CN215490075U - Solution dehumidification fresh air conditioner using carbon dioxide refrigerant - Google Patents

Abstract

The utility model discloses a solution dehumidifying fresh air conditioner using carbon dioxide refrigerant, which is realized by that the solution is conveyed to the inner side of a titanium pipe D in an integrated regenerator through a pipeline to exchange with a high-temperature heat source from a carbon dioxide compressor in the titanium pipe C by an integrated dehumidifier, then the solution is cooled by a water liquid exchanger and is sent into the integrated dehumidifier to realize double-source refrigeration, the fresh air is cooled again by a surface cooler after being dehumidified and sterilized and is sent into a room, the solution dehumidifying fresh air conditioner using the carbon dioxide refrigerant removes the traditional method of using a heat pump to refrigerate and an external solution exchanger, thereby improving the refrigeration efficiency by more than 30 percent compared with the heat pump, adopting the integrated dehumidifier and the integrated regenerator can effectively reduce the loss of cold and heat source exchange and greatly reduce the system cost and the power consumption energy, due to the improvement of the refrigeration efficiency, the overall energy is saved by 20-30%, and the running cost of the whole system can be greatly reduced.

Description

Solution dehumidification fresh air conditioner using carbon dioxide refrigerant

Technical Field

The utility model belongs to the technical field of energy, and particularly relates to a solution dehumidification fresh air conditioner using a carbon dioxide refrigerant.

Background

The currently used solution air conditioning system adopts a heat pump and an external exchanger to dehumidify and regenerate solution, and the system has the main defects that the heat pump can not provide double-source refrigeration, the external exchanger is easy to corrode and leak, the energy consumption of the system is increased, and the problems that the system carries the solution, the maintenance cost is increased and the like are caused.

Disclosure of Invention

Therefore, the utility model aims to overcome the defects in the solution air conditioning system and provide a solution dehumidification fresh air conditioner using a carbon dioxide refrigerant.

The object of the utility model is achieved in that it comprises: the device comprises a carbon dioxide compressor, a titanium pipe A, a titanium pipe B, a liquid transfer hole A, a non-woven cloth A, a shunt A, an integrated dehumidifier, a dehumidifying pump, a dehumidifying liquid box, a titanium pipe C, a titanium pipe D, a liquid transfer hole B, a non-woven cloth B, a shunt B, an integrated regenerator, a regenerating pump, a regenerating liquid box, a surface air cooler, a water-liquid exchanger, a refrigerating device, a sprayer, a cooling water pump, a water pump and a water tank;

preferably, the high-pressure output end of the carbon dioxide compressor is connected with the inlet of the titanium pipe A through a pipeline.

Preferably, the high-pressure input end of the carbon dioxide compressor is connected with the outlet of the titanium pipe A through a pipeline.

Preferably, the low-pressure output end of the carbon dioxide compressor is connected with the inlet of the titanium pipe C through a pipeline.

Preferably, the low-pressure input end of the carbon dioxide compressor is connected with the outlet of the titanium pipe C through a pipeline.

Preferably, the multiple rows of titanium tubes A are respectively arranged among the multiple rows of titanium tubes B.

Preferably, each titanium tube B is provided with a plurality of liquid transmission holes A.

Preferably, the non-woven fabric A is respectively surrounded on the outer side of each titanium tube B.

Preferably, the flow divider A is arranged above the titanium pipe A and the titanium pipe B.

Preferably, the titanium pipe A and the titanium pipe B are arranged in the middle of the integrated dehumidifier.

Preferably, the dehumidifying liquid tank is integrated at the bottom of the integrated dehumidifier.

Preferably, the bottom of the dehumidification liquid tank is provided with a pipeline and the dehumidification pump is connected with the flow divider B through the pipeline.

Preferably, the multiple rows of titanium tubes C are respectively arranged among the multiple rows of titanium tubes D.

Preferably, each titanium tube D is provided with a plurality of liquid transfer holes B.

Preferably, the non-woven fabric B is respectively wrapped on the outer side of each titanium tube D.

Preferably, the flow divider B is arranged above the titanium pipe C and the titanium pipe D.

Preferably, the titanium pipe C and the titanium pipe D are arranged in the middle of the integrated regenerator.

Preferably, the regeneration liquid tank is integrated in the bottom of the integrated regenerator.

Preferably, the bottom of the regeneration liquid tank is provided with a pipeline which passes through the regeneration pump and is connected with the flow divider A through a pipeline and a water liquid exchanger through a pipeline.

Preferably, the integrated regenerator is disposed above the integrated dehumidifier.

Preferably, the surface cooler is arranged at the front end of an air outlet of the integrated dehumidifier.

Preferably, the bottom of the water tank is provided with a pipeline which is connected with the upper part of the water tank through a cooling water pump and a surface cooler through pipelines.

Preferably, the sprayer is arranged above the refrigerating device.

Preferably, the bottom of the refrigerating device is connected with the water tank through a pipeline.

Preferably, the bottom of the water tank is provided with a pipeline which is connected with a sprayer on the refrigerating device through a water pump and a water liquid exchanger through pipelines.

Compared with the prior art, the utility model has the beneficial effects that:

(1) according to the utility model, the high-pressure output end of the carbon dioxide compressor is connected with the inlet of the titanium pipe A through a pipeline, the pipeline at the bottom of the regeneration liquid tank is connected with the current divider A through the regeneration pump and the water liquid exchanger through pipelines, and the characteristic of waste heat of the carbon dioxide compressor and the integrated regenerator is adopted, so that double-source refrigeration is realized, the refrigeration efficiency is improved, and the system cost and the electric energy consumption are greatly reduced due to the improvement of the refrigeration efficiency.

(2) According to the utility model, the titanium pipe A and the titanium pipe B are arranged in the middle of the integrated dehumidifier, and the titanium pipe C and the titanium pipe D are arranged in the middle of the integrated regenerator, so that the exchange efficiency of the system can be effectively improved, and the problems of corrosion of solution to the exchanger and solution leakage are solved.

(3) The utility model is connected with the sprayer at the upper part of the refrigerating device through the pipeline at the bottom of the water tank, the water pump and the water liquid exchanger, the pipeline is connected with the sprayer at the upper part of the refrigerating device through the pipeline, each titanium pipe B is provided with a plurality of liquid transmission holes A, the non-prevention cloth A is respectively surrounded at the outer side of each titanium pipe B, the waste heat of the regenerated solution is fully utilized under the action of the surface cooler and the refrigerating device, the temperature of the solution is reduced, the refrigeration obtained by the waste heat under the action of the refrigerating device is effectively utilized, the energy saving rate of the system is greatly improved, the structure is particularly compact, simple and reasonable, the solution can be transmitted to the non-prevention cloth A through the liquid transmission holes A on the titanium pipes B, so that bacteria and PM2.5 in the air are removed, and the system is energy-saving and environment-friendly.

Drawings

FIG. 1 is a schematic diagram of the working principle of the present invention;

in the figure: 1-carbon dioxide compressor, 2-titanium pipe A, 3-titanium pipe B, 4-liquid transmission hole A, 5-non-waterproof cloth A, 6-shunt A, 7-integrated dehumidifier, 8-dehumidification pump, 9-dehumidification liquid tank, 10-titanium pipe C, 11-titanium pipe D, 12-liquid transmission hole B, 13-non-waterproof cloth B, 14-shunt B, 15-integrated regenerator, 16-regeneration pump, 17-regeneration liquid tank, 18-surface cooler, 19-water exchanger, 20-refrigerating device, 21-sprayer, 22-cooling water pump, 23-water pump and 24-water tank.

Detailed Description

The utility model is further described with reference to the accompanying drawings and the detailed description:

as shown in fig. 1, the solution dehumidification fresh air conditioner using carbon dioxide refrigerant of the present invention comprises: the system comprises a carbon dioxide compressor 1, a titanium pipe A2, a titanium pipe B3, a liquid transfer hole A4, a non-waterproof cloth A5, a flow divider A6, an integrated dehumidifier 7, a dehumidifying pump 8, a dehumidifying liquid tank 9, a titanium pipe C10, a titanium pipe D11, a liquid transfer hole B12, a non-waterproof cloth B13, a flow divider B14, an integrated regenerator 15, a regenerating pump 16, a regenerating liquid tank 17, a surface air cooler 18, a water liquid exchanger 19, a refrigerating device 20, a sprayer 21, a cooling water pump 22, a water pump 23 and a water tank 24;

preferably, the high-pressure output end of the carbon dioxide compressor 1 is connected with the inlet of the titanium pipe A2 through a pipeline.

Preferably, the high-pressure input end of the carbon dioxide compressor 1 is connected with the outlet of the titanium pipe A2 through a pipeline.

Preferably, the low-pressure output end of the carbon dioxide compressor 1 is connected with the inlet of a titanium pipe C10 through a pipeline.

Preferably, the low-pressure input end of the carbon dioxide compressor 1 is connected with the outlet of the titanium pipe C10 through a pipeline.

Preferably, the multiple rows of titanium tubes A2 are respectively arranged in the middle of the multiple rows of titanium tubes B3.

Preferably, each titanium tube B3 is provided with a plurality of liquid transmission holes A4.

Preferably, the non-woven fabric A5 is respectively wrapped on the outer side of each titanium tube B3.

Preferably, the flow splitter a6 is disposed above titanium tube a2 and titanium tube B3.

Preferably, the titanium pipe a2 and the titanium pipe B3 are arranged in the middle of the integrated dehumidifier 7.

Preferably, the dehumidification liquid tank 9 is integrated in the bottom of the integrated dehumidifier 7.

Preferably, the dehumidification liquid tank 9 has a pipeline at the bottom and the dehumidification pump 8 is connected with the flow divider B14 through a pipeline.

Preferably, the multiple rows of titanium tubes C10 are respectively arranged in the middle of the multiple rows of titanium tubes D11.

Preferably, each titanium tube D11 is provided with a plurality of liquid transmission holes B12.

Preferably, the non-woven fabric B13 is respectively wrapped on the outer side of each titanium tube D11.

Preferably, the flow splitter B14 is disposed above titanium tube C10 and titanium tube D11.

Preferably, the titanium pipe C10 and the titanium pipe D11 are disposed in the middle of the integrated regenerator 15.

Preferably, the regeneration liquid tank 17 is integrated in the bottom of the integrated regenerator 15.

Preferably, the bottom of the regeneration liquid tank 17 is connected with a flow divider A6 through a pipeline by a regeneration pump 16 and a liquid water exchanger 19.

Preferably, the integrated regenerator 15 is arranged above the integrated dehumidifier 7.

Preferably, the surface cooler 18 is disposed at a front end of an air outlet of the integrated dehumidifier 7.

Preferably, the bottom of the water tank 24 is connected with the upper part of the water tank 24 through a pipeline by the cooling water pump 22 and a pipeline by the surface cooler 18.

Preferably, the sprayer 21 is disposed above the refrigerating apparatus 20.

Preferably, the bottom of the refrigeration device 20 is connected to the water tank 24 through a pipeline.

Preferably, the bottom of the water tank 24 is provided with a pipeline which is connected with the sprayer 21 on the refrigerating device 20 through a water pump 23 and a water liquid exchanger 19 through pipelines.

The working principle of the utility model is as follows: when the device is used, after the carbon dioxide compressor 1 is started, the high-pressure output end transmits a heat source into the titanium pipe C10 through a pipeline to exchange heat with a solution which is shunted by the titanium pipe D11 and flows back to the high-pressure input end into the carbon dioxide compressor 1 through the pipeline, the low-pressure output end transmits a cold source into the titanium pipe A2 through the pipeline to cool the solution which is shunted by the shunt A6 and flows back to the low-pressure input end into the carbon dioxide compressor 1 through the pipeline, the solution in the dehumidification liquid tank 9 is transmitted into the shunt B14 through the pipeline under the action of the dehumidification pump 8, the solution is distributed in the titanium pipe D11 under the action of the shunt B14 and is heated and concentrated by the heat source in the titanium pipe C10, and the solution is distributed on the non-cloth B13 through the liquid transmission hole B12 on the titanium pipe D11 to exchange with indoor return air and then the water in the solution is discharged to the outdoor, the concentrated and heated solution flows into the bottom of a regeneration liquid tank 17, is conveyed into a water liquid exchanger 19 through a pipeline to exchange with water under the action of a regeneration pump 16, is cooled and flows into a shunt A6 through the pipeline, is distributed in a titanium pipe B3 under the action of the shunt A6 and is cooled by a cold source in the titanium pipe A2, is distributed on a non-waterproof cloth A5 through a liquid transmission hole A4 on the titanium pipe B3 to exchange with the fresh air outside and is cooled, the dehumidified and sterilized air is cooled and conveyed into a room through a surface cooler 18 for the second time, the dehumidified and sterilized solution flows into the bottom of a dehumidification liquid tank 9 after being diluted, the water is conveyed into the water liquid exchanger 19 through the pipeline to exchange with the solution under the action of a water pump 23 to be heated, the heated water flows into a sprayer 21 through the pipeline, and is sprayed into a refrigerating device 20 to exchange with the fresh air by the sprayer 21 to generate heat and mass, the exchanged water is vaporized and then changed into cooling water, the cooling water is conveyed to the surface air cooler 18 through a pipeline under the action of the cooling water pump 22 to cool the supplied air, the water flows back to the water tank through the pipeline after being heated, and the whole operation process is automatic.

Claims (1)

1. The utility model provides an use solution dehumidification new trend air conditioner of carbon dioxide refrigerant which characterized in that: comprises a carbon dioxide compressor (1), a titanium pipe A (2), a titanium pipe B (3), a liquid transmission hole A (4), a non-waterproof cloth A (5), a shunt A (6), an integrated dehumidifier (7), a dehumidifying pump (8), a dehumidifying liquid box (9), a titanium pipe C (10), a titanium pipe D (11), a liquid transmission hole B (12), a non-waterproof cloth B (13), a shunt B (14), an integrated regenerator (15), a regenerating pump (16), a regenerating liquid box (17), a surface cooler (18), a water liquid exchanger (19), a refrigerating device (20), a sprayer (21), a cooling water pump (22), a water pump (23) and a water tank (24), wherein the high-pressure output end of the carbon dioxide compressor (1) is connected with the inlet of the titanium pipe A (2) through a pipeline, the low-pressure output end of the carbon dioxide compressor (1) is connected with the inlet of the titanium pipe C (10) through a pipeline, a plurality of rows of titanium pipes A (2) are respectively arranged among a plurality of rows of titanium pipes B (3), the device is characterized in that a plurality of liquid transmission holes A (4) are formed in each titanium pipe B (3), a non-prevention cloth A (5) is respectively surrounded on the outer side of each titanium pipe B (3), the titanium pipes A (2) and the titanium pipes B (3) are arranged in the middle of an integrated dehumidifier (7), a plurality of rows of titanium pipes C (10) are respectively arranged in the middle of a plurality of rows of titanium pipes D (11), a plurality of liquid transmission holes B (12) are formed in each titanium pipe D (11), a non-prevention cloth B (13) is respectively surrounded on the outer side of each titanium pipe D (11), the titanium pipes C (10) and the titanium pipes D (11) are arranged in the middle of an integrated regenerator (15), a pipeline is arranged at the bottom of a regeneration liquid tank (17) and connected with a flow divider A (6) through a regeneration pump (16) and a water liquid exchanger (19), a pipeline is arranged at the bottom of the water tank (24) and connected with the upper part of the water tank (24) through a cooling water pump (22) and a surface cooler (18) through pipelines, the bottom of the water tank (24) is provided with a pipeline which passes through a water pump (23) and passes through a pipeline and a water liquid exchanger (19) and a sprayer (21) on the refrigerating device (20) through a pipeline.

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