RU2669226C1 - Combined cooling tower - Google Patents

Abstract

FIELD: heat exchange.SUBSTANCE: invention relates to heat power engineering, in particular to heat exchangers, and can be used in circulating water supply systems of thermal power plants and industrial enterprises where tower and/or fan cooling towers are used. Combined cooling tower includes a hull in the form of an exhaust tower with air inlet windows in the lower part, a water-catching device, catchment basin placed under the hull of the cooling tower, a water distribution system with spray nozzles, the outlets of which are directed upwards, an irrigation device, spray jets, recirculating water supply system has separate hydraulic circuits for the preparation and consumption of water, at that, in the bottom of the cooling towers bodies, at least two water collecting tanks are located, which are connected to each other by a compensation pipe, ensuring the hydraulic independence of the process water preparations and its consumption loops, at that, one tank is connected to a pump, which supplies water cooled in the cooling tower to a consumer, which again enters via a valve along a pipeline into the second tank, from which heated water is sent via a pump with a filter and a valve along a pipeline to a header with nozzles, placed in the cooling tower body upper part, and in the section between the filter and the valve, a hydraulic filter resistance monitoring system is installed, consisting of a manometer and a valve, each of the spray nozzles of the water distribution system comprises a housing with a swirl chamber and a nozzle, the housing is in the form of a supply fitting with a central hole and rigidly connected thereto and a coaxial cylindrical sleeve with an internal thread and an expansion chamber coaxial to the housing, at the same time, a nozzle is connected to the shell at its lower part through a thread. This nozzle is made in the form of an inverted cup, in the bottom of which there is a turbulent swirler of the liquid flow with at least two inclusions to the nozzle axis in the form of cylindrical holes located in the end surface of the nozzle, where also a central cylindrical throttle opening is made connected to the nozzle mixing chamber, in series connected to the diffuser outlet chamber, and in the lower part of the mixing chamber of the nozzle a hollow conical swirler is fixed, its conical shell is fixed by means of at least three spokes fixed at one end to the conical shell of the swirler in its upper part, and the other end – in the annular groove made on the inner surface of the mixing chamber, and on the outer surface of the hollow conical swirler a screw cutting is made.EFFECT: increased efficiency of secondary energy resources by means of increasing the value of the active area of the cooling tower without increasing the aerodynamic drag.1 cl, 2 dwg

Description

The invention relates to a power system, in particular to heat exchangers, and can be used in water recycling systems of thermal power plants and industrial enterprises where tower and / or fan cooling towers are used.

The closest in technical essence and the achieved result to the claimed object is a cooling tower containing a housing with air inlet windows in the lower part, a water distribution system with nozzles directed upward by the outlet openings, and located symmetrically to the longitudinal axis of the exhaust tower, a drainage basin located under the cooling tower housing a device made in the form of a fan and located above the housing, a water trap device and a droplet-holding device in the form of a spatial design (RF patent N 2455602, F28C 1/00. prototype).

A disadvantage of the known device, where water is cooled from the surface of a finely fractional droplet stream, is the relatively small range of hydraulic and thermal loads under which this type of cooling tower effectively cools the circulating water flow.

A technically achievable result is an increase in the efficiency of using secondary energy resources by increasing the active region of the tower without increasing aerodynamic drag.

This is achieved by the fact that in a combined cooling tower containing a housing in the form of an exhaust tower with air inlets in the lower part, a water trap, a drainage basin located under the cooling tower housing, a water distribution system with spray nozzles, the outlet openings pointing upwards, an irrigation device, spray nozzles , the water recycling system has separate hydraulic circuits for the preparation and consumption of water, while at the bottom of the cooling tower housing there are at least two tanks for collecting water, which are interconnected by a compensation pipe, ensuring hydraulic independence of the circuits for the preparation of working water and its consumption, while one tank is connected to a pump that delivers the water cooled in the cooling tower to the consumer, which again flows through the valve through the pipeline into the second tank, from which heated water is pumped through the filter through the filter and the valve through the pipeline to the manifold with nozzles located in the upper part of the tower tower, and in the area between the filter and the filter is installed using a gauge and a valve, each of which spray nozzles of the water distribution system contains a housing with a swirl chamber and a nozzle, the housing is made in the form of a supply fitting with a central hole, and rigidly connected to it and a coaxial cylindrical sleeve with an internal thread and an expansion chamber, coaxial to the housing, while coaxially to the housing, in its lower part is connected to the sleeve by means of a thread a nozzle made in the form of a a returned glass, in the bottom of which a turbulent swirl of a fluid flow is made with at least two inlet in the form of cylindrical holes located in the end surface of the nozzle, inclined to the nozzle axis, where a central cylindrical throttle hole is also connected to the nozzle mixing chamber connected in series with a diffuser outlet chamber, and in the lower part of the nozzle mixing chamber a hollow conical swirl is fixed, the conical shell of which is fixed by It least three spokes fixed at one end to a conical shell swirler at its upper part, and the other end - in an annular groove formed on the inner surface of the mixing chamber and on the outer surface of the hollow conical swirler formed helical cutting.

In FIG. 1 shows a diagram of a combined cooling tower with a reverse water supply system having separate hydraulic circuits for the preparation and consumption of water, FIG. 2 - an embodiment of the spray nozzles 7 of the water distribution system 3.

The combined cooling tower contains an exhaust tower (or fan case) 1, a water trap 2, a water distribution system 3, an irrigation device 4, air inlets 5, a drainage basin 6. The involute-type spray nozzles 7 of the water distribution system 3 are located at a distance of (0.1 ÷ 1, 0) × h from the upper boundary of the irrigation device 4, where h is the height of the irrigation device.

The reverse water supply system has separate hydraulic circuits for preparing and consuming water for the cooling tower (a variant with several parallel connected cooling towers is possible - not shown in the drawing); it contains two tanks for collecting water: tank 8 and tank 9 with a recharge system 10 of the water spent on evaporation. Tanks 8 and 9 (tanks) are interconnected by a compensation pipe that provides hydraulic independence of the circuits for the preparation of working water and its consumption.

The tank 8 is connected to a pump 20, which supplies the water cooled in the cooling tower to the consumer. In the area between the pump 20 and the consumer, a system for monitoring the hydraulic resistance of the system is installed, consisting of a pressure gauge 13 and valve 14. After heating the water in the consumer, it again enters through the valve 12 through the pipe 11 into the second tank 9, from which the heated water by the pump 18 through the filter 19 and the valve 17 is piped into the water distribution system 3 with nozzles 7 located in the upper part of the cooling tower irrigation device 4.

The water is cooled by a counter flow of air coming in counterflow from below and the cycle of heat and mass transfer process is repeated. In the area between the filter 19 and the valve 17, a hydraulic resistance control system for the filter 19 is installed, consisting of a pressure gauge 16 and a valve 15.

A possible embodiment of the spray nozzles 7 of the water distribution system 3 (Fig. 2).

Each of the spray nozzles 7 (Fig. 2) of the water distribution system 3 includes a housing 21, which is made in the form of a supply fitting with a central hole 23, and rigidly connected to it and a coaxial cylindrical sleeve 22 with an internal thread 25. An expansion chamber is located in the cylindrical sleeve 22 24, coaxial to the housing. In this case, coaxially to the housing, in its lower part, a nozzle 26 made in the form of an inverted cup is connected to the sleeve 22 by means of a thread 25, in the bottom 27 of which a turbulent swirl of a fluid flow is made with at least two inlet in the form of cylindrical openings 29 and 30 located in the end surface of the nozzle 26 formed by its bottom 27. In the end surface of the nozzle 26, a central cylindrical throttle hole 28 is also connected to the mixing chamber 31 of the nozzle, in series ennoy diffuser with outlet chamber 32. Moreover, the effective area of flow sections of inclined cylindrical holes 29 and 30, taken in combination, and the center hole 28 are equal.

In the lower part of the nozzle mixing chamber 31, a hollow conical swirl 35 is fixed, the conical shell of which is fixed by means of at least three spokes 33 fixed at one end on the swirl conical shell in its upper part and the other end in the annular groove (in the drawing not shown), made on the inner surface of the mixing chamber 31. On the outer surface of the hollow conical swirl 35 made screw thread 34.

Vortex nozzle operates as follows.

The sprayed liquid enters the housing 21 through the central hole 23, then into the expansion chamber 24, coaxial to the housing 21. After the chamber 24, the fluid is directed to the nozzle 26, where it is distributed in several directions: the first is sent through the central cylindrical throttle hole 28 to the mixing chamber 31, and the second — into a turbulent swirl of a fluid flow with inlet inclined to the nozzle axis in the form of cylindrical holes 29 and 30, also connected to the mixing chamber 31 of the nozzle, where during the interaction of these encountered flows Odita crushing them to form a turbulent flow heading to the diffuser outlet chamber 32, where the additional fragmentation of liquid droplets when they collide with each other due to the expanding of the turbulent fluid flow.

The use of a nozzle as a finely dispersed sprayer of the described design allows one to obtain a stream of droplets of finely dispersed surfactant that is uniform in volume in the range of droplet diameters from 30 to 150 microns with a supply pressure of no more than 1 MPa.

Combined cooling tower with a circulating water supply system operates as follows.

An exhaust tower (fan case) 1 provides air draft that enters the combined cooling tower through the air inlet windows 5. Once in the area occupied by the irrigation device 4, the air flow equalizes its velocity field, and active heat removal takes place here. Next, the air is directed through a water distribution system 3, equipped with spray nozzles 7, a water trap 2 and is released into the atmosphere. Through the water distribution system 3, hot circulating water is supplied, which is sprayed upward by the directed outlet, spraying nozzles 7 into the stream of air coming from below cooled in the irrigation device 4. Here, the cooling of the hot circulating water takes place, and the more intense, the greater the pressure of the water on the spray nozzles 7. The pressure of the water cooled before the spray nozzle 7 is in the range 0.2 ÷ 1.0 atm. Hence, the aforementioned limitation of the elevation of the placement of the spray nozzles 7 is to provide as much pressure of the cooled water on them as possible, which creates an active region of the small fraction droplet stream.

The cooling effect in the tower is achieved by evaporation of 1% of the water circulating through the tower, which is sprayed by nozzles 7 and flows into the tank in the form of a film through a complex system of irrigation channels to meet the flow of cooling air pumped by fans (not shown in the drawing). An effective droplet separator reduces water loss due to drip entrainment. The amount of droplet moisture carried away by the air flow depends on the density of irrigation and at a maximum value of 25 m ³ / (hour m ² ) does not exceed 0.1% of the volumetric flow rate of the cooled water through the cooling tower.

One of the important points for the most efficient use of cooling towers in a water circulation system is the optimal choice of hydraulic connection circuit diagrams. Hydraulic circuit diagrams may vary depending on the number of cooling towers used in one circuit, as well as on the nature of the consumer. The range of regulation of cooling tower performance is determined by the nature of the consumer. In the field of industrial construction, especially when the water flow circulating through the consumer cooler is noticeably less than the water flow circulating through the cooling towers, the diagram shown in the drawing is applied. Here, the return water coming from consumers 21 is settled in storage tanks (tanks) 8 and 9, the volume of which is calculated for about 5-10 minutes of operation of the installation. From the tank 9, the pump 18 (pumps) of the working fluid preparation circuit pumps water to the irrigation device 4 of the evaporative cooling tower. From the cooling tower, chilled water enters a similar bath (tank). The main distinguishing feature of such a scheme is the hydraulic independence of the circuits for the preparation of working water and consumption, provided by the presence of a compensation pipe between the tanks (tanks). One container with a partition providing overflow between its parts can also be used. As a result of this, it is not necessary to constantly adjust the power of the towers in accordance with the requirements of the user. Cooling tower fans can simply operate on / off. In addition, each such cooling tower always works at full load and provides the maximum possible cooling of water for given weather conditions. Both circuits are not sensitive to frost, since the cooling towers are completely drained into storage tanks installed indoors or located underground.

In winter, the operation of cooling towers can be complicated due to the freezing of their structures, especially this applies to cooling towers located in harsh climatic conditions. Freezing of cooling towers can lead to an emergency state, causing deformation and collapse of the irrigator due to additional loads from the ice formed on it. Therefore, during the winter period, fluctuations in thermal and hydraulic loads should not be allowed.

The proposed combined cooling tower increases the cooling depth of circulating water by 2 ÷ 4 ° C in comparison with the cooling level of traditional cooling towers with a film or drip-film irrigation device, which practically brings this cooling tower closer to the cooling towers in terms of cooling efficiency of circulating water. If deeper water cooling for a particular power plant is not necessary, then by performing the combined heat and mass transfer in the cooling tower, the unit capacity of tower or fan-type cooling towers can be increased by 20–30%. The implementation of the invention is not associated with additional capital investments in the estimate for the construction of a new or reconstruction of an existing cooling tower.

Claims (1)

Combined cooling tower, comprising a casing in the form of an exhaust tower with air inlet windows at the bottom, a water trap, a drainage basin located under the casing of the cooling tower, a water distribution system with spray nozzles, the outlet openings pointing upwards, an irrigation device, spray nozzles, and a reverse water supply system hydraulic circuits for the preparation and consumption of water, with at least two ba in the lower part of the cooling tower housing and for collecting water, which are interconnected by a compensation pipe, ensuring hydraulic independence of the circuits for the preparation of working water and its consumption, while one tank is connected to a pump that delivers the water cooled in the cooling tower to the consumer, which again enters through the pipeline through the valve into the second tank, from which heated water is pumped through the filter and valve through a pipeline to a manifold with nozzles located in the upper part of the cooling tower housing, and a system is installed between the filter and the valve him control the hydraulic resistance of the filter, consisting of a manometer and valve, characterized in that each of the spray nozzles of the water distribution system contains a housing with a swirl chamber and a nozzle, the housing is made in the form of a supply fitting with a central hole, and rigidly connected to it and a coaxial cylindrical sleeve with internal thread and expansion chamber, coaxial to the housing, while coaxially to the housing, in its lower part is connected to the sleeve by means of a thread a nozzle made in the form of an inverted akana, in the bottom of which a turbulent swirl of a fluid flow is made with at least two inputs inclined in the form of cylindrical holes located in the end surface of the nozzle, where a central cylindrical throttle hole is connected to the mixing chamber of the nozzle connected in series with a diffuser outlet chamber, and in the lower part of the mixing chamber of the nozzle a hollow conical swirl is fixed, the conical shell of which is fixed by at least three x knitting needles fixed at one end on the conical shell of the swirl, in its upper part, and the other end in the annular groove made on the inner surface of the mixing chamber, and screw cutting is made on the outer surface of the hollow conical swirl.

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