CN116871032A - Continuous attapulgite forming device and production line - Google Patents

Abstract

The application discloses a continuous attapulgite forming device and a production line, comprising a superfine pulverizer and an upper bin movably arranged on the superfine pulverizer, wherein a plurality of stirring assemblies are arranged on the upper bin, each stirring assembly comprises a shell and a plurality of movable sleeves arranged on the shell, and a second shifting pipe is arranged on each movable sleeve, wherein the stirring assemblies comprise a first shifting pipe, a second shifting pipe and a third shifting pipe, wherein the second shifting pipe is arranged on each movable sleeve, and the second shifting pipe is arranged on the second shifting pipe, and the third shifting pipe is arranged on the second shifting pipe, and the second shifting pipe is formed on the upper bin, and the upper bin is respectively provided with a plurality of stirring assemblies. The movable sleeves sequentially extend out of the shell, the movable sleeve extending to the outer side of the shell rotates, and the second shifting tube thereon extends out. According to the continuous attapulgite forming device and the continuous attapulgite forming production line, when the attapulgite powder is produced, firstly, the primarily crushed attapulgite is conveyed into the feeding bin, the stirring assemblies work, the movable sleeves sequentially extend out of the shell and enter the space between the feeding bin and the shell, the attapulgite is pushed, the second shifting tube on the movable sleeve extending out of the shell also extends out of the movable sleeve, and the movable sleeve rotates the second shifting tube to shift the attapulgite, so that the attapulgite in the feeding bin can smoothly enter the superfine pulverizer.

Description

Continuous attapulgite forming device and production line

Technical Field

The application relates to the technical field of attapulgite, in particular to a continuous attapulgite forming device and a continuous attapulgite forming production line.

Background

Attapulgite is an ore with large specific surface area, has good adsorption capacity, catalytic capacity and rheological property, and is widely applied to various fields of chemical industry, pesticides, building materials and the like.

When the attapulgite is used, the attapulgite is generally crushed into small particles, and then mixed with other ingredients to prepare a powder or granular finished product.

According to publication number CN106915750B, publication number 2018.12.25, a purifying device for attapulgite is disclosed, comprising an outer barrel and an inner barrel arranged in the outer barrel, the axes of the outer barrel and the inner barrel are the same and are both in a transversely arranged cylindrical structure, the inner barrel is in a front-back opening structure, and the front-back opening of the inner barrel is fixedly connected with the inner wall of the outer barrel; the outer barrel body comprises a first liquid inlet pipe arranged at the top, a feed inlet and a discharge outlet which are arranged on the side wall of the front end, wherein the first liquid inlet pipe extends downwards to be communicated with the inner cavity of the inner barrel body, the feed inlet is arranged above the discharge outlet, and movable flip covers are arranged on the feed inlet and the discharge outlet and are communicated with the inner cavity of the inner barrel body; the inner barrel body comprises a top air hole arranged at the top, a rotating shaft horizontally arranged in the inner cavity, a liquid level meter vertically arranged on the bottom wall and a first liquid discharge pipe arranged at the bottom and communicated with the inner cavity. Opening the movable flip on the feed inlet, throwing the attapulgite that needs to purify into the interior staving, closing the feed inlet after throwing, opening the solenoid valve on the first feed liquor pipe this moment, first feed liquor union coupling outside water source, the water injection in the first feed liquor pipe is to interior staving, soak and purify the attapulgite, open actuating mechanism in the water injection, make it drive pivot and rabbling mechanism rotatory, rabbling mechanism stirs the attapulgite, open the solenoid valve of first fluid-discharge tube at last, under the effect of filter screen, impurity in the attapulgite is together through the filter screen along with rivers, discharge in the first fluid-discharge tube, the attapulgite after the purification is derived from the discharge gate.

In the prior art including above-mentioned patent, when carrying out the production of attapulgite powder, need utilize superfine milling machine to carry out further smashing to preliminary kibbling attapulgite, preliminary kibbling attapulgite is accumulated in superfine milling machine's last feed bin and slowly gets into superfine milling machine, but go up the passageway that the feed bin got into superfine milling machine and is comparatively narrow, and preliminary kibbling attapulgite is easy to bridge in last feed bin, influences continuous unloading.

Disclosure of Invention

The application aims to provide a continuous attapulgite forming device and a production line, and aims to solve the problem that preliminary crushed attapulgite is easy to bridge in an upper bin and affects continuous blanking.

In order to achieve the above object, the present application provides a continuous attapulgite clay forming device, comprising an ultrafine powder mill and an upper bin movably mounted thereon, wherein the upper bin is provided with a plurality of stirring components, the stirring components comprise a shell and a plurality of movable sleeves arranged on the shell, the movable sleeves are provided with second poking pipes, wherein:

the movable sleeves sequentially extend out of the shell, the movable sleeve extending to the outer side of the shell rotates, and the second shifting tube on the movable sleeve extends out.

Preferably, a triangular shifting plate is arranged on the second shifting pipe, and a spring is arranged between the second shifting pipe and the movable sleeve.

Preferably, the automatic feeding device further comprises a driving mechanism, wherein the driving mechanism comprises a first connecting pipe and an air inlet pipe, the first connecting pipe and the air inlet pipe are arranged on the feeding bin, and the air inlet pipe is inflated with hot air so as to enable the first connecting pipe to rotate and drive the movable sleeves to sequentially move.

Preferably, the movable sleeve is rotatably provided with a second connecting pipe, a square part on the second connecting pipe extends to the inside of the limit sleeve on the shell, and a notch convenient for hot air flow is formed in the square part.

Preferably, the end of the second connecting pipe is provided with an air hole, the end of the second poking pipe is provided with an air vent, the inside of the movable sleeve is provided with a baffle, and the baffle comprises the following two states:

in the first state, the exhaust hole of the second shifting pipe faces to the upper part of the horizontal plane, and the baffle plate seals the air hole on the second connecting pipe;

and in the second state, the exhaust hole of the second poking pipe faces to the lower part of the horizontal plane, and the baffle is staggered with the air hole on the second connecting pipe.

Preferably, the shell is movably provided with a first locking piece for fixing the movable sleeve, the shell is movably provided with a gear ring, the gear ring is symmetrically provided with reeds for poking the first locking piece, and the first connecting pipe rotates so that the gear ring rotates.

Preferably, the movable sleeve is provided with a bevel gear, the first connecting pipe is provided with a circular ring, the circular ring is provided with gear teeth meshed with the bevel gear, and the first connecting pipe rotates to enable the movable sleeve to rotate.

Preferably, sliding rods corresponding to the movable sleeves are movably arranged on the shell, stay wires are arranged between the sliding rods and the corresponding movable sleeves, and the gear ring rotates to stir the sliding rods to move.

Preferably, the first connecting pipe extends to the lower part of the plurality of stirring assemblies and is provided with a plurality of first poking pipes, and the first poking pipes are provided with vertical downward air injection holes.

The continuous attapulgite forming production line comprises the continuous attapulgite forming device in the scheme.

In the technical scheme, the continuous attapulgite forming device and the production line provided by the application have the following beneficial effects: when producing the attapulgite powder, send the attapulgite of preliminary smashing to go up in the feed bin earlier, a plurality of stirring subassembly work, a plurality of movable sleeve are stretched out in proper order from the casing, get into in the space between feed bin and the casing, promote the attapulgite, the second driving tube of movable sleeve that stretches out in the follow casing also stretches out from the movable sleeve, the movable sleeve rotates the second driving tube and stirs the attapulgite, make the attapulgite in the feed bin can get into superfine milling machine smoothly in order to carry out further grinding to preliminary smashing's attapulgite.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings required for the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments described in the present application, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

FIG. 1 is a schematic diagram of the overall structure provided by an embodiment of the present application;

FIG. 2 is a schematic view of an internal structure of an exhaust pipe according to an embodiment of the present application;

fig. 3 is a schematic structural diagram of the inside of the upper bin according to the embodiment of the application;

FIG. 4 is a schematic view of an agitation assembly according to an embodiment of the present application;

FIG. 5 is a schematic view of the structure of the inside of the movable sleeve according to the embodiment of the present application;

fig. 6 is an enlarged view at a in fig. 5.

Reference numerals illustrate:

1. an agitation assembly; 11. a driving mechanism; 111. a first connection pipe; 112. an impeller; 113. a first gear; 114. a circular ring; 115. gear teeth; 116. a first tube-shifting device; 117. a second gear; 118. a gear ring; 119. an elastic sheet; 121. a movable sleeve; 122. a second tube-shifting device; 123. a poking plate; 124. a second connection pipe; 125. square parts; 126. a circular portion; 127. a baffle; 128. a limit sleeve; 129. bevel gears; 13. a housing; 131. a mounting plate; 132. a first locking piece; 133. a shifting block; 134. a first connecting rod; 135. a second locking piece; 136. a slide bar; 137. a pull wire; 2. feeding a bin; 21. a feed pipe; 22. a first feeding pipe; 23. an exhaust pipe; 24. a partition plate; 25. a second feeding pipe; 26. an air supply pipe; 27. an air inlet pipe; 28. a mounting cavity; 29. a guide groove; 3. superfine pulverizer.

Detailed Description

In order to make the technical scheme of the present application better understood by those skilled in the art, the present application will be further described in detail with reference to the accompanying drawings.

As shown in fig. 1-6, a continuous attapulgite forming device and a production line, comprising an ultrafine powder mill 3 and an upper bin 2 movably mounted thereon, wherein a plurality of stirring assemblies 1 are arranged on the upper bin 2, the stirring assemblies 1 comprise a shell 13 and a plurality of movable sleeves 121 arranged on the shell 13, and the movable sleeves 121 are provided with second poking tubes 122, wherein:

the movable sleeves 121 sequentially protrude from the housing 13, and the movable sleeve 121 extending to the outside of the housing 13 rotates and the second dial tube 122 thereon protrudes.

Specifically, when carrying out the production of attapulgite powder, send the superfine milling machine 3 with preliminary kibbling attapulgite earlier in, superfine milling machine 3 carries out further grinding to the powder, and the air-blower blows the air in superfine milling machine 3, and the air blows the powder, and the powder upwards moves in superfine milling machine 3, screens through the analytical engine, and unqualified attapulgite is got rid of, continues to grind, and qualified attapulgite leaves superfine milling machine 3, and this is prior art, and is not described in detail.

Further, a feed pipe 21 is arranged at the top of the upper bin 2, a check valve is arranged in the feed pipe 21, a first feed pipe 22 connected with the bottom of the superfine pulverizer 3 is arranged at the bottom of the upper bin 2, and a through hole matched with the movable sleeve 121 is formed in the shell 13; when attapulgite powder is produced, firstly, the primarily crushed attapulgite is conveyed into the feeding pipe 21 and the feeding bin 2, the stirring assemblies 1 work, the movable sleeves 121 sequentially extend out of the shell 13 and enter the space between the feeding bin 2 and the shell 13, the attapulgite is pushed, the second shifting pipe 122 on the movable sleeve 121 extending out of the shell 13 also extends out of the movable sleeve 121, and the movable sleeve 121 rotates the second shifting pipe 122 to shift the attapulgite, so that the attapulgite in the feeding bin 2 can smoothly enter the superfine pulverizer 3 through the first feeding pipe 22, and further grinding is carried out on the primarily crushed attapulgite.

Still further, in the above embodiment, a micro motor may be installed in the casing 13, an electric telescopic rod is disposed at an output end of the motor, a movable sleeve 121 is disposed at an end of the electric telescopic rod, a second electric telescopic rod is disposed between the movable sleeve 121 and the second stirring tube 122, when the attapulgite is required to be stirred, the electric telescopic rod stretches to send the movable sleeve 121 to the outside of the casing 13, the second electric telescopic rod stretches to push the second stirring tube 122 to stretch out of the movable sleeve 121, at this time, the motor works to drive the movable sleeve 121 to rotate, and the second stirring tube 122 on the movable sleeve 121 stirs the attapulgite in the upper bin 2 to avoid bridging in the upper bin 2; and may be any other structure that can be obtained by a person skilled in the art according to common general knowledge.

In the above technical scheme, when producing the attapulgite powder, firstly, the primarily crushed attapulgite is conveyed into the feeding bin 2, the plurality of stirring assemblies 1 work, the plurality of movable sleeves 121 sequentially extend out of the shell 13 and enter the space between the feeding bin 2 and the shell 13, the attapulgite is pushed, the second shifting tube 122 on the movable sleeve 121 extending out of the shell 13 also extends out of the movable sleeve 121, and the movable sleeve 121 rotates the second shifting tube 122 to shift the attapulgite, so that the attapulgite in the feeding bin 2 can smoothly enter the superfine pulverizer 3, and further grinding is carried out on the primarily crushed attapulgite.

As a further provided embodiment of the present application, a triangular dial 123 is provided on the second dial tube 122, and a spring is provided between the second dial tube 122 and the movable sleeve 121.

Specifically, the dial 123 is a right triangle, and the end of the movable sleeve 121 is provided with a cone.

Further, when the movable sleeve 121 extends from the casing 13, the cone at the end of the movable sleeve can better squeeze out the attapulgite, the second shifting tube 122 thereon is staggered with the side wall of the casing 13, the second shifting tube 122 extends from the movable sleeve 121 under the action of the spring, when the movable sleeve 121 rotates, the second shifting tube 122 stirs more attapulgite, so as to avoid bridging of the attapulgite in the upper bin 2, when the movable sleeve 121 retracts into the casing 13, the side wall of the casing 13 abuts against the inclined surface of the triangular shifting plate 123 and pushes against the shifting plate 123, so that the shifting plate 123 drives the second shifting tube 122 to retract into the movable sleeve 121, and when the movable sleeve 121 returns to the initial position, the second shifting tube 122 abuts against the side wall of the casing 13.

As still another embodiment of the present application, the present application further includes a driving mechanism 11, which includes a first connection pipe 111 and an air inlet pipe 27 disposed on the upper bin 2, and the air inlet pipe 27 blows hot air to rotate the first connection pipe 111 and drive the plurality of movable sleeves 121 to move in sequence.

Specifically, the top of the upper bin 2 is provided with a mounting cavity 28, a first connecting pipe 111 extends into the mounting cavity 28 and is provided with an impeller 112, the mounting cavity 28 is provided with an air inlet pipe 27, and an air hole which is convenient for hot air to enter the shell 13 is formed in the first connecting pipe 111.

Further, during operation, hot air is blown into the installation cavity 28 by the air pump through the air inlet pipe 27, the hot air pushes the impeller 112 and the first connecting pipe 111 to rotate, the hot air enters the first connecting pipe 111 through a gap between the first connecting pipe 111 and the installation cavity 28, then enters the shell 13 through an air hole on the first connecting pipe 111 and is released into the upper bin 2, attapulgite in the upper bin 2 is further dried so as to facilitate the follow-up grinding operation, and when the first connecting pipe 111 rotates, the first connecting pipe 111 drives the movable sleeves 121 to sequentially extend out of the shell 13, agitates the attapulgite in the upper bin 2 and then retracts into the shell 13, so that bridging of the attapulgite in the upper bin 2 is avoided.

As a further embodiment of the present application, a second connecting pipe 124 is rotatably disposed on the movable sleeve 121, and a square portion 125 above the second connecting pipe 124 extends into a stop collar 128 on the housing 13, and a gap for facilitating the flow of hot air is formed in the square portion 125.

Specifically, the second connecting tube 124 includes a circular portion 126 and a square portion 125, the circular portion 126 is rotatably mounted on the movable sleeve 121, the square portion 125 is slidably mounted on the limiting sleeve 128, and the movable sleeve 121 is provided with an exhaust hole.

Further, when the first connecting pipe 111 rotates, the first connecting pipe 111 drives the movable sleeves 121 to sequentially move towards the outer side of the shell 13, when the movable sleeves 121 move towards the outer side of the shell 13, the square parts 125 of the second connecting pipe 124 partially extend out of the limiting sleeve 128 to expose the notch on the square parts, hot air enters the movable sleeve 121 through the notch and is discharged from the exhaust hole on the movable sleeve 121 to the upper bin 2, and the hot air further dries the attapulgite in the upper bin 2.

As still another embodiment of the present application, the end of the second connecting tube 124 is provided with an air hole, the end of the second dial tube 122 is provided with an air hole, the inside of the movable sleeve 121 is provided with a baffle 127, and the baffle 127 comprises the following two states:

in the first state, the exhaust hole of the second poking pipe 122 faces upwards in the horizontal plane, and the baffle 127 seals the air hole on the second connecting pipe 124;

in the second state, the exhaust hole of the second deflector 122 faces downward in the horizontal plane, and the baffle 127 is staggered from the air hole of the second connecting pipe 124.

Specifically, the inner wall of the upper bin 2 is provided with guide grooves 29 distributed in a circumferential array.

Further, when the first connecting pipe 111 rotates, the movable sleeve 121 extends out of the shell 13, at this time, the second connecting pipe 124 on the movable sleeve 121 is communicated with the space inside the shell 13, hot air enters the second connecting pipe 124, the second stirring pipe 122 extends out of the movable sleeve 121, the movable sleeve 121 drives the second stirring pipe 122 to rotate, when the exhaust hole at the end part of the second stirring pipe 122 faces to the upper part of the horizontal plane, the baffle 127 on the movable sleeve 121 seals the air hole at the end part of the second connecting pipe 124, hot air cannot enter the movable sleeve 121, when the exhaust hole at the end part of the second stirring pipe 122 faces to the lower part of the horizontal plane, the baffle 127 and the air hole at the end part of the second connecting pipe 124 are staggered, the hot air enters the movable sleeve 121 through the air hole and is discharged from the exhaust hole on the second stirring pipe 122, the second stirring pipe 122 sprays the hot air to the lower part of the horizontal plane, and more attapulgite under the second stirring pipe 122 can be influenced, so that the attapulgite under the second stirring pipe can enter the pulverizer 3 through the first upper material pipe 22, when the hot air passes through the gap between the attapulgite and the upper material bin 2, the hot air can permeate the lower wall 29 better along the upper wall of the upper wall 2, and can permeate the lower wall of the bin better.

As a further embodiment of the present application, a first locking piece 132 for fixing the movable sleeve 121 is movably provided on the housing 13, a gear ring 118 is movably provided on the housing 13, and reeds for pulling the first locking piece 132 are symmetrically provided on the gear ring 118, and the first connecting tube 111 is rotated to rotate the gear ring 118.

Specifically, the inside activity of casing 13 is provided with mounting panel 131, be provided with first gear 113 on the first connecting pipe 111, it is provided with ring gear 118 to rotate on the mounting panel 131, the activity is provided with second gear 117 on the mounting panel 131, second gear 117 and first gear 113, ring gear 118 all mesh, be provided with a plurality of first locking pieces 132 on the mounting panel 131, set up the annular groove with first locking piece 132 adaptation on the movable sleeve 121, be provided with the slope on the lateral wall of first locking piece 132 near corresponding movable sleeve 121 one side, be provided with the shifting block 133 on the first locking piece 132, be provided with the slope on the shifting block 133, be provided with the spring between first locking piece 132 and the mounting panel 131, be provided with the spring between square portion 125 and the stop collar 128.

Further, when the first connecting tube 111 rotates, the first gear 113 on the first connecting tube 111 drives the second gear 117 meshed with the first gear 113 to rotate, the second gear 117 drives the gear ring 118 to rotate, the reed on the gear ring 118 moves along the slope on the shifting block 133 and pushes the shifting block 133 to move downwards, the shifting block 133 drives the first locking block 132 to move downwards to be separated from the movable sleeve 121, at the moment, the spring between the square part 125 and the limiting sleeve 128 pushes the square part 125 to move outwards of the shell 13 and drives the movable sleeve 121 to move outwards of the shell 13, the movable sleeve 121 stretches to the outer side of the shell 13, and attapulgite is stirred to avoid bridging of the attapulgite in the upper bin 2.

As still another embodiment further provided by the present application, the movable sleeve 121 is provided with a bevel gear 129, the first connection pipe 111 is provided with a circular ring 114, the circular ring 114 is provided with gear teeth 115 engaged with the bevel gear 129, and the first connection pipe 111 is rotated to rotate the movable sleeve 121.

Specifically, a connecting rod is disposed between the first connecting tube 111 and the ring 114, the mounting plate 131 is sleeved on the first connecting tube 111, and a plurality of elastic pieces 119 extending to the bottom of the housing 13 are disposed at the bottom of the mounting plate 131, when the connecting rod on the ring 114 passes through, part of the elastic pieces 119 can be stirred, enough moving space is reserved for the connecting rod on the ring 114, and other elastic pieces 119 can cooperate with the first connecting tube 111 to maintain the stability of the mounting plate 131.

Further, after the movable sleeve 121 extends out of the casing 13, the bevel gear 129 on the movable sleeve 121 is meshed with the gear teeth 115 on the circular ring 114, and when the first connecting pipe 111 rotates, the circular ring 114 is driven to rotate, and the gear teeth 115 on the circular ring 114 drive the bevel gear 129 to rotate, so that the movable sleeve 121 is driven to rotate, and the attapulgite in the feeding bin 2 is stirred.

As a further embodiment of the present application, a sliding rod 136 corresponding to the movable sleeves 121 is movably arranged on the housing 13, a pull wire 137 is arranged between the sliding rod 136 and the corresponding movable sleeve 121, and the gear ring 118 rotates to stir the sliding rod 136 to move.

Specifically, a first connecting rod 134 is disposed on the locking block, a second locking block 135 for fixing the sliding rod 136 is disposed on the first connecting rod 134, a slope is disposed on the second locking block 135, a movable ring is disposed on the movable sleeve 121, and a pull wire 137 is disposed between the movable ring and the sliding rod 136.

Further, when the gear ring 118 rotates, the spring on the gear ring 118 pushes the shifting block 133 to move downwards, the shifting block 133 drives the first locking block 132 to move downwards, the first locking block 132 is separated from the movable sleeve 121, the first locking block 132 drives the second locking block 135 to move downwards through the first connecting rod 134, the sliding rod 136 can move on the mounting plate 131, the spring between the square portion 125 and the limiting sleeve 128 pushes the movable sleeve 121 to move towards the outer side of the shell 13, the gear ring 118 continues to rotate, the spring on the gear ring 118 gradually contacts with the sliding rod 136 and pulls the sliding rod 136, the sliding rod 136 drives the movable sleeve 121 to move towards the inner side of the shell 13 through the pull wire 137, the sliding rod 136 moves along the slope of the second locking block 135, after the sliding rod 136 is staggered with the second locking block 135, the second locking block 135 is pushed upwards by the spring to lock the sliding rod 136, meanwhile, the movable sleeve 121 moves along the slope on the first locking block 132 until the first locking block 132 is opposite to the annular groove on the movable sleeve 121, the first locking block 132 is pushed by the spring to be inserted into the annular groove on the movable sleeve 121, and the movable sleeve 121 is further staggered with the sliding rod 136.

As a further embodiment of the present application, the first connection pipe 111 extends below the plurality of stirring assemblies 1 and is provided with a plurality of first deflector pipes 116, and the first deflector pipes 116 are provided with vertical downward air injection holes.

Specifically, the first connecting pipe 111 extends to the connection between the feeding bin 2 and the first feeding pipe 22, and is provided with a plurality of first poking pipes 116.

Further, when the first connecting pipe 111 rotates, the first stirring pipe 116 stirs the attapulgite at the joint of the feeding bin 2 and the first feeding pipe 22, so that the attapulgite enters the first feeding pipe 22, and meanwhile, the first stirring pipe 116 sprays hot air vertically downwards, so that the attapulgite can be pushed to move into the superfine pulverizer 3.

As a further embodiment of the present application, the top of the feeding bin 2 is provided with an exhaust pipe 23, the end of the exhaust pipe 23 is provided with a horizontal partition plate 24, an air supply pipe 26 communicated with the first feeding pipe 22 is arranged above the partition plate 24, and a second feeding pipe 25 communicated with the superfine mill 3 is arranged below the partition plate 24.

Specifically, when producing attapulgite powder, firstly, the primarily crushed attapulgite is sent to the feeding bin 2 by the feeding pipe 21, hot air is blown into the installation cavity 28 by the air pump through the air inlet pipe 27, the hot air pushes the impeller 112 and the first connecting pipe 111 to rotate, and the hot air enters the first connecting pipe 111 through a gap between the first connecting pipe 111 and the installation cavity 28, and then enters the shell 13 through an air hole on the first connecting pipe 111;

when the first connecting pipe 111 rotates, the first gear 113 on the first connecting pipe 111 drives the second gear 117 meshed with the first gear 113 to rotate, the second gear 117 drives the gear ring 118 to rotate, the reed on the gear ring 118 moves along the slope on the shifting block 133 and pushes the shifting block 133 to move downwards, the shifting block 133 drives the first locking block 132 to move downwards and separate from the movable sleeve 121, at the moment, the spring between the square part 125 of the second connecting pipe 124 and the limiting sleeve 128 pushes the square part 125 to move outwards of the shell 13 and drives the movable sleeve 121 to move outwards of the shell 13, the movable sleeve 121 stretches to the outer side of the shell 13, the cone at the end part of the movable sleeve 121 can better squeeze out attapulgite, the second shifting pipe 122 on the movable sleeve is staggered with the side wall of the shell 13, the second shifting pipe 122 stretches out of the movable sleeve 121 under the action of the spring, at the moment, the bevel gear 129 on the movable sleeve 121 is meshed with the gear teeth 115 on the circular ring 114, the first connecting pipe 111 drives the circular ring 114 to rotate, and the gear teeth 115 on the circular ring 114 drive the bevel gear 129 to rotate, and then drive the movable sleeve 121 to rotate, and the attapulgite in the bin 2 is stirred;

after the movable sleeve 121 extends out of the shell 13, a second connecting pipe 124 on the movable sleeve 121 is communicated with the space inside the shell 13, hot air enters the second connecting pipe 124, a second poking pipe 122 extends out of the movable sleeve 121, the movable sleeve 121 drives the second poking pipe 122 to rotate, when the exhaust hole at the end part of the second poking pipe 122 faces upwards of the horizontal plane, a baffle 127 on the movable sleeve 121 seals the air hole at the end part of the second connecting pipe 124, hot air cannot enter the movable sleeve 121, when the exhaust hole at the end part of the second poking pipe 122 faces downwards of the horizontal plane, the baffle 127 is staggered with the air hole at the end part of the second connecting pipe 124, the hot air enters the movable sleeve 121 through the air hole and is discharged from the exhaust hole on the second poking pipe 122, the second poking pipe 122 sprays the hot air downwards of the horizontal plane, so that the attapulgite below the second poking pipe can be further dried, the attapulgite can enter the superfine grinding mill 3 through the first upper bin 22, and when the hot air passes through the gap between the attapulgite and the upper bin 2, the hot air can permeate downwards along the upper inner wall 29 of the upper bin 2, and the hot air can permeate downwards better;

the gear ring 118 continues to rotate, the reed on the gear ring 118 gradually contacts with the slide bar 136 and dials the slide bar 136, the slide bar 136 drives the movable sleeve 121 to move towards the inside of the shell 13 through the pull wire 137, the side wall of the shell 13 abuts against the inclined surface of the triangular shifting plate 123 and abuts against the shifting plate 123, the shifting plate 123 drives the second shifting tube 122 to retract into the movable sleeve 121, the slide bar 136 moves along the inclined surface of the second locking piece 135, after reaching a preset position, the slide bar 136 is staggered with the second locking piece 135, the second locking piece 135 is pushed by a spring to move upwards, the slide bar 136 is locked by the slide bar 136, meanwhile, the movable sleeve 121 moves along the inclined surface of the first locking piece 132 until the first locking piece 132 is opposite to the annular groove on the movable sleeve 121, the first locking piece 132 is inserted into the annular groove on the movable sleeve 121 under the pushing of the spring, at this moment, the second shifting tube 122 abuts against the side wall of the shell 13, the gear ring 118 continues to rotate, the reed is deformed, and is staggered with the slide bar 136, and the next movable sleeve 121 continues to move;

when the first connecting pipe 111 rotates, the first stirring pipe 116 stirs the attapulgite at the joint of the feeding bin 2 and the first feeding pipe 22 so that the attapulgite enters the first feeding pipe 22, and meanwhile, the first stirring pipe 116 sprays hot air vertically downwards, so that the attapulgite can be pushed to move into the superfine pulverizer 3;

the hot air flows in the upper bin 2, a part of the hot air carries fine attapulgite powder to the top of the upper bin 2, the hot air flows along the exhaust pipe 23, most of the powder in the hot air is concentrated in the lower half, when the hot air flows through the partition plate 24, the partition plate 24 divides the air with more powder into the lower part, the air enters the superfine pulverizer 3 along the second feeding pipe 25 and is directly sent to the analyzer area of the superfine pulverizer 3 for screening, the hot air with less powder above the partition plate 24 enters the first feeding pipe 22 from the air supply pipe 26 and is mixed with the airflow in the first feeding pipe 22, enters the bottom of the superfine pulverizer 3, and the powder in the superfine pulverizer 3 is blown to move upwards and is screened by the analyzer.

While certain exemplary embodiments of the present application have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the application. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the application, which is defined by the appended claims.

Claims (10)

1. The utility model provides a continuous type attapulgite forming device, its characterized in that includes superfine milling machine (3) and movable mounting on it go up feed bin (2), go up and be provided with a plurality of stirring subassembly (1) on feed bin (2), stir subassembly (1) including casing (13) and a plurality of set up in activity cover (121) on casing (13), be provided with second driving tube (122) on activity cover (121), wherein:

the movable sleeves (121) sequentially extend out of the shell (13), the movable sleeves (121) extending to the outer side of the shell (13) rotate, and the second shifting tube (122) on the movable sleeves extends out.

2. The continuous attapulgite forming apparatus according to claim 1, wherein a triangular poking plate (123) is provided on the second poking tube (122), and a spring is provided between the second poking tube (122) and the movable sleeve (121).

3. The continuous attapulgite molding apparatus as recited in claim 1, further comprising a driving mechanism (11) including a first connecting pipe (111) and an air intake pipe (27) disposed on the upper bin (2), wherein the air intake pipe (27) blows hot air to rotate the first connecting pipe (111) and drive the movable sleeves (121) to sequentially move.

4. The continuous attapulgite molding device according to claim 1, wherein a second connecting pipe (124) is rotatably arranged on the movable sleeve (121), a square portion (125) on the second connecting pipe (124) extends into a limit sleeve (128) on the shell (13), and a notch for facilitating hot air flow is formed in the square portion (125).

5. The continuous attapulgite molding apparatus as set forth in claim 4, wherein an air hole is provided at an end of said second connection pipe (124), an air vent is provided at an end of said second poking pipe (122), a baffle (127) is provided inside said movable sleeve (121), said baffle (127) comprises two states:

in a first state, the exhaust hole of the second deflector pipe (122) faces upwards in the horizontal plane, and the baffle (127) seals the air hole on the second connecting pipe (124);

in the second state, the exhaust hole of the second deflector pipe (122) faces downwards in the horizontal plane, and the baffle plate (127) is staggered with the air hole on the second connecting pipe (124).

6. A continuous attapulgite molding device according to claim 3, characterized in that a first locking piece (132) for fixing the movable sleeve (121) is movably arranged on the housing (13), a gear ring (118) is movably arranged on the housing (13), reeds (119) for poking the first locking piece (132) are symmetrically arranged on the gear ring (118), and the first connecting pipe (111) rotates to enable the gear ring (118) to rotate.

7. A continuous attapulgite molding device according to claim 3, characterized in that a bevel gear (129) is provided on the movable sleeve (121), a circular ring (114) is provided on the first connecting tube (111), gear teeth (115) meshed with the bevel gear (129) are provided on the circular ring (114), and the first connecting tube (111) rotates to rotate the movable sleeve (121).

8. The continuous attapulgite forming apparatus as recited in claim 6, wherein a sliding bar (136) corresponding to a plurality of said movable sleeves (121) is movably disposed on said housing (13), a pull wire (137) is disposed between said sliding bar (136) and the corresponding movable sleeve (121), and said gear ring (118) rotates to shift said sliding bar (136) for movement.

9. A continuous attapulgite forming apparatus according to claim 3, wherein said first connecting pipe (111) extends below a plurality of said stirring modules (1) and is provided with a plurality of first deflector pipes (116), said first deflector pipes (116) being provided with vertically downward gas injection holes.

10. A continuous attapulgite forming line, characterized by comprising a continuous attapulgite forming device according to any of the preceding claims 1-9.