RU51186U1 - SECTIONAL COOLING TOWER - Google Patents

Abstract

The invention relates to the field of power engineering, and in particular to devices of contact devices for cooling water in water recycling systems of industrial enterprises and to the reconstruction of these devices. Known sectional cooling tower, each of the sections of which contains a housing with breathable casing and a fan, equipped with air inlets in the form of louvres and vertical water inlets in the lower part of the cooling tower housing, a water recovery system, a water distribution system in the form of a distribution manifold with distribution pipes equipped with nozzles, located in the upper part of the body, a downstream irrigation system made in the form of blocks of corrugated vertical foxes open-pore heat transfer material, such as polyvinyl chloride, with the blocks stacked in rows one below the other, and a common rectangular drainage basin with a cross-sectional area larger than the cross-sectional area of the cooling towers is placed under the sections of the sectional cooling tower; the tower rests on vertical supports located inside the air basin. A disadvantage of the known cooling tower is the low efficiency and reliability of its operation and high cost. A sectional cooling tower, each section of which contains a housing equipped with a fan, a water trap system, a water distribution system in the form of a distribution manifold with distribution pipes equipped with water-spraying nozzles located in the upper part of the housing, a downstream irrigation pump and a common catchment basin with a cross-sectional area larger than the cross-sectional area sections of cooling towers, including

air inlets, the lower edge of each of the cooling tower housings being placed at the level of the upper edge of the drainage basin with the formation of horizontal air inlets between the inner wall of the drainage basin and the cooling tower bases at a ratio ,

where F _in - the area of the air inlets of the towers;

F _c - the cross-sectional area of the cooling towers and at a distance from the upper edge of the drainage basin to the water mirror in it Where

l is the total external perimeter of the sectional cooling tower.

Description

The utility model relates to the field of heat power engineering, namely to devices of contact devices for cooling water in water recycling systems of industrial enterprises, in particular cooling towers, and to their reconstruction.

A known cooling tower comprising a pool, a cooling tower housing located above it with a fan, in the lower part of which a blower window is installed around the entire perimeter, and a droplet eliminator is installed in the upper part, over the entire cross section of the housing; in the cooling tower casing, under the droplet eliminator there is a distribution system for the cooled liquid, equipped with water-spraying nozzles, and located inside the casing in a horizontal plane. In this case, the nozzles are oriented vertically upwards (see certificate for utility model RU No. 15220, IPC F 28 C 1/00, with priority 02.22.2000, published on 09.27.2000, bulletin No. 27 // h.) .

A disadvantage of the known cooling tower is the low cooling efficiency of heated water, due to the lack of irrigation and, therefore, low heat transfer coefficient.

Known cooling tower, comprising a housing with a vertical anti-wind partition in its middle part, air inlets located longitudinally along the vertical walls of the housing in its lower part, an inclined shield above the windows inside the cooling tower housing, on both sides of the anti-wind partition, nozzles mounted on the headers of the water distribution system and drainage basin; cooling tower air inlets are equipped with adjustable louvres installed in window openings with the possibility of rotation around the axis, and additional windows are mounted above these windows with an inclined shield above them inside the cooling tower casing, and nozzles are installed opposite openings of additional air inlet windows / nozzles

both inside and outside the cooling tower / (see RU patent for utility model No. 40450, IPC F 28 C 1/00 with a priority of 05/06/2004, published on 09/10/2004, bulletin No. 25 (IV part ), 2004).

The disadvantages of the known cooling tower are the low efficiency of the cooling tower: as a result of the absence of a heat exchange nozzle-sprinkler, which leads to a deterioration in the cooling process of heated water, significant unproductive losses of water in the circulating system, due to the absence of a droplet eliminator, which leads to increased drip removal of water from the cooling tower, and to wetting of adjacent territories; and due to the presence of a horizontal shield installed inside the tower body, narrowing its live section and creating additional aerodynamic resistance to the flow of cooling air and sharply reducing its volume, as well as low reliability due to the formation of ice at negative air temperatures in connection with the implementation of vertical air inlet windows .

A sectional cooling tower is known that is closest in purpose and technical essence to the claimed one, each section of which contains a housing with breathable casing and a fan, equipped with air inlets made in the form of louvres and vertical water inlets in the lower part of the cooling tower casing, water recovery system, water distribution system in the form of a distribution manifold with distribution pipes equipped with nozzles, located in the upper part of the housing, below an irrigation system made in the form of blocks of corrugated vertical sheets of heat-transfer material with “open pores”, for example, polyvinyl chloride, with the blocks stacked in rows one below the other, and under the sectional cooling tower housings there is a common rectangular drainage basin with a larger cross-sectional area than the cross-sectional area of cooling towers

(see patent RU No. 2144124, IPC E 04 H 5/12 with priority 02/03/98, priority US 04/02/1997, publ. 01/10/2001).

A disadvantage of the known cooling tower is:

- Low work efficiency in the winter season, due to the formation of ice in the area of the vertical air inlets and on the sprinkler, which entails a decrease in the flow cross-section of the cooling tower up to the termination in some cases of the penetration of air into the cooling tower, which significantly impairs the cooling effect and leads to a sharp deterioration in fan efficiency;

- low reliability and laboriousness of operation up to the occurrence of emergencies due to collapse of the sprinkler, due to the formation of ice on it at negative temperatures due to the removal of water droplets from the tower body, as well as as a result of icing of the vertical air inlet openings of the cooling tower and water-tight casing, requiring laborious measures to eliminate icing;

- the high cost of the tower, due to its significant height and, therefore, increased construction volume due to equipping the tower with vertical air inlets, also leading to an increase in the height of the water supply and, consequently, to increased energy consumption.

The technical result of the utility model is to increase the efficiency of the cooling tower, the reliability of its operation and reduce the complexity of operation in the winter season, as well as reducing the cost of a sectional cooling tower and energy costs.

The technical result is achieved by the fact that a sectional cooling tower, each section of which contains a housing equipped with a fan,

a water trap system, a water distribution system in the form of a distribution manifold with distribution pipes equipped with water spray nozzles located in the upper part of the casing, a lower irrigation sprinkler and a common drainage basin with a cross-sectional area larger than the cross-sectional area of cooling towers, including air inlets, the lower edge of each of the casings the tower, separated from the neighboring tower by a vertical partition, is located at the top of the water collecting basin to form a horizontal air inlet between the inner wall of the catchment and cooling towers at a ratio bases

where F _in - the area of the air inlets of the towers;

F _c - the cross-sectional area of the cooling towers and at a distance from the upper edge of the drainage basin to the water mirror in it Where

i is the total external perimeter of the sectional cooling tower.

The drawing shows a sectional cooling tower.

A sectional cooling tower, each of the sections of which contains a housing 1 with a fan 2 located in its upper part, located under the fan 2, a water trap system 3, a downstream water distribution system made in the form of a distribution manifold with distribution pipes 4, equipped with water-spraying nozzles 5 and a sprinkler 6 - heat exchange nozzle in the form of blocks, or individual lattice, plate or corrugated elements from polymeric or other materials. Directly under the buildings 1 cooling towers is a common catchment basin 7 with a cross-sectional area greater than the total cross-sectional area of the buildings 1 cooling towers. Shells 1 of neighboring cooling towers

divided by vertical intersectional partitions 8. The cooling towers are mounted so that the lower edge of the cooling tower bodies 1 is located at the level of the upper edge of the drainage basin 7 with the formation of horizontal air inlets 9. The sectional cooling tower works as follows:

The water distribution system provides heated water to the cooling tower housings 1, separated by vertical intersection partitions 8, through the distribution manifold of heated water with distribution pipes 4, water is supplied to the water spray nozzles 5. The heated water passing through the downstream sprinkler 6 is a heat exchange nozzle in the form blocks, or individual lattice, plate or corrugated elements made of polymer or other materials, cooled by contact with air, m due to the vacuum created by fan 2 through horizontal air inlets 9 formed when the lower edges of the cooling tower shells 1 are located at the level of the upper edge of the drainage basin 7 between the inner wall of the cooling tower and the bases of the cooling towers when the ratio of the area of the air inlet openings to the cross-sectional areas of the cooling towers

where F _in - the area of the air inlets of the towers;

F _c - the cross-sectional area of the cooling towers and at a distance from the upper edge of the drainage basin to the water mirror in it where

i is the total external perimeter of the sectional cooling tower.

The presence of horizontal air inlets 9 in the horizontal plane between the inner wall of the drainage basin 7 and the bases of the cooling towers provides increased operational reliability in the winter season due to the exclusion of ice formation on

cooling tower, improves the operating conditions and efficiency of the cooling tower, because excludes emergency situations due to the possibility of irrigator collapse as a result of ice formation on it at negative temperatures, excludes icing of air inlets and improves heat transfer by preventing icing of the irrigator.

The claimed ratio of the area of the air inlets to the cross-sectional areas of the cooling towers and the distance from the upper edge of the drainage basin to the water mirror in it provides an increase in the efficiency of the cooling tower, guaranteeing the flow rate required for optimal heat transfer through the air inlets of the multi-section cooling tower by reducing the aerodynamic drag of the air inlets to zero.

With a decrease in the above ratio and the distance to the minimum, the cooling tower operation efficiency decreases due to the deterioration of heat transfer due to a decrease in air flow due to an increase in the aerodynamic resistance of the air inlets by 1, 2 times.

Cooled water flows into the catchment basin 7. The water trap system 3 prevents water droplets from moving outside the enclosures 1 of the cooling towers.

Each section of the proposed cooling tower can be used as an independent cooling tower.

The claimed technical solution is of interest for the reconstruction of existing cooling towers using small-sized prefabricated cooling towers installed both on the general drainage basin of the reconstructed cooling tower and on its own pallet.

Depending on the required capacity of the reconstructed cooling tower, one to several small-capacity cooling towers are placed on its catchment basin.

The proposed tower in comparison with the known one provides an increase in operating efficiency, reliability of operation and a decrease in the complexity of its maintenance in the winter season due to the creation of horizontal air inlets with the claimed ratio of the area of the air inlets of the cooling towers to the cross-sectional area of cooling towers ≥0.4 and the claimed distance h from the top the edges of the catchment basin to a mirror of water in it, preventing icing, and therefore, excluding the possibility of such emergencies in winter At the time, both the irrigation collapse, reduced performance and fan failure, as well as difficulties in eliminating the formed ice.

The proposed cooling tower is cheaper than the known one, because its height decreases by 2-5 times due to the location of the air inlets in the horizontal plane, i.e. replacing horizontal vertical air inlets eliminating ice formation; a decrease in the height of the tower entails a decrease in its building volume by 20-40%.

Only by reducing the height of the water supply to the tower due to a decrease in its height, the energy consumption at the pumps is reduced by 1.5-2 times.

Claims (1)

A sectional cooling tower, each section of which contains a housing equipped with a fan, a water trap system, a water distribution system in the form of a distribution manifold with distribution pipes equipped with water-spraying nozzles located in the upper part of the housing, a downstream irrigation pump and a common catchment basin with a cross-sectional area larger than the cross-sectional area section of cooling towers, including air inlet openings, characterized in that the lower edge of each of the cooling tower housings, placed at the upper edge of the drainage basin with the formation of horizontal air inlets between the inner wall of the drainage basin and the bases of the cooling towers at a ratio

, where F _in - the area of the air inlets of the towers; F _c - the cross-sectional area of the cooling towers and at a distance from the upper edge of the drainage basin to the water mirror in it

, where l is the total perimeter of the cooling towers.