RU2319906C1 - Device for air conditioning - Google Patents

Abstract

FIELD: air conditioning or ventilation.

SUBSTANCE: device comprises forced air chamber, sprinkling chamber, droplet trap, and fan. The deicer made of a heat exchanger is mounted at the inlet to the forced air chamber. The inlet of the deicer is connected with the supply pipeline, and the outlet of the deicer is connected with the return pipeline of the hot water supply system. The heat exchanger is mounted downstream of the droplet trap. The inlet of the heat exchanger is connected with the supply pipeline, and its outlet is connected with the discharge pipeline. The heat exchanger of the secondary heating is mounted downstream of the droplet trap parallel to the deicer. The inlet of the heat exchanger is connected with the supply pipeline, and its outlet is connected with the return pipeline of the hot water supply system. The nozzle has housing provided with the inlet port, lid, sealing spacer between the housing and lid, and spring interposed between the lid and swirler made of an overturned cylindrical sleeve that is mounted with a spaced relation to the housing.

EFFECT: enhanced efficiency and reliability.

1 cl, 3 dwg

Description

The invention relates to techniques for air conditioning and ventilation and can be used to create comfortable microclimate conditions in domestic, administrative and industrial premises.

The closest technical solution to the claimed object is the air conditioning system according to the patent of the Russian Federation No. 2031319, class. F24F 5/00 from 04/27/92 (prototype), containing a supply air chamber, an irrigation chamber, a droplet eliminator and a fan.

The disadvantage of the prototype is the relatively low efficiency of the dust collection process due to the underdeveloped spray surface of the liquid.

The technical result is an increase in the efficiency and reliability of the dust collection process by increasing the degree of liquid atomization by nozzles.

This is achieved by the fact that in an energy-saving air conditioning system containing an inlet chamber, an irrigation chamber, a droplet eliminator and a fan, an anti-icer is installed at the inlet of the inlet chamber, made in the form of a heater, the inlet of which is connected to a direct heating main, and the output - to the return heating main of the heating system, and in front of the droplet eliminator, a heat exchanger of the secondary energy resources (VER) system is installed, the input of which is connected to the supply line from the VER source, and the output - to the discharge line and after the drip trap, in parallel with the de-icer in the heat supply system, a second heating air heater is installed, the input of which is connected to the direct heating main, and the output to the return heating main of the heat supply system, each nozzle consists of a body with an inlet, a cover, a sealing gasket between the body and the cover , a spring located between the cover and the swirl, made in the form of an inverted bottom up cylindrical cup mounted relative to the housing with an annular gap, pr than at least two rows of throttle openings are made in the swirl, and at least two tangential throttle openings evenly spaced along the annular wall of the swirl are made in the swirl, and a nozzle insert with a calibrated conical is installed in the lower part of the casing the hole coaxial with the cylindrical surface of the swirl, and the taper, the inverse taper of the conical washer of the liner.

Figure 1 shows a schematic diagram of an energy-saving conditioning system, figure 2 is a General view of the nozzle for spraying liquids, figure 3 is a section aa of figure 2.

The energy-saving air conditioning system contains a supply air chamber 1, at the inlet of which an anti-icer 6 is installed, which is a heater, the inlet of which is connected to the direct heat pipe 10, and the output to the return heat pipe 11 of the heat supply system. At the outlet of the supply chamber 1, a fan 2 is installed. In the irrigation chamber 4 there is a collector 14 with nozzles for forming a finely divided water curtain, a bath 15 for collecting waste water, overflowing and draining it through valves 3 and 8, filtering through a filter 16 and pumping 5 manifold 14 with nozzles, i.e. the irrigation chamber 4 operates in a closed cycle. In front of the drip trap 17, a heat exchanger 7 of the secondary energy resources (VER) system is installed, the input of which is connected to the supply line 12 from the VER source, and the output - to the discharge line 13, and after the drop catcher 17, in parallel with the de-icer 6 in the heat supply system, a second heater is installed, the input of which is connected to the direct heating main 10, and the output to the return heating 11.

The centrifugal nozzle (Fig.2-3) consists of a housing 18 with an inlet 19, a cover 20, a sealing gasket 21 between the housing and the cover, a spring 22 located between the cover and the swirl 23, made in the form of an upside down cylindrical cup mounted relative to casing 18 with an annular gap 24. At least two rows of throttle openings 25 are made in the swirl 23, each row has at least two throttle openings 25 evenly spaced along the annular wall of the swirl 23. In the lower part of the housing 18 is installed in the form of a conical washer nozzle insert 26 made of solid materials: tungsten carbide, ruby, sapphire with a calibrated conical hole 27, coaxial with the cylindrical surface of the swirl 23, and the hole 27 has the opposite taper with the conical washer of the insert 26.

Energy-saving air conditioning system operates as follows.

An anti-icer 6 is installed at the inlet to the inlet chamber, which in the cold season reduces the aerodynamic drag of the tract and avoids icing of the intake valve elements. In front of the drip trap 17, a heat exchanger 7 of the secondary energy resources (VER) system is installed, the input of which is connected to the supply line 12 from the VER source, and the output - to the discharge line 13, and after the drop catcher 17, in parallel with the de-icer 6 in the heat supply system, a second heater is installed, the input of which is connected to the direct heat supply line 10, and the output - to the return heat supply line 11, which makes it possible to ensure the optimal heat and humidity operation of the supply chamber and the entire air conditioning system as a whole.

A centrifugal nozzle for spraying liquids works as follows.

The fluid is supplied through the inlet 19 to the annular gap 24, from where to the swirl 23 through the throttling holes 25 tangentially located to the inner surface of the swirl 23. The rotating fluid flow from the swirl 23 exits through a calibrated conical hole 27 of the nozzle insert 26, resulting in a spray of liquid whose root angle is determined by the angle of inclination of the conical surface of the hole 27.

When the average diameter of the hole 27, which is in the range of 2.5 ... 3.5 mm, and the pressure supplied through the inlet 19 of the liquid under a pressure of 6 ... 9 MPa, atomization of 400 to 1000 kg / h of liquid is provided. The nozzle is easy to manufacture and maintain.

Claims (2)

1. An energy-saving air conditioning system containing a supply air chamber, an irrigation chamber, a droplet eliminator and a fan, an anti-icer is installed at the inlet to the intake chamber, made in the form of a heater, the inlet of which is connected to a direct heat main, and the output is connected to a return heat main of the heat supply system, and is installed in front of the droplet eliminator a heat exchanger of the secondary energy resources (VER) system, whose input is connected to the supply line from the VER source, and the output to the outlet line, and after the drop catcher In parallel with the defroster, a second heater is installed in the heat supply system, the input of which is connected to the direct heat supply, and the output is connected to the return heat supply of the heat supply system, characterized in that each nozzle consists of a body with an inlet, a cover, a gasket between the body and the cover, and springs located between the cover and the swirl, made in the form of an inverted bottom up cylindrical cup mounted relative to the housing with an annular gap, moreover at least two rows of throttle openings are made in the swirl, and at least two tangential throttle openings evenly spaced along the annular wall of the swirl are made in each row, and a nozzle insert with a calibrated conical hole is installed in the lower part of the casing, coaxial with the cylindrical surface of the swirl, and the taper, the inverse taper of the conical washer of the liner. 2. The energy-saving conditioning system according to claim 1, characterized in that the nozzle nozzle insert is made of solid materials: tungsten carbide, ruby, sapphire.

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