WO2016082726A1 - Electrolysis furnace - Google Patents

Abstract

An electrolysis furnace, relating to the technical field of rare-earth metallurgical devices and applications. The electrolysis furnace comprises: an adjusting member (3), a sealing cover (4), a cathode (8), an anode (9), and an impermeable insulating member (20). The cathode (8) and the anode (9) are in vertical arrangement in parallel. The anode (9) is movable to adjust the distance between the cathode and the anode. The present invention has the following advantages: the reaction gas readily escapes and collects, the product is easily collected, residue generated by the reaction is easy to clean, a product removal member is easy to install, and the product is easily taken out; the cathode has a long service life; multiple sets of cathode and anode groups can be simultaneously disposed in the same electrolysis furnace to facilitate large-scale and automated manufacturing; the invention saves energy, enabling clean manufacturing; a cooling device reduces the cathode temperature, enhancing electrolyte liquid leakage prevention, mitigating cathode oxidation loss, and reducing cathode resistance.

Description

Electrolytic furnace Technical field

The present invention relates to an electrolytic furnace for producing rare earth metals and alloys thereof, and an electrolytic furnace group and a method of using the same. It belongs to the field of rare earth metallurgical equipment and application technology.

Background technique

In the production of rare earth metals and their alloys, electrolysis is a common production method. The electrolysis temperature for the production of rare earth metals and their alloys is usually above about 900 °C.

The publication date is February 13, 2013, and the Chinese Patent Application No. CN102925931A, which is named as a side-plugging submerged cathode rare earth molten salt electrolysis cell, discloses "including: trough shell (10), side plug cathode (1) , cathode conductive row (2), insulating side wall (3), side fireplace lining (4), insulating ring (5), metal baffle (6), 坩埚 (7), furnace bottom (8), anode (9 The cathode (1) is connected at one end to the cathode conductive row (2) and buried in the side fireplace lining, the insulating side wall (3), and inserted into the electrolytic cell furnace from the lower position of the side fireplace lining (4). The side-inserted cathode (1) is located below the anode (9) with a certain angle with respect to the horizontal parallel position of the anode (9). When the electrolytic cell of the technical solution is used for a long time, since the anode working surface is the anode bottom surface, the gas generated by the electrolytic reaction is not easily escaped, and the anode effect is likely to cause the electrolytic efficiency to decrease and the effective electrolytic area to decrease; the electrolytically generated product is horizontal or The side-inserted cathode with a certain slope slowly flows into the crucible, so that the product stays in the reaction zone for a long time to increase the secondary reaction; the upper surface of the cathode is easy to deposit unelectrolyzed materials, resulting in a decrease in effective electrolytic area, a decrease in current efficiency, and an increase in power consumption. .

The utility model is a power saving method for the rare earth molten salt electrolysis. The Chinese patent application published as CN1690252A on November 2, 2005 discloses that "the plurality of electrolytic cells are combined in series and then used. A set of rectifying power supply equipment supplies power to a plurality of electrolyzers at the same time... Using an electrolyzer with an air-cooling device, the cooling device of the electrolyzer is turned on when the temperature of an electrolyzer is too high" The technical problem that the temperature of one of the electrolytic cells is too high when the same electrolytic current is produced later. This technical solution has the potential to transfer part of the energy to an environment that is not strongly related to the product, which wastes energy and pollutes the environment, and it is difficult to timely and accurately control the temperature of the electrolytic cell.

Summary of the invention

In view of the above defects existing in the prior art electrolytic cell, the present invention provides an electrolytic furnace which adopts the following technical solutions:

An electrolytic furnace comprising a feeding pipe 1, an adjusting member 3, a sealing cover 4, a furnace 5, a furnace wall 6, a casing 7, a cathode 8, an anode 9, a crucible 10, an insulating layer 16, and an anti-seepage insulating member 20, from the outside to the outside The inside is the outer casing 7, the heat insulating layer 16, the furnace wall 6, the furnace 5, and the cavity in the furnace wall 6 forms a top open furnace 5, and the upper part of the furnace 5 is provided with a sealing cover 4 to cover the opening of the furnace 5. on. A cathode 8, an anode 9, and a crucible 10 are disposed in the furnace 5. The cathode 8 is vertically disposed through the outer casing 7, the heat insulating layer 16 and the furnace wall 6, and the portion of the furnace wall 6 outside the outer casing 7 is the terminal 81; the terminal 81 and the furnace wall 6, the heat insulating layer 16 and the outer casing There is a barrier insulating member 20 between 7. The anode 9 is suspended from the side of the cathode 8. The adjusting member 3 is located above the sealing cover 4 to control the movement of the anode 9; the movement of the anode 9 is moving back and forth, moving up and down, moving left and right, and/or rotating, the rotation including deflection about a horizontal line and/or a vertical line and Swing back and forth. That is, the anode 9 can reciprocate in at least one dimension. The crucible 10 is placed under the cathode 8 at the bottom of the furnace 5, and the feed tube 1 is in communication with the furnace 5 through the sealing cover 4. Preferably, the adjusting member 3 is fixed to the sealing cover 4. Preferably, the barrier insulating member 20 is provided in each of the furnace wall 5 and the heat insulating layer 16.

One of the preferred embodiments of the present invention is that the cathode 8 is embedded in the furnace wall 6 on the opposite side of the terminal 81 at one end of the furnace, and the barrier insulating member 20 is disposed between the cathode 8 and the furnace wall 6.

According to still another preferred embodiment of the present invention, the cathode 8 has an anode 9 on both sides thereof.

Still another preferred embodiment of the present invention is that the cathode 8 is arranged to intersect the anode 9.

According to still another preferred embodiment of the present invention, the cathode 8 extends into the furnace 5 from both sides of the furnace wall 6, respectively. That is, the two terminals 81 of the cathode 8 extend from the inside of the furnace 5 through the furnace wall 6, the heat insulating layer 16, and the outer casing 7 from opposite sides.

According to still another preferred embodiment of the present invention, the two opposing cathodes 8 are connected in a furnace.

According to still another preferred embodiment of the present invention, the cathode 8 traverses the furnace wall 6 and the outer casing 7 on both sides, and the two terminals 81 of the cathode 8 are respectively located outside the outer casing 7 on both sides.

According to still another preferred embodiment of the present invention, the upper edge of the crucible 10 is horizontally arranged, and the bottom of the crucible 10 is inclined from one end to the other end.

According to still another preferred technical solution of the present invention, the width of the lower end of the bottom of the crucible 10 is greater than the width of the other end.

Still another preferred embodiment of the present invention further includes the passage 11 connecting the two or more turns 10.

According to still another preferred embodiment of the present invention, the terminal 81 of the cathode 8 is further provided with a cooling device 12.

According to still another preferred embodiment of the present invention, the cooling device 12 is located at a corresponding position of the cathode terminal 81 and/or the cooling barrier insulating layer 20 for cooling the cathode terminal 81 and/or the cooling barrier insulating layer 20.

According to still another preferred embodiment of the present invention, the cooling device 12 is an external cooler and/or an internal cooler, and the external cooler is disposed on an outer surface of the terminal 81, and the internal cooler is disposed in the terminal 81.

According to still another preferred embodiment of the present invention, the cooling device 12 is a cooling cathode terminal 81 and/or a cooling barrier insulating layer 20.

According to still another preferred embodiment of the present invention, the anode 9 is parallel to the cathode 8.

The method for using the rare earth electrolytic furnace of the present invention: controlling the left and right movements of the anode 9 by the adjusting member 3 to change the distance between the anode and the cathode to achieve the purpose of adjusting the corresponding electrolytic voltage, furnace temperature and the like.

One of the preferred technical solutions for the use of the rare earth electrolytic furnace of the present invention is to adjust the corresponding process parameters by adjusting the component 3 to control the elevation and/or movement of the anode 9 and the rotation to change the effective conductive area of the anode 9 and the current density.

Another method of using the rare earth electrolytic furnace of the present invention is a method of using a rare earth electrolytic furnace, characterized in that the adjustment member 3 controls the anode 9 to move back and forth, move up and down, move left and right, and/or rotate to help the gas generated by the electrolysis escape.

Still another method of using the rare earth electrolytic furnace of the present invention: adjusting the process parameters by adjusting the power supply voltage and/or current.

An electrolytic furnace group consisting of a common power supply and at least two electrolytic furnaces connected in series. Each of the electrolytic furnaces includes a cathode 8 and an anode 9. The common power source 12 and each electrolytic furnace are connected to the anode of the first electrolytic furnace according to the positive pole of the common power source 12, and then the anode of each electrolytic furnace is connected to the cathode of the previous electrolytic furnace, and the last one of the electrolytic furnaces The cathode is connected to the negative electrode of the common power source 12. The circuit for supplying power to the respective electrolytic furnaces by the common power source 12 is a main circuit 41, wherein each of the electrolytic furnaces further includes an adjusting member 3 that controls the movement of the anode 9.

One of the preferred technical solutions of the electrolytic furnace group of the present invention, the cathode 8 is vertically arranged through the outer casing 7, the heat insulating layer 16 and the furnace wall 6, and the portion of the furnace wall 6 outside the outer casing 7 is the terminal 81; The anode 9 is suspended from the side of the cathode 8.

According to still another preferred embodiment of the electrolytic furnace of the present invention, the anode 9 is parallel to the cathode 8.

According to still another preferred embodiment of the electrolytic furnace of the present invention, the movement of the anode 9 is for moving back and forth, moving up and down, moving left and right, and/or rotating.

According to still another preferred embodiment of the electrolytic furnace of the present invention, the adjusting member 3 is located above the sealing cover 4.

According to still another preferred technical solution of the electrolytic furnace group of the present invention, each of the electrolytic furnaces further includes a feeding pipe 1, a sealing cover 4, a furnace 5, a furnace wall 6, an outer casing 7, a crucible 10, an insulating layer 16, and an anti-seepage insulating member 20. From the outside to the inside, the outer casing 7, the heat insulating layer 16, the furnace wall 6, and the furnace 5, the cavity in the furnace wall 6 forms a top open furnace 5, and the upper portion of the furnace 5 is provided with a sealing cover 4 over the opening of the furnace 5. A cathode 8, an anode 9, and a crucible 10 are disposed in the furnace 5. An insulating member 20 is provided between the terminal 81 and the furnace wall 6, the insulating layer 16, and the outer casing 7. The crucible 10 is placed under the cathode 8 at the bottom of the furnace 5, and the feed tube 1 is in communication with the furnace 5 through the sealing cover 4.

According to still another preferred embodiment of the electrolytic furnace of the present invention, the adjusting member 3 is fixed to the sealing cover 4.

According to still another preferred embodiment of the electrolytic furnace of the present invention, the barrier insulating member 20 is disposed in the furnace wall 5 and the heat insulating layer 16, respectively.

According to still another preferred embodiment of the electrolytic furnace of the present invention, the movement of the anode 9 includes front and rear movement, up and down movement, left and right movement, and/or rotation. That is, the anode 9 can reciprocate in at least one dimension.

According to still another preferred embodiment of the electrolytic furnace of the present invention, the rotating comprises rotating about a horizontal line and/or a vertical line. The rotation is excellent to swing back and forth.

According to still another preferred technical solution of the electrolytic furnace group of the present invention, each of the electrolytic furnaces is the same electrolytic furnace in the "Summary of the Invention" of the specification or an electrolytic furnace of the "invention" of the specification.

Still another preferred embodiment of the electrolytic furnace of the present invention further includes a switch 17 and a switch 18. Each switch 18 is located at the main power The anode 9 of each electrolytic furnace in the path 41 is between the anode 8 of the preceding electrolytic furnace or the anode 9 of the first electrolytic furnace and the positive electrode of the common power source 12. Each of the switches 17 is connected to each of the switches 18 in the main circuit 41, and the other end is connected to the next switch 18 in the main circuit 41 to form the respective control circuits 42. The switch 18 can cut off the power supply of the common power source 12 to each of the electrolytic furnaces, and at this time, the switch 17 is turned on without affecting the use of other electrolytic furnaces in the electrolytic furnace group.

A further preferred embodiment of the electrolytic furnace of the present invention further comprises a switch and a control circuit 42 for shutting off any of the electrolytic furnaces from the furnace.

According to still another preferred technical solution of the electrolytic furnace group of the present invention, at least one electrolytic furnace is further provided with an auxiliary power source 13. The anode of the auxiliary power source 13 is connected to the anode of the respective electrolytic furnace, and the anode of the auxiliary power source 13 and the cathode of the respective electrolytic furnace connection.

In the method for using the electrolytic furnace group of the present invention, the common power source 12 is used to supply power to each electrolytic furnace in the electrolytic furnace group, and the electrolysis voltage, electrolysis temperature and current density of each electrolytic furnace are adjusted by adjusting the voltage and/or current output from the common power source 12. Electrolytic process parameters.

A further method for using the electrolytic furnace group of the present invention is characterized in that a common power source is used to supply power to each electrolytic furnace, and the adjusting portion 3 of each electrolytic furnace controls the movement of the anode 9 to adjust the distance between the poles of the anode and the cathode of each electrolytic furnace and/or The effective electrolytic area adjusts the process parameters such as the electrolysis temperature of each electrolytic furnace in the electrolytic furnace group.

According to a preferred technical solution of the electrolytic furnace group of the present invention, the common power source 12 is used to supply the main power source for each electrolytic furnace, and the output voltage and/or current of the auxiliary power source 13 is adjusted to adjust the electrolysis temperature and current density of the respective electrolytic furnaces. Process parameters.

The method for using the electrolytic furnace group of the present invention is still a preferred technical solution, and the anode and cathode pole pitches are first adjusted when adjusting the process parameters of each electrolytic furnace.

Further preferred technical solution of the method for using the electrolytic furnace group of the present invention, when any one of the electrolytic furnaces needs to be suspended, the corresponding switch 17 in the main circuit 41 should be controlled to cut off the power supply to the electrolytic furnace, and the corresponding power is turned on. The control circuit 42 cuts off any of the electrolytic furnaces from the furnace group.

The electrolytic furnace of the invention has a sealed cover, the vertical and vertical poles of the anode and the cathode in the furnace are arranged in parallel, the anode and the anode pole are adjustable, the anode can be moved and rotated, and the cathode terminal is led out from the side of the furnace wall so that the cathode terminal is located outside the casing. The utility model has the structure that the cooling device and the bottom of the crucible are inclined toward one end, and the anode is moved to the left and right to adjust the pole distance to control the electrolysis voltage, and the movement can be stirred on the one hand to stir the electrolyte on the one hand, and to accelerate the gas leaving the anode on the other hand, and the anode effect can be eliminated, not only hindering the reaction. The gas escapes, and the movement of the anode also contributes to the escape of the gas and enhances the effect of the electrolyte flow. On the one hand, the reaction gas is easy to escape and is easy to collect, the product is easy to collect, and the slag generated by the reaction is easy to clean, and the product is easily taken out. And the removal of the product, as well as reducing the temperature and dust above the sealing cover, greatly reducing the corrosion and electrical resistance of the anode wire; on the other hand, it is convenient to collect and treat the electrolytic waste gas, which is beneficial to protect the environment and improve working conditions; Support base; the cathode in the furnace is completely immersed in molten salt electrolysis In the quality, the cathode life is extended. The anode and the anode are vertically arranged in the same electricity In the furnace, multiple sets of cathode and anode groups can be set at the same time; the rare earth molten salt electrolysis furnace of the invention is convenient to realize large-scale and automation, and is more energy-saving and realizes clean production; the cooling device reduces the cathode temperature, and can enhance the leakage prevention effect of the electrolyte liquid. It reduces the cathode oxidation loss and reduces the cathode resistance.

The electrolytic furnace group of the invention overcomes the need of the prior art to supply the current of the electrolytic cell requiring the maximum current in the electrolytic cell group, which will cause defects such as excessive electrolysis temperature of the electrolytic cell, waste of electric energy and the like, and has the control sensitivity and can separately respectively The electrolysis temperature of the electrolysis furnace is controlled within a suitable range in time, and the advantages of overall control or single control can be achieved. The output voltage of the shared power supply is increased, the power supply equipment and the line are reduced, the loss of the power supply equipment itself is reduced, the circuit loss is also reduced after the electrolytic furnace is connected in series, the energy utilization rate is high, and the power consumption of the product is low. By changing the pole distance, the electrolytic voltage of any electrolytic furnace can be adjusted in time, and the furnace temperature can be controlled, so that the electrolysis temperature of each electrolytic furnace is suitable and the energy utilization rate is high. After the auxiliary power supply is added, it is more convenient to control the process parameters of each electrolytic furnace. In the electrolytic furnace group, not only a single product but also a plurality of products can be simultaneously produced in the electrolytic furnace group. It is also possible to cut the electrolytic furnace of any combination in the electrolytic furnace group. The absolute value of the difference between the output voltage of the common power source 12 and the voltage of the individual electrolytic rare earth metal of each electrolytic furnace increases as the number of electrolytic furnaces operating in the electrolytic furnace group increases; the electricity consumption of the product varies with the electrolytic furnace operating in the electrolytic furnace group. The number increases and decreases. When adjusting the process power of the auxiliary power supply of the electrolytic furnace to adjust the process parameters of each electrolytic furnace, it is beneficial to reduce the electrolytic power consumption.

DRAWINGS

1 is a schematic view of Embodiments 1, 4, 5, 8, 9, and 11.

Figure 2 is a schematic view of Embodiments 2 and 13.

Figure 3 is a schematic view of Embodiments 3, 6, 7, 10, and 12.

4 is a schematic view of Embodiment 4.

Figure 5 is a schematic view of Embodiment 8.

Figure 6 is a schematic view of Embodiment 5.

Figure 7 is a schematic view of Embodiments 1, 2, 3, 9, and 13.

Figure 8 is a schematic view of Embodiments 5 and 8.

Figure 9 is a schematic view of Embodiments 6, 10, and 12.

Figure 10 is a schematic view of Embodiments 6, 10, and 12.

Figure 11 is a schematic view of Embodiments 7 and 11.

Figure 12 is a schematic view of Embodiment 9.

Figure 13 is a schematic view of Embodiments 10 and 12.

Figure 14 is a schematic view of Embodiment 11.

Figure 15 is a schematic view of Comparative Example 1.

detailed description

Example 1

See Figure 1 and Figure 7.

Electrolytic furnace, including feed pipe 1, adjusting member 3, sealing cover 4, furnace 5, furnace wall 6, outer casing 7, cathode 8, graphite anode 9, crucible 10, fixing member 11, jacket water cooler 12, insulation layer 16 and a barrier insulating member 20. The outer casing 7 has an inner insulating layer 16 and a furnace wall 6 made of graphite material. The cavity in the furnace wall 6 forms a top open furnace 5, and the top of the furnace 5 is provided with a sealing cover 4 and is covered with an insulating layer. Above 16. One cathode 8 and two graphite anodes 9 are provided in the furnace 5. The cathode 8 is made of a metal plate, one end is vertically suspended in the furnace 5, and the other end is a terminal 81. The terminal 81 passes through the furnace wall 6 and the outer casing 7 and the like to the outside of the casing 7; the terminal 81 A portion of the seal is fixed to the furnace wall 6, the heat insulating layer 16, and the outer casing 7, and the insulating member 20 is interposed between the terminal 81 and the furnace wall 6, the heat insulating layer 16, and the outer casing 7. The adjustment member 3 further includes a link 33, wherein the adjustment member 3 is located above the sealing cover 4, and the link 33 is connected through the sealing cover 4 to a graphite anode 9 suspended from both sides of the cathode 8 in parallel with the cathode 8. The length and width of the anode 9 match the electrolytic working surface of the cathode 8 in the furnace 5 (the same applies hereinafter). The adjusting member 3 controls the up and down and/or front and rear, left and right movement, and rotation of the anode 9 through the link 33. The rotations are respectively rotated about a vertical line, rotated about a longitudinal horizontal line, and rotated about a vertical line or a horizontal horizontal line. The up and down movement (including rotation) refers to the movement of the anode 9 relative to the cathode 9 as seen from the terminal 81 (the same applies hereinafter). One end of the crucible 10 is smaller in width and shallower than the other end, and is placed below the bottom cathode 8 of the furnace 5 to keep the upper edge of the crucible 10 horizontal, collecting the product dropped by the cathode 8. In order to accurately place the crucible 10, a crucible positioning groove may be provided at an appropriate position on the bottom of the furnace wall 6. The jacket water cooler 12 is mounted on the surface of the terminal 81 outside the outer casing 7.

When the metal crucible is electrolyzed, the anode 9 is connected to the positive electrode of the power source, and the terminal 81 is connected to the negative electrode of the power source outside the casing 7. The cathode 8 in the furnace 5 is immersed in the molten electrolyte substantially perpendicular to the liquid level of the electrolyte. After the power is turned on, the ruthenium compound is electrolyzed on the cathode 8 to form a liquid metal. The ruthenium is collected along the cathode 8 and collected in the crucible 10 to be automatically concentrated at the deeper and wider end of the crucible 10. During the production process, when the power output is stable, the adjustment component 3 can be used to control the anode 9 to move up and down or move back and forth to change the effective conductive area and current density of the anode 9 to adjust the corresponding process parameters, and the adjustment component 3 can also control the anode 9 to move left and right to change the yin and yang. The distance between the two poles achieves the purpose of adjusting process parameters such as electrolysis voltage, electrolysis current, and electrolysis temperature. Of course, it is also possible to adjust the voltage and/or current of the power output to adjust the process parameters such as electrolysis voltage, electrolysis current, and electrolysis temperature. When the anode 9 moves, it also exerts a certain agitation effect on the liquid electrolyte, which is favorable for the electrolyte flow and the escape of the gas; the gas is also not easily attached to the anode 9. When it is necessary to stir the electrolyte, the effect of the anode 9 swinging back and forth around the plumb line is most remarkable. When it is necessary to accelerate the escape of the gas, it is preferable to reciprocate (or vibrate) the anode up and down.

Since the anode 9 is a consumable in the production process, the thickness of the anode 9 is continuously reduced as the production progresses, so that the anode and the anode are made. The distance between them continues to increase, causing the electrolysis voltage to rise. By adjusting the component 3 to control the left and right movement of the anode 9, the distance between the anode and the cathode can be adjusted in time, or the distance between the anode and the cathode can be continuously changed according to the consumption speed of the anode 9, and the distance between the anode and the cathode is reduced, resulting in a single The block anode current is small, the local electrolysis reaction is poor, or the distance between the anode and the cathode is too close, causing an anode effect and the like, which is unfavorable to the electrolysis reaction, and ensures the stability of the electrolysis production process.

Since the anode 9 may consume more non-uniform consumption on one side of the opposite side during the consumption process, as the usage time increases, the difference between the ends of the same group of cathodes and anodes becomes larger and larger. Controlling the rotation of the anode 9 about the vertical line or about the longitudinal horizontal line can maximize the distance between the ends of the same group of anodes and anodes. That is to say, the electrolysis working faces of the yin and yang electrodes are kept parallel, the effective electrolysis area can be increased, and the high efficiency can be maintained when the electrolysis current and voltage are constant.

The cathode 8 is vertically arranged in parallel with the anode 9, which facilitates the escape of the electrolyte and the gas generated during the electrolysis reaction, and is also advantageous for reducing impurities in the metal product and preventing local electrolyte material solidification in the furnace.

If necessary, the anode 9 can be continuously moved back and forth in a horizontal or vertical direction along a plane parallel to the electrolysis working surface of the cathode 8, and the electrolyte can be continuously stirred while maintaining the distance between the cathode 8 and the anode 9 to accelerate the oxide. The rate of melting in the electrolyte maintains uniformity of the concentration of oxides in the electrolyte, and also avoids the occurrence or extinction of the "anode effect", and also accelerates the gas attached to the anode electrolysis working surface from the anode 9 and escapes. In contrast, since the height of the anode 9 is substantially the same as that of the cathode 8, the horizontal movement of the anode 9 along a plane parallel to the electrolysis working surface of the cathode 8 is more advantageous for maintaining the anode 9 and the electrolytic working surface of the cathode 8 to match, and the motion amplitude can be more vertical. The plane movement is bigger.

Since the anode 9 can stir the electrolyte to accelerate the melting rate of the oxide in the electrolyte and maintain the uniformity of the concentration of the raw material in the electrolyte, the feeding tube 1 can be inserted into the electrolyte to directly concentrate the electrolytic raw material into the electrolyte to make the electrolytic raw material. It is isolated from the hot gas such as gas produced by electrolysis, so as to avoid the loss of the electrolyzed raw material with the flow of hot air.

The distance between the anode and the cathode is adjustable, so that the production stability of the electrolytic furnace is good, the current fluctuation is small, and the output is stable. The utility model can improve the use efficiency of the power source, stabilize the electrolysis current as the rated output current of the power source, fully improve the power utilization rate, and avoid the defects of the power supply large horse-drawn car; so that more than two electrolytic furnaces can be connected in series with the same electrolysis current to save the equipment. Resources and further reduce power consumption.

After the sealing cover 4 is added, the oxidative corrosion of the graphite and the like in the anode and the tank body caused by the open structure of the prior art electrolytic furnace is severely solved, the effective utilization rate of the anode is low, the volatilization loss of the molten salt is serious, and the heat loss is large. The defects reduce the temperature outside the sealing cover 4 above the furnace and reduce the dust, which greatly reduces the corrosion and electrical resistance of the anode wire; on the other hand, it is convenient to collect and treat the electrolytic waste gas, which is beneficial to protect the environment and improve working conditions; The sealing cover 4 can also serve as a supporting base for the adjusting member 3, and functions to simplify the structure.

The provision of the barrier insulating member 20 between the terminal 81 of the cathode 8 and the furnace wall 6, the insulating layer 16 and the outer casing 7 solves the problem that the electrolyte in the furnace 5 easily leaks outside the furnace casing 7 along the outer surface of the cathode 8. The long-term stable operation of the electrolytic furnace is ensured, the service life of the electrolytic furnace is prolonged, and the use cost is reduced. The barrier insulating member 20 can be made in one piece or in the furnace. The wall 5 and the heat insulating layer 16 are provided separately or separately. When the impervious insulating member 20 is separately disposed in the furnace wall 5 and the heat insulating layer 16, different materials can be selected according to the operating temperature to improve the anti-seepage effect. It is because the barrier insulating member 20 achieves the function of preventing the electrolyte from oozing out along the cathode 8, so that the cathode 8 can implement the technical solution of taking out the terminal 81 from the side of the outer casing 7. The invention discloses that the cathode (1) is connected to the cathode conductive row (2) and buried in the side fireplace lining and the insulating sidewall (3) disclosed in the Chinese Patent Application Publication No. CN102925931A. The technical solution results in the cathode (1) and the cathode. The conductive row (2) connection is inconvenient to maintain and reduce the resistance, and the side fireplace lining, the insulating side wall (3) affect the inconvenient construction and other defects.

The cathode 8 is led out on the side of the outer casing 7, which reduces the components above the furnace and facilitates the installation of the adjustment member 3 which controls the movement of the anode 9. At the same time, the cathode 8 and its power line are avoided from the high temperature corrosion zone of the upper part of the furnace, and the cathode 8 in the furnace is completely immersed in the electrolyte, and is not in contact with the air, which is beneficial to reducing the resistance and prolonging the service life.

The jacketed water cooler 12 located on the surface of the terminal 81 outside the outer casing 7 effectively lowers the temperature of the terminal 81, thereby lowering the electrical resistance and improving the electrical conductivity. The lower cathode temperature also helps prevent electrolyte leakage along the cathode 8 outside of the furnace wall 6.

The smaller width and shallower depth of one end of the crucible 10 relative to the other end facilitates the concentration of the liquid metal product in the crucible 10 toward the deeper end, facilitating the placement of the product and the removal of the product.

KG6000A power supply is used for electrolytic metal crucible. The main technical specifications are: electrolysis temperature 1030-1100 °C, electrolysis current about 6000A, power output voltage 6.5V, metal cesium electricity consumption 5.2kW·h/(kgNd).

KG6000A power supply is used for electrolytic metal crucible. The main technical specifications are: electrolysis temperature 950-1050 °C, electrolysis current about 6000A, power output voltage 6.3V, metal cesium electricity consumption 5.2kW·h/(kgPr).

Example 2

See Figure 2 and Figure 7.

The electrolytic furnace includes a feed pipe 1, an adjusting member 3, a sealing cover 4, a furnace 5, a furnace wall 6, an outer casing 7, a cathode 8, an anode 9, a crucible 10, a water cooler 12, an insulating layer 16, and a barrier insulating member 20. . The outer casing 7 has a heat insulating layer 16 and a furnace wall 6, and the cavity in the furnace wall 6 forms a furnace 5 with an open top. A cover 4 is placed over the outer casing 7 to house the outer casing 7 therein. The furnace 5 is provided with two cathodes 8a, 8b and three anodes 9a, 9b, 9c. Each of the cathodes 8 is a metal plate, and one end of the outer wall of the furnace wall 7 to the inner wall of the furnace wall 6 is a terminal 81, and the other end is suspended from the outside of the outer casing 7 through the outer casing 7 and the heat insulating layer 16, and the furnace wall 6 is vertically suspended. The furnace 5 is sealed and fixed to the furnace wall 6, the heat insulating layer 16, and the casing 7 by the barrier insulating member 20. The respective upper ends 91a, 91b, 91c of the anodes 9a, 9b, 9c are respectively connected to the corresponding adjusting members 3a, 3b, 3c located above the sealing cover 4 through the sealing cover 4, and the adjusting members 3a, 3b, 3c are fixed in the seal The brackets (not shown) above the cover 4 respectively control the movement of the corresponding anodes 9a, 9b, 9c. Each anode 9 is parallel to each cathode 8, and one anode 9 is suspended from each side of each cathode 8, and the cathode 8 and the anode 9 are alternately arranged. Each of the adjusting members 3 can respectively control the corresponding anode 9 to move up and down and/or to move forward and backward, left and right. The crucible 10 has a trapezoidal cross section and is placed at the bottom of the furnace 5 under two cathodes 8 The upper edge of the square is kept horizontal, and the bottom corner is deeper with respect to the remaining corners. The surface of the terminal 81 of the water cooler 12 mounted outside the outer casing 7 is kept at an appropriate distance from the outer casing 7. Maintaining the water cooler 12 at an appropriate distance from the outer casing 7 may save the insulating material disposed between the water cooler 12 and the outer casing 7 when in direct contact.

Since the anode 9b located in the middle is double-sided electrolysis, that is, double-sided consumption, the distance between the second electrolysis working surface of the anode 9b and the cathodes 8a, 8b is continuously increased, and the consumption speed of the anode 9b electrolysis working surface may be different, so that the anode 9b is The distance between the left electrolysis surface and the cathode 8a is different from the distance between the right electrolysis surface of the anode 9b and the cathode 8b. The electrolysis speed of the electrolysis section of each electrode is not uniform, and the difference in the concentration of the electrolysis raw materials in different electrolysis zones is increased. The electrolytic raw material in the electrolysis section where the concentration of the electrolytic raw material is too high is not completely electrolyzed and will sink to the bottom of the furnace, and the electrolysis zone where the concentration of the electrolytic raw material is too low may have an anode effect due to the lack of electrolytic raw materials. At this time, the movement of the anode 9b can be controlled by the adjusting member 3b so that the distance between the left and right electrolysis faces of the anode 9b and the cathodes 8a, 8b are adapted to each other. According to the change of the distance between the left and right electrolysis faces of the anode 9b and the cathodes 8a, 8b, the spacing between the electrolysis surface of the anode 9a and the anode 9c and the cathodes 8a, 8b can be adjusted correspondingly by the adjusting members 3a, 3c, respectively, to achieve uniformity in each electrolysis zone. The purpose of electrolysis.

When the metal crucible is electrolyzed, the top end of the anode 9 is connected to the positive electrode of the power source through a wire, and the two terminals 81 are connected in parallel with the outer casing 7 and connected to the negative electrode of the power source. Raw materials such as bismuth compounds enter the furnace 5 from the feed pipe 1, and the molten electrolyte completely immerses the cathode 8 in the furnace 5. After the power is turned on, the ruthenium compound is electrolyzed on the cathode 8 to form a metal ruthenium liquid which flows along the cathode 8 toward the crucible 10 and is collected in the crucible 10 and automatically concentrated toward the deeper end. When it is necessary to adjust the process parameters such as the voltage, current, and current density of the electrolytic furnace, the process parameters such as the effective electrolysis area and current density of the anode 9 can be changed by the adjustment member 3 to control the elevation and movement of the anode 9 or the back and forth movement, and the anode can also be controlled by the adjusting member 3. The left and right movement changes the distance between the yin and yang poles to achieve the purpose of adjusting the process parameters.

The cross section of the crucible 10 is trapezoidal to reduce the material used to make the crucible 10, save resources and prevent the deformation of the crucible 10, and is also advantageous for the furnace.

The main electrolysis process technical indicators: electrolysis temperature 950-1000 ° C, electrolysis current of about 8000 A, power supply output voltage of 6.6 V, metal 镧 electricity consumption of 5.5 kW·h / (kgLa).

Example 3

See Figure 3 and Figure 7.

The electrolytic furnace comprises a feed pipe 1, an adjusting member 3, a sealing cover 4, a furnace 5, a furnace wall 6, an outer casing 7, a cathode 8, an anode 9, a crucible 10, a passage 11, a jacket water cooler 12, an insulation layer 16 and Impervious insulation member 20. The outer casing 7 has a heat insulating layer 16 and a furnace wall 6 in this order. The cavity in the furnace wall 6 forms a top open furnace 5, and the top of the furnace 5 is provided with a sealing cover 4 over the thermal insulation layer 16. The furnace 5 is provided with two cathodes 8 and four anodes 9. One end of each cathode 8 passes through the outer casing 7 and the heat insulating layer 16 from the outside of the outer casing 7, and the furnace wall 6 is vertically suspended in the furnace 5, and the other end of the outer casing 7 is connected. The wire end 81 is connected to the negative electrode of the power source outside the furnace; each cathode 8 is sealed and fixed to the outer casing 7 and the heat insulating layer 16, the furnace wall 6, and the cathode 8 is impervious to the furnace wall 6, the heat insulating layer 16 and the outer casing 7. Insulating member 20. The adjustment member 3 further includes a link 33, wherein the adjustment member 3 is located above the sealing cover 4, and the link 33 is connected to each graphite anode 9 through the sealing cover 4. The adjusting member 3 has a rectangular shape through the anode 9, and is engaged with the lower end of the connecting rod 33, and an anode 9 is suspended in parallel on both sides of each of the cathodes 8. The adjusting member 3 controls the anode 9 to move up and down and/or move back and forth, left and right, and the adjusting member 3 can also control the rotation of the anode 9 about a horizontal line and/or a vertical line. A crucible 10 is disposed at the bottom of the furnace 5 below each cathode 8, and a passage 11 connecting the crucibles 10 is disposed between the two crucibles 10. The jacket water cooler 12 is mounted on the surface of the terminal 81 outside the outer casing 7.

In the case of electrolytic niobium alloy, the graphite anode 9 is connected to the positive electrode of the power source, and the terminal 81 is connected to the negative electrode of the power source. The cathode 8 in the furnace 5 is immersed in a material such as molten salt. After the power is turned on, the rare earth compound is electrolyzed on the cathode 8 to form a mixed metal liquid which is collected in the crucible 10 along the cathode 8. When it is necessary to adjust the process parameters such as the voltage and current density of the electrolytic furnace, the adjustment component 3 can be used to control the elevation and/or movement of the anode 9 and to change the effective conductive area and current density of the anode 9 to adjust the corresponding process parameters, or to adjust the components. 3 Control the left and right movement of the anode 9 to change the distance between the yin and yang poles to achieve the purpose of adjusting the corresponding process parameters.

The cathode 8 is arranged in parallel with the anode 9 to facilitate the escape of the reaction gas. An anode 9 is suspended in parallel on each side of each cathode 8, and any of the anodes 9 can be individually adjusted to facilitate smooth production control.

If necessary, the anode 9 can be controlled to continuously perform a small lift and/or back and forth movement to agitate the electrolyte to make the electrolyte more uniform and/or to accelerate the escape of gas.

After the channel 11 is provided, the tantalum alloy electrolyzed from the two cathodes 8 respectively enters the same crucible 10, and the product can be taken out from only one crucible 10, thereby overcoming the defect that multiple furnaces are required to be taken out from each crucible 10 respectively. At the same time, the consistency of the product is improved.

In this embodiment, a plurality of sets of anode and cathode can be arranged to realize large-scale, and the use of the Chinese patent ZL201320875408.4 can facilitate automation, and is more energy-saving and realizes clean production.

The HISFB-10000A high-frequency switching power supply is used for electrolytic niobium alloy. The main technical specifications are: electrolysis temperature 1000-1080°C, electrolysis current about 10000A, power output voltage 6.4V, niobium alloy electric unit consumption 5.1kW·h/(kgPrNd ).

Example 4

See Figure 1 and Figure 4.

The electrolytic furnace includes a feed pipe 1, an adjusting member 3, a sealing cover 4, a furnace 5, a furnace wall 6, a casing 7, a cathode 8, an anode 9, a crucible 10, an insulating layer 16, and a barrier insulating member 20. The outer casing 7 has a furnace wall 6 in which a cavity in the furnace wall 6 forms a top open furnace 5, and a sealing cover 4 is provided on the top of the furnace 5. Two furnaces 8 and two anodes 9 are provided in the furnace 5. The two cathodes 8 are respectively opposed from the two sides of the outer casing 7 through the outer casing 7 and the heat insulating layer 16, and the furnace wall 6 has one end suspended in the furnace 5 in the same vertical plane and does not contact each other, and the outer casing 7 has another One end is a respective terminal 81; each cathode 8 is sealed and fixed to the outer casing 7 and the heat insulating layer 16 and the furnace wall 6 by a barrier insulating member 20, respectively. The anode 9 has a rectangular shape and is sized to match the size of the two cathodes 8 in the furnace 5. The connecting rod 33 of the adjusting member 3 is screwed and suspended from the cathode 8 in parallel with the cathode 8. The adjusting member 3 can control the anode 9 to move up and down and/or to move back and forth, left and right. The crucible 10 is placed at the bottom of the furnace 5 below the two cathodes 8.

With two cathodes 8 arranged in opposite planes in the same plane, a smaller cathode material that is easier to obtain can be used, reducing cathode cost.

When the metal crucible is electrolyzed, the anode 9 is connected to the positive electrode of the power source, and the terminal 81 is connected to the negative electrode of the power source respectively outside the furnace.

The HISFB-10000A high-frequency switching power supply is used for electrolytic metal crucible. The main technical specifications are: electrolysis temperature 950-1050 °C, electrolysis current about 10000A, power output voltage 6.3V, metal cesium electricity consumption 5.2kW·h/(kgPr).

Example 5

See Figure 1, Figure 6, and Figure 8.

The electrolytic furnace includes a feed pipe 1, an adjusting member 3, a seal cover 4, a furnace 5, a furnace wall 6, a casing 7, a cathode 8, an anode 9, a crucible 10, a cooler 12b, a heat insulating layer 16, and a barrier insulating member 20. The outer casing 7 has an inner insulating layer 16 and a furnace wall 6 made of graphite material. The cavity in the furnace wall 6 forms a top open furnace 5, and the top of the furnace 5 is provided with a sealing cover 4 and is covered with an insulating layer. 16 on. The furnace 5 is provided with two cathodes 8 and two anodes 9. The two cathodes 8 are plate-shaped, and are respectively fixedly connected from the two sides of the outer casing 7 through the outer casing 7 and the heat insulating layer 16 and the furnace wall 6 in the same vertical plane, and the other ends outside the furnace wall 6 become their respective The terminal 81 is sealed and fixed to the outer casing 7 and the heat insulating layer 16 and the furnace wall 6. The anti-seepage insulating member 20 is disposed between the cathode 8 and the outer casing 7 and the heat insulating layer 16 and the furnace wall 6. The anode 9 has a rectangular shape and is sized to match the size of the two cathodes 8 in the furnace 5. The upper end is bolted to the lower end of the connecting rod 33 located above the sealing cover 4 and passing through the adjusting member 3 of the sealing cover 4, and The cathodes 8 are suspended in parallel on both sides of the cathode 8. The adjusting member 3 can control the anode 9 to move up and down and/or to move back and forth, left and right. The crucible 10 is placed at the bottom of the furnace 5 below the cathode 8. Inside the terminal 81 of the cathode 8, there is an inner hole 12a for cooling the terminal 81 of the cathode 8 and a portion of the cathode 8 and the barrier insulating member 20 located in the outer casing 7 and the heat insulating layer 16, the furnace wall 6. The cooler 12b is provided with a coolant inlet and outlet (not shown) wrapped around the outer side of the barrier insulating member 20 against the furnace wall 6. The cooler 12b can also be kept at an appropriate distance from the furnace wall 6.

The use of two cathodes 8 fixedly connected to each other in the same vertical plane is advantageous for enhancing the stability of the cathode 8. It is also possible to use shorter cathode materials that are easier to obtain.

Opening the inner hole 12a at the terminal 81 of the cathode 8 can improve the terminal 81 located in the furnace wall 6 and the heat insulating layer 16 and The cooling effect of a part of the cathode 8 or the like in the vicinity thereof reduces the electric resistance. At the same time, since the temperature of the terminal 81 in the furnace wall 6 and the heat insulating layer 16 is lowered, it is advantageous for the liquid such as electrolyte which may ooze out along the cathode 8 to solidify, and the liquid such as molten salt is prevented from seeping outside the casing.

The cooler 12b is wrapped around the outer side of the barrier insulating member 20 to adhere to the furnace wall 6, which can effectively cool the impervious insulating member 20 and the furnace wall 6, and further enhance the effect of preventing liquid leakage such as electrolyte.

The HISFB-10000A high-frequency switching power supply is used for the electrolysis of the metal crucible, and the anode 9 is connected to the positive electrode of the power supply. The two terminals 81 may be respectively connected to the negative pole of the power source, or only one terminal 81 may be connected to the negative pole of the power source. When the two terminals 81 are respectively connected to the negative pole of the power source, the current of the terminal 81 and the wires can be reduced.

The main process technical indicators: electrolysis temperature 1030-1100 ° C, electrolysis current about 10000A, power output voltage 6.4V, metal cesium electricity consumption 5.1kW · h / (kgNd).

Example 6

See Figure 3, Figure 9, and Figure 10.

The electrolytic furnace comprises a feeding pipe 1, an adjusting member 3, a sealing cover 4, a furnace 5, a furnace wall 6, a casing 7, a cathode 8, an anode 9, a crucible 10, a jacket water cooler 12, a drainage plate 15, and an insulating layer 16. And a barrier insulating member 20. The outer casing 7 has a heat insulating layer 16 and a furnace wall 6 in this order. The cavity in the furnace wall 6 forms a top open furnace 5, and the top of the furnace 5 is provided with a sealing cover 4 to cover the heat insulating layer 16. Three cathodes 8 and six anodes 9 are provided in the furnace 5. Each of the cathodes 8 is made of a metal plate, one end of which is disposed from outside the outer casing 7 through the outer casing 7, the heat insulating layer 16 and the furnace wall 6 are vertically disposed in the furnace 5 to reach the opposite side wall 6 and have an anti-seepage insulating member. 20 isolating each cathode 8 from the furnace wall 6; the other end outside the outer casing 7 is a terminal 81; each terminal 81 is sealingly fixed to the outer casing 7, the heat insulating layer 16 and the furnace wall 6, and each terminal 81 and the outer casing 7 An insulating member 20 is provided between the insulating layer 16 and the furnace wall 6. The drainage plate 15 is made of a metal material, a total of six pieces, which are respectively located under the respective anti-seepage insulating members 20 and the cathode 8 in the furnace 5, and the furnace wall 6 under the anti-seepage insulating member 20 is inclined toward the crucible 10, and ends at the crucible 10 10 above the inner wall. The anode 9 is spliced in a rectangular shape by a plurality of pieces of graphite, and is detachably connected to the link 33 of the adjusting member 3, and an anode 9 is suspended in parallel on both sides of each of the cathodes 8. The adjusting member 3 can control the anode 9 to move up and down and/or to move back and forth, left and right. A crucible 10 is provided at each bottom of the furnace 5 below each cathode 8. The jacket water cooler 12a is mounted on the surface of the terminal 81 outside the outer casing 7. A copper tube 12b is further disposed in the terminal 81 of the cathode 8 for cooling the terminal 81 of the cathode 8 and a portion of the cathode 8 located at the furnace wall 6, the insulating layer 16, and the barrier insulating member 20.

The end of the cathode 8 fixed in the furnace wall at one end of the furnace 81 improves the influence of its own gravity on the cathode 8, and reduces the possibility of the cathode 8 being deformed by its own gravity during operation.

The drain plate 15 can introduce the rare earth metal falling on the cathode 8 near the furnace wall 6 into the crucible 10 to prevent the rare earth metal and the cathode 8 generated by the cathode 8 between the furnace wall 6 and the furnace wall 6 from being installed, The deformation caused during use causes the rare earth metal product to flow along the deformed cathode 8 to the outside of the crucible 10, thereby directly forming the graphite material with the furnace wall 6 The defect that the carbon content of the rare earth metal product increases after contact, resulting in a decrease in product quality. The carbon content of a rare earth metal or alloy product that typically falls outside the crucible 10 can be increased from about 0.02 wt% to about 0.1 wt%, which can seriously affect product quality.

The HISFB-15000A high-frequency switching power supply is used for the electrolytic niobium alloy, and the anodes 9 are respectively connected to the positive electrode of the power source. Each cathode 8 is connected to a negative electrode of a power source. The main technical indicators: electrolysis temperature 1000-1080 ° C, electrolysis current about 15000A, power output voltage 6.2V, niobium alloy electric unit consumption 5kW · h / (kgPrNd).

Example 7

See Figure 3 and Figure 11.

The electrolytic furnace comprises a feeding pipe 1, an adjusting member 3, a sealing cover 4, a furnace 5, a furnace wall 6, a casing 7, a cathode 8, an anode 9, a crucible 10, a jacket water cooler 12, a drainage plate 15, and an insulating layer 16. And a barrier insulating member 20. The outer casing 7 has a furnace wall 6 in which a cavity in the furnace wall 6 forms a top open furnace 5, and a sealing cover 4 is provided on the top of the furnace 5. Three cathodes 8 and six anodes 9 are provided in the furnace 5. Each of the cathodes 8 is respectively formed by stacking a plurality of rectangular metal rods, and the two ends are respectively welded and integrated, and the two ends are vertically arranged through the outer casing 7 and the furnace wall 6 respectively; The terminal 81 is connected to the negative pole of the power source; each cathode 8 is sealed and fixed in the furnace wall 6, and an anti-seepage insulating member 20 is disposed between both ends of each cathode 8 and the furnace wall 6 and the casing 7. The drainage plate 15 is made of a metal material, a total of six pieces, which are respectively located under the respective anti-seepage insulating members 20 and the cathode 8 in the furnace 5, and are inclined from the anti-seepage insulating member 20 toward the crucible 10 and stop above the inner wall of the crucible 10. The anode 9 has a rectangular shape, and the upper end is connected to the adjusting member 3, and an anode 9 is suspended in parallel on both sides of each cathode 8. The anode 9 is connected to the positive electrode of the power source through a wire. The adjusting member 3 can control the anode 9 to move up and down and/or to move back and forth, left and right. A crucible 10 is provided at each bottom of the furnace 5 below each cathode 8. The jacket water cooler 12 is mounted on the surface of the terminal 81 outside the outer casing 7.

The rectangular rod-shaped metal is easy to obtain, has high strength, is convenient to manufacture and install, and is reliable to use.

The HISFB-15000A high-frequency switching power supply is used for electrolytic niobium alloy. The main technical specifications are: electrolysis temperature 1000-1080°C, electrolysis current about 15000A, power output voltage 6.1V, niobium alloy electric unit consumption 4.9kW·h/(kgPrNd ).

Example 8

See Figure 1, Figure 5, Figure 8.

The electrolytic furnace includes a feed pipe 1, an adjusting member 3, a seal cover 4, a furnace 5, a furnace wall 6, a casing 7, a cathode 8, an anode 9, a crucible 10, a cooler 12b, a heat insulating layer 16, and a barrier insulating member 20. The outer casing 7 has an inner insulating layer 16 and a furnace wall 6 made of graphite material. The cavity in the furnace wall 6 forms a top open furnace 5, and the top of the furnace 5 is provided with a sealing cover 4 and is covered with an insulating layer. 16 on. One cathode 8 and two anodes 9 are provided in the furnace 5. The cathode 8 has a plate shape, and the two ends respectively pass through the outer casing 7 and the heat insulating layer 16, and the furnace wall 6 becomes two terminals 81 outside the outer casing 7; the two terminals 81 respectively The outer casing 7 and the heat insulating layer 16 and the furnace wall 6 are sealed and fixed on both sides, and the impervious insulating member 20 is disposed between the cathode 8 and the outer casing 7 and the heat insulating layer 16 and the furnace wall 6. The anode 9 has a rectangular shape matching the size of the cathode 8 in the furnace 5, and is bolted to the connecting rod 33 of the adjusting member 3 located above the sealing cover 4 through the sealing cover 4, in parallel with the cathode 8. Suspended from both sides of the cathode 8. The adjusting member 3 can control the anode 9 to be lifted and lowered and/or moved forward and backward, left and right, and rotated by the link 33. The rotation includes rotation about a horizontal line and/or a vertical line. The crucible 10 is placed at the bottom of the furnace 5 below the cathode 8. Inside the terminal 81 of the cathode 8, there is an inner hole 12a for cooling the terminal 81 of the cathode 8 and the outer casing 7 and the barrier insulating member 20.

The entire cathode 8 passes through and is fixed in the outer casing 7 and the heat insulating layer 16 and the furnace wall 6. The cathode 8 has good strength and is excellent in its own gravity.

Opening the inner hole 12a at one end of the terminal 81 of the cathode 8 can improve the cooling effect on the terminal 81 located in the furnace wall 6 and a portion of the cathode 8 and the like in the vicinity thereof, and reduce the electric resistance. At the same time, since the temperature of the terminal 81 in the furnace wall 6 is lowered, it is advantageous for the liquid such as electrolyte which may ooze out along the cathode 8 to solidify, and the liquid such as molten salt is prevented from seeping outside the casing.

The cooler 12b is wrapped around the outer side of the barrier insulating member 20 to adhere to the furnace wall 6, which can effectively cool the impervious insulating member 20 and the furnace wall 6, and further enhance the effect of preventing liquid leakage such as electrolyte.

The HISFB-10000A high-frequency switching power supply is used for the electrolysis of the metal crucible, and the anode 9 is connected to the positive electrode of the power supply. The two terminals 81 may be respectively connected to the negative pole of the power source, or only one terminal 81 may be connected to the negative pole of the power source. When the two terminals 81 are respectively connected to the negative pole of the power source, the current of the terminal 81 and the wires can be reduced. The main technical indicators: electrolysis temperature 1030-1100 ° C, electrolysis current about 10000A, power output voltage 6.4V, metal cesium electricity consumption 5.1kW · h / (kgPrNd).

Comparative example 1

See Figure 15

The existing 5KA rare earth molten salt electrolysis furnace comprises a furnace cover 30, a cathode 31, an anode conductive plate 32, a corundum gasket 33, a heat insulating layer 34, a furnace wall 35, an anode 36, a furnace shell 37 and a molybdenum crucible 38. The furnace shell 37 is made of steel plate welded, and is made of a heat insulating layer 34 made of materials such as heat insulating cotton and heat insulating brick, and a graphite crucible and a filling material are used to form a graphite tank wall 35. The cavity in the furnace wall 35 forms a furnace 39. The graphite tank furnace 39 is provided with a molybdenum crucible 38, four anodes 36 and one cathode 31. The cathode 31 is vertically suspended in the furnace 39 and above the molybdenum crucible 38. The anode 36 is suspended in the furnace 39 around the cathode 31. The cathode 31 is connected to the negative electrode of the power source. The molybdenum crucible 38 is located at the bottom of the furnace 39. The lower end of the anode conductive plate 32 is bolted to the anode 36, and the upper end is connected to the positive pole of the power source.

Using the KG6000A power supply of this comparative 5KA electrolytic furnace, the main technical specifications of electrolytic production of metal bismuth: electrolysis temperature 1030-1150 °C, electrolysis current about 5000A, tank voltage 9.5V, electricity consumption 8.8kW·h/(kgNd) .

The existing rare earth electrolytic furnace type has the following defects: the cathode hanging structure with the open mouth of the furnace, the exhaust gas collection is difficult, and the work The environment is harsh and the labor intensity is large; the scale is small, the tank voltage is high, the furnace temperature is high, the energy consumption is high, and the small space of the upper space of the furnace mouth is complicated, and it is difficult to realize automation and large-scale. In order to ensure the normal operation of the electrolytic furnace, in order to facilitate the adjustment of the process parameters, it is usually necessary to use a larger power supply than the actual needs. That is, there is room for the power supply, and the utilization and efficiency are low during normal electrolysis.

Example 9

See Figure 1, Figure 7, and Figure 12.

The electrolytic furnace group includes a common power source 12 and electrolytic furnaces I and II. Two electrolytic furnaces I and II are connected in series, and two electrolytic furnaces and a common power supply 12 are combined to form a circuit 41 (thick line in Fig. 12). That is, the anode 9 of the electrolytic furnace I is connected to the positive electrode of the common power source 12, the cathode 8 of the electrolytic furnace II is connected to the negative electrode of the common power source 12, and the cathode 8 of the electrolytic furnace I is connected to the anode 9 of the electrolytic furnace II to constitute an electrolytic furnace group.

The electrolytic furnaces I and II are the same and are the electrolytic furnace described in the first embodiment. The shared power source 12 uses a KG6000A power supply.

At the time of electrolysis, the total voltage and electrolysis current required for the electrolysis furnaces I and II are supplied from the common power source 12. When it is necessary to adjust the electrolysis current, current density, temperature and other process parameters of each electrolyzer, the adjustment parameters of each electrolysis furnace 3 can be used to control the corresponding anode 9 to rise or fall or change the effective conductive area and current density of the anode 9 to adjust the corresponding process parameters. The adjustment component 3 can also be used to control the left and right movement of the anode 9 to change the distance between the anode and the cathode to achieve the purpose of adjusting the corresponding process parameters.

In the electrolysis, the electrolytic furnace I produces metal crucibles, and the electrolytic furnace II produces metal crucibles. The main technical indicators are as follows:

Electrolyzer I: The electrolysis temperature is 1030-1100 ° C, the electrolysis current is about 6000 A, and the metal cesium electricity consumption is 4.8 kW·h/(kg Nd).

Electrolyzer II: The electrolysis temperature is 1000-1050 ° C, the electrolysis current is about 6000 A, and the metal cesium electricity consumption is 4.7 kW·h/(kgPr).

The common power supply 12 has an output voltage of 12.7V and an output current of 6000A.

The output voltage of the shared power supply 12 is increased to help reduce the loss of electrical energy.

After replacing the production type or model/specification, it is also possible to adjust the process parameters of each electrolytic furnace in the electrolytic furnace group by adjusting only the distance between the anode and the cathode.

Example 10

See Figure 3, Figure 9, Figure 10, Figure 13.

Electrolytic furnace group, including one shared power supply 12, 4 electrolytic furnaces (A, N, P, Z), 2 auxiliary power supplies (13N, 13P) and 8 switches (17A, 18A, 17N, 18N, 17P, 18P) , 17Z and 18Z). The four electrolytic furnaces were all the electrolytic furnaces described in Example 6. The shared power source 12 is a HISFB-15000A high frequency switching power supply.

The anode 9A of the electrolytic furnace A is connected to the positive electrode of the common power source 12, the anode 18A and the common power source 12 are connected with a switch 18A, the cathode 8A of the electrolytic furnace A is connected to the anode 9N of the electrolytic furnace N, and between the cathode 8A and the anode 9N. There is a switch 18N, the cathode 8N of the electrolytic furnace N is connected to the anode 9P of the electrolytic furnace P, and the switch 18P is connected between the cathode 8N and the anode 9P, and the electrolytic furnace P The cathode 8P is connected to the anode 9Z of the electrolytic furnace Z, and the switch 18Z is connected between the cathode 8P and the anode 9Z. The cathode 8Z of the electrolytic furnace Z is connected to the negative electrode of the common power source 12 to constitute the main circuit 41 of the electrolytic furnace group.

The electrolytic furnace N is also provided with an auxiliary power source 13N, and the electrolytic furnace P is also provided with an auxiliary power source 13P.

The anode of the auxiliary power source 13N is connected to the anode 9N, and the cathode is connected to the cathode 8N. The positive electrode of the auxiliary power source 13P is connected to the anode 9P, and the negative electrode is connected to the cathode 8P.

The switch 17A is connected in parallel with the wire composition control circuit 42A at both ends of the electrolytic furnace A in the main circuit 41, and the control circuit 42A in combination with the switch 18A can cut off the electrolytic furnace A. The switch 17N is connected in parallel with the wire composition control circuit 42N at both ends of the electrolytic furnace N in the main circuit 41, and the control circuit 42N and the switch 18N are combined to cut the electrolytic furnace N. The switch 17P is connected in parallel with the wire composition control circuit 42P at both ends of the electrolytic furnace P in the main circuit 41, and the control circuit 42P and the switch 18P are combined to cut the electrolytic furnace P. The switch 17Z is connected in parallel with the wire composition control circuit 42Z in the circuit of the electrolytic furnace Z, and the control circuit 42Z and the switch 18Z are combined to cut the electrolytic furnace Z.

The above-mentioned switches 18 and the corresponding control circuits 42 act in combination, and the electrolytic furnaces A, N, P, and Z can be cut off from the electrolytic furnace group without affecting the use of the remaining electrolytic furnaces.

During electrolysis, the total voltage required for the electrolysis furnaces A, N, P, and Z is supplied from the common power source 12, and the electric current required for the electrolysis furnaces A and Z having the lowest electrolysis current in the electrolysis furnace group is supplied. When it is necessary to adjust the process parameters such as electrolysis current, current density, temperature, etc. of the remaining electrolyzers, the adjustment component 3 can be used to control the anode 9 to rise and fall or to move back and forth to change the effective conductive area and current density of the anode 9, and the corresponding process parameters can also be adjusted. The adjusting component 3 controls the left and right movement of the anode 9 to change the distance between the anode and the cathode to achieve the purpose of adjusting the corresponding process parameters. If necessary, each auxiliary power source 13 can also be controlled to adjust process parameters such as temperature, current, and current density of the electrolytic furnace of the corresponding electrolytic furnace.

In the production, the electrolytic furnaces A and Z are mainly controlled by the anodes 9A and 9Z, and the process parameters such as the electromagnet A and Z electrolysis temperatures are controlled. The electrolytic furnace N adjusts the pole pitch by the movement of the anode 9N, and is supplemented by the auxiliary power source 13N output current 100A-600A to control the process parameters such as the temperature of the electrolytic furnace. The electrolytic furnace P adjusts the pole pitch by moving the anode 9P to the left and right, and is supplemented by the auxiliary power source 13P output current 200A-500A to control the process parameters such as the temperature of the electrolytic furnace.

On the basis of the stable power supply of the shared power supply 12, the above adjustment mode is the most sensitive to adjust the pole pitch of the anode and the cathode. Therefore, the anode and cathode pole pitches should be adjusted first when adjusting the process parameters. When the optimal process parameters cannot be achieved by adjusting the pole pitch, each auxiliary power source 13 can also be controlled to adjust the process parameters such as the temperature, current, and current density of the electrolytic furnace of the corresponding electrolytic furnace.

After the electrolytic furnace A and/or N, P, and Z are cut and stopped in the electrolytic furnace group, the total voltage and/or current output from the common power supply 12 should be adjusted to adjust the corresponding process parameters. It is also possible to control the auxiliary power source 13 to adjust the process parameters such as the temperature, current, and current density of the electrolytic furnace corresponding to the electrolytic furnace.

Main electrolysis process technical indicators:

The electrolytic furnaces A, N, P, and Z all produce niobium alloy, and the common power supply 12 has an output voltage of 24.6V and a current of about 15000A. The solution temperature is 1000-1080 ° C, and the bismuth alloy electricity consumption is 4.5 kW·h/(kgPrNd).

The output voltage of the shared power source 12 is lower than the sum of the power supply output voltages of the four electrolytic furnaces A alone.

Example 11

See Figure 1, Figure 11, and Figure 14.

The electrolytic furnace group includes a common power source 12, an auxiliary power source 13, and electrolytic furnaces A, Z.

The electrolytic furnaces A and Z are the same and are the electrolytic furnaces of the seventh embodiment.

The shared power source 12 is a HISFB-15000A high frequency switching power supply.

The common power source 12 is connected in series with the electrolytic furnace A and the electrolytic furnace Z, and the electrolytic circuit formed is the main circuit 41. That is, the anode A9 of the electrolytic furnace A is connected to the positive electrode of the common power source 12, the cathode 8Z of the electrolytic furnace Z is connected to the negative electrode of the common power source 12, and the cathode 8A of the electrolytic furnace A is connected to the anode 9Z of the electrolytic furnace Z to constitute the electrolytic main circuit 41 (Fig. 14 thick and solid lines). The auxiliary power source 13 is connected to both ends of the electrolytic furnace Z in the electrolysis main circuit 41. That is, the anode of the auxiliary power source 12 is connected to the anode Z9 of the electrolytic furnace Z, and the anode is connected to the anode Z8 of the electrolytic furnace Z. That is to say, when the auxiliary power source 13 is in operation, the common power source 12 is used to supply power to the electrolytic furnace Z in parallel.

When the niobium alloy is electrolyzed, the total voltage of the electrolysis furnace group is controlled by the output voltage of the common power source 12, and the electric energy required for the electrolysis furnaces A and Z is supplied according to the current output current required by the electrolysis furnace A. In the production, the electrolysis furnaces A and Z respectively adjust the process parameters such as the electrolysis temperature of the electrolysis furnaces A and Z by the anodes 9A and 9Z, and the anodes 9A and 9Z can be controlled to change the lift or the back and forth movements by adjusting the components 3A and 3Z, respectively. The effective conductive area, current density, etc. of the anode are adjusted corresponding to the process parameters. The electrolytic furnace Z can also control the process parameters such as the electrolysis current and temperature of the electrolytic furnace Z by adjusting the pole pitch by the anode 9Z and the auxiliary power source Z13 output current 100A-600A. It is also possible to separately adjust the auxiliary power source 13Z output current 100A-600A to control the process parameters such as the electrolysis current and temperature of the electrolytic furnace Z. The working surface of each cathode 8 is substantially perpendicular to the liquid level of the electrolyte liquid, and the liquid metal crucible falls directly into the crucible 10 along the working face of the cathode 8. As each anode 9 is consumed, each of the adjustment members 3 controls the respective anodes 9 to gradually move toward the corresponding cathodes 8 to maintain a proper cathode-anode distance. Since each anode 9 may be non-uniformly consumed during consumption, each adjustment member 3 can also control the anodes 9 to move back and forth and/or up and down to adjust the effective electrolysis area; if necessary, the control of each anode 9 in the corresponding adjustment member 3 It is also possible to rotate around the horizontal line and/or the plumb line to keep the anode 9 electrolysis working surface parallel to the cathode 8 working surface as much as possible. Usually the angle of rotation of the anode 9 is within 15°, and the most common is 3-5°. All of the above movements of the anode 9 contribute to the escape of gas generated during electrolysis.

During electrolysis, the electrolytic furnaces A and Z all produce niobium alloy: the output voltage of the common power supply 12 is 12.4V, the output current is about 15000A; the auxiliary power supply Z13 outputs the current 100A-600A, the electrolysis temperature is 1030-1100°C, and the average electric consumption of the metal crucible is 4.5. kW·h/(kgPrNd).

Example 12

See Figure 3, Figure 9, Figure 10, Figure 13.

Electrolytic furnace group, including 1 common power supply 12, 6 electrolytic furnaces (A, B, N, P, Y and Z), 6 auxiliary power supplies (13A, 13B, 13N, 13P, 13Y and 13Z) and 12 switches (17A, 18A, 17B, 18B, 17N, 18N, 17P, 18P, 17Y, 18Y, 17Z and 18Z). The shared power source 12 is a HISFB-15000A high frequency switching power supply.

The anode 9A of the electrolytic furnace A is connected to the positive electrode of the common power source 12, the switch 18A is connected between the anode 9A and the common power source 12, the cathode 8A of the electrolytic furnace A is connected to the anode 9B of the electrolytic furnace B, and between the cathode 8A and the anode 9B. There is a switch 18B, the cathode 8B of the electrolytic furnace B is connected to the anode 9N of the electrolytic furnace N, a switch 18N is provided between the cathode 8B and the anode 9N, the cathode 8N of the electrolytic furnace N is connected to the anode 9P of the electrolytic furnace P, and the cathode 8N and the anode 9P are connected. There is a switch 18P, the cathode 8P of the electrolytic furnace P is connected to the anode 9Y of the electrolytic furnace Y, the switch 18Y is connected between the cathode 8P and the anode 9Y, the cathode 8Y of the electrolytic furnace Y is connected to the anode 9Z of the electrolytic furnace Z, and the cathode 8Y is There is a switch 18Z between the anodes 9Z, and the cathode 8Z of the electrolytic furnace Z is connected to the negative electrode of the common power source 12 to constitute a main circuit 41 for simultaneously supplying power to the respective electrolytic furnaces in the electrolytic furnace group.

Each of the electrolytic furnaces is provided with one auxiliary power source 13, and the positive electrodes of the auxiliary power sources 13 are connected to the anodes 9 of the respective electrolytic furnaces, and the negative electrodes of the auxiliary power sources 13 are connected to the cathodes 8 of the respective electrolytic furnaces.

The switch 17A is connected in parallel with the wire composition control circuit 42A at both ends of the electrolytic furnace A in the main circuit 42, and the control circuit 42A in combination with the switch 18A can cut off the electrolytic furnace A. The switch 17B is connected in parallel with the wire composition control circuit 42B at both ends of the electrolytic furnace B in the main circuit 42, and the control circuit 42B and the switch 18B are combined to cut the electrolytic furnace B. The switch 17N is connected in parallel with the wire composition control circuit 42N in the electric circuit of the electrolytic circuit N in the main circuit 42, and the control circuit 42N and the switch 18N are combined to cut the electrolytic furnace N. The switch 17P is connected in parallel with the wire composition control circuit 42P at both ends of the electrolytic furnace P in the main circuit 42, and the control circuit 42P and the switch 18P are combined to cut the electrolytic furnace P. The switch 17Y is connected in parallel with the wire composition control circuit 42Y at both ends of the electrolytic furnace Y in the main circuit 42, and the control circuit 42Y and the switch 18Y are combined to cut the electrolytic furnace Y. The switch 17Z is connected in parallel with the wire composition control circuit 42Z at both ends of the electrolytic furnace Z in the main circuit 42, and the control circuit 42Z and the switch 18Z are combined to cut the electrolytic furnace Z.

The electrolytic furnaces A, B, N, P, Y and Z are the same, and the electrolytic furnace A is the electrolytic furnace used in the second embodiment.

The above-mentioned switches 18 and the corresponding control circuits 42 act in combination, and any electrolytic furnace can be cut from the electrolytic furnace group without affecting the use of the remaining electrolytic furnaces.

At the time of electrolysis, the total voltage required for the electrolysis furnaces A, B, N, P, Y, and Z is supplied from the common power source 12 and the electric current required for the electrolysis furnace A having the lowest electrolysis current in the electrolysis furnace group is supplied. When it is necessary to adjust the process parameters such as electrolysis current, current density, temperature, etc. of the remaining electrolyzers, the adjustment component 3 can be used to control the anode 9 to rise and fall or to move back and forth to change the effective conductive area and current density of the anode 9, and the corresponding process parameters can also be adjusted. The adjusting component 3 controls the left and right movement of the anode 9 to change the distance between the anode and the cathode to achieve the purpose of adjusting the corresponding process parameters. If necessary, it is also possible to control each auxiliary power source 13 to adjust the corresponding electrolytic furnace Process parameters such as temperature, current, and current density of the furnace.

On the basis of the stable power supply of the shared power supply 12, when adjusting the process parameters of each electrolytic furnace, the adjustment method needs to adjust the yin and yang poles of the electrolytic furnace to be the most sensitive. Therefore, when adjusting the process parameters, the yin and yang pole pitches should be adjusted first. . When the optimal process parameters cannot be achieved by adjusting the pole pitch, each auxiliary power source 13 can also be controlled to adjust the process parameters such as the temperature, current, and current density of the electrolytic furnace of the corresponding electrolytic furnace. It is most convenient to adjust the auxiliary power supply of the electrolytic furnace to adjust the process parameters of one or a few electrolytic furnaces.

When adjusting the process parameters of each electrolytic furnace by adjusting the auxiliary power output current of the electrolytic furnace, since it is not necessary to adjust the electrolytic voltage of the electrolytic furnace, it is advantageous to reduce the electrolytic power consumption.

Under the action of the cooling water in the jacket water cooler 12 and the copper tube 12b, on the one hand, the temperature of the cathode 8 decreases, the electrical resistance decreases, and the power consumption of the product decreases; on the other hand, if the electrolyte liquid in the furnace oozes along the cathode 8, it can be timely. Solidified and oozing electrolyte.

After the electrolytic furnace A and/or B, N, P, Y, and Z are cut and cut in any of the electrolytic furnace groups, the total voltage and/or current output from the common power supply 12 can be adjusted to adjust the corresponding process parameters. It is also possible to control the auxiliary power source 13 to adjust the process parameters such as the temperature, current, and current density of the electrolytic furnace corresponding to the electrolytic furnace.

Main electrolysis process technical indicators:

The electrolytic furnaces A, B, N, P, Y and Z all produce niobium alloy. The output voltage of the common power supply 12 is 37.6V, the current is about 15000A, the electrolysis temperature is 1000-1080°C, and the electric consumption of niobium alloy is 4.4kW·h/( kgPrNd).

In the production, each electrolytic furnace mainly controls the electrolysis voltage and electrolysis temperature of each electrolytic furnace by adjusting the distance between the cathode 8 and the anode 9 by the anode 9 movement, and the auxiliary power sources A13, B13 and Z13 respectively output current 100-400A. The electrolytic furnace N is adjusted by the anode N9 to adjust the pole pitch, and is supplemented by the auxiliary power source N13 output current 400-600A to control the process temperature of the electrolytic furnace. The electrolysis furnaces P and Y are adjusted by the anode P9 to adjust the pole pitch, and the auxiliary power sources P13 and Y13 respectively output current 600-900A to control the process parameters such as the temperature of the electrolytic furnace.

When it is necessary to adjust the process parameters such as the electrolysis temperature of a single electrolytic furnace in production, the current output from the corresponding auxiliary power source 13 can be adjusted, and the influence on the remaining electrolytic furnaces in the electrolytic furnace group is smaller.

The absolute value of the difference between the output voltage of the common power source 12 and the output voltage of the power source for separately electrolyzing the rare earth metal of each electrolytic furnace increases as the number of electrolytic furnaces operating in the electrolytic furnace group increases; the electricity consumption of the product varies with the operation of the electrolytic furnace group. The number of electrolytic furnaces increases and decreases.

Example 13

See Figure 2 and Figure 7.

The electrolytic furnace includes a feed pipe 1, an adjusting member 3, a sealing cover 4, a furnace 5, a furnace wall 6, an outer casing 7, a cathode 8, an anode 9, a crucible 10, a water cooler 12, an insulating layer 16, and a barrier insulating member 20. . The outer casing 7 has an insulation layer 16 and a furnace wall 6. The cavity in the furnace wall 6 forms a furnace 5 with an open top. A cover 4 is placed over the outer casing 7 to house the outer casing 7 therein. The furnace 5 is provided with two cathodes 8a, 8b and three anodes 9a, 9b, 9c. Each of the cathodes 8 is a metal plate, and one end of the outer wall of the furnace wall 7 to the inner wall of the furnace wall 6 is a terminal 81, and the other end is suspended from the outside of the outer casing 7 through the outer casing 7 and the heat insulating layer 16, and the furnace wall 6 is vertically suspended. The furnace 5 is sealed and fixed to the furnace wall 6, the heat insulating layer 16, and the casing 7 by the barrier insulating member 20. The upper ends 91a, 91b, 91c of the anodes 9a, 9b, 9c are respectively connected to the corresponding adjusting members 3a, 3b, 3c on the sealing cover 4 through the sealing cover 4, and each adjusting member 3 controls the corresponding anode 9 respectively. motion. Each anode 9 is parallel to each cathode 8, and one anode 9 is suspended from each side of each cathode 8, and the cathode 8 and the anode 9 are alternately arranged. Each of the adjusting members 3 can respectively control the corresponding anode 9 to move up and down and/or to move forward and backward, left and right. The crucible 10 has a trapezoidal cross section and is placed under the two cathodes 8 at the bottom of the furnace 5. The upper edge is horizontal and the bottom corner is deeper relative to the remaining corners. The surface of the terminal 81 of the water cooler 12 mounted outside the outer casing 7 is kept at an appropriate distance from the outer casing 7. Maintaining the water cooler 12 at an appropriate distance from the outer casing 7 may save the insulating material disposed between the water cooler 12 and the outer casing 7 when in direct contact.

The top end of the anode 9 is connected to the positive pole of the power source through a wire, and the two terminals 81 are connected in parallel with the outer side of the outer casing 7 and connected to the negative pole of the power source. Raw materials such as bismuth compounds enter the furnace 5 from the feed pipe 1, and the molten electrolyte completely immerses the cathode 8 in the furnace 5. After the power is turned on, the ruthenium compound is electrolyzed on the cathode 8 to form a metal ruthenium liquid which flows along the cathode 8 toward the crucible 10 and is collected in the crucible 10 and automatically concentrated toward the deeper end. When it is necessary to adjust the process parameters such as the voltage, current, and current density of the electrolytic furnace, the process parameters such as the effective electrolysis area and current density of the anode 9 can be changed by the adjustment member 3 to control the elevation and movement of the anode 9 or the back and forth movement, and the anode can also be controlled by the adjusting member 3. The left and right movement changes the distance between the yin and yang poles to achieve the purpose of adjusting the process parameters.

When the metal ruthenium is electrolyzed in the chloride molten salt system using anhydrous ruthenium chloride as a raw material, the anode 9 is consumed slowly, and thus the change in the pitch between the anode and the cathode caused by the consumption of the anode 9 is small. Therefore, the anode 9 located between the two cathodes 8 can be double-sided electrolyzed to increase the efficiency of the anode 9.

Main electrolysis process technical indicators: electrolysis temperature 920-980 ° C, electrolysis current about 8000 A, power supply output voltage 10 V, metal bismuth electricity consumption unit 10.7 kW·h / (kg La).

The above are only a few preferred modes of the present invention. Those skilled in the art should understand that the embodiments of the present invention are not limited to the above, and any equivalent transformation made on the basis of the present invention should belong to the present invention. category.

Claims (10)

1. An electrolytic furnace comprising a feeding pipe (1), an adjusting member (3), a sealing cover (4), a furnace (5), a furnace wall (6), a casing (7), a cathode (8), and an anode (9) , 坩埚 (10), insulation layer (16) and anti-seepage insulation parts (20); from the outside to the inside are the outer casing (7), insulation layer (16), furnace wall (6), furnace (5), furnace wall ( The inner cavity of 6) forms a top open furnace (5). The upper part of the furnace has a sealing cover (4); the furnace (5) has a cathode (8), an anode (9) and a crucible (10), and the cathode (8) passes through the outer casing (7) and the thermal insulation layer (16). And the furnace wall (6) is vertically arranged, and the part outside the furnace wall (6) to the outer casing (7) is a terminal (81), a terminal (81) and a furnace wall (6), and an insulation layer (16) And an anti-seepage insulating member (20) between the outer casing (7); the anode (9) is suspended from the side of the cathode (8); and the upper portion of the anode (9) is connected with an adjusting member located above the sealing cover (4) ( 3) controlling the movement of the anode (9); the crucible (10) is placed under the cathode (8) at the bottom of the furnace (5); the feed tube (1) is connected to the furnace (5) through the sealing cover (4) It is characterized in that the movement of the anode (9) is forward and backward movement, up and down movement, left and right movement and/or rotation, the rotation comprising rotation about a horizontal line and/or a vertical line.
2. The electrolytic furnace according to claim 1, characterized in that the cathode (8) has anodes (9) on both sides thereof.
3. The electrolytic furnace according to claim 1, characterized in that the cathode (8) is embedded in the furnace wall (6) on the opposite side of the terminal (81) at one end of the furnace, and has an anti-seepage between the furnace wall (6) Insulating member (20).
4. A rare earth electrolytic furnace according to claim 1, wherein said cathode (8) extends into the furnace (5) from both sides of the furnace wall.
5. The electrolytic furnace according to claim 4, wherein said cathode (8) traverses the furnace wall (6) and the outer casing (7) on both sides, and the two terminals (81) of the cathode (8) are respectively located at two Outside the side casing (7).
6. The electrolytic furnace according to claim 1, characterized in that the terminal (81) of the cathode (8) is further provided with a cooling device (12).
7. The electrolytic furnace according to any one of claims 1 to 6, characterized in that the bottom of the crucible (10) is inclined from one end to the other end.
8. A method of using an electrolytic furnace according to claim 1, wherein controlling the movement of the anode (9) changes the distance between the anode and the cathode and/or the effective electrolytic area adjusts the corresponding process parameters.
9. A method of using an electrolytic furnace according to claim 1, wherein the anode (9) is controlled to move back and forth, move up and down, move left and right, and/or rotate to assist in the escape of gas generated by the electrolysis.
10. A method of using a rare earth electrolytic furnace according to claim 1, wherein the process parameters are adjusted by adjusting a power supply voltage and/or current.

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