The present invention belongs to the technical field of underwater positioning, and relates to a submarine optical positioning beacon system, in particular to a submarine optical positioning beacon system with self-generating capability.
Due to the large amount of ions and other impurities in seawater, radio positioning is currently difficult to achieve in this environment. At present, the main underwater positioning methods mainly use sonar positioning and laser positioning. Sound waves are longitudinal so they are more stable underwater, but their propagation speed is relatively slow, therefore there is hysteresis in medium and long-distance positioning, which will cause that the position of the rover at that time cannot be correctly reflected. The cost of laser positioning is expensive, and the rover needs to carry energy and receivers that provide sufficient power, which greatly affects the rover performance. A few positioning systems use LED lighting for positioning, but due to the high amount of impurities on the seabed, the penetration of LED lights is weak, and it is necessary to use high-power LEDs to work properly. High-power LEDs consume a lot of power, thus systems based on the use of LED light location beacons generally do not work well for a long time.
To solve the problems in the background, the present invention provides a submarine optical positioning beacon system with self-generating capability.
The technical solution of the invention:
A submarine optical positioning beacon system with self-generating capability, consisting of an array 1, which composed of a plurality of underwater beacons Ai;
The underwater beacon Ai is mainly composed of an LED lamp group 2, a runner 5, a generator 10 and a battery 11; the LED lamp group 2 and a COMS sensor 3 are both fixed on a waterproof casing 4, and the COMS sensor 3 is used for monitoring the light emitted by the target that needs to be positioned externally, and is used as a switch for controlling the opening and closing of the LED group 2, the COMS sensor 3 is in operation after the underwater beacon Ai is turned on until the underwater beacon Ai is turned off; The waterproof casing 4 is internally packaged with a circuit board, and the LED lamp group 2 and the COMS sensor 3 pin are soldered to the inner circuit board of the waterproof casing 4; the waterproof casing 4 is fixedly connected to the top end of a pillar 6, and a bearing 25 is fixed in the middle of the pillar 6; The generator 10 and the runner 5 are fixed on the bearing 25, the rotating core of the generator 10 is connected to the middle shaft of the runner 5 by soldering, and the electric power is generated by the electromagnetic induction generator 10 when the runner 5 rotates; one end of the horizontal bracket 24 is fixed on the opposite side of the bearing position of the generator 10 and the runner 5, and a deflector 16 is fixed on the other end of the horizontal bracket 24. The deflector 16, the horizontal bracket 24, the generator 10 and the runner 5 are located on the same horizontal line, and the deflector 16 is forced to drive the horizontal bracket 24, generator 10 and runner 5 rotate together, thereby ensuring that the runner 5 is always facing the ocean current; the pillar 6 is fixed on the base 9, and the base 9 is internally group with a microprocessor 14 and a battery 11; the microprocessor 14 generates a PWM wave through the control module to adjust the light species of the LED lamp group 2 to generate different color lights; the generator 10 and the battery 11 are connected by a cable 7, and the electric energy generated by the generator 10 is stored in the battery 11 through the cable 7; The surface of the base 9 of the underwater beacon Ai has an ISP interface 13 for downloading the program in the control module; the bottom bracket b21 and the bottom bracket c22 are fixed at the bottom of the base 9, so that the underwater beacon Ai can be smoothly fixed at the sea bottom 18; The upper ends of the chain a8 and the chain b15 are fixedly connected with the waterproof casing 4, and the lower ends are respectively fixedly connected to the bottom bracket a12, the bottom bracket b21, the bottom bracket c22 and the bottom bracket d23, so that the underwater beacon Ai can be uniformly and smoothly fixed at the sea bottom 18;
The pillar 6 is a hollow pillar with a cable in the middle to supply power to the LED lamp group 2 and the COMS sensor 3.
The LED lamp group 2 is a high-power LED lamp capable of propagating 1-2 m in a turbid seawater environment and 5-10 m in clear seawater.
The beneficial effects of the present invention: each underwater beacon Ai in the submarine optical positioning beacon system with self-power generating capability has an independent power generation component, which can generate power by utilizing ocean current, greatly increasing the working time of the beacon. And the LED light group of the underwater beacon is not always in working state, it works when the COMS sensor detects that the required positioning target is near the beacon; and the LED light group gives positional information feedback through light, which can reduce the system power consumption and increase the system working duration.
In the figures: 1 an array of a plurality of underwater beacons Ai; 2 LED light group; 3 COMS sensor; 4 waterproof casing; 5 runner; 6 pillar; 7 cable; 8 chain a; 9 base; 10 generator; 11 battery; 12 bottom bracket a; 13 ISP interface; 14 microprocessor; 15 chain b; 16 deflector; 17 rover; 18 sea bottom; 19 underwater beacon LED lighting area; 20 rover LED lighting area; 21 Bottom bracket b; 22 bottom bracket c; 23 bottom bracket d; 24 horizontal bracket; 25 bearing.
The specific embodiments of the present invention are further described below in combination with the technical solutions and the accompanying drawings.
A circuit connection of a submarine optical positioning beacon system with self-generating capability is shown in
The working steps of a submarine optical positioning beacon system with self-generating capability are as follows:
First, the water quality assessment is performed on the active sea area where the target rover is to be located, and the optimal distance between the set beacons is determined accordingly. The program is downloaded by the ISP interface 13 of the underwater beacon Ai, and the microprocessor 14 executes the program command to adjust and generate different PWM waves. Under the action of the PWM wave, the LED lamp group 2 can emit a specific color light, and the LED lamp groups 2 of different underwater beacons Ai emit a specific color light or a specific plurality of color lights that carry positional information corresponding to the underwater beacon Ai.
As shown in
As shown in
When the underwater rover 17 is away from a certain underwater beacon Ai, the COMS sensor 3 of the underwater beacon Ai turns off the LED light group 2 of the underwater beacon Ai because the LED light of the underwater rover 17 is not detected;
When the submarine current does not flow from the front surface of the runner 5, the deflector 16 will must be subjected to the thrust of the ocean current to drive the horizontal bracket 24, the generator 10 and the runner 5 to rotate together until the deflector 16 faces the ocean current again, reaching the balance of force and stopping rotating. At this time, the runner 5 will also faces the ocean current, and will rotate under the action of the ocean current. The runner 5 and the rotating core of the generator 10 are directly connected. When the runner 5 rotates, the rotating core of the generator 10 also rotates. The electric energy generated by the rotating core cutting the magnetic induction line is stored in the battery 11 through the cable 7.
Number | Date | Country | Kind |
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2018 1 0901484 | Aug 2018 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2018/103122 | 8/30/2018 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2020/029346 | 2/13/2020 | WO | A |
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Entry |
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Search Report and Written Opinion dated Aug. 9, 2018, in International Application No. PCT/CN2018/103122. |
Number | Date | Country | |
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20200189706 A1 | Jun 2020 | US |