| CPC G01C 13/00 (2013.01) [B63B 35/44 (2013.01); B63B 79/15 (2020.01); G01W 1/02 (2013.01); H01Q 1/34 (2013.01); B63B 2035/4466 (2013.01)] | 5 Claims |
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1. A low-energy-consumption floating automatic oceanographic and meteorological observation platform, comprising a meteorological observation module, a sea surface monitoring module, a profile observation module, floating body strips, and a rope channel; wherein
the meteorological observation module is configured to provide a buoyant platform to realize observation of meteorological data while guaranteeing power supply and providing a space for equipment placement;
the sea surface monitoring module is configured to realize observation of sea surface data while preventing the buoyant platform from drifting;
the profile observation module is located below the meteorological observation module and configured to complete automatic observation of an ocean profile in a low energy consumption manner;
the profile observation module includes a bobbin, a clockwork, a rope, a gravity regulation bin, an electrically operated gas valve, a high-pressure gas storage cylinder, electrically operated gates, and a first ocean detector;
the bobbin is configured to wind and store the rope;
the clockwork is secured to the bobbin and configured to convert a portion of kinetic energy generated during sinking of the first ocean detector into elastic potential energy to be stored and released in a subsequent upward movement;
the rope is configured to connect the gravity regulation bin and the first ocean detector;
the gravity regulation bin is configured to regulate gravity to realize upward and downward movements of the first ocean detector;
the electrically operated gas valve is configured to regulate a gas release process in the high-pressure gas storage cylinder, i.e., an intake process;
the meteorological observation module includes a communication antenna, a meteorological detector, a hollow support barrel, a solar panel, and a data collector;
the communication antenna is configured to communicate with a remote transmitting device;
the meteorological detector is configured to detect an atmospheric condition and generate the meteorological data;
the hollow support barrel is configured to support the communication antenna and the meteorological detector;
the solar panel being configured to generate electricity;
the data collector is configured to collect and store data generated by various detectors;
the sea surface monitoring module includes a floating body block, a connection chain, a second ocean detector, and an anchor chain;
the floating body block is configured to disperse a sinking position of the anchor chain, display positioning, and provide identification;
the connection chain is connected with the meteorological observation module and configured to transmit a force to stabilize the buoyant platform;
the second ocean detector is configured to detect an ocean state of a sea surface and generate the sea surface data;
the anchor chain is configured for anchoring to prevent the buoyant platform from drifting;
the meteorological observation module further includes a control center, the control center being configured to control the electrically operated gas valve and the electrically operated gates to regulate time of gas intake, water intake, exhaust, and drainage;
the control center is secured in a floating body housing, the floating body housing being configured to insulate internal devices from wind and waves and provide buoyancy;
the floating body strips is secured to the rope and configured to increase the buoyancy of the rope to reduce energy consumption of the first ocean detector during the upward movement;
the rope channel is configured to reduce friction loss due to motion steering during upward and downward movements of the rope.
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