RU2493520C1 - Water reuse system - Google Patents

Abstract

FIELD: power engineering.SUBSTANCE: water reuse system with application of cooling towers comprises cooling towers connected to each other by hydraulic circuits of water preparation and consumption, at the same time cooling towers have separate hydraulic circuits of water preparation and consumption, every of connected cooling towers comprises a body, in the lower part of which there are at least two tanks for water collection, which are connected to each other with a compensating pipe, providing for hydraulic independence of working water preparation and consumption circuits, at the same time one tank is connected with a pump, which supplies water cooled in the cooling tower to the consumer, and this water again arrives via a valve along the pipeline into the second tank, from which the heated water with a pump via a filter is supplied along a pipeline into a header with nozzles placed in the upper part of the cooling tower body, and in the section between the filter and the valve there is a system of control of hydraulic resistance of the filter, comprising a pressure gauge and a valve, the body of every nozzle is made in the form of a supply nipple with a hole for liquid supply from the manifold, and a coaxially connected cylindrical cartridge, and coaxially to the body, in its lower part, there is a nozzle connected, made in the form of a centrifugal swirler in the form of a dead cylindrical insert with at least three tangential inputs in the form of cylindrical holes, at the same time in the end surface of the centrifugal swirler there are serially connected and coaxial between each other and the body axial conical and cylindrical throttling holes, and the centrifugal swirler is installed in the cylindrical chamber of the body to create a circular cylindrical chamber to supply liquid to tangential inputs of the centrifugal swirler and is connected to three chambers, installed in series and coaxially to it: conical, cylindrical, diffuser output chamber, besides, chambers are installed in such a manner that the output of one chamber is the input for the other one, at the same time tangential inputs are made in the form of channels, which are tangentially arranged to the inner surface of the insert.EFFECT: increased efficiency of operation of contact coolers.2 dwg

Description

The invention relates to contact coolers, in particular to cooling towers, and can be used at thermal power plants for cooling circulating water.

The closest technical solution to the claimed object is a solution for A. with. USSR No. 435442, С02В 1/10 of 07/04/72, including a water recycling system using cooling towers interconnected by hydraulic circuits for the preparation and consumption of water (prototype).

The disadvantage of this method is the relatively low efficiency due to the low degree of atomization of the liquid by nozzles and uneconomical due to water overruns due to the absence of a plate sprinkler and a droplet eliminator.

The technical result is an increase in the performance of contact coolers.

This is achieved by the fact that in a water recycling system using cooling towers interconnected by hydraulic circuits for preparing and consuming water, each of the interconnected cooling towers contains a housing, at the bottom of which at least two water collection tanks are located, which are connected between each other by a compensation pipe, which ensures hydraulic independence of the circuits for the preparation of working water and its consumption, while one tank is connected to a pump that supplies water cooled in the cooling tower to the consumer, which again passes through the valve through the pipeline to the second tank, from which heated water is pumped through the filter through the filter and the valve to the manifold with nozzles located in the upper part of the cooling tower, and a filter hydraulic resistance control system is installed in the area between the filter and the valve consisting of pressure gauge and valve.

Figure 1 shows a diagram of a circulating water supply system with cooling towers having separate hydraulic circuits for the preparation and consumption of water, figure 2 is a diagram of a nozzle.

The reverse water supply system with cooling towers having separate hydraulic circuits for preparing and consuming water (Fig. 1) includes a cooling tower housing 1 (a variant with several parallel connected cooling towers is possible - not shown in the drawing), at least at the bottom of which two tanks for collecting water: tank 2 and tank 12 with a recharge system 3 of water used for evaporation. Tanks 2 and 12 (containers) are interconnected by a compensation pipe that provides hydraulic independence of the circuits for the preparation of working water and its consumption.

The tank 2 is connected to the pump 6, which supplies the water cooled in the cooling tower to the consumer 8. In the area between the pump 6 and the consumer 8, a system for monitoring the hydraulic resistance of the system is installed, consisting of a pressure gauge 9 and valve 10. After heating the water in consumer 8, it again enters through the valve 11 through a pipe 4 to a second tank 12, from which heated water is pumped through a filter 7 and a valve 17 through a manifold 14 to nozzles 5 located in the upper part of the cooling tower housing.

The water is cooled by a counter flow of air coming in counterflow from below and the cycle of the heat and mass transfer process is repeated. In the area between the filter 7 and the valve 17, a hydraulic resistance control system for the filter 7 is installed, consisting of a pressure gauge 16 and a valve 15. A nozzle 5 for spraying liquids is located on the manifold.

Each of the nozzles (figure 2) includes a housing 18, which is made in the form of a supply fitting with an opening 25 for supplying fluid from the line, and a cylindrical sleeve 19 coaxially connected to it with an external thread 20. Coaxially to the housing 18, in its lower the parts are connected by means of a sleeve 21 with an internal thread, a nozzle 22 made in the form of a centrifugal swirl 23 of a fluid flow in the form of a blind cylindrical insert 29 with at least three tangential inlets 30 in the form of cylindrical holes. The sleeve 21 is part of the nozzle 22 and is mounted coaxially and coaxially with respect to the centrifugal swirler 23. In the end surface of the centrifugal swirl 23 are made axially conical 27 and cylindrical 28 throttle openings, coaxial with each other and the body 18.

A centrifugal swirl 23 is mounted in a cylindrical chamber 26 of the housing with the formation of an annular cylindrical chamber 24 for supplying fluid to the tangential inlets 30 of the centrifugal swirl 23 and is connected to three chambers installed in series and coaxial with it: conical 31, cylindrical 32, diffuser output chamber 33, and the chambers set so that the output of one camera is the input to another. The tangential inputs 30 are made in the form of channels tangentially located to the inner surface of the insert 29.

The water recycling system using cooling towers works as follows.

The cooling effect in the tower is achieved by evaporating 1% of the water circulating through the tower, which is sprayed by nozzles 5 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. The simplest hydraulic circuit of an individual tower used for one service site is shown in FIG. Water from cooling tower 1 enters tank 2, from where it is supplied to consumer 8 by a circulation pump 6 and then to cooling tower 1. Here, the return water from consumers 8 settles in storage tanks (tanks) 2 and 12, the volume of which is estimated at about 5-10 minutes of installation. From it, the pump 13 (pumps) of the preparation of the working fluid pump water to the evaporative cooling towers 1. From the cooling tower, the cooled 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 absolutely not necessary to constantly adjust the power of the cooling towers in accordance with the requirements of the user. Cooling tower fans can simply operate on / off. In addition, each such tower always works at full load and provides the maximum possible cooling of water for given weather conditions. Both schemes are not. susceptible to frost, because cooling towers are completely drained into storage tanks installed indoors or located underground.

The nozzle of the spray device operates as follows. In the cavity of the insert 29, which performs the function of a centrifugal fluid swirler 23, a vortex is formed, which swirls a stream of fluid flowing out of the cylindrical 28 throttle hole. The swirling fluid flow in the cavity of the insert 29 is formed by mixing the jets flowing from the tangentially directed channels 30. At the exit from the cavity of the insert 29 a fluid flow is formed, characterized by a constant tangential velocity. The angular velocity of the swirling fluid flow in the channel of the nozzle 22 of the atomizer determines the value of the spray angle of the generated gas-droplet flow.

The magnitude of the tangential velocity in the cavity of the insert 29 depends on the ratio of the total cross-sectional area of the tangential channels 30 and the cross-sectional area of the axial cylindrical 28 throttle bore. Formed in a centrifugal swirler 23 swirling fluid flow enters the inlet of the conical chamber 31. When passing sections 32 and 33, an accelerated fluid flow is formed. Intensive formation of cavitation bubbles in a swirling fluid flow occurs in the diffuser outlet chamber 33.

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 condition, causing deformation and collapse of the irrigator due to additional loads from the ice formed on it. Therefore, in the winter period, fluctuations in thermal and hydraulic loads should not be allowed, it is necessary to ensure an even distribution of the cooled water over the irrigated area and not to allow a decrease in the density of irrigation in individual areas.

Claims (1)

A recycling water supply system using cooling towers containing cooling towers interconnected by hydraulic circuits for preparing and consuming water, the cooling towers having separate hydraulic circuits for preparing and consuming water, each of the interconnected cooling towers containing a housing, at least at the bottom of which , two tanks for collecting water, which are interconnected by a compensation pipe that provides hydraulic independence of the circuits for the preparation of working water and its consumption besides, one tank is connected to the pump, which supplies the water cooled in the cooling tower to the consumer, which again flows through the valve through the pipeline to the second tank, from which heated water is pumped through the filter and valve to the manifold with nozzles located in the upper part the cooling tower housing, and in the area between the filter and the valve, a filter hydraulic resistance control system is installed, consisting of a manometer and a valve, characterized in that the housing of each of the nozzles is made in the form of a supply a nozzle with an opening for supplying fluid from the line and a cylindrical sleeve coaxially connected to it, and a nozzle made in the form of a centrifugal swirler in the form of a blind cylindrical insert with at least three tangential inlets in the form of cylindrical holes is connected coaxially to the body in its lower part at the same time, axial conical and cylindrical throttle openings are made in series in the end surface of the centrifugal swirl, and the centrifugal swirl the spruce is installed in the cylindrical chamber of the housing with the formation of an annular cylindrical chamber for supplying fluid to the tangential inlets of the centrifugal swirl and is connected to three chambers installed in series and coaxial to it: a conical, cylindrical, diffuser output chamber, and the chambers are installed in such a way that the output of one chamber is input for another, while the tangential inputs are made in the form of channels tangentially located to the inner surface of the insert.