CN215572250U - High-temperature steam cooler capable of realizing rapid heat exchange - Google Patents

Abstract

The utility model discloses a high-temperature steam cooler capable of realizing rapid heat exchange, which relates to the technical field of coolers and comprises a working box, a pipe body and a collecting box, wherein a PLC (programmable logic controller) is installed in the middle of the top end of one end of the working box, the pipe body is installed at the upper end of the inner part of the working box, cold water pipes penetrating through the working box are installed on two sides of the pipe body, the pipe array is uniformly installed in the pipe body, an exhaust pipe penetrating through the working box is installed on one side of the top end of the pipe body, and an evaporation structure is arranged at the bottom end of the pipe body. According to the utility model, steam is decelerated by the baffle plate, and fully contacts with the outer wall of the tube nest to exchange heat, meanwhile, heat is quickly absorbed by the second heat conduction plate and is discharged by the second radiating fins to perform auxiliary heat dissipation, condensed water falls into the collecting box, and is adsorbed by the cotton ropes, so that heat is quickly evaporated and absorbed, and finally, heat exchange is quickly realized, thereby solving the problem that quick heat exchange cannot be realized.

Description

High-temperature steam cooler capable of realizing rapid heat exchange

Technical Field

The utility model relates to the technical field of coolers, in particular to a high-temperature steam cooler capable of realizing rapid heat exchange.

Background

In a factory, a large amount of high-temperature steam is often generated, and the high-temperature steam needs to be cooled to a certain extent and then can be discharged to the next link, so that the high-temperature steam needs to be rapidly cooled by using a cooler, but the existing high-temperature steam cooler still has certain defects.

Through retrieval, chinese patent No. CN209341865U, publication No. 2019, 09.03.2019, discloses a high-temperature steam cooler, wherein "a right side of the cooler body is fixedly connected with a mounting seat, a fixing block is arranged inside the mounting seat, a limiting block is arranged at a front side of the fixing block, a sealing strip is arranged on an inner wall of the fixing block, a connecting block is arranged inside the sealing strip, the fixing rod is arranged inside a limiting hole, a liquid outlet pipe is arranged inside the mounting seat, and a filter screen is arranged on a left side of the liquid outlet pipe", wherein rapid heat exchange cannot be realized, and rapid cooling of high-temperature steam cannot be realized, so that working efficiency is not high.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to a high temperature steam cooler capable of achieving rapid heat exchange, so as to solve the problem of the prior art that rapid heat exchange cannot be achieved.

In order to achieve the purpose, the utility model provides the following technical scheme: a high-temperature steam cooler capable of realizing rapid heat exchange comprises a working box, a pipe body and a collecting box, and further comprises a heat dissipation structure convenient for improving the air circulation rate, an evaporation structure convenient for rapid auxiliary cooling and a filtering structure convenient for filtering steam;

the middle position of the top end of one end of the working box is provided with a PLC, the upper end of the inside of the working box is provided with a pipe body, two sides of the pipe body are respectively provided with a cold water pipe penetrating through the working box, the inside of the pipe body is uniformly provided with a row of pipes, one side of the top end of the pipe body is provided with an exhaust pipe penetrating through the working box, and the evaporation structure is arranged at the bottom end of the pipe body;

the heat dissipation structure is arranged at the lower end of one side in the working box;

the filtering structure is arranged at the bottom end of the other side in the working box.

Preferably, the evaporation structure comprises a collection box, the collection box is installed at the bottom end of the pipe body, drain pipes penetrating through the pipe body are installed on two sides of the top end of the collection box, and an evaporation net is evenly installed at the bottom end of the collection box.

Preferably, the middle position department of the inside bottom of work box installs the under casing, and the top of under casing evenly installs the cotton rope, the top of cotton rope runs through evaporation net and extends to the inside of collecting box.

Preferably, the baffle is all installed to the inside top of body and bottom, and the height of baffle is the half of body height.

Preferably, the second heat-conducting plate is installed in the middle of the outer wall of the pipe body, and second cooling fins are evenly installed on the outer side of the second heat-conducting plate.

Preferably, the heat radiation structure includes fan, bellows and multidirectional tuber pipe, the lower extreme in work box one side is installed to bellows, and the internally mounted of bellows has the fan, the intermediate position department on one side of the bellows installs the multidirectional tuber pipe.

Preferably, filtration includes thin filter screen, coarse strainer, filter box, intake pipe and outlet duct, the filter box is installed in the bottom of the inside opposite side of work box, and the top of filter box installs the intake pipe that runs through the work box, the outlet duct that runs through the body is installed to the bottom of filter box one side, the coarse strainer is installed to the upper end of filter box inside, and the thin filter screen is installed to the lower extreme of filter box inside.

Preferably, a first heat-conducting plate is installed at the middle position of one side of the filter box, and first radiating fins are evenly installed on the outer side of the first heat-conducting plate.

Compared with the related art, the high-temperature steam cooler capable of realizing rapid heat exchange has the following beneficial effects:

1. the utility model provides an air inlet pipe, a filter box, a coarse filter screen, a fine filter screen, an air outlet pipe, a pipe body, a first heat conducting plate and a first radiating fin, high-temperature steam is guided into the filter box through the air inlet pipe, impurities are isolated through the filtering treatment of the coarse filter screen and the fine filter screen, finally the high-temperature steam enters the pipe body through the air outlet pipe for cooling treatment, and meanwhile, the heat is absorbed by the first heat conducting plate and is discharged through the first radiating fin for auxiliary heat radiation, so that the problem of easy blockage is solved;

2. the utility model provides a cold water pipe, a row pipe, a baffle, a second heat conducting plate, a second radiating fin, a collecting box and a cotton rope, wherein cooling water circulates in the row pipe through the cold water pipe, steam is decelerated through the baffle and fully contacted with the outer wall of the row pipe to exchange heat, meanwhile, the heat is quickly absorbed by the second heat conducting plate and is discharged through the second radiating fin to perform auxiliary heat dissipation, condensed water falls into the collecting box, and is adsorbed by the cotton rope to quickly evaporate and absorb the heat, and finally, the heat exchange is quickly realized, so that the problem that the quick heat exchange cannot be realized is solved;

3. the utility model provides a PLC (programmable logic controller), a fan, a working box, a cotton rope, a first radiating fin and a second radiating fin, wherein the PLC is used for controlling the fan to work to generate wind power, so that the air circulation speed in the working box is increased, water on the surface of the cotton rope is quickly evaporated and absorbed, heat on the surfaces of the first radiating fin and the second radiating fin is quickly dissipated, the radiating efficiency is improved, and the problem of low radiating efficiency is solved.

Drawings

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

FIG. 2 is a schematic side view of the cross-sectional structure of the present invention;

FIG. 3 is a schematic side sectional view of an evaporation mesh of the present invention;

FIG. 4 is a schematic front view of the present invention;

fig. 5 is an enlarged schematic view of the utility model at a in fig. 1.

In the figure: 1. a work box; 2. a cold water pipe; 3. a pipe body; 4. a heat dissipation structure; 401. a fan; 402. an air box; 403. a multidirectional air duct; 5. a bottom box; 6. a cotton rope; 7. evaporating the net; 8. a first heat sink; 9. a filter structure; 901. a fine filter screen; 902. coarse filtration; 903. a filter box; 904. an air inlet pipe; 905. an air outlet pipe; 10. a first heat-conducting plate; 11. a baffle plate; 12. arranging pipes; 13. an exhaust pipe; 14. a collection box; 15. a PLC controller; 16. a second heat-conducting plate; 17. a second heat sink; 18. and a water discharge pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1: referring to fig. 1-5, a high temperature steam cooler capable of realizing rapid heat exchange includes a working box 1, a pipe 3, a collecting box 14, a heat dissipation structure 4 for improving air circulation rate, an evaporation structure for facilitating rapid auxiliary cooling, and a filtering structure 9 for facilitating filtering of steam;

a PLC (programmable logic controller) 15 is installed in the middle of the top end of one end of the working box 1, a pipe body 3 is installed at the upper end of the inside of the working box 1, cold water pipes 2 penetrating through the working box 1 are installed on two sides of the pipe body 3, row pipes 12 are evenly installed inside the pipe body 3, an exhaust pipe 13 penetrating through the working box 1 is installed on one side of the top end of the pipe body 3, and an evaporation structure is arranged at the bottom end of the pipe body 3;

the heat dissipation structure 4 is arranged at the lower end of one side in the working box 1;

the filtering structure 9 is arranged at the bottom end of the other side in the working box 1;

referring to fig. 1-5, a high temperature steam cooler capable of realizing rapid heat exchange includes an evaporation structure, the evaporation structure includes a collection box 14, the collection box 14 is installed at the bottom end of the tube 3, and both sides of the top end of the collection box 14 are installed with drain pipes 18 penetrating through the tube 3, the bottom end of the collection box 14 is uniformly installed with an evaporation net 7;

a bottom box 5 is arranged in the middle of the bottom end in the working box 1, cotton ropes 6 are uniformly arranged at the top end of the bottom box 5, and the top ends of the cotton ropes 6 penetrate through the evaporation net 7 and extend into the collection box 14;

the top end and the bottom end inside the pipe body 3 are both provided with baffles 11, and the height of each baffle 11 is half of the height of the pipe body 3;

a second heat conduction plate 16 is arranged in the middle of the outer wall of the tube body 3, and second radiating fins 17 are uniformly arranged on the outer side of the second heat conduction plate 16;

specifically, as shown in fig. 1, fig. 2, fig. 3, fig. 4 and fig. 5, at first, through cold water pipe 2, make the cooling water at tubulation 12 internal circulation, steam is through blockking of baffle 11 and is slowed down, carries out the heat transfer with tubulation 12 outer wall full contact, absorbs the heat through second fin 17 discharge fast simultaneously through second heat-conducting plate 16 and assists the heat dissipation, the water of condensation falls into the inside absorption through cotton rope 6 of collecting box 14, the heat absorption is evaporated fast, finally comparatively quick realization heat exchange.

Example 2: the heat dissipation structure 4 comprises a fan 401, an air bellow 402 and a multidirectional air pipe 403, wherein the air bellow 402 is mounted at the lower end of one side of the working box 1, the fan 401 is mounted inside the air bellow 402, and the multidirectional air pipe 403 is mounted in the middle of one side of the air bellow 402;

specifically, as shown in fig. 1, the PLC controller 15 controls the fan 401 to generate wind power, so as to increase the air circulation rate inside the work box 1, so that water on the surface of the cotton rope 6 evaporates and absorbs heat quickly, so that heat on the surfaces of the first cooling fin 8 and the second cooling fin 17 is dissipated quickly, and the heat dissipation efficiency is improved.

Example 3: the filtering structure 9 comprises a fine filtering net 901, a coarse filtering net 902, a filtering box 903, an air inlet pipe 904 and an air outlet pipe 905, wherein the filtering box 903 is arranged at the bottom end of the other side in the working box 1, the air inlet pipe 904 penetrating through the working box 1 is arranged at the top end of the filtering box 903, the air outlet pipe 905 penetrating through the pipe body 3 is arranged at the bottom end of one side of the filtering box 903, the coarse filtering net 902 is arranged at the upper end in the filtering box 903, and the fine filtering net 901 is arranged at the lower end in the filtering box 903;

a first heat conducting plate 10 is arranged in the middle of one side of the filter box 903, and first radiating fins 8 are uniformly arranged on the outer side of the first heat conducting plate 10;

specifically, as shown in fig. 1 and 2, high-temperature steam is firstly introduced into the filter box 903 through the air inlet pipe 904, impurities are isolated through the filtering treatment of the coarse filter screen 902 and the fine filter screen 901, and finally the high-temperature steam enters the inside of the pipe body 3 through the air outlet pipe 905 for cooling treatment, and is simultaneously absorbed by the first heat conduction plate 10 and discharged through the first cooling fins 8 for auxiliary heat dissipation.

The working principle is as follows: when the device is used, an external power supply is firstly switched on;

the first innovation point implementation step:

the first step is as follows: introducing high-temperature steam into the filter box 903 through an air inlet pipe 904, and isolating impurities through filtering treatment of a coarse filter screen 902 and a fine filter screen 901;

the second step is that: the high-temperature steam enters the inside of the tube body 3 through the outlet pipe 905 for cooling treatment.

Third cloth: the heat absorbed by the first heat conduction plate 10 is discharged through the first heat radiation fins 8 to perform auxiliary heat radiation.

The implementation step of the second innovation point:

the first step is as follows: cooling water circulates in the tubes 12 through the cold water pipes 2, and steam is decelerated through the blocking of the baffles 11 and fully contacted with the outer walls of the tubes 12 to exchange heat;

the second step is that: the heat is quickly absorbed by the second heat conduction plate 16 and is discharged through the second radiating fins 17 for assistance;

the third step: the condensed water falls into the collecting box 14 and is adsorbed by the cotton rope 6, and the condensed water is quickly evaporated to absorb heat, so that heat exchange is finally realized quickly.

The third innovation point implementation step:

the first step is as follows: the PLC 15 controls the fan 401 to work to generate wind power, so that the air circulation rate in the working box 1 is increased;

the second step is that: so that water on the surface of the cotton rope 6 is quickly evaporated and absorbs heat, heat on the surfaces of the first radiating fin 8 and the second radiating fin 17 is quickly dissipated, and the radiating efficiency is improved.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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 utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a can realize high temperature steam cooler of quick heat exchange, includes work box (1), body (3) and collecting box (14), its characterized in that: the steam generator also comprises a heat dissipation structure (4) which is convenient for improving the air circulation rate, an evaporation structure which is convenient for rapidly assisting in cooling and a filtering structure (9) which is convenient for filtering the steam;

a PLC (programmable logic controller) (15) is installed in the middle of the top end of one end of the working box (1), a pipe body (3) is installed at the upper end of the inside of the working box (1), cold water pipes (2) penetrating through the working box (1) are installed on two sides of the pipe body (3), row pipes (12) are evenly installed inside the pipe body (3), an exhaust pipe (13) penetrating through the working box (1) is installed on one side of the top end of the pipe body (3), and the evaporation structure is arranged at the bottom end of the pipe body (3);

the heat dissipation structure (4) is arranged at the lower end of one side in the working box (1);

the filtering structure (9) is arranged at the bottom end of the other side in the working box (1).

2. A high-temperature steam cooler capable of realizing rapid heat exchange according to claim 1, wherein: the evaporation structure comprises a collection box (14), the collection box (14) is installed at the bottom end of the pipe body (3), drain pipes (18) penetrating through the pipe body (3) are installed on two sides of the top end of the collection box (14), and an evaporation net (7) is evenly installed at the bottom end of the collection box (14).

3. A high-temperature steam cooler capable of realizing rapid heat exchange according to claim 1, wherein: the middle position department of the inside bottom of work box (1) installs under casing (5), and the top of under casing (5) evenly installs cotton rope (6), the inside that evaporates net (7) and extend to collecting box (14) is run through on the top of cotton rope (6).

4. A high-temperature steam cooler capable of realizing rapid heat exchange according to claim 1, wherein: baffle (11) are all installed to the inside top of body (3) and bottom, and the height of baffle (11) is the half of body (3) height.

5. A high-temperature steam cooler capable of realizing rapid heat exchange according to claim 1, wherein: the middle position department of body (3) outer wall installs second heat-conducting plate (16), and second fin (17) are evenly installed in the outside of second heat-conducting plate (16).

6. A high-temperature steam cooler capable of realizing rapid heat exchange according to claim 1, wherein: the heat dissipation structure (4) comprises a fan (401), an air box (402) and a multidirectional air pipe (403), wherein the air box (402) is installed at the lower end of one side of the working box (1), the fan (401) is installed inside the air box (402), and the multidirectional air pipe (403) is installed at the middle position of one side of the air box (402).

7. A high-temperature steam cooler capable of realizing rapid heat exchange according to claim 1, wherein: filtration (9) are including thin filter screen (901), coarse strainer (902), filter box (903), intake pipe (904) and outlet duct (905), the bottom at the inside opposite side of work box (1) is installed in filter box (903), and the top of filter box (903) installs intake pipe (904) that run through work box (1), outlet duct (905) that run through body (3) are installed to the bottom of filter box (903) one side, coarse strainer (902) are installed to the inside upper end of filter box (903), and fine filter screen (901) are installed to the inside lower extreme of filter box (903).

8. A high-temperature steam cooler capable of realizing rapid heat exchange according to claim 7, wherein: a first heat-conducting plate (10) is installed at the middle position of one side of the filter box (903), and first radiating fins (8) are evenly installed on the outer side of the first heat-conducting plate (10).

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