WO2005021935A1

WO2005021935A1 - Steam power plant

Info

Publication number: WO2005021935A1
Application number: PCT/EP2004/008348
Authority: WO
Inventors: Georg Haberberger; Christoph Kail
Original assignee: Siemens Aktiengesellschaft
Priority date: 2003-08-27
Filing date: 2004-07-26
Publication date: 2005-03-10
Also published as: DE20313279U1; RS51511B; JP2007503544A; EG24289A; US20060266040A1; RS20060127A; EP1658418A1; KR20060069852A; CN1842638A; IL173778A0

Abstract

An inventive steam power plant (1) comprises at least one steam turbine (2) and a steam generator (5), whereby a combustion chamber (19), in the direction (9) of the flow of steam (17), is mounted after a first turbine stage (11) and before a second turbine stage (13) of the steam turbine (3), and the flow of steam (9) inside a combustion chamber (19) can be heated by mixing it with a hot gas that can be produced inside said combustion chamber (19).

Description

description

Steam power plant

The invention relates to a steam power plant with at least one steam turbine and a fired steam generator.

In known steam power plants, operating steam for a steam turbine is usually generated in a fired steam generator, the energy contained in a hot gas being released to one or more heat exchangers which are fed with water, so that operating steam can be generated by heating this water, or steam are fed so that an overheating of the steam can be achieved by means of a last-mentioned heat exchanger; such a

In known steam turbines, overheating takes place, for example, between a high pressure stage and a medium pressure stage of the steam turbine, the steam leaving the high pressure stage being overheated by means of an intermediate superheater heating surface arranged in the steam generator and being fed to the medium pressure stage.

Such intermediate superheating of the steam contributes, for example, to a higher efficiency of the steam turbine.

In known steam power plants, the supply of thermal energy for generating and / or reheating steam takes place by means of heat exchanger surfaces which are arranged in the fired steam generator, for example a coal or oil-fired or biomass-fired or generally fossil or nuclear-fired steam boiler, and with one guided in the steam generator Hot gas come into contact. The heated heat exchanger surfaces in turn give off their thermal energy to water and / or steam, which are guided within the body formed by a heat exchanger surface. The heating takes place by means of a heat transfer from the hot gas to the heat exchanger. shear surface and from the heat exchanger surface to the medium to be heated.

Since in the heat exchangers known from the prior art, which are used in steam generators of known steam power plants, the energy of a hot gas is transferred to the medium to be heated by means of a material of the heat exchanger surface heated by the hot gas, the amount of energy which is transferred to the Medium to be heated, for example water and / or steam, can be transferred, limited by the material properties of the heat exchanger surface.

For this reason, the permissible steam temperatures are limited in known steam power plants, since the heat exchanger surface which transfers the thermal energy cannot be heated to an arbitrarily high temperature due to its material properties and the associated thermal load limits.

Furthermore, the heat transfer from hot gas to the medium to be heated is delayed, essentially due to the heating-up time required for the heat exchanger surface.

The invention is therefore based on the object of specifying a steam power plant with at least one steam turbine and a steam generator which can be used flexibly and overcomes the disadvantages mentioned in the prior art.

The object is achieved according to the invention by a steam power plant comprising at least one steam turbine and a fired steam generator, in which a combustion chamber is arranged in the direction of the steam flow after a first turbine stage and before a second turbine stage of the steam turbine, and the steam flow in the combustion chamber by mixing with an in the hot gas that can be generated in the combustion chamber is heated. The invention is based on the consideration that the heat transfer from a hot gas to a medium to be heated is less restricted compared to the prior art if the energy transfer to the medium to be heated does not use a heat exchanger surface.

In the case of the invention, this is achieved in that the steam stream to be heated is introduced directly into a combustion chamber and is mixed there directly with the hot gas.

This internal additional firing according to the invention can be used in the steam flow direction after the steam generator and before the steam turbine, i.e. already for overheating fresh steam, or also for overheating steam, which already releases part of its energy in a turbine stage and, after overheating according to the invention, is fed to a further turbine stage becomes.

By means of a steam power plant according to the invention, higher steam temperatures can be achieved compared to the prior art, which can contribute to a higher efficiency of the steam power plant.

If, in a steam power plant according to the invention, the additional firing realized by means of the combustion chamber is switched off or fails, the steam power plant can continue to be operated like a known steam power plant.

Hydrogen and / or a hydrocarbon, in particular methane, can advantageously be supplied to the combustion chamber as fuel.

In particular, the fuel comprises carbon and / or hydrogen. The main advantage of using hydrogen as a fuel is that if the hydrogen is produced from a hydrocarbon, as is often the case by reforming or gasifying, carbon dioxide is retained during the production of the hydrogen when reforming or gasifying a hydrocarbon with comparatively little energy expenditure can and so the formation of an acidic steam mixture within the steam turbine and / or other components of the steam power plant is avoided from the outset.

In order to achieve particularly good firing of the combustion chamber, the firing device can advantageously be supplied with an oxygen-containing gas, in particular pure oxygen and / or air, in order to generate a combustion atmosphere.

This embodiment of the invention takes into account the requirement that combustion of a fuel is only possible in a suitable combustion atmosphere. A particularly efficient combustion is possible by supplying pure oxygen, since compared to air this contains no further components which are more of a hindrance to the combustion and which may would have to be separated before the combustion, for example in an air separation device, in order to create a suitable combustion atmosphere.

In a further preferred embodiment of the invention, the resulting combustion products can be removed from the steam flow by means of a condenser connected downstream of the steam turbine.

In practically all combustion processes, combustion products are created, which are mostly to be discharged, since they can accumulate in the combustion chamber or other components, especially after a long period of operation, and restrict their function. If, for example, hydrocarbon is burned as fuel in an atmosphere of pure oxygen in a steam power plant according to the invention, at least the combustion products water and carbon dioxide are produced. These combustion products are carried along by the steam flow and fed to the condenser. In known steam power plants, a condenser is usually present anyway, so that in connection with the invention it is not absolutely necessary to provide a separate condenser suitable for removing the combustion products.

When the steam, which contains the combustion products as a water-carbon dioxide mixture, is cooled, the water portion largely condenses and almost pure, gaseous carbon dioxide remains, which can be removed from the condenser and stored, for example.

As already mentioned, when using hydrogen as fuel, which is produced by means of reforming or gasifying a hydrocarbon, carbon dioxide produced can be removed before the fuel is introduced into the combustion chamber, so that in this case practically none during combustion Carbon dioxide is created as a combustion product.

The internal additional firing realized by means of the combustion chamber of a steam power plant according to the invention can be made available very quickly during the operation of the steam turbine. All that is required is the ignition of fuel introduced into the combustion chamber; in particular, the heating-up times of known heat exchanger surfaces are eliminated.

Furthermore, a steam power plant according to the invention has the advantage that combustion products and / or exhaust gas do not necessarily have to be removed from the combustion chamber by means of a separate discharge device, since they are carried along and can be coupled out at another point in the steam cycle, for example the condenser mentioned. In addition, a higher steam temperature can be achieved by the invention without having to change the design of the steam generator.

A steam power plant according to the invention can in particular also be used to provide energy during peak load times or to support the network frequency of an electrical energy supply network; A steam power plant according to the invention offers the possibility of rapid power control and can be used very flexibly.

An exemplary embodiment of the invention is illustrated in more detail below.

It shows:

FIG an inventive steam power plant.

In the figure, a steam power plant 1 according to the invention is shown, which comprises a steam turbine 3 coupled to a generator 21 and a fired steam generator 5.

The steam turbine 3 is constructed in three stages and has a first turbine stage 11, a second turbine stage 13 and a third turbine stage 15, which are designed as a high pressure stage, medium pressure stage or low pressure stage.

In the present exemplary embodiment of the figure, the steam generator 5 is a boiler fired by coal 27, to which combustion air 29 is fed in order to maintain the coal furnace. A heating surface 37 is arranged in the steam generator 5 in the region of its hot end and an intermediate superheater heating surface 35 is arranged in a region of lower temperature.

The heating surface 37 serves to heat feed water 24 from a feed water tank 23 in the steam generator 5 in such a way that operating steam can be supplied to the first turbine stage 11.

After partial relaxation in the first turbine stage 11, the steam is reheated by means of the reheater heating surface 35. A steam flow 17 emerges in the direction 9 from the reheater heating surface 35 and is fed to a firing device. The steam flow 17 is heated in a combustion chamber 19 by means of a fuel 33 and the addition of oxygen 31, the steam flow 17 in the combustion chamber 19 mixing with the hot gas which arises in the combustion chamber 19 during the combustion of the fuel 33.

The heat transfer from the hot gas to the steam flow 17 thus takes place directly by mixing, without a material, for example a heat exchanger surface, being provided for the heat transfer.

Instead of oxygen 31, it is also possible to use air to generate a suitable combustion atmosphere, the air possibly being split into oxygen and residual gas by means of an air separation device before being introduced into the combustion chamber.

For example, a hydrocarbon, in particular methane, or hydrogen can be used as fuel 33.

The steam stream 17 heated by means of the combustion chamber 19 is fed to the second turbine stage 13, where it converts at least part of the energy it contains into mechanical work. The steam, which has continued to relax, leaves the second Turbine stage 13 and is fed to the third turbine stage 15, where the energy still present in the steam is converted as well as possible into mechanical energy.

The expanded steam leaves the third turbine stage 15 as a water-steam mixture and is fed to a condenser 25, where the steam portion still present is condensed to water.

This water, which accumulates in the condenser 25, is fed as condensate 26 to the feed water tank 23.

Combustion products 39, which arise during combustion in the combustion chamber 19, can be removed from the condenser 25.

Since the combustion takes place within the steam flow 17 in the combustion chamber 19, the combustion products 39 are carried along by the steam flow 17 in the steam cycle and removed from the condenser 25 according to this embodiment of the invention.

If, for example, a hydrocarbon is burned with oxygen 31 as fuel 33, the combustion products 39 include water and carbon dioxide. This water-carbon dioxide mixture is carried along by the steam flow 17 and can be removed from the condenser 25, since when the water-carbon dioxide mixture cools, the water portion largely condenses and almost pure gaseous carbon dioxide remains as gas, which is then transported away and can be stored, for example.

Claims

claims

1. steam power plant (1) comprising at least one steam turbine (3) and a fired steam generator (5), characterized in that a combustion chamber (7) in the direction (9) of the steam flow (17) after a first turbine stage (11) and before one second turbine stage (13) of the steam turbine (3) and the steam flow (17) in the combustion chamber (19) can be heated by mixing with a hot gas that can be generated in the combustion chamber (19).

2. Steam power plant (1) according to claim 1, that the fueling device (7) can be supplied with hydrogen and / or a hydrocarbon, in particular methane, as fuel (33).

3. steam power plant (1) according to one of claims 1 or 2, d a d u r c h g e k e n e z e i c h n e t that the firing device (7) for generating a combustion atmosphere in the combustion chamber (19) an oxygen-containing gas, in particular pure oxygen (31) and / or air, can be supplied.

4. Steam power plant (1) according to one of claims 1 to 3, so that combustion products (39) can be removed from the steam flow (9) by means of a condenser (25) connected downstream of the steam turbine (3).