RU2648478C2 - Maneuvered regenerative steam gas thermal power plant operating method and device for its implementation - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: invention relates to power engineering. Maneuvered regenerative steam gas thermal power plant operating method and device for its implementation, the heat of gases, expanded in a gas turbine, is used for regenerative heating of compressed air and delivery water of the heating network. During the non-heating work period, the compressed air is regeneratively heated, and during the heating period only a part of the compressed air, which decreases with decreasing air temperature is regeneratively heated. Regenerative heating is stopped when the air temperature drops to the predetermined value. Heat of the combustion products is used to generate overheated steam of medium pressure and to heat the delivery water of the heating network, overheated steam is expanded in a back pressure steam turbine, its useful work is used to generate electricity, the expanded steam is condensed, heat of steam condensation is used to heat the delivery water of the heating network, the condensate is deaerated, compressed and used in the recovery boiler to produce overheated steam; in the heating period, when the ambient air temperature drops to the set temperature, additional fuel is burned between the evaporator stages of the waste heat boiler, production of overheated steam, electric and thermal power are increased, consumption of additional fuel is increased when the heat load of consumers increases.

EFFECT: invention provides higher economy, electric and thermal power, maneuverability and the amount of cogeneration energy production.

2 cl, 1 dwg

Description

The invention relates to the field of energy, and more specifically to heating cogeneration plants.

A known method of operation of a combined cycle gas turbine power plant (CCGT-CHP), according to which both in non-heating and in heating modes its operation compresses atmospheric air, burns fuel in it, expands the combustion products in a gas turbine, using its useful work to generate electricity in exhaust the gases of a gas turbine produce afterburning of fuel to increase the temperature of the gases in front of the recovery boiler and use their heat to generate superheated steam of high parameters and heat the network water, expand Macaw in a backpressure cogeneration steam turbine with electricity generation in an electric generator. During the heating period, in the gases cooled in the recovery boiler, additional fuel is burned and the heat of the combustion products is used to heat the network water of the heating system and increase the thermal capacity of the CCGT-CHP plant (S.V. Tsanev, V.D. Burov, A.N. Remizov, Gas-turbine and combined-cycle plants of thermal power plants, Moscow: Publishing House of MPEI, 2002. P. 423, Fig. 9.31). The afterburning of fuels in front of the recovery boiler allows the required superheating of the steam, to increase the steam capacity of the recovery boiler and the electric capacity of the CCGT CHP.

The disadvantage of this method is that in both unheated and heating modes of the CCGT-CHP plant, the use of afterburning of fuel in front of the recovery boiler leads to a decrease in its thermal efficiency. At the same time, in the heating modes of its operation, the afterburning of fuel in gases after the recovery boiler allows increasing the thermal capacity of the CCGT-CHP, but without increasing the capacity of the steam turbine and generating electricity.

Closest to the present invention is a method of operating a maneuverable regenerative GTU-CHP of the utilization type, according to which atmospheric air is compressed, fuel is burned in it, combustion products are expanded in a gas turbine, its useful work is used to generate electricity, and the thermal energy of gases leaving the gas turbines are used to heat the heating network water. In the non-heating period of its operation, the heat of these gases is used for regenerative heating of all compressed air before burning fuel in it, and in the heating period, depending on the temperature of the air, regenerative heating of only part of the compressed air is performed with bypassing of the rest of it directly for burning fuel; at a given temperature of atmospheric air, the regenerative heating of compressed air is stopped, reaching maximum utilization of the heat of the gases exhausted in the gas turbine and the thermal power of the GTU-TPP. With a further decrease in air temperature and an increased heat load of consumers, the temperature of the network water is increased by additional fuel combustion in the peak boiler (Article by V.V.Semin, E.A. Larina. Modeling of operating conditions and determination of the system fuel efficiency of GTU-TPP “Problems” electric power industry. ”Collection of scientific papers. SSTU. P. 126-133. Saratov, 2010).

The positive side of the described method of operation of the maneuverable regenerative GTU-CHP of the utilization type, adopted as a prototype of the invention, is to increase the efficiency in the non-heating period of operation with a small heat load of hot water supply to consumers.

The disadvantage of this method, when the GTU-CHPP is operating in heating modes, is the insufficiently high level of joint cogeneration generation of electric and heat energy, especially when the heat load of consumers is increased and an additional peak boiler is turned on.

The technical result achieved by the present invention is to increase the efficiency, electrical and thermal power, maneuverability and the value of cogeneration energy production in both unheated and heating modes of operation of a maneuverable combined cycle gas-fired combined heat and power plant.

To achieve these results, in the proposed method of operation of a maneuverable regenerative combined-cycle heat and power plant, they compress atmospheric air, burn fuel in it, expand the combustion products in a gas turbine and use its useful work to generate electricity, use the thermal energy of expanded gases to regeneratively heat compressed air and network water of the heating system at the same time, during the non-heating period of operation, the whole is regeneratively heated, and during the heating period only part of the compressed air, with its reduction with decrease in temperature of atmospheric air; regenerative heating is stopped when the temperature of the atmospheric air drops to a predetermined value, and in both heating and non-heating periods, the heat of the combustion products is used to generate medium-pressure superheated steam, it is expanded in a counter-pressure heating steam turbine, the useful work of which is used to generate electricity, expanded steam is condensed, the heat of condensation of steam is used to heat the network water of the heating system, the condensate is deaerated, compressed and used comfort in a waste heat boiler for generating superheated steam; during the heating period, when the temperature of the atmospheric air drops to a predetermined value, between the steps of the evaporator of the recovery boiler, additional fuel is burned, the production of superheated steam is increased, the electric and thermal power of the installation is increased, the consumption of additional fuel is increased with increasing heat load of consumers.

The proposed method of operation allows to increase the maneuverability and thermal efficiency of the combined heat and power plant, moreover:

- the use of regenerative air heating at a degree of regeneration of about 6-8 and a temperature in front of the gas turbine above 1150 ° C allows us to provide the required temperature head in the superheater of the recovery boiler and generate superheated steam of average parameters with a temperature of 435-440 ° C and a pressure of 3.3- 3.4 MPa;

- in the non-heating period of operation, even with small thermal loads of hot water supply to consumers, the thermal efficiency of CCGT-CHP increases due to the regenerative heating of compressed air;

- at the beginning of the heating period with moderate outdoor temperatures (+8 - -5 ° С) and low heat loads of consumers, the thermal efficiency of the CCGT-CHP will also increase due to the regenerative heating of part of the compressed air;

- during the heating period, when the air temperature drops to a predetermined value, additional fuel combustion between the stages of the evaporator allows to increase the steam capacity of the recovery boiler, electric and thermal power and maneuverability of the CCGT-CHP, with their increase with increasing thermal load of consumers.

In FIG. 1 shows a schematic thermal diagram of a CCGT-CHP plant for implementing the method of operation of a maneuverable regenerative combined-cycle combined heat and power plant. It includes an electric generator 1, a compressor 2, a regulator 3, a combustion chamber 4, a gas turbine 5, a bypass duct 6, a steam pipe of medium-pressure superheated steam 7, a cogeneration counterpressure steam turbine 8, an electric generator 9, a regenerative air heater 10, a superheater 11, a second stage evaporator 12, the afterburner 13, the evaporator of the first stage 14, the economizer of the second stage 15, the economizer of the first stage 16, the gas-water heater for network water 17, the network heater of the second stage 18, network ogrevatel first stage 19, line preheated water network 20, the condensate 21, deaerator 22, feedwater line 23 with feed pump, a conduit 24, a straight line heating system, heating system return line conduit 25.

The output of the compressor 2 is connected directly to the combustion chamber 4 through the regulator 3, and also through it and the bypass duct 6. The gas turbine 5 and the compressor 2 are connected by a common shaft to the electric generator 1, the output of the gas turbine 5 is connected through a regenerative air heater 10 with a superheater 11 of the boiler the utilizer, in which the gases are located - the second stage evaporator 12, the afterburner 13, the first stage evaporator 14, the second stage economizer 15, the first stage economizer 16, the gas-water network water heater 17. Parope The heater 11 is connected by a steam line of superheated steam 7 to the input of a cogeneration counterpressure steam turbine 8. Its cogeneration is paired with a network heater of the second stage 18, and the output of a steam turbine is coupled in a couple with a network heater of the first stage 19. 16, a deaerator 22 and a feed water pipe 23 with a feed pump, with an economizer of the second stage 15 of the recovery boiler. The return pipe of the heating network 25 is connected to the straight pipe of the heating network 24 through a network heater of the first stage 19, a network heater of the second stage 18, and also through a gas-water heater of network water 17.

The proposed method of operation of a maneuverable regenerative cogeneration combined-cycle plant is as follows. When it is operating in non-heating mode, atmospheric air is compressed in the compressor 2 and, with the regulator closed, 3, it is directed through the regenerative air heater 10 and bypass duct 6 into the combustion chamber 4 and fuel is burned in it. At the same time, in the regenerative air heater 10, the compressed air is heated by the heat of the combustion products expanded in the gas turbine 5, the useful work of which is used to drive the compressor 2 and generate electricity in the electric generator 1. The heat of the gases leaving the regenerative air heater 10 is used to generate superheated medium pressure steam in the heating surfaces of the waste heat boiler-superheater 11, second 12 and first 14 stages of the evaporator, in the economizer of the second stage 15 and the economizer of the first stage 16, and also for heating the network water of the heating system in the gas-water heater of network water 17. The superheated steam from the superheater 11 is fed through the steam pipe of the superheated steam 7 to the backpressure heating steam turbine 8. The steam from its heating selection is sent to the network heater of the second stage 18, and from the outlet of this turbine to the network heater of the first stage 19. The heat of condensation of steam in the network heater of the first stage 19 and in the network heater of the second stage 18 is used to heat the network water of the heating system supplied to of them from the return line of the heating network 25 and discharged into the pipeline of the direct heating network 24 through the heated network water pipe 20. The heating network water is also heated in the gas-water heater of the network water 17 by the heat of gases cooled in the waste heat boiler. Steam condensate from the network heater of the first stage 19 is supplied through the condensate line 21 through the economizer of the first stage 16 of the recovery boiler, the deaerator 22, where it is deaerated, and the feed water pipe 23, with a feed pump, to the economizer of the second stage 15 of the recovery boiler to generate it overheated steam medium pressure.

When operating the maneuverable CCGT-CHP in heating mode, while lowering the temperature of the ambient air, only part of the air compressed in the compressor 2 is heated in the regenerative air heater 10, and the rest of it is fed into the combustion chamber 4. The heat of the gases after the regenerative air heater 10, as well as and in non-heating operation, they are used to generate medium-pressure superheated steam in the heating surfaces of the waste heat boiler-superheater 11, second 12 and first 14 stages of the evaporator, in the economizer of the second 15 and the economizer of the first stage 16, as well as for heating the network water of the heating system in the gas-water heater of the network water 17. The superheated steam from the superheater 11 is fed through the steam line of the superheated steam 7 to the backpressure heat recovery steam turbine 8. The steam from its heat recovery is sent to the network heater of the second stage 18, and from the back pressure of this turbine is fed into the network heater of the first stage 19. The heat of condensation of steam in the network heater of the first stage 19 and in the network heater of the second stage 18 heat the network water of the heating network supplied to them from the return pipe of the heating network 25 and discharged to the pipeline of the direct heating network 24 through the heated network water pipe 20. Heating of the heating network water is also carried out in the gas-water heating network heater 17 with the heat of gases cooled in a waste heat boiler. Steam condensate from the network heater of the first stage 19 is supplied through the condensate line 21 through the economizer of the first stage 16 of the recovery boiler, the deaerator 22, where it is deaerated, and the feed water pipe 23 with a feed pump to the economizer of the second stage 15 of the recovery boiler to generate overheated in it medium pressure steam. But when the temperature of atmospheric air drops to a predetermined value, the regenerative heating of compressed air is stopped and additional fuel is burned in the afterburner 13 located in the flue of the recovery boiler between the second 12 and first 14 stages of the evaporator of the recovery boiler, while increasing the production of superheated steam, the electric power of the electric generator of the backpressure heating steam turbine 8 and the heat power of the network heater of the first stage 19 and network heating STUDIO second stage 18, the flow of additional fuel into the afterburner chamber 13.

Claims (2)

1. The method of operation of the maneuverable regenerative cogeneration combined-cycle heat and power plant, according to which atmospheric air is compressed, fuel is burned in it, the products of combustion are expanded in a gas turbine and useful work is used to generate electricity, the thermal energy of expanded gases is used for regenerative heating of compressed air and network water of the heating system, at the same time, during the non-heating period of operation, the whole is regeneratively heated, and during the heating period only part of the compressed air, with its reduction in mind lower air temperature; regenerative heating is stopped when the temperature of the atmospheric air drops to a predetermined value, characterized in that, both in the heating and non-heating periods of operation, the heat of the combustion products is used to generate medium-pressure superheated steam, it is expanded in a counter-pressure heating steam turbine, the useful work of which is used for electricity generation, expanded steam is condensed, the heat of condensation of the steam is used to heat the heating network water, the condensate is deaerated, compressed bathe and use in a waste heat boiler to generate superheated steam; during the heating period, when the temperature of the atmospheric air drops to a predetermined value, between the steps of the evaporator of the recovery boiler, additional fuel is burned, the production of superheated steam is increased, the electric power of the electric generator and the thermal power of the installation, the consumption of additional fuel is increased with increasing heat load of consumers. 2. Installation of a maneuverable regenerative cogeneration combined-cycle combined heat and power plant, including a gas turbine unit with a compressor, a combustion chamber, a gas turbine, a regenerative air heater, an electric generator, a gas-water heater for network water; the compressor output is connected through a combustion chamber to a gas turbine connected by a common shaft through a compressor to an electric generator, the gas turbine output is connected to the inlet of the regenerative air heater, its output is connected to the atmosphere through a gas-water heater of network water, characterized in that the compressor output is also connected to the combustion chamber through the regulator and the bypass duct, the outlet of the regenerative air heater is connected to the superheater of the recovery boiler, in which it will evaporate along the gases eh the second stage afterburning chamber, the evaporator of the first stage, second stage economiser, the economiser first stage; the superheater is connected by a superheated steam steam line to the input of a cogeneration counterpressure steam turbine, the cogeneration of which is paired with a second stage network heater, and the steam turbine output is connected to a first stage network heater connected by a condensate line through the first stage economizer, deaerator and feed water pipe, to the feed pump, with an economizer of the second stage, the return pipe of the heating network is connected to the pipeline of the direct heating line through the network howling heater of the first stage, network heater of the second stage, as well as through a gas-water heater of network water.

Images