RU2527010C2 - Gas turbine plant with water steam injection - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: gas turbine plant with water steam injection in a gas turbine circuit comprises a compressor for compressing air, a fuel pump, means for supplying fuel, a combustion chamber, a gas turbine, an electric generator for power generation, mechanical means for transmitting mechanical energy from the turbine to the compressor operation and the rotation an electric generator, a heat recovery boiler. In the combustion chamber the air compressed by the compressor enters and the supplied fuel and their mixing, ignition and combustion is carried out. The heat recovery boiler is designed for heating the fed water and generation of steam due to combustion products heat, the steam injection system in the combustion chamber. The gas turbine plant is equipped with the supply system of combustion promoter and the system of mixing the combustion promoter with the water steam injected into the combustion chamber.

EFFECT: invention is aimed at increase in the specific power rating, increase in efficiency, reduction in specific fuel consumption and increase (prolongation) of the resource, and reduction of the emission to the atmosphere of toxic substances such as nitrogen oxides (NO_x) and carbon monoxide (CO) with the combustion products.

1 dwg

Description

The invention relates to gas turbine units (GTU) with water vapor injection (gas-steam power plants) and can be used to increase specific power, increase efficiency, reduce specific fuel consumption and increase (extend) the resource, as well as to reduce emissions of toxic substances into the atmosphere with products combustion.

Known gas-steam cycle STIG (Steam Injected in Gas) of the company "General Electric" (USA) (Kolp D.A., Meller D.Z. Commissioning of the world's first gas turbine full cycle STIG based on the LV-5000 gas generator. Modern engineering, series A, 1989, No. 11, pp. 1–14.), in which, in order to increase the efficiency and specific power of a gas turbine power plant, they supply (inject) water vapor to the gas turbine combustion chamber (CS). Water vapor (hereinafter for brevity "steam"), used as an additional working fluid for turbine operation, is obtained in a regenerative heat exchanger, the so-called a waste heat boiler by heating and evaporating the supplied water due to the heat of the combustion products. Similar schemes were used in the domestic installation of MES-60 (Batenin V.M., Belyaev V.E., Vasyutinsky V.Yu. and others. Integrated combined-cycle plant with steam injection and heat pump unit (CCP MES-60) for Mosenergo The Institute of High Temperatures of the Russian Academy of Sciences, MMPP FGUP Salyut, OJSC Mosenergo, Moscow, 2001), as well as are described, for example, in US Patents No. 4823546 dated 04/25/1989, No. 5564269 dated October 15, 1996, No. 6370862 dated April 16. 2002.

Along with achieving higher energy characteristics, the use of the STIG cycle lowers the flame temperature in the combustion chamber and inhibits the formation of toxic nitrogen oxides (NO _x ), and their concentration in emissions decreases several times. However, lowering the flame temperature slows down the combustion processes and reduces the completeness of combustion of methane (the main component of gas fuel), and with an increase in steam injection, the concentration of carbon monoxide CO (the main product of "unburning") in emissions. Therefore, due to an unacceptable increase in CO concentration with a substantial increase in steam injection, in the indicated STIG cycle it is not possible to increase the ratio of the mass of injected steam to the mass of methane burned above a critical level of about 2: 1.

A fundamental obstacle to increasing the steam: methane ratio above critical in the STIG cycle is the inability to uniformly mix the injected steam with gas components for a short time in the combustion chamber (see, for example, Ivanov A.A., Ermakov A.N., Shlyakhov R. A. About deep suppressing NO _x emissions and CO in the gas turbine with injection water or steam. Math. Sciences, Energy, 2010, №3, 119-128). As a result, local regions with both low and high steam content are formed in the CS relative to the average steam: methane ratio (2: 1). In areas with a high proportion of steam, i.e. under conditions of a strong decrease in temperature, the process of burning out CO is excessively inhibited, and this leads to an unacceptable increase in the concentration of CO in the emissions of gas turbines with an increase in steam injection.

Thus, the drawback of the STIG cycle is the excessive retardation of the CO burning process in local areas of the gas turbine compressor station with an increased proportion of steam, where there is a significant decrease in temperature, which prevents the complete combustion of fuel (natural gas, synthesis gas) in the gas turbine compressor station, which cannot be increased steam injection in the gas turbine compressor station above the specified limit with respect to the methane content (2: 1), and, accordingly, it is impossible to further increase the efficiency of a gas turbine unit, and also to reduce the emissions of harmful nitrogen oxides (NO _x ) and carbon monoxide (CO) falling within f with combustion products into the atmosphere.

Closest to the claimed invention in its technical essence is a gas turbine installation with steam injection, described in US patent No. 5564269 from 10/15/1996 (prototype). Such a gas turbine installation contains: a compressor for compressing air, a fuel pump, means (nozzles) for supplying fuel, a combustion chamber, where compressed air and supplied fuel enter, and where they are mixed, ignited and burned, a gas turbine, an electric generator for generating electricity , mechanical means for transferring mechanical energy from the turbine to the compressor and to rotate the electric generator, a waste heat boiler designed to heat the supplied water and produce steam by pla of combustion products, a steam injection system into the combustion chamber.

In this device, as well as in other known devices with steam injection into the gas turbine combustion chamber (see, for example, the canceled patent of the Russian Federation for utility model No. 83544 of 06/10/2009), a local excess of the proportion of steam relative to the average ratio of steam: methane leads excessive temperature decrease and inhibition of the fuel combustion process. This, in turn, leads to its incomplete combustion and to an unacceptable increase in the concentration of carbon monoxide in emissions, because of which it is impossible to increase the proportion of steam injected into the gas turbine engine above a certain limit, and, accordingly, it is impossible to further increase the gas turbine engine efficiency, and reduce emissions of harmful nitrogen oxides (NO _x ) and carbon monoxide (CO), which enter the atmosphere together with combustion products.

The claimed invention is aimed at solving the problem of accelerating the combustion processes and increasing the completeness of combustion of gas fuel while increasing the proportion of water vapor injected into the combustion chamber of a gas turbine.

The essence of the claimed invention lies in the fact that a gas turbine installation with water vapor injection into a gas turbine circuit containing a compressor for compressing air, a fuel pump, means for supplying fuel, a combustion chamber, where compressed air and fuel are supplied by the compressor, and where they are mixed, ignition and combustion, a gas turbine, an electric generator for generating electricity, mechanical means for transferring mechanical energy from the turbine to the compressor and the rotation of the electric generator, recovery boiler Op for heating the feed water and produce steam by the heat of combustion, steam injection into the combustion chamber system, equipped with a further feed system and combustion system activator mixing combustion activator steam injected into the combustor.

The implementation of the claimed invention provides several technical results, including: 1) acceleration of combustion processes, 2) increase in the completeness of methane combustion, 3) increase in gas turbine efficiency, 4) decrease in harmful emissions of nitrogen oxides and carbon monoxide, 5) increase in specific gas turbine power, 6) decrease in specific fuel consumption in gas turbines; 7) increase in gas turbine service life.

The combustion activator is a substance that easily dissociates at elevated temperatures to form hydroxyl radicals (OH), which accelerates the combustion of fuel and the products of its high-temperature transformations, including CO. One example of a combustion activator is hydrogen peroxide (H ₂ O ₂ ), which at high temperatures easily dissociates with the formation of hydroxyl radicals (OH), which contributes to the acceleration and deepening of the fuel combustion process, including in local areas of gas turbine compressor stations with an increased proportion a pair where a strong drop in temperature occurs. Increasing the completeness of combustion of CO allows increasing the injection of steam into the combustion chamber, due to which it is possible to increase the efficiency and at the same time lower the content of CO and nitrogen oxides in emissions. The activator combustion advantageous to use aqueous solutions of hydrogen peroxide (H ₂ O _2), in particular, 30% aqueous hydrogen peroxide solution (H ₂ O _2).

The acceleration and deepening of the fuel combustion process under the action of a combustion activator allows the use of such systems for mixing a combustion activator with steam, such as, for example, steam ejectors.

An example of a gas turbine device of the present invention is shown in FIG.

A gas turbine gas injection engine in figure 1 contains: a compressor 1 for compressing air, a fuel pump 2, means 3 for supplying fuel, a combustion chamber 4, where compressed air and fuel are supplied by the compressor, and where they are mixed, ignited and burned, a gas turbine 5, an electric generator 6 for generating electricity, mechanical means 7 and 8 for transferring the mechanical energy of the turbine to the compressor 1 and to rotate the electric generator 6, respectively, a waste heat boiler 9, an injection system 10 of steam into the combustion chamber, a system feed 11 of the activator of combustion and the mixing system 12 of the activator of combustion with steam.

The device in figure 1 works as follows. After starting with the help of a gas turbine starter and warming up and reaching the rated mode of the boiler, the utilizer 9 includes an injection system of 10 steam into the combustion chamber. Then include a feed system 11 of the combustion activator, which is used, for example, 30% aqueous hydrogen peroxide (H ₂ O ₂ ), and a mixing system 12 of the combustion activator with steam. Due to the heat of superheated steam in the thus obtained vapor-droplet mixture, predominant evaporation of water occurs due to the greater volatility of its vapor. Due to the predominant evaporation of water, the concentration of the combustion activator in the droplets of the vapor-droplet mixture will increase, and at the same time, its properties as a combustion activator will be enhanced. As a result, a mixture of steam and finely divided moisture containing the required concentration of the combustion activator is sprayed in the combustion chamber 4. When finely dispersed droplets with a high concentration of the combustion activator get into the CS, the combustion of fuel near them is significantly accelerated due to the decomposition (dissociation) of hydrogen peroxide into hydroxyl radicals and their release into the gas phase. In addition, due to the instability of hydrogen peroxide at high temperatures, part of it, upon evaporation of the droplets, turns into water and gaseous oxygen, which contribute, like a propellant, to additionally spray the remaining droplets. Due to the evolution of oxygen and hydroxyl radicals, the addition of a combustion activator contributes to the complete combustion of the fuel and when the ratios of steam to methane are unattainable in the absence of a combustion activator, which increases the efficiency of gas turbine operation. It is important in this case that the bulk of hydrogen peroxide does not undergo premature high-temperature decomposition before it enters the combustion chamber.

By turning on the supply system 11 of the combustion activator and the mixing system 12 of the combustion activator with steam, the following can be achieved: a) an increase in efficiency of more than 3%, b) an increase in power (specific power) in forced mode more than 3% of the nominal; c) a decrease (saving) in fuel consumption in the nominal mode of installed capacity of more than 2%, d) an increase in the service life of a gas turbine in the nominal mode of installed power by more than 1.1-1.2 times due to a decrease in temperature gradients in the circuit of a gas turbine. At the same time, a reduction in harmful emissions of nitrogen oxides by more than 10-50% is achieved due to a decrease in the temperature in the gas turbine combustion chamber, as well as a reduction in carbon monoxide emissions by more than 10-30% due to the activation of combustion.

Claims (1)

A gas turbine installation with water vapor injection into a gas turbine circuit containing a compressor for compressing air, a fuel pump, means for supplying fuel, a combustion chamber, where compressed air and fuel are supplied, and where they are mixed, ignited and burned, a gas turbine, an electric generator for generating electricity, mechanical means for transferring mechanical energy from the turbine to the compressor and to rotate the electric generator, a waste heat boiler designed to heat the supplied water and radiation steam by the heat of the combustion products, steam injection into the combustion chamber system, wherein the gas turbine unit is equipped with a feed system and combustion system activator mixing combustion activator steam injected into the combustor.

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