RU2458288C1 - Air conditioning device - Google Patents

Abstract

FIELD: ventilation.

SUBSTANCE: device includes main and auxiliary flow supply fans, control valves, housing with air flow inlet and outlet connection pipes, water tank with water supply system to capillary porous material, heat exchange section with the main and auxiliary adjacent channels, and one inlet and two outlet air distributing chambers, which are arranged in the housing; besides, each of the above air distributing chambers is divided into two cavities with partitions and equipped with additional control valves. Device provides three ventilation modes: positive-pressure, pressure in the room and air circulation. The proposed device refers to energy-efficient air conditioning system for all climatic zones of RF and is used for cooling of ventilated air during warm season of the year, air heating during cold period of the year, dehydration, humidification with wet air cleaning and heat utilisation of the removed air in positive-pressure ventilation mode of the room. In plenum ventilation mode the device serves for displacement of exhaust warm air with cooled outside air from the room.

EFFECT: circulation mode allows reducing the supply of outside air under non-favourable conditions as much as possible, thus keeping the possibility of independent control of temperature and humidity parameters of air in the room.

5 cl, 6 dwg

Description

The invention relates to the field of ventilation and air conditioning by indirect evaporative cooling and heat and mass transfer.

The method of indirect evaporative cooling is that the main air stream is cooled by passing it through a channel with moisture-proof walls in heat exchange relation with an adjacent channel through which an auxiliary air stream is supplied. The cooling effect is achieved due to the evaporation of moisture, a corresponding decrease in temperature and heat transfer from the warmer main stream through the moisture-proof wall to the wet wall of the adjacent channel. In this case, the moisture content of the main stream remains constant.

The heat and mass transfer method in the recovery process consists in equalizing the potential difference of temperature and moisture content during the interaction of immiscible flows (main and auxiliary) through a heat-conducting wall separating these flows.

A device for indirect-evaporative cooling of air by the method of indirect-evaporative cooling and heat and mass transfer (RF patent No. 2177115, CL F24F 3/14 from 16/12/1999). The device contains fans for supplying the main and auxiliary flows, a housing with inlet and outlet flow nozzles, a water tank located in the housing, heat exchange sections, an air distribution chamber located at the outlet of the dry channels of the heat exchange sections of the auxiliary stream and gas-dynamically connected to the inputs of the wet channels of the milestones of the sections and air-conditioned room. The known device cools the air and operates in heat recovery mode in the winter.

A disadvantage of the known device according to patent No. 2177115 is the presence of two types of sections, one of which serves to pre-cool the auxiliary stream and should not work in the recovery mode in winter. This significantly increases the air flow resistance and reduces the efficiency of this device as a heat recovery unit in winter, since maximum efficiency in the recovery of heat (or cold) is achieved when the flow of supplied air in the room and that removed from it are equal. A disadvantage of the known device according to patent No. 2177115 is also the water supply by lifting it from the bath with a capillary-porous material, which limits the height of the capillary-porous material, leads to the accumulation of salts in the upper part of the capillary-porous material and reduces the life of the device.

Closest to the claimed invention is an air conditioning device by indirect evaporative cooling and heat and mass transfer (RF patent No. 2216694, CL F24F 3/14 from 06/28/2002). The device contains: fans for supplying the main and auxiliary flows, control valves, a housing with air inlet and outlet nozzles, a water tank in the housing with a water supply system for capillary-porous material, a heat exchange section with main and auxiliary adjacent channels, an air distribution chamber wherein the adjacent channels of the heat exchange section of the main stream are made of moisture-proof material, and the adjacent channels of the auxiliary stream are made of capillary-porous material. The device is equipped with an additional valve, and the air distribution chamber is divided into two cavities by a partition in which an additional valve is installed, while one cavity of the air distribution chamber is connected to the outlet pipe of the main stream, and the other cavity is connected on the other side to adjacent channels of the auxiliary stream, the water supply device equipped with a nozzle mounted on the input side of the auxiliary stream in the heat exchange section.

A disadvantage of the known device according to patent No. 2216694 is the inability to work in the internal air circulation in the rooms and the inability to control the temperature and moisture content of the air supplied to the room. In winter, with a low moisture content of the outdoor air supplied to the room, a significant decrease in the relative humidity in the room is possible and, therefore, a significant deviation from the comfortable environment. In summer, the absence of an internal circulation mode does not allow the use of an air conditioning device with a high gas contamination of the outdoor air.

The proposed technical solution is aimed at improving the efficiency of the air conditioning device by expanding the functions and the range of their regulation, including: deeper cooling and dehumidification of air in the summer, air heating and humidification in the winter, air conditioning of the room when the outside air is gas, as well as regulation of the parameters of the ventilated air by selecting the optimal combination of ventilation modes - supply, supply and exhaust or internal her circulation.

This result is achieved by the following design solutions:

1) the device is equipped with a second air distribution chamber, divided into two cavities by a partition, in which a second additional valve is installed, while one cavity of the air distribution chamber is connected to the main flow inlet pipe, and the other cavity is connected to the auxiliary flow outlet pipe. This will allow the device to work in the internal circulation mode and in winter to regulate the temperature and humidity of the air supplied to the room, and in summer to autonomously cool the air in the room when the outside air is gas;

2) the second additional valve in the partition of the second air distribution chamber is made in the form of a regulator, which allows to supply part of the moist air from the wet channels of the auxiliary stream to the main stream (if necessary);

3) the device is equipped with an air heater installed in the inlet pipe of the auxiliary stream, which allows in winter to maintain a comfortable temperature level at the outlet of the dry channels and to prevent freezing of the channels of the heat exchange section;

4) the device is equipped with a vapor compression cooling system with an evaporative heat exchanger and a condenser with a compressor, while the evaporative heat exchanger is installed in the outlet pipe of the main stream, and the condenser with the compressor is installed in the outlet pipe of the auxiliary stream, which provides additional cooling and drainage of the main stream in summer with an increase moisture content of atmospheric air (above 10 g / kg), which reduces the efficiency of evaporative cooling, and the location of the condensation Sator with a compressor in the outlet pipe of the auxiliary stream increases its efficiency at a high outdoor temperature;

5) an additional condensate collection tank is installed in the evaporative heat exchanger, connected to the housing capacity, which allows the condensate formed in the evaporative heat exchanger to be disposed of by draining it into the water tank in the air conditioning device body, which reduces the water consumption during cooling of the main stream.

The figure 1 shows a General view of the air conditioning device with a longitudinal section through the dry channels of the heat exchange section.

The figure 2 and figure 3 presents the cross-section of a set of plates of dry and wet channels of the heat exchange section in width and height.

In figure 4, figure 5 and figure 6 shows the operation of the device in the modes, respectively, supply and exhaust ventilation, ventilation and circulation of air in the room.

An air conditioning device using indirect evaporative cooling and heat and mass transfer comprises: a fan 1 for supplying the main stream 2, a fan 3 for removing the auxiliary stream 4, a housing 5 with a water tank 6, control valves 7 and 8, respectively, of the main and auxiliary flows, nozzles of the input 9 and output 10 of the main stream, the nozzles of the inlet 11 and the output 12 of the auxiliary stream, the heat exchange section 13 with dry channels 14 and adjacent wet channels 15 bounded at the inlet by the intake manifold 16 and the exhaust manifold m 17 of the auxiliary flow, the outlet air distribution chamber 18, divided by a partition 19 into two cavities, and an additional control valve 20 installed in this partition, moreover, one cavity of the outlet air distribution chamber 18 is connected to the outlet pipe of the main stream 10, and the other cavity is connected to the inlet auxiliary flow collector 16, dry channels 14 of the heat exchange section 13 are formed by walls 21 of a moisture-proof material, and wet channels 15 are formed by walls of a capillary-porous material Ala 22, the inlet manifold 16 is connected to the inlet pipe of the auxiliary stream 11, is limited by the top cover 23 of the tank 6 and the plugs 24, and the exhaust manifold 17 is connected to the outlet pipe of the auxiliary stream 12, the inlet air distribution chamber 25 and limited by the plugs 26, the inlet air distribution chamber 25 is divided into two cavities by a partition 27 with an additional valve-regulator 28, while one cavity of the inlet air distribution chamber is connected to the inlet of the main flow 9, and the other cavity dinene with an auxiliary flow output manifold 17, an air heater 29 installed in the inlet pipe of the auxiliary stream 11, an evaporative heat exchanger of the vapor compression system 30 with a condensate collection tray 32 installed in the output pipe of the main stream 10, a condenser with compressor 31 installed in the auxiliary pipe outlet flow 12, the pan 32 of the evaporative heat exchanger 30 is connected to drain the condensate into a container 6, a water supply pump 33 is installed in this container, supplying water through the pipe 34 at an irrigation nozzle 35 directed to the inlet of the auxiliary stream 4 into the wet channels 15, a water supply valve 36 to the tank 6 from the water supply system and a sludge drain valve 37 from the tank 6 to the sewer, a drop catcher 38 is installed in the output manifold 17 at the outlet of the auxiliary stream 4 from the wet channels 15 of the heat exchange section 13.

The proposed device can operate in 3 main modes: supply and exhaust ventilation, supply ventilation and air circulation in the premises. These modes are set depending on the external conditions and the conditioning task in the following ways.

BUT). Supply and exhaust ventilation. Both fans are on, valves 7 and 8 are open, and valves 20 and 28 are closed. The flow pattern is shown in FIG. 4. The fan 1 supplies the main air stream 2 through the inlet pipe 9 to the inlet air distribution chamber 25, from which the main stream is sent to the dry channels 14 of the heat exchange section 13, where it is cooled (during the warm season) or heated (during the cold season) due to heat exchange with countercurrent adjacent channels 15 and through the outlet air distribution chamber 18 and the outlet pipe 10 is fed into an air-conditioned room. The removal of the auxiliary stream 4 to the atmosphere is provided by the fan 3 through the pipe 12.

In summer, indirect evaporative cooling of the air is ensured by the supply of water with a pump 33 from the tank 6 through the nozzle 34 to the nozzle 35 to the entrance to the moist channels 15 of the heat exchange section 13. At high outdoor air humidity or a high level of heat generation in the room, a vapor compression cooling system with a condenser 31 and an evaporative heat exchanger is activated 30, which further cool and dry the conditioned main stream.

In winter, the pump 33 is turned off, water is not supplied to the tank 6, and the heater 29 in the inlet pipe 11 of the auxiliary stream 4 can be turned on to increase the temperature of the auxiliary stream 4 and heated in the heat exchange section 13 of the main stream 2. At the same time, a comfortable level of air temperature is supplied to the room , and excludes the possibility of freezing of channels in the installation. The removal of the auxiliary stream 4 is also provided by the fan 3 through the pipe 12.

The main stream 2 is humidified (both during cooling and during heating) by opening the control valve 28 and bypassing part of the auxiliary stream from the exhaust manifold 17 into the air inlet chamber 25. When the auxiliary stream is moistened, it is additionally cleaned (along with standard filters in ventilation system).

B) Forced ventilation. Fans 1 and 3 are on, valves 7 and 20 are open, and valves 8 and 28 are closed (there is no air supply to the installation). The flow pattern is shown in FIG. 5. The flow sucked by the fan 1 through the pipe 9 into the inlet air distribution chamber 25 is common and after cooling in the dry channels 14 of the heat exchange section 13 is divided in the air distribution chamber 18 into main 2 and auxiliary 4 flows. Next, the main stream 2 through the outlet pipe 10 by the fan 1 is fed into an air-conditioned room. The removal of auxiliary stream 4 into the atmosphere after passing through wet channels occurs in the same way as with supply and exhaust ventilation.

AT). Indoor air circulation. Fan 1 is on, valves 8 and 28 are open, fan 3 is turned off, valves 7 and 20 are closed. The flow pattern is shown in FIG. 6. The circulation stream is sucked up by the fan 1 from the room through the pipe 11 to the inlet manifold 16, then it is moistened in the wet channels 15 and through the outlet manifold 17 it enters the inlet air distribution chamber 25, from which, turning into the main stream 2, passes through the dry channels 14 into the outlet water distribution the chamber 18 and is fed by the fan 1 through the pipe 10 into the premises. If the device is in the initial state at a negative temperature, then before turning on the pump 33 and supplying water to the input manifold 16, it is heated in the circulation mode with the heater 29 turned on.

The proposed device relates to an energy-efficient air conditioning system for all climatic zones of the Russian Federation and is used for cooling ventilated air in the warm season, heating air in the cold season, drainage, humidification with wet air purification and heat recovery of exhaust air in the supply and exhaust ventilation mode premises.

In the ventilation mode, the device serves to displace the exhausted warm air from the room with chilled outside air. For dry climate conditions with sufficient cooling capacity of the indirect evaporative air cooling system, the vapor compression cooling system is disabled. At high humidity, the vapor compression system is additionally turned on, which cools and drains the air, while condensate drained from the evaporative heat exchanger tray is used as the main source of water for the indirect evaporation system.

The circulation mode is used for humidification and additional wet air purification, and also, if necessary, allows to minimize the supply of outdoor air under adverse external conditions (severe frost or abnormal heat and smoke), while maintaining the ability to control the temperature and humidity parameters of the air in the room.

Claims (5)

1. An air conditioning device comprising primary and secondary flow fans, control valves, a housing with air inlet and outlet nozzles, a water tank in the housing with a water supply system for capillary-porous material, a heat exchange section with main and auxiliary adjacent channels, the air distribution chamber, divided into two cavities by a partition with a valve, while one cavity of the air distribution chamber is connected to the outlet pipe of the main stream, and the carbon cavity is connected on the other hand with adjacent channels of the auxiliary flow, the water supply device being provided with a nozzle mounted on the inlet side of the auxiliary flow in the heat exchange section, characterized in that the device is equipped with a second air distribution chamber divided into two cavities by a partition in which the second additional valve, while one cavity of the air distribution chamber is connected to the main flow pipe, and the other cavity is connected to the auxiliary output pipe gatelnogo stream. 2. The air conditioning device according to claim 1, characterized in that the second additional valve is made in the form of a flow regulator redistributing the flows in the second air distribution chamber and the auxiliary flow outlet manifold. 3. The air conditioning device according to claim 1, characterized in that it is equipped with an air heater installed in the inlet pipe of the auxiliary stream. 4. The air conditioning device according to claim 1, characterized in that it is equipped with a vapor compression cooling system with an evaporative heat exchanger and a condenser with a compressor, while the evaporative heat exchanger is installed in the outlet pipe of the main stream, and the condenser with the compressor is installed in the outlet pipe of the auxiliary stream. 5. The air conditioning device according to claim 4, characterized in that the evaporative heat exchanger has an additional condensate collecting tank connected to the housing capacity.

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