CN219218109U - Extraction equipment for producing rare earth oxide - Google Patents

Abstract

The utility model relates to extraction equipment for producing rare earth oxide, belongs to the technical field of rare earth oxide extraction, and solves the technical problem that rare earth raw materials are easy to block an extraction liquid outlet of the extraction equipment. An extraction apparatus for producing rare earth oxides includes a housing having a stir chamber. The sleeve is inserted in the stirring cavity and rotates relative to the shell. The sleeve is abutted with the bottom of the stirring cavity, and a filtering hole is formed in the peripheral side, close to the bottom of the stirring cavity, of the sleeve. The first helical blade is wound on the peripheral side surface of the sleeve, and the first helical blade rotates to drive the rare earth oxide to be mixed with the extraction liquid. The driving mechanism is mounted on the housing and is used for driving the sleeve to rotate. The driving mechanism is provided with a liquid conveying channel communicated with the inside of the sleeve. One end of the liquid taking pipe is positioned at the outer side of the shell, and the other end of the liquid taking pipe penetrates through the shell and is positioned in the sleeve.

Description

Extraction equipment for producing rare earth oxide

Technical Field

The utility model belongs to the technical field of rare earth oxide extraction, and particularly relates to extraction equipment for producing rare earth oxide.

Background

Rare earth is generally separated in an oxide state, although the reserves are very huge on the earth, the smelting and purifying difficulty is high, rare earth is obtained, rare earth elements are widely applied to the fields of petroleum, chemical industry, metallurgy, textile, ceramic, glass, permanent magnetic materials and the like, and the extraction of the rare earth needs to be carried out through extraction equipment in the industrial production process.

The utility model provides a multi-functional rare earth oxide extraction device has been mentioned in the authorized utility model of discovery publication number CN209405735U name through the applicant, this rare earth oxide extraction device includes the box, box one side outer wall is provided with the protective housing, and protective housing one side inner wall is provided with the motor, the one end outer wall of motor output shaft is provided with the dwang, and dwang top and bottom outer wall all are provided with the stirring leaf, box both sides inner wall all opens flutedly, and recess top and bottom inner wall all are provided with first spring, first spring top and bottom outer wall all are provided with the connecting plate, and connecting plate bottom outer wall is provided with vibrating motor, box top inner wall is provided with electric telescopic handle, and electric telescopic handle is pegged graft to electric telescopic handle bottom inner wall. The utility model can crush the rare earth, so that the rare earth can be more quickly dissolved in the extractant in the later stage of rare earth extraction, meanwhile, the motor drives the rotating rod and the stirring blade to rotate together, so that the rare earth can be quickly dissolved in the extractant, and the through hole is formed in the outer wall of one side of the stirring blade, so that the stirring effect can be improved.

However, this rare earth oxide extraction device still has the problem that the rare earth raw material easily blocks the extraction liquid outlet of the extraction equipment when the extraction liquid is discharged because the rare earth oxide is in a solid state.

Disclosure of Invention

The utility model provides extraction equipment for producing rare earth oxides, which is used for solving the technical problem that rare earth raw materials are easy to block an extraction liquid outlet of the extraction equipment.

In order to achieve the above purpose, the present utility model is realized by the following technical scheme: the extraction equipment for producing the rare earth oxide comprises a shell, a sleeve, a first spiral blade, a driving mechanism and a liquid taking pipe. The shell is provided with a stirring cavity. The sleeve is inserted in the stirring cavity and rotates relative to the shell. The sleeve is abutted with the bottom of the stirring cavity, and a filtering hole is formed in the peripheral side, close to the bottom of the stirring cavity, of the sleeve. The first helical blade is wound on the peripheral side surface of the sleeve, and the first helical blade rotates to drive the rare earth oxide to be mixed with the extraction liquid. The driving mechanism is mounted on the housing and is used for driving the sleeve to rotate. The driving mechanism is provided with a liquid conveying channel communicated with the inside of the sleeve. One end of the liquid taking pipe is positioned at the outer side of the shell, and the other end of the liquid taking pipe penetrates through the shell and is positioned in the sleeve.

Through the structure, the extraction equipment for producing the rare earth oxide can prevent the liquid taking pipe from being blocked by the rare earth raw material. Specifically, when rare earth oxide is extracted, rare earth oxide and an extraction liquid are added into the shell, and meanwhile, the extraction liquid is not higher than one end of the liquid taking pipe, which is positioned in the sleeve. And then the driving mechanism moves to drive the sleeve to rotate, so that the first helical blade is driven to rotate, and the rare earth oxide is driven to move along the axis of the sleeve in the direction away from the filtering holes. Meanwhile, the rare earth oxide is driven to be fully mixed with the extraction liquid, so that the rare earth oxide can be fully extracted by the extraction liquid. Then adding extract from the liquid delivery channel to the sleeve and the stirring cavity, so that the extract is positioned at one end of the sleeve by the liquid taking pipe, and the extract in the stirring cavity is driven to leave the stirring cavity under the siphon action and sequentially pass through the filtering holes, the sleeve and the liquid taking pipe and be collected by an operator, and meanwhile, the driving mechanism rotates to drive the sleeve to rotate, thereby driving the first helical blade to rotate, and driving the rare earth oxide to move along the axis of the sleeve in the direction away from the filtering holes. To prevent rare earth oxides from blocking the filter holes.

Optionally, the drive mechanism includes a drive motor, a first bevel gear, a connecting tube, and a second bevel gear. The drive motor is mounted on the housing and has a rotating end. The first bevel gear is arranged on the rotating end, and the driving motor is used for driving the rotating end to rotate. One end of the connecting pipe is arranged on the sleeve, the other end of the connecting pipe penetrates through the shell and is positioned outside the shell, the middle part of the connecting pipe is rotatably arranged on the shell, and a liquid conveying channel is arranged in the connecting pipe. The second bevel gear is sleeved outside the connecting pipe and meshed with the first bevel gear. The design makes the driving motor rotate and can drive the sleeve to rotate by driving the connecting pipe to rotate, and meanwhile, the connecting pipe can also convey the extracting solution into the sleeve through the liquid conveying channel.

Optionally, the rare earth oxide production extraction apparatus further comprises a mounting frame and a third bevel gear. The casing rotates and installs on the mounting bracket, and driving motor installs on the mounting bracket to be located the top of casing, the one end that gets the liquid pipe and be located the casing outside is installed and is being added. The third bevel gear is arranged at the top of the shell, sleeved outside the connecting pipe and rotated relative to the connecting pipe, and meshed with the first bevel gear. The design makes the casing also be driven by the driving motor to rotate relative to the mounting frame and rotate in the same axial direction and in opposite directions relative to the sleeve. So that the rare earth oxide and the extract liquid in the stirring cavity are mixed more uniformly.

Optionally, a production rare earth oxide extraction apparatus further comprises a second helical blade. The second helical blade winds around establishing on the week side in stirring chamber, and the casing rotates for the mounting bracket to drive second helical blade and rotate. By means of the design, the shell can drive the second helical blade to rotate when rotating relative to the mounting frame, and then the rare earth oxide and the extraction liquid in the stirring cavity are more uniformly mixed.

Optionally, the first helical blade is co-rotating with the second helical blade. The design makes when first helical blade drives rare earth oxide to move along the axis of sleeve pipe to the direction away from the filtration pore, because first helical blade and second helical blade coaxial counter-rotation, second helical blade can drive rare earth oxide to move along the axis of stirring chamber to the direction near the filtration pore. Thereby enabling the rare earth oxide to be sufficiently stirred in the stirring cavity.

Optionally, the mounting bracket includes a first mounting plate, a post, a second mounting plate, and a third mounting plate. One end of the shell, which is close to the liquid taking pipe, is rotatably arranged on the first mounting plate, and one end of the liquid taking pipe, which is positioned outside the shell, penetrates through the first mounting plate and is positioned outside the end face of the first mounting plate, which is far away from the shell. One end of the upright post is vertically arranged on the first mounting plate. The second mounting plate is installed on the stand to parallel with first mounting plate, the middle part of casing rotates and installs on the second mounting plate. The third mounting panel is installed on the stand one end of keeping away from first mounting panel, and the second mounting panel is located between first mounting panel and the third mounting panel, and the one end that first mounting panel was kept away from to the casing is rotated and is installed on the third mounting panel, and driving motor installs on the third mounting panel.

Optionally, the rare earth oxide production extraction device further comprises a feeding gate and a discharging gate. The circumference of the shell is provided with a feed inlet communicated with the stirring cavity. Distance H between one side of the feed inlet far away from the driving mechanism and the driving mechanism ₁ And the distance H between one end of the liquid taking pipe in the sleeve and the driving mechanism ₂ Satisfy H ₁ ＞H ₂ The feed gate is slidably mounted on the outside of the housing and is used to close and open the feed inlet. The circumference side of the shell, which is close to the connecting pipe, is provided with a discharge opening, and the discharge door is slidably arranged on the outer side of the shell and is used for closing and opening the discharge opening. By the design, when an operator puts rare earth oxide and extraction liquid into the stirring cavity through the feeding port, the extraction liquid is not higher than one end of the liquid taking pipe, which is positioned in the sleeve.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of an apparatus for producing rare earth oxides according to an embodiment of the present utility model;

FIG. 2 is a cross-sectional view taken along line A-A of FIG. 1;

FIG. 3 is an enlarged view at B in FIG. 2;

FIG. 4 is an enlarged view at C in FIG. 2;

fig. 5 is a schematic structural diagram of a mounting frame according to an embodiment of the present utility model.

In the figure:

1-a housing; 101-a stirring cavity; 102-a feed inlet; 103-a discharge port; 11-second helical blades; 2-a sleeve; 201-a filter hole; 21-first helical blades; 3-a driving mechanism; 31-a drive motor; 32-a first bevel gear; 33-connecting pipes; 331-liquid feeding channel; 332-fourth bearing; 34-a second bevel gear; 35-a third bevel gear; 4-a liquid taking pipe; 5-mounting frames; 51-a first mounting plate; 511-a first bearing; 52-stand columns; 53-a second mounting plate; 531-first mounting holes; 532—a second bearing; 54-a third mounting plate; 541-a second mounting hole; 542-third bearing.

Detailed Description

Embodiments of the present application are described in detail below with reference to the accompanying drawings.

In the description of the present application, it should be understood that the terms "center," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate description of the present application and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present application.

The terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present application, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present application, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the terms in this application will be understood by those of ordinary skill in the art in a specific context.

Examples

The utility model provides a multi-functional rare earth oxide extraction device has been mentioned in the authorized utility model of discovery publication number CN209405735U name through the applicant, this rare earth oxide extraction device includes the box, box one side outer wall is provided with the protective housing, and protective housing one side inner wall is provided with the motor, the one end outer wall of motor output shaft is provided with the dwang, and dwang top and bottom outer wall all are provided with the stirring leaf, box both sides inner wall all opens flutedly, and recess top and bottom inner wall all are provided with first spring, first spring top and bottom outer wall all are provided with the connecting plate, and connecting plate bottom outer wall is provided with vibrating motor, box top inner wall is provided with electric telescopic handle, and electric telescopic handle is pegged graft to electric telescopic handle bottom inner wall. The utility model can crush the rare earth, so that the rare earth can be more quickly dissolved in the extractant in the later stage of rare earth extraction, meanwhile, the motor drives the rotating rod and the stirring blade to rotate together, so that the rare earth can be quickly dissolved in the extractant, and the through hole is formed in the outer wall of one side of the stirring blade, so that the stirring effect can be improved.

However, this rare earth oxide extraction device still has the problem that the rare earth raw material easily blocks the extraction liquid outlet of the extraction equipment when the extraction liquid is discharged because the rare earth oxide is in a solid state.

In order to solve the above-mentioned technical problems, the present embodiment provides a production rare earth oxide extraction apparatus, which includes a housing 1, a sleeve 2, a first helical blade 21, a driving mechanism 3, and a liquid-taking pipe 4 as shown in fig. 1 and 2. The housing 1 has a stirring chamber 101. The sleeve 2 is inserted in the stirring chamber 101 and rotates relative to the housing 1. The sleeve 2 is abutted with the bottom of the stirring cavity 101, and as shown in fig. 4, a filter hole 201 is formed on the peripheral side of the sleeve 2, which is close to the bottom of the stirring cavity 101. As shown in fig. 2, the first spiral blade 21 is left-handed, the first spiral blade 21 is wound around the outer peripheral side surface of the casing 2, and the first spiral blade 21 rotates clockwise to drive the rare earth oxide to mix with the extraction liquid. A drive mechanism 3 is mounted on the housing 1 and is used to drive the rotation of the sleeve 2. The driving mechanism 3 is provided with a liquid feeding channel 331 communicated with the inside of the sleeve 2. One end of the liquid taking pipe 4 is positioned at the outer side of the shell 1, and the other end passes through the shell 1 and is positioned in the sleeve 2.

With the above structure, the production rare earth oxide extraction apparatus provided by the present embodiment can prevent the rare earth raw material from clogging the liquid taking pipe 4. Specifically, when rare earth oxide is extracted, rare earth oxide and an extraction liquid are added into the casing 1 while taking care that the extraction liquid is not higher than the end of the liquid-taking tube 4 located in the sleeve 2. The drive mechanism 3 then moves to drive the sleeve 2 to rotate clockwise, which in turn drives the first helical blades 21 to rotate clockwise to drive the rare earth oxide to move along the axis of the sleeve 2 in a direction away from the filter holes 201. Meanwhile, the rare earth oxide is driven to be fully mixed with the extraction liquid, so that the rare earth oxide can be fully extracted by the extraction liquid. Then, the extraction liquid is added from the liquid feeding channel 331 to the sleeve 2 and the stirring cavity 101, so that the extraction liquid is beyond the end of the liquid taking pipe 4 in the sleeve 2, and the extraction liquid in the stirring cavity 101 is driven to leave the stirring cavity 101 under the siphoning effect and sequentially pass through the filtering holes 201, the sleeve 2 and the liquid taking pipe 4 to be collected by an operator, and meanwhile, the driving mechanism 3 rotates to drive the sleeve 2 to rotate clockwise, so that the first helical blade 21 is driven to rotate clockwise, and the rare earth oxide is driven to move along the axis of the sleeve 2 in a direction away from the filtering holes 201. To prevent rare earth oxides from clogging the filter holes 201.

Based on the above, in order to enable the drive mechanism 3 to rotate the sleeve. The driving mechanism 3 includes a driving motor 31, a first bevel gear 32, a connection pipe 33, and a second bevel gear 34 as shown in fig. 3. Wherein the driving motor 31 is a servo motor with the model number of 750W ECMA-C20807RS-B2-0421, and the driving motor 31 is arranged on the shell 1 by welding and is provided with a rotating end. The first bevel gear 32 is mounted on the rotating end by welding, and the driving motor 31 is used to drive the rotating end to rotate. One end of the connecting tube 33 is mounted on the sleeve 2, the other end passes through the housing 1 and is located outside the housing 1, the middle part of the connecting tube 33 is rotatably mounted on the housing 1 through a fourth bearing 332 as shown in fig. 3, and a liquid feeding channel 331 is provided in the connecting tube 33 as shown in fig. 2. The second bevel gear 34 is disposed outside the connection pipe 33 through an interference connection sleeve, and is engaged with the first bevel gear 32. Specifically, the rotating end of the driving motor 31 rotates to drive the first bevel gear 32 to rotate, thereby driving the second bevel gear 34 to rotate clockwise. At the same time, the operator can throw in the extraction liquid into the stirring chamber 101 through the liquid feed passage 331 of the connecting pipe 33.

In order to make the mixing of the extraction liquid and the rare earth oxide more uniform, the extraction of the rare earth oxide by the extraction liquid is convenient. The apparatus for producing rare earth oxide extraction as shown in fig. 2 and 3 further comprises a mounting frame 5 and a third bevel gear 35. The casing 1 rotates and installs on mounting bracket 5, and driving motor 31 installs on mounting bracket 5 to be located the top of casing 1, the one end that gets liquid pipe 4 to be located the casing 1 outside is installed and is added the installation. The third bevel gear 35 is installed at the top of the housing 1, is sleeved outside the connection pipe 33, and rotates with respect to the connection pipe 33, and the third bevel gear 35 is engaged with the first bevel gear 32. Thus, when the driving motor 31 drives the first bevel gear 32 to rotate, the third bevel gear 35 can also be driven to rotate anticlockwise. So that the extract and the rare earth oxide are mixed more uniformly.

Based on the above, in order to further make the mixing of the extract and the rare earth oxide more uniform, the extraction of the rare earth oxide by the extract is facilitated. One production rare earth oxide extraction apparatus as shown in fig. 2 further includes a second helical blade 11. The second helical blade 11 is wound around the circumferential side of the stirring chamber 101, and the housing 1 is rotated with respect to the mounting frame 5 to rotate the second helical blade 11. By the design, the shell 1 can drive the second helical blade 11 to rotate when rotating relative to the mounting frame 5, so that the mixing of rare earth oxide and extract in the stirring cavity 101 is more uniform.

Based on the above, the first helical blade 21 and the second helical blade 11 are both left-handed as shown in fig. 2. The design is that when the first helical blade 21 drives the rare earth oxide to move along the axis of the sleeve 2 in the direction away from the filtering holes 201, the second helical blade 11 can drive the rare earth oxide to move along the axis of the stirring cavity 101 in the direction close to the filtering holes 201 due to the coaxial opposite rotation of the first helical blade 21 and the second helical blade 11. Thereby enabling the rare earth oxide and the extraction liquid to be thoroughly mixed in the stirring chamber 101.

Based on the above, the mounting bracket 5 shown in fig. 5 includes a first mounting plate 51, a column 52, a second mounting plate 53, and a third mounting plate 54. As shown in fig. 4, one end of the housing 1, which is close to the liquid taking tube 4, is rotatably mounted on the first mounting plate 51 through the first bearing 511, and one end of the liquid taking tube 4, which is located outside the housing 1, sequentially passes through the first bearing 511 and the first mounting plate 51, and is located outside the end surface of the first mounting plate 51, which is far from the housing 1.

One end of the upright 52 is vertically mounted on the first mounting plate 51 as shown in fig. 5. The second mounting plate 53 is mounted on the upright post 52 and parallel to the first mounting plate 51, and the middle part of the housing 1 provided with the first mounting hole 531 on the second mounting plate 53 is rotatably mounted on the second mounting plate 53 through the second bearing 532.

As shown in fig. 5, the third mounting plate 54 is mounted on an end of the upright 52 away from the first mounting plate 51, the second mounting plate 53 is located between the first mounting plate 51 and the third mounting plate 54, the third mounting plate 54 is provided with a second mounting hole 541, and an end of the housing 1 away from the first mounting plate 51 is rotatably mounted on the third mounting plate 54 through a third bearing 542. The driving motor 31 is mounted on the third mounting plate 54 by welding.

Based on the above, the rare earth oxide is put in and taken out for convenience. An apparatus for producing rare earth oxide extraction as shown in fig. 2 further comprises a feed gate (not shown) and a discharge gate (not shown). A feed inlet 102 communicated with the stirring cavity 101 is formed in the peripheral side of the shell 1. As shown in FIG. 2, the distance H1 between the side of the feed inlet 102 far away from the driving mechanism 3 and the distance H2 between the end of the liquid taking tube 4 in the sleeve 2 and the driving mechanism 3 satisfy H1 > H2. This design allows the operator to place rare earth oxide and extraction liquid into the stirring chamber 101 through the feed inlet 102 without the extraction liquid being higher than the end of the liquid extraction tube 4 located in the sleeve 2.

A loading door (not shown) is slidably mounted on the outside of the housing 1 and serves to close and open the loading port 102. The casing 1 is provided with a discharge port 103 on a peripheral side thereof adjacent to the connection pipe 33, and a discharge door (not shown) is slidably mounted on an outer side of the casing 1 and serves to close and open the discharge port 103.

In summary, in the process of extracting the rare earth oxide, firstly, the rare earth oxide and the extraction solution are added into the casing 1 through the feed inlet 102, and as shown in fig. 2, the distance H1 between the side of the feed inlet 102 far away from the driving motor 31 and the first mounting plate 51 and the distance H2 between the end of the liquid taking tube 4 located in the casing 2 and the first mounting plate 51 satisfy H1 > H2, so that the extraction solution is not higher than the end of the liquid taking tube 4 located in the casing 2.

The drive motor 31 then rotates the first bevel gear 32 to rotate the second bevel gear 34 and the connecting tube 33 and the sleeve 2 and the first helical blade 21 clockwise. To drive the rare earth oxide to move along the axis of the sleeve 2 in a direction away from the filter holes 201. Meanwhile, the rare earth oxide is driven to be fully mixed with the extraction liquid, so that the rare earth oxide can be fully extracted by the extraction liquid. Meanwhile, the first bevel gear 32 drives the third bevel gear 35 to rotate so as to drive the shell 1 and the second helical blade 11 to rotate anticlockwise relative to the shell 1, thereby driving the rare earth oxide close to the shell 1 to move along the axis of the stirring cavity 101 towards the direction close to the filtering holes 201, so that the movable rare earth oxide can be more conveniently driven by the first helical blade 21 to move along the axis of the sleeve 2 towards the direction away from the filtering holes 201. Thereby enabling the rare earth oxide and the extract to be thoroughly mixed in the stirring chamber 101. Then, the extraction liquid is added into the sleeve 2 and the stirring cavity 101 from the liquid feeding channel 331 of the connecting pipe 33, so that the extraction liquid is in the sleeve 2 beyond the end of the liquid taking pipe 4, thereby driving the extraction liquid in the stirring cavity 101 to leave the stirring cavity 101 under the siphoning effect, and the extraction liquid is collected by an operator after passing through the filtering holes 201, the sleeve 2 and the liquid taking pipe 4 in turn, and meanwhile, the driving mechanism 3 rotates to drive the sleeve 2 to rotate, thereby driving the first helical blade 21 to rotate, and driving the rare earth oxide to move along the axis of the sleeve 2 in a direction away from the filtering holes 201. To prevent rare earth oxides from clogging the filter holes 201. It can be seen from the above that the extraction apparatus for producing rare earth oxide according to the present embodiment can prevent the liquid extraction tube 4 from being clogged with rare earth raw material.

The above description is merely an embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art can easily think about changes or substitutions within the technical scope of the present utility model, and it is intended to cover the scope of the present utility model. Therefore, the protection scope of the present utility model shall be subject to the protection scope of the claims.

Claims (7)

1. An extraction apparatus for producing rare earth oxides, comprising:

a housing having a stir chamber;

the sleeve is inserted into the stirring cavity and rotates relative to the shell, the sleeve is abutted to the bottom of the stirring cavity, and a filtering hole is formed in the periphery of the sleeve, which is close to the bottom of the stirring cavity;

the first spiral blade is wound on the outer peripheral side surface of the sleeve and rotates to drive the rare earth oxide to be mixed with the extraction liquid;

the driving mechanism is arranged on the shell and used for driving the sleeve to rotate, and a liquid conveying channel communicated with the inside of the sleeve is formed on the driving mechanism;

one end of the liquid taking pipe is positioned at the outer side of the shell, and the other end of the liquid taking pipe penetrates through the shell and is positioned in the sleeve.

2. The apparatus for producing rare earth oxide extraction as claimed in claim 1, wherein said driving mechanism comprises:

a driving motor mounted on the housing and having a rotating end;

the first bevel gear is arranged on the rotating end, and the driving motor is used for driving the rotating end to rotate;

one end of the connecting pipe is arranged on the sleeve, the other end of the connecting pipe penetrates through the shell and is positioned outside the shell, the middle part of the connecting pipe is rotatably arranged on the shell, and the liquid conveying channel is arranged in the connecting pipe;

the second bevel gear is sleeved outside the connecting pipe and meshed with the first bevel gear.

3. The rare earth oxide production extraction apparatus according to claim 2, further comprising:

the installation frame is rotatably installed on the shell, the driving motor is installed on the installation frame and is positioned above the shell, and one end of the liquid taking pipe positioned outside the shell is installed on the installation frame;

and the third bevel gear is arranged at the top of the shell, sleeved outside the connecting pipe and rotated relative to the connecting pipe, and meshed with the first bevel gear.

4. A rare earth oxide production extraction apparatus according to claim 3, further comprising:

and the second helical blade is wound on the peripheral side of the stirring cavity, and the shell rotates relative to the mounting frame so as to drive the second helical blade to rotate.

5. The rare earth oxide production extraction apparatus of claim 4, wherein the first helical blade is co-rotating with the second helical blade.

6. A production rare earth oxide extraction apparatus according to claim 3, wherein the mounting frame comprises:

the liquid taking pipe is arranged on the first mounting plate in a rotating way, and one end of the liquid taking pipe outside the shell penetrates through the first mounting plate and is positioned outside the end face of the first mounting plate far away from the shell;

one end of the upright post is vertically arranged on the first mounting plate;

the second mounting plate is mounted on the upright post and parallel to the first mounting plate, and the middle part of the shell is rotatably mounted on the second mounting plate;

the third mounting plate is arranged at one end of the upright post far away from the first mounting plate, the second mounting plate is positioned between the first mounting plate and the third mounting plate, one end of the shell far away from the first mounting plate is rotatably arranged on the third mounting plate, and the driving motor is arranged on the third mounting plate.

7. The rare earth oxide production extraction apparatus according to claim 1, further comprising:

the feeding door is provided with a feeding port communicated with the stirring cavity on the peripheral side of the shell, and the distance H between one side, far away from the driving mechanism, of the feeding port and the driving mechanism is equal to the distance H between the driving mechanism and the feeding port ₁ And the distance H between one end of the liquid taking pipe positioned in the sleeve and the driving mechanism ₂ Satisfy H ₁ ＞H ₂ The feeding door is slidably arranged on the outer side of the shell and is used for closing and opening the feeding opening;

the discharging door is arranged on the periphery of the shell, which is close to the connecting pipe, and is slidably arranged on the outer side of the shell and used for closing and opening the discharging opening.

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