WO2017202661A1 - Group of installations for manufacturing mineral building materials and method for operating the group of installations - Google Patents

Abstract

The invention relates to a group of installations for manufacturing mineral building materials, comprising a furnace (1) for generating mineral building materials, a cooler (2) for cooling the mineral building materials, and a gas line system (3) for gases incurred during the manufacture of the mineral building materials. The group of installations has a biotechnology installation (4) connected to the gas line system (3). The group of installations has a secondary fuel supply device (23) for supplying biomass for the at least partial operation of the group of installations, in particular the furnace (1), for generating mineral building materials using secondary fuels.

Description

 Plant network for the production of mineral building materials as well as a process for the

 Operating the plant network

State of the art

The present invention relates to a plant network for the production of mineral building materials and a method for operating the plant network.

Equipment for the production of mineral building materials comprising a kiln for producing mineral building materials and a cooler for cooling the mineral building materials are known in the prior art in a variety of embodiments. In particular, a cement plant may be such a plant or component of such a plant. In cement plants, the raw materials which are mostly mined in quarries and precrushed, such as limestone, in particular as a source of calcium oxide, clay, especially as a source of silica and alumina, sand, for example as a source of silica and iron ore, especially as a source of iron (III ) oxide, for example in raw mills together and dried at the same time. The resulting so-called raw meal is then fired in a kiln, such as a rotary kiln to produce mineral building materials at temperatures of about 1400 - 1450 ° C to the so-called clinker. The clinker is then cooled down to a temperature below 200 ° C in a cooler. In this manufacturing process, in particular, the carbon contained in the raw materials and fuels is converted into carbon dioxide and released. Carbon dioxide (CO2) is a greenhouse gas and, when it enters the atmosphere, contributes as one of the major factors in enhancing the greenhouse effect. In this context, C0 ₂ emissions are levied on greenhouse gas emissions in some countries.

The present invention is therefore based on the object to further improve the sustainability, in particular the economic and ecological conditions of the overall process and in particular to provide a plant network for the production of mineral building materials, with which it is possible, associated with the production and use of mineral building materials release of C0 ₂ into the atmosphere and / or cost of producing and / or using mineral building materials to reduce. In addition, efforts are being made to reduce C0 ₂ emissions during the production of mineral building materials. In addition, the profitability of the overall process should be further improved. Disclosure of the invention

This object is achieved with a plant network according to claim 1 and a method for operating a plant network for the production of mineral building materials according to claim 10.

Compared with conventional plants, the plant network according to the invention has the advantage that individual plants are combined in a plant network and material flows, in particular gas flow rates, thermal energy and energy flows can be combined. In addition, the further use or processing of carbon dioxide is possible before it is released into the atmosphere. In this way, the environmental impact is reduced and / or increases the cost of production of mineral building materials and / or achieved an overall optimum in terms of economic and / or ecological production and / or use of mineral building materials for a plant network.

The invention relates to a plant network for the production of mineral building materials with a kiln for producing mineral building materials, a cooler for cooling the mineral building materials, and

a gas line system for gases that are generated during the production of mineral building materials, the plant network has a connected to the gas line system biotechnology plant and the plant network a

Has secondary fuel supply means for supplying biomass for at least partial operation of the system network, in particular the kiln for producing mineral building materials with secondary fuels.

Another object of the invention relates to a method for operating a plant network for the production of mineral building materials, a kiln for producing mineral building materials, a cooler for cooling the mineral building materials and a gas line system for gases resulting from the production of mineral building materials, a to the Gas line system connected biotechnology plant and a secondary fuel supply device for at least partial operation of the system network, in particular the kiln for the production of mineral building materials with secondary fuels wherein at least a subset of the resulting in the production of mineral building materials gas is used as a useful gas for operating the biotechnology plant.

In the context of the invention, mineral building materials are understood as meaning building materials which comprise a composition of minerals. Examples include calcium-containing building materials, such as cement, lime, gypsum and calcined clays, as well as already treated residues from production processes, especially from metal production, especially iron and steel production, such as slag (s) and combinations thereof. In a chemical plant, chemical products can be produced from the supplied gas flow rates and / or the useful gases and / or the synthesis gas, which in each case contain the components of the end product. The synthesis gas produced by the process according to the invention are gas mixtures which are used for synthesis. Under the term "synthesis gas" z. B. mixtures of N ₂ and H ₂ for ammonia synthesis and especially gas mixtures containing mainly CO and H ₂ or C0 ₂ and H ₂ or CO, C0 ₂ and H ₂ . From the synthesis gases chemical products can be produced in a chemical plant, which each contain the components of the educt. Chemical products may be, for example, ammonia or methanol or other hydrocarbon compounds.

For the production of ammonia, a synthesis gas must be provided which contains nitrogen and hydrogen in the correct ratio. For example, an air separation plant for the at least partial separation of ambient air into an at least partially oxygen-containing gas and an at least partially nitrogen-containing gas can additionally be provided as the nitrogen source. As a hydrogen source, for example, an additional plant for hydrogen production, such as a Wasserelektrolyseanlage be provided. For the preparation of hydrocarbon compounds, for example methanol, a synthesis gas consisting essentially of CO and / or CO ₂ and -H _{2 must be} provided, which contains the components carbon monoxide and / or carbon dioxide and hydrogen in the correct ratio. The ratio is often described by the module (H ₂ -C0 ₂ ) / (CO + C0 ₂ ). The hydrogen can be provided for example by an additional plant for hydrogen production. The provision of CO can be carried out with an additional reverse water gas shift reactor (RWGS reactor). The C0 ₂ source can be the carbon dioxide released during the manufacturing process. In the concepts described above, however, the C content of the gases resulting from the production of mineral building materials, can not be fully utilized, since there is a hydrogen deficit. In order to fully utilize the C content of the resulting in the production of mineral building materials gases for the production of chemical products, hydrogen is metered according to the invention, which is formed in a plant for hydrogen production. The hydrogen production is preferably carried out by electrolysis of water, the electrolysis of water is suitably operated with electric power generated from renewable energy. In the electrolysis of water also produces oxygen, which can be used in the kiln for the production of mineral building materials. The supply of oxygen is also known as oxyfuel process, in which particularly high flame temperatures can be achieved. In particular, the oxyfuel process is applicable to both gaseous and liquid and solid fuels.

In addition or instead of the chemical plant for the production of products from the supplied gas flow rates and / or the Nutzgasen and / or the synthesis gas, a biotechnological plant can be used in the invention. This is a plant for the fermentation of the aforementioned gases. The supplied gas flow rates and / or useful gases and / or synthesis gases are used biochemically via a fermentation, wherein products such as alcohols (ethanol, butanol), acetone or organic acids can be produced. These products, which are produced by fermentation of synthesis gas, are mentioned in the present case only as an example.

However, when using a biochemical process, the hydrogen essentially comes from the water used as a medium during fermentation. The provision of CO can be carried out with an additional reverse water gas shift reactor (RWGS reactor). Consequently, by means of a biotechnological process, it is possible to produce products which contain carbon from the CO and / or CO ₂ content of the raw gases produced in the production of mineral building materials and hydrogen from the water used in a fermentation process.

The performance of the chemical plant or the biotechnological plant is regulated as a function of the gas flow rates supplied to this plant, in particular the used gases and / or the synthesis gases. A major challenge for the chemical plant is the dynamic driving style with changing plant loads. The operation of changing plant loads can be realized in particular by the fact that the chemical plant a Has a plurality of parallel connected small units, which are individually switched on or off depending on the available Nutzgasmengenstrom.

The dynamic control of the chemical plant during load changes is technically complex. According to the invention, initially only the power of the biotechnology plant is adapted during a load change. The teaching according to the invention makes use of the fact that a biotechnology plant is considerably more flexible in terms of load changes compared to a chemical plant. According to a further embodiment of the invention, the plant network comprises a production plant with a carbon dioxide source and a C0 ₂ -Gasleitungssystem for at least one resulting from the production plant with a carbon dioxide source carbon dioxide-containing gas flow rate, the C0 ₂ gas line system is connected to the gas line system. A production plant with a carbon dioxide source is, for example, a power plant, a bioethanol plant, a metallurgical plant and / or other plants for producing mineral building materials or a combination thereof.

In the context of the present invention, a controllable gas switch means a device with which the supply quantity of gases to the systems arranged in the network can be controlled. For example, according to certain requirements, in particular available gas quantities, gas compositions, energy and electricity, the admission of one and / or several plants in the plant network can take place as required.

The plant composite can optionally additionally have an oxygen supply device in the composite, which is connected to the kiln for producing mineral building materials. For example, the oxygen supply device may be the exit of a pipeline, a nozzle, or a combination thereof. With the supply of oxygen via the oxygen supply device in the kiln particularly high flame temperatures can be achieved. This, for example, also known as oxyfuel process method is applicable to both gaseous and liquid and solid fuels. In particular, oxygen for the oxygen supply device can be provided from an electrolysis plant for water electrolysis and / or air separation plant.

According to a further embodiment of the invention, the plant composite additionally has a plant for C0 ₂ separation of the from the production plant with a Carbon dioxide gas arising from the carbon dioxide source and / or gas produced during the production of the mineral building materials.

According to a further embodiment of the invention, the plant for C0 ₂ separation for the separation of C0 ₂ from the at least one carbon dioxide-containing gas flow stream resulting from the production plant with a carbon dioxide source comprises an absorber device and a desorbing device connected downstream of the absorber device.

According to a further embodiment of the invention, the plant network additionally has a facility for C0 ₂ purification and / or C0 ₂ conditioning. In particular, the plant for C0 ₂ purification and / or C0 ₂ conditioning is connected to the production plant with a carbon dioxide source and / or the plant for C0 ₂ separation. In the context of the present invention, gas purification, in particular C0 ₂ purification and gas conditioning, in particular C0 ₂ conditioning, means the treatment of the gases for the plants downstream of the plant network. For example, the C0 ₂ purification unit may include a CG wash to separate C0 ₂ .

According to a further embodiment of the invention, the plant network additionally comprises a gasification device for concentration of C0 ₂ -Anteils, wherein the gasification C0 ₂ -Waschanlage for separating C0 ₂ from the at least one arising from the production plant with a carbon dioxide source carbon dioxide-containing gas flow upstream is arranged. In a further embodiment of the invention, the plant composite additionally comprises a SGyAbtrennvorrichtung for separating S0 ₂ from the at least one resulting from the production plant with a carbon dioxide source carbon dioxide-containing gas flow rate, in particular, the S0 ₂ -Abtrennvorrichtung a cooling device. According to a further embodiment of the invention, the system composite additionally comprises a water vapor separator.

According to a further embodiment of the invention, the system composite additionally comprises a CGy separator, in particular a membrane filter. In a further embodiment of the invention, the plant network additionally comprises a C0 ₂ compressor for compressing carbon dioxide-containing gas arising from the production plant with a carbon dioxide source and / or gas produced during the production of the mineral building materials.

In a further preferred embodiment of the invention, the plant network additionally comprises a plant for hydrogen production and a H ₂ gas line system for arising from the plant for hydrogen production hydrogen-containing gas flow rates. For example, the plant for hydrogen production is an electrolysis plant for water electrolysis. The electrolysis plant for water electrolysis is connected by means of an oxygen return line with the oxygen supply device. The oxygen produced during the electrolysis of water can be supplied to the kiln for producing mineral building materials, for example via the oxygen return line and the oxygen supply device. The water electrolysis plant is preferably electrically connected to an energy store and at least part of the electrical energy necessary for water electrolysis is taken from the energy store. In addition, external power can be used, preferably from renewable sources.

According to a further preferred embodiment of the invention, the gas line system in the flow direction after the controllable gas switch is connected to the H ₂ gas line system via a mixing device for producing one of gases arising from the production plant with a carbon dioxide source and / or in the production of mineral Building materials and resulting hydrogen-containing gases from the plant for hydrogen production existing mixed gases and are the chemical plant and / or biotechnology plant supplied gas flow rates controlled by the controllable gas switch. According to a further preferred embodiment of the invention, the H ₂ - gas line system on a controllable H ₂ gas soak and are the chemical plant and / or biotechnology plant supplied hydrogen-containing gas flow rates controllable by means of the controllable H ₂ gas soak. In the context of the present invention, a controllable H ₂ gas switch is understood to mean a device with which the supply quantity of H ₂ gases to the systems arranged in the network can be controlled. For example, according to certain requirements, the admission of one or more plants in the plant network with H ₂ can take place as required.

Furthermore, the system network can additionally have a H ₂ storage for storing at least a portion of emitted hydrogen-containing gases from the plant for hydrogen production, wherein the H ₂ storage is connected to the H ₂ gas line system.

According to a further embodiment of the invention, the system network additionally has an energy store, in particular an electrochemical store to cover at least part of the power requirement of the system network. According to a further embodiment of the invention, the plant composite additionally comprises an air separation plant for at least partially decomposing ambient air into an at least partially oxygen-containing gas and an at least partially nitrogen-containing gas with an oxygen-containing gas leading line and a nitrogen-containing gas leading line. Further, the oxygen-containing gas leading pipe is connected to the oxygen supply means by means of an oxygen return pipe. Oxygen-containing gas in the oxygen-containing gas-carrying line can be supplied to the kiln for producing mineral building materials, for example, via the oxygen return line and the oxygen supply device. Nitrogen-containing gas of the nitrogen-containing gas-carrying line can be supplied in particular as a nitrogen source of a downstream system of the plant network, such as the chemical plant and / or the biotechnology plant.

According to a further embodiment of the invention, the nitrogen-containing gas-carrying line is connected by means of a mixing device with the H ₂ gas line system, in particular for the production of ammonia.

In a further preferred embodiment of the invention, the system network additionally comprises a reverse water gas shift system and a CO gas line system for carbon monoxide-containing gas flow streams arising from the reverse water gas shift system, the reverse water gas shift system following in the flow direction the controllable gas switch is connected to the gas line system and the H ₂ -Gasleitungssystem and that the gas flow rates supplied to the chemical plant and / or biotechnology plant are controllable by means of the controllable gas switch. In the context of the present invention, a reverse water gas shift plant is understood to mean a plant which comprises carbon dioxide-containing gas flow streams, in particular gases which are produced during the production of the mineral building materials, from the carbon dioxide fraction by a reverse water gas shift reaction (C0 ₂ + H ₂ CO + H ₂ O) at least partially convert to carbon monoxide. For example, the hydrogen required for the reaction may be provided from a hydrogen production plant. According to a further preferred embodiment of the invention, the C0 gas line system has a controllable CO gas switch and the carbon monoxide-containing gas flow rates supplied to the chemical plant and / or biotechnology plant can be controlled by means of the controllable CO gas switch. In the context of the present invention, a controllable CO gas switch is understood to mean a device with which the supply quantity of CO gases to the plants arranged in the network can be controlled. For example, according to certain requirements, the admission of one or more plants in the plant network with CO can take place as required.

In a further embodiment of the invention, the plant network additionally has a biomass storage for storing biomass, in particular from the biotechnology plant, wherein at least a subset of the biomass from the biomass storage and / or the biotechnology plant of the secondary fuel supply of the plant network is supplied.

In a further embodiment of the invention, the plant network additionally has a material storage. Examples of a material storage are a methanol storage, a synthetic natural gas (SNG) storage, substitute natural gas storage, FT-fuel storage (Fischer-Tropsch synthesis fuels), ethanol storage.

According to a further embodiment of the method according to the invention, the plant network, in particular the kiln for producing mineral building materials, is additionally supplied with an oxygen stream with an oxygen supply device. In a further embodiment of the method according to the invention for operating a plant network for the production of mineral building materials, the plant network has a kiln for producing mineral building materials, a cooler for cooling the mineral building materials, a gas line system for gases that are produced in the production of mineral building materials, a connected to the gas line system biotechnology plant and a Sekundärbrennstoffzufuhreinrichtung for at least partial operation of the plant network, in particular the kiln for producing mineral building materials with secondary fuels, wherein at least a subset of the resulting in the production of mineral building materials gas is used as a useful gas for operating the biotechnology plant.

According to a further embodiment of the method according to the invention, at least a portion of the resulting in the production of mineral building materials gas is mixed with at least a portion of resulting hydrogen-containing gases from the plant for hydrogen production and the mixed gas is used as a useful gas for operating the chemical plant and / or biotechnology plant.

In a further embodiment of the method according to the invention, at least part of the useful gas after gas conditioning and / or gas purification is used as synthesis gas for the production of chemical products and / or supplied to the biotechnology plant and used for biochemical processes.

According to a further embodiment of the method according to the invention, a synthesis gas is produced from at least a subset of the gas produced during the production of the mineral building materials after gas conditioning and / or gas purification.

According to a further embodiment of the method according to the invention, at least part of the synthesis gas produced after gas conditioning and / or gas purification is used for the production of chemical products or supplied to the biotechnology plant and used for biochemical processes.

In a further embodiment of the method according to the invention, the power of the chemical plant and / or the biotechnology plant is regulated as a function of the amount of useful gas supplied to this plant (s). According to a further embodiment of the method according to the invention for operating a plant network for the production of mineral building materials, a kiln for the production of mineral building materials, a cooler for cooling the mineral building materials, a gas line system for gases resulting from the production of mineral building materials, a to the Gas line system connected to chemical plant and / or biotechnology plant, at least one connected to the gas line system controllable gas switch for dividing the chemical plant and / or biotechnology plant gas flow rates and as a plant for hydrogen production an electrolysis plant for water electrolysis and a H ₂ - gas line system emitted from the electrolysis plant for water electrolysis Has hydrogen-containing gas flow rates, a) at least a subset of the resulting in the production of mineral building materials gas with b) at least a subset of the d c) mixed and d) wherein the mixed gas is used as a useful gas for operation of the chemical plant and / or biotechnology plant and e) wherein at least a portion of the resulting from the electrolysis plant for electrolysis water electrolysis gas in the plant network for the preparation of the electrolysis plant mineral building materials is used, in particular in the kiln for the production of mineral building materials is recycled.

According to a further embodiment of the method according to the invention for operating a plant network for producing mineral building materials, the plant network additionally comprises an air separation plant for at least partially decomposing ambient air into an at least partially oxygen-containing gas and an at least partially nitrogen-containing gas with an oxygen-containing gas leading line and a nitrogen-containing gas Having at least a portion of the at least partially oxygen-containing gas from the air separation plant in the plant composite for the production of mineral building materials, in particular is recycled to the kiln for producing mineral building materials and / or at least a subset of the at least partially nitrogen-containing from the air separation plant Gas with at least one Partly mixed of the hydrogen-containing gas emitted from the electrolysis plant for water electrolysis, in particular for the production of ammonia.

According to a further embodiment of the method according to the invention for operating a plant network for producing mineral building materials, a kiln for producing mineral building materials, a cooler for cooling the mineral building materials, a gas line system for gases resulting from the production of mineral building materials, one to the gas line system connected chemical plant and / or biotechnology plant, at least one connected to the gas line system controllable gas switch for dividing the chemical plant and / or biotechnology plant supplied gas flow rates and a plant for hydrogen production and a H ₂ gas line system for emitted from the plant for hydrogen generation hydrogen-containing gas flow rates, the Gas line system in the flow direction after the controllable gas switch is connected to the H ₂ gas line system via a H ₂ mixing device for producing a mixed gas comprising gases, arising in the production of mineral building materials and resulting hydrogen-containing gases from the plant for hydrogen production and a reverse water gas shift system and a CO gas line system for emitted from the reverse Wassergas shift system carbon monoxide gas flow rates, the reverse Water gas shift system in the flow direction after the controllable gas switch is connected to the gas line system and / or the H ₂ gas line system and that the chemical plant and / or biotechnology plant supplied gas flow rates are controllable by the controllable gas switch, wherein at least a subset a) of at the production of mineral building materials accumulating gas and / or b) of the resulting from the reverse-water gas shift system carbon monoxide-containing gas and / or

0 of the resulting from the electrolysis plant for water electrolysis material-containing gas d) is mixed and wherein the mixed gas is used as Mischnutzgas for operating the chemical plant and / or biotechnology plant. According to a further embodiment of the method according to the invention for operating a plant composite for the production of mineral building materials a) at least a subset of the resulting in the production of mineral building materials gas with b) at least a portion of the resulting from the electrolysis plant for water electrolysis hydrogen-containing gas c) mixed and d ) wherein the mixed gas is used as C0 ₂ -H ₂ -Nutzgas and / or CO-H ₂ -Nutzgas and / or C0 ₂ - CO-H ₂ -Nutzgas for operating the chemical plant and / or biotechnology plant and / or e) wherein at least a subset of the carbon monoxide-containing gas resulting from the reverse-water-gas shift system is used as CO useful gas for operating the chemical plant and / or biotechnology plant.

According to a further embodiment of the method according to the invention for operating a plant network for producing mineral building materials, the hydrogen content of the C0 ₂ - H ₂ -Nutzgasstromes and / or CO-H ₂ -Nutzgasstromes and / or C0 ₂ -CO-H ₂ -Nutzgasstromes to a ratio is set in the range of 5% by volume to 95% by volume based on the total volume of the associated Nutzgasstroms.

According to a further embodiment of the method according to the invention for operating a plant network for the production of mineral building materials a) at least a subset of the resulting from the reverse water gas shift plant carbon monoxide gas with b) at least a portion of the resulting from the electrolysis plant for water electrolysis hydrogen-containing gas c mixed and d) wherein the mixed gas is used as CO-H ₂ -Nutzgas and / or CO-H ₂ -Nutzgas and / or C0 ₂ -C0-H ₂ -Nutzgas for operating the chemical plant and / or biotechnology plant and / or e) wherein at least a subset of the carbon monoxide-containing gas resulting from the reverse-water-gas shift system is used as CO useful gas for operating the chemical plant and / or biotechnology plant.

According to a further embodiment of the method according to the invention for operating a plant network for the production of mineral building materials, the hydrogen content of the C0-H ₂ -Nutzgasstromes and / or CO-H ₂ -Nutzgasstromes and / or C0 ₂ -CO-H ₂ -Nutzgasstromes to a ratio in Range of 5 vol% to 95 vol% based on the total volume of the associated Nutzgasstromes set. According to a further embodiment of the inventive method for operating a plant network for the preparation of mineral building materials is / are the Mischnutzgas and / or the C0 ₂ -Nutzgas and / or the C0 ₂ -H ₂ -Nutzgas and / or the CO useful gas and / or the CO-H ₂ -Nutzgas and / or the CO-CO ₂ -H ₂ -Nutzgas processed, wherein the treatment comprises a gas purification and / or a gas conditioning.

According to a further embodiment of the inventive method for operating a plant network for the preparation of mineral building materials is / are the Mischnutzgas and / or the C0 ₂ -Nutzgas and / or the C0 ₂ -H ₂ -Nutzgas and / or the CO useful gas and / or the CO-H ₂ -NG and / or the CO-CO ₂ -H ₂ -Nutzgas processed, wherein the processing comprises a compression.

According to a further embodiment of the method according to the invention for operating a plant network for the production of mineral building materials, the power of the chemical plant and / or the biotechnology plant depending on the / n plant (s) supplied Nutzgasmenge of mixed commercial gas and / or C0 ₂ -Nutzgas and / or C0 ₂ -H ₂ -Nutzgas and / or CO-Nutzgas and / or CO-H ₂ -Nutzgas and / or the CO-CO ₂ -H ₂ -Nutzgas regulated.

According to a further embodiment of the method according to the invention for operating a plant network for the production of mineral building materials comprising a kiln for producing mineral building materials, a cooler for cooling mineral building materials, and a gas pipeline system for gases, which occur in the production of mineral building materials, and a connected to the gas line system chemical plant and / or biotechnology plant and the plant network comprises a production plant with a carbon dioxide source and a C0 ₂ gas line system for at least one resulting from the production plant with a carbon dioxide carbon dioxide gas stream, at least a subset of the in the production of mineral Building materials accumulating gas and / or arising from the production plant with a carbon dioxide source carbon dioxide-containing gas is used as a useful gas for operating the chemical plant and / or biotechnology plant. According to a further embodiment of the method according to the invention for operating a plant network for producing mineral building materials, the plant network, in particular the kiln for producing mineral building materials, is additionally supplied with an oxygen stream with an oxygen supply device. According to a further embodiment of the method according to the invention for operating a plant network for the production of mineral building materials of the plant network additionally comprising a plant for hydrogen production and a H ₂ gas line system for arising from the plant for hydrogen production hydrogen-containing gas flow rates, at least a subset of the in the production of mineral building materials accumulating gas and / or arising from the production plant with a carbon dioxide source carbon dioxide containing gas mixed with at least a subset of resulting hydrogen-containing gases from the plant for hydrogen production and the mixed gas is used as a useful gas for operating the chemical plant and / or biotechnology plant. According to a further embodiment of the method according to the invention for operating a plant network for the production of mineral building materials, at least a portion of the useful gas is used after a gas conditioning and / or gas purification as synthesis gas for the production of chemical products and / or the biotechnology plant is fed and used for biochemical processes.

According to a further embodiment of the method according to the invention for operating a plant network for producing mineral building materials, this is obtained from at least a subset of the gas produced during the production of the mineral building materials and / or from the production plant with a carbon dioxide source Carbon dioxide-containing gas produced after a gas conditioning and / or gas purification a synthesis gas.

According to a further embodiment of the method according to the invention for operating a plant composite for producing mineral building materials, at least part of the synthesis gas produced after gas conditioning and / or gas purification is used for the production of chemical products or is supplied to the biotechnology plant and is used for biochemical processes. According to a further embodiment of the method according to the invention for operating a plant network for producing mineral building materials, at least a subset of the biofuel biomass is supplied as secondary fuel with the secondary fuel supply to the plant network, in particular the kiln for producing mineral building materials and / or the plant network additionally has a biomass storage for storing biomass, in particular from the biotechnology plant, wherein at least a subset of the biomass stored in the biomass storage is supplied as a secondary fuel with the secondary fuel supply means the plant network, in particular the kiln for producing mineral building materials.

According to a further embodiment of the method according to the invention for operating a plant network for the production of mineral building materials, the supply of at least a subset of accumulating in the biotechnology plant and / or biomass stored in the biomass storage as secondary fuel with the secondary fuel supply to the plant network, in particular the kiln for generating mineral building materials controlled depending on the calorific value of the biomass.

At all plants according to the invention compressors for compressing the gases, mixing gases may be arranged.

The subject matter of the invention also encompasses all combinations of the aforementioned embodiments, in particular of the plants within the plant network.

Short description of the drawing The plant combination according to the invention for the production of mineral building materials will be explained with reference to the drawing. Fig. 1 shows a schematic, highly simplified block diagram of a plant network for the production of mineral building materials according to an embodiment of the invention.

FIG. 1 shows an overview of a plant network for producing mineral building materials. The plant network comprises a kiln 1 for the production of mineral building materials, a cooler 2 for cooling the mineral building materials and a gas pipe system 3 for gases that are produced in the production of mineral building materials. To the gas line system 3, a chemical plant 4 and a biotechnology plant 5 is connected. The gas line system 3 comprises a controllable gas diverter 6 which divides the gas flow streams supplied to the chemical plant 4 and / or biotechnology plant 5. Furthermore, an oxygen supply device 14 is additionally shown via which air with an increased oxygen content and / or oxygen can be supplied to the kiln 1. In addition, the plant network may have a hydrogen production plant 7, T and an H ₂ gas line system 8 for hydrogen-containing gas flow streams arising from the hydrogen production plant 7, T. With the H ₂ gas line 8, the gas line system 3 may be connected via a mixing device, in particular arranged in the flow direction after the controllable gas switch (6). As a result, mixed gases, consisting of gases obtained in the production of mineral building materials and resulting hydrogen-containing gases from the plant for hydrogen production 7, T mixed and the chemical plant 4 and / or biotechnology plant 5 are supplied. In addition, the H ₂ gas line system 8 may comprise a controllable H ₂ -gas diverter 9, wherein the hydrogen-containing gas flow streams supplied to the chemical plant 4 and / or the biotechnology plant 5 can be controlled by means of the controllable H ₂ -gas diverter 9. Likewise, the H ₂ gas line system 8 for storing at least a partial amount of resulting hydrogen-containing gases from the plant for generating hydrogen 7, T include a H ₂ memory 10, wherein the H ₂ memory 10 is connected to the H ₂ - gas line 8. The plant for hydrogen production 7, T can also be designed as an electrolysis plant for water electrolysis 7 ', wherein the electrolysis plant for water electrolysis 7' is connected to the oxygen supply device 14 by means of an oxygen return line 15. In addition, the plant network a reverse water gas shift system 11 (RWGS system) and a CO gas line system 12 for from the reverse water gas shift system 11 resulting carbon monoxide-containing gas flow rates includes. Preferably, the reverse water gas shift system 11 is connected in the flow direction after the controllable gas switch 6 with the gas line system 3 and the H ₂ gas line system 8. Furthermore, the plant composite can have a plant for C0 ₂ separation 16 of the gas produced during the production of the mineral building materials. The plant composite can additionally have a plant for C0 ₂ cleaning 17, T and / or a plant for C0 ₂ conditioning 18, wherein the plant for C0 ₂ cleaning 17, T and / or the system for C0 ₂ conditioning 18 with the system for C0 ₂ separation 16 are connected / is. The CO gas line system 12 may have a controllable CO gas switch 13, wherein by means of the controllable CO gas switch 13, the the gas plant 4 and / or the biotechnology plant 5 supplied carbon monoxide-containing gas flow rates are controllable. The plant network may additionally have an energy storage 19, in particular an electrochemical storage to cover at least part of the power requirement of the system network. In addition, the plant composite of an air separation plant 20 for at least partial decomposition of ambient air into an at least partially oxygen-containing gas and an at least partially nitrogen-containing gas having an oxygen-containing gas-carrying line and a nitrogen-containing gas-carrying line 25, wherein the oxygen-containing gas-carrying line with the oxygen supply means 14 is connected. In addition, the plant network can include a plant for producing ammonia 26, which is connected to the plant network by means of the nitrogen-containing gas-carrying line 25. A supply of hydrogen-containing gas via the H ₂ - gas line 8 to the plant for ammonia production 26. Furthermore, the plant network, a production plant with a carbon dioxide source 21 and a C0 ₂ - gas line system 22 for at least one resulting from the production plant with a carbon dioxide source 21 containing carbon dioxide Gas quantities comprise electricity, wherein the C0 ₂ -Gasleitungssystem 22 is connected to the gas line system 3. The plant network may additionally have a secondary fuel supply device 23 for supplying biomass for at least partial operation of the plant network, in particular the kiln 1 for producing mineral building materials with secondary fuels. Furthermore, the plant network may have a biomass storage 24 for storing biomass, in particular from the biotechnology plant 5, wherein at least a subset of the biomass from the bio mass storage 24 and / or the biotechnology plant 5 as a secondary fuel via the Sekundärbrennstoffzuführeinrichtung 23 the kiln 1 for the production of mineral building materials can be supplied. The isosceles trapezoidal elements exemplified are compressors for compressing gas (s). Industrial Applicability

Plants from the above system composite and are used for the production of mineral building materials.

LIST OF REFERENCE NUMBERS

1 = kiln

 2 = cooler

 3 = gas line system

 4 = chemical plant

 5 = biotechnology plant

 6 = gas switch

 7, 7 '= plant for the production of hydrogen

 7 '= electrolysis plant for water electrolysis

8 = H ₂ gas line system

9 = H ₂ gas switch

10 = H ₂ memory

 11 = reverse water gas shift system (RWGS)

 12 = CO gas line system

 13 = CO gas switch

 14 = oxygen supply device

 15 = oxygen return line

16 = plant for C0 ₂ separation

17 = installation for C0 ₂ cleaning

18 = conditioning for C0 ₂ conditioning

 19 = energy storage

 20 = air separation plant

 21 = production plant with a carbon dioxide source

22 = C0 ₂ gas line system

 23 = secondary fuel supply

 24 = biomass storage

 25 = nitrogen-containing gas leading line

 26 = plant for ammonia production

I = secondary fuel

 II = electricity

 III = Renewable Energy

 IV = product (s)

Claims

 Claims l. Plant network for the production of mineral building materials with

 a kiln (1) for producing mineral building materials, a cooler (2) for cooling the mineral building materials, and

 a gas line system (3) for gases, which occur in the production of mineral building materials, characterized in that the plant network has a to the gas line system (3) connected biotechnology plant (4) and the plant network a

Secondary fuel supply means (23) for supplying biomass for at least partial operation of the plant network, in particular the kiln (1) for generating mineral building materials with secondary fuels.

2. Plant network according to claim 1, characterized in that the

Gas line system (3) at least one controllable gas switch (6) for dividing a chemical plant (4) and / or the biotechnology plant (5) supplied gas flow rates.

3. Plant network according to one of claims 1 to 2, characterized in that the

Plant network additionally comprises an oxygen supply device (14), which is connected to the kiln (1) for producing mineral building materials.

4. Plant network according to one of claims 1 to 3, characterized in that the plant network additionally a plant for CC ^ cleaning (17) and / or a facility for

CGr conditioning (18).

5. Plant network according to one of claims 1 to 4, characterized in that the

Plant network additionally comprises a reverse water gas shift system (11) and a C0 gas line system (12) for carbon monoxide-containing gas flow streams emitted from the reverse water gas shift system (11), the C0 gas line system (12) having a controllable CO -Gasweiche (13) and that by means of the controllable gas switch (6) of the chemical plant (4) and / or biotechnology plant (5) supplied gas flow rates are controllable.

6. Plant network according to one of claims 1 to 5, characterized in that the

Plant network additionally comprises a plant for hydrogen production (7) and a H ₂ - gas line system (8) for from the plant for hydrogen production (7) resulting hydrogen-containing gas flow rates.

7. Plant network according to claim 5, characterized in that the

Gas line system (3) in the flow direction in front of the controllable gas switch (6) is connected to the H ₂ gas line system (8) via a mixing device for producing a gas from the out of production plant with a

Incurred carbon dioxide source (6) and / or incurred in the production of mineral building materials and resulting hydrogen-containing gases from the plant for hydrogen production (7) existing mixed gases and that by means of the controllable gas switch (6) of the chemical plant (4) and / or biotechnology plant ( 5) supplied gas flow rates are controllable.

8. system composite according to one of claims 6 to 7, characterized in that the

H ₂ gas line system (8) has a controllable H ₂ gas soak (9) and that by means of the controllable H ₂ gas soak (9) of the chemical plant (4) and / or biotechnology plant (5) supplied hydrogen-containing gas flow rates are controllable.

9. system network according to one of claims 1 to 8, characterized in that the

Plant composite additionally has a biomass storage (24) for storing biomass, in particular from the biotechnology plant (4), wherein at least one

Subset of the biomass from the biomass storage (24) and / or the biotechnology plant (4) with the secondary fuel supply means (23) is supplied to the plant network.

10. A method for operating a plant network for the production of mineral building materials, a kiln (1) for producing mineral building materials, a cooler (2) for cooling the mineral building materials, a gas line system (3) for gases used in the production of mineral building materials accumulate, a to the gas line system (3) connected biotechnology plant (4) and a secondary fuel supply means (23) for at least partially operating the plant network, in particular the

Kiln (1) for the production of mineral building materials with secondary fuels wherein at least a subset of the resulting in the production of mineral building materials gas is used as a useful gas for operating the biotechnology plant (4).

11. The method according to claim 10, characterized in that at least a subset of in the biotechnology plant (4) resulting biomass is fed as a secondary fuel with the secondary fuel supply means (23) the plant network, in particular the kiln (1) for producing mineral building materials and / or the Plant composite also has a biomass storage (24) for storing biomass, in particular from the biotechnology plant (4), wherein at least a subset of the biomass stored in the biomass storage (24) biomass as a secondary fuel with the secondary fuel supply means (23) the plant network, in particular the kiln (1 ) is fed to the production of mineral building materials.

12. The method according to any one of claims 10 to 11, characterized in that the

Feeding the at least a subset of in the biotechnology plant (4) resulting and / or stored in the biomass storage (24) biomass as a secondary fuel with the Sekundärbrennstoffzufuhreinrichtung (23) in the system network, in particular the kiln (1) for producing mineral building materials as a function of the calorific value of the biomass is controlled.