SU956353A1 - Device for automatic control of water desalinating plant - Google Patents

Description

FIELD OF THE INVENTION The invention relates to shipbuilding and relates to devices for the automatic control of a desalination adiabatic installation. A device is known for automatically controlling a desalination adiabatic plant having evaporators and condensers, comprising a flow sensor installed in a pipeline, a signaling device connected with its input to the output of the flow sensor, and an output to the input of the control unit, and a correction sensor of temperature, mounted on the seawater piping at the inlet to the condenser and connected by its output to the inlet of the detector 1. The disadvantage of this device is the low accuracy of the installation control. The purpose of the invention is to improve the installation control accuracy. This goal is achieved by the fact that the device is equipped with an additional flow sensor installed on the semiconductor TO INPUT detector mounted on the seawater pipe behind the condenser, and also an additional flow sensor is installed on the seawater pipeline at the evaporator inlet. The drawing shows a diagram of an apparatus for controlling a desalination adiabatic installation. The device contains an alarm device 1, a distillate flow sensor 2, an installation control system unit 3, as well as sensors and 5 temperature and flow of seawater pumped through a desalination condenser, seawater flow sensor 6 entering the evaporator. The detector 1 is connected with its input to the sensor 2 for the flow rate of the distillate, and the output to the unit 3 of the control system. One of the i-S sensors or at the same time those of the sensors that measure the operational parameters of the operating parameters that change during operation can be connected to the correction inputs of the detector. This device is included in a desalination adiabatic installation (for example, a three-chamber one) consisting of evaporation chambers, condensers 10 built in them and collectors 11 of distillate, preheater 12 with water temperature regulator 13, pumps 1, 15 and 16, respectively distillates tnyh, brine and sea water (nutrient), the ejector 17 vapor-air mixture. Collections 11 of the distillate are hydraulically connected by pipelines 18. The mechanisms and apparatus included in the desalination plant are connected by pipelines. The device operates as follows. In a desalination adiabatic installation, the sea water is pumped by the feed pump 16 through the condensers 10 of all the evaporation chambers 7-9, starting with the last chamber 9, in which the pressure (vacuum) is sequentially understood from the first chamber to the last one. An underpressure in the chambers is created by an ejector 17, which sucks the vapor-air mixture out of the chamber. In capacitors 10, the desalinated seawater is heated by transferring heat to the condensing vapors. After that, part of the seawater can be discharged, and the remaining c, which is necessary to ensure the capacity of the installation, passes through the preheater 12, which is heated by a coolant. The controller 13 maintains a constant value of the seawater temperature at the inlet to the evaporator. The water after the preheater is overheated with respect to the saturation temperature corresponding to the vacuum in chamber 7 and the evaporation. As a result of overheating, the initial water in this chamber boils and part of it evaporates, and the remaining part, having cooled down to the temperature of the Nasicena in this chamber, flows due to the pressure difference. To the next evaporation chamber. The same process is repeated in the subsequent chambers, since the vacuum in each and them is greater than in the previous one. WATER vapors are condensed in condensers and the distillate flows into collectors 11, and which, due to the pressure difference in the chambers, flows through pipelines into the collection of distillate of the last chamber 9 and is pumped out of it by the distillation pump 16 to the consumer. The brine from chamber 9 is pumped out by the pump 15. The plant capacity, the limit of the distillate consumption, depends on the inlet temperature; the evaporator, maintained by the regulator 13, the vacuum in the evaporator and the flow rate of the water entering the evaporator. At the same time, the change in the magnitude of the vacuum in the evaporator and the flow rate of the source water entering the evaporator depends on both possible malfunctions and the change in operating conditions, such as temperature and flow of seawater pumped through the condenser, possible under operating conditions. evaporator. The distillate consumption is measured by a sensor 2, the signal of which is fed to the input of the detector 1, where it is compared with a reference value determined by the reference setting value of the reference flow rate. The temperature and flow rate of seawater pumped through a condenser, affecting the magnitude of the vacuum in the evaporator, is measured by sensors k and 5. The consumption of seawater entering the evaporator, influenced by the amount of distillate produced, is measured by sensor 6. The signals from sensors -6 (depending on the operating conditions of the installation — one of them, two or all three); sensors 4-6 and compared with the measured flow rate of the distillate determined by the signal of the sensor 2. The control value in operating conditions is always lower than the measured flow rate of the distillate. If a malfunction occurs in the installation resulting in a decrease in productivity (for example, a decrease in the temperature of sea water entering the evaporator due to a malfunction of the temperature regulator 13, a decrease in the vacuum pressure in the evaporator due to a malfunction of the ejector, or leakage of the evaporator case, etc.) the signal of the distillate flow sensor 2 becomes less than the reference value corresponding to the values that occur

Claims (2)

Claim 1. A device for automatically controlling a desalination adiabatic plant having evaporators and condensers, comprising a flow sensor mounted on the pipeline, an alarm connected to the input to the output of the flow sensor, and the output to the input of the control unit, and a correction temperature sensor installed on the sea water pipeline at the inlet to the condenser and connected with its output to the input of the detector, characterized in that, in order to improve the accuracy of regulation of the installation, it is equipped with connected to the input with gnalizatora additional flow sensor mounted on the sea water piping for the capacitor. 2. The device according to π. 1, wherein the additional flow sensor is installed on the sea water pipe at the inlet to the evaporator.