CN213862599U - Self-powered unmanned ship automatic parking charging device - Google Patents

Abstract

The utility model discloses a self-powered unmanned ship automatic berthing and charging device, which solves the defect that the existing unmanned ship can not conveniently and rapidly realize the automatic supply of electric energy in a remote sea shore area, and the key point of the technical scheme is that the self-powered unmanned ship automatic berthing and charging device comprises a floating platform provided with a berth and a power generation device arranged below the floating platform; the device also comprises a fixing device fixedly arranged on the floating platform and used for fixedly connecting the unmanned ship berthed to the berth, and an electromagnetic charging device arranged on the floating platform and used for charging the fixed unmanned ship; the floating platform still be provided with and carry out the unmanned ship communication module that communicates between the unmanned ship, guide and reach near the unmanned ship of floating platform and berth to the guide radar of berthing the position, to unmanned ship berth the state carry out the detection module that detects, the controller that controls, the utility model discloses a self-powered unmanned ship automatic berths charging device can utilize the ocean energy to realize the self-power to realize the convenient charging to unmanned ship, the operation is automatic, intelligent.

Description

Self-powered unmanned ship automatic parking charging device

Technical Field

The utility model relates to an unmanned ship charging platform, in particular to self-powered unmanned ship automatic berths charging device.

Background

The existing unmanned ship generally adopts a storage battery as a power source, the electric energy is supplied by manual recovery to charge or replace the storage battery, the operation mode has high labor intensity and low efficiency, and particularly, when the ship runs to an area far away from a coastline, the charging cost can be greatly improved, the all-weather automatic operation of the unmanned ship cannot be really realized, and the space for improvement is remained.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a self-powered unmanned ship automatic berths charging device can utilize the ocean to realize the self-power to the realization is automatic, intelligent to unmanned ship's convenient charging, operation.

The above technical purpose of the present invention can be achieved by the following technical solutions:

a self-powered unmanned ship automatic parking charging device comprises a floating platform and a power generation device, wherein the floating platform is provided with a parking space for the unmanned ship to park, and the power generation device is arranged below the floating platform and can generate power through tidal current energy; the device also comprises a fixing device fixedly arranged on the floating platform and used for fixedly connecting the unmanned ship berthed to the berth, and an electromagnetic charging device arranged on the floating platform and used for charging the fixed unmanned ship; the floating platform is also provided with an unmanned ship communication module which is communicated with the unmanned ship to guide the unmanned ship to navigate, a guiding radar which guides the unmanned ship which reaches the vicinity of the floating platform to berth to a berth position, a detection module which detects the berthing state of the unmanned ship, and a controller which is coupled with the detection module and controls the fixing device and the electromagnetic charging device according to the detection result;

when the detection module detects that the unmanned ship is parked to the parking position, the controller controls the fixing device to fix the unmanned ship; when the detection module detects that the unmanned ship is fixed, the controller controls the electromagnetic charging device to charge the unmanned ship.

Preferably, the floating platform is provided with a control box on the surface, the controller is installed in the control box, and the floating platform further comprises a power transformation box installed in the control box and coupled to the power generation device, and a storage battery coupled to the power transformation box for storing and supplying power.

Preferably, the power generation device comprises a fixed frame fixedly installed on the lower surface of the floating platform for connection and installation, a guide cover fixedly installed at the lower end of the fixed frame, guide vanes installed at two ends of the guide cover, a rotating shaft rotatably installed between the guide vanes at two sides through bearings along the central axial direction of the guide vanes at two sides, a power generation roller fixedly installed on the outer side wall of the rotating shaft to drive the rotating shaft to rotate according to water flow, and a power generator fixedly installed on the guide vanes at two sides to rotate according to the rotating shaft and the power generation roller to generate power; and a lead connected with the generator and the transformer box is arranged in the fixing frame in a penetrating manner.

Preferably, the floating platform further comprises a mooring turntable arranged on the lower surface of the floating platform and an anchor body connected to the mooring turntable through a mooring rope.

Preferably, the fixing device comprises a limiting groove and a fixing component, wherein the limiting groove is formed in the side wall of the floating platform and used for limiting and placing a clamping ring of the unmanned ship parked at the parking position, and the fixing component is arranged in the fixing groove and used for fixing the clamping ring; the inner side wall of the fixing groove is provided with an energy-absorbing sponge for buffering;

the fixing assembly comprises a lock pin which vertically penetrates through the fixing groove and a clamping ring of the unmanned ship to perform limiting fixing, a lock hole which is formed in the side wall of the fixing groove and used for clamping and fixing the lock pin, and a driving piece which is arranged on the upper surface of the floating platform and controlled by the controller to drive the penetrated lock pin;

the detection module comprises a fixed radar which is arranged in the fixed groove and used for detecting whether the unmanned ship is parked in place or not, and the controller is coupled with the fixed radar and used for controlling the driving piece to drive the lock pin to limit and fix the clamp ring of the unmanned ship when the fixed radar detects that the unmanned ship is parked in place.

Preferably, the electromagnetic charging device comprises a base, a rotary table, an electromagnetic charging plate and a mechanical arm, wherein the base is arranged on the upper surface of the floating platform and is used for fixing, the rotary table is arranged on the base and is used for steering adjustment, the electromagnetic charging plate is used for being connected to the unmanned ship charging plate to perform electromagnetic charging, and the mechanical arm is hinged between the rotary table and the electromagnetic charging plate and is used for adjusting the position and the height of the electromagnetic charging plate;

the electromagnetic charging panel comprises a charging tray for charging the unmanned ship charging panel, electromagnetic suckers arranged around the charging tray for adsorption, and a positioning radar arranged on the surface of the charging tray for searching and determining the position of the unmanned ship charging panel.

Preferably, the detection module further comprises a pressure detection module for detecting whether the electromagnetic charging device is attracted in place, and the controller is coupled to the pressure detection module to control the electromagnetic charging device to charge the unmanned ship when the pressure detection module detects that the electromagnetic charging device is attracted in place.

Preferably, the floating platform is further provided with a monitoring camera for real-time monitoring shooting and a roadbed communication module which is coupled with the monitoring camera and the controller and is communicated with the shore-based control room.

Preferably, the floating platform further comprises two floating pontoons which are respectively arranged at two sides of the floating platform, and a connecting rod which is fixedly connected between the floating pontoons and the floating platform;

the berthing position is arranged on the front side of the floating platform and is in an arc groove shape corresponding to the bow of the unmanned ship, and an anti-collision gasket is arranged on the side wall of the berthing position.

Preferably, warning lamps for warning at night are arranged on the two sides of the berth position on the upper surface of the floating platform; the guiding radar is provided with two floating platform side walls which are respectively positioned at two sides of the berth.

To sum up, the utility model discloses following beneficial effect has:

the unmanned ship can be moored through the floating platform with the berth, the fixing device arranged on the floating platform can enable the unmanned ship to be stably connected with the floating platform after being moored, the electromagnetic charging device can charge the unmanned ship, and the power generation device arranged below the floating platform can generate power by utilizing tidal current energy so as to provide power for all power utilization equipment on the floating platform and can be used for supplying power to the unmanned ship, so that the electric energy supply of the unmanned ship is facilitated, and the battery does not need to be replaced frequently by people; the controller and the detection device can perform stable detection and control combination, so that charging is accurate, overall operation is automatic and intelligent, the floating platform can effectively utilize tide energy to realize self-power supply through the power generation device, and charging of the unmanned ship is realized conveniently and intelligently.

Drawings

Fig. 1 is a schematic block diagram of the present invention;

fig. 2 is a schematic view of a first structure of the present invention;

fig. 3 is a top view of the present invention;

fig. 4 is a second structural schematic diagram of the present invention;

FIG. 5 is a schematic structural diagram of an electromagnetic charging device;

FIG. 6 is a schematic structural diagram of an electromagnetic charging pad;

FIG. 7 is a schematic structural view of the lower surface of the floating platform;

fig. 8 is a schematic structural diagram of a generator set of the power generation device.

In the figure: 100. a floating platform; 101. a first buoy; 102. a second buoy; 103. a control box; 104. a connecting rod; 105. a storage battery; 106. a power transformation box; 107. a controller; 108. an unmanned ship communication module; 109. a roadbed communication module; 110. guiding the radar; 111. a surveillance camera; 112. a warning light; 113. a mooring turntable; 114. a mooring line; 115. an anchor body; 116. an anti-collision washer; 200. a power generation device; 201. a pod; 202. a rotating shaft; 203. a power generation roller; 204. a generator; 205. a fixed mount; 206. a guide vane; 300. an electromagnetic charging device; 301. a base; 302. a turntable; 303. a large arm; 304. a small arm; 305. an electromagnetic charging pad; 306. an electromagnetic chuck; 307. a charging tray; 308. positioning a radar; 400. a fixing device; 401. an energy absorbing sponge; 402. a lock pin; 403. a drive member; 404. fixing a radar; 405. fixing grooves; 406. and (6) locking the hole.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

According to one or more embodiments, a self-powered unmanned ship automatic berthing and charging device is disclosed, as shown in fig. 1 and 2, comprising a floating platform 100, a power generation device 200, a fixing device 400 for fixing the unmanned ship, and an electromagnetic charging device 300 for charging the unmanned ship. The floating platform 100 is further provided with an unmanned ship communication module 108 for communication and navigation with an unmanned ship, a roadbed communication module 109 for communication with a shore-based control room, a monitoring camera 111, a warning light 112, a guiding radar 110, buoys located on two sides of the floating platform 100 and used for providing buoyancy, and a detection module for detecting the mooring state of the unmanned ship.

As shown in fig. 1 to 3, two sides of the floating platform 100 are respectively connected to buoys for providing buoyancy to float the sea surface, and the buoys are a first buoy 101 and a second buoy 102 which are respectively fixedly installed on two sides of the floating platform 100 through a connecting rod 104. The front side of the floating platform 100 is provided with a parking position for the unmanned ship needing to be charged to park, the parking position is in an arc-shaped groove shape corresponding to the bow of the unmanned ship, when the unmanned ship parks, the bow part can enter the parking position, the contact area between the bow part and the unmanned ship can be increased due to the arc-shaped groove shape, and therefore the unmanned ship can be parked more stably and reliably. And the anti-collision gasket 116 is arranged along the side wall of the parking position so as to reduce the collision damage when the unmanned ship is parked, and the effective buffer protection effect can be realized on the unmanned ship body.

The floating platform 100 is provided with a control box 103, a battery 105, a power transformation box 106 and a controller 107 are installed in the control box 103, the control box 103 is closed by a cover plate, and a top view of the cover plate after being opened is shown in fig. 3. The storage battery 105 is preferably provided with six pieces, which are uniformly arranged in the control box 103, the transformation box 106 is installed in the center of the control box 103, is connected with the power generation device 200 through a lead, and is connected with the six storage batteries 105, and is used for converting the electric energy provided by the power generation device 200 and storing the converted electric energy into the storage battery 105, so that the electric energy can be stored, and the electric energy can be supplied to the electric devices on the floating platform 100 through the storage battery 105.

The unmanned ship communication module 108 and the roadbed communication module 109 are installed on the upper surface of the floating platform 100, preferably symmetrically along the central axis in the front-rear direction, and are respectively installed on both sides of the berth. The front side wall of the floating platform 100 is provided with guide radars 110 at both sides of the berth, and an unmanned ship approaching the floating platform 100 and requiring berthing charging is guided to the berth by the guide radars 110. The warning lamps 112 are disposed on the upper surface of the floating platform 100 and are separately disposed at both sides of the berth to prevent the sea surface sailing ship from colliding at night. The monitoring camera 111 is disposed on the upper surface of the floating platform 100 and is located at one side of the berth to monitor the situation at the berth in real time.

After the unmanned ship is docked to the docking station, the unmanned ship may be fixedly connected to the floating platform 100 through the fixing device 400 by means of the snap ring provided at the bow of the ship. As shown in fig. 2 to 4, the fixing device 400 includes a limit groove opened on a sidewall of the floating platform 100 for limiting the position of the snap ring of the unmanned ship docked at the docking station, and a fixing member installed in the fixing groove 405 for fixing the snap ring; an energy absorbing sponge 401 for buffering is installed on the inner sidewall of the seating groove 405. The fixing groove 405 is opened at one side near the upper surface of the floating platform 100, and the fixing member is penetrated into the fixing groove 405 from the upper surface of the floating platform 100. The fixing component comprises a locking pin 402 which vertically penetrates through a fixing groove 405 and a clamping ring of the unmanned ship to perform limiting fixing, a locking hole 406 which is formed in the side wall of the fixing groove 405 and used for clamping and embedding the locking pin 402 for fixing, and a driving piece 403 which is installed on the upper surface of the floating platform 100 and controlled by the controller 107 to drive the penetrating locking pin 402, wherein the driving piece 403 is sleeved on the locking pin 402, and the locking and unlocking are completed by driving the locking pin 402 to move up and down through rotation control.

The detection module comprises a fixed radar 404 which is arranged in a fixed groove 405 to detect whether the unmanned ship is parked in place, and the controller 107 is coupled to the fixed radar 404 and controls the driving piece 403 to drive the lock pin 402 to limit and fix the clamp ring of the unmanned ship when the fixed radar 404 detects that the unmanned ship is parked in place.

As shown in fig. 3 and 5, the electromagnetic charging device 300 is installed on the upper surface of the floating platform 100 and located on one side of the fixing device 400, and includes a base 301 installed on the upper surface of the floating platform 100 for fixing, a turntable 302 installed on the base 301 for steering adjustment, an electromagnetic charging board 305 for connecting to a charging board of an unmanned ship for electromagnetic charging, and a robot arm hinged between the turntable 302 and the electromagnetic charging board 305 for adjusting the position and height of the electromagnetic charging board 305, wherein the robot arm includes a large arm 303 and a small arm 304 hinged to each other for adjustment. As shown in fig. 6, the electromagnetic charging panel 305 includes a charging tray 307 for charging the unmanned ship charging panel, an electromagnetic chuck 306 disposed around the charging tray 307 for adsorption, and a positioning radar 308 disposed on the surface of the charging tray 307 for finding and determining the position of the unmanned ship charging panel, and by the arrangement of the charging tray 307, the disadvantages that the contact of the conventional contact charging is easily corroded by water, has a short-circuit risk, and is not high in reliability are avoided.

The detection module further comprises a pressure detection module for detecting whether the electromagnetic charging device 300 is in place in an attraction manner, whether the connection and installation of the electromagnetic charging plate 305 of the electromagnetic charging device 300 and the unmanned ship charging plate is successful is judged through pressure detection, and the controller 107 is coupled to the pressure detection module to control the electromagnetic charging device 300 to charge the unmanned ship when the pressure detection module detects that the electromagnetic charging device 300 is in place in the attraction manner.

As shown in fig. 7, the power generation device 200 is fixedly installed on the lower surface of the floating platform 100, and includes two power generation sets for generating power, as shown in fig. 8, each power generation set includes a fixing frame 205 connected to the lower surface of the floating platform 100, a guide cover 201 fixedly installed at the lower end of the fixing frame 205, guide vanes 206 installed at both ends of the guide cover 201, a rotating shaft 202 rotatably installed between the guide vanes 206 at both sides through bearings along the central axial direction of the guide vanes 206 at both sides, a power generation roller 203 fixedly installed on the outer side wall of the rotating shaft 202 to drive the rotating shaft 202 to rotate according to water flow, and a power generator 204 fixedly installed on the guide vanes 206 at both sides to rotate according to the rotating shaft 202 and the power generation roller 203 to generate power; the power generation device 200 is connected to the transformer box 106 by a lead wire inserted into the fixing frame 205. The dome 201 is a bidirectional opening, and the two sides of the dome are outward and gradually enlarged in caliber.

The mooring device is further installed on the lower surface of the floating platform 100, and comprises a mooring turntable 113 and an anchor body 115 connected to the mooring turntable 113 through a mooring rope 114, and the mooring device is connected with the anchor body 115 through the mooring rope 114 so that the floating platform 100 does not flow with the tidal water, the mooring turntable 113 can rotate along with the flow direction of the tidal water, and the platform can rotate along with the flow direction of the tidal water under the condition that the floating platform 100 is not moved, so that the power generation device 200 can maximally utilize the energy of the tidal water. Through the utilization of the tidal current energy by the power generation device 200, the tidal current energy is converted into mechanical energy through the power generation rollers 203, the mechanical energy is transmitted to the power generator 204 through the rotating shaft 202 and converted into electric energy, and then the electric energy is connected with the power transformation box 106 in the floating platform 100 through a wire, and the stable electric energy is continuously transmitted to the floating platform 100 through the conversion of the power transformation box 106 so as to meet the requirement of self power supply, so that the automatic supply of energy is realized, and the defect that the existing charging platform cannot realize self power supply and needs to prepare sufficient batteries in advance is overcome.

The communication module and the battery module on the unmanned ship are managed, when the electric quantity is insufficient and charging is needed, the floating platform 100 guides the unmanned ship to sail through the unmanned ship communication module 108 by mutual communication with the unmanned ship communication module 108 of the floating platform 100 so as to set the sailing direction and speed to reach the front of the floating platform 100;

when the unmanned ship arrives in front of the floating platform 100, the guiding radars 110 on two sides of the berthing position of the floating platform 100 accurately guide and detect the berthing of the unmanned ship and send corresponding signals to the controller 107, and the controller 107 sends control signals to the unmanned ship through the unmanned ship communication module 108 to realize the accurate berthing of the unmanned ship;

after the unmanned ship is parked in place, the clamping ring at the bow of the ship is correspondingly clamped and embedded into the fixing groove 405 of the fixing device 400, and after the detection is carried out through the fixing radar 404, the clamping ring is fixed through the fixing component, so that the unmanned ship and the floating platform 100 are stably connected, and the stability of the ship body in the charging process is kept;

the controller 107 controls the electromagnetic charging device 300 to act, the electromagnetic charging plate 305 is in butt joint with the unmanned ship charging plate through the positioning radar 308, and after the electromagnetic charging device 300 is judged to be installed in place through pressure detection, the controller 107 controls the storage battery 105 to charge the unmanned ship through the electromagnetic charging device 300;

after the unmanned ship finishes charging, the controller 107 controls the electromagnetic charging device 300 to be separated from the charging plate of the unmanned ship and the fixing device 400 to be unlocked, so that the unmanned ship can drive away from the berth of the floating platform 100, and the floating platform 100 is ready to wait for charging of the next unmanned ship;

the monitoring camera 111 transmits the monitoring signal to the shore-based control room through the roadbed communication module 109 in real time, and various electric signals received by the controller 107 are also transmitted to the shore-based control room through the roadbed communication module 109, so that shore-based personnel can conveniently know and master the actual situation, and the stability and controllability of the device are ensured; and a control signal can be transmitted by a person to perform a manual control charging operation on the parked unmanned ship through the roadbed communication module 109.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications to the present embodiment without inventive contribution as required after reading the present specification, but all of them are protected by patent laws within the scope of the claims of the present invention.

Claims (10)

1. A self-powered unmanned ship automatic berths charging device, characterized by: the unmanned ship comprises a floating platform (100) which is provided with a parking space for the unmanned ship to park, and a power generation device (200) which is arranged below the floating platform (100) and can generate power and supply power through tidal current energy; the device also comprises a fixing device (400) fixedly installed on the floating platform (100) and used for fixedly connecting the unmanned ship berthed to the berth, and an electromagnetic charging device (300) installed on the floating platform (100) and used for charging the fixed unmanned ship; the floating platform (100) is also provided with an unmanned ship communication module (108) which is communicated with the unmanned ship to guide the unmanned ship to sail, a guiding radar (110) which guides the unmanned ship arriving near the floating platform (100) to berth, a detection module which detects the berthing state of the unmanned ship, and a controller (107) which is coupled with the detection module and controls the fixing device (400) and the electromagnetic charging device (300) according to the detection result;

when the detection module detects that the unmanned ship is parked at the parking position, the controller (107) controls the fixing device (400) to fix the unmanned ship; when the detection module detects that the unmanned ship is fixed, the controller (107) controls the electromagnetic charging device (300) to charge the unmanned ship.

2. A self-powered unmanned ship automatic berthing and charging facility, as defined in claim 1, wherein: the floating platform is characterized in that a control box (103) is arranged on the surface of the floating platform (100), the controller (107) is arranged in the control box (103), the floating platform further comprises a power transformation box (106) which is arranged in the control box (103) and is coupled to the power generation device (200), and a storage battery (105) which is coupled to the power transformation box (106) for storing and supplying power.

3. A self-powered unmanned ship automatic berthing and charging facility, as defined in claim 2, wherein: the power generation device (200) comprises a fixed frame (205) fixedly installed on the lower surface of the floating platform (100) for connection and installation, a guide cover (201) fixedly installed at the lower end of the fixed frame (205), guide vanes (206) installed at two ends of the guide cover (201), a rotating shaft (202) rotatably installed between the guide vanes (206) at two sides through bearings along the central axial direction of the guide vanes (206) at two sides, a power generation roller (203) fixedly installed on the outer side wall of the rotating shaft (202) for driving the rotating shaft (202) to rotate according to water flow, and a power generator (204) fixedly installed on the guide vanes (206) at two sides for generating power according to the rotation of the rotating shaft (202) and the power generation roller (203); and a lead connected with the generator (204) and the transformer box (106) is arranged in the fixed frame (205) in a penetrating way.

4. A self-powered unmanned ship automatic berthing and charging facility, as defined in claim 3, wherein: the floating platform also comprises a mooring turntable (113) arranged on the lower surface of the floating platform (100) and an anchor body (115) connected to the mooring turntable (113) through a mooring rope (114).

5. A self-powered unmanned ship automatic berthing and charging facility, as defined in claim 1, wherein: the fixing device (400) comprises a limiting groove and a fixing component, wherein the limiting groove is formed in the side wall of the floating platform (100) and used for limiting and placing a clamping ring of the unmanned ship parked at the parking position, and the fixing component is arranged in the fixing groove (405) and used for fixing the clamping ring; the inner side wall of the fixing groove (405) is provided with an energy absorption sponge (401) for buffering;

the fixing assembly comprises a lock pin (402) which vertically penetrates through a fixing groove (405) and is limited and fixed by a clamp ring of the unmanned ship, a lock hole (406) which is formed in the side wall of the fixing groove (405) and used for clamping and fixing the lock pin (402), and a driving piece (403) which is arranged on the upper surface of the floating platform (100) and is controlled by a controller (107) to drive the penetrating lock pin (402);

the detection module comprises a fixed radar (404) which is arranged in a fixed groove (405) and used for detecting whether the unmanned ship is parked in place, and the controller (107) is coupled to the fixed radar (404) and controls the driving piece (403) to drive the lock pin (402) to limit and fix the clamp ring of the unmanned ship when the fixed radar (404) detects that the unmanned ship is parked in place.

6. A self-powered unmanned ship automatic berthing and charging facility, as defined in claim 1, wherein: the electromagnetic charging device (300) comprises a base (301) which is arranged on the upper surface of the floating platform (100) and is fixed, a rotary table (302) which is arranged on the base (301) and is used for steering adjustment, an electromagnetic charging plate (305) which is used for being connected to a charging plate of the unmanned ship to carry out electromagnetic charging, and a mechanical arm which is hinged between the rotary table (302) and the electromagnetic charging plate (305) and is used for adjusting the position and the height of the electromagnetic charging plate (305);

the electromagnetic charging plate (305) comprises a charging disc (307) for charging the unmanned ship charging plate, an electromagnetic sucker (306) arranged around the charging disc (307) for sucking, and a positioning radar (308) arranged on the surface of the charging disc (307) for searching and determining the position of the unmanned ship charging plate.

7. A self-powered unmanned ship automatic berthing and charging facility, according to claim 6, characterized by: the detection module is characterized by further comprising a pressure detection module for detecting whether the electromagnetic charging device (300) is attracted in place or not, and the controller (107) is coupled to the pressure detection module to control the electromagnetic charging device (300) to charge the unmanned ship when the pressure detection module detects that the electromagnetic charging device (300) is attracted in place.

8. A self-powered unmanned ship automatic berthing and charging facility, as defined in claim 1, wherein: the floating platform (100) is further provided with a monitoring camera (111) for real-time monitoring shooting, and a roadbed communication module (109) which is coupled to the monitoring camera (111) and the controller (107) and is used for communicating with a shore-based control room.

9. A self-powered unmanned ship automatic berthing and charging facility, as defined in claim 1, wherein: the device also comprises two buoys which are respectively arranged at two sides of the floating platform (100) and a connecting rod (104) which is fixedly connected between the buoys and the floating platform (100);

the berthing position is arranged on the front side of the floating platform (100) and is in an arc groove shape corresponding to the bow of the unmanned ship, and an anti-collision gasket (116) is arranged on the side wall of the berthing position.

10. A self-powered unmanned ship automatic berthing and charging facility, according to claim 9, characterized by: warning lamps (112) for warning at night are mounted on the two sides of the parking position on the upper surface of the floating platform (100); the guiding radar (110) is provided with two floating platform (100) side walls which are respectively positioned at two sides of the parking position.

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