CN112931148B - Positive and negative pyrophyllite nutrient soil batching processing apparatus - Google Patents

Abstract

The invention relates to the field of pyrophyllite, in particular to a positive and negative pyrophyllite nutrient soil batching treatment device. The technical problems of the invention are as follows: provides a positive and negative pyrophyllite nutrient soil batching processing device. The technical implementation scheme of the invention is as follows: the positive and negative pyrophyllite nutrient soil batching processing device comprises a bottom frame, a screening component, an alignment component, a separation component and a control screen; the underframe is connected with the screening component; the underframe is connected with the alignment assembly; the underframe is connected with the separation assembly; the underframe is connected with the control screen; the screening assembly is connected with the alignment assembly. When the invention is used, wood sticks which are not burnt out in peat soil are automatically screened out, then the relative shortages in the wood sticks are automatically separated and collected, simultaneously, the two ends of a plurality of groups of wood sticks are automatically aligned, and charcoal at the two ends of the plurality of groups of wood sticks is respectively removed and collected, thereby greatly improving the efficiency.

Description

Positive and negative pyrophyllite nutrient soil batching processing apparatus

Technical Field

The invention relates to the field of pyrophyllite, in particular to a positive and negative pyrophyllite nutrient soil batching treatment device.

Background

Pyrophyllite is: a hydroxyl group-containing layered aluminosilicate mineral, monoclinic, which has not heretofore found independent, intact crystals, often in the form of cryptocrystalline lump or microcrystalline flake aggregates, and sometimes in the form of fibrous radial aggregates; white, or yellow, pale green, brown green, pale blue, pale brown, etc. due to different impurities.

In the prior art, pyrophyllite compressed nutrient soil is prepared from acidified pyrophyllite tailings, peat soil, plant fibers and the like, wood sticks which are burnt out or not are mixed in the peat soil, when stirring and mixing operation is carried out, the overlong wood sticks can be clamped into a stirrer to seriously influence the working efficiency, even the stirrer is damaged, meanwhile, the wood sticks are mixed in the stirred slurry to seriously influence the purity of the slurry, the subsequent purification difficulty is greatly increased, in addition, charcoal is adhered to the surfaces of the two ends of the wood sticks which are not burnt out, the wood sticks can be added into the slurry as raw materials, the lengths of the wood sticks are different, and the existing device cannot separate the charcoal at the two ends of a plurality of groups of wood sticks with different lengths.

In summary, it is necessary to develop a positive and negative pyrophyllite nutrient soil batching processing device to overcome the above problems.

Disclosure of Invention

In order to overcome the defects that in the prior art, pyrophyllite compressed nutrient soil is prepared from acidified pyrophyllite tailings, peat soil, plant fibers and the like, wood sticks which are burnt out are mixed in the peat soil, when stirring and mixing operations are carried out, the overlong wood sticks can be blocked into a stirrer to seriously influence the working efficiency, even the stirrer is damaged, meanwhile, the wood sticks are mixed in the stirred slurry to seriously influence the purity of the slurry, the subsequent purification difficulty is greatly increased, charcoal is adhered to the surfaces of two ends of the wood sticks which are not burnt out, the wood sticks can be added into the slurry as raw materials, the lengths of the wood sticks are different, and the charcoal at two ends of a plurality of wood sticks with different lengths cannot be separated by the traditional device, the technical problem of the invention is that: provides a positive and negative pyrophyllite nutrient soil batching processing device.

The technical implementation scheme of the invention is as follows: the positive and negative pyrophyllite nutrient soil batching processing device comprises a bottom frame, a screening component, an alignment component, a separation component and a control screen; the underframe is connected with the screening component; the underframe is connected with the alignment assembly; the underframe is connected with the separation assembly; the underframe is connected with the control screen; the screening assembly is connected with the alignment assembly.

In a preferred embodiment of the present invention, the screening assembly includes a first driving wheel, a second driving wheel, a first loop bar, a first prismatic bar, a first slider, a first electric sliding rail, a first bevel gear, a second bevel gear, a first screw rod, a second slider, a first rail block, a first electric rotating shaft, a first linkage block, a second electric sliding rail, a third slider, a first clamp, a third electric sliding rail, a fourth slider, a second clamp, a first storage box and a first electric push rod; the first driving wheel is in driving connection with the second driving wheel through a belt; the first driving wheel is internally connected with the alignment assembly; the inner part of the second driving wheel is fixedly connected with the first loop bar; the first sleeve rod is internally connected with a first prismatic rod; the outer surface of the first loop bar is rotationally connected with the underframe; the outer surface of the first prismatic rod is rotationally connected with the first sliding block; the outer surface of the first prismatic rod is fixedly connected with a first bevel gear; the first sliding block is in sliding connection with the first electric sliding rail; the first electric sliding rail is fixedly connected with the underframe; a second bevel gear is arranged above the first bevel gear; the inside of the second bevel gear is fixedly connected with the first screw rod; the outer surface of the first screw rod is screwed with the second sliding block; the outer surface of the first screw rod is rotationally connected with the first guide rail block; the second sliding block is in sliding connection with the first guide rail block; the second sliding block is fixedly connected with the first electric rotating shaft; the first guide rail block is fixedly connected with the underframe; the first electric rotating shaft is fixedly connected with the first linkage block; the first linkage block is fixedly connected with the second electric sliding rail; the first linkage block is fixedly connected with the third electric sliding rail; the second electric sliding rail is in sliding connection with the third sliding block; the third sliding block is fixedly connected with the first clamp; the third electric sliding rail is in sliding connection with the fourth sliding block; the fourth sliding block is fixedly connected with the second clamp; a first storage box is arranged below the second clamp; the first storage box is fixedly connected with two groups of first electric push rods; the first electric push rod is fixedly connected with the underframe.

In a preferred embodiment of the present invention, the alignment assembly includes a first motor, a second sleeve rod, a second prismatic rod, a fifth slider, a fourth electric sliding rail, a third bevel gear, a fourth bevel gear, a first transmission rod, a first straight gear, a second transmission rod, a correction mechanism, a third transmission wheel, a fourth transmission wheel, a third transmission rod, a fifth bevel gear, a sixth bevel gear, a third sleeve rod, a third prismatic rod, a sixth slider, a seventh electric push rod and a first cam; the output end of the first motor is fixedly connected with the second loop bar; the first motor is connected with the underframe; the second sleeve rod is internally connected with a second prismatic rod; the outer surface of the second sleeve rod is fixedly connected with a third driving wheel; the outer surface of the second sleeve rod is rotationally connected with the underframe; the outer surface of the second prismatic rod is rotationally connected with the fifth sliding block; the outer surface of the second prismatic rod is fixedly connected with a third bevel gear; the fifth sliding block is in sliding connection with the fourth electric sliding rail; the fourth electric sliding rail is fixedly connected with the underframe; a fourth bevel gear is arranged below the third bevel gear; the inside of the fourth bevel gear is fixedly connected with the first transmission rod; the outer surface of the first transmission rod is fixedly connected with the first straight gear; the outer surface of the first transmission rod is rotationally connected with the underframe; the first straight gear is meshed with the second straight gear; the inside of the second straight gear is fixedly connected with a second transmission rod; the second transmission rod is connected with the correction mechanism; the outer surface of the second transmission rod is rotationally connected with the underframe; the third driving wheel is in driving connection with the fourth driving wheel through a belt; the inside of the fourth driving wheel is fixedly connected with a third driving rod; the outer surface of the third transmission rod is fixedly connected with a fifth bevel gear; the outer surface of the third transmission rod is rotationally connected with the underframe; the outer surface of the third transmission rod is fixedly connected with the first transmission wheel; the fifth bevel gear is meshed with the sixth bevel gear; the inside of the sixth bevel gear is fixedly connected with a third loop bar; the inside of the third sleeve rod is connected with a third triangular rod; the outer surface of the third sleeve rod is rotationally connected with the underframe; the outer surface of the third prism is rotationally connected with the sixth sliding block; the third prism is fixedly connected with the first cam; the sixth sliding block is fixedly connected with the seventh electric push rod; and the seventh electric push rod is fixedly connected with the underframe.

In a preferred embodiment of the present invention, the correction mechanism includes a first connecting frame, a first spring, a first linkage frame, a first limiting cylinder, a first electric cover plate, a second electric push rod, a third clamp and a fourth clamp; the first connecting frame is fixedly connected with the first spring; the first connecting frame is fixedly connected with the second transmission rod; the first spring is fixedly connected with the first linkage frame; the first linkage frame is fixedly connected with the first limiting cylinder; the first linkage frame is fixedly connected with the second electric push rod; the first linkage frame is fixedly connected with the third electric push rod; the first limiting cylinder is connected with the first electric cover plate; the first limiting cylinder is connected with the second electric cover plate; the second electric push rod is fixedly connected with the fourth clamp; and the third electric push rod is fixedly connected with the third clamp.

In a preferred embodiment of the present invention, the separation assembly includes a fourth electric push rod, a second linkage block, a first push plate, a fifth electric push rod, a first steel brush block, a sixth electric push rod, a second steel brush block, a fifth electric sliding rail, a seventh sliding block, a third linkage block, a second storage box and a third storage box; the fourth electric push rod is fixedly connected with the second linkage block; the fourth electric push rod is fixedly connected with the underframe; the second linkage block is fixedly connected with the first push plate; the second linkage block is fixedly connected with the fifth electric push rod; the second linkage block is fixedly connected with the sixth electric push rod; the fifth electric push rod is fixedly connected with the first steel brush block; the sixth electric push rod is fixedly connected with the second steel brush block; a fifth electric sliding rail is arranged below the side edge of the second steel brush block; the fifth electric sliding rail is in sliding connection with the seventh sliding block; the fifth electric sliding rail is fixedly connected with the underframe; the seventh sliding block is fixedly connected with the third linkage block; the third linkage block is fixedly connected with the second storage box; the third linkage block is fixedly connected with the third storage box.

In a preferred embodiment of the invention, the first clamp is provided with two semicircular rings, the second clamp is provided with three semicircular rings at equal intervals, and the two semicircular rings of the first clamp are aligned with the gaps of the three semicircular rings of the second clamp respectively.

In a preferred embodiment of the invention, the first springs are arranged in a circular array of four sets.

In a preferred embodiment of the invention, the steel wire head of the second steel brush block is provided with metal balls.

The beneficial effects of the invention are as follows: (1) In order to solve the problems that in the prior art, a pyrophyllite compressed nutrient soil is prepared from acidified pyrophyllite tailings, peat soil, plant fibers and the like, wood sticks which are burnt out are mixed in the peat soil, when stirring and mixing operations are carried out, the overlong wood sticks can be blocked into a stirrer to seriously influence the working efficiency, even the stirrer is damaged, meanwhile, the wood sticks are mixed in the stirred slurry to seriously influence the purity of the slurry, the subsequent purification difficulty is greatly increased, charcoal is adhered to the surfaces of two ends of the wood sticks which are not burnt out, the wood sticks can be added into the slurry as raw materials, and in addition, the lengths of the wood sticks are different, so that the existing device can not simultaneously separate the charcoal at two ends of a plurality of wood sticks with different lengths;

(2) A screening assembly, an alignment assembly and a separation assembly are designed; when the device is ready to work, the device is placed on a horizontal plane, a power supply is connected, then a proper amount of peat soil is poured into a screening assembly, a proper amount of clear water is injected into the screening assembly, then a control screen control device on a bottom frame is controlled to start to operate, wood sticks which are not burned out in the peat soil float on the water surface, then the screening assembly simultaneously drags out a plurality of groups of wood sticks from the water, the plurality of groups of wood sticks are made to present in the same direction, then the screening assembly drives the wood sticks to rotate ninety degrees and transport the wood sticks into an alignment assembly, then the alignment assembly vibrates the wood sticks, so that the relatively short wood sticks move to the lowest part, then the alignment assembly transports the relatively short wood sticks into a separation assembly, then the alignment assembly fixes the plurality of groups of wood sticks, at the moment, then the separation assembly performs reciprocating friction on the bottoms of the plurality of groups of wood sticks, so that charcoal at the bottoms of the plurality of groups of wood sticks is removed, then the alignment assembly rotates one hundred eighty degrees of wood sticks, the other ends of the plurality of groups of wood sticks are aligned, and then the other ends of the plurality of groups of wood sticks are subjected to reciprocating friction, and charcoal removal on the other ends of the wood sticks is performed, so that charcoal removal on the wood sticks is clean;

(3) When the invention is used, the wood sticks which are not burnt out in peat soil are automatically screened out, then the relative shortages in the wood sticks are automatically separated and collected, simultaneously, the two ends of a plurality of groups of wood sticks are automatically aligned, and then the charcoal at the two ends of the plurality of groups of wood sticks is respectively removed and collected, thereby greatly improving the efficiency.

Drawings

FIG. 1 is a schematic perspective view of a first embodiment of the present invention;

FIG. 2 is a schematic view of a second perspective structure of the present invention;

FIG. 3 is a schematic perspective view of a screening assembly according to the present invention;

FIG. 4 is a schematic perspective view of an alignment assembly of the present invention;

FIG. 5 is a schematic perspective view of the correcting mechanism of the present invention;

FIG. 6 is a schematic perspective view of a part of the structure of the correcting mechanism of the present invention;

FIG. 7 is a schematic perspective view of a separator assembly according to the present invention;

fig. 8 is an enlarged perspective view of the present invention at a.

Wherein the above figures include the following reference numerals: 1_chassis, 2_screening assembly, 3_alignment assembly, 4_separation assembly, 5_control screen, 201_first drive wheel, 202_second drive wheel, 203_first lever, 204_first lever, 205_first slide, 206_first power slide, 207_first bevel gear, 208_second bevel gear, 209_first lead screw, 2010_second slide, 2011_first rail block, 2012_first power spindle, 2013_first linkage block, 2014_second power slide, 2015_third slide, 2016_first clamp, 2017_third power slide, 2018_fourth slide, 2019_second clamp, 2020_first receiver, 2021_first power push rod, 301_first motor, 302_second lever, 303_second lever, 304_fifth slide, 305_fourth power slide, 306_third bevel gear, 307_fourth bevel gear, 308_first drive rod, 309_first straight gear, 3010_second spur gear, 3011_second drive rod, 3012_correction mechanism, 3013_third drive wheel, 3014_fourth drive wheel, 3015_third drive rod, 3016_fifth bevel gear, 3017_sixth bevel gear, 3018_third set of levers, 3019_third prism, 3020_sixth slider, 3021_seventh electric push rod, 3022_first cam, 301201 _first connection frame, 301202_first spring, 301203 _first connection frame, 301204 _first limit cylinder, 301205 _first electric cover plate, 301206 _second electric cover plate, 301207 _second electric push rod, 301208 _third electric push rod, 301209 _third clamp, 301210 _fourth clamp, 401_fourth electric push rod, 402_second connection block, 403_first push plate, 404_fifth electric push rod, 405_first steel brush block, 406_sixth electric push rod, 402_second steel brush block, 408_fifth electric slide rail, 409_seventh slider, 4010_third linkage block, 4011_second receiver, 4012_third receiver.

Detailed Description

The following description is of the preferred embodiments of the invention, and is not intended to limit the scope of the invention.

Example 1

The positive and negative pyrophyllite nutrient soil batching processing device, as shown in figures 1-8, comprises a bottom frame 1, a screening component 2, an alignment component 3, a separation component 4 and a control screen 5; the underframe 1 is connected with the screening component 2; the underframe 1 is connected with the alignment assembly 3; the underframe 1 is connected with the separation assembly 4; the underframe 1 is connected with the control screen 5; the screening assembly 2 is connected to an alignment assembly 3.

The working steps are as follows: when the device is ready to work, the device is placed on a horizontal plane, a power supply is connected, then a proper amount of peat soil is poured into the screening component 2, a proper amount of clean water is injected into the screening component 2, then the control screen 5 on the underframe 1 is controlled to control the device to start to operate, wood sticks which are not burned out in the peat soil float on the water surface, then the screening component 2 simultaneously drags out a plurality of groups of wood sticks from the water, the wood sticks are made to present the same direction, then the screening component 2 drives the wood sticks to rotate ninety degrees and transport the wood sticks into the aligning component 3, then the aligning component 3 shakes the wood sticks, so that the wood sticks with relatively short length move to the lowest part, then the aligning component 3 transports the wood sticks with relatively short length into the separating component 4, then the aligning component 3 fixes the wood sticks with the plurality of groups, then the separation assembly 4 carries out reciprocating friction on the bottoms of the plurality of groups of wood sticks, so that charcoal at the bottoms of the plurality of groups of wood sticks is removed, then the alignment assembly 3 rotates the plurality of groups of wood sticks by one hundred eighty degrees, then the wood sticks are vibrated to align the other ends of the plurality of groups of wood sticks, then the separation assembly 4 carries out reciprocating friction on the other ends of the plurality of groups of wood sticks, so that charcoal at the other ends of the plurality of groups of wood sticks is removed, further the charcoal on the wood sticks is removed completely, and the separation assembly 4 collects the charcoal.

The screening assembly 2 includes a first driving wheel 201, a second driving wheel 202, a first loop bar 203, a first prismatic bar 204, a first slider 205, a first electric sliding rail 206, a first bevel gear 207, a second bevel gear 208, a first screw rod 209, a second slider 2010, a first rail block 2011, a first electric rotating shaft 2012, a first linkage block 2013, a second electric sliding rail 2014, a third slider 2015, a first clamp 2016, a third electric sliding rail 2017, a fourth slider 2018, a second clamp 2019, a first receiving box 2020, and a first electric push rod 2021; the first driving wheel 201 is in driving connection with the second driving wheel 202 through a belt; the first driving wheel 201 is internally connected with the alignment assembly 3; the inside of the second driving wheel 202 is fixedly connected with a first loop bar 203; the first sleeve rod 203 is internally connected with a first prismatic rod 204; the outer surface of the first loop bar 203 is rotationally connected with the underframe 1; the outer surface of the first prismatic rod 204 is rotationally connected with the first sliding block 205; the outer surface of the first prismatic rod 204 is fixedly connected with a first bevel gear 207; the first sliding block 205 is in sliding connection with the first electric sliding rail 206; the first electric sliding rail 206 is fixedly connected with the underframe 1; a second bevel gear 208 is arranged above the first bevel gear 207; the inside of the second bevel gear 208 is fixedly connected with the first screw rod 209; the outer surface of the first screw rod 209 is screwed with the second slider 2010; the outer surface of the first screw rod 209 is rotationally connected with a first guide rail block 2011; the second slider 2010 is slidably connected to the first rail block 2011; the second slider 2010 is fixedly connected with the first electric rotating shaft 2012; the first guide rail block 2011 is fixedly connected with the underframe 1; the first electric rotating shaft 2012 is fixedly connected with the first linkage block 2013; the first linkage block 2013 is fixedly connected with the second electric sliding rail 2014; the first linkage block 2013 is fixedly connected with a third electric sliding rail 2017; the second electric sliding rail 2014 is slidably connected with the third sliding block 2015; the third slider 2015 is fixedly connected to the first clamp 2016; the third electric sliding rail 2017 is in sliding connection with the fourth sliding block 2018; the fourth slider 2018 is fixedly connected with the second clamp 2019; a first receiving box 2020 is provided below the second clamp 2019; the first storage box 2020 is fixedly connected with two groups of first electric push rods 2021; the first electric putter 2021 is fixedly connected to the chassis 1.

Firstly, pouring a proper amount of peat soil into a first storage box 2020, pouring a proper amount of clean water into the first storage box 2020, floating a plurality of groups of wood sticks on the water surface, then driving the first storage box 2020 to move upwards simultaneously by two groups of first electric push rods 2021, immersing two thirds of a first clamp 2016 in water, driving a third slide 2014 and a fourth slide 2018 to move towards the middle by a second electric slide 2014 and a third electric slide 2017 respectively, driving the first clamp 2016 and the second clamp 2019 to move towards the middle by the third slide 2015 and the fourth slide 2018 respectively, fixing a plurality of groups of wood sticks on the water surface by the first clamp 2016 and the second clamp 2019, enabling the plurality of groups of wood sticks to be in the same direction, driving the first storage box 2020 to move downwards to return to the original position simultaneously by two groups of first electric push rods 2021, driving a first driving wheel 201 to rotate by an alignment assembly 3, the second driving wheel 202 drives the first loop bar 203 to drive the first prismatic bar 204 to rotate, the first prismatic bar 204 drives the first bevel gear 207 to rotate, then the first electric sliding rail 206 drives the first sliding block 205 to move upwards, the first sliding block 205 drives the first prismatic bar 204 to drive the first bevel gear 207 to move upwards, the first bevel gear 207 is meshed with the second bevel gear 208, then the first bevel gear 207 drives the second bevel gear 208 to drive the first lead screw 209 to rotate, the first lead screw 209 drives the second sliding block 2010 to move on the first guide rail block 2011 to move towards the second bevel gear 208, the second sliding block 2010 drives the components associated with the second sliding block 2010 to move above the alignment component 3, then the first electric sliding rail 206 drives the first sliding block 205 to move downwards to return to the original position, the first bevel gear 207 and the second bevel gear 208 are stopped from being meshed, then the first electric rotating shaft 2012 drives the first linkage block 2013 to rotate ninety degrees, the first linkage block 2013 drives the components associated with the first clamp 2016 and the second clamp 2019 to rotate ninety degrees, so that the first clamp 2016 and the second clamp 2019 rotate the plurality of groups of wood sticks by ninety degrees, at the moment, the plurality of groups of wood sticks are in a vertical state, then the second electric sliding rail 2014 and the third electric sliding rail 2017 respectively drive the third sliding block 2015 and the fourth sliding block 2018 to move to two sides, the first clamp 2016 and the second clamp 2019 are enabled to move to two sides to stop fixing the plurality of groups of wood sticks, the plurality of groups of wood sticks fall into the alignment component 3, and when the peat soil is used, the plurality of groups of wood sticks are automatically screened out, and the plurality of groups of wood sticks are transported to the alignment component 3 in a vertical state.

The alignment assembly 3 includes a first motor 301, a second sleeve rod 302, a second prismatic rod 303, a fifth sliding block 304, a fourth electric sliding rail 305, a third bevel gear 306, a fourth bevel gear 307, a first transmission rod 308, a first straight gear 309, a second straight gear 3010, a second transmission rod 3011, a correction mechanism 3012, a third transmission wheel 3013, a fourth transmission wheel 3014, a third transmission rod 3015, a fifth bevel gear 3016, a sixth bevel gear 3017, a third sleeve rod 3018, a third prismatic rod 3019, a sixth sliding block 3020, a seventh electric push rod 3021, and a first cam 3022; the output end of the first motor 301 is fixedly connected with the second loop bar 302; the first motor 301 is connected with the chassis 1; the second sleeve rod 302 is internally connected with a second prismatic rod 303; the outer surface of the second sleeve rod 302 is fixedly connected with a third transmission wheel 3013; the outer surface of the second sleeve rod 302 is rotationally connected with the underframe 1; the outer surface of the second prismatic rod 303 is rotationally connected with the fifth sliding block 304; the outer surface of the second prismatic rod 303 is fixedly connected with a third bevel gear 306; the fifth sliding block 304 is in sliding connection with the fourth electric sliding rail 305; the fourth electric slide rail 305 is fixedly connected with the chassis 1; a fourth bevel gear 307 is arranged below the third bevel gear 306; the inside of the fourth bevel gear 307 is fixedly connected with a first transmission rod 308; the outer surface of the first transmission rod 308 is fixedly connected with a first straight gear 309; the outer surface of the first transmission rod 308 is rotationally connected with the underframe 1; the first spur gear 309 meshes with the second spur gear 3010; the inside of the second straight gear 3010 is fixedly connected with a second transmission rod 3011; the second transmission rod 3011 is connected with the correcting mechanism 3012; the outer surface of the second transmission rod 3011 is rotationally connected with the underframe 1; the third transmission wheel 3013 is in transmission connection with the fourth transmission wheel 3014 through a belt; the inside of the fourth transmission wheel 3014 is fixedly connected with a third transmission rod 3015; the outer surface of the third transmission rod 3015 is fixedly connected with a fifth bevel gear 3016; the outer surface of the third transmission rod 3015 is rotationally connected with the underframe 1; the outer surface of the third transmission rod 3015 is fixedly connected with the first transmission wheel 201; the fifth bevel gear 3016 meshes with the sixth bevel gear 3017; the inside of the sixth bevel gear 3017 is fixedly connected with a third sleeve rod 3018; the inside of the third sleeve rod 3018 is connected with a third triangular rod 3019; the outer surface of the third sleeve rod 3018 is rotationally connected with the underframe 1; the outer surface of the third prism 3019 is rotationally connected with a sixth sliding block 3020; the third lever 3019 is fixedly connected to the first cam 3022; the sixth slider 3020 is fixedly connected to the seventh electric push rod 3021; the seventh power push rod 3021 is fixedly connected to the chassis 1.

When the screening assembly 2 stops fixing the multiple groups of wood sticks, the correction mechanism 3012 starts to work, multiple groups of wood sticks naturally fall into the correction mechanism 3012, then the first motor 301 drives the second sleeve rod 302 to rotate, the second sleeve rod 302 drives the third driving wheel 3013 to drive the fourth driving wheel 3014 to rotate, the fourth driving wheel 3014 drives the third driving rod 3015 to drive the fifth bevel gear 3016 to rotate, the third driving rod 3015 drives the screening assembly 2 to operate, the fifth bevel gear 3016 drives the sixth bevel gear 3017 to drive the third sleeve rod 3018 to rotate, the third sleeve rod 3018 drives the third triangular rod 3019 to drive the first cam 3022 to rotate, then the seventh electric push rod 3021 drives the sixth slider 3020 to move towards the correction mechanism 3012, the sixth slider 3020 drives the third triangular rod 3019 to drive the first cam 3022 to move towards the bottom of the correction mechanism 3012, then the first cam 3022 drives the correction mechanism 3012 to operate, the correction mechanism 3012 vibrates the multiple groups of wood sticks, the relative small wood sticks move towards the bottom, and the multiple groups of wood sticks bottom are aligned, then the fifth bevel gear 3022 drives the first motor 3027 to drive the third bevel gear 306 to move towards the bottom of the fourth bevel gear 306, then the fourth motor 3021 drives the fourth bevel gear 3022 to move towards the bottom of the fourth bevel gear 303, and then the fourth motor 3021 drives the fourth bevel gear 3022 to move towards the bottom of the fourth bevel gear 306, and then the fourth motor 3021 moves towards the fourth bevel gear 3021, and then the fourth motor 3021 moves towards the fourth bevel gear is rotated towards the fourth bevel gear, and then the fourth bevel gear 301 is rotated towards the fourth bevel gear, and then the third bevel gear is moved towards the third bevel gear, the first transmission rod 308 drives the first straight gear 309 to drive the second straight gear 3010 to rotate, the second straight gear 3010 drives the second transmission rod 3011 to drive the correcting mechanism 3012 to rotate by one hundred eighty degrees, then the fourth electric sliding rail 305 drives the fifth sliding block 304 to move back to the original position, the third bevel gear 306 is stopped to be meshed with the fourth bevel gear 307, then the above operation is repeated to vibrate the sticks to align the other ends of the multiple groups of sticks, and then the separating assembly 4 carries out reciprocating friction on the other ends of the multiple groups of sticks, so that charcoal on the other ends of the multiple groups of sticks is removed, charcoal on the sticks is removed completely, and when the wooden sticks are used, the wooden sticks which are relatively short and short are automatically separated and transported to the separating assembly 4 are also aligned at the two ends of the multiple groups of the sticks.

The correcting mechanism 3012 comprises a first connecting frame 301201, a first spring 301202, a first linkage frame 301203, a first limiting cylinder 301204, a first electric cover plate 301205, a second electric cover plate 301206, a second electric push rod 301207, a third electric push rod 301208, a third clamp 301209 and a fourth clamp 301210; the first connecting frame 301201 is fixedly connected with the first spring 301202; the first connecting frame 301201 is fixedly connected with the second transmission rod 3011; the first spring 301202 is fixedly connected to the first linkage frame 301203; the first linkage frame 301203 is fixedly connected with the first limiting cylinder 301204; the first linkage frame 301203 is fixedly connected with the second electric push rod 301207; the first linkage frame 301203 is fixedly connected with the third electric push rod 301208; the first limiting cylinder 301204 is connected with the first electric cover plate 301205; the first limiting cylinder 301204 is connected with the second electric cover plate 301206; second electric push rod 301207 is fixedly connected with fourth clamp 301210; third electric putter 301208 is fixedly coupled to third clamp 301209.

When the screening assembly 2 stops fixing the multiple groups of wood sticks, the first electric cover plate 301205 is opened, the multiple groups of wood sticks naturally fall into the first limiting cylinder 301204, then the first cam 3022 moves to the bottom of the second electric cover plate 301206, the second electric cover plate 301206 is pushed to move upwards when the first cam 3022 rotates, the second electric cover plate 301206 drives the first limiting cylinder 301206 to drive the first linkage frame 301206 to move upwards, the first linkage frame 301206 stretches four groups of first springs 301202 on the first connecting frame 301206, then the first cam 3022 continues to rotate to stop contacting with the second electric cover plate 301206, at the moment, the first springs 301202 drive the first linkage frame 301206 to drive the first limiting cylinder 301206 to move downwards, the first limiting cylinder 301206 drives the first electric cover plate 301206 and the second electric cover plate 301206 to vibrate the wood sticks in the first limiting cylinder 301206, the relatively short wood sticks fall onto the upper surface of the second electric cover plate 301206, at this time, the lower parts of the multiple groups of wood sticks are aligned, then the second electric push rod 301206 and the third electric push rod 301206 respectively drive the fourth clamp 301206 and the third clamp 301206 to move towards the middle part, so that the fourth clamp 301206 and the third clamp 301206 simultaneously fix the multiple groups of wood sticks, the first cam 3022 is far away from the bottom of the second electric cover plate 301206, then the second electric cover plate 301206 is opened, the relatively short wood sticks naturally fall into the separating assembly 4, the separating assembly 4 performs reciprocating friction on the bottoms of the multiple groups of wood sticks, thereby removing charcoal at the bottoms of the multiple groups of wood sticks, the second electric cover plate 301206 is closed, the second electric push rod 301206 and the third electric push rod 301206 respectively drive the fourth clamp 301206 and the third clamp 301206 to move back to the original positions, then the second transmission rod 3011 drives the first connection frame 301206 to rotate for one hundred eighty degrees, the first connection frame 301206 drives the components associated with the first connection frame to rotate for one hundred eighty degrees, then the operations are repeated to vibrate the wood sticks, the other ends of the plurality of groups of wood sticks are aligned, and then the separation assembly 4 carries out reciprocating friction on the other ends of the plurality of groups of wood sticks, so that charcoal on the other ends of the plurality of groups of wood sticks is removed, the charcoal on the wood sticks is removed completely, and the purpose that the plurality of groups of wood sticks are automatically driven to rotate by one hundred eighty degrees is achieved when the wood stick is used, so that the wood stick is simple in structure and maintenance.

The separation assembly 4 comprises a fourth electric push rod 401, a second linkage block 402, a first push plate 403, a fifth electric push rod 404, a first steel brush block 405, a sixth electric push rod 406, a second steel brush block 407, a fifth electric sliding rail 408, a seventh sliding block 409, a third linkage block 4010, a second storage box 4011 and a third storage box 4012; the fourth electric push rod 401 is fixedly connected with the second linkage block 402; the fourth electric push rod 401 is fixedly connected with the underframe 1; the second linkage block 402 is fixedly connected with the first push plate 403; the second linkage block 402 is fixedly connected with the fifth electric push rod 404; the second linkage block 402 is fixedly connected with a sixth electric push rod 406; the fifth electric push rod 404 is fixedly connected with the first steel brush block 405; the sixth electric push rod 406 is fixedly connected with the second steel brush block 407; a fifth electric sliding rail 408 is arranged below the side edge of the second steel brush block 407; the fifth electric sliding rail 408 is in sliding connection with a seventh sliding block 409; the fifth electric sliding rail 408 is fixedly connected with the chassis 1; the seventh sliding block 409 is fixedly connected with the third linkage block 4010; the third linkage block 4010 is fixedly connected with the second storage box 4011; the third linkage block 4010 is fixedly connected to the third housing box 4012.

The alignment assembly 3 separates out relatively short wood sticks and enables the wood sticks to naturally fall into the third storage box 4012, then the fifth electric sliding rail 408 drives the seventh sliding block 409 to drive the third linkage block 4010 to move, the third linkage block 4010 simultaneously drives the second storage box 4011 and the third storage box 4012 to move, the second storage box 4011 is enabled to move to the initial position of the third storage box 4012, then the alignment assembly 3 aligns the lower parts of the multiple groups of wood sticks, then the fourth electric push rod 401 drives the second linkage block 402 to move towards the alignment assembly 3, the second linkage block 402 drives the components associated with the second linkage block to move towards the alignment assembly 3, the first push plate 403 is inserted into the middle of the multiple groups of wood sticks, the first steel brush block 405 and the second steel brush block 407 are respectively located on two sides of the multiple groups of wood sticks, then the fifth electric push rod 404 and the sixth electric push rod 406 respectively drive the first steel brush block 405 and the second steel brush block 407 to reciprocate, the first steel brush block 405 and the second steel brush block 407 to reciprocate to rub the bottoms of the multiple groups of wood sticks, the wood sticks are enabled to reciprocate, the wood sticks are removed from the wood sticks, the two ends of the wood sticks are removed by the wood sticks, and the wood sticks are removed by the opposite to the other sides by the opposite direction, and the wood sticks are removed by the opposite to the opposite direction, and the wood sticks, and the charcoal is removed by the opposite to the opposite direction.

The first clamp 2016 is provided with two semicircular rings, the second clamp 2019 is provided with three semicircular rings at equal intervals, and the two semicircular rings of the first clamp 2016 are aligned with the gaps of the three semicircular rings of the second clamp 2019, respectively.

After the first clamp 2016 and the second clamp 2019 are moved toward each other, the first clamp 2016 and the second clamp 2019 can clamp different numbers of sticks without interference.

The first springs 301202 are arranged in a circular array of four groups.

The first linkage frame 301203 can be driven to vibrate at the same time, so that the stability is improved.

The steel wire head of the second steel brush block 407 is provided with a metal ball.

The damage to the wooden stick wooden parts by the second steel brush block 407 can be reduced.

It will be appreciated by persons skilled in the art that the above embodiments are not intended to limit the invention in any way, and that all technical solutions obtained by means of equivalent substitutions or equivalent transformations fall within the scope of the invention.

Claims (4)

1. The positive and negative pyrophyllite nutrient soil batching processing device comprises a bottom frame (1) and a control screen (5), and is characterized by further comprising a screening component (2), an alignment component (3) and a separation component (4); the underframe (1) is connected with the screening component (2); the underframe (1) is connected with the alignment assembly (3); the underframe (1) is connected with the separation assembly (4); the underframe (1) is connected with the control screen (5); the screening component (2) is connected with the alignment component (3);

the screening assembly (2) comprises a first driving wheel (201), a second driving wheel (202), a first sleeve rod (203), a first prismatic rod (204), a first sliding block (205), a first electric sliding rail (206), a first bevel gear (207), a second bevel gear (208), a first screw rod (209), a second sliding block (2010), a first guide rail block (2011), a first electric rotating shaft (2012), a first linkage block (2013), a second electric sliding rail (2014), a third sliding block (2015), a first clamp (2016), a third electric sliding rail (2017), a fourth sliding block (2018), a second clamp (2019), a first storage box (2020) and a first electric push rod (2021); the first driving wheel (201) is in driving connection with the second driving wheel (202) through a belt; the first driving wheel (201) is internally connected with the alignment assembly (3); the inside of the second driving wheel (202) is fixedly connected with the first sleeve rod (203); the inside of the first sleeve rod (203) is connected with a first prismatic rod (204); the outer surface of the first sleeve rod (203) is rotationally connected with the underframe (1); the outer surface of the first prismatic rod (204) is rotationally connected with the first sliding block (205); the outer surface of the first prismatic rod (204) is fixedly connected with a first bevel gear (207); the first sliding block (205) is in sliding connection with the first electric sliding rail (206); the first electric sliding rail (206) is fixedly connected with the underframe (1); a second bevel gear (208) is arranged above the first bevel gear (207); the inside of the second bevel gear (208) is fixedly connected with the first screw rod (209); the outer surface of the first screw rod (209) is screwed with the second sliding block (2010); the outer surface of the first screw rod (209) is rotationally connected with a first guide rail block (2011); the second sliding block (2010) is in sliding connection with the first guide rail block (2011); the second sliding block (2010) is fixedly connected with the first electric rotating shaft (2012); the first guide rail block (2011) is fixedly connected with the underframe (1); the first electric rotating shaft (2012) is fixedly connected with the first linkage block (2013); the first linkage block (2013) is fixedly connected with the second electric sliding rail (2014); the first linkage block (2013) is fixedly connected with a third electric sliding rail (2017); the second electric sliding rail (2014) is in sliding connection with the third sliding block (2015); the third slide block (2015) is fixedly connected with the first clamp (2016); the third electric sliding rail (2017) is in sliding connection with the fourth sliding block (2018); the fourth sliding block (2018) is fixedly connected with the second clamp (2019); a first storage box (2020) is arranged below the second clamp (2019); the first storage box (2020) is fixedly connected with the two groups of first electric push rods (2021); the first electric push rod (2021) is fixedly connected with the underframe (1);

the alignment assembly (3) comprises a first motor (301), a second loop bar (302), a second prismatic bar (303), a fifth sliding block (304), a fourth electric sliding rail (305), a third bevel gear (306), a fourth bevel gear (307), a first transmission bar (308), a first straight gear (309), a second straight gear (3010), a second transmission bar (3011), a correction mechanism (3012), a third transmission wheel (3013), a fourth transmission wheel (3014), a third transmission bar (3015), a fifth bevel gear (3016), a sixth bevel gear (3017), a third loop bar (3018), a third prismatic bar (3019), a sixth sliding block (3020), a seventh electric push bar (3021) and a first cam (3022); the output end of the first motor (301) is fixedly connected with the second sleeve rod (302); the first motor (301) is connected with the underframe (1); the inside of the second sleeve rod (302) is connected with a second prismatic rod (303); the outer surface of the second sleeve rod (302) is fixedly connected with a third driving wheel (3013); the outer surface of the second sleeve rod (302) is rotationally connected with the underframe (1); the outer surface of the second prismatic rod (303) is rotationally connected with a fifth sliding block (304); the outer surface of the second prismatic rod (303) is fixedly connected with a third bevel gear (306); the fifth sliding block (304) is in sliding connection with the fourth electric sliding rail (305); the fourth electric sliding rail (305) is fixedly connected with the underframe (1); a fourth bevel gear (307) is arranged below the third bevel gear (306); the inside of the fourth bevel gear (307) is fixedly connected with a first transmission rod (308); the outer surface of the first transmission rod (308) is fixedly connected with a first straight gear (309); the outer surface of the first transmission rod (308) is rotationally connected with the underframe (1); the first straight gear (309) is meshed with the second straight gear (3010); the inside of the second straight gear (3010) is fixedly connected with a second transmission rod (3011); the second transmission rod (3011) is connected with the correction mechanism (3012); the outer surface of the second transmission rod (3011) is rotationally connected with the underframe (1); the third transmission wheel (3013) is in transmission connection with the fourth transmission wheel (3014) through a belt; the inside of the fourth driving wheel (3014) is fixedly connected with a third driving rod (3015); the outer surface of the third transmission rod (3015) is fixedly connected with a fifth bevel gear (3016); the outer surface of the third transmission rod (3015) is rotationally connected with the underframe (1); the outer surface of the third transmission rod (3015) is fixedly connected with the first transmission wheel (201); the fifth bevel gear (3016) is meshed with the sixth bevel gear (3017); the inside of the sixth bevel gear (3017) is fixedly connected with a third sleeve rod (3018); the inside of the third sleeve rod (3018) is connected with a third triangular rod (3019); the outer surface of the third sleeve rod (3018) is rotationally connected with the underframe (1); the outer surface of the third prism (3019) is rotationally connected with a sixth sliding block (3020); the third prism (3019) is fixedly connected with the first cam (3022); the sixth sliding block (3020) is fixedly connected with the seventh electric push rod (3021); the seventh electric push rod (3021) is fixedly connected with the underframe (1);

the correcting mechanism (3012) comprises a first connecting frame (301201), a first spring (301202), a first linkage frame (301203), a first limiting cylinder (301204), a first electric cover plate (301205), a second electric cover plate (301206), a second electric push rod (301207), a third electric push rod (301208), a third clamp (301209) and a fourth clamp (301210); the first connecting frame (301201) is fixedly connected with the first spring (301202); the first connecting frame (301201) is fixedly connected with the second transmission rod (3011); the first spring (301202) is fixedly connected with the first linkage frame (301203); the first linkage frame (301203) is fixedly connected with the first limit cylinder (301204); the first linkage frame (301203) is fixedly connected with the second electric push rod (301207); the first linkage frame (301203) is fixedly connected with the third electric push rod (301208); the first limiting cylinder (301204) is connected with the first electric cover plate (301205); the first limit cylinder (301204) is connected with the second electric cover plate (301206); the second electric push rod (301207) is fixedly connected with the fourth clamp (301210); the third electric push rod (301208) is fixedly connected with the third clamp (301209);

the separation assembly (4) comprises a fourth electric push rod (401), a second linkage block (402), a first push plate (403), a fifth electric push rod (404), a first steel brush block (405), a sixth electric push rod (406), a second steel brush block (407), a fifth electric sliding rail (408), a seventh sliding block (409), a third linkage block (4010), a second storage box (4011) and a third storage box (4012); the fourth electric push rod (401) is fixedly connected with the second linkage block (402); the fourth electric push rod (401) is fixedly connected with the underframe (1); the second linkage block (402) is fixedly connected with the first push plate (403); the second linkage block (402) is fixedly connected with a fifth electric push rod (404); the second linkage block (402) is fixedly connected with a sixth electric push rod (406); the fifth electric push rod (404) is fixedly connected with the first steel brush block (405); the sixth electric push rod (406) is fixedly connected with the second steel brush block (407); a fifth electric sliding rail (408) is arranged below the side edge of the second steel brush block (407); the fifth electric sliding rail (408) is in sliding connection with the seventh sliding block (409); the fifth electric sliding rail (408) is fixedly connected with the underframe (1); the seventh sliding block (409) is fixedly connected with the third linkage block (4010); the third linkage block (4010) is fixedly connected with the second storage box (4011); the third linkage block (4010) is fixedly connected with the third storage box (4012).

2. A positive and negative pyrophyllite nutrient soil batching processing device as claimed in claim 1, characterized in that the first clamp (2016) is provided with two semicircular rings, the second clamp (2019) is provided with three semicircular rings at equal intervals, and the two semicircular rings of the first clamp (2016) are aligned with the gaps of the three semicircular rings of the second clamp (2019), respectively.

3. A positive and negative pyrophyllite nutrient soil proportioning device as claimed in claim 2, characterized in that the first springs (301202) are arranged in a circular array of four groups.

4. A positive and negative pyrophyllite nutrient soil batching processing device according to claim 3, characterized in that the steel wire head of the second steel brush block (407) is provided with metal balls.

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