CN215373152U - Multi-stage water cooling system - Google Patents
Multi-stage water cooling system Download PDFInfo
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- CN215373152U CN215373152U CN202121502974.1U CN202121502974U CN215373152U CN 215373152 U CN215373152 U CN 215373152U CN 202121502974 U CN202121502974 U CN 202121502974U CN 215373152 U CN215373152 U CN 215373152U
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Abstract
The utility model discloses a multi-stage water cooling system, wherein a tank body is communicated with a cooling tower through an external circulating cooling pipe, the tank body is divided into a first area, a second area, a third area, a fourth area and a fifth area which are sequentially communicated through a first partition plate, a second partition plate, a third partition plate and a fourth partition plate, and a cooling hopper, a first spiral feeder, a second spiral feeder, a third spiral feeder, a fourth spiral feeder, a fifth spiral feeder, a sixth spiral feeder and a discharge port which are sequentially connected are arranged in the tank body; the second spiral feeder passes through the fourth baffle, and the third spiral feeder passes the third baffle, and the fourth spiral feeder passes the second baffle, and the fifth spiral feeder passes first baffle, and the sixth spiral feeder passes the lateral wall of cell body. The utility model has the advantages of multi-stage and multi-time cooling of materials and good cooling effect.
Description
Technical Field
The utility model relates to the field of environment-friendly equipment, in particular to a multistage water cooling system.
Background
In order to protect the environment, the agricultural and forestry wastes such as rice straws and the like are not required to be burned, the fresh rice straws are not required to be directly reused, and the harmless treatment of the agricultural and forestry wastes such as the rice straws and the like is a trend. At present, the common method is to carbonize the agricultural and forestry wastes such as rice straws and the like into powder for reutilization. The temperature of the carbon powder formed in the carbonization process can reach 600 ℃, and the carbon powder needs to be effectively cooled. However, the cooling equipment in the prior art cannot realize multi-stage and multi-time cooling, has poor cooling effect, and cannot be directly applied to the cooling treatment of high-temperature carbon powder.
SUMMERY OF THE UTILITY MODEL
Utility model purpose: aiming at the defects and shortcomings of the prior art, the utility model provides a multistage water cooling system which has the beneficial effects of multistage and repeated cooling of materials and good cooling effect.
The technical scheme is as follows: the multistage water cooling system is characterized in that: the device comprises a tank body, wherein the tank body is communicated with a cooling tower through an external circulating cooling pipe, the tank body is divided into a first area, a second area, a third area, a fourth area and a fifth area which are sequentially communicated through a first partition plate, a second partition plate, a third partition plate and a fourth partition plate, and a cooling hopper, a first spiral feeder, a second spiral feeder, a third spiral feeder, a fourth spiral feeder, a fifth spiral feeder, a sixth spiral feeder and a discharge port which are sequentially connected are arranged in the tank body; the cooling hopper is positioned at the water inlet end of the circulating cooling pipe, and the discharge port is positioned at the water outlet end of the circulating cooling pipe; the second spiral feeder passes through the fourth baffle, and the third spiral feeder passes through the third baffle, and the fourth spiral feeder passes through the second baffle, and the fifth spiral feeder passes through first baffle, and the sixth spiral feeder passes through the lateral wall of cell body.
The first area, the second area, the third area, the fourth area and the fifth area are sequentially connected end to end through end channels.
The first screw feeder, the second screw feeder, the third screw feeder, the fourth screw feeder, the fifth screw feeder and the sixth screw feeder are all obliquely arranged; the included angle between the first spiral feeder, the second spiral feeder, the third spiral feeder, the fourth spiral feeder, the fifth spiral feeder and the sixth spiral feeder and the horizontal plane is 35-55 degrees; the first screw feeder, the second screw feeder, the third screw feeder, the fourth screw feeder, the fifth screw feeder and the sixth screw feeder are connected through vertical connecting pipes.
Wherein the cooling hopper is communicated with the bottom of the first screw feeder; and the discharge hole is communicated with the top of the sixth screw feeder.
The connection structures between the first spiral feeder and the second spiral feeder, between the second spiral feeder and the third spiral feeder, between the third spiral feeder and the fourth spiral feeder, between the fourth spiral feeder and the fifth spiral feeder, and between the fifth spiral feeder and the sixth spiral feeder are the same; the top of the first spiral feeder is communicated with the bottom of the second spiral feeder through a vertical connecting pipe.
Has the advantages that: compared with the prior art, the utility model has the following remarkable advantages: the utility model divides the tank body into a plurality of areas, and a plurality of spiral feeders are arranged in the tank body, thereby increasing the running time of the materials in the tank body and being capable of cooling the materials more fully. Meanwhile, the cooling water is continuously updated through the circulating cooling pipe, and the cooling effect of the cooling water is ensured. The cooling device has the beneficial effects of multistage repeated cooling of materials and good cooling effect.
Drawings
FIG. 1 is a schematic structural view of the present invention;
FIG. 2 is a schematic view of a connection structure of the cooling hopper, the first screw feeder and the second screw feeder according to the present invention;
in the figure, 1 is a tank body, 2 is a circulating cooling pipe, 3 is a cooling tower, 4 is a first partition plate, 5 is a second partition plate, 6 is a third partition plate, 7 is a fourth partition plate, 8 is a first area, 9 is a second area, 10 is a third area, 11 is a fourth area, 12 is a fifth area, 13 is a cooling hopper, 14 is a first screw feeder, 15 is a second screw feeder, 16 is a third screw feeder, 17 is a fourth screw feeder, 18 is a fifth screw feeder, 19 is a sixth screw feeder, 20 is a discharge port, and 21 is a vertical connecting pipe.
Detailed Description
The technical solution of the present invention is further described with reference to the accompanying drawings and the detailed description.
The multistage water cooling system comprises a tank body 1, wherein the tank body 1 is communicated with a cooling tower 3 through an external circulating cooling pipe 2, the tank body 1 is divided into a first area 8, a second area 9, a third area 10, a fourth area 11 and a fifth area 12 which are sequentially communicated through a first partition plate 4, a second partition plate 5, a third partition plate 6 and a fourth partition plate 7, and a cooling hopper 13, a first spiral feeder 14, a second spiral feeder 15, a third spiral feeder 16, a fourth spiral feeder 17, a fifth spiral feeder 18, a sixth spiral feeder 19 and a discharge port 20 which are sequentially connected are arranged in the tank body 1; the cooling hopper 13 is positioned at the water inlet end of the circulating cooling pipe 2, and the discharge port 20 is positioned at the water outlet end of the circulating cooling pipe 2; the second screw feeder 15 passes through the fourth partition 7, the third screw feeder 16 passes through the third partition 6, the fourth screw feeder 17 passes through the second partition 5, the fifth screw feeder 18 passes through the first partition 4, and the sixth screw feeder 19 passes through the side wall of the tank body 1.
The first region 8, the second region 9, the third region 10, the fourth region 11 and the fifth region 12 are sequentially connected end to end through end channels. The first screw feeder 14, the second screw feeder 15, the third screw feeder 16, the fourth screw feeder 17, the fifth screw feeder 18 and the sixth screw feeder 19 are all obliquely arranged; the included angles between the first screw feeder 14, the second screw feeder 15, the third screw feeder 16, the fourth screw feeder 17, the fifth screw feeder 18 and the sixth screw feeder 19 and the horizontal plane are 35-55 degrees; the first screw feeder 14, the second screw feeder 15, the third screw feeder 16, the fourth screw feeder 17, the fifth screw feeder 18, and the sixth screw feeder 19 are connected to each other by a vertical connecting pipe 21. The cooling hopper 13 is communicated with the bottom of the first screw feeder 14; the discharge port 20 communicates with the top of the sixth screw feeder 19. The connection structures between the first screw feeder 14 and the second screw feeder 15, between the second screw feeder 15 and the third screw feeder 16, between the third screw feeder 16 and the fourth screw feeder 17, between the fourth screw feeder 17 and the fifth screw feeder 18, and between the fifth screw feeder 18 and the sixth screw feeder 19 are the same; the top of the first screw feeder 14 is communicated with the bottom of the second screw feeder 15 through a vertical connecting pipe 21.
When in use, the cooling hopper 13 in the tank body 1 is communicated with the bottom of the first screw feeder 14. The vertical connecting pipes 21 are arranged between the first screw feeder 14 and the second screw feeder 15, between the second screw feeder 15 and the third screw feeder 16, between the third screw feeder 16 and the fourth screw feeder 17, between the fourth screw feeder 17 and the fifth screw feeder 18, and between the fifth screw feeder 18 and the sixth screw feeder 19. The discharge port 20 communicates with the top of the sixth screw feeder 19. Thereby forming a channel for the feed. The material enters the cooling hopper 13, passes through the first screw feeder 14, the second screw feeder 15, the third screw feeder 16, the fourth screw feeder 17, the fifth screw feeder 18, and the sixth screw feeder 19 in this order, and is discharged from the discharge port 20.
The pond body 1 is communicated with the cooling tower 3 through the external circulating cooling pipe 2, the cooling hopper 13 is positioned at the water inlet end of the circulating cooling pipe 2, the discharge port 20 is positioned at the water outlet end of the circulating cooling pipe 2, the cooled water body enters the pond body 1 from the cooling hopper 13 and sequentially passes through the fifth area 12, the fourth area 11, the third area 10, the second area 9 and the first area 8, the materials in the first spiral feeder 14, the second spiral feeder 15, the third spiral feeder 16, the fourth spiral feeder 17, the fifth spiral feeder 18 and the sixth spiral feeder 19 are cooled, the amount of the materials is absorbed, the high-temperature water body enters the circulating cooling pipe 2 to reach the cooling tower 3 to be cooled, the cooled water body enters the pond body 1 again through the circulating cooling pipe 2, and the materials are cooled.
The design that the second spiral feeder 15 penetrates through the fourth partition plate 7, the third spiral feeder 16 penetrates through the third partition plate 6, the fourth spiral feeder 17 penetrates through the second partition plate 5, the fifth spiral feeder 18 penetrates through the first partition plate 4, and the sixth spiral feeder 19 penetrates through the side wall of the tank body 1 increases the operation time of the materials in the tank body 1, so that the materials can be cooled more sufficiently, and the cooled materials are discharged from the discharge hole 20. The multistage water cooling system has the beneficial effects that the multistage water cooling system can cool materials for multiple times and has a good cooling effect.
Claims (5)
1. Multistage water cooling system, its characterized in that: the device comprises a pool body (1), wherein the pool body (1) is communicated with a cooling tower (3) through an external circulating cooling pipe (2), the pool body (1) is divided into a first area (8), a second area (9), a third area (10), a fourth area (11) and a fifth area (12) which are communicated in sequence through a first partition plate (4), a second partition plate (5), a third partition plate (6) and a fourth partition plate (7), and a cooling hopper (13), a first spiral feeder (14), a second spiral feeder (15), a third spiral feeder (16), a fourth spiral feeder (17), a fifth spiral feeder (18), a sixth spiral feeder (19) and a discharge port (20) which are connected in sequence are arranged in the pool body (1); the cooling hopper (13) is positioned at the water inlet end of the circulating cooling pipe (2), and the discharge hole (20) is positioned at the water outlet end of the circulating cooling pipe (2); the second spiral feeder (15) penetrates through the fourth partition plate (7), the third spiral feeder (16) penetrates through the third partition plate (6), the fourth spiral feeder (17) penetrates through the second partition plate (5), the fifth spiral feeder (18) penetrates through the first partition plate (4), and the sixth spiral feeder (19) penetrates through the side wall of the tank body (1).
2. The multi-stage water cooling system of claim 1, wherein: the first area (8), the second area (9), the third area (10), the fourth area (11) and the fifth area (12) are sequentially connected end to end through end channels.
3. The multi-stage water cooling system of claim 1, wherein: the first screw feeder (14), the second screw feeder (15), the third screw feeder (16), the fourth screw feeder (17), the fifth screw feeder (18) and the sixth screw feeder (19) are all obliquely arranged; the included angle between the first spiral feeder (14), the second spiral feeder (15), the third spiral feeder (16), the fourth spiral feeder (17), the fifth spiral feeder (18) and the sixth spiral feeder (19) and the horizontal plane is 35-55 degrees; the first screw feeder (14), the second screw feeder (15), the third screw feeder (16), the fourth screw feeder (17), the fifth screw feeder (18) and the sixth screw feeder (19) are connected through a vertical connecting pipe (21).
4. The multi-stage water cooling system of claim 1, wherein: the cooling hopper (13) is communicated with the bottom of the first screw feeder (14); the discharge hole (20) is communicated with the top of the sixth screw feeder (19).
5. The multi-stage water cooling system of claim 3, wherein: the connection structures between the first screw feeder (14) and the second screw feeder (15), between the second screw feeder (15) and the third screw feeder (16), between the third screw feeder (16) and the fourth screw feeder (17), between the fourth screw feeder (17) and the fifth screw feeder (18), and between the fifth screw feeder (18) and the sixth screw feeder (19) are the same; the top of the first screw feeder (14) is communicated with the bottom of the second screw feeder (15) through a vertical connecting pipe (21).
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202121502974.1U CN215373152U (en) | 2021-07-04 | 2021-07-04 | Multi-stage water cooling system |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202121502974.1U CN215373152U (en) | 2021-07-04 | 2021-07-04 | Multi-stage water cooling system |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN215373152U true CN215373152U (en) | 2021-12-31 |
Family
ID=79606965
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202121502974.1U Active CN215373152U (en) | 2021-07-04 | 2021-07-04 | Multi-stage water cooling system |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN215373152U (en) |
-
2021
- 2021-07-04 CN CN202121502974.1U patent/CN215373152U/en active Active
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Address after: 210000 rooms 631, 632 and 633, building A2, No. 129-3, Guanghua Road, Qinhuai District, Nanjing City, Jiangsu Province Patentee after: All things environmental energy technology (Jiangsu) Co.,Ltd. Address before: 210000 rooms 631, 632 and 633, building A2, No. 129-3, Guanghua Road, Qinhuai District, Nanjing City, Jiangsu Province Patentee before: NANJING WANWU NEW ENERGY TECHNOLOGY Co.,Ltd. |