WO1992021858A1

WO1992021858A1 - Environmentally acceptable energy generation process and plant in a combined gas/steam generating power station

Info

Publication number: WO1992021858A1
Application number: PCT/DE1992/000412
Authority: WO
Inventors: Gerhard Scholl; Friedrich Bleif; Lothar Stadie; Hans-Karl Petzel
Original assignee: Saarbergwerke Aktiengesellschaft; Siemens Aktiengesellschaft
Priority date: 1991-05-25
Filing date: 1992-05-21
Publication date: 1992-12-10
Also published as: DE4117192A1; EP0586431A1; DE4117192C2; JPH06511060A; AU1691892A; CA2109963A1

Abstract

A process is disclosed for generating energy in a combined gas/steam generating power station in an environmentally acceptable manner by the efficient expansion of a high-pressure hot working medium in a gas turbine (4) and of high-pressure overheated steam in a steam turbine (11). The residual heat from the expanded working medium in the gas turbine (4) is used to generate steam. The steam is further heated before being expanded in a heat exchanger (7) arranged in the heating chamber of a fluidized bed furnace (8) and part (20) of the efficiently expanded and cooled working medium from the gas turbine is mixed into the fresh air to be compressed in the gas turbine.

Description

Process for the environmentally compatible generation of energy in a combined gas-steam power plant and plant for carrying out the process

The invention relates to a method for the environmentally compatible generation of energy in a combined gas-steam power plant by work-relieving relaxation of a high-tension hot working medium in a gas turbine and of high-tension superheated steam in a steam turbine, the residual heat of the relaxed working medium of the gas turbine Generation of water vapor is used, as well as a plant for performing such a method.

In the known process for the combined generation of power using gas and steam turbines in general, the accumulating in the oil or gas fired combustor of the gas turbine compressed working gas at a Tempe¬ is first work-expanded temperature of now more than 1,000 ^* C in the gas turbine and then further cooled in a waste heat boiler to produce high-pressure steam. The cooled flue gas is released into the atmosphere via a chimney. The steam generated is expanded in a steam turbine. In this procedure, the steam temperatures and thus the working capacity of the steam turbine are disadvantageously predetermined or limited by the, in some cases, relatively low exhaust gas temperatures of the gas turbine.

In addition, the exhaust gases of the gas turbine having high concentrations Stickoxidkon¬, ^'since the combustion is performed in excess of the combustion chamber at high temperatures and considerable air or oxygen. The excess of oxygen is to be attributed to the fact that an amount of air which goes far beyond the actual amount of combustion air is required to make available the mass flow required for the gas turbine.

The invention is therefore based on the object of a method of the type mentioned at the outset for generating energy in a combined gas-steam turbine process both for achieving higher outputs and thus for reducing the specific CO2 emissions and also for reducing the nitrogen oxide ¬ to further develop emissions.

This object is achieved in that the water vapor is additionally overheated before it relaxes in the furnace of a fluidized bed furnace.

Due to the proposed additional heating of the water vapor before it relaxes, the performance of the turbine is increased considerably. For example, performs a Tempe¬ raturerhöhung the highly strained water vapor from 500 * C to 600 ^* C already an increase in the turbine power by more than 5%. It proves particularly advantageous that the temperature increase of the water vapor takes place in a fluidized bed furnace, since such furnaces are characterized by particularly good heat transfers from the fluidizing bed material to the heat exchanger surfaces immersed in the bed. As a result of the relatively low and, above all, very uniform temperatures distributed over the cross section of the bed there are also no material problems with regard to the heat exchanger tubes through which the high pressure steam flows. Due to the low bed temperatures, the formation of thermal nitrogen oxides is also not very pronounced in fluidized bed firing.

According to the invention, the fluidized bed combustion can be operated both with oil or gas and with a solid fuel, with in the case of oil or gas firing a suitable foreign material, such as e.g. Quartz sand, to be provided as bed material, while the ashes are used as bed material in the combustion of coal.

The nitrogen oxide formation in the combustion chamber of the gas turbine can also be considerably reduced if, according to a further feature of the invention, part of the working medium of the gas turbine, which is relaxed and cooled during work, that is to say the low-oxygen gas turbine exhaust gas, is mixed with and mixed with the fresh air to be compressed is fed back into the combustion chamber of the gas turbine. This measure replaces the part of the fresh air, which was essentially only provided as a mass flow for the gas turbine in a method according to the prior art, with the oxygen-poor exhaust gas from the gas turbine, so that the combustion in the combustion chamber with far less excess oxygen can be done. This in turn has the consequence that almost no thermal nitrogen oxides are generated in the combustion chamber of the gas turbine.

The remainder of the non-recycled gas turbine gas, which still has a temperature of approximately 80 ° C., is expediently mixed with the flue gas from the fluidized bed furnace and released together with the latter into the atmosphere via a suitable chimney.

If the fluidized bed combustion is operated with coal, additional devices for dust separation and reduction are provided the sulfur oxides required, such as; the installation of an electrostatic filter and a wet wash. In this case ver¬ the cleaned flue gas leaving the desulfurization fully saturated at a temperature of about 40 ^* C. The proposed mixing of such a flue gas with the exhaust gas from the gas turbine leads to an increase in the temperature with a corresponding improvement in the thermal conduction into the atmosphere via a cooling tower.

The proposal according to the invention for the process engineering combination of a gas turbine with a waste heat boiler and a fluidized bed combustion proves to be particularly advantageous in the case of small and medium-sized power plants with an output of approximately 50-300 MW.

In the case of a higher power requirement, the invention provides for the integration of a further self-heated steam generator, in which case the flue gases from the fluidized bed furnace are then introduced directly into the furnace of the further steam generator. As a result, the residual heat of the flue gas from the fluidized bed furnace can be directly used in the further steam generator. In addition, there are no separate measures for cleaning the flue gases from the fluidized bed furnace. Also, due to the low nitrogen oxide concentration in the flue gas from the fluidized bed combustion, the nitrogen oxide content in the total smoke gas stream of the further steam generator can be influenced favorably. This is particularly the case when, similarly to the gas turbine, part of the cleaned flue gas flow is fed back into the fluidized bed furnace instead of fresh air and in this way an almost stoichiometric combustion in the fluidized bed is achieved, with the result that thermal nitrogen oxides are reduced to zero . Incomplete combustion with increased formation of carbon monoxide does not prove to be disadvantageous, since the flue gas is introduced into the combustion chamber of the further steam generator and is subsequently burned there. According to a further feature of the invention, the temperature and thus the working capacity of the superheated high-pressure steam obtained in the further steam generator can be increased if it is mixed with the very hot water vapor from the fluidized bed combustion in a suitable mixing collector before it is released , and both steam flows are then fed to the same steam turbine.

A combined gas-steam power plant for carrying out the method according to the invention has a gas turbine, a waste heat boiler downstream of the gas turbine for steam generation and a steam turbine and is characterized by a fluidized bed combustion with a heat exchanger arranged in the combustion chamber, the cold end of which connects to the steam outlet of the heat exchanger and its warm end mi ^* ; - is connected to the steam inlet of the steam turbine.

Particularly in the case of large power plants with an output> 500 MW or when retrofitting existing power plants, it proves expedient to integrate a further mixing collector in the steam line from the fluidized bed furnace to the steam turbine, and this in addition with the hot end of the water-steam cycle to connect the further steam generator. In addition, a connecting line for the flue gas from the fluidized bed combustion system must be provided between the fluidized bed and the combustion chamber of the further steam generator.

If all of the features according to the invention are implemented, an environmentally compatible large-scale power plant with an efficiency> 45% can therefore be represented.

With an optimal design, that is, with an optimal distribution of the required total heat output to the various firings in the combustion chamber of the gas turbine, in the fluidized bed system and in the further steam generator, due to the low formation of nitrogen oxide in the combustion chamber and in the fluidized bed -6-

the nitrogen oxide content is also relatively low in the total smoke gas flow to be released into the atmosphere, so that - depending on the required limit values - only correspondingly reduced measures or no measures at all are required for subsequent denitrification of the smoke gases. Of course, due to the high level of efficiency, the formation of CO2 is reduced accordingly.

It is obvious that the application of the invention also lends itself particularly to the retrofitting of existing power plants. Instead of installing a denitrification system that is relatively expensive in terms of both investment and operating costs (e.g. high own energy requirements), the proposed measures, such as connecting upstream and connecting a gas turbine and fluidized bed combustion to the existing steam generator and moving a part, can now be implemented the heat output of the steam generator on the upstream furnaces. Assuming that the investment costs for the proposals according to the invention are comparable at least in the order of magnitude with the costs for subsequent denitrification measures, it follows that at least the energy gain resulting from the increase in efficiency is made available practically free of charge.

In connection with the retrofitting of old power plants, but also in the construction of new power plants, the invention with the same advantages can be used both in coal dust furnaces with dry ash removal and in furnaces with liquid ash extraction.

Further explanations of the invention can be found in the exemplary embodiments shown schematically in the figures. Show it:

Figure 1 shows an embodiment of a combined steam power plant in the range of small to medium power and

Figure 2 shows an embodiment in connection with the Um-. or retrofitting an existing coal-fired power plant.

According to FIG. 1, fresh air for the gas turbine cycle is fed to the system via a line 1, compressed to about 6-20 bar in a compressor 2 and then introduced as combustion air into a gas or oil-fired combustion chamber 3. The hot working gas produced in the combustion chamber 3 is expanded to about 1 bar in a gas turbine 4, which is seated on a shaft with a generator 5 and the compressor 2. The inlet temperature of the gas turbine 4 is approximately 800 - 1,300 * C and the outlet temperature is approximately 400 - 600 * C.

The residual heat of at 400-600 ^* C accumulating exhaust gas of the Gas¬ turbine 4 is used in a waste heat boiler 6 for generating steam for the steam turbine process. This high-tension (approximately 20-300 bar) water vapor occurring in the waste heat boiler 6 at a temperature of approximately 300-500 ° C. is now, according to the invention, in a heat exchanger 7 which is arranged in the fluidized bed of a fluidized bed furnace 8 with a fuel supply 9, to a temperature of about 540-600 ^* C, and then further heated in a relaxed connected to a generator 10 steam turbine. 11 The processed steam is liquefied in a condenser 12, pressurized again in a feed water pump 13 and returned to the waste heat boiler 6 via a line 23 in the circuit. It has been shown that the performance of the steam turbine 11 can be increased considerably by the further overheating of the water vapor in the fluidized bed furnace 8.

The flue gas of the fluidized bed system 8 fired with coal in the present example is cooled in a heat exchanger 14 against fresh air, dedusted in an electrostatic filter 15, in one. System 16 desulfurized and then withdrawn via a line 17. A suction fan 24 serves to compensate for the pressure losses.

The fresh air required for the fluidized bed combustion 8 is supplied via a line 18, an induced draft fan 19 and a pressure increasing fan 25.

With the proposed method, in addition to the increase in performance achieved by the overheating in the fluidized bed furnace 8, a considerable reduction in nitrogen oxide formation can also be achieved if a partial stream of the gas turbine exhaust gas is continuously mixed with the fresh air via a line 20 and together with this in the combustion chamber 3 is returned. The amount of the recirculated exhaust gas partial flow is measured according to the mass flow required for optimal performance of the gas turbine 4 and can be up to 50% of the total exhaust gas amount. With an optimal design, only the amount of fresh air required for the combustion in the combustion chamber 3 is supplied and the additional amount required as mass flow for the gas turbine 4 is provided by recirculated oxygen-poor exhaust gas. In this way it is achieved that the combustion in the combustion chamber 3 takes place with substantially less, or with an optimal design, no oxygen excess at all, with the result that thermal nitrogen oxides form towards zero.

For the same reasons, part of the flue gas from the fluidized bed furnace 8 can also be returned to the furnace via a line 21, the fluidized bed Firing (8) is known, however, already characterized by a low nitrogen oxide formation.

The virtually non-nitrogen oxide-free residual stream of the gas turbine exhaust gas which is not returned to the combustion chamber 3 is fed via a line. 22 deducted, mixed with the flue gas stream flowing via line 17 and released into the atmosphere via a chimney or a cooling tower, not shown here. Additional measures for denitrification are generally not necessary to achieve the required limit values.

In the embodiment according to FIG. 2, the invention is explained again using the example of converting or retrofitting an existing hard coal-fired power plant to a low-nitrogen-gas flue gas output, instead of the usual denitrification device downstream of the power plant boiler, e.g. a catalytically accelerated denitrification with ammonia as a reactant, the proposals according to the invention are now used. In FIG. 2, the same reference numbers as in FIG. 1 are provided for the same device parts.

The power plant to be retrofitted consists of a steam generator 30 with a dry-ash buried fire chamber 31, a fuel supply 32 and heating surfaces 33, 34 for generating the high-pressure steam in the water-steam cycle, which in addition to the heating surfaces 33, 34 is a steam turbine 35 as further main components having a generator 36, a steam condenser 37 and a feed water pump 38. The flue gas from the steam generator 30 successively passes through an air preheater 39, an electrostatic filter 40, a suction fan 41, a desulfurization system 42 and is then fed via line 43 to a chimney (not shown) or a cooling tower (also not shown) for discharge into the atmosphere . The required fresh air is drawn in via a fresh air blower 44, preheated in the heat exchangers 45 and 39 and then fed into the combustion chamber 31.

In order to reduce the nitrogen oxides, but also to increase the overall efficiency at the same time, it is now proposed to couple the existing power plant with a power plant according to FIG. 1 and part of the combustion output of the steam generator 30, which is associated with the customarily high nitrogen oxide formation, by means of the additional low nitrogen oxide firings to be replaced in the combustion chamber 30 of the gas turbine cycle and in the fluidized bed system 8.

The coupling takes place, inter alia, in that the still hot, low nitrogen oxide flue gases of the fluidized bed system 8 are introduced directly into the combustion chamber 31 of the steam generator 30, whereby on the one hand the residual heat of the flue gases is emitted directly to the water-steam circuit 33, 34 of the steam generator 30 can and on the other hand the existing devices for flue gas cooling and purification can also be used for the treatment of the flue gases of the fluidized bed furnace 8.

The high pressure steam of the steam generator 30 is mixed with the strongly superheated water vapor from the fluidized bed system 8 in a mixing collector 46 after it has been relaxed in the steam turbine 35. The resulting mixing temperature is above the maximum temperature achievable in the steam generator 30, so that the steam turbine 35 has a higher inlet temperature with a corresponding increase in output.

After a further merlcnal, the exhaust gas stream of the gas turbine 4 flowing via the line 22, which is still a temperature -11-

of about 80 * C, mixed with the flue gas in line 42, which has been desulfurized in most power plants and is thus saturated with water vapor at a temperature of about 40 * C. This mixing leads to an increase in the temperature of the total smoke gas stream and accordingly improves the thermal conditions for the discharge into the atmosphere via a cooling tower.

Since the total smoke gas flow of the power plant is now composed of the partial flue gas flows of the three firings described, namely the combustion chamber 3, the fluidized bed furnace 8 and the furnace 31 of the steam generator 30, the flue gas streams from the combustion chamber 3 and the fluidized bed furnace 8 being almost the result of the proposed measures are nitrogen oxide-free, with a corresponding optimization, in particular in old plants with dry ash removal, a final nitrogen oxide concentration can generally be set which satisfies the respectively required limit values. In addition, the integration of a gas turbine cycle and the additional superheating of the water vapor in the mixing collector 46 can improve the efficiency of the power plant> 45% with a corresponding reduction in the specific CO2 emissions.

Claims

Patent claims

1. Process for the environmentally compatible generation of energy in a combined gas-steam power plant by work-relieving relaxation of a high-tension hot working medium in a gas turbine and of high-tension superheated steam in a steam turbine, the residual heat of the relaxed working medium of the gas turbine Generation of the water vapor is used, characterized in that the water vapor is additionally heated in a heat exchanger arranged in the firing chamber of a fluidized bed firing prior to its relaxation.

2. The method according to claim 1, characterized in that a part of the work-relaxing and cool down working means of the gas turbine is mixed with the fresh air to be compressed of the gas turbine.

3. The method according to claims 1 or 2, characterized gekenn¬ characterized in that the flue gases of the fluidized bed combustion are introduced into the furnace of a further steam generator.

4. The method according to any one of claims 1 to 3, characterized in that the water vapor generated in the further steam generator is mixed with the superheated steam in the fluidized bed combustion.

5. The method according to any one of claims 1 to 4, characterized in that a part of the cleaned flue gases from the fluidized bed combustion or the further steam generator is returned to the fluidized bed combustion.

6. The method according to any one of claims I to 5, characterized in that the non-recirculated rest of the work-relieved relaxed working medium of the gas turbine is mixed with the cooled, cleaned flue gas from the fluidized bed combustion or the additional steam generator.

7. Combined gas-steam power plant for performing the method according to claim 1 with a gas turbine, a downstream of the gas turbine waste heat boiler for steam generation and a steam turbine, characterized by a fluidized bed combustion (8) with a heat exchanger (7) arranged in the combustion chamber, the cold end of which with the steam outlet of the waste heat boiler (6) and the warm end of which is connected to the steam inlet of the steam turbine (11).

8. Combined gas-steam power plant according to claim 7, da¬ characterized in that a mixing header (46) is integrated in the steam line from the fluidized bed firing to the steam turbine, which additionally with the hot end of the water-steam circuit of a further steam generator (30) communicates and that a connecting line for flue gas is provided between the fluidized bed combustion (8) and the combustion chamber (31) of the further steam generator (30).

9. Combined gas-steam power plant according to claim 8, da¬ characterized in that the further steam generator (30) is the steam generator of an existing coal power plant.