CN209836261U - Aluminothermic method magnesium smelting device - Google Patents

Abstract

The utility model discloses a device for smelting magnesium by an aluminothermic method, which comprises a vacuum induction furnace, a vacuumizing device and a condensation collection system, wherein the top of the vacuum induction furnace is provided with a feeding system, the bottom of the vacuum induction furnace is provided with a slag collecting system, the condensation collection system comprises a condensation pipe and a collection tank, the first end of the condensation pipe is communicated with the vacuum induction furnace, and the second end of the condensation pipe is communicated with the collection tank; during the system magnesium, pack the system magnesium raw materials in the vacuum induction furnace through charge-in system earlier, recycle evacuating device to the vacuum induction furnace evacuation, and heat vacuum induction furnace to reaction temperature, make magnesium oxide take place reduction reaction and produce magnesium steam, the magnesium steam of production passes through condenser pipe cooling and transport to the collection tank and condenses, after reduction reaction, the waste residue accessible in the vacuum induction furnace is received the sediment system and is discharged from the below, the material loading with arrange the sediment simple and convenient, time saving and labor saving, it is efficient.

Description

Aluminothermic method magnesium smelting device

Technical Field

The utility model relates to the technical field of metallurgy, in particular to a magnesium smelting device by an aluminothermic method.

Background

Magnesium is a metal element with abundant reserves in the earth, and magnesium alloy have the characteristics of light specific gravity, high strength, good shock absorption, good machinability, good thermal conductivity, cyclic utilization and the like, have good environmental advantages and performance advantages, are wide in application range and have huge market demands.

The production method of magnesium mainly comprises two types of electrolytic methods and thermal reduction methods. At present, 85 percent of magnesium in the world is produced by adopting a silicothermic reduction method (namely a Pidgeon method) in a thermal reduction method, and the main principle is that calcined dolomite is reduced into metal magnesium by utilizing a ferrosilicon reducing agent in a reduction tank.

The silicothermic method is a solid state reaction, and has a plurality of defects: large heat conducting radius, large heat loss, serious environmental pollution and long reduction time which is about 12 to 14 hours; secondly, all manual operations are carried out, the labor intensity of field workers is high, and the efficiency is low; high energy consumption, high cost of a reduction tank, low yield and high comprehensive production cost caused by the fact that waste residues cannot be comprehensively utilized; and fourthly, large-scale continuous production cannot be formed, and the requirements of modern large-scale industrial production are not met.

In addition, when adopting present pidgeon method magnesium smelting device production magnesium, need consume a large amount of time to go to load the reaction storehouse that the level set up with reaction material, and when heating the reaction storehouse, need set up multistage heat preservation measure to the reaction storehouse, in order to guarantee the temperature stability in the reaction storehouse, ensure the normal clear of reaction, this will cause the cost of installing the heat preservation additional too high, can not condense simultaneously after the magnesium steam that produces gets into condensing equipment in the production process, lead to magnesium after condensing to scatter in condensing equipment, be not convenient for collect, after the reaction is accomplished, still need consume a large amount of time and clear up the waste material in the reaction storehouse, lead to production efficiency low.

Therefore, the magnesium making device which is convenient for feeding and slag removal and short in reaction time is provided, and the technical problem which needs to be solved by the technical personnel in the field at present is solved.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a magnesium device is smelted to aluminothermy method, the sediment is arranged to the material loading simple and convenient, labour saving and time saving, and is efficient.

In order to solve the technical problem, the utility model provides a magnesium device is smelted to aluminothermic method, including the vacuum induction furnace, be used for with the evacuating device of vacuum induction furnace evacuation and the condensation collecting system that is used for the condensation to collect magnesium vapour, the top of vacuum induction furnace is equipped with charge-in system, the bottom of vacuum induction furnace is equipped with receipts slag system, the condensation collecting system is including the condenser pipe that is used for the condensation and carries magnesium vapour and the collection tank that is used for collecting magnesium liquid, the first end intercommunication of condenser pipe the vacuum induction furnace, second end intercommunication the collection tank.

Preferably, the vacuum induction furnace includes base, furnace body and upper cover, be equipped with charge door and magnesium vapour export on the upper cover, the charge door passes through the conveying pipeline and connects feed system, the first end of condenser pipe is connected magnesium vapour exit, receive the sediment system through arrange the sediment valve with furnace body inner chamber intercommunication, be equipped with in the furnace body and be used for holding crucible, the parcel that makes the magnesium raw materials and be in heat preservation outside the crucible and winding are in induction heating coil on the outer wall of heat preservation.

Preferably, charge-in system includes from last to holding hopper, one-level vacuum feed bin and the second grade vacuum feed bin that connects gradually down, the discharge gate of second grade vacuum feed bin pass through the conveying pipeline with the charge door links to each other, just hold the hopper with be equipped with one-level vacuum valve between the one-level vacuum feed bin, one-level vacuum feed bin with be equipped with the second grade vacuum valve between the second grade vacuum feed bin, the discharge gate of second grade vacuum feed bin with be equipped with tertiary vacuum valve between the charge door.

Preferably, the slag collecting system comprises a slag storage chamber arranged below the base, the crucible comprises a bottom plate and a barrel which are detachably connected, the slag discharging valve comprises a pull rod and the bottom plate, one end of the pull rod is connected with the bottom of the bottom plate, and the other end of the pull rod extends out of the furnace body.

Preferably, the slag receiving system further comprises a slag bin, a slag storage tank and a chain plate slag conveyor, the slag bin is arranged below the slag storage chamber and is connected with the slag storage chamber through a first vacuum valve, and the chain plate slag conveyor for conveying waste slag into the slag storage tank is arranged below a discharge port at the bottom of the slag bin.

Preferably, the condensation pipe comprises a plurality of condensation parts with different condensation temperatures, heating wires for controlling the temperature in the condensation parts are respectively wound on the condensation parts, the condensation parts are sequentially connected according to the condensation temperature, the condensation part with the highest condensation temperature is connected with the vacuum induction furnace, and the condensation part with the lowest condensation temperature is connected with the collection tank.

Preferably, the condensation and collection system further comprises a collecting pipe, the pipe diameter of the collecting pipe gradually increases from the first end to the second end, the first end of the collecting pipe is connected with the second end of the condensation pipe, a vertically downward collecting port is formed in the side surface of the second end of the collecting pipe, and the collecting port is communicated with the collecting tank through a conduit.

Preferably, a vertical upward air outlet is further arranged on the side face of the second end of the collecting pipe, a three-way pipe is connected to the air outlet, the other two outlets of the three-way pipe are respectively connected with the cyclone separating pipe and the dust separator, a collecting pipe is arranged below the cyclone separating pipe, the diameter of the cyclone separating pipe is gradually reduced from top to bottom, the diameter of the collecting pipe is gradually increased from top to bottom, an upper pipe opening of the collecting pipe is communicated with a lower pipe opening of the cyclone separating pipe, a baffle plate used for shielding the communication position of the cyclone separating pipe and the collecting pipe is arranged between the cyclone separating pipe and the collecting pipe, and an ash receiving hopper is arranged at a dust outlet of the dust separator.

Preferably, the vacuum extractor is connected to an air outlet of the dust separator.

The utility model provides a magnesium device is smelted to aluminothermic process, including the vacuum induction furnace, be used for with the evacuating device of vacuum induction furnace evacuation and be used for the condensation collecting system that the magnesium vapour was collected in the condensation, the top of vacuum induction furnace is equipped with charge-in system, the bottom of vacuum induction furnace is equipped with receipts sediment system, the condensation collecting system is including the condenser pipe that is used for the condensation and carries the magnesium vapour and be used for collecting the collection tank of magnesium liquid, the first end intercommunication vacuum induction furnace of condenser pipe, second end intercommunication collection tank.

During magnesium production, the magnesium production raw material is filled in the vacuum induction furnace through the feeding system, the vacuum induction furnace is vacuumized by the vacuumizing device, the vacuum induction furnace is heated to the reaction temperature, magnesium oxide is subjected to reduction reaction to generate magnesium steam, the generated magnesium steam is cooled through the condensing pipe and conveyed to the collecting tank for condensation, and after the reduction reaction is finished, condensed magnesium can be taken out of the collecting tank and waste residues in the vacuum induction furnace are discharged from the lower part through the slag collecting system.

To sum up, the utility model provides a magnesium device is smelted to aluminothermic process connects feeding system, vacuum induction furnace and receipts slag system from top to bottom in proper order, can realize automatic feeding and arrange the sediment, greatly reduced the material loading arrange the sediment time, improved production efficiency.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of an apparatus for producing magnesium by aluminothermic process according to the present invention;

FIG. 2 is a schematic structural diagram of another embodiment of the magnesium smelting apparatus by aluminothermic process according to the present invention;

fig. 3 is a schematic structural diagram of an embodiment of the vacuum induction furnace provided by the present invention;

fig. 4 is a schematic structural diagram of an embodiment of a condensation collection system provided by the present invention.

The drawings are numbered as follows:

the device comprises a vacuum induction furnace 1, a base 11, a furnace body 12, an upper cover 13, a crucible 14, a heat insulation layer 15, an induction heating wire 16, a vacuumizing device 2, a condensation collection system 3, a condensation pipe 31, a collection tank 32, heating wires 33, a collection pipe 34, a feeding system 4, a material loading hopper 41, a primary vacuum bin 42, a secondary vacuum material 43, a slag collection system 5, a slag storage chamber 51, a slag bin 52, a chain plate slag conveyor 53, a slag storage tank 54, a cyclone separation pipe 6 and a collection pipe 7.

Detailed Description

The core of the utility model is to provide a device for smelting magnesium by an aluminothermic method, which is simple and convenient in feeding and deslagging, time-saving and labor-saving, and high in efficiency.

In order to make the technical field better understand the solution of the present invention, the following detailed description of the present invention is provided with reference to the accompanying drawings and the detailed description.

Referring to fig. 1 to 4, fig. 1 is a schematic structural diagram of an embodiment of an aluminothermic magnesium smelting apparatus provided in the present invention; FIG. 2 is a schematic structural diagram of another embodiment of the magnesium smelting apparatus by aluminothermic process according to the present invention; fig. 3 is a schematic structural diagram of an embodiment of the vacuum induction furnace provided by the present invention; fig. 4 is a schematic structural diagram of an embodiment of a condensation collection system provided by the present invention.

The magnesium smelting device by the aluminothermic process provided by the concrete embodiment of the utility model mainly comprises a vacuum induction furnace 1, a vacuum pumping device 2, a feeding system 4, a condensing and collecting system 3 and a slag collecting system 5,

the vacuum induction furnace 1 is a container for generating reduction reaction and is used for filling magnesium preparation raw materials, and the vacuumizing device 2 is connected with the vacuum induction furnace 1 and is used for vacuumizing the vacuum induction furnace 1 during magnesium preparation so as to prevent oxygen in the air from influencing the normal operation of the reduction reaction; the feeding system 4 is arranged at the top of the vacuum induction furnace 1, so that reaction raw materials can be filled from the upper part of the vacuum induction furnace 1, the slag collecting system 5 is arranged at the bottom of the vacuum induction furnace 1, and waste slag after reaction can be directly discharged from the bottom of the vacuum induction furnace 1;

the condensation collection system 3 specifically comprises a condensation pipe 31 for condensing and conveying magnesium vapor and a collection tank 32 for collecting magnesium liquid, wherein the first end of the condensation pipe 31 is communicated with the vacuum induction furnace 1, the second end of the condensation pipe is communicated with the collection tank 32, the magnesium vapor generated in the vacuum induction furnace 1 in the magnesium production process is output through the condensation pipe 31, and the condensation collection system is cooled in the conveying process until the magnesium vapor is conveyed to the collection tank 32 for condensation.

Wherein, evacuating device 2 can establish the second end at condenser pipe 31 to through condenser pipe 31 and vacuum induction furnace 1 intercommunication, can reduce connection opening on the vacuum induction furnace 1, more be favorable to vacuum induction furnace 1 in the realization of vacuum environment.

During the system magnesium, pack the system magnesium raw materials in vacuum induction furnace 1 through charge-in system 4 earlier, reuse evacuating device 2 to vacuum induction furnace 1 evacuation to predetermineeing pressure, and heat vacuum induction furnace 1 to reaction temperature, make magnesium oxide take place reduction reaction and produce magnesium steam, the magnesium steam of production passes through condenser pipe 31 cooling and carries to the collection tank 32 and condense, after reduction reaction, can take out the magnesium that condenses from collection tank 32, and discharge the waste residue in the vacuum induction furnace 1 from the below through receiving slag system 5.

To sum up, the utility model provides a magnesium device is smelted to aluminothermic method only needs to accomplish through control feeding system and puts into the furnace body with the system magnesium raw materials, and the reaction is accomplished the back, can accomplish through control machinery discharge apparatus and discharge the waste residue, and the sediment is arranged to the material loading simple and convenient, labour saving and time saving, and is efficient.

On the basis of the above specific embodiment, the utility model provides a magnesium device is smelted to aluminothermic process, specifically, vacuum induction furnace 1 can include base 11, furnace body 12 and upper cover 13, as shown in fig. 3, be equipped with charge door and magnesium vapour export on upper cover 13, the charge door passes through the conveying pipeline and connects feed system 4, the first end of condenser pipe 31 is connected in magnesium vapour exit, receive slag system 5 and furnace body 12 inner chamber intercommunication through the slag discharge valve, be equipped with the reaction vessel who is used for holding the system magnesium raw materials in the furnace body 12, the reaction vessel is preferably crucible 14, the reaction vessel is equipped with heat preservation 15 and heating device outward;

the heat-insulating layer 15 is preferably wrapped outside the crucible 14, the heating device is preferably an induction heating coil 16 and is wound on the outer wall of the heat-insulating layer 15, the heat-insulating layer 15 can isolate a vacuum reaction chamber in the furnace body 12, the crucible 14 is placed in the vacuum reaction chamber, and the magnesium preparation process is that the magnesium preparation raw material is placed in the crucible 14 in the furnace body 12 through the feeding system 4 and is electrified and heated through the induction heating coil 16, so that the magnesium preparation raw material is subjected to a reduction reaction at a high temperature to generate magnesium steam; set up reaction furnace body 12 into hollow structure to keep warm to the vacuum reaction chamber through heat preservation 15, be favorable to maintaining the temperature stable, and choose crucible 14 for use as reaction vessel, because crucible 14 is high temperature resistant, thermal insulation performance is superior and chemical property is stable, consequently can make the reduction reaction of magnesium raw materials more stable, efficiency is higher.

Further, can also be equipped with first temperature measuring device on the upper cover 13, the temperature probe of first temperature measuring device stretches into to furnace body 12 in to can the accurate temperature measurement in furnace body 12, the reading end of first temperature measuring device is located outside furnace body 12, in order to make things convenient for operating personnel to read, measures the interior temperature of furnace body 12 through first temperature measuring device, whether reach standard in order to make things convenient for operating personnel to detect vacuum induction furnace 1.

In addition, a vacuum detection port for placing a vacuum gauge can be further arranged on the upper cover 13, so that an operator can conveniently detect whether the vacuum degree in the vacuum induction furnace 1 reaches the standard or not.

Further, for the convenience of operating personnel to observe the condition in the furnace, a peeping hole can be arranged on the upper cover 13, and high-temperature glass can be specifically installed at the peeping hole and is in sealing connection with the upper cover 13.

On the basis of each above-mentioned specific embodiment, the utility model provides a magnesium device is smelted to thermite process, feed system 4 specifically can be including holding hopper 41, holds hopper 41 and passes through vacuum valve and charge door intercommunication, will make the magnesium raw materials put into during the material loading and hold hopper 41, will make the magnesium raw materials through the vacuum valve and put into vacuum induction furnace 1.

In order to ensure the vacuum environment in the vacuum induction furnace 1, the feeding system 4 can further comprise a first-stage vacuum bin 42 and a second-stage vacuum bin 43, the material holding hopper 41, the first-stage vacuum bin 42 and the second-stage vacuum bin 43 are sequentially connected from top to bottom, a discharge port of the second-stage vacuum bin 43 is connected with a feed inlet through a feed delivery pipe, a first-stage vacuum valve is arranged between the material holding hopper 41 and the first-stage vacuum bin 42, a second-stage vacuum valve is arranged between the first-stage vacuum bin 42 and the second-stage vacuum bin 43, and a third-stage vacuum valve is arranged between the discharge port of the second-stage vacuum bin; put into holding hopper 41 during the material loading with the system magnesium raw materials, put into one-level vacuum feed bin 42 through controlling the system magnesium raw materials in one-level vacuum valve will hold hopper 41, then carry out vacuum treatment to this feed bin, discharge air through one-level vacuum valve, then put into second grade vacuum feed bin 43 through the second grade vacuum valve with the system magnesium raw materials, and discharge the air in second grade vacuum feed bin 43 again through the second grade vacuum valve, put into the vacuum reaction chamber of vacuum induction furnace 1 through the tertiary vacuum valve with the system magnesium raw materials through the conveying pipeline at last, through setting up multistage feed bin, and carry out evacuation processing in the time of the feeding, guarantee that the system magnesium raw materials at last get into in vacuum reaction chamber's crucible 14 does not have the air admission, thereby guarantee vacuum reaction chamber's vacuum environment.

On the basis of the above embodiments, the utility model provides a magnesium device is smelted to aluminothermic process, receive slag system 5 and be used for discharging the waste residue in vacuum induction furnace 1, specifically, can be equipped with deposit room 51 below base 11, deposit room 51 communicates with furnace body 12 inner chamber through the slag-off valve, the slag-off valve can be become by the bottom plate of pull rod and crucible 14, the bottom plate and the barrel of crucible 14 can be dismantled and be connected, one end of pull rod links to each other with the bottom of bottom plate, the other end stretches out outside furnace body 12; when magnesium is produced, the pull rod is pushed inwards to enable the bottom plate to seal the bottom of the crucible 14, after the reaction is finished, the pull rod is pulled outwards to enable the bottom plate to move horizontally away from the bottom of the crucible 14, the bottom of the crucible 14 is in an open state, and waste residues in the crucible 14 can be directly discharged from the bottom opening of the crucible 14 and fall into a residue storage chamber 51 arranged below the vacuum reaction furnace, so that the method is simple and convenient.

Further, receive sediment system 5 can also include the cinder storehouse 52 and the sediment storage tank 54 that is used for collecting the waste residue of being connected with sediment chamber 51, cinder storehouse 52 is established in sediment chamber 51 below, the discharge gate below of cinder storehouse 52 bottom is provided with the defeated sediment machine 53 of link joint that is used for carrying the waste residue into sediment storage tank 54, will carry from the waste residue of cinder storehouse exhaust through the defeated sediment machine 53 of link joint and collect in the sediment storage tank 54, carry out subsequent processing, realize automatic collection packing reaction waste residue, prevent that the waste residue from dying the environment in disorder, in addition can also carry out waste utilization according to the characteristic of waste residue, improve resource utilization.

In order to ensure the vacuum environment in the vacuum induction furnace 1, the bottom of the slag storage chamber 51 is preferably connected with the slag bin 52 through a first vacuum valve, and a second vacuum valve can be arranged at a discharge port at the bottom of the slag bin 52 to prevent air from entering the vacuum induction furnace 1 through the slag storage chamber 51 during magnesium making.

Wherein, can install second temperature measuring device on vacuum reaction furnace's base 11, second temperature measuring device's temperature probe stretches into in deposit sediment room 51, carry out the temperature measurement to the waste residue of discharging deposit sediment room 51 through second temperature measuring device, prevent that the too high waste residue of temperature from getting into the damage that the sediment feed bin caused equipment, in addition, can utilize the waste heat of waste residue to reduce vacuum reaction room and deposit sediment room 51's heat exchange, be favorable to the indoor temperature stability of vacuum reaction, guarantee continuous production, wait to discharge when the temperature of waste residue is low in deposit sediment room 51, prevent microthermal waste residue from absorbing the heat to the reaction chamber, and the production efficiency is reduced.

On the basis of each above-mentioned embodiment, for guaranteeing the synchronous condensation of magnesium vapour, prevent to be close to the magnesium vapour cooling fast condensation of pipe wall in the pipeline, the utility model provides a magnesium device is smelted to the aluminothermic method, condenser pipe 31 includes a plurality of condensation portions that have different condensing temperature, twine respectively on each condensation portion and have the heating wire 33 that is used for controlling its intraductal temperature, can generate heat after heating wire 33 circular telegram to make each condensation portion can keep certain intraductal temperature throughout, each condensation portion connects gradually according to the condensing temperature height, and the highest condensation portion of condensing temperature is connected with vacuum induction furnace 1, and the lowest condensation portion of condensing temperature is connected with collection tank 32.

Note that the condensing temperature of the condensing portion refers to the temperature inside the condensing portion tube, and if the condensing temperature of a certain condensing portion is 900 ℃, the temperature of the magnesium vapor is reduced to 900 ℃ when passing through the condensing portion of the condensing tube 31.

In addition, the condensing temperature of the condensing portion connected to the collecting tank 32 is preferably slightly higher than the liquefying temperature of the magnesium vapor, that is, the temperature in the condensing portion with the lowest condensing temperature is slightly higher than the liquefying temperature of the magnesium vapor, so as to avoid the magnesium vapor from liquefying in the condensing pipe 31 and ensure that the magnesium vapor falls into the collecting tank 32 after being condensed.

Magnesium vapour that reduction reaction produced gets into condenser pipe 31 from smelting magnesium vacuum induction furnace 1, prevent that magnesium vapour from condensing because of the temperature drop is too fast before getting into collection tank 32, through setting up condenser pipe 31 into a plurality of condensation portions that have different condensing temperature, make the intraductal temperature of every condensation portion unanimous basically, and make the intraductal temperature of each condensation portion reduce gradually, can guarantee that magnesium vapour is everywhere the same temperature in same section condenser pipe 31, thereby make magnesium vapour can the synchronous condensation and all fall into collection tank 32, the problem of condenser pipe 31 jam has effectively been avoided, make the magnesium product collect conveniently, and need not frequently to clear up condenser pipe 31, condensation efficiency has been improved.

The condensation pipe 31 is provided with a plurality of condensation portions, and it should be noted that the number of the condensation portions and the condensation temperature of each condensation portion are not particularly limited in the present application, and may be specifically selected according to the cooling rate. Preferably, the condensation pipe 31 may include three condensation portions, which may be respectively referred to as a first condensation portion, a second condensation portion and a third condensation portion from high to low, wherein the condensation temperature of the first condensation portion may be 950 ℃, the condensation temperature of the second condensation portion may be 900 ℃ and the condensation temperature of the third condensation portion may be 860 ℃.

Optionally, each condensing part of the condensing pipe 31 is integrally cast, that is, the condensing pipe 31 is integrally formed, mechanical connection is not required between each condensing part, and the sealing performance is good. Of course, each condensation portion may also be a pipe, that is, the condensation pipe 31 may be formed by connecting a plurality of pipes in sequence, which is also within the protection scope of the present invention.

In addition to the above-mentioned embodiments, the condensing portions have different condensing temperatures, which can be realized in various ways, in one embodiment, the resistance values of the heating wires 33 wound on the condensing portions are different, and the resistance value of the heating wire 33 on the condensing portion with a high condensing temperature is greater than the resistance value of the heating wire 33 on the condensing portion with a low condensing temperature; by selecting the heating wires 33 having different resistance values, the heating amounts of the heating wires 33 are different when the condenser is energized, and the heating amount of the heating wire 33 having a large resistance value is high and the heating amount of the heating wire 33 having a small resistance value is low, thereby realizing different temperatures in the respective condenser tubes.

In another embodiment, the number of winding turns of the heating wire 33 wound on each condensing portion is different, and the number of winding turns of the heating wire 33 on the condensing portion where the condensing temperature is high is greater than the number of winding turns of the heating wire 33 on the condensing portion where the condensing temperature is low; in the case of the same current, the heating wire 33 having a large number of winding turns generates a large amount of heat cumulatively, thereby increasing the temperature and controlling the temperature difference in the respective condensation portion pipes.

In another embodiment, the heating wires 33 wound on the condensing portions may be connected in parallel, and the heating wires 33 are connected to a power supply through a voltage regulator, and the voltage across the heating wires 33 is adjusted through the voltage regulator, so as to adjust the current of the heating wires 33, and control the heat generation amount of each heating wire 33, and the heat generation amount is more when the voltage is high and less when the voltage is low, thereby controlling the temperature difference in each condensing portion.

On the basis of the above embodiments, the condensing and collecting system 3 of the device for smelting magnesium by aluminothermic process provided by the present invention specifically comprises a collecting pipe 34, wherein the pipe diameter of the collecting pipe 34 is gradually increased from the first end to the second end, the first end of the collecting pipe 34 is connected with the second end of the condensing pipe 31, a vertical downward collecting port is opened on the side surface of the second end of the collecting pipe 34, and the collecting port is communicated with the collecting tank 32 through a conduit; after the magnesium vapor cooled by the condenser pipe 31 is condensed into magnesium liquid in the collecting pipe 34, the magnesium liquid can flow into the collecting tank 32 along the inner wall of the collecting pipe 34 and through the conduit, and the collecting pipe 34 can play a guiding role for collecting the magnesium liquid, so that the magnesium vapor can enter the collecting tank 32 more smoothly.

Further, a blind plate is mounted at the second end of the header 34, the blind plate is preferably detachably connected with the header 34, and the condenser pipe 31 can be cleaned simply and conveniently by detaching the blind plate. To prevent magnesium vapor from condensing and falling onto the junction of the blind plate and the header 34, which would make the blind plate difficult to remove, the tube may be attached to the second end of the header 34 and the blind plate may be mounted to the end of the tube remote from the header 34, with the blind plate being removably attached to the tube.

Furthermore, the device for smelting magnesium by using the aluminothermic process provided by the utility model is also doped with protective gas and a small amount of dust in the high-temperature magnesium vapor discharged from the magnesium smelting vacuum induction furnace 1, so that in order to reduce the pollution to the environment, a vertical upward gas outlet can be arranged on the side surface of the second end of the collecting pipe 34, the gas outlet is connected with a dust separator, and a dust outlet of the dust separator can be provided with a dust receiving hopper;

in addition, the magnesium vapor can overflow from the gas outlet when the temperature of part of the magnesium vapor is reduced too slowly, in order to improve the collection rate of the magnesium, a three-way pipe can be connected to the gas outlet, the other two outlets of the three-way pipe are respectively connected with a cyclone separating pipe 6 and a dust separator, a collecting pipe 7 can be arranged below the cyclone separating pipe 6, the diameter of the cyclone separating pipe 6 is gradually reduced from top to bottom, the diameter of the collecting pipe 7 is gradually increased from top to bottom, an upper pipe opening of the collecting pipe 7 is communicated with a lower pipe opening of the cyclone separating pipe 6, and a baffle plate used for shielding the communication part of the cyclone separating pipe 6 and;

magnesium vapor mixed with protective gas, dust and the like enters the cyclone separation pipe 6 after overflowing from the gas outlet, the magnesium vapor is changed into magnesium particles after cooling and temperature reduction and falls on the baffle, the magnesium particles can fall into the collecting pipe 7 after the baffle is opened, the protective gas, the dust and the like enter the dust separator after overflowing from the gas outlet, the dust separator separates the dust from other gases, the separated dust falls into the dust receiving hopper, and the gases such as argon gas, carbon monoxide and the like are discharged into the atmosphere from the gas outlet of the dust separator.

Further, the vacuumizing device 2 can be connected to the air outlet of the dust separator, and the connection is simple and convenient.

To sum up, the device for smelting magnesium by the aluminothermic process provided by the utility model connects the feeding system, the vacuum induction furnace 1 and the slag collecting system 5 up and down in sequence, realizes automatic feeding and slag discharging, greatly reduces the feeding and slag discharging time, and improves the production efficiency; the reaction furnace body 12 is arranged to be a hollow sandwich structure, and the crucible 14 is adopted as a reaction container, so that a large amount of heat preservation equipment is avoided, and the equipment cost is reduced; through setting up condenser pipe 31 as the condensation portion of a plurality of different temperatures, guarantee that the temperature in every section condenser pipe 31 is unanimous basically, and condenser pipe 31's temperature reduces gradually to guarantee that magnesium steam is the same at same pipeline everywhere temperature, make magnesium steam condensate simultaneously fall into in the holding vessel 32, avoided the problem of condenser pipe 31 jam, improved condensation efficiency.

The application also provides a process for smelting magnesium by an aluminothermic method, which can be implemented by adopting the magnesium smelting device, and the process for smelting magnesium by the aluminothermic method specifically comprises the following steps:

mixing 99% of aluminum powder and 95% of magnesium oxide according to the proportion of 1:3 and pressing into spherical pellets; then the material mass is loaded into a vacuum induction furnace 1 through a feeding system 4; vacuumizing the vacuum induction furnace 1 to a preset pressure by using the vacuumizing device 2, heating the vacuum induction furnace 1 to a preset temperature to enable magnesium oxide in the material mass to perform a reduction reaction, cooling magnesium steam generated by the reaction through a condensing pipe 31, and conveying the magnesium steam to a collecting tank 32 for condensation; after the reduction reaction is finished, taking out the condensed magnesium from the collecting tank 32, and discharging the waste slag in the vacuum induction furnace 1 through the slag collecting system 5.

The diameter of the material mass is preferably set within the range of 20mm to 40mm, the material mass in the vacuum induction furnace 1 is heated more uniformly and has good heat preservation effect, and the reduction reaction efficiency is higher; the preset pressure in the vacuum induction furnace 1 is set within the range of 10Pa to 100Pa, and the preset temperature is set within the range of 1150 ℃ to 1250 ℃.

Under the above conditions, the reduction time is only about 2 hours, most of magnesium oxide can be reduced into magnesium vapor, compared with a silicothermic reduction method, the reduction time is greatly shortened, the production efficiency is greatly improved, and in addition, the heat preservation time required by the vacuum induction furnace 1 is also greatly shortened, so the production energy consumption is reduced, and the production cost is reduced.

In the description of the present invention, it is to be understood that the terms "upper", "lower", and the like, indicate orientations or relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the designated device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

It is noted that, in this specification, relational terms such as first and second, and the like are used solely to distinguish one entity from another entity without necessarily requiring or implying any actual such relationship or order between such entities.

In addition, the embodiments in the specification are described in a progressive manner, each embodiment focuses on differences from other embodiments, and similar parts among the embodiments are referred to each other. The device disclosed by the embodiment corresponds to the method disclosed by the embodiment, so that the description is simple, and the relevant part can be referred to the method part for description.

The device for smelting magnesium by the aluminothermic method provided by the utility model is introduced in detail. The principles and embodiments of the present invention have been explained herein using specific examples, and the above descriptions of the embodiments are only used to help understand the method and its core ideas of the present invention. It should be noted that, for those skilled in the art, without departing from the principle of the present invention, the present invention can be further modified and modified, and such modifications and modifications also fall within the protection scope of the appended claims.

Claims (9)

1. The utility model provides a magnesium device is smelted to aluminothermic method, characterized in that, including vacuum induction furnace (1), be used for with evacuating device (2) of vacuum induction furnace (1) evacuation and be used for the condensation to collect magnesium vapour condensation collecting system (3), the top of vacuum induction furnace (1) is equipped with charge-in system (4), the bottom of vacuum induction furnace (1) is equipped with receives slag system (5), condensation collecting system (3) are including being used for condensation and condenser pipe (31) of carrying magnesium vapour and being used for collecting the collection tank of magnesium liquid, the first end intercommunication of condenser pipe (31) vacuum induction furnace (1), the second end intercommunication collection tank (32).

2. The aluminothermic magnesium smelting device according to claim 1, wherein the vacuum induction furnace (1) comprises a base (11), a furnace body (12) and an upper cover (13), the upper cover (13) is provided with a feeding port and a magnesium vapor outlet, the feeding port is connected with the feeding system (4) through a conveying pipe, a first end of the condensing pipe (31) is connected at the magnesium vapor outlet, the slag collecting system (5) is communicated with the inner cavity of the furnace body (12) through a slag discharge valve, a crucible (14) for containing magnesium raw materials, a heat insulation layer (15) wrapping the crucible (14) and an induction heating coil (16) wound on the outer wall of the heat insulation layer (15) are arranged in the furnace body (12).

3. The aluminothermic method magnesium smelting device according to claim 2, wherein the feeding system (4) comprises a material receiving hopper (41), a first-stage vacuum bin (42) and a second-stage vacuum bin (43) which are sequentially connected from top to bottom, a discharge port of the second-stage vacuum bin (43) is connected with the feed inlet through a feed delivery pipe, a first-stage vacuum valve is arranged between the material receiving hopper (41) and the first-stage vacuum bin (42), a second-stage vacuum valve is arranged between the first-stage vacuum bin (42) and the second-stage vacuum bin (43), and a third-stage vacuum valve is arranged between a discharge port of the second-stage vacuum bin (43) and the feed inlet.

4. A device for producing magnesium by aluminothermic process according to claim 3, wherein said slag collecting system (5) comprises a slag storage chamber (51) disposed below said base (11), said crucible (14) comprises a bottom plate and a cylinder which are detachably connected, said slag discharging valve comprises a pull rod and said bottom plate, one end of said pull rod is connected to the bottom of said bottom plate, and the other end of said pull rod extends out of said furnace body (12).

5. The aluminothermic magnesium smelting device according to claim 4, wherein the slag collecting system (5) further comprises a slag bin (52), a slag storage tank (54) and a chain plate slag conveyor (53), the slag bin (52) is arranged below the slag storage chamber (51) and is connected with the slag storage chamber (51) through a first vacuum valve, and the chain plate slag conveyor (53) for conveying waste slag into the slag storage tank (54) is arranged below a discharge hole at the bottom of the slag bin (52).

6. An aluminothermic magnesium smelting apparatus according to any one of claims 1 to 5, wherein the condensing pipe (31) comprises a plurality of condensing portions having different condensing temperatures, each condensing portion is wound with an electric heating wire (33) for controlling the temperature inside the pipe, the condensing portions are connected in sequence according to the condensing temperatures, the condensing portion with the highest condensing temperature is connected to the vacuum induction furnace (1), and the condensing portion with the lowest condensing temperature is connected to the collecting tank (32).

7. An aluminothermic magnesium smelting device according to claim 6, wherein the condensing and collecting system (3) further comprises a collecting pipe (34), the pipe diameter of the collecting pipe (34) gradually increases from a first end to a second end, the first end of the collecting pipe (34) is connected with the second end of the condensing pipe (31), a vertically downward collecting port is formed in the side surface of the second end of the collecting pipe (34), and the collecting port is communicated with the collecting tank (32) through a conduit.

8. The aluminothermic magnesium smelting device according to claim 7, wherein a vertical upward gas outlet is further formed in the side face of the second end of the collecting pipe (34), a three-way pipe is connected to the gas outlet, the other two outlets of the three-way pipe are respectively connected with a cyclone separating pipe (6) and a dust separator, a collecting pipe (7) is arranged below the cyclone separating pipe (6), the diameter of the cyclone separating pipe (6) is gradually reduced from top to bottom, the diameter of the collecting pipe (7) is gradually increased from top to bottom, an upper pipe opening of the collecting pipe (7) is communicated with a lower pipe opening of the cyclone separating pipe (6), a baffle plate used for shielding the communication position of the cyclone separating pipe (6) and the collecting pipe (7) is arranged between the cyclone separating pipe (6) and the collecting pipe (7), and a dust receiving hopper is arranged at a dust outlet of the dust separator.

9. An apparatus for producing magnesium by aluminothermic process according to claim 8, wherein said vacuum extractor (2) is connected to an outlet of said dust separator.