RU2505682C1 - Power plant - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: power plant includes a steam-gas turbine, a compressor and a fuel combustion chamber. The plant includes a waste gas heat recovery unit having the possibility of its being used as a steam source. For that purpose, the plant is equipped with a heat pump, the circuit of which includes an evaporator, a throttle valve, a condenser and an additional compressor having the possibility of being actuated from the steam-gas turbine. Besides, the plant is equipped with a steam turbine that can operate for one shaft with a steam-gas turbine. On a gas removal line between the outlet of the steam-gas turbine and the heat removal circuit of the condenser there arranged is a heat removal circuit of the heat exchanger. A condenser gas outlet is connected to atmosphere, and its condensate outlet is connected to a condensate trap that is connected to the combustion chamber and to the steam turbine inlet through a line that includes a pump and in-series connected heat-receiving circuits of the heat exchanger and the evaporator; the steam turbine outlet is interconnected with the second condenser, the condensate outlet of which is connected to the condensate trap through the second feed pump.

EFFECT: invention allows reducing heat and water losses to atmosphere.

2 cl, 1 dwg

Description

The invention relates to a power system, in particular to power plants designed to produce electrical energy and / or to perform mechanical work.

A power plant is known, comprising a steam-gas plant equipped with a payload output with steam inlet, the output of which is connected to the first input of the heater, the output of which is connected to the first input of the condenser, the first output of which is in communication with the environment, the first water circuit connected to the second input and the second output of the condenser, including a series-connected first pump and a refrigerator, at its first input and first output, as well as a second water circuit connected to the input dy input steam combined cycle power plant and to the first water circuit comprising a series connected second pump and preheater at its second input and the second output (see. UK application 2074659, cl. F01K 21/04, publ. 04.11.81).

The disadvantages of the known installation are large heat losses with the exhaust gas-vapor mixture and large water losses due to the low efficiency of the refrigerator.

A power plant is also known, which contains a steam-gas plant equipped with a payload output with steam inlet, the output of which is connected to the first input of the heater, the first output of which is connected to the first input of the condenser, the first output of which is in communication with the environment, the first water circulation circuit connected to the second the input and second output of the condenser, including the first pump and the refrigerator connected in series, at its first input and first output, as well as the second water circuit, connect associated with the steam inlet of the combined cycle plant and the first water circulation circuit, including the second pump and heater connected in series, at its second input and second output (see AS USSR 547121, class F01 21/04, published 07.12. 82).

The disadvantages of the known installation are large losses of heat with cooling water and large losses of water due to the low efficiency of the refrigerator. This is explained by the fact that during the operation of the known device a large amount of heat is discharged into the atmosphere, and when the heat discharges into the atmosphere is limited, not all water from the vapor-gas mixture is extracted in the condenser and is also released into the atmosphere.

Closest to the proposed power plant is a power plant containing a combined cycle gas turbine configured to drive a consumer of mechanical energy and a compressor configured to take air from the atmosphere, the output of which is connected to a fuel combustion chamber connected to a fuel source and a steam source, the output of which is communicated with the input of the combined cycle gas turbine; in addition, the facility includes an exhaust gas heat recovery means configured to use it formation in a source of steam (see. Stepanov IR "cycle plant. Basic theory, application and Prospects", Apatity, 2000, pp 100-103.).

Significant disadvantages of this solution are the high costs of demineralized water and low plant efficiency associated with the heat leaving with the steam.

The task to which the proposed technical solution is directed is to reduce heat and water losses to the environment.

The technical result achieved in solving the problem is expressed in an increase in the utilization coefficient of the heat of the installation (the ratio of the amount of power allocated from the turbine to the consumer and the heat allocated from the condenser for technological needs to the heat of combustion of the fuel in the combustion chamber). The solution allows to significantly expand the scope of installations of this type, cutting off the need for a source of fresh water in the area of application. It also reduces the harmful effects of the installation on the environment, reducing the mass of the working fluid removed from the cycle.

The problem is solved in that a power plant comprising a combined-cycle turbine configured to drive a consumer of mechanical energy and a compressor configured to take air from the atmosphere, the output of which is connected to a fuel combustion chamber connected to a fuel source and a steam source, the output of which is communicated with the input of the combined cycle gas turbine, in addition, the facility includes an exhaust gas heat recovery means configured to be used as a source steam, characterized in that the installation is equipped with a heat pump, the circuit of which includes an evaporator, a condenser and an additional compressor configured to be driven by a combined-cycle turbine, while the output of the additional compressor through the heat-transfer circuit of the evaporator and the throttle valve is in communication with the heat-receiving condenser circuit, the output of which is communicated with the input of an additional compressor, in addition, the installation is equipped with a steam turbine configured to work on one shaft with a combined-cycle turbine, to In addition, on the exhaust line between the outlet of the gas turbine and the heat transfer circuit of the condenser there is a heat transfer circuit of the heat exchanger, while the gas output of the condenser is connected to the atmosphere, and its condensate output is connected to the condensate drain, which is connected through a line that includes a feed pump and heat-transferring circuits of the heat exchanger connected in series and an evaporator communicated with the combustion chamber and the input of the steam turbine, while the output of the steam turbine is in communication with the second condenser, a condensate output which through a second feed pump is connected to a steam trap. In addition, the gas outlet of the condenser is equipped with a vacuum pump.

A comparative analysis of the essential features of the proposed technical solution with the essential features of analogues and prototype indicates its compliance with the criterion of "novelty."

The features of the characterizing part of the claims solve the following functional tasks.

The sign "... the unit is equipped with a heat pump ..." provides the possibility of utilizing the heat contained in the discharged (outgoing) volume of the working fluid - the vapor-gas mixture.

Signs indicating that the heat pump circuit includes “an evaporator, a condenser and an additional compressor configured to be driven by a combined-cycle turbine, while the output of the additional compressor through the heat transfer circuit of the evaporator and the throttle valve is in communication with the heat-receiving condenser circuit, the output of which is communicated with the input of the additional compressor "Ensure the selection of heat contained in the discharged (outgoing) volume of the working fluid - the vapor-gas mixture into the heat pump circuit.

The sign "... the installation is equipped with a steam turbine, configured to work on one shaft with a combined cycle gas turbine" allows you to utilize thermal energy that cannot be returned to the cycle of a combined cycle gas turbine.

A sign indicating that “on the gas outlet line between the outlet of the combined cycle gas turbine and the heat transfer circuit of the condenser there is a heat transfer circuit of the heat exchanger” ensures the utilization of the heat of the discharged (outgoing) volume of the working fluid — the gas mixture, at its initial temperature parameters.

The sign "... the gas outlet of the condenser is in communication with the atmosphere ..." provides the discharge into the atmosphere of the dehydrated gas component of the outgoing steam-gas mixture.

A sign indicating that the condensate outlet of the condenser is “connected to the steam trap” ensures the return of condensed water to the heat transfer circuit of the heat exchanger.

A sign indicating that the steam trap "... is in communication with the combustion chamber ..." provides the possibility of forming a working fluid in it - a gas-vapor mixture.

Signs indicating that the steam trap is connected to the combustion chamber and the steam turbine inlet with a “line including the first feed pump and successively connected heat-receiving circuits of the heat exchanger and evaporator” ensure the formation of steam from the condensate, due to the utilization of the heat of the discharged (outgoing) volume of the working fluid — the vapor-gas mixture.

The signs “the output of the steam turbine is in communication with the second condenser, the condensate output of which is connected to the steam trap through the second feed pump” allows you to remove excess heat not transferred to the main working fluid from the evaporator and direct it both to the consumer and to the heat pump compressor drive.

Signs of the second claim provide for the discharge into the atmosphere of the products of fuel combustion and can increase the triggered heat transfer in the turbine.

Figure 1 shows a diagram of a power plant.

The drawing shows a sampling device for atmospheric air 1, a combustion chamber 2, a compressor 3, a fuel source 4 and a steam supply line 5, a gas-turbine 6, a mechanical energy consumer drive 7, a heat exchanger 8, a condenser 9, a vacuum 10 and a first feed pump 11, an evaporator 12 , a steam turbine 13, an additional compressor 14, as well as a heat pump line 15, a pipe 16, a steam trap 17, a butterfly valve 18, a second condenser 19 and a second feed pump 20.

The power plant comprises a combined-cycle turbine 6 configured to drive a consumer of mechanical energy 7 (for example, an electric generator or ship propulsion) and a compressor 3 configured to take air from the atmosphere through means 1 (for example, a filter). The output of the compressor 3 is in communication with the combustion chamber 2 of the fuel associated with the fuel source 4 and the steam source (steam supply line 5), the output of which is communicated with the input of the combined cycle gas turbine 6. The installation includes a means of utilizing waste gas heat, made with the possibility of using it as source of steam. To this end, the installation is equipped with a heat pump, the circuit of which includes an evaporator 12, a condenser 9 and an additional compressor 14, configured to be driven by a combined-cycle turbine 6. The gas output of the condenser 9 can be equipped with a vacuum pump 10. The output of the additional compressor 14 through the heat transfer circuit of the evaporator 12 and the throttle valve 18 is in communication with the heat-receiving circuit of the condenser 9, the output of which is communicated with the input of the additional compressor 14. In addition, the installation is equipped with a steam turbine 13 made with the possibility of working on one shaft with a combined-cycle turbine 6. On the exhaust line between the outlet of the combined-cycle turbine 6 and the heat transfer circuit of the condenser 9, a heat transfer circuit of the heat exchanger 8 is placed. The gas output of the condenser 9 is connected to the atmosphere, and its condensate output is connected to the steam trap 17, which is connected via a line comprising a first feed pump 11 and sequentially connected heat transfer loops of the heat exchanger 8 and the evaporator 12, is in communication with the combustion chamber 2 and the input of the steam turbine 13. The output of the steam turbine 13 communicated with a second capacitor 19, the condensate output of which is connected through a second feed pump 20 to a steam trap 17.

Gas-steam turbine installation operates as follows. Atmospheric air is cleaned in a means of atmospheric air extraction 1, (for example, in a filter) is compressed by a compressor 3 and sent to a combustion chamber 2 where fuel is supplied from a fuel source 4. Steam is supplied to a combustion zone from a steam supply line 5. The gas-vapor mixture of high temperature is fed through the pipeline 16 to the gas-turbine 6. The operation of the gas-turbine 6 is used to compress air in the compressor 3 and drive the consumer of mechanical energy 7 (for example, generating electricity in an electric generator). The expanded (spent) vapor-gas mixture through a pipe 16 is sent to a heat exchanger 8, where the heat of the spent vapor-gas mixture is utilized. From the heat exchanger 8, the vapor-gas mixture is sent to the condenser 9, the vapor component of the vapor-gas mixture is condensed, and the fuel combustion products by the vacuum pump 10 (or directly) are taken off into the atmosphere. The condensed steam is removed from the condenser 9 by means of a steam trap 17 and supplied with condensate from the second feed pump 20 to the first feed pump 11, which increases the pressure of the condensate. Then, through the heat exchanger 8 and the evaporator 12, the steam is sent partially to the combustion chamber 2, partially to the steam turbine 13. The steam that has been exhausted in the steam turbine 13 is condensed in the condenser 19. Then the condensate enters the second feed pump 20, where its pressure rises to the pressure after condenser 9. From the feed pump 20, condensate flows to the first feed pump 11. A secondary steam turbine circuit is introduced to recover the excess heat removed from the condenser 9 by the heat pump, which cannot be efficiently Reda in the evaporator 12 the water circulating in the main circuit. The condensation heat of steam is removed from the condenser 9 by the refrigerant (e.g., water) of the heat pump. The refrigerant from the condenser 9 through the heat pump line 15 enters the input of the additional compressor 14, kinematically connected with the shaft of the combined-cycle turbine 6, then the refrigerant compressed in the compressor 14 from the output of the compressor 14 through the heat-transfer circuits of the evaporator 12, the inductor 18, enters the condenser 9.

Claims (2)

1. Power plant containing a combined cycle gas turbine configured to drive a consumer of mechanical energy and a compressor configured to take air from the atmosphere, the output of which is connected to a fuel combustion chamber connected to a fuel source and a steam source, the output of which is connected to the input of a combined cycle gas turbine in addition, the installation includes a means of utilization of heat of exhaust gases, made with the possibility of its use as a source of steam, characterized in that the installation and equipped with a heat pump, the circuit of which includes an evaporator, a condenser and an additional compressor configured to be driven by a combined-cycle turbine, while the output of the additional compressor through the heat-transfer circuit of the evaporator and the throttle valve is in communication with the heat-receiving circuit of the condenser, the output of which is communicated with the input of the additional compressor, except Moreover, the installation is equipped with a steam turbine configured to work on one shaft with a combined-cycle turbine, in addition, on the gas exhaust line between the outlet of the steam-gas turbine and the heat transfer circuit of the condenser there is a heat transfer circuit of the heat exchanger, while the gas output of the condenser is connected to the atmosphere, and its condensate output is connected to the condensate trap, which is connected to the combustion chamber through a line that includes the feed pump and series-connected heat transfer circuits of the heat exchanger and evaporator and the input of the steam turbine, while the output of the steam turbine is in communication with the second condenser, the condensate output of which through the second second pump is connected to the condensate drain. 2. The power plant according to claim 1, characterized in that the gas outlet of the capacitor is equipped with a vacuum pump.

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