RU178851U1 - DEVICE FOR INDIRECT EVAPORATION COOLING - Google Patents

Abstract

The utility model relates to the field of air conditioning and can be used to cool the air. The indirect evaporative cooling device comprises a housing with inlet and outlet channels for the main and auxiliary flows, a package of plates made of capillary-porous material, equipped on one side with sections of waterproof coating with a total area of 50-98% of the heat transfer area of the plates. The plates are installed with the formation of dry and wet channels. The upper part of the plates is installed in the tank with water. Provides increased cooling efficiency of the air flow. 3 s.p. f-ly, 3 ill.

Description

The utility model relates to the field of air conditioning and can be used to cool the air.

A device for indirect evaporative cooling (RF patent No. 2221969, F24F 3/14, 2004), comprising a housing with an inlet and outlet channels for the main and auxiliary air flows, is placed in the plate body of a capillary-porous material, one side of which is waterproof coating installed with the formation of dry and wet channels. A disadvantage of the known device is the low efficiency of air cooling.

Closest to the claimed and accepted as the closest analogue is an indirect evaporative cooling device (RF patent for the invention No. 2229436, F24F 3/14, publ. 10.12.2014), containing a housing with an inlet and outlet channels for the main and auxiliary air flows placed in the body of the plate of a capillary-porous material with protrusions, one side of which has a waterproof coating, installed with the formation of dry and wet channels, a device for wetting the plates. Moreover, on the sides of the plates with a waterproof coating in the end part, uncoated sections with an area of 7-10% of the heat transfer area of the plate are made. The disadvantage of this device is the insufficiently high cooling efficiency of the total air flow. The design of the device provides up to 85% of the possible thermodynamic limit of cooling (to the dew point).

The technical problem of the utility model is the creation of an indirect evaporative cooling device with increased efficiency of the total air flow.

This problem is solved due to the fact that the claimed indirect evaporative cooling device includes a housing with an inlet and outlet channels for the main and auxiliary flows, a package of plates of capillary-porous material separated by ribs, the system of which forms dry and wet channels, a device for wetting the capillary-porous material of the plates, a pallet, characterized in that the plates on one side are provided with sections of a waterproof coating distributed over the entire surface, total the total area of which is 50-98% of the heat transfer areas of the plates. The device for wetting the capillary-porous material of the plates can be made in the form of a reservoir with water, in the bottom of which the upper parts of the plates are installed with the possibility of water leakage.

The plate wetting device may be equipped with a pump for pumping water from the pan to the tank.

The surface of the plates with waterproof areas can be made in the form of a continuous coating with a system of holes made in it.

The choice of the value of the total area of waterproof areas, comprising 50-98% of the heat transfer areas of the plates, is due to the fact that with an increase in the area, the cooling efficiency of the main air flow decreases, and with a decrease in the area, the humidification of the main stream increases, which affects its consumer properties.

The technical result provided by the given set of features is to increase the cooling efficiency of the main air stream.

The technical result is ensured by the fact that part of the air of the main stream penetrates into the wet channels through areas free of waterproof coating. At the same time, passing through the entire thickness of the wetted capillary-porous material of the plates, the air is saturated with steam with greater intensity compared with the option of its passage only along these plates. With further movement of air through the moist channels towards the outlet pipe, additional evaporation of water from the surface of the plates occurs. The indicated process of water evaporation from the body of the plates leads to their intensive cooling and, therefore, to the cooling of the main air stream in contact with them. In the direction of the main stream along the dry channel, its temperature decreases while maintaining moisture content and from some point drops below the temperature of the wet thermometer, which increases the efficiency of the device. The presence of a pump in the humidification device allows virtually eliminating the loss of water used to moisten the plates.

The essence of the utility model is illustrated by drawings, which depict:

In FIG. 1 - shows a General view of the device of indirect evaporative cooling with local breakouts of the side of the housing and a local breakout along the plane of the channels of the auxiliary air flow.

In FIG. 2 shows a view A of an indirect evaporative cooling device with a transverse section of the plate stack along the axis of the outlet channel for the auxiliary air flow.

In FIG. 3 shows a section BB.

The indirect evaporative cooling device comprises a housing 1 with an input channel 2 and output channels: 3 for the main and 4 for auxiliary air flows. A package of alternating plates 5 and 6 of capillary-porous material is installed in the housing 1. One side of the plates 5 and 6 is provided with waterproof sections 7. The total area of such sections on each plate is 50-98% of the heat transfer area of the plate. In a particular case, areas with a waterproof coating can be a continuous coating with holes made in it. The total area of the holes is determined based on the permissible humidity of the main air stream. Each pair of plates on the side of the waterproof sections are separated by ribs 8, which form channels 9 for the output of the auxiliary (wet) stream 10. On the opposite side, each pair of plates is divided by ribs 11, which form the channels 12 for the output of the main (dry) stream 13. The upper part of the plates 14 is installed in a tank of water 15 with the possibility of wetting the capillary-porous material of the plates. In the lower part of the housing there is a drip tray 16 for collecting non-evaporated water. The device includes a fan 17 and a filter 18. The device can be equipped with a pump 19. A water tank is connected to a water supply channel, and a tray with a water drain channel (not shown in the figures).

The claimed device operates as follows.

Water from the reservoir 15 moistens the capillary-porous material of the plates and drains into the sump 16. From the sump, the water drains into the drain channel or can be pumped to the reservoir 15 by the pump 19, providing almost 100% utilization of the consumed water. The air flow supplied by the fan 17 through the filter 18 and the inlet 2 passes through the dry channels 12 and partially penetrates into the channels 9 through areas free of moisture-proof coating 7. In this case, the plates and the main and auxiliary air flows are cooled. The cooled air of the main stream through the pipe 3 enters the consumer, and the cooled auxiliary stream with high humidity through the pipe 4 is vented to the atmosphere or used in accordance with its properties, for example, to moisten the main stream or to cool objects that allow contact with moist air.

Thus, the use of a utility model improves the efficiency of cooling the air flow.

Claims (4)

1. Indirect evaporative cooling device, characterized in that it includes: a housing with an inlet and outlet channels for the main and auxiliary flows, a package of plates of capillary-porous material, separated from each other by fins, the system of which forms dry and wet channels, the device wetting of the capillary-porous material of the plates, a tray, characterized in that the plates are provided on one side with watertight coating sections distributed over the entire surface, the total area of which is m 50-98% heat exchanging area of the plates. 2. The indirect evaporative cooling device according to claim 1, characterized in that the device for wetting the capillary-porous material of the plates is made in the form of a reservoir with water, in the bottom of which the upper parts of the plates are installed with the possibility of wetting them. 3. The indirect evaporative cooling device according to claim 2, characterized in that the plate wetting device is equipped with a pump for pumping water from the pan to the tank. 4. The indirect evaporative cooling device according to claim 1, characterized in that the surface of the plates with waterproof sections is made in the form of a continuous coating with a system of holes made in it.

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