System and method for preparing high purity vanadium electrolyte

What is claimed is: 1 . A system for preparing a high-purity vanadium electrolyte, comprising: a vanadium oxytrichloride storage tank, an ammonium salt precipitating device, an ammonium salt feeding device, a preheating system, a reduction fluidized bed, a cooling system, a secondary cooling device, a low-valence vanadium oxide feeding device, and a dissolution and activation reactor; wherein the ammonium salt precipitating device comprises an ammonium salt precipitating reaction tank and a washing filter; the ammonium salt feeding device comprises an ammonium salt hopper and an ammonium salt screw feeder; the preheating system comprises a primary cyclone preheater, a venturi preheater, a secondary cyclone preheater, and a first cyclone separator; the reduction fluidized bed comprises a feeder, a bed body, a discharger, a gas heater, a gas purifier, and an ammonium chloride settling tower; the cooling system comprises a venturi cooler, a cyclone cooler, and a second cyclone separator; the low-valence vanadium oxide feeding device comprises a low-valence vanadium oxide hopper and a low-valence vanadium oxide screw feeder; wherein a feed outlet at the bottom of the vanadium oxytrichloride storage tank connected with a chloride inlet of the ammonium salt precipitating reaction tank through a pipeline; an ammonia solution inlet of the ammonium salt precipitating reaction tank is connected with a purified ammonia liquor main pipe and a gas outlet of the first cyclone separator through pipelines; a flue gas outlet of the ammonium salt precipitating reaction tank is connected with a tail gas treatment system through a pipeline; a slurry outlet of the ammonium salt precipitating reaction tank is connected with a slurry inlet of the washing filter through a pipeline; a clean water inlet of the washing filter is connected with a clean water main pipe through a pipeline; a washing liquid outlet of the washing filter is connected with a wastewater treatment unit through a pipeline; and a solid material outlet of the washing filter is connected with a feed inlet of the ammonium salt hopper through a pipeline; a feed outlet at the bottom of the ammonium salt hopper is connected with a feed inlet of the ammonium salt screw feeder; and a feed outlet of the ammonium salt screw feeder is connected with a feed inlet of the venturi preheater through a pipeline; a gas inlet of the venturi preheat is connected with a gas outlet of the primary cyclone preheater through a pipeline; a feed outlet of the venturi preheater is connected with a gas inlet of the secondary cyclone preheater through a pipeline; a gas outlet of the secondary cyclone preheater is connected with a gas inlet of the first cyclone separator through a pipeline; a feed outlet of the secondary cyclone heater is connected with a gas inlet of the primary cyclone heater through a pipeline; a gas outlet of the first cyclone separator is connected with the ammonia solution inlet of the ammonium salt precipitating reaction tank through a pipeline; a feed outlet of the first cyclone separator is connected with the gas inlet of the primary cyclone preheater through a pipeline; the gas inlet of the primary cyclone preheater is connected with a gas outlet of the ammonium chloride settling tower through a pipeline; a feed outlet of the primary cyclone preheater is connected with a feed inlet of the feeder through a pipeline; a feed outlet of the feeder is connected with a feed inlet of the bed body through a pipeline; an aeration air inlet of the feeder is connected with a purified nitrogen gas main pipe through a pipeline; a high-temperature flue gas outlet of the bed body is connected with a gas inlet of the ammonium chloride settling tower through a pipeline; the gas outlet of the ammonium chloride settling tower is connected with the gas inlet of the primary cyclone preheater through a pipeline; a gas inlet of the bed body is connected with a gas outlet of the gas heater through a pipeline; a gas inlet of the gas heater connected with gas outlets of the second cyclone separator and the gas purifier through pipelines, respectively; a combustion air inlet of the gas heater is connected with a compressed air main pipe; a fuel inlet of the gas heater is connected with a fuel main pipe; and a gas inlet of the gas purifier is connected with a reducing gas main pipe; a gas inlet of the venturi cooler is connected with the purified nitrogen gas main pipe; a gas outlet of the venturi cooler is connected with a gas inlet of the cyclone cooler through a pipeline; a gas outlet of the cyclone cooler is connected with a gas inlet of the second cyclone separator through a pipeline; a feed outlet of the cyclone cooler is connected with a feed inlet of the secondary cooling device through a pipeline; a gas outlet of the second cyclone separator is connected with the gas inlet of the gas heater through a pipeline; and a feed outlet of the second cyclone separator is connected with the feed inlet of the secondary cooling device through a pipeline; a feed outlet of the secondary cooling device is connected with a feed inlet of the low-valence vanadium oxide hopper through a pipeline; a process water inlet of the secondary cooling device is connected with a process water main pipe; and a process water outlet of the secondary cooling device is connected with a water cooling system; a feed outlet at the bottom of the low-valence vanadium oxide hopper is connected with a feed inlet of the low-valence vanadium oxide screw feeder; and a feed outlet of the low-valence vanadium oxide screw feeder is connected with a feed inlet of the dissolution and activation reactor through a pipeline; a clean water inlet of the dissolution and activation reactor is connected with the clean water main pipe; a sulfuric acid solution inlet of the dissolution and activation reactor connected with a sulfuric acid solution main pipe; and a gas outlet of the dissolution and activation reactor is connected with the tail gas treatment system. 2 . A method for preparing a high-purity vanadium electrolyte based on the system of claim 1 , comprising the following steps: introducing vanadium oxytrichloride liquid from the vanadium oxytrichioride storage tank into the ammonium salt precipitating reaction tank through a pipeline, and undergo hydrolysis precipitation together with ammonia liquor from the purified ammonia liquor main pipe and ammonia-rich tail gas from the reduction fluidized bed to form a mixed slurry of ammonium salt precipitate containing ammonium polyvanadate and ammonium metavanadate with an ammonium chloride solution; transmitting a generated flue gas to the a tail gas treatment system; introducing the slurry to enter the washing filter in order to be subjected to washing with clean water and filtration, to obtain washing liquid and ammonium salt precipitate powder; transmitting the washing liquid into a wastewater treatment system; and transmitting the ammonium salt precipitate into the ammonium salt hopper; introducing the ammonium salt precipitate in the ammonium salt hopper to enter the ammonium salt screw feeder, the venturi preheater, the secondary cyclone preheater, and the primary cyclone preheater to enter the bed body through the feeder together with the fine powder recovered by the first cyclone separator; introducing purified nitrogen gas from the purified nitrogen gas main pipe into the venturi cooler, the cyclone cooler and the second cyclone separato in order to merge it with purified reducing gas from the gas purifier, and then transmitted into the bed body, such that the ammonium salt precipitate powder material is kept at a fluidized state and reduced to obtain low-valence vanadium oxide powder and ammonia-rich reduction flue gas; introducing the ammonia-rich reduction flue gas to settle through the ammonium chloride settling tower, and then moved to the primary