CN116351375B

CN116351375B - Equipment for producing temperature-sensitive electronic adhesive

Info

Publication number: CN116351375B
Application number: CN202310637465.7A
Authority: CN
Inventors: 吴志龙; 康润华; 陈金亮
Original assignee: Shenzhen Hongjin Technology Co ltd
Current assignee: Shenzhen Hongjin Technology Co ltd
Priority date: 2023-06-01
Filing date: 2023-06-01
Publication date: 2023-08-04
Anticipated expiration: 2043-06-01
Also published as: CN116351375A

Abstract

The invention discloses equipment for producing a temperature-sensitive electronic adhesive, and relates to the technical field of production of heat-sensitive adhesives. The equipment for producing the temperature-sensitive electronic adhesive comprises a bottom plate, wherein the upper side wall of the bottom plate is fixedly connected with two symmetrically arranged supporting legs, the upper ends of the supporting legs are fixedly connected with a reaction kettle, and the top of the reaction kettle is fixedly connected with a plurality of feed valves. Can be when stirring for first puddler and solid fixed ring carry out reciprocating motion on the horizontal direction on the one hand, and on the other hand carries out reciprocating motion on vertical direction, thereby carry out the cutting stirring of level and vertical direction to the raw materials, thereby make the efficiency of stirring higher, the effect is better, guarantee the efficiency and the effect that temperature sensitive electronic adhesive was emulsified, simultaneously, can carry out reciprocating knock vibrations to the inside wall of reation kettle and the lateral wall of (mixing) shaft, thereby reduce the material adhesion, guarantee the ejection of compact efficiency and the effect of temperature sensitive electronic adhesive after the emulsification, avoid extravagant.

Description

Equipment for producing temperature-sensitive electronic adhesive

Technical Field

The invention relates to the technical field of production of heat-sensitive adhesives, in particular to equipment for producing a temperature-sensitive electronic adhesive.

Background

The temperature sensitive electronic adhesive is used for gluing electronic products, and when the electronic products are produced, various raw materials and surfactants are required to be stirred and emulsified by using emulsifying equipment.

However, current emulsification equipment of production temperature sensitive type electron adhesive is when using, mainly utilizes the (mixing) shaft to drive stirring vane's rotation and stir and mix the emulsification, but, when stirring, multiple raw materials produce the layering easily, influence the efficiency and the effect of stirring to influence the efficiency and the effect of emulsification, and then influence the production efficiency and the quality of temperature sensitive type electron adhesive, and, the material is easy to adhere on reation kettle inner wall and stirring subassembly, not only influences the efficiency and the effect of stirring, moreover, influences the ejection of compact efficiency and the effect of temperature sensitive type electron adhesive after emulsifying, causes the waste.

Disclosure of Invention

The invention aims to provide equipment for producing temperature-sensitive electronic adhesive, so as to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a production temperature sensitive electronic adhesive equipment, includes the bottom plate, the landing leg that two symmetries set up of upper side wall fixedly connected with of bottom plate, and the upper end fixedly connected with reation kettle of landing leg, the top fixedly connected with of reation kettle has a plurality of feed valves, and the upper end fixedly connected with inlet pipe of feed valve, the bottom fixedly connected with bleeder valve of reation kettle, and the lower extreme fixedly connected with discharging pipe of bleeder valve, be connected with the (mixing) shaft through the pivot rotation in the reation kettle, and the top fixedly connected with L shape backup pad that sets up of reation kettle, the upper side wall fixedly connected with first motor of backup pad, and the output of first motor is fixed with the upper end of pivot, the lateral wall of (mixing) shaft is provided with first rabbling mechanism and the second rabbling mechanism that is used for stirring the raw materials, and is provided with in the reation kettle and the (mixing) shaft and beats the mechanism that shakes.

The second stirring mechanism comprises a plurality of first connecting plates arranged in an array, each first connecting plate is connected with the side wall of the stirring shaft through a moving mechanism, the lower side wall of each first connecting plate is fixedly connected with a plurality of first stirring rods arranged in the array, the side wall of each first stirring rod is fixedly sleeved with a fixing ring, and the movement of each first connecting plate is pushed through a first pushing mechanism.

Preferably, the first stirring mechanism comprises a second connecting plate fixedly connected to the side wall of the stirring shaft in a plurality of array mode, the lower side wall of the second connecting plate is fixedly connected with a plurality of second stirring rods in array mode, the side wall of the second connecting plate is fixedly connected with a first connecting block, and the side wall of the first connecting block is fixedly connected with a scraping plate.

Preferably, the moving mechanism comprises two symmetrically arranged fixed plates fixedly connected to the side wall of the stirring shaft, the side wall of the fixed plates is provided with a sliding groove which is obliquely arranged, the side wall of the first connecting plate is fixedly inserted with a sliding block, the sliding block slides in the sliding groove, and a reset mechanism is arranged between the first connecting plate and the fixed plates.

Preferably, the reset mechanism comprises a second connecting block fixedly connected to the side wall of the fixed plate, the lower side wall of the second connecting block is rotationally connected with a first ball, the side wall of the first ball is fixedly connected with a first connecting rod, the lower end of the first connecting rod is fixedly connected with a sleeve, the sleeve is internally and slidably connected with a sliding disc through a first spring, the lower end of the sliding disc is fixedly connected with a loop bar, the lower end of the loop bar is fixedly connected with a second connecting rod, the upper side wall of the first connecting plate is rotationally connected with a second ball, and the lower end of the second connecting rod is fixed with the side wall of the second ball.

Preferably, the first pushing mechanism comprises a first L-shaped plate fixedly connected to the upper side wall of the first connecting plate, the top of the reaction kettle is rotationally connected with a rotating ring through a rotating mechanism, the lower side wall of the rotating ring is fixedly connected with a plurality of second L-shaped plates arranged in an array, the upper side wall of the second L-shaped plate is fixedly connected with a triangular block, the triangular block comprises an inclined plane, and the first L-shaped plate slides on the inclined plane.

Preferably, the rotating mechanism comprises a supporting ring fixedly connected to the top of the reaction kettle, the side wall of the supporting ring is rotationally connected with a gear ring, the top of the reaction kettle is rotationally connected with a gear through a rotating rod, the gear is meshed with the gear ring, and the rotation of the rotating rod is driven by a driving mechanism.

Preferably, the driving mechanism comprises a first belt pulley fixedly sleeved on the side wall of the rotating shaft, the upper end of the rotating rod is fixedly connected with a second belt pulley, and belt transmission is carried out between the second belt pulley and the first belt pulley.

Preferably, the knocking mechanism comprises a moving plate, the moving plate is connected with the side wall of the fixed plate through a lifting mechanism, two symmetrically arranged first T-shaped guide rods are inserted into the side wall of the moving plate, a second spring is sleeved on the side wall of the first T-shaped guide rods, one end of each first T-shaped guide rod is fixedly connected with a U-shaped plate, the side wall of each U-shaped plate is fixedly connected with a knocking pin and a knocking rod, and the U-shaped plates are moved to push through a second pushing mechanism.

Preferably, the elevating system includes the third connecting block of fixed plate lateral wall, and the lower lateral wall fixedly connected with guide arm of third connecting block, the lateral wall cover of guide arm is equipped with the pipe, and the lower extreme of pipe is fixed with the last lateral wall of movable plate, the last lateral wall fixedly connected with screwed pipe of movable plate, and screwed pipe internal thread connection has the threaded rod, the upper end of threaded rod is rotated with the lower lateral wall of third connecting block and is connected, the last lateral wall fixedly connected with second motor of third connecting block, and the output of second motor is fixed with the upper end of threaded rod, visual sensor has been inserted to reation kettle's top is fixed, and second motor and visual sensor electric connection.

Preferably, the second pushing mechanism comprises a second T-shaped guide rod which is inserted into the lower side wall of the third connecting block and symmetrically arranged, the lower end of the second T-shaped guide rod is fixedly connected with a moving block, a third spring is sleeved on the side wall of the second T-shaped guide rod, the side wall of the moving block is fixedly connected with a pushing plate, the side wall of the pushing plate is fixedly connected with a plurality of convex strips arranged in an array, the side wall of the U-shaped plate is fixedly connected with a pushing pin, and one end of the pushing pin slides on the side wall of the convex strip.

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

(1) This kind of production temperature sensitive type electronic adhesive equipment, through setting up second rabbling mechanism etc, when emulsifying, add raw materials and surfactant in to reation kettle through the inlet pipe, then, start first motor, the rotation of first motor drives the rotation of (mixing) shaft, and then drive the rotation of second connecting plate and first connecting plate, thereby make second puddler and first puddler stir the raw materials, simultaneously, the rotation of second connecting plate drives the synchronous rotation of scraper blade through first connecting block, can strike off the clearance to the material of reation kettle inner wall adhesion, make the stirring more abundant, simultaneously, reduce the adhesion of material, and, when first L shaped plate offsets with the inclined plane, promote the sliding block and upwards slide along the spread groove, when first L shaped plate passes the inclined plane, the sliding block can down remove the reset under reset mechanism's effect, thereby make first connecting plate reciprocate in the incline direction, decompose its motion, can make first puddler and solid fixed ring reciprocate in the horizontal direction on the one hand, on the other hand reciprocate in vertical direction, thereby carry out the adhesion of horizontal and vertical direction, thereby make the efficiency of cutting the adhesive of emulsion type that the efficiency is better, and the efficiency of emulsification type is guaranteed.

(2) This kind of production temperature sensitive type electronic adhesive equipment through setting up slewing mechanism etc. when stirring, the rotation of (mixing) shaft drives the synchronous rotation of first belt pulley to drive the rotation of second belt pulley and dwang through the belt, and then drive the rotation of ring gear, when the ring gear rotates, drive swivel becket and second L shaped plate and carry out synchronous rotation, thereby adjust the position of triangular block, and then adjust the position when first connecting plate upwards moves to one side, make the efficiency of stirring higher, the effect is better, guarantee the efficiency and the effect that temperature sensitive type electronic adhesive was emulsified.

(3) When stirring, the sliding block moves upwards along the sliding groove obliquely and is propped against the lower side wall of the moving block, so that the moving block and the pushing plate are pushed to move upwards, when the end part of the pushing pin is propped against the side wall of the raised line, the U-shaped plate is pushed to move far away from the pushing plate, meanwhile, the first T-shaped guide rod is compressed, when the end part of the pushing pin passes over the side wall of the raised line, the U-shaped plate can move and reset under the action of the second spring, so that the U-shaped plate moves in a reciprocating manner, the U-shaped plate moves to drive the beating rod and the beating pin to synchronously move, so that the beating rod can perform reciprocating beating vibration on the inner side wall of the reaction kettle, and meanwhile, the beating pin performs reciprocating beating vibration on the side wall of the stirring shaft, so that material adhesion is reduced, the discharging efficiency and effect of the emulsified temperature-sensitive electronic adhesive are ensured, and waste is avoided.

Drawings

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

FIG. 2 is a schematic cross-sectional structural view of a reaction vessel according to the present invention;

FIG. 3 is a schematic cross-sectional view of another view of the reactor of the present invention;

FIG. 4 is a schematic diagram of a first stirring mechanism and a second stirring mechanism according to the present invention;

FIG. 5 is a schematic view of the position of the moving mechanism and the resetting mechanism according to the present invention;

FIG. 6 is a schematic view of the overall structure of the striking mechanism according to the present invention;

FIG. 7 is an enlarged schematic view of FIG. 2A;

FIG. 8 is an enlarged schematic view of the structure shown at B in FIG. 3;

FIG. 9 is an enlarged schematic view of FIG. 4C;

FIG. 10 is an enlarged schematic view of the structure of FIG. 5D;

fig. 11 is an enlarged schematic view of the structure at E in fig. 6.

In the figure: 1. a bottom plate; 2. a first stirring mechanism; 201. a second connecting plate; 202. a second stirring rod; 203. a first connection block; 204. a scraper; 3. a second stirring mechanism; 301. a first connection plate; 302. a first stirring rod; 303. a fixing ring; 4. a moving mechanism; 401. a fixing plate; 402. a sliding groove; 403. a sliding block; 5. a reset mechanism; 501. a first sphere; 502. a sleeve; 503. a first spring; 504. a sliding plate; 505. a loop bar; 506. a second connecting rod; 507. a second sphere; 508. a second connection block; 509. a first connecting rod; 6. a first pushing mechanism; 601. a first L-shaped plate; 602. a rotating ring; 603. a second L-shaped plate; 604. triangular blocks; 605. an inclined plane; 7. a rotating mechanism; 701. a support ring; 702. a gear ring; 703. a rotating lever; 704. a gear; 8. a knocking mechanism; 801. a moving plate; 802. a first T-shaped guide bar; 803. a second spring; 804. a U-shaped plate; 805. knocking the rod; 806. knocking the pin; 9. a lifting mechanism; 901. a third connecting block; 902. a guide rod; 903. a conduit; 904. a threaded rod; 905. a threaded tube; 906. a second motor; 907. a visual sensor; 10. a driving mechanism; 1001. a first pulley; 1002. a second pulley; 1003. a belt; 11. a support leg; 12. a reaction kettle; 13. a feed valve; 14. a feed pipe; 15. a discharge pipe; 16. a stirring shaft; 17. a second pushing mechanism; 1701. a second T-shaped guide bar; 1702. a moving block; 1703. a third spring; 1704. a pushing plate; 1705. a convex strip; 1706. pushing the pin; 18. a discharge valve; 19. a support plate; 20. a first motor.

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 11, the present invention provides a technical solution: the utility model provides a production temperature sensitive electronic adhesive equipment, including bottom plate 1, the upper side wall fixedly connected with of bottom plate 1 has landing leg 11 that two symmetries set up, and the upper end fixedly connected with reation kettle 12 of landing leg 11, the top fixedly connected with of reation kettle 12 has a plurality of feed valves 13, and the upper end fixedly connected with inlet pipe 14 of feed valve 13, the bottom fixedly connected with bleeder valve 18 of reation kettle 12, and the lower extreme fixedly connected with discharging pipe 15 of bleeder valve 18, rotationally connect with (mixing) shaft 16 through the pivot in reation kettle 12, and the top fixedly connected with backup pad 19 of reation kettle 12 that L shape set up, the upper side wall fixedly connected with first motor 20 of backup pad 19, and the output of first motor 20 is fixed with the upper end of pivot, the lateral wall of (mixing) shaft 16 is provided with first rabbling mechanism 2 and second rabbling mechanism 3 that are used for carrying out the stirring to the raw materials, and be provided with in reation kettle 12 and the rabbling mechanism 8 that is used for carrying out the knocking vibrations to stirred shaft 16;

the second rabbling mechanism 3 includes the first connecting plate 301 that a plurality of arrays set up, and each first connecting plate 301 is connected with the lateral wall of (mixing) shaft 16 through moving mechanism 4, the lower lateral wall fixedly connected with of first connecting plate 301 is a plurality of first puddler 302 that the array set up, and the fixed cover of lateral wall of first puddler 302 is equipped with solid fixed ring 303, the removal of first connecting plate 301 promotes through first pushing mechanism 6, can be when stirring, make first puddler 302 and solid fixed ring 303 carry out reciprocating motion in the horizontal direction on the one hand, on the other hand carry out reciprocating motion in the vertical direction, thereby carry out the cutting stirring of horizontal and vertical direction to the raw materials, thereby make the efficiency of stirring higher, the effect is better, guarantee the efficiency and the effect that temperature sensitive electronic adhesive is emulsified, simultaneously, can carry out reciprocating strike vibrations to the inside wall of reation kettle 12 and the lateral wall of (mixing) shaft 16, thereby reduce the material adhesion, guarantee the ejection of compact efficiency and the effect of temperature sensitive electronic adhesive after the emulsification, avoid extravagant.

Referring to fig. 5, the first stirring mechanism 2 includes a second connecting plate 201 fixedly connected to a plurality of arrays on a side wall of the stirring shaft 16, and a plurality of second stirring rods 202 arranged in arrays are fixedly connected to a lower side wall of the second connecting plate 201, a first connecting block 203 is fixedly connected to a side wall of the second connecting plate 201, a scraper 204 is fixedly connected to a side wall of the first connecting block 203, the first motor 20 is started, the rotation of the first motor 20 drives the rotation of the stirring shaft 16, and then drives the rotation of the second connecting plate 201 and the second stirring rods 202, so that materials are stirred, and meanwhile, the rotation of the second connecting plate 201 drives synchronous rotation of the scraper 204 through the first connecting block 203, so that the materials adhered to the inner wall of the reaction kettle 12 can be scraped and cleaned, so that the stirring is more sufficient, and meanwhile, the adhesion of the materials is reduced.

Referring to fig. 10, the moving mechanism 4 includes two symmetrically disposed fixing plates 401 fixedly connected to the side wall of the stirring shaft 16, and a sliding groove 402 disposed obliquely is formed in the side wall of the fixing plate 401, a sliding block 403 is fixedly inserted into the side wall of the first connecting plate 301, and the sliding block 403 slides in the sliding groove 402, and a reset mechanism 5 is disposed between the first connecting plate 301 and the fixing plate 401, so as to guide and limit the movement of the first connecting plate 301.

Referring to fig. 10, the reset mechanism 5 includes a second connection block 508 fixedly connected to a side wall of the fixed plate 401, wherein a lower side wall of the second connection block 508 is rotatably connected to a first ball 501, a side wall of the first ball 501 is fixedly connected to a first connection rod 509, a lower end of the first connection rod 509 is fixedly connected to a sleeve 502, a sliding disc 504 is slidably connected to the sleeve 502 through a first spring 503, a sleeve rod 505 is fixedly connected to a lower end of the sliding disc 504, a second connection rod 506 is fixedly connected to a lower end of the sleeve rod 505, a second ball 507 is rotatably connected to an upper side wall of the first connection plate 301, and a lower end of the second connection rod 506 is fixedly connected to a side wall of the second ball 507, when the first connection plate 301 moves obliquely upwards, the first ball 501 and the second ball 507 are rotated, meanwhile, the first spring 503 is compressed, and the first connection plate 301 can move downwards under the action of the first spring 503 to reset, so as to reset the movement of the first connection plate 301.

Referring to fig. 2, 7 and 8, the first pushing mechanism 6 includes a first L-shaped plate 601 fixedly connected to an upper side wall of the first connecting plate 301, a rotating ring 602 is rotatably connected to a top of the reaction kettle 12 through a rotating mechanism 7, a plurality of second L-shaped plates 603 arranged in an array are fixedly connected to a lower side wall of the rotating ring 602, a triangular block 604 is fixedly connected to an upper side wall of the second L-shaped plate 603, the triangular block 604 includes an inclined plane 605, and the first L-shaped plate 601 slides on the inclined plane 605, when the first L-shaped plate 601 abuts against the inclined plane 605, the sliding block 403 is pushed to slide upwards along the sliding groove 402, and when the first L-shaped plate 601 passes over the inclined plane 605, the sliding block 403 can move downwards to reset under the action of the reset mechanism 5.

Referring to fig. 7, the rotating mechanism 7 includes a supporting ring 701 fixedly connected to the top of the reaction kettle 12, and a gear ring 702 is rotatably connected to the side wall of the supporting ring 701, a gear 704 is rotatably connected to the top of the reaction kettle 12 through a rotating rod 703, and the gear 704 is meshed with the gear ring 702, the rotating rod 703 is driven by a driving mechanism 10, the rotating rod 703 is driven by the driving mechanism 10 to rotate, and then the gear ring 702 is driven to rotate, and when the gear ring 702 rotates, the rotating ring 602 and the second L-shaped plate 603 are driven to synchronously rotate, so that the position of the triangular block 604 is adjusted, and then the position of the first connecting plate 301 moves obliquely upwards is adjusted, so that stirring efficiency is higher, effects are better, and emulsifying efficiency and effects of the temperature sensitive electronic adhesive are guaranteed.

Referring to fig. 1, the driving mechanism 10 includes a first pulley 1001 fixedly sleeved on a side wall of the rotating shaft, a second pulley 1002 fixedly connected to an upper end of the rotating rod 703, and a belt 1003 between the second pulley 1002 and the first pulley 1001, wherein when stirring, the rotation of the stirring shaft 16 drives the first pulley 1001 to rotate synchronously, and the belt 1003 drives the second pulley 1002 and the rotating rod 703 to rotate.

Referring to fig. 6, 8 and 11, the knocking mechanism 8 includes a moving plate 801, the moving plate 801 is connected with a side wall of the fixed plate 401 through a lifting mechanism 9, two symmetrically arranged first T-shaped guide rods 802 are inserted into the side wall of the moving plate 801, a second spring 803 is sleeved on the side wall of the first T-shaped guide rods 802, one end of each first T-shaped guide rod 802 is fixedly connected with a U-shaped plate 804, a knocking pin 806 and a knocking rod 805 are fixedly connected to the side wall of each U-shaped plate 804, the movement of each U-shaped plate 804 is pushed by a second pushing mechanism 17, and when stirring is performed, the second pushing mechanism 17 pushes the U-shaped plate 804 to reciprocate, the movement of the U-shaped plate 804 drives the knocking rod 805 and the knocking pin 806 to synchronously move, so that the knocking rod 805 reciprocates the inner side wall of the reaction kettle 12, and at the same time, the pins 806 reciprocate the side wall of the stirring shaft 16, so that material adhesion is reduced, the discharging efficiency and the effect of the emulsified temperature sensitive electronic adhesive are ensured, and waste is avoided.

Referring to fig. 9 and 11, the lifting mechanism 9 includes a third connecting block 901 fixedly connected to a side wall of the fixed plate 401, a guide rod 902 is fixedly connected to a lower side wall of the third connecting block 901, a guide pipe 903 is sleeved on a side wall of the guide rod 902, a lower end of the guide pipe 903 is fixed to an upper side wall of the movable plate 801, a threaded pipe 905 is fixedly connected to an upper side wall of the movable plate 801, a threaded rod 904 is connected to an inner thread of the threaded pipe 905, an upper end of the threaded rod 904 is rotatably connected to a lower side wall of the third connecting block 901, a second motor 906 is fixedly connected to an upper side wall of the third connecting block 901, an output end of the second motor 906 is fixed to an upper end of the threaded rod 904, a visual sensor 907 is fixedly inserted into a top of the reaction kettle 12, the second motor 906 is electrically connected to the visual sensor 907, a height of a material in the reaction kettle 12 is detected through the visual sensor 907, and the second motor 906 is started, rotation of the second motor 906 drives the threaded rod 904 to rotate, so that the movable plate 801 is lifted, and a high knocking degree of the rod 805 and a knocking pin 806 is regulated, and a vibrating effect is ensured.

Referring to fig. 9 and 11, the second pushing mechanism 17 includes two symmetrically disposed second T-shaped guide rods 1701 inserted into the lower side wall of the third connecting block 901, the lower end of the second T-shaped guide rod 1701 is fixedly connected with a moving block 1702, the side wall of the second T-shaped guide rod 1701 is sleeved with a third spring 1703, the side wall of the moving block 1702 is fixedly connected with a pushing plate 1704, the side wall of the pushing plate 1704 is fixedly connected with a plurality of ribs 1705 arranged in an array, the side wall of the U-shaped plate 804 is fixedly connected with a pushing pin 1706, one end of the pushing pin 1706 slides on the side wall of the ribs 1705, when the sliding block 403 moves obliquely upwards along the sliding groove 402, the sliding block 1702 and the pushing plate 1704 move upwards, when the end of the pushing pin 1706 abuts against the side wall of the ribs 1705, the pushing U-shaped plate 804 moves away from the pushing plate 1704, meanwhile, the first T-shaped guide rod 802 is compressed, and when the end of the pushing pin 1706 passes over the side wall of the ribs 1705, the U-shaped plate 804 moves under the action of the second spring 803, so that the U-shaped plate 804 can reciprocate.

Working principle: in use, during emulsification, raw materials and a surfactant are added into the reaction kettle 12 through the feed pipe 14, then the first motor 20 is started, the rotation of the first motor 20 drives the stirring shaft 16 to rotate, and then drives the second connecting plate 201 and the first connecting plate 301 to rotate, so that the second stirring rod 202 and the first stirring rod 302 stir the raw materials, meanwhile, the rotation of the second connecting plate 201 drives the scraper 204 to synchronously rotate through the first connecting block 203, the materials adhered to the inner wall of the reaction kettle 12 can be scraped and cleaned, so that stirring is more sufficient, meanwhile, adhesion of the materials is reduced, and when the first L-shaped plate 601 abuts against the inclined plane 605, the sliding block 403 is pushed to slide upwards along the sliding groove 402, and when the first L-shaped plate 601 passes over the inclined plane 605, the sliding block 403 can move downwards to reset under the action of the reset mechanism 5, when the first connecting plate 301 moves obliquely upwards, the first ball 501 and the second ball 507 are enabled to rotate, meanwhile, the first spring 503 is compressed, and the first connecting plate 301 can move downwards under the action of the first spring 503 to reset, so that the first connecting plate 301 moves in a reciprocating manner in an inclined direction, the first connecting plate 301 moves in a reciprocating manner, the first stirring rod 302 and the fixing ring 303 can move in a reciprocating manner in the horizontal direction on one hand, and in a reciprocating manner in the vertical direction on the other hand, and therefore raw materials are cut and stirred in the horizontal and vertical directions, stirring efficiency is higher, effects are better, and emulsifying efficiency and effects of the temperature-sensitive electronic adhesive are guaranteed;

meanwhile, the rotation of the stirring shaft 16 drives the first belt pulley 1001 to synchronously rotate, and drives the second belt pulley 1002 and the rotating rod 703 to rotate through the belt 1003, so as to drive the gear ring 702 to rotate, and when the gear ring 702 rotates, the rotating ring 602 and the second L-shaped plate 603 are driven to synchronously rotate, so that the position of the triangular block 604 is adjusted, and then the position of the first connecting plate 301 when moving obliquely upwards is adjusted, so that stirring efficiency is higher, the effect is better, and the emulsifying efficiency and effect of the temperature-sensitive electronic adhesive are ensured;

when the sliding block 403 moves obliquely upwards along the sliding groove 402, the sliding block 403 is propped against the lower side wall of the moving block 1702, so that the moving block 1702 and the pushing plate 1704 are pushed to move upwards, when the end part of the pushing pin 1706 is propped against the side wall of the raised strip 1705, the U-shaped plate 804 is pushed to move away from the pushing plate 1704, meanwhile, the first T-shaped guide rod 802 is compressed, when the end part of the pushing pin 1706 passes over the side wall of the raised strip 1705, the U-shaped plate 804 can move and reset under the action of the second spring 803, so that the U-shaped plate 804 moves reciprocally, the movement of the U-shaped plate 804 drives the synchronous movement of the knocking rod 805 and the knocking pin 806, so that the knocking rod 805 performs reciprocating knocking vibration on the inner side wall of the reaction kettle 12, and meanwhile, the knocking pin 806 performs reciprocating knocking vibration on the side wall of the stirring shaft 16, so that material adhesion is reduced, discharging efficiency and effect of the emulsified temperature sensitive electronic adhesive are ensured, and waste is avoided;

the height of materials in the reaction kettle 12 can be detected through the visual sensor 907, and the second motor 906 is started, and the rotation of the second motor 906 drives the rotation of the threaded rod 904, so that the movable plate 801 is lifted, the knocking height of the knocking rod 805 and the knocking pin 806 is adjusted, and the knocking vibration effect is guaranteed.

Claims

1. A device for producing a temperature-sensitive electronic adhesive, comprising a base plate (1), characterized in that: the utility model discloses a stirring device, including bottom plate (1), supporting legs (11) that two symmetries set up are connected with to the upper side wall of bottom plate (1), and the upper end fixedly connected with reation kettle (12) of supporting legs (11), the top fixedly connected with of reation kettle (12) a plurality of feed valves (13), and the upper end fixedly connected with inlet pipe (14) of feed valve (13), the bottom fixedly connected with bleeder valve (18) of reation kettle (12), and the lower extreme fixedly connected with discharging pipe (15) of bleeder valve (18), be connected with (16) through the pivot rotation in reation kettle (12), and the top fixedly connected with L shape backup pad (19) that set up of reation kettle (12), the upper side wall fixedly connected with first motor (20), and the output of first motor (20) is fixed with the upper end of pivot, the lateral wall of (16) is provided with first rabbling mechanism (2) and second rabbling mechanism (3) that are used for stirring the raw materials, and is provided with in reation kettle (12) and beats (8) of beating mechanism (16) of beating reaction kettle (16);

the second stirring mechanism (3) comprises a plurality of first connecting plates (301) arranged in an array, each first connecting plate (301) is connected with the side wall of the stirring shaft (16) through a moving mechanism (4), the lower side wall of each first connecting plate (301) is fixedly connected with a plurality of first stirring rods (302) arranged in the array, the side wall of each first stirring rod (302) is fixedly sleeved with a fixing ring (303), and the movement of each first connecting plate (301) is pushed by a first pushing mechanism (6);

the first stirring mechanism (2) comprises a second connecting plate (201) fixedly connected to the side wall of the stirring shaft (16) and arranged in a plurality of arrays, the lower side wall of the second connecting plate (201) is fixedly connected with a plurality of second stirring rods (202) arranged in the arrays, the side wall of the second connecting plate (201) is fixedly connected with a first connecting block (203), and the side wall of the first connecting block (203) is fixedly connected with a scraping plate (204);

the moving mechanism (4) comprises two symmetrically arranged fixed plates (401) fixedly connected to the side wall of the stirring shaft (16), a sliding groove (402) is formed in the side wall of the fixed plate (401), a sliding block (403) is fixedly inserted into the side wall of the first connecting plate (301), the sliding block (403) slides in the sliding groove (402), and a reset mechanism (5) is arranged between the first connecting plate (301) and the fixed plate (401);

the first pushing mechanism (6) comprises a first L-shaped plate (601) fixedly connected to the upper side wall of the first connecting plate (301), the top of the reaction kettle (12) is rotatably connected with a rotating ring (602) through a rotating mechanism (7), the lower side wall of the rotating ring (602) is fixedly connected with a plurality of second L-shaped plates (603) arranged in an array, the upper side wall of the second L-shaped plates (603) is fixedly connected with a triangular block (604), the triangular block (604) comprises an inclined surface (605), and the first L-shaped plates (601) slide on the inclined surface (605);

the knocking mechanism (8) comprises a moving plate (801), the moving plate (801) is connected with the side wall of the fixed plate (401) through a lifting mechanism (9), two symmetrically arranged first T-shaped guide rods (802) are inserted into the side wall of the moving plate (801), second springs (803) are sleeved on the side wall of the first T-shaped guide rods (802), one end of each first T-shaped guide rod (802) is fixedly connected with a U-shaped plate (804), knocking pins (806) and knocking rods (805) are fixedly connected with the side wall of each U-shaped plate (804), and the U-shaped plates (804) are moved by a second pushing mechanism (17);

the lifting mechanism (9) comprises a third connecting block (901) fixedly connected to the side wall of the fixed plate (401), a guide rod (902) is fixedly connected to the lower side wall of the third connecting block (901), a guide pipe (903) is sleeved on the side wall of the guide rod (902), the lower end of the guide pipe (903) is fixed to the upper side wall of the movable plate (801), a threaded pipe (905) is fixedly connected to the upper side wall of the movable plate (801), a threaded rod (904) is connected to the threaded pipe (905) in a threaded manner, the upper end of the threaded rod (904) is rotatably connected to the lower side wall of the third connecting block (901), a second motor (906) is fixedly connected to the upper side wall of the third connecting block (901), the output end of the second motor (906) is fixed to the upper end of the threaded rod (904), a visual sensor (907) is fixedly inserted into the top of the reaction kettle (12), and the second motor (906) is electrically connected to the visual sensor (907);

the second pushing mechanism (17) comprises a second T-shaped guide rod (1701) which is inserted into the lower side wall of the third connecting block (901) and symmetrically arranged, the lower end of the second T-shaped guide rod (1701) is fixedly connected with a moving block (1702), a third spring (1703) is sleeved on the side wall of the second T-shaped guide rod (1701), a pushing plate (1704) is fixedly connected with the side wall of the moving block (1702), a plurality of convex strips (1705) which are arranged in an array are fixedly connected with the side wall of the pushing plate (1704), pushing pins (1706) are fixedly connected with the side wall of the U-shaped plate (804), and one end of each pushing pin (1706) slides on the side wall of each convex strip (1705).

2. A device for producing a temperature-sensitive electronic adhesive according to claim 1, wherein: the reset mechanism (5) comprises a second connecting block (508) fixedly connected to the side wall of the fixed plate (401), a first ball (501) is rotationally connected to the lower side wall of the second connecting block (508), a first connecting rod (509) is fixedly connected to the side wall of the first ball (501), a sleeve (502) is fixedly connected to the lower end of the first connecting rod (509), a sliding disc (504) is slidingly connected to the sleeve (502) through a first spring (503), a sleeve rod (505) is fixedly connected to the lower end of the sliding disc (504), a second connecting rod (506) is fixedly connected to the lower end of the sleeve rod (505), a second ball (507) is rotationally connected to the upper side wall of the first connecting plate (301), and the lower end of the second connecting rod (506) is fixedly connected to the side wall of the second ball (507).

3. A device for producing a temperature-sensitive electronic adhesive according to claim 1, wherein: the rotary mechanism (7) comprises a supporting ring (701) fixedly connected to the top of the reaction kettle (12), a gear ring (702) is rotatably connected to the side wall of the supporting ring (701), a gear (704) is rotatably connected to the top of the reaction kettle (12) through a rotary rod (703), the gear (704) is meshed with the gear ring (702), and the rotary rod (703) is driven by a driving mechanism (10).

4. A device for producing a temperature-sensitive electronic adhesive according to claim 3, wherein: the driving mechanism (10) comprises a first belt pulley (1001) fixedly sleeved on the side wall of the rotating shaft, a second belt pulley (1002) is fixedly connected to the upper end of the rotating rod (703), and the second belt pulley (1002) and the first belt pulley (1001) are in transmission through a belt (1003).