RU2326247C1 - Method of combined cycle power plant operation with closed circuit of gas circulation - Google Patents

Abstract

FIELD: heat power industry.

SUBSTANCE: invention relates to combined cycle power plant (CCPP) with closed gas circulation circuit. Method of CCPP operation with closed gas circulation circuit is that gas is heated in heater and then supplied to gas turbine where part of gas heat is converted into mechanical work. Other part of gas heat is exchanged to liquid contained in heat exchangers having serial connection by liquid and steam is produced at heat exchangers outlet. Cooled in heat exchangers gas is compressed and returned to heater for re-heating and produced from liquid steam is supplied to steam turbines to convert stream energy into mechanical work. Gas is compressed in multi-stage compressor where additional heat exchangers are installed between stages to evaporate liquid by gas heat. Produced steam is heated in first steam heat exchanger installed on the way of gas supply after gas turbine. Liquid is evaporated in the second heat exchanger after gas turbine and is heated to the temperature close to boiling temperature in the third heat exchanger after gas turbine. Liquid is simultaneously evaporated in additional heat exchangers connected in parallel in the direction of liquid movement to heat exchanger for liquid evaporation and interconnected in series in gas movement direction between compressor stages.

EFFECT: invention allows to increase heat efficiency factor of CCPP with closed gas circulation circuits.

Description

The invention relates to combined cycle gas turbine power plants.

A known method of operation of a combined cycle gas turbine power plant is that the gas is heated in a heater, the heated gas is sent to a gas turbine, where part of the heat of this gas is converted into mechanical work, then part of the heat of this gas is transferred to the liquid in series heat exchangers to obtain this liquid at the outlet of the heat exchangers, after which the gas cooled in the heat exchangers is compressed by a compressor and returned to the heater for re-heating , and the steam received from the liquid is sent to steam turbines to convert steam energy into mechanical work (see, B. G. Ganchev et al., edited by N. A. Dollezhal. Nuclear power plants, textbook for universities. - M .: Energoatomizdat, 1990, p. 124).

In this method, the liquid is evaporated with a large change in the temperature head between the gas and the liquid, since the temperature of the gas during heat transfer decreases, and the temperature of the evaporated liquid is constant. A large change in the temperature head in the evaporator limits the thermal efficiency of the closed steam-gas cycle due to the limitation of the temperature of evaporation of the liquid at the given parameters of the gas turbine.

The problem to which the present invention is directed, is to increase the efficiency of transfer of thermal energy from heated liquid gas.

The technical result achieved by using the invention is to increase the thermal efficiency of combined-cycle power plants with a closed gas circuit.

This problem is solved, and the technical result is achieved due to the fact that the method of operation of a combined cycle gas power plant with a closed gas circuit, which means that the gas is heated in a heater, the heated gas is sent to a gas turbine, where part of the heat of this gas is converted into mechanical work then part of the heat of this gas is transferred to the liquid in heat exchangers connected in series with the liquid to obtain this liquid at the outlet of the steam heat exchangers, after which the gas cooled in the heat exchangers they are compressed by a compressor and returned to the heater for reheating, and the steam obtained from the liquid is sent to steam turbines to convert the steam energy into mechanical work, while the gas is compressed in a multi-stage compressor, additional heat exchangers are installed between the compressor steps to evaporate the liquid with the heat of this gas, and after evaporation of the liquid, the resulting steam is heated in a steam heat exchanger installed first along the gas after the gas turbine, in the second along the gas after the gas turbine the exchanger evaporates the liquid and in the third heat exchanger downstream of the gas turbine, the liquid is heated to a temperature close to the boiling point, while the liquid is evaporated in additional heat exchangers connected in parallel along the liquid to the heat exchanger to evaporate the liquid and interconnected in series along the gas compressor steps.

The choice of the degree of compression of the gas in the compressor stages and the regulation of the liquid flow through the heat exchangers preferably provide the same gas temperature at the outlet of the heat exchangers to evaporate the liquid.

The gas can be heated in the heater in at least two stages, and after leaving the first stage, the heated gas is sent to additional gas turbines parallel to the first stage of the heater to convert part of the heat of the gas heated in the first stage to mechanical work.

The steam heat exchanger can be made in two sections, and between the sections of the steam heat exchanger along the steam, part of the heat of this steam is converted into mechanical work in additional steam turbines, and gas is supplied to these sections in parallel flows.

Considering that the liquid is evaporated with a large change in the temperature head between the gas and the liquid, since the temperature of the gas decreases during heat transfer and the temperature of the liquid being evaporated is constant, the gas is evaporated by the heat of the gas into several successive stages along the gas side when the vaporized liquid is supplied to these stages allows you to reduce the temperature difference in the heat exchangers for evaporation of the liquid in the number of times corresponding to the number of these heat exchangers, that is, to increase the temperature liquid evaporation at constant gas turbine parameters. Due to this, an increase in thermal efficiency of the combined cycle plant is achieved.

The choice of the degree of compression of the gas in the compressor stages and the regulation of the flow rate of the evaporated liquid ensures the same gas temperature at the outlet of the heat exchangers to evaporate the liquid. Due to this, it is possible to maintain a minimum temperature head in these heat exchangers and, accordingly, a maximum temperature of liquid evaporation.

The gas in the heater can be heated in at least two stages, between which part of the heat of this gas is converted into mechanical work in additional gas turbines. With a constant maximum gas temperature, this will increase the degree of gas compression and, accordingly, increase the thermal efficiency of a combined cycle power plant.

Steam can be heated in at least two sections of the steam heat exchanger along the steam, between which it is possible to convert part of the heat of this steam into mechanical work in additional steam turbines, and gas can be supplied to these sections in parallel flows. The parallel gas supply to the steam heat exchanger section facilitates the regulation of the steam turbine operation mode.

The drawing shows a schematic diagram of a combined cycle gas turbine power plant.

The combined cycle gas turbine power plant contains a heater 1, a gas turbine 2 connected to it, heat exchangers 3, 4 and 5 connected in series with the fluid, the heat exchanger 3 being made steam and a multi-stage compressor 6. Additional heat exchangers 7 are installed between the stages of the compressor 6, the latter being connected in parallel along the liquid path to the heat exchanger 4 for evaporation of the liquid and sequentially connected to each other along the gas flow between the stages of the compressor 6.

The heater 1 is made two-stage, and additional gas turbines 9 are connected in parallel to the first stage 8 of the heater 1, and the gas turbine 2 is connected to the output of the second stage 10 of the heater 1.

The steam heat exchanger 3 is made two-section. The second stage 11 of the steam heat exchanger 3 is connected to the steam turbine 12, between the sections 11 and 13 of the steam heat exchanger 3 along the course of the steam, additional steam turbines 14 are installed.

The method of operation of a combined cycle gas turbine power plant is that the gas is heated in the heater 1. The heated gas is sent to a gas turbine 2, where part of the heat of this gas is converted into mechanical work. Then part of the heat of this gas is transferred to the liquid in heat exchangers 3, 4, and 5 connected in series with the liquid to obtain steam from this heat exchanger 3, 4, and 5, which is sent to the steam turbine 12. The gas cooled in the heat exchangers 3, 4, and 5 is compressed multi-stage compressor 6 and returned to the heater 1 for re-heating. In additional heat exchangers 7, parallel to the heat exchanger 4, the liquid is additionally evaporated by the heat of the gas heated in the stages of the multi-stage compressor 6, and after the liquid is evaporated, the resulting steam is additionally heated in the steam heat exchanger 3, installed first along the gas after the gas turbine 2. From the heat exchanger 3, the steam is sent to the steam a turbine 12 for converting its energy into the mechanical work of rotating the shaft of the steam turbine 12. In the second gas along the gas turbine 2, the heat exchanger 4, as described above, is yayut liquid and in the third direction of the gas after the gas turbine 2 liquid heat exchanger 5 is heated to a temperature close to boiling temperature.

The choice of the degree of compression of the gas in the stages of the compressor 6 and the regulation of the liquid flow through the heat exchangers 4 and 7 preferably provide the same gas temperature at the outlet of the heat exchangers 4 and 7 to evaporate the liquid.

The gas can be heated in the heater 1 in at least two stages 8 and 10, and after leaving the first stage 8, the heated gas is sent to additional gas turbines 9 connected in parallel to the first stage 8 of the heater 1 to convert part of the heat heated in the first stage 8 gas in mechanical work.

The steam heat exchanger 3, as noted, can be performed in two sections, and between the sections 13 and 11 of the steam heat exchanger 3 along the steam, in part of the additional steam turbines 14, part of the heat of this steam is converted into mechanical work, and gas is supplied to these sections 13 and 11 in parallel flows.

The present invention can be used in energy, for example in nuclear energy.

Claims (4)

1. The method of operation of a combined cycle gas-fired power plant, in which the gas is heated in a heater, the heated gas is sent to a gas turbine, where part of the heat of this gas is converted into mechanical work, then part of the heat of this gas is transferred to the liquids in series heat exchangers in liquid to produce this liquid at the outlet of the steam heat exchangers, after which the gas cooled in the heat exchangers is compressed by a compressor and returned to the heater for re-heating, and the floor The steam from the liquid is sent to steam turbines to convert the steam energy into mechanical work, characterized in that the gas is compressed in a multi-stage compressor, additional heat exchangers are installed between the compressor steps to evaporate the liquid with the heat of this gas, and after the liquid has evaporated, the steam obtained is heated in a steam heat exchanger, installed first along the gas after the gas turbine, in the second along the gas after the gas turbine heat exchanger evaporate the liquid and in the third along the gas after the gas Urbina liquid heat exchanger is heated to a temperature close to the boiling point, and simultaneously vaporized liquid in the additional heat exchangers are connected in parallel during the fluid to the heat exchanger for evaporation of a liquid and interconnected in series along the gas between compressor stages. 2. The method according to claim 1, characterized in that the choice of the degree of compression of the gas in the compressor steps and the regulation of the liquid flow through the heat exchangers provide the same gas temperature at the outlet of the heat exchangers for evaporation of the liquid. 3. The method according to claim 1, characterized in that the gas is heated in the heater in at least two stages, and after exiting the first stage, the heated gas is sent to additional gas turbines parallel to the first stage of the heater to convert part of the heat of the heated into the first stage of gas into mechanical work. 4. The method according to claim 1, characterized in that the steam heat exchanger is performed in two sections, and between the sections of the steam heat exchanger along the steam, part of the heat of this steam is converted into mechanical work in additional steam turbines, and gas is supplied to these sections in parallel flows.