KR20130081778A - Thermo-reduction apparatus for manufacturing magnesium with temperature control condenser - Google Patents

Abstract

PURPOSE: A thermal reduction device for manufacturing magnesium with temperature controlling units is provided to improve the efficiency of separating magnesium and alkali metal while improving the efficiency of collecting magnesium. CONSTITUTION: A thermal reduction device for manufacturing magnesium includes a thermal reduction furnace, a thermal reduction reaction pipe (20), condensers (30), and temperature controlling units (40,50). The thermal reduction furnace heats a green compact briquette in which calcined dolomite, ferrosilicon, and fluorite powder are mixed. The green compact briquette is inserted into the thermal reduction reaction pipe, and the thermal reduction reaction pipe is heated by the thermal reduction furnace. The condensers condense the magnesian steam generated in the thermal reduction reaction pipe. The temperature controlling units controls the inner temperatures of the condensers.

Description

Thermo-Reduction apparatus for manufacturing magnesium with temperature control condenser

The present invention relates to a heat reduction device for manufacturing magnesium having a temperature controlled condenser, and more particularly, a temperature controlled condenser for producing magnesium metal in a solid or molten phase by calcining dolomite ore as a raw material and then thermally reducing it at a high temperature in a vacuum. It relates to a heat reduction device for producing magnesium having.

Methods for producing magnesium metal include heat reduction and electrolytic smelting. The thermal reduction method of magnesium production developed in the 1940s has been the most representative magnesium smelting technology for nearly 70 years. Currently, about 80% of the world's primary magnesium production is produced by thermal reduction.

As shown in FIG. 1, a molded briquette prepared by mixing dolomite and a reducing agent powder in a predetermined composition is introduced into a heat reduction reaction tube 120, and the thermal reduction furnace 110 is maintained at about 1000 ° C. or more while maintaining a vacuum state. When heated, a reduction reaction occurs, generating magnesium vapor.

The high temperature magnesium vapor is generated through the vacuum pump 140 attached to the upper end of the heat reduction reaction tube 120 and the upward flow due to the vacuum exhaust and high temperature, the condenser maintained at a temperature below the melting point of magnesium Once reached 130 it is deposited to form a magnesium crown. Then, when the heat reduction reaction is completed in the heat reduction reaction tube 120, the upper lid of the vacuum chamber equipped with the condenser 130 is opened to take out the condenser 130 to extract the magnesium crown.

The conventional heat reduction device for producing magnesium is to increase the size of the heat reduction reaction tube 120, to increase the diameter and length of the condenser 130 in order to improve productivity, energy efficiency and life of the heat reduction reaction tube (120). However, in addition to the structural stability of the heat reduction reaction tube 120, the separation of magnesium and alkali metal in the condenser 130 is not complete, so there is a high possibility that a safety accident and a fire may occur due to the rapid oxidation of the alkali metal during recovery. There was a problem.

In particular, dolomite, which is used as a raw material for magnesium vacuum heat reduction, has a high reactive alkali metal having a lower melting point and higher vapor pressure than magnesium, such as a small amount of K and Na, in the form of a compound such as an oxide.

If such impurity metal is not properly separated from magnesium and deposited in the magnesium crown, a fire occurs in the recovery of the magnesium crown in actual operation, and at the same time, it causes oxidation of the metal magnesium to reduce the productivity.

In actual heat reduction, small amounts of K and Na metal gas, which are mixed with magnesium gas, rise together with magnesium gas, and magnesium is first deposited on the lower part of the condenser where the condensation temperature is relatively high. K and Na metals are deposited and recovered.

However, the lower the pressure in the vacuum vessel, the more space therebetween and the collision between particles is reduced. Normally, at pressures above 0.01 torr, when some gas molecules are exhausted, a viscous induction phenomenon occurs in which other molecules move and fill the empty space immediately. Under high vacuum of 0.01 torr, the movement of molecules is irregular and influences each other. Molecular flow phenomena occur that do not affect this.

In the case of magnesium heat reduction, vertically rising magnesium gas must be circumferentially diffused and collide with the surface of the condenser surface in order to be deposited on the condenser. However, during heat reduction, it is usually maintained at 0.1 to 0.01 torr, so the viscosity of the gas rising vertically is weakened, and the diffusion rate in the circumferential direction is decreased, so that magnesium is frequently deposited on the condenser. There is a problem that the longer the larger the length.

In addition, as the length of the condenser increases, heat inflow to the upper condenser decreases, and when the temperature falls below about 300 ° C., K and Na are deposited, thereby causing a safety accident.

The present invention has been made to solve the above-mentioned conventional problems, and improves the separation efficiency between magnesium and alkali metal and at the same time improve the recovery efficiency of magnesium, it is possible to apply the condenser to the heat reduction reaction tube of various metals In addition, it reduces the installation space of the heat reduction device and at the same time improves the fluidity of the metal vapor, and a heat reduction device for manufacturing magnesium having a temperature-controlled condenser that can safely separate magnesium and alkali metal by the difference in condensation temperature to prevent safety accidents. To provide that purpose.

The present invention for achieving the above object, as a heat reduction device for producing magnesium used in the magnesium manufacturing process, a heat reduction furnace for heating the molded briquettes mixed with the molded dolomite, ferrosilicon and fluorspar powder; A heat reduction reaction tube installed inside the heat reduction furnace and charged with the molded briquettes and heated by the heat reduction reactor; A condenser connected to the heat reduction reaction tube to condense magnesium vapor generated in the heat reduction reaction tube; And a temperature control unit installed in the condenser to adjust a temperature inside the condenser.

The heat reduction reaction tube of the present invention is provided vertically or horizontally inside the heat reduction passage. The said condenser of this invention is integrally provided in the upper part of the said heat reduction reaction tube.

The temperature control unit of the present invention comprises a cooling unit installed around the outside to cool down to reduce the internal condensation temperature, and a heating unit installed around the inside to heat up to increase the condensation temperature inside. The said heating part of this invention is provided in the inner upper end of the said condenser.

As described above, the present invention provides an effect of improving the recovery efficiency of magnesium while improving the separation efficiency between magnesium and alkali metal by installing a temperature control unit around the condenser.

By installing the heat reduction reaction tube vertically or horizontally in the heat reduction furnace, the condenser can be applied to the heat reduction reaction tube of various metals.

By integrally installing the upper part of the heat reduction reaction tube so as to communicate with the condenser, it is possible to reduce the installation space of the heat reduction device and at the same time improve the fluidity of the metal vapor.

By installing a heating unit and a cooling unit to change the condensation temperature of the condenser, it provides an effect that can safely separate the magnesium and alkali metal by the condensation temperature difference to prevent safety accidents.

1 is a block diagram showing a vertical heat reduction apparatus for producing a typical magnesium.
Figure 2 is a block diagram showing a heat reduction device for producing magnesium having a temperature controlled condenser according to an embodiment of the present invention.
Figure 3 is a detailed view showing a heat reduction device for producing magnesium having a temperature controlled condenser according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram showing a heat reduction device for producing magnesium with a temperature controlled condenser according to an embodiment of the present invention, Figure 3 is a heat reduction device for producing magnesium with a temperature controlled condenser according to an embodiment of the present invention It is a detailed view which shows.

As shown in Figures 2 and 3, the heat reduction device for producing magnesium provided with a temperature control condenser of the present embodiment, the heat reduction reactor 10, the heat reduction reaction tube 20, the condenser 30 and the temperature control unit ( 40, 50) is a heat reduction device for manufacturing magnesium used in the magnesium manufacturing process.

The heat reduction furnace 10 is a heat source for heating the molded briquettes in which the calcined dolomite, ferrosilicon, and fluorite powder are mixed and molded, and a coal gas or LNG gas is used around the inside of the cylindrical heating furnace 11 as a heat source. A plurality of thermal reduction furnace regenerative burners 12 are burned apart.

The heat reduction reaction tube 20 is a cylindrical retort installed in the heat reduction furnace 10 and filled with a molded briquette 100 and heated by the heat reduction furnace 10 to perform vacuum heat reduction reaction ( 21, and a cooling member 22 provided around the lower end of the retort 21.

The heat reduction reaction tube 20 may be installed vertically or horizontally in the heat reduction path 10 to constitute a vertical heat reduction device or a horizontal heat reduction device.

The condenser 30 is a cylindrical condenser connected to the heat reduction reaction tube 20, and condenses magnesium vapor generated in the heat reduction reaction tube 20, and the first combustion chamber 31 and the pedestal 32. It consists of a communication plate (33).

The first combustion chamber 31 is formed in a cylindrical shape in the condenser 30, and communicates with the heat reduction reaction tube 20, the magnesium vapor generated in the heat reduction reaction tube 20 is introduced into the condensation on the inner peripheral surface do.

Pedestal 32 is formed around the lower end of the inner circumferential surface of the condenser 30 is formed as a support member for supporting the lower portion of the first combustion chamber 31, the communication plate 33 is installed in the upper portion of the first combustion chamber 31 The central part has a communication hole penetrating the upper part.

In addition, the condenser 30 may be integrally installed and communicated with an upper portion of the heat reduction reaction tube 20 when the heat reduction reaction tube 20 is vertically installed inside the heat reduction reactor 10. to be.

A vacuum pipe is installed on one of the outer circumferential surfaces of the condenser 30, and a vacuum pump 60 provided outside is connected to the condenser 30 through the vacuum pipe. The vacuum pump 60 is a vacuum source for making the internal atmosphere of the condenser 30 into a vacuum, and the internal atmosphere of the heat reduction reaction tube 20 communicated therewith as well as the condenser 30 is made into a vacuum.

Temperature control unit (40, 50) is installed in the condenser (30) is a temperature control means for controlling the temperature inside the condenser 30, is installed around the outside of the condenser 30 to adjust the condensation temperature inside the condenser (30) It consists of a cooling part 50 which cools so that it may lower, and the heating part 40 which is installed around the inside of the condenser 30, and heats it so that the condensation temperature inside the condenser 30 may be raised.

In addition, the heating unit 40 is installed on the inner upper end of the condenser 30 to increase the deposition temperature of the upper condenser 30 to induce the magnesium vapor introduced from the lower side to the lower side of the condenser 30 to be deposited.

In particular, it is preferable to use a heater as the heating part 40, and variously selected and used, such as a heating plate in which a heating wire for applying heat to the condenser 30 is buried, or a heating plate in which a pipe through which a heat transfer medium flows is embedded. Of course it is also possible.

In addition, the cooling unit 50 is installed around the outer circumference of the condenser 30 to reduce the condensation temperature inside the condenser 30 to prevent the magnesium vapor introduced from the lower is deposited on the upper side of the condenser, condensation, The cooling unit 50 is preferably made of a cooling member in which a cooling medium such as cooling water or cooling gas is inserted.

The temperature control unit 40, 50 is installed in the condenser 30 of the vertical heat reduction apparatus of the present embodiment to change the condensation temperature of the condenser 30, the magnesium vapor is condensed by heating or cooling the condenser 30 It is a matter of course that the shape of the temperature adjusting means may be formed in a cylindrical shape, a plate shape consisting of a plurality of plates, or a rod shape.

In this way, by adjusting the temperature of the condenser 30 inside the condenser 30 by the temperature control unit 40, 50, the internal temperature of the condenser 30 is lower than the melting point of magnesium and 300 to higher than the deposition temperature of alkali metals such as K and Na. By maintaining the temperature of about 550 ℃, by installing a temperature sensor for detecting the temperature on the upper part of the condenser 30 to control the operation of the temperature control unit 40, 50 based on the detected temperature, the condenser 30 The temperature at the top is kept below 300 ° C.

Therefore, in the vacuum heat reduction reaction, only magnesium is deposited in the condenser 30 of the magnesium gas containing the impurity metal, K, Na, or other alkali metal gas, and then the metal gas continues to rise to increase the magnesium in the condenser 30. A self-contained gas containing alkali metals such as K and Na, which are condensed and extinguished by gas, passes through the upper portion of the condenser 30 and is separately installed on the upper portion of the condenser 30 to recover alkali metals such as K and Na. It is recovered by the device.

As described above, the present invention provides an effect of improving the recovery efficiency of magnesium while improving the separation efficiency between magnesium and alkali metal by providing a temperature control unit around the condenser.

In addition, by installing the heat reduction reaction tube vertically or horizontally inside the heat reduction furnace, the condenser can be applied to the heat reduction reaction tube of various metals, and by integrally installed to communicate with the condenser on top of the heat reduction reaction tube. In addition, the installation space of the heat reduction device is reduced, and the flowability of the metal vapor is improved.

In addition, by installing a heating unit and a cooling unit to change the condensation temperature of the condenser, it provides an effect that can safely separate the magnesium and alkali metal by the condensation temperature difference to prevent safety accidents.

The present invention described above can be embodied in many other forms without departing from the spirit or main features thereof. Therefore, the above embodiments are merely examples in all respects and should not be interpreted limitedly.

10: heat reduction reactor 20: heat reduction reaction tube
30: condenser 40: heating part
50: cooling unit

Claims (5)

As a heat reduction device for manufacturing magnesium used in the magnesium manufacturing process,
A heat reduction furnace for heating the molded briquettes in which the calcined dolomite, ferrosilicon, and fluorite powder are mixed and molded;
A heat reduction reaction tube installed inside the heat reduction furnace and charged with the molded briquettes and heated by the heat reduction reactor;
A condenser connected to the heat reduction reaction tube to condense magnesium vapor generated in the heat reduction reaction tube; And
And a temperature control unit installed in the condenser to control the temperature of the inside of the condenser. The method of claim 1,
The heat reduction reaction tube is a heat reduction device for producing magnesium having a temperature controlled condenser, characterized in that installed in the interior of the heat reduction path vertically or horizontally. The method of claim 1,
The condenser is a heat reduction device for producing magnesium provided with a temperature controlled condenser, characterized in that integrally installed on the heat reduction reaction tube. The method of claim 1,
The temperature control unit, the temperature control condenser is installed in the outer periphery, the cooling unit for cooling to lower the condensation temperature of the inside, and the heating unit is installed in the inner circumference for heating to increase the condensation temperature of the inside Thermal reduction apparatus for manufacturing magnesium provided with. 5. The method of claim 4,
The heating unit is a heat reduction device for producing magnesium having a temperature controlled condenser, characterized in that installed on the inner upper end of the condenser.

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