Large intelligent underwater new technology test pool

By using ultrasonic dynamic monitoring, underwater wave simulators, and temperature control devices in a large intelligent underwater test pool, the problems of incorrect movements and fatigue among divers during simulated operations were solved, enabling real-time monitoring and correction, and improving training effectiveness and safety.

CN224383797UActive Publication Date: 2026-06-19SHANGHAI HUNENG ANTI CORROSION & HEAT INSULATION ENG

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANGHAI HUNENG ANTI CORROSION & HEAT INSULATION ENG
Filing Date
2025-07-18
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

In current diver skills training, inexperienced divers often use incorrect techniques and movements during simulated operations, which are difficult to correct in a timely manner. Prolonged underwater environments lead to fatigue, causing their operations to gradually become distorted and stiff, and the operators are unable to identify the problems themselves.

Method used

It employs ultrasonic dynamic monitoring, an underwater wave simulator module, and a temperature control device to monitor divers' movements in real time, correct errors promptly, and adjust the pool temperature to simulate a real marine environment.

Benefits of technology

It enables real-time monitoring and correction of divers' movements, avoids dangers, enhances the simulation learning effect, improves the operational accuracy and safety of operators, and simulates the realism of the marine environment.

✦ Generated by Eureka AI based on patent content.

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Patent Text Reader

Abstract

This application relates to a large-scale intelligent underwater new technology test pool, specifically within the technical field of underwater new technology test pools. The pool includes a pool body, with an ultrasonic dynamic monitoring and underwater wave simulator module fixedly connected to the top of one side of the pool body. The monitoring output terminal of the ultrasonic dynamic monitoring and underwater wave simulator module extends into the pool body. A display screen is fixedly connected to the middle of one side of the pool body. This application, through the ultrasonic dynamic monitoring and underwater wave simulator module, temperature control device, temperature conduction module, and temperature control device, achieves the goal of real-time monitoring of the actions and working conditions of diving personnel using ultrasonic technology, avoiding dangers during simulated operations and enabling timely correction of erroneous operating techniques. It also controls temperature changes within the pool, making the simulated ocean conditions more realistic.
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Description

Technical Field

[0001] This application relates to an underwater new technology test pool, specifically a large-scale intelligent underwater new technology test pool. Background Technology

[0002] Currently, with the vigorous development of national marine development, a large number of research and development projects are being carried out on various civilian underwater navigation, underwater exploration, and underwater separation equipment. In order to test the performance of underwater vehicles, relevant underwater tests must be conducted. Divers are the direct participants in underwater operations, and specialized training is conducted in test pools to enhance their underwater operation skills. This includes equipment, coating equipment, underwater coating tests, underwater construction process tests, underwater coating quality inspection tests, and underwater corrosion protection tests. Simulated marine conditions are implemented to conduct underwater coating corrosion protection tests on steel structures in underwater areas and tidal zones.

[0003] Current diver skills training involves specialized training conducted in test pools during diving operations. However, during simulated operations, inexperienced divers' techniques and movements may not be correct or streamlined, making timely correction difficult. Furthermore, prolonged simulated underwater environments can cause fatigue for divers, gradually distorting and stiffening their operations, problems that are difficult for the divers themselves to detect in a timely manner. Utility Model Content

[0004] In view of the aforementioned technologies, the purpose of this application is to provide a large-scale intelligent underwater new technology test pool, which is equipped with real-time monitoring of the actions and working conditions of diving personnel based on ultrasonic technology, to avoid dangers during simulated operations and to correct errors in operating techniques in a timely manner. It can also control temperature changes in the pool to make the simulated ocean conditions more realistic. This solves the problems that during simulated operations, inexperienced divers may not be able to correct their incorrect or simplified operating techniques and movements in a timely manner, and prolonged simulated underwater environment may cause fatigue in diving personnel, causing their operations to gradually become distorted and stiff, which is difficult for the personnel to detect in time.

[0005] The large-scale intelligent underwater new technology test pool provided in this application adopts the following technical solution: it includes a pool body, an ultrasonic dynamic monitoring and underwater wave simulator module is fixedly connected to the top of one side of the pool body, the monitoring output end of the ultrasonic dynamic monitoring and underwater wave simulator module extends into the interior of the pool body, a display screen is fixedly connected to the middle of one side of the pool body, the display screen and the ultrasonic dynamic monitoring and underwater wave simulator module are electrically connected, a temperature control device is fixedly connected to the middle of the other side of the pool body, the output end of the temperature control device extends into the interior of the pool body and is fixedly connected to a temperature conduction module, and the output end of the temperature conduction module is fixedly connected to a temperature transfer pipe that is consistent with the inner wall of the pool body.

[0006] By adopting the above technical solution, the ultrasonic dynamic monitoring and underwater wave simulator module, temperature control device, and temperature conduction module are activated respectively. The temperature control device heats or cools the water in the pool, while the ultrasonic dynamic monitoring and underwater wave simulator module simulates possible waves and ocean currents and emits ultrasonic waves into the pool. Based on the ultrasonic feedback, the module locates the actions and operations of the simulated workers in the pool. This achieves the goal of real-time monitoring of the actions and operations of diving workers using ultrasonic technology, avoiding dangers during simulated operations, correcting errors in operating techniques in a timely manner, and controlling temperature changes in the pool to make the simulated ocean conditions more realistic.

[0007] Preferably, two step fixing seats are fixedly connected to the bottom of both sides of the pool body, and a frame platform is fixedly connected to the top of the pool body, with a common ladder fixed between one of the step fixing seats and the frame platform.

[0008] By adopting the above technical solution, it is very convenient to simulate workers entering the pool, and the manufacturing cost is low.

[0009] Preferably, a handrail with a perimeter consistent with the frame is fixedly connected to the top of the frame, a plurality of symmetrical inner pool handles are fixedly connected to the inner side of the pool, and support columns are fixedly connected to the corners of the inner wall of the pool.

[0010] By adopting the above technical solution, support is provided inside the pool, avoiding deformation caused by continuous changes in wave temperature over a long period of time, and extending the service life of the pool.

[0011] Preferably, the top and bottom of the inner wall of the pool are fixedly connected with soft-light waterproof lamp tubes, wherein the soft-light waterproof lamp tubes are fixedly connected through the support column, and multiple transparent windows arranged in a linear array are fixedly connected to both sides of the pool.

[0012] By adopting the above technical solution, support and protection are provided for the soft light waterproof tube, making it very easy for the pool to be illuminated by the tube, and at the same time making it clearer for the workers in the pool to see during the operation.

[0013] Preferably, the top of both sides of the pool body is fixedly connected with multiple T-shaped slot holes, and the multiple slot holes are respectively placed on the top of multiple transparent windows.

[0014] By adopting the above technical solution, fixing or opening the cover plate is easier and faster.

[0015] Preferably, both sides of the bottom of the pool are rotatably connected to cover plates, and multiple cover plates cover one side of multiple transparent windows respectively.

[0016] By adopting the above technical solution, the lighting inside the pool can be improved after the cover is opened, and people outside the pool can also observe the operation methods of the simulated workers.

[0017] Preferably, each of the multiple cover plates has two sliders slidably connected to its top center, and each slider is slidably connected to a common crossbar. The outer walls of the multiple crossbars are provided with springs, and the bottom ends of the multiple sliders are fixedly connected to a handle rod.

[0018] By adopting the above technical solution, it is easier for staff to open the cover, and the anti-slip properties are stronger.

[0019] Preferably, each of the plurality of sliders has an L-shaped locking head fixedly connected to one side, wherein two adjacent locking heads fit together to fit into the locking slot hole.

[0020] By adopting the above technical solution, the two adjacent grip rods are gripped tightly, thereby allowing the card block head to leave the card slot hole.

[0021] In summary, this application includes at least one of the following beneficial technical effects:

[0022] This large-scale intelligent underwater technology test pool utilizes an ultrasonic dynamic monitoring and underwater wave simulator module, a temperature control device, and a temperature conduction module. The temperature control device heats or cools the water in the pool, while the ultrasonic dynamic monitoring and underwater wave simulator module simulates potential waves and currents, emitting ultrasonic waves into the pool. Based on the ultrasonic feedback, it locates the actions and operations of simulated personnel within the pool, allowing external instructors to provide timely guidance and adjustments to the simulated operators. This enhances the practical learning effect of the simulation, achieving real-time monitoring of diving personnel's actions and operations using ultrasonic technology. This prevents dangers during simulated operations, corrects erroneous techniques promptly, and controls temperature changes within the pool, making the simulated ocean conditions more realistic.

[0023] This large-scale intelligent underwater technology test pool features a transparent window, a cover, and soft-light waterproof lamps. During use, two adjacent handles can be gripped tightly, allowing the locking block head to disengage from the locking slot. The slider compresses and stores energy in the spring on the outer wall of the central crossbar. After releasing the handles, the slider springs back to its original position, pulling the cover away from the transparent window. This provides ample illumination to the inside of the device, preventing dark corners that could affect the simulation effect and the operation of the divers. Opening the cover also increases the lighting inside the pool and allows people outside to observe the operation techniques of the simulated personnel. Attached Figure Description

[0024] Figure 1 This is a frontal view illustration of the present application;

[0025] Figure 2 This is a side view diagram of this application;

[0026] Figure 3 This is a cross-sectional view of the present application;

[0027] Figure 4 For this application Figure 1 Diagram of A in the middle;

[0028] Figure 5 For this application Figure 3 Diagram B in the middle.

[0029] In the picture:

[0030] 1. Pool body; 2. Step fixing seat; 3. Frame platform; 4. Handrail; 5. Inner pool handle; 6. Ultrasonic dynamic monitoring and underwater wave simulator module; 7. Display screen; 8. Temperature control device; 9. Temperature conduction module; 10. Temperature transfer pipe; 11. Support column; 12. Soft light waterproof lamp tube; 13. Transparent window; 14. Slot hole; 15. Cover plate; 16. Slider; 17. Crossbar; 18. Handle bar; 19. Locking block head. Detailed Implementation

[0031] The following is in conjunction with the appendix Figure 1 - Appendix Figure 5 This application will be described in further detail below.

[0032] Example 1: A large-scale intelligent underwater new technology test pool, referring to... Figure 1 , Figure 3 , Figure 5The system includes a pool body 1. An ultrasonic dynamic monitoring and underwater wave simulator module 6 is fixedly connected to the top of one side of the pool body 1. The monitoring output of the ultrasonic dynamic monitoring and underwater wave simulator module 6 extends into the interior of the pool body 1. A display screen 7 is fixedly connected to the middle of one side of the pool body 1, and the display screen 7 and the ultrasonic dynamic monitoring and underwater wave simulator module 6 are electrically connected. A temperature control device 8 is fixedly connected to the middle of the other side of the pool body 1. The output of the temperature control device 8 extends into the interior of the pool body 1 and is fixedly connected to a temperature conduction module 9. The output of the temperature conduction module 9 is fixedly connected to a temperature transfer pipe 10 that conforms to the inner wall of the pool body 1. The system utilizes the ultrasonic dynamic monitoring and underwater wave simulator module 6 and the temperature control device 8 to transmit signals. The configuration of module 8 and temperature control module 9 allows the ultrasonic dynamic monitoring and underwater wave simulator module 6 and temperature control device 8 to be turned on during use. The temperature control device 8 heats or cools the water in the pool, while the ultrasonic dynamic monitoring and underwater wave simulator module 6 simulates possible waves and currents and emits ultrasonic waves into the pool. Based on the ultrasonic feedback, the module locates the actions and operations of the simulated workers in the pool. This achieves the goal of real-time monitoring of the actions and operations of diving workers using ultrasonic technology, avoiding dangers during simulated operations, correcting errors in operating techniques in a timely manner, and controlling temperature changes in the pool to make the simulated ocean conditions more realistic.

[0033] Example 2: A large-scale intelligent underwater new technology test pool, referring to... Figure 1 , Figure 2 , Figure 4 , Figure 5The pool body 1 has two step fixing seats 2 fixedly connected to the bottom of both sides. A frame platform 3 is fixedly connected to the top of the pool body 1. A common handrail is fixed between one of the step fixing seats 2 and the frame platform 3. A handrail 4 with the same circumference as the frame platform 3 is fixedly connected to the top of the frame platform 3. Multiple symmetrical inner pool handles 5 are fixedly connected to the inner side of the pool body 1. Support pillars 11 are fixedly connected to the corners of the inner wall of the pool body 1. Soft-light waterproof lamp tubes 12 are fixedly connected to the top and bottom of the inner wall of the pool body 1. The soft-light waterproof lamp tube 12 is fixedly connected to the support column 11. Multiple transparent windows 13 arranged in a linear array are fixedly connected to both sides of the pool body 1. Multiple T-shaped slot holes 14 are fixedly connected to the top of both sides of the pool body 1, with each slot hole 14 positioned on top of a transparent window 13. Cover plates 15 are rotatably connected to the bottom of both sides of the pool body 1, covering one side of each transparent window 13. Two sliders 16 are slidably connected to the top center of each cover plate 15. Each of the multiple sliders 16 is slidably connected to a common crossbar 17, and the outer wall of the multiple crossbars 17 is provided with a spring. The bottom end of each of the multiple sliders 16 is fixedly connected to a handle rod 18, and one side of each of the multiple sliders 16 is fixedly connected to an L-shaped locking head 19. When two adjacent locking heads 19 are joined together, they fit into the locking slot hole 14. Through the setting of the transparent window 13, the cover plate 15, and the soft light waterproof tube 12, during use, two adjacent handle rods 18 can be gripped tightly, so that the locking head 19 can be disengaged from the locking slot hole 14. Inside the device, slider 16 compresses and stores the spring on the outer wall of the central crossbar 17. After releasing the handle rod 18, slider 16 springs back to its original position and then pulls the cover plate 15 away from the transparent window 13. This allows for sufficient lighting inside the device, avoiding dark corners in the pool that could affect the simulation effect and the operation of the diving personnel. Opening the cover plate 15 also improves the lighting inside the pool and allows people outside the pool to observe the operation of the simulated personnel.

[0034] The implementation principle of this application embodiment is as follows: First, after adding enough water to the pool body 1, turn on the soft light waterproof tube 12 to fill the pool with light. When the external sunlight is good during the day, a person grips the two adjacent handle rods 18 tightly, so that the locking block head 19 can leave the locking slot hole 14. The slider 16 compresses and stores the spring on the outer wall of the middle crossbar 17. After releasing the handle rod 18, the slider 16 springs back to its original position. Then, the cover plate 15 is pulled away from the side of the transparent window 13. Then, the simulated operator enters the pool body 1 from the frame platform 3 by holding the inner pool handle 5. Then, the external staff turns on the ultrasonic dynamic monitoring and underwater wave simulator module 6 and the temperature control device 8 respectively, so that the control... The temperature control device 8 heats or cools the water in the pool. The temperature conduction module 9 collects the temperature and transmits it to the entire pool through the temperature transfer pipe 10, so that the temperature in the pool can be raised or lowered to a specified value, making the simulated ocean water temperature difference during the day or night more realistic and consistent with reality. The ultrasonic dynamic monitoring and underwater wave simulator module 6 simulates possible waves and ocean currents and emits ultrasonic waves into the pool. Based on the ultrasonic feedback, it locates the actions and operations of the simulated workers in the pool and displays the feedback images on the display screen 7, so that external instructors can promptly guide the simulated workers inside and make quick adjustments to their actions, thereby enhancing the actual learning effect of the simulation.

[0035] The embodiments described in this specific implementation are preferred embodiments of this application and are not intended to limit the scope of protection of this application. Identical components are represented by the same reference numerals. Therefore, all equivalent changes made to the structure, shape, and principle of this application should be covered within the scope of protection of this application.

Claims

1. A large intelligent underwater new technology test pool, comprising a pool body (1), characterized in that: An ultrasonic dynamic monitoring and underwater wave simulator module (6) is fixedly connected to the top of one side of the pool body (1). The monitoring output end of the ultrasonic dynamic monitoring and underwater wave simulator module (6) extends into the pool body (1). A display screen (7) is fixedly connected to the middle of one side of the pool body (1). The display screen (7) and the ultrasonic dynamic monitoring and underwater wave simulator module (6) are electrically connected. A temperature control device (8) is fixedly connected to the middle of the other side of the pool body (1). The output end of the temperature control device (8) extends into the pool body (1) and is fixedly connected to a temperature conduction module (9). The output end of the temperature conduction module (9) is fixedly connected to a temperature transfer pipe (10) that matches the inner wall of the pool body (1).

2. The large-scale intelligent underwater new technology test pool according to claim 1, characterized in that: Two step fixing seats (2) are fixedly connected to the bottom of both sides of the pool body (1), and a frame platform (3) is fixedly connected to the top of the pool body (1). A common ladder is fixed between one of the step fixing seats (2) and the frame platform (3).

3. The large-scale intelligent underwater new technology test pool according to claim 2, characterized in that: The top of the frame (3) is fixedly connected with a handrail (4) that is consistent with the perimeter of the frame (3). The inner side of the pool body (1) is fixedly connected with a plurality of symmetrical inner pool handles (5). The inner corners of the pool body (1) are all fixedly connected with support columns (11).

4. The large-scale intelligent underwater new technology test pool according to claim 1, characterized in that: The inner wall of the pool (1) is fixedly connected to the top and bottom of the soft light waterproof lamp tube (12), wherein the soft light waterproof lamp tube (12) is fixedly connected to the support column (11), and multiple transparent windows (13) arranged in a linear array are fixedly connected to both sides of the pool (1).

5. The large-scale intelligent underwater new technology test pool according to claim 1, characterized in that: The top of both sides of the pool body (1) is fixedly connected with multiple T-shaped slot holes (14), and the multiple slot holes (14) are respectively placed on the top of multiple transparent windows (13).

6. The large-scale intelligent underwater new technology test pool according to claim 1, characterized in that: Both sides of the bottom of the pool body (1) are rotatably connected to cover plates (15), and multiple cover plates (15) cover one side of multiple transparent windows (13).

7. The large-scale intelligent underwater new technology test pool according to claim 6, characterized in that: Two sliders (16) are slidably connected to the top of the middle part of each of the multiple cover plates (15), and a common crossbar (17) is slidably connected between the two sliders (16). The outer wall of the multiple crossbars (17) is provided with springs, and a handle bar (18) is fixedly connected to the bottom end of each of the multiple sliders (16).

8. The large-scale intelligent underwater new technology test pool according to claim 7, characterized in that: Each of the multiple sliders (16) has an L-shaped locking head (19) fixedly connected to one side, wherein two adjacent locking heads (19) are fitted together to fit the locking slot (14).