KR102504714B1 - Crew training system and method based on vr space information - Google Patents

Abstract

The present invention relates to a seafarer training system based on VR spatial information, comprising: an image receiving unit configured to receive and store an image of a vessel space and one or more equipment; a simulation image production unit for producing MIMIC images and GA (General Arrangement) drawings that provide simulation of standard operating procedures of the vessel and equipment; a VR image production unit that creates a VR image of the interior of the vessel space and the one or more equipments by stitching interlocking parts of individual images captured in the vessel space received by the image receiver; In the MIMIC and GA drawings, a VR linkage unit for linking VR images related to the one or more equipment and each equipment operation process performed on the ship, and a CG linkage unit for linking various CGs to VR images related to each equipment operation process. do.

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 seafarer training system and method, and more particularly, to provide effective seafarer training by establishing an operation manual system for major equipment of a ship using virtual reality (VR) technology, thereby providing more efficient seafarer training. It relates to a seafarer training system and method based on VR spatial information to support job performance.

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

In general, ships built at shipyards must be finally delivered to the owner before crew members can board the ship and set sail. However, with the rapid development of technology applied to ships, experienced sailors often experience difficulties in operation due to the large number of equipment they have never seen before, and shipyards are incurring costs to respond to increased equipment operation advice after delivery.

Therefore, in order to solve these difficulties, the need for effective manual information delivery during ship crew training has emerged.

Republic of Korea Patent Publication No. 10-2016-0171819 (published on 2018.06.25.) Republic of Korea Patent Publication No. 10-2015-0085853 (published on July 27, 2015)

Therefore, the present invention has been made to solve the above-mentioned problems of the prior art, and the object of the present invention is to support customized crew training for the main equipment of the ship by fusing the shipyard's ship-related know-how and VR technology so that the sailors can learn more It is to provide a crew training system and method based on VR spatial information that can 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 not mentioned will be clearly understood by those skilled in the art from the description below. You will be able to.

A sailor training system based on VR spatial information according to a preferred embodiment of the present invention for achieving the above object includes an image receiving unit configured to receive and store images of a ship space and one or more equipment; a simulation image production unit for producing MIMIC images and GA (General Arrangement) drawings that provide simulation of standard operating procedures of the vessel and equipment; a VR image production unit that creates a VR image of the interior of the vessel space and the one or more equipments by stitching interlocking parts of individual images captured in the vessel space received by the image receiver; In the MIMIC and GA drawings, a VR linkage unit for linking VR images related to the one or more equipment and each equipment operation process performed on the ship, and a CG linkage unit for linking various CGs to VR images related to each equipment operation process. do.

On the other hand, according to a preferred embodiment of the present invention, the VR spatial information-based sailor training system method includes the steps of receiving and storing an image of a ship space and one or more equipment; producing MIMIC images and GA drawings providing simulations of standard operating procedures of the vessel and equipment; making a VR image of the inside of the ship space and the one or more equipments by splicing interlocking parts of individual images taken in the ship space; Linking VR images related to the one or more equipment and each equipment driving process performed in the ship to the MIMIC and GA drawings, and linking various CGs to VR images related to each equipment driving process.

As described above, the crew training system and method based on VR spatial information according to the present invention applies panoramic VR technology to ship driving education so that the user can see the inside and outside of the ship three-dimensionally implemented through the screen implemented in VR. It can be visualized with a high sense of reality and supported to easily and quickly specify a suitable movement route according to the user's needs and intentions in the space inside the ship, so that effective training and work efficiency for crew members can be improved.

In addition, it is realistically and meticulously configured so that crew members can apply it to actual work immediately, and through prior training, equipment damage caused by crew members' inexperienced driving, frequent A/S, and additional costs caused by equipment operation inquiries can be greatly reduced.

1 is a block diagram schematically showing the configuration of a seafarer 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 seafarer education system based on VR space information according to a preferred embodiment of the present invention.
3A to 3C show process overview content screens of a seafarer training system based on VR spatial information according to a preferred embodiment of the present invention.
4A to 4C show local board view content screens of a seafarer 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 seafarer training 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 seafarer education system based on VR space information according to a preferred embodiment of the present invention.
7A and 7B show a VR content screen on a board view of a seafarer education system based on VR spatial information according to a preferred embodiment of the present invention.

Advantages and features of the present invention, and methods of achieving them, will become clear with reference to the detailed description of the following embodiments taken in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms, but the embodiments only allow the disclosure of the present invention to be complete, and the common knowledge in the art to which the present invention belongs. It is provided to fully inform the holder of the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

The functional blocks shown in the drawings and described below are only examples of possible implementations. Other functional blocks may be used in other implementations without departing from the spirit and scope of the detailed description. Also, while one or more functional blocks of the present invention are represented as separate 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 of including certain elements simply indicates that the corresponding elements exist as an open expression, and should not be understood as excluding additional elements.

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

The seafarer training system according to the present invention presented below proposes a case based on a liquefied natural gas carrier (LNGC), which has the fastest technological evolution, as a preferred embodiment, but is not limited thereto. .

In this specification, "MIMIC" is to provide simulation so that standard operating procedures (SOPs) 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 arrangement drawing in which the outline of the phase and the approximate location of equipment are marked with symbols. A “spot” refers to a specific place or location within a vessel.

Hereinafter, the seafarer training 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 seafarer education system based on VR spatial information according to a preferred embodiment of the present invention.

As shown in FIG. 1, the seafarer training system 100 based on VR spatial information 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 a VR linkage. It may be made including the unit 140 and the CG interlocking unit 150, but is not limited to these components and may further include additional components or may be configured in an integrated or omitted form.

The image receiving unit 110 is a vessel (eg, liquefied natural gas carrier (LNGC)), the entire space and the main and other equipment through which the gas flow passes, such as Hi-Com, Hi-Var, and PRS. It is configured to receive and store an image taken by a group of people. For example, the image receiving unit 110 may receive a photographing result such as a panoramic image photographed of about 400 to 500 individual spaces of a ship by using an aerial video photographing equipment such as a halicam and may form a database.

The simulation image production unit 120 produces MIMIC images and GA drawings that provide simulation 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 them to other interlocked MIMICs when a valve state or gas pressure changes through an 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 ship space received by the image receiver 110 to convert the interior of the ship space, main and other equipment into one completed 360 panoramic VR image. make

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

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 seafarer education system based on VR space information according to a preferred embodiment of the present invention.

As shown in FIGS. 2A and 2B, the main screen functioning as the home screen of the VR space information-based seafarer training 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 training system. , ② category located at the top right of the main screen to support the menu of contents constituting the education system, ③ individual menu icon located on the wall of the main screen that can be rotated 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 each individual menu icon, ⑤ A function that makes it easy to quickly and easily find the desired VR space by classifying ships by zones such as engine room and cargo room. A combo box (quick menu) that provides current space information to the user along with GA drawings, a home menu that supports the function of moving to the main screen as a menu displayed when the ⑥ execution file is clicked, and a function that supports the current VR location sharing function As a menu that is displayed when clicking the screen sharing menu and the executable file menu consisting of Exit, which supports the function of exiting from the executable file, and the ⑦ Screen sharing menu, an IO (Input Output)-tag is created when clicked, and when moved to the desired location, the corresponding location is URL IO-tag generation button created by IO-tag creation, URL copy button that can copy and share the location in URL form after IO-tag creation, and URL movement button that moves to the VR location by entering the copied or received URL. It can be made including a configured control menu.

3A to 3C show process overview content screens of a seafarer training system based on VR spatial information according to a preferred embodiment of the present invention.

As shown in FIGS. 3A to 3C, the process overview content of the VR spatial information-based sailor training system according to a preferred embodiment of the present invention helps the crew understand how the actual LNG gas flows. For this purpose, real-life VR and CG are combined to provide relevant information such as gas flow by operation mode and functions and specifications of related major equipment in three dimensions.

Specifically, the process overview content screen is ① a menu name indicating the name of the corresponding content menu, ② a gas flow indicating the name of the gas flow in the vessel (eg, HiCOM1, HiCOM2, HiVAR1, HiVAR2, etc.) Name, ③ The name of the equipment that supports the function to check the gas flow in the corresponding equipment when clicked by displaying the name of the main equipment in each gas flow, ④ The stage icon to select the stage of the gas flow when clicked, ⑤ Equipment image/text pop-up displaying the name or image of major equipment through which the gas flow passes, ⑥ NEXT pop-up that moves to the next stage of gas flow when clicked, ⑦ Gas flow subtitles explaining the gas flow of 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 a PDF E-book of the equipment is executed, and when the pop-up is closed, the next stage of gas flow is automatically performed. Executable design information and ⑩ drawings and precautions of the equipment can be provided in the form of a PDF E-book, etc., and can include a PDF E-book pop-up that supports enlargement/reduction and print functions.

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

Specifically, the local based on board view (Local based on board View) content screen is ① a shortcut pop-up that supports a shortcut to the ship's main equipment MIMIC, ② an activated icon that is implemented identically to the actual MOP (Main Operation Panel) MOP that can move to the MIMIC of main and other equipment when clicked, ③ MIMIC name indicating the name of the MIMIC on the current screen, ④ If the 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 appears and automatically disappears when the mouse is moved, and displays the VR image pop-up when the displayed IO-tag icon is clicked, ⑤ VR image pop-up that provides current location and snapshot information of the equipment , ⑥ VR image pop-up displayed when IO-tag icon is clicked on MIMIC, ⑦ IO-tag icon that displays the name and location of the device clicked on MIMIC, ⑧ A close-up image of the selected device, when the mouse hovers over the IO-tag icon automatically , and IO-tagged snapshots that automatically disappear when the mouse is moved, and ⑨ a radar icon that displays the direction of VR on the current screen and can be moved according to the screen movement.

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

As shown in FIGS. 5A and 5B, the operation guide view content of the seafarer education system based on VR spatial information according to a preferred embodiment of the present invention indicates the gas flow in the ship in MIMIC and displays CG and VR It learns the complex automatic gas operation sequence and gas flow step by step by interlocking and enables virtual perception of actual operation.

Specifically, the Operation Guide View content screen includes ① a menu name indicating the name of the corresponding content menu, ② equipment name indicating the name of the main equipment of the ship, ③ name of the gas sequence corresponding to the main equipment operation. Gas sequence name to be marked, ④ step guide icon to be selected in the MIMIC, each step is numbered and applied when it is necessary to check in sequence, ⑤ text to check or refer to during operation A pop-up that is displayed in the form of a tip box that is applied when there is a need for operation, a pop-up that is displayed when the MIMIC view icon is clicked in the ⑥ step box. It displays the equipment to be used as a box, and when there is a linked VR image, VR pop-up is displayed when clicked, and when there is animation in the MOP menu, when clicked, the animation is driven.

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

As shown in FIGS. 6A and 6B , the trouble shooting content of the seafarer education system based on VR spatial information according to a preferred embodiment of the present invention transmits information related to inspection and maintenance of ships and equipment through video 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 during equipment operation.

Specifically, the Trouble Shooting content screen is ① menu name indicating the name of the corresponding content menu, ② equipment name indicating the name of the main equipment of the ship, ③ case name indicating the main trouble shooting case of the corresponding equipment , ④ TROUBLESHOOTING icon that displays after moving to the VR spot of the equipment when clicking the case name and displays PDF E-book when clicked, and ⑤ TROUBLESHOOTING icon of the selected case when clicking the TROUBLESHOOTING icon, Actions, etc. can be provided in the form of an E-book, etc., and can include a PDF E-book pop-up that supports enlargement/reduction, saving and printing functions.

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

As shown in FIGS. 7A and 7B , the VR on board View (VR on board View) contents of the VR spatial information-based seafarer education system according to a preferred embodiment of the present invention are not directly broadcast by seafarers and engineers, but by PC or It is possible to easily grasp the location and actual appearance of facilities and sensors on the drawing by linking GA drawings and actual VR so that the entire interior and exterior space of the ship can be checked through a laptop computer.

Specifically, the VR on board View (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 (eg, home screen, cargo room, and engine room) of the corresponding GA drawing Shortcut pop-up that supports shortcuts ③ If there is a VR image linked to the GA drawing, the space is marked 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 display VR linkage to move to detailed drawing, ④ Move to VR image when clicking the VR spot icon on the GA drawing, MIMIC pop-up that is reduced in size and converted to a pop-up form, ⑤ Click the white hot spot icon on the VR screen A hot spot icon that moves to the VR image and ⑥ a radar icon that displays the position and direction of VR on the current screen in conjunction with MIMIC can be included.

Although the present invention has been described in more detail with several examples above, the present invention is not necessarily limited to these examples and may be variously modified without departing from the technical spirit of the present invention.

100: Crew training system based on VR spatial information
110: video receiver
120: simulation image production unit
130: VR image production unit
140: VR interlocking unit
150: CG interlocking unit

Claims (8)

an image receiving unit configured to receive and store images of a vessel space and one or more equipment;
a simulation image production unit for producing MIMIC images and GA (General Arrangement) drawings that provide simulation of standard operating procedures of the vessel and equipment;
a VR image production unit that creates a VR image of the inside of the vessel space and the one or more equipments by stitching interlocking parts of individual images captured in the ship space received by the image receiver;
A VR linkage unit that links VR images related to the one or more equipment and each equipment operation process performed in the ship to the MIMIC and GA drawings, and
A CG interlocking unit that interlocks various CGs with VR images related to each of the equipment operation processes,
The equipment is equipment through which the gas flow passes,
Process overview content that provides information related to the gas flow and the equipment through which the gas flow passes by grafting the VR image and various CGs;
Local based on board view content providing the MIMIC with the shipboard location and shape of the equipment by interlocking VR and IO-tags of the equipment;
Trouble shooting content that provides information related to inspection and maintenance of the vessel and equipment, and
A seafarer training system including VR on board view (VR on board view) content on board view that enables the position and actual appearance of the equipment to be grasped by linking the GA drawing and VR. The method of claim 1,
Said ship is a liquefied natural gas carrier (Liquefied Natural Gas Carrier, LNGC) crew training system. delete The method of claim 1,
The simulation image production unit interlocks data between MIMICs and accumulates and applies them to other interlocked MIMICs when the valve state or gas pressure changes through each of the equipment operation processes in the current MIMIC. Receiving and storing an image of a vessel space and one or more equipment;
producing MIMIC images and GA drawings providing simulations of standard operating procedures of the vessel and equipment;
making a VR image of the inside of the ship space and the one or more equipments by splicing interlocking parts of individual images taken in the ship space;
Linking VR images related to the one or more equipment and each equipment operation process performed in the ship to the MIMIC and GA drawings, and
Linking various CGs to VR images related to each of the equipment operation processes,
The equipment is equipment through which the gas flow passes,
Process overview content that provides information related to the gas flow and the equipment through which the gas flow passes by grafting the VR image and various CGs;
Local based on board view content that provides the MIMIC with the position and shape of the equipment on board by interlocking the VR and IO-tag of the equipment;
Trouble shooting content that provides information related to inspection and maintenance of the vessel and equipment, and
A crew member training method for providing VR (VR on board view) content on board view that enables the position and actual appearance of the equipment to be grasped by linking the GA drawing and VR. The method of claim 5,
Said ship is a liquefied natural gas carrier (Liquefied Natural Gas Carrier, LNGC) crew member training method. delete The method of claim 5,
The step of producing the MIMIC image and GA drawing is a crew member training method in which data between MIMICs is linked and accumulated and applied to other MIMICs interlocked when the valve state or gas pressure changes through each equipment operation process in the current MIMIC.

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