SU1134843A1 - Automatic control system for water feed to multiflow steam generator of power-generating unit - Google Patents

Abstract

AUTOMATIC CONTROL SYSTEM OF WATER SUPPLY IN MULTI-FLOW STEAM GENERATOR PAN POWER BLOCK POWER PLANTS, containing feed pumps that regulate the ICP on each and the current, power controllers, whether: a pc unit, pcry.ui.ui flow control circuits, in the same time, I can apply the same. Xl1) 1 nutrition regulators and. position sensors perx.inpyionuix pshate. the valves are connected to the inputs, and) the unit, and the outputs of the logic unit are connected to the control unit power supply and the main pump and the power supply unit pumps, characterized by the fact that. since it is economical and reliable for an eperblock, opto (). 1Nits, 1S1 () contains sensors for actual water consumption on a steam generator, for 1H) water consumption on a steam generator, gpdrav.1cheskogo () for resistance of the steam generator path and for iHai KH , B1 1 which inputs are connected to the inputs of the logic unit. o :) 4 00 WITH

Description

The invention relates to automatic systems for regulating the supply of water to a multi-flow steam generator and can be used on steam generators of thermal power plants.

There is a known automatic system for regulating the water supply to consumers, and each consumer has a regulating feed valve. All consumers are powered by a common mistral, to which water is supplied by feed pumps. When the valves are in an intermediate position, they are turned off in the direction of reducing water consumption, and when the valves are fully opened, one of the feed valves is turned off in both directions and the feed pumps are connected. This switching is performed by a logic unit, the input of which is connected to the output of the position sensors of the supply valves 1.

However, when switching the action of the regulator, the valve of which has reached the limit position, the properties of the automatic control system significantly change the feed pump, since the dynamic properties of the pump-flow section are significantly worse than those of the valve section.

In addition, there is a strong interconnection between the regulators of individual consumers.

One of the consumer control valves (flows) must be fully open. This leads to a decrease in the hydraulic resistance of the feed pump path, i.e., the section “control valve - steam generator” A decrease in the hydraulic resistance increases the sensitivity of the object to pressure fluctuations.

With slight pressure fluctuations, for example, due to the uneven supply of fuel by the dust pickers, the water consumption changes significantly, which leads to frequent operation of the power regulators and reduces the reliability of the system.

The aim of the invention is to increase the efficiency and reliability of the power unit.

This goal is achieved by the fact that the automatic system for regulating the water supply to the multi-flow steam generator of the power unit contains feed pumps, regulating feed valves on each flow, power regulators, logic block, sensors for regulating feed valves, and outputs for power regulators and sensors for regulating feed. valves are connected to the logical inputs

block, and the outlets of the logic unit are connected to regulating feed valves and feed pumps, additionally contains sensors of actual water flow to the steam generator, predetermined water flow to the steam generator, hydraulic resistance of the steam generator path and the load of the steam generator, the outputs of which are connected to the inputs of the logic unit.

The drawing shows a block diagram of the proposed system.

The system includes supply controllers 1, sensors 2 positions of regulating supply valves, sensor 3 of the actual water flow per steam generator, sensor 4 of a predetermined water flow per steam generator, sensor 5 hydraulic resistance of the steam generator path, sensor 6 of the steam generator load, feed pumps (PN) 7 regulating feed valves (PKK) 8, logic block 9.

The system works as follows.

The logic unit, receiving information from sensors .2-6, switches the action of regulators 1 to PN 7 or PKK 8.

When one of the PKK 8 is fully opened, the action of the corresponding power regulator 1 is directed to the MON 7, and the "Smaller signal is sent to the PKK 8." The signal "Less than the power regulator I of the PN 7 to the PKK 8" does not switch when the PKK 8 is fully opened , and at partial. The magnitude of this partial opening is determined so that, in normal mode, the flow rate of pit-Geln water is controlled only by the PKK 8, and not by the MO 7.

To eliminate the connection between the power supply controllers 1, information on the actual and target water flow is used (sensors 3 and 4). Depending on the ratio of the actual and predetermined water flow in logic unit 9, the control circuits are switched as follows: if the actual flow is greater than the set value, the "More power regulators 1" circuit is disconnected; if the actual flow rate is equal to or less than the set value, the "Less power regulators" switch off .

Thus, if the flow rate on one of the threads is greater than the target, and on the other it is equal to the target, then the cover of the PKK 8 does not occur until the deviation of the water flow from the target flow is completely eliminated, but until the difference between the actual and target water flow to the boiler is eliminated Although the flow rate is not yet equal to the setpoint, the action of the regulator is interrupted and other controllers come into operation, since the flow along their lines is less than the setpoint due to the falling characteristic of the pump. By restoring consumption to their threads, i.e. having slightly opened their PKK 8, they lead i iio to the first line of the flow rate to the given one, since opening the valves leads to a decrease in pressure for the PN 7 and a decrease in the flow along the first string. The permissible degree of their opening is determined by the total hydraulic resistance of the steam generator path and the properties of the PN 7. To take this into account, logic block 9 is given a signal on the hydraulic resistance of the steam generator path (sensor 5) and the signal on the steam generator load (sensor 6). These two signals allow to calculate the allowable and actual total hydraulic resistance of the steam generator path. These signals are fed to an analog-to-discrete converter. Depending on the ratio of the actual and permissible total hydraulic resistance of the boiler in the PKK 8, logic block 9 switches the control circuits as follows: if the hydraulic resistance is greater than the allowable, then the signals "Less regulator 1 of the feeder are fed to PN 7 until RPK 8 will not open to a predetermined degree of opening, after which all signals from the regulators 1 of the feeder are switched to the PKK 8; if the hydraulic resistance is less than the allowable one, then all the signals from the regulators 1 of the feeder are more fed to Г1Н 7 until the hydraulic resistance is not equal to the allowable one; if the hydraulic resistance is equal to the preset, all the signals of the power regulators are transmitted to the PKK 8. Thus, the described automatic system for regulating the water supply to the multi-flow steam generator allows improving the quality of regulation, reducing the number of regulator actuations, ensuring operation at the lowest possible differences and thus increase the reliability and efficiency of the power unit.

Claims (1)

AUTOMATIC SYSTEM FOR REGULATING WATER SUPPLY TO A MULTI-THREAD POWER GENERATOR OF A POWER UNIT, containing feed pumps, control feed valves on each flow, power controllers, logic block, position sensors of control feed valves, and the outputs of power regulators and position sensors of the control block with input pilot valves and the outputs of the logic unit are connected to control feed valves and feed pumps, characterized in that. in order to increase the efficiency and reliability of the power unit, it is additionally contain! sensors of the actual water flow rate of the steam generator, the specified flow rate of water to the steam generator, the hydraulic resistance of the steam generator path and the load of the steam generator, the outputs of which are connected to the inputs of the logic unit.