CN218994073U - Silica gel cooling and collecting system - Google Patents

Silica gel cooling and collecting system Download PDF

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Publication number
CN218994073U
CN218994073U CN202223462507.8U CN202223462507U CN218994073U CN 218994073 U CN218994073 U CN 218994073U CN 202223462507 U CN202223462507 U CN 202223462507U CN 218994073 U CN218994073 U CN 218994073U
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China
Prior art keywords
cylinder
pipe
cooling
material sucking
collecting system
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CN202223462507.8U
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Chinese (zh)
Inventor
罗建军
刘光永
罗科
聂国祥
罗庆林
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Chongqing Kerui Nanhai Pharmaceutical Co ltd
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Chongqing Kerui Nanhai Pharmaceutical Co ltd
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Abstract

The utility model discloses a silica gel particle cooling and collecting system, which is characterized by comprising the following components: the tail end of the rotary cooling cylinder is provided with a housing, and a blanking pipe is fixed at the bottom of the housing; the blanking pipe of the cover shell is positioned in the foundation pit; the material sucking device is fixed above a base station, a material accumulation cavity is formed in the base station, one end of the material accumulation cavity is opened, a discharging pipe of the material sucking device is located right above the material accumulation cavity, and the material sucking device is connected to the lower area of the foundation pit through a material sucking pipe. This collecting system simple structure, can be quick cool off the silica gel grain, can be convenient pack it after the cooling and transport.

Description

Silica gel cooling and collecting system
Technical Field
The utility model belongs to the field of silica gel cooling, and particularly relates to a silica gel particle cooling and collecting system.
Background
In the pharmaceutical field, silica gel particles are auxiliary materials for purifying products, the silica gel particles are mainly used for separating impurities in artemisinin products, a large amount of impurities exist in pores after the silica gel particles are used, the impurities are required to be removed through a high-temperature calcination method, the aim of repeated use is fulfilled, after the silica gel particles are calcined at high temperature, the silica gel particles are required to be cooled and then transported to the next process, at present, the silica gel particles are naturally dried in a stacking mode when cooled, and are scooped up and collected in an artificial mode after being dried in the air, and finally transported.
Disclosure of Invention
In order to solve one or more of the defects in the prior art, the technical problem to be solved by the utility model is to provide a silica gel cooling and collecting system, which has a simple structure, can rapidly cool silica gel particles, and can conveniently pack and transport the cooled silica gel particles.
In order to achieve the above object, the present utility model provides a silica gel particle cooling and collecting system, comprising:
the tail end of the rotary cooling cylinder is provided with a housing, and a blanking pipe is fixed at the bottom of the housing;
the blanking pipe of the cover shell is positioned in the foundation pit;
the material sucking device is fixed above a base station, a material accumulation cavity is formed in the base station, one end of the material accumulation cavity is opened, a discharging pipe of the material sucking device is located right above the material accumulation cavity, and the material sucking device is connected to the lower area of the foundation pit through a material sucking pipe.
Further, the rotary cooling cylinder is connected through two sets of supporting seats, and every supporting seat all includes two pedestal, rotates on every pedestal to be connected with the backing roll, installs driving motor between two sets of supporting seats, be fixed with the driving gear on driving motor's the motor shaft, the rotary cooling cylinder includes urceolus and inner tube, inner tube and urceolus pass through branch fixed connection, urceolus left end board is connected with the water inlet joint, urceolus right end board is connected with the water outlet joint, the water outlet joint is connected with the outlet pipe through rotary joint, still fixedly connected with and driving gear assorted driven gear on the urceolus, feed inlet and discharge gate have still been seted up on the rotary cooling cylinder.
Further, the feed inlet of the rotary cooling cylinder is arranged on the left end plate of the rotary cooling cylinder and penetrates through the outer cylinder and the inner cylinder, a first sealing cylinder is fixed in the feed inlet, the discharge outlet of the rotary cooling cylinder is arranged in the tail end area of the rotary cooling cylinder and also penetrates through the outer cylinder and the inner cylinder, a second sealing cylinder is fixed in the discharge outlet, and the discharge outlet corresponds to the housing.
Furthermore, an anti-falling screen plate is further connected above the foundation pit.
Further, the material sucking pipe comprises a bent pipe body and a vertical pipe body, and the material sucking device is fixed on the vertical pipe body through a reinforcing rod.
Furthermore, the vertical pipe body is also connected with a flexible pipe body through a pipe joint, and the tail end of the flexible pipe body is positioned in the lower area of the foundation pit.
Further, the material sucking device comprises a material sucking kettle, and the material sucking kettle is connected with a negative pressure fan through a pipeline.
Further, the bent pipe body of the material sucking pipe is communicated with the top of the material sucking kettle.
The beneficial effects of the utility model are as follows:
firstly, the collection system is simple in structure, the silica gel particles are rapidly cooled through the rotary cooling cylinder, the material sucking device is convenient to suck after cooling, and meanwhile, the silica gel particles can be conveniently packed and transported;
secondly, as the base station is provided with the accumulation cavity, after the fork truck moves the collection bin to the accumulation cavity, the silica gel particles can be directly placed into the collection bin for transportation through the discharging pipe of the suction device, so that the transportation efficiency is improved;
thirdly, as the cooled silica gel particles firstly fall into the foundation pit, the foundation pit can have a better polymerization effect on the silica gel particles, and the suction pipe is convenient for sucking the silica gel particles;
fourth, through circulating water cooling's mode, can realize the quick cooling of silica gel material, the silica gel material can move forward at rotatory in-process simultaneously, reaches the automatic discharge of discharge gate at last.
Drawings
FIG. 1 is a schematic diagram of the structure of the present utility model;
FIG. 2 is an enlarged view of portion A of FIG. 1 in accordance with the present utility model;
FIG. 3 is an enlarged view of portion B of FIG. 1 in accordance with the present utility model;
fig. 4 is a structural diagram of the base station of the present utility model.
In the figure: 1. rotating the cooling cylinder; 2. a foundation pit; 3. a base station; 4. a material accumulation cavity; 5. anti-falling screen plate; 6. bending the tube body; 7. a vertical tube body; 8. a reinforcing rod; 9. a flexible tube; 10. a pipe joint; 11. a material sucking kettle; 12. a negative pressure fan; 13. a discharge pipe; 14. a silicon gel particle; 15. discharging pipes; 16. a discharging valve; 17. a water inlet joint; 18. an outer cylinder; 19. an inner cylinder; 20. a support rod; 21. cooling water; 22. a spiral plate; 23. a discharge port; 24. a housing; 25. a water inlet pipe; 26. a support leg; 27. a second seal cartridge; 28. a rotary joint; 29. a first seal cartridge; 30. a water outlet joint; 31. a blanking cover; 32. a water outlet pipe; 33. a base; 34. a drive gear; 35. a driven gear; 36. a driving motor; 37. a support roller;
Detailed Description
The utility model is further illustrated by the following examples in conjunction with the accompanying drawings:
referring to FIGS. 1-3, a silica gel cooling and collecting system comprises:
the tail end of the rotary cooling cylinder is provided with a housing 24, and a blanking pipe is fixed at the bottom of the housing 24;
a foundation pit 2 in which the blanking pipe of the cover 24 is located;
the material sucking device is fixed above a base station 3, a material accumulation cavity 4 is formed in the base station 3, one end of the material accumulation cavity 4 is opened, a discharging pipe 13 of the material sucking device is located right above the material accumulation cavity 4, and the material sucking device is connected to a lower area of the foundation pit 2 through a material sucking pipe.
When the utility model is used, firstly, the silicon rubber particles 14 needing to be cooled are continuously introduced into the rotary cooling cylinder 1 for cooling, the rotary cylinder of the rotary cooling cylinder 1 is driven by a motor to rotate, the cooling mode can be water-cooled or air-cooled, when the silicon rubber particles 14 reach the tail end of the rotary cooling cylinder 1, the silicon rubber particles fall into the housing 24 from the tail end of the rotary cooling cylinder 1, a gap of 20-30cm is reserved between the tail end of the rotary cooling cylinder 1 and the housing 24, and as the blanking pipe is connected to the housing 24, the silicon rubber particles fall into the foundation pit from the blanking pipe, at the moment, a suction device is started, the suction pipe of the suction device can suck the cooled silicon rubber particles 14 in the foundation pit 2 because of being in the lower area of the foundation pit 2, after the silicon rubber particles 14 are adsorbed into the suction device, the silicon rubber particles are temporarily stored, after the silicon rubber particles 14 are stored, a collection bin fork is lifted into the accumulation cavity 4, finally, a discharge valve 16 on the discharge pipe 15 of the suction device is opened, the silicon rubber particles 14 are discharged into the collection bin, and finally, the next operation can be carried out.
Further, the rotary cooling cylinder is connected through two groups of supporting seats, each group of supporting seats comprises two seat bodies 33, a supporting roller 37 is rotationally connected to each seat body 33, a driving motor 36 is installed between the two groups of supporting seats, a driving gear 34 is fixed on a motor shaft of the driving motor 36, the rotary cooling cylinder comprises an outer cylinder 18 and an inner cylinder 19, a spiral plate 22 for discharging is connected in the inner cylinder 19, the inner cylinder 19 and the outer cylinder 18 are fixedly connected through a supporting rod 20, a water inlet joint 17 is connected to a left end plate of the outer cylinder 18, a water outlet joint 30 is connected to a right end plate of the outer cylinder 18, a water inlet pipe 25 is connected to the water outlet joint 30 through a rotary joint 28, a driven gear 35 matched with the driving gear 34 is fixedly connected to the outer cylinder 18, and a material inlet and a material outlet 23 are further formed in the rotary cooling cylinder. Specifically, the rotary cooling cylinder adopts a water cooling mode, specifically, the water inlet joint 17 and the water outlet joint 30 at two ends of the outer cylinder 18 are connected with the water inlet pipe 25 and the water outlet pipe 32, and the rotary cooling cylinder is driven by the driving motor 36 to rotate because the water inlet pipe 25 and the water outlet pipe 32 are driven by the rotating joint 28, the water inlet pipe 25 and the water outlet pipe 32 keep static during rotation, cooling water 21 enters from the water inlet pipe 25 and is discharged from the water outlet pipe 32 to ensure that the water temperature is kept at a lower temperature, meanwhile, silica gel particles enter from a feeding hole of the rotary cooling cylinder, when entering into the inner cylinder 19, the spiral plate 22 on the inner cylinder 19 drives the silica gel particles to move forwards, finally falls into the housing 24 from the discharging hole 23 and is discharged from the housing 24.
Further, the feeding port of the rotary cooling cylinder is arranged at the left end plate of the rotary cooling cylinder and penetrates through the outer cylinder 18 and the inner cylinder 19, a first sealing cylinder 29 is fixed in the feeding port, the discharging port 23 of the cooling cylinder is arranged at the tail end area of the cooling cylinder and penetrates through the outer cylinder 18 and the inner cylinder 19, a second sealing cylinder 27 is fixed in the discharging port 23, and the discharging port 23 corresponds to the housing 24. Specifically, the feeding port is arranged on the end plate, when the silica gel particles are fed, the rotary cooling cylinder can be kept still, then the silica gel particles are manually discharged into the feeding port or discharged into the feeding port through the suction device, after the silica gel particles are fed, the feeding port can be plugged through a plugging cover 31 (the plugging cover 31 is convenient to take off through transitional connection), then the rotary cooling cylinder rotates, meanwhile, cooling water 21 is fed, the silica gel particles are cooled and simultaneously move forwards under the action of the spiral plate 22, finally enter the discharging port 23 and fall into the housing 24, the housing 24 can be directly fixed on the ground through the supporting leg 26 at the bottom of the housing 24, and if clamping stagnation occurs, the housing 24 is conveniently cleaned after moving.
Furthermore, a falling-preventing net plate 5 is further connected above the foundation pit 2. Specifically, in order to avoid personnel in the workshop from carelessly stepping empty into the foundation pit 2, an anti-falling screen plate 5 is further connected above the foundation pit 2, and the operator can clearly see the specific condition of the silicon rubber particles 14 in the foundation pit 2 due to the adoption of the screen plate.
Further, the suction pipe comprises a bent pipe body 6 and a vertical pipe body 7, and the suction device is fixed on the vertical pipe body 7 through a reinforcing rod 8. Specifically, the suction pipe comprises a bent pipe body and a vertical pipe body 7, and the vertical pipe body 7 can directly extend into the lower area of the foundation pit 2 to realize the suction of the silica gel particles 14.
Further, the vertical pipe body is further connected with a flexible pipe body 9 through a pipe joint 10, and the tail end of the flexible pipe body 9 is positioned in the lower area of the foundation pit 2. Because the vertical pipe body 7 is connected with the flexible pipe body 9 through the pipe joint 10, the flexible pipe body 9 can be deformed and folded, so that the cleaning of the foundation pit 2 is more convenient, interference cannot be generated during cleaning, and the pipe joint 10 can be a rotary joint 28 or a fixed joint.
Further, the material sucking device comprises a material sucking kettle 11, and the material sucking kettle 11 and a negative pressure fan 12 are connected through a pipeline. Specifically, the utility model adopts the material sucking kettle 11, the material sucking kettle 11 is connected right above the base station 3 through the supporting legs 26, when the silicon rubber particles 14 in the rotary cooling cylinder 1 are required to be adsorbed, the negative pressure fan 12 is started, the negative pressure fan 12 enables negative pressure to be generated in the material sucking kettle 11, and the material sucking pipe is driven to adsorb the silicon rubber particles 14 in the foundation pit 2.
Further, the bent pipe body 6 of the suction pipe is communicated with the top of the suction kettle 11. The suction pipe is communicated with the top of the suction kettle 11 through the bent pipe body 6 at the top, so that enough space is reserved between the suction kettle 11 and the rotary cooling cylinder 1, other personnel or forklifts in workshops can conveniently pass through the space, and meanwhile, the suction pipe is connected with the top of the suction kettle 11, so that after more silica gel particles are stored in the suction kettle 11, the silica gel particles can be transported again, and the transportation efficiency is improved.
The foregoing describes in detail preferred embodiments of the present utility model. It should be understood that numerous modifications and variations can be made in accordance with the concepts of the utility model by one of ordinary skill in the art without undue burden. Therefore, all technical solutions which can be obtained by logic analysis, reasoning or limited experiments based on the prior art by the person skilled in the art according to the inventive concept shall be within the scope of protection defined by the claims.

Claims (8)

1. A silicone gel cooling and collecting system, comprising:
the tail end of the rotary cooling cylinder is provided with a housing, and a blanking pipe is fixed at the bottom of the housing;
the blanking pipe of the cover shell is positioned in the foundation pit;
the material sucking device is fixed above a base station, a material accumulation cavity is formed in the base station, one end of the material accumulation cavity is opened, a discharging pipe of the material sucking device is located right above the material accumulation cavity, and the material sucking device is connected to the lower area of the foundation pit through a material sucking pipe.
2. The silica gel particle cooling and collecting system according to claim 1, wherein the rotary cooling cylinder is connected through two groups of supporting seats, each group of supporting seats comprises two seats, a supporting roller is rotationally connected to each seat, a driving motor is installed between the two groups of supporting seats, a driving gear is fixed to a motor shaft of the driving motor, the rotary cooling cylinder comprises an outer cylinder and an inner cylinder, a spiral plate for discharging is connected to the inner cylinder, the inner cylinder and the outer cylinder are fixedly connected through a supporting rod, a water inlet joint is connected to a left end plate of the outer cylinder, a water outlet joint is connected to a right end plate of the outer cylinder, a water inlet pipe is connected to the water outlet joint through a rotary joint, a driven gear matched with the driving gear is fixedly connected to the outer cylinder, and a feed inlet and a discharge outlet are further formed in the rotary cooling cylinder.
3. A silicone gel cooling and collecting system as set forth in claim 2, wherein: the feeding hole of the rotary cooling cylinder is formed in the left end plate of the rotary cooling cylinder and penetrates through the outer cylinder and the inner cylinder, a first sealing cylinder is fixed in the feeding hole, the discharging hole of the rotary cooling cylinder is formed in the tail end area of the rotary cooling cylinder and also penetrates through the outer cylinder and the inner cylinder, a second sealing cylinder is fixed in the discharging hole, and the discharging hole corresponds to the housing.
4. A silicone gel cooling and collecting system as set forth in claim 3, wherein: and an anti-falling screen plate is further connected above the foundation pit.
5. A silicone gel cooling and collecting system as set forth in claim 4, wherein: the suction pipe comprises a bent pipe body and a vertical pipe body, and the suction device is fixed on the vertical pipe body through a reinforcing rod.
6. A silicone gel cooling and collection system as set forth in claim 5 wherein: the vertical pipe body is also connected with a flexible pipe body through a pipe joint, and the tail end of the flexible pipe body is positioned in the lower area of the foundation pit.
7. A silicone gel cooling and collecting system as set forth in claim 6, wherein: the material sucking device comprises a material sucking kettle, and the material sucking kettle is connected with a negative pressure fan through a pipeline.
8. A silicone gel cooling and collecting system as set forth in claim 7, wherein: the bent pipe body of the material sucking pipe is communicated with the top of the material sucking kettle.
CN202223462507.8U 2022-12-24 2022-12-24 Silica gel cooling and collecting system Active CN218994073U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202223462507.8U CN218994073U (en) 2022-12-24 2022-12-24 Silica gel cooling and collecting system

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202223462507.8U CN218994073U (en) 2022-12-24 2022-12-24 Silica gel cooling and collecting system

Publications (1)

Publication Number Publication Date
CN218994073U true CN218994073U (en) 2023-05-09

Family

ID=86219721

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202223462507.8U Active CN218994073U (en) 2022-12-24 2022-12-24 Silica gel cooling and collecting system

Country Status (1)

Country Link
CN (1) CN218994073U (en)

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Date Code Title Description
GR01 Patent grant
GR01 Patent grant
PE01 Entry into force of the registration of the contract for pledge of patent right
PE01 Entry into force of the registration of the contract for pledge of patent right

Denomination of utility model: A cooling and collection system for silicone particles

Granted publication date: 20230509

Pledgee: Agricultural Bank of China Limited Chongqing Qianjiang Branch

Pledgor: CHONGQING KERUI NANHAI PHARMACEUTICAL Co.,Ltd.|CHONGQING KERUI PHARMACEUTICAL (Group) Co.,Ltd.

Registration number: Y2024980015377