KR20210062251A - Crew training system and method based on vr space information - Google Patents

Abstract

The present invention relates to a sailor education system based on VR spatial information, comprising: an image receiving unit configured to receive and store an image obtained by photographing a vessel space and one or more equipment; a simulation image production unit for producing MIMIC images and general arrangement (GA) drawings which provide simulations for the standard operating procedures of the vessel and equipment; a VR image production unit which creates a VR image of the inside of the vessel space and the one or more equipment by stitching interlocking parts of individual images photographed in the vessel space received by the image receiving unit; a VR linkage unit which links VR images related to the one or more equipment and each equipment operation process performed in the vessel to the MIMIC and GA drawings; and a CG linkage unit which links various CGs to the VR image related to the respective equipment operation process. The present invention is to enable easy learning of the operation method of the relevant equipment by supporting customized crew training for the main equipment of the vessel by fusing the vessel-related know-hows and VR technology.

Description

Crew training system and method based on VR spatial information {CREW TRAINING SYSTEM AND METHOD BASED ON VR SPACE INFORMATION}

The present invention relates to a sailor education system and method, and more particularly, to provide effective sailor education by establishing an operation manual system for major equipment of a ship using virtual reality (VR) technology. It relates to a sailor education system and method based on VR spatial information to support business performance.

Virtual Reality (VR), which has emerged as one of the key elements in the era of the 4th Industrial Revolution, is a simulation technology that allows you to experience real life in a virtual world created by a computer. A human-computer interface that makes it into a virtual environment consisting of three dimensions like reality and makes it as if the person who uses it is interacting with the real surrounding environment or situation based on the virtual space and objects in the virtual environment. Say.

Usually, ships built at the shipyard must be finally delivered to the shipowner before crew members can board the ship and go on voyage. However, as the technology applied to ships rapidly develops, there are many equipments that even experienced crew members encounter for the first time, so it is often difficult to operate, and in addition, costs are incurred in shipyards to respond to the increasing number of equipment operation advice after delivery of the ship.

Therefore, in order to solve these difficulties, the necessity of effective manual information delivery has emerged when training ship crew members.

Republic of Korea Patent Publication No. 10-2016-0171819 (published date 2018.06.25.) Korean Patent Application Publication No. 10-2015-0085853 (Publication date 2015.07.27.)

Accordingly, the present invention has been made to solve the problems of the prior art, and an object of the present invention is to provide tailored crew training for the main equipment of the ship by fusion of ship-related know-how and VR technology of a shipyard, thereby allowing sailors to It is to provide a sailor education system and method based on VR spatial information that supports to easily learn how to operate the equipment and apply it to work.

The technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems that are not mentioned will be clearly understood by those of ordinary skill in the technical field to which the present invention belongs from the following description. I will be able to.

A sailor education system based on VR space information according to a preferred embodiment of the present invention for achieving the above object comprises: an image receiving unit configured to receive and store an image photographed of a ship space and one or more equipment; A simulation image production unit for producing a MIMIC image and a general arrangement (GA) drawing that provides a simulation for the standard operating procedure of the ship and equipment; A VR image production unit that stitches the interlocking portion of the individual images captured in the ship space received by the image receiving unit into a VR image of the interior of the ship space and the at least one equipment; The MIMIC and GA drawings include a VR linking unit for linking VR images related to the at least one equipment and each equipment driving process performed on the ship, and a CG linking unit for linking various CGs to VR images related to the respective equipment driving process. do.

Meanwhile, a method for a sailor education system based on VR space information according to a preferred embodiment of the present invention includes the steps of receiving and storing an image photographed of a ship space and one or more equipment; Producing MIMIC images and GA drawings that provide simulations for standard operating procedures of the ship and equipment; Creating a VR image of the inside of the ship space and the one or more equipment by splicing the interlocking parts of the individual images captured in the ship space; And linking VR images related to the at least one equipment and each equipment driving process performed on the ship to the MIMIC and GA drawings, and linking various CGs to VR images related to the respective equipment driving processes.

As described above, the sailor education system and method based on VR spatial information according to the present invention applies the panoramic VR technology to the ship driving education, so that the user can see the interior and exterior of the ship three-dimensionally implemented through a screen implemented in VR. It is possible to improve the effective training and work efficiency for seafarers by enabling them to be visualized and viewed with a high sense of reality, and to quickly and easily specify a suitable moving route according to the needs and intentions of users in the space inside the ship.

In addition, it is realistic and meticulously configured so that crew can apply it to actual work, and through prior training, additional costs incurred due to equipment damage, frequent A/S, and equipment operation inquiries due to the crew's inexperience in operation can be greatly reduced.

1 is a block diagram schematically showing the configuration of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.
2A and 2B show a main screen of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.
3A to 3C are process overview content screens of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.
4A to 4C illustrate a local-based board view content screen of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.
5A and 5B show an operation guide view content screen of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.
6A and 6B show trouble shooting content screens of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.
7A and 7B show VR content screens on a board view of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.

Advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in a variety of different forms, and only the embodiments make the disclosure of the present invention complete, and common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the scope of the invention to the possessor, and the invention is only defined by the scope of the claims. The same reference numerals refer to the same elements throughout the specification.

The functional blocks shown in the drawings and described below are only examples of possible implementations. In other implementations, other functional blocks may be used without departing from the spirit and scope of the detailed description. Further, although one or more functional blocks of the present invention are represented as individual blocks, one or more of the functional blocks of the present invention may be a combination of various hardware and software configurations that perform the same function.

In addition, the expression that certain elements are included is an open expression and simply refers to the existence of the corresponding elements, and should not be understood as excluding additional elements.

In addition, when a component is connected to or is referred to as being connected to another component, it should be understood that it may be directly connected or connected to the other component, but other components may exist in the middle.

Sailor education system according to the present invention presented below is proposed as a preferred embodiment based on a liquefied natural gas carrier (LNGC), which has the fastest technology evolution rate in recent years, but is not limited thereto. .

In this specification, "MIMIC" is to provide a simulation so that standard operating procedures (SOP) for stable operation can be achieved in important processes such as ship start-up and shutdown, and "GA (General Arrangement) drawing" is the overall appearance of the ship. It refers to a general layout drawing in which the outline of the image and the approximate position of the equipment are marked with symbols. "Spot" refers to a specific place or location on the ship.

Hereinafter, a sailor education system based on VR spatial information of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram schematically showing the configuration of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.

As shown in Fig. 1, the VR spatial information-based sailor education system 100 according to a preferred embodiment of the present invention includes an image receiving unit 110, a simulation image producing unit 120, a VR image producing unit 130, and VR interlocking. The unit 140 and the CG linking unit 150 may be included, but are not limited to these components, and additional components may be further included, or some components may be omitted or integrated.

The image receiving unit 110 includes the entire space of a ship (for example, a liquefied natural gas carrier (LNGC)) and major and other equipment through which gas flows such as Hi-Com, Hi-Var, PRS, etc. It is configured to receive and store the captured image. For example, the image receiving unit 110 may receive a photographing result, such as a panoramic image photographed for about 400 to 500 individual spaces of a ship, using aerial image photographing equipment such as Hallicam, and create a database in the form of a database.

The simulation image production unit 120 produces MIMIC images and GA drawings that provide simulations so that standard operating procedures (SOPs) for stable operation can be achieved in important processes such as ship start-up and shutdown. In particular, the simulation image production unit 120 interlocks data between MIMICs and accumulates and applies it to other MIMICs that are linked when the valve state or gas pressure changes through the equipment operation process in the current MIMIC.

The VR image production unit 130 stitches the interlocking parts of the individual images captured in the entire space of the ship received by the image receiving unit 110 to combine the interior of the ship space and main and other equipment into a single completed 360 panoramic VR image. Make.

The VR linkage unit 140 links the VR images related to each equipment driving process performed on the ship to the MIMIC and GA drawings.

The CG linking unit 150 links various CGs to VR images related to each equipment operation process.

2A and 2B show a main screen of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.

2A and 2B, the main screen functioning as the home screen of the VR spatial information-based sailor education system according to a preferred embodiment of the present invention is ① a home button that moves to the main screen when clicked while using the education system. , ② A category located at the top right of the main screen to support the menu of contents constituting the education system, ③ An individual menu icon located on the wall of the main screen that can rotate 360 degrees to support the menu of contents constituting the education system , ④ Individual menu name indicating the corresponding menu located at the top of the individual menu icon, ⑤ It is a function that allows you to quickly and easily find the desired VR space by classifying ships by zone, such as engine room and cargo room. A combo box (quick menu) that provides current spatial information to the user along with GA drawings, ⑥ is a menu displayed when an executable file is clicked, a home menu that supports the function to move to the main screen, and the current VR location sharing function. Executable file menu consisting of screen sharing menu and exit function that supports exit from executable file, and ⑦ menu displayed when clicking the screen sharing menu. When clicked, IO (Input Output)-tag is created, and when moving to the desired location, the corresponding location is URL With the IO-tag creation button that is created by using the IO-tag creation button, the URL copy button that allows you to share the location by copying the location in URL form after the IO-tag creation is completed, and the URL move button that allows you to move to the VR location by entering the copied or received URL. It can be made by including a configured control menu.

3A to 3C are process overview content screens of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.

3A to 3C, the process overview content of the VR spatial information-based sailor education system according to a preferred embodiment of the present invention helps the sailor understand how the actual LNG gas flows. By combining VR and CG, it provides three-dimensional information such as gas flow by operation mode and functions and specifications of related main equipment.

Specifically, the Process Overview content screen includes: ① the menu name indicating the name of the corresponding contents menu, ② the gas flow indicating the name of the gas flow in the vessel (for example, HiCOM1, HiCOM2, HiVAR1, HiVAR2, etc.) Name, ③ The name of the equipment that supports the function of checking the gas flow in the equipment when clicked by indicating the name of the main equipment in each gas flow, ④ Step icon that can select the stage of the gas flow when clicked, ⑤ Equipment image/text pop-up that displays the name or image of the main equipment that the gas flow passes through in a pop-up, ⑥ NEXT pop-up that allows you to move to the next stage of the gas flow when clicked, ⑦ Gas flow caption describing the gas flow in that stage , ⑧ VR direction guide indicating where the current VR screen is facing on the ship, ⑨ When clicked, a pop-up such as PDF E-book of the equipment is executed, and when the pop-up is closed, the next step of gas flow is automatically performed. Executable design information and ⑩ drawings and precautions of the equipment can be provided in the form of PDF E-books, etc., and can include PDF E-book pop-ups that support enlargement/reduction and printing functions.

4A to 4C illustrate a local-based board view content screen of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.

As shown in FIGS. 4A to 4C, the local based on board view content of the VR spatial information based sailor education system according to a preferred embodiment of the present invention implements the position and shape of the ship on the MIMIC. It helps to identify the same location as the main ship by linking the live-action VR of the ship and equipment with the IO-tag of the snapshot.

Specifically, the Local based on board View content screen includes ① a shortcut pop-up that supports shortcuts to the ship's main equipment MIMIC, ② an icon activated by implementing the same as the actual MOP (Main Operation Panel). MOP that can be moved to MIMIC of major and other equipment when clicked, ③ MIMIC name indicating the name of MIMIC on the current screen, ④ If VR image is linked to the equipment of the corresponding icon on the MIMIC screen, the corresponding IO-tag when the mouse is over IO-tag name pop-up that automatically displays the name pop-up and automatically disappears when the mouse is moved, and displays the corresponding VR image pop-up when the displayed IO-tag icon is clicked, ⑤ VR image pop-up that provides information on the current location and snapshot of the device , ⑥ VR image pop-up displayed when the IO-tag icon is clicked in MIMIC, ⑦ IO-tag icon that displays the name and location of the device clicked in MIMIC, ⑧ As a proximity image of the selected device, it is automatically over the mouse over the IO-tag icon. The IO-tag snapshot that is displayed as and disappears automatically when the mouse is moved, and ⑨ displays the direction of the VR on the current screen, and can include a radar icon that can be moved according to the screen movement.

5A and 5B show an operation guide view content screen of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.

5A and 5B, the contents of the Operation Guide View of the sailor education system based on VR spatial information according to a preferred embodiment of the present invention indicate the gas flow in the ship on the MIMIC, and CG and VR By interlocking, it is possible to learn the complex gas operation automatic sequence and gas flow step by step, and to virtually recognize the actual operation.

Specifically, the Operation Guide View content screen includes: ① the menu name indicating the name of the content menu, ② the equipment name indicating the name of the ship's main equipment, and ③ the name of the gas sequence for the operation of the main equipment. Gas sequence name to be marked, ④ Step guide icon to be selected in the corresponding MIMIC, step box applied when there is a need to check sequentially because each step is assigned a number, ⑤ A text indicating the matters to be checked or referenced during operation This is a pop-up that is displayed in the form of a tip box that is applied when there is a need for operation. ⑥ It is a pop-up that is displayed when you click the MIMIC view icon in the step box. When there is an interlocked VR image, a VR pop-up is displayed when the connected device is displayed as a box, and in the MOP menu, when there is an animation, a caution box that activates the animation when clicked can be included.

6A and 6B show trouble shooting content screens of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.

6A and 6B, the trouble shooting content of the sailor education system based on VR spatial information according to a preferred embodiment of the present invention includes information related to inspection and maintenance of ships and equipment as images or text. It is provided as a manual, so that trouble shooting scenarios can be visually and repeatedly learned so that emergency measures can be taken when a problem occurs while operating the equipment.

Specifically, the Trouble Shooting content screen includes ① the menu name indicating the name of the content menu, ② the equipment name indicating the name of the ship's main equipment, and ③ the case name indicating the main trouble shooting case of the equipment. , ④ When the case name is clicked, it moves to the VR spot of the device and is displayed, and when clicked, a troupe shooting icon that displays a PDF E-book, and ⑤ when the trunning shooting icon is clicked, the selected case's MIMIC, equipment image, and cause and actions to be taken. Actions, etc., can be provided in the form of e-books, etc., and can be implemented including PDF e-book pop-ups that support zooming, saving, and printing functions.

7A and 7B show VR content screens on a board view of a sailor education system based on VR spatial information according to a preferred embodiment of the present invention.

7A and 7B, VR (VR on board View) content on the board view of the sailor education system based on VR spatial information according to a preferred embodiment of the present invention is not directly broadcast by sailors and engineers, but The GA drawing and the actual VR are linked so that the entire space inside and outside the ship can be checked through a laptop, making it easy to grasp the location and actual appearance of facilities and sensors on the drawing.

Specifically, the VR (VR on board View) content screen on the board view is: ① the drawing name indicating the name of the corresponding GA drawing, ② the main space of the corresponding GA drawing (for example, home screen, cargo compartment, and engine compartment) to VR. Shortcut pop-up that supports shortcuts, ③ If there is a VR image linked to the GA drawing, mark the space as a box, and when clicking the box or zooming in with the mouse wheel, the corresponding VR spot icon is displayed on the GA drawing, and when clicked, the corresponding VR spot Or, a VR interlocking display that moves to a detailed drawing, ④ When clicking the VR spot icon in the GA drawing, it moves to the VR image, and the MIMIC is reduced in size and converted into a pop-up MIMIC pop-up, ⑤ Corresponds when clicking the white hot spot icon visible on the VR screen. It may include a hot spot icon that moves to a VR image and a radar icon that displays the location and direction of the VR on the current screen in connection with the MIMIC.

Although the present invention has been described in more detail with reference to several embodiments above, the present invention is not necessarily limited to these embodiments, and various modifications may be made without departing from the spirit of the present invention.

100: sailor education system based on VR spatial information
110: image receiving unit
120: simulation image production unit
130: VR image production department
140: VR linkage unit
150: CG linkage

Claims (8)

An image receiving unit configured to receive and store an image of a ship space and one or more equipment;
A simulation image production unit for producing a MIMIC image and a general arrangement (GA) drawing that provides a simulation for the standard operating procedure of the ship and equipment;
A VR image production unit that stitches an interlocking portion of the individual images photographed in the ship space received by the image receiving unit to create a VR image of the interior of the ship space and the at least one equipment;
A VR linking unit for linking VR images related to the at least one equipment and each equipment driving process performed on the ship to the MIMIC and GA drawings, and
Sailor education system comprising a CG linking unit for linking various CGs to VR images related to the respective equipment driving processes. The method according to claim 1,
Said ship is a liquefied natural gas carrier (Liquefied Natural Gas Carrier, LNGC), the equipment is a crew training system that is a gas flow through the equipment. The method according to claim 2,
Process overview content for providing the gas flow and equipment-related information via the gas flow by grafting the VR image and various CGs;
Local based on board view content providing the MIMIC with the location and shape of the equipment on board by linking the VR and IO-tags of the equipment;
Trouble shooting content that provides information related to the inspection and maintenance of the vessel and equipment, and
Sailor education system including VR on board view (VR) content on the board view that enables the user to grasp the location and actual state of the equipment by interlocking the GA drawing with the VR. The method of claim 3,
The simulation image production unit interlocks data between MIMICs and accumulates and applies the change in valve state or gas pressure in the current MIMIC through the respective equipment operation process to other MIMICs. Receiving and storing images of the ship space and one or more equipment;
Producing MIMIC images and GA drawings that provide simulations for standard operating procedures of the ship and equipment;
Creating a VR image of the inside of the ship space and the one or more equipment by splicing the interlocking parts of the individual images captured in the ship space;
Linking a VR image related to the at least one equipment and each equipment driving process performed on the ship to the MIMIC and GA drawings, and
Sailor training method comprising the step of linking various CGs to VR images related to the respective equipment driving process. The method of claim 5,
Said ship is a liquefied natural gas carrier (Liquefied Natural Gas Carrier, LNGC), and the equipment is a crew training method in which gas flow is passed. The method of claim 6,
Process overview content for providing the gas flow and equipment-related information via the gas flow by grafting the VR image and various CGs;
Local based on board view content providing the MIMIC with the location and shape of the equipment on board by linking the VR and IO-tags of the equipment;
Trouble shooting content that provides information related to the inspection and maintenance of the vessel and equipment, and
Sailor training method for providing VR (VR on board view) content on the board view that enables the user to grasp the location and actual state of the equipment by linking the GA drawing and VR. The method of claim 7,
In the step of producing the MIMIC image and the GA drawing, when the current MIMIC changes the valve state or gas pressure through the respective equipment operation process by linking data between the MIMICs, the method of accumulating and applying them to other MIMICs linked thereto.

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