DE102021202617A1 - Process for generating steam with defined steam parameters - Google Patents

Abstract

The present invention relates to a method for generating steam with defined steam parameters. The process is characterized by the following process steps: - pressurized, internal combustion of hydrogen with oxygen with the addition of water, in a steam generator (1) and generation of live steam; - supplying the live steam generated in the steam generator (1) to a steam turbine ( 2);- Expanding the live steam along an expansion section in the steam turbine (2);- Extracting intermediate steam along the expansion section and/or extracting exhaust steam at the end of the expansion section with defined steam parameters and- Feeding the extracted intermediate steam and/or exhaust steam to a subsequent one industrial process.

Description

The invention relates to a method for generating steam with defined steam parameters according to the preamble of independent claim 1.

Steam is often used in processes and in the heat supply, in the following the term industrial processes is used in general. A typical area of application is the provision of heat, for example for cooking, evaporation or distillation processes. In addition, drying processes or the provision of heat for endothermic reactions in the chemical industry can be realized with steam. Steam which is used in industrial processes is often referred to as process steam.

The generation of steam for industrial processes places high demands on the equipment required for generation on the one hand, and on the other hand the generation also has a significant impact on energy consumption. Classic steam generation using a conventional boiler (and possibly a steam turbine) is limited in terms of operational flexibility (load gradients, start-up time, ...). In addition, the use of a boiler entails high investment costs. The boiler is usually fired with fossil fuels, which has a negative effect on the emissions from the system and thus also on ecological and economic aspects.

The object of the present invention is to avoid the disadvantages of the prior art when providing steam with defined steam parameters and to demonstrate a more effective process for providing the steam.

The object is solved by the features of independent claim 1.

Further configurations of the invention, which can be used individually or in combination with one another, are the subject matter of the dependent claims.

• - Druck beaufschlagte, interne Verbrennung von Wasserstoff mit Sauerstoffund unter Zugabe von Wasser (unabhängig vom Aggregatzustand), in einem Dampferzeuger und Erzeugung von Frischdampf;
• - Zuführen des im Dampferzeuger erzeugten Frischdampfs zu einer Dampfturbine;
• - Expandieren des Frischdampfs entlang einer Expansionsstrecke in der Dampfturbine;
• - Entnehmen von Zwischendampf entlang der Expansionsstrecke und/oder Entnehmen von Abdampf am Ende der Expansionsstrecke mit definierten Dampfparametern und
• - Zuführen des entnommenen Zwischendampfs und/oder Abdampfs zu einem nachfolgenden Industrieprozess.

The process according to the invention for generating steam with defined steam parameters is characterized by the following process steps:

• - Pressurized, internal combustion of hydrogen with oxygen and with the addition of water (regardless of the aggregate state), in a steam generator and production of live steam;
• - Supplying the live steam generated in the steam generator to a steam turbine;
• - Expanding the live steam along an expansion path in the steam turbine;
• - Removal of intermediate steam along the expansion section and/or removal of waste steam at the end of the expansion section with defined steam parameters and
• - Feeding the extracted intermediate steam and/or waste steam to a subsequent industrial process.

In contrast to classic steam generation with the help of a conventional boiler, there is a significantly increased operational flexibility (load gradients, start-up time, ...). In particular, the internal combustion of hydrogen with oxygen results in very short start-up times. By adding water (regardless of the state of aggregation) a (pre-)conditioning of the live steam can already take place. The supply and expansion of the live steam in the steam turbine enables the provision of steam with defined and possibly different steam parameters. For this purpose, water vapor with the corresponding steam parameters can be extracted by one or more intermediate steam extractions along the expansion section within the steam turbine and fed to the respective industrial process. As an alternative or in addition to the steam turbine as a control element for the process steam parameters, other technical devices such as throttles (e.g. in combination with water injection or other cooling) can also be used.

One embodiment of the invention provides that the hydrogen and oxygen used for combustion is generated using regenerative energy. As a result, the process steam can be generated completely emission-free.

A further embodiment of the invention provides that at least part of the live steam is removed before it enters the steam turbine and fed directly to an industrial process. By adding water, the steam parameters of the live steam, which is produced during the internal combustion of hydrogen with oxygen, can be influenced in such a way that at least part of the live steam can be fed directly to the industrial process. If additional steam with lower steam parameters is required, this can be provided by expanding another part of the live steam in a steam turbine.

A further embodiment of the invention provides that the mechanical energy generated by the steam turbine is used to drive machines and/or to generate electrical energy using a generator. Due to the double use of the steam, which is also referred to as combined heat and power generation, particularly high overall efficiencies can be achieved, which increase the economic efficiency of the method according to the invention.

Further advantages of the invention are explained below with reference to a figure. The figure shows a plant which is suitable for carrying out the method according to the invention. The figure only shows the essential components required to explain the process and does not represent a true-to-scale representation.

The system for carrying out the method according to the invention essentially comprises a steam generator 1 and a steam turbine 2 downstream of the steam generator.

In the process according to the invention, the steam is generated by internal combustion and not, as is otherwise customary, by the pure supply of heat (partly from external combustion), as is the case, for example, when using a conventional boiler.

The internal combustion takes place in a steam generator 1 known as a Clean Steam Generator, CSG. The CSG 1 is produced by pressurized, internal combustion of hydrogen H ₂ with oxygen O ₂ and the addition of water H ₂ O ₂ (regardless of the aggregate state ) characterized, whereby live steam S _L is produced with defined steam parameters (pressure, temperature...) and in a defined quantity and purity.

The live steam S _L is then fed to the steam turbine 2 downstream of the CSG. The live steam is expanded to lower steam parameters along an expansion section, which extends from a steam turbine inlet 4 to a steam turbine outlet 5 . Depending on which steam parameters are required for the respective industrial process, the steam can be removed along the expansion section by one or more intermediate steam extractions and fed to the respective industrial process as process steam S _P2 . The remaining part of the steam is completely expanded along the expansion section and leaves the steam turbine at the steam turbine outlet 5 as exhaust steam _SW . The waste steam can then be fed to a condenser or fed to a further industrial process as process steam S _P3 . Depending on whether the steam at the end of the expansion section is fed to the condenser as exhaust steam or as process steam to an industrial process, the steam turbine 1 is designed as a (extraction) condensation turbine or as an (extraction) back-pressure turbine.

If an industrial process requires very high steam parameters, part or all of the live steam can be derived before the steam turbine and fed directly to an industrial process as process steam S _P1 . The distribution of the water vapor S _P1 - S _P3 to the different industrial processes can vary both in terms of time and the respective amount of steam.

In the exemplary embodiment, the steam turbine drives a generator 3 for generating electrical energy; alternatively, the steam turbine can also drive a working machine (compressor, pump,...).

The steam turbine can be designed in one or more stages and also consist of one or more housings. It is also possible for the live steam to be divided between several steam turbines, expanded and fed to the various industrial processes. The various steam turbines and housings can be operated at the same or different speeds and do not necessarily have to be mechanically coupled to one another via a shaft (several generators) and do not necessarily have to serve the same purpose (e.g. high-pressure turbine as a mechanical drive for a prime mover, low-pressure turbine as a generator drive). .)

The hydrogen and oxygen used for combustion can preferably be generated using regenerative energy and then stored for further use in the CSG. Due to the regenerative production of the hydrogen and the oxygen, the method according to the invention for the production of process steam can be carried out CO ₂ -free.

The method according to the invention for generating steam offers significant advantages over the conventional methods both in terms of fuel utilization and operational flexibility (the CSG can run higher load gradients than a conventional boiler).

Claims (4)

Process for generating steam with defined steam parameters , characterized by the following process steps: - pressurized, internal combustion of hydrogen with oxygen with the addition of water, in a steam generator (1) and generation of live steam; - Supplying the live steam generated in the steam generator (1) to a steam turbine (2); - Expanding the live steam along an expansion path in the steam turbine (2); - removal of intermediate steam along the expansion section and/or removal of waste steam at the end of the expansion section with defined steam parameters and - supplying the removed intermediate steam and/or waste steam to a subsequent industrial process. Process for generating steam with defined steam parameters claim 1 , characterized in that the hydrogen and oxygen used for combustion is generated by means of regenerative energy. Process for generating steam with defined steam parameters claim 1 or 2 , characterized in that at least part of the live steam is removed before it enters the steam turbine (2) and fed to an industrial process. Method for generating steam with defined steam parameters according to one of the preceding claims, characterized in that the mechanical energy generated by the steam turbine (1) is used to drive machines or to generate electricity with the aid of a generator (3).

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