SU1346824A2 - Method of contrrolling heat load to extraction turbine plant - Google Patents

Abstract

The invention makes it possible to increase the economics of operating a turbine with the production of steam extraction from the chamber in front of the steam distribution bodies of a part of medium pressure. When the steam distribution bodies reach 4 parts of the average pressure, the maximum opening of the electric drive control circuit of the valve 11 or the valves 15, 16 and 21 through the OR element 38 by the switch 35 occurs until they reach a predetermined position. This position corresponds to the complete or partial shutdown of regenerative heaters. Steam extraction for production is carried out via pipeline 39. As a result, an increase in pressure in the production selection chamber and a decrease in turbine power are prevented. 1 il. g / n /) 2, - i I 35 L, 1 g Jvl35 I. Gl J fl JlfiJQLQl 3J t 32L33JL 26 L.SL4.4i - I; i: ii.z j t123 (L, -6 I with co: 00 x 4: ISJ

Description

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The invention relates to a power system, can be used in the operation of heat and power plants with heating and production steam extraction and is an improvement of the device according to the author. St. No. 1134737.

There is a known method for controlling the heat load of a heat-generating turbine installation, according to which in the operation mode with a peak source of heating of the supply water, which is switched on when the set value of the supply water temperature is reached, steam consumption in parts of the high and low pressure of the turbine is measured according to the positions of their steam distribution bodies and when the maximum steam flow rate in the high pressure part is reached, and the minimum steam flow rate in the low pressure part and the specified set point of the network temperature Howling water reduces steam supply to regenerative heaters.

The purpose of the invention is to increase the efficiency of the turbine with the production of steam from the chamber in front of the steam distribution bodies of the medium pressure part.

The drawing shows a diagram of the heat turbogeneration plant for the implementation of the proposed method.

The heat-recovery turbine unit contains a turbine consisting of a cylinder 1 of high pressure —jQ with steam distributing bodies 2 high pressure parts and a mechanical electric sensor 3 their positions with steam distributing bodies 4 parts of medium pressure, a low pressure mechanoelectric sensor 5 and a cylinder 6 of low pressure with steam distribution bodies 7 low pressure parts and a mechano-electric sensor 8 their positions, regenerative heaters 9 with a control unit 10 to turn off the regenerative heaters Leu 9 by acting on the valve 11, equipped with an electric actuator 12 and a limit switch 13 and installed on the steam supply pipe 14 to the heaters 9, or by acting on the valves 15 and 16, equipped with electric drives 17 and 18 and a limit switch 19 and installed on the pipeline 20 supplying feedwater to the heaters 9, and a valve 21, equipped with an electric actuator 22 and installed on the feedwater circuit 23 of the feedwater in addition to the regenerative heaters 9.

The mains water is heated to the temperature specified in the heating network operation, given in heaters 24 and the peak source 25.

The preheaters 9 are produced by a control 29.

The control unit 10, in which the current value of the temperature of the supply water and the output signal of the setpoint 29 measured by the thermocouple 26 or 27, is compared, contains the adder 30, which leads to the signals of the thermocouple and settingter and performs the algebraic addition of the transformed signals , and a relay element 31, triggered by the equality of these signals. In control unit 10, there are two more relay elements 32 and 33, to the input of which signals from sensors 3 and 8 of the location of the steam distribution bodies 2 and

7. The operation of the relay element 32 occurs at the maximum opening of the steam distribution parts of the high pressure, and the element 33 - at the minimum opening of the steam distribution parts of the low pressure. The relay elements 31-33 are connected to the logic element AND 34 so that only when all three relay elements are triggered, the actuators of the valves 11 or 15, 16 and 21 start. The switch 35 actuating the actuator circuits of the valve actuator also turns on from the limit switches of the valve 11 or one of the valves 15, 16, 21 and from the relay 36 controlled by the adder 37 comparing the temperature of the supply water behind the peak source and before it measured by thermocouples 26 and 27. Switch 35 and relay 36 are connected to the log OR 38, so that the opening of the control circuit of the electric drives of the valves occurs either when the supply water temperatures are equal before and after the peak boiler, or when the valves 11, 15, 16 and 21 reach a predetermined position corresponding to the full or partial disconnection of the regenerative heaters.

When the steam distribution bodies reach 4 parts of the average pressure, the maximum opening of the electric drive control circuit of the valve 11 or the valves 15, 16 and 21 through the OR 38 element 45 by the switch 35 occurs until they reach a predetermined position corresponding to the full or partial disconnection of the regenerative heaters. The steam extraction for production is carried out via pipeline 39.

The method is carried out as follows.

At the maximum opening of the steam distribution bodies 2, which is detected by the sensor 3, their position and transmitted to

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Thermocouples 26 and 27 are used to measure 55 the relay element 32 of the control unit 10.

mains water temperature in the pipeline 28. Setting the mains water temperature at which the minimum opening of the steam distribution bodies 7 is disconnected, which is fixed by sensors 8 of their position and transmitted to

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The preheaters 9 are produced by a control 29.

The control unit 10, in which the current value of the temperature of the supply water and the output signal of the setpoint 29 measured by the thermocouple 26 or 27, is compared, contains the adder 30, which leads to the signals of the thermocouple and settingter and performs the algebraic addition of the transformed signals , and a relay element 31, triggered by the equality of these signals. In control unit 10, there are two more relay elements 32 and 33, to the input of which signals from sensors 3 and 8 of the location of the steam distribution bodies 2 and

7. The operation of the relay element 32 occurs at the maximum opening of the steam distribution parts of the high pressure, and the element 33 - at the minimum opening of the steam distribution parts of the low pressure. The relay elements 31-33 are connected to the logic element AND 34 so that only when all three relay elements are triggered, the actuators of the valves 11 or 15, 16 and 21 start. The switch 35 actuating the actuator circuits of the valve actuator also turns on from the limit switches of the valve 11 or one of the valves 15, 16, 21 and from the relay 36 controlled by the adder 37 comparing the temperature of the supply water behind the peak source and before it measured by thermocouples 26 and 27. Switch 35 and relay 36 are connected to the log OR 38, so that the opening of the control circuit of the electric drives of the valves occurs either when the supply water temperatures are equal before and after the peak boiler, or when the valves 11, 15, 16 and 21 reach a predetermined position corresponding to the full or partial disconnection of the regenerative heaters.

When the steam distribution bodies reach 4 parts of the average pressure, the maximum opening of the electric drive control circuit of the valve 11 or the valves 15, 16 and 21 through the OR 38 element 45 by the switch 35 occurs until they reach a predetermined position corresponding to the full or partial disconnection of the regenerative heaters. The steam extraction for production is carried out via pipeline 39.

The method is carried out as follows.

At the maximum opening of the steam distribution bodies 2, which is detected by the sensor 3, their position and transmitted to

five

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55 relay element 32 of control unit 10.

and the minimum opening of the steam distribution bodies 7, which is fixed by the sensor m 8 of their position and transmitted to

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Ley element 33 of control unit 10, measures the temperature of the mains water using a thermocouple 26 behind the heater 24 and compares it in the adder 30 with the predetermined value 29, and when the temperature of the mains water is equal to this preset value, they cover the steam access to the regenerative heaters 9 by acting on the adders 30 on the actuators of the valves 11 or 15, 16 and 21.

If in the process of disconnecting regenerative heaters the steam distribution bodies 4 parts of the average pressure reach the maximum at a given pressure in the production sampling, the scheme will stop the disconnection of the regenerative heaters from the mechano-electric sensor 5 to the element 38, thereby causing the connection is broken in the electric drive control circuit of the valve 11 or the valves 15, 16 and 21.

Thus, as a result of the suspension of reduced steam access in the regen

Reactive heaters, when the steam distributors reach a part of the average pressure, maximize their opening to prevent an increase in pressure in the production selection chamber and a decrease in turbine power, which will preserve its efficiency.

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Claims (1)

Invention Formula The method of regulating the heat load of a heat-turbine installation according to aut. St. No. 1134737, characterized in that, in order to increase the economics of the turbine. With production steam from the meter to the steam distributors of the medium pressure part, the position of the steam distributors of the average pressure turbine is additionally measured and, when they reach maximum opening, the feed reduction stops steam to regenerative booster.