A device for underwater equipment tamperproofing and leakage monitoring and method thereof
By introducing auxiliary use and dehumidification cleaning mechanisms into the underwater equipment monitoring terminal, the problem of moisture absorption in humid environments has been solved, thus improving the service life and ease of operation of the device.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Patents(China)
- Current Assignee / Owner
- JIANGSU OCEAN UNIV
- Filing Date
- 2025-03-06
- Publication Date
- 2026-07-07
AI Technical Summary
Existing underwater equipment monitoring terminals are used in environments with high humidity, which causes electronic components to become damp and damaged, reducing the lifespan of the device and causing economic losses.
An underwater equipment monitoring terminal was designed, equipped with an auxiliary operation mechanism, a locking mechanism, and a dehumidification and cleaning mechanism. The auxiliary operation mechanism is easy to operate with one hand, the locking mechanism is kept in a folded state, and the dehumidification and cleaning mechanism dehumidifies and dissipates heat through dry air.
This improved the lifespan of the device, avoided economic losses, and made it easy to operate in confined spaces, thus achieving practicality and reliability.
Smart Images

Figure CN120096772B_ABST
Abstract
Description
Technical Field
[0001] This invention belongs to the field of equipment monitoring technology, and specifically discloses a device and method for monitoring the anti-dismantling and leakage of underwater equipment. Background Technology
[0002] In fields such as marine development, underwater scientific research, and deep-sea exploration, the safe and stable operation of underwater equipment is crucial. These devices are not only expensive to manufacture, but the scientific data and key technologies they carry are also invaluable. However, underwater equipment often faces the risk of unauthorized dismantling and leakage, which can lead to equipment damage, serious safety accidents, and huge economic losses. To effectively address these issues, devices for preventing dismantling and monitoring leakage in underwater equipment have emerged. These devices are not only used for existing underwater equipment, but also for underwater equipment utilizing new materials, to ensure the reliability of these new materials.
[0003] Currently, devices used for underwater equipment anti-tampering and leakage monitoring are divided into underwater devices and underwater equipment monitoring terminals. The underwater equipment monitoring terminal analyzes and processes the data transmitted by the underwater device and displays it to facilitate the judgment of the staff. At the same time, it is portable, so that the staff can carry out monitoring operations in different locations as needed.
[0004] The underwater equipment monitoring terminals in existing underwater equipment anti-tampering and leakage monitoring devices are usually used in water environments. These environments have high humidity, and prolonged use can cause the internal electronic components to become damp, leading to damage to the electronic components, reduced lifespan of the device, and economic losses. Summary of the Invention
[0005] In view of this, the purpose of this invention is to provide a device and method for underwater equipment anti-tampering and leakage monitoring, in order to solve the problem that in existing devices for underwater equipment anti-tampering and leakage monitoring, the underwater equipment monitoring terminal is used for a long time in a high humidity environment, causing the internal electronic components of the device to be damaged by moisture, reducing the service life of the device, and thus causing economic losses.
[0006] To achieve the above objectives, the present invention provides a device for tamper prevention and leakage monitoring of underwater equipment, including an underwater equipment monitoring terminal. The bottom of the underwater equipment monitoring terminal is provided with an auxiliary operating mechanism for easy one-handed operation. A locking mechanism is provided on the outer side of the underwater equipment monitoring terminal to maintain the auxiliary operating mechanism in a folded state. A dehumidification and cleaning mechanism is provided at the bottom of the underwater equipment monitoring terminal to dissipate heat while removing humid air from the underwater equipment monitoring terminal. A data plug is detachably connected to the side of the underwater equipment monitoring terminal away from the locking mechanism, and a data cable is fixedly connected to the side of the data plug away from the underwater equipment monitoring terminal.
[0007] In the above technical solution, preferably, the auxiliary use mechanism includes two rotating support arms, which are respectively fixedly connected to the bottom sides of the underwater equipment monitoring terminal. The rotating support arms have placement grooves inside and sliding grooves on both sides. Rotating folding rods are rotatably connected to both sides of the bottom of the underwater equipment monitoring terminal. Sliding pins are fixedly connected to the bottom of the rotating folding rods. The two ends of the sliding pins are respectively set inside the two sliding grooves. A stabilizing rod is fixedly connected between the two rotating support arms. A hanging rope is fixedly connected to the outside of the underwater equipment monitoring terminal.
[0008] In the above technical solution, preferably, the locking mechanism includes a fixed rod, the fixed rod is fixedly connected to the outside of the underwater equipment monitoring terminal, a rotating hollow column is rotatably connected to the outside of the fixed rod, a torsion spring is provided inside the rotating hollow column, a toggle plate is fixedly connected to the top of the rotating hollow column, a locking head is fixedly connected to the bottom of the rotating hollow column, and the fixed rod is sleeved on the inside of the torsion spring.
[0009] In the above technical solution, preferably, the dehumidification and cleaning mechanism includes an installation cylinder, the outside of which is fixedly connected to the bottom of the underwater equipment monitoring terminal. One end of the installation cylinder is threadedly connected to a rotating cover. A filter box is installed inside the installation cylinder. A miniature air pump is fixedly connected to the middle of the bottom of the underwater equipment monitoring terminal. A connecting hose is fixedly connected between the input end of the miniature air pump and the bottom of the rotating cover. A connecting cooling pipe is fixedly connected to the output end of the miniature air pump. An air inlet connecting pipe is fixedly connected to the side of the underwater equipment monitoring terminal away from the locking mechanism. An exhaust connecting pipe is fixedly connected to the outside of the underwater equipment monitoring terminal adjacent to the air inlet connecting pipe. An elastic connecting pipe is fixedly connected to the end of the exhaust connecting pipe away from the underwater equipment monitoring terminal. An air jet column is fixedly connected to the end of the elastic connecting pipe away from the exhaust connecting pipe. Multiple heat sinks are fixedly connected to the bottom of the underwater equipment monitoring terminal. The connecting cooling pipe is disposed inside the multiple heat sinks.
[0010] In the above technical solution, preferably, one end of the torsion spring is fixedly connected to the inner side of the rotating hollow column, and the other end of the torsion spring is fixedly connected to the outside of the fixed rod.
[0011] In the above technical solution, preferably, the jet column is snapped into the inner side of the underwater equipment monitoring terminal, and a ventilation slot is opened inside one side of the underwater equipment monitoring terminal.
[0012] In the above technical solution, preferably, a fixing cylinder is fixedly connected to the inner side of the rotating cover, and a compression spring is provided inside the fixing cylinder.
[0013] In the above technical solution, preferably, a sliding limiting plate is slidably connected inside the fixed cylinder, and a pressing column is fixedly connected to the side of the sliding limiting plate away from the compression spring.
[0014] In the above technical solution, preferably, one end of the compression spring is fixedly connected to the inside of the fixed cylinder, and the other end of the fixed cylinder is fixedly connected to the end of the sliding limiting plate away from the pressing post.
[0015] A method for an apparatus for tamper prevention and leakage monitoring of underwater equipment, comprising the following steps:
[0016] Step 1: When using the device in a narrow space, unfold the auxiliary mechanism and place the device against your body. At this time, you can operate it with one hand.
[0017] Step 2: After the device has been used for a period of time or left unused for a period of time, dry and cool air can be introduced into the underwater equipment monitoring terminal using the dehumidification and cleaning mechanism to quickly dehumidify and cool the device.
[0018] Step 3: When there is dust on the outside of the device, use the air sprayed from the underwater equipment monitoring terminal to remove the dust from the outside of the underwater equipment monitoring terminal.
[0019] Compared with the prior art, the present invention has the following beneficial effects:
[0020] 1. This invention uses a dehumidification and cleaning mechanism to dry the air entering the device, preventing the electronic components inside the device from being damaged by moisture. This can improve the service life of the device and avoid economic losses. At the same time, it can also cool the inside of the device and clean the outer surface of the device, thus better protecting the device.
[0021] 2. By combining the auxiliary operating mechanism and the locking mechanism, this invention enables easy operation with one hand in narrow spaces where it is inconvenient to operate with both hands, thereby facilitating the use of the device in different environments and improving its practicality. Attached Figure Description
[0022] Figure 1 The three-dimensional representation of the present invention Figure 1 ;
[0023] Figure 2 The three-dimensional representation of the present invention Figure 2 ;
[0024] Figure 3 This is a schematic diagram of the rotating support arm in this invention;
[0025] Figure 4 This is a schematic diagram of the structure of the fixing rod in this invention;
[0026] Figure 5 The three-dimensional representation of the present invention Figure 3 ;
[0027] Figure 6 This is a schematic diagram of the structure of the connecting cooling pipe in this invention;
[0028] Figure 7 This is a schematic diagram of the mounting cylinder in this invention;
[0029] Figure 8 This is a schematic diagram of the structure of the fixed cylinder in this invention;
[0030] Figure 9 This is a schematic diagram of the jet column structure in this invention.
[0031] In the diagram: 1. Underwater equipment monitoring terminal; 2. Auxiliary operating mechanism; 201. Rotating support arm; 202. Placement slot; 203. Sliding slot; 204. Rotating folding rod; 205. Sliding locking post; 206. Stabilizing rod; 207. Hanging rope; 3. Locking mechanism; 301. Fixing rod; 302. Rotating hollow column; 303. Torsion spring; 304. Actuating curved plate; 305. Locking head; 4. Dehumidification and cleaning mechanism; 401. Mounting cylinder 402. Rotating cover; 403. Filter box; 404. Miniature air pump; 405. Connecting hose; 406. Connecting cooling pipe; 407. Air inlet connection pipe; 408. Exhaust connection pipe; 409. Flexible connection pipe; 410. Air jet column; 411. Vent slot; 412. Fixing cylinder; 413. Compression spring; 414. Sliding limit plate; 415. Clamping post; 416. Heat sink; 5. Data plug; 6. Data cable. Detailed Implementation
[0032] To better understand the above-mentioned objectives, features, and advantages of the present invention, the present invention will be further described in detail below with reference to the accompanying drawings and specific embodiments.
[0033] Numerous specific details are set forth in the following description in order to provide a full understanding of the invention. However, the invention may also be practiced in other ways different from those described herein, and therefore the invention is not limited to the specific embodiments disclosed below.
[0034] like Figures 1-9 The device shown is for preventing tampering and monitoring leakage of underwater equipment. It includes an underwater equipment monitoring terminal 1. An auxiliary use mechanism 2 is provided at the bottom of the underwater equipment monitoring terminal 1. The auxiliary use mechanism 2 allows the underwater equipment monitoring terminal 1 to be operated with one hand. A locking mechanism 3 is provided on the outer side of the underwater equipment monitoring terminal 1. The locking mechanism 3 is used to keep the auxiliary use mechanism 2 in a folded state. A dehumidification and cleaning mechanism 4 is provided at the bottom of the underwater equipment monitoring terminal 1. The dehumidification and cleaning mechanism 4 is used to remove humid air from the underwater equipment monitoring terminal 1 while dissipating heat. A data plug 5 is detachably connected to the side of the underwater equipment monitoring terminal 1 away from the locking mechanism 3. A data cable 6 is fixedly connected to the side of the data plug 5 away from the underwater equipment monitoring terminal 1.
[0035] The auxiliary operating mechanism 2 includes two rotating support arms 201, which provide support. The two rotating support arms 201 are fixedly connected to the bottom sides of the underwater equipment monitoring terminal 1. Each rotating support arm 201 has a placement slot 202 inside, providing storage space. Sliding grooves 203 are provided on both sides of each rotating support arm 201. Rotating folding rods 204 are rotatably connected to both sides of the bottom of the underwater equipment monitoring terminal 1. The rotating folding rods 204 can be retracted into the placement slots 202, thus enabling the auxiliary operating mechanism 2 to fold. A sliding locking post 205 is fixedly connected to the bottom of each rotating folding rod 204, and the sliding grooves 203 provide sliding... The sliding locking post 205 slides, with its two ends respectively set inside the two sliding grooves 203. A stabilizing rod 206 is fixedly connected between the two rotating support arms 201. The stabilizing rod 206 can simultaneously drive the two rotating support arms 201 to rotate and can improve the stability of the two stabilizing rods 206. A hanging rope 207 is fixedly connected to the outside of the underwater equipment monitoring terminal 1. When using the device in narrow places or places where it is inconvenient to use both hands, first hang the hanging rope 207 around the neck of the operator. At this time, the locking mechanism 3 and the stabilizing rod 206 are released, and the rotating support arm 201 can rotate downward under the action of gravity. At this time, the folding rod 204 rotates. Under the pull of the rotating support arm 201 and the action of gravity, it rotates downwards, allowing the sliding pin 205 to slide inside the sliding groove 203. The sliding pin 205 engages with the side of the sliding groove 203 near the stabilizing rod 206. At this point, gravity prevents the rotating support arm 201 from automatically rotating upwards. Simultaneously, the rotating support arm 201 and the stabilizing rod 206 are pressed against the operator's body. Supported by the operator's body, the sliding groove 203 also remains stationary, allowing the rotating support arm 201 to unfold. This allows the display screen of the underwater equipment monitoring terminal 1 to be at approximately a 90-degree angle to the operator's body. The screen is positioned so that it faces upwards, making it convenient for staff to use. When folding up, simply lift the stabilizer 206 upwards, which will cause the rotating support arm 201 to rotate upwards. When the rotating support arm 201 rotates upwards, it releases the engagement between the sliding pin 205 and the sliding groove 203. Under the pressure of the rotating support arm 201, the sliding pin 205 slides inside the sliding groove 203 and moves away from the stabilizer 206. When the rotating support arm 201 is fully folded up, the rotating folding rod 204 rotates into the placement groove 202, which allows the stabilizer 206 to engage with the bottom of the engagement mechanism 3, thus completing the folding of the auxiliary use mechanism 2.
[0036] The locking mechanism 3 includes a fixed rod 301, which provides installation conditions. The fixed rod 301 is externally fixedly connected to the outer side of the underwater equipment monitoring terminal 1. A rotating hollow column 302 is rotatably connected to the outside of the fixed rod 301. The rotating hollow column 302 provides the installation position and serves as a connection. A torsion spring 303 is installed inside the rotating hollow column 302, which enables the rotating hollow column 302 to automatically reset. A movable curved plate 304 is fixedly connected to the top of the rotating hollow column 302, which facilitates rotation by the operator. The hollow column 302 is rotated, and a locking head 305 is fixedly connected to its outer bottom end. A fixing rod 301 is sleeved on the inner side of a torsion spring 303. One end of the torsion spring 303 is fixedly connected to the inner side of the hollow column 302, and the other end is fixedly connected to the outer side of the fixing rod 301. When the locking mechanism 3 releases its engagement with the auxiliary operating mechanism 2, it first rotates the actuating plate 304 towards the underwater equipment monitoring terminal 1. The rotation of the actuating plate 304 drives the hollow column 302 to rotate. This allows the locking head 305 to rotate away from the underwater equipment monitoring terminal 1, thus disengaging it from the stabilizing rod 206. At this point, the locking head 305 is released from its engagement with the stabilizing rod 206, and the torsion spring 303 is compressed. After the locking head 305 is released from its engagement with the stabilizing rod 206, the actuating plate 304 is released. Under the action of the torsion spring 303, the actuating plate 304 drives the rotating hollow column 302 to rotate in the opposite direction, thereby causing the locking head 305 to rotate in the opposite direction and thus achieving the reset of the locking head 305. To engage with the stabilizer bar 206, rotate the stabilizer bar 206 upwards. When the stabilizer bar 206 contacts the bottom of the engaging head 305, since the bottom of the engaging head 305 is curved and the stabilizer bar 206 is also curved, the engaging head 305 can be rotated under the pressure, allowing the stabilizer bar 206 to enter the inside of the engaging head 305. After the stabilizer bar 206 is fully inside the engaging head 305, the engaging head 305 is reset under the action of the torsion spring 303, thus completing the engagement between the engaging head 305 and the stabilizer bar 206.
[0037] The dehumidification and cleaning mechanism 4 includes a mounting cylinder 401, which provides installation space. The mounting cylinder 401 is externally fixedly connected to the bottom of the underwater equipment monitoring terminal 1. One end of the mounting cylinder 401 is threadedly connected to a rotating cover 402, which can seal the mounting cylinder 401. A filter box 403 is installed inside the mounting cylinder 401, which can hold desiccant. A miniature air pump 404 is fixedly connected to the middle of the bottom of the underwater equipment monitoring terminal 1, which provides the power for air flow. A connecting hose 405 is fixedly connected between the input end of the miniature air pump 404 and the bottom of the rotating cover 402. A connecting cooling pipe 406 is fixedly connected to the output end of the miniature air pump 404. The underwater equipment monitoring terminal 1 is located away from the locking mechanism. An air inlet pipe 407 is fixedly connected to one side of mechanism 3. An exhaust pipe 408 is fixedly connected to the exterior of underwater equipment monitoring terminal 1, adjacent to the air inlet pipe 407. An elastic connecting pipe 409 is fixedly connected to the end of the exhaust pipe 408 away from underwater equipment monitoring terminal 1, providing a connection. A jet column 410 is fixedly connected to the end of the elastic connecting pipe 409 away from the exhaust pipe 408, facilitating the ejection of gas. Multiple heat sinks 416 are fixedly connected to the bottom of underwater equipment monitoring terminal 1, accelerating cooling. A cooling pipe 406 is located inside the multiple heat sinks 416. The jet column 410 is snapped into the inner side of underwater equipment monitoring terminal 1. A ventilation slot 411 is provided inside one side of the measuring terminal 1. A fixed cylinder 412 is fixedly connected to the inner side of the rotating cover 402. A compression spring 413 is installed inside the fixed cylinder 412. A sliding limit plate 414 is slidably connected inside the fixed cylinder 412. A pressing post 415 is fixedly connected to the side of the sliding limit plate 414 away from the compression spring 413. One end of the compression spring 413 is fixedly connected to the inside of the fixed cylinder 412, and the other end of the fixed cylinder 412 is fixedly connected to the end of the sliding limit plate 414 away from the pressing post 415. When performing cooling and dehumidification operation, the micro air pump 404 is first started. Air is drawn in through the connecting hose 405 from the input end of the micro air pump 404. The air enters the interior of the filter box 403 and is filtered by the air inside the filter box 403. A desiccant dehumidifies the air and is introduced into the underwater equipment monitoring terminal 1 through the connecting cooling pipe 406 and the air inlet connecting pipe 407. After the dry air enters, it exhausts the air inside the underwater equipment monitoring terminal 1 through the exhaust connecting pipe 408. At this time, the interior of the underwater equipment monitoring terminal 1 is filled with dry air, thus achieving the dehumidification effect. Simultaneously, the connecting cooling pipe 406, through which the dry air is introduced, is cooled by the heat sink 416, thereby lowering the temperature of the air inside the connecting cooling pipe 406 and thus cooling the underwater equipment monitoring terminal 1. Meanwhile, the air ejected from the exhaust connecting pipe 408 enters the interior of the jet column 410 through the flexible connecting pipe 409. If it is not necessary to clean the outer surface of the underwater equipment monitoring terminal 1...Air will then be discharged through the ventilation port 411. If cleaning of the outer surface of the underwater equipment monitoring terminal 1 is required, the jet column 410 is pulled out from inside the underwater equipment monitoring terminal 1, and the jet outlet of the jet column 410 is directed towards the area on the outer surface of the underwater equipment monitoring terminal 1 that needs cleaning, thereby cleaning the outer surface of the underwater equipment monitoring terminal 1.
[0038] A method for an apparatus for tamper prevention and leakage monitoring of underwater equipment, comprising the following steps:
[0039] Step 1: When using the device in a narrow space, the auxiliary use mechanism 2 can be unfolded and the device can be placed against the body, at which point it can be operated with one hand;
[0040] Step 2: After the device has been used for a period of time or left unused for a period of time, the dehumidification and cleaning mechanism 4 can be used to introduce dry and cool air into the interior of the underwater equipment monitoring terminal 1 to quickly dehumidify and cool down the device.
[0041] Step 3: When there is dust on the outside of the device, use the air sprayed from the underwater equipment monitoring terminal 1 to remove the dust from the outside of the underwater equipment monitoring terminal 1.
[0042] Working Principle: When using the device in confined spaces or where it is inconvenient to use both hands, first hang the hanging rope 207 around the worker's neck. Then, release the engaging mechanism 3 and the stabilizing rod 206. Under gravity, the rotating support arm 201 will rotate downwards. Simultaneously, the rotating folding rod 204 will rotate downwards under the pull of the rotating support arm 201 and gravity, allowing the sliding pin 205 to slide inside the sliding groove 203. The sliding pin 205 will then engage in the sliding groove 203 near the stabilizing rod 206. Under gravity, the rotating support arm 201 will not automatically rotate upwards. Simultaneously, the rotating support arm 201 and the stabilizing rod 206 will rest against the worker's body, and the worker's body support will also prevent the sliding groove 203 from rotating upwards. Then the rotating support arm 201 can be unfolded, so that the display screen of the underwater equipment monitoring terminal 1 and the operator's body are at an angle of nearly 90 degrees, thus ensuring that the display screen faces upwards, which is convenient for the operator to use. When retracting, simply lift the stabilizing rod 206 upwards, which will drive the rotating support arm 201 to rotate upwards. When the rotating support arm 201 rotates upwards, the sliding pin 205 and the sliding groove 203 are released from engagement, and the sliding pin 205 slides inside the sliding groove 203 under the pressure of the rotating support arm 201 and moves away from the stabilizing rod 206. When the rotating support arm 201 is fully retracted, the rotating folding rod 204 rotates into the placement groove 202, which allows the stabilizing rod 206 to engage with the bottom of the engagement mechanism 3, thus completing the folding of the auxiliary use mechanism 2.
[0043] When the engaging mechanism 3 releases its engagement with the auxiliary operating mechanism 2, it first rotates the actuating plate 304 towards the underwater equipment monitoring terminal 1. The rotation of the actuating plate 304 drives the rotating hollow column 302 to rotate, which in turn drives the engaging head 305 to rotate away from the underwater equipment monitoring terminal 1. This causes the engaging head 305 to disengage from the stabilizing rod 206, releasing the engagement between the engaging head 305 and the stabilizing rod 206. Simultaneously, the torsion spring 303 is compressed. After the engaging head 305 and the stabilizing rod 206 are released, the actuating plate 304 is released. Under the action of the torsion spring 303, the actuating plate 304 will then drive the rotating hollow column 305 to rotate. 02 Reverse rotation, which drives the locking head 305 to rotate in the opposite direction, thereby enabling the locking head 305 to reset. When it is necessary to engage with the stabilizer bar 206, the stabilizer bar 206 is rotated upward. When the stabilizer bar 206 contacts the bottom of the locking head 305, since the bottom of the locking head 305 is curved and the stabilizer bar 206 is also curved, the locking head 305 can be rotated under the action of compression, thereby enabling the stabilizer bar 206 to enter the inner side of the locking head 305. After the stabilizer bar 206 is fully inside the locking head 305, the locking head 305 is reset under the action of the torsion spring 303, thus completing the engagement of the locking head 305 and the stabilizer bar 206.
[0044] During the cooling and dehumidification operation, the micro air pump 404 is first started. Air is drawn in through the connecting hose 405 from the input end of the micro air pump 404. The air enters the filter box 403 and is dehumidified by the desiccant inside the filter box 403. The dehumidified air then flows through the cooling pipe 406 and the air inlet pipe 407 into the underwater equipment monitoring terminal 1. The dry air then exhausts the air inside the underwater equipment monitoring terminal 1 through the exhaust pipe 408. At this point, the interior of the underwater equipment monitoring terminal 1 is filled with dry air, thus achieving dehumidification. Simultaneously, the cooling pipe 406, through which the dry air flows, is cooled by the heat sink 416, thereby cooling the air inside the cooling pipe 406 and thus cooling the underwater equipment monitoring terminal 1. Meanwhile, the air ejected from the exhaust pipe 408 enters the air jet column 410 through the flexible connecting pipe 409. If no cleaning is required... When cleaning the outer surface of the underwater equipment monitoring terminal 1, air will be discharged through the ventilation slot 411. If it is necessary to clean the outer surface of the underwater equipment monitoring terminal 1, the jet column 410 is pulled out from the inside of the underwater equipment monitoring terminal 1, and the jet outlet of the jet column 410 is directed towards the area on the outer surface of the underwater equipment monitoring terminal 1 that needs to be cleaned, thereby cleaning the outer surface of the underwater equipment monitoring terminal 1. When replacing the filter box 403, first turn the rotating cover 402 to open it, then pour the filter box 403 out from the inside of the mounting cylinder 401, and put the new filter box 403 into the inside of the mounting cylinder 401. Then screw the rotating cover 402 back onto one end of the mounting cylinder 401. When the rotating cover 402 is screwed on, the clamping column 415 will press against one end of the filter box 403, and the reaction force of the compression spring 413 will be used to press the filter box 403 tightly.
[0045] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely principles of the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed invention. The scope of protection claimed by the appended claims and their equivalents is defined.
Claims
1. A device for preventing tampering and monitoring leakage of underwater equipment, comprising an underwater equipment monitoring terminal (1), characterized in that, The underwater equipment monitoring terminal (1) is provided with an auxiliary use mechanism (2) at the bottom, which is convenient for one-handed operation. The underwater equipment monitoring terminal (1) is provided with a locking mechanism (3) on the outer side, which is used to keep the auxiliary use mechanism (2) in a folded state. The underwater equipment monitoring terminal (1) is provided with a dehumidification and cleaning mechanism (4) at the bottom, which is used to dissipate heat from the underwater equipment monitoring terminal (1) and remove humid air from the underwater equipment monitoring terminal (1). A data plug (5) is detachably connected to the side of the underwater equipment monitoring terminal (1) away from the locking mechanism (3). A data cable (6) is fixedly connected to the side of the data plug (5) away from the underwater equipment monitoring terminal (1). The auxiliary operating mechanism (2) includes two rotating support arms (201), which are fixedly connected to the bottom sides of the underwater equipment monitoring terminal (1). The rotating support arms (201) have placement slots (202) inside and sliding slots (203) on both sides. Rotating folding rods (204) are rotatably connected to the bottom sides of the underwater equipment monitoring terminal (1). Sliding pins (205) are fixedly connected to the bottom of the rotating folding rods (204). The two ends of the sliding pins (205) are respectively set inside the two sliding slots (203). A stabilizing rod (206) is fixedly connected between the two rotating support arms (201). A hanging rope (207) is fixedly connected to the outside of the underwater equipment monitoring terminal (1).
2. The device for anti-dismantling and leakage monitoring of underwater equipment according to claim 1, characterized in that, The locking mechanism (3) includes a fixed rod (301), which is fixedly connected to the outside of the underwater equipment monitoring terminal (1). A rotating hollow column (302) is rotatably connected to the outside of the fixed rod (301). A torsion spring (303) is provided inside the rotating hollow column (302). A toggle plate (304) is fixedly connected to the top of the rotating hollow column (302). A locking head (305) is fixedly connected to the bottom of the rotating hollow column (302). The outside of the fixed rod (301) is sleeved on the inside of the torsion spring (303).
3. The device for anti-dismantling and leakage monitoring of underwater equipment according to claim 1, characterized in that, The dehumidification and cleaning mechanism (4) includes a mounting cylinder (401), which is externally fixedly connected to the bottom of the underwater equipment monitoring terminal (1). One end of the mounting cylinder (401) is threadedly connected to a rotating cover (402). A filter box (403) is installed inside the mounting cylinder (401). A miniature air pump (404) is fixedly connected to the bottom center of the underwater equipment monitoring terminal (1). A connecting hose (405) is fixedly connected between the input end of the miniature air pump (404) and the bottom of the rotating cover (402). A connecting cooling pipe (406) is fixedly connected to the output end of the miniature air pump (404). An air inlet pipe (407) is fixedly connected to the side of the underwater equipment monitoring terminal (1) away from the locking mechanism (3). An exhaust pipe (408) is fixedly connected to the outside of the underwater equipment monitoring terminal (1) adjacent to the air inlet pipe (407). An elastic connecting pipe (409) is fixedly connected to the end of the exhaust connecting pipe (408) away from the underwater equipment monitoring terminal (1). An air jet column (410) is fixedly connected to the end of the elastic connecting pipe (409) away from the exhaust connecting pipe (408). A plurality of heat sinks (416) are fixedly connected to the bottom of the underwater equipment monitoring terminal (1). The connecting cooling pipe (406) is arranged inside the plurality of heat sinks (416).
4. The device for anti-dismantling and leakage monitoring of underwater equipment according to claim 2, characterized in that, One end of the torsion spring (303) is fixedly connected to the inside of the rotating hollow column (302), and the other end of the torsion spring (303) is fixedly connected to the outside of the fixed rod (301).
5. The device for anti-dismantling and leakage monitoring of underwater equipment according to claim 3, characterized in that, The jet column (410) is snapped into the inner side of the underwater equipment monitoring terminal (1), and a ventilation slot (411) is provided inside one side of the underwater equipment monitoring terminal (1).
6. The device for anti-dismantling and leakage monitoring of underwater equipment according to claim 3, characterized in that, A fixed cylinder (412) is fixedly connected to the inner side of the rotating cover (402), and a compression spring (413) is provided inside the fixed cylinder (412).
7. The device for anti-dismantling and leakage monitoring of underwater equipment according to claim 6, characterized in that, The fixed cylinder (412) is slidably connected to a sliding limiting plate (414), and a clamping post (415) is fixedly connected to the side of the sliding limiting plate (414) away from the compression spring (413).
8. The device for anti-dismantling and leakage monitoring of underwater equipment according to claim 7, characterized in that, One end of the compression spring (413) is fixedly connected to the inside of the fixed cylinder (412), and the other end of the fixed cylinder (412) is fixedly connected to the end of the sliding limit plate (414) away from the abutment post (415).
9. A method for an underwater equipment anti-tampering and leakage monitoring device, applied to the underwater equipment anti-tampering and leakage monitoring device according to any one of claims 1-8, characterized in that, Including the following methods: Step 1: When using the device in a narrow space, unfold the auxiliary use mechanism (2) and place the device against your body. At this time, you can operate it with one hand. Step 2: After the device has been used for a period of time or left for a period of time, the dehumidification and cleaning mechanism (4) can be used to introduce dry and cool air into the interior of the underwater equipment monitoring terminal (1) to quickly dehumidify and cool down the device. Step 3: When there is dust on the outside of the device, use the air sprayed from the underwater equipment monitoring terminal (1) to remove the dust from the outside of the underwater equipment monitoring terminal (1).