RU2103625C1 - Spray-type cooling tower - Google Patents

Abstract

FIELD: power engineering; cooling circulating water. SUBSTANCE: cooling tower includes housing 1 with air inlet ports in lower portion, collector system 3 with injectors 4 located in upper portion of housing 1, pool 5 located under housing 1, exhaust device made in form of fan 6 with contraction ferrule 7 and diffuser ferrule 8, drip pan 9 and guide plates 10 located inside housing 1 opposite each air inlet port 2; angle of inclination of plate to level changes from 0 deg for lower plates to 90 deg for upper ones. EFFECT: enhanced efficiency. 1 dwg

Description

 The invention relates to contact coolers, in particular to cooling towers, and can be used at enterprises of the chemical and energy industries for cooling circulating water.

 Known cooling tower comprising a housing with air inlet windows in the lower part, a manifold system with nozzles located horizontally in the upper part of the housing, a pool located under the housing, an exhaust device located above the housing, a droplet eliminator and guide plates, while the cooling tower has a number of additional air intake windows in height, between which the nozzle steps are located, and the guide plates are located outside the housing opposite all the air inlets and are made rotatable [1].

 This solution has a drawback, namely, it cannot be used in spray (non-nozzle) cooling towers to distribute air over the cross section and volume of the cooling tower.

 Due to the fact that the guide plates are located outside the casing and although they are made rotatable, they cannot create a uniform air flow over the cross section and volume of the tower when it is sprayed (non-nozzle); these plates can only regulate the air flow, and its distribution over the cross section is carried out by the nozzle itself, i.e. this solution is applicable only to packed cooling towers.

 Known cooling tower comprising a housing with air inlet windows in the lower part, a manifold system with nozzles located horizontally in the upper part of the housing, a pool located under the housing, an exhaust device located above the housing, a droplet eliminator and guide plates, while the cooling tower is equipped with a nozzle located above the upper cut of the air inlet windows and below the collector system, the guide plates are installed directly in the air inlet windows, are rotatable, connected to rods, equipped with ice sensors in the form of cargo [2].

 This solution also has a drawback, namely, it cannot be used in spray (non-nozzle) cooling towers to distribute air over the cross section and volume of the cooling tower.

 Due to the fact that the guide plates are installed directly in the air intake windows, they can only be used to automatically control the air flow in winter due to the connection with rods equipped with ice formation sensors; air distribution over the cross section of the tower is carried out by the nozzle.

 The closest in technical essence and the achieved technical result is a cooling tower containing a housing with air inlet windows in the lower part, a collector system with nozzles located horizontally in the upper part of the housing, a pool located under the housing, an exhaust device located above the housing, a droplet eliminator and guide plates located opposite the air intake windows and mounted fan-shaped one above the other at an angle in the horizon [3].

 The disadvantage of this device is that the upper plate intersects the movement of air along the upper part of the window and does not create air flow along the body inside the tower.

 The objective of the invention is to distribute air over the cross-section and volume of the spray (non-nozzle) cooling tower, i.e. elimination of stagnant zones and vortex formation zones, which leads to an increase in the overall efficiency of the cooling tower.

To solve the problem in a spray tower, the guide plates are located inside the housing and the angle of inclination of the plates to the horizon varies from 0 ^o for the lower plates to 90 ^o for the upper ones.

Due to the fact that in front of each window there are several plates that are located inside the case and are fan-shaped one above the other and at an angle to the horizon, varying from 0 ^o for plates to 90 ^o for upper plates, the air entering the window is divided into several streams, each from which it is guided by plates to a specific area of the tower; thus, a uniform distribution of air over the cross section and volume of the tower is achieved, in particular, the stagnant zone in the central lower part of the tower and the swirl zone in the peripheral upper parts of the tower are eliminated. The overall efficiency of the cooling tower is improved.

 The drawing shows a longitudinal section of the proposed cooling tower.

The spray tower contains a housing 1 with air inlets 2 in the lower part, a collector system 3 with nozzles 4 located in the upper part of the housing 1, a pool 5 located under the housing 1, an exhaust device located above the housing 1 and made in the form of a fan 6 with confuser 7 and diffuser 8 rims, a droplet eliminator 9, installed between the collector system 3 and the confuser rim 7, and the guide plates 10. Moreover, several guide plates 10 are located opposite each window 2, which are fan-shaped an off over one another and at an angle to the horizontal, varying from 0 ^o to the lower plates 90 ^o for the upper plates.

 The cooling tower works as follows.

 The fan 6 carries out the air supply through the windows 2. Once on the guide plates 10, the air is divided into several streams, each of which is directed to a specific place in the tower, thereby uniformly distributing it over the section and volume of the tower. Further, air is directed through a collector system 3, equipped with nozzles 4, a droplet eliminator 9, a confuser shell 7, a fan 6 and is discharged through the diffuser shell 8 into the atmosphere.

 Through the collector system 3 he delivers hot water, which is sprayed by nozzles 4 into the flow of cold air coming from below. When this happens, the cooling water and cold water enters the pool 5.

 In the absence of a mechanism for the distribution of air in the form of plates in spray towers with low air resistance, entering through the windows 2 is sent to the fan 6 by the shortest route. In this case, a stagnation zone is formed in the lower central part of the tower and swirl zone in the upper peripheral parts.

 Thanks to the installation of several guide plates diverging fan-shaped, the possibility of uniform distribution of air over the cross-section and volume of the tower is created and stagnation and swirl zones are eliminated, while the overall efficiency of the tower is significantly improved.

Claims (1)

A spray tower comprising a casing with air inlet windows at the bottom, a manifold system with nozzles located horizontally in the upper part of the casing, a pool located under the casing, an exhaust device located above the casing, a droplet eliminator and guide plates located opposite the air inlet windows and mounted fan-shaped to each other above the other at an angle to the horizon, characterized in that the guide plates are located inside the housing and the angle of inclination of the plates to the horizon varies from 0 for lower to 90 ^o for the upper.