JP7320414B2 - 3D DATA DESIGNER SEARCH SYSTEM, 3D DATA DESIGNER SEARCH METHOD, AND PROGRAM - Google Patents

Description

TECHNICAL FIELD The present invention relates to a 3D data designer search system, a 3D data designer search method, and a program for searching for a designer of 3D data used to manufacture a modeled object using a 3D printer.

A 3D printer forms a modeled object, which is a three-dimensional object, by layering materials based on 3D data. 3D data representing the desired shape must be prepared when a 3D printer is used to produce a desired shape.

Japanese Patent Laying-Open No. 2017-146972 (Patent Document 1) discloses a web-based order design 3D printing service system. In this system, a user terminal executes a 3D scanning program to generate video data into a 3D modeling file. A three-dimensional modeling file is input from a user terminal via a website provided by a cloud server. The cloud server executes the 3D printer model authoring program to generate 3D content based on the input 3D modeling file. The printer module performs 3D printing operations for 3D content.

It may be preferable for a designer to create 3D data for a 3D printer based on 2D data such as two-dimensional image data. For example, in many cases, it is necessary for a designer to perform creative activities in order to capture the characteristics of an object from an illustration or photograph and express the object in a three-dimensional manner.

Japanese Patent Application Laid-Open No. 2002-15033 (Patent Document 2) describes a needs integration system that mediates transactions between customers and designers using a computer system that stores information about a plurality of designers.

JP 2017-146972 A JP-A-2002-15033

The conventional needs integration system described above is not intended for designers of 3D data for 3D printers. The inventors studied construction of a computer system for matching a designer who creates 3D data for 3D printer modeling with a client who requests creation of 3D data. In the study, the problem was how to evaluate the client's needs and the designer's ability and individuality, and to convert them into data. Therefore, the following examination was conducted in more detail.

In creating 3D data, a modeled object obtained by transforming an object shown in a draft image such as a two-dimensional image is represented by 3D data. Designers tend to show their ingenuity in this transformation process. For example, based on a photograph of a person who actually exists, 3D data of a modeled object of a person having eye sizes and cheek shapes that do not exist in reality may be created. Such transformation from an object represented by a draft image to a modeled object represented by 3D data is called deformation. The inventors found that the ability and individuality of the designer appear in this deformation method. Furthermore, it was found that there are latent requests and preferences of the client regarding the deformation method.

The inventors studied a mechanism in which a requester can select a designer who can perform deformation that meets his/her request or preference after grasping the deformation ability and tendency of the 3D data designer. However, the ability or tendency of the designer to deform in creating 3D data is vague and difficult to grasp. In addition, the client often cannot clearly express the desired deformation.

The present application discloses a 3D data designer search system, a 3D data designer search method, and a program that can search for a designer who meets the user's needs in searching for a designer for 3D data used in 3D printer modeling.

A 3D data designer search system according to an embodiment of the present invention is a 3D data designer search system for searching for a designer of 3D data used to produce a modeled object using a 3D printer. The 3D data designer search system includes a deformation degree receiving unit that receives from a user a designation of a degree of deformation indicating the degree of deformation of an object represented by a draft image to a modeled object represented by 3D data, and a plurality of designers. Designer information associated with a deformation degree value corresponding to the deformation degree specified by the user is extracted from designer data including designer information and a value indicating a deformation degree associated with the designer information of each designer. a search unit; and an output unit that outputs designer information extracted by the search unit to the user.

According to the present disclosure, it is possible to search for a designer who meets the user's needs when searching for a designer for 3D data used in 3D printer modeling.

FIG. 1 is a diagram showing a configuration example of a 3D data designer search system according to this embodiment. FIG. 2 is a diagram showing an example of designer data in the recording unit shown in FIG. FIG. 3 is a diagram showing an example of designer data in the recording unit shown in FIG. FIG. 4 is a flow chart showing an operation example of the 3D data designer search system shown in FIG. FIG. 5 is a diagram showing an example of a screen displayed in steps S1 and S2 of FIG. FIG. 6 is a diagram showing an example of a screen transitioned from the screen of FIG. FIG. 7 is a diagram showing an example of the screen output in step S4 of FIG. FIG. 8 is a diagram showing another example of the screen output in step S4 of FIG.

A 3D data designer search system according to an embodiment of the present invention is a 3D data designer search system for searching for a designer of 3D data used to produce a modeled object using a 3D printer. The 3D data designer search system includes a deformation degree receiving unit that receives from a user a designation of a degree of deformation indicating the degree of deformation of an object represented by a draft image to a modeled object represented by 3D data, and a plurality of designers. Designer information associated with a deformation degree value corresponding to the deformation degree specified by the user is extracted from designer data including designer information and a value indicating a deformation degree associated with the designer information of each designer. a search unit; and an output unit that outputs designer information extracted by the search unit to the user.

In the 3D data designer search system, the deformation degree receiving unit receives a designation of the degree of deformation from the user. As a result, even a user who cannot clearly express the desired deformation can easily input information about the desired deformation. The search unit extracts designer information from the designer data based on the degree of deformation specified by the user. In the designer data, a value indicating the degree of deformation is associated with designer information of each designer. As a result, the deformation features of each designer are recorded as quantitative data. Therefore, the search unit can extract designer information that matches the degree of deformation specified by the user from the designer data. As a result, designer information related to the deformation desired by the user is extracted. In this way, the 3D data designer search system provides a mechanism for converting user needs and designer characteristics into data from the perspective of deformation and matching them. Deformation is an element in which the designer's ability and individuality is exhibited, and an element in which the user's latent needs exist. Therefore, in searching for a designer for 3D data used in 3D printer modeling, it is possible to search for a designer who meets the user's needs.

The degree-of-deformation receiving unit may receive, from the user, designation of degrees of deformation for a plurality of items. In this case, the designer data may include deformation degree data of a plurality of items associated with the designer information of each designer. The search unit can extract designer information corresponding to the degree of deformation of a plurality of items specified by the user. As a result, it is possible to classify the deformation characteristics by the designer into a plurality of items and match the needs of the user for each item. Therefore, it is possible to search for a design that meets the user's needs in more detail.

The degree-of-deformation receiving unit may provide a screen for receiving designation of the degree of deformation from the user, and display a sample image of the modeled object corresponding to the degree of deformation that the user can designate on the screen. Thereby, the user can specify the degree of deformation after grasping the degree of deformation by looking at the sample image on the screen. Therefore, it becomes easier for the user to specify the degree of deformation that he or she desires.

The designer information of each designer may include a work image of 3D data created in the past by each designer, and a value indicating the degree of deformation may be associated with the work image. In this case, the search unit can extract from the designer data the work image associated with the value of the degree of deformation corresponding to the degree of deformation specified by the user. As a result, the user can be presented with the work image corresponding to the degree of deformation specified by the user. Therefore, it is possible to present an image of the designer's work that meets the user's needs.

The designer data may include a value indicating a degree of deformation acceptable to each designer as a value indicating the degree of deformation. In this case, the search unit can extract designer information of a designer who can accept the degree of deformation specified by the user. As a result, it is possible to search for a designer who can create 3D data according to the degree of deformation specified by the user.

The 3D data designer search system may further include an object reception unit that receives designation of a type of object from the user. The designer data may include data indicating the type of object associated with the designer information of each designer. The search unit can extract the designer information associated with the type of object specified by the user and the value of the degree of deformation corresponding to the degree of deformation specified by the user. The method of deformation tends to differ depending on the type of object. By extracting designer information based on both the type of object and the degree of deformation, it is possible to search for a designer that better meets the user's needs.

The 3D data designer search system receives input of designer information and a value indicating the degree of deformation from the designer, associates the input designer information with the value indicating the degree of deformation, and includes the designer data in the designer data. A data update unit may be further provided. As a result, the designer information and the corresponding value indicating the degree of deformation can be accumulated in the designer data.

The 3D data designer search system receives from the user a specification of a designer to be requested and a specification of the degree of deformation to be requested, and requests the designer specified by the user to create 3D data together with the specified degree of deformation. You may further provide a request part which transmits. This allows the designer to create 3D data based on the degree of deformation desired by the user. Therefore, the designer can create 3D data according to the user's requests and preferences.

A 3D data designer search method according to an embodiment of the present invention is a 3D data designer search method for searching a computer for a designer of 3D data used to produce a modeled object using a 3D printer. The 3D data designer search method includes a deformation degree reception step in which the computer receives from a user a designation of a deformation degree indicating the degree of deformation of an object represented by a draft image to a modeled object represented by 3D data; corresponds to the deformation degree value corresponding to the deformation degree specified by the user from the designer data including the designer information about each of the plurality of designers and the value indicating the deformation degree associated with the designer information of each designer. a search step of extracting the attached designer information; and an output step of outputting the designer information extracted by the search unit to the user.

A program in the embodiment of the present invention is a program that causes a computer to execute a process of searching for a designer of 3D data used for manufacturing a modeled object by a 3D printer. The program includes a deformation degree reception process for receiving from a user a designation of a degree of deformation indicating the degree of deformation from an object shown in the draft image to a modeled object represented by 3D data, designer information about each of a plurality of designers, and a search process for extracting designer information associated with a deformation degree value corresponding to the deformation degree specified by the user from designer data including a value indicating a deformation degree associated with designer information of each designer; and an output process of outputting the designer information extracted by the search unit to the user.

[Embodiment]
Hereinafter, embodiments will be described with reference to the drawings. The same reference numerals are given to the same and corresponding configurations in the drawings, and the same description will not be repeated. In addition, in order to make the description easier to understand, in the drawings referred to below, the configuration is shown in a simplified or schematic form, or some constituent members are omitted.

(System configuration example)
FIG. 1 is a diagram showing a configuration example of a 3D data designer search system according to this embodiment. In the example shown in FIG. 1, the 3D data designer search system 10 can access the user terminal 2, the designer terminal 3, and the recording unit 4 via the network N. FIG. In this embodiment, the user is a person looking for a 3D data designer for use in 3D printer modeling. A designer is a person who creates 3D data that is used to produce a modeled object with a 3D printer. The network N is, but not limited to, a communication network such as the Internet or an intranet.

The 3D data designer search system 10 includes a deformation degree reception unit 11 , an object reception unit 12 , a search unit 13 , an output unit 14 , a designer data update unit 15 and a request unit 16 . Designer data is recorded in the recording unit 4 .

The deformation degree reception unit 11 receives designation of the deformation degree from the user. The degree of deformation is the degree of deformation that indicates the degree of deformation from the object shown in the draft image to the modeled object represented by the 3D data. The designer creates 3D data based on the draft image. If the object represented by the 3D data is a faithful reproduction of the object shown in the draft image, the degree of deformation is small. Conversely, if the modeled object represented by the 3D data is greatly deformed by, for example, exaggerating the characteristic portion of the object shown in the draft image, the degree of deformation is large.

The degree-of-deformation reception unit 11 causes the user terminal 2 to display, for example, a screen for the user to specify the degree of deformation. The input form for specifying the degree of deformation by the user is not particularly limited. For example, the deformation degree receiving unit 11 may prompt the user to select one of a plurality of stages of deformation degrees, or may prompt the user to input a value indicating the deformation degree. The deformation degree reception unit 11 may determine the value of the deformation degree specified by the user according to the user's specifying operation. The deformation degree reception unit 11 may add an interface to the screen for supporting the designation of the deformation degree by the user. A specific example will be described later.

The target object receiving unit 12 receives designation of the type of target object from the user. The object receiving unit 12 causes the user terminal 2 to display, for example, a screen for the user to specify the type of object. The designation of the degree of deformation and the designation of the type of object may be received on the same screen. For example, the object reception unit 12 may allow the user to select one of a plurality of object types, or may allow the user to input a character string indicating the object type.

The search unit 13 extracts designer information corresponding to the degree of deformation and object specified by the user from the designer data in the recording unit 4 . The designer data includes designer information about the designer, a value indicating the degree of deformation associated with the designer information, and data indicating the type of object associated with the designer information. Designer data includes a combination of data indicating designer information, degree of deformation, and type of object for a plurality of designers.

The designer information may include, for example, data identifying the designer, 3D data image of the work created by the designer in the past, and data indicating other features of the designer (eg, career, skills, personality, etc.).

2 and 3 are diagrams showing an example of designer data. In the table shown in FIG. 2, designer identifiers (designer IDs), names, types of objects, degree of deformation, number of actual works, and access information to representative work images are recorded in association with each other. In FIG. 2, the type of object indicates the type of object that the designer can deal with. In FIG. 2, the degree of deformation indicates the degree of deformation acceptable by the designer. The designer ID, name, number of completed works, and access information to representative work images are examples of designer information. The representative work image may be 3D data of the representative work, or may be a two-dimensional image representing the 3D data.

In the table shown in FIG. 3, the work identifier (work ID), designer ID, object, degree of deformation, and file storage location are recorded in association with each other. In FIG. 3, the object is the object of the work specified by the work ID. In FIG. 3, the degree of deformation is the degree of deformation of the work specified by the work ID. The file storage location is information for accessing the file of the work indicated by the work ID. The work ID, designer ID, file storage location, and work file are examples of designer information. The work file may be 3D data of the work, or may be a two-dimensional image representing the 3D data.

For example, designer data may include both the table of FIG. 2 and the table of FIG. In this example, the designer data includes the degree of deformation associated with the designer ID as shown in FIG. 2 and the degree of deformation associated with the work ID as shown in FIG. The degree of deformation associated with the designer ID is the degree of deformation recorded for each designer, and indicates, for example, the degree of deformation acceptable to the designer. The acceptable degree of deformation is the degree of deformation that a designer can employ in creating 3D data. The degree of deformation associated with the work ID is the degree of deformation recorded for each work, and indicates, for example, the degree of deformation employed in the work. In this way, by including the degree of deformation corresponding to the designer and the degree of deformation corresponding to the work in the designer data, it is possible to extract both the designer and the work from the viewpoint of deformation. The designer data may include at least one of the degree of deformation for each designer and the degree of deformation for each work.

When the designer data includes the table of FIG. 2 and the table of FIG. 3, the designer data corresponds to the object type associated with the designer ID as shown in FIG. 2 and the work ID as shown in FIG. Contains the type of object attached. The type of object associated with the designer ID is the type of object recorded for each designer, and indicates, for example, the type of object for which the designer can create 3D data. The type of object associated with the work ID is the type of object recorded for each work, and indicates, for example, the type of object in the work. In this way, by including the type of object corresponding to the designer and the type of object corresponding to the work in the designer data, it is possible to extract both the designer and the work from the viewpoint of the object. The designer data may include at least one of the type of object for each designer and the type of object for each work.

In the examples shown in FIGS. 2 and 3, the value indicating the degree of deformation is a numerical value. The value indicating the degree of deformation is not limited to a numerical value, and may be, for example, a value indicating a stage such as large, medium, or small, or a value indicating a range. In addition, in the examples shown in FIGS. 2 and 3, there is only one type of value indicating the degree of deformation, but the designer data may include values indicating the degree of deformation of a plurality of items. For example, deformations can be classified into a plurality of types according to the deformation target part and directionality. A deformation degree value may be recorded for each of a plurality of types. Alternatively, a deformation degree value may be recorded for each of a plurality of object types.

Referring to FIG. 1 again, the search unit 13 searches the designer data using the degree of deformation specified by the user as a search key. Specifically, the search unit 13 extracts the designer information associated with the deformation degree value corresponding to the deformation degree specified by the user. For example, the search unit 13 extracts the value of the degree of deformation of the designer data corresponding to the degree of deformation specified by the user, and extracts the designer information associated with the extracted degree of deformation. For example, when the value of the degree of deformation of the designer data matches the value of the specified degree of deformation, it may be determined that the value of the degree of deformation corresponds. Alternatively, the value of the degree of deformation of the designer data and the value of the specified degree of deformation may be compared to determine whether or not there is correspondence.

As the designer information, the search unit 13 can extract, for example, at least one of information specifying the designer corresponding to the specified degree of deformation and information specifying the work corresponding to the specified degree of deformation.

The search unit 13 may search the designer data using the degree of deformation specified by the user and the type of the specified object as search keys. In this case, the search unit 13 retrieves the designer information associated with the type of object designated by the user and the value of the degree of deformation corresponding to the degree of deformation designated by the user. Extract designer information. Note that the search unit 13 may search designer data using a search key other than the degree of deformation and the type of object.

The output unit 14 outputs the designer information extracted by the search unit 13 to the user. The output unit 14 causes the user terminal 2 to display the designer information, for example. The output form is not limited to display, and may be, for example, data transmission or data storage of designer information.

The designer data update unit 15 receives input of designer information and a value indicating the degree of deformation from the designer. For example, the designer data updating unit 15 causes the designer terminal 3 to display a screen for receiving these inputs. These inputs can be accepted via the designer terminal 3 . The designer data updating unit 15 associates the input designer information with the value indicating the degree of deformation, and includes them in the designer data of the recording unit 4 .

The designer data update unit 15 may, for example, receive an input of the degree of deformation acceptable to the designer. In this case, the designer data updating unit 15 records the received deformation degree value in association with the designer ID. Further, the designer data update unit 15 may receive input from the designer of information specifying the work created by the designer and the degree of deformation of the work. In this case, the designer data update unit 15 records the received deformation degree value in association with the work ID. Note that the designer data update unit 15 may receive input of degrees of deformation acceptable to the designer for a plurality of items.

Further, the designer data update unit 15 may receive input from the designer of the type of object for which the designer can create 3D data. In this case, an input of an acceptable degree of deformation may be accepted for each type of object. Further, the designer data updating unit 15 may receive input from the designer of information specifying the work created by the designer and the type of the object of the work.

The request unit 16 receives a request for creating 3D data from the user terminal 2 and transmits the request to the designer terminal 3 . The requesting unit 16 displays a screen for accepting the user terminal 2, specification of the designer to be requested, and specification of the degree of deformation to be requested. The request unit 16 transmits a request for 3D data creation and the specified degree of deformation to the designer terminal 3 of the designer specified by the user terminal 2 . The request unit 16 may allow the user to designate a designer corresponding to the designer information output by the output unit 14 to the user as the designer requested by the user. The requesting unit 16 may allow the user to specify the degree of deformation received from the user by the degree-of-deformation receiving unit 11 as the degree of deformation to be requested.

The request unit 16 may receive, from the user terminal 2, draft data indicating a modeled object that the user wants to model. In this case, the request unit 16 can receive draft data input from the user terminal 2 and record it in the recording unit 4 . Although the format of the draft data is not particularly limited, it can be, for example, a two-dimensional image (2D data) representing a modeled object, three-dimensional data, text data, or the like. The request unit 16 makes the draft data accessible from the designer terminal 3 . For example, by providing the designer terminal 3 with information for accessing the draft data, the designer terminal 3 can access the draft data. The information for accessing the draft data may include, for example, information indicating the storage location of the draft data and authentication information. Alternatively, the request unit 16 may transmit the draft data to the designer terminal 3 .

The 3D data designer search system 10 is configured by a computer having a processor and memory. The functional units of the deformation degree reception unit 11, the object reception unit 12, the search unit 13, the output unit 14, the designer data update unit 15, and the request unit 16 are implemented by the processor executing programs. A program that causes a computer to execute processing of each functional unit, and a non-transitory recording medium that records such a program are also included in the embodiments of the present invention. The 3D data designer search system 10 may be composed of multiple computers. The recording unit 4 can be realized by a recording device that can be accessed from a computer that constitutes the 3D data designer search system 10 . In the example shown in FIG. 1, the 3D data designer search system 10 can access the recording unit 4 via the network N. It may be composed of a recording device that Also, at least part of the functions of the 3D data designer search system 10 may be implemented by a computer that constitutes the user terminal 2 or designer terminal 3 .

(Operation example)
FIG. 4 is a flow chart showing an operation example of the 3D data designer search system 10. As shown in FIG. In the example shown in FIG. 4, the deformation degree reception unit 11 receives a designation of the deformation degree from the user (step S1). The target object receiving unit 12 receives designation of the type of target object from the user (step S2). The order of steps S1 and S2 is not particularly limited. For example, the 3D data designer search system 10 causes the user terminal 2 to display a screen for accepting the degree of deformation and the type of object.

FIG. 5 is a diagram showing an example of a screen for accepting the degree of deformation and the type of object. A screen G1 shown in FIG. 5 includes an area T1 for designating the type of object and an area T2 for designating the degree of deformation. In the area T1, the user can select one of a plurality of target object types. The area T1 also includes a text input area for inputting a type that is not included in the plurality of object types. In the region T2, it is possible to select one of a plurality of stages of deformation degree (for example, three stages of large, medium, and small).

In the example shown in FIG. 5, on the screen G1, sample images E1 to E3 of molded objects corresponding to degrees of deformation that can be specified by the user are displayed. In the example shown in FIG. 5, a sample image is displayed for each level of deformation degree (large, medium, small) selectable by the user. A sample image corresponding to a certain degree of deformation can be an image of a modeled object represented by 3D data created using that degree of deformation. The sample image assists the user in specifying the degree of deformation.

Note that the display mode of the sample image corresponding to the specifiable degree of deformation is not limited to the example shown in FIG. For example, an interface may be provided in which the degree of deformation can be designated by inputting a numerical value or using a slider bar. In this case, a sample image corresponding to the degree of deformation according to the user's input operation can be displayed. For example, the sample images can be switched and displayed according to the user's input operation for designating the degree of deformation.

The screen G1 shown in FIG. 5 has a button B1 for selecting detailed settings of the degree of deformation and a button B2 for instructing execution of search. When the button B2 is designated, the data indicating the type and degree of deformation of the object selected by the user on the screen G1 are sent to the 3D data designer search system 10 together with a search execution request. When the button B1 is specified, a detailed setting screen for the degree of deformation is displayed. FIG. 6 is a diagram showing an example of the detail setting screen.

The screen G2 shown in FIG. 6 accepts designation of the degree of deformation for a plurality of items. In the example shown in FIG. 6, designation of the degree of deformation is accepted for a plurality of target parts (eg, head/body balance, eye shape, cheek shape, etc.). Also, for each target part, designation of the degree of deformation is accepted for one or more directions of deformation (for example, the degree of glitter, the degree of realism, the degree of largeness, etc.). When the OK button B2 is specified on the screen G2, the degree of deformation specified on the screen G2 is confirmed, and the screen returns to the screen G1. The content of the degree of deformation specified in G2 may be displayed on the screen G1.

Referring again to FIG. 4, in step S3, the search unit 13 extracts data corresponding to the degree of deformation and the type of object designated by the user from the designer data. As an example, the search unit 13 extracts data having a deformation degree value corresponding to the deformation degree designated by the user and having the object type designated by the user from the designer data. Further, the search unit 13 extracts designer information associated with the extracted data.

As an example, a processing example for extracting designer information from the designer data shown in FIG. 2 will be described. A case where the type of object specified by the user=person and the specified degree of deformation=large will be described. In this case, the search unit 13 can determine that the deformation degree value of 4 or 5 associated with the designer ID shown in FIG. 2 is data corresponding to the designated deformation degree. Also, data that includes a person in the object type associated with the designer ID is determined to be data corresponding to the specified object type. In the example shown in FIG. 2, data of designer ID=0002, 0003, 0004 are extracted. For example, the name, the degree of deformation, and the number of completed works are extracted as designer information. The extracted designer information is displayed on the user terminal 2 by the output unit 14 (step S4 in FIG. 4). FIG. 7 is an example of a screen displaying the extracted designer information. In the example shown in FIG. 7, designer information for each of the extracted designer IDs is displayed in a distinguishable format for each designer. An image of a representative work may be displayed for each designer. In this case, the image of the representative work may be linked to 3D data or detailed images of the representative work.

As another example, a processing example for extracting designer information from the designer data shown in FIGS. 2 and 3 will be described. A case where the type of object specified by the user=person and the specified degree of deformation=large will be described. In this case, the search unit 13 can determine that the deformation degree value of 4 or 5 associated with the work ID shown in FIG. 3 is data corresponding to the designated deformation degree. Also, data whose type of object associated with the work ID is a person is determined to be data corresponding to the designated type of object. In the example shown in FIG. 3, data of work ID=0002 and 0004 are extracted. In addition to the designer information associated with the extracted work ID, the search unit 13 can extract designer information further associated with the designer ID associated with the work ID. For example, the name of the designer who created the work, the type of object of the work, the degree of deformation of the work, and the image representing the 3D data of the work (or access information to the image) are extracted as designer information. The extracted designer information is displayed on the user terminal 2 by the output unit 14 (step S4 in FIG. 4). FIG. 8 is an example of a screen displaying the extracted designer information. In the example shown in FIG. 8, designer information for each of the extracted work IDs is displayed in a distinguishable format for each work. The display records R4 and R5 of each work include the designer, the type of object, the degree of deformation, and images (R41 and R51) representing the 3D data of the work. The images R41 and R51 representing the 3D data of the work may be linked to the 3D data of the work or detailed images.

In the example shown in FIG. 7, records of designers who can accept the degree of deformation specified by the user are displayed as search results. In the example shown in FIG. 8, records of works created with the degree of deformation specified by the user are displayed as search results. The user may be able to select which of the search results shown in FIGS. 7 and 8 to display as results.

Note that the operation example of the 3D data designer search system 10 is not limited to the example shown in FIG. For example, after outputting the search results in step S4, a process of accepting a request for creating 3D data from the user may be executed. As an example, each designer on the screen shown in FIG. 7 or each work on the screen shown in FIG. 8 may be displayed in association with an interface element such as a button for the user to execute a request. In this case, the user can specify the designer to request by specifying the button corresponding to the designer or the work. When the user performs such a request operation, a request screen (not shown) for inputting information required for the request is displayed. On the request screen, for example, it is possible to accept specification of the degree of default and input of draft data from the user. The designer data may include access information to the designer terminal 3 of each designer. The request unit 16 can use this access information to transmit a 3D data request to the designer terminal 3 of the designer specified by the user.

In this embodiment, the 3D data designer search system 10 converts the vague concept of deformation that both the user and the designer have into data, and provides a mechanism for searching for designers from the viewpoint of deformation. As a result, it becomes possible to search for a designer that meets the user's requirements or preferences.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments. The configuration of the 3D data designer search system 10 is not limited to the example shown in FIG. For example, in FIG. 1, at least one of the designer data updating unit 15 and the requesting unit 16 may be omitted. Also, the 3D data designer search system 10 may be part of a system for matching users and designers, or a system for ordering 3D modeling using a 3D printer.

10: 3D data designer search system, 2: user terminal, 3: designer terminal, 4: recording unit, 11: deformation degree reception unit, 12: object reception unit, 13: search unit, 14: output unit, 15: designer data update unit, 16: request unit

Claims (10)

A 3D data designer search system for searching for a 3D data designer used in the production of a modeled object by a 3D printer,
a deformation degree reception unit that receives, from a user, a designation of a deformation degree indicating the degree of deformation of the object represented by the draft image to the modeled object represented by the 3D data;
Designer information about each of a plurality of designers and designer data including a value indicating the degree of deformation associated with the designer information of each designer are associated with a value of the degree of deformation corresponding to the degree of deformation specified by the user. a search unit for extracting designer information from
and an output unit configured to output designer information extracted by the search unit to the user. the degree-of-deformation receiving unit receives from the user a designation of degree of deformation for a plurality of items;
The designer data includes deformation degree data for a plurality of items associated with the designer information of each designer,
2. The 3D data designer search system according to claim 1, wherein said search unit extracts designer information corresponding to degrees of deformation of a plurality of items designated by said user. 3. The method according to claim 1, wherein the degree-of-deformation receiving unit provides a screen for receiving designation of the degree of deformation from a user, and displays a sample image of a modeled object corresponding to a degree of deformation that can be designated by the user on the screen. A 3D data designer search system as described. The designer information of each designer includes a work image of 3D data created in the past by each designer, and the work image is associated with a value indicating the degree of deformation,
4. The 3D data according to any one of claims 1 to 3, wherein the search unit extracts from the designer data a work image associated with a deformation degree value corresponding to the deformation degree specified by the user. Designer search system. the designer data includes a value indicating a degree of deformation acceptable to each designer as a value indicating the degree of deformation;
5. The 3D data designer search system according to any one of claims 1 to 4, wherein said search unit extracts designer information of a designer who can accept the degree of deformation designated by said user. further comprising a target object reception unit that receives designation of the type of target object from the user;
the designer data includes data indicating the type of object associated with the designer information of each designer;
6. The method according to claim 1, wherein the search unit extracts designer information associated with the type of object designated by the user and a deformation degree value corresponding to the degree of deformation designated by the user. 3D data designer retrieval system according to any one of the preceding items. further comprising a designer data updating unit that receives input of designer information and a value indicating the degree of deformation from the designer, associates the input designer information with the value indicating the degree of deformation, and includes the inputted designer information in the designer data; 7. The 3D data designer search system according to any one of items 1 to 6. A requesting unit is further provided for receiving, from the user, a specification of a designer to be requested and a specification of a degree of deformation to be requested, and transmitting a request for creating 3D data together with the specified degree of deformation to the designer specified by the user. A 3D data designer search system according to any one of claims 1 to 7. A 3D data designer search method for searching a computer for a 3D data designer used in the production of a modeled object by a 3D printer, comprising:
a deformation degree reception step in which the computer receives from a user a designation of a deformation degree indicating the degree of deformation of the object represented by the draft image to the modeled object represented by the 3D data;
The computer obtains a deformation degree value corresponding to the deformation degree specified by the user, from designer data including designer information about each of a plurality of designers and a value indicating a deformation degree associated with the designer information of each designer. a search step for extracting designer information associated with the
and an output step in which the computer outputs the designer information extracted in the search step to the user. A program that causes a computer to execute a process of searching for a 3D data designer used to produce a modeled object with a 3D printer,
Deformation degree reception processing for receiving, from a user, a designation of a degree of deformation indicating the degree of deformation of the object represented by the draft image to the modeled object represented by the 3D data;
Designer information about each of a plurality of designers and designer data including a value indicating the degree of deformation associated with the designer information of each designer are associated with a value of the degree of deformation corresponding to the degree of deformation specified by the user. a search process for extracting designer information from
and an output process for outputting the designer information extracted by the search process to the user.

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