particularly limited. The number of operation terminals 110 may be one or a plurality. The server 120 collectively manages information about a plurality of dental processing machines 100. A plurality of dental processing machines 100 are connected to the server 120. In the present embodiment, a plurality of operation terminals 110 are communicably connected to the server 120, and a plurality of dental processing machines 100 are connected via the operation terminals 110.

The status display device 200 manages and displays the respective statuses of the dental processing machine 100. Here, the status display device 200 is communicably connected to the server 120. The number of status display devices 200 is also not particularly limited. The number of the status display devices 200 may be one or a plurality. In the present embodiment, the status display system 1 may be realized by a client-server type system or may be realized by cloud computing. Hereinafter, the dental processing machine 100, the photographing device 105, the operation terminal 110, the server 120, and the status display device 200 will be described in detail.

First, the dental processing machine 100 will be described. The models of the plurality of dental processing machines 100 may be different. However, the basic configuration of the plurality of dental processing machines 100 is the same. Therefore, here, the basic configuration of one dental processing machine 100 will be described.

FIG. 2 is a perspective view of the dental processing machine 100. FIG. 3 is a front view of the dental processing machine 100, showing a state in which the cover 12 is opened. FIG. 4 is a perspective view of the tool magazine 14, the rotation support member 15, and the clamp 16 described later. FIG. 5 is a block diagram of the status display system 1. In the following description, the left side and the right side mean the left side and the right side as seen from the user in front of the dental processing machine 100, respectively. Further, the bottom surface forming the processing space 26 (see FIG. 3) inside the main body 11 of the dental processing machine 100 is inclined downward from the front to the back when viewed from the user. Therefore, in the present embodiment, the direction in which the user moves away from the dental processing machine 100 along the bottom surface is defined as the front, and the direction in which the user approaches the dental processing machine 100 along the bottom surface is defined as the rear. Further, in the direction orthogonal to the bottom surface, the upper side is upward and the lower side is downward. Note that F, Rr, L, R, U, and D in the drawing mean front, back, left, right, top, and bottom, respectively.

In the present embodiment, the dental processing machine 100 is arranged on a plane composed of the X-axis and the Y-axis when the axes orthogonal to each other are the X-axis, the Y-axis, and the Z-axis. The X-axis is an axis extending in the left-right direction, the Y-axis is an axis extending in the front-rear direction, and the Z-axis is an axis extending in the up-down direction. Further, the symbols θx, θy, and θz in the drawings indicate the rotation directions around the X-axis, the Y-axis, and the Z-axis, respectively. However, the above-mentioned direction is merely a direction determined for convenience of explanation, and does not limit the installation mode of the dental processing machine 100 at all, and does not limit the present invention at all.

The dental processing machine 100 produces an object by processing the work piece 5 (see FIG. 4). Here, the type of the object is not particularly limited, but is, for example, a crown prosthesis. Crown prostheses include, for example, inlays, crowns, bridges and the like. In the present embodiment, the dental processing machine 100 is used in the dental field, and a crown prosthesis is produced from the workpiece 5.

The shape of the workpiece 5 is, for example, a disk shape. The workpiece 5 is formed of a type of material such as zirconia, wax, polymethyl methacrylate resin (PMMA), hybrid resin, PEEK (polyetheretherketone resin), and gypsum. When zirconia is used as the material of the work piece 5, for example, semi-sintered zirconia is used. However, the shape and material of the workpiece 5 are not particularly limited.

As shown in FIG. 2, the dental processing machine 100 includes a main body 11, a cover 12, a processing mechanism 13 (see FIG. 3), a tool magazine (see FIG. 4), a rotation support member 15, and a clamp 16 (FIG. 2). 4) and. The main body 11 is formed in a box shape and has a space inside. This space is the processing space 26. The processing space 26 is a space in which the workpiece 5 is machined. Although detailed illustration is omitted, the bottom surface forming the processing space 26 is inclined downward from the front to the rear. The front part of the main body 11 is open. As shown in FIG. 3, the cover 12 is supported by the main body 11 so that the opening of the main body 11 can be opened and closed. The cover 12 is provided with a window portion 12a. The user can visually recognize the processing space 26 of the main body 11 from the window portion 12a.

As shown in FIG. 3, the machining mechanism 13 cuts the workpiece 5 using the machining tool 8. The processing mechanism 13 processes the workpiece 5 by bringing the machining tool 8 into contact with the workpiece 5 while rotating it. The processing mechanism 13 has a spindle 31 and a tool grip portion 32. The spindle 31 and the tool grip portion 32 are arranged in the processing space 26 of the main body 11. The spindle 31 rotates the tool grip portion 32 and the machining tool 8 gripped by the tool grip portion 32 about the longitudinal direction. The spindle 31 is provided so as to be replaceable with respect to the main body 11. The spindle 31 extends in the vertical direction and is configured to be rotatable around the Z axis θz. The tool gripping portion 32 grips the machining tool 8 and is provided on the spindle 31. Specifically, the tool grip portion 32 is provided on the bottom surface of the spindle 31. The tool gripping portion 32 selectively grips one of the plurality of processing tools 8. As the spindle 31 rotates around the Z-axis θz, the tool gripping portion 32 and the machining tool 8 gripped by the tool gripping portion 32 rotate around the Z-axis θz, in other words, around the central axis of the machining tool 8. ..

In the present embodiment, the dental processing machine 100 includes a moving mechanism 33. The moving mechanism 33 is a mechanism for moving the processing mechanism 13 (specifically, the spindle 31 and the tool gripping portion 32). Here, the moving mechanism 33 is configured to move the processing mechanism 13 in the left-right direction and the up-down direction. The configuration of the moving mechanism 33 is not particularly limited. For example, the moving mechanism 33 is composed of a motor, and the processing mechanism 13 moves when the motor is driven.

In the present embodiment, there are a plurality of processing tools 8 gripped by the tool gripping portion 32. The processing tool 8 has a rod shape and has a cutting tool portion 8a at the lower portion. A plurality of types of processing tools 8 having different shapes of the blade portion 8a are prepared in advance. During machining, the machining tool 8 gripped by the tool grip portion 32 is replaced with another machining tool 8 as necessary according to the machining program PG1 (see FIG. 5) described later.

As shown in FIG. 4, the tool magazine 14 can accommodate a plurality of processing tools 8. In this embodiment, the tool magazine 14 is formed in a box shape. A plurality of accommodating holes 35 for accommodating the processing tool 8 are formed on the upper surface of the tool magazine 14. The processing tool 8 is inserted into the accommodating hole 35 with its upper portion exposed. The number of accommodating holes 35 is not particularly limited, but is 10 here. Therefore, in the present embodiment, the tool magazine 14 can accommodate 10 processing tools 8. When replacing the machining tool 8 gripped by the tool grip portion 32, the machining tool 8 gripped by the tool grip portion 32 is returned to the accommodating hole 35. Then, the machining mechanism 13 is moved to a position above the machining tool 8 to be used next. After that, the tool grip portion 32 grips the upper end of the machining tool 8 located below the tool grip portion 32.

In the present embodiment, the tool magazine 14 is provided with a first rotation shaft 41 that rotatably supports the rotation support member 15. The first rotation shaft 41 extends in the left-right direction and is connected to the rotation support member 15. Although not shown, the tool magazine 14 is provided with a second drive mechanism for rotating the first rotation shaft 41. The first rotating shaft 41 is configured to be rotatable about θx around the X axis by the second driving mechanism. When the first rotation shaft 41 rotates around the X axis θx, the rotation support member 15 rotates around the X axis θx.

The rotation support member 15 rotatably supports the clamp 16. The rotation support member 15 is formed in a substantially C shape in a plan view. The rotation support member 15 is connected to the tool magazine 14 via the first rotation shaft 41. The rotation support member 15 has a first portion 51, a second portion 52, and a third portion 53. The first portion 51 is arranged on the left side of the tool magazine 14, and extends in the front-rear direction. The second portion 52 extends to the left from the rear end of the first portion 51. The third portion 53 extends to the left from the front end of the first portion 51. The third portion 53 faces the second portion 52. In the present embodiment, the clamp 16 is arranged between the second portion 52 and the third portion 53.

The clamp 16 is a member that supports the workpiece 5 when the workpiece 5 is machined. In the present embodiment, an adapter (not shown) is attached to the workpiece 5, and the clamp 16 supports the workpiece 5 via the adapter. For example, the clamp 16 has a shape corresponding to a part of the shape of the workpiece 5. Here, the clamp 16 has a substantially C shape in a plan view. In the present embodiment, the workpiece 5 supported by the clamp 16 is processed. The clamp 16 is rotatably supported by the second portion 52 and the third portion 53 of the rotation support member 15. One end of the second rotating shaft 42 is connected to the rear portion of the clamp 16, and the second portion 52 is connected to the other end of the second rotating shaft 42. One end of the third rotating shaft 43 is connected to the front portion of the clamp 16, and the third portion 53 is connected to the other end of the third rotating shaft 43. In the present embodiment, the third portion 53 is provided with a drive motor 16a (see FIG. 5) that rotates the clamp 16 around the Y axis θy.

The dental processing machine 100 according to the present embodiment may be a dental processing machine with a so-called disc changer. As the disc changer in this case, a conventionally known disc changer can be adopted. As the disc changer, for example, the workpiece transfer device described in JP-A-2018-89763 can be adopted.

As shown in FIG. 2, the dental processing machine 100 includes a control device 60. The control device 60 is a device that controls the processing of the workpiece 5. The control device 60 is composed of a microcomputer and is provided inside the main body 11. The control device 60 includes, for example, a central processing unit (CPU), a ROM that stores a program executed by the CPU, a RAM, and the like. Here, the program stored in the microcomputer is used to control the processing of the workpiece 5.

As shown in FIG. 5, the control device 60 is communicably connected to the spindle 31 and controls the rotation of the spindle 31. The control device 60 is communicably connected to the drive motor 16a that rotates the clamp 16 in θy about the Y axis, and controls the drive motor 16a. The control device 60 is communicably connected to a moving mechanism 33 that moves the processing mechanism 13 in the left-right direction and the up-down direction, and controls the moving mechanism 33. Although not shown, the control device 60 is communicably connected to the second drive mechanism that rotates the first rotation shaft 41, and controls the second drive mechanism.

In the present embodiment, the control device 60 includes a storage unit 61, a processing control unit 62, an information acquisition unit 64, and a transmission unit 66. Each part of the control device 60 may be composed of software or hardware. Each part of the control device 60 may be realized by one or more processors, or may be incorporated by a circuit.

By the way, the dental processing machine 100 according to the present embodiment creates a desired object by automatically processing the workpiece 5 using one or a plurality of processing tools 8 based on the processing program PG1. To do. The dental processing machine 100 processes the workpiece 5 based on the processing program PG1. This machining program PG1 is so-called NC data (NC program) or job data (job program). The processing program PG1 indicates the procedure by which the dental processing machine 100 processes the workpiece 5. The machining program PG1 is a recording of a plurality of commands in which the operation of the machining mechanism 13 and the operation of the clamp 16 supporting the workpiece 5 are defined by coordinate values.

The machining program PG1 is created, for example, by a CAM device (not shown). CAM is an abbreviation for Computer Aided Manufacturing, and the CAM device is called a computer-aided manufacturing device. The CAM apparatus creates a processing program PG1 based on data on the shape of one or more objects (hereinafter, also referred to as object data) produced by processing the workpiece 5. The object data is STL data, and is data created by, for example, a computer-aided design device (hereinafter, also referred to as a CAD (Computer Aided Design) device). The machining program PG1 created by the CAM apparatus is transmitted to the dental machine 100, for example, at the start of machining. Then, the dental processing machine 100 creates an object from the workpiece 5 by sequentially executing the commands of the received processing program PG1.

The processing program PG1 transmitted to the dental processing machine 100 at the start of processing may be one or a plurality. When there are a plurality of machining programs PG1 transmitted to the dental processing machine 100, a list of the plurality of machining programs PG1 (hereinafter, also referred to as a machining program list) PL1 is stored in the storage unit 61. The dental processing machine 100 executes the processing program PG1 in the order of the processing program list PL1 to prepare an object from the workpiece 5.

In the present embodiment, the machining control unit 62 is configured to machine the workpiece 5 by executing the machining program PG1. The machining control unit 62 controls the machining mechanism 13 and the clamp 16 so as to machine the workpiece 5 based on the machining program PG1. In the present embodiment, the machining control unit 62 controls the operations of the machining mechanism 13 and the clamp 16 based on the coordinate values indicated by the command of the machining program PG1. The machining control unit 62 comprehensively controls the operation of the clamp 16 as a whole together with the operation of the machining mechanism 13. As a result, the relative positional relationship between the workpiece 5 supported by the clamp 16 and the machining tool 8 is changed in three dimensions, and the X-axis direction, the Y-axis direction, the Z-axis direction, and the X-axis circumference θx, High-precision machining can be realized by 5-axis control of θy around the Y-axis. In the present embodiment, the cutting tool portion 8a (see FIG. 3) of the machining tool 8 rotated by the spindle 31 of the machining mechanism 13 is brought into contact with the workpiece 5 supported by the clamp 16 to bring the workpiece 5 into contact with the workpiece 5. Can be processed. Here, the object is produced by abutting the machining tool 8 at an arbitrary position with respect to the workpiece 5.

In the present embodiment, the information acquisition unit 64 acquires the information of the dental processing machine 100. As shown in FIG. 6, the information of the dental processing machine 100 includes, for example, information regarding the processing state S1 of the dental processing machine 100, internal information SR1, and the like. Here, the processing state S1 indicates what kind of state the dental processing machine 100 is in. The processing state S1 includes, for example, an operating state S11, a non-operating state S12, and an error state S13. The operating state S11 means a state in which the dental processing machine 100 is processing the workpiece 5. The non-operating state S12 means a state in which the dental processing machine 100 is not processing the workpiece 5. The error state S13 is a state in which an error has occurred in the dental processing machine 100. The machining state S1 may include other states, for example, a completion state indicating that all executions of the machining program PG1 in the machining program list PL1 have been completed may be included. The information acquisition unit 64 acquires such a processing state S1.

The internal information SR1 includes, for example, firmware version SR11, operation information SR12, origin adjustment correction value SR13 of the spindle 31, machining tool 8 type SR14, workpiece 5 type SR15, and error information SR16. At least one of them is included. However, the internal information SR1 may include other information of the dental processing machine 100. The firmware version SR11 is the version of the firmware incorporated in the control device 60 of the dental processing machine 100. For example, when the firmware of the dental processing machine 100 is updated to a new firmware due to a defect or the like, the firmware version SR11 is also updated. The firmware version SR11 is stored in the storage unit 61. The information acquisition unit 64 acquires the firmware version SR11 from the dental processing machine 100.

The operation information SR12 is information when the dental processing machine 100 is operating (that is, information when the workpiece 5 is being processed). For example, the operating time SR121 of the dental processing machine 100 and the rotation of the spindle 31. It has a time SR 122, a spindle 31 replacement number SR 123, and a working tool 8 usage time SR 124. The operating time SR121 of the dental processing machine 100 is the total time processed by the target dental processing machine 100. In other words, the operating time SR121 of the dental processing machine 100 is the total time during which the processing program PG1 was executed.

The rotation time SR122 of the spindle 31 is the total time during which the spindle 31 actually rotates when the dental processing machine 100 is processing the workpiece 5. The rotation time SR122 of the spindle 31 is obtained by measuring each time the spindle 31 rotates during machining. The spindle 31 is replaceably provided on the main body 11. The number of times the spindle 31 is replaced SR123 is the number of times the spindle 31 is replaced in the target dental processing machine 100. The usage time SR124 of the processing tool 8 is the time during which the processing tool 8 was used for processing. The usage time SR124 of the machining tool 8 is, for example, the total time during which the machining tool 8 is gripped by the tool grip portion 32. In the present embodiment, since the plurality of machining tools 8 are selectively used, the usage time SR124 of the machining tool 8 is measured for each of the plurality of machining tools 8. The operation information SR 12 is stored in the storage unit 61. The information acquisition unit 64 acquires the operation information SR12 from the dental processing machine 100.

The spindle 31 moves in the machining space 26, and if it is used for a long time, misalignment may occur. A predetermined origin position is set on the spindle 31, and by adjusting this origin position, the position deviation of the spindle 31 is less likely to occur. Mechanically adjusting the origin position of the spindle 31 is called origin adjustment of the spindle 31, and a value that eliminates the deviation of the origin position when the origin position is adjusted is called a correction value SR13. For example, the correction value SR13 is stored in the storage unit 61. The information acquisition unit 64 acquires the correction value SR13 for adjusting the origin of the spindle 31 from the dental processing machine 100.

The type SR14 of the processing tool 8 is information on the type of the processing tool 8 held by the tool gripping portion 32 of the target dental processing machine 100, and is information on the type of the processing tool 8 housed in the tool magazine 14. Is. The type SR14 of the processing tool 8 is a material forming the processing tool 8, the shape of the cutting tool portion 8a of the processing tool 8, and the like. However, the information SR14 of the machining tool 8 may include information about other machining tools 8.

Type of work piece 5 SR15 is a type of work piece 5 processed by the dental processing machine 100. In other words, the type SR15 of the workpiece 5 is the type of the workpiece 5 supported by the clamp 16 (see FIG. 4) of the dental processing machine 100, and the processing program executed by the dental processing machine 100. This is the type of work piece 5 specified by PG1. In this embodiment, the type SR14 of the processing tool 8 and the type SR15 of the workpiece 5 are shown in the processing program PG1. This processing program PG1 is stored in the terminal storage unit 114 of the operation terminal 110 and the storage unit 61 of the dental processing machine 100. For example, the information acquisition unit 64 acquires the type SR14 of the processing tool 8 and the type SR15 of the workpiece 5 from the dental processing machine 100.

The error information SR16 of the dental processing machine 100 is information regarding an error of the dental processing machine 100 that occurs when the workpiece 5 is being processed. The content of this error is not particularly limited, and it is assumed that a conventionally known error is included, but at least a fatal error is included. Here, the fatal error is an error in which the user cannot immediately resolve the error, and an error in which machining by the dental processing machine 100 cannot be restarted immediately. The error occurs when the workpiece 5 cannot be machined properly. The errors are, for example, an error caused by the machining tool 8 being broken, an error caused by the tool gripping portion 32 failing to grip the machining tool 8, an error caused by the spindle 31 not rotating at an appropriate rotation speed, a machining mechanism 13 or a clamp. It includes an error due to the 16 not being able to move to an appropriate position. In the present embodiment, the specific content of the error information SR 16 is not particularly limited, but the error information includes, for example, an error code. The error code is a unique code attached to the content of the error. This error code makes it possible to uniquely identify the content of the error. When an error occurs in the dental processing machine 100, the information acquisition unit 64 acquires error information SR16 using an error code corresponding to the content of the error as an example.

The transmission unit 66 transmits information (for example, internal information SR1) about the dental processing machine 100 acquired by the information acquisition unit 64 to the operation terminal 110.

Next, the photographing apparatus 105 shown in FIG. 1 will be described. The photographing device 105 captures an image of the processing space 26 (see FIG. 3) of the dental processing machine 100. The photographing device 105 photographs an image of the workpiece 5 being cut by the machining tool 8 by the machining mechanism 13 in the machining space 26. Here, the "image" means an event that is visually fixed on the medium. In the present embodiment, the "image" includes moving images and still images.

The type of the photographing apparatus 105 is not particularly limited. For example, the photographing device 105 is a camera capable of photographing a moving image or a still image. As described above, in the present embodiment, one imaging device 105 is provided for each dental processing machine 100. However, the number of photographing devices 105 provided in one dental processing machine 100 is not limited to one, and may be two or more.

The position of the photographing device 105 with respect to the dental processing machine 100 is not particularly limited, and it is preferable that the position is such that the state in which the workpiece 5 is processed can be photographed in the processing space 26 of the dental processing machine 100. The photographing device 105 may be arranged inside the main body 11 (specifically, the processing space 26) as long as it can photograph the state in which the workpiece 5 is being processed, or outside the main body 11. Therefore, it may be arranged at a position where the inside of the processing space 26 can be photographed through the window portion 12a (see FIG. 2) of the cover 12. When the photographing device 105 is arranged in the processing space 26, the photographing device 105 is arranged at a position where the processing powder generated when the workpiece 5 is being machined does not easily adhere to the photographing device 105. It is preferable to have. In this case, for example, the photographing apparatus 105 may be arranged in the upper part of the processing space 26. For example, when the number of photographing devices 105 provided in one dental processing machine 100 is three, the photographing device 105 includes a first photographing device, a second photographing device, and a third photographing device. In this case, the first imaging device is arranged, for example, in front of the clamp 16. The second imaging device is arranged above, for example, the tool magazine 14 and the clamp 16. The third photographing device is arranged at a position where the state of the disc changer can be photographed (for example, a position above the disc changer).

Next, the operation terminal 110 shown in FIG. 1 will be described. In this embodiment, the plurality of operation terminals 110 have the same configuration. Therefore, the configuration of one operation terminal 110 will be described below. The operation terminal 110 is a terminal for operating the dental processing machine 100. The operation terminal 110 is realized by, for example, a personal computer. The operation terminal 110 may be realized by a general-purpose computer or may be realized by a dedicated computer.

As shown in FIG. 1, one or a plurality of dental processing machines 100 are communicably connected to the operation terminal 110. The operation terminal 110 can operate the dental processing machine 100 which is communicably connected. Further, one or a plurality of photographing devices 105 are communicably connected to the operation terminal 110. As shown in FIG. 5, the operation terminal 110 includes, for example, a terminal display screen 111, a terminal operation unit 112, and a terminal control device 113.

The type of the terminal display screen 111 is not particularly limited, and is, for example, a desktop type or notebook type personal computer display. The terminal operation unit 112 is, for example, a keyboard and a mouse of a personal computer. However, the terminal operation unit 112 may be a touch panel provided on the terminal display screen 111.

The terminal control device 113 is, for example, a microcomputer. The hardware configuration of the microcomputer is not particularly limited, but includes, for example, a CPU, a ROM, a RAM, and a storage device. The terminal control device 113 is communicably connected to the terminal display screen 111 and the terminal operation unit 112.

A dedicated application for operating the dental processing machine 100 is installed in the terminal control device 113. The user can operate the dental processing machine 100 by displaying the application on the terminal display screen 111 using the terminal operation unit 112 and operating the application via the terminal operation unit 112. The terminal control device 113 includes a terminal storage unit 114, a terminal state acquisition unit 115, a terminal image acquisition unit 116, a terminal list acquisition unit 117, a terminal internal acquisition unit 118, and a terminal transmission unit 119. Each part of the terminal control device 113 may be configured by software or may be configured by hardware. Each part of the terminal control device 113 may be realized by one or more processors, or may be incorporated in a circuit. A detailed description of each part of the terminal control device 113 will be described later.

Next, the server 120 shown in FIG. 1 will be described. One or more operating terminals 110 are communicably connected to the server 120, and one or more dental processing machines 100 are communicably connected via the operating terminals 110. In addition, one or a plurality of photographing devices 105 are communicably connected to the server 120 via the operation terminal 110. For example, when the status display system 1 is realized by cloud computing, the server 120 is a cloud. The server 120 is an example of the storage device of the present invention.

Next, the status display device 200 will be described. The status display device 200 collectively manages and displays the processing status and information related to the plurality of dental processing machines 100. The status display device 200 is realized by, for example, a personal computer, like the operation terminal 110. The status display device 200 may be realized by a general-purpose computer or a dedicated computer.

As shown in FIG. 1, the status display device 200 is communicably connected to the server 120. The status display device 200 acquires the processing state S1, internal information SR1, processing program list PL1 and image M1 for each dental processing machine 100 stored in the server 120, and as shown in FIG. 6, relates to each dental processing machine 100. The processing state S1, the internal information SR1, the processing program list PL1, and the image M1 are displayed. As shown in FIG. 5, the status display device 200 includes a display device 201, an operation unit 202, and a display processing device 210.

The type of display device 201 is not particularly limited. The display device 201 is, for example, a display of a portable terminal. However, the display device 201 may be, for example, a display of a desktop type or notebook type personal computer.

The operation unit 202 is for the user to operate what is displayed on the display device 201. For example, the user can switch what is displayed on the display device 201 by operating the operation unit 202. The type of the operation unit 202 is not particularly limited. The operation unit 202 is, for example, a touch panel arranged on the screen of the display device 201. However, the operation unit 202 may be a keyboard and a mouse of a personal computer.

The display processing device 210 acquires information about each dental processing machine 100 from the server 120, and displays the information about each dental processing machine 100 on the display device 201. The configuration of the display processing device 210 is not particularly limited. The display processing device 210 is, for example, a microcomputer. The display processing device 210 includes a CPU, a ROM, a RAM, a storage device, and the like. In the present embodiment, the display processing device 210 is separate from the server 120, but may be integrated with the server 120. The display processing device 210 is communicably connected to the server 120 via a wired or wireless connection. Although not shown, the display processing device 210 is communicably connected to the operation terminal 110. In the present embodiment, the display processing device 210 is separate from the operation terminal 110, but may be integrated with the operation terminal 110. In this case, the display processing device 210 may be incorporated in the terminal control device 113 of the operation terminal 110.

In the present embodiment, as shown in FIG. 5, the display processing device 210 includes a display storage unit 211, a state acquisition instruction unit 212, a state acquisition unit 213, a state creation unit 215, and an image acquisition instruction unit 223. It includes an image acquisition unit 225, a list acquisition instruction unit 233, a list acquisition unit 235, an internal acquisition instruction unit 243, an internal acquisition unit 245, and a display processing unit 251. Each part of the display processing apparatus 210 may be composed of software or hardware. Each part of the display processing device 210 may be realized by one or more processors, or may be incorporated in a circuit. A detailed description of each part of the display processing device 210 will be described later.

In the present embodiment, as shown in FIG. 6, one state screen DP1 is displayed on the display device 201. The state list SL1, the image M1, the processing program list PL1, and the internal information SR1 are arranged on the state screen DP1. The status list SL1, the image M1, the processing program list PL1, and the internal information SR1 are created and displayed by a plurality of dental processing machines 100, an operation terminal 110, a server 120, and a status display device 200, respectively. Hereinafter, the state list SL1, the image M1, the machining program list PL1, and the internal information SR1 will be described in detail.

The state list SL1 is a list showing the processing states S1 of each dental processing machine 100. In the present embodiment, the machining state S1 includes the operating state S11, the non-operating state S12, and the error state S13 as described above. FIG. 7 is a diagram showing a data flow when displaying the state screen DP1 on the display device 201. As shown in FIG. 7, the state list SL1 is created by the terminal state acquisition unit 115 of the operation terminal 110, and the state acquisition instruction unit 212, the state acquisition unit 213, and the state creation unit 215 of the state display device 200.

In the present embodiment, the state acquisition instruction unit 212 of the state display device 200 connects to the operation terminal 110 communicably connected to the state display device 200 via the server 120, and the processing state for each of the plurality of dental processing machines 100. Instructs to acquire the information of S1. At this time, the terminal state acquisition unit 115 of the operation terminal 110 acquires the processing state S1 from each dental processing machine 100 that is communicably connected. After acquiring the processing state S1 of the dental processing machine 100 from the dental processing machine 100, the terminal transmission unit 119 transmits the processing state S1 to the server 120. The server 120 stores the processing state S1 in each dental processing machine 100.

In the present embodiment, each dental processing machine 100 is provided with a unique device ID 101. From this device ID 101, which dental processing machine 100 can be uniquely specified. Here, the terminal transmission unit 119 transmits the processing state S1 and the device ID 101 to the server 120. When the server 120 stores the processing state S1 related to each dental processing machine 100, it stores it in association with the device ID 101. The server 120 stores the processing state S1 of each dental processing machine 100 by associating the device ID 101 with the processing state S1 using, for example, a table.

The state acquisition unit 213 of the display processing device 210 acquires the processing state S1 of each dental processing machine 100 and the device ID 101 stored in the server 120. The state creation unit 215 creates a state list SL1 of each processing state S1 of the plurality of dental processing machines 100 acquired by the state acquisition unit 213. The configuration of the state list SL1 is not particularly limited. In the present embodiment, as shown in FIG. 6, the state list SL1 is a list in which the device ID 101 attached to the dental processing machine 100 and the processing state S1 of the dental processing machine 100 corresponding to the device ID 101 are associated with each other. .. The state list SL1 may be associated with the name 102a of the dental processing machine 100 arbitrarily assigned by the user, the model name 102b of the dental processing machine 100, and the machine number 102c. In an example of FIG. 6, the processing state S1 corresponding to the device ID 101 a1 and a4 is the operating state S11. This means that the dental processing machine 100 whose device ID 101 is a1 and a4 is being processed. Further, in an example of FIG. 6, it is shown that an error has occurred in the dental processing machine 100 in which the device ID 101 is a5.

In the present embodiment, the state list SL1 is an operation unit from among a plurality of dental processing machines 100 belonging to the state list SL1 (here, the dental processing machines 100 whose device IDs are a1, a2, a3, a4, and a5). One dental processing machine 100 can be selected by 202. That is, the user can operate the operation unit 202 to select one dental processing machine 100 from the plurality of dental processing machines 100 displayed in the state list SL1. The display processing unit 251 displays the status list SL1 having the above configuration on the display device 201.

As shown in FIG. 6, the image M1 displayed on the display device 201 is an image M1 in the processing space 26 in one dental processing machine 100 selected from the plurality of dental processing machines 100, and is a photographing device. Image M1 taken by 105 (see FIG. 1). In the present embodiment, as shown in FIG. 7, the image M1 displayed on the display device 201 is the terminal image acquisition unit 116 of the operation terminal 110, and the image acquisition instruction unit 223 and the image acquisition unit 225 of the state display device 200. Determined by.

In the present embodiment, the image acquisition instruction unit 223 of the status display device 200 notifies the server 120 to acquire the image M1 for one dental processing machine 100 selected by the user among the plurality of dental processing machines 100. Instruct the operation terminal 110 via. Here, the user selects one dental processing machine 100 from the state list SL1 displayed on the display device 201 by operating the operation unit 202. The image acquisition instruction unit 223 instructs the operation terminal 110 to acquire the image M1 for one dental processing machine 100 selected from the state list SL1. In one example of FIG. 6, it is assumed that the dental processing machine 100 whose device ID 101 is a1 is selected from the state list SL1. In this case, the image acquisition instruction unit 223 instructs the operation terminal 110 to which the dental processing machine 100 whose device ID 101 is a1 is connected to acquire the image M1.

At this time, the terminal image acquisition unit 116 of the operation terminal 110 acquires the image M1 from the photographing device 105 for the dental processing machine 100 whose device ID 101 is a1. After acquiring the image M1 from the photographing device 105, the terminal transmission unit 119 transmits the image M1 and the device ID 101 to the server 120. The server 120 stores the image M1 in association with the device ID 101.

The image acquisition unit 225 of the display processing device 210 acquires the image M1 stored in the server 120, and in the example of FIG. 6, the device ID 101 acquires the image M1 associated with the a1. The display processing unit 251 displays the image M1 acquired by the image acquisition unit 225 on the display device 201 (see FIG. 6).

The machining program list PL1 displayed on the display device 201 shown in FIG. 6 is a list of machining programs PG1 executed by one dental machining machine 100 selected from a plurality of dental machining machines 100. In the present embodiment, as shown in FIG. 7, the machining program list PL1 displayed on the display device 201 includes the terminal list acquisition unit 117 of the operation terminal 110 and the list acquisition instruction unit 233 of the status display device 200. Determined by part 235.

In the present embodiment, the list acquisition instruction unit 233 of the status display device 200 requests the server to acquire the processing program list PL1 for one dental processing machine 100 selected by the user among the plurality of dental processing machines 100. The operation terminal 110 is instructed via 120. Here, the user selects one dental processing machine 100 from the state list SL1 displayed on the display device 201 by operating the operation unit 202. The list acquisition instruction unit 233 instructs the operation terminal 110 to acquire the processing program list PL1 for the dental processing machine 100 selected from the state list SL1. In one example of FIG. 6, since the dental processing machine 100 whose device ID 101 is a1 is selected, the list acquisition instruction unit 233 processes the operation terminal 110 to which the dental processing machine 100 whose device ID 101 is a1 is connected. Instructs to acquire the program list PL1.

At this time, the terminal list acquisition unit 117 of the operation terminal 110 acquires the processing program list PL1 of the dental processing machine 100 in which the device ID 101 is a1. In the present embodiment, the terminal storage unit 114 of the operation terminal 110 stores the processing program list PL1 for the dental processing machine 100. Therefore, the terminal list acquisition unit 117 can acquire the processing program list PL1 from the terminal storage unit 114. However, the terminal list acquisition unit 117 may be configured to acquire the processing program list PL1 from the dental processing machine 100. After the terminal list acquisition unit 117 acquires the machining program list PL1, the terminal transmission unit 119 transmits the machining program list PL1 and the device ID 101 to the server 120. The server 120 stores the machining program list PL1 in association with the device ID 101.

The list acquisition unit 235 of the display processing device 210 acquires the machining program list PL1 stored in the server 120, and in the example of FIG. 6, the device ID 101 acquires the machining program list PL1 associated with a1. The display processing unit 251 displays the machining program list PL1 acquired by the list acquisition unit 235 on the display device 201. When displaying the machining program list PL1, the display processing unit 251 also displays information 103 as to whether or not the execution of the machining program PG1 displayed in the machining program list PL1 is completed, as shown in FIG. You may. The information 103 as to whether or not the execution of the processing program PG1 is completed is information that can be acquired from the dental processing machine 100 by the terminal list acquisition unit 117. In one example of FIG. 6, the machining program PG1 of Sample1 and Sample2 is a machining program that has already been executed, and "end" information 103a is attached. The machining program PG1 of Sample3 is a machining program currently being executed, and information 103b of "working" is attached. Further, the machining program PG1 of Sample4 and Sample5 is a machining program to be executed from now on, and the information 103c of "before machining" is attached.

The internal information SR1 displayed on the display device 201 is the internal information SR1 of one dental processing machine 100 selected from the plurality of dental processing machines 100. In the present embodiment, as shown in FIG. 7, the internal information SR1 displayed on the display device 201 includes the terminal internal acquisition unit 118 of the operation terminal 110, and the internal acquisition instruction unit 243 and the internal acquisition unit of the status display device 200. Determined by 245.

In the present embodiment, the internal acquisition instruction unit 243 of the status display device 200 obtains the internal information SR1 of one dental processing machine 100 selected by the user from among the plurality of dental processing machines 100. Instruct the operation terminal 110 via. Here, the user selects one dental processing machine 100 from the state list SL1 displayed on the display device 201 by operating the operation unit 202. The internal acquisition instruction unit 243 instructs the operation terminal 110 to acquire the internal information SR1 of the dental processing machine 100 selected from the state list SL1. In one example of FIG. 6, since the dental processing machine 100 whose device ID 101 is a1 is selected, the internal acquisition instruction unit 243 is internally connected to the operation terminal 110 to which the dental processing machine 100 whose device ID 101 is a1 is connected. Instructs to acquire the information SR1.

At this time, the terminal internal acquisition unit 118 of the operation terminal 110 acquires the internal information SR1 of the dental processing machine 100 whose device ID 101 is a1 from the dental processing machine 100. However, the terminal internal acquisition unit 118 acquires a part of the internal information SR1 (for example, the type SR14 of the processing tool 8 and the type SR15 of the workpiece 5) from the processing program PG1 stored in the terminal storage unit 114. You may. After the terminal internal acquisition unit 118 acquires the internal information SR1, the terminal transmission unit 119 transmits the internal information SR1 and the device ID 101 to the server 120. The server 120 stores the internal information SR1 in association with the device ID 101.

The internal acquisition unit 245 of the display processing device 210 acquires the internal information SR1 stored in the server 120, and in the example of FIG. 6, the device ID 101 acquires the internal information SR1 associated with a1. The display processing unit 251 displays the internal information SR1 acquired by the internal acquisition unit 245 on the display device 201. Here, as shown in FIG. 6, the display processing unit 251 uses the firmware version SR11, the operation information SR12, the correction value SR13 for adjusting the origin of the spindle 31, the type SR14 of the machining tool 8, and the workpiece as the internal information SR1. The five types SR15, error information SR16, and the like are displayed on the display device 201.

In the present embodiment, the display processing unit 251 displays the state list SL1, the image M1, the processing program list PL1, and the internal information SR1 on the same screen (here, the state screen DP1). Specifically, the display processing unit 251 divides the state screen DP1 into four vertically and horizontally in FIG. 6, and divides the state list SL1, the image M1, the processing program list PL1, and the internal information SR1 into the upper left and upper right of the state screen DP1, respectively. , Lower left, lower right. However, the arrangement positions of the state list SL1, the image M1, the processing program list PL1, and the internal information SR1 are not particularly limited. Further, the state list SL1, the image M1, the processing program list PL1, and the internal information SR1 may be displayed on separate screens.

In the present embodiment, the display device 201 (specifically, the state screen DP1 displayed on the display device 201) has a state update button BT1, an image update button BT2, a list update button BT3, and an internal information update button BT4. Has been done. The buttons BT1 to BT4 are pressed by the user operating the operation unit 202. Here, when the state update button BT1 is pressed, the state list SL1 displayed on the display device 201 is updated. When the status update button BT1 is pressed, the terminal status acquisition unit 115 of the operation terminal 110 and the status acquisition instruction unit 212 of the status display device 200 store the latest processing status S1 of each dental processing machine 100 in the server 120. Will be done. The state acquisition unit 213 acquires the latest processing state S1 of each dental processing machine 100 stored in the server 120, and the state creation unit 215 creates the latest state list SL1. The display processing unit 251 displays the latest status list SL1 on the display device 201.

When the image update button BT2 is pressed, the image M1 displayed on the display device 201 is updated. When the image update button BT2 is pressed, the terminal image acquisition unit 116 of the operation terminal 110 and the image acquisition instruction unit 223 of the status display device 200 cause the server 120 to use one dental processing machine 100 selected by the user. The latest image M1 corresponding to is stored. The image acquisition unit 225 acquires the latest image M1 stored in the server 120. The display processing unit 251 displays the latest image M1 on the display device 201.

When the list update button BT3 is pressed, the machining program list PL1 displayed on the display device 201 is updated. When the list update button BT3 is pressed, one dental processing machine 100 selected by the user is sent to the server 120 by the terminal list acquisition unit 117 of the operation terminal 110 and the list acquisition instruction unit 233 of the status display device 200. The latest machining program list PL1 of the machining program PG1 executed by is stored. The list acquisition unit 235 acquires the latest machining program list PL1 stored in the server 120. The display processing unit 251 displays the latest machining program list PL1 on the display device 201.

When the internal information update button BT4 is pressed, the internal information SR1 displayed on the display device 201 is updated. When the internal information update button BT4 is pressed, one dental processing machine selected by the user is used as the server 120 by the terminal internal acquisition unit 118 of the operation terminal 110 and the internal acquisition instruction unit 243 of the status display device 200. The latest 100 latest inside information SR1 is stored. The internal acquisition unit 245 acquires the latest internal information SR1 stored in the server 120. The display processing unit 251 displays the latest internal information SR1 on the display device 201.

As described above, in the present embodiment, as shown in FIG. 6, the processing states S1 of the plurality of dental processing machines 100 are displayed on the display device 201. Therefore, the user can recognize at a glance which dental processing machine 100 is operating by looking at the processing state S1 of each dental processing machine 100 displayed on the display device 201 by the display processing unit 251. it can. Further, by looking at the image M1 displayed on the display device 201 by the display processing unit 251 it is possible to know the details of the processing of one dental processing machine 100 selected by the user. Therefore, it is possible to know the processing state S1 of the dental processing machine 100 located at a remote location, and also to know the detailed processing state of the dental processing machine 100 located at a remote location. Therefore, it is easy to recognize the state of the dental processing machine 100 located at a remote location.

In the present embodiment, the machining state S1 has at least an operating state S11, a non-operating state S12, and an error state S13. As a result, it is possible to recognize at a glance which of the plurality of dental processing machines 100 is operating or not operating. Further, when an error has occurred in the dental processing machine 100, the error state S13 is displayed, so that it is easy to recognize the dental processing machine 100 in which the error has occurred. Further, by displaying the image M1 of the processing space 26 of the dental processing machine 100 in which the error has occurred, even a user at a remote location can easily understand the detailed state of the error.

In the present embodiment, the list acquisition unit 235 acquires the processing program list PL1 of the processing program PG1 executed by one dental processing machine 100 selected by the user among the plurality of dental processing machines 100. The display processing unit 251 displays the machining program list PL1 acquired by the list acquisition unit 235. As a result, even if the dental processing machine 100 is located in a remote location, by looking at the processing program list PL1 displayed by the display processing unit 251, what kind of processing program PG1 can be used by the dental processing machine 100. You can recognize at a glance whether to execute it.

In the present embodiment, the internal acquisition unit 245 acquires the internal information SR1 set in one dental processing machine 100 selected by the user among the plurality of dental processing machines 100. The display processing unit 251 displays the internal information SR1 acquired by the internal acquisition unit 245. As a result, even if the dental processing machine 100 is located at a remote location, the internal information SR1 of the dental processing machine 100 can be known by looking at the internal information SR1 displayed by the display processing unit 251. .. The user can give an appropriate instruction to the operator of the dental processing machine 100 based on the inside information SR1.

In the present embodiment, the image acquisition instruction unit 223 instructs the operation terminal 110 to acquire the image M1 of one dental processing machine 100 selected by the user among the plurality of dental processing machines 100. The terminal image acquisition unit 116 of the operation terminal 110 acquires the image M1 instructed by the image acquisition instruction unit 223 from the photographing device 105. The terminal transmission unit 119 transmits the image M1 acquired by the terminal image acquisition unit 116 to the server 120. The image acquisition unit 225 acquires the image M1 from the server 120. As a result, the image M1 of the dental processing machine 100 that the user wants to see is acquired, so that the image M1 can be efficiently acquired.

In the present embodiment, the state list SL1 displayed on the display device 201 is configured so that one dental processing machine 100 can be selected by the operation unit 202 from the plurality of dental processing machines 100 shown in the state list SL1. ing. The image acquisition unit 225 acquires an image M1 for one dental processing machine 100 selected by the user via the operation unit 202 from the plurality of dental processing machines 100 shown in the state list SL1. As a result, the image M1 of the dental processing machine 100 that the user wants to see can be acquired by a simple method of selecting one dental processing machine 100 from the state list SL1.

In the present embodiment, the display processing unit 251 includes a state list SL1 created by the state creation unit 215, an image M1 acquired by the image acquisition unit 225, a machining program list PL1 acquired by the list acquisition unit 235, and an interior. The internal information SR1 acquired by the acquisition unit 245 is displayed on the same screen (here, the status screen DP1). As a result, the user can see the state list SL1, the image M1, the processing program list PL1, and the internal information SR1 at the same time, so that the state of the dental processing machine 100 can be easily understood.

In the present embodiment, the display device 201 displays a state update button BT1 for updating the state list SL1 displayed on the display device 201, and an image update button BT2 displayed on the display device 201. When the state update button BT1 is pressed via the operation unit 202, the state acquisition unit 213 acquires information on the processing state S1 for each of the plurality of dental processing machines 100. The image acquisition unit 225 acquires the image M1 of one dental processing machine 100 selected by the user when the image update button BT2 is pressed via the operation unit 202. Further, in the present embodiment, the display device 201 has a list update button BT3 for updating the machining program list PL1 displayed on the display device 201, and an internal information update for updating the internal information SR1 displayed on the display device 201. Button BT4 is displayed. The list acquisition unit 235 acquires the processing program list PL1 indicating the processing program PG1 executed by one dental processing machine 100 selected by the user when the list update button BT3 is pressed via the operation unit 202. To do. The internal acquisition unit 245 acquires the internal information SR1 of one dental processing machine 100 selected by the user when the internal information update button BT4 is pressed via the operation unit 202.

In this way, by pressing the buttons BT1 to BT4, only the information that the user wants to update is selected and updated from the information of the state list SL1, the machining program list PL1, the image M1, and the internal information SR1. be able to.

In the above embodiment, for example, the state acquisition instruction unit 212 has instructed the operation terminal 110 to acquire the processing state S1 via the server 120. The state acquisition unit 213 has acquired the processing state S1 from the server 120. However, the state acquisition instruction unit 212 may directly instruct the operation terminal 110 to acquire the processing state S1. The state acquisition unit 213 may directly acquire the processing state S1 from the operation terminal 110. Similarly, the image acquisition instruction unit 223 may directly instruct the operation terminal 110 to acquire the image M1. The image acquisition unit 225 may acquire the image M1 directly from the operation terminal 110. The list acquisition instruction unit 233 may directly instruct the operation terminal 110 to acquire the machining program list PL1. The list acquisition unit 235 may directly acquire the machining program list PL1 from the operation terminal 110. The internal acquisition instruction unit 243 may directly instruct the operation terminal 110 to acquire the internal information SR1 of the dental processing machine 100. The internal acquisition unit 245 may directly acquire the internal information SR1 of the dental processing machine 100 from the operation terminal 110.

1 Status display system 5 Work piece 100 Dental processing machine 110 Operation terminal 120 Server (storage device)
200 Status display device 212 Status acquisition instruction unit 213 Status acquisition unit 215 State creation unit 223 Image acquisition instruction unit 225 Image acquisition unit 235 List acquisition unit 245 Internal acquisition unit 251 Display processing unit M1 Image S1 Processing status SL1 Status list

Claims (11)

A state acquisition unit that acquires the processing state for each of multiple dental processing machines,
A state creation unit that creates a state list indicating the processing state of each of the plurality of dental processing machines acquired by the state acquisition unit, and a state creation unit.
Image acquisition that acquires the image taken by the photographing apparatus, which is an image of the processing space in which the workpiece in one of the dental processing machines selected by the user is processed. Department and
The state list created by the state creation unit, a display processing unit that displays the image acquired by the image acquisition unit, and a display processing unit.
A status display device for dental processing machines equipped with. The state display device for a dental processing machine according to claim 1, wherein the processing state has at least an operating state, a non-operating state, and an error state. A list acquisition unit for acquiring a machining program list of a machining program executed by one of the dental machines selected by the user among the plurality of dental machines is provided.
The state display device for a dental processing machine according to claim 1 or 2, wherein the display processing unit displays the processing program list acquired by the list acquisition unit. It is provided with an internal acquisition unit that acquires internal information set in one of the dental processing machines selected by the user among the plurality of dental processing machines.
The state display device for a dental processing machine according to any one of claims 1 to 3, wherein the display processing unit displays the internal information acquired by the internal acquisition unit. The dental processing machine is
A tool gripper that grips the machining tool,
A spindle that rotates the tool grip and
A moving mechanism for moving the spindle and
And is configured to process the work piece,
A predetermined origin position is set on the spindle.
The inside information includes
The version of the firmware installed in the dental processing machine and
The operation information of the dental processing machine and
The correction value when the origin position of the spindle is adjusted and
The type of processing tool and
The type of work piece and
The error information of the dental processing machine and
The state display device for a dental processing machine according to claim 4, wherein at least one of them is included. The status display device according to any one of claims 1 to 5.
An operation terminal communicatively connected to the dental processing machine, the photographing device, and the status display device,
A storage device communicatively connected to the status display device and the operation terminal,
With
The status display device includes an image acquisition instruction unit that instructs the operation terminal to acquire the image of one of the dental processing machines selected by the user among the plurality of dental processing machines.
The operation terminal is
A terminal image acquisition unit that acquires the image instructed by the image acquisition instruction unit from the photographing device, and a terminal image acquisition unit.
A terminal transmission unit that transmits the image acquired by the terminal image acquisition unit to the storage device, and a terminal transmission unit.
With
The image acquisition unit is a state display system that acquires the image from the storage device. Display device and
The operation unit operated by the user and
With
The state display system according to claim 6, wherein the display processing unit displays at least the state list created by the state creation unit and the image acquired by the image acquisition unit on the display device. The state list displayed on the display device is configured so that one of the dental machines can be selected by the operation unit from the plurality of dental machines shown in the state list.
The claim that the image acquisition unit acquires the image of one dental processing machine selected by the user via the operation unit from the plurality of dental processing machines shown in the state list. The status display system according to 7. The state according to claim 7 or 8, wherein the display processing unit displays at least the state list created by the state creation unit and the image acquired by the image acquisition unit on the same screen. Display system. The display device displays a state update button for updating the state list displayed on the display device and an image update button for updating the image displayed on the display device.
When the state update button is pressed via the operation unit, the state acquisition unit acquires information on the processing state for each of the plurality of dental processing machines.
Any of claims 7 to 9, wherein the image acquisition unit acquires the image of one of the dental processing machines selected by the user when the image update button is pressed via the operation unit. The status display system described in one. The state display system according to any one of claims 6 to 10, further comprising the plurality of the dental processing machines.

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