Method for smelting magnesium quickly and continuously

What is claimed is: 1. A method for smelting magnesium quickly and continuously, comprising the following steps of: Step 1: ingredient preparing and pelletizing ingredient preparing: preparing dolomite, 75Si—Fe alloy and fluorite at a mass ratio of 110:(10-13):(3.0-4.0), uniformly mixing the prepared ingredients so as to obtain a mixture, and then adding soluble glass as a bonding agent which accounts for 1.0-2.0% of the total mass of the prepared ingredients and water which accounts for 2.0-5.0% of the total mass of the prepared ingredients; or, preparing dolomite, Al and fluorite at a mass ratio of 115:(10-13):(2.0-3.0), uniformly mixing the prepared ingredients so as to obtain a mixture, and then adding soluble glass as a bonding agent which accounts for 1.0-2.0% of the total mass of the prepared ingredients and water which accounts for 2.0-5.0% of the total mass of the prepared ingredients; pelletizing: uniformly mixing the prepared ingredients so as to obtain a mixture, pelletizing the mixture so as to obtain pellets with particle sizes of 5-20 mm, and naturally drying the pellets for 10-24 h; Step 2: pellet calcining placing the dried pellets in a high-temperature furnace, a rotary kiln or a fluidized bed, heating the dried pellets to 150-250° C., keeping the temperature for 30-60 min, dehydrating the dried pellets after the temperature is kept, then heating the dehydrated dried pellets to 850-1050° C. in an argon or nitrogen atmosphere, keeping the temperature, and performing calcination for 30-120 min; Step 3: continuous high-temperature reduction of calcined pellets continuously feeding the high-temperature calcined pellets without being cooled under argon protection into a closed high-temperature reduction furnace, then performing a high-temperature reduction reaction in a flowing argon atmosphere with a reduction temperature of 1300-1600° C., a reduction time of 20-90 min, and an argon flow rate of 2.0-5.0 m 3 /h in order to continuously obtain high-temperature magnesium steam, mixing the magnesium steam with argon gas to form a high-temperature gas mixture, and besides, continuously discharging reduction slag out of the high-temperature reduction furnace; and Step 4: condensing of high-temperature magnesium steam enabling the high-temperature magnesium steam to be carried out of the high-temperature reduction furnace by the argon flow, and to be delivered through a sealed pipeline to a condensation system for condensation so as to obtain metal magnesium. 2. A method for smelting magnesium quickly and continuously, comprising the following steps of: Step 1: ingredient preparing and pelletizing ingredient preparing: preparing magnesite, 75Si—Fe alloy, CaO and fluorite at a mass ratio of 45:(10-13):(16-20):(2.0-3.0), uniformly mixing the prepared ingredients so as to obtain a mixture, and then adding soluble glass as a bonding agent which accounts for 2.0-3.0% of the total mass of the prepared ingredients and water which accounts for 2.0-6.0% of the total mass of the prepared ingredients; or, preparing magnesite, Al, CaO and fluorite at a mass ratio of 48:(10-13):(15-18):(2.0-3.0), uniformly mixing the prepared ingredients so as to obtain a mixture, and then adding soluble glass as a bonding agent which accounts for 2.0-3.0% of the total mass of the prepared ingredients and water which accounts for 2.0-6.0% of the total mass of the prepared ingredients; Step 2: pellet calcining placing the dried pellets in a high-temperature furnace, a rotary kiln or a fluidized bed, heating the dried pellets to 150-250° C., keeping the temperature for 30-60 min, dehydrating the dried pellets after the temperature is kept, then heating the dehydrated dried pellets to 850-1050° C. in an argon or nitrogen atmosphere, keeping the temperature, and performing calcination for 30-120 min; Step 3: continuous high-temperature reduction of calcined pellets continuously feeding the high-temperature calcined pellets without being cooled under argon protection into a closed high-temperature reduction furnace, then performing a high-temperature reduction reaction in a flowing argon atmosphere with a reduction temperature of 1300-1600° C., a reduction time of 20-90 min, and an argon flow rate of 2.0-5.0 m 3 /h in order to continuously obtain high-temperature magnesium steam, mixing the magnesium steam with argon gas to form a high-temperature gas mixture, and besides, continuously discharging reduction slag out of the high-temperature reduction furnace; and Step 4: condensing of high-temperature magnesium steam enabling the high-temperature magnesium steam to be carried out of the high-temperature reduction furnace by the argon flow, and to be delivered through a sealed pipeline to a condensation system for condensation so as to obtain metal magnesium. 3. The method for smelting magnesium quickly and continuously according to claim 1 , wherein the Al or 75Si—Fe alloy in Step 1 is replaced with composite reductants selected from one of the following three groups: (1) Al+75Si—Fe alloys; (2) Ca+75Si—Fe alloys; (3) Al+Ca+75Si—Fe alloy; the standard dosage of the composite reductants are: 1 mass unit of Al can be replaced with 2.2 mass units of Ca; 1 mass unit of 75Si—Fe alloy can be replaced with 2.2 mass units of Ca; and 1 mass unit of Al is equivalent to 1 mass unit of 75Si—Fe alloy. 4. The method for smelting magnesium quickly and continuously according to claim 1 , wherein the condensing way in Step 4 is in direct condensation or atomizing condensation. 5. The method for smelting magnesium quickly and continuously according to claim 2 , wherein the Al or 75Si—Fe alloy in Step 1 is replaced with composite reductants selected from one of the following three groups: (1) Al+75Si—Fe alloys; (2) Ca+75Si—Fe alloys; (3) Al+Ca+75Si—Fe alloy; the standard dosage of the composite reductants are: 1 mass unit of Al can be replaced with 2.2 mass units of Ca; 1 mass unit of 75Si—Fe alloy can be replaced with 2.2 mass units of Ca; and 1 mass unit of Al is equivalent to 1 mass unit of 75Si—Fe alloy. 6. The method for smelting magnesium quickly and continuously according to claim 2 , wherein the condensing way in Step 4 is in direct condensation or atomizing condensation.