RU15220U1 - COOLING TOWER - Google Patents

Abstract

A cooling tower comprising a pool, a housing located above it, in the lower part of which there is an air duct around the entire perimeter, and a droplet eliminator installed in the upper part of the entire cross section, a cooling liquid distribution system communicated with a number of nozzles, characterized in that the cooling liquid distribution system is located inside the housing in a horizontal plane, and the nozzles are oriented vertically upward.

Description

COOLING TOWER

The utility model relates to a power system, namely to contact heat and mass transfer devices used in water recycling systems and can be used in chemical petrochemical, oil refining, metallurgical, REFRIGERATING and other industries.

A cooling tower is known, comprising a pool, a housing located above it, in the side surface of which, at the bottom of it, an air inlet window is located around the perimeter. The inside of the cooling tower housing is filled with a nozzle with a developed surface, above which a water distribution system is mounted. An electric fan is placed above the casing (see the Handbook of heat exchangers, vol. 2, M., Energoatomizdat, 1987, p. 120, 131),

The disadvantage of such a cooling tower is the need to use an expensive nozzle and high energy consumption.

Known sectional tower cooling tower, in which a control method is implemented, comprising a tower with a water distributor located therein with spray nozzles. At the bottom of the tower is a partitioned catchment. Sensors for measuring the water temperature in the water distributor are installed on the water distributor, and sensors for measuring the water temperature in the water collector are installed in the sections of the water collector. Sensors for measuring air temperature and

its humidity. :, On the water distributor, adjustable taps and flow rate are installed above the corresponding sections of the catchment (see AS USSR No. 1809278, class / 28 С 1/00). The disadvantage of this tower is the low cooling efficiency.

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The closest in technical rigidity and the achieved positive effect and adopted by the authors for the prototype is an ejection cooler containing a pool, a tower placed above it with a cross section in the form of a regular polygon, an air inlet window with vertical and horizontal shields, made in the lower part of the tower around its perimeter , the collector of the cooled fluid in communication with a number of nozzles horizontally mounted in the air inlet window, and a horizontal visor located in the central part b shni, while the cooler is equipped with an additional row of nozzles located below the horizontally mounted nozzles, and a water trap located above the horizontal visor and made with a central opening that repeats the shape of the latter in plan, the nozzles of the additional row are installed at an angle to the horizontal and at the same angles to the radii the vectors passing through the center of the tower, their outlet openings are oriented up and located at the edge of the pool, and horizontally mounted nozzles are shifted to the periphery flax additional row of nozzles and oriented along said radius vectors (sm.pat. RF jYt 2002186, class / 28 C 1/00).

The disadvantage of this design is the reduced cooling efficiency due to the fact that the working volume of the tower is not fully used. This is due to the fact that the location of the nozzles in the window involves installing them at an angle to the vertical. After flowing out of the nozzle, the cooled water and the ejected air in the initial segment move in the same direction. However, under the influence of gravitational forces, the trajectory of the droplets of water changes, and they begin to move down and fall into the pool. The air as a result of heat and mass transfer is heated and saturated with moisture, its density decreases, which makes it move up. Thus, there is a separation of water and air, which reduces - 3 cooling efficiency. In addition, in large-sized structures, the length of the spray pattern and the geometric dimensions of the tower may be incommensurable. So, the use of nozzles in a round tower with a cross section of 1200 m is irrational, since the length of the spray jet is only 3-10 m, and the diameter of the structure is 39 m.

The purpose of the proposed utility model is to increase the intensification of heat and mass transfer.

This goal is achieved by the fact that in the cooling tower containing the pool, the housing located above it, in the lower part of which there is an air inlet window around the entire perimeter, and in the upper part along the entire cross-section there is a cap catcher, a system for distributing the cooled liquid in communication with a number of nozzles, while the system of distribution of the cooled liquid of the sawdust inside the case in the horizontal plane, and 1 unit are oriented vertically upwards.

In FIG. given a cross section of the tower.

The cooling tower contains a pool 1, a housing placed above it, made in cross section, for example, in the form of a circle, a rectangle, a regular polygon, etc. But the entire perimeter of the housing 2 has an air inlet window 3, inside the housing, in a horizontal plane there is a distribution system 4 of chilled water, to which a heated water pipe b is connected using a valve 5, the cooling water distribution system 4 is equipped with nozzles 7 that are oriented vertically upwards and placed in cross section of the cooling tower evenly. On the top 3 of the housing d, a drop eliminator 8 is installed along the Bcej section, and above it is a fan U.

The cooling tower works as follows.

Heated water coming from the water circulation system through pipeline 6 with a valve 5 is distributed using system 4 over the entire cross section of the tower and is sprayed by nozzles 7, filling the working volume of the tower. The water droplets are cooled, rising together with the air ejected through the air inlet window 3. When the point at which the liquid flow velocity is quenched is reached, the droplets begin to move down under the action of gravitational force, continuing to cool by the oncoming air flow, and collect in basin I, Air stream with small with drops, continuing to move upward, a droplet eliminator 8 passes and leaves the tower due to natural draft or by means of a fan 9. The cooled water from pool I returns to the water circulation system.

The proposed utility model in comparison with the prototype and other known technical solutions has the following advantages:

-increase in intensification of heat and mass transfer;

-increase the reliability of the cooling tower;

-simplification of the design;

-improvement of the ecology of the environment.

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Authors:, V.V. Zelentsov

 B.S. Opekunov

Claims (1)

A cooling tower comprising a swimming pool, a housing located above it, in the lower part of which an air duct is installed around the entire perimeter, and a droplet eliminator is installed in the upper part along the entire cross section, a cooling liquid distribution system communicated with a number of nozzles, characterized in that the cooling liquid distribution system is located inside the housing in a horizontal plane, and the nozzles are oriented vertically upward.