SU1712742A1 - Sprinkling chamber - Google Patents

Abstract

The invention relates to air conditioning and allows to intensify heat and mass transfer. Stops 2 with centrifugal nozzles 3 oriented in pairs towards each other are installed in the irrigation chamber, the storages are installed in an amount of no more than four with the possibility of rotation around the vertical axis, and the nozzles the third with the possibility of rotation around the axis. The nozzle 3 is made in the form of a successively narrowing nozzle, a body and grids 6. ne-5Wv 'I i I 1 m ^ ^,: gsh <: \\\\ ^ AirSuM

Description

covering the outlet section of the housing; The nozzle has a diaphragm 8 with a central hole 9 and a curler 10 with tangential side and axial holes 11 and 12, and an annular gate 13 is installed on the body, blocking the side openings 23 of the body. The water supplied from the sump by the pump is sprayed by the nozzles 3, creating a developed heat exchange surface due to their rotation. The air after treatment in the irrigation chamber is supplied to the working room. The water supplied to the nozzle 3 passes

the central opening 9 enters the curler 10, where it acquires a spin, flows further into the housing and enters the grate 6, air is supplied through the openings 23. Forming with the rotating water-air mixture enters the grate 6 contributing to the turbulization of the mixture, and further to the exit grate 6 into the chamber volume. The interaction of two jets from the oppositely located nozzles leads to their intensive mixing and intensive heat and mass transfer. 1 h. n. fly, 5 ill.

The invention relates to air conditioning, to devices for humidifying air.

The aim of the invention was the intensification of heat and mass transfer.

FIG. 1 is a schematic diagram of the irrigation chamber; in fig. 2 is a diagram of a centrifugal nozzle; in fig. 3 - section A-Anafig. 2; in fig. 4 shows a section BB in FIG. 2; in fig. 5 shows a section B-B in FIG. 2

The irrigation chamber contains collectors 1 and 2 of columns with centrifugal nozzles 3 oriented towards each other.

Stokes 2 are installed in pairs against each other in an amount of no more than four with the possibility of rotation around a vertical axis, and centrifugal nozzles 3 can be rotated around the rows 2, with centrifugal nozzle 3 made in the form of successively narrowing nozzles 4, body 5 and grids , overlapping the output section 7 of the housing 5, while in the converging nozzle 4 there is installed a diaphragm 8 with a central opening 9 and a twister 10 with tangential lateral and axial openings 11 and 12, and on the housing 5 ene annular slide valve 13 is movable, and viodnoy grating 6 has a central hole 14 with its diameter-to-diameter lattice b equal to 0.1-0.25.

The irrigation chamber has a pallet 15.

The collectors 1 are installed in the pallet 15c with the joint 16 moving along the axis of the chamber.

The nozzles 3 are installed in the middle part of the legs 2 on the movable connection 17. The pallet 16 is connected by pipeline to the suction of the centrifugal pump 18, and its pressure nozzle - with the movable connection 16.

At the entrance of the irrigation chamber, a section 19 for mixing fresh air and recirculated air is installed, and behind the chamber is an air heater 20, a fan 21 connected to room 22.

In the wall of the housing 5 is made openings 23, and the annular gate 13 is installed on its outer surface.

The tapering nozzle 4 is provided with an outlet 24. The grill 6 is pressed against the housing 5 with a cap nut 25, and the upper grill 6 is connected with a cap nut 25 tons gami 26.

The irrigation chamber works as follows.

in a way.

Water of the required temperature is sucked in by the centrifugal pump 18 from the pallet 15, flows to the stoves 2 and is sprayed by the centrifugal nozzles 3 into small

drops, creating a developed heat exchange surface. The air is sucked from the atmosphere by the fan 21, passes through the irrigated space of the rectangular chamber, is heated in the surface

the heat exchanger 20 acquires the required parameters and is supplied to the room 22 for technological needs. Water flows into the sump 15 and flows through the pipeline to the centrifugal pump 18. Water also flows into the interior of the centrifugal nozzle 3, passes through the central hole 9 of the diaphragm 8, and then is divided into two streams. One flow along the axis of the converging nozzle 4 passes through the central opening 12 of the twister 10. The other flow passes through the tangential side openings 11 of the twister 10, acquiring a twist in the upper part of the nozzle 4. At the same time, the flow of water moving to the output

hole 24 is twisted. Since the moment of momentum, equal to the product m-vT, remains constant,

when moving along a cone to the outlet 24 with decreasing radius, the tangential velocity of the swirling flow increases by the same amount. At the outlet of the hole 24, the swirling flow in turn affects the central axial flow, mixes with it and the spray jet flows out of the hole 24. The diameter of the hole 24 at water flow 1215 is 10-12 mm. To this ground, a stream of water with coarse spraying of droplets with a diameter of 1.2-1, & mm mm emerges from the hole. After passing through the outlet 24, a swirling stream of water is formed, which passes into the housing 5 and falls onto the surface of the grille 6. When water moves, air is injected through adjustable apertures 23. The air-rotary mixture that forms with the air flows onto the surface of the grid 6, the presence of which promotes the turbulence of the mixture and, as a result, splits the droplets of the jet into smaller parts. The degree of crushing of droplets is regulated by the amount of incoming air, by turning the ring gate 13, which overlaps the cross section of the opening. 23. The secondary fragmented jet of water moves further and hits the surface of the outlet grid 6.

Water droplets are crushed on the surface of the outlet grate 6 to a size of 0.3-0.4 mm. That is, an air mixture of water and air drawn onto the surface of the exit grate 6 through the central opening 14 also falls onto the exit grate 6. Pass the exit grate 6, the water-air mixture has a fine dispersion of droplets and enters the space of the irrigation chamber. Towards this flow from the opposite .-: this centrifugal

nozzle 3 flows from head to back. The interaction of the two jets leads to their intensive mixing, turbulence in the water-air flow, and a high intensification of heat and mass transfer. This ensures efficient crushing of water droplets at low energy costs and regulation of the length and width of the torch of the nozzle 3. Due to the change in lengths of the rip 26, the distance between the grids 6 decreases. As the distance decreases, the torch captures only part of the surface of the output grid 6 and the degree of fragmentation jet is reduced.

5 Formula of invention

Claims (2)

1. Irrigation chamber containing collectors and runners with centrifugal nozzles oriented towards each other, characterized in that 0 intensification of heat and mass transfer, no more than four stoves are installed in pairs against each other with the possibility of rotation around the vertical axis, and the centrifugal nozzles are rotatably mounted 5 around the sinks, let us accept the centrifugal nozzle made in the form of a successively narrowing nozzle, a housing and grids overlapping the output section of the housing, while in a narrowing nozzle 0 a diaphragm with a central bore and a swirling device with tangential lateral and axial bores are installed, and the annular gate is mounted on the housing with the possibility of movement, and 5 output lattice made central hole. 2. The camera according to claim 1, characterized in that the central opening is made with a ratio of its diameter to the diameter of the grating, equal to 0.1-0.25;