RU2295014C1 - Airflow control method and device for cooling tower - Google Patents

Abstract

FIELD: industrial buildings forming part of cooling plants, particularly cooling towers for enterprisers and power plants.

SUBSTANCE: air flow control device comprises air-guiding deflector and rotary jalousie gate sections installed on pile foundation base or on water catchment basin wall and extending at 45-135° angles to horizontal surface. Gate position is regulated by means of manual drive or with the use of automatic drive installed inside air-guiding deflector. Rotary jalousie gates are made of thin sheet material and have individual drives, which provide independent upper and lower gate section operation, arranged within the limits of each section. Air flow control method involves regulating gate opening through angle, which provides design specific air flow rate; closing upper and lower gates of rotary jalousie gate sections in dependence of change of atmospheric air temperature and hydraulic and heat load of cooling tower.

EFFECT: increased efficiency of air flow regulation in dependence of atmospheric air temperature and hydraulic and heat load.

6 cl, 5 dwg

Description

The invention relates to tower and fan cooling towers of an evaporative type of industrial enterprises and power plants, is intended to reduce the negative impact of wind on their work, improve their cooling efficiency and can be used to distribute air over their irrigation area, to control the volume and direction of air supply, depending on changes in its hydraulic and thermal loads, changes in meteorological parameters, wind direction and speed.

The cooling tower is an atmospheric cooler, the cooling depth of which largely depends on the direction and speed of the wind at its base. The pulsation and turbulence of atmospheric air flows creates air turbulence in the tower, through blowing and removal of water from under the irrigation space.

A known method of supplying air to the tower through the air inlets at its base. The method is carried out by the device of the guide visor [1].

The disadvantage of this method is the uneven flow of air into the tower, the dependence of its flow and distribution over the irrigation area on the direction and speed of the wind, the inability to direct and distribute air over the irrigation area, to control the volume of its flow depending on changes in its hydraulic and thermal loads, changes in meteorological parameters, direction and wind speed.

A known method of supplying and regulating air. The method is carried out by the device of hinged and rotary shields of the louvre type on the air inlet windows [1].

The disadvantage of this method is the uneven flow of air into the tower, the dependence of its flow and distribution over the irrigation area on the direction and speed of the wind, the inability to direct and distribute air over the irrigation area, to control the volume of its flow depending on changes in its hydraulic and thermal loads, changes in meteorological parameters, direction and wind speed, susceptibility to freezing.

The present invention eliminates these disadvantages. The technical result of the invention is achieved in that the flow of air into the tower and distribution over its area of irrigation is ordered by stratification into independent layers along the height and perimeter of the air inlet window, each of which receives its own trajectory. The change in the trajectory of air movement and the volume of its intake is regulated depending on the direction and speed of the atmospheric wind, changes in the hydraulic and thermal loads of the tower, changes in meteorological parameters, while the flow of air into the tower can be completely stopped or stopped in separate sections of the air inlet window.

A device for implementing the method, comprising an air guide visor 1, comprises sections 2 of rotary louvres of thin sheet material 3, installed at an angle β = 45-135 ° to the horizontal surface on the pile foundation base 4 or on the wall of the basin of the catchment basin 5, while controlling the position of the wings is made by a manual 6 or automatic drive 7, while the automatic drive is installed inside the air guide visor. Rotary louvre shutters within the section can have separate drives for independent operation of the upper and lower shutters in a ratio of 4: 1 ÷ 1: 4. The sections of the rotary louvre shutters are made with a width of A = 0.4-3.0 m, are installed along the height of the air inlet window, while the lower edge of the sections is located from the axis (forming the outer surface) of the frame or shell of the tower, at its base, at a distance L = 0,0 -5.5 m. Rotary louvre shutters by rotation around their axis can be installed at any arbitrary fixed angle, including the closed position. Rotary louvre shutters are made in the form of a rectangular figure with an area of 0.04-3.0 m ² , while the edges of the long sides are bent in opposite directions, each at an angle α = 90-120 °, or in the form of a rectangular figure having a wavy surface with an area of 0 , 04-3.0 m ² .

The device operates as follows.

At negative temperatures of atmospheric air, in the absence of a thermal load of the tower and until its specific value of 10-15 Mcal / m ² h and a hydraulic load of 3-5 m ³ / m ² m are reached, the rotary louvre shutters 3 are set to the closed position, and the air does not enter the cooling tower. As the heat and hydraulic loads increase, the lower leaflets of the sections of the rotary louvre shutters are opened and set at an angle that provides the calculated value of the specific air flow rate, while the upper leaflets of the sections of the rotary louvre shutters are in the "closed" position. The incoming air, regardless of the intensity of its turbulence and pulsation, is cut by rotary louvre shutters into beds, each of which receives its own path of flow and distribution over the irrigation area of the cooling tower, depending on the installation angle of the louvered rotary shutters. The upper flaps of the sections of the rotary louvre shutters are opened and set at an angle that, together with the lower flaps, provides the calculated value of the specific air flow rate and its effective distribution over the area of cooling tower irrigation, at a specific heat load of 25-150 Mcal / m ² h.

At positive temperatures of atmospheric air, in the absence of thermal load of the tower, the rotary louvre shutters 3 are set to the "closed" position and no air enters the tower. As the heat and hydraulic loads increase, the lower shutters of the sections of the rotary louvre shutters are opened and set at an angle that provides the calculated value of the specific air flow rate, while the upper part of the shutters is in the “closed” position. The incoming air, regardless of the intensity of its turbulence and pulsation, is dissected by rotary louvre shutters into formations, each of which receives its own path of flow and distribution over the area of the tower irrigation depending on the angle of their installation. The upper shutters of the sections of the rotary louvre shutters are opened and set at an angle that, together with the lower shutters, provides the calculated value of the specific air flow rate and its effective distribution over the area of the tower irrigation, at a specific heat load of 25-150 Mcal / m ² h and a hydraulic load of 5-15 m ³ / m ² hours

The implementation of the method is described in the description of the operation of the device.

Figure 1 shows a section of an air control device.

Figure 2 and figure 3 shows an air control device.

In Fig.4 and Fig.5. sections of rotary louvre shutters are shown.

Information sources

1. B.S. Farforovsky, V. B. Farforovsky. Coolers of circulating water of thermal power plants. Energy, Leningrad Branch, 1972, Ch. 4, p. 45, 87.

Claims (6)

1. Device for air regulation in the tower, containing an air guide visor, sections of rotary louvre shutters installed at an angle to the horizontal surface and made with a manual drive to control the position of the rotary louvre shutters, characterized in that it is equipped with an automatic drive to control the position of the rotary louvre shutters in depending on changes in atmospheric air temperature, hydraulic and thermal loads of the cooling tower, wind direction and speed, located in the inside of the air guide visor, the sections of the rotary louvre shutters are installed on a pile foundation base or on the wall of the basin of the catchment basin at an angle of 45-135 ° to the horizontal surface, and the rotary louvre shutters are made of thin sheet material and within the section with separate drives for independent operation of the upper and lower cusps. 2. The device according to claim 1, characterized in that the ratio of the upper and lower rotary louvre shutters with separate drives for independent operation within the section is 4: 1 ÷ 1: 4. 3. The device according to claim 1, characterized in that the sections of the rotary louvre shutters are made of a width of 0.4-3.0 m and are installed along the height of the air inlet window, while the lower edge of the sections is located from the axis of the frame or shell of the tower at a distance of 0.0 -5.5 m. 4. The device according to claim 1, characterized in that the rotary louvre shutters are made to rotate around its axis and install at any arbitrary fixed angle, including the closed position. 5. The device according to claim 1, characterized in that the rotary louvre shutters are made in the form of a rectangular figure with an area of 0.04-3.0 m ² , while the edges of their long sides are bent in opposite directions, each at an angle of 90-120 °. 6. The method of air regulation in the tower using the device according to claims 1-5, characterized in that at negative temperatures of atmospheric air, in the absence of thermal load of the tower and until its specific value of 10-15 Mcal / (m ² h) and the value of hydraulic loads of 3-5 m ³ / (m ² h), the rotary louvre shutters are set to the “closed” position, and air does not enter the cooling tower, as the heat and hydraulic loads increase, the lower shutters of the sections of the rotary louvre shutters are opened and installed on the angle that provides the calculated value of the specific air flow rate, the incoming air, regardless of the intensity of its turbulence and ripple, is cut with rotary louvre shutters into layers, each of which is given a path of flow and distribution over the irrigation area of the tower depending on the installation angle of the louvered rotary shutters, when the specific heat load reaches 25-150 Mcal / (m ² h), the upper shutters of the sections of the rotary louvre shutters are opened and set at an angle, providing together with the lower flaps, the calculated value of the specific air flow rate and its effective distribution over the irrigation area of the cooling tower, and at positive atmospheric temperatures and in the absence of thermal load of the cooling tower, the rotary louvre shutters are set to the “closed” position and air does not enter the cooling tower, as it grows thermal and hydraulic loads open the lower leaves of the sections of the rotary louvre shutters and set them at an angle that provides the calculated value of the specific consumption the air entering this air, regardless of the intensity of its turbulence and pulsation, is cut by rotary louvre shutters into formations, each of which is given a path of flow and distribution over the irrigation area of the tower depending on the installation angle of the rotary louvre shutters, when the specific heat load reaches 25 -150 Mcal / (m ² h) and a hydraulic load is 5-15 m ³ / (m ² h) opening the upper flap section pivoting louvre slats and set them at an angle, which provides jointly with LO calculated value of flaps specific air flow and its distribution by efficiently cooling tower irrigation area.

Images