RU2339880C1 - Air additional moistening system - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: proposed system made up of pneumatic nozzles, pipeline system designed to feed water and compressed air thereto and a pneumatic nozzle control unit, features a pneumatic nozzle representing an acoustic nozzle with acoustic oscillation generator arranged there inside composed of a nozzle and a resonator and a pipe to feed a spraying agent and fluid. Note here that the housing represents a cup with its bottom arranged inside the acoustic oscillation generator and representing a hollow rod with a wedge-like slit and a nozzle. Note here that fluid comes towards the circular gap between the resonator outer surface and the nozzle inner surface, the fluid feed channel being made tangential to the cup inner surface and representing a rectangular slit. Note also that air is fed through the housing union and the resonator orifice and, further on, into, at least, one wedge-like slit arranged at an angle to the resonator axis, while the circular gap between the cup inner surface and resonator outer surface houses a screw guide device.

EFFECT: higher spraying efficiency and reliability.

Description

The invention relates to techniques for air conditioning and can be used to create comfortable microclimate conditions in domestic, office and industrial premises, in particular, as local dampening systems for air, spray systems for flavored and medicinal solutions.

The closest technical solution to the claimed object is a humidification system according to the patent of the Russian Federation No. 2293923, class. F24F 3/06 of 10/10/96, containing a sprayer in the form of a pneumatic nozzle and a control unit.

Its disadvantage is the relatively low efficiency of the pneumatic spraying process.

The technical result is an increase in the efficiency and reliability of the process of pneumatic spraying of water.

This is achieved by the fact that in the air after-humidification system consisting of pneumatic nozzles, piping networks used to supply water and compressed air to them and a pneumatic nozzle control unit, the pneumatic nozzle is made acoustic, containing a housing with an acoustic oscillation generator located inside the nozzle and a resonator and a tube for supplying a spraying agent and liquid, while the housing is made in the form of a glass with a bottom, with an acoustic oscillation generator placed inside the housing in the form e of a hollow rod with a wedge gap and a nozzle, while the fluid enters an annular gap made between the outer surface of the resonator and the inner surface of the nozzle, and the channel for supplying fluid is located tangentially to the inner surface of the glass and is made in the form of a rectangular gap, while air is supplied through the fitting in the housing and the cavity of the resonator, and then enters at least one wedge slot located at an angle with respect to the axis of the resonator, the angle being in the optimal range Ale values of 30 ÷ 60 °, and in the annular gap between the inner surface of the cup and the outer surface of the resonator taken screw guide device facilitates creation of a vortex fluid stream flowing through the channel.

Figure 1 presents the frontal section of the pneumatic nozzle of the humidification system, figure 2 - control unit for the operation of pneumatic nozzles.

Pneumatic humidification systems consist of nozzles (Fig. 1), piping networks used to supply water and compressed air to them and a control unit for the operation of pneumatic nozzles (Fig. 2). In addition, there are safety devices that exclude the possibility of pouring water from the nozzles when the supply of compressed air to them is stopped (not shown in the drawing).

Pneumatic acoustic nozzle (figure 1) contains a housing 12, made in the form of a glass with a bottom 13, with an acoustic oscillation generator placed in the form of a hollow rod 5 with a wedge slot 6 and a nozzle 1. The fluid enters the annular gap made between the outer surface the resonator 5 and the inner surface of the nozzle 1, and then into the annular gap 2 between the inner surface of the housing 12 and the outer surface of the glass 15. Then, through the channel 16, made in the side wall of the glass 15, mounted coaxially to the housing 12, the liquid enters the annular gap between the inner surface of the cup 15 and the outer surface of the resonator 5, and the channel 16 is located tangentially to the inner surface of the cup 15 and is made in the form of a rectangular slit.

Air is supplied through a nozzle 7 located coaxially with the nozzle body 12 through a tube 3 with a hole 8, a hole 10 made in the valve 9, coaxially with the nozzle 7 and the hole 4 of the resonator 5, and then enters at least one wedge slot 6. Wedge slot 6 located at an angle with respect to the axis of the resonator 5, and the angle is in the optimal range of values 30 ÷ 60 °. The valve 9 interacts with a seat 11, integral with the resonator 5, and resting on an elastic gasket 14 located between the end surfaces of the glass 15 and the seat 11. In the annular gap between the inner surface of the glass 15 and the outer surface of the resonator 5 there is a screw guide device 17, contributing to the creation of a vortex flow of fluid entering the channel 16.

For optimal operation and reduction of energy consumption, the pneumatic nozzle is made with the following size ratios of its main elements, which are in the optimal range of values:

the ratio of the distance h ₂ from the outer surface of the bottom 13 of the housing 12 to the lower end of the valve 9 to the distance h from the outer surface of the bottom 13 of the housing 12 to the point of intersection of the axes of the inner hole 4 of the resonator 5 with the wedge gap 6 lies in the optimal range of values: h ₂ / h = 6 ÷ 10;

the ratio of the distance h ₂ from the outer surface of the bottom 13 of the housing 12 to the lower end of the valve 9 to the distance h ₁ from the outer surface of the bottom 13 of the housing 12 to the axis of the channel 16 for supplying liquid lies in the optimal range of values: h ₂ / h ₁ = 1,5 ÷ 3 ;

the ratio of the diameter d of the inner hole 4 of the resonator 5 to the diameter d _{4 of the} inner surface of the housing 12 lies in the optimal range of values: d / d ₄ = 0.1 ÷ 0.3;

the ratio of the diameter d of the inner hole 4 of the resonator 5 to the diameter d _{1 of the} outer surface of the resonator 5 lies in the optimal range of values: d / d ₁ = 0.3 ÷ 0.7;

the ratio of the diameter d _{2 of the} nozzle 1 to the diameter d _{1 of the} outer surface of the resonator 5 lies in the optimal range of values: d ₂ / d ₁ = 1.3 ÷ 1.7;

the ratio of the diameter d _{2 of the} nozzle 1 to the distance h ₁ from the outer surface of the bottom 13 of the housing 12 to the axis of the fluid supply channel 16 lies in the optimal range of values: d ₂ / h ₁ = 3.5 ÷ 4.5;

the ratio of the diameter d of the inner hole 4 of the resonator 5 to the distance h from the outer surface of the bottom 13 of the housing 12 to the point of intersection of the axes of the inner hole 4 of the resonator 5 with the wedge gap 6 lies in the optimal range of values: d / h = 0.3 ÷ 0.7.

Figure 2 presents the control unit of the pneumatic nozzles. It contains a hair moisture regulator 20, diaphragm valves 19 and 22, shut-off valves 18, a needle throttle 21 for regulating the pressure of compressed air in front of the diaphragm valves, a voltage transformer 23, control lamps 24 and 27, a switch 26 and an electro-pneumatic relay 25.

The humidification system operates as follows.

Pneumatic nozzles (figure 1) spray water using compressed air, which is supplied through the hole 8 of the tube 3, then the hole 10 made in the valve 9 and the hole 4 of the resonator 5, after which it enters at least one wedge slot 6. The liquid the channel 16, made in the side wall of the glass 15, enters the annular gap between the inner surface of the glass 15 and the outer surface of the resonator 5. As a result of the passage of the resonator 5 by a spray agent (for example, air), pressure pulsations arise in the latter, creating a spherical oscillations, the frequency of which depends on the parameters of the resonator. The acoustic vibrations of the spraying agent contribute to a finer atomization of the solution supplied to the annular gap, while when hit, they create sound vibrations affecting the liquid stream. The specified nozzle provides good spray quality at low air flow rates. The experiments showed that at an air pressure of 100 kPa, the average droplet diameter is 90 μm, with an increase in air pressure by about 4 times (up to 400 kPa), the average droplet diameter decreases slightly and amounts to 87 μm.

The control unit (figure 2) the operation of pneumatic nozzles works as follows. When supplying compressed air to the cavity above the membranes of valves 19 and 22, the supply of compressed air and then water is first opened. After turning off the compressed air supply, the valves close in the reverse order; this protects against the risk of leakage of unsprayed water in the pipes through the nozzles. The described safety device is also used to automatically control the operation of the nozzles, which is carried out using a humidity controller 20 acting on an electro-pneumatic relay (electromagnetic valve) 25 mounted above the membrane valve 19 located on the water supply line. This relay, depending on whether the electric current is turned on or off, opens or closes a narrow hole in the valve cover 19, opening or closing the air outlet under the membrane to the atmosphere. At the same time, the pressure on the corresponding membranes changes, and consequently, the supply of water and compressed air to the nozzles. In some cases, each membrane valve has its own electro-pneumatic relay, which is switched on via an independent time relay. The electro-pneumatic relays are adjusted so that the water supply is turned off 10 seconds before the compressed air supply is cut off, and turned on 10 seconds later than the resumed air supply.

Claims (3)

1. The air humidification system, consisting of pneumatic nozzles, piping networks used to supply water and compressed air to them and a pneumatic nozzle control unit, characterized in that the pneumatic nozzle is made acoustic, containing a housing with an acoustic oscillator located inside the nozzle and a resonator and a tube for supplying a sawing agent and liquid, while the housing is made in the form of a glass with a bottom, with an acoustic oscillation generator placed inside the housing in the form of a rod with a wedge gap and a nozzle, while the liquid enters an annular gap made between the outer surface of the resonator and the inner surface of the nozzle, and the channel for supplying liquid is located tangentially to the inner surface of the glass and is made in the form of a rectangular gap, while air is supplied through the nozzle in the housing and the cavity of the resonator, and then enters at least one wedge gap located at an angle with respect to the axis of the resonator, the angle being in the optimal range values of 30 ÷ 60 °, and in the annular gap between the inner surface of the cup and the outer surface of the resonator taken screw guide device facilitates creation of a vortex fluid stream flowing through the channel. 2. The air humidification system according to claim 1, characterized in that the pneumatic nozzle operation control unit comprises a hair moisture regulator, membrane valves, shut-off valves, a needle throttle for regulating the pressure of compressed air in front of the membrane valves, a voltage transformer, control lamps, a switch and an electro-pneumatic relay. 3. The air humidification system according to claim 1, characterized in that the pneumatic acoustic nozzle is made with the following aspect ratios of its main elements: the ratio of the distance h ₂ from the outer surface of the bottom of the body to the lower end of the valve to the distance h from the outer surface of the bottom of the body to the point of intersection the axes of the inner hole of the resonator with a wedge gap lies in the optimal range of values of h ₂ / h = 6 ÷ 10; the ratio of the distance h ₂ from the outer surface of the bottom of the body to the lower end of the valve to the distance h ₁ from the outer surface of the bottom of the body to the axis of the fluid supply channel lies in the optimal range of values of h ₂ / h ₁ = 1.5 ÷ 3; the ratio of the diameter d of the inner hole of the resonator to the diameter d _{4 of the} inner surface of the housing lies in the optimal range of values d / d ₄ = 0.1-0.3; the ratio of the diameter d of the inner hole of the resonator to the diameter d _{1 of the} outer surface of the resonator lies in the optimal range of values d / d ₁ = 0.3 ÷ 0.7; the ratio of the diameter d _{2 of the} nozzle to the diameter d _{1 of the} outer surface of the resonator lies in the optimal range of values of d ₂ / d ₁ = 1.3 ÷ 1.7; the ratio of the diameter d _{2 of the} nozzle to the distance h ₁ from the outer surface of the bottom of the housing to the axis of the fluid supply channel lies in the optimal range of values d ₂ / h ₁ = 3.5 ÷ 4.5, the ratio of the diameter d of the inner hole of the resonator to the distance h from the outer surface the bottom of the body to the point of intersection of the axes of the inner hole of the resonator with the wedge gap lies in the optimal range of values d / h = 0.3 ÷ 0.7.

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