RU49206U1 - COOLING HOUSE (OPTIONS) - Google Patents

Abstract

The proposed technical solution relates to heat engineering, in particular to evaporative cooling towers, and can be used both in existing thermal and nuclear power plants, as well as in the construction or modernization of cooling towers, as well as in other industrial facilities that require cooling of water or other liquids.

The objective of the proposed technical solution is to expand the functionality of this tower.

The problem is solved due to the fact that the known cooling tower contains a casing, a catchment basin under the casing, air inlet windows for placing opposite them in horizontal rows on the vertical water distribution manifolds of the water distribution system of the nozzle-sprayers, and a shield inclined inward upward, above the air inlet windows .

According to the claimed technical solution, lower air inlet windows are made between the casing and the catchment basin in the side wall of the casing, the openings of which are adjustable, with the possibility of rotation (0-90 °) around the axis, the blinds, and middle ones are located above the lower air inlet windows air-inlet windows, opposite the openings of which, on the vertical water-distributing headers of the main water distribution system, are installed in horizontal rows of nozzles-nozzles. Attached to the upper cut of the middle air inlet windows, along the wall of the case: or a shield inclined inward upwards of the case; or horizontal, inside the case shield. Above the middle air inlet windows, upper air inlet windows are made in the side wall of the casing, and inclined additional shields are mounted one above the other to the lower and upper sections of the casing, between which additional horizontal panels are mounted on the inclined water distribution manifolds of the additional water distribution system, spray nozzles, while spray nozzles connected to the main water distribution system with a smaller nozzle diameter in a smaller quantity for greater pressure or to an additional water distribution system with a larger nozzle diameter in a larger quantity for less pressure.

In addition, an ejection channel of a trapezoidal section is formed between an upwardly inclined shield and a water mirror in a drainage basin, and a rectangular section ejection channel is formed between a horizontal shield inside a housing and a water mirror in a drainage basin. Between the additional shields inclined inward downward, a channel of trapezoidal section is formed.

Spray nozzles are attached to the nozzles of the water-distributing manifolds directly or on round flanges with the installation of several spray nozzles on them, for example, from two to eight.

The design of this tower allows for high-performance operation of cooling towers of any required dimensions with any: rectangular, polygonal or other cross-section.

Description

The proposed technical solution relates to heat engineering, in particular to evaporative cooling towers, and can be used both in existing thermal and nuclear power plants, as well as in the construction or modernization of cooling towers, as well as in other industrial facilities that require cooling of water or other liquids.

Known cooling tower, comprising a housing with air-inlet windows in its lower part, and placed in groups on the water distribution manifold in the window openings, water-jet nozzles-sprays located at an angle facing each other, symmetrically relative to the vertical axis of the tower with an offset from the plane of the window to the center of the tower .

Spray nozzles are mounted on platforms with the ability to rotate around the horizontal axis by an angle that provides the height of the intersection of the jets of liquid torches. Each platform is a swivel housing with movable flanges connected to a water distribution system.

On the upper flange of each turntable there are several water-jet nozzles. This leads to a large number of flange connections, which complicates the design of the water distribution system, as well as the repair and maintenance of the cooling tower. (Patent of the Republic of Belarus No. 3450, IPC F 28 C 1/00, F 28 F 25/06, 2000).

The disadvantage of this cooling tower is that the pipelines of the water distribution system are in the form of a stepped inverted pyramid, in which the perimeters for each lower row are reduced relative to the upper one. This leads to a decrease in the number of nozzles in each lower level relative to the higher one, especially in polyhedral cooling towers, which reduces the performance of the tower, and the attachment of each turntable to the collector through separate rotary flanges significantly complicates the design by increasing the number of flange connections.

Known cooling tower containing a vertical tower with air intake windows in its lower part, a reservoir for collecting chilled water and a water distribution system made in the form of a water supplying collector with radial inclined nozzles, on which spray nozzles-sprayers are mounted on the belt, and the radial nozzles are mounted with a slope from the center to the periphery of the tower, and the nozzle nozzles are oriented to the center of the tower at different angles to the horizontal plane, while the total

the cross section and the angle of inclination of the nozzle nozzles of each upstream tier is greater than the total cross section and the angle of inclination of the nozzle nozzles of the nozzles of the lower tier. (Patent of the Russian Federation No. 2099662, IPC F 28 C 1 / 00.1997).

The disadvantage of this tower is the reduced cooling efficiency of the circulating water, due to the uneven arrangement of the nozzles in the volume of the tower and the piping of the water distribution system in the form of an inverted truncated cone, in which the diameter of the upper base is larger than the diameter of the lower base.

This leads to a decrease in the number of nozzles in each lower tier in relation to the higher tier, which reduces the performance of the tower, and the implementation of the nozzles on each ring collector at different angles to the horizontal plane from 0 ° in the lower tier to 45 ° in the upper tier, significantly complicates the design of the tower .

The closest in essence and the achieved effect is the cooling tower according to the patent of the Republic of Belarus No. 1307 IPC F 28 C 1 / 00,2004.

The objective of the proposed technical solution is to expand the functionality of this tower.

The problem is solved due to the fact that the known cooling tower contains a casing, a catchment basin under the casing, air inlet windows for placing opposite them in horizontal rows on the vertical water distribution manifolds of the water distribution system of the nozzle-sprayers, and a shield inclined inward upward, above the air inlet windows .

According to the claimed technical solution, lower air inlet windows are made between the casing and the catchment basin in the side wall of the casing, the openings of which are adjustable, with the possibility of rotation (0-90 °) around the axis, the blinds, and middle ones are located above the lower air inlet windows air-inlet windows, opposite the openings of which, on the vertical water-distributing headers of the main water distribution system, are installed in horizontal rows of nozzles-nozzles. Attached to the upper cut of the middle air inlet windows, along the wall of the case: either a shield inclined upward inside the case (option 1, FIG. 1), or a horizontal shield inside the case (option 2, FIG. 2). Above the middle air inlet windows, upper air inlet windows are made in the side wall of the casing, and to the lower and upper sections of the casing, additional inclined shields are mounted one above the other, inwardly facing downwards, between which horizontal horizontally mounted manifolds of the additional water distribution system are fixed

in rows, spray nozzles, while spray nozzles connected to the main water distribution system with a smaller nozzle diameter in smaller quantities for greater pressure or to an additional water distribution system with a larger nozzle diameter in larger quantities for lower pressure.

In addition, an ejection channel of a trapezoidal section (option 1, FIG. 1) is formed between an upwardly inclined shield and a water mirror in the catchment basin (option 1, FIG. 1), and an ejection channel of a rectangular cross section is formed between a horizontal shield inside the case and a water mirror in the catchment basin (option 2, FIG. .2). Between the additional shields inclined inward downward, a channel of trapezoidal section is formed. Spray nozzles are attached to the nozzles of the water-distributing manifolds directly or on round flanges with the installation of several spray nozzles on them, for example, from two to eight.

Spray nozzles are installed on the water-distributing manifolds in increments that provide partial intersection of the jets of torch cones from the spray nozzles.

Figure 1 shows a General view of the tower with sloping shields.

Figure 2 shows a General view of the tower with horizontal and inclined boards.

The cooling tower comprises a housing 1, a drainage basin 2, lower air inlet windows 3, middle air inlet windows 4 and upper air inlet windows 5. In the openings of the lower air inlet windows 3, blinds 6 are adjustable that can be rotated about the axis. A shield 7 (see FIG. 1) or a shield 8, horizontal inside the case 1, shield 8 (see FIG. 2) is attached to the upper cut of the air-inlet window 4 by a lower rib. An additional shield 9 is attached to the lower cut of the air inlet window 5 by the upper edge, and an additional shield 10 is attached to the upper cut of the air inlet window 5 by the upper edge.

When the tower is operating between the inclined shield 7 and the water mirror in the pool 2, a channel 11 of trapezoidal section is formed (Fig. 1), and between the horizontal shield 8 and the water mirror in the pool 2 is a channel 12 of rectangular cross section (Fig. 2). Between the additional shields 9 and 10 inclined inward downward, a channel 13 of trapezoidal section is formed. Opposite the openings of the middle air inlet windows 4, nozzles-sprayers 14 are installed on the water-distributing collectors 15 of the main water distribution system 16.

Between the inclined inward downward additional shields 9 and 10, nozzle-sprayers 17 are installed on the inclined water-distributing collectors 18 of the additional water distribution system 19. The drawings (Figs. 1 and 2) show torches 20 flowing from the nozzles-

nozzles 14 and 17 and arrows 21 showing the direction of the current flow of cooling air.

Opposite the openings of the middle air inlet windows 4 inside the housing 1 are mounted horizontal rows of nozzles-sprayers 14, on the vertical water supply manifolds 15. The nozzles-sprayers 14 are connected to the main water distribution system 16.

Opposite the openings of the upper air inlet windows 5 between the additional inclined shields 9 and 10, nozzle nozzles 17 are installed, which are connected through an inclined water supply manifold 18 to an additional water distribution system 19, while the nozzle nozzles connected to the main 16, or to an additional water distribution system 19 are made with different sizes of nozzle diameters, and are designed for different water pressures in the mentioned water distribution systems.

The size of the droplets (average droplet diameter) in the volume of the cone of the jet of the torch 20 from the nozzles-nozzles 17 is an order of magnitude smaller than in the volume of the cone of the jet of the torch from the nozzles-nozzles 14. The direction of the flow of cooling air is indicated by arrows 21. The cooling tower works as follows.

The cooled circulating water through the main water distribution system 16 and the vertical water supply manifold 15 is supplied to the spray nozzles 14 and through the additional water distribution system 19 and the inclined water supply manifold 18 to the spray nozzles 17.

The temperature head inside and outside the cooling tower and the vacuum created by the torches 20 to spray the cooled water, create conditions for the ejection of cooling air through the air inlet windows 3, 4 and 5 and channels 11, 12 and 13 into the housing 1, while the flow of cooling external air is ejected through the air inlet windows 3, bypassing the fully or partially open blinds b, first lowers to the water mirror in the pool 2, as shown by arrows 21, and then, heating up from drops of heated water, turns around and goes up towards the top about the cut-off of the cooling tower towards 2 drops of circulating water falling into the pool.

As a result of the mutual collision of drops of cooled water at the intersection of the spray cones of the torches 20, they are crushed again with the formation of a "fluidized bed" in a mixture of drops of cooling air and cooled water.

The crushing of droplets of cooled water is also facilitated by the installation of atomizer nozzles on the collectors 15 and 18 with a step that ensures mutual intersection of the cones of the torches 20, for example, from 30 to 70%.

Separated from the drip-air stream, water is collected in pool 2, from where it flows to consumers (not shown).

Separated from the drip-air stream, the air is discharged outward through the upper section of the tower body 1.

By setting blinds 6 in the range from 0-90 °, from full opening in hot weather to full closing in cold weather, the temperature and volumes of air entering the cooling tower are regulated, which allows to reduce the number of circulating water cycles and thereby reduce energy consumption.

A significant increase in the total volume of air entering the cooling tower creates favorable conditions for the effective cooling of circulating water.

The design of this cooling tower allows for high-performance operation of cooling towers of any required dimensions with any:

rectangular, polygonal or other cross-section. Information sources.

1. Patent RB No. 3450, IPC F 28 С 1/00, F 28 F 25 / 06,2000

2. RF patent No. 2099662, IPC F 28 C 1/00

3. Patent RB No. 1307, IPC F 28 C 1 / 00,2004 (prototype).

Claims (2)

1. Cooling tower, comprising a casing, a drainage basin under the casing, upper, middle and lower air inlet windows in the form of openings in the side wall of the casing, the main and additional water distribution systems with water-distributing manifolds and nozzles, main and additional inclined shields, characterized in that an inclined shield directed inward upward of the body forms, together with a water mirror in the catchment basin, a trapezoidal ejection air channel. 2. The cooling tower, including the casing, the drainage basin under the casing, the upper, middle and lower air inlet windows in the form of openings in the side wall of the casing, the main and additional water distribution systems with water distributing collectors and nozzles, the main horizontal and inclined, and additional inclined panels, characterized in that a horizontal shield directed inside the housing forms together with a water mirror in the catchment basin a rectangular ejection air channel.