RU2213910C1 - Conditioner - Google Patents

Abstract

FIELD: cooling of rooms with a low humidity in hot foundries, as well as in the areas with a dry and hot climate. SUBSTANCE: the conditioner has a mixing-distributing device, cooling chamber filled with water connected to the device for maintaining the water level, pipe-line system and a power distributing device and a vortex tube with a tangential inlet of compressed air, with a cold outlet connected to the mixing-distributing device installed in the cooling chamber. The conditioner is provided with a heat exchanger, filter and the second cooling chamber with an additional power distributing device, developed surface and a fan fastened in the chamber, the heat exchanger is installed between the hot outlet of the vortex tube and the power distributing device, and the filter - between the cooling chambers, the additional power distributing device is connected to a compressed air source, and the second cooling chamber communicates with the mixing-distributing device. EFFECT: enhanced efficiency due to additional cooling of conditioned air. 1 dwg

Description

 The invention relates to techniques for air conditioning, and in particular to air conditioners operating using vortex tubes, and can be used to cool rooms with low humidity in hot, foundries, as well as in areas with a dry and hot climate.

 A known installation for air conditioning, which contains a vortex tube, the hot end of which is made finned with a control valve mounted on it and located in the cooling chamber. The control valve is in communication with the atmosphere and the heat exchanger, and the cold end of the vortex tube with the consumer through the blowing chamber. The cooling chamber has opposite openings in the case and an ejector for the release of cooled air into the atmosphere [1].

 Common signs of the claimed air conditioner and the described analogue is the presence of a vortex tube, a cooling chamber, in which the hot part of the vortex tube, and a heat exchanger are located.

 An analog device allows you to adjust the aerodynamic and temperature characteristics of the chilled air stream entering the consumer.

 The disadvantage of the analogue is that its design does not allow the use of all air supplied by the turbocharger in air conditioning, but only about 60%, the rest is used to eject external air, which enters through the openings into the cooling chamber and blows around the finned end of the vortex tube, cooling it. At high outside temperatures, ejection reduces the conditioning effect. In addition, the disadvantage of an analogue is the high energy costs, lack of humidification.

 Also known apparatus for thermo-humid treatment of air, containing a vortex tube with a tangential nozzle connected to an air-liquid mixer, which through a dispenser communicates with a water tank. The inlet of the air-liquid mixer and the above-water space of the tank are connected to the high pressure air duct. The energy separation channel in the vortex tube is enclosed between the hot air outlet and the diaphragm in front of the cold air outlet. A control valve is installed in the channel. The pipe for the release of cold air is in communication with an ejector-type mixer. The mixer output is facing the consumer. Coaxial to the energy separation channel is a humidified hot air return channel through which hot air enters the ejector-type mixer. The vortex tube is equipped with a gas collector chamber connected to the energy separation channel and the hot air return channel [2].

 Common signs of the claimed air conditioner and the described analogue is the presence of a vortex tube with a tangential input of compressed air, a mixer and a piping system. The cold outlet of the vortex tube communicated with the mixer.

The positive in the analogue is that both flows separated in the vortex tube (hot and cold) participate in the mixing at the outlet, i.e., 100% utilization of compressed air is achieved. The consumer receives the mixture, which is moist air with high relative humidity at a temperature of 35-40 ^o C.

The disadvantage of the analogue is that for the operation of the vortex tube, a sufficiently high pressure of compressed air is necessary to ensure mixing of air with water before being fed into the tangential nozzle of the vortex tube. This increases energy costs. Another disadvantage of the analogue is the relatively high temperature (35-40 ^o C) of the mixture supplied to the consumer. In addition, water is taken at the entrance to the vortex tube, which reduces its efficiency.

 As a prototype, an air conditioner was selected that contains a piping system and a vortex tube with a tangential inlet of compressed air, with a cold outlet connected to a mixing and distribution device, and hot connected to a gas-collecting chamber, and the outlet with a mixing and distribution device, the hot part a vortex tube with a gas collector chamber and a dispersant are installed in a cooling chamber connected by a pipeline to a device for maintaining the water level [3].

 Common signs of the claimed air conditioner and prototype is the presence of a mixing and distribution device, a cooling chamber with water poured into it, connected to a water level maintaining device, a piping system and a disperser and a vortex tube installed in the cooling chamber with a tangential inlet of compressed air, with a cold outlet connected with mixing and distribution device.

 Positive in the prototype is that both flows separated in the vortex tube are involved in the mixing at the outlet, i.e., 100% utilization of compressed air is achieved.

 However, the prototype has insufficient efficiency, since the air entering the mixing and distribution device from the end of the dispersant does not have time to cool and its temperature is higher than the temperature of the inlet air.

 The technical problem solved by the claimed device is to increase efficiency by additional, deeper cooling of the conditioned air.

 The problem is solved in that an air conditioner comprising a mixing and distributing device, a cooling chamber with water poured into it, connected to a water level maintaining device, a piping system and a disperser and a vortex tube installed in the cooling chamber with a tangential inlet of compressed air, with a cold outlet connected with a mixing and distribution device, according to the invention is equipped with a heat exchanger, a filter and a second cooling chamber with an additional dispersant fixed therein, developed a fan and a heat exchanger installed between the hot outlet of the vortex tube and the dispersant, and the filter between the cooling chambers, an additional dispersant is connected to the compressed air source, and the second cooling chamber is in communication with the mixing and distribution device.

 New distinctive features: heat exchanger, filter, second cooling chamber, additional dispersant, developed surface and fan.

 A heat exchanger installed between the hot outlet of the vortex tube and the dispersant is necessary to cool the hot air stream. Finely dispersed moisture enters the heat exchanger and the hot part of the vortex tube from the nozzle of the disperser, causing the process of evaporation and condensation, which contributes to the cooling of all nodes located in the chamber.

 The filter is installed between two cooling chambers and cuts off excess moisture from the air entering the second cooling chamber and then through the air distribution flaps to the mixing and distribution device.

 An additional dispersant and fan blowing over the developed surface contribute to a deeper cooling of the air flow entering the second cooling chamber. Plates of the developed surface have roughnesses that prevent rolling from the surface of the water, increase the contact of air with fine moisture, which produces an additional dispersant.

 In the second cooling chamber, an increase in the cooling efficiency of the air entering it is provided.

 The fan helps to eliminate stagnant zones, increase the volume of cold air output and recirculation.

 The listed new structural elements, their location and connections between them allow us to solve the technical problem - to increase the efficiency of the created device.

 The set of distinctive features of the claimed device is not found in the patent and scientific literature.

The drawing shows a diagram of the inventive air conditioner, where:
1 - vortex tube
2 - cold flow output
3 - conclusion of a hot stream
4 - pipeline
5 - source of compressed air
6 - pipeline
7 - mixing distribution device
8 - cooling chamber
9 - pipeline
10 - device for maintaining the water level
11 - pipeline
12 - heat exchanger
13 - dispersant
14 - second cooling chamber
15 - filter
16 - additional dispersant
17 - developed surface
18 - fan
19 - pipeline
20 - air distribution flaps
21 - silencer
22 - outlet openings
The air conditioner contains a vortex tube 1 with a tangential inlet of compressed air, which enters through a pipe 4 from a source 5 of compressed air, such as a compressor or supercharger. The output 2 of the cold flow of the vortex tube 1 is connected by a pipe 6 with a mixing and distributing device 7.

 The vortex tube 1 is installed in the cooling chamber 8, in which water is poured.

 The cooling chamber 8 is connected by a pipe 9 to a device for maintaining the water level 10. The outlet 3 of the hot stream of the vortex tube 1 is connected by a pipe 11 to a heat exchanger 12 and then to a dispersant 13, which are also installed in the cooling chamber 8. A filter 15 is installed between the cooling chambers. Second the cooling chamber 14 is rigidly fixed additional dispersant 16, the developed surface 17 and the fan 18.

 Additional dispersant 16 pipe 19 is connected to a source 5 of compressed air. The second cooling chamber 14 is in communication with the mixing and distributing device 7 through the air distribution flaps 20.

 The mixing and distribution device 7 contains cylindrical containers of different diameters with perforations along the length of the cylinders. Conclusion to the consumer of the conditioned air in the desired direction is carried out through the outlet openings 22 on the front side of the housing of the mixing and distribution device 7.

 Air conditioning works as follows.

 Compressed air from a source of compressed air 5 (compressor or supercharger), after being cleaned, enters through a tangential inlet into the vortex tube 1, where it is twisted and divided into two streams: cold and hot. The jets of the cold stream are turned to the axis of the vortex tube 1 and through the outlet 2 of the cold stream through the pipe 6 enter the mixing and distribution device 7, passing a noise muffler 21.

 Through terminal 3, the hot stream from the vortex tube 1 through the pipe 11 enters the heat exchanger 12 and then to the inlet of the dispersant 13. In the course of its operation, the dispersant 13 sucks in the water located at the bottom of the cooling chamber 8. Through nozzles, part of the water is sprayed into the chamber where the process takes place evaporation and condensation, as a result of the heat exchanger 12 and the casing of the vortex tube 1 are cooled. From the end outlet of the dispersant 13, part of the water is sprayed into the second cooling chamber 14. In the second cooling chamber 14, an additional disperser 16 of lower power, a developed surface 17, and a fan 18 are installed.

 Developed surface 17 is a series of plates with a rough surface to increase air contact with moisture.

 Between the cooling chambers 8 and 14, a filter 15 is installed, which cuts off excess moisture from the air coming from the first cooling chamber to the second.

 An additional dispersant 16 sucks in the water located at the bottom of the cooling chamber 8 and sprays fine moisture, which fills the second cooling chamber 14.

 The fan 18 blows the plates of the developed surface 17, helps to eliminate stagnant zones, increase the volume of outgoing cold air and recirculate.

 In the second chamber there is a deeper cooling of the air and its saturation with moisture.

 The air conditioner implements the vortex and evaporative principle of operation.

 As a result of air humidification, its temperature drops. The air from the dispersants has a temperature lower than at the inlet. In the mixing and distributing device 7, the moistened air flows coming from the second cooling chamber 14 through the air distribution shutters 20 are mixed and the cold stream coming from the vortex tube, which previously enters the noise muffler 21, and then the air flows in the desired direction to the consumer.

 The air temperature from the mixing and distribution device is lower than the temperature of the air supplied to the inlet of the vortex tube. The temperature difference complies with sanitary standards.

 The pressure control of the inlet compressed air is carried out using pressure gauges and is regulated by a valve. The temperature of the compressed air is monitored by a thermoelectric thermometer. Automatic and manual adjustment of maintaining the water level is possible (adding water after 4-5 hours of continuous operation), as well as automatic humidity control.

 The air conditioner works smoothly and without vibration, has 100% use of compressed air.

 The air conditioner produces humidified air, providing a comfortable environment for consumers. In the air conditioner, an increase in the efficiency of its work is achieved, which allows to expand the scope of its application.

Sources of information
1. Copyright certificate SU 1803680 A1, 03/23/1993.

 2. Copyright certificate SU 1820157 A1, 06/07/1993.

 3. RU 2177587 C1, 12/27/2001.

Claims (1)

 An air conditioner containing a mixing and distributing device, a cooling chamber with water poured into it, connected to a water level maintaining device, a piping system and a disperser and a vortex tube installed in the cooling chamber with a tangential inlet of compressed air, with a cold outlet connected to the mixing and distributing device characterized in that it is equipped with a heat exchanger, a filter and a second cooling chamber with an additional dispersant fixed therein, a developed surface and a fan rum, while the heat exchanger is installed between the hot outlet of the vortex tube and the dispersant, and the filter is between the cooling chambers, an additional dispersant is connected to a source of compressed air, and the second cooling chamber is in communication with the mixing and distribution device.