RU2221968C2 - Indirectly evaporative air cooling plant - Google Patents

Abstract

FIELD: air ventilation and conditioning equipment, particularly for metallurgical workshop crane cabins. SUBSTANCE: device has connected in series heat exchangers having means for fluid organizing. Heat exchangers are composed of plate blocks defining wet and dry channels. Device has inlet pipe for total air flow communicated with dry and wet channel inlet ends and connected with the first heat exchanger; the first outlet pipe for main air flow communicated with dry channel outlet ends and joined to the second heat exchanger, the second outlet pipe for additional air flow communicated with wet channel outlet ends and connected with the first and the second heat exchangers; air supplying fan for total air flow feeding. The second outlet pipe has air-exhauster. Wet channels of the first and the second heat exchangers are closed by caps located on the side of connected heat exchanger ends. The second heat exchanger wet channel inlet ends are connected with dry channel outlet ends. The second heat exchanger is arranged above the first heat exchanger. The second heat exchanger fluid organizing means is located into average in height section of plate block. The first and the second wet channel outlet ends face each other and located coaxially to each other. EFFECT: decreased dimensions without outlet conditioning air quality deterioration. 3 cl, 4 dwg

Description

 The invention relates to the field of ventilation and air conditioning of various objects, for example, crane cabins of metallurgical shops.

 A known installation of indirect-evaporative cooling of air, comprising a means for accommodating liquid heat exchanger with a package of plates forming dry and wet channels, connected with the inputs of the dry channels inlet pipe for the total air flow, in communication with the outputs of the dry channels, the output pipe for the main air stream and communicated with the outputs of the wet channels, an outlet pipe for the auxiliary air flow, while the wet channels of the heat exchanger are muffled from the inlet side for the total flow ozduha and inputs moist heat exchanger channels communicated with the outputs of its dry channels (see. AS USSR 979796, cl. F 24 F 3/14). In this installation, a fluid placement means is located at the bottom of the heat exchanger.

 This installation does not provide a sufficiently low temperature for air conditioning.

 Another installation for indirect evaporative air cooling is known, comprising two heat exchangers with plate packs forming dry and wet channels, connected to the first heat exchanger and communicated with the inlets of its dry and wet channels in series with each other, successively communicated at their ends with each other; for the total air flow, connected to the second heat exchanger and connected with the exits of its dry channels, the outlet pipe for the main air flow, a common heat exchanger for these in and connected to the outputs of their wet channels, an outlet pipe for an auxiliary air stream with an exhaust fan and a fan for supplying a common air stream, while the wet channels of the first and second heat exchangers are muffled from the ends of these heat exchangers communicated with each other, and the inputs of the wet channels of the second heat exchanger communicated with the exits of its dry channels (see AS USSR 1758347, class F 24 F 3/14). In this installation, liquid holding means are located in the lower parts of the heat exchanger.

 This installation compared to the above allows you to lower the temperature of the conditioned air, as it has two heat exchangers.

 The disadvantage of this installation is that it has a sufficiently large dimensions in length.

 The objective of the present invention is to develop the design of the installation of indirect evaporative air cooling, which allows to reduce its dimensions along the length without compromising the parameters of the conditioned air coming out of it.

 The problem is solved in that in the installation of indirect-evaporative air cooling, containing successively communicated at its ends with each other, having means for placing liquid two heat exchangers with packages of plates forming dry and wet channels, connected to the first heat exchanger and communicated with its dry inlets and wet channels, an inlet pipe for a common air flow, connected to a second heat exchanger and communicated with outlets of its dry channels, an outlet pipe for a main air stream, common for these heat exchangers and the outlet pipe connected with the outputs of their wet channels for an auxiliary air stream with an exhaust fan and a fan for supplying a common air stream, while the wet channels of the first and second heat exchangers are muffled from the ends of these heat exchangers connected to each other, and the inputs of the wet channels the second heat exchanger communicated with the outputs of its dry channels, the second heat exchanger is located above the first heat exchanger, while the means for accommodating the liquid of the second heat exchanger It is located in the middle-high part of the package of its plates, and the outputs of the wet channels of these heat exchangers are facing each other and are aligned with each other.

 In addition, a shutter can be installed in the outlet for the auxiliary air flow to control the flow of air at the exits from the moist channels of the first and second heat exchangers.

 In addition, the means for accommodating the liquid of the first heat exchanger can be located in the mid-height part of the package of its plates.

 The difference between the proposed installation of indirect evaporative air cooling from the above known, closest to it, is that in it the second heat exchanger is located above the first heat exchanger, while the means for placing the liquid of the second heat exchanger is located in the middle part of the package of its plates, and the outputs of the wet channels of these heat exchangers are facing each other and are aligned with each other.

 The location of the second heat exchanger above the first heat exchanger allows the passage of air flows in the second heat exchanger above the air flows in the first heat exchanger.

 The location of the means for placing the liquid of the second heat exchanger in the mid-height part of the package of its plates ensures the saturation of the material of the plates forming the wet channels of this heat exchanger along the entire length of these plates.

 The direction of the outputs of the wet channels of the heat exchangers to each other and the location of these outputs coaxially to each other ensures the connection of the moist air flows of the two heat exchangers.

 Thus, the technical result of the proposed installation is to reduce its dimensions along the length without compromising the parameters of the conditioned air coming out of it.

 The installation in the outlet pipe for the auxiliary air flow damper to control the flow rate of the air flow at the exits from the wet channels of the first and second heat exchangers allows you to adjust the flow rate of the air flow at the exits of these channels.

 The location of the means for placing the liquid of the first heat exchanger in the middle height portion of the package of its plates allows you to increase the height of these plates.

 The proposed installation of indirect evaporative cooling of the air is illustrated by the drawings presented in figures 1-4.

In FIG. 1 shows a General view of the installation of indirect evaporative cooling of the air with a cut along the wet channel;
figure 2 is a section aa in figure 1;
figure 3 is a section bB in figure 1;
figure 4 - section bb in figure 1.

 The indirect evaporative air cooling unit contains successively communicated at its ends with each other, having means for accommodating the liquid heat exchanger 1 and heat exchanger 2 with packages of plates 3 forming dry channels 4 and wet channels 5, connected to the first heat exchanger 1 and communicated with its dry inlets and wet channels 4 and 5, the inlet pipe 6 for the total air flow associated with the second heat exchanger 2 and communicated with the outputs of its dry channels 4, the outlet pipe 7 for the main air flow, common to these heat exchangers and the outlet pipe 8 connected to the outputs of their wet channels 5 for an auxiliary air stream with an exhaust fan 9 and a fan 10 for supplying a common air stream, while the wet channels 5 of the first and second heat exchangers 1 and 2 are plugged with plugs 11 from the side of each other the ends of these heat exchangers, and the inputs 12 of the wet channels 5 of the second heat exchanger 2 are connected with the outputs 13 of its dry channels 4.

 The second heat exchanger 2 is located above the first heat exchanger 1, while the means for placing the liquid of the second heat exchanger 2 is located in the middle part of the package of plates 3, and the outputs 14 of the wet channels 5 of these heat exchangers are facing each other and are aligned with each other.

 Means for accommodating liquid, for example, water of the second heat exchanger 2, can be made in the form of at least one plate 3 of a row of tanks 15 transversely arranged in its package, installed in dry and wet channels 4 and 5. One of the walls of the tanks 15 is formed by plates 3. Tanks 15 are interconnected through holes 16 made in the plates 3, and have nozzles 17 for supplying and discharging liquid. In this particular embodiment, the heat exchanger 2 has two rows of tanks 15 located in height.

 The means for accommodating the liquid of the second heat exchanger 2 can be made in at least one container (not shown) through which the plates 3 pass.

 In the outlet pipe 8 for the auxiliary air flow, a shutter 18 can be installed to regulate the flow of air at the outputs 14 from the wet channels 5 of the first and second heat exchangers 1 and 2.

 The means for placing the liquid of the first heat exchanger 1 can be located in the middle height portion of the package of its plates 3. The specified means can be identical to the means for placing the liquid of the second heat exchanger 2. This tool can also be made in the form of a tray (not shown) located in bottom of heat exchanger 1.

 The plates 3 have a liquid impermeable coating 19 and a capillary-porous material 20.

 Position 21 indicates the adjusting screw for the shutter 18, position 22 is the connecting pipe connecting the heat exchangers 1 and 2, position 23 is the outdoor air intake in the inlet pipe 6, and position 24 is the air-conditioned room.

 Installation of indirect evaporative cooling of air works as follows.

 The total air flow sucked by the fan 10 from the air-conditioned room 24, through the inlet 6 enters the dry and wet channels 4 and 5 of the heat exchanger 1. From the wet channels 5 of the heat exchanger 1 (see Fig. 1), air enters the outlet 8 of the auxiliary air stream . From the dry channels 4 of the heat exchanger 1, air enters the connecting pipe 22, and from it to the dry channels 4 of the heat exchanger 2. At the outlet of 13 dry channels 4 of the heat exchanger 2, part of the air enters the wet channels 5 of the heat exchanger 2, and from them to the outlet pipe 8 auxiliary air flow. The movement of air through the wet channels 5 of the heat exchangers 1 and 2 and the outlet pipe 8 is provided by an exhaust fan 9. The flow rates of the air at the outputs 14 of the wet channels 5 of the heat exchangers 1 and 2 are controlled by turning the shutter 18 using the adjustment screw 21. Another part of the air from the dry channels 4 of the heat exchanger 2 enters the outlet pipe 7 of the main air stream, and from it to the air-conditioned room 24.

 The recharge of fresh air entering the heat exchanger 1, occurs through the intake 23.

 Dry channels 4 and wet channels 5 of the heat exchangers 1 and 2 are in heat exchange relations. Air passing through moist channels 5 along the walls of capillary-porous material 20 plates 3 (wetted with water from containers 15 due to capillary wetting) is cooled by evaporation of water from the surfaces of this material and cools the air flow passing through dry channels 4.

 In the heat exchanger 1, the air stream, without changing its moisture content, is cooled to the temperature of the wet thermometer, and then passing through the dry channels 4 of the heat exchanger 2, it is cooled to the dew point temperature.

 The location of the means (containers 15) for placing liquid in the middle-high part of the package of plates 3 of the heat exchanger 2 provides normal capillary wetting of the material 20 of the plates 3 along their entire length. In other words, the drying out of the capillary-porous material 20 of the plates 3 of the heat exchanger 2 at the places where the auxiliary air stream exits into the outlet pipe 8 is excluded.

 Thus, the technical result of the proposed installation is to reduce its dimensions along the length without compromising the parameters of the conditioned air coming out of it.

Claims (3)

1. Installation of indirect-evaporative cooling of air, containing in series communicated at its ends with each other, having means for placing liquid two heat exchangers with packages of plates forming dry and wet channels, connected to the first heat exchanger and communicated with the inlet pipe inlets with its dry and wet channels for the total air flow, connected to the second heat exchanger and connected with the exits of its dry channels, the outlet pipe for the main air flow, common to these heat exchangers and communicated with the outputs of their wet channels, an outlet pipe for an auxiliary air stream with an exhaust fan and a fan for supplying a common air stream, while the wet channels of the first and second heat exchangers are muffled from the ends of these heat exchangers communicated with each other, and the inputs of the wet channels of the second heat exchanger are in communication with the outputs its dry channels, characterized in that the second heat exchanger is located above the first heat exchanger, while the means for accommodating the liquid of the second heat exchanger is located in one of the height of the part of the package of its plates, and the outputs of the wet channels of these heat exchangers are facing each other and are aligned with each other. 2. The installation according to claim 1, characterized in that in the outlet for the auxiliary air flow there is a shutter for regulating the flow of air at the exits from the wet channels of the first and second heat exchangers. 3. Installation according to claim 1, characterized in that the means for accommodating the liquid of the first heat exchanger is located in the middle height portion of the package of its plates.

Images