CN113026058B - Automatic equipment for rare earth metal electrolysis - Google Patents

Abstract

The invention relates to automation equipment, in particular to automation equipment for rare earth metal electrolysis. The invention provides an automatic device for electrolyzing rare earth metals, which can automatically electrolyze rare earth metals, automatically discharge and automatically collect rare earth metals. An automated rare earth metal electrolysis apparatus comprising: the base is provided with a first support frame; the electrolytic cell is arranged on the upper side of the first support frame; the first support frame is provided with a lifting component; the lifting assembly is matched with the electrolysis assembly; the electrodes are arranged on the electrolysis assembly, and the number of the electrodes is two. The invention can realize the extraction work of the rare earth metal by arranging the lifting component which is matched with the electrolysis component; through lifting unit and cooling module cooperation, can realize that the temperature in electrolytic bath and electrode nearby reduces rapidly, prolongs the life of electrode.

Description

Automatic equipment for rare earth metal electrolysis

Technical Field

The invention relates to automation equipment, in particular to automation equipment for rare earth metal electrolysis.

Background

In the rare earth metal production process, molten salt electrolysis is a main production method of single rare earth metal, mixed rare earth metal and rare earth metal alloy, the groove structure adopted by the rare earth electrolysis is in an upper inserted cathode form, the rare earth metal is taken as an important strategic resource in China, the demand of the rare earth metal is larger and larger, the improvement of the groove structure gradually receives attention in the industry along with the enlargement of the production scale, but continuous high temperature is generated in the rare earth metal electrolysis process, so that the service life of an electrode is short, the production cost is high, and the production efficiency is low.

Patent application No.: CN105112948A discloses an automatic unloader of tombarthite electrolysis trough, including the workbin etc. motor and control system control connection, control system realizes the unloading as required of tombarthite electrolysis trough through control motor rotational speed and rotation time, realizes the material balance of tombarthite electrolysis trough operation, however this equipment does not better realize the collection of tombarthite metal.

Therefore, there is a need to develop an automatic apparatus for electrolyzing rare earth metals, automatically discharging and automatically collecting rare earth metals.

Disclosure of Invention

In order to overcome the defects of short service life, high production cost and low production efficiency of an electrode caused by continuous high temperature generated in the process of electrolyzing rare earth metal, the technical problems to be solved are as follows: provides an automatic device for electrolyzing rare earth metals, which can automatically electrolyze rare earth metals, automatically discharge and automatically collect rare earth metals.

The technical scheme of the invention is as follows: an automated rare earth metal electrolysis apparatus comprising:

the base is provided with a first support frame;

the electrolytic cell is arranged on the upper side of the first support frame;

the first support frame is provided with a lifting component;

the lifting assembly is matched with the electrolysis assembly;

the electrodes are arranged on the electrolysis assembly, and the number of the electrodes is two.

Preferably, the lifting assembly comprises:

the two sides of the upper part of the first support frame are both provided with a first sliding block in a sliding way;

the middle parts of the two first sliding blocks are provided with supporting rods;

the fixing plate is connected between the upper parts of the two support rods;

the upper parts of the two support rods are connected with a second support frame in a sliding manner;

the supporting rod is wound with a first spring, and the first spring is connected between the fixing plate and the second supporting frame;

the third support frame is arranged between the tops of the two support rods;

the cylinder, third support frame mid-mounting has the cylinder.

Preferably, the electrolytic assembly comprises:

the two sides of the lower part of the second support frame are both provided with a first guide rod in a sliding way;

the two first guide rods are provided with a first sliding block in a sliding manner;

the first guide rod is wound with a first spring, and the first spring is connected between the first guide rod and the first sliding block;

the connecting devices are arranged at the bottoms of the two first guide rods, and the electrodes are connected with the connecting devices;

the battery is installed on the fixed plate, and the electrode is electrically connected with the battery.

Preferably, the cooling device further comprises a cooling assembly, and the cooling assembly further comprises:

the two sides of the bottom of the first support frame are provided with fourth support frames;

the water tank is connected between the two fourth supporting frames;

the water pump is mounted at the top of the first support frame;

the water pipe is installed on the water pump, and the both ends of water pipe all are connected with the water tank, and the water pipe winding is at the outer wall of electrolytic bath.

Preferably, the mobile assembly further comprises:

the bottom of the first support frame is provided with the double-shaft motor;

the output shafts on two sides of the double-shaft motor are respectively provided with a first rotating shaft, and the two first rotating shafts are rotatably connected with the first support frame;

the screw rods are rotatably arranged on two sides of the first support frame;

the two screw rods are both provided with a third sliding block in a threaded manner, and the first sliding block at the same side is connected with the third sliding block at the same side;

the outer sides of the two first rotating shafts are provided with first bevel gears;

and the two screws are respectively provided with a second bevel gear, and the second bevel gears on the same side are meshed with the first bevel gears on the same side.

Preferably, still including the unloading subassembly, the unloading subassembly still includes:

the base is provided with a storage frame;

a blanking plate is arranged at the lower part of the storage frame;

the two sides of the blanking plate are provided with second guide rods;

the two second guide rods are connected with the material breaking plates in a sliding mode;

the two sides of the top of the material breaking plate are provided with the stop blocks;

the second guide rod is wound with a second spring, and the second spring is connected between the blanking plate and the material cutting plate;

the wedge, fixed plate both sides all are equipped with the wedge, and the wedge of homonymy cooperates with the first dog of homonymy.

Preferably, the device also comprises a collecting component, and the collecting component also comprises;

the two sides of the first support frame are provided with support plates;

the upper parts of the two supporting plates are respectively and rotatably provided with a second rotating shaft;

straight gears are arranged on the two second rotating shafts;

the upper parts of the two supporting plates are respectively provided with a first sliding chute;

the upper parts of the two supporting plates are respectively provided with a second sliding chute;

racks are arranged in the first sliding chute and the second sliding chute in a sliding manner, the two racks are connected with the lower parts of the two supporting plates in a sliding manner, and the two racks on the same side are meshed with the straight gear on the same side;

the bottom parts of the two racks positioned on the lower side are provided with scrapers;

the lower parts of the two supporting plates are provided with limiting blocks;

the base is provided with a collecting frame;

the two sides of the top of the second support frame are provided with pressure rods, and the pressure rods on the same side are matched with the racks on the upper parts of the same side;

and the fourth springs are wound on the two racks and connected between the support plate and the racks.

Preferably, the material of the rack is forged steel.

The beneficial effects are that: 1. the invention can realize the extraction work of the rare earth metal by arranging the lifting component which is matched with the electrolysis component;

2. the lifting assembly is matched with the cooling assembly, so that the temperature near the electrolytic cell and the electrode can be quickly reduced, the service life of the electrode is prolonged, the industrial production cost is reduced, and the economic benefit is improved;

3. through the cooperation of unloading subassembly and collection subassembly, can realize the interval unloading of tombarthite, also can realize simultaneously that tombarthite metal's interval collects the work.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of the lifting assembly of the present invention.

FIG. 3 is a schematic perspective view of an electrolytic module according to the present invention.

Fig. 4 is a perspective view of the cooling module of the present invention.

Fig. 5 is a schematic perspective view of the moving assembly of the present invention.

Fig. 6 is a schematic perspective view of the blanking assembly of the present invention.

Fig. 7 is an enlarged schematic perspective view of the present invention a.

Fig. 8 is a perspective view of a first portion of a collection assembly of the present invention.

Fig. 9 is a perspective view of a second portion of the collection assembly of the present invention.

Labeled as: 1-a base, 2-a first support frame, 3-an electrolytic cell, 4-an electrode, 5-a lifting component, 51-a first sliding block, 52-a support rod, 53-a fixing plate, 54-a first spring, 55-a second support frame, 56-a third support frame, 57-an air cylinder, 6-an electrolytic component, 61-a first guide rod, 62-a second spring, 63-a second sliding block, 64-a connecting device, 65-a battery, 7-a cooling component, 71-a fourth support frame, 72-a water tank, 73-a water pump, 74-a water pipe, 8-a moving component, 81-a double-shaft motor, 82-a first rotating shaft, 83-a screw rod, 84-a first bevel gear, 85-a second bevel gear and 86-a third sliding block, 9-blanking component, 91-storage frame, 92-blanking plate, 93-second guide rod, 94-third spring, 95-blanking plate, 96-stop block, 97-wedge block, 10-collection component, 101-support plate, 102-second rotating shaft, 103-straight gear, 104-first sliding groove, 105-second sliding groove, 106-rack, 107-scraper, 108-limiting block, 109-collection frame, 1010-pressure rod, 1011-fourth spring.

Detailed Description

The invention will be further described with reference to examples of embodiments shown in the drawings to which the invention is attached.

Example 1

The utility model provides a rare earth metal automation equipment for electrolysis, as shown in fig. 1-3, including base 1, first support frame 2, electrolytic bath 3, electrode 4, lifting unit 5 and electrolytic component 6, be equipped with first support frame 2 on the base 1, first support frame 2 rear portion upside is equipped with electrolytic bath 3, install lifting unit 5 on the first support frame 2, the last electrolytic component 6 of installing of lifting unit 5, lifting unit 5 and the cooperation of electrolytic component 6, install electrode 4 on the electrolytic component 6, the quantity of electrode 4 is two.

When a worker needs to electrolyze rare earth metal, the device can be used, the worker firstly puts rare earth and electrolyte solution into the electrolytic cell 3, the electrolytic cell 3 is opened, the electrolytic cell 3 operates to generate a certain temperature, meanwhile, the lifting assembly 5 is started, the lifting assembly 5 operates to drive the electrolytic assembly 6 to operate, the electrolytic assembly 6 operates to drive the electrode 4 to move downwards to be in contact with the electrolyte solution in the electrolytic cell 3 and generate current, direct current is introduced into the electrolyte solution, so that the electrolyte generates chemical reaction on the electrode 4, chemically generated rare earth metal can attach to the electrode 4, the production of the rare earth metal can be stopped by closing the electrolytic cell 3 and the lifting assembly 5, and the worker can extract the rare earth metal by repeating the steps again.

Lifting unit 5 is including first slider 51, bracing piece 52, fixed plate 53, first spring 54, second support frame 55, third support frame 56 and cylinder 57, first slider 51 is all slidingly equipped with in the upper portion left and right sides of first support frame 2, two first slider 51 middle parts all are equipped with bracing piece 52, be connected with fixed plate 53 between two bracing piece 52 upper portions, sliding connection has second support frame 55 between two bracing piece 52 upper portions, around having first spring 54 on the bracing piece 52, first spring 54 is connected between fixed plate 53 and second support frame 55, be equipped with third support frame 56 between two bracing piece 52 tops, cylinder 57 is installed to third support frame 56 mid-mounting.

When needing electrolysis rare earth metal, the workman starts cylinder 57, the telescopic link extension of cylinder 57 drives second support frame 55 reciprocating up and down, first spring 54 adaptability compression and reseing, second support frame 55 drives electrolysis unit 6 reciprocating up and down, electrolysis unit 6 reciprocating up and down drives electrode 4 reciprocating up and down, electrode 4 downstream to with the electrolytic solution contact in the electrolytic bath 3 and produce the electric current, thereby take place chemical reaction, make rare earth metal depend on electrode 4, when not needing electrolysis rare earth metal, when waiting that cylinder 57 resets the back, close cylinder 57 can.

The electrolysis assembly 6 comprises a first guide rod 61, a second spring 62, a second sliding block 63, a connecting device 64 and a battery 65, the left side and the right side of the lower part of the second support frame 55 are both provided with the first guide rod 61 in a sliding manner, the two first guide rods 61 are both provided with the second sliding block 63 in a sliding manner, the first guide rod 61 is wound with the second spring 62, the second spring 62 is connected between the first guide rod 61 and the second sliding block 63, the bottoms of the two first guide rods 61 are both provided with the connecting device 64, the electrode 4 is connected with the connecting device 64, the battery 65 is installed on the fixing plate 53, and the electrode 4 is electrically connected with the battery 65.

The second support 55 moves downwards to drive the first guide rod 61, the second spring 62, the second slider 63, the connecting device 64 and the electrode 4 to move downwards, when the second slider 63 moves downwards to be in contact with the battery 65, the electrode 4 is electrified, the second spring 62 is compressed, the connecting device 64 continues to move downwards to drive the electrode 4 to move downwards to be in contact with the electrolyte solution and generate current, chemical reaction is generated, rare earth metal is attached to the electrode 4, the second support 55 moves upwards to drive the first guide rod 61, the second spring 62, the second slider 63, the connecting device 64 and the electrode 4 to move upwards for resetting, when the second slider 63 moves upwards to be not in contact with the battery 65, the electrode 4 is powered off, and the second spring 62 resets to drive the second slider 63, the connecting device 64 and the electrode 4 to move upwards for resetting.

Example 2

On the basis of embodiment 1, as shown in fig. 4 to 9, the electrolytic cell further comprises a cooling assembly 7, the cooling assembly 7 further comprises a fourth support frame 71, a water tank 72, a water pump 73 and a water pipe 74, the fourth support frame 71 is arranged on the left side and the right side of the front side of the bottom of the first support frame 2, the water tank 72 is connected between the two fourth support frames 71, the water pump 73 is arranged on the front side of the top of the first support frame 2, the water pipe 74 is arranged on the water pump 73, two ends of the water pipe 74 are connected with the water tank 72, and the water pipe 74 is wound on the outer wall of the electrolytic cell 3.

Considering that the operation of the electrolytic cell 3 generates high temperature, the water pump 73 is turned on, the water pump 73 operates to pump the water in the water tank 72 through the water pipe 74, and the water pipe 74 is communicated with the water tank 72, so that the water in the water tank 72 is recycled by the water pipe 74, the temperature of the electrolytic cell 3 and the temperature of the vicinity of the electrode 4 are rapidly reduced, the service life of the electrode 4 is prolonged, the industrial production cost is reduced, the economic benefit is improved, and when the temperature does not need to be reduced, the water pump 73 is turned off.

Still including moving subassembly 8, moving subassembly 8 is still including biax motor 81, first pivot 82, the screw rod 83, first bevel gear 84, second bevel gear 85 and third slider 86, biax motor 81 is installed to first support frame 2 bottom front side, all be equipped with first pivot 82 on the biax motor 81 left and right sides output shaft, two first pivot 82 all are connected with first support frame 2 rotary type, the equal rotary type in first support frame 2 left and right sides is equipped with screw rod 83, equal thread type is equipped with third slider 86 on two screw rods 83, first slider 51 and the third slider 86 of homonymy are connected, two first pivot 82 outsides all are equipped with first bevel gear 84, two screw rod 83 front portions all are equipped with second bevel gear 85, the second bevel gear 85 of homonymy meshes with the first bevel gear 84 of homonymy.

In order to facilitate taking out the rare earth metal attached to the electrode 4, a worker starts the double-shaft motor 81, an output shaft of the double-shaft motor 81 rotates to drive the first rotating shaft 82 to rotate, so as to drive the first bevel gear 84 to rotate, the first bevel gear 84 is meshed with the second bevel gear 85, the second bevel gear 85 drives the screw 83 to rotate, the screw 83 rotates to drive the third slider 86 to move forward, so as to drive the first slider 51, the support rod 52, the fixing plate 53, the first spring 54, the second support frame 55, the third support frame 56, the cylinder 57 and the electrode 4 to move forward, then the worker takes out the rare earth metal on the electrode 4, so that the rare earth metal conveying work on the electrode 4 is realized, when the conveying work is not required, the worker controls the double-shaft motor 81 to rotate reversely, the double-shaft motor 81 drives the first rotating shaft 82 and the first bevel gear 84 to rotate reversely, the first bevel gear 84 is meshed with the second bevel gear 85, the second bevel gear 85 drives the screw 83 to rotate reversely, the screw 83 rotates reversely to drive the third slide block 86 to move backwards and reset, so as to drive the first slide block 51, the support rod 52, the fixing plate 53, the first spring 54, the second support frame 55, the third support frame 56, the cylinder 57 and the electrode 4 to move backwards and reset, and then the dual-shaft motor 81 is turned off.

Still including unloading subassembly 9, unloading subassembly 9 is still including storage frame 91, unloading board 92, second guide arm 93, third spring 94, disconnected material board 95, dog 96 and wedge 97, base 1 rear portion is equipped with storage frame 91, storage frame 91 lower part is equipped with unloading board 92, the anterior left and right sides of unloading board 92 all is equipped with second guide arm 93, two second guide arms 93 go up the sliding connection and have disconnected material board 95, disconnected material board 95 top left and right sides all is equipped with dog 96, around having third spring 94 on the second guide arm 93, third spring 94 is connected between unloading board 92 and disconnected material board 95, the fixed plate 53 rear portion left and right sides all is equipped with wedge 97, the wedge 97 and the dog 96 cooperation of homonymy.

The workman puts into storage frame 91 the tombarthite, the tombarthite in storage frame 91 falls to contacting with disconnected flitch 95 through flitch 92 down, the initial condition of third spring 94 is the compression, fixed plate 53 moves forward and drives wedge 97 and move forward to not contacting with dog 96, third spring 94 resets and drives disconnected flitch 95 upward movement, thereby drive dog 96 upward movement, tombarthite will not be blockked up to disconnected flitch 95, the tombarthite can fall to electrolytic bath 3 in, fixed plate 53 moves backward and drives wedge 97 and move backward to contacting with dog 96, wedge 97 extrudes dog 96 downward movement, thereby drive disconnected flitch 95 downward movement, third spring 94 is compressed, disconnected flitch 95 downward movement is blockked up the tombarthite, the interval unloading work of tombarthite has been realized.

The collecting component 10 further comprises a supporting plate 101, a second rotating shaft 102, a straight gear 103, a first sliding groove 104, a second sliding groove 105, racks 106, a scraping plate 107, a limiting block 108, a collecting frame 109, a pressing rod 1010 and a fourth spring 1011, wherein the supporting plate 101 is arranged on the left side and the right side of the front part of the first supporting frame 2, the second rotating shaft 102 is arranged on the upper parts of the two supporting plates 101 in a rotating mode, the straight gear 103 is arranged on the two second rotating shafts 102, the first sliding groove 104 is arranged on the front side of the upper parts of the two supporting plates 101, the second sliding groove 105 is arranged on the rear side of the upper parts of the two supporting plates 101, the racks 106 are arranged in the first sliding groove 104 and the second sliding groove 105 in a sliding mode, the two racks 106 on the front side are connected with the front sides of the lower parts of the two supporting plates 101 in a sliding mode, the two racks 106 on the same side are meshed with the straight gear 103 on the same side, the scraping plate 107 is arranged at the bottom of the two racks 106 on the lower part of the same side, the two supporting plates 101 are provided with the limiting block 108, the front portion of the base 1 is provided with a collecting frame 109, the left side and the right side of the top of the second support frame 55 are provided with pressure rods 1010, the pressure rods 1010 on the same side are matched with the racks 106 on the upper portion of the same side, the two racks 106 on the front side are wound with fourth springs 1011, and the fourth springs 1011 are connected between the support plate 101 and the racks 106.

The second support frame 55 moves forward to drive the pressing rod 1010 to move forward to contact with the rack 106 on the upper side, at the moment, the electrode 4 is positioned right above the scraping opening of the scraping plate 107, at the moment, the second support frame 55 moves downward to drive the pressing rod 1010 to move downward, the pressing rod 1010 pushes the rack 106 on the upper side to move downward in the first sliding groove 104, the rack 106 on the upper side can be protected by the first sliding groove 104, the damage of the rack 106 on the upper side is reduced, the fourth spring 1011 is compressed, the rack 106 is meshed with the straight gear 103, the straight gear 103 drives the rack 106 on the lower side to move upward, so as to drive the scraping plate 107 to move upward, the scraping plate 107 can scrape the rare earth metal on the electrode 4, the scraped rare earth metal can fall into the collecting frame 109 to be collected, the second support frame 55 moves backward to drive the pressing rod 1010 to move backward not to contact with the rack 106 on the upper side, the fourth spring 1011 resets to drive the rack 106 on the upper side to move upward to reset, the rack 106 is meshed with the straight gear 103, and the straight gear 103 drives the rack 106 and the scraper 107 on the lower side to move upwards and reset, so that the rare earth metal is collected at intervals.

It should be understood that this example is only for illustrating the present invention and is not intended to limit the scope of the present invention. Further, it should be understood that various changes or modifications of the present invention may be made by those skilled in the art after reading the teaching of the present invention, and such equivalents may fall within the scope of the present invention as defined in the appended claims.

Claims (2)

1. An automatic equipment for rare earth metal electrolysis is characterized by comprising:

the device comprises a base (1) and a first support frame (2), wherein the base (1) is provided with the first support frame (2);

the electrolytic cell (3) is arranged on the upper side of the first support frame (2);

the lifting component (5) is arranged on the first support frame (2);

the electrolytic component (6) is arranged on the lifting component (5), and the lifting component (5) is matched with the electrolytic component (6);

the electrodes (4) are arranged on the electrolytic component (6), and the number of the electrodes (4) is two;

the lifting component (5) comprises:

the two sides of the upper part of the first support frame (2) are both provided with a first sliding block (51) in a sliding way;

the middle parts of the two first sliding blocks (51) are provided with supporting rods (52);

a fixing plate (53), wherein the fixing plate (53) is connected between the upper parts of the two support rods (52);

the second support frame (55) is connected between the upper parts of the two support rods (52) in a sliding manner;

the first spring (54) is wound on the supporting rod (52), and the first spring (54) is connected between the fixing plate (53) and the second supporting frame (55);

a third support frame (56), wherein the third support frame (56) is arranged between the tops of the two support rods (52);

the middle part of the third supporting frame (56) is provided with the cylinder (57);

the electrolytic assembly (6) comprises:

the two sides of the lower part of the first guide rod (61) and the second support frame (55) are both provided with the first guide rod (61) in a sliding way;

the second sliding blocks (63) are arranged on the two first guide rods (61) in a sliding manner;

the second spring (62) is wound on the first guide rod (61), and the second spring (62) is connected between the first guide rod (61) and the second sliding block (63);

the connecting devices (64) are arranged at the bottoms of the two first guide rods (61), and the electrodes (4) are connected with the connecting devices (64);

the battery (65), the battery (65) is installed on the fixing plate (53), and the electrode (4) is electrically connected with the battery (65);

still including cooling module (7), cooling module (7) still include:

the fourth support frames (71) are arranged on two sides of the bottom of the first support frame (2);

the water tank (72) is connected between the two fourth supporting frames (71);

the water pump (73), the top of the first support frame (2) is provided with the water pump (73);

the water pump (73) is provided with the water pipe (74), two ends of the water pipe (74) are connected with the water tank (72), and the water pipe (74) is wound on the outer wall of the electrolytic cell (3);

still including removing subassembly (8), remove subassembly (8) still including:

the bottom of the first support frame (2) is provided with a double-shaft motor (81);

the output shafts on two sides of the double-shaft motor (81) are respectively provided with a first rotating shaft (82), and the two first rotating shafts (82) are rotatably connected with the first support frame (2);

the screw rods (83) are rotatably arranged on both sides of the first support frame (2);

the two screw rods (83) are both provided with a third sliding block (86) in a threaded manner, and the first sliding block (51) at the same side is connected with the third sliding block (86) at the same side;

the outer sides of the two first rotating shafts (82) are respectively provided with a first bevel gear (84);

the two screw rods (83) are respectively provided with a second bevel gear (85), the second bevel gears (85) on the same side are meshed with the first bevel gears (84) on the same side;

still including unloading subassembly (9), unloading subassembly (9) still including:

the storage frame (91), the base (1) is provided with the storage frame (91);

a blanking plate (92), wherein the lower part of the storage frame (91) is provided with the blanking plate (92);

the two sides of the blanking plate (92) are provided with the second guide rods (93);

the two second guide rods (93) are connected with the material breaking plate (95) in a sliding mode;

the stop blocks (96) are arranged on the two sides of the top of the material cutting plate (95);

the third spring (94) is wound on the second guide rod (93), and the third spring (94) is connected between the blanking plate (92) and the material cutting plate (95);

the wedge blocks (97) are arranged on the two sides of the fixing plate (53), and the wedge blocks (97) on the same side are matched with the stop blocks (96) on the same side;

the device also comprises a collecting component (10), and the collecting component (10) also comprises a collecting body;

the two sides of the first support frame (2) are provided with support plates (101);

the upper parts of the two supporting plates (101) are respectively and rotatably provided with a second rotating shaft (102);

straight gears (103) are arranged on the two second rotating shafts (102);

the upper parts of the two supporting plates (101) are respectively provided with a first sliding chute (104);

the upper parts of the two supporting plates (101) are provided with second sliding grooves (105);

the racks (106) are arranged in the first sliding chute (104) and the second sliding chute (105) in a sliding manner, the two racks (106) are connected with the lower parts of the two supporting plates (101) in a sliding manner, and the two racks (106) on the same side are meshed with the straight gear (103) on the same side;

the bottom parts of the two racks (106) positioned at the lower side are respectively provided with a scraper (107);

the lower parts of the two supporting plates (101) are provided with limiting blocks (108);

the collecting frame (109) is arranged on the base (1);

the two sides of the top of the second support frame (55) are provided with the pressure rods (1010), and the pressure rods (1010) on the same side are matched with the racks (106) on the upper parts on the same side;

and the fourth springs (1011) are wound on the two racks (106), and the fourth springs (1011) are connected between the support plate (101) and the racks (106).

2. The automatic apparatus for the electrolysis of rare earth metals according to claim 1, wherein the material of the rack (106) is forged steel.

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