CN111844536A

CN111844536A - Cold press for recycling waste foamed plastic

Info

Publication number: CN111844536A
Application number: CN202010703570.2A
Authority: CN
Inventors: 唐永林
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-07-21
Filing date: 2020-07-21
Publication date: 2020-10-30

Abstract

The invention relates to the field of foam recovery, in particular to a cold press for recovering waste foamed plastic, which comprises a crushing frame, a crushing mechanism, a cleaning cavity frame, a conveying mechanism I, a cleaning stirring mechanism, a conveying mechanism II, an extruding mechanism, a cutting mechanism and a pushing mechanism, wherein the crushing mechanism is connected in the crushing frame, the lower end of the cleaning cavity frame is fixedly connected in the crushing frame, the conveying mechanism I is connected at the right end of the cleaning cavity frame, the conveying mechanism II is connected at the left end of the cleaning cavity frame, the cleaning stirring mechanism is connected on the crushing frame, the upper end of the extruding mechanism is fixedly connected below the left end of the cleaning cavity frame, the cutting mechanism is fixedly connected at the lower end of the extruding mechanism, the two pushing mechanisms are respectively connected at the front side and the rear side of the upper end of the extruding mechanism, and the invention can compress the foamed plastic, the space occupied by the foam plastic with the same weight is reduced, and the transportation cost is reduced.

Description

Cold press for recycling waste foamed plastic

Technical Field

The invention relates to the field of foam recovery, in particular to a cold press for recovering waste foamed plastics.

Background

At present, in the process of product production, sales and circulation, a plurality of transportation links are often needed, in order to prevent the product from being damaged in the transportation process, a large amount of foam plastics are lined outside the product except for an outer-layer packaging box, so as to buffer the impact force of external force on the packaging box from reaching the product. Because foamed plastic is a thing that can't naturally degrade, consequently just need retrieve it, generally adopt the wrapping bag to pack foamed plastic and transport now, but because the foamed plastic in the packing box is the dysmorphism, consequently there is a large amount of spaces in the packing bag, because foamed plastic's proportion is very little moreover, consequently has occupied a large amount of spaces in the transportation, greatly increased the cost of transportation.

Disclosure of Invention

The invention aims to provide a cold press for recycling waste foamed plastics, which can compress the foamed plastics, reduce the space occupied by the foamed plastics with the same weight and reduce the transportation cost.

The purpose of the invention is realized by the following technical scheme:

a cold press for recycling waste foamed plastic comprises a crushing frame, a crushing mechanism, a cleaning cavity frame, a conveying mechanism I, a cleaning stirring mechanism, a conveying mechanism II, an extruding mechanism, a cutting mechanism and a pushing mechanism, the crushing mechanism is connected in the crushing frame, the lower end of the cleaning cavity frame is fixedly connected in the crushing frame, the right end of the cleaning cavity frame is communicated with the right end of the crushing frame, the conveying mechanism I is connected with the right end of the cleaning cavity frame, the conveying mechanism II is connected with the left end of the cleaning cavity frame, the cleaning stirring mechanism is connected on the crushing frame and is rotationally connected with the cleaning cavity frame, the upper end of the extrusion mechanism is fixedly connected below the left end of the cleaning cavity frame, the cutting mechanism is fixedly connected at the lower end of the extrusion mechanism, the two pushing mechanisms are respectively connected to the front side and the rear side of the upper end of the extruding mechanism;

The crushing frame comprises a water tank, a water tank connecting plate, a supporting plate, a crushing cavity pipe, a charging opening, a crushing mounting plate, water tank supporting legs and a sewage discharge pipe, wherein the four corners of the lower end of the water tank are fixedly connected with the water tank supporting legs, the lower end of the water tank is provided with the sewage discharge pipe, the sewage discharge pipe is provided with a valve, the water tank connecting plate is fixedly connected to the upper end of the water tank, the lower end of the supporting plate is fixedly connected to the water tank connecting plate, the crushing cavity pipe is obliquely and fixedly connected to the supporting plate, the charging opening is formed;

the crushing mechanism comprises a crushing motor, a crushing shaft and crushing cutters, the lower end of the crushing shaft is provided with a plurality of crushing cutters, the upper end of the crushing shaft is rotatably connected to the crushing mounting plate, the crushing motor is fixedly connected to the crushing mounting plate, and the output shaft of the crushing motor is fixedly connected with the crushing shaft;

the cleaning cavity frame comprises a connecting cavity, a conveying mounting plate I, a conveying straight pipe I, a conveying bent pipe, a stirring mounting pipe, a cleaning straight pipe, through long holes, connecting plates, a conveying straight pipe II, a blanking port, a conveying mounting plate II and a suction pump, wherein a plurality of through long holes are uniformly formed in the cleaning straight pipe in the circumferential direction, two connecting plates are fixedly connected to the lower side of the cleaning straight pipe, the lower ends of the two connecting plates are fixedly connected to the inside of a water tank, the horizontal height of the cleaning straight pipe is lower than that of a side edge plate of the water tank, conveying bent pipes are fixedly connected to the two ends of the cleaning straight pipe, stirring mounting pipes are fixedly connected to the two conveying bent pipes, the two stirring mounting pipes are coaxial with the cleaning straight pipe, the lower end of the conveying straight pipe I is fixedly connected to the upper end of the conveying bent pipe at the right end, the conveying mounting plate I is fixedly, a heating plate is arranged inside the conveying straight pipe II, the lower end of the conveying straight pipe II is fixedly connected to the upper end of the conveying bent pipe at the left end, the upper end of the conveying straight pipe II is fixedly connected with a conveying mounting plate II, a blanking port is arranged below the upper end of the conveying straight pipe II, and an air suction pump is fixedly connected to and communicated with the conveying straight pipe II;

The conveying mechanism I comprises a conveying motor I, a conveying shaft I and a conveying spiral plate I, the conveying spiral plate I is fixedly connected to the conveying shaft I, an output shaft of the conveying motor I is fixedly connected with the upper end of the conveying shaft I, the conveying motor I is fixedly connected to the conveying mounting plate I, the upper end of the conveying shaft I is rotatably connected to the conveying mounting plate I, and the conveying spiral plate I is rotatably connected to a conveying straight pipe I and a conveying bent pipe located at the right end;

the cleaning and stirring mechanism comprises a cleaning and stirring motor, a stirring shaft and stirring spiral plates, wherein two ends of the stirring shaft are respectively and rotatably connected to the left end and the right end of the water tank;

the conveying mechanism II comprises a conveying motor II, a conveying shaft II and a conveying spiral plate II, the conveying spiral plate II is fixedly connected to the conveying shaft II, an output shaft of the conveying motor II is fixedly connected with the upper end of the conveying shaft II, the conveying motor II is fixedly connected to the conveying mounting plate II, the upper end of the conveying shaft II is rotatably connected to the conveying mounting plate II, and the conveying spiral plate II is rotatably connected to the conveying straight pipe II and a conveying bent pipe located at the left end;

The extrusion mechanism comprises an extrusion cavity pipe, a lower connecting plate, upper connecting plates, guide inclined plates, an extrusion motor and extrusion rollers, wherein the left end and the right end of the extrusion cavity pipe are fixedly connected with the lower connecting plates, the four corners of the upper end of the extrusion cavity pipe are fixedly connected with the upper connecting plates, the upper ends of the four upper connecting plates are fixedly connected to a blanking port, an upper end opening of the extrusion cavity pipe is positioned right below the blanking port, the front side and the rear side of the upper end of an inner cavity of the extrusion cavity pipe are obliquely and fixedly connected with the guide inclined plates, the two extrusion rollers are rotatably connected in the extrusion cavity pipe, the right ends of the two extrusion rollers are in meshing transmission connection, the extrusion motor is fixedly connected to the extrusion cavity pipe, the extrusion motor is in transmission connection with one of the extrusion rollers, and a gap at;

the cutting mechanism comprises a cutting platform, platform supporting legs, baffles, falling holes, a cutter chute, a linkage plate I, a transmission round wheel and a cutting motor, wherein the platform supporting legs are fixedly connected to four corners of the cutting platform, the cutting platform is provided with the falling holes, the falling holes are positioned right below a gap between two extrusion rollers, the baffles are arranged on the rear sides of the falling holes, the cutter chutes are arranged at the left and right ends of the cutting platform, the two ends of the cutter are respectively connected in the cutter chute in a sliding manner, the cutting motor is fixedly connected onto the cutting platform, an output shaft of the cutting motor penetrates through the cutting platform and is fixedly connected with the transmission round wheel, one end of the linkage plate I is rotatably connected with the cutter, and the other end of the linkage plate I is rotatably connected with the eccentric position of the transmission round;

Push mechanism include push plate, push-and-pull board, interlock board II, transmission round wheel II and propelling movement motor, the lower extreme fixed connection of push plate is in the middle part of push plate, the lower extreme of interlock board II rotates with the upper end of push-and-pull board to be connected, the upper end of interlock board II rotates with the eccentric department of transmission round wheel II to be connected, II fixed connection of transmission round wheel are on the output shaft of propelling movement motor, push mechanism be equipped with two, two push plate sliding connection respectively on two direction swash plates, two propelling movement motors fixed connection respectively are in the upper end of two direction swash plates.

The invention has the beneficial effects that: the invention provides a cold press for recycling waste foamed plastic, which is characterized in that the waste foamed plastic is fed into a crushing cavity pipe through a feeding port, and the waste foamed plastic is crushed through a crushing cutter; the crushed foamed plastic falls into the conveying straight pipe I, is spirally pushed to the conveying bent pipe at the right end through the conveying spiral plate I, is contacted with clean water in the conveying bent pipe, and is continuously pushed along with the conveying spiral plate I, so that the crushed foamed plastic is squeezed into the cleaning straight pipe from the conveying bent pipe at the right end and is fully contacted with the clean water to clean impurities on the crushed foamed plastic; the cleaning and stirring motor drives the stirring spiral plate to rotate through the stirring shaft, so that the foamed plastic in the cleaning straight pipe is stirred, the foamed plastic is further cleaned, meanwhile, the foamed plastic is pushed leftwards into the conveying bent pipe at the left end, and along with continuous conveying of foam, the foamed plastic is extruded into the conveying straight pipe II at the conveying bent pipe at the left end and is separated from clear water, and the cleaning is finished; the conveying spiral plate II rotates to enable foam to be pushed to drop at the material dropping opening in a rotating mode, in the pushing process, a heating plate in the conveying straight pipe II heats the foam, the foam is dried when dropping at the material dropping opening, meanwhile, air in the conveying straight pipe II is absorbed by an air suction pump and discharged, and the drying effect of the foam is further improved; the foamed plastic falls into the extrusion cavity pipe at the blanking port, is guided by the two guide inclined plates, and falls between the two extrusion rollers which rotate oppositely from a gap between the lower ends of the two guide inclined plates, so that the crushed foamed plastic is extruded into a foamed thin plate, the space occupied by the foamed plastic is reduced, the foamed thin plate continuously forms and falls into a falling hole, the cutting motor drives the cutter to reciprocate, the cutter slides backwards to match with the baffle plate to cut the foamed thin plate, and the foamed thin plate with the same appearance is obtained below the falling hole, so that the packaging and the transportation are facilitated; and the pushing motor drives the pushing plate to move up and down in a reciprocating manner on the guide inclined plates to push the foamed plastic of the guide inclined plates, so that the foamed plastic is prevented from being blocked at a gap between the lower ends of the two guide inclined plates to influence the extrusion of the foamed plastic.

Drawings

FIG. 1 is a first general structural diagram of the present invention;

FIG. 2 is a second overall structural schematic of the present invention;

FIG. 3 is a first schematic view of the crushing frame of the present invention;

FIG. 4 is a schematic view of the crushing frame of the present invention;

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

FIG. 6 is a schematic view of the cleaning chamber frame of the present invention;

FIG. 7 is a schematic cross-sectional view of a wash chamber rack of the present invention;

FIG. 8 is a schematic structural view of a conveying mechanism I of the invention;

FIG. 9 is a schematic view of the cleaning agitation mechanism of the present invention;

FIG. 10 is a schematic structural view of a conveying mechanism II of the invention;

FIG. 11 is a schematic view of the pressing mechanism of the present invention;

FIG. 12 is a schematic cross-sectional view of the extrusion mechanism of the present invention;

FIG. 13 is a schematic structural view of the cutting mechanism of the present invention;

fig. 14 is a schematic structural view of the pushing mechanism of the present invention.

In the figure: a crushing frame 1; 1-1 of a water tank; a water tank connecting plate 1-2; support plates 1-3; crushing cavity pipes 1-4; 1-5 parts of a feed inlet; crushing the mounting plates 1-6; 1-7 of water tank supporting legs; 1-8 parts of a sewage discharge pipe; a crushing mechanism 2; a crushing motor 2-1; 2-2 parts of a crushing shaft; 2-3 of a crushing cutter; cleaning the cavity frame 3; a connecting cavity 3-1; conveying the mounting plate I3-2; 3-3 parts of a conveying straight pipe; 3-4 parts of conveying bent pipe; 3-5 parts of a stirring installation pipe; cleaning 3-6 parts of a straight pipe; 3-7 of a through long hole; 3-8 of a connecting plate; conveying the straight pipe II 3-9; 3-10 parts of a blanking port; conveying the mounting plates II 3-11; 3-12 parts of a getter pump; a conveying mechanism I4; a conveying motor I4-1; a conveying shaft I4-2; conveying a spiral plate I4-3; a cleaning agitation mechanism 5; cleaning a stirring motor 5-1; 5-2 of a stirring shaft; 5-3 of a stirring spiral plate; a conveying mechanism II 6; a conveying motor II 6-1; a conveying shaft II 6-2; conveying a spiral plate II 6-3; an extrusion mechanism 7; an extrusion cavity tube 7-1; a lower connecting plate 7-2; an upper connecting plate 7-3; 7-4 of a guide inclined plate; 7-5 of an extrusion motor; 7-6 parts of extrusion roller; a cutting mechanism 8; a cutting platform 8-1; a platform leg 8-2; 8-3 of a baffle plate; 8-4 of a dropping hole; 8-5 parts of a cutter; 8-6 parts of a cutter chute; 8-7 of a linkage plate; 8-8 parts of a transmission round wheel; cutting off the motor 8-9; a pushing mechanism 9; a push plate 9-1; a push-pull plate 9-2; a linkage plate II 9-3; a transmission round wheel II 9-4; and a pushing motor 9-5.

Detailed Description

The invention is described in further detail below with reference to fig. 1-14.

The fixed connection in the device can be fixed by welding, thread fixing and the like, the rotary connection can be realized by baking the bearing on a shaft, a spring retainer groove or an inter-shaft baffle is arranged on the shaft or a shaft hole, the axial fixation of the bearing is realized by clamping an elastic retainer ring in the spring retainer groove or the inter-shaft baffle, and the rotation is realized by the relative sliding of the bearing; different connection modes are used in combination with different use environments.

The first embodiment is as follows:

as shown in fig. 1-14, a cold press for recycling waste foamed plastic comprises a crushing frame 1, a crushing mechanism 2, a cleaning cavity frame 3, a conveying mechanism I4, a cleaning stirring mechanism 5, a conveying mechanism II 6, an extruding mechanism 7, a cutting mechanism 8 and a pushing mechanism 9, wherein the crushing mechanism 2 is connected in the crushing frame 1, the lower end of the cleaning cavity frame 3 is fixedly connected in the crushing frame 1, the right end of the cleaning cavity frame 3 is communicated with the right end of the crushing frame 1, the conveying mechanism I4 is connected at the right end of the cleaning cavity frame 3, the conveying mechanism II 6 is connected at the left end of the cleaning cavity frame 3, the cleaning stirring mechanism 5 is connected on the crushing frame 1, the cleaning stirring mechanism 5 is rotatably connected with the cleaning cavity frame 3, the upper end of the extruding mechanism 7 is fixedly connected below the left end of the cleaning cavity frame 3, the cutting mechanism 8 is fixedly connected at the lower end of the extruding mechanism 7, the two pushing mechanisms 9 are arranged, and the two pushing mechanisms 9 are respectively connected to the front side and the rear side of the upper end of the extruding mechanism 7;

When in use, the waste foamed plastic is fed into the crushing cavity pipe 1-4 through the feeding port 1-5, the crushing motor 2-1 drives the crushing cutter 2-3 to rotate in the crushing cavity pipe 1-4 through the crushing shaft 2-2, so that the waste foamed plastic is crushed, the crushed foamed plastic falls into the connecting cavity 3-1 from the lower end of the crushing cavity pipe 1-4 and then falls into the conveying straight pipe I3-3, the conveying motor I4-1 drives the conveying spiral plate I4-3 to rotate in the conveying straight pipe I3-3 through the conveying shaft I4-2, so that the crushed foamed plastic is spirally pushed to the conveying bent pipe 3-4 at the right end and is contacted with clean water in the conveying bent pipe 3-4, the crushed foamed plastic is extruded into the cleaning straight pipe 3-6 from the conveying bent pipe 3-4 at the right end along with the continuous pushing of the conveying spiral plate I4-3, fully contacting with clean water, cleaning impurities on crushed foam plastics, driving a stirring spiral plate 5-3 to rotate by a cleaning stirring motor 5-1 through a stirring shaft 5-2, stirring the foam plastics in a cleaning straight pipe 3-6, further cleaning the foam plastics, simultaneously pushing the foam plastics to the left into a conveying bent pipe 3-4 at the left end, extruding the foam plastics into a conveying straight pipe II 3-9 at the conveying bent pipe 3-4 at the left end along with continuous conveying of foam, simultaneously separating from the clean water to finish cleaning, driving the conveying spiral plate II 6-3 to rotate by a conveying motor II 6-1 through a conveying shaft II 6-2, pushing the foam at the lower end of the conveying straight pipe II 3-9 to a blanking port 3-10 at the upper end of the conveying straight pipe II 3-9 to drop, in the pushing process, the heating plate in the conveying straight pipe II 3-9 heats the foamed plastic, the foamed plastic is dried when falling at the blanking port 3-10, and meanwhile, the air in the conveying straight pipe II 3-9 is absorbed and discharged through the air suction pump 3-12, so that the drying effect of the foamed plastic is further improved; the foamed plastic falls into an extrusion cavity pipe 7-1 at a blanking port 3-10, is guided by two guide inclined plates 7-4, falls between two extrusion rollers 7-6 which rotate oppositely from a gap between the lower ends of the two guide inclined plates 7-4 to be extruded into a foamed thin plate, the foamed thin plate is continuously molded and falls into a falling hole 8-4, a cutting motor 8-9 drives a transmission circular wheel 8-8 to rotate, a linkage plate I8-7 is driven to drive a cutter 8-5 to reciprocate at the falling hole 8-4 on a cutting platform 8-1, the cutter 8-5 slides backwards to be matched with a baffle 8-3 to cut the foamed thin plate, so that the foamed thin plate with the same shape is obtained below the falling hole 8-4 to facilitate packaging and transportation, and the transmission circular wheel II 9-4 is driven to rotate by a pushing motor 9-5, the linkage plate II 9-3 is driven to drive the push-pull plate 9-2 and the push plate 9-1 to reciprocate up and down on the guide inclined plate 7-4 to push the foamed plastic of the guide inclined plate 7-4, so that the foamed plastic is prevented from being blocked at a gap between the lower ends of the two guide inclined plates 7-4 to influence the extrusion of the foamed plastic.

The second embodiment is as follows:

as shown in figures 1-14, the crushing frame 1 comprises a water tank 1-1, a water tank connecting plate 1-2, a supporting plate 1-3, a crushing cavity pipe 1-4, a charging opening 1-5, a crushing mounting plate 1-6, water tank supporting legs 1-7 and a sewage discharge pipe 1-8, wherein the four corners of the lower end of the water tank 1-1 are fixedly connected with the water tank supporting legs 1-7, the lower end of the water tank 1-1 is provided with the sewage discharge pipe 1-8, the sewage discharge pipe 1-8 is provided with a valve, the water tank connecting plate 1-2 is fixedly connected with the upper end of the water tank 1-1, the lower end of the supporting plate 1-3 is fixedly connected with the water tank connecting plate 1-2, the crushing cavity pipe 1-4 is fixedly connected with the supporting plate 1-3 in an inclined manner, the crushing mounting plate 1-6 is fixedly connected with the upper end of the crushing cavity tube 1-4;

the water tank 1-1 is used for containing clear water for foam cleaning and discharging sewage through the sewage discharge pipe 1-8, and the feed inlet 1-5 is used for adding foam plastics into the crushing cavity pipe 1-4 so as to facilitate crushing of the foam plastics.

The third concrete implementation mode:

as shown in fig. 1-14, the crushing mechanism 2 comprises a crushing motor 2-1, a crushing shaft 2-2 and crushing blades 2-3, the lower end of the crushing shaft 2-2 is provided with a plurality of crushing blades 2-3, the upper end of the crushing shaft 2-2 is rotatably connected to a crushing mounting plate 1-6, the crushing motor 2-1 is fixedly connected to the crushing mounting plate 1-6, and the output shaft of the crushing motor 2-1 is fixedly connected to the crushing shaft 2-2;

The crushing motor 2-1 drives the crushing knife 2-3 to rotate in the crushing cavity pipe 1-4 through the crushing shaft 2-2, so that the waste foam plastic is crushed.

The fourth concrete implementation mode:

as shown in the figures 1-14, the cleaning cavity frame 3 comprises a connecting cavity 3-1, a conveying mounting plate I3-2, a conveying straight pipe I3-3, a conveying bent pipe 3-4, a stirring mounting pipe 3-5, a cleaning straight pipe 3-6, a through long hole 3-7, a connecting plate 3-8, a conveying straight pipe II 3-9, a blanking port 3-10, a conveying mounting plate II 3-11 and an air suction pump 3-12, wherein the cleaning straight pipe 3-6 is uniformly provided with a plurality of through long holes 3-7 along the circumferential direction, the lower side of the cleaning straight pipe 3-6 is fixedly connected with two connecting plates 3-8, the lower ends of the two connecting plates 3-8 are fixedly connected in a water tank 1-1, the horizontal height of the cleaning straight pipe 3-6 is lower than that of a side plate of the water tank 1-1, and the two ends of the cleaning straight pipe 3-6 are, the two conveying bent pipes 3-4 are fixedly connected with stirring installation pipes 3-5, the two stirring installation pipes 3-5 are coaxial with the cleaning straight pipe 3-6, the lower end of the conveying straight pipe I3-3 is fixedly connected with the upper end of the conveying bent pipe 3-4 positioned at the right end, the upper end of the conveying straight pipe I3-3 is fixedly connected with a conveying installation plate I3-2, the upper side of the conveying straight pipe I3-3 is provided with a connecting cavity 3-1, the connecting cavity 3-1 is fixedly connected and communicated with the lower end of the crushing cavity pipe 1-4, a heating plate is arranged inside the conveying straight pipe II 3-9, the lower end of the conveying straight pipe II 3-9 is fixedly connected with the upper end of the conveying bent pipe 3-4 positioned at the left end, and the upper end of the conveying straight pipe II 3-9, a blanking port 3-10 is arranged below the upper end of the conveying straight pipe II 3-9, and an air suction pump 3-12 is fixedly connected and communicated with the conveying straight pipe II 3-9;

The cleaning straight pipe 3-6 is positioned in the water tank 1-1, clean water in the water tank 1-1 enters the cleaning straight pipe 3-6 and the two conveying bent pipes 3-4 through the through long holes 3-7 so that foam plastics can be cleaned by the contact of the clean water, impurities washed out by the foam plastics are discharged through the through long holes 3-7, cleaned foam plastics are heated through the heating plate in the conveying straight pipe II 3-9, water on the foam plastics is evaporated quickly, the drying of the foam plastics is accelerated, air is sucked into the inner cavity of the conveying straight pipe II 3-9 through the air suction pump 3-12, air in the conveying straight pipe II 3-9 is discharged through the air suction pump 3-12, and the drying of the foam plastics is further accelerated.

The fifth concrete implementation mode:

as shown in fig. 1-14, the conveying mechanism i 4 includes a conveying motor i 4-1, a conveying shaft i 4-2 and a conveying spiral plate i 4-3, the conveying shaft i 4-2 is fixedly connected with the conveying spiral plate i 4-3, an output shaft of the conveying motor i 4-1 is fixedly connected with an upper end of the conveying shaft i 4-2, the conveying motor i 4-1 is fixedly connected with the conveying mounting plate i 3-2, an upper end of the conveying shaft i 4-2 is rotatably connected with the conveying mounting plate i 3-2, and the conveying spiral plate i 4-3 is rotatably connected with the conveying straight pipe i 3-3 and a conveying bent pipe 3-4 located at a right end;

conveying motor I4-1 drives conveying spiral plate I4-3 to rotate in conveying straight tube I3-3 through conveying axle I4-2 to carry the spiral propelling movement of kibbling foamed plastic to the conveying return bend 3-4 that is located the right-hand member.

The sixth specific implementation mode:

as shown in fig. 1-14, the cleaning and stirring mechanism 5 includes a cleaning stirring motor 5-1, a stirring shaft 5-2 and a stirring spiral plate 5-3, wherein two ends of the stirring shaft 5-2 are respectively rotatably connected to the left and right ends of the water tank 1-1, the stirring spiral plate 5-3 is fixedly connected to the middle part of the stirring shaft 5-2, the stirring spiral plate 5-3 is located in the cleaning straight pipe 3-6, the stirring shaft 5-2 is rotatably connected to the two stirring installation pipes 3-5, the cleaning stirring motor 5-1 is fixedly connected to the right end of the water tank 1-1, and the cleaning stirring motor 5-1 is in transmission connection with the stirring shaft 5-2;

the cleaning and stirring motor 5-1 drives the stirring spiral plate 5-3 to rotate through the stirring shaft 5-2, so that the foamed plastic in the cleaning straight pipe 3-6 is stirred, the foamed plastic is further cleaned, and meanwhile, the foamed plastic is pushed leftwards to the conveying bent pipe 3-4 at the left end.

The seventh embodiment:

as shown in fig. 1-14, the conveying mechanism ii 6 includes a conveying motor ii 6-1, a conveying shaft ii 6-2 and a conveying spiral plate ii 6-3, the conveying shaft ii 6-2 is fixedly connected with the conveying spiral plate ii 6-3, an output shaft of the conveying motor ii 6-1 is fixedly connected with an upper end of the conveying shaft ii 6-2, the conveying motor ii 6-1 is fixedly connected with the conveying mounting plate ii 3-11, an upper end of the conveying shaft ii 6-2 is rotatably connected with the conveying mounting plate ii 3-11, and the conveying spiral plate ii 6-3 is rotatably connected with a conveying straight pipe ii 3-9 and a conveying bent pipe 3-4 at a left end;

The conveying motor II 6-1 drives the conveying spiral plate II 6-3 to rotate through the conveying shaft II 6-2, and foams at the lower end of the conveying straight pipe II 3-9 are pushed to the position of a blanking port 3-10 at the upper end of the conveying straight pipe II 3-9 to fall off in a rotating mode.

The specific implementation mode is eight:

as shown in fig. 1-14, the extrusion mechanism 7 comprises an extrusion cavity tube 7-1, a lower connecting plate 7-2, an upper connecting plate 7-3, a guide inclined plate 7-4, an extrusion motor 7-5 and extrusion rollers 7-6, wherein the left and right ends of the extrusion cavity tube 7-1 are fixedly connected with the lower connecting plate 7-2, four corners of the upper end of the extrusion cavity tube 7-1 are fixedly connected with the upper connecting plate 7-3, the upper ends of the four upper connecting plates 7-3 are fixedly connected with a blanking port 3-10, an upper end opening of the extrusion cavity tube 7-1 is positioned right below the blanking port 3-10, the front and rear sides of the upper end of an inner cavity of the extrusion cavity tube 7-1 are fixedly connected with the guide inclined plate 7-4 in an inclined manner, two extrusion rollers 7-6 are arranged, and the two extrusion rollers 7-6 are rotatably connected in, the right ends of the two extrusion rollers 7-6 are in meshing transmission connection, an extrusion motor 7-5 is fixedly connected to an extrusion cavity pipe 7-1, the extrusion motor 7-5 is in transmission connection with one extrusion roller 7-6, and a gap at the lower ends of the two guide inclined plates 7-4 is positioned right above a gap between the two extrusion rollers 7-6;

The extrusion motor 7-5 drives one extrusion roller 7-6 to rotate, the extrusion roller 7-6 is meshed with the other extrusion roller 7-6 to rotate, so that the two extrusion rollers 7-6 rotate oppositely, the foamed plastic falls into the extrusion cavity pipe 7-1 at the blanking port 3-10, is guided by the two guide inclined plates 7-4 and falls between the two extrusion rollers 7-6 rotating oppositely through a gap between the lower ends of the two guide inclined plates 7-4, and the crushed foamed plastic is extruded into a foamed thin plate.

The specific implementation method nine:

as shown in figures 1-14, the cutting mechanism 8 comprises a cutting platform 8-1, platform supporting legs 8-2, a baffle 8-3, a drop hole 8-4, a cutter 8-5, cutter chutes 8-6, a linkage plate I8-7, a transmission round wheel 8-8 and a cutting motor 8-9, wherein the platform supporting legs 8-2 are fixedly connected at four corners of the cutting platform 8-1, the cutting platform 8-1 is provided with the drop hole 8-4, the drop hole 8-4 is positioned right below a gap between two extrusion rollers 7-6, the baffle 8-3 is arranged at the rear side of the drop hole 8-4, the cutter chutes 8-6 are respectively arranged at the left end and the right end of the cutting platform 8-1, the two ends of the cutter 8-5 are respectively connected in the cutter chutes 8-6 in a sliding manner, the cutting motor 8-9 is fixedly connected to the cutting platform 8-1, an output shaft of the cutting motor 8-9 penetrates through the cutting platform 8-1 and is fixedly connected with a transmission round wheel 8-8, one end of a linkage plate I8-7 is rotatably connected with a cutter 8-5, and the other end of the linkage plate I8-7 is rotatably connected with the eccentric position of the transmission round wheel 8-8;

The cutting motor 8-9 drives the transmission circular wheel 8-8 to rotate, the eccentric position of the transmission circular wheel 8-8 drives the linkage plate I8-7 to drive the cutter 8-5 to reciprocate back and forth at the position of the falling hole 8-4 on the cutting platform 8-1, the cutter 8-5 slides backwards to match with the baffle 8-3 to cut off the foam thin plate, and therefore the foam thin plate with the same shape is obtained below the falling hole 8-4, and packaging and transportation are facilitated.

The detailed implementation mode is ten:

as shown in fig. 1-14, the pushing mechanism 9 includes a pushing plate 9-1, a pushing plate 9-2, a linkage plate ii 9-3, a transmission circular wheel ii 9-4 and a pushing motor 9-5, the lower end of the pushing plate 9-2 is fixedly connected to the middle of the pushing plate 9-1, the lower end of the linkage plate ii 9-3 is rotatably connected to the upper end of the pushing plate 9-2, the upper end of the linkage plate ii 9-3 is rotatably connected to the eccentric position of the transmission circular wheel ii 9-4, the transmission circular wheel ii 9-4 is fixedly connected to the output shaft of the pushing motor 9-5, the two pushing mechanisms 9 are arranged, the two pushing plates 9-1 are respectively connected to the two inclined guide plates 7-4 in a sliding mode, and the two pushing motors 9-5 are respectively fixedly connected to the upper ends of the two inclined guide plates 7-4.

The driving round wheel II 9-4 is driven to rotate by the pushing motor 9-5, the eccentric part of the driving round wheel II 9-4 drives the linkage plate II 9-3 to drive the push-pull plate 9-2 and the push plate 9-1 to reciprocate up and down on the guide inclined plate 7-4, so that the foamed plastic of the guide inclined plate 7-4 is pushed, and the foamed plastic is prevented from being blocked at a gap between the lower ends of the two guide inclined plates 7-4 to influence the extrusion of the foamed plastic.

The invention relates to a cold press for recycling waste foamed plastic, which has the use principle that: when in use, the waste foamed plastic is fed into the crushing cavity pipe 1-4 through the feeding port 1-5, the crushing motor 2-1 drives the crushing cutter 2-3 to rotate in the crushing cavity pipe 1-4 through the crushing shaft 2-2, so that the waste foamed plastic is crushed, the crushed foamed plastic falls into the connecting cavity 3-1 from the lower end of the crushing cavity pipe 1-4 and then falls into the conveying straight pipe I3-3, the conveying motor I4-1 drives the conveying spiral plate I4-3 to rotate in the conveying straight pipe I3-3 through the conveying shaft I4-2, so that the crushed foamed plastic is spirally pushed to the conveying bent pipe 3-4 at the right end and is contacted with clean water in the conveying bent pipe 3-4, the crushed foamed plastic is extruded into the cleaning straight pipe 3-6 from the conveying bent pipe 3-4 at the right end along with the continuous pushing of the conveying spiral plate I4-3, fully contacting with clean water, cleaning impurities on crushed foam plastics, driving a stirring spiral plate 5-3 to rotate by a cleaning stirring motor 5-1 through a stirring shaft 5-2, stirring the foam plastics in a cleaning straight pipe 3-6, further cleaning the foam plastics, simultaneously pushing the foam plastics to the left into a conveying bent pipe 3-4 at the left end, extruding the foam plastics into a conveying straight pipe II 3-9 at the conveying bent pipe 3-4 at the left end along with continuous conveying of foam, simultaneously separating from the clean water to finish cleaning, driving the conveying spiral plate II 6-3 to rotate by a conveying motor II 6-1 through a conveying shaft II 6-2, pushing the foam at the lower end of the conveying straight pipe II 3-9 to a blanking port 3-10 at the upper end of the conveying straight pipe II 3-9 to drop, in the pushing process, the heating plate in the conveying straight pipe II 3-9 heats the foamed plastic, the foamed plastic is dried when falling at the blanking port 3-10, and meanwhile, the air in the conveying straight pipe II 3-9 is absorbed and discharged through the air suction pump 3-12, so that the drying effect of the foamed plastic is further improved; the foamed plastic falls into an extrusion cavity pipe 7-1 at a blanking port 3-10, is guided by two guide inclined plates 7-4, falls between two extrusion rollers 7-6 which rotate oppositely from a gap between the lower ends of the two guide inclined plates 7-4 to be extruded into a foamed thin plate, the foamed thin plate is continuously molded and falls into a falling hole 8-4, a cutting motor 8-9 drives a transmission circular wheel 8-8 to rotate, a linkage plate I8-7 is driven to drive a cutter 8-5 to reciprocate at the falling hole 8-4 on a cutting platform 8-1, the cutter 8-5 slides backwards to be matched with a baffle 8-3 to cut the foamed thin plate, so that the foamed thin plate with the same shape is obtained below the falling hole 8-4 to facilitate packaging and transportation, and the transmission circular wheel II 9-4 is driven to rotate by a pushing motor 9-5, the linkage plate II 9-3 is driven to drive the push-pull plate 9-2 and the push plate 9-1 to reciprocate up and down on the guide inclined plate 7-4 to push the foamed plastic of the guide inclined plate 7-4, so that the foamed plastic is prevented from being blocked at a gap between the lower ends of the two guide inclined plates 7-4 to influence the extrusion of the foamed plastic.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a cold press for abandonment foamed plastic retrieves, includes crushing frame (1), rubbing crusher constructs (2), washs chamber frame (3), conveying mechanism I (4), washs rabbling mechanism (5), conveying mechanism II (6), extrusion mechanism (7), shutdown mechanism (8) and push mechanism (9), its characterized in that: the crushing mechanism (2) is connected in the crushing frame (1), the lower end of the cleaning cavity frame (3) is fixedly connected in the crushing frame (1), the right end of the cleaning cavity frame (3) is communicated with the right end of the crushing frame (1), the conveying mechanism I (4) is connected with the right end of the cleaning cavity frame (3), the conveying mechanism II (6) is connected with the left end of the cleaning cavity frame (3), the cleaning and stirring mechanism (5) is connected on the crushing frame (1), the cleaning and stirring mechanism (5) is rotationally connected with the cleaning cavity frame (3), the upper end of the extrusion mechanism (7) is fixedly connected below the left end of the cleaning cavity frame (3), the cutting mechanism (8) is fixedly connected with the lower end of the extrusion mechanism (7), the two pushing mechanisms (9) are arranged, and the two pushing mechanisms (9) are respectively connected to the front side and the rear side of the upper end of the extruding mechanism (7).

2. The cold press for the recycling of waste cellular plastic according to claim 1, characterized in that: the crushing frame (1) comprises a water tank (1-1), a water tank connecting plate (1-2), a supporting plate (1-3), a crushing cavity pipe (1-4), a charging opening (1-5), a crushing mounting plate (1-6), water tank supporting legs (1-7) and a sewage discharge pipe (1-8), wherein the four corners of the lower end of the water tank (1-1) are fixedly connected with the water tank supporting legs (1-7), the lower end of the water tank (1-1) is provided with the sewage discharge pipe (1-8), a valve is arranged on the sewage discharge pipe (1-8), the water tank connecting plate (1-2) is fixedly connected to the upper end of the water tank (1-1), the lower end of the supporting plate (1-3) is fixedly connected to the water tank connecting plate (1-2), and the crushing cavity pipe (1-4) is obliquely and fixedly connected, the upper side of the crushing cavity pipe (1-4) is provided with a charging opening (1-5), and the crushing mounting plate (1-6) is fixedly connected with the upper end of the crushing cavity pipe (1-4).

3. The cold press for the recycling of waste cellular plastic according to claim 1, characterized in that: the crushing mechanism (2) comprises a crushing motor (2-1), a crushing shaft (2-2) and crushing cutters (2-3), a plurality of crushing cutters (2-3) are arranged at the lower end of the crushing shaft (2-2), the upper end of the crushing shaft (2-2) is rotatably connected onto a crushing mounting plate (1-6), the crushing motor (2-1) is fixedly connected onto the crushing mounting plate (1-6), and an output shaft of the crushing motor (2-1) is fixedly connected with the crushing shaft (2-2).

4. A cold press for the recycling of waste foam according to claim 3, characterized in that: the cleaning cavity frame (3) comprises a connecting cavity (3-1), a conveying installation plate I (3-2), a conveying straight pipe I (3-3), a conveying bent pipe (3-4), a stirring installation pipe (3-5), a cleaning straight pipe (3-6), a through long hole (3-7), a connecting plate (3-8), a conveying straight pipe II (3-9), a blanking port (3-10), a conveying installation plate II (3-11) and an air suction pump (3-12), wherein the cleaning straight pipe (3-6) is circumferentially and uniformly provided with a plurality of through long holes (3-7), the lower side of the cleaning straight pipe (3-6) is fixedly connected with two connecting plates (3-8), the lower ends of the two connecting plates (3-8) are fixedly connected in a water tank (1-1), and the horizontal height of the cleaning straight pipe (3-6) is lower than that of the water tank (1-1), both ends of the cleaning straight pipe (3-6) are fixedly connected with conveying bent pipes (3-4), stirring installation pipes (3-5) are fixedly connected on the two conveying bent pipes (3-4), the two stirring installation pipes (3-5) are coaxial with the cleaning straight pipe (3-6), the lower end of the conveying straight pipe I (3-3) is fixedly connected to the upper end of the conveying bent pipe (3-4) positioned at the right end, the upper end of the conveying straight pipe I (3-3) is fixedly connected with a conveying installation plate I (3-2), a connecting cavity (3-1) is arranged on the upper side of the conveying straight pipe I (3-3), the connecting cavity (3-1) is fixedly connected and communicated with the lower end of the crushing cavity pipe (1-4), a heating plate is arranged inside the conveying straight pipe II (3-9), the lower end of the conveying straight pipe II (3-9) is fixedly connected to the upper end of the conveying bent pipe (3-4), the upper end of the conveying straight pipe II (3-9) is fixedly connected with a conveying mounting plate II (3-11), a blanking port (3-10) is arranged below the upper end of the conveying straight pipe II (3-9), and the air suction pump (3-12) is fixedly connected and communicated with the conveying straight pipe II (3-9).

5. The cold press for the recycling of waste cellular plastic according to claim 4, characterized in that: conveying mechanism I (4) including conveying motor I (4-1), carry axle I (4-2) and carry spiral plate I (4-3), fixedly connected with carries spiral plate I (4-3) on carrying axle I (4-2), the output shaft of conveying motor I (4-1) and the upper end fixed connection who carries axle I (4-2), conveying motor I (4-1) fixed connection is on carrying mounting panel I (3-2), the upper end of carrying axle I (4-2) is rotated and is connected on carrying mounting panel I (3-2), carry spiral plate I (4-3) to rotate and connect in carrying I (3-3) and being located the transport return bend (3-4) of right-hand member.

6. The cold press for the recycling of waste cellular plastic according to claim 5, characterized in that: the cleaning and stirring mechanism (5) comprises a cleaning and stirring motor (5-1), a stirring shaft (5-2) and a stirring spiral plate (5-3), wherein two ends of the stirring shaft (5-2) are respectively connected to the left end and the right end of the water tank (1-1) in a rotating manner, the stirring spiral plate (5-3) is fixedly connected to the middle of the stirring shaft (5-2), the stirring spiral plate (5-3) is located in the cleaning and straight pipe (3-6), the stirring shaft (5-2) is rotatably connected with the two stirring installation pipes (3-5), the cleaning and stirring motor (5-1) is fixedly connected to the right end of the water tank (1-1), and the cleaning and stirring motor (5-1) is in transmission connection with the stirring shaft (5-2).

7. The cold press for the recycling of waste cellular plastic according to claim 6, characterized in that: the conveying mechanism II (6) comprises a conveying motor II (6-1), a conveying shaft II (6-2) and a conveying spiral plate II (6-3), the conveying shaft II (6-2) is fixedly connected with the conveying spiral plate II (6-3), an output shaft of the conveying motor II (6-1) is fixedly connected with the upper end of the conveying shaft II (6-2), the conveying motor II (6-1) is fixedly connected onto the conveying mounting plate II (3-11), the upper end of the conveying shaft II (6-2) is rotatably connected onto the conveying mounting plate II (3-11), and the conveying spiral plate II (6-3) is rotatably connected into a conveying straight pipe II (3-9) and a conveying bent pipe (3-4) located at the left end.

8. The cold press for the recycling of waste cellular plastic according to claim 7, characterized in that: the extrusion mechanism (7) comprises an extrusion cavity pipe (7-1), a lower connecting plate (7-2), an upper connecting plate (7-3), a guide inclined plate (7-4), an extrusion motor (7-5) and an extrusion roller (7-6), the left end and the right end of the extrusion cavity pipe (7-1) are fixedly connected with the lower connecting plate (7-2), four corners of the upper end of the extrusion cavity pipe (7-1) are fixedly connected with the upper connecting plate (7-3), the upper ends of the four upper connecting plates (7-3) are fixedly connected with a blanking port (3-10), an opening at the upper end of the extrusion cavity pipe (7-1) is positioned under the blanking port (3-10), and the front side and the rear side of the upper end of an inner cavity of the extrusion cavity pipe (7-1) are fixedly connected with the guide inclined plates (7-4), two extrusion rollers (7-6) are arranged, the two extrusion rollers (7-6) are rotatably connected in an extrusion cavity pipe (7-1), the right ends of the two extrusion rollers (7-6) are in meshed transmission connection, an extrusion motor (7-5) is fixedly connected to the extrusion cavity pipe (7-1), the extrusion motor (7-5) is in transmission connection with one of the extrusion rollers (7-6), and a gap at the lower end of each of the two inclined guide plates (7-4) is located right above a gap between the two extrusion rollers (7-6).

9. The cold press for the recycling of waste foam according to claim 8, characterized in that: the cutting mechanism (8) comprises a cutting platform (8-1), platform supporting legs (8-2), baffles (8-3), falling holes (8-4), cutters (8-5), cutter sliding chutes (8-6), a linkage plate I (8-7), transmission round wheels (8-8) and a cutting motor (8-9), wherein the platform supporting legs (8-2) are fixedly connected at four corners of the cutting platform (8-1), the falling holes (8-4) are formed in the cutting platform (8-1), the falling holes (8-4) are located right below a gap between the two extrusion rollers (7-6), the baffles (8-3) are arranged on the rear side of the falling holes (8-4), the cutter sliding chutes (8-6) are arranged at the left end and the right end of the cutting platform (8-1), two ends of a cutter (8-5) are respectively connected in a cutter sliding groove (8-6) in a sliding mode, a cutting motor (8-9) is fixedly connected to a cutting platform (8-1), an output shaft of the cutting motor (8-9) penetrates through the cutting platform (8-1) and is fixedly connected with a transmission round wheel (8-8), one end of a linkage plate I (8-7) is rotatably connected with the cutter (8-5), and the other end of the linkage plate I (8-7) is rotatably connected with the eccentric position of the transmission round wheel (8-8).

10. The cold press for the recycling of waste cellular plastic according to claim 9, characterized in that: the pushing mechanism (9) comprises a pushing plate (9-1), a push-pull plate (9-2), a linkage plate II (9-3), a transmission circular wheel II (9-4) and a pushing motor (9-5), the lower end of the push-pull plate (9-2) is fixedly connected to the middle of the pushing plate (9-1), the lower end of the linkage plate II (9-3) is rotatably connected with the upper end of the push-pull plate (9-2), the upper end of the linkage plate II (9-3) is rotatably connected with the eccentric position of the transmission circular wheel II (9-4), the transmission circular wheel II (9-4) is fixedly connected to an output shaft of the pushing motor (9-5), two pushing mechanisms (9) are arranged, the two pushing plates (9-1) are respectively and slidably connected to the two guide inclined plates (7-4), two pushing motors (9-5) are respectively and fixedly connected with the upper ends of the two guide inclined plates (7-4).