METHOD FOR OPERATING AT LEAST ONE APPARATUS FOR MANUFACTURING OF THREE-DIMENSIONAL OBJECTS

Abstract

Method for operating at least one apparatus (1) for additively manufacturing of three-dimensional objects (2-4) by means of successive layerwise selective irradiation and consolidation of layers of a build material (5) which can be consolidated by means of an energy beam (6), wherein a communication interface (10) connected or connectable with the at least one apparatus (1) is adapted to receive at least a first data set (15-17) comprising object data from at least a first user (12-14), relating to at least one object (2-4) to be built, and at least a second data set (15-17) comprising object data from at least a second user (12-14), wherein a manufacturing process of at least two objects (2-4) is controlled dependent on the data sets (15-17) of the at least two users (12-14).

Claims

1. Method for operating at least one apparatus (1) for additively manufacturing of three-dimensional objects (2-4) by means of successive layerwise selective irradiation and consolidation of layers of a build material (5) which can be consolidated by means of an energy beam (6), characterized in that a communication interface (10) connected or connectable with the at least one apparatus (1) is adapted to receive at least a first data set (15-17) comprising object data from at least a first user (12-14), relating to at least one object (2-4) to be built, and at least a second data set (15-17) comprising object data from at least a second user (12-14), wherein a manufacturing process of at least two objects (2-4) is controlled dependent on the data sets (15-17) of the at least two users (12-14).

2. Method according to claim 1, characterized in that at least one data set (15-17), in particular the object data, comprises at least one of the following parameters: three-dimensional data of at least one object (2-4) to be built at least one chemical parameter of the object (2-4) to be built, in particular a material parameter at least one physical parameter of the object (2-4) to be built, in particular a density and/or a mechanical property time information relating to a due date information relating to at least one post-processing step

3. Method according to claim 1, characterized in that the at least one data set (15-17) comprises build data relating to the at least one object (2-4) to be built or that build data are generated.

4. Method according to claim 3, characterized in that the build data comprise at least one of the following parameters: at least one chemical parameter of the object (2-4) to be built, in particular a material parameter at least one physical parameter of the object (2-4) to be built, in particular a density and/or a mechanical property time information relating to a duration of the manufacturing process of the object (2-4) to be built material consumption information relating to an irradiation strategy

5. Method according to claim 1, characterized by at least one set of job data generated dependent on at least two data sets (15-17), wherein at least two objects (2-4) are assigned to the same build plane (8) dependent on the at least one set of job data.

6. Method according to claim 5, characterized in that the job data comprise at least one of the following parameters: number of objects (2-4) assigned to at least one build plane (8) time information relating to a duration of the manufacturing process of all objects (2-4) assigned to the same build plane (8) price information initiation information occupancy rate of a build plane (8) of the at least one apparatus (1) number of build jobs number of users (12-14)

7. Method according to claim 6, characterized in that a manufacturing process is initiated dependent on the job data, in particular dependent on the at least one initiation information.

8. Method according to claim 1, characterized in that a data storage (11) is provided, wherein the object data and/or build data and/or job data of at least one user (12-14) is stored.

9. Method according to claim 1, characterized in that the at least one data set (15-17) is transmitted encrypted.

10. Method according to claim 1, characterized in that a topology and/or an orientation of an object (2-4) to be built is optimized, in that a material consumption and/or a build time and/or an occupancy rate of the build plane (8) of the apparatus (1) is reduced.

11. Apparatus (1) for additively manufacturing of three-dimensional objects (2-4) by means of successive layerwise selective irradiation and consolidation of layers of a build material (5) which can be consolidated by means of an energy beam (6), characterized in that a communication interface (10) connected or connectable with the at least one apparatus (1) is adapted to receive at least a first data set (15-17) comprising object data from at least a first user (12-14), relating to at least one object (2-4) to be built, and at least a second data set (15-17) comprising object data from at least a second user (12-14), wherein a control unit is adapted to control the manufacturing process of at least two objects (2-4) dependent on the data sets (15-17) of the at least two users (12-14).

12. Apparatus (1) according to claim 11, characterized in that the apparatus (1) is adapted to perform a method for operating at least one apparatus (1) for additively manufacturing of three-dimensional objects (2-4) by means of successive layerwise selective irradiation and consolidation of layers of a build material (5) which can be consolidated by means of an energy beam (6), characterized in that a communication interface (10) connected or connectable with the at least one apparatus (1) is adapted to receive at least a first data set (15-17) comprising object data from at least a first user (12-14), relating to at least one object (2-4) to be built, and at least a second data set (15-17) comprising object data from at least a second user (12-14), wherein a manufacturing process of at least two objects (2-4) is controlled dependent on the data sets (15-17) of the at least two users (12-14).

Description

[0053] Exemplary embodiments of the invention are described with reference to the FIG. The FIG. are schematic diagrams, wherein

[0054] FIG. 1 shows an inventive apparatus; and

[0055] FIG. 2 shows a process diagram of the inventive method.

[0056] FIG. 1 shows an apparatus 1 for additively manufacturing of three-dimensional objects 2, 3, 4 by means of successive layerwise selective irradiation and consolidation of layers of a build material 5 which can be consolidated by means of an energy beam 6. To generate the energy beam 6 the apparatus 1 comprises an irradiation device 7 adapted to generate and guide the energy beam 6 (or multiple energy beams 6) onto a build plane 8 of build material 5. In other words, a surface of build material 5 is arranged in the build plane 8. For the sake of simplicity, only one build material 5 is depicted in the FIG., wherein it is, of course, possible to use different build materials 5 throughout the manufacturing process. Further, the number of objects 2-4 is merely exemplary, wherein any other number of objects 2-4 is possible.

[0057] The apparatus 1 further comprises a control unit 9 adapted to control, inter alia, the irradiation device 7 of the apparatus 1. According to the control of the control unit 9 the irradiation device 7 is adapted to generate at least one energy beam 6 and guide the energy beam 6 over the build plane 8 to irradiate the objects 2-4 in a layerwise successive manner.

[0058] Additionally, the apparatus 1 is connected with a communication interface 10, wherein the communication interface 10 can be considered as a component of the apparatus 1 or the communication interface 10 may be a separate component the apparatus 1 is connected with. The communication interface 10 may, for example, be designed as wired and/or wireless accessible platform, in particular an internet platform. Via the communication interface 10 data and/or information can be transmitted to the apparatus 1, in particular to the control unit 9. To store the respective data and/or information the apparatus 1 may further comprise a data storage 11. The data transmitted to and/or stored in the apparatus 1 are preferably encrypted to ensure that no other than authorized users can access the data, in particular confidential information.

[0059] As can further be derived from FIG. 1 an exemplary number of three users 12, 13, 14 transmit data sets via the communication interface 10 to the apparatus 1 (depicted by arrows). For example a first user 12 transmits a first data set 15, a second user 13 transmits a second data set 16 and a third user 14 transmits a third data set 17. The data sets 15-17 relate to the objects 2-4 to be manufactured, wherein, for instance, the first user 12 has the object 2 to be built, the second user 13 has the object 3 to be built and third user 14 has the object 4 to be built. The objects 2-4 are to be built in the same manufacturing process and on the same build plane 8. The objects 2-4 in particular differ, e.g. in shape and/or in their dimensions.

[0060] Further, depicted as a dashed line, another user 18 may transmit a data set 19 via the communication interface 10. The users 12-14 may be grouped into a first user group, for example consumer or client and the other user 18 may be assigned to a second user group, for example provider or plant operator. The user 18 may therefore, be regarded as the operator of the apparatus 1 and may input data such as job data and/or build data. It is also possible that the job data and/or build data are generated automatically or that the build data are provided by the users 12-14.

[0061] In other words, the users 12-14 transmit data sets 15-17 via the communication interface 10, which data sets 15-17 relate to the objects 2-4 to be built throughout the additive manufacturing process performed by the apparatus 1. The data sets 15-17 comprise information relating to the objects 2-4, for example a chemical parameter such as the build material 5. In the embodiment depicted in FIG. 1, the objects 2-4 are to be built of the same build material 5. Further, the data sets 15-17 may comprise information relating to three-dimensional data of the objects 2-4, such as a dimensions and/or the shape of the objects 2-4 and/or physical parameters of the objects 2-4 such as the density and/or mechanical properties.

[0062] Further, each of the users 12-14 may add time information to the data sets 15-17, e.g. relating to a due date up to which the corresponding object 2-4 has to be built. Additionally, the data sets 15-17 may comprise information relating to at least one post-processing step that is to be performed on the corresponding object 2-4.

[0063] As described before, build data may be generated automatically by the apparatus 1, in particular by the control unit 9, or provided by the users 12-14, wherein the build data relate to information used for the manufacturing process, such as information relating to an irradiation strategy, wherein parameters are defined relating to the irradiation of at least one layer of at least one of the objects 2-4. Further, e.g. based on the data sets 15-17 various parameters can be determined, from which build data can be generated, such as the material consumption of the objects 2-4 or a writing time, i.e. a time required for the energy beam 6 to irradiate respective layers of the objects 2-4.

[0064] Based on the data sets 15-17 provided by the users 12-14 and/or the data set 19 provided by the user 18 and/or the build data (generated or provided) job data can be generated that relate to the entire manufacturing process of the objects 2-4. The job data may define the number of objects 2-4 and the number of users 12-14. Thus, the job data may also relate to the occupancy rate of the build plane 8 of the apparatus 1, wherein based on the build data and/or the job data and/or the data sets 15-17, 19 price information can be generated relating to the cost the individual users 12-14 have to bear.

[0065] The job data further can define an initiation information defining at least one initiation parameter, wherein the manufacturing process is initiated, if the initiation parameter is met. The initiation parameter, for example, may depend on the price information and/or the occupancy rate. Thus, the manufacturing process performed by the apparatus one may be initiated after a defined occupancy rate of the build plane 8 is met and/or after the price for the individual users 12-14 has reached a defined value.

[0066] The inventive method is further described according to an embodiment depicted in FIG. 2, wherein same reference signs are used. In a first step 20 of the inventive method the data sets 15-17 of the users 12-14 are transmitted to the communication interface 10. Further, the user 18 may transmit a data set 19 via the communication interface 10 to the apparatus 1. In step 21 the data sets 15-17 are transmitted to the apparatus 1, in particular stored in the data storage 11 or transmitted to the control unit 9 of the apparatus 1. As described before, the connection of the communication interface 10 to the control unit 9 and/or the data storage 11 does not have to be a direct connection. It is also possible to have the respective data sets 15-17 indirectly transferred to the apparatus 1, e.g. via a virtual machine or via a portable mass storage, such as a USB-stick. The object 2-4 the data sets 15-17 relate to are then assigned to the build plane 8 in a step 22, if various parameters are met, in particular that the object 2-4 are to be built of the build material 5 that is used on the build plane 8.

[0067] Afterwards, in a step 23 build data and/or a job data are generated based on the data sets 15-17. Based on the generated job data, in particular an initiation information contained in the job data, in step 24 is decided whether the manufacturing process is started. For example, if a predefined occupancy rate of the build plane 8 is not met, the initiation of the manufacturing process can be postponed until, for example another user 12-14 transmits a dataset 15-17 via the communication interface 10 relating to an object 2-4 that is suitable to be manufactured in the same manufacturing process on the same build plane 8, until the predefined occupancy rate is met.

[0068] After the requirements defined by the initiation information are fulfilled, in step 25 the manufacturing process is being performed. Afterwards in a step 26 at least one post-processing step may be performed to at least one of the object 2-4 as defined by the data sets 15-17. Thus, it may further be ensured that the built objects 2-4 are transferred, in particular shipped, to the corresponding user 12-14. Of course, the inventive method may be performed on the inventive apparatus 1.