CN114906788B - Storage system for glue mixing - Google Patents

Abstract

The application discloses storage system for mixing glue, which comprises a controller, user terminal, a first inlet pipe, the storage tank, a first solenoid valve, the material taking tank, a first vacuum pump and a second vacuum pump, one end of first inlet pipe is communicated with the storage tank, a first solenoid valve is arranged on the first inlet pipe, the first vacuum pump is communicated with the storage tank, a fixed slot is formed in the inner bottom wall of the storage tank, a material taking rod is arranged in the storage tank and on the side wall of the fixed slot, a feed inlet is formed in the material taking rod, a material taking pipe is arranged between the material taking tank and the material taking rod, the second vacuum pump is communicated with the material taking tank, the first solenoid valve is opened during material storage, and the first vacuum pump is started to enable raw materials entering the first inlet pipe to enter the storage tank; when getting the material, start the second vacuum pump, the raw materials in the holding vessel enter into the material jar of getting through the feed inlet of getting the material stick in, effectively avoided storing the raw materials in the storage tank and air contact, improved the leakproofness of storage tank.

Description

Storage system for glue mixing

Technical Field

The application relates to the technical field of glue production, in particular to a storage system for glue mixing.

Background

Glue is an intermediate for connecting two materials, is mostly in the form of water, belongs to the class of fine chemical industry, is various, and is mainly classified by a binder, a physical form, a hardening method and a material of an adherend. The bottom of the aviation carpet is required to be provided with a layer of adhesive layer made of special glue.

During the production process of the specially-made glue, various raw materials are required to be used, a worker respectively and independently loads the various raw materials into different raw material barrels, the top opening of the raw material barrels is hinged with barrel doors, and when the raw materials are used or added, the barrel doors of the raw material barrels are required to be opened, so that the tightness of the raw material barrels is poor, and the raw materials in the raw material barrels are in contact with air to generate chemical reaction.

Disclosure of Invention

In order to improve the leakproofness of former storage bucket, this application provides a storage system for mixing glue.

The application provides a storage system for mixing adopts following technical scheme:

the utility model provides a storage system for mixing glue, includes controller, user terminal, first inlet pipe, storage tank, first solenoid valve, material taking tank, first vacuum pump and second vacuum pump, the inside cavity of storage tank, the one end and the storage tank intercommunication of first inlet pipe, the other end are used for the feeding, first solenoid valve sets up on first inlet pipe, first solenoid valve is used for opening and close first inlet pipe, first vacuum pump and storage tank intercommunication;

a fixed groove is arranged on the inner bottom wall of the storage tank, a guide surface is arranged on the side wall of the fixed groove and near the edge of the bottom wall of the fixed groove, a material taking rod is arranged in the storage tank and is arranged on the side wall of the guide surface, the inside of the material taking rod is hollow, a material inlet is formed in the outer side wall of the material taking rod in an array manner, a material taking pipe is arranged between the material taking tank and the material taking rod, and the second vacuum pump is communicated with the material taking tank;

the controller is in communication connection with the user terminal, and the first electromagnetic valve, the first vacuum pump and the second vacuum pump are all electrically connected with the controller.

By adopting the technical scheme, during material storage, raw materials are poured into the first feeding pipe, a worker opens the first electromagnetic valve through the user terminal control controller and starts the first vacuum pump, and the first vacuum pump enables negative pressure to be formed in the material storage tank, so that the raw materials entering the first feeding pipe enter the material storage tank, fall onto the guide surface under the action of gravity and are contacted with the material taking rod, and the raw materials are stored in the material storage tank; when getting the material, start the second vacuum pump, make and get the material jar in forming the negative pressure, the raw materials in the holding vessel enter into the material jar of getting through the feed inlet of getting the material stick in, enter into the material in the material jar and fall the bottom of sample jar and pile up in the sample jar, effectively avoided storing the raw materials in the storage tank and air contact, improved the leakproofness of storage tank.

Optionally, be provided with the selective examination jar between first inlet pipe and the storage tank, the discharge gate has been seted up to the inside cavity and the bottom of selective examination jar, the both ends of selective examination jar communicate with first inlet pipe and storage tank respectively, the bottom of selective examination jar is provided with the sliding plate, sliding plate is along horizontal direction sliding connection in the bottom of selective examination jar, the connecting hole has been seted up on the sliding plate, be provided with on the selective examination jar and be used for driving the gliding first electric jar of sliding plate, the sliding plate can communicate with the discharge gate along the gliding in-process connecting hole of horizontal direction, first electric jar and controller electric connection.

Through adopting above-mentioned technical scheme, when the staff carries out the spot check to the raw materials that enters into first inlet pipe, start first electric jar, first electric jar drives the sliding plate and slides, make connecting hole and discharge gate intercommunication, the raw materials that enters into the spot check jar falls the connecting hole from the discharge gate under the effect of gravity, and discharge from the connecting hole, the staff carries out the spot check to the raw materials that discharges from the connecting hole, then first electric jar drives the sliding plate and slides and make connecting hole and discharge gate not communicate, under the prerequisite that does not influence the raw materials storage in the storage tank, make things convenient for the staff to carry out the spot check to the raw materials.

Optionally, the storage tank is provided with four along the horizontal direction interval, every all be provided with the second inlet pipe on the storage tank, the one end that first solenoid valve was kept away from to first inlet pipe is provided with first branch hopper, the top of first branch hopper is provided with two branch material pipes, two divide and be provided with the second on the material pipe and divide the hopper, two feed inlets have been seted up at the top of second divides the hopper, the second inlet pipe passes through feed inlet and second divides the hopper intercommunication, all be provided with the second solenoid valve on second inlet pipe and the branch material pipe, second solenoid valve and controller electric connection.

Through adopting above-mentioned technical scheme, when the staff will need pour into different storage tanks with different raw materials in, open first vacuum pump on this storage tank earlier, then open the second solenoid valve on the second inlet pipe of this storage tank, then open the second solenoid valve of the branch material pipe with this second inlet pipe intercommunication, pour into first inlet pipe with a raw materials afterwards, realized that different raw materials use same first inlet pipe to enter into the purpose of different storage tanks, practiced thrift area, improved storage efficiency.

Optionally, get material stick along the incline direction sliding connection of guide surface on the guide surface, it is provided with first bellows to get material stick and get between the material pipe, first bellows is scalable along the length direction of first bellows, it is fixed to be provided with the fixed block to get the top of material stick, be provided with the movable rod on the lateral wall of storage tank, the one end of movable rod passes the storage tank inside and with fixed block fixed connection, be provided with the second electric jar that is used for driving the movable rod to remove on the storage tank, the waste gate has been seted up on the lateral wall of fixed slot, the top opening of waste gate can be sealed to get material stick, be provided with the waste pipe on the lateral wall of storage tank, one end and waste gate intercommunication, the other end of waste pipe are provided with the waste tank, be provided with the third vacuum pump on the waste tank, second electric jar, third vacuum pump and controller electric connection.

Through adopting above-mentioned technical scheme, when clearing up remaining raw materials in the storage tank, start the second jar, make the second jar drive get the material stick and remove the contact with the lateral wall of fixed slot, make the waste material mouth open, then open the third vacuum pump, form the negative pressure in the messenger's waste material jar to bring into the waste material jar with remaining raw materials in the storage tank, clear up remaining raw materials in the storage tank and convenient and clean.

Optionally, the material taking rod is kept away from the fixed fixture block that is provided with in one side of material taking pipe, fixture block and waste material mouth joint.

Through adopting above-mentioned technical scheme, fixture block and waste material mouth joint effectively avoid having the raw materials to enter into between the waste material mouth from the gap between the lateral wall of getting material stick and fixed slot, moreover, still improved the stability of getting material stick connection on the guide surface, effectively avoid second vacuum pump operation in-process, take place relative displacement between material stick and the guide surface.

Optionally, be provided with the support frame on the storage tank, storage tank is along vertical direction sliding connection on the support frame, fixedly be provided with the supporting shoe on the lateral wall of storage tank, be provided with pressure sensor between support frame and the supporting shoe, pressure sensor and controller electric connection.

Through adopting above-mentioned technical scheme, the staff can accurately know the storage condition of storage tank through pressure sensor.

Optionally, be provided with the second bellows between fixed block and the inside wall of storage tank, the second bellows is scalable along the length direction of second bellows, the coaxial cover of movable rod is established in the second bellows.

Through adopting above-mentioned technical scheme, effectively avoid entering into the raw materials in the storage tank and moving rod contact, improve the integrality of raw materials and convenient clearance.

Optionally, the material taking rod is kept away from one side of material taking pipe and is offered the intercommunicating pore with the inside intercommunication of material taking rod, the opening of intercommunicating pore can be sealed to the lateral wall of fixed slot.

Through adopting above-mentioned technical scheme, when clearing up the storage tank, the raw materials of remaining in getting the material stick is discharged outside getting the material stick through the intercommunicating pore, and it is convenient to clear up and get the material stick.

Optionally, the bottom of getting the material stick is fixed and is provided with the stopper, the spacing groove has been seted up on the lateral wall of guide surface, the stopper is along the incline direction sliding connection of guide surface in the spacing inslot.

Through adopting above-mentioned technical scheme, stopper sliding connection has improved the stability of getting material stick and guide surface contact in the spacing inslot.

Optionally, the inside of storage tank is provided with a plurality of charge level indicators along the direction of height interval of storage tank, every charge level indicator all with controller electric connection.

Through adopting above-mentioned technical scheme, the staff knows the storage tank through the charge level indicator and stores the condition to in time carry out the feed supplement when the raw materials is not enough in the storage tank, and when storing the raw materials too much in the storage tank, in time stop this storage tank storage material.

In summary, the present application includes at least one of the following beneficial technical effects:

during storage, raw materials are poured into a first feeding pipe, a worker opens a first electromagnetic valve through a user terminal control controller, a first vacuum pump is started, and the first vacuum pump enables negative pressure to be formed in a storage tank, so that the raw materials entering the first feeding pipe enter the storage tank, fall onto a guide surface under the action of gravity and are in contact with a material taking rod, and the raw materials are stored in the storage tank; when the material is taken, the second vacuum pump is started to form negative pressure in the material taking tank, raw materials in the storage tank enter the material taking tank through the feeding port of the material taking rod, and the raw materials entering the material taking tank fall to the bottom of the material taking tank and are accumulated in the material taking tank, so that the raw materials stored in the material storage tank are effectively prevented from being contacted with air, and the sealing performance of the material storage tank is improved;

when a worker performs sampling inspection on the raw materials entering the first feeding pipe, the first electric cylinder is started, the first electric cylinder drives the sliding plate to slide, so that the connecting hole is communicated with the discharge hole, the raw materials entering the sampling inspection tank fall into the connecting hole from the discharge hole under the action of gravity and are discharged from the connecting hole, the worker performs sampling inspection on the raw materials discharged from the connecting hole, and then the first electric cylinder drives the sliding plate to slide, so that the connecting hole is not communicated with the discharge hole, and the raw materials are conveniently sampled inspected by the worker on the premise that the raw materials are not affected to be stored in the storage tank;

when the staff will need pour different raw materials into different storage tanks, open the first vacuum pump on this storage tank earlier, then open the second solenoid valve on the second inlet pipe of this storage tank, then open the second solenoid valve of the feed tube that will communicate with this second inlet pipe, pour a raw materials into first inlet pipe afterwards, realized that different raw materials use same first inlet pipe to enter into the purpose of different storage tanks, practiced thrift area, improved storage efficiency.

Drawings

Fig. 1 is a schematic overall structure of a storage system for mixing glue according to an embodiment of the present application.

Fig. 2 is a schematic cross-sectional view of a storage tank.

Fig. 3 is a flow chart of a glue stock system according to an embodiment of the present application.

Fig. 4 is a schematic diagram of a connection structure of the spot inspection tank according to the embodiment of the present application.

Fig. 5 is a partial cross-sectional view of a spot check tank according to an embodiment of the present application.

Fig. 6 is a schematic diagram of a connection structure of the first and second dispensing hoppers according to an embodiment of the present application.

Fig. 7 is an enlarged partial schematic view of the portion a in fig. 2.

Reference numerals illustrate: 1. a controller; 2. a user terminal; 3. a first feed tube; 4. a storage tank; 41. a fixing groove; 42. a guide surface; 43. a waste port; 44. a limit groove; 5. a first electromagnetic valve; 6. a material taking tank; 7. a first vacuum pump; 8. a second vacuum pump; 9. a material taking rod; 91. a feed inlet; 92. a communication hole; 10. a material taking pipe; 11. a spot inspection tank; 111. a discharge port; 12. a sliding plate; 121. a connection hole; 13. a first electric cylinder; 14. a second feed tube; 15. a first distributing hopper; 16. a material dividing pipe; 17. a second separation hopper; 18. a second electromagnetic valve; 19. a first bellows; 20. a fixed block; 21. a moving rod; 22. a second electric cylinder; 23. a waste material pipe; 24. a third vacuum pump; 25. a clamping block; 26. a support frame; 27. a support block; 28. a pressure sensor; 29. a second bellows; 30. a limiting block; 31. a level gauge; 32. a canister.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-7.

The embodiment of the application discloses a storage system for glue mixing. Referring to fig. 1, the material storage system comprises a first feeding pipe 3, a material storage tank 4, a material taking tank 6, a first vacuum pump 7 and a second vacuum pump 8, wherein the first feeding pipe 3 is used for feeding and is communicated with the material storage tank 4, the material taking tank 6 is provided with a material taking pipe 10, the material taking pipe 10 is communicated with the material storage tank 4, the first vacuum pump 7 is arranged on the material storage tank 4, the second vacuum pump 8 is arranged on the material taking tank 6, a worker contacts raw materials with the first feeding pipe 3, the first vacuum pump 7 is started, the first vacuum pump 7 operates to form negative pressure in the material storage tank 4, and accordingly raw materials are driven to enter the material storage tank 4 through the first feeding pipe 3; when getting the material, open second vacuum pump 8, second vacuum pump 8 operation makes the formation negative pressure in the storage tank 4 to in entering into the storage tank 4 with the raw materials in the storage tank 4 through getting material jar 6, effectively avoided storing the raw materials and the air contact in storage tank 4, improved the leakproofness of storage tank 4.

In this embodiment, whole compounding system installs in the warehouse, the one end that storage tank 4 was kept away from to first inlet pipe 3 outwards stretches out one section from the warehouse, the end that stretches out of first inlet pipe 3 is used for the feeding, in this embodiment, outside the raw materials transported to the warehouse through the tank car, be provided with the pipeline with first inlet pipe 3 looks adaptation on the tank car, make pipeline and first inlet pipe 3 joint, and make in the tank car raw materials enter into in the first inlet pipe 3 through the pipeline of tank car, effectively avoid the raw materials volatilize in the warehouse, the operational environment of protection warehouse.

In other embodiments, the worker may also load the material into the bag, and the extended end of the first feed tube 3 may extend into the bag to draw the material into the first feed tube 3.

Referring to fig. 1 and 2, the tank 4 is hollow and made of alloy. The second feeding pipe 14 is arranged on the storage tank 4, the second feeding pipe 14 is arranged on the side wall of the storage tank 4, and raw materials entering the second feeding pipe 14 enter the storage tank 4 from the side wall of the storage tank 4. The top coaxial mounting of storage tank 4 has support frame 26, and support frame 26 and the lateral wall fixed connection in warehouse.

The first vacuum pump 7 is mounted on a support frame 26, and the first vacuum pump 7 is communicated with the top of the storage tank 4 through a pipeline. The first vacuum pump 7 operates to enable negative pressure to be formed inside the storage tank 4, air entering the storage tank 4 is sucked away from the top of the storage tank 4 by the first vacuum pump 7, raw materials entering the storage tank 4 fall into the storage tank 4 under the action of gravity, raw materials and air are separated, a certain vacuum state is formed inside the storage tank 4, and the raw material storage effect is improved.

A fixed groove 41 is formed in the inner bottom wall of the storage tank 4, a guide surface 42 is formed in the side wall of the fixed groove 41 and close to the edge of the bottom wall of the fixed groove 41, the higher end of the guide surface 42 is in contact with the inner bottom wall of the storage tank 4, and the lower end of the guide surface is in contact with the bottom of the side wall opposite to the fixed groove 41. In this embodiment, guide surfaces 42 are formed on the side walls of the opposite sides of the fixing groove 41, so that the lower ends of the two guide surfaces 42 are connected to each other.

A material taking rod 9 is arranged in the material storage tank 4, and the material taking rod 9 is a rectangular block made of alloy materials. The material taking bar 9 is mounted on the side wall of one of the guide surfaces 42, and the bottom of the material taking bar 9 abuts against the side wall of the other guide surface 42. The inside of the material taking rod 9 is hollow, and the outer side wall of the material taking rod 9 is provided with a feed inlet 91 in an array, and in this embodiment, the feed inlet 91 is provided on the top and the side walls of the two sides of the material taking rod 9. Perforations are formed in the side wall of the storage tank 4 and below the second feed pipe 14, and the material taking pipe 10 is coaxially arranged on the perforated side wall and communicated with the inside of the storage tank 4. A first bellows 19 is mounted on the side wall of the higher end of the take-out bar 9, and the first bellows 19 is telescopic along the length direction of the first bellows 19. One end of the first corrugated pipe 19 is hollow in the material taking rod 9, and the other end of the first corrugated pipe is fixedly connected with the material taking pipe 10 and is communicated with the material taking pipe 10.

The material taking rod 9 is connected to the guide surface 42 in a sliding manner along the inclined direction of the guide surface 42, and the top of the material taking rod 9 is fixedly provided with the fixing block 20. The movable rod 21 is installed on the outer side wall of the storage tank 4, one end of the movable rod 21 penetrates through the storage tank 4 and is fixedly connected with the fixed block 20, and the movable rod 21 is slidably connected in the storage tank 4 along the inclined direction of the guide surface 42. The second electric cylinder 22 for driving the moving rod 21 to slide along the inclined direction of the guide surface 42 is arranged on the outer side wall of the storage tank 4, the second electric cylinder 22 is fixedly arranged on the outer side wall of the storage tank 4, and a piston rod of the second electric cylinder 22 is fixedly connected with one end of the moving rod 21, which is far away from the fixed block 20.

The bottom of the material taking rod 9 is fixedly provided with a limiting block 30, the limiting block 30 is a T-shaped block, a limiting groove 44 is formed in the side wall of a guide surface 42 which is in contact with the bottom of the material taking rod 9, and the limiting groove 44 is provided with a T-shaped groove. The limiting block 30 is slidably connected in the limiting groove 44 along the inclined direction of the guide surface 42, so that the contact stability of the material taking rod 9 and the guide surface 42 is improved.

A second corrugated pipe 29 is arranged between the fixed block 20 and the inner side wall of the storage tank 4, the second corrugated pipe 29 is telescopic along the length direction of the second corrugated pipe 29, and the moving rod 21 is coaxially sleeved in the second corrugated pipe 29. The raw materials that enter into storage tank 4 are effectively avoided contacting with movable rod 21, improve the integrality of raw materials and convenient clearance.

Referring to fig. 1 and 2, a waste port 43 is formed in a guide surface 42 abutting against the lower end of the take-out rod 9, and when the lower end of the take-out rod 9 abuts against the side wall of the guide surface 42, the take-out rod 9 closes the top opening of the waste port 43. The waste pipe 23 is installed on the outer side wall of the storage tank 4, one end of the waste pipe 23 is communicated with the waste port 43, the waste tank 32 is installed at the other end of the waste pipe, the interior of the waste tank 32 is hollow and is provided with an open top, and the open top of the waste tank 32 is hinged with a tank door for closing the open top of the waste tank 32. The canister 32 has a third vacuum pump 24 mounted thereon, the third vacuum pump 24 being operated to create a negative pressure within the canister 32. When the residual raw materials in the storage tank 4 are cleaned, the second electric cylinder 22 is started, the second electric cylinder 22 drives the material taking rod 9 to be in contact with the side wall of the fixed groove 41, the waste port 43 is opened, and then the third vacuum pump 24 is opened, so that the residual raw materials in the storage tank 4 are brought into the waste tank 32, the residual raw materials in the storage tank 4 are cleaned conveniently and cleanly, and the raw materials stored in the waste tank 32 are replaced conveniently by workers.

One side of the material taking rod 9 away from the material taking pipe 10 is fixedly provided with a mounting clamping block 25, and the clamping block 25 is clamped with a waste port 43. The fixture block 25 is clamped with the waste material port 43, so that raw materials are effectively prevented from entering between the waste material port 43 from a gap between the material taking rod 9 and the side wall of the fixed groove 41, and the relative displacement between the material taking rod 9 and the guide surface 42 is effectively avoided in the operation process of the second vacuum pump 8, so that the material sucking stability of the material taking rod 9 is improved.

The side wall of the lower end of the material taking rod 9 is provided with a communication hole 92 communicated with the inside of the material taking rod 9, and when the side wall of the lower end of the material taking rod 9 is abutted to the guide surface 42, the side wall of the guide surface 42 seals the opening of the communication hole 92. When the storage tank 4 is cleaned, the raw materials remained in the material taking rod 9 are discharged out of the material taking rod 9 through the communicating hole 92, and the material taking rod 9 is cleaned conveniently.

When the residual raw materials in the storage tank 4 are cleaned, the second electric cylinder 22 is started, the second electric cylinder 22 drives the material taking rod 9 to be separated from the side wall of the fixed groove 41, the waste port 43 is opened, the third vacuum pump 24 is opened, negative pressure is formed in the waste tank 32, the residual raw materials in the storage tank 4 are brought into the waste tank 32, and the residual raw materials in the storage tank 4 are cleaned conveniently and cleanly.

Referring to fig. 1, 2 and 3, the storage system further includes a controller 1 and a user terminal 2, the first vacuum pump 7, the second vacuum pump 8, the second electric cylinder 22 and the third vacuum pump 24 are all electrically connected with the controller 1, the controller 1 is in communication connection with the user terminal 2, the user terminal 2 adopts a computer, a worker can manually control the start and stop of the first vacuum pump 7, the second vacuum pump 8, the second electric cylinder 22 and the third vacuum pump 24 through the controller 1 at the user terminal 2, and the control is convenient.

Referring to fig. 4, the first feeding pipe 3 is a circular pipe made of alloy material, a first electromagnetic valve 5 for opening and closing the first feeding pipe 3 is installed on the first feeding pipe 3, and the first electromagnetic valve 5 is electrically connected with the controller 1.

Referring to fig. 3, 4 and 5, a sampling tank 11 is mounted at the end of the first feed pipe 3 extending away from the first feed pipe 3, and the sampling tank 11 is communicated with the storage tank 4. The inside of the sampling inspection tank 11 is hollow, the bottom of the sampling inspection tank 11 is provided with a discharge hole 111, and the sampling inspection tank 11 is a rectangular tank made of alloy materials. The first feed pipe 3 includes two pipes, one for feeding the raw material into the sampling tank 11 and the other for feeding the raw material into the sampling tank 11 in a direction approaching the storage tank 4. In the present embodiment, the first solenoid valve 5 is installed at the first feed pipe 3 for feeding the raw material into the spot check tank 11. The top of the sampling inspection tank 11 is provided with a sampling inspection hole, and the first feeding pipe 3 used for conveying raw materials into the sampling inspection tank 11 is communicated with the inside of the sampling inspection tank 11 through the sampling inspection hole. The side wall of the sampling inspection tank 11 is provided with an inspection hole, and the first feeding pipe 3 used for conveying the raw material entering the sampling inspection tank 11 to a direction close to the discharging pipe is communicated with the inside of the sampling inspection tank 11 through the inspection hole.

The sliding plate 12 is installed at the bottom of the spot check tank 11, the sliding plate 12 is a rectangular plate made of alloy materials, and the length of the sliding plate 12 along the horizontal direction is the same as the length of the spot check tank 11 along the horizontal direction. The sliding plate 12 is only slidably connected to the bottom of the spot check tank 11 along the horizontal direction, and the sliding plate 12 is provided with a connecting hole 121. When the two ends of the sliding plate 12 along the horizontal direction and the two ends of the sampling tube along the horizontal direction are respectively positioned on the same horizontal plane, the connecting hole 121 and the discharge hole 111 are completely misplaced, and the connecting hole 121 and the discharge hole 111 are not communicated with each other.

Referring to fig. 1, 4 and 5, a first electric cylinder 13 for driving the sliding plate 12 to slide in the horizontal direction is mounted on the sampling test tank 11, the first electric cylinder 13 is fixedly mounted on the outer side wall of the sampling test tank 11, and a piston rod of the first electric cylinder 13 is fixedly connected with the side wall of the sliding plate 12. When the first electric cylinder 13 drives the sliding plate 12 to slide in the horizontal direction, and the connecting hole 121 can be aligned coaxially with the discharge port 111 after the sliding plate 12 extends out from the bottom of the spot inspection tank 11, the connecting hole 121 communicates with the discharge port 111. The bottom of the discharge hole 111 is coaxially provided with a discharge hopper, when a worker performs sampling inspection on raw materials entering the first feed pipe 3, the first electric cylinder 13 is started, the first electric cylinder 13 drives the sliding plate 12 to extend out of the bottom of the sampling inspection tank 11 and enable the connecting hole 121 to be communicated with the discharge hole 111, the worker uses a storage tray to be placed under the discharge hopper, the raw materials entering the sampling inspection tank 11 fall into the storage tray from the discharge hole 111, the connecting hole 121 and the discharge plug in sequence under the action of gravity, the worker performs quality detection on the raw materials in the storage tray, then the first electric cylinder 13 is started to enable the sliding plate 12 to be located in the sampling inspection tank 11, the connecting hole 121 is not communicated with the discharge hole 111, so that the raw materials in the sampling inspection tank 11 continue to move towards the direction close to the storage tank 4, the purpose of sampling inspection on the part of the raw materials entering the sampling inspection tank 11 is fast under the premise that the raw materials are not influenced to be stored in the storage tank 4, and the sampling inspection of the raw materials is convenient, fast and efficient.

In addition, after the storage of the batch of raw materials is finished, the first electric cylinder 13 is started again, the connecting hole 121 is communicated with the discharge hole 111, part of raw materials remained between the sliding plate 12 and the connecting hole 121 fall into the storage tray through the discharge hopper to be detected again, the batch of raw materials are effectively prevented from being remained in the sampling inspection tank 11, the cleanliness in the sampling inspection tank 11 is improved, the sampling inspection result is also increased, and the sampling inspection accuracy is improved.

When the sliding plate 12 does not extend from the sampling inspection tank 11, it is indicated that the connecting hole 121 is not aligned with the discharge hole 111, and the raw material entering the sampling inspection tank 11 cannot fall out from the discharge hole 111; when the slide plate 12 is extended from the bottom of the spot check tank 11, it is indicated that the connection hole 121 is aligned with the discharge port 111, and the raw material introduced into the spot check tank 11 may fall out of the discharge port 111. The staff knows fast whether connecting hole 121 communicates with discharge gate 111 according to the positional relationship of sliding plate 12 and spot check jar 11 bottom, and connecting hole 121 keeps the intercommunication state with discharge gate 111 when effectively avoiding not using spot check jar 11, makes impurity enter into in the spot check jar 11 to influence the pure degree of raw materials, and enter into the raw materials whereabouts from discharge gate 111 in the spot check jar 11, improve the stability of using spot check jar 11.

Referring to fig. 3, the first electric cylinder 13 is electrically connected to the controller 1.

Referring to fig. 1, a material taking tank 6 is a tank body made of alloy materials, a material taking opening is formed in the bottom of the material taking tank 6, and a tank door is mounted at the bottom of the material taking tank 6 to seal the material taking opening.

Referring to fig. 1 and 6, a plurality of storage tanks 4 may be installed according to the use requirement, and in this embodiment, four storage tanks 4 are installed at intervals in the horizontal direction.

Referring to fig. 1, 3 and 6, a first material distributing hopper 15 is attached to a first material feeding pipe 3 for feeding the raw material introduced into the sample testing tank 11 in a direction approaching the material discharging pipe in the sample testing tank 11, the inside of the first material distributing hopper 15 is hollow, and the raw material of the first material feeding pipe 3 enters the first material distributing hopper 15. Two second sub-hoppers 17 are arranged at the top of the first sub-hopper 15, a sub-material pipe 16 is arranged between the first sub-hopper 15 and the second sub-hopper 17, a second material inlet pipe 14 in the material storage tanks 4 is communicated with the top of the second sub-hopper 17, wherein the top of one second sub-hopper 17 is communicated with two material storage tanks 4, and the top of the other sub-material degree is communicated with the other two material storage tanks 4. A second electromagnetic valve 18 for opening and closing the pipeline is arranged on each second feeding pipe 14 and each distributing pipe 16, and the second electromagnetic valve 18 is electrically connected with the controller 1.

When a worker pours different raw materials into different storage tanks 4, the first vacuum pump 7 on the storage tank 4 is firstly opened, then the second electromagnetic valve 18 on the second feeding pipe 14 of the storage tank 4 is opened, then the second electromagnetic valve 18 of the material distributing pipe 16 communicated with the second feeding pipe 14 is opened, then one raw material is poured into the first feeding pipe 3, the purpose that different raw materials enter different storage tanks 4 by using one first feeding pipe 3 is achieved, occupied area is saved, and storage efficiency is improved.

In other embodiments, the number of the first and second distribution hoppers 15, 17 and the distribution pipes 16 may be changed according to the use requirements.

Referring to fig. 2 and 3, a plurality of level gauges 31 are installed inside the storage tank 4 at intervals along the height direction of the storage tank 4, in this embodiment, three level gauges 31 are installed at intervals along the height direction of the storage tank 4, and all three level gauges 31 are electrically connected with the controller 1. After the charge level indicator 31 contacts with the raw materials, the charge level indicator 31 generates an electric signal to the controller 1, the controller 1 receives and recognizes the electric signal of the charge level indicator 31, then the electric signal is sent to the user terminal 2, the user terminal 2 knows the storage condition of the storage tank 4 in real time through the electric signal of the charge level indicator 31, when the staff only receives the electric signal of the charge level indicator 31 positioned at the lowest position at the user terminal 2, the staff needs to feed the storage tank 4, when the staff receives the charge level indicator 31 at the highest position, the staff stops continuously storing the raw materials in the storage tank 4, and the staff can know the storage condition of the raw materials of the storage tank 4 in real time conveniently.

When the same raw materials are stored, after the controller 1 receives an electric signal of the level gauge 31 positioned at the uppermost part of the storage tank 4, the controller 1 closes the second electromagnetic valve 18 leading to the storage tank 4; then the controller 1 opens the second electromagnetic valve 18 of the storage tank 4 which does not receive the uppermost charge level indicator 31, so that the residual raw materials enter the storage tank 4 from the first distributing hopper 15 or the second distributing hopper 17, the purpose that the same raw materials enter different storage tanks 4 by using one first feeding pipe 3 is achieved, the occupied area is saved, and the storage efficiency is improved.

Referring to fig. 3 and 7, the storage tank 4 is slidably connected to the support frame 26 in the vertical direction, the support blocks 27 are welded on the outer side wall of the storage tank 4, and four support blocks 27 are installed along the circumferential direction of the outer side wall of the storage tank 4 at intervals. A pressure sensor 28 is arranged between the support frame 26 and the support block 27, the pressure sensor 28 adopts a resistance strain type pressure sensor 28, and the pressure sensor 28 is electrically connected with the controller 1. The pressure sensor 28 transmits the pressure value of the supporting block 27 to the pressure sensor 28 to the user terminal 2 through the pressure value, so that a worker can conveniently and accurately know the storage condition of the storage tank 4.

When the staff gets the material, the pressure value of this storage tank 4 is input on user terminal 2, and controller 1 receives the pressure value back at user terminal 2, starts second vacuum pump 8, and the raw materials in the storage tank 4 enter into and get material jar 6, and when controller 1 received the pressure value of pressure sensor 28 and the pressure value of user terminal 2 input unanimity, it is convenient to stop starting second vacuum pump 8 to get the material.

The implementation principle of the storage system for glue mixing in the embodiment of the application is as follows: during material storage, a worker opens the first electromagnetic valve 5, the first vacuum pump 7 on the corresponding material storage tank 4 and the second electromagnetic valve 18 communicated with the material storage tank 4 through the user terminal 2, and raw materials sequentially enter the first feeding pipe 3, the sampling inspection tank 11, the first distributing hopper 15 and the second distributing hopper 17 and finally enter the material storage tank 4 through the second distributing pipe 16; when the material is taken, the second vacuum pump 8 is started, the material in the material storage tank 4 is taken from the material taking rod 9, the first corrugated pipe 19 and the material taking tank 6 and enters the material taking tank 6, and then the staff takes the material in the sampling tank, so that the material storage and the material taking are convenient.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (9)

1. The utility model provides a storage system for mixed glue which characterized in that: the automatic feeding device comprises a controller (1), a user terminal (2), a first feeding pipe (3), a storage tank (4), a first electromagnetic valve (5), a material taking tank (6), a first vacuum pump (7) and a second vacuum pump (8), wherein the storage tank (4) is hollow, one end of the first feeding pipe (3) is communicated with the storage tank (4), the other end of the first feeding pipe is used for feeding, the first electromagnetic valve (5) is arranged on the first feeding pipe (3), the first electromagnetic valve (5) is used for opening and closing the first feeding pipe (3), and the first vacuum pump (7) is communicated with the storage tank (4);

the material taking device is characterized in that a fixed groove (41) is formed in the inner bottom wall of the material storage tank (4), a guide surface (42) is formed in the side wall of the fixed groove (41) and close to the edge of the bottom wall of the fixed groove (41), a material taking rod (9) is arranged in the material storage tank (4), the material taking rod (9) is arranged on the side wall of the guide surface (42), the material taking rod (9) is hollow, a material inlet (91) is formed in the outer side wall of the material taking rod (9) in an array manner, a material taking pipe (10) is arranged between the material taking tank (6) and the material taking rod (9), and the second vacuum pump (8) is communicated with the material taking tank (6);

the controller (1) is in communication connection with the user terminal (2), and the first electromagnetic valve (5), the first vacuum pump (7) and the second vacuum pump (8) are electrically connected with the controller (1);

the material taking rod (9) is slidably connected to the guide surface (42) along the inclined direction of the guide surface (42), a first corrugated pipe (19) is arranged between the material taking rod (9) and the material taking pipe (10), the first corrugated pipe (19) is telescopic along the length direction of the first corrugated pipe (19), a fixed block (20) is fixedly arranged at the top of the material taking rod (9), a movable rod (21) is arranged on the outer side wall of the material storage tank (4), one end of the movable rod (21) penetrates through the inside of the material storage tank (4) and is fixedly connected with the fixed block (20), be provided with second electric jar (22) that are used for driving movable rod (21) to remove on storage tank (4), waste material mouth (43) have been seted up on the lateral wall of fixed slot (41), the open-top of waste material mouth (43) can be sealed to extracting stick (9), be provided with waste pipe (23) on the lateral wall of storage tank (4), one end and waste material mouth (43) intercommunication, the other end of waste pipe (23) are provided with waste material jar (32), be provided with third vacuum pump (24) on waste material jar (32), second electric jar (22), third vacuum pump (24) and controller (1) electric connection.

2. A glue stock system as set forth in claim 1 wherein: the novel sampling inspection device is characterized in that a sampling inspection tank (11) is arranged between the first feeding pipe (3) and the storage tank (4), a discharge hole (111) is formed in the hollow inside of the sampling inspection tank (11) and in the bottom of the sampling inspection tank, two ends of the sampling inspection tank (11) are respectively communicated with the first feeding pipe (3) and the storage tank (4), a sliding plate (12) is arranged at the bottom of the sampling inspection tank (11) in a sliding mode, the sliding plate (12) is connected to the bottom of the sampling inspection tank (11) in a sliding mode along the horizontal direction, a connecting hole (121) is formed in the sliding plate (12), a first electric cylinder (13) for driving the sliding plate (12) to slide is arranged on the sampling inspection tank (11), and the sliding plate (12) can be communicated with the discharge hole (111) along the sliding mode along the horizontal direction, and the first electric cylinder (13) is electrically connected with the controller (1).

3. A glue stock system as set forth in claim 1 wherein: storage tank (4) are provided with four along the horizontal direction interval, every all be provided with second inlet pipe (14) on storage tank (4), the one end that first solenoid valve (5) was kept away from to first inlet pipe (3) is provided with first branch hopper (15), the top of first branch hopper (15) is provided with two branch material pipes (16), two be provided with second branch hopper (17) on branch material pipe (16), two feed inlets have been seted up at the top of second branch hopper (17), second inlet pipe (14) are through feed inlet and second branch hopper (17) intercommunication, all be provided with second solenoid valve (18) on second inlet pipe (14) and the branch material pipe (16), second solenoid valve (18) and controller (1) electric connection.

4. A glue stock system as set forth in claim 1 wherein: one side of the material taking rod (9) far away from the material taking pipe (10) is fixedly provided with a clamping block (25), and the clamping block (25) is clamped with the waste port (43).

5. A glue stock system as set forth in claim 1 wherein: the automatic feeding device is characterized in that a supporting frame (26) is arranged on the storage tank (4), the storage tank (4) is connected to the supporting frame (26) in a sliding mode along the vertical direction, a supporting block (27) is fixedly arranged on the outer side wall of the storage tank (4), a pressure sensor (28) is arranged between the supporting frame (26) and the supporting block (27), and the pressure sensor (28) is electrically connected with the controller (1).

6. A glue stock system as set forth in claim 1 wherein: a second corrugated pipe (29) is arranged between the fixed block (20) and the inner side wall of the storage tank (4), the second corrugated pipe (29) is telescopic along the length direction of the second corrugated pipe (29), and the movable rod (21) is coaxially sleeved in the second corrugated pipe (29).

7. A glue stock system as set forth in claim 1 wherein: one side of the material taking rod (9) far away from the material taking pipe (10) is provided with a communication hole (92) communicated with the inside of the material taking rod (9), and the side wall of the fixed groove (41) can seal the opening of the communication hole (92).

8. A glue stock system as set forth in claim 1 wherein: the bottom of the material taking rod (9) is fixedly provided with a limiting block (30), the side wall of the guide surface (42) is provided with a limiting groove (44), and the limiting block (30) is slidably connected in the limiting groove (44) along the inclined direction of the guide surface (42).

9. A glue stock system according to claim 1 or 5, wherein: the inside of storage tank (4) is provided with a plurality of charge level indicators (31) along the direction of height interval of storage tank (4), every charge level indicator (31) all with controller (1) electric connection.