CN213932121U

CN213932121U - Cooling arrangement is used in graphite alkene processing

Info

Publication number: CN213932121U
Application number: CN202022233812.4U
Authority: CN
Inventors: 沈利利
Original assignee: Shenyang Huatianxin Graphite Technology Co ltd
Current assignee: Shenyang Huatianxin Graphite Technology Co ltd
Priority date: 2020-10-09
Filing date: 2020-10-09
Publication date: 2021-08-10
Anticipated expiration: 2030-10-09

Abstract

The utility model relates to the technical field of graphene, and discloses a cooling device for processing graphene, which comprises a working panel, a first circulating cooling tank is welded and fixed on the left side of the front side surface of the working panel, a liquid inlet pipe is welded and fixed on the upper surface of the first circulating cooling tank, a second circulating cooling box is welded and fixed on the right side of the back surface of the working panel, a liquid outlet pipe is welded and fixed on the upper surface of the second circulating cooling box, a heat dissipation plate is welded and fixed on the side surface of the working panel and positioned at the outer sides of the first circulating cooling tank and the second circulating cooling tank, a liquid groove is arranged inside the working panel, an outer cooling pipe and an inner cooling pipe are respectively welded and fixed inside the working panel and positioned at the outer side and the inner side of the liquid groove, the outer side surface of the outer cooling pipe is fixedly welded with a heat conducting fin, and a cooling device is arranged in the outer cooling pipe. This cooling arrangement is used in graphite alkene processing can be to the liquid circulation cooling of fluid bath inside through cooling device to improve cooling efficiency.

Description

Cooling arrangement is used in graphite alkene processing

Technical Field

The utility model relates to a graphite alkene technical field specifically is a cooling arrangement is used in graphite alkene processing.

Background

Graphite alkene cooling arrangement is a indirect heating equipment for cooling fluid, because graphite alkene possess splendid heat conductivity, can carry out rapid cooling with the hot-fluid, the present commonly used mainly is shell and tube cooler, be applicable to the condensation, the heating, the evaporation, different work condition such as waste heat recovery, present graphite alkene cooler is that a single cooling tube cools off the hot-fluid, mainly pour into the cooling chamber through the cooling tube with the cooling water, cool off the hot-fluid in the cooling tube, but this kind of cooling method can only one-way cool off, can not the rapid cooling hot-fluid, the efficiency that leads to the heat exchange is lower.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Not enough to prior art, the utility model provides a cooling arrangement is used in graphite alkene processing has solved graphite alkene processing refrigerated problem.

(II) technical scheme

For realizing the refrigerated purpose of above-mentioned graphite alkene processing, the utility model provides a following technical scheme: the utility model provides a cooling arrangement is used in graphite alkene processing, includes the work panel, the positive side left side welded fastening of work panel has first circulative cooling case, the upper surface welded fastening of first circulative cooling case has the feed liquor pipe, the back right side welded fastening of work panel has the second circulative cooling case, the upper surface welded fastening of second circulative cooling case has the drain pipe, the outside welded fastening that the side of work panel and lie in first circulative cooling case and second circulative cooling case has the heating panel, the liquid flow groove has been seted up to the inside of work panel, the outside both sides welded fastening that the inside of work panel and lie in the liquid flow groove have outer cooling tube and interior cooling tube respectively, the outside surface welded fastening of outer cooling tube has the conducting strip, the inside of outer cooling tube is provided with cooling device.

Preferably, the cooling device comprises heat dissipation holes, a heat dissipation cavity, a cooling pipe, a cooling cavity, a roller and a flow deflector, the heat dissipation holes are formed in the upper side of the outer surface of the outer cooling pipe, the heat dissipation cavity is formed in the outer cooling pipe, the cooling pipe is welded and fixed in the heat dissipation cavity, the cooling cavity is formed in the cooling pipe, the roller is welded and fixed on the inner wall of the cooling cavity through a bearing, the flow deflector is welded and fixed on the outer surface of the roller, liquid can be discharged from a liquid outlet pipe after being injected into a flow liquid groove through a liquid inlet pipe, the graphene nano particle cooling liquid in the cooling cavity can circularly flow through a first circulating cooling box and a second circulating cooling box, cooling air is conveyed to the heat dissipation holes from the heat dissipation cavity and is discharged, the working panel is cooled, and the flow deflector can be pushed to rotate and perform flow guiding and stirring on the graphene nano particle cooling liquid while flowing, the mobility of the graphene nano particles is increased, and then the temperature of liquid is reduced by reducing the working environment of the working panel, so that the heat exchange efficiency of the liquid is improved.

Preferably, the two ends of the outer cooling pipe, the inner cooling pipe and the cooling pipe are respectively communicated with the first circulating cooling tank and the second circulating cooling tank, so that the graphene nano particle cooling liquid can flow in a circulating manner through the first circulating cooling tank and the second circulating cooling tank.

Preferably, the inside of cooling chamber is provided with graphite alkene nanometer particle coolant liquid, can improve the cooling efficiency of liquid through pour into graphite alkene nanometer particle coolant liquid into the inside of cooling chamber.

Preferably, the outer cooling pipe, the inner cooling pipe and the cooling pipe are all S-shaped, so that the cooling time of the liquid can be prolonged through the S-shaped outer cooling pipe, the S-shaped inner cooling pipe and the S-shaped cooling pipe.

Preferably, the conducting strip is welded and fixed with the heat dissipation plate, after the same outer cooling pipe and inner cooling pipe are arranged inside the device to cool the working panel in a heat dissipation manner, the heat inside the outer cooling pipe and the working panel can be respectively led out through the conducting strip and dissipated to the outside of the working panel through the heat dissipation plate, and therefore the cooling efficiency of the working device is further improved.

Preferably, two ends of the liquid flowing groove are respectively communicated with the liquid inlet pipe and the liquid outlet pipe, so that liquid can be conveniently injected and discharged through the liquid inlet pipe and the liquid outlet pipe.

Compared with the prior art, the utility model provides a cooling arrangement is used in processing of graphite alkene possesses following beneficial effect:

1. this cooling arrangement is used in graphite alkene processing, can be discharged by the drain pipe after flowing through the flow tank through injecting liquid into the flow through the feed liquor pipe, and can make the inside graphite alkene nano particle coolant liquid circulation of cooling chamber flow and carry cooled air to the louvre discharge by the heat dissipation chamber through first circulative cooling case and second circulative cooling case, and cool down to work panel, and can promote the water conservancy diversion piece to rotate and carry out the water conservancy diversion stirring to it when graphite alkene nano particle coolant liquid flows, increase the mobility of graphite alkene nano particle, and then the operational environment through reducing work panel reduces the temperature of liquid, thereby improve the efficiency of liquid heat exchange.

2. This cooling arrangement is used in graphite alkene processing sets up the same outer cooling tube and interior cooling tube in inside and dispels the heat cooling back to the work panel, can be respectively with the heat derivation of outer cooling tube and work panel inside and by the outside of heating panel effluvium to the work panel through the conducting strip to further improve the cooling efficiency of work the device.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the structure of the liquid tank of the present invention;

fig. 3 is a schematic view of the structure of the flow deflector of the present invention.

Wherein: 1. a working panel; 2. a first circulating cooling tank; 3. a liquid inlet pipe; 4. a second circulating cooling tank; 5. a liquid outlet pipe; 6. a heat dissipation plate; 7. a liquid flowing groove; 8. an outer cooling tube; 9. cooling the tube internally; 10. a heat conductive sheet; 11. heat dissipation holes; 12. a heat dissipation cavity; 13. a cooling tube; 14. a cooling chamber; 15. a roller; 16. and a flow deflector.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, the utility model provides a cooling device for graphene processing, which comprises a working panel 1, a first circulation cooling box 2 is welded and fixed on the left side of the front side of the working panel 1, a liquid inlet pipe 3 is welded and fixed on the upper surface of the first circulation cooling box 2, a second circulation cooling box 4 is welded and fixed on the right side of the back side of the working panel 1, a liquid outlet pipe 5 is welded and fixed on the upper surface of the second circulation cooling box 4, a heat dissipation plate 6 is welded and fixed on the side of the working panel 1 and outside the first circulation cooling box 2 and the second circulation cooling box 4, a liquid flow groove 7 is opened inside the working panel 1, an outer cooling pipe 8 and an inner cooling pipe 9 are welded and fixed on the outer side and both sides of the liquid flow groove 7 respectively in the inside of the working panel 1, a heat conduction sheet 10 is welded and fixed on the outer side surface of the outer cooling pipe 8, a cooling device is arranged inside the outer cooling pipe 8, the cooling device comprises a heat dissipation hole 11, a heat dissipation cavity 12, a cooling pipe 13, a cooling cavity 14, a rolling shaft 15 and a flow deflector 16, wherein the heat dissipation hole 11 is arranged on the upper side of the outer surface of the outer cooling pipe 8, the heat dissipation cavity 12 is arranged inside the outer cooling pipe 8, the cooling pipe 13 is fixedly welded inside the heat dissipation cavity 12, the cooling cavity 14 is arranged inside the cooling pipe 13, the rolling shaft 15 is fixedly welded on the inner wall of the cooling cavity 14 through a bearing, the flow deflector 16 is fixedly welded on the outer surface of the rolling shaft 15, liquid can be discharged from the liquid outlet pipe 5 after being injected into the flow liquid tank 7 through the liquid inlet pipe 3, the graphene nano particle cooling liquid inside the cooling cavity 14 can circularly flow through the first circulating cooling box 2 and the second circulating cooling box 4, cooling air is conveyed to the heat dissipation hole 11 through the heat dissipation cavity 12 to be discharged, the working panel 1 is cooled, and the flow deflector 16 can be pushed to rotate and flow and stir the graphene nano particle cooling liquid, the mobility of the graphene nano particles is increased, and then the temperature of the liquid is reduced by reducing the working environment of the working panel 1, so that the heat exchange efficiency of the liquid is improved, the two ends of the outer cooling pipe 8, the inner cooling pipe 9 and the cooling pipe 13 are respectively communicated with the first circulating cooling tank 2 and the second circulating cooling tank 4, so that the graphene nano particle cooling liquid can flow in a circulating manner through the first circulating cooling tank 2 and the second circulating cooling tank 4, the graphene nano particle cooling liquid is arranged in the cooling cavity 14, the cooling efficiency of the liquid can be improved by injecting the graphene nano particle cooling liquid into the cooling cavity 14, the outer cooling pipe 8, the inner cooling pipe 9 and the cooling pipe 13 are S-shaped, so that the cooling time of the liquid can be prolonged through the S-shaped outer cooling pipe 8, the inner cooling pipe 9 and the cooling pipe 13, and the heat conducting fins 10 are welded and fixed with the heat dissipation plate 6, set up the same back of outer cooling tube 8 and interior cooling tube 9 to the cooling of working panel 1 heat dissipation inside, can be respectively with the heat derivation of outer cooling tube 8 and 1 inside of working panel and by the outside of 6 effluviums to working panel 1 of heating panel through conducting strip 10 to further improve the cooling efficiency of work the device, the both ends of fluid bath 7 are linked together with feed liquor pipe 3 and drain pipe 5 respectively, are convenient for pour into liquid into and discharge by feed liquor pipe 3 and drain pipe 5 respectively.

When the device is used, liquid is injected into the flow liquid groove 7 from the liquid inlet pipe 3 and then can be discharged from the liquid outlet pipe 5, the graphene nano particle cooling liquid in the cooling cavity 14 can flow circularly through the first circulating cooling box 2 and the second circulating cooling box 4, cooling air is conveyed to the heat dissipation holes 11 from the heat dissipation cavity 12 and is discharged, the working panel 1 is cooled, the flow deflector 16 can be pushed to rotate and stir the flow deflector while the graphene nano particle cooling liquid flows, the mobility of the graphene nano particles is increased, the temperature of the liquid is reduced by reducing the working environment of the working panel 1, the heat exchange efficiency of the liquid is improved, after the working panel 1 is cooled by arranging the same outer cooling pipe 8 and the same inner cooling pipe 9 inside to dissipate heat of the working panel 1, the heat in the outer cooling pipe 8 and the working panel 1 can be respectively led out through the heat conduction sheet 10 and dissipated to the outside of the working panel 1 through the heat dissipation plate 6, thereby further improving the cooling efficiency of the device.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a cooling arrangement is used in graphite alkene processing, includes work panel (1), its characterized in that: the working panel is characterized in that a first circulating cooling box (2) is welded and fixed on the left side of the front side of the working panel (1), a liquid inlet pipe (3) is welded and fixed on the upper surface of the first circulating cooling box (2), a second circulating cooling box (4) is welded and fixed on the right side of the back of the working panel (1), a liquid outlet pipe (5) is welded and fixed on the upper surface of the second circulating cooling box (4), a heat dissipation plate (6) is welded and fixed on the outer sides of the first circulating cooling box (2) and the second circulating cooling box (4) and on the side of the working panel (1), a liquid flowing groove (7) is formed in the working panel (1), an outer cooling pipe (8) and an inner cooling pipe (9) are respectively welded and fixed on the inner sides of the outer cooling pipe (8) and on the inner sides of the liquid flowing groove (7), and heat conducting fins (10) are welded and fixed on the outer side surfaces of the outer cooling pipe (8), and a cooling device is arranged in the outer cooling pipe (8).

2. The cooling apparatus for graphene processing according to claim 1, wherein: cooling device includes louvre (11), heat dissipation chamber (12), cooling tube (13), cooling chamber (14), roller bearing (15) and water conservancy diversion piece (16), the surface upside in outer cooling tube (8) is seted up in louvre (11), the inside in outer cooling tube (8) is seted up in heat dissipation chamber (12), cooling tube (13) welded fastening is in the inside in heat dissipation chamber (12), the inside in cooling tube (13) is seted up in cooling chamber (14), roller bearing (15) are through bearing welded fastening at the inner wall in cooling chamber (14), water conservancy diversion piece (16) welded fastening is at the surface of roller bearing (15).

3. The cooling apparatus for graphene processing according to claim 2, wherein: and the two ends of the outer cooling pipe (8), the inner cooling pipe (9) and the cooling pipe (13) are respectively communicated with the first circulating cooling box (2) and the second circulating cooling box (4).

4. The cooling apparatus for graphene processing according to claim 2, wherein: and graphene nano particle cooling liquid is arranged in the cooling cavity (14).

5. The cooling apparatus for graphene processing according to claim 2, wherein: the outer cooling pipe (8), the inner cooling pipe (9) and the cooling pipe (13) are all S-shaped.

6. The cooling apparatus for graphene processing according to claim 1, wherein: the heat conducting fins (10) are welded and fixed with the heat dissipation plate (6).

7. The cooling apparatus for graphene processing according to claim 1, wherein: and two ends of the liquid flowing groove (7) are respectively communicated with the liquid inlet pipe (3) and the liquid outlet pipe (5).