RU2071015C1 - Air-conditioning device - Google Patents

Abstract

FIELD: air-conditioning systems. SUBSTANCE: device has heat exchanger with clearances, plenum air passage, fan and sprinkling unit. Device is provided with additional plenum air passage above heat exchanger for supply of air to clearances between elements of heat exchanger in direction of action of gravitational force. Sprinkling unit is arranged above heat exchanger. EFFECT: enhanced reliability. 5 cl, 1 dwg

Description

 The invention relates to techniques for air conditioning and can be used in residential and public buildings for various purposes.

 A device for conditioning is known, including a heat exchanger, a tray, a fan (see, for example, Av.St. N 1665182, class F 24 F 1/02).

Closest to the invention, the technical solution is a device for air conditioning, comprising a heat exchanger with tubular ducts located with gaps, a supply air channel, a fan and an irrigation unit (see AS USSR N 332293, M CL ⁶ F 24 F 3/14 , 1970).

 Significant disadvantages of the known solution is that the air moving in the gaps between the tubular air ducts has velocity components in all directions, while the velocity vector mainly does not coincide with the gravity vector acting on the water film flowing down the surface of the air ducts and in the gaps between them. This leads to an increase in thickness, water film and the formation of water droplets on the lower surface of the ducts, which increases the heat transfer resistance and reduces the efficiency of the device as a whole.

 In the known device, the irrigation unit includes a container with a perforated bottom, from where water enters the outer surface of the heat exchanger in accordance with the process described above, since blowing the heat exchanger in the direction of gravity is excluded.

 The technical task is to increase the heat engineering efficiency of the heat exchanger and the device as a whole by eliminating the noted disadvantages.

 The essence of the invention lies in the fact that the device for air conditioning, including a heat exchanger with tubular ducts located with gaps, the supply air channel, a fan and an irrigation unit, is equipped with an additional air supply channel formed above the heat exchanger along its perimeter in plan for supplying air to the gaps between tubular ducts in the direction of gravity.

 In this case, the irrigation unit may include an annular container located above the heat exchanger with nozzles, the inner walls of which form an additional air supply channel with a fan installed in it along the perimeter of the heat exchanger; or a nozzle system located above the heat exchanger in the area adjacent to it an additional channel.

 The additional channel can communicate both with the main channel and with the air-conditioned volume.

 Compared with the prototype, the proposed technical solution contains new features, consisting in the presence of an additional air supply channel formed above the heat exchanger along its perimeter in plan to supply air to the gaps between the tubular ducts in the direction of gravity.

 The irrigation unit may include an annular container located above the heat exchanger with nozzles, the inner walls of which form an additional air supply channel with a fan installed in it along the perimeter of the heat exchanger; or a nozzle system located above the heat exchanger in the area adjacent to it an additional channel.

 The additional channel can communicate both with the main channel and with the air-conditioned volume.

 The invention is illustrated in the drawing, which shows a device for air conditioning; longitudinal section in the vertical plane.

 A device for air conditioning includes a heat exchanger 1 with tubular ducts 2 with gaps 3 between them.

 Supply (external) air enters the tubular ducts 2 through the main channel 4, in which the fan 5 can be installed.

 An additional air supply channel 6 is formed above the heat exchanger 1 along its perimeter in plan and has a longitudinal axis at the outlet portion coinciding with the direction of gravity, i.e. provides air in the gaps 3 in the specified direction.

 In the additional channel 6 can also be installed fan 7.

 Fans 5 and 7 can be used both jointly and independently from each other, if channels 4 and 6 communicate with each other.

 At the outlet of the heat exchanger, an air-distributing device 8 is installed, directly through which air enters the air-conditioned volume 9. A fan 5 can be installed inside the air-distributing device 8, which will reduce the longitudinal dimensions of the device.

 From the annular space, moist air is removed into the atmosphere through channel 10.

 The irrigation unit may include an annular tank 11 located above the heat exchanger 1, while its inner walls along the perimeter of the heat exchanger in plan form an additional channel 6 with a longitudinal axis coinciding with the direction of gravity and the pressure of the water flowing through the nozzle 12 from the tank 11.

 Together with the tank 11, it is also possible to use a system of nozzles 13 located in the adjacency zone of the additional channel 6 to the heat exchanger 1, or any other known devices.

 The fluid from the annulus flows into the sump 14.

 The main channel 4 and the additional channel 6 can communicate with each other and with an air-conditioned volume 9 (not shown in the drawing).

 A device for conditioning works as follows.

 External air is pumped or sucked (depending on the location of the fan 5) into the tubular air ducts 2 of the heat exchanger 1. At the same time, the irrigation unit (ring tank 11, nozzle 13 or other known devices) is turned on and liquid begins to flow to the surface of the tubular air ducts 2, blown through additional channel 6 in the direction of gravity.

 The evaporation of water from the surface of the ducts 2 implements the principle of indirect evaporative cooling of the air entering the air-conditioned volume 9.

 As a result of the coincidence of the directions of air movement through the additional channel 6 and gravity, as well as in the considered example and the direction of water, its distribution is much more uniform with a thin layer on the surface of air ducts 2, droplets are removed from them, and more intensive evaporation, and, therefore, and more efficient heat transfer.

 The efficiency of the device will be quite high in the case of fluid in the other direction, since in any case it will be under the influence of gravity and air entering through an additional channel 6.

 If the primary and secondary channels communicate with each other, then it is possible to use only one fan 5.

 When the main channel 4 communicates with an air-conditioned volume 9, recirculation is ensured by the flow of cooled air to the heat exchanger 1, which, of course, will further increase the efficiency of the device as a whole.

 Wet air from the annulus is discharged into the atmosphere, and excess water flows into the sump 14, from where it can again be supplied to irrigate the heat exchanger.

 The invention, as shown by preliminary calculations, increases the thermal performance of the device as a whole by 8-12%

Claims (5)

 1. A device for air conditioning, comprising a heat exchanger, between the irrigated surfaces of the elements of which there are gaps, a supply air channel, a fan and an irrigation unit, characterized in that it is formed with an additional supply air channel formed above the heat exchanger in terms of its area in plan to supply it to the gaps between the elements of the heat exchanger in the direction of gravity, while the irrigation unit is also located above the heat exchanger.  2. The device according to claim 1, characterized in that the irrigation unit includes an annular container with nozzles, the inner walls of which form an additional air supply channel with a fan installed in it along the perimeter of the heat exchanger.  3. The device according to p. 1, characterized in that the irrigation unit includes a system of nozzles located above the heat exchanger in the adjoining zone of the additional channel.  4. The device according to claims 1 to 3, characterized in that the additional channel communicates with the main one.  5. The device according to claims 1 to 3, characterized in that the additional channel communicates with an air-conditioned volume.