| CPC G01N 35/10 (2013.01) [G01N 33/24 (2013.01); G01N 2001/002 (2013.01); G01N 2035/00465 (2013.01)] | 4 Claims |
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1. An intelligent experimental device for collaborative mining of associated resources, comprising:
a signal transmission mechanism comprising a centralized controller, an annunciator, signal receivers, a power supply, a power cord, signal transmitters, and signal sensing valves,
a pressure maintaining mechanism comprising an ambient pressure oil chamber, an axial pressure oil chamber, an ambient pressure pump, an axial pressure pump, an ambient pressure liquid distribution tank, an axial pressure liquid distribution tank, a comprehensive pressure distribution pipe, and hydraulic transmission pipes,
a feeding mechanism comprising monitoring analyzers, temperature controllers, solution transfer pipes, seepage pumps, mixture conveying pipes, a comprehensive liquid distributor, an aggregate chamber, a liquid chamber, an oil chamber, a gas chamber, mixing chambers and an analytical purifier, and
a reaction mechanism comprising a uranium mine cavity, a coal seam cavity, an oil-gas cavity, nuclear magnets, temperature hydraulic sensors, and shearing gaskets,
wherein
the annunciator is arranged in the centralized controller,
the signal receiver is arranged in the axial pressure pump, the ambient pressure pump, the temperature controller, the seepage pump and the comprehensive liquid distributor,
the signal transmitter is arranged in the temperature hydraulic sensor, the nuclear magnet, and the monitoring analyzer,
the signal sensing valves are arranged at the bottoms of the ambient pressure oil chamber, the axial pressure oil chamber, the aggregate chamber, the liquid chamber, the oil chamber, the gas chamber,
the mixing chamber, the ambient pressure oil chamber and the axial pressure oil chamber are respectively and directly connected to the ambient pressure pump and the axial pressure pump through the hydraulic transmission pipes,
the two ends of the ambient pressure liquid distribution tank are respectively connected to the ambient pressure pump and the comprehensive pressure distribution pipe,
the two ends of the axial pressure liquid distribution tank are respectively connected to the axial pressure pump and the comprehensive pressure distribution pipe,
one end of the monitoring analyzer is connected to the temperature controller,
one end of the seepage pump is connected to the temperature controller, while the other end of the seepage pump is connected to the mixing chamber through the mixture conveying pipe,
the front end of the comprehensive liquid distributor is connected to the mixing chamber through the mixture conveying pipe, while the rear end of the comprehensive liquid distributor is connected to the aggregate chamber, the liquid chamber, the oil chamber, and the gas chamber respectively through the mixture conveying pipes,
the analytical purifier is connected to an outlet end of the oil-gas cavity, the uranium mine cavity, the coal seam cavity, and the oil-gas cavity which are connected in series through the solution transfer pipes,
one ends of the uranium mine cavity, the coal seam cavity, and the oil-gas cavity are directly connected to the comprehensive pressure distribution pipe, while the other ends of the uranium mine cavity, the coal seam cavity, and the oil-gas cavity are directly connected to the monitoring analyzer,
the outer sides of the uranium mine cavity, the coal seam cavity, and the oil-gas cavity are wrapped with the nuclear magnets,
the shearing gaskets are arranged inside the cavities,
a signal transmitter is installed on the nuclear magnet, and
the temperature hydraulic sensors are installed on the side walls of the uranium mine cavity, the coal seam cavity and the oil-gas cavity, and each cavity is respectively provided with a thermohydraulic sensor at the front, middle and back positions, which is externally connected to the signal transmitter.
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