SU1013347A1 - Apparatus for controlling the process of desalinating sea water - Google Patents

Abstract

A device for regulating the desalination process of sea water in the Adia & 1t desalination plant with heat carrier and sea water pipelines, condensers and a heater, containing a seawater flow sensor and the first regulator installed on the seawater pipeline, the flow control unit, the reactor, and the first water regulator, and the first regulator unit installed on the seawater pipeline, the flow control unit, and the heater. It is connected with the joked seawater flow rate sensor, and the output is connected with the first regulator, the temperature sensor installed on the seawater pipeline after the preheater, the second regulator A tangent body located on the coolant pipe and a temperature control unit, the first input of which is connected to said temperature sensor, and the output is connected to a second regulating body, characterized in that, in order to improve the accuracy of regulation, it is equipped with an additional temperature sensor installed on the seawater piping in front of the condensers and connected with its outlets with the second correction inputs of the unit (L flow control and temperature control block. co oo 4

Description

The flare is applied to shipbuilding, in-time to a device for controlling the desalination process of seawater in an adiabatic desalination plant. A device for regulating the desalination process of a naval unit in an adiabatic desalination plant with heat transfer and seawater pipelines, condensers and a heater, containing a sensor, is known. reguing an organ installed on the pipeline of a marine warmer, a flow control unit, the first input of which is connected to said sensor The sensor is equipped with a temperature sensor installed on the seawater pipeline after the iodine heater, a second regulator located on the coolant pipeline and a temperature control unit, the first input of which is connected to the temperature sensor. and the output is with the second regulator l. A disadvantage of the known device is the possibility of inconsistent change (decrease or increase) in the consumption of seawater and its temperature after the preheater while maintaining Advantage of the installation, due to the difference in the dynamic characteristics of the control units and regulatory bodies. The purpose of the invention is to improve the accuracy of regulating the process of desalination of sea water. This goal is achieved by the fact that the device for regulating the desalination of seawater in an adiabatic desalination plant with coolant and seawater pipelines, condensers and a preheater, a seawater flow sensor and the first regulator installed on the seawater pipeline, a flow control unit , the first input of which is connected with the above-mentioned seawater water flow meter, and the output from the first regulating body, a temperature sensor mounted on the seawater pipeline via The preheater, the second regulator located on the coolant pipe and the temperature control unit, the first input jcoTOporo is connected to the temperature sensor and the outlet is connected to the second regulator, equipped with an additional temperature sensor installed on the seawater pipeline in front of the condensers and connected connected to their outputs with the second correction inputs of the flow control unit and the temperature control unit. The drawing shows a block diagram of a device for regulating the desalination process of seawater. The device consists of interconnected temperature sensor 1, temperature control unit 2, first regulator 3, seawater flow sensor 4, flow control unit 5, second regulator 6, and an additional temperature sensor 7. This device is included in the adiabatic desalination plant consisting of evaporation chambers 8–10, capacitors 11 built in them and collections of 12 cystillas, preheater 13, pumps 14–16, respectively, distillate, brine and sea water (feedwater), ejector 17 exhaust steam-air mixture. 12 distillate collections are hydraulically connected by pipelines 18. The machinery and apparatus included in the desalination plant are connected by pipelines. The temperature sensor 1 is installed in the seawater pipeline after the preheater 13, the flow sensor 4 and the first regulator 3 can be installed anywhere on the sea (feed) water path, temperature sensor 7 is installed in the seawater pipeline before the capacitors 11, and the second regulator 6 - on the pipeline coolant supplied to the heater 13. The device for regulating the process of desalination of sea water in the adiabatic desalination plant works as follows. B. The adiabatic desalination unit, the desalinated seawater is pumped by the feed pump 16 through the condensers 11 of all the evaporation chambers 8-10, starting with the last chamber, 10, in which the pressure (vacuum) is successively reduced from the first chamber 8 to the last chamber 10. The vacuum in the chambers creates an ejector17 that sucks the vapor-air mixture from the evaporation chambers and depends on the flow rate and temperature of the seawater pumped through the condensers 11. The condensate. In seawaters 11, seawater is reheated by transferring to it heat of condensing vapors. The seawater then passes through a preheater 13, in which the preheater is cooled through a heat transfer medium passing through the agora b. At the exit from the warmer, the sea water is overheated with respect to the temperature of the target, corresponding to the vacuum in the first evaporation chamber 8. As a result, the neperw roar of the sea in the first chamber 8 boils, and part of it evaporates, and the other part, cooled from the saturation temperature in this chamber, flows due to the pressure difference to the next evaporation chamber. The same process is repeated in subsequent chambers, since the vacuum in each of them is greater than in the previous one. Water vapor is condensed in condensers 11, and the distillate flows down into unclean 12, of which 34 due to the pressure difference in the chambers flows through the pipe wires 18 to collector 12 of the distillate of the last chamber 1O and is pumped out of it by distillation pump 14 to beatalu. The brine from the last evaporation chamber Yu is pumped out with a brine pump 15. The flow control loop 34-5 maintains the specified value of the sea water flow, and the control loop temperature 1-2-6 - the temperature setpoint after the heater 13 at the inlet to the first chamber 8 evaporation. A temperature sensor 7 measures the temperature of the seawater inlet to the installation and sends the appropriate signal to the correct inputs of the temperature and flow control units 2 and 5. The signals of the temperature sensor 1 and the flow sensor 4 are compared in measurement circuits, respectively, 474 blocks 2 and 5 with the signals of temperature sensor 7, and the imbalances signals are output from the outputs of blocks 2 and 5 to the regulators 6 and 3, 11 and 11 above. in turn, the costs of the coolant to the heater 13 and sea water. Thus, according to a predetermined program, the temperature of the sea water before the first evaporation chamber 8 and the sea water consumption versus its temperature at the entrance to the installation is maintained. When the temperature of the seawater entering the installation decreases, the temperature decreases and the boiling point of water in the evaporation chambers decreases, and therefore the temperature difference in the chambers of the rhenium increases, causing the plant to increase its output. However, at the same time with a decrease in the incidence in the set-. According to the CIS sensor of temperature 7, the device, as described above, is rearranged according to a predetermined rate to maintain a lower temperature of sea water at the entrance to the first chamber 8 evaporating {with decreasing temperature difference in the evaporation chambers) and a smaller consumption of sea water. This invention makes it possible to reduce the intensity of scale formation on the heat exchange surfaces of the desalination plant, to increase the reliability of its operation and to reduce the complexity of its maintenance associated with the heat exchange surfaces from scale.

Claims (1)

DEVICE FOR REGULATING THE SEA WATER DESCRIPTION PROCESS in an adiabatic desalination plant with coolant and sea water pipelines, condensers and a heater, comprising a seawater flow sensor and a first regulator installed on the sea water pipeline, a flow control unit, the first inlet of which is connected to the aforementioned a seawater flow sensor, and the output with the first regulatory body, a temperature sensor mounted on the sea water pipeline after the heater, the second regulating the th body located on the coolant pipeline, and the temperature control unit, the first input of which is connected to the mentioned temperature sensor, and the output - to the second regulatory body, characterized in that in order to increase the accuracy of regulation, it is equipped with an additional temperature sensor mounted on the marine pipeline water in front of the condensers and their outputs connected with the second corrective inputs of the flow control unit and the temperature control unit.