CN215336823U - Cooling system for heat supply boiler and heat supply boiler room - Google Patents

Abstract

The utility model discloses a cooling system for a heat supply boiler and a heat supply boiler room, wherein the cooling system comprises an air conditioner tail end, a conveying pipeline and a cooling tower; the tail end of the air conditioner is arranged in the heat supply boiler room, and the tail end of the air conditioner conveys cold air into the heat supply boiler room through a conveying pipeline; the cooling tower is arranged outside the heat supply boiler room and communicated with the tail end of the air conditioner. The heat supply boiler machine room comprises the cooling system, and further comprises a room body and a plurality of sets of ore machines arranged in the room body. This novel heat dissipation through cooling tower realizes the cooling of ore deposit machine in the heat supply boiler computer lab, need not mechanical refrigeration, has the advantage that reduces the energy consumption, and greatly reduced heat supply boiler computer lab's construction and running cost.

Description

Cooling system for heat supply boiler and heat supply boiler room

Technical Field

The present invention relates to a cooling system and a heat supply boiler machine room, and more particularly, to a cooling system for a heat supply boiler and a heat supply boiler machine room.

Background

In the heat supply boiler machine room, the ore mining machine can generate a large amount of heat, and if the heat cannot be evacuated in time, the service life of the ore mining machine can be seriously influenced. On the premise of ensuring the safe and high-performance operation of the mining machine, various energy-saving means are comprehensively utilized, the energy utilization efficiency of a heat supply boiler room is improved, the PUE is reduced, and energy conservation and emission reduction become one of the targets pursued by data center infrastructure.

At present, the design of heat supply boiler computer lab is more and more emphatic the efficiency and the cost advantage ore deposit equipment supplier that the ore deposit machine worked under higher temperature ambient temperature and is obtained also striven for the air inlet temperature restriction that promotes heat supply boiler computer lab, and through continuous optimization dig the inside overall arrangement of ore deposit equipment and choose for use high temperature resistant electronic components, the ore deposit machine can be in higher air inlet temperature and normal operating under the humidity environment of more humidity. However, the conventional heat supply boiler room generally still adopts a method of directly refrigerating by an air conditioner, so that the energy consumption is high, the operation cost of the heat supply boiler room is increased, and the air conditioning system is easy to damage in long-time high-intensity work, so that the operation cost of the heat supply boiler room is further increased.

SUMMERY OF THE UTILITY MODEL

In order to solve the defects of the technology, the utility model provides a cooling system for a heat supply boiler and a heat supply boiler machine room.

In order to solve the technical problems, the utility model adopts the technical scheme that: a cooling system for a heating boiler, the cooling system comprising an air conditioning terminal, a transfer line and a cooling tower;

the tail end of the air conditioner is arranged in the heat supply boiler room, the tail end of the air conditioner is connected with a conveying pipeline, the conveying pipeline is arranged in the heat supply boiler room, and the tail end of the air conditioner conveys cold air into the heat supply boiler room through the conveying pipeline; the cooling tower is arranged outside the heat supply boiler room and communicated with the tail end of the air conditioner.

Furthermore, a water outlet pipeline and a water return pipeline are communicated between the cooling tower and the tail end of the air conditioner.

Furthermore, the conveying pipeline consists of a main pipeline, branch pipelines and a distributor, the branch pipelines are provided with a plurality of branches, the branch pipelines are communicated with the main pipeline through the distributor, and the main pipeline is communicated with the tail end of the air conditioner.

Furthermore, a water pump is installed on the water outlet pipeline.

Furthermore, the water outlet pipeline and the water return pipeline are heat insulation pipes or are externally coated with heat insulation layers.

A heating boiler machine room comprises the cooling system for the heating boiler machine room.

Further, it still includes the room body and installs the ore deposit in the room body, and the ore deposit is equipped with the multiunit, and the multiunit ore deposit is side by side and the interval sets up.

Furthermore, a return air duct is formed at the top of the chamber body and communicated with the tail end of the air conditioner;

a floor is arranged in the chamber body, and the floor is transversely separated in the chamber body; the space formed between the floor and the floor of the chamber body is an air supply channel, a conveying pipeline of the cooling system is installed in the air supply channel, and the mining machine is arranged on the floor.

Furthermore, a through hole is formed in the floor, and the through hole is used for enabling branch pipelines of the conveying pipeline to pass through.

Furthermore, a return air fan is installed in the return air duct.

The utility model discloses a cooling system for a heat supply boiler and a heat supply boiler machine room, wherein high-temperature return air cooled by a novel mining machine can exchange heat with cooling liquid at the tail end of an air conditioner, and the temperature of the cooling liquid rises and then flows to a cooling tower to release heat, and then flows back to the tail end of the air conditioner to exchange heat with a high-temperature return air mechanical; the whole working process of the cooling system is natural cooling, the cooling of an ore machine in the heat supply boiler machine room is realized in a natural cooling mode, namely, the cooling of the ore machine in the heat supply boiler machine room is realized through the heat dissipation of the cooling tower, mechanical refrigeration is not needed, the cooling system has the advantage of reducing energy consumption, and the construction and running cost of the heat supply boiler machine room is greatly reduced.

Drawings

Fig. 1 is a schematic view of a heating boiler room according to an embodiment of the present invention.

In the figure: 200. a heat supply boiler room; 210. a chamber body; 220. a floor; 230. an ore machine; 310. an air return duct; 320. an air supply duct; 1. an air conditioner terminal; 2. a delivery line; 21. a main pipeline; 22. distributing pipelines; 23. a dispenser; 3. a cooling tower; 41. a water outlet pipeline; 42. a water return pipeline; 43. and (4) a water pump.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

A cooling system for a heating boiler, as shown in fig. 1, comprises an air-conditioning terminal 1, a conveying pipe 2 and a cooling tower 3;

the air conditioner tail end 1 is installed in a heat supply boiler machine room 200, the air conditioner tail end 1 is connected with a conveying pipeline 2 arranged in the heat supply boiler machine room 200, and cold air is conveyed into the heat supply boiler machine room 200 from the air conditioner tail end 1 through the conveying pipeline 2; the cold air enters the heat supply boiler machine room 200 to cool the ore machine 230, the cold air absorbs heat to become high-temperature air (namely high-temperature return air), the high-temperature return air after cooling the ore machine 230 becomes the cold air after heat exchange in the air conditioner terminal 1, and the part of the cold air is conveyed to the ore machine 230 in the heat supply boiler machine room 200 through the conveying pipeline 2.

The air conditioner terminal 1 is internally provided with cooling liquid, and cooling water can be selected as the cooling liquid. The return air cooled by the ore 230 in the heating boiler room 200 (i.e., the high temperature air cooled by the ore 230) is heat exchanged by the air conditioning terminal 1. The method specifically comprises the following steps: the return air enters the air conditioner terminal 1 to exchange heat with the cooling liquid in the surface air cooler of the air conditioner terminal 1, the temperature of the return air is reduced, the air after heat exchange is conveyed to the mining machine 230 in the heat supply boiler machine room 200 through the air conditioner terminal 1 again, the mining machine 230 is cooled, the air after cooling of the mining machine 230 flows back to the air conditioner terminal 1 again to exchange heat, and primary circulation is completed.

For the cooling of the air conditioner tail end 1 to the high-temperature return air, the cooling is mainly realized by a cooling tower 3; the cooling tower 3 is arranged outside the heat supply boiler room 200 and communicated with the air conditioner tail end 1; a water outlet pipeline 41 and a water return pipeline 42 are communicated between the cooling tower 3 and the air conditioner tail end 1; the temperature of the cooling liquid at the air conditioner terminal 1 after heat exchange with the return air rises, the high-temperature cooling liquid flows back to the cooling tower 3 from the return pipeline 42, the temperature is reduced after heat exchange with the outside air at the cooling tower 3 to become low-temperature cooling liquid, and the low-temperature cooling liquid flows back to the air conditioner terminal 1 through the water outlet pipeline 41 and exchanges heat with the high-temperature return air again to complete one cycle.

Therefore, for the cooling system for the heating boiler disclosed in this embodiment, the high-temperature return air can exchange heat with the cooling liquid at the end 1 of the air conditioner, the cooling liquid after rising in temperature flows to the cooling tower 3 to release heat, and then flows back to the end 1 of the air conditioner to continue exchanging heat with the high-temperature return air, so that the cooling system cools the ore machine 230 in the machine room 200 of the heating boiler in a natural cooling manner, that is, the heat dissipated when the ore machine 230 works is dissipated into the air through the cooling tower 3. The cooling system of this novel disclosure realizes the cooling of heat supply boiler computer lab 200 ore deposit 230 completely through the heat dissipation of cooling tower 3, need not mechanical refrigeration, has practiced thrift heat supply boiler computer lab 200's construction and running cost greatly.

Further, in order to increase the reflux rate of the cooling liquid refluxed from the reflux column 3, a water pump 43 may be installed on the water outlet line 41. Meanwhile, the water outlet pipeline 41 and the return pipeline 42 both have a heat insulation function, the water outlet pipeline 41 and the return pipeline 42 can be set as heat insulation pipes (namely, pipelines made of heat insulation materials), and a heat insulation layer can be coated outside the water outlet pipeline 41 and the return pipeline 42; the water return pipeline 42 has a heat preservation function, and can prevent the cooling liquid from exchanging heat with the outside air in the process of flowing back to the cooling tower 3, so that the water return pipeline has the functions of heat preservation and condensation prevention; similarly, the water outlet pipeline 41 has a heat preservation function, so that heat exchange between the cooling liquid and the outside air when flowing to the air conditioner terminal 1 can be prevented, and the water outlet pipeline also has heat preservation and anti-condensation functions.

Further, the conveying pipeline 2 can be further optimally designed to better meet the cooling requirements of the ore machine 230; as also shown in fig. 1, the conveying pipeline 2 is composed of a main pipeline 21, branch pipelines 22 and a distributor 23, the branch pipelines 22 are provided with a plurality of branch pipelines, the plurality of branch pipelines are communicated with the main pipeline 21 through the distributor 23, wherein the main pipeline 21 is communicated with the air-conditioning terminal 1, and the number of the branch pipelines 22 can be set according to the number of the mining machines 230 in the heating boiler room 200. The branch pipes 23 are connected with the main pipe 21 by the distributor 23, so that the air after heat exchange at the air conditioner terminal 1 can enter the main pipe 21, then the cold air is distributed to the plurality of branch pipes by the distributor 23, and then the cold air is conveyed to the heating boiler room 200 by the plurality of branch pipes. The provision of the distributor 23 makes it possible to better distribute the cold air in the main duct 21 to the plurality of branch ducts, thereby improving the conveying efficiency.

Therefore, for the cooling system for a heating boiler disclosed in the present embodiment, the cool air at the air conditioner terminal 1 enters the heating boiler room 200 through the main pipe 21, the distributor 23 and the plurality of branch pipes 22, and after exchanging heat with the ore machines 230 in the heating boiler room 200, the temperature rises to become the high temperature return air, and the high temperature return air may flow back to the air conditioner terminal 1 through the return air duct 310 and exchange heat with the low temperature coolant at the air conditioner terminal 1, and becomes the low temperature cool air and is delivered to the heating boiler room 200 again. The low-temperature cooling liquid and the high-temperature return air are subjected to heat exchange, the temperature of the low-temperature cooling liquid rises and becomes high-temperature cooling liquid, the high-temperature cooling liquid can flow to the cooling tower 3 through the water return pipeline 42, the high-temperature cooling liquid exchanges heat with the outside air at the cooling tower 3, and the low-temperature cooling liquid is pumped by the water pump 43 and flows back to the air conditioner terminal 1 again through the water outlet pipeline 41 to exchange heat with the high-temperature return air.

The cooling system of the utility model operates in a water side natural cooling mode, greatly reduces or even does not need mechanical refrigeration, reduces the energy consumption of the heat supply boiler room 200, saves the operation cost of the heat supply boiler room 200, and has simple structure, low cost, convenient maintenance and particularly obvious energy-saving effect.

The utility model also discloses a heat supply boiler machine room which comprises the cooling system for the heat supply boiler machine room.

Further, it also includes a chamber 210 and a plurality of ore-collecting machines 230 installed in the chamber 210, the ore-collecting machines 230 are provided with a plurality of groups, and the plurality of groups of ore-collecting machines are arranged side by side and at intervals.

As also shown in fig. 1, a floor 220 is installed in the chamber body 210, the floor 220 being laterally partitioned in the chamber body 210; therefore, a certain space is formed between the floor 220 and the floor of the chamber body 210, the space is the air supply channel 320, and the conveying pipeline 2 of the cooling system is installed in the air supply channel 320; to facilitate passage of the branch pipes 22 of the conveyor pipe 2, the floor 220 is provided with through holes that direct the cryogenic air to the mining machine disposed on the floor 220.

Meanwhile, a return air duct 310 is formed at the top of the chamber 210, the return air duct 310 is communicated with the air conditioner terminal 1, and high-temperature hot air is introduced into the air conditioner terminal 1 through the return air duct 310; a return air fan may be installed in the return air duct 310, and when the heating boiler room 200 is normally operated, the return air fan operates, so that the high-temperature return air that can be introduced flows back to the air conditioner terminal 1 at a rate. The return air fan can be provided with a plurality of fans, can adopt common fans, and can also adopt centrifugal wind wheels. Instead of providing the return air fan, the fan of the air conditioning terminal 1 may be used to draw the air in the return air duct 310.

Therefore, for the heat supply boiler room disclosed by the utility model, the cooling system is additionally arranged, the cooling system completely cools the ore machine 230 of the heat supply boiler room 200 by heat dissipation of the tower 3, mechanical refrigeration is not needed, the construction and operation cost of the heat supply boiler room 200 is greatly saved, and the heat supply boiler room has a good application prospect.

The above embodiments are not intended to limit the present invention, and the present invention is not limited to the above examples, and those skilled in the art may make variations, modifications, additions or substitutions within the technical scope of the present invention.

Claims (10)

1. A cooling system for a heating boiler, characterized by: the cooling system comprises an air conditioner tail end (1), a conveying pipeline (2) and a cooling tower (3);

the air conditioner tail end (1) is installed in a heat supply boiler machine room (200), the air conditioner tail end (1) is connected with a conveying pipeline (2), the conveying pipeline (2) is arranged in the heat supply boiler machine room (200), and the air conditioner tail end (1) conveys cold air into the heat supply boiler machine room (200) through the conveying pipeline (2); the cooling tower (3) is arranged outside the heat supply boiler room (200) and communicated with the air conditioner tail end (1).

2. A cooling system for a heating boiler according to claim 1, characterized in that: and a water outlet pipeline (41) and a water return pipeline (42) are communicated between the cooling tower (3) and the air conditioner tail end (1).

3. A cooling system for a heating boiler according to claim 1 or 2, characterized in that: the conveying pipeline (2) is composed of a main pipeline (21), branch pipelines (22) and a distributor (23), the branch pipelines (22) are provided with a plurality of branches, the branch pipelines are communicated with the main pipeline (21) through the distributor (23), and the main pipeline (21) is communicated with the air conditioner tail end (1).

4. A cooling system for a heating boiler according to claim 2, characterized in that: and a water pump (43) is arranged on the water outlet pipeline (41).

5. A cooling system for a heating boiler according to claim 2, characterized in that: the water outlet pipeline (41) and the water return pipeline (42) are heat insulation pipes or are externally coated with heat insulation layers.

6. A heating boiler machine room, its characterized in that: cooling system for a heating boiler room comprising any of claims 1-5.

7. A heating boiler machine room according to claim 6, characterized in that: the mining machine further comprises a chamber body (210) and a plurality of mining machines (230) installed in the chamber body (210), wherein the plurality of mining machines (230) are arranged in parallel at intervals.

8. A heating boiler room according to claim 7, characterized in that: a return air duct (310) is formed at the top of the chamber body (210), and the return air duct (310) is communicated with the tail end (1) of the air conditioner;

a floor (220) is arranged in the chamber body (210), and the floor (220) is transversely separated in the chamber body (210); the space formed between the floor (220) and the floor of the chamber body (210) is an air supply channel (320), the conveying pipeline (2) of the cooling system is installed in the air supply channel (320), and the mining machine (230) is arranged on the floor (220).

9. A heating boiler machine room according to claim 8, characterized in that: the floor (220) is provided with a through hole, and the through hole is used for the branch pipeline (22) of the conveying pipeline (2) to pass through.

10. A heating boiler machine room according to claim 8, characterized in that: and a return air fan is arranged in the return air duct (310).

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