CN115674481A

CN115674481A - Polymer sand processingequipment based on clamp plate method

Info

Publication number: CN115674481A
Application number: CN202211293799.9A
Authority: CN
Inventors: 曾斯维; 朱杰; 周宽; 吴帅
Original assignee: Jiangxi Yinshan White Cement Co ltd
Current assignee: Jiangxi Yinshan White Cement Co ltd
Priority date: 2022-10-21
Filing date: 2022-10-21
Publication date: 2023-02-03

Abstract

The invention discloses a macromolecular sand processing device based on a plate pressing method, which adopts the technical scheme that: the mixing box is arranged in the shell, the bottom end of the mixing box extends to the outer side of the bottom of the shell, the mixing box is connected with the shell through a bearing, an auxiliary mechanism is arranged in the shell and comprises a cylinder, the cylinder is connected to the top of the mixing box and connected with the mixing box through a sealing bearing, a fixing plate is fixedly connected in the shell, and the fixing plate is fixedly sleeved outside the cylinder, and the mixing box has the advantages that: realize the puddler and rotate at the inside limit circular motion limit of mixing box, the rotor plate pivoted in addition under the design of lug, annular plate and spring the rotor plate still can be continuous reciprocates, just so can make the continuous reciprocating of puddler, and then realize the puddler reciprocating when the inside limit circular motion limit of mixing box is rotating, just can increase the stirring effect to the material, thereby avoid appearing the dead angle that the stirring was mixed.

Description

Polymer sand processingequipment based on clamp plate method

Technical Field

The invention relates to the technical field of polymer sand processing, in particular to a polymer sand processing device based on a plate pressing method.

Background

The polymer sand is a main raw material for producing the inorganic artificial stone plate, most of the inorganic artificial stone plate is produced by a plate pressing method when the inorganic artificial stone plate is produced, powder (cement, silica powder and the like), additives and pigments are required to be added into the polymer sand for mixing and stirring when the inorganic artificial stone plate is produced, then the mixture is put into a plate pressing method die, then a forming press is used for pressing the inorganic artificial stone plate to form the inorganic artificial stone plate, a processing device of the polymer sand is required when the plate pressing method is used for producing the inorganic artificial stone plate, and the polymer sand, the powder, the additives and the pigments are stirred and mixed by the processing device;

the existing polymer sand processing device has a certain stirring dead angle when stirring polymer sand, powder, additives and pigments, so that the phenomenon of uneven mixing can occur, secondary stirring and mixing are needed, and the production efficiency of the inorganic artificial stone plate can be influenced by the secondary mixing, so that improvement is needed;

therefore, the invention is necessary to provide a polymer sand processing device based on a plate pressing method.

Disclosure of Invention

Therefore, the invention provides a macromolecular sand processing device based on a plate pressing method, which solves the problems in the background technology through the design of an auxiliary mechanism.

In order to achieve the above purpose, the invention provides the following technical scheme: a high polymer sand processing device based on a plate pressing method comprises a shell, wherein a mixing box is arranged in the shell, the bottom end of the mixing box extends to the outer side of the bottom of the shell, the mixing box is connected with the shell through a bearing, and an auxiliary mechanism is arranged in the shell;

the auxiliary mechanism comprises a cylinder, the cylinder is connected to the top of the mixing box and is connected with the mixing box through a sealed bearing, a fixed plate is fixedly connected inside the shell, the fixed plate is fixedly sleeved outside the cylinder, a movable plate is arranged inside the shell in a sliding mode and is located at the top of the cylinder, a first cavity is formed inside the movable plate, a rotating plate is arranged on the inner sides of the movable plate and the cylinder, the top end of the rotating plate penetrates through the cavity and extends to the outer side of the top of the movable plate, the rotating plate is connected with the movable plate through the sealed bearing, a second cavity is formed inside the rotating plate, a first rotating shaft and a second rotating shaft are arranged inside the second cavity, the bottom ends of the first rotating shaft and the second rotating shaft extend into the mixing box, the first rotating shaft and the second rotating shaft are fixedly embedded with the first box bodies, and the first rotating shaft and the second rotating shaft are linearly distributed up and down, four first box bodies are all internally and slidably provided with two stirring rods, the outer ends of the two stirring rods respectively extend to the outer parts of two sides of the first box body, one side of the rotating plate is fixedly connected with an L-shaped support, the L-shaped support is in contact with the top of the first cavity and is in sliding connection with the top of the first cavity, one side of the L-shaped support is fixedly connected with a motor, an output shaft of the motor is fixedly connected with a third rotating shaft, one end of the third rotating shaft extends to the inner part of the second cavity, the outer part of the third rotating shaft is fixedly sleeved with a first bevel gear, the first bevel gear is positioned in the first cavity, the bottom of the first cavity is fixedly connected with a first bevel gear ring, the first bevel gear is positioned at the top of the first bevel gear and is meshed with the first bevel gear ring, a first driving component is arranged between the third rotating shaft and the first rotating shaft, a second driving component is arranged between the first rotating shaft and the second rotating shaft, the bottom of the rotating plate is fixedly connected with two arc-shaped plates, and the two arc-shaped plates are annular, the improved cylinder structure comprises a cylinder, and is characterized in that two convex blocks are fixedly connected to the top of the cylinder and respectively contacted with two arc-shaped plates, two springs are fixedly connected to the inner sides of a movable plate and a fixed plate and respectively located on two sides of the cylinder, an auxiliary assembly is arranged at the top of the rotary plate and respectively extends to the insides of a first rotating shaft and a second rotating shaft, a plurality of connecting rods are fixedly sleeved on the outer portion of a mixing box and are uniformly distributed in a circumferential mode, and rotating assemblies and two rotating assemblies are arranged on two sides of the mixing box and are distributed in mirror symmetry.

Preferably, the bottom of the rotating plate is fixedly connected with two U-shaped supports, the first rotating shaft and the second rotating shaft are distributed and penetrate through the two U-shaped supports, the first sliding block is fixedly connected to the top of the L-shaped support, the first sliding groove is formed in the top of the cavity, the first sliding block is embedded in the first sliding groove and is in sliding connection with the first sliding groove, the first sliding groove is annular, the first rotating shaft is connected with the rotating plate and the U-shaped supports through sealing bearings, and the second rotating shaft is connected with the rotating plate and the U-shaped supports through sealing bearings.

Preferably, drive assembly one includes bevel gear two and bevel gear three, two fixed connection of bevel gear are in three one end of pivot, three fixed cover of bevel gear are established in pivot one outside, bevel gear three is located two one sides of bevel gear and meshes with bevel gear two, drive assembly two includes two sprocket and chain, two the sprocket is fixed the cover respectively and is established in pivot one and two outsides of pivot, the chain cover is established in two sprocket outsides, two connect through chain drive between the sprocket, pivot three is connected through sealed bearing with the rotor plate.

Preferably, the auxiliary assembly comprises two box bodies two, two box body two are fixedly connected to the top of the rotating plate, a first pipeline is arranged inside the box body two and close to the motor, one end of the first pipeline penetrates through the rotating shaft and extends to the inside of one of the box bodies inside the rotating shaft, a second pipeline is arranged inside the box body two and far away from the motor, one end of the second pipeline penetrates through the rotating shaft and extends to the inside of one of the box bodies inside the rotating shaft, the rotating shaft I and the rotating shaft two are fixedly embedded with a third pipeline, two ends of the third pipeline respectively extend to the inside of the two box bodies and are fixedly connected with the box body I, the first pipeline is fixedly connected with the box body II, the rotating shaft I and the box body I, and the rotating shaft II are fixedly connected with the box body II, the rotating shaft II and the box body I.

Preferably, four the first inside of the box body all slides and is equipped with two pistons one and two pistons two respectively fixed connection at two puddler the inner, two the second inside of the box body all slides and is equipped with piston two, two the equal fixedly connected with reciprocating screw in the two outsides of piston two, two reciprocating screw outer end extends to the two outsides of two boxes respectively, two reciprocating screw outside all overlaps and is equipped with the sliding seat, the sliding seat passes through ball screw pair with reciprocating screw and is connected, two the sliding seat inlays respectively to be established in two outsides of two boxes and the sliding seat is connected with two box outsides of two through sealed bearings, movable plate top fixedly connected with awl ring gear two, two the equal fixed cover in sliding seat outside is equipped with bevel gear four, two bevel gear four all is located two tops of awl ring gears and meshes with awl ring gear two.

Preferably, two equal fixedly connected with gag lever post in two tops of box, two the gag lever post outside all slides the cover and is equipped with stopper, two the stopper respectively with two reciprocal lead screw top fixed connection, the equal fixedly connected with slider two in movable plate both sides, spout two has all been seted up to shell both sides inner wall, slider two inlays to be established inside spout two and with spout two sliding connection.

Preferably, rotating assembly includes box three, three fixed connection of box are in the fixed plate bottom, three inside slips of box are equipped with piston three, three top fixedly connected with push rods of piston, the push rod top runs through fixed plate and spring and fixed connection in the movable plate bottom, the through-hole has been seted up to shell one side, shell one side outside is equipped with box four, four one ends of box extend to the through-hole inside and with through-hole fixed connection, three inside pipelines four of being equipped with of box, four one end of pipeline extend to four inside and pipelines four and three and four equal fixed connection of box, four inside slips of box are equipped with piston four, four one end fixedly connected with movable box of piston, movable box one end extends to inside the shell, four inside fixedly connected with fixed blocks of box, movable box run through the fixed block and with fixed block sliding connection.

Preferably, the helicla flute has been seted up to the mobile box inner wall, the mobile box is inside to be rotated and is connected with pivot four, four one ends in pivot extend to mixing box one side, four balls of four outside fixedly connected with in pivot four, four the ball is the heliciform and distributes, four the ball all slides and establishes inside the helicla flute, the four outside covers in pivot are equipped with the sleeve, the sleeve crosses one-way bearing with the pivot cross-section and is connected, the outside fixed cover of sleeve is equipped with a plurality of driving levers and a plurality of driving lever are circumference form evenly distributed, driving lever and connecting rod cross distribution, two firm poles of shell bottom inner wall fixedly connected with and two firm poles are located the sleeve both sides respectively, pivot four runs through two firm poles and passes through the bearing with firm pole and is connected.

Preferably, the inside fixed feeder hopper that is equipped with of rotor plate, the feeder hopper is located two rear sides of cavity, the mixing box bottom outside is equipped with the discharging pipe, the discharging pipe top extend to the mixing box inside and with mixing box fixed connection, the discharging pipe outside is equipped with the ooff valve, the mixing box bottom sets up to the slope form, the shell inlays and is equipped with the chamber door, the chamber door passes through hinge connection with the shell, logical groove has been seted up at the shell top.

Preferably, an auxiliary plate is fixedly sleeved outside the shell and fixedly connected with the box body, and supporting legs are fixedly connected to four corners of the bottom of the auxiliary plate.

The invention has the beneficial effects that:

1. according to the invention, the rotating shaft III can rotate through the work of the motor, the rotating shaft III rotates to drive the bevel gear I to rotate, and the bevel gear I is fixedly connected to the bottom of the cavity I, so that the rotating plate rotates when the bevel gear I rotates, the rotating shaft I and the rotating shaft II perform circular motion in the mixing box, and the rotating shaft I and the rotating shaft II can also rotate under the design of the driving assembly I and the driving assembly II, so that the stirring rod can rotate, the stirring rod rotates while performing circular motion in the mixing box, and the rotating plate can also continuously move up and down under the design of a bump, an annular plate and a spring while rotating, so that the stirring rod can continuously move up and down, the stirring rod can further move up and down while rotating while performing circular motion in the mixing box, the stirring effect on materials can be increased, and the dead angle of stirring and mixing can be avoided;

2. according to the invention, through the design of the reciprocating screw rod, the sliding seat, the piston II, the pipeline I, the pipeline II, the pipeline III and the like, the air can be inflated and exhausted into the four box bodies I, so that the piston I can continuously move in the box bodies I, and the stirring rod can continuously contract in the box bodies I, so that the stirring quality can be increased when materials are stirred, and the stirring efficiency is increased;

3. the push rod can also move when the movable plate continuously moves up and down, so that the piston III can continuously move up and down, then the four inner parts of the box body can be continuously inflated and blown under the design of the pipeline IV, and further the piston IV can move in the four inner parts of the box body, so that the movable box can move, then the rotating shaft IV can rotate back and forth under the design of the spiral groove and the ball, the rotating shaft IV rotates back and forth to drive the sleeve to rotate, because the sleeve and the rotating shaft IV are connected through the one-way bearing, the sleeve can rotate towards one direction when rotating, then the mixing box can rotate under the design of the shift lever and the connecting rod, and the rotating direction is opposite to the rotating direction of the rotating plate, so that the materials can be stirred and mixed at one time, secondary stirring and mixing are not needed, so that the stirring and mixing time can be reduced, and the production efficiency of the inorganic artificial stone plate is increased.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structures, ratios, sizes, and other characteristics of the present invention are only used for matching the content disclosed in the specification, so that those skilled in the art can understand and read the present invention, and the present invention is not limited by the conditions that the present invention can be implemented, so that the present invention has no technical essence, and any structural modification, ratio relationship change or size adjustment should still fall within the range that the technical content disclosed in the present invention can cover without affecting the efficacy and the achievable purpose of the present invention

FIG. 1 is a schematic view of the overall structure provided by the present invention;

FIG. 2 is a front cross-sectional view provided by the present invention;

FIG. 3 is an enlarged view taken at A in FIG. 2 according to the present invention;

FIG. 4 is an enlarged view of the invention at B of FIG. 2;

FIG. 5 is an enlarged view at C of FIG. 2 according to the present invention;

FIG. 6 is an enlarged view taken at D of FIG. 2 in accordance with the present invention;

FIG. 7 is an enlarged view at E of FIG. 2 according to the present invention;

FIG. 8 is a perspective view of the rotating plate, annular plate and feed hopper provided by the present invention;

FIG. 9 is a perspective cross-sectional view of FIG. 8 provided by the present invention;

FIG. 10 is a perspective cross-sectional view of a fourth spindle, a ball, a helical groove, and a traveling box according to the present invention;

FIG. 11 is a perspective view of the mixing box, the connecting pipe, the fourth rotating shaft, the sleeve and the shifting rod provided by the present invention;

in the figure: 1 shell, 2 mixing box, 3 cylinder, 4 fixing plate, 5 moving plate, 6 rotating plate, 7 rotating shaft I, 8 rotating shaft II, 9 box I, 10 stirring rod, 11L-shaped bracket, 12 motor, 13 rotating shaft III, 14 bevel gear I, 15 bevel gear I, 16 arc-shaped plate, 17 lug, 18 spring, 19 connecting rod, 20U-shaped bracket, 21 slide block I, 22 bevel gear II, 23 bevel gear III, 24 chain wheel, 25 chain, 26 box II, 27 pipeline I, 28 pipeline II, 29 pipeline III, 30 piston I, 31 piston II, 32 reciprocating lead screw, 33 sliding seat, 34 bevel gear II, 35 bevel gear IV, 36 limiting rod, 37 limiting block, 38 slide block II, 39 box III, 40 piston III, 41 push rod, 42 box IV, 43 pipeline IV, 44 piston IV, 45 moving box, 46, 47 spiral groove, 48 rotating shaft IV, 49 ball, 50 sleeve, 51 driving rod, 52 stabilizing rod, 53 feeding hopper, 54 discharging pipe, 55 switch valve, 56 box door, 57 auxiliary plate, 58 auxiliary supporting leg.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it should be understood that they are presented herein only to illustrate and explain the present invention and not to limit the present invention.

Referring to the attached drawings 1-11, the invention provides a high polymer sand processing device based on a plate pressing method, which comprises a shell 1, wherein a mixing box 2 is arranged in the shell 1, the bottom end of the mixing box 2 extends to the outer side of the bottom of the shell 1, the mixing box 2 is connected with the shell 1 through a bearing, and an auxiliary mechanism is arranged in the shell 1;

the auxiliary mechanism comprises a cylinder 3, the cylinder 3 is connected to the top of a mixing box 2 and is connected with the mixing box 2 through a sealed bearing, a fixed plate 4 is fixedly connected inside a shell 1, the fixed plate 4 is fixedly sleeved outside the cylinder 3, a moving plate 5 is arranged inside the shell 1 in a sliding mode and is located at the top of the cylinder 3, a first cavity is formed inside the moving plate 5, a rotating plate 6 is arranged on the inner sides of the moving plate 5 and the cylinder 3, the top end of the rotating plate 6 penetrates through the cavity and extends to the outer side of the top of the moving plate 5, the rotating plate 6 is connected with the moving plate 5 through the sealed bearing, a second cavity is formed inside the rotating plate 6, a first rotating shaft 7 and a second rotating shaft 8 are arranged inside the second cavity, the bottom ends of the first rotating shaft 7 and the second rotating shaft 8 extend into the mixing box 2, the first rotating shaft 7 and the second rotating shaft 8 are fixedly embedded with two first box bodies 9, and the first box bodies 9 are vertically and linearly distributed, two stirring rods 10 are arranged inside the four first box bodies 9 in a sliding mode, the outer ends of the two stirring rods 10 extend to the outer portions of two sides of the first box bodies 9 respectively, one side of the rotating plate 6 is fixedly connected with an L-shaped support 11, the L-shaped support 11 is in contact with the top of the first cavity and is in sliding connection with the top of the first cavity, one side of the L-shaped support 11 is fixedly connected with a motor 12, an output shaft of the motor 12 is fixedly connected with a third rotating shaft 13, one end of the third rotating shaft 13 extends to the inner portion of the second cavity, a first bevel gear 14 is fixedly sleeved outside the third rotating shaft 13, the first bevel gear 14 is located inside the first cavity, a first bevel gear ring 15 is fixedly connected to the bottom of the first cavity, the first bevel gear 14 is located at the top of the first bevel gear 14 and is meshed with the first bevel gear ring 15, a first driving assembly is arranged between the third rotating shaft 13 and the first rotating shaft 7, a second driving assembly is arranged between the first rotating shaft 7 and the second rotating shaft 8, two arc plates 16 are fixedly connected to the bottom of the rotating plate 6, and the two arc plates 16 are annular, the top of the cylinder 3 is fixedly connected with two convex blocks 17, the two convex blocks 17 are respectively contacted with two arc-shaped plates 16, the inner sides of the movable plate 5 and the fixed plate 4 are fixedly connected with two springs 18, the two springs 18 are respectively positioned at two sides of the cylinder 3, the top of the rotating plate 6 is provided with an auxiliary component, the auxiliary component respectively extends into the rotating shaft I7 and the rotating shaft II 8, the outer part of the mixing box 2 is fixedly sleeved with a plurality of connecting rods 19, the connecting rods 19 are uniformly distributed in a circumferential shape, the two sides of the mixing box 2 are both provided with rotating components, the two rotating components are distributed in mirror symmetry, the bottom of the rotating plate 6 is fixedly connected with two U-shaped brackets 20, the rotating shaft I7 and the rotating shaft II 8 are distributed to penetrate through the two U-shaped brackets 20, the top of the L-shaped bracket 11 is fixedly connected with a slide block I21, the top of the cavity I is provided with a slide groove I, the first sliding block 21 is embedded in the first sliding groove and is in sliding connection with the first sliding groove, the first sliding groove is annular, the first rotating shaft 7 is connected with the rotating plate 6 and the U-shaped support 20 through sealing bearings, the second rotating shaft 8 is connected with the rotating plate 6 and the U-shaped support 20 through sealing bearings, the first driving assembly comprises a second bevel gear 22 and a third bevel gear 23, the second bevel gear 22 is fixedly connected to one end of the third rotating shaft 13, the third bevel gear 23 is fixedly sleeved outside the first rotating shaft 7, the third bevel gear 23 is located on one side of the second bevel gear 22 and is meshed with the second bevel gear 22, the second driving assembly comprises two chain wheels 24 and a chain 25, the two chain wheels 24 are fixedly sleeved outside the first rotating shaft 7 and the second rotating shaft 8 respectively, the chain 25 is sleeved outside the two chain wheels 24, the two chain wheels 24 are in driving connection through the chain 25, and the third rotating shaft 13 is connected with the rotating plate 6 through sealing bearings;

in this embodiment, the motor 12 can rotate the third rotating shaft 13 when operating, the third rotating shaft 13 rotates to drive the first bevel gear 14 to rotate, the first bevel gear 14 is fixedly connected to the bottom of the first cavity, so that the rotating plate 6 rotates when the first bevel gear 14 rotates, so that the first rotating shaft 7 and the second rotating shaft 8 perform circular motion inside the mixing box 2, and the first rotating shaft 7 and the second rotating shaft 8 can also rotate under the design of the first driving assembly and the second driving assembly, so that the stirring rod 10 can rotate, so that the stirring rod 10 rotates while performing circular motion inside the mixing box 2, and the rotating plate 6 can continuously move up and down under the design of the projection 17, the annular plate and the spring 18 while rotating, so that the stirring rod 10 can continuously move up and down, thereby realizing that the stirring rod 10 moves up and down while rotating during circular motion inside the mixing box 2, increasing the stirring effect on materials, and avoiding dead angles of stirring and mixing.

Wherein, in order to realize the purpose that puddler 10 constantly contracts, this device adopts following technical scheme to realize: the auxiliary assembly comprises two box bodies 26, the two box bodies 26 are fixedly connected to the top of the rotating plate 6, a first pipeline 27 is arranged inside the box body 26 close to the motor 12, one end of the first pipeline 27 penetrates through the rotating shaft I7 and extends into one box body I9 inside the rotating shaft I7, a second pipeline 28 is arranged inside the box body 26 far away from the motor 12, one end of the second pipeline 28 penetrates through the rotating shaft II 8 and extends into one box body I9 inside the rotating shaft II 8, a third pipeline 29 is fixedly embedded inside the rotating shaft I7 and the rotating shaft II 8, two ends of the third pipeline 29 respectively extend into the two box bodies I9 and are fixedly connected with the box bodies I9, the first pipeline 27 is fixedly connected with the box bodies II 26, the rotating shaft I7 and the box bodies I9, the rotating shaft II 8 is fixedly connected with the box bodies II 26, the rotating shaft II 8 and the box bodies I9, two pistons I30 are arranged inside the four box bodies I9 in a sliding mode, and two pistons II 31 are respectively and fixedly connected to the inner ends of the two stirring rods 10, the two pistons 31 are arranged inside the two second boxes 26 in a sliding manner, the outer sides of the two pistons 31 are fixedly connected with reciprocating screw rods 32, the outer ends of the two reciprocating screw rods 32 extend to the outer sides of the two second boxes 26 respectively, sliding seats 33 are sleeved outside the two reciprocating screw rods 32 respectively, the sliding seats 33 are connected with the reciprocating screw rods 32 through ball 49 screw pairs, the two sliding seats 33 are embedded outside the two second boxes 26 respectively, the sliding seats 33 are connected with the second boxes 26 through sealing bearings, the top of the moving plate 5 is fixedly connected with a bevel gear ring two 34, bevel gear four 35 are fixedly sleeved outside the two sliding seats 33, the two bevel gear four 35 are positioned at the top of the bevel gear ring two 34 and meshed with the bevel gear ring two 34, and the four boxes 9 can be inflated and exhausted through the design of the reciprocating screw rods 32, the sliding seats 33, the two pistons 31, the first pipeline 27, the second pipeline 28, the third pipeline 29 and other components, therefore, the first piston 30 can move continuously in the first box body 9, so that the stirring rod 10 can shrink continuously in the first box body 9, the stirring quality can be improved when materials are stirred, and the stirring efficiency is improved;

wherein, in order to realize spacing purpose, this device adopts following technical scheme to realize: the tops of the two second box bodies 26 are fixedly connected with limiting rods 36, the limiting rods 37 are sleeved outside the two limiting rods 36 in a sliding mode, the two limiting rods 37 are fixedly connected with the tops of the two reciprocating screw rods 32 respectively, two sides of the moving plate 5 are fixedly connected with second sliding blocks 38, two inner walls of two sides of the shell 1 are provided with second sliding grooves, the second sliding blocks 38 are embedded in the second sliding grooves and are in sliding connection with the second sliding grooves, the limiting rods 37 can limit the reciprocating screw rods 32, therefore, the reciprocating screw rods 32 can be moved left and right continuously, and the moving plate 5 can be moved up and down stably by the second sliding blocks 38;

wherein, in order to realize the purpose that mixing box 2 rotated, this device adopts following technical scheme to realize: the rotating assembly comprises a box body III 39, the box body III 39 is fixedly connected to the bottom of the fixed plate 4, a piston III 40 is arranged in the box body III 39 in a sliding mode, a push rod 41 is fixedly connected to the top end of the piston III 40, the top end of the push rod 41 penetrates through the fixed plate 4 and the spring 18 and is fixedly connected to the bottom of the movable plate 5, a through hole is formed in one side of the shell 1, a box body IV 42 is arranged outside one side of the shell 1, one end of the box body IV 42 extends into the through hole and is fixedly connected with the through hole, a pipeline IV 43 is arranged inside the box body III 39, one end of the pipeline IV 43 extends into the box body IV 42, the pipeline IV 43 is fixedly connected with the box body III 39 and the box body IV 42, a piston IV 44 is arranged in the box body IV 42 in a sliding mode, one end of the piston IV 44 is fixedly connected with a moving box 45, one end of the moving box 45 extends into the shell 1, a fixed block 46 is fixedly connected inside the box body IV 42, and the moving box 45 penetrates through the fixed block 46 and is slidably connected with the fixed block 46, a spiral groove 47 is formed in the inner wall of the movable box 45, a rotating shaft four 48 is rotatably connected in the movable box 45, one end of the rotating shaft four 48 extends to one side of the mixing box 2, four balls 49 are fixedly connected to the outside of the rotating shaft four 48, the four balls 49 are spirally distributed, the four balls 49 are all slidably arranged in the spiral groove 47, a sleeve 50 is sleeved outside the rotating shaft four 48, the sleeve 50 is connected with the rotating shaft four 48 through a one-way bearing, a plurality of deflector rods 51 are fixedly sleeved outside the sleeve 50, the deflector rods 51 are uniformly distributed in a circumferential shape, the deflector rods 51 are crossly distributed with the connecting rod 19, two stabilizing rods 52 are fixedly connected to the inner wall of the bottom of the shell 1, the two stabilizing rods 52 are respectively positioned at two sides of the sleeve 50, the rotating shaft four 48 penetrates through the two stabilizing rods 52 and is connected with the stabilizing rods 52 through a bearing, the deflector rods 51 can rotate under the design of the push rod 41, the piston three 40, the piston four 44, the movable box 45, the rotating shaft four 48, the sleeve 50 and other components, then the mixing box 2 can rotate under the design of the deflector rod 51 and the connecting rod 19, and the rotating direction is opposite to the rotating direction of the rotating plate 6, so that the materials can be stirred and mixed once, and secondary stirring and mixing are not needed, so that the stirring and mixing time can be reduced, and the production efficiency of the inorganic artificial stone plate is improved;

wherein, in order to realize the purpose of reinforced and ejection of compact, this device adopts following technical scheme to realize: a feed hopper 53 is fixedly embedded in the rotating plate 6, the feed hopper 53 is positioned at the rear side of the cavity II, a discharge pipe 54 is arranged on the outer side of the bottom of the mixing box 2, the top end of the discharge pipe 54 extends into the mixing box 2 and is fixedly connected with the mixing box 2, a switch valve 55 is arranged outside the discharge pipe 54, the bottom of the mixing box 2 is arranged in an inclined shape, a box door 56 is embedded in the shell 1, the box door 56 is connected with the shell 1 through a hinge, a through groove is formed in the top of the shell 1, the feed hopper 53 can facilitate feeding, and the discharge pipe 54 can facilitate discharging;

wherein, in order to realize the purpose of supporting, this device adopts following technical scheme to realize: an auxiliary plate 57 is fixedly sleeved outside the shell 1, the auxiliary plate 57 is fixedly connected with the box body IV 42, four corners of the bottom of the auxiliary plate 57 are fixedly connected with supporting legs 58, and the supporting legs 58 can support the device.

The using process of the invention is as follows: when the present invention is used, various materials can be added into the mixing box 2 through the design of the through groove and the feed hopper 53 when the various materials need to be stirred and mixed, the box door 56 can be opened for viewing, thereby the falling phenomenon of the materials can be avoided, after the addition is completed, the motor 12 can be controlled to work, the motor 12 works to drive the rotating shaft three 13 to rotate, the rotating shaft three 13 rotates to drive the bevel gear one 14 to rotate, the rotating plate 6 rotates clockwise (clockwise when viewed from top to bottom) due to the fact that the bevel gear one 14 is meshed with the bevel gear one 15 and the bevel gear one 15 is fixedly connected to the bottom of the cavity one, so that the rotating plate 6 can be driven by the bevel gear one 14 when the rotating shaft three rotates, the rotating plate 6 rotates to drive the rotating shaft one 7 and the rotating shaft two 8 to perform circular motion inside the mixing box 2, namely, the rotating shaft one 7 and the rotating shaft two 8 rotate inside the mixing box 2, and the rotating shaft three 13 can also rotate the bevel gear two 22, the bevel gear two bevel gear three 22 rotates to drive the bevel gear three bevel gear 23 to rotate, the rotating plate 23 to drive the rotating shaft one 7 to rotate, the rotating plate 7 and the rotating plate 8 to rotate, and the rotating plate 6 and the rotating plate 2 moves downwards, and the rotating plate 6 moves downwards when the rotating plate 6 rotates, the rotating plate 2 moves downwards, and the rotating plate 6 moves downwards, and the rotating plate 2 and the rotating plate moves downwards, the rotating plate 6 and the moving plate 5 can continuously move up and down through circulation, and further the stirring rod 10 can continuously move up and down, so that the stirring rod 10 can move up and down while rotating in the mixing box 2 in a circumferential motion manner, the stirring effect on materials can be increased, and dead angles of stirring and mixing are avoided;

the rotating plate 6 rotates while the two bevel gears four 35 also revolve, and the bevel gears four 35 are also meshed with the bevel gear ring two 34, so that the two bevel gears four 35 rotate during revolution, and thus the two sliding seats 33 can be driven to rotate, and as the sliding seats 33 are embedded in the box body two 26, the two reciprocating screw rods 32 can be continuously moved left and right when the two sliding seats 33 rotate, so that the two pistons two 31 can be continuously moved left and right in the box body two 26, and then the four box bodies one 9 can be inflated and exhausted through the design of the parts such as the pipeline one 27, the pipeline two 28, the pipeline three 29 and the like, so that the piston one 30 can be continuously moved in the box body one 9, and thus the stirring rod 10 can be continuously contracted in the box body one 9, and the stirring quality can be increased when materials are stirred, and the stirring efficiency can be increased;

the moving plate 5 can drive the two push rods 41 to continuously move up and down when continuously moving up and down, so that the two pistons three 40 can be driven to continuously move up and down in the two boxes three 39, then the two pipes four 43 can continuously inflate and deflate the boxes four 42, so that the pistons four 44 in the two boxes four 42 can continuously move left and right, and further the two moving boxes 45 are driven to continuously move left and right, because the spiral grooves 47 are formed in the inner wall of the moving boxes 45, the balls 49 distributed in a spiral manner are arranged outside the rotating shafts four 48, so that the two rotating shafts four 48 can continuously rotate back and forth when the two moving boxes 45 move left and right, the two rotating shafts four 48 rotate back and forth, so that the two sleeves 50 can rotate, because the sleeves 50 are connected with the rotating shafts four 48 through one-way bearings, the sleeve 50 on the left side only rotates forward, the sleeve 50 on the right side only rotates backward, so that the mixing rod 51 and the connecting rod 19 can rotate the mixing box 2 under the design, and the rotating direction is opposite to the rotating direction of the rotating plate 6, so that the materials can be stirred and mixed once, and the secondary mixing time of inorganic slabstones is reduced, and the production efficiency of inorganic artificial stone is increased;

when the material is mixed, the valve 55 is opened and the receiving vessel is placed at the bottom of the apparatus so that the material can enter the vessel through the discharge pipe 54.

The above is only a preferred embodiment of the present invention, and any person skilled in the art may modify the present invention or modify it to an equivalent technical solution by using the technical solution described above. Therefore, any simple modifications or equivalent substitutions made in accordance with the technical solution of the present invention are within the scope of the claims of the present invention.

Claims

1. The utility model provides a polymer sand processingequipment based on clamp plate method, includes shell (1), its characterized in that: a mixing box (2) is arranged in the shell (1), the bottom end of the mixing box (2) extends to the outer side of the bottom of the shell (1), the mixing box (2) is connected with the shell (1) through a bearing, and an auxiliary mechanism is arranged in the shell (1);

the auxiliary mechanism comprises a cylinder (3), the cylinder (3) is connected to the top of the mixing box (2) and connected with the mixing box (2) through a sealed bearing, a fixed plate (4) is fixedly connected to the inside of the shell (1), the fixed plate (4) is fixedly sleeved on the outside of the cylinder (3), a movable plate (5) is arranged in the shell (1) in a sliding mode, the movable plate (5) is located at the top of the cylinder (3), a first cavity is formed in the movable plate (5), a rotating plate (6) is arranged on the inner sides of the movable plate (5) and the cylinder (3), the top end of the rotating plate (6) penetrates through the cavity and extends to the outer side of the top of the movable plate (5), the rotating plate (6) is connected with the movable plate (5) through a sealed bearing, a second cavity is formed in the rotating plate (6), a first rotating shaft (7) and a second rotating shaft (8) are arranged in the cavity, the first rotating shaft (7) and the second rotating shaft (8) extend to the inside of the mixing box (2), two first stirring rods (9) are fixedly arranged in the first box (9) and two stirring rods (10) extend to the inside of the mixing box (10), the improved structure comprises a rotating plate (6), wherein an L-shaped support (11) is fixedly connected to one side of the rotating plate (6), the L-shaped support (11) is in contact with the top of a cavity and is in sliding connection with the top of the cavity, a motor (12) is fixedly connected to one side of the L-shaped support (11), a rotating shaft III (13) is fixedly connected to the output shaft of the motor (12), one end of the rotating shaft III (13) extends into a cavity II, a bevel gear I (14) is fixedly sleeved outside the rotating shaft III (13), the bevel gear I (14) is positioned inside the cavity I, a bevel gear ring I (15) is fixedly connected to the bottom of the cavity I, the bevel gear I (14) is positioned at the top of the bevel gear I (14) and is meshed with a bevel gear ring I (15), a driving assembly I is arranged between the rotating shaft III (13) and a rotating shaft I (7), a driving assembly II is arranged between the rotating shaft I (7) and a rotating shaft II (8), two arc plates (16) are fixedly connected to the bottom of the rotating plate (6), the two arc plates (16) are annular, two rotating plates (16) are fixedly connected to the top of the cylinder (3), two rotating plate (17) are respectively in contact with two arc plates (6), two fixed springs (18) and are respectively positioned at the two inner sides of an auxiliary spring fixing plate (6), the auxiliary assembly extends to inside pivot one (7) and pivot two (8) respectively, the fixed cover of mixing box (2) outside is equipped with a plurality of connecting rods (19) and a plurality of connecting rod (19) and is circumference form evenly distributed, mixing box (2) both sides all are equipped with rotating assembly and two rotating assembly and are the mirror symmetry and distribute.

2. The polymer sand processing device based on the plate pressing method as claimed in claim 1, wherein: the improved rotary plate structure is characterized in that two U-shaped supports (20) are fixedly connected to the bottom of the rotary plate (6), the first rotary shaft (7) and the second rotary shaft (8) are distributed to penetrate through the two U-shaped supports (20), a first sliding block (21) is fixedly connected to the top of the L-shaped support (11), a first sliding groove is formed in the top of the cavity, the first sliding block (21) is embedded in the first sliding groove and is in sliding connection with the first sliding groove, the first sliding groove is annular, the first rotary shaft (7) is connected with the rotary plate (6) and the U-shaped supports (20) through sealing bearings, and the second rotary shaft (8) is connected with the rotary plate (6) and the U-shaped supports (20) through sealing bearings.

3. The polymer sand processing device based on the plate pressing method according to claim 1, characterized in that: drive assembly one includes bevel gear two (22) and bevel gear three (23), bevel gear two (22) fixed connection is in three (13) one end of pivot, bevel gear three (23) fixed cover is established in pivot one (7) outsidely, bevel gear three (23) are located bevel gear two (22) one side and mesh mutually with bevel gear two (22), drive assembly two includes two sprocket (24) and chain (25), two sprocket (24) fixed cover is established respectively and is established in pivot one (7) and pivot two (8) outsidely, chain (25) cover is established in two sprocket (24) outsidely, two drive connection is passed through chain (25) between sprocket (24), pivot three (13) are connected through sealed bearing with rotor plate (6).

4. The polymer sand processing device based on the plate pressing method according to claim 1, characterized in that: the auxiliary assembly comprises two second box bodies (26), the two second box bodies (26) are fixedly connected to the top of the rotating plate (6), a first pipeline (27) is arranged inside the second box body (26) close to the motor (12), one end of the first pipeline (27) penetrates through the first rotating shaft (7) and extends to the inside of one first box body (9) of the first rotating shaft (7), a second pipeline (28) is arranged inside the second box body (26) far away from the motor (12), one end of the second pipeline (28) penetrates through the second rotating shaft (8) and extends to the inside of one first box body (9) of the second rotating shaft (8), the first rotating shaft (7) and the second rotating shaft (8) are fixedly embedded with a third pipeline (29), two ends of the third pipeline (29) extend to the insides of the first box bodies (9) respectively and are fixedly connected with the first box body (9), the first pipeline (27) is fixedly connected with the second box body (26), the first rotating shaft (7) and the first box body (9), and the second rotating shaft (8) and the first box body (9) are fixedly connected with the rotating shaft (26).

5. The polymer sand processing device based on the plate pressing method as claimed in claim 4, wherein: four the inside equal slip of box (9) is equipped with two pistons one (30) and two pistons two (31) and respectively fixed connection is in two puddlers (10) the inner, two the inside equal slip of box two (26) is equipped with piston two (31), two the equal fixedly connected with reciprocal lead screw (32) in piston two (31) outside, two reciprocal lead screw (32) outer end extends to two box two (26) outsides respectively, two reciprocal lead screw (32) outside all overlaps and is equipped with sliding seat (33), sliding seat (33) and reciprocal lead screw (32) are connected through ball (49) screw pair, two sliding seat (33) inlay respectively and establish in two box two (26) outsides and sliding seat (33) and box two (26) and are connected through sealed bearing, moving plate (5) top fixedly connected with awl ring gear two (34), two the outside equal fixed cover of sliding seat (33) is equipped with bevel gear four (35), two bevel gear four (35) all are located awl ring gear (34) top and mesh mutually with awl ring gear two (34).

6. The polymer sand processing device based on the plate pressing method according to claim 5, wherein: two equal fixedly connected with gag lever post (36) in box two (26) top, two the outside equal slip cap of gag lever post (36) is equipped with stopper (37), two stopper (37) respectively with two reciprocal lead screw (32) top fixed connection, two (38) of equal fixedly connected with slider in movable plate (5) both sides, spout two has all been seted up to shell (1) both sides inner wall, slider two (38) inlay establish in spout two inside and with two sliding connection of spout.

7. The polymer sand processing device based on the plate pressing method according to claim 1, characterized in that: the rotary component comprises a box body three (39), the box body three (39) is fixedly connected to the bottom of a fixing plate (4), the box body three (39) is internally provided with a piston three (40) in a sliding mode, the piston three (40) top end fixedly connected with push rod (41) is arranged on the top end of the push rod (41) in a penetrating mode, the fixing plate (4) and a spring (18) are fixedly connected to the bottom of a moving plate (5), a through hole is formed in one side of the shell (1), the shell (1) is externally provided with a box body four (42) in one side, the box body four (42) one end is extended to the through hole in the inside and fixedly connected with the through hole, the box body three (39) is internally provided with a pipeline four (43), the pipeline four (43) one end of the pipeline extends to the box body four (42) in the inside and the four (43) and the three (39) and four (42) in the box body are fixedly connected, the box body four (42) is internally provided with a piston four (44 in a sliding mode, the piston four (44) one end fixedly connected with a moving box (45) is fixedly connected with a moving box (45), one end of the moving box (45) extends to the shell (1) in the inside, the four (42) is connected with a fixing block (46) and the moving box (46).

8. The polymer sand processing device based on the plate pressing method according to claim 7, characterized in that: spiral groove (47) have been seted up to removal case (45) inner wall, removal case (45) internal rotation is connected with four (48) of pivot, four (48) one end of pivot extend to mixing box (2) one side, four (48) four outside fixedly connected with balls (49) of pivot, four ball (49) are the heliciform and distribute, four ball (49) all slide and establish inside spiral groove (47), the outside cover of four (48) of pivot is equipped with sleeve (50), sleeve (50) are connected through one-way bearing with four (48) of pivot, the fixed cover of sleeve (50) outside is equipped with a plurality of driving levers (51) and a plurality of driving lever (51) and is circumference form evenly distributed, driving lever (51) and connecting rod (19) cross distribution, shell (1) bottom inner wall fixedly connected with two firm pole (52) and two firm pole (52) are located sleeve (50) both sides respectively, four (48) of pivot run through two firm pole (52) and with firm pole (52) through the bearing connection.

9. The polymer sand processing device based on the plate pressing method as claimed in claim 1, wherein: rotor plate (6) inside fixed the inlaying and be equipped with feeder hopper (53), feeder hopper (53) are located two rear sides of cavity, mixing box (2) bottom outside is equipped with discharging pipe (54), discharging pipe (54) top extend to mixing box (2) inside and with mixing box (2) fixed connection, discharging pipe (54) outside is equipped with ooff valve (55), mixing box (2) bottom sets up to the slope form, shell (1) inlays and is equipped with chamber door (56), chamber door (56) pass through hinge connection with shell (1), logical groove has been seted up at shell (1) top.

10. The polymer sand processing device based on the plate pressing method according to claim 1, characterized in that: the outer portion of the shell (1) is fixedly sleeved with an auxiliary plate (57), the auxiliary plate (57) is fixedly connected with the four box bodies (42), and four corners of the bottom of the auxiliary plate (57) are fixedly connected with supporting legs (58).