CN210014687U - Graphite alkene stirring cooling device - Google Patents

Abstract

A graphene stirring and cooling device relates to the technical field of graphene cooling and has the characteristic of rapid heat exchange; the utility model discloses a heat exchange device, including the heat exchange tube, the heat exchange tube is provided with the graphite alkene heat exchange tube, the heat exchange tube is provided with the heat exchange shaft, the heat exchange tube is provided with the heat exchange tube, the heat exchange.

Description

Graphite alkene stirring cooling device

Technical Field

The utility model relates to a graphite alkene cooling technology field, concretely relates to graphite alkene stirring cooling device.

Background

The graphene cooling device is a heat exchange device for cooling fluid, wherein a layer of graphene is attached to a small pipe of a cooling pipe, and the graphene has excellent thermal conductivity, so that the thermal fluid can be rapidly cooled. Water or air is typically used as a coolant to remove heat. They can be mainly classified into shell and tube coolers, plate coolers and air-cooled coolers. The cooler is a heat exchange device commonly used in the industrial departments of metallurgy, chemical industry, energy, traffic, light industry, food and the like, and is suitable for different working conditions of the cooler, condensation, heating, evaporation, waste heat recovery and the like. Therefore, among the numerous types of heat exchangers, tube heat exchangers remain in a significant position.

The traditional graphene cooler cools hot fluid by a single cooling unit, cooling water is mainly injected into a cooling cavity of the cooler through the cooling unit to cool the hot fluid in a cooling pipe, but the hot fluid cannot be cooled rapidly by the cooling mode, so that the heat exchange efficiency is low.

SUMMERY OF THE UTILITY MODEL

The utility model overcomes prior art's is not enough, provides a graphite alkene stirring cooling device, has the characteristics of quick heat transfer.

The utility model provides a technical scheme that its technical problem adopted is:

the utility model provides a graphite alkene stirring cooling device, includes first container and second container, a container wall of first container on be equipped with first fixing base and first motor, first spiral (mixing) shaft has been cup jointed through the bearing in the first fixing base, all be equipped with gear and intermeshing on the main shaft of first spiral (mixing) shaft and first motor, first spiral (mixing) shaft has cup jointed first graphite alkene heat exchange pipe through the bearing outside, first graphite alkene heat exchange pipe keeps away from the one end of first fixing base and has cup jointed first sealed bearing, first sealed bearing outside has cup jointed first pipeline, first tube coupling has the cold source storage tank.

One end vessel wall of second container on be equipped with second fixing base and second motor, second spiral (mixing) shaft has been cup jointed through the bearing in the second fixing base, all be equipped with gear and intermeshing on the main shaft of second spiral (mixing) shaft and second motor, second spiral (mixing) shaft has cup jointed the hot pipe of second graphite alkene outside through the bearing, the hot pipe of second graphite alkene keeps away from the one end of second fixing base and has cup jointed the sealed bearing of second, the sealed bearing outside of second has cup jointed the second pipeline, the second tube coupling has the heat source storage tank.

One end of the first graphene heat-exchanging tube, which is far away from the cold source storage tank, is connected with one end of the second graphene heat-exchanging tube, which is far away from the heat source storage tank, through a third pipeline, and a first flow pump is arranged on the third pipeline.

In a further preferred structure, the first container and the second container are provided with a material inlet and a material outlet.

In a further preferred configuration, the first container and the second container are provided with temperature sensors on the wall thereof, respectively.

In a further preferred construction, a thermally expandable annular ring is provided on the sealed bearing in the first container.

In a further preferable structure, the heat source storage tank and the cold source storage tank are connected through a fourth pipeline, and a second flow pump is arranged on the fourth pipeline.

The specific working process is as follows: a refrigerant in a cold source storage tank enters a first graphene heat exchange tube through a first pipeline, the first graphene heat exchange tube rotates under the drive of a first spiral stirring shaft, a material to be cooled is input from a material inlet of a first container, the material is stirred under the rotation of the first graphene heat exchange tube, heat exchange is simultaneously carried out, the flow of a first flow pump is adjusted according to a temperature sensor on the first container, a heat medium formed after heat absorption in the first graphene heat exchange tube enters a second graphene heat exchange tube of a second container through a third pipeline, then the material to be heated is input from a material inlet of the second container, similarly, the second graphene heat exchange tube rotates under the drive of a second spiral stirring shaft, the material to be heated is stirred under the rotation of the second graphene heat exchange tube, heat exchange is simultaneously carried out, the material to be heated is heated, and (4) enabling a refrigerant formed after heat release in the second graphene heat exchange tube to enter a heat source storage tank through a second pipeline.

The utility model discloses produced beneficial effect does for prior art.

The utility model discloses combine together stirring and heat exchange process, at the in-process of heat exchange, the material in the container under the effect of stirring, and the contact frequency between the hot exchange pipe of graphite alkene improves, also makes the temperature variation of material more even in the heat exchange simultaneously to, this device combines together heat absorption and exothermic process, can satisfy the temperature requirement of different materials simultaneously, make full use of heat energy has good economy and environmental protection benefit.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Wherein, 1 is first container, 2 is the second container, 3 is first graphite alkene heat exchange pipe, 4 is second graphite alkene heat exchange pipe, 5 is the cold source storage tank, 6 is the heat source storage tank, 7 is the material import, 8 is the material export, 9 is first motor, 10 is first fixing base, 11 is first sealed bearing, 12 is first flow pump, 13 is the third pipeline, 14 is first pipeline, 15 is the second fixing base, 16 is the second motor, 17 is second sealed bearing, 18 is the second pipeline, 19 is the fourth pipeline, 20 is the second flow pump.

Detailed Description

In order to make the technical problem, technical scheme and beneficial effect that the utility model will solve more clearly understand, combine embodiment and attached drawing, it is right to go on further detailed description the utility model discloses. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention. The technical solution of the present invention is described in detail below with reference to the embodiments and the drawings, but the scope of protection is not limited thereto.

As shown in fig. 1, a graphene stirring and cooling device, including first container 1 and second container 2, be equipped with first fixing base 10 and first motor 9 on the one end wall of first container 1, first spiral (mixing) shaft has been cup jointed through the bearing in the first fixing base 10, all be equipped with gear and intermeshing on the main shaft of first spiral (mixing) shaft and first motor 9, first spiral (mixing) shaft has cup jointed first graphene heat exchange pipe 3 through the bearing outside, first sealed bearing 11 has been cup jointed to the one end that first fixing base 10 was kept away from to first graphene heat exchange pipe 3, first pipeline 14 has been cup jointed to first sealed bearing 11 outside, first pipeline 14 is connected with cold source storage tank 5.

A second fixed seat 15 and a second motor 16 are arranged on the wall of one end of the second container 2, a second spiral stirring shaft is sleeved in the second fixed seat 15 through a bearing, gears are arranged on the second spiral stirring shaft and a main shaft of the second motor 16 and are meshed with each other, a second graphene heat exchange tube 4 is sleeved outside the second spiral stirring shaft through a bearing, a second sealing bearing 17 is sleeved at one end, far away from the second fixed seat 15, of the second graphene heat exchange tube 4, a second pipeline 18 is sleeved outside the second sealing bearing 17, and the second pipeline 18 is connected with a heat source storage tank 6;

one end of the first graphene heat exchange tube 3, which is far away from the cold source storage tank 5, and one end of the second graphene heat exchange tube 4, which is far away from the heat source storage tank 6, are connected through a third pipeline 13, and a first flow pump 12 is arranged on the third pipeline 13. The first container 1 and the second container 2 are provided with a material inlet 7 and a material outlet 8. The walls of the first container 1 and the second container 2 are respectively provided with a temperature sensor. A heat expansion ring is provided on the sealed bearing in the first container 1. The outlet of the heat source storage tank 6 and the inlet of the cold source storage tank 5 are connected through a fourth pipeline 19, and a second flow pump 20 is arranged on the fourth pipeline 19.

The specific working process is as follows: cooling water in a cold source storage tank 5 enters a first graphene heat exchange tube 3 through a first pipeline 14, the first graphene heat exchange tube 3 is driven by a first spiral stirring shaft to rotate, a material to be cooled is input from a material inlet 7 of a first container 1, the material is stirred under the rotation of the first graphene heat exchange tube 3, heat exchange is simultaneously carried out, the flow of a first flow pump 12 is adjusted according to a temperature sensor on the first container 1, hot water formed after heat absorption in the first graphene heat exchange tube 3 enters a second graphene heat exchange tube 4 of a second container 2 through a third pipeline 13, then the material to be heated is input from a material inlet 7 of the second container 2, similarly, the second graphene heat exchange tube 4 rotates under the drive of a second spiral, the material to be heated is stirred under the rotation of the second graphene heat exchange tube 4, and meanwhile, heat exchange is carried out, the material to be heated is heated, and cold water formed after heat release in the second graphene heat exchange tube 4 enters the heat source storage tank 6 through the second pipeline 18. The inlet fourth pipeline 19 of the water in the heat source storage tank 6 flows back to the cold source storage tank 5 for recycling.

The utility model discloses combine together stirring and heat exchange process, at the in-process of heat exchange, the material in the container is under the effect of stirring, and the contact frequency between the hot exchange pipe of graphite alkene improves, and the temperature variation that also makes the material simultaneously in the heat exchange is more even, and graphite alkene itself has quick heat transfer effect, can accelerate thermal conduction, and, this device combines together heat absorption and exothermic process, can satisfy the temperature requirement of different materials simultaneously, make full use of heat energy has good economy and environmental protection benefit.

The above description is for further details of the present invention with reference to specific preferred embodiments, and it should not be understood that the embodiments of the present invention are limited thereto, and it will be apparent to those skilled in the art that the present invention can be implemented in a plurality of simple deductions or substitutions without departing from the scope of the present invention, and all such alterations and substitutions should be considered as belonging to the present invention, which is defined by the appended claims.

Claims (5)

1. The graphene stirring and cooling device is characterized by comprising a first container (1) and a second container (2), wherein a first fixing seat (10) and a first motor (9) are arranged on the wall of one end of the first container (1), a first spiral stirring shaft is sleeved in the first fixing seat (10) through a bearing, gears are arranged on the first spiral stirring shaft and a main shaft of the first motor (9) and are meshed with each other, a first graphene heat exchange tube (3) is sleeved outside the first spiral stirring shaft through a bearing, a first sealing bearing (11) is sleeved at one end, away from the first fixing seat (10), of the first graphene heat exchange tube (3), a first pipeline (14) is sleeved outside the first sealing bearing (11), and the first pipeline (14) is connected with a cold source storage tank (5);

a second fixing seat (15) and a second motor (16) are arranged on the wall of one end of the second container (2), a second spiral stirring shaft is sleeved in the second fixing seat (15) through a bearing, gears are arranged on the second spiral stirring shaft and a main shaft of the second motor (16) and are meshed with each other, a second graphene heat exchange tube (4) is sleeved outside the second spiral stirring shaft through a bearing, a second sealing bearing (17) is sleeved at one end, far away from the second fixing seat (15), of the second graphene heat exchange tube (4), a second pipeline (18) is sleeved outside the second sealing bearing (17), and the second pipeline (18) is connected with a heat source storage tank (6);

one end, far away from cold source storage tank (5), of first graphite alkene heat exchange pipe (3) is connected through third pipeline (13) with one end, far away from heat source storage tank (6), of second graphite alkene heat exchange pipe (4), third pipeline (13) on be provided with first flow pump (12).

2. The graphene stirring and cooling device according to claim 1, wherein the first container (1) and the second container (2) are provided with a material inlet (7) and a material outlet (8).

3. The graphene stirring and cooling device according to claim 1, wherein the first container (1) and the second container (2) are respectively provided with a temperature sensor on the wall.

4. The graphene stirring and cooling device according to claim 1, wherein a thermal expansion ring is arranged on a sealing bearing in the first container (1).

5. The graphene stirring and cooling device according to claim 1, wherein the heat source storage tank (6) and the cold source storage tank (5) are connected through a fourth pipeline (19), and a second flow pump (20) is arranged on the fourth pipeline (19).

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