CN115007101B - Epoxy recovery system - Google Patents

Abstract

The invention relates to the technical field of processing equipment, in particular to an epoxy resin recovery system, which comprises an equipment box and a motor box, wherein a bearing is fixedly embedded on the inner side wall of the equipment box, a stirring horizontal barrel is fixedly arranged on the inner ring of the bearing, a feed inlet is formed in the side wall of the equipment box and the side wall of the stirring horizontal barrel relatively, a discharge outlet is formed in the side wall of the equipment box and the side wall of the stirring horizontal barrel in a penetrating manner, a stirring mechanism is arranged in the stirring horizontal barrel, a driving mechanism is arranged in the motor box, the stirring horizontal barrel is connected with the driving mechanism, and a slag scraping mechanism is arranged in the stirring horizontal barrel. According to the invention, the driving mechanism is arranged to provide power for the stirring mechanism, so that the stirring mechanism disperses the crushed materials, the contact area of the dissolving agent for the crushed materials is increased, the dissolving efficiency is increased, and after the dissolution is completed, the crushed materials are scraped out by the slag scraping mechanism, so that the labor is saved.

Description

Epoxy recovery system

Technical Field

The invention relates to the technical field of processing equipment, in particular to an epoxy resin recovery system.

Background

Epoxy resins are organic polymeric compounds having two or more epoxy groups in the molecule, and their relative molecular masses are not high unless they are individually used. The cured epoxy resin has good physical and chemical properties, excellent bonding strength on the surfaces of metal and nonmetal materials, good dielectric property, small set shrinkage, good dimensional stability, high hardness and better flexibility of products, and is stable to alkali and most solvents, thus being widely applied to various departments of national defense and national economy, and being used for casting, dipping, laminating materials, adhesives, coatings and the like.

In the prior art, in the chemical dissolution process of epoxy resin solid after smashing, smashing objects can be precipitated at the bottom of a dissolution box, smashing objects are few in contact with a dissolving agent, and the epoxy resin is sticky, so that the speed is low in the dissolution process, the dissolution time of the dissolving agent and the epoxy resin is greatly prolonged, and the dissolution efficiency is very influenced.

For this purpose, an epoxy resin recovery system is proposed.

Disclosure of Invention

The invention aims to provide an epoxy resin recovery system, which solves the problems that in the chemical dissolution process of epoxy resin solids after crushing, crushed materials are precipitated at the bottom of a dissolution box, the crushed materials are less in contact with a dissolving agent, and the epoxy resins are sticky, so that the speed is low in the dissolution process, the dissolution time of the dissolving agent and the epoxy resins is greatly prolonged, the dissolution efficiency is very influenced and the like.

In order to achieve the above purpose, the present invention provides the following technical solutions:

The utility model provides an epoxy recovery system, includes equipment box and motor case, the fixed bearing that inlays on the equipment box inside wall, the inner circle fixed mounting of bearing has the stirring to lie in the bucket, the feed inlet has been seted up relatively on the lateral wall of equipment box and stirring to lie in the bucket, the discharge gate has been seted up to link up on the lateral wall of equipment box and stirring to lie in the bucket, be equipped with rabbling mechanism in the bucket, be equipped with actuating mechanism in the motor case, the stirring lies in the bucket and is connected with actuating mechanism, be equipped with in the stirring lying in the bucket and scrape sediment mechanism.

In order to prevent epoxy resin solid from being in the dissolution process, the crushed material is precipitated at the bottom of the dissolution box, so that the dissolution rate is slower, the driving mechanism provides power for the stirring mechanism, the stirring mechanism disperses the crushed material, the contact area of the crushed material for the dissolution agent is increased, the dissolution efficiency is increased, and after dissolution is completed, the crushed material is scraped out by the slag scraping mechanism, so that the labor is saved.

Preferably, the driving mechanism comprises a motor case, a large motor is fixedly installed at the bottom of the inner wall of the motor case, a first gear is fixedly connected to the output end of the large motor, a second gear and a third gear are symmetrically meshed and connected to the two ends of the first gear, one end of the second gear is rotatably connected to the inner wall of the motor case, and one end of the third gear is rotatably installed on the motor case in a penetrating mode.

During operation start big motor, big motor drives first gear and rotates, and first gear drives second gear and third gear meshing and rotates, and the second gear drives the dwang and rotates, and the third gear drives stirring bench press bucket and rotates, so second gear and third gear pivoted opposite direction because second gear and third gear are located first gear symmetry for stirring bench press bucket and dwang relative rotation, stirring mechanism and stirring bench press bucket relative rotation promptly have played the effect of the intensity of increase striking and the degree that smashing the thing rocked, make smashing thing and solution area of contact more abundant.

Preferably, the stirring mechanism comprises a stirring horizontal barrel, the stirring horizontal barrel is fixedly inserted on the third gear and fixedly sleeved in the bearing, the rotating rod is fixedly inserted on the second gear, the rotating rod is rotatably inserted in the stirring horizontal barrel, two supporting rods are symmetrically and fixedly installed on the side wall of the rotating rod, stirring rods are fixedly connected between the two supporting rods, and a plurality of impact rods are fixedly installed on the outer side of the stirring rod.

Because the epoxy resin is sticky, the epoxy resin is not fully contacted with the dissolving agent, the rotating rod drives the impact rod to rotate in the rotating process, and the sticky epoxy resin is hit, so that the sticky epoxy resin is separated, the contact area of the epoxy resin and the dissolving agent is increased, and the dissolving rate is increased.

Preferably, a sliding groove is formed in the outer wall of the stirring and lying barrel, a sliding rod is connected in the sliding groove in a sliding mode, a clamping box is fixedly installed on the outer side wall of the stirring and lying barrel, and a feeding mechanism is arranged in the stirring and lying barrel.

Debugging is carried out before the work, in order to prevent that stirring lying barrel from taking place the dislocation at the inlet and outlet of equipment box and stirring lying barrel after the work, at first to the slip slide bar, with the outstanding one end card of slide bar go into in the card box, make equipment box and stirring lying barrel's import and export play corresponding effect, prevent to advance the material and spill into outside in the time of the ejection of compact, cause the machine damage.

Preferably, the feeding mechanism comprises a first mounting groove, a first conductive spring is fixedly mounted on one side wall of the first mounting groove close to the feeding hole, a baffle is fixedly mounted at one end of the first conductive spring, a first clamping groove matched with the baffle is formed in the opposite surface of the baffle, and a discharging mechanism is arranged in the stirring horizontal barrel.

When the feeding hole is connected with a circuit, the first conductive spring compresses to drive the baffle to move, so that the feeding hole is opened, materials can enter the stirring horizontal barrel, and the first conductive spring of the disconnecting switch pushes the baffle to move to close the feeding hole, so that materials cannot be spilled in the rotation process of the stirring horizontal barrel.

Preferably, the discharging mechanism comprises a discharging groove, the discharging groove is formed in the side wall of the stirring horizontal barrel, a telescopic plate is symmetrically connected to one side wall of the discharging groove, a second conductive spring is fixedly arranged on one side wall of the first mounting groove, a stop block plate is fixedly arranged on one end of the second conductive spring, the stop block plate is fixedly connected with the telescopic plate, a second clamping groove matched with the stop block plate is formed in one side of the first mounting groove, and a control mechanism is arranged in the stirring horizontal barrel.

When the circuit is switched on, the second conductive spring compresses and drives the stop plate to move, the stop plate drives the telescopic plate to shrink, the effect of opening the discharge hole is achieved, finished materials in the stirring horizontal barrel can be discharged from the stirring horizontal barrel, when the switch is disconnected, the second conductive spring pushes the stop plate to move, the stop plate drives the telescopic plate to stretch, the discharge chute is closed, and materials are not spilled in the rotation process of the stirring horizontal barrel.

Preferably, the control mechanism comprises a guide rod, the guide rod is penetrated and is established on the equipment box, the movable sleeve is equipped with first compression spring on the guide rod, one side fixed mounting that the guide rod is close to the stirring bench-mark bucket has the circular telegram board, circular telegram board is towards the one end fixed mounting of stirring bench-mark bucket has the bolt, the second mounting groove has been seted up to the position that the stirring bench-mark bucket corresponds the guide rod, movable mounting has the sliding plate in the second mounting groove, one side fixed mounting of sliding plate has the hinge plate, rotate on the hinge plate and install the conducting rod, the cover is equipped with second compression spring on the conducting rod, fixedly connected with first water leakage section of thick bamboo on the diapire of stirring bench-mark bucket, fixedly connected with first short rope on the roof of first water leakage section of thick bamboo, the bottom fixedly connected with first floater of first short rope, fixedly mounted with first conductive plate and second conductive plate on the inside wall of first water leakage section of thick bamboo, fixedly mounted with third compression spring on the inside wall of first water leakage section of thick bamboo, third compression spring one end fixedly connected with hinge plate, trigger mechanism is equipped with in the inclined drum.

When the initial state, when the slide bar slip card at the box in-process, the slide bar extrudees first compression spring, first compression spring promotes the sliding plate, the sliding plate promotes hinge plate, the conducting bar forward motion, the conducting bar makes the feed inlet circular telegram open and makes the material get into through aperture and first conducting plate contact, first floater come-up when the liquid level rises, the third compression spring blocks the guide arm and prevents conducting bar and second conducting plate contact circular telegram, has played and has made the feed inlet open always, the effect that the discharge gate was closed always.

After the work is finished, when the work is finished, the same sliding rod is clamped into the clamping box, when the liquid level continuously descends, the first floating ball pushes the conducting rod under the action of gravity to enable the hinge plate to be in contact with the first conducting plate, the blanking opening is closed, the feeding opening is opened, and the hinge plate is rotationally connected with the conducting rod due to the fact that the third compression spring is an inclined plane, so that the conducting rod is easier to contact with the first conducting plate under the action of gravity of the first floating ball.

Preferably, the triggering mechanism comprises a second water leakage barrel, the second water leakage barrel is fixedly arranged on the inner wall of the stirring horizontal barrel, a hollow box is fixedly arranged at the top of the inner wall of the second water leakage barrel, two second magnets are fixedly arranged on the inner top wall of the hollow box, a sliding block matched with the hollow box is inserted at the bottom of the hollow box in a sliding manner, a first magnet corresponding to the second magnets is arranged at the top of the sliding block, a conducting strip matched with the sliding block is fixedly arranged at the bottom of the hollow box, a second short rope is fixedly connected at the bottom of the sliding block, and a second floating ball is fixedly connected at the bottom end of the second short rope.

When the material is full of the whole stirring horizontal barrel, the second floating ball floats upwards, and the sliding block opens the switch under the action of attraction of the first magnet and the second magnet to close the feeding hole. At this moment, the first floating ball is in an upward floating state, the conducting rod is contacted with the second conducting plate to electrify the discharge hole, the discharge hole is opened, and the sliding block slides downwards under the action of gravity and contacts with the conducting plate to close the knife switch in the liquid level descending process.

Preferably, the slag scraping mechanism comprises a small motor, the small motor is fixedly arranged on the stirring horizontal barrel, the output end of the small motor is fixedly connected with a reciprocating screw rod, and a sliding block matched with the reciprocating screw rod is movably arranged on the reciprocating screw rod.

When the sliding rod is clamped on the clamping box, the small motor is started simultaneously, the small motor drives the reciprocating screw rod to rotate, the reciprocating screw rod drives the sliding block to slide in a reciprocating manner while rotating, and meanwhile the scraping plate is driven to move in a reciprocating manner, slag is removed from the discharge hole, and when the scraping plate moves in a direction away from the small motor, the scraping plate is blocked by the sliding block to scrape the crushed slag.

Preferably, the bottom fixed mounting of slider has the plectane, set up the fan-shaped groove in the plectane, fixed mounting has the fourth compression spring in the fan-shaped groove, fixedly connected with scraper blade on the fourth compression spring, scraper blade movable mounting is in the fan-shaped groove, fixed mounting has the guide way on the stirring bench press bucket inner wall, slider sliding connection is on the guide way.

When the scraping plate moves towards the direction close to the small motor, the scraping plate is rotatably arranged on the circular plate, so that the risk that the scraping plate is broken in the moving process is prevented, and when the scraping plate moves to the position without the crushed slag, the scraping plate is restored under the action of the spring, and the effect of circularly removing slag is achieved.

Compared with the prior art, the invention has the beneficial effects that:

1. In order to prevent epoxy resin solid from being in the dissolution process, the crushed material is precipitated at the bottom of the dissolution box, so that the dissolution rate is slower, the driving mechanism provides power for the stirring mechanism, the stirring mechanism disperses the crushed material, the contact area of the crushed material for the dissolution agent is increased, the dissolution efficiency is increased, and after dissolution is completed, the crushed material is scraped out by the slag scraping mechanism, so that the labor is saved.

2. During operation start big motor, big motor drives first gear and rotates, and first gear drives second gear and third gear meshing and rotates, and the second gear drives the dwang and rotates, and the third gear drives stirring bench press bucket and rotates, so second gear and third gear pivoted opposite direction because second gear and third gear are located first gear symmetry for stirring bench press bucket and dwang relative rotation, stirring mechanism and stirring bench press bucket relative rotation promptly have played the effect of the intensity of increase striking and the degree that smashing the thing rocked, make smashing thing and solution area of contact more abundant.

3. Debugging is carried out before the work, in order to prevent that stirring lying barrel from taking place the dislocation at the inlet and outlet of equipment box and stirring lying barrel after the work, at first to the slip slide bar, with the outstanding one end card of slide bar go into in the card box, make equipment box and stirring lying barrel's import and export play corresponding effect, prevent to advance the material and spill into outside in the time of the ejection of compact, cause the machine damage.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

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

FIG. 3 is a side view of A-A of the present invention;

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

FIG. 5 is an enlarged view of the invention at B;

FIG. 6 is an enlarged view of the invention at C;

FIG. 7 is an enlarged view of the invention at D;

FIG. 8 is an enlarged view of D-1 of the present invention;

FIG. 9 is an enlarged view of the invention at E;

FIG. 10 is an enlarged view of E-1 of the present invention.

In the figure: 1. an equipment box; 2. a feed inlet; 3. a driving mechanism; 301. a large motor; 302. a first gear; 303. a second gear; 304. a third gear; 4. a stirring mechanism; 401. stirring the horizontal barrel; 402. a rotating lever; 403. a support rod; 404. a stirring rod; 405. a striker rod; 61. a feed mechanism; 601. a first mounting groove; 602. a first conductive spring; 603. a baffle; 604. a first clamping groove; 62. a discharging mechanism; 605. a telescoping plate; 606. a second conductive spring; 607. a stopper plate; 608. a second clamping groove; 609. a discharge chute; 6011. a discharge port; 71. a control mechanism; 701. a guide rod; 702. an L-shaped rod; 703. a first compression spring; 704. an energizing plate; 705. a plug pin; 700. a second mounting groove; 706. a sliding plate; 707. a hinge plate; 708. a conductive rod; 709. a second compression spring; 7000. a first water leakage cylinder; 710. a first conductive plate; 711. a sloping block; 712. a third compression spring; 713. a second conductive plate; 714. a first floating ball; 715. a first short rope; 716. a second floating ball; 717. a second short rope; 72. a trigger mechanism; 7001. a second water leakage cylinder; 7002. a hollow box; 718. a sliding block; 719. a conductive sheet; 720. a first magnet; 721. a second magnet; 8. a slag scraping mechanism; 801. a small motor; 802. a guide groove; 803. a reciprocating screw rod; 804. a slide block; 805. a scraper; 806. a circular plate; 807. a fan-shaped groove; 808. a fourth compression spring; 9. a motor case; 10. a bearing; 11. a slide bar; 12. a sliding groove; 13. a cartridge.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 to 10, the present invention provides an epoxy resin recovery system, which has the following technical scheme:

The utility model provides an epoxy recovery system, including equipment box 1 and motor case 9, fixedly inlay on the equipment box 1 inside wall is equipped with bearing 10, bearing 10's inner circle fixed mounting has stirring horizontal barrel 401, feed inlet 2 has been seted up relatively on the lateral wall of equipment box 1 and stirring horizontal barrel 401, discharge gate 6011 has been seted up to link up on the lateral wall of equipment box 1 and stirring horizontal barrel 401, be equipped with rabbling mechanism 4 in the stirring horizontal barrel 401, be equipped with actuating mechanism 3 in the motor case 9, stirring horizontal barrel 401 is connected with actuating mechanism 3, be equipped with in the stirring horizontal barrel 401 and scrape sediment mechanism 8.

In order to prevent epoxy resin solid from being in the dissolution process, the crushed material is precipitated at the bottom of the dissolution box, so that the dissolution rate is slower, the driving mechanism provides power for the stirring mechanism, the stirring mechanism disperses the crushed material, the contact area of the crushed material for the dissolution agent is increased, the dissolution efficiency is increased, and after dissolution is completed, the crushed material is scraped out by the slag scraping mechanism, so that the labor is saved.

As an embodiment of the present invention, referring to fig. 2, the driving mechanism 3 includes a motor case 9, a large motor 301 is fixedly installed at the bottom of the inner wall of the motor case 9, a first gear 302 is fixedly connected to the output end of the large motor 301, two ends of the first gear 302 are symmetrically connected to a second gear 303 and a third gear 304 in a meshed manner, one end of the second gear 303 is rotatably connected to the inner wall of the motor case 9, and one end of the third gear 304 is rotatably installed on the motor case 9 in a penetrating manner.

When the stirring horizontal barrel stirring device works, the large motor 301 is started, the large motor 301 drives the first gear 302 to rotate, the first gear 302 drives the second gear 303 and the third gear 304 to mesh and rotate, the second gear 303 drives the rotating rod 402 to rotate, the third gear 304 drives the stirring horizontal barrel 401 to rotate, and as the second gear 303 and the third gear 304 are located on the first gear 302 and are symmetrical, the directions of the rotation of the second gear 303 and the rotation of the third gear 304 are opposite, the stirring horizontal barrel 401 and the rotating rod 402 rotate relatively, namely the stirring mechanism rotates relatively with the stirring horizontal barrel 401, the impact strength of the impact is increased, the shaking degree of crushed materials is increased, and the contact area between the crushed materials and the dissolved solution is larger and more sufficient.

As an embodiment of the present invention, referring to fig. 2, the stirring mechanism 4 includes a stirring horizontal barrel 401, the stirring horizontal barrel 401 is fixedly inserted on the third gear 304 and fixedly sleeved in the bearing 10, the rotating rod 402 is fixedly inserted on the second gear 303, the rotating rod 402 is rotatably inserted in the stirring horizontal barrel 401, two support rods 403 are symmetrically and fixedly installed on the side wall of the rotating rod 402, a stirring rod 404 is fixedly connected between the two support rods 403, and a plurality of impact rods 405 are fixedly installed on the outer sides of the stirring rod 404.

Because the epoxy resin has viscosity, the epoxy resin is not fully contacted with the dissolving agent, the rotating rod 402 drives the impact rod 405 to rotate in the rotating process, and the adhered epoxy resin is hit, so that the adhered epoxy resin is separated, the contact area of the epoxy resin and the dissolving agent is increased, and the dissolving rate is increased.

As an embodiment of the present invention, referring to fig. 2, a sliding groove 12 is formed in a stirring and lying barrel 401, a sliding rod 11 is slidably connected in the sliding groove 12, a cartridge 13 is fixedly mounted on the outer side wall of the equipment box 1, and a feeding mechanism 61 is provided in the stirring and lying barrel 401.

Before the work, debugging is carried out, in order to prevent that the material inlet 2 and the material outlet 6011 of the equipment box 1 and the inlet and outlet of the stirring and lying barrel 401 can be misplaced after the work, the sliding rod 11 is firstly slid, one protruding end of the sliding rod 11 is clamped into the clamping box 13, the corresponding effect is achieved between the equipment box 1 and the inlet and outlet of the stirring and lying barrel 401, and the material is prevented from being scattered into the outside during the material inlet and the material outlet, so that the machine is damaged.

As an embodiment of the present invention, referring to fig. 2 and 5, the feeding mechanism 61 includes a first mounting groove 601, a first conductive spring 602 is fixedly mounted on a side wall of the first mounting groove 601 adjacent to the feeding port 2, a baffle plate 603 is fixedly mounted on one end of the first conductive spring 602, a first clamping groove 604 adapted to the baffle plate 603 is formed on the opposite surface of the baffle plate 603, and a discharging mechanism 62 is disposed in the stirring horizontal barrel 401.

When the feeding hole 2 is connected with a circuit, the first conductive spring 602 is electrified to shrink so as to drive the baffle 603 to move, so that the feeding hole is opened to enable materials to enter the stirring horizontal barrel 401, and when the first conductive spring 602 is disconnected, the first conductive spring 602 is stretched to push the baffle 603 to move so as to close the feeding hole 2, so that materials are not spilled in the rotation process of the stirring horizontal barrel 401.

As an embodiment of the present invention, referring to fig. 9, the discharging mechanism 62 includes a discharging tank 609, the discharging tank 609 is opened on a side wall of the stirring and lying barrel 401, a telescopic plate 605 is symmetrically connected to a side wall of the discharging tank 609, a second conductive spring 606 is fixedly installed on a side wall of the first installation tank 601, a stop plate 607 is fixedly installed at one end of the second conductive spring 606, the stop plate 607 is fixedly connected with the telescopic plate 605, a second clamping groove 608 adapted to the stop plate 607 is opened on one side of the first installation tank 601, and a control mechanism 71 is provided in the stirring and lying barrel 401.

When the circuit is on, the second conductive spring 606 compresses and drives the stop plate 607 to move, the stop plate 607 drives the telescopic plate 605 to shrink, the effect of opening the discharge hole 6011 is achieved, the finished material in the stirring and lying barrel 401 can be discharged from the stirring and lying barrel 401, when the switch is turned off, the second conductive spring 606 pushes the stop plate 607 to move, the stop plate 607 drives the telescopic plate 605 to stretch, the discharge chute 609 is closed, and the material is not spilled in the rotation process of the stirring and lying barrel 401.

As an embodiment of the present invention, referring to fig. 10, the control mechanism 71 includes a guide rod 701, the guide rod 701 is inserted through and arranged on the equipment box 1, a first compression spring 703 is movably sleeved on the guide rod 701, one side of the guide rod 701, which is close to the stirring and lying barrel 401, is fixedly provided with an energizing plate 704, one end of the energizing plate 704, which faces the stirring and lying barrel 401, is fixedly provided with a bolt 705, a second installation groove 700 is formed in the position of the stirring and lying barrel 401 corresponding to the guide rod 701, a sliding plate 706 is movably installed in the second installation groove 700, one side of the sliding plate 706 is fixedly provided with a hinge plate 707, a conductive rod 708 is rotatably installed on the hinge plate 707, a second compression spring 709 is sleeved on the conductive rod 708, a first water leakage barrel 7000 is fixedly connected to the bottom wall of the stirring and lying barrel 401, a first short rope 715 is fixedly connected to the bottom end of the first short rope 715, a first floating ball 714 is fixedly installed on the inner side wall of the first water leakage barrel 7000, a first conductive plate 710 and a second conductive plate 713 are fixedly installed on the inner wall of the first water leakage barrel 7000, a third compression spring 712 is fixedly installed on the inner wall of the first water leakage barrel 7000, one end of the third compression spring 712 is fixedly connected to the stirring and the inclined mechanism 401 is provided with a trigger mechanism 72.

In the initial state, the sliding rod 11 is slidably clamped in the clamping box 13, the sliding rod 11 moves towards the guide rod 701 to push the guide rod 701, the guide rod 701 pushes the sliding plate 706, the sliding plate 706 pushes the hinge plate 707 and the conductive rod 708 to move forwards, the conductive rod 708 contacts with the first conductive plate 710 and is electrified to open the feeding port to enable materials to enter (note that a fine hole for the conductive rod 708 to enter and exit is formed in the stirring horizontal barrel 401, so that the materials cannot leak out, but the conductive rod 708 can be allowed to pass through), and as the crushed epoxy resin and the dissolving agent are mixed, the density of the floating ball is smaller than that of the crushed epoxy resin and the dissolving agent, the first floating ball 714 moves upwards along with the rising of the liquid level after feeding, and the third compression spring 712 clamps the conductive rod 708 to prevent the conductive rod 708 from contacting with the second conductive plate 713 and electrifying, so that the feeding port 2 is always opened, and the discharging port 6011 is always closed.

After the work is finished, the sliding rod 11 is clamped into the clamping box 13, when the liquid level continues to descend, the first floating ball 714 pushes the conductive rod 708 under the action of gravity, the conductive rod 708 is clamped originally, the first floating ball 714 contacts with the first conductive plate 710 under the action of pressure, so that the blanking port is closed, the feeding port is opened, and the hinge plate 707 is rotationally connected with the conductive rod 708 due to the fact that the third compression spring 712 is an inclined plane, so that the conductive rod 708 is easier to contact with the first conductive plate 710 under the action of gravity of the first floating ball 714.

As an embodiment of the present invention, referring to fig. 6, the triggering mechanism 72 includes a second water leakage tube 7001, the second water leakage tube 7001 is fixedly installed on the inner wall of the stirring horizontal tube 401, a hollow box 7002 is fixedly installed on the top of the inner wall of the second water leakage tube 7001, two second magnets 721 are fixedly installed on the inner top wall of the hollow box 7002, a sliding block 718 adapted to the hollow box 7002 is slidably inserted at the bottom of the hollow box 7002, a first magnet 720 corresponding to the second magnet 721 is installed at the top of the sliding block 718, a conductive sheet 719 adapted to the sliding block 718 is fixedly installed at the bottom of the hollow box 7002, a second short rope 717 is fixedly connected to the bottom of the sliding block 718, and a second floating ball 716 is fixedly connected to the bottom of the second short rope 717.

When the material fills the whole stirring horizontal barrel 401, the second floating ball 716 floats upwards, and the sliding block 718 turns off the switch under the action of the attraction of the first magnet 720 and the second magnet 721 to close the feed inlet 2. At this time, the first floating ball 714 is in an upward floating state, the conductive rod 708 contacts with the second conductive plate 713 to energize the discharge port 6011, the discharge port 6011 is opened, the sliding block 718 slides downward under the gravity action of the second floating ball 716 to contact with the conductive sheet 719 in the process of lowering the top surface of the material, so that the power is turned on, and the first conductive spring 602 is energized to open the feed port 2, so that new material is replenished for next mixing.

As an embodiment of the invention, referring to fig. 2 and 7, the slag scraping mechanism 8 comprises a small motor 801, the small motor 801 is fixedly arranged on the stirring horizontal barrel 401, the output end of the small motor 801 is fixedly connected with a reciprocating screw 803, and a sliding block 804 which is matched with the reciprocating screw 803 is movably arranged on the reciprocating screw 803.

When the sliding rod 11 is clamped on the clamping box 13 and the small motor 801 is started, the small motor 801 drives the reciprocating screw rod 803 to rotate, the reciprocating screw rod 803 drives the sliding block 804 to slide in a reciprocating manner while driving the scraping plate 805 to move in a reciprocating manner, slag is removed from the discharge hole 6011, and when the scraping plate 805 moves away from the small motor 801, the scraping plate 805 is blocked by the sliding block 804 to scrape the crushed slag.

As an embodiment of the present invention, referring to fig. 8, a circular plate 806 is fixedly installed at the bottom of the sliding block 804, a fan-shaped groove 807 is formed in the circular plate 806, a fourth compression spring 808 is fixedly installed in the fan-shaped groove 807, a scraper 805 is fixedly connected to the fourth compression spring 808, the scraper 805 is movably installed in the fan-shaped groove 807, a guide groove 802 is fixedly installed on the inner wall of the stirring and lying barrel 401, and the sliding block 804 is slidably connected to the guide groove 802.

When the scraper 805 moves in a direction approaching the small motor 801, the scraper 805 is rotatably mounted on the circular plate 806, so that the risk of breakage of the scraper 805 is prevented in the moving process, and the scraper 805 returns to the original state under the action of a spring when the scraper 805 moves to a position without crushing slag, thereby playing a role in cyclic deslagging.

Working principle: firstly, a user performs debugging before working, as the stirring horizontal barrel 401 is arranged after working, the feeding and discharging holes of the equipment box 1 and the stirring horizontal barrel 401 are staggered, and firstly, one protruding end of the sliding rod 11 is clamped into the clamping box 13 by the sliding rod 11, so that the equipment box 1 corresponds to the feeding and discharging holes of the stirring horizontal barrel 401, and the situation that materials are scattered into the outside to cause machine damage during feeding and discharging is prevented. Meanwhile, as a single-pole double-throw switch is used, when the sliding rod 11 is clamped in the clamping box 13 in a sliding manner, the sliding rod 11 pushes the guide rod 701 to push the sliding plate 706, the sliding plate 706 pushes the hinge plate 707 and the conductive rod 708 to move forward, the conductive rod 708 contacts the first conductive plate 710 through the small hole to complete a circuit, so that the first conductive spring 602 compresses to drive the baffle 603 to move, and the effect of opening the feed inlet 2 is achieved, and materials enter. When the liquid level rises, the first floating ball 714 floats upwards, the third compression spring 712 clamps the guide rod 701, the conductive rod 708 is prevented from being electrified by contact with the second conductive plate 713, the discharge chute 609 is closed all the time, when the material fills the whole stirring horizontal barrel 401, the second floating ball 716 floats upwards, and the sliding block 718 opens the switch under the action of the attraction of the first magnet 720 and the second magnet 721, so that the feed inlet 2 is closed.

Then the sliding rod 11 slides out of the clamping groove of the clamping box 13, the large motor 301 is started to start to work, the large motor 301 drives the first gear 302 to rotate, the first gear 302 drives the second gear 303 and the third gear 304 to mesh and rotate, the second gear 303 drives the rotating rod 402 to rotate, the third gear 304 drives the stirring horizontal barrel 401 to rotate, and the second gear 303 and the third gear 304 are positioned on the first gear 302 symmetrically, so that the rotating directions of the second gear 303 and the third gear 304 are opposite, the stirring horizontal barrel 401 and the rotating rod 402 relatively rotate, and the stirring mechanism relatively rotates to increase the impact strength and the shaking degree of crushed materials, so that the contact area between the crushed materials and the dissolved solution is larger and more sufficient.

When the work is finished, the sliding rod 11 is clamped into the clamping box 13, at the moment, the first floating ball 714 floats upwards under the action of buoyancy, the conductive rod 708 is in contact with the second conductive plate 713 for electrifying, the second conductive spring 606 compresses to drive the stop plate 607 to move, and the stop plate 607 drives the telescopic plate 605 to shrink, so that the effect of opening the discharging chute 609 is achieved. Meanwhile, the small motor 801 is started, the small motor 801 drives the reciprocating screw rod 803 to rotate, the reciprocating screw rod 803 rotates and drives the sliding block 804 to slide in a reciprocating manner, meanwhile, the scraping plate 805 is driven to move in a reciprocating manner, slag is removed from the discharge hole 6011, when the scraping plate 805 moves away from the small motor 801, the scraping plate 805 is blocked by the sliding block 804 to scrape the crushed slag, when the scraping plate 805 moves towards the direction close to the small motor 801, the scraping plate 805 is rotatably arranged on the circular plate 806, the risk that the scraping plate 805 is broken is prevented in the moving process, and when the scraping plate 805 moves to a position without the crushed slag, the scraping plate 805 is restored to be in a state under the action of the spring, and the effect of cyclic slag removal is achieved. When the liquid level descends, the sliding block 718 slides downwards under the action of gravity to be in contact with the conductive plate 719, so that the power supply is turned on, and when the liquid level continues to descend, the first floating ball 714 pushes the conductive rod 708 under the action of gravity to disconnect the hinge plate 707 from the second conductive plate 713 and make contact with the first conductive plate 710, so that the discharge chute 609 is closed, the feed inlet 2 is opened, and because the third compression spring 712 is an inclined plane, the hinge plate 707 is rotationally connected with the conductive rod 708, so that the conductive rod 708 is easier to contact with the first conductive plate 710 under the action of gravity of the first floating ball 714.

The electric elements are all connected with an external main controller and 220V mains supply through a transformer, and the main controller can be conventional known equipment for controlling a computer and the like.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (4)

1. An epoxy recovery system, includes equipment box (1) and motor case (9), its characterized in that: the stirring horizontal barrel comprises a stirring horizontal barrel body and is characterized in that a bearing (10) is fixedly embedded in the inner side wall of the equipment box (1), a stirring horizontal barrel body (401) is fixedly arranged on the inner ring of the bearing (10), a feeding hole (2) is formed in the side wall of the equipment box (1) and the side wall of the stirring horizontal barrel body (401) in a penetrating manner, a discharging hole (6011) is formed in the side wall of the equipment box (1) and the side wall of the stirring horizontal barrel body (401), a stirring mechanism (4) is arranged in the stirring horizontal barrel body (401), a driving mechanism (3) is arranged in the motor box (9), the stirring horizontal barrel body (401) is connected with the driving mechanism (3), and a slag scraping mechanism (8) is arranged in the stirring horizontal barrel body (401);

The stirring mechanism (4) comprises a stirring horizontal barrel (401), the stirring horizontal barrel (401) is fixedly inserted on a third gear (304) and fixedly sleeved in a bearing (10), a rotating rod (402) is fixedly inserted on a second gear (303), the rotating rod (402) is rotatably inserted in the stirring horizontal barrel (401), two supporting rods (403) are symmetrically and fixedly arranged on the side wall of the rotating rod (402), stirring rods (404) are fixedly connected between the two supporting rods (403), and a plurality of impact rods (405) are fixedly arranged on the outer sides of the stirring rods (404);

A sliding groove (12) is formed in the outer wall of the stirring horizontal barrel (401), a sliding rod (11) is connected in the sliding groove (12) in a sliding manner, a clamping box (13) is fixedly arranged on the outer side wall of the equipment box (1), and a feeding mechanism (61) is arranged in the stirring horizontal barrel (401);

The feeding mechanism (61) comprises a first mounting groove (601), a first conductive spring (602) is fixedly arranged on one side wall of the first mounting groove (601) close to the feeding hole (2), a baffle plate (603) is fixedly arranged at one end of the first conductive spring (602), a first clamping groove (604) matched with the baffle plate (603) is formed in the opposite surface of the baffle plate (603), and a discharging mechanism (62) is arranged in the stirring horizontal barrel (401);

The discharging mechanism (62) comprises a discharging groove (609), the discharging groove (609) is formed in the side wall of the stirring horizontal barrel (401), a telescopic plate (605) is symmetrically connected to one side wall of the discharging groove (609), a second conductive spring (606) is fixedly arranged on one side wall of the discharging groove (609), a stop block plate (607) is fixedly arranged at one end of the second conductive spring (606), the stop block plate (607) is fixedly connected with the telescopic plate (605), a second clamping groove (608) matched with the stop block plate (607) is formed in one side of the discharging groove (609), and a control mechanism (71) is arranged in the stirring horizontal barrel (401);

The control mechanism (71) comprises a guide rod (701), the guide rod (701) is inserted and arranged on the equipment box (1), a first compression spring (703) is movably sleeved on the guide rod (701), one side of the guide rod (701) close to the stirring horizontal barrel (401) is fixedly provided with an electrifying plate (704) through an L-shaped rod (702), one end of the stirring horizontal barrel (401) close to the electrifying plate (704) is provided with a plug pin (705), the position of the stirring horizontal barrel (401) corresponding to the guide rod (701) is provided with a second mounting groove (700), a sliding plate (706) is movably arranged in the second mounting groove (700), one side of the sliding plate (706) is fixedly provided with a hinge plate (707), a conducting rod (708) is rotatably arranged on the hinge plate (707), a second compression spring (709) is sleeved on the conducting rod (708), the bottom wall of the stirring horizontal barrel (401) is fixedly connected with a first drain cylinder (7000), the top wall of the first drain cylinder (401) is fixedly connected with a first short rope (7000), one side of the first drain cylinder (714) is fixedly connected with a first floating ball (7000), one side of the first drain cylinder (713) is fixedly connected with the first drain plate (713), a third compression spring (712) is fixedly arranged on the inner side wall of the first water leakage barrel (7000), one end of the third compression spring (712) is fixedly connected with an inclined block (711), and a trigger mechanism (72) is arranged in the stirring horizontal barrel (401);

The trigger mechanism (72) comprises a second water leakage barrel (7001), the second water leakage barrel (7001) is fixedly arranged on the inner wall of the stirring horizontal barrel (401), a hollow box (7002) is fixedly arranged at the top of the inner wall of the second water leakage barrel (7001), two second magnets (721) are fixedly arranged on the inner top wall of the hollow box (7002), a sliding block (718) matched with the hollow box (7002) is inserted in a sliding manner at the bottom of the hollow box (7002), a first magnet (720) corresponding to the second magnets (721) is arranged at the top of the sliding block (718), a conductive sheet (719) matched with the sliding block (718) is fixedly arranged at the bottom of the hollow box (7002), and a second short rope (717) is fixedly connected to the bottom of the sliding block (718), and a second floating ball (716) is fixedly connected to the bottom of the second short rope (717).

2. An epoxy resin recovery system according to claim 1, wherein: the driving mechanism (3) comprises a motor case (9), a large motor (301) is fixedly arranged at the bottom of the inner wall of the motor case (9), a first gear (302) is fixedly connected to the output end of the large motor (301), a second gear (303) and a third gear (304) are symmetrically connected to the two ends of the first gear (302) in a meshed mode, one end of the second gear (303) is rotatably connected to the inner wall of the motor case (9), and one end of the third gear (304) is rotatably installed on the motor case (9) in a penetrating mode.

3. An epoxy resin recovery system according to claim 1, wherein: the slag scraping mechanism (8) comprises a small motor (801), the small motor (801) is fixedly arranged on the stirring horizontal barrel (401), the output end of the small motor (801) is fixedly connected with a reciprocating screw rod (803), and a sliding block (804) which is matched with the reciprocating screw rod (803) is movably arranged on the reciprocating screw rod.

4. An epoxy resin recovery system according to claim 3, wherein: the bottom fixed mounting of slider (804) has plectane (806), set up fan-shaped groove (807) in plectane (806), fixed mounting has fourth compression spring (808) in fan-shaped groove (807), fixedly connected with scraper blade (805) on fourth compression spring (808), scraper blade (805) movable mounting is in fan-shaped groove (807), fixed mounting has guide way (802) on stirring bench bucket (401) inner wall, slider (804) sliding connection is on guide way (802).