JP7322217B2 - Information processing device, system, control method, program - Google Patents

Description

The present invention relates to an information processing apparatus, system, control method, and program for displaying information of a modeling apparatus that models a three-dimensional object.

A control device that forms a three-dimensional object based on model data is generally called a 3D (3-dimensional) printer, and 3D printers have rapidly spread in recent years. Techniques related to three-dimensional structures are also called additive manufacturing. On the other hand, a 2D (2-dimensional) printer is a printing device that prints two-dimensionally on paper (sheets) or the like.

3D printers have existed for a long time, but they have only been used in a limited number of industries and applications due to the fact that they are large devices, require dedicated/special equipment and materials, and are difficult to handle. . Due to recent technological innovations, various modeling methods such as Fused Deposition Modeling (FDM) have been devised and put into practical use. Other modeling methods include a stereolithography (STL) method, a selective laser sintering (SLS) method, an inkjet method, and the like. In addition, a wide range of 3D printers are provided, from inexpensive 3D printers that can be used by general consumers to high-performance commercial 3D printers for manufacturers and companies in various industries.

When a user wants to purchase a 3D printer, he/she selects the model of the 3D printer from the product list displayed on the website of the 3D printer manufacturer or agent, and confirms the specifications etc. on the detailed screen of the selected model. At this time, in order to make it easier for the user to select the model that meets his or her needs, the product list is narrowed down based on the conditions specified by the user. After that, the user makes an inquiry regarding the purchase of the 3D printer that the user is considering purchasing from the inquiry form on the website, and the user consults with the person in charge of the manufacturer or agency to purchase the 3D printer.

In addition, as an optional product separate from the main body of the 3D printer, additional equipment is required to perform post-processing and processing to support the operation of the 3D printer depending on the modeling method. For example, in the case of stereolithography, a modeled object is formed in a semi-cured state, in which the modeled object is partially cured. After modeling, the modeled object is washed to remove excess resin from the surface, and after the cleaning is completed, the modeled object is subjected to a final hardening treatment. In other words, in the stereolithography method, it is essential to use additional equipment such as a cleaning device for cleaning the modeled object and a post-curing device for applying a final hardening treatment to the modeled object. On the other hand, an uninterruptible power supply is sometimes used in case of power outages that may occur during long build times on a 3D printer, but the use of an uninterruptible power supply is not essential.

Japanese Patent Application Laid-Open No. 2002-200002 describes a system that presents the optimum product determined according to the usage history of the printer used by the user. In this system, when calculating the average number of sheets per month, the obtained number of sheets printed for each paper size can be used to recommend an image forming apparatus and optional products to the user according to the number of sheets printed for each paper size.

JP-A-2003-108344

As for 3D printers, a system is assumed in which users specify conditions related to 3D printers, such as modeling methods, types of modeling materials, and prices, and present information such as models that meet the conditions. However, when actually purchasing, after meeting with the person in charge of the manufacturer or agency, as a result, additional equipment will be purchased along with the 3D printer, and the purchase cost may be higher than originally planned. It can happen. In addition, it may happen that the necessary conditions (area, environment, etc.) of the installation site are not satisfied. Therefore, the user needs to refer to the product catalog to obtain information on the additional equipment required or recommended for the 3D printer, which is troublesome. Patent Literature 1 does not consider 3D printers.

In order to solve the above problems, the present invention provides a system including a server and an information processing device capable of communicating with the server,
the server has transmission means for transmitting screen information based on a request from the information processing device;
The information processing apparatus includes receiving means for receiving screen information from the server, a first screen on which a user can specify search conditions based on the screen information received from the server, and a modeling apparatus that satisfies the search conditions by the user. a second screen that is displayed in an identifiable state;
When the user specifies, as the search condition, a condition related to the thickness of each layer of the modeling material that is stacked when the modeling apparatus models the three-dimensional object on the first screen, the display control means controls the display control means as specified by the user. The second screen is controlled so that the molding apparatuses satisfying the search condition related to the thickness are displayed in a state identifiable by the user.

According to the present invention, the information processing device can display the information of the modeling device that satisfies the search condition regarding the thickness of each layer of the modeling material that is stacked when the modeling device models the three-dimensional object.

It is a figure which shows the example of the system configuration|structure which concerns on embodiment of this invention. It is a figure which shows the example of an information processing function hardware configuration. It is a figure which shows the software of this system, and the example of a hardware configuration. FIG. 10 is a diagram showing an example of a 3D printer display screen UI; 4 is a diagram showing an example of a table for managing product data 361. FIG. 10 is a flowchart showing an example of the flow of processing by a narrowing down execution unit 352; FIG. 11 is a flowchart showing an example of a flow of narrowing down processing based on the area of an installation location; FIG. FIG. 10 is a diagram showing an example of a 3D printer details screen UI; 8 is a flow chart showing the flow of processing for displaying essential additional equipment 810 and recommended additional equipment 820 on the 3D printer details screen 800 in Embodiment 1. FIG. 10 is a flow chart showing the flow of processing for displaying essential additional equipment 810 and recommended additional equipment 820 on the 3D printer details screen 800 in Example 2. FIG. 4 is a flow chart showing an example of the flow of display on a display screen 400 for 3D printer information.

BEST MODE FOR CARRYING OUT THE INVENTION The best mode for carrying out the present invention will be described below with reference to the drawings.

(Example 1)
FIG. 1 illustrates an example system configuration of a display system according to an embodiment of the present invention.

Network 101 is a network such as an intranet or a local area network (LAN). The computer 102 is a client computer in which control software for giving instructions to the 3D printer 104 and the like is installed. The computer 103 has a web browser capable of connecting to external web services and operating web applications.

The 3D printer 104 is an example of a control device that forms a three-dimensional object based on model data. The additional equipment 105 is equipment or equipment that performs necessary processing during or after modeling by the 3D printer 104 . Examples of devices that perform necessary processing after modeling include a cleaning device that cleans a modeled object modeled by the 3D printer 104, a device that cleans the modeling table of the 3D printer 104, and the like. Examples of devices that perform necessary processing during modeling include an uninterruptible power supply that allows modeling to continue in the event of a power failure during modeling, and an air conditioning system that prepares the environment for the installation location of the 3D printer. and so on. Also, the computer 106 is a management device on which the 3D printer management application 340 operates.

The computers 102, 103, and 106 are classified into personal computers (PCs), tablet computers, smart phones, and the like. The 3D printer 104 and the computers 102 , 103 and 106 can mutually transmit and receive information via the network 101 . Note that the network 101 may be a wireless network such as a wireless LAN. Also, the network 101 may be a public network such as the Internet as long as it is possible to transmit and receive information. Note that the control software includes control software for giving instructions to the 3D printer 104 and control software for giving instructions to the additional equipment 105, and these software may be installed in different computers.

FIG. 2 is a diagram showing a hardware configuration example of the information processing functions of the computers 102, 103, 106, 3D printer 104, and additional equipment 105. As shown in FIG. In the 3D printer 104 and the additional equipment 105, the configuration of the embedded computer shown in FIG. 3, which will be described later, corresponds to the hardware of the information processing function shown in FIG.

A user interface (hereinafter referred to as UI) 201 inputs and outputs information and signals through a display, keyboard, mouse, touch panel, buttons, and the like. Computers without such hardware can be connected to and operated from other computers using remote desktop or remote shell.

A network interface 202 connects to a network such as a LAN and communicates with other computers and network devices. The ROM 204 stores embedded programs and data. RAM 205 is a temporary memory area. The secondary storage device 206 is an HDD, flash memory, or the like. The CPU 203 executes programs read from the ROM 204, the RAM 205, the secondary storage device 206, and the like. The units 201 to 206 described above are connected via an internal bus 207 .

The 3D printer 104 further has a hardware configuration according to the modeling method. The hardware configuration according to the modeling method is specifically the engine section of the 3D printer 104 . The engine section has a storage device such as a CPU, ROM, and RAM, as well as hardware corresponding to the modeling method controlled by the CPU. For example, in the case of the fused lamination method, the hardware includes a print head (head, extruder), a motor that drives the stage and print head in the X, Y, and Z axis directions, a heater that heats the nozzles of the print head, cooling and air intake. , fans for exhaust, etc. Other modeling methods include, for example, an optical modeling method, a powder sintering method, an inkjet method, and the like. The 3D printer 104 also includes a plurality of sensors (not shown) for detecting status. A specific example of a sensor is a temperature sensor for detecting the temperature status of the print head.

FIG. 3 is a diagram showing an example of the software configuration and hardware configuration of the system in the first and second embodiments.

In this embodiment, a configuration is described in which different computers create processing instructions for the 3D printer and additional equipment, manage the 3D printer and additional equipment, and access the web server unit 351 of the computer 106 . However, a configuration in which each process is processed by one computer may be adopted.

First, the configuration of the computer 102 will be described. The control software 301 is software installed and executed in the computer 102 . The control software 301 is software including settings related to modeling and functions for generating control instructions to be executed by the 3D printer. Software that generates control instructions for a 3D printer includes software called a slicer, for example.

The control software 301 also includes a function of setting the additional equipment 105 and a function of generating a control command for executing a process in the additional equipment 105 . Note that the function of generating the control command for the 3D printer and the function of generating the control command for the additional equipment may be included in different control software. Further, if the control software 301 does not have a function of generating a control command for the additional equipment, the 3D printer may instruct the additional equipment to perform the processing.

The setting information 302 is setting information related to modeling set by the control software 301 or the like. Setting items related to modeling include, for example, the model name of the 3D printer used for modeling, the temperature of components such as the print head, the type and name of the material to be used, and the filling pattern.

The 3D model data 303 is model data representing a three-dimensional shape of an object that the user desires to model. The 3D model data 303 is, for example, data represented by STL (STereo Lithography), which is a file format for storing data representing a three-dimensional shape.

A control command 304 is a control command generated by the control software 301 based on the 3D model data 303 or the like. The control instructions 304 include control instructions for modeling an object with the 3D printer 104 and control instructions for performing post-processing and the like with additional equipment. As a control command for the 3D printer 104, for example, a format obtained by extending a machine tool command called G-code for a 3D printer is used. The control software 301 converts the 3D model data 303 into control instructions (3D printer) 304 executable by the 3D printer 104 based on the setting information 302 .

Note that the 3D printer control instructions generated by the control software 301 include not only the object, which is the modeled part represented by the 3D model data, but also information about the modeling of support structures necessary for modeling.

Next, the configuration of the computer 103 will be explained. The web browser 310 transmits a request message to the web server unit 351 that provides web services. After that, the web browser 310 receives the response message sent from the web server unit 351 and displays a screen based on the received data. As a result, the user can view product data of 3D printers and additional equipment that match the entered conditions.

Next, the configuration of the 3D printer 104 will be described. Embedded computer 320 is a computer embedded in 3D printer 104 . The embedded computer 320 is manufactured at a low cost by specializing necessary functions and eliminating unnecessary functions, performance, and parts compared to a general-purpose computer. Note that the embedded computer 320 may be a general-purpose computer depending on the functions and performance required of the 3D printer.

Control application 321 is an application that runs on embedded computer 320 . The control application 321 includes a UI 325 , an API (Application Programming Interface) 326 and a hardware control section 327 .

The UI 325 may be a combination of a display displaying only several lines of characters and a hardware operation button for an inexpensive one, or a display with a touch panel for an expensive one. The status of the 3D printer is confirmed by the display contents of the UI 325, and the desired processing is commanded to the 3D printer by operating the UI 325.

The API 326 accepts commands and data transmission/reception from the external computers 102 and 106 . Commands are sent from the external computers 102 and 106 to the 3D printer control application 321 via the API 326 to control the 3D printer 104 .

The hardware control unit 327 operates each unit that constitutes hardware (not shown) according to commands received via the UI 325 and API 326 and commands issued by the 3D printer control application 321, and outputs a modeled object. . The hardware that makes up a 3D printer differs depending on the modeling method.

A 3D printer control instruction 304 generated by the control software 301 described above is sent to the control application 321 via the network 101 and the API 326 . At this time, the control command 304 may be sent via the computer 106 . Also, when the 3D printer 104 does not have a network interface, the control command 304 may be sent to the control application 321 via a storage device such as a USB memory.

The control application 321 interprets the control instruction 304 according to the output instruction from the UI 325 or API 326, and the hardware control section 327 operates each hardware section to execute modeling.

The error information 323 is an error in which, when a specific state or failure is detected within the 3D printer 104 according to the definition unique to the 3D printer 104, output management such as the content and notification method is performed according to the definition of the 3D printer 104. It is information indicating Instead of the 3D printer 104 outputting an error, an error in the 3D printer 104 may be detected by a management application running on the computer 106 based on status information included in the device information 324 (to be described later).

The device information 324 is device information of the 3D printer 104 including identification information and status information of the 3D printer 104 . The device information 324 includes information for determining the operating state and operating rate of the 3D printer. The information for determining the operating state includes the status of the 3D printer (operating, preparing, waiting, sleeping, error, etc.), status log information, and the like. The information for determining the operating rate includes status logs, history information including power-on time, operating time, error (failure) occurrence time, and the like.

As the device information 324, information that can be acquired by a protocol common to many models of 3D printers defined by IPP (Internet Printing Protocol) will be described as an example. IPP is a protocol for transmitting and receiving print (modeling) data and monitoring a modeling apparatus that operates on a general-purpose communication protocol. Also, other protocols that have equivalent information acquisition definitions can be substituted. The present invention can also use device information defined by other protocols in addition to IPP, and the device information 324 may include information defined by those protocols. As a result, for example, information defined by IPP that is not supported by the model and status information undefined by IPP can be analyzed by the 3D printer management application 340 .

In this example, device information 324 is obtained from 3D printer 104 by management application 340 . However, device information 324 may not necessarily be obtained from 3D printer 104 , for example, device information 324 may be obtained from computer 102 .

Next, the configuration of the additional equipment 105 will be described. Embedded computer 330 is a computer embedded in additional equipment 105 . The embedded computer 330 is manufactured at a low cost by specializing necessary functions and removing unnecessary functions, performance, and parts compared to a general-purpose computer. Note that the embedded computer 330 may be a general-purpose computer depending on the functions and performance required for the additional equipment.

Control application 331 is an application that runs on embedded computer 330 . The control application 331 includes a UI 335 , an API (Application Programming Interface) 336 and a hardware control section 337 . The additional equipment 105 may not have the UI 335 or the API 336 . In the case of inexpensive additional equipment, the user switches the power supply to activate the additional equipment. Of course, like the 3D printer 104, the control command 304 may be interpreted by the processing command from the UI 325 or API 326, and the hardware control unit 327 may operate each hardware unit to perform processing.

The device information 332 is device information including identification information and operation information of the additional equipment 105 . Any protocol may be used as long as the device information can be acquired. The device information 332 includes information that can identify the operating state and operating rate of the additional equipment. For example, the information that can identify the operating state is, for example, the status of the additional equipment (operating, preparing, waiting, sleeping, in error, etc.), status log information, and the like. The information that can identify the operating rate includes the power-on time, operating time, failure occurrence time, number of times of use, and the like.

In this example, device information 332 is obtained from additional equipment 105 by management application 340 . However, device information 332 need not be obtained from additional equipment 105 , for example, device information 332 may be obtained from computer 102 .

Next, the configuration of computer 106 will be described. Computer 106 includes management application 340 , display application 350 and database 360 . In this embodiment, a configuration in which the management application 340, the display application 350, and the database 360 are provided in one computer will be described, but the present invention can also be applied to a configuration in which they are arranged in different computers. .

The management application 340 is an application that acquires device information and error information from the 3D printer 104 and the additional equipment 105 and manages them, and is executed on the computer 106 .
Management application 340 includes data acquisition unit 341 , data management unit 343 , and data transmission unit 345 .

The data acquisition unit 341 has an interface for acquiring device information, error information, and the like from the 3D printer 104 and the additional equipment 105 . The data acquisition unit 341 acquires various types of information from the 3D printer 104 and the additional equipment 105 periodically or according to a predetermined schedule. Note that the management application 340 may acquire information input by the user from the screen UI of the computer as the device information of the 3D printer 104 and the additional equipment 105 .

The data management unit 343 manages information on the 3D printers to be managed, and error information 323 and device information 324 on the managed devices acquired by the data acquisition unit 341 . The data management unit 343 stores information on additional equipment to be managed and device information 332 of the additional equipment to be managed acquired by the data acquisition unit 341 . Furthermore, the data management unit 343 manages identification information of users who have already been registered as users, information on 3D printers owned by the users, and information on additional equipment.

The data transmission unit 345 transmits 3D printer information upon request. For example, if the data transmission unit 345 receives information on a specific 3D printer, it returns information on the specified 3D printer, otherwise it returns a list of 3D printers to be managed. Further, the data transmission unit 345 transmits information on additional equipment upon request. For example, when the data transmission unit 345 receives information on a specific additional facility, it returns the information on the specified additional facility, otherwise it returns a list of additional facilities to be managed.

The display application 350 is an application that displays 3D printer information on a UI screen in response to a request from the web browser 310 or the like, and is executed on the computer 106 . The display application 350 includes a web server section 351 , a narrowing down execution section 352 , a product data API 353 and a managed device API 355 .

The web server unit 351 operates as a web server and provides web pages such as a 3D printer information display screen 400 shown in FIG. 4, which will be described later. On the 3D printer information display screen 400 shown in FIG. 4, information on the 3D printer is displayed. The web server unit 351 has a function as an HTTP service that receives a request message from the web browser 310, which is a client, and executes processing according to the request message. Specifically, the web server unit 351 receives a URL as a request message, analyzes the URL, and calls the corresponding web application along with the request according to the request. Here, the request message is specifically an HTTP request message, and can include parameter values from the web browser linked to the URL.

The narrow-down execution unit 352 performs narrow-down processing of 3D printers according to the conditions set by the narrow-down condition setting unit 420 or the narrow-down conditions dynamically created by the program, and sends information of the 3D printers satisfying the conditions to the web browser 310. return.

The product data API 353 acquires information on 3D printers and additional equipment from the product data 361 of the database 360 .

The managed device API 355 has an interface that calls the data transmission unit 345 of the management application 340 and acquires information on the 3D printers and additional equipment managed by the data management unit 343 of the management application 340 .

The database 360 manages product data 361 of the 3D printer 104 and the additional equipment 105 . Note that each product data may be updated by the administrator from a screen UI provided by a web browser (not shown) in this embodiment. Product data 361 is detailed information about the 3D printer and additional equipment.

FIG. 4 is a diagram showing an example of a 3D printer information display screen UI provided by the computer 106. As shown in FIG. The display screen 400 can be viewed by accessing the web server unit 351 of the computer 106 from the web browser 310 of the computer 103 .

The display screen 400 includes a list display section 410 for displaying a list of data held by the computer 106 and a narrowing condition setting section 420 for narrowing down the required 3D printers from among the 3D printers displayed in the list.

A list of 3D printers registered in the database 360 is displayed in the list display section 410 . When a narrowing-down condition is input to the narrowing-down condition setting portion 420 , 3D printers that match the set narrowing-down condition are displayed in the list display portion 410 . Note that the display method of the list display unit 410 may be such that all 3D printers are always displayed and 3D printers that do not meet the narrowing-down conditions are grayed out.

The narrowing-down condition setting section 420 is a field for allowing the user to specify a narrowing-down condition for narrowing down the 3D printers displayed in the list display section 410 . The narrowing down conditions include the following items, and the user specifies one or more of these conditions. As for the method of inputting the narrowing conditions, a text box may be prepared for free input, or a check box or dropdown may be prepared so that the user can make a selection.

Manufacturer: Manufacturer name of the 3D printer.
Usage: Classification according to usage of objects that are created by 3D printers. For example, "design confirmation", "design/function evaluation", "jig/mold/production equipment", etc. can be mentioned.
Material: Classification by material of modeling materials that can be used for modeling with a 3D printer. For example, types such as "resin", "rubber", "gypsum", and "metal" can be mentioned.
Material properties: A classification based on the properties of materials that can be used by 3D printers. For example, "heat resistance", "durability", "impact resistance", "transparency", etc. can be mentioned.
Lamination pitch: Lamination pitch that can be selected by 3D printers.
Modeling method: Classification of the modeling method of 3D printers. For example, the "thermal fusion lamination method", the "stereolithography method", the "powder sintering method", the "ink jet method", and the like can be mentioned.
Model size: The size of an object that can be modeled by a 3D printer.
Modeling speed: Information on the speed at which a 3D printer models a modeled object. For example, head speed information can be given.
Noise level: Information on the volume (dB) of the sound emitted by the 3D printer during modeling.
Support material: Information on the necessity of support material when creating a modeled object. Alternatively, information on the availability of water-soluble support materials.
Hollow Structure Manufacturability: Information on whether or not a hollow structure model can be manufactured.
Number of Heads: The number of printer heads in the 3D printer.
Color: Single color, two colors, and color information. Alternatively, information on whether or not a modeled object of the specified color can be modeled by selecting a color (transparent, white, blue, red, etc.).
Price: The purchase price of the 3D printer.
Environment of installation site: Information about the environment of the installation site required when installing the 3D printer. Additional equipment for adjusting the environment of the installation site based on the conditions specified here includes, for example, air conditioning equipment and equipment for removing or reducing vibration.
Area of installation site: Information on the area of the site required to install and use the 3D printer.

In this embodiment, FIG. 4 exemplifies the narrowing-down conditions in which the conditions of "manufacturer", "application", "material", "layer pitch", "modeling size", "price", and "installation area" can be input. Note that the area of the installation location may be information about the space required for using the 3D printer and additional equipment. In that case, not only the area but also the height information will be included.

Note that the 3D printers may be narrowed down by specifying conditions related to additional equipment. Conditions related to the additional equipment include, for example, the type of processing performed by the additional equipment such as cleaning and curing, and the model of the additional equipment. Further, the items of the narrowing-down conditions may be selectable by the user himself or may be prepared by using tabs to prepare a plurality of patterns according to the characteristics of narrowing-down. For example, narrowing down items corresponding to the characteristics of each manufacturer or molding method may be prepared.

FIG. 5 is an example of a table for managing product data 361 of 3D printers and additional equipment in this embodiment. FIG. 5 shows information necessary for narrowing down on the 3D printer display screen shown in FIG. Items not shown in FIG. 5 may be added to the product data 361 according to settable narrowing conditions. Using the information in the table shown in FIG. 5, a display screen UI shown in FIG. 4, which will be described later, is provided.

First, a table for managing the product data 361 of the 3D printer will be described with reference to FIG. 5(a).

Name 501 is the 3D printer name. The 3D printer name can uniquely identify the 3D printer. If the 3D printer name is not unique, a separate ID column may be prepared. Maker502 is the name of the manufacturer of the 3D printer. The modeling method 503 is information representing the type of modeling method of the 3D printer. The purpose 504 is information indicating the purpose of use of the object formed by the 3D printer. The lamination pitch 505 is information on the lamination pitch printable by the 3D printer. The maximum modeling size 506 is information on the maximum size that can be modeled by the 3D printer. A price 507 is the price of the 3D printer. Body size 508 is the size of the 3D printer. Required additional equipment 509 is information of Type 522 of additional equipment required when introducing a 3D printer. Recommended additional equipment 510 is information of Type 522 of additional equipment that is recommended to be purchased together when introducing the 3D printer. The recommended installation area 511 is information on the recommended area for installing the 3D printer. This is information considering the area required for opening and closing a 3D printer whose cover or the like needs to be opened and closed for maintenance or the like. Also, the recommended installation area 511 is information indicating an area in which installation of additional equipment is also taken into consideration.

Next, a table for managing the product data 361 of additional equipment will be described with reference to FIG. 5(b).

Name 521 is the name of additional equipment. The additional equipment name can uniquely identify the additional equipment. If the accessory device name is not unique, a separate ID column may be prepared. Type 522 is information representing the type of additional equipment. For example, there are "cleaning equipment", "ultrasonic cleaning equipment", "curing equipment", and "uninterruptible power supply". A price 523 is the price of the additional equipment. The processable size 524 is a size that can be processed by additional equipment. A value of the processable size 524 is set for additional equipment that performs post-processing of a modeled object formed by a 3D printer. The body size 525 is the size of the additional equipment.

FIG. 6 is a flowchart showing the flow of processing by the narrowing-down execution unit 352. As shown in FIG. In this embodiment, the computer 106 performs the narrowing down process based on a request from the web browser 310. However, the information necessary for the narrowing down process is sent from the web server unit 351 to the web browser 310, and the browser side dynamically You can narrow down.

In S601, the product data API 353 is called to obtain a product data list of 3D printers that are display candidates.

In S602, a narrowing-down condition for narrowing down the product data of the 3D printers acquired in S601 is acquired. The narrowing conditions are conditions set by the narrowing condition setting unit 420 .

In S<b>603 , the managed device API 355 is called to acquire information on the 3D printers managed by the management application 340 .

In steps S604 to S606, processing for narrowing down products that match the conditions from the product list for each narrow-down item that meets the specified conditions is performed. In S605, the 3D printer narrowing process is executed using the product data of the 3D printers acquired in S601, the narrowing conditions acquired in S602, and the information of the managed 3D printers acquired in S603. The narrowing down process is performed for each narrowing down item for the product data of the 3D printer acquired in S601. When the processing for all the designated items is completed, the processing advances to S607.

In the present embodiment, a detailed description will be given of an installation area narrowing process with reference to the flowchart of FIG. 7, which will be described later. In this embodiment, the product data of the 3D printer acquired in S601 is narrowed down for each narrowing-down item. may

In step S<b>607 , the web server unit 351 generates screen information including information on the narrowed-down 3D printers, and outputs the screen information to the web browser.

In FIG. 7, the narrowing down processing of S605 will be described by taking the installation area narrowing down processing as a specific example. FIG. 7 is a flowchart showing an example of the flow of processing for narrowing down the installation area. In S701 to S708, processing is executed for all 3D printers in the 3D printer list acquired in S601.

In S702, if the information of the recommended installation area 511 is registered in the acquired information of the 3D printer, the process proceeds to S706, and if the information of the recommended installation area 511 is not registered, the value of the recommended installation area is calculated. Proceed to S703.

In S703, when the information of the required additional equipment 509 is registered in the acquired information of the 3D printer, the process advances to S704 to acquire the information of the additional equipment from the product data API 353. If the information of the required additional equipment 509 is not registered, the process proceeds to S704.

At S704, a product data list of additional equipment is obtained.

In S705, if the body size 508 of the 3D printer and the product data of the additional equipment are obtained in S704, the recommended installation area is calculated based on the information of the body size 525 of the additional equipment. Specifically, the area required for the use of the 3D printer and additional equipment is summed up. In addition, the recommended installation area calculated here is information that takes into consideration the space required for opening and closing a 3D printer whose cover or the like needs to be opened and closed for maintenance or the like. Specifically, it is calculated by a method such as adding a predetermined area that allows opening and closing of a cover or the like.

In S706, the recommended installation area 511 of the 3D printer information or the recommended installation area calculated in S705 is compared with the installation area set by the narrowing-down condition. As a result of the comparison, if the recommended installation area exceeds the setting value of the narrowing-down condition, the process proceeds to S707, and the 3D printer is deleted from the 3D printer display candidates. If the recommended installation area does not exceed the set value in the narrowing down condition, proceed to the next process.

Note that the calculation of the recommended installation area may be set to be executed regardless of the presence or absence of information on the recommended installation area 511 in the product data of the 3D printer using a setting screen (not shown) in this embodiment. In this embodiment, the 3D printer 104 and the required additional equipment 509 are included in the calculation of the installation area. may

Furthermore, although FIG. 7 shows the flow of processing for narrowing down by installation area, processing for narrowing down by purchase price may also be performed. It is determined whether or not the sum of the purchase price of the 3D printer and the purchase price of the additional equipment satisfies the purchase price condition specified by the user.

FIG. 8 is an example of a 3D printer details screen 800 displayed when a specific 3D printer displayed in the list display portion 410 of the 3D printer information display screen 400 is selected. It is characterized in that information of additional equipment 105 related to the selected 3D printer 104 is displayed. Here, additional equipment that must be used and recommended additional equipment are displayed separately.

In this embodiment, when a 3D printer displayed in the list display section 410 of the 3D printer information display screen 400 is selected, the screen transitions to the 3D printer details screen 800, but the information may be displayed in another method. . For example, when the cursor is placed on the 3D printer in the list display section 410, information on additional equipment may be displayed in a tooltip.

Required additional equipment 810 is a space for displaying additional equipment that is essential when installing the selected 3D printer. In this embodiment, spec information 811 and an image 812 of the corresponding additional equipment are displayed. If there is no mandatory additional equipment, the mandatory additional equipment 810 may not be present.

Recommended additional equipment 820 is a space for displaying additional equipment that can be installed when installing the selected 3D printer. In this embodiment, spec information 821 and an image 822 of the corresponding additional equipment are displayed. If there is no recommended additional equipment, the recommended additional equipment 820 may not exist.

FIG. 9 is a flow chart showing the flow of processing for displaying the required additional equipment 810 and recommended additional equipment 820 on the 3D printer details screen 800 . It is a flow until the web server unit 351 receives a request from the web browser 310 and returns a response.

In S901, the product data API 353 is called to obtain a product data list of additional equipment.

At S902, a list of additional equipment is created. The list of additional equipment is a list for storing information of additional equipment to be displayed, and is held in the RAM 205 of the computer 106 .

In S903, the required additional equipment 509 is acquired from the information of the selected 3D printer, and if the value exists, the process proceeds to S904. If the value does not exist, proceed to S905.

In S904, the product data of the additional equipment acquired in S901 is searched for additional equipment that satisfies the conditions, and added to the list prepared in S902. The search adds additional equipment to the list that matches the required additional equipment 509 and Type 522 of the 3D printer and that the maximum modeling size 506 of the 3D printer is smaller than the processable size 524 of the additional equipment.

In S905, the recommended additional equipment 509 is acquired from the information of the selected 3D printer, and if the value exists, the process proceeds to S906. If the value does not exist, the process proceeds to S907.

In S906, additional equipment that meets the conditions is searched from the product data of the additional equipment acquired in S901, and added to the list prepared in S902. Here, the additional equipment that matches the recommended additional equipment 509 of the 3D printer and the Type 522 and that satisfies the condition that the maximum modeling size 506 of the 3D printer is smaller than the processable size 524 of the additional equipment is added to the list.

In S907, the web server unit 351 generates screen information based on the list of additional equipment and transmits the screen information to the web browser.

In this example, based on the conditions specified by the user, a 3D printer that meets the conditions was presented, including additional equipment that performs necessary processing during or after modeling with the 3D printer. In particular, we presented information on the area required for installing and using 3D printers, etc., and additional equipment that must be used. As a result, it is possible to present the information of the control device that satisfies the conditions specified by the user in consideration of the additional equipment.

(Example 2)
In Example 1, narrowing down based on additional equipment and display of the 3D printer details screen 800 were performed. However, in an environment where 3D printers have already been introduced, there are cases where 3D printers and additional equipment are replaced or additionally purchased. In such a case, the user has to compare the product specifications of the products that have already been introduced and select the product by himself in consideration of the usage situation so far, which takes a lot of time and effort.

In the second embodiment, the 3D printer information display screen 400 and the 3D printer details screen 800 are displayed in consideration of the 3D printers and additional equipment owned by the user. In Example 2, the user can easily select the 3D printer and additional equipment that the user needs. In the second embodiment, the points different from the first embodiment will be mainly described.

FIG. 10 is a flowchart showing the flow of processing for displaying the required additional equipment 810 and recommended additional equipment 820 on the 3D printer details screen 800 illustrated in FIG. In this embodiment, the information to be displayed in the required additional equipment 810 and the recommended additional equipment 820 is dynamically determined in consideration of the information on the additional equipment already possessed by the user. Here, only parts different from FIG. 9 will be described.

In S1001 to S1005, the process is repeated by the number of additional facilities added to the list prepared in S902.

In S1002, the managed device API 355 is called, and the device information 332 of the additional equipment to be managed is acquired using the Name 521 as a key. At this time, the information of the additional equipment that matches the identification information of the user who specified the condition via the information display screen 400 of the 3D printer is acquired.

In S1003, it is determined whether or not the user owns the additional equipment with respect to the information on the additional equipment acquired in S1002. If the user owns the additional equipment, the process proceeds to S1004. On the other hand, if the user does not own the additional equipment, the process proceeds to S1005.

At S1004, the additional equipment is deleted from the list.

Instead of the process of S1003, or in addition to the process of S1003, a process different from S1003 for determining whether or not the additional equipment is to be replaced may be executed. For example, using the operation information included in the device information 332, if the operating rate of the additional equipment is above a certain level, the additional equipment may be deleted from the list.

When the processing for all the additional equipment on the list is finished, the processing of S1001 to S1005 is finished and the processing proceeds to S907.

In this embodiment, when the user does not own the additional equipment to be managed, the information of the additional equipment is presented. This makes it easier for the user to choose which additional equipment to purchase.

(Example 3)
In the second embodiment, information on additional equipment owned by the user is not presented. In this embodiment, information about the 3D printer and additional equipment owned by the user is presented when the operating rate thereof exceeds a certain level.

FIG. 11 is a flow chart showing the flow of displaying the 3D printer information display screen 400 . It is a flow until the web server unit 351 receives a request from the web browser 310 and returns a response corresponding to the request.

In S1101, the product data API 353 is called to obtain a list of 3D printer product data.

In S1102, the managed device API 355 is called and the device information 324 of the 3D printer managed by the management application 340 is obtained.

In S1103, if the information of the 3D printer to be managed can be acquired in S1102, the process proceeds to S1104. If there is no 3D printer to be managed, the process proceeds to S1112.

At S1104, an empty list is created that stores information about 3D printers that are candidates for replacing 3D printers. This list is held in RAM 205 of computer 106 .

In S1105, with respect to the information of the 3D printers to be managed acquired in S1102, it is determined whether the operation rate exceeds the threshold value or whether there are any 3D printers among these 3D printers. For a 3D printer whose operation rate exceeds the threshold, in S1106, information about the 3D printer is added to the list created in S1104. If there is no 3D printer whose operating rate exceeds the threshold, the process proceeds to S1107.

In this embodiment, the operating rate is calculated using the status included in the device information 324 of the 3D printer acquired from the 3D printer. For example, the operating rate can be obtained by dividing the time during which the status is operating by the total time. Here, the total time may be 24 hours or the time during which the 3D printer is running. A method for calculating the operating time may be standardized in the monitoring system, or may be set for each user.

In S1107, if there is a printer in which an error occurs more than a certain number of times within a certain period of time among the managed 3D printers acquired in S1102, the process proceeds to S1108, and the information of the 3D printer is added to the list. If there is no printer in which errors occur a specific number of times within a certain period of time, the process advances to S1109.

Note that the threshold value, period, number of times, and the like used in S1105 and S1107 may be determined in advance by a program, or may be set by the user by preparing a setting screen (not shown).

In S1109, if the list contains 3D printer information, the process proceeds to S1110, and if the list is empty, the process proceeds to S1112.

In S1110, information for each narrowing-down item is acquired from the device information added to the list, and a narrowing-down condition is created.

In S1111, the narrow-down execution unit 352 executes narrow-down processing on the list of 3D printers acquired in S1101 based on the narrow-down conditions created in S1110.

In S1112, screen information for displaying a list of 3D printers in the list display section 410 of the 3D printer information display screen 400 is generated and output to the web browser. Here, the list of 3D printers is a list of 3D printers acquired in S1101 and narrowed down according to the status of managed 3D printers.

In this embodiment, the operating rate of the 3D printer is used when determining whether or not to display information on the 3D printer as a replacement target. As for the additional equipment, the operation rate may be used to determine the narrowing down. As a result, the user can grasp the 3D printer to be replaced, and can easily select the 3D printer to purchase.

(Other examples)
The present invention also includes an apparatus or system configured by appropriately combining the first, second, and third embodiments described above, as well as its method.

Here, the present invention is a main device or system that executes one or more software (programs) that realize the functions of the above-described embodiments. A method for realizing the above-described embodiments executed by the device or system is also one aspect of the present invention. Also, the program is supplied to a system or device via a network or various storage media, and is read and executed by one or more computers (CPU, MPU, etc.) of the system or device. In other words, one aspect of the present invention includes the program itself or various computer-readable storage media storing the program. The present invention can also be realized by a circuit (for example, an ASIC) that implements the functions of the above-described embodiments.

103, 106 computer 350 display application 351 web server unit 352 refinement execution unit

Claims (16)

A system comprising a server and an information processing device capable of communicating with the server,
The server is
a transmitting means for transmitting screen information based on a request from the information processing device;
The information processing device is
receiving means for receiving screen information from the server;
Based on the screen information received from the server, the information processing apparatus has a first screen on which the user can specify a search condition, and a second screen on which the user can identify the modeling apparatus that satisfies the search condition. and display control means for displaying on the display of
When the user specifies, as the search condition, a condition related to the thickness of each layer of the modeling material that is stacked when the modeling apparatus models the three-dimensional object on the first screen, the display control means controls the display control means as specified by the user. and controlling the second screen to display molding apparatuses that satisfy a search condition related to the thickness in a manner identifiable by the user. On the second screen, the information of the modeling apparatus that does not satisfy the search condition regarding the thickness specified by the user through the first screen is not displayed in a state that the user can select the information. 2. The system of claim 1, wherein information of modeling devices that satisfy a specified thickness search condition is displayed in a user-selectable manner. On the second screen, as information on the modeling apparatus that satisfies the search condition regarding the thickness specified by the user via the first screen, information on the additional equipment used when modeling the three-dimensional object with the modeling apparatus is further provided. 3. System according to claim 1 or 2, characterized in that it is displayed. 4. The system according to any one of claims 1 to 3, further comprising specifying means for specifying a modeling apparatus that satisfies a search condition regarding thickness specified by a user via said first screen. On the first screen, at least one of search conditions relating to modeling materials used for modeling a three-dimensional object, search conditions relating to the size of a three-dimensional object that can be shaped, search conditions relating to the price of a modeling apparatus, and search conditions relating to a modeling method. 2. The system of claim 1, further capable of accepting a specification of . The server specifies a modeling apparatus that satisfies a search condition regarding the thickness specified by the user via the first screen ,
2. The system according to claim 1 , wherein said display control means performs control so that said specified modeling apparatus is displayed on said second screen in a state identifiable by said user. On the second screen, the modeling apparatus that stacks the modeling material with the thickness per layer indicated by the condition specified by the user via the first screen as the search condition is displayed in a user-identifiable state. 7. A system according to any preceding claim, characterized in that: On the second screen, modeling apparatuses that do not satisfy the thickness condition specified by the user through the first screen as the search condition are not displayed. 8. The system of any one of claims 1 to 7, wherein modeling devices satisfying a condition regarding are displayed. 9. The second screen displays an image showing a molding apparatus satisfying a thickness-related condition specified by a user through the first screen as the search condition. 1. The system according to claim 1. A control method for a system including a server and an information processing device capable of communicating with the server,
Said server
a transmission step of transmitting screen information based on a request from the information processing device;
The information processing device is
a receiving step of receiving screen information from the server;
Based on the screen information received from the server, the information processing apparatus has a first screen on which the user can specify a search condition, and a second screen on which the user can identify the modeling apparatus that satisfies the search condition. and a display control step of displaying on the display unit of
When the user specifies, as the search condition, a condition related to the thickness of each layer of modeling material that is stacked when the modeling apparatus models a three-dimensional object on the first screen, the display control step controls the display control step to perform the search condition specified by the user. A control method, wherein control is performed such that a modeling apparatus that satisfies a search condition related to the thickness is displayed on the second screen in a state identifiable by the user. A program for causing an information processing device to execute a control method related to display based on screen information received from a server ,
The control method is
Based on the screen information received from the server, the information processing apparatus has a first screen on which the user can specify a search condition, and a second screen on which the user can identify the modeling apparatus that satisfies the search condition. having a display control step of displaying on the display of
When the user specifies, as the search condition, a condition related to the thickness of each layer of modeling material that is stacked when the modeling apparatus models a three-dimensional object on the first screen, the display control step controls the display control step to perform the search condition specified by the user. A program characterized by performing control to display on the second screen in a state identifiable by the user that a modeling apparatus that satisfies a search condition related to thickness. On the second screen, the information of the modeling apparatus that does not satisfy the search condition regarding the thickness specified by the user through the first screen is not displayed in a state that the user can select the information. 12. The program according to claim 11 , wherein the information of the modeling apparatus that satisfies the specified thickness-related search condition is displayed in a user-selectable state. 13. The program according to claim 11 , further comprising a specifying step of specifying a modeling apparatus that satisfies a search condition regarding thickness specified by the user via the first screen. displaying the first screen and the second screen based on the screen information received from the server by a web browser operating on the information processing device;
14. The web browser according to any one of claims 11 to 13 , wherein the display of the modeling apparatus that satisfies the search condition on the second screen in the display control step is dynamically executed by the web browser. 1. The program according to item 1. 12. The program according to claim 11, wherein on said first screen, it is possible to further receive, as said search condition, specification of a condition relating to a forming material used for forming a three-dimensional object. On the first screen, as the search conditions, it is possible to further accept specification of at least one of a search condition regarding the size of a three-dimensional object that can be shaped, a search condition regarding the price of a modeling apparatus, and a search condition regarding a modeling method. 12. The program of claim 11, wherein:

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