RU2409797C1 - Cooling tower - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: cooling tower includes the tower on side surface of which there located are air inlet openings with atomisers for ejection of cooling air; at that, in openings there installed are louvres inclined inward the cooling tower and forming the channels located in tiers, and atomisers are arranged before inlet necks of the latter; atomisers are centrifugal, and each of which includes housing with chamber into which a screw is pressed; at that, throttle hole is made in the housing bottom, and nozzle with cylindrical hole, diffuser and gasket is located in upper part, and hole with screw thread the direction of which coincides with direction of external screw thread of screw is made inside the screw, and cone-shaped mixing chamber for forming total fine rotating flow is located above throttle hole.

EFFECT: increasing operating efficiency of cooling tower.

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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, C02B 1/10 of 07/04/72., Containing a tower, on the lateral surface of which there are air inlet windows with nozzles for ejecting cooling air, and the windows have louvres tilted into the cooling tower, forming channels arranged in tiers, and the nozzles are placed in front of the inlets necks of 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 inlet windows with nozzles for ejecting cooling air, moreover, the windows have louvres tilted into the cooling tower and forming channels arranged in tiers, and the nozzles are placed in front of the inlets of the latter, the nozzles are made of centrifugal , each of which contains a housing with a chamber into which the screw is pressed in, and a throttle hole is made in the bottom of the housing, and a fitting with a cylindrical position is placed in the upper part m aperture, and a diffuser gasket and formed within the screw hole with a screw thread, whose direction coincides with the direction of the external screw thread of the screw, and the throttle opening is located above the conical mixing chamber to form a particulate aggregate of the rotating flow.

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

The tower contains a tower 1 with a bath 6 for collecting liquid, having a trapezoid in cross section. On the side surface of the tower there are air inlets 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 through the nozzles 5.

The centrifugal nozzle (figure 2) consists of a housing 9, inside of which there is a screw 7, pressed into the housing 9. The outer surface of the screw 7 is a helical groove with a right (or left) thread. Inside the screw 7, a hole 8 is made with a left (or right) screw thread. At the bottom of the housing 9, a throttle hole 10 is made, the axis of which coincides with the axis of the hole 8 in the screw 7. Between the lower end of the screw 7 and the slice of the throttle hole 10 there is a conical mixing chamber 11. The solution (liquid) is supplied through the nozzle 13 fixed in the upper part the housing 9 through the sealing gasket 12. Inside the fitting 13, a cylindrical hole 14 is made, passing into the diffuser 15, which is connected to the cylindrical chamber 16, made in the housing 9, into which the screw 7 is pressed.

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 there is heat and mass transfer between the air and the cooled water. The use of centrifugal 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.

Centrifugal nozzle for sawing liquids works as follows.

The fluid is supplied through a cylindrical hole 14 into the diffuser 15, and from it into the chamber 16, from which it flows simultaneously in two directions under pressure: firstly, into the screw external cavity of the screw 7 and, secondly, into the hole 8 with screw thread . A rotating fluid flow from the screw outer cavity of the screw 7 enters the mixing chamber 11. On the other hand, fluid 11 enters the screw chamber 11 from the screwed hole 8, rotating in the direction opposite to the external flow going through the screw 7, or by passing (the same ) rotation. In the interaction of the rotating flows in the chamber 11, an additional crushing of the liquid droplets occurs due to their collision in the associated or opposite rotating fluid flows (external and internal). The total finely dispersed rotating stream exits through the throttle aperture 10, and the direction of its rotation is determined by the hydraulic resistance of the external or internal screw cavities and grooves of the screw 7, respectively. The nozzle screw 7 can be made of solid materials: tungsten carbide, ruby, sapphire. With an average diameter of the throttle hole 10, which is in the range of 2.5 ... 3.5 mm, and the pressure supplied through the cylindrical hole 14 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 (1)

A cooling tower 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 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 centrifugal, each of which contains a housing with a chamber into which the screw is pressed in, and a throttle hole is made in the bottom of the housing, and a fitting with a cylindrical a hole, a diffuser and a gasket, and a screw-threaded hole is made inside the screw, the direction of which coincides with the direction of the external screw-threading of the screw, and a conical mixing chamber is located above the throttle hole to form a total finely dispersed rotating stream.

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