SU1430563A1 - Heat-electric generating plant - Google Patents

Abstract

The invention allows to increase the efficiency and maneuverability of the installation. The main steam circuit consists of connected in series along the path of the working fluid of the steam generator, 1, turbine 2, condenser 3, heaters (P) 4 and 5 low and g high pressure, battery, heat exchanger (that) 7 heating the heat carrier connected to the steam generator, tanks 8 are hot water coolant and TO 9 and 10 coolant coolants connected in parallel. The peak steam power circuit consists of a turbine 11, a condenser 12 and a heat transfer fluid connected to a TO10 battery. The storage tank 17 of the atmospheric condensate is pumped through the I9 pump to the MOT 9 and the condensate pipeline parallel to the network П 16 ..- During the period of reduced electrical loads, the accumulator of the steam generator –– steam into the accumulator is charged to the 7. At the same time, the condensate heating steam is sent to P 1 b and then returns to the main circuit. During the period of increasing electrical loads, the battery is discharged through TO 9 and 10. 1 sludge. 1} CO o ate

Description

The invention relates to a powerplant and can be used in combined heat and power plants.

The purpose of the invention is to increase the economy and maneuverability of the installation.

The drawing shows a schematic diagram of the installation.

The heat-generating power plant contains the main steam-powered loop, consisting of connected in series along the working fluid path of the steam generator 1, turbine 2, condenser 3, low pressure preheaters 4, high pressure preheaters 5, a battery consisting of cold heat storage tank 6, heat exchanger 7 for heating the heat transfer fluid connected to the steam generator 1, the heat carrier 8 and heat exchangers 9 and 10 for cooling the heat transfer medium connected in parallel, the peak steam power circuit from turbine 11 and condenser 12 and connected to the heat exchanger 10 of the battery via a heating coolant.

The installation also contains pipelines 13 and 14 of the direct and reverse network water, the heating network 15 of the network water, built-in condenser 2 of the peak circuit, network heater 16 connected at the inlet of the heating condensate to the battery heat exchanger 7 and to the heat exchanger 9, and the outlet to the condensate line of the main steam power circuit and to the storage tank I7 of the atmospheric condensate condensate connected to the heat exchanger 9. The installation contains pumps 18-22 and stop valves 23-32

The installation works as follows.

During the period of reduced electrical loads. The accumulator is charged with heat by condensing steam from steam generator i in heat exchanger 7. At the same time, heating steam condensate is directed to network heater 16, where it heats the network water, and then returns to main steam power circuit. At the same time, pumps 18 and 22 are working, shut-off valves 24,25,26, 32 open and shut-off valves 27-31 are closed.

In the period of increasing electric

The load of the battery is discharged through heat exchangers 9 and 10. In this case, in the heat exchanger 10

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evaporation of the working fluid of the peak steam power circuit takes place, and in the heat exchanger 9 - condensate is heated from the storage tank, precompressed in the pump 19 and fed to the input of the network preheater 16 instead; heating condensate from the heat exchanger 7, the consumption of which decreases with increasing electrical loads. Next, the condensate from the mains heater 16 is fed to the storage tank 17, previously throttled to atmospheric pressure. At the same time, pumps 19-21 are working, valves 27,28,29,31 and 32 are open and valves 24-26 are closed.

The present invention allows to increase the economy and maneuverability of the heat and power plant by ensuring full coverage of the heat load of consumers with increasing electrical load.

Claims (1)

Invention Formula Heat and power installation, containing the main steam power circuit with a steam generator, a peak steam power circuit, a battery with pipelines connected in series, the capacity of the cold heat carrier; heated surface connected by the heating medium to the steam generator, hot heat carrier capacity and heating surface connected by the heated medium to the peak steam-power circuit, and a network heater installed in the condensate pipe and connected to the heated surface of the heated surface accumulator-. The main steam power circuit to the condensate line, characterized in that, in order to improve efficiency and maneuverability, the installation is additionally equipped with an atmospheric condensate tank with a pump, a surface type heat exchanger with a pump, and the tank is connected via a pump to the heat exchanger and the condensate pipe parallel to the network heater, while the heat exchanger is connected to the heating medium by a pipeline through the pump parallel to the heating surface of the battery.