RU2347997C1 - Impulse 7 type cooling tower - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: present invention pertains to contact coolers, particularly to cooling towers, and can be used in thermal power stations for cooling circulating water. The cooler has a tower, on the side face of which are air inlet windows with sprayers for injecting air coolant. On the windows there are inward tilting cooling gills, forming tiered channels, while sprayers are fitted in front of the inlet nozzles of the latter. The sprayers are acoustic. They have a case, inside of which there is an acoustic generator in form of a nozzle and a resonator, and pipes for movement of the spraying agent and liquid. The case is in form of a cup with a bottom, inside of which there is a case of the acoustic generator, which is in form of a hollow rod with a V-shaped aperture and a nozzle. Liquid enters the annular gap between the outer surface of the resonator and the inner surface of the nozzle. The channel for moving liquid is at a tangent to the inner surface of the cup and is in form of a rectangular slit. Air is let in through a connection pipe in the case and the resonator opening, and then through at least, one V-shaped aperture, located at an angle to the axis of the resonator. The angle lies in the optimum interval: 30°÷60°. In the annular gap between the inner surface of the cup and outer surface of the resonator, there is a helical guide, capable of creating a swirling stream of liquid, going into the channel.

EFFECT: increased efficiency of the cooling tower.

2 cl, 2 dwg

Description

The invention relates to contact coolers, in particular to cooling towers, and can be used at thermal power plants for cooling circulating water.

The closest technical solution to the claimed facility is a cooling tower on.with. USSR No. 435442, С02В 1/10 dated 04.07.72, comprising a tower, on the lateral surface of which there are air inlet windows with nozzles for ejecting cooling air, moreover, the windows have louvres tilted into the cooling tower, forming channels arranged in tiers, and the nozzles are placed in front of the inlet necks the latter (prototype).

The disadvantage of the cooling tower is the relatively low efficiency due to the low degree of atomization of the liquid nozzles.

The technical result is an increase in the performance of the tower.

This is achieved by the fact that in the cooling tower containing the tower, on the lateral surface of which there are air inlets with nozzles for ejecting cooling air, moreover, the windows have louvres tilted into the cooling tower, forming channels arranged in tiers, and the nozzles are placed in front of the mouths of the latter, the nozzles are made of acoustic comprising a housing with an acoustic oscillator located inside the nozzle and resonator, and a tube for supplying a spraying agent and liquid, the housing being nen in the form of a glass with a bottom, with an acoustic oscillator placed inside the body in the form of a hollow 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 tangential to the inner surface of the glass and is made in the form of a rectangular slit, while air is supplied through the nozzle in the housing and through the hole of the resonator, and then enters at least one wedge gap laid at an angle with respect to the axis of the resonator, the angle being in the optimal range of 30–60 °. and in the annular gap between the inner surface of the glass and the outer surface of the resonator there is a screw guide device that contributes to the creation of a vortex flow of fluid entering the channel.

Figure 1 shows a diagram of a cooling tower, figure 2 is a General view of an acoustic nozzle for spraying liquid.

The cooling tower comprises a tower 1 having a trapezoid in cross section. On the side surface of the tower there are air inlet windows in which the louvers 2, inclined into the cooling tower, are installed, forming rectangular channels 3. In front of the inlet necks of the channels 3, collectors 4 are placed for supplying cooled liquid.

The acoustic nozzle (figure 2) for spraying liquids contains a housing 18 made in the form of a glass with a bottom 19, with an acoustic oscillation generator arranged in the form of a hollow rod 11 with a wedge slot 12 and a nozzle 7. The fluid enters the annular gap made between the outer surface of the resonator 11 and the inner surface of the nozzle 7, and then into the annular gap 8 between the inner surface of the housing 18 and the outer surface of the cup 21. Then, through the channel 22, made in the side wall of the cup 21, installed co it is clear to the housing 18. the liquid enters the annular gap between the inner surface of the cup 21 and the outer surface of the resonator 11, and the channel 22 is located tangentially to the inner surface of the cup 21 and is made in the form of a rectangular slit.

Air is supplied through the nozzle 13, located coaxially with the nozzle body 18, through a pipe 9 with an opening 14, an opening 16 made and a valve 15, coaxial with the fitting 13 and the opening 10 of the resonator 11, and then enters at least one wedge slot 12. The wedge gap 12 is located at an angle with respect to the axis of the resonator 11, and the angle is in the optimal range of 30 ÷ 60 °. The valve 15 interacts with a seat 17, integral with the resonator 11 and resting on an elastic gasket 20 located between the end surfaces of the cup 21 and the seat 17. In the annular gap between the inner surface of the cup 21 and the outer surface of the resonator 11 there is a helical guide device 23, contributing to creating a vortex flow of fluid entering the channel 22.

For the operation of the nozzle in optimal mode, the following ratios of its parameters are provided:

the ratio of the distance h ₂ from the outer surface of the bottom 19 of the housing 18 to the lower end of the valve 15 to the distance h from the outer surface of the bottom 19 of the housing 18 to the point of intersection of the axes of the inner hole 10 of the resonator 11 with the wedge gap 12 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 19 of the housing 18 to the lower end of the valve 15 to the distance h ₁ from the outer surface of the bottom 19 of the housing 18 to the axis of the fluid supply channel 22 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 10 of the resonator 11 to the diameter d _{1 of the} inner surface of the housing 18 lies in the optimal range of values d / d ₄ = 0.1 ÷ 0.3;

the ratio of the diameter d of the inner hole 10 of the resonator 11 to the diameter d _{1 of the} outer surface of the resonator 11 lies in the optimal range of values d / d ₁ = 0.3 ÷ 0.7;

the ratio of the diameter d _{2 of the} nozzle 7 to the diameter d _{1 of the} outer surface of the resonator 11 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 7 to the distance h ₁ from the outer surface of the bottom 19 of the housing 18 to the axis of the fluid supply channel 22 lies in the optimal range of values of d ₂ / h ₁ = 3.5 ÷ 4.5;

the ratio of the diameter d of the inner hole 10 of the resonator 11 to the distance h from the outer surface of the bottom 19 of the housing 18 to the point of intersection of the axes of the inner hole 10 of the resonator 11 with the wedge target 6 lies in the optimal range of d / h = 0.3 ÷ 0.7.

The acoustic nozzles 5 are staggered. At the bottom of the tower is a reservoir 6 for collecting chilled water.

The cooling tower works as follows.

The cooling air is ejected by the supplied water, first in the channels formed by the blinds 2, and then in the tower 1, heat and mass transfer between the air and the cooled water takes place. The use of acoustic nozzles 5 with a uniform spray of liquid allows to obtain high ejection coefficients. The separation of moisture from the air takes place in a trapezoidal tower 1 due to a gradual decrease in the air velocity at the outlet.

The acoustic nozzle for spraying liquids works as follows.

The spraying agent, for example air, is supplied through the opening 14 of the tube 9, then the opening 16 made in the valve 15 and the opening 10 of the resonator 11, after which it enters at least one wedge slot 12. The liquid is passed through a channel 22 made in the lateral the wall of the glass 21, enters the annular gap between the inner surface of the glass 21 and the outer surface of the resonator 11. As a result of the passage of the resonator 11 by a spraying agent (for example, air), pressure pulsations arise in the latter, creating acoustic vibrations, the frequency of which x is dependent on the resonator parameters. Acoustic vibrations of the spraying agent contribute to finer atomization of the solution supplied to the annular gap, while impacting, it creates 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.

Claims (2)

1. A cooling tower comprising a tower, on the lateral surface of which there are air inlets with nozzles for ejecting cooling air, the windows having louvres tilted inward of the cooling tower and forming channels arranged in tiers, and the nozzles are placed in front of the mouths of the latter, characterized in that the nozzles are made of acoustic containing a housing with an acoustic oscillator located inside the nozzle and resonator, and a tube for supplying a sawing agent and liquid, the housing being made in the form of a glass with a bottom, with an acoustic oscillation generator located inside the case in the form of a hollow rod with a wedge gap and a nozzle, the liquid entering 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 the surface of the glass and is made in the form of a rectangular slit, while air is supplied through the nozzle in the housing and the hole 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 of values: 30–60 °, and in the annular gap between the inner surface of the glass and the outer surface of the resonator there is a helical guide device that helps to create a vortex fluid flow entering the channel. 2. The cooling tower according to claim 1, characterized in that the ratio of the distance h ₂ from the outer surface of the bottom of the housing to the lower end of the valve to the distance h from the outer surface of the bottom of the housing 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: 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: 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: 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 body to the axis of the feed channel liquid 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 of the bottom of the housing 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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