Device and method for preparing pure titanium by electrolysis-chlorination-electrolysis

What is claimed is: 1 . A device for preparing pure titanium by electrolysis-chlorination-electrolysis, comprising a first electrolytic cell, a second electrolytic cell, a chlorination reactor and a plurality of guide tubes; wherein, the first electrolytic cell and the second electrolytic cell are horizontally disposed; a first heating and temperature controlling system is provided at a bottom and a periphery of the first electrolytic cell and a bottom and a periphery of the second electrolytic cell to control a temperature of a electrolyte in the first electrolytic cell and the second electrolytic cell; the chlorination reactor is located at an upper position of an anode of the first electrolytic cell, and a porous ceramic partition plate is disposed at a bottom of the chlorination reactor; a shell of the chlorination reactor is made of steel, and the chlorination reactor is lined with a ceramic material; a second heating and temperature controlling system is arranged outside the chlorination reactor to control a temperature of materials inside the chlorination reactor; a first guide tube of the plurality of guide tubes is located at a position of the anode in the first electrolytic cell and is connected to the bottom of the chlorination reactor; a first end of a second guide tube of the plurality of guide tubes is connected to a top of the chlorination reactor, and a second end of the second guide tube is located at a position of a cathode in the second electrolytic cell; a first end of a third guide tube of the plurality of guide tubes is located at a position of an anode in the second electrolytic cell, and a second end of the third guide tube is connected to the first guide tube in the first electrolytic cell; the plurality of guide tubes are made of steel and are lined with ceramic or polytetrafluoroethylene. 2 . A method for preparing pure titanium by means of the device of claim 1 , comprising: 1) uniformly mixing titanium dioxide and carbonaceous material powder according to a stoichiometric ratio to obtain a mixture and performing a press molding on the mixture, in a temperature range of 900° C. to 1600° C., preparing TiC x O y in vacuum or TiC x O y N z in a nitrogen atmosphere to introduce into the chlorination reactor; 2) in the first electrolytic cell, using a molten alkali metal chloride, a molten alkaline earth metal chloride, molten aluminum chloride or a mixture of the molten alkali metal chloride, the molten alkaline earth metal chloride and the molten aluminum chloride as a supporting electrolyte, using a carbon material as an anode and a metal material as a cathode, controlling a temperature of the first electrolytic cell at 150° C. to 1000° C., and controlling a temperature of the chlorination reactor at 200° C. to 600° C.; wherein after an electrolysis starts, Cl − migrates to the anode and reacts to produce Cl 2 ; the Cl 2 at the anode passes through a porous partition plate and enters the chlorination reactor via the first guide tube and reacts with TiC x O y or TiC x O y N z in the chlorination reactor to produce TiCl 4 gas; the TiCl 4 gas enters the cathode of the second electrolytic cell via the second guide tube; 3) in the second electrolytic cell, using a molten alkali metal chloride, a molten alkaline earth metal chloride or a mixture of the molten alkali metal chloride and the molten alkaline earth metal chloride as a supporting electrolyte, using a carbon material as an anode and a metal material as a cathode, and controlling a temperature of the second electrolytic cell at 500° C. to 1000° C.; wherein after an electrolysis starts, the TiCl 4 gas transported by the second guide tube enters the the supporting electrolyte at a position of the cathode of the second electrolytic cell, Ti 4+ reacts at the cathode to generate low-valent titanium ions, and the low-valent titanium ions continue to react for deposition to obtain pure titanium at the cathode, and the reaction is as follows: Ti 4+ +e =Ti 3+ Ti 3+ +e =Ti 2+ Ti 2+ +2 e =Ti Cl − migrates to an anode of the second electrolytic cell and generates Cl 2 at the anode of the second electrolytic cell; then, the Cl 2 is transported into the first guide tube via the third guide tube, and is mixed with the Cl 2 generated at the anode of the first electrolytic cell to enter the chlorination reactor to participate in a chlorination of TiC x O y or TiC x O y N z ; 4) after an end of one electrolysis cycle, taking a first product at the cathode of the first electrolytic cell and a second product at the cathode of the second electrolytic cell, and performing pickling, washing, and drying on the first product and the second product; wherein the second product is high-purity titanium, and the first product is byproducts including alkali metal, alkaline earth metal, aluminum or alloy; 5) after completing the step 4), mounting the cathode of the first electrolytic cell into the first electrolytic cell and mounting the cathode of the second electrolytic cell into the second electrolytic cell, and putting new TiC x O y or TiC x O y N z raw material into the chlorination reactor for a new round of operation to produce the high-purity titanium by electrolysis. 3 . The method for preparing the pure titanium according to claim 2 , wherein, the carbonaceous material powder is one or a combination of graphite, petroleum coke, carbon black, coal, and charcoal. 4 . The method for preparing the pure titanium according to claim 2 , wherein, a ratio of a number of oxygen atoms in the titanium dioxide to a number of carbon atoms in the carbon material powder is 1.2:1-0.5:1. 5 . The method for preparing the pure titanium according to claim 2 , wherein, a ratio of a number of oxygen atoms in the titanium dioxide to a number of carbon atoms in the carbon material powder is 1:1-0.667:1. 6 . The method for preparing the pure titanium according to claim 2 , wherein, the metal material for the cathode in the first electrolytic cell and the metal material for the cathode in the second electrolytic cell are titanium, carbon steel or nickel. 7 . The method for preparing the pure titanium according to claim 2 , wherein, during the electrolysis in the first electrolytic cell, current densities are 0.01 A/cm 2 to 2.00 A/cm 2 at the anode and 0.01 A/cm 2 to 2.00 A/cm 2 at the cathode; and during the electrolysis in the second electrolytic cell, current densities are 0.01 A/cm 2 to 2.00 A/cm 2 at the anode and 0.01 A/cm 2 to 2.00 A/cm 2 at the cathode. 8 . The method for preparing the pure titanium according to claim 4 , wherein, the ratio is 1:1-0.667:1.