RU163731U1 - SECTIONAL COOLING TOWER - Google Patents

Abstract

1. Sectional cooling tower, comprising a casing with casing, air-intake windows made in the casing, a coating, characterized in that the sectional cooling tower along the perimeter of the coating contains horizontal aerodynamic wind deflectors, consisting of an arched frame, sheathed from the inside with plastic sheet material, and the front part of the deflector , relative to the incoming wind flow, is equipped with a rising visor having the wing profile of the aircraft, with an adjustable counterweight. 2. The sectional cooling tower according to claim 1, characterized in that it is additionally equipped with vertical aerodynamic wind deflectors located at the corners of the cooling tower at a distance from them, consisting of a fairing in the form of an arc of constant radius and two vertical shields located at the ends of the fairing arc and forming the passage channels of air between the fairing and the shields, while the opposite edges of the shields are horizontally deflected in the direction to the cooling tower.

Description

The utility model relates to a power system, namely to sectional cooling towers of water recycling systems of power plants and industrial enterprises.

Known sectional cooling tower, comprising a casing with casing, air inlet windows made in the casing, cooling tower cover Ponomarenko, Yu.I. Arefyev, M: Energoatomizdat, 1998, pp. 31-37]. In the zones of aerodynamic shadows of such a cooling tower, rarefaction of atmospheric air is formed. Accordingly, the disadvantage of such a cooling tower is its design, forming aerodynamic shadows.

The objective of the utility model is the design of a sectional cooling tower with design features that allow the use of wind energy to increase the efficiency of water cooling, as well as eliminate the appearance of an aerodynamic shadow area, which eliminates lateral drop entrainment, improves the environmental situation of the adjacent territory, ensures simplicity of design and high operational reliability . Thus, the utility model eliminates the disadvantages of the known sample.

The essence of the proposed utility model is to equip the tower with horizontal aerodynamic deflectors; in addition, the tower can be equipped with vertical aerodynamic deflectors. The technical result is achieved by the fact that a sectional tower comprising a casing with a casing, air inlet windows made in the casing, the cooling tower coating, according to a utility model, contains horizontal aerodynamic wind deflectors (hereinafter referred to as deflectors) around the perimeter of the coating, consisting of an arcuate frame, sheathed from the inside by sheet plastic material, the front part of the deflectors relative to the incoming wind flow is equipped with a rising visor having the profile of the wing of the aircraft, with an adjustable vovesom. In addition, at the corners of the tower, at a distance from them, there are vertical aerodynamic wind deflectors, consisting of a fairing in the form of an arc of constant radius and two vertical shields located at the ends of the fairing arc and forming in this place air ducts between the fairing and shields, this, the opposite edges of the shields are horizontally deflected towards the cooling tower.

The figure 1 shows a General view of a sectional tower with horizontal aerodynamic wind deflectors, a diagram of their installation and vectors of air flows, showing the mechanism of suppressing the rarefaction of atmospheric pressure in the area of the aerodynamic shadow of the tower; figure 2 is a top view of a sectional cooling tower, vertical aerodynamic wind deflectors, a diagram of their installation and air flow vectors showing the mechanism for suppressing atmospheric pressure rarefaction in the area of the aerodynamic shadow of the tower; figure 3 is a profile and a diagram of the operation of horizontal aerodynamic wind deflectors.

The sectional cooling tower according to the proposed utility model has the following design.

A sectional cooling tower comprises a casing 1 with casing, air inlet windows 2 made in the casing, cooling tower 3 covering. Horizontal aerodynamic wind deflectors (hereinafter referred to as deflectors) 4 are located along the perimeter of the cooling tower cover, and the front part of the deflectors relative to the incoming wind flow is provided with a rising visor 5, with adjustable counterweight 6. The cooling tower, additionally equipped with vertical aerodynamic deflectors, also has fairings in the form of an arc of constant radius 8 and two vertical shields on each deflector 9.

From the windward side, the wind flows around the deflector 4, while the visor 5 is located horizontally under the influence of wind force. In this configuration and with this wind direction, the deflector works like an ejection pump, i.e. layers of air enveloping the deflector cause a vacuum at its trailing edge, which draws in the lower layers of air with excessive pressure. Thus, the air velocity above the tower cover becomes higher than the present wind speed. This air velocity, like a manure, reaches the deflector 4 located on the leeward side of the tower. Under the influence of wind force, the visor 5, with the wing lifting force, rises by a certain angle, increasing the inlet section of the deflector 4. The high-speed wind pressure from the larger inlet section goes into the smaller section of the deflector mouth, increasing its kinetic energy, which is sufficient to extinguish the rarefaction of air in aerodynamic shadows of the cooling tower. In this configuration and with this wind direction, the deflector acts as an air blower.

The principle of operation of vertical aerodynamic deflectors is as follows:

On the windward side, an incoming wind stream goes around the fairing 8 from the outside, passes into the channel between the fairing 8 and the vertical shield 9, which directs it to the air inlet window 2 of the tower. On the leeward side, a wind stream flows around the inner surface of the fairing 8, and then is sent by a vertical shield 9 to the air inlet window 2 of the tower. Vertical shields 9 are stabilizers of air flow. Thus, aerodynamic wind deflectors allow the use of wind energy to increase the efficiency of water cooling and to exclude lateral drop entrainment.

On the well-known cooling tower, taken as a prototype, with a differential micromanometer, air pressures were measured from the windward and leeward sides relative to atmospheric pressure, which showed the following results: plus 45 Pa and minus 187 Pa, respectively, with moderate wind strength. Water vapor and small droplets from the zone of the undergrowth space with increased pressure rush into the zone of low pressure of the aerodynamic shadow of the tower, reducing its water cooling efficiency and worsening the environment of the surrounding area (Fig. 4). When using the proposed utility model, the inherent disadvantages of the prototype are eliminated.

Claims (2)

1. Sectional cooling tower, comprising a casing with casing, air-intake windows made in the casing, a coating, characterized in that the sectional cooling tower along the perimeter of the coating contains horizontal aerodynamic wind deflectors, consisting of an arched frame, sheathed from the inside with plastic sheet material, and the front part of the deflector , relative to the incoming wind flow, is equipped with a rising visor having the profile of an airplane wing, with an adjustable counterweight. 2. The sectional cooling tower according to claim 1, characterized in that it is additionally equipped with vertical aerodynamic wind deflectors located at the corners of the cooling tower at a distance from them, consisting of a fairing in the form of an arc of constant radius and two vertical shields located at the ends of the fairing arc and forming in this place, the air ducts between the fairing and the shields, while the opposite edges of the shields are horizontally deflected towards the tower.

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