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KR-20260066197-A - System and method for using a graphical user interface of a sea vessel with a digital twin vessel model

KR20260066197AKR 20260066197 AKR20260066197 AKR 20260066197AKR-20260066197-A

Abstract

In one embodiment, a computer-implemented method comprises: receiving first information regarding the configuration of a factory ship; and causing a graphical user interface (GUI) to be displayed on a computing device. The GUI represents the configuration of the factory ship. The method comprises: receiving second information related to a mission; determining one or more parts required to perform the mission based on the second information; determining a configuration of the factory ship to enable the manufacture of one or more parts based on the one or more parts and the first information; causing the GUI to be modified to represent the configuration of the factory ship; and performing a first simulation of the operation of the factory ship to manufacture one or more parts through the GUI and using a digital twin model of the configuration of the factory ship.

Inventors

  • 크라비츠, 아놀드

Assignees

  • 블루포지 얼라이언스

Dates

Publication Date
20260512
Application Date
20240920
Priority Date
20240320

Claims (20)

  1. As a computer implementation method, A step of receiving first information regarding the composition of the line; A step of causing a graphical user interface to be displayed on a computing device, wherein the graphical user interface represents a configuration of a line; A step of receiving second information related to the mission; A step of determining one or more parts required to perform the mission based on the second information above; A step of determining the reconstruction of the collinear line to enable the manufacture of the one or more parts based on the one or more parts and the first information; A step of changing the graphical user interface to represent the reconstruction of the above-mentioned collinearity; and A step of performing a first simulation of the behavior of the collinearity for manufacturing the one or more parts using the graphical user interface and the digital twin collinearity model of the reconstruction. A computer-implemented method including
  2. In paragraph 1, A computer-implemented method comprising a sea-based or land-based mission performed by one or more personnel, one or more underwater carriers, one or more underwater objects, one or more robots, or a combination of some of these.
  3. In paragraph 1, A computer implementation method further comprising: a step of generating a result of the first simulation; and a step of displaying the result value on the computing device.
  4. In paragraph 1, A computer-implemented method further comprising the step of using one or more machine learning models to generate one or more recommendations based on the first simulation above.
  5. In paragraph 1, A computer-implemented method further comprising the step of causing one or more robots to move one or more factory units based on the reconstruction in response to receiving a positive result value associated with the first simulation.
  6. In paragraph 5, A computer-implemented method further comprising the step of controlling one or more operation parameters of one or more production machines included in one or more factory units to manufacture one or more of the above-mentioned parts.
  7. In paragraph 1, In response to receiving a negative result value associated with the first simulation, a step of generating a second reconstruction of the collinearity for manufacturing the one or more parts using one or more machine learning models; and A step of performing a second simulation of the operation of the collinearity for manufacturing the one or more parts using the graphical user interface and the digital twin collinearity model according to the second reconstruction. A computer implementation method that additionally includes
  8. In paragraph 1, A computer implementation method in which the configuration of the above-mentioned line and/or the reconstruction of the above-mentioned line includes the arrangement, layout, and/or orientation of one or more factory units and/or production machines, including conveyor belts, presses, machines, computers, servers, air compressors, clamps, forklifts, lathes, ladders, pulleys, equipment, or a combination of some of these.
  9. In paragraph 1, A step of receiving one or more inputs related to the reconstruction through the graphical user interface displayed on one or more computing devices; A step of generating a second reconstruction by modifying the reconstruction based on one or more of the above inputs; and A step of simulating the operation of the collinearity for manufacturing the one or more parts using the graphical user interface and the digital twin collinearity model according to the second reconstruction. A computer implementation method that additionally includes
  10. As a system, A memory device configured to store instructions; and A processing device coupled to the memory device so as to be communicable Includes, The above processing device executes the above command, Receive first information regarding the composition of the public line; A graphical user interface representing the configuration of the above-mentioned line is displayed on a computing device; Receive second information related to the mission; Based on the above second information, determine one or more parts required to perform the above mission; Based on the above one or more parts and the above first information, the reconstruction of the above collinear is determined so as to manufacture the above one or more parts; To represent the reconstruction of the above-mentioned collinearity, the graphical user interface is modified; A system that performs a first simulation of the behavior of the collinearity for manufacturing the one or more parts using the above graphical user interface and the above reconstruction digital twin collinearity model.
  11. In Paragraph 10, A system comprising a sea-based or land-based mission performed by one or more personnel, one or more underwater carriers, one or more underwater objects, one or more robots, or a combination of some of these.
  12. In Paragraph 10, A system in which the processing device generates the first simulation result value and causes the result value to be displayed on the computing device.
  13. In Paragraph 10, The processing device is a system that uses one or more machine learning models to generate one or more recommendations based on the first simulation.
  14. In Paragraph 10, In response to receiving a positive result value associated with the first simulation above, the processing device is a system that causes one or more robots to move one or more factory units based on the reconstruction.
  15. In Paragraph 14, The above processing device is a system that controls one or more operation parameters of one or more production machines included in one or more factory units to manufacture one or more parts.
  16. In Paragraph 10, The above processing device is, In response to receiving a negative result value associated with the first simulation, a second reconstruction of the collinearity for manufacturing the one or more parts is generated using one or more machine learning models; A system that performs a second simulation of the behavior of the collinearity for manufacturing the one or more parts using the graphical user interface and the digital twin collinearity model according to the second reconstruction.
  17. In Paragraph 10, A system comprising, in the configuration of the above-mentioned line and/or the reconfiguration of the above-mentioned line, the arrangement, layout, and/or orientation of one or more factory units and/or production machines including conveyor belts, presses, machines, computers, servers, air compressors, clamps, forklifts, lathes, ladders, pulleys, equipment, or a combination of some of these.
  18. In Paragraph 10, The above processing device is, Receiving one or more inputs related to the reconstruction through the graphical user interface displayed on one or more computing devices; Based on the above one or more inputs, modify the above reconstruction to generate a second reconstruction; A system for simulating the behavior of the collinearity for manufacturing the one or more parts using the above graphical user interface and the digital twin collinearity model according to the above second reconstruction.
  19. As a tangible, non-transient, computer-readable medium for storing instructions, said instructions, when executed, a processing unit, To receive first information regarding the composition of the public line; A graphical user interface representing the configuration of the above-mentioned line is displayed on a computing device; To receive second information related to the mission; Based on the above second information, one or more parts required to perform the above mission are determined; Based on the above one or more parts and the above first information, the reconstruction of the above collinear is determined so as to manufacture the above one or more parts; To represent the reconstruction of the above-mentioned collinearity, the above-mentioned GUI is modified; A type of non-transient computer-readable medium that enables the simulation of the behavior of the collinearity for manufacturing the one or more parts through the graphical user interface and using the digital twin collinearity model of the reconstruction.
  20. In Paragraph 19, The above processing device is, In response to receiving a positive result value associated with the above simulation, one or more robots move one or more factory units based on the above reconstruction; A non-transient computer-readable medium of the type that controls one or more operation parameters of one or more production machines included in one or more factory units to manufacture one or more of the above-mentioned parts.

Description

System and method for using a graphical user interface of a sea vessel with a digital twin vessel model Cross-reference regarding related applications The present application claims the benefit of U.S. Utility Model Application No. 18/614,451 filed on March 22, 2024, and claims the benefit and priority of U.S. Partial Continuation Application No. 18/611,506 filed on March 20, 2024, which claims the benefit of U.S. Provisional Application No. 63/541,466 filed on September 29, 2023 and U.S. Provisional Application No. 63/602,962 filed on November 27, 2023, the entire contents of each of these applications are incorporated herein by reference. The present disclosure generally relates to manufacturing, and in particular to a system and method for manufacturing a product on the sea in a marine vessel. The description of the 'background art' provided herein is intended to provide an overall context for the present disclosure. The work of the inventors currently named within the scope described in this 'background art' section, as well as modes of description that may not otherwise be recognized as prior art at the time of filing, are not recognized, expressly or impliedly, as prior art for the present disclosure. Conventional manufacturing methods on land (e.g., at one or more stationary or non-mobile facilities) are highly developed globally. Generally, product development and manufacturing can be carried out at a single facility, at various locations within a single facility, or at various stages within multiple facilities transporting products between them. Various related manufacturing procedures, processes, and specifications may apply to each product and location, and these may vary depending on various factors, including, but are not limited to, the product and/or product type being manufactured, the facility or facility type, and environmental factors affecting the manufacturing process. The present disclosure will be better understood through the detailed description and accompanying drawings. In order to understand and achieve the features and advantages of the embodiments in greater detail, a more specific description may be provided by referring to the embodiments illustrated in the attached drawings. However, the drawings illustrate only some embodiments, and since other equivalent effective embodiments may exist, they should not be construed as limiting the scope. It should be noted that some of the details and/or features shown in the drawings of this invention may not be depicted at actual scale in some elements for clarity. FIGS. 1a and 1b schematically illustrate exemplary collinear lines according to the principles of the present disclosure. FIG. 2 is a side view of another exemplary collinear line according to the principles of the present disclosure. FIG. 3 illustrates an exemplary factory unit according to the principles of the present disclosure. FIG. 4 illustrates a block diagram of an exemplary computing device configured to implement the functions of the system and method of the present disclosure. FIG. 5 illustrates the steps of an exemplary method for carrying out a marine manufacturing process according to the principles of the present disclosure. FIG. 6 illustrates the steps of another exemplary method for carrying out a marine manufacturing process according to the principles of the present disclosure. FIG. 7 illustrates the steps of an exemplary method of using a graphical user interface to form a line according to the principles of the present disclosure. FIG. 8 illustrates the steps of an exemplary method for arranging one or more factory units and controlling production machines included in the factory units according to the principles of the present disclosure. FIG. 9 illustrates the steps of another exemplary method of using a graphical user interface to form a line according to the principles of the present disclosure. FIG. 10 illustrates an exemplary graphical user interface used to configure a factory unit of a line according to the principles of the present disclosure. FIG. 11 illustrates an exemplary graphical user interface used to simulate a marine manufacturing process through production machinery according to the principles of the present disclosure. In drawings, reference numbers may be reused to identify similar and/or identical elements. Typically, the manufacturing of various products is carried out at one or more facilities or locations. Various associated manufacturing procedures, processes, specifications, etc., may apply to each product and location, and these may vary depending on various factors, including, but are not limited to, the product and/or product type being manufactured, the facility or facility type, and environmental factors affecting the manufacturing procedures. For example, different locations may be associated with variations in their respective procedures or processes. A manufacturing system and method according to the present disclosure ar