SU1483051A1 - Method of operation of power-and-heating plant - Google Patents

Abstract

The invention relates to a power system and can be used at heat and power plants (CHP). The aim of the invention is to increase the efficiency of the CHP when the load fluctuates production (high-grade) selection. With a decrease (increase) in steam consumption from high-potential withdrawals 15 and 16 increase (decrease) the steam consumption from these withdrawals 15, 16 to peak preheaters (PP) 22 of network water, maintaining the initial values of fresh steam consumption to turbine 1.2 and pressure in high-potential selections 15 and 16. When the temperature of the mains water reaches the PP 22, the maximum permissible value reduces the flow of fresh steam and regulates the vapor pressure at PP 22, maintaining it less than the pressure of the mains water and the set value of the mains water temperature. Excess steam is used to generate additional electricity based on the heat released. 1 il.

Description

The invention relates to a power system and can be used at combined heat and power plants (CHP) to obtain additional power based on the released heat.

The aim of the invention is to increase the efficiency of the CHPP during fluctuations in the load of production steam extraction.

The drawing shows a schematic diagram of a thermal power plant for implementing this method.

The CHPP contains turbines 1 and 2 with adjustable Steam Extraction (type ПТ) and backpressure (type Р), high pressure cylinders 3 and 4 (CVP), which are connected through the control valves (PK) 5 and 6 to the steam pipeline 7 of fresh steam. CVP 3 through a regulating device (RU) 8 is in communication with part 9 of medium pressure (CHS), which through RU 10 is connected with part 11 of low pressure (NPP) connected to the condenser 12. Turbines 1 and 2 are connected to generators 13 and 14, and the selection of 15 and 16 high-potential steam from their CVP 3 and 4 through RU 17 and 18 are communicated with the collector 19, on which the pressure sensor 20 is mounted. The collector 19 through RU 21 is connected to a peak heater (PP) 22 of network water, a production consumer (PRP) 23 and consumers (not shown) using steam for their own needs of the CHP. The main network heater (0P) 25, connected with the selection of 26 low-grade steam from ChSD 9, is connected to the pipeline 24 of the return network water; PP 22 is connected through the shut-off-control devices (ZRU) 27 and 28 to the peak boiler (PVC) 29, and through A switchgear 30 with a direct network water pipe 31 to which a PVC 29 is connected, and the latter has a burner (nozzles) 32. A steam pressure sensor 33 is installed in front of the PP 22, and a network water temperature sensor 34 is installed behind the PP 22.

The method of operation of the CHP is as follows.

With a decrease in steam consumption from high-potential selection 15 to manufacturing consumer 23 or for own needs of the CHP, the pressure in the manifold 19 increases, pressure sensor 20 gives an impulse to open the switchgear 21 and steam consumption increases at PP 22. After that, the pressure in high-potential withdrawals 15 and 16 (manifold 19) is restored to the previous level while maintaining the initial value of the fresh steam flow rate to turbines 1 and 2. Moreover, switchgear 8 and 10 on turbine 1 can remain unchanged when the flow rate the steam in BS 9 reached the maximum permissible value. If the steam flow rate in ChSD 9 has not reached the maximum value, RU 8 opens and the steam flow rate increases in OP 25 and (or) in NPV 11 by opening the RF 10. After that, the steam flow rate on PP 22 increases by opening the RU 21.

If the temperature of the supply water for PP 22 reaches the maximum permissible value, the sensor 34 gives an impulse to cover RU 21, while simultaneously covering RK 5 and 6 in front of the HPC 3 and 4 of turbines 1 and 2 or in front of the HPC 3, 4 of one of the turbines 1, 2 and the consumption of fresh steam decreases. Additional pulses are carried out using sensors 20 and 33. The sensor 33 corrects the vapor pressure in front of the PP 22 using the RU 21 so that the steam pressure in front of the PP 22 does not exceed the pressure of the supply water behind the PP 22. This is necessary to prevent boiling water in PP 22 and beyond. The sensor 20 provides a pulse to RK 5 and 6 to maintain the “set pressure in the manifold 19 of the steam pipe (extraction 15 and 16 of high potential steam). PP 22 using the switchgear 27, 28 and 30 can be connected to the PVC 29 in series or in parallel. In the first case, the open switchgear 27 opens and the closed switchgear 28 and 30. In the second case, the open switchgear 28 and 30 opens and the closed switchgear 27.

When using this method, the maximum allowable and set temperature of the mains water after PP 22 can be higher and lower than the temperature of the water leaving PVC 29. The temperature is lower than after PVC 29 is set if the pressure of mains water: after PP 22 is lower than the pressure saturation of the corresponding water temperature behind the PVC 29. This can occur when a network pump (not shown) is installed between the PP 22 and the PVC 29 and the pressure of the network water in front of the PVC 29 rises significantly. The maximum water temperature after PP 22 is set higher than after PVC 29, if PP 22 is connected to PVC 29 in parallel through the mains water and the pressure of the mains water in front of ΓΙΠ 22 is sufficient to achieve this goal. The increase in water temperature after PP 22 is higher than the water temperature after PVC 29, and even higher than the schedule (water temperature in the 31st pipeline allows you to additionally displace the heat transferred to the network water in PVC 29 and increase the generation of electricity by increasing steam consumption in TsVD 3 and 4 of turbines 1 and 2, At 15 this the temperature of the supply water after the PVC 29 can be significantly lower than the temperature of the water in the pipe 31, and the set temperature in it is maintained by displacing the water coming after PP 22 and the PVC 29 . With fluctuations in flow ode of steam going to the PRP 23 or to the own needs of the CHPP from the high-pressure steam sampling 15 and 16, surplus steam is used for 25 additional power generation based on the released heat, thereby displacing the condensation power generation.

Claims (1)

Claim The method of operation of the combined heat and power plant by supplying a variable flow rate of fresh steam to the turbines, heat supply to the production consumer and to the own needs of the combined heat and power plant and mains water, respectively, from high-potential and low-grade turbine selections when the flow rate and pressure of the steam change and heating in peak heaters and hot water boilers to a predetermined value of its temperature, characterized in that (which, in order to increase efficiency, while reducing (increasing) the flow of steam from high Of the total withdrawals increase (decrease) the steam flow from these withdrawals to the peak heaters, maintaining the initial values of the fresh steam flow and pressure in high-potential withdrawals, and when the network water temperature behind the peak heaters reaches the maximum permissible value, they reduce the fresh steam flow and change the steam pressure to the peak heaters while maintaining it lower pressure network water and temperature at a given level.