CN113786752A

CN113786752A - Tombarthite purification is with quick dissolving equipment

Info

Publication number: CN113786752A
Application number: CN202111069662.0A
Authority: CN
Inventors: 许忠田
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-09-13
Filing date: 2021-09-13
Publication date: 2021-12-14

Abstract

The invention relates to dissolving equipment, in particular to rapid dissolving equipment for purifying rare earth. The invention provides the rapid dissolving equipment for rare earth purification, which can rapidly dissolve rare earth, can vibrate and beat the rare earth, and can collect the dissolved rare earth, thereby reducing the labor intensity of workers. A rapid dissolving device for rare earth purification comprises: the upper part of the support frame is provided with the rotating mechanism; the lower part of the inner wall of the rotating mechanism is provided with the vibrating mechanism, and the rotating mechanism is matched with the vibrating mechanism. According to the invention, the rotating mechanism is arranged, and the rotating mechanism is matched with the vibrating mechanism, so that the rare earth can be dissolved, and meanwhile, the dissolved rare earth can be screened; the vibration mechanism is matched with the lifting mechanism, so that the work of taking out impurities on the sieve plate can be realized; through the cooperation of the rotating mechanism and the blanking mechanism, the rare earth can be collected.

Description

Tombarthite purification is with quick dissolving equipment

Technical Field

The invention relates to dissolving equipment, in particular to rapid dissolving equipment for purifying rare earth.

Background

China is the country with the largest rare earth reserves in the world, elements are distributed comprehensively, through development of nearly 40 years, the China has established the largest rare earth industry in the world, and becomes the largest rare earth producing country in the world, the largest rare earth consuming country and the largest rare earth supplying country, the traditional rare earth dissolving mode is that workers generally dissolve rare earth, meanwhile, the interior of the traditional rare earth dissolving mode is easy to enable the rare earth to be adhered to the inner wall of a dissolving device, and the workers can collect the rare earth within a long time, so that the rare earth dissolving efficiency is reduced.

Patent application No. CN203971779U discloses a novel rare earth dissolving tank, which comprises a dissolving tank, an up-and-down reciprocating stirring system and the like; the liquid feeding port is arranged at the upper left part of the dissolving tank; the control system is connected with the vertical reciprocating stirring system and the high-pressure liquid spraying system, the structure of the rare earth dissolving device is simple, rare earth dissolving is achieved, but the rare earth is not vibrated and beaten better in the operation process, and the working efficiency of rare earth dissolving is reduced.

Therefore, there is a need to design a rapid dissolving apparatus for rare earth purification, which can rapidly dissolve rare earth, simultaneously shake and beat rare earth, and collect dissolved rare earth, thereby reducing labor intensity of workers.

Disclosure of Invention

In order to overcome traditional tombarthite dissolving mode generally all be the workman and dissolve tombarthite, inside relatively easy messenger tombarthite simultaneously glues on the dissolving device inner wall, and the workman consumes longer time moreover and can collect the tombarthite, reduces the shortcoming of the efficiency that the tombarthite dissolved, and the technical problem is: the utility model provides a can dissolve tombarthite fast, can shake simultaneously and beat the tombarthite, can collect the tombarthite after dissolving moreover to can alleviate workman intensity of labour's tombarthite purification uses quick dissolving equipment.

The technical scheme is as follows: a rapid dissolving device for rare earth purification comprises:

the upper part of the support frame is provided with the rotating mechanism;

the lower part of the inner wall of the rotating mechanism is provided with the vibrating mechanism, and the rotating mechanism is matched with the vibrating mechanism.

Preferably, the rotating mechanism includes:

the upper part of the supporting frame is provided with the charging bucket;

the upper part of the outer wall of the charging bucket is provided with a first fixed block;

the servo motor is arranged at the upper part of the first fixed block;

the output shaft of the servo motor is provided with a first rotating shaft;

the first rotating block is arranged on the first rotating shaft in a sliding mode.

Preferably, the vibration mechanism includes:

the lower part of the inner wall of the charging basket is provided with a second fixed block;

the first telescopic rods are uniformly arranged on the second fixing block;

the screen plates are connected among the four first telescopic rods;

the first spring is sleeved on the first telescopic rod, and two ends of the first spring are respectively connected to the first telescopic rod and the sieve plate;

the lug is arranged on the sieve plate and matched with the first rotating block.

Preferably, the device further comprises a lifting mechanism, wherein the lifting mechanism comprises:

the guide rods are uniformly arranged on the sieve plate in a sliding manner, the number of the guide rods is four, and the four guide rods are fixedly connected with the inner wall of the upper part of the charging bucket;

the upper part of the first fixed block is rotatably provided with a second rotating shaft;

the two sides of the second rotating shaft are provided with the reels;

the stay wires are connected between the two reels and the sieve plate.

Preferably, the utility model also comprises a hammering mechanism, and the hammering mechanism comprises:

the upper part of the first rotating shaft is provided with a second rotating block;

the third fixed blocks are arranged on the two sides of the charging bucket;

the first sliding rods are arranged on the two third fixing blocks in a sliding manner;

the bottoms of the two first slide bars are respectively provided with a pressing block, and the two pressing blocks are matched with the sieve plate;

the tops of the two first sliding rods are respectively provided with a first wedge-shaped block, and the two first wedge-shaped blocks are matched with the second rotating block;

the fixture blocks are arranged on the two first sliding rods in a sliding mode, and the fixture blocks on the same side are clamped with the third fixture block on the same side;

the clamping sleeves are arranged on the two first sliding rods in a sliding mode and are positioned below the clamping blocks, and the clamping sleeves on the same side are clamped with the third fixing blocks on the same side;

and the two ends of the second spring are respectively connected to the pressing block and the clamping sleeve.

Preferably, the device further comprises a knocking mechanism, and the knocking mechanism comprises:

the upper parts of the two first sliding rods are respectively provided with a second wedge-shaped block;

the fifth fixing blocks are arranged on two sides of the upper part of the outer wall of the charging bucket;

two connecting rods are arranged on the two fifth fixing blocks in a sliding manner;

the tops of the two connecting rods are respectively provided with a third wedge block, and the second wedge block on the same side is matched with the third wedge block on the same side;

the lower parts of the two connecting rods are respectively provided with a knocking block, and the two knocking blocks are matched with the charging bucket;

the lower parts of the two connecting rods are respectively provided with a second slide rod, and the second slide rods on the same side are connected with a fifth fixing block on the same side in a sliding manner;

and the two second sliding rods are sleeved with third springs, and two ends of each third spring are connected to the connecting rod and the fifth fixing block respectively.

Preferably, still including unloading mechanism, unloading mechanism is including:

the bottom of the charging bucket is provided with a fourth fixed block;

the fourth fixed block is provided with a stop block in a sliding manner;

a second telescopic rod is connected between the lower part of the fourth fixed block and the lower part of the stop block;

the second telescopic rod is sleeved with a fourth spring, and two ends of the fourth spring are respectively connected to the stop block and the second telescopic rod;

and the upper parts of the discharging pipes and the fourth fixing block are symmetrically provided with discharging pipes.

Preferably, the fourth spring is made of alloy steel.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the invention, the rotating mechanism is arranged, and the rotating mechanism is matched with the vibrating mechanism, so that the rare earth can be dissolved, and meanwhile, the dissolved rare earth can be screened;

2. the vibration mechanism is matched with the lifting mechanism, so that the work of taking out impurities on the sieve plate can be realized;

3. through the cooperation of the rotating mechanism and the blanking mechanism, the rare earth can be collected.

Drawings

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

Fig. 2 is a schematic perspective view of the rotating mechanism of the present invention.

Fig. 3 is a schematic sectional perspective view of the vibration mechanism of the present invention.

Fig. 4 is a schematic perspective view of the lifting mechanism of the present invention.

Fig. 5 is a schematic perspective view of the hammering mechanism of the present invention.

Fig. 6 is a schematic perspective view of the knocking mechanism according to the present invention.

Fig. 7 is a schematic perspective view of the blanking mechanism of the present invention.

Part names and serial numbers in the figure: 1_ support frame, 2_ rotation mechanism, 21_ first fixed block, 22_ servo motor, 23_ first rotation shaft, 24_ first rotation block, 25_ charging basket, 3_ vibration mechanism, 31_ second fixed block, 32_ first telescopic rod, 33_ first spring, 34_ sieve plate, 35_ projection, 4_ lifting mechanism, 41_ guide rod, 42_ reel, 43_ second rotation shaft, 44_ stay wire, 5_ hammering mechanism, 51_ second rotation block, 52_ third fixed block, 53_ first slide rod, 54_ first wedge block, 55_ second spring, 56_ press block, 57_ clamp block, 58_ clamp sleeve, 6_ knocking mechanism, 61_ second wedge block, 62_ fifth fixed block, 63_ connecting rod, 64_ third wedge block, 65_ second slide rod, 66_ third spring, 67_ knock block, 7_ blanking mechanism, 71_ fourth wedge block, fixed block 72_ telescopic rod, 74_ fourth spring, 75_ blanking tube.

Detailed Description

The technical scheme of the invention is further explained by combining the attached drawings.

Example 1

A rapid dissolving device for purifying rare earth is shown in figures 1-3 and comprises a support frame 1, a rotating mechanism 2 and a vibrating mechanism 3, wherein the rotating mechanism 2 is installed on the upper portion of the support frame 1, the vibrating mechanism 3 is installed on the lower portion of the inner wall of the rotating mechanism 2, and the rotating mechanism 2 is matched with the vibrating mechanism 3.

The worker firstly puts the rare earth into the rotating mechanism 2, then the rare earth in the rotating mechanism 2 falls into the vibrating mechanism 3, the worker starts the rotating mechanism 2, the rotating mechanism 2 can dissolve the rare earth, the vibrating mechanism 3 can screen the dissolved rare earth, the worker closes the rotating mechanism 2 to stop dissolving the rare earth, and the rare earth dissolving work can be realized by repeating the steps.

The rotating mechanism 2 comprises a first fixing block 21, a servo motor 22, a first rotating shaft 23, a first rotating block 24 and a charging basket 25, the charging basket 25 is arranged on the upper portion of the supporting frame 1, the first fixing block 21 is arranged on the rear side of the upper portion of the outer wall of the charging basket 25, the servo motor 22 is installed on the upper portion of the first fixing block 21, the first rotating shaft 23 is arranged on an output shaft of the servo motor 22, and the first rotating block 24 is arranged on the first rotating shaft 23 in a sliding mode.

When the workman used rotary mechanism 2, start servo motor 22, servo motor 22 output shaft is rotatory to drive first pivot 23 rotatory to it is rotatory to drive first revolving block 24, and first revolving block 24 can dissolve tombarthite, and when need not dissolving the tombarthite, it can to close start servo motor 22.

Vibrations mechanism 3 is including second fixed block 31, first telescopic link 32, first spring 33, sieve 34 and lug 35, storage bucket 25 inner wall lower part is equipped with second fixed block 31, evenly be equipped with first telescopic link 32 on the second fixed block 31, first telescopic link 32 quantity is four, be connected with sieve 34 between four first telescopic links 32, the cover is equipped with first spring 33 on the first telescopic link 32, first spring 33's both ends are connected respectively on first telescopic link 32 and sieve 34, be equipped with lug 35 on the sieve 34, lug 35 cooperates with first rotary block 24.

When the workman used vibrations mechanism 3, tombarthite can drop to on sieve 34 this moment, when first revolving block 24 is rotatory, first revolving block 24 is rotatory to contacting with lug 35, thereby extrude lug 35 shake downwards, and then drive sieve 34 shake downwards, then drive first telescopic link 32 downstream, first spring 33 is compressed, first revolving block 24 continues to rotate to not contacting with lug 35, first spring 33 resets and drives first telescopic link 32 upward movement, and then drive sieve 34 and lug 35 upward shake, sieve 34 shake from top to bottom can be screened the tombarthite that dissolves.

Example 2

In a preferred embodiment of the present invention, as shown in fig. 1, fig. 2, fig. 4, fig. 5, fig. 6 and fig. 7, the present invention further includes a lifting mechanism 4, the lifting mechanism 4 includes guide rods 41, reels 42, a second rotating shaft 43 and pull wires 44, the sieve plate 34 is provided with the guide rods 41 in a sliding manner, the number of the guide rods 41 is four, the four guide rods 41 are all fixedly connected with the inner wall of the upper portion of the charging basket 25, the upper portion of the first fixing block 21 is rotatably provided with the second rotating shaft 43, the left and right sides of the second rotating shaft 43 are provided with the reels 42, and the pull wires 44 are connected between the two reels 42 and the sieve plate 34.

When the sieve plate 34 screens the dissolved rare earth, other impurities can stay on the sieve plate 34, a worker holds the second rotating shaft 43, then the worker rotates the second rotating shaft 43 to drive the reel 42 to rotate, the reel 42 tightens the pull wire 44, the pull wire 44 tightens to drive the sieve plate 34 to move upwards to be in contact with the first rotating block 24, the sieve plate 34 moves upwards to drive the first rotating block 24 to move upwards, the sieve plate 34 moves upwards to drive the first telescopic rod 32 to move upwards, the first spring 33 is stretched to drive the impurities to move upwards, the worker can conveniently take out the impurities on the sieve plate 34, then the worker looses the second rotating shaft 43 to reset the first spring 33, the first spring 33 resets to drive the first telescopic rod 32 and the sieve plate 34 to move downwards to reset, the sieve plate 34 resets to drive the first rotating block 24 to move downwards to reset, so that the pull wire 44 is loosened to drive the reel 42 to rotate reversely, thereby driving the second shaft 43 to rotate in the opposite direction.

The punching mechanism 5 comprises a second rotating block 51, a third fixing block 52, first sliding rods 53, first wedge-shaped blocks 54, a second spring 55, pressing blocks 56, clamping blocks 57 and clamping sleeves 58, wherein the second rotating block 51 is arranged at the upper part of a first rotating shaft 23, the third fixing blocks 52 are arranged at the left side and the right side of a charging basket 25, the first sliding rods 53 are arranged on the two third fixing blocks 52 in a sliding manner, the pressing blocks 56 are arranged at the bottoms of the two first sliding rods 53, the two pressing blocks 56 are matched with a sieve plate 34, the first wedge-shaped blocks 54 are arranged at the tops of the two first sliding rods 53, the two first wedge-shaped blocks 54 are matched with the second rotating blocks 51, the clamping blocks 57 are arranged on the two first sliding rods 53 in a sliding manner, the clamping blocks 57 at the same side are clamped with the clamping sleeves 52 of the third fixing blocks at the same side, the two first sliding rods 53 are provided with the clamping sleeves 58 in a sliding manner, the clamping sleeves 58 are positioned below the clamping blocks 57, the clamping sleeves 58 at the same side are clamped with the third fixing blocks 52 at the same side, the two first sliding rods 53 are sleeved with second springs 55, and two ends of each second spring 55 are connected to the pressing block 56 and the clamping sleeve 58 respectively.

Considering that the sieve plate 34 has large rare earth, the clamping block 57 and the clamping sleeve 58 are in a clamping state initially, when the first rotating shaft 23 rotates, the first rotating shaft 23 drives the second rotating block 51 to rotate, the second rotating block 51 rotates to be in contact with the first wedge-shaped block 54, so as to drive the first wedge-shaped block 54 to move upwards, further drive the first sliding rod 53 to move upwards, further drive the pressing block 56 to move upwards, the second spring 55 is compressed, the second rotating block 51 rotates to be not in contact with the first wedge-shaped block 54, the second spring 55 resets to drive the pressing block 56 to move downwards and reset, further drive the first sliding rod 53 and the first wedge-shaped block 54 to move downwards and reset, the pressing block 56 resets to hammer the rare earth block, when a worker needs to take out impurities on the sieve plate 34, the worker needs to pull up the clamping sleeve 57 and 58 in advance, the second spring 55 is stretched, and then pulls the first wedge-shaped block 54 to move upwards, and then drive first slide bar 53, second spring 55 and briquetting 56 and move upwards in step, the workman makes sieve 34 move upwards through acting as go-between 44 afterwards, the workman can take out impurity, after sieve 34 resets, the workman drives first wedge 54 and moves downwards to drive first slide bar 53, second spring 55, fixture block 57, cutting ferrule 58 and briquetting 56 move downwards, second spring 55 resets, the workman inserts fixture block 57 and cutting ferrule 58 afterwards, fixture block 57 and cutting ferrule 58 initial state are the block, realize the effect that the rare earth piece is beaten the bits.

Also comprises a knocking mechanism 6, the knocking mechanism 6 comprises a second wedge-shaped block 61, a fifth fixed block 62 and a connecting rod 63, third wedge 64, second slide bar 65, third spring 66 and strike piece 67, two first slide bar 53 upper portions all are equipped with second wedge 61, the upper portion left and right sides of storage bucket 25 outer wall all is equipped with fifth fixed block 62, two connecting rods 63 all are equipped with to the equal slidingtype on two fifth fixed blocks 62, two connecting rod 63 tops all are equipped with third wedge 64, the second wedge 61 of homonymy and the cooperation of the third wedge 64 of homonymy, two connecting rod 63 lower parts all are equipped with strike piece 67, two strike pieces 67 all cooperate with storage bucket 25, two connecting rod 63 lower parts all are equipped with second slide bar 65, the second slide bar 65 of homonymy and the sliding connection of the fifth fixed block 62 of homonymy, all overlap on two second slide bars 65 and be equipped with third spring 66, the both ends of third spring 66 are connected respectively on connecting rod 63 and fifth fixed block 62.

When the first slide bar 53 moves upwards, the first slide bar 53 moves upwards to drive the second wedge-shaped block 61 to move upwards to be in contact with the third wedge-shaped block 64, so as to drive the third wedge-shaped block 64 to move outwards, further drive the connecting rod 63 to move outwards, further drive the second slide bar 65 to move outwards, the third spring 66 is compressed, the connecting rod 63 moves outwards to drive the knocking block 67 to move outwards, when the first slide bar 53 moves downwards, the first slide bar 53 moves downwards to drive the second wedge-shaped block 61 to move downwards to be not in contact with the third wedge-shaped block 64, the third spring 66 resets to drive the second slide bar 65 and the connecting rod 63 to move inwards to reset, so as to drive the third wedge-shaped block 64 to move inwards to reset, the knocking block 67 resets to knock the material barrel 25, so that the material barrel 25 can shake the sieve plate 34, and the sieve plate 34 can filter the dissolved rare earth again, the efficiency of screening the dissolved rare earth is effectively improved.

Still including unloading mechanism 7, unloading mechanism 7 is including fourth fixed block 71, dog 72, second telescopic link 73, fourth spring 74 and unloading pipe 75, storage bucket 25 bottom is equipped with fourth fixed block 71, fourth fixed block 71 right side slidingtype is equipped with dog 72, be connected with second telescopic link 73 between fourth fixed block 71 lower part and the dog 72 lower part, the cover is equipped with fourth spring 74 on the second telescopic link 73, dog 72 and second telescopic link 73 are connected respectively at the both ends of fourth spring 74, fourth fixed block 71 upper portion front side symmetry is equipped with unloading pipe 75.

When using needs unloading mechanism 7, the tombarthite that dissolves this moment can fall to in the fourth fixed block 71, the dog 72 is held to the workman, promote dog 72 and move right afterwards, thereby drive second telescopic link 73 and move right, fourth spring 74 is stretched, when the gap of dog 72 and fourth fixed block 71 is great, the tombarthite that dissolves in the fourth fixed block 71 can fall to support frame 1 and collect, when the tombarthite that dissolves need not be collected, the workman loosens dog 72 and makes fourth spring 74 reset, thereby drive dog 72 and second telescopic link 73 and move left and reset, realize the work that the tombarthite that dissolves was collected.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.

Claims

1. A rare earth purification is with quick dissolving equipment which characterized in that, including:

the device comprises a support frame (1) and a rotating mechanism (2), wherein the rotating mechanism (2) is arranged at the upper part of the support frame (1);

the vibration mechanism (3) is installed on the lower portion of the inner wall of the rotating mechanism (2), and the rotating mechanism (2) is matched with the vibration mechanism (3).

2. The rapid dissolving apparatus for purifying rare earth according to claim 1, wherein the rotating mechanism (2) comprises:

the upper part of the supporting frame (1) is provided with the charging bucket (25);

the upper part of the outer wall of the charging bucket (25) is provided with a first fixed block (21);

the servo motor (22) is mounted at the upper part of the first fixing block (21);

a first rotating shaft (23) is arranged on an output shaft of the servo motor (22);

the first rotating block (24) is arranged on the first rotating shaft (23) in a sliding mode, and the first rotating block (24) is arranged on the first rotating shaft in a sliding mode.

3. The rapid dissolving apparatus for purifying rare earth according to claim 2, wherein the vibrating mechanism (3) comprises:

the lower part of the inner wall of the charging bucket (25) is provided with a second fixed block (31);

the first telescopic rods (32) are uniformly arranged on the second fixing block (31), and the number of the first telescopic rods (32) is four;

the screen plates (34) are arranged, the number of the first telescopic rods (32) is four, and the screen plates (34) are connected among the four first telescopic rods (32);

the first spring (33) is sleeved on the first telescopic rod (32), and two ends of the first spring (33) are respectively connected to the first telescopic rod (32) and the sieve plate (34);

the lug (35) is arranged on the sieve plate (34), and the lug (35) is matched with the first rotating block (24).

4. The rapid dissolving apparatus for purifying rare earth according to claim 3, further comprising an elevating mechanism (4), wherein the elevating mechanism (4) comprises:

the sieve plate (34) is uniformly and slidably provided with four guide rods (41), and the four guide rods (41) are fixedly connected with the inner wall of the upper part of the charging bucket (25);

the upper part of the first fixed block (21) is rotatably provided with a second rotating shaft (43);

the two sides of the second rotating shaft (43) are provided with the reels (42);

the pull wire (44) is connected between the two reels (42) and the sieve plate (34).

5. The rapid dissolving apparatus for rare earth purification according to claim 4, further comprising a hammering mechanism (5), wherein the hammering mechanism (5) comprises:

the upper part of the first rotating shaft (23) is provided with a second rotating block (51);

the third fixed block (52) is arranged on each of the two sides of the charging bucket (25);

the first sliding rod (53) is arranged on each of the first fixing block (53) and the second fixing block (52) in a sliding manner;

the pressing blocks (56) are arranged at the bottoms of the two first sliding rods (53), and the two pressing blocks (56) are matched with the sieve plate (34);

the tops of the two first sliding rods (53) are respectively provided with a first wedge-shaped block (54), and the two first wedge-shaped blocks (54) are matched with the second rotating block (51);

the fixture blocks (57) are arranged on the two first sliding rods (53) in a sliding mode, and the fixture blocks (57) on the same side are clamped with the third fixture blocks (52) on the same side;

the clamping sleeves (58) are arranged on the two first sliding rods (53) in a sliding mode, the clamping sleeves (58) are located below the clamping blocks (57), and the clamping sleeves (58) on the same side are clamped with the third fixing blocks (52) on the same side;

and the two first sliding rods (53) are sleeved with second springs (55), and two ends of each second spring (55) are respectively connected to the pressing block (56) and the clamping sleeve (58).

6. The rapid dissolving apparatus for purifying rare earth according to claim 5, further comprising a knocking mechanism (6), wherein the knocking mechanism (6) comprises:

the upper parts of the two first sliding rods (53) are respectively provided with a second wedge-shaped block (61);

the fifth fixed blocks (62) are arranged on both sides of the upper part of the outer wall of the charging bucket (25);

the two connecting rods (63) are arranged on the two fifth fixing blocks (62) in a sliding manner;

the tops of the two connecting rods (63) are respectively provided with a third wedge block (64), and the second wedge block (61) on the same side is matched with the third wedge block (64) on the same side;

the lower parts of the two connecting rods (63) are respectively provided with a knocking block (67), and the two knocking blocks (67) are respectively matched with the charging bucket (25);

the lower parts of the two connecting rods (63) are respectively provided with a second sliding rod (65), and the second sliding rods (65) on the same side are connected with the fifth fixing blocks (62) on the same side in a sliding manner;

and the two second sliding rods (65) are sleeved with third springs (66), and two ends of each third spring (66) are respectively connected to the connecting rod (63) and the fifth fixing block (62).

7. The rapid dissolving apparatus for purifying rare earth according to claim 6, further comprising a feeding mechanism (7), wherein the feeding mechanism (7) comprises:

a fourth fixed block (71), wherein the bottom of the charging basket (25) is provided with the fourth fixed block (71);

the stop block (72) is arranged on the fourth fixing block (71) in a sliding mode;

a second telescopic rod (73) is connected between the lower part of the fourth fixed block (71) and the lower part of the stop block (72);

the fourth spring (74) is sleeved on the second telescopic rod (73), and two ends of the fourth spring (74) are respectively connected to the stop block (72) and the second telescopic rod (73);

the upper parts of the discharging pipes (75) and the fourth fixing blocks (71) are symmetrically provided with the discharging pipes (75).

8. The rapid dissolving apparatus for rare earth purification according to claim 7, wherein the fourth spring (74) is made of alloy steel.