RU2687382C1 - Operating method of thermal power plant and device for its implementation - Google Patents

Abstract

FIELD: electric power engineering.SUBSTANCE: invention relates to power engineering and can be used at thermal power plants with steam turbine Rankine cycle, for example at condensing power plants – CPP, at combined-cycle power plants – CCP using fuel – traditional natural gas. Application of proposed method allows to achieve technical task in increase of efficiency and reliability of power plant, as in any modes, including normal and emergency, in power system own needs and heating of network water are always power supply. In operation method of thermal power plant with own needs, according to which network water supplied from consumers through heat exchanger is heated in network heaters from turbine working medium take-offs, electric power plant is equipped with power plant on fuel elements for auxiliary power supply, reduces turbine working medium withdrawals to network heaters and proportionally, before heating of network water in network heaters, its temperature in heat exchanger is increased, in which heating medium is used products of reactions in power plant on fuel elements.EFFECT: technical result consists in increase of power supply to power system by value of consumption of own needs and due to increase of thermal efficiency of station.2 cl, 1 dwg

Description

The invention relates to methods of operation of a thermal power plant, and can be used in thermal power plants.

The analogue of the proposed method is a method of operating a thermal power plant (see patent No. 2269013, IPC F01K 17/02, published on January 27, 2006), through which network water coming from consumers is fed to the evaporator of a heat pump installation as a low potential heat source , is heated in the condenser of the heat pump installation and in the network heaters of the heating turbines. Heating of the entire flow of the network water in the condenser of the heat pump installation is carried out after heating water in the network heaters of the heat turbines.

The disadvantage of this method is a significant consumption of electrical energy.

The prototype of the proposed method is the method of operation of a thermal power plant (see patent No. 2406830, IPC F01K 17/02, publ. 12/20/2010 by Bull. No. 35), according to which the network water supplied from consumers is heated in the network heaters of the heat turbine , while before heating the network water in the network heaters, its temperature is reduced in a heat exchanger, installed in a network installation in a heating medium in front of the network heaters of the cogeneration turbine, and in a heating turbine that has a condensation ator, after condensation pump.

The disadvantage of the prototype method is that its implementation requires two different types of turbines at the thermal power plant - heat and condensation. In addition, the additional heating of the condensation turbine working environment by the heat of the return network water reduces the extraction of the condensing turbine to its regenerative heaters, which, in turn, reduces the thermal efficiency of the condensing turbine (see pp. 128-130 in the book: Balyan. S.V. Technical thermodynamics and heat engines. Ed. 2nd, revised and enlarged L., "Mashinostroenie", 1973, 304 p.).

The technical problem solved by the invention is to improve the efficiency and reliability of the power plant.

The technical result consists in increasing the power supply to the power system by the amount of own needs consumption and by increasing the thermal efficiency of the plant, as well as maintaining power supply for the power plant's own needs during any normal and emergency conditions in the power system and at the power plant itself.

The technical problem is solved by the fact that in the method of operating a thermal power station with its own needs, according to which the network water supplied from consumers through a heat exchanger is heated in the network heaters from the turbine working medium selections, the power station is supplied with a power plant on fuel cells to power its own needs, reduce turbine working environment selections for network heaters and proportionally, before heating network water in network heaters, increase its temperature in the heat source CENI, wherein the heating medium used in the reaction products of the fuel cell power plant.

In the part of the device, the technical problem is solved by the fact that in the known device comprising a steam boiler, the inlet of which is connected to the gas supply system of the power station, and the outlet is connected to the turbine with electric generators on the shaft, the stator windings of which are connected to the power system and through the transformer to the tires of the own needs of the thermal power station , the turbine output through the condenser and the feed pump is connected to the steam boiler inlet, the selection of the turbine steam is connected to the regenerative heater and the network heater, before the cat The heat exchanger is connected, the tires of the own needs of the power plant according to the invention, the thermal power plant is equipped with an inverter and a fuel cell power plant, the input of which is connected to the station’s gas supply system, the output of reaction products is connected to the input of the heat exchanger heating medium, and the output of electricity is connected through an inverter tires own needs.

The drawing shows a schematic diagram of a simple thermal power plant that implements the proposed method of operating a thermal power plant with the Rankine cycle.

Thermal power plant using gas fuel, such as natural gas, contains the working body circuit in the form of the Rankine steam turbine cycle (Heat Engineering. Textbook for universities / AP Baskakov, BV Berg, OK Witt, etc .; Pod Edited by AP Baskakov. - M .: Energoizdat, 1982, pp. 65-71) with a steam boiler 1 with a steam superheater 2, at the input connected to the system 3 of the gas supply of the power plant, and output connected to the steam turbine 4 with electric generator 5 on the shaft, the findings of the stator windings of which are connected to the power system 6 and through a transform torus 7 to tires 8 own needs of the power plant, as well as power plant 9 on fuel cells (Korovin N.V. Fuel cells and electrochemical power plants. - M .: MEI Publishing House, 2005. - 280 pp., ill.), the input of which is also connected to the specified system 3 gas supply, and the electrical output through the inverter 10 is connected to the tires 8 own needs. The output of the turbine 4 through the working body of the Rankine cycle is connected through a condenser 11 and a feed pump 12 with a steam boiler 1, and the selection 13 of a pair of turbine 4 is connected to a regenerative heater 14 and a network heater 15, before which a heat exchanger 16 is connected along the network water path heating medium connected to the path 17 of the reaction products in the power plant 9 on fuel cells. To the tires 8 of the own needs of the power station also 18 consumers of their own needs are connected. In addition, in FIG. 1 designates: 19, 20 - switches in electric circuits of connections of elements of the scheme; 21 - circulation pump for cooling water supply to condenser 11; 22РП, 23СП - controlled valves in coolant extraction paths; 24-condensate pump. PM25 and OM26 - direct (supply) and reverse mains of network water, respectively.

According to FIG. 1 thermal power plant according to the proposed method works as follows. In the steam boiler 1, gas is supplied from the system 3 of the gas supply of the power plant, and through the outlet steam is supplied to the turbine 4 with the electric generator 5 on the shaft. From the generator 5 electricity is supplied to the power system 6 and through the transformer 7 to the tires 8 own needs thermal power plant. The exhaust steam from the output of the turbine 4 through the condenser 11 is returned by the feed pump 12 in the form of condensate to the steam boiler 1. 13 steam turbines 4 are sampled into the regenerative heater 14 and the network heater 15. At the same time, steam turbine 4 selection 13 is reduced to network heaters 15 s using a controlled valve 23 and proportionally, before heating in the network heaters 15, increase the temperature of the supply water in the heat exchanger 16, in which heating products through the path 17 are used in the heating medium 9 through the heating medium in the elements. When operating in the power supply mode, the power consumers 18 of their own needs from the power plant 9 on the fuel cells switch 20 and turn off the switch 19, gas is supplied to the input of the fuel cell unit 9 from the same gas supply system 3. The direct current electric power from the output of the power plant 9 on the fuel cells is supplied through an inverter 10 converted into alternating current to the own busbars 8, from which 18 own needs are fed to electrical receivers.

A thermodynamic analysis was carried out, which allowed us to obtain for the scheme of Fig 1 the following formula for the interrelation of enthalpy flows for turbine working medium selections:

,

,

- коэффициент общей доли отбора пара в сечении "a" паровой турбины 4;

- коэффициент доли отбора пара в сечении "a" на регенеративный подогреватель 14 через управляемый клапан 22 в канале теплоносителя;

- коэффициент доли отбора пара в сечении "a" на сетевой подогреватель 15 через управляемый клапан 23 в канале теплоносителя.where: h _i - enthalpies, respectively, in the selected four index points "a", "b", "c" and "d" of the circuit of FIG. one;

- the ratio of the total share of steam extraction in the section "a" of the steam turbine 4;

- the ratio of the fraction of the steam in section "a" on the regenerative heater 14 through controlled valve 22 in the coolant channel;

- the ratio of the fraction of the steam in section "a" on the network heater 15 through a controlled valve 23 in the coolant channel.

From the formula it follows that for a given mass flow rate of steam D in the installation with an increase in the coefficient α, i.e. with an increase in the simultaneous extraction of steam at point "a" for regenerative heater β and network heater γ, the turbine capacity N _T decreases, since the proportions of vapor extraction D _RP and D _SP , which do not perform useful work in the section between the points, increase accordingly "a" and "c". However, for a given coefficient α, simultaneously with an increase in the coefficient β, the heat Q _T supplied to the working fluid decreases (i.e. reduced fuel consumption in the installation. This will increase the thermal efficiency of the cycle, as according to FIG. 1 the condition (h _a -h _d )> (h _a -h _c ) is always met.

For a given coefficient β, an increase in the coefficient γ (i.e., an increase in the share of steam extraction at point "a" for the heater 15) leads to a decrease in turbine power and, accordingly, to a decrease in the thermal efficiency of the cycle, and vice versa - a decrease in the coefficient γ leads to increase thermal efficiency cycle.

, т.е. КПД энергоустановок на топливных элементах должен быть больше или, по крайней мере, равным КПД-нетто тепловой электростанции. Например, при использовании энергоустановок 9 на топливных элементах одновременно для электропитания нагрузок 18 собственных нужд тепловой электростанции и для дополнительного подогрева сетевой воды в теплообменнике 16 блока мощностью 300 МВт с турбоустановкой К-300-240 повышает КПД - нетто станции на 0.7%, а, например, при использовании энергоустановок 9 на топливных элементах только для дополнительного подогрева сетевой воды в теплообменнике 16 повышает КПД - нетто станции на 0.3%, что эквивалентно повышению мощности блока на 0.9 МВт.Calculations justified that for the application of power plants on fuel cells to power their own needs thermal power plant is the condition

i.e. The efficiency of fuel cell power plants must be greater than or at least equal to the net power efficiency of the thermal power plant. For example, when using power plants 9 on fuel cells at the same time to power the loads of 18 auxiliary needs of a thermal power plant and to additionally heat network water in a heat exchanger 16 of a 300 MW power unit with a K-300-240 turbine, the efficiency increases - the net station increases by 0.7%, and, for example , when using power plants 9 on fuel cells only for additional heating of the network water in the heat exchanger 16 increases the efficiency - the net station by 0.3%, which is equivalent to increasing the capacity of the unit by 0.9 MW.

Thus, the application of the proposed method allows to achieve the technical goal in improving the efficiency and reliability of the power plant, as in any mode, including normal and emergency, in the power system, own needs and heated network water are always energy-efficient. In addition, there is an increase in the supply of electricity to the grid by the amount of consumption of its own needs and by increasing the thermal efficiency of the station.

Claims (2)

1. A method of operating a thermal electric station with its own needs, in which the network water supplied from consumers through a heat exchanger is heated in network heaters from selections of the turbine's working medium, characterized in that the electric station is supplied with a power plant on fuel cells to power its own needs, reduce selections working environment of the turbine on the network heaters and proportionally, before heating the network water in the network heaters, increase its temperature in the heat exchanger, in which Food uses reaction products in a fuel cell power plant. 2. A device for implementing the method of operation of a thermal power station according to claim 1, comprising a steam boiler whose inlet is connected to the gas supply system of the power plant, and the outlet is connected to a turbine with an electric generator on the shaft, the stator windings of which are connected to the power system and through a transformer with tires of their own needs the thermal power plant, the turbine output through the condenser and the feed pump is connected to the steam boiler inlet, the selection of the turbine steam is connected to the regenerative heater and the network heater, before the heat exchanger is connected to, the tires of the plant’s own needs, characterized in that the thermal power plant is equipped with an inverter and a power plant for fuel cells, the input of which is connected to the station’s gas supply system, the output of reaction products is connected to the input of the heat exchanger heating medium, and the output of electricity is connected via an inverter with tires own needs.

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