RU193755U1 - Ice Prevention Device in a Fan Cooling Tower - Google Patents

Abstract

The utility model relates to a power system and can be used to cool recycled water in cooling towers of industrial enterprises. The device for preventing ice formation in the cooling tower at atmospheric air temperatures below zero contains pivoting louvers installed in the air inlet windows and located at the top and bottom of the air inlet windows, respectively, upper and lower pipelines, while the rotary louvres are made in two sections and are installed with the possibility of adjusting the air pass depending from the operating mode of the cooling tower, wind load and atmospheric air temperature, by sectionwise rotation of the blinds over which an aerodynamic visor is installed, the upper pipeline is made with water-spraying nozzles to form the last water curtain between the air inlets and the sprinkler, the upper and lower pipelines are connected to the water distribution pipe with the supply of warm, cooled water, and the upper pipeline is fixed to the side wall of the tower from the inside of the casing and a water-canopy visor is made above it, the lower pipeline is fixed near the air inlets between the latter and the side wall of the core from the outside, the water distribution pipe is connected to a water distribution system with water-spraying nozzles mounted above the sprinkler and configured to supply cooled water with a higher density of irrigation in the extreme peripheral zone. As a result, it is possible to prevent ice formation in the fan tower at atmospheric air temperatures below zero. 4 ill.

Description

The utility model relates to a power system and can be used to cool recycled water in cooling towers of industrial enterprises.

A device for preventing ice formation in a fan cooling tower is known, comprising a heat exchanger installed outside the tower casing and connected to an additional heating system for part of the warm water supplied to the lower water distribution manifold, the additional heating water heating system including a heat pump and an underground heat accumulator, the lower water distribution manifold is coaxially the casing of the tower and is equipped with nozzles oriented inward of the tower to the lower peripheral part of the sprinkler at an angle α = 45-65 ° to the vertical plane, while the nozzles of the lower water-distributing collector of the anti-icing system are equipped with nozzles with slit-like openings (see patent RU No. 2425313, class F28C 1/00, publ. July 27, 2011).

Installing a heat exchanger outside the cooling tower casing and connecting it to the additional heating system for part of the warm water supplied to the lower water distributing collector allows the additional heating system of warm water to increase the reliability of the cooling tower in winter due to the supply of heated water through nozzles with nozzles with slit-shaped openings with spraying water to the peripheral sprinkler near the entrance windows.

However, this installation only allows you to destroy the formed ice and does not prevent the formation of ice, which narrows the installation.

The closest to the utility model in terms of technical nature and the achieved result is a device for preventing ice formation in a fan tower at atmospheric air temperatures below zero, containing rotary shutters installed in the air inlets and located at the top and bottom of the air inlets, respectively the upper and lower pipelines (see copyright certificate SU No. 1467351, class F28C 1/00, publ. 03.23.1989).

However, this device also does not allow to completely prevent freezing of the lower part of the sprinkler, due to the fact that it is possible to heat the air only of the peripheral sections of the air inlet windows.

The technical problem solved by the utility model is the elimination of identified shortcomings.

The technical result consists in the fact that it is possible to prevent ice formation in the fan tower at atmospheric temperatures below zero.

This technical problem is solved, and the technical result is achieved due to the fact that the device for preventing ice formation in the fan tower at atmospheric air temperatures below zero contains rotary shutters installed in the air inlet windows and located at the top and bottom of the air inlet windows, respectively, the upper and lower pipelines, this rotary blinds are made two-sectional and installed with the ability to adjust the air pass depending on the operating mode of the cooling tower, wind loads and atmospheric air temperatures, by sectionally turning the blinds above which an aerodynamic visor is installed, the upper pipeline is made with water-spraying nozzles to form the last water curtain between the air inlet windows and the sprinkler, the upper and lower pipes are connected to the water distribution pipe with the supply of warm, cooled water, moreover, the upper pipeline is fixed to the side wall of the tower from the inside of the casing and a water guard is made above it, the lower pipeline is fixed near the air inlets between the latter and the side wall of the casing from its outer side, the water distribution pipe is connected to the water distribution system with water-spraying nozzles installed above the sprinkler and configured to supply cooled water with a higher density of irrigation in the extreme peripheral zone.

The above-described design feature of the device to prevent ice formation in the fan tower at atmospheric air temperatures below zero allows you to prevent the cold air from entering the tower during the winter period of operation of the tower over the entire area of the air inlet windows and, at the same time, to ensure that the main function of the tower is its full function - reverse cooling water to the required temperature.

In FIG. 1 shows a longitudinal section of a cooling tower with an ice formation prevention device in a fan cooling tower at atmospheric temperatures below zero.

In FIG. 2 shows a remote element 1 in FIG. one.

In FIG. 3 shows a remote element 2 in FIG. one.

In FIG. 4 shows a remote element 3 in FIG. one.

The device for preventing ice formation in the cooling tower at atmospheric air temperatures below zero contains rotary shutters 4 installed in the air inlet windows 5 and located at the top and bottom of the air inlet windows 5, respectively, the upper 6 and lower 7 pipelines.

The rotary blinds 4 are made two-sectional and are installed with the possibility of adjusting the air pass depending on the operating mode of the tower, wind load and air temperature, by sectional rotation of the blinds 4, over which the aerodynamic visor 8 is installed.

The upper pipe 6 is made with water-spraying nozzles 9 with the formation of the last water curtain between the air inlet windows 5 and the sprinkler 10.

The upper 6 and lower 7 pipelines are connected to a water distribution pipe 11 with the supply of warm, cooled water from it, and the upper pipe 6 is fixed to the side wall 12 of the tower from the inside of the housing 13 and a water pick-up visor 14 is made above it.

The lower pipeline 7 is fixed near the air inlet windows 5 between the latter and the side wall 12 of the housing 13 from its outer side. The water distribution pipe 11 is connected to a water distribution system 15 with water-spraying nozzles mounted above the sprinkler 10 and configured to supply cooled water with a higher density of irrigation in the extreme peripheral zone.

During the operation of the cooling tower in winter, the upper pipeline 6 provides a curtain of warm water along all the air inlet windows 5 and a thermal curtain along the upper perimeter of the air inlet windows 5 to prevent stalactite formations, and the lower pipeline 7 creates a thermal curtain in the air entering the cooling tower at the bottom of the air inlets 5 to prevent stalagmite formations, while the air control system allows you to adjust the air supply depending on the operating mode of the tower, wind load, and automatic or manual air temperatures by rotary shutters 4, divided into upper and lower sections, which allows you to adjust the flow of cold air by partially overlapping the air inlet windows 5, which in combination with the formation of a water curtain over the entire area of the air inlet windows 5, heating the incoming air along the upper and the lower perimeter of the air inlet windows 5 and the use of a water distribution system with a higher density of irrigation in the extreme peripheral zone of the sprinkler 10 prevents the formation of Contents of ice in the cooling tower at a very low air temperatures (below 0 ° C wet bulb), and aerodynamic 8 and 14 of baffle sunshields prevent inflow of cold air past the air-intake windows 5.

Claims (1)

A device for preventing ice formation in a cooling tower at atmospheric air temperatures below zero, comprising pivoting louvers installed in the air inlet windows and upper and lower ducts located at the top and bottom of the air inlet windows, characterized in that the rotary louvres are made in two sections, while the rotary louvres are installed with the ability to adjust the air pass depending on the operating mode of the tower, wind load and air temperature by means of projection rotation of the blinds, over which an aerodynamic visor is installed, the upper pipeline is made with water-spraying nozzles with the formation of the last water curtain between the air inlet windows and the sprinkler, the upper and lower pipelines are connected to the water distribution pipeline with the supply of warm, cooled water, and the upper pipeline is fixed to the side wall cooling towers on the inside of the casing and above it a water visor is made, the lower pipeline is fixed near the air inlets n between the latter and the side wall of the housing with its outer side, connected to the water distribution pipe water distribution system with Water-spraying nozzle mounted above the sprinkler and adapted to supply cooling water with a higher density at reflux in a peripheral area.

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