SU1096226A2 - Method for controlling water rotation cycle - Google Patents

Abstract

METHOD OF MANAGING A WATER CHAIN CYCLE according to aut. St. 899483, characterized in that, in order to reduce the cost of the process, an additional stream of water is supplied to one of the nozzle chambers and the quantitative relationship between the water flows to different nozzle chambers is controlled, depending on the water level in the cooling tower basin.

Description

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10 11 tz fJ i ts and 17 te ts to, I, IP The invention relates to the technology of wastewater treatment in the water-circulation cycle, which includes injection gas, zirnu, in particular, the methods of control, operation of the water-circulation cycle, and can be used in workshops of industrial enterprises, According to the main auth. No. 899483, a method for controlling the water cycle is known, consisting of an injection cooling tower for evaporating wastewater, a warming area and a heating zone, by adjusting the level in the cooling tower basin and adjusting the temperature of the water entering the cooling tower, by changing the coolant supply to the heating zone In order to improve the quality of regulation, they regulate the pressure of water entering the nozzles of the cooling tower depending on the level in the basin of the cooling tower, and the temperature of the cooling water is kept constant. A disadvantage of the known method is a wide range of pressure variations in front of the nozzles. At the same time, it is almost impossible to choose a pump that would have the optimum efficiency when operating in modes that correspond to different sections of the network characteristics. This leads to energy waste and additional capital costs due to an increase in the power factor. The purpose of the invention is to reduce the energy costs of the water cycle management process. This goal is achieved by the fact that according to the method of controlling the water cycle, consisting of an injection cooling tower with centrifugal jets for evaporation of wastewater, heat supply zone and water heating zone, by adjusting the level in the cooling basin and maintaining the temperature of the water entering In the cooling tower, by measuring the flow of coolant into the water heating zone, an additional stream of water is supplied. In one of the nozzle chambers, the proportion between the water flows supplied 1 1 to various e injector chamber depending on the level in the tower basin. The conducted studies allowed us to reveal the dependence of the degree of evaporation - f / (the ratio of the amount of evaporated water to the circulation flow rate of the liquid to the cooling tower, expressed as a percentage) in the injection cooling tower as a function of the pressure ratio P) and PJI (or equivalently, quantities) between the liquid flows, supplied to the axial and twisting chambers of a centrifugal-jet nozzle. FIG. 1 shows the dependence X f il / Pr) t in FIG. 2 is a schematic adjustment scheme implementing this method. The method is carried out as follows. The water circulation cycle with make-up water and the recycling of part of the water cycle in the technological scheme includes an injection cooling tower 1 with windows 2 for air entry and centrifugal-jet nozzles 3 located in them. From the cooling tower pool, cooled water is fed to the heat remover zone 4. Water is circulated in the cycle and the required pressure in front of the nozzles is provided by the pump 5. From the pressure line of the pump two collectors 6 and 7 are withdrawn, which are connected to two cameras of the nozzles 3: collector 6c with an axial chamber, and collector 7 with a twisting KaMepoii. The control circuit includes pressure sensors B, pressure regulators 9, level sensor 10 ,. a regulator setting out unit 11, regulating valves 12. To maintain the temperature of the water entering the cooling tower, the heated water zone 13, the sensor 14 and the temperature regulator 15, and also the valve 16 on the coolant supply line to the heated zone are intended. If a . If the amount of evaporated water decreases, the level in the catchment basin of cooling tower 1 rises above the nominal value, then the level sensor 10 gives a signal to change the reference through unit 11 to the regulators 9. Pressure regulators 9 by means of control valves 12. on lines 6 and 7 establish a new ratio of pressure R. / P2. In this case, the mode of operation of the pump remains almost unchanged. The degree of evaporation of water increases, and this leads to a decrease in the level in the catchment basin. Since the temperature of the chilled water somewhat decreases due to an increase in the degree of evaporation, with a constant heat load of the heat removal zone 4, the water temperature at the outlet from this zone will be lower than before. The temperature change signal from sensor 14 goes to controller 15, which increases the flow of heat carrier to heating zone 13 by increasing the capacity of control valve 16. Obviously, when the level in the catchment area decreases, the circuit works similarly, but the pressure ratio changes in the opposite direction.

Other control options are possible. For example, the pressure or the amount of one of the streams 6 or 7 can be kept constant, and the pressure or the amount of the second stream 7 or 6 can be adjusted depending on the required South value of the Ef / Pg ratio.

The use of this method of regulation allows the circulation pump to operate in a relatively narrow range of changes in its characteristics, corresponding to the area of optimum efficiency, reduce power consumption and reduce power loss.

Claims (1)

METHOD FOR WATER CIRCULATION CONTROL by ed. No. 899483, characterized in that, in order to reduce energy costs for the process, an additional water flow is supplied to one of the nozzle chambers and the quantitative ratio between the water flows supplied to different nozzle chambers is regulated, depending on the water level in the cooling tower basin. I