WO2011101137A1

WO2011101137A1 - Method and system for the production of cbm (compressed biomethane) as a greenhouse gas-reduced fuel

Info

Publication number: WO2011101137A1
Application number: PCT/EP2011/000748
Authority: WO
Inventors: Michael Feldmann
Original assignee: Meissner, Jan A.
Priority date: 2010-02-17
Filing date: 2011-02-16
Publication date: 2011-08-25
Also published as: DE102010017818A1; WO2011101137A8; EP2536839A1

Abstract

The invention relates to a method and systems for producing greenhouse gas-reduced biogas, for the processing of the same to greenhouse gas-reduced biomethane and regenerative carbon dioxide (CO₂), for mixing greenhouse gas-reduced biomethane and natural gas (CNG) to give a greenhouse gas-reduced mixed gas and for use of the greenhouse gas-reduced biomethane and/or the greenhouse gas-reduced mixed gas as a greenhouse gas-reduced energy source, especially as a greenhouse gas-reduced traffic fuel.

Description

METHOD AND APPARATUS FOR THE PRODUCTION OF CBM (COMPRES SED B I OMETHANE) ALS

GREENHOUSE GAS REDU IERTER FUEL

State of the art

As with carbon dioxide (C0 ₂ ), methane (CH), nitrous oxide (N ₂ 0), the various fluorocarbons, sulfur hexafluoride (SF ₆ ), nitrogen trifluoride (NF ₃ ) and other gases greenhouse gases (hereinafter also GHG) with a variety of Greenhouse gas effects are standardized and quantified using C0 ₂ equivalents. These are usually related to consumed energy units (eg gC0 ₂ -eq / kWh or gC0 ₂ -eq / MJ) or traveled distances (gC0 ₂ -eq / km). While the C0 ₂ values published by the automotive industry indicate the effective stoichiometric C0 ₂ production of fuel combustion, environmental institutions and authorities are additionally charging their respective energy sources for C0 ₂ emissions over their entire development over the entire life cycle (lifecycle) or over the entire production route from the source of the energy carrier to the wheel of the car (well-to-wheel). For example, the LCA consideration of, for example, gasoline also includes the emissions of (fossil) C0 ₂ , which are generated in the process chain by the crude oil tankers, by the pipelines, by the refineries, by the power plants that generate the electricity required in the production line. and be caused by the gas stations.

In accordance with all national and international environmental authorities (eg the Intergovernmental Panel on Climate Change IPCC and the UNFCCC = United Nations Framework Convention on Climate Change and governmental bodies (including the Federal Ministry for the Environment and the Federal Ministry of Finance ), the CO ₂ emissions of the various energy carriers are considered below over their entire generation process, ie on the basis of a so-called Life Cycle Analysis (LCA) or well to wheel (WtW).

In the transport sector, sensitivity to greenhouse gas emissions is highest. The respective C0 ₂ emissions per km must be specified in the European Union eg for car sales. According to the EU decision, the taxation of fuels and vehicles will soon be C0 ₂ -oriented. Precisely because the GHG reduction In the transport sector, this is the most difficult and cost-intensive way, and the best way to reward a GHG reduction is by doing so. Apart from that, GHG-reduced and GHG-free fuels are of course better for the environment than GHG-intensive fossil fuels.

Producers of greenhouse gas-reduced and, in particular, greenhouse gas-free fuels will be able to count on increased market demand in the future. According to EU Directive RED 2009/28 / EC of 23 April 2009, the energy consumption of transport in each member state of the EU is to be covered by 10% with GHG-reduced (bi) fuels by 2020. By 2050, the German government is aiming for largely GHG-free traffic. Conventional bio-methane produced by the known process of anaerobic bacterial fermentation from manure and renewable raw materials (NawaRo) has the deficit that it is not an environmentally friendly energy carrier per se, but on the contrary is burdened to a considerable extent with greenhouse gases. The greenhouse gas pollution results from the sum of the greenhouse gas emissions of all energies or all energy carriers that are involved in the cultivation of biomass, in their storage, in their transport, in their conversion to biogas, in the treatment of biogas to bio methane and in the compression and Ein - Supply of BioMethane in a natural gas network and its distribution are used.

When using cultivated biomass as a fermentation substrate, energy-intensive cultivation and harvesting processes in particular burden the LCA greenhouse gas balance of the products "biogas" and "bio methane". In particular, the fermentation substrate "maize" used in biogas plants (BGA) has high greenhouse gas emissions in the process step "cultivation" due to the required intensive fertilization with mineral fertilizer and due to the carbon release from the soil (humus degradation): In the production of mineral fertilizer significant amounts of fossil fuels are used. When applying the mineral fertilizer, the highly polluting nitrous oxide (N ₂ 0) is produced. In essence, two bacterial processes are responsible for this: in the bacterial nitrification of urea / ammonium (NH ₄ ) to nitrate nitrous oxide (N ₂ 0) is produced as well as in the bacterial denitrification of nitrate to N ₂ . Only the degradation of soil-bound carbon (humus) that occurs in maize cultivation accounts for around 70% of total GHG emissions. It is not without reason that maize has been given the title of "ground robber" by farmers in ancient times. Nitrous oxide is approximately 296 times as polluting as C0 ₂ , so that fertilizer fertilizer fertilized with mineral fertilizer is more or less heavily polluted with greenhouse gas emissions. Since corn not only requires a relatively large amount of mineral fertilizer, but also absorbs a relatively large amount of carbon from the soil, the most important fermentation substrate used for anaerobic bacterial fermentation (corn accounts for around 80% of the renewable resources used in biogas plants in Germany, approx. 60% of the total German biogas production comes from corn) in the sub-process "cultivation" is excessively burdened with the emission of greenhouse gases, in addition to the greenhouse gas effects resulting from the use of fossil diesel fuel in the various cultivation and harvesting processes (pre-treatment of the field, sowing Fertilization, treatment with fungicides and pesticides, harvest, etc.).

The storage of various fermentation substrates leads to biochemical processes, which also result in greenhouse gas emissions. The aerobic oxidation process of rotting, for example, generates significant amounts of C0 ₂ . Storage of maize silage is expected to result in storage losses of more than 5% of the stored quantities. Added to this is the use of energy for storage, which is mostly of fossil origin (eg diesel fuel for the tractors that are stuck in the silo silage).

Since the transport of the fermentation substrates from the field to the storage place and from the storage place to the biogas plant is usually carried out with conventional tractors or trucks, for which mostly fossil diesel is used as fuel, also the transport of the cultivation biomass is burdened with greenhouse gas effects, because diesel fuel is as well as gasoline per kWh over the entire production and distribution process (lifecycle or well-to-wheel) approx. 302 g of (fossil) C0 ₂ -equivalents free. Since BioDiesel also has significant GHG emissions, the replacement of diesel fuel by BioDiesel hardly improves the GHG balance. In the conversion of biomass into biogas, conventional biogas plants use considerable quantities of electricity (eg for the permanent homogenization of the digestate), which are usually obtained from the public electricity grid. At present, this electricity from various sources in Germany is subject to an average of up to 624 gC0 ₂ - equivalent / kWhei, which means that the "conversion" process step also places a significant burden on the greenhouse gas balance of the "BioMethane" product. If the biogas obtained via the anaerobic bacterial fermentation is not exuded, but a treatment to BioMethan takes place, for the compression of the biogas (eg during the pressure swing process) and / or for its heating (eg in the process of pressureless amine scrubbing) again considerable amounts of energy (electricity and / or heat), which are mostly of fossil origin. This input of fossil energy further pollutes the greenhouse gas balance of BioMethan.

As a rule, the processed bio methane is fed into a natural gas grid. Natural gas networks are under considerable pressure. Therefore, the bio methane must be brought to the respective pressure level during the feed-in with energy-intensive compressors. Mostly electricity from the regional electricity mix is used here. In Germany this is

Electricity mix as already mentioned with currently up to 624 gC0 ₂ -equivalent / kWh _e i charged with the result that also the process step feed-in the GHG-balance of the product "BioMethan" considerably loaded.

Finally, the bio methane fed into the natural gas network is transported regionally during distribution. Compressors are also used, which either use fossil natural gas or electricity from the regional electricity mix as energy. In both cases, the activities taking place in this sub-process lead to greenhouse gas emissions. This additionally pollutes the LCA greenhouse gas balance of the product "BioMethan".

According to various studies, bio-methane produced from corn over the whole production process (lifecycle or well-to-wheel) is 140 gC0 ₂ -equivalent / kWh-methane to 234 gC-0, depending on the design of the production route ₂ equivalents / kWh-methane loaded. Compared with the GHG emissions of gasoline and diesel fuel (302 gC0 ₂ -equivalent / kWh), conventionally produced BioMethane achieves a reduction of 23% to 54%, a greenhouse gas freedom or a so-called C0 ₂ neutrality energy content not more than 0 g of (fossil) C0 ₂ equivalents are emitted per kWh, but is far from given. BioMethan is not per se C0 ₂ -free, but pollutes the environment to a considerable extent.

In particular, if BioMethan is to be used as fuel in traffic, its greenhouse gas (GHG) pollution plays a decisive role. A reduction of only 23 - 54% compared to. Gasoline, for example, is sufficient for BioMethan, which is produced in newly constructed plants, in accordance with EU Directive "Renewable Energy Directive 2009/28 / EC" of 23 April 2009 2018, because from 1 January 2018 biofuels produced in new plants will have to achieve a GHG reduction of at least 60%. Particularly advantageous would be a fuel that is not contaminated with greenhouse gases at all, the GHG balance is therefore neutral - which means that by using the fuel no other (fossil) C0 ₂ enters the atmosphere.

task

The invention is therefore based on the object to eliminate the lack of GHG burden of conventional bio methane and to create a process and a usable plant for the conversion of biomass, which have as an energy source whose greenhouse gas pollution is significantly lower than that of conventionally produced bio-methane, and which can be used as greenhouse-gas-reduced fuels, preferably as greenhouse-gas-free and particularly preferably as greenhouse gas-negative fuels in traffic. The term "greenhouse gas reduced" in this disclosure means, depending on the context, a reduction in fossil greenhouse gas (GHG) emissions to levels below either the LCA value of conventional bio methane (140-234 g C0 ₂ -equivante / kWh) or below the LCA value of natural gas (233 - 245 gC0 ₂ -equivalent / kWh) or below the LCA value of gasoline and diesel (302 gC0 ₂ -equivalent / kWh).

solution

This object is achieved with regard to the method essentially by the invention listed in claim 1 and with respect to the system essentially by the invention set forth in claim 9. The inventions are based in part on the previously known disclosures DE4409487 (Steffen / Grooterhorst), DE19532359 (Winkler), DE19633928 (Vollmer), DE19805045 (Hoffmann / ATB), DE1062 1337 (Hoffmann), DE10026771 (Hoffmann), DE10034279 (Bekon), DE10050623 (Schiedermeier), DE102004054468 (Lehmann), DE102005029306 (Krausch / Kreidl), DE202006 003293 (Müller), EP1926810 (Bekon), DE 10200702491 1 (Bekon), DE202007010912 (BioSonic) as well as the prior art disclosures of the inventor (DE102007029700A1 WO002009000 305A1,

WO002009000307A1, WO002009000309A1, DE102010008287.2, US-020100285556A1 and DE102010017818.7). Except for the writings DE102010008287.2 and

However, none of these disclosures is directed to minimizing the emission of fossil greenhouse gases (GHG). Neither are the processes presented including the individual process steps aimed at minimizing the GHG pollution of biogas or bio methane products.

The process for the production of BioMethane, which is consistently geared towards minimizing the emission of fossil greenhouse gases, consists of a total of 27 process steps, with full utilization of all construction and expansion options. These comprise in detail the process steps "substrate selection", "substrate cultivation / harvesting", "substrate storage", "substrate transport", "substrate acceptance / intermediate storage", "pretreatment", "in-house transport" , "Conversion", "biogas split", "electrification", "biogas scrubbing / C0 ₂ capture", "recuperation of the regenerative C0 ₂ ", "splitting of the regenerative C0 ₂ ", "reforming of the regenerative C0 ₂ ", "sequestering of regenerative C0 ₂ "," Substitution of fossil C0 ₂ "," BioMethane partition "," External mixing of biomethane and natural gas "," Compression "," Injection "," Liquefaction "," Filling "," Nutrient extraction "," Fuel production "," Ascherecuperation "," Fertilizer production ", and" Distribution BioMethan ", of which most are optional: The 9 process steps" substrate selection "," Biogas scrubbing / C0 ₂ separation "," Recuperation of regenerative C0 ₂ "," C0 ₂ sequestration de s regenerative C0 ₂ "," Substitution of fossil C0 ₂ "," Substitution of fossil fuels by synthetic methane "," Nutrient extraction "," Fuel production "and" Fertilizer production "have - as the inventor has stated for the first time and as explained below - particularly important influence on the GHG balance of the end products.

Apart from the design of the overall process, the GHG balance is optimized by additionally carrying out a GHG-oriented control of the energy input in each of the process steps, i. the greenhouse gas load is minimized in each case. This is done both on the fiction, contemporary selection of each used in the process steps energy sources and energy as well as on the design of the individual process steps themselves. Thus, sub-methods are preferably used in the individual process steps, which burden the GHG balance less than other possible sub-methods.

Instead, as greenhouse gas-free straw, greenhouse gas-free agricultural residues such as straw-containing straw and mixtures of straw and liquid manure and greenhouse gas-poor organic waste are used, ie substrates that do not need to be specially grown and therefore in the process step " Substrate cultivation / harvest "until collection are not contaminated or to a very limited extent with greenhouse gases. If the design of the overall process using the optional process steps reveals that the resulting product "BioMethane" or "CBM" (Compressed BioMethane) becomes greenhouse gas-negative, the shares of low-greenhouse NawaRo or possibly also of greenhouse gas-rich NawaRo at Frischmasse input until the LCA greenhouse gas balance of BioMethan or CBM has barely changed from negative to positive. The generated energy sources thus remain at least greenhouse gas free.

Care should be taken during substrate storage so that no emissions of methane or ammonia or nitrous oxide occur. In addition, decomposition processes are prevented as far as possible because the oxidation processes that take place during this process are linked to the production and emission of C0 ₂ . This sub-process essentially remains free of greenhouse gases.

In the transport of biomass according to the invention tractors and / or trucks are used, which are powered by greenhouse gas-free or greenhouse gas-negative bio-methane or a mixture of fossil diesel, greenhouse gas-free or greenhouse gas-negative bio-methane and fossil natural gas or with a corresponding natural gas equivalent, so that the greenhouse gas pollution of the process step " Transport "even with a blend of bio methane and natural gas with fossil diesel to a mixed fuel very low precipitates and the GHG load preferably due to a greenhouse gas neutrality of the fuel mixture even goes back to zero When substrate acceptance and intermediate storage of the substrates in the biogas plant is as in Care should be taken to ensure substrate storage that no emissions of methane or ammonia or nitrous oxide occur, and that rotting processes are prevented as far as possible, with the result that this sub-process also remains GHG-free.

The pretreatment of the straw and the straw-containing feedstocks takes place in such a way that the energy expenditure used in this process step is smaller than the additional energy yield attributable to the pretreatment. The use of greenhouse gas-free energy ensures that this sub-process also remains GHG-free.

In the case of in-house transport, GHG-negative bio-methane or a corresponding natural gas equivalent produced by this method is used so that the greenhouse gas emissions load of diesel fuel also used is compensated and the overall GHG balance of this process step remains neutral.

In the conversion of the already greenhouse gas-poor biomass to biogas, greenhouse gas-free energies are also used in a modified fermentation process or in a modified biogas plant, preferably greenhouse-gas-free electricity produced by the conversion plant itself and greenhouse gas-free heat generated by it itself. The "conversion" sub-process also does not contribute, or hardly does so, to any greenhouse gas emissions that contribute to a poor greenhouse gas balance of the energy sources produced (biogas, bio methane, alternative fuel, bioethanol, if applicable) and the generated energies (electricity, heat).

When dividing the biogas, the generated biogas and the biogas supplied from external sources are distributed among the 3 utilization strands and sub-processes "power generation", "biogas scrubbing / C0 ₂ separation" including the subsequent "C0 ₂ recuperation" and "C0 ₂ reforming ". By integrating the sub-process "biogas subdivision" into the entire process sequence, a flexible control or regulation of the respective biogas components is possible, so that the generation of the various energy sources and the separation and recuperation of the C0 ₂ to the changing technical and or economic conditions can be adjusted.

Since GHG-reduced or THG-free or GHG-negative BioMethane produced according to the method is usually more valuable than effluent biogas, it is advantageous to minimize the proportion of biogas entering the "power generation" step In addition, only power plants with the highest electrical efficiencies are used, which also minimizes the biogas quantities to be used This is done with greenhouse gas-free electricity and greenhouse gas-free heat, preferably with electricity generated by the biogas plant and self-generated heat, so that even this process step the greenhouse gas balance of the product or hardly BioMethan with greenhouse gases The biogasau preparation includes the deposition of C0 ₂ according to one of the known methods (inter alia, pressure swing absorption, non-pressurized A- minwäsche, cryogenic cooling technology).

Recuperation of regenerative CO ?: The deposited during biogas scrubbing regenerative C0 ₂ in the method disclosed here is not as in conventional treatment processes in the ambient air and thus returned to the (short-term) C0 ₂ cycle, but collected (recuperated) and possibly stored temporarily. The C0 ₂ precipitation and the C0 ₂ recuperation can be combined in one plant (compare Figures 19 to 39 and claim 9).

In the sub-process "CCySequestierung" downstream of the recuperation, the C0 _{2 is} geologically stored (sequestered), but it can also be used in a further sub-process "Substitution of fossil CO?" used as a material substitute for fossil C0 ₂ or in the subprocess "CO ^ reforming" to a regenerative energy source, preferably according to the known Sabatier process to synthetic methane (CH ₄ ) or according to the known methods (steam reforming, Bertau / Pätzold / Singliar-V) to synthetic methanol (CH ₃ OH).

Sequencing removes regenerative C0 ₂ from the C0 ₂ cycle, which is significantly more than avoiding further GHG emissions. Without other measures and procedural steps, only the sequestering step can relieve the greenhouse gas balance of the BioMethane remaining after the deposition of the C0 ₂ fraction to such an extent that it becomes strongly negative (!). At best, the GHG "burden" of the BioMethane reach ₀ methane equivalents / kWhßi - along with the other measures described even up to -468 GC0 _second

The best case is achieved when the collected regenerative C0 ₂ is sequestered as described above, at the same time THG-free energies and energy carriers are used in the process, and at the same time a nutrient extraction takes place, which is connected to a fertilizer production (see below), as well as the fermentation residues the anaerobic bacterial fermentation treated to alternative fuels and used as fuel oil or gas or Kohlesubstitut (see below) and also the ashes of alternative fuels is recuperated and mineral fertilizers replaced, in short, if all the process steps described above 27 are used. The biogas produced according to the method and / or the biogas recuperated from external sources and / or the recuperated regenerative CO ₂ can be reformed into bio-methane and / or bio-methanol in the optional "CO? -Reforming" sub-process as described above, for example for methanol synthesis The steam reforming (sub-) processes of steam reforming have been in use for decades in other applications, but the required amounts of electricity and heat are covered by regenerative or at least low-GHG sources of energy for the methanation of C0 ₂ The well-known Sabatier process can be used, whereby the hydrogen required for this purpose is to be generated electrolytically by means of GHG-free electricity, so that the hydrogen thus produced is not burdened with GHG emissions (hitherto hydrogen is mostly made from fossil, GHG-contaminated Natural gas or produced as a waste product of the chemical industry).

The energetic use of the C0 ₂ portion of the biogas avoids the otherwise necessary use of fossil fuels. This avoidance effect is attributed to the main product of the process, which considerably improves the GHG balance of the methane content of the biogas or the bio-methane.

When the C0 ₂ reformer releases synthetic methane, it is physically added to biogas from biogas scrubbing; in the GHG balance, it replaces fossil natural gas and, if natural gas replaces diesel fuel or gasoline, with diesel and gasoline. In the case of the production of bio-methanol, this energy source is supplied separately for use, preferably as a greenhouse gas reduced fuel component. BioMethanol also replaces fossil fuels, resulting in GHG credits attributed to BioMethan.

The bio methane produced in accordance with the process is preferably fed into an existing natural gas grid in the feed-in subsystem. "Since gas networks are usually under considerable gas pressure, it is necessary to compress the bio methane using energy-intensive compressors, which become more efficient with increasing size , in the upstream sub-process "Compression". It is therefore not least beneficial for the GHG balance if the compression quantities and thus also the feed-in quantities are as large as possible. As far as possible, THG-free electricity is also used as the current in this process step, so that the fed-in bio-methane remains at least THG-free, but preferably GHG-negative. As an alternative to a gaseous delivery, the gases "BioMethan" and "Regenerative C0 ₂ " produced in accordance with the process can be delivered in the liquid state. For BioMethane, for example, this makes sense if BioMethan is to be available as fuel in regions without a gas grid connection. According to the above directive, the energy used for this purpose originates from regenerative sources which are preferably low in greenhouse gases and particularly preferably produced free of greenhouse gases and in particular by the conversion plant itself GHG balance for liquefied gases GHG-free or GHG-negative If necessary, the gasses "BioMethan" and "Regeneratives C0 ₂ " in the gaseous state are required, then it is necessary to fill and deliver them in pressure tanks energy-intensive compressors in the sub-process "bottling". Here, too, greenhouse gas-reduced electricity is used, preferably low-GHG electricity, particularly preferably greenhouse gas-free electricity and in particular greenhouse gas-negative electricity. In this sub-process, the intermediate storage and filling of the liquid energy carriers takes place. It may be necessary to cool the filled tanks. This cooling also takes place with low-GHG or THG-free electricity or with dry ice produced from regenerative C0 ₂ according to the process, so that the energy sources generated remain GHG-free or THG-negative. Of all the process steps and measures, the sequestration of regenerative C0 _{2 has} the greatest effect on the GHG balances of the process or on the energy products obtained by the process. This is not a computational assignment, the C0 ₂ is rather physically stored in deep geological formations. The effective CO reduction (final removal of the regenerative C0 ₂ from the C0 ₂ cycle) is attributed to the main product of the process, the bio-methane, which is the main reason for the GHG-freedom or GHG negativity of the produced BioMethans.

For the other options of C0 ₂ recovery, C0 ₂ reforming and material substitution of fossil carbon dioxide, "only" results in Q avoidance, C0 ₂ from fossil sources, eg crude oil or C0 ₂ produced from natural gas is replaced by regenerative CO ₂ from the process described here, the unneeded fossil CO ₂ is no longer generated, which relieves the burden on the environment Substitution of fossil C0 ₂ ". This avoidance effect is also attributed to the bio-methane.

An additional improvement in the GHG balance is achieved by separating and recuperating the nutrients contained in the feedstock and digestate in a "nutrient extraction" sub-process, and then converting the nutrients into the "fertilizer production" sub-process Substitute mineral fertilizer, which is usually generated with considerable energy expenditure from and with fossil fuels. This substitution avoids just this use of fossil fuels, which means less release of additional greenhouse gases. Also, this GHG prevention is attributed to the BioMethan, which further improves its GHG balance.

Another positive effect of the GHG effect is that the residual energy contained in the fermentation residues is harnessed in an optional sub-process "fuel production." In this case, alternative fuel pellets prepared from fermentation substitute fossil greenhouse gas-releasing fuel oil or fossil greenhouse gas-releasing natural gas or even fossil fuel Greenhouse gas-releasing coal: These avoided greenhouse gas emissions are also attributed to BioMethan, which further improves its GHG balance sheet.

Recuperation of the pellet bag: Special advantages arise when the ashes of fermentation residue pellets or digestate briquettes are recuperated and fed into fertilizer production. Thus, the phytochemicals contained in the solid phase of the fermentation residues, in particular the phosphate, which is expected to be on the run out of crude oil, can largely be recycled to the nutrient cycle. The recuperated nutrients replace mineral fertilizers, which further improves the GHG balance of the BioMethan product. The synthetic methane (SynMethane) produced in the "CO ^ Reformulation" sub-process is fed into a natural gas or bio methane network in the further sub-process "feed", like the BioMethane generated in the biogas scrubbing or CC separation sub-process (see above).

In the "mixing" sub-process, the BioMethane is mixed with natural gas, which can be physically mixed before the BioMethane feeds into the natural gas grid by extracting and decompressing the natural gas from the grid and using the pressureless BioMethane. mixed and then compressed together with this again and returned to the network. It is more elegant and advantageous if the BioMethan and / or the SynMethan is first brought to the pressure level of the network into which it is to be fed, if it is mixed with the natural gas taken from the gas network but still under pressure, and when finally a return to the natural gas network takes place. The most elegant and advantageous is when the mixing is done only statistically / virtually, such as that recycled BioMethan and / or SynMethan is fed into a natural gas network, it is mixed with natural gas in the natural gas network and that the gas removed by the consumer from the natural gas network only calculated (statistical / virtual) has a certain percentage of bio methane. Depending on the desired GHG reduction, then corresponding excess amounts of (mixed) gas can be taken from the natural gas network. With a desired bio-methane content of, for example, 50% of the mixed gas, twice the amount of energetic bio-methane feed can be taken as mixed gas. This is of particular advantage because it indirectly increases the available amount of final energy. The production factor "biomass", which occurs as a bottleneck, can be better exploited via the multiplier effect of the blended natural gas.

In the "Distribution" sub-process, the "BioMethan" and "Regenerative C0 ₂ " gases are distributed either via gas pipelines or, as in the case of BioMethanol, with mobile tanks.The distribution of the BioMethan is preferably carried out using trucks with or without greenhouse gas-free or greenhouse gas-negative BioMethane a mixture of fossil diesel, greenhouse gas-free or greenhouse gas-negative bio-methane and fossil natural gas or a corresponding natural gas equivalent are driven, so that the greenhouse gas pollution of the process step "distribution" even when mixing the bio methane and natural gas with fossil diesel to a mixed fuel very low and the GHG load may even decrease to zero due to greenhouse gas neutrality of the fuel mixture. This means that the GHG balance of the distributed Bio / SynMethan remains as good as that of the not yet distributed Bio / SynMethan.

The overall objective of the invention is the production of greenhouse-gas-reduced energy carriers, preferably the production of greenhouse-gas-free energy carriers and, particularly preferably, the production of greenhouse gas-negative (!) Energy carriers. While fossil

According to Life Cycle Analysis (LCA) contribute to the greenhouse effect with 302 gC0 ₂ - eq / kWh and natural gas (CNG) with 233 - 245 gC0 ₂ - eq / kWh and conventional corn produced bio methane with approximately 140 to 234 gC0 ₂ -equivalent / kWh, the energy carriers generated by the method disclosed here should significantly undercut the GHG load of 120 gC0 ₂ -equivalent kWh and, ideally, reach -468 gC0 ₂ -equivalent / kWh. Overall, the greenhouse gas reduction of the bio methane produced in accordance with the innovative process should go so far that the energy source "bio methane / natural gas mixture" has a GHG emission of <120 gC0 ₂ -equivalent / kWh and thus be used as a greenhouse gas-reduced energy source Preferably, it should be used as a low-GHG energy source with a GHG load of <50 gC0 ₂ -equivalent / kWh, particularly preferably as a greenhouse gas-free energy (GHG load of = 0 gC0 ₂ -equivalents / kWh) and in particular as greenhouse gas-negative Energy carrier (GHG load of <0 gC0 ₂ -equivalent / kWh).

Particular advantages arise when GHG-poor or GHG-free or GHG-negative BioMethan is mixed with natural gas. Yoy. The fuels gasoline and diesel fuel can then be used after new knowledge and the C0 ₂ -minderung effect of the natural gas, which compared with. Gasoline and diesel at least about 63 gC0 ₂ -equivalent / kWhE _r dgas or approx. 21%.

Another goal is the use of energy sources as fuel in traffic, preferably in a mixture of bio methane and natural gas as greenhouse gas-poor fuel with a GHG load of <50 gC0 ₂ -equivalent / kWh, particularly preferably as greenhouse gas-free fuel and in particular as a greenhouse gas-negative fuel.

If realized with all steps, THG negative bio methane can be generated by the method disclosed herein. The THG-negative bio methane can then be mixed with fossil and thus greenhouse gas-loaded natural gas (CNG) with a corrugated load of about 233 - 245 gC0 ₂ -equivalent / kWhcNG Mixed gas any GHG load between -468 gC0 ₂ -

Equivalent / kWliMischgas and +239 gC0 ₂ -equivalent / kWh i _S gas has. Thus, with the method disclosed here both a whole range of mixed gases with different GHG emission and thus different GHG reduction effects can be generated as well as an absolutely GHG-free mixed gas and even various GHG negative (!) Mixed gases. These mixed gases can be used as fuel in traffic. Achieved benefits

With the generation of mixed gases different GHG reduction effects can be achieved. These can reach 35% or 50% or 60% or 80% or even 100% if the mixing ratio is appropriate. In the substitution of gasoline or diesel fuel, the particular advantage of mixing GHG-negative bio methane with fossil, GHG-contaminated natural gas (CNG) is that the GHG reduction effect of natural gas is added to the GHG reduction effect of BioMethane. The more GHG-negative the bio-methane generated by the process, the more natural gas can be added to the bio-methane to achieve a particular mix gas quality and the higher the proportionate GHG reduction effect of the natural gas. That is, the more effort is made to produce the GHG-reduced BioMethan and the better the intermediate "BioMethan" used for GHG reduction, the more "bad" fossil natural gas (CNG) can be converted into "good" GHG. If, for example, a BioMethan-4 _68g with up to -468 gC0 ₂ A _q kWhBi ₀ methane is used as the base gas for mixing, the production of a mixed gas of _-35 _oo (GHG load according to Life Cycle Analysis rd 195 gC0 ₂ -equivalent / kWl of isochgas, which means a reduction in THG emissions of 107 g gC0 ₂ -equivalent / kWh or 35% compared to gasoline) per 1 kWh of _B ioMethan-468g around 7.7 kWh ₊₂₃ 9 _{g can be} added to achieve the GHG reduction rate of 35% for the production of a mixed gas with a GHG reduction of 55% (GHG load according to Life Cycle Analysis approx. 137 gC0 ₂ - equivalents / kWl mixing gas , which compared to gasoline, a reduction of the GHG emission vo n 165 g gC0 ₂ -equivalent / kWh or 55% means) per 1 kWhBi ₀ methane-4 ₆ 8g still approx. 3.0 kWh of natural gas can be added.

Overall, in these exemplary calculations, up to 4.0 kWh of mixed gas are available per 1 kWh of methane, which are approximately conventionally made of maize-produced bio-methane with regard to the GHG load (whose GHG values according to Life Cycle Analysis, as set out above, are between 140 and 234 gC0 ₂ equivalents / kWh of methanol). An innovative biogas plant, which produces bio-methane according to the method presented here, can thus provide an amount of energy that is up to 4 times the energy input of biomass. While conventional biogas plants achieve a conversion rate of 70-80%, plants operating according to the method described here achieve an input / output ratio of up to 400%. Without the automobile technology (ie neither the product nor the manufacturing plants) having to change or further develop, zero emissions mobility is possible with the combined use of gas vehicles and GHG-free or GHG-free mixed gas, possibly even GHG-negative mobility. The international automotive industry can still build high-quality cars without having to change the technology greatly. Petrol engines must be modified in a known manner only to gas engines.

The disadvantages of possibly also C0 ₂ -free electromobility such as short range, long load times, high battery weight, very high additional cost, problematic heating in winter and problematic air conditioning in summer, investment in new production lines, high R & D expenditures, etc. occur not on, because gas vehicles are up to the additional gas tanks and some modifications to the engine conventional gasoline vehicles. Neither has the sophisticated combustion engine technology to be switched to a simple electric motor technology, nor high-performance batteries must be developed, produced and paid. Also against. hydrogen technology currently praised as a last resort, the production process described here, the resulting product and the use described have advantages. The efficiency of mobile gas engines is + 5% to + 8% compared to. Although mobile petrol engines at approx. 28% - 29% improved, but not nearly as good as that of fuel cells, which have an efficiency of about 40 - 50%. However, this disadvantage is overcompensated by the considerably lower production costs of the CNG vehicle required for the use of "CBM." While the additional purchase costs of hydrogen passenger cars today amount to € 50,000 and more compared with comparable gasoline vehicles, they amount to CNG vehicles. Passenger cars average only € 2,800, and hardly a car can compensate for this cost disadvantage during its normal useful life by reducing its fuel consumption.

The production of GHG-reduced or GHG-free bio methane and its use as fuel in gas vehicles is therefore an advantage for the automotive industry, for their employees, for car buyers and users and last but not least for the environment. Detailed description

For a better understanding of the present invention, reference will be made below to exemplary embodiments illustrated in the drawings, which are described by means of subject-specific terminology. It should be noted, however, that the scope of the invention should not be limited by the disclosure of embodiments, as changes and modifications to the disclosed method and to the disclosed biogas plant and its variants and other applications of the invention and other uses of the products as usual present or future expertise of a competent person skilled in the art. FIGS. 1 to 18 show exemplary embodiments of the method according to the invention, namely:

Figure 1 is a schematic block diagram of the essential process steps for the production of biogas from GHG-rich NawaRo, the deposition of C0 ₂ and the use of GHG-reduced bioMethane as GHG-reduced or THG-free energy source Figure 2 is a schematic block diagram of a development of in 1, comprising a feed of greenhouse-gas-reduced bio-methane into a natural gas grid, an outfeed of an energy equivalent and its use as a THG-reduced or THG-free fuel

FIG. 3 shows a schematic block diagram of a development of the method described in FIG. 2 with low-GHG NawaRo as the fermentation substrate

Figure 4 is a schematic block diagram of a development of the method described in Figure 3 with THG-free or low-GHG organic waste as a fermentation substrate

5 shows a schematic block diagram of a development of the method described in FIG. 4 with straw and straw-containing starting materials as fermentation substrates FIG. 6 shows a schematic block diagram of a development of the method described in FIG. 5 comprising a pretreatment of the fermentation substrates straw and straw-containing feedstocks Figure 7 is a schematic block diagram of a development of the method described in Figure 6 comprising the optional use of low-GHG and / or GHG-rich renewable resources as additional fermentation substrates

FIG. 8 shows a schematic block diagram of a development of the preceding method variants, comprising a selection from a wide range of starting materials and the use of regenerative and greenhouse gas-poor energies in the various method steps

FIG. 9 shows a schematic block diagram of a development of the method described in FIG. 8 comprising a net-external mixing of the produced bio-methane with natural gas FIG. 10 a schematic block diagram of a development of the method described in FIG. 9 comprising an optional reforming of the CO ₂ contained in the THG-reduced biogas to THG -reduced SynMethan and / or to GHG-reduced SynMethanol

FIG. 11 shows a schematic block diagram of a development of the method described in FIG. 10, comprising an optional reforming of separated regenerative CO ₂ to give THG-reduced bio-methane and / or to THG-reduced bio-methanol

FIG. 12 shows a schematic block diagram of a development of all the methods described above, comprising a substitution of fossil CO ₂ by deposited regenerative CO ₂

FIG. 13 shows a schematic block diagram of a development of all the methods described above, including an optional generation of electricity from GHG-reduced biogas

Figure 14 is a schematic block diagram of one embodiment of all the methods described above including optional liquefaction of greenhouse gas reduced bio methane or mixed gas consisting of greenhouse gas reduced biomethane and natural gas

Figure 15 is a schematic block diagram of a development of the method described in Figure 8 comprising an optional utilization of the digestate as a mineral fertilizer substitute FIG. 16 shows a schematic block diagram of a development of the method described in FIG. 15, comprising an optional extraction of plant nutrients from the fermentation residues and their optional utilization in a fertilizer production

FIG. 17 shows a schematic block diagram of a further development of the method described in FIG. 16, comprising an optional preparation of the solid fermentation residues for alternative fuel

FIG. 18 shows a schematic block diagram of a further development of the method described in FIG. 17 comprising an optional recuperation of the fuel ash and its utilization as fertilizer component. FIGS. 1 to 18 show processes as a rectangle and substances or products as a rectangle with cut corners. In the figures 19 to 39 plants or devices are shown as a rectangle and fabrics or products as a rectangle with cut corners. Figures 19 to 39 show embodiments of the system according to the invention, namely: Figure 19 is a schematic block diagram of the essential components of a biogas plant for the production of greenhouse gas reduced bio methane and regenerative C0 ₂ and the use of greenhouse gas reduced BioMethans as a greenhouse gas reduced or greenhouse gas free gas fuel

FIG. 20 shows a schematic block diagram of a development of the system described in FIG. 19, comprising the use of a fermentation substrate mixture improved with regard to the GHG balance

FIG. 21 shows a schematic block diagram of a further development of the plant described in FIG. 20, comprising the use of straw and straw-containing feedstocks as fermentation substrates. FIG. 22 shows a schematic block diagram of a development of the plant described in FIG. 21, comprising a housed acceptance area and an enclosed intermediate storage facility FIG. 23 shows a schematic block diagram of a development of the plant described in FIG. 22, comprising plants for the pretreatment of straw and straw-containing starting materials

FIG. 24 shows a schematic block diagram of a development of the plant described in FIG. 23, comprising the additional use of organic waste as a fermentation substrate

FIG. 25 shows a schematic block diagram of a further development of the system described in FIG. 24, comprising the additional use of low-GHG and GHG-rich renewable raw materials as a fermentation substrate

FIG. 26 shows a schematic block diagram of a development of the system described in FIG. 25, comprising the additional or alternative use of regenerative CO ₂ as substitute for fossil CO ₂

FIG. 27 shows a schematic block diagram of a further development of the system described in FIG. 26, comprising the additional use of digestate as a substitute for mineral fertilizer. FIG. 28 shows a schematic block diagram of a development of the system described in FIG. 27, comprising a secondary fermenter

FIG. 29 shows a schematic block diagram of a further development of the plant described in FIG. 28, comprising a compressor for compressing the generated greenhouse-reduced bio-methane (Compressed BioMethane CBM) and at least one feed-in point for the feed of this bio-methane into a natural gas or a bio-methane network

FIG. 30 shows a schematic block diagram of a development of the system described in FIG. 29, comprising at least one exit point for the outfeed of BioMethane or BioMethan substitute or BioMethane / natural gas mixtures or corresponding energy equivalents from a natural gas network. FIG. 31 shows a schematic block diagram of a development the plant described in Figure 30, comprising facilities for converting the produced greenhouse gas reduced biogas to GHG-reduced electricity FIG. 32 shows a schematic block diagram of a development of the plant described in FIG. 31, comprising a plant for reforming biogas into bio-methane or bio-methanol

FIG. 33 shows a schematic block diagram of a development of the plant described in FIG. 32, comprising a connection from the C0 ₂ capture and recrystallization plant to the C0 ₂ reformation plant for introducing recuperated regenerative C0 ₂ into the C0 ₂ reformation plant

FIG. 34 shows a schematic block diagram of a further development of the system described in FIG. 33, comprising a device for the net-external mixing of greenhouse-reduced bio-methane with natural gas, for compressing the mixed gas and for feeding the compressed mixed gas into a natural gas network

FIG. 35 shows a schematic block diagram of a development of the plant described in FIG. 34, comprising a plant for the liquefaction of greenhouse-gas-reduced bio-methane or a gas mixture consisting of greenhouse-gas-reduced bio-methane and natural gas

FIG. 36 shows a schematic block diagram of a development of the plant described in FIG. 35, comprising a plant for extracting plant nutrients from the resulting fermentation residues

FIG. 37 shows a schematic block diagram of a development of the plant described in FIG. 36, comprising a fertilizer treatment plant for processing the extracted organic nutrients into fertilizers and fertilizer components

Figure 38 is a schematic block diagram of a development of the system described in Figure 37, comprising systems for processing the solid part of digestate to alternative fuel

Figure 39 is a schematic block diagram of a development of the system described in Figure 38, comprising a boiler with devices for recuperation of the digestate

These embodiments will be described in detail below. FIG. 1 shows the simplest embodiment of the method. It reproduces the common basic principle of a biogas plant, but with the additions a) separation of regenerative C0 _2j b) recuperation of the separated regenerative C0 ₂ , c) geological disposal (sequestering) of the separated and recuperated regenerative C0 ₂ and d) use of the GHG-reduced BioMethans as a greenhouse gas-reduced energy source. Subvariants of this embodiment variant may consist in the fact that the bio-methane is used as a greenhouse gas-reduced fuel or (not shown) as a greenhouse gas-free or greenhouse gas-negative energy carrier or as a greenhouse gas-free or greenhouse gas-negative fuel. The respective fuel is preferably used in traffic (see claims 2 and 5).

In this simplest embodiment variant of the process, no changes to the conventional procedure are provided in the "substrate selection" process step, as is still the case for relatively GHG-rich NawaRo.Also, the previously customary procedures in the process step "substrate cultivation Z harvest" remain. unchanged. In the process step "substrate storage", at first no attention is paid to whether the stored feedstocks exhale methane or nitrous oxide, and in the process step "substrate transport", conventional tractors are transported from biomass to biogas plant and trucks used. In the process step "substrate acceptance and intermediate substrate storage", as in the case of substrate storage, care is still not taken to ensure that any emissions of methane or nitrous oxide occur.

The conversion of the biomass into biogas (fermentation), which is arranged in the process step "conversion", is carried out as previously practiced by the industry.Conversion is an energy-intensive process, especially if the plants used are wet plants in which the digestate is almost permanently involved If the entire biogas yield is emitted, up to 15% of the electricity yield must be spent on conventional wet systems, even if the biogas produced is converted to electricity on site, the required electricity is usually still required The electricity purchased from the grid is usually cheaper than the tariff for the electricity fed in. With a GHG value of the German electricity mix of 624 gC0 ₂ -equivalent / kWhei, the process step "conversion" therefore becomes conventional in considerable Dimensions burdened with greenhouse gas emissions. This procedure, which has hitherto been customary, initially remains unchanged.

According to the method according to the invention, the conventionally generated (GHG-loaded) biogas and possibly supplied from external sources biogas in the process steps "biogas scrubbing / CO ^ -Abscheidung" and "recuperation of regenerative CO?" processed into bio methane. The biogas is "washed" in a gas treatment plant, ie the biogas with about 39 - 47% contained C0 ₂ and other gases (sulfur, ammonia, nitrogen, oxygen, which together contain about 5% in the biogas) are separated This is done with conventional methods (inter alia with a pressure swing process) or with the (sub-) process of pressureless amine scrubbing, but preferably with a previously unused refrigeration process (cryo-technology) .The deposited regenerative CO ₂ , however, is not as usual but released for further use (recuperated) and possibly stored or fed into a gas line (see address 1) The uses of the recuperated C0 ₂ include the geological disposal (sequestering), its reforming into synthetic methane ( SynMethan) or synthetic methanol (SynMethanol) and the material substitution fossil C0 ₂ (see claim 1).

It is advantageous if a process is used for C0 ₂ capture in which methane slip and its GHG emission are very low (methane is 23 times more harmful to the environment than carbon dioxide). This is the case with pressureless amine scrubbing (cf claim 7). If the transport or use of the C0 ₂ or the resulting BioMethans to be done in liquid form (see claim 1), it is advantageous to use as a gas scrubbing a cryogenic process that works with cold and can provide the C0 ₂ in liquid form and with relatively little further energy expenditure for the cooling (see claim 7).

It has been shown that biogas scrubbing or C0 ₂ separation results in scale effects. With a doubling of the capacity of the systems used, the expenditure on equipment increases only minimally. As a result, the unit costs or the costs per m ^{3 of} biogas fall sharply. It is therefore advantageous if the volume flow has a certain minimum size (see claim 7). The CO ₂ precipitated from the biogas is not fossil C0 ₂ but C0 ₂ from plants that was in the atmosphere 1 or 2 years earlier. This C0 ₂ is referred to below as regenerative C0 ₂ .

Reducing greenhouse gas (GHG) emissions is one thing, but removal of (regenerative) carbon dioxide (C0 ₂ ) from the atmosphere is a process that goes well beyond avoiding extra GHG emissions. In the use variant "sequestering", the method thus does not avoid the emission of additionally generated fossil C0 ₂ by a type CCS (Carbon Capture and Storage), but already in the atmosphere C0 ₂ is deposited, recuperated and stored or sequestered ( see claim 1).

While the deposition of the regenerative C0 ₂ in the process step "Biogaswäsche / C0 ₂ - deposition" and the recuperation of the deposited regenerative C0 ₂ in the step "C0 ₂ -Rekuperation" made, the final storage of the (regenerative) C0 _{2 takes place} in the process step ,, CO Sequestration of the recuperated regenerative C0 _{2 leads to} better greenhouse gas effects than reforming the recuperated C0 ₂ to methane (CH ₄ ) or to methanol (CH ₃ OH) and also better ones Greenhouse gas effects as in the substitution of fossil C0 ₂ by the recuperated regenerative C0 ₂ , it is advantageous if the largest possible proportion of biogas in the strand "biogas scrubbing / C0 ₂ capture / C0 ₂ -reecipitation" is passed (see claim 7 ), because it could also be performed in the reforming (see embodiment of Figure 10) or in the flow (see embodiment of Figure 13).

Since the C0 ₂ can be stored geologically only at selected locations, it usually has to be transported from the deposition apparatus to the sequestering location. This is done cooled in liquid tanks or in gaseous form in pressure tanks or in solid form as dry ice or in gaseous form via a C0 _{2 line} . Apart from transport by means of a dedicated gas line, trucks which use GHG-free fuel (see claim 1) are preferably used as the means of transport.

The final removal of the C0 ₂ from the atmosphere and from the C0 ₂ cycle, as shown above, not only prevents the avoidance of additional GHG emissions, but also a real reduction in GHG emissions. This GHG reduction is attributed to the product of the process, the "BioMethan", solely because of the level of C0 ₂ - Reduction, the GHG balance of BioMethans can be negative (!). This advantageous C0 ₂ reduction is the higher, the higher the proportion of regenerative C0 _{2 which} is fed into the sequencing (cf claim 7).

Due to the geological disposal of regenerative C0 ₂ , the GHG balance of the resulting bio methane drastically improves: the biogas produced conventionally from the conventional feedstock "GHG-rich NawaRo" is initially burdened with GHG emissions (when using maize according to the latest studies) with 140-234 GC0 ₂ -. equivalents / kWhßiogas), removal of the regenerative C0 ₂ from the C0 ₂ cycle the energy source is, however, ascribed, thus the BioMethan When a sufficiently large portion of the deposited and recuperated C0 ₂ is sequestiert, can GHG exposure to less than 100 gC0 ₂ -equivalent / kWhBioMethane, possibly even below 50 gC0 ₂ -equivalent / kWhBioMethan or to below 1 gC0 ₂ -equivalent / kWhMioethane and possibly even below -100 gC0 ₂ Equivalents / kWhBi ₀ -methane (see claim 1).

The method illustrated in FIG. 2 is an advantageous development of the embodiment variant of the method described in FIG. The process is improved by distributing the THG-reduced or THG-free BioMethan or CBM after an appropriate feed via a natural gas or bio methane network. This modification reduces the distribution costs and lowers the energy input.

In the "Compression" step, the bio methane remaining after biogas scrubbing / C0 ₂ capture and C0 ₂ recuperation is compressed to a slightly higher pressure level than prevailing in the natural gas grid section into which it is to be fed It is therefore not least of advantage for the GHG balance if the gas quantity to be compressed is as large as possible (see claim 7) .To further improve the GHG balance, electricity is also used in this case Process step preferably uses THG-reduced, preferably THG-free, stream (see claim 1). Compressing converts the pressureless or moderately pressurized BioMethane into so-called "compressed bio-methane" (also referred to below as CBM).

The CBM is fed into the intended section of a natural gas or bio-methane network in accordance with the "feed-in" process step (see claim 2.) The feed is also preferably carried out using GHG-reduced, preferably preferably THG-free, electricity (cf. Claim 1). Since there are strong volume effects when feeding BioMethane into natural gas grids, it is advantageous if the volumes fed in have a minimum size (see claim 7).

In the process step "Distribution BioMethan", the physical or virtual / statistical transport of the bio methane fed into a natural gas or bio methane network takes place to the consumer, where the fed bio methane mixes with the natural gas in the network (see claim 2) However, they can also be mixed in such a way that natural gas is taken from the natural gas network and mixed with the CBM outside the natural gas network (see the embodiment of FIG.

The most elegant and advantageous is when the mixing is done only statistically / virtually, for example, such that pure BioMethan or a mixture of bio methane, propane and / or butane is fed into a natural gas network and this mixture is mixed in the natural gas network with natural gas. Also possible is an embodiment variant of the method in which the gas finally taken by the consumer from the natural gas network has a certain amount of THG-negative bio-methane relative to a certain amount of energy (energy or natural gas equivalent) and therefore corresponding excess amounts of (mixed) gas be taken from the natural gas network. The possible withdrawal quantities result from the GHG target load, i. the higher the permitted GHG pollution of the withdrawal gas, the greater the possible withdrawal quantity (see claim 2).

Due to the impossible physical separation of CBM and CNG, gas fed out is compared with the gas fed in via energy or natural gas equivalents or at the same energy content of the gases over standard quantities (Nm). If the quantities of energy fed out and fed in correspond to the outgassing quantities, they can be referred to as "pure CBM." If the amounts of energy expelled are greater than the amounts of energy fed in, then the gas expelled is by definition a CBM / CNG mixture GHG possible negativity of the CBM may still have a GHG load of 0 GC02 eq / kWh i _SC H gas with the removed CBM / CNG mixture.

From the network into which CBM has been fed, an energy-equivalent quantity plus an additional quantity of natural gas can be taken at any exit point of the natural gas network, which can be extracted by virtual / statistical clearing with exactly the same (negative) Physically, the extracted gas is not identical with the injected CBM, but other than the natural gas consumers connected to the designated exit point use it to a greater or lesser extent without knowing it Ultimately, it does not matter for the global climate, where the GHG saving takes place.When using the extracted mixed gas, the end consumers emit correspondingly lower amounts of long-term, fossil C0 _2. Stoichiometrically, the resulting C0 ₂ amount remains unchanged Only a certain proportion of the "short" C0 ₂ cycle is from the long-term fossil C0 ₂ cycle. If the amount of energy expelled corresponds exactly to the amount of CBM fed in, then it is possible to accurately attribute the GHG effects of the fed CBM to an outgassed gas quantity. If the exit quantity measured in Nm is greater than the CBM feed amount, then a dilution of the GHG effect takes place, and this dilution can be continued until the desired GHG value is reached. For example, if the GHG "load" of the injected CBM is -468 gC0 ₂ -

Equivalent / kWhc _BM and a TGH-free mixed gas is to be fed, can at a dedicated exit point in total per 1 kWh of fed CBM approx. 2.98 kWh of gas (1 kWhc of _BM with a GHG load of -468 gC0 ₂ - eq / kWhc _BM and 1.98 kWhcNG with a GHG load of +236 gC0 ₂ -eq / kWhcNG gives 2.98 kWh Ausspeisegas with a THG-load of 0 GC0 ₂ eq / kWh _a usspeisegas) - The common or average GHG load is then at 0 GC0 ₂ equivalents / kWliAuss eisegas- Ausspeisegas This can inter alia as GHG reduced or GHG free fuel can be used (see claim 5).

The dilution may also go so far as to achieve a GHG value between 0 and 235 gC0 ₂ -eq / kWh of feed gas or between 0 and 301 gC0 ₂ -eq / kWh feed gas. These

Ausspeisegase then apply in the first case as compared. Natural gas (CNG) GHG reduced and in the second case as compared to. Gasoline GHG reduced. CBM is considered to be Conventionally produced from maize produced bio methane GHG-reduced, if its GHG value (according to most recent studies approx. 140 - 234 gC0 ₂ -Equivalent / kWhBioMethan) is fallen below. If the GHG load of the exhaust gas at 0 gC0 is ₂ equivalents / kWh "cBM"_> then the discharged "CBM" can be designated as greenhouse gas-free fuel and used as such. If the GHG load of the exhausted gas is below 0 gC0 ₂ - Equivalent / kWh "cBM", then the discharged "CBM" can be designated as greenhouse gas-negative fuel and used as such. If the GHG load of the fed-out "CBM" is above 0 gC0 ₂ -equivalents / kWh "cB", but still below 236 gC0 ₂ -equivalent / kWh "cBM"> then the fed-out "CBM" can be compared to. Natural gas is a greenhouse gas-reduced energy source. The same applies to "CBM" / CNG blended feeds: if their GHG load is between 0 and 235 gCO2 equivalents / kWti of mixed gas, the mixed gas is GHG-reduced, the GHG load is exactly 0 gC0 _2- equivalent / kWh mixed gas, then it is THG-free mixed gas, if it is below it, then the mixed gas is GHG negative. It is advantageous to use the discharged "CBM" and the "CBM" / CNG mixtures as greenhouse gas-reduced or in greenhouse gas-free fuels, preferably in traffic (see claim 5). Since in Germany with <0.2% of the car fleet today hardly gas powered CNG are in operation and thus virtually every new, powered by CBM gas vehicle is a gasoline - or diesel vehicle replaced, the effective GHG reduction for Germany results as difference between the GHG load of gasoline and the respective GHG load of the "CBM" or the "CBM" / CNG mixed gas with a GHG load of the "CBM" / CNG mixed gas of eg 40 gC 02-Equivalent / kWh _M isch _g as is the GHG reduction compared to. Gasoline 262 gC0 ₂ -equivalent / kWh or approx. 87%, with a THG-loading of the "CBM" -. / CNG mixed gas of 0 GC0 ₂ equivalents / kWh _M i _S chgas the GHG reduction to 302 GC0 ₂ equivalents / kWhMischgas or approximately 100% amounts.

The method illustrated in FIG. 3 is an advantageous development of the embodiment variant of the method described in FIG. The GHG balance of the process is improved by using to a greater extent also low-GHG NawaRo as fermentation substrate in the process step "substrate selection." GHG arms NawaRo are, for example, landscaped property, growth of extensively cultivated land, grass and miscanthus. Maize and fertilizer-intensive substrates such as green cereal crop cut are not low greenhouse gas NawaRo, they are therefore used in this embodiment only in second choice as a fermentation substrate. The GHG effect is all the more positive, the higher the proportion of low-GHG NawaRo in the fresh mass. For the first time, the biogas is already GHG-reduced, because in particular low-GG substrates are used (those introduced in the variants of FIGS. 1 and 2) Process changes only affect the GHG value of the BioMethane, not the GHG value of the biogas produced in the manufacturing process).

It should be noted that the measure presented here for reducing the emission of GHGs can also be combined with the basic variant of the method described in FIG. 1 as well as all other embodiments.

4 shows a combination of processes with which the GHG balance is further improved by the exclusive use of organic waste (the organic portion of household refuse and commercial waste) as a fermentation substrate (see claim 3). Since organic waste is hardly contaminated with GHG emissions, an improvement in the GHG value of the biogas is achieved solely by switching from renewable resources to organic waste - even before the process steps "biogas scrubbing / CO ₂ separation" and "CO ₂ -Rekuperation ". Together with the CO ₂ precipitation already shown in FIG. 1 and the resulting GHG effects, the GHG balance of the process is further improved. This effect caused by substrate selection is stronger, the higher the proportion of organic waste in the fresh mass. In FIG. 4, the sole use of organic waste as a fermentation substrate is shown; nevertheless, the use of a substrate mixture consisting of NawaRo and organic waste is also possible.

The process step "substrate selection" is configured in FIG. 5 such that exclusively greenhouse-free straw and greenhouse gas-free agricultural residues (including farmyard manure) were selected as the fermentation substrates (cf claim 3) harvest "almost completely. Straw must be e.g. only pressed into bales and collected, with solid manure eliminates the pressing, he only has to be collected. With regard to the greenhouse gas effect, this selection is the conventional feedstocks (meaning the maize, cereal whole plant cut, cereal grains, grass silage, beets) are given a first advantage, that is to say, until including the process step "substrate cultivation", a zero or almost zero GHG load is used ,

In the process step "substrate storage" care is taken in accordance with the method disclosed here that the stored feed materials do not exhale methane or nitrous oxide (cf claim 1.) The various mastic are taken immediately after their removal from the barn and into a BGA-internal , enclosed and with a vacuum bleeding tion provided temporary storage. Also rotting processes are prevented if possible, because the oxidation processes taking place are connected with the production of C0 ₂ . Among other things, the straw is stored dry, so that no (aerobic) rotting processes can take place and thus no C0 ₂ enters the atmosphere. In the process step "substrate transport" are used in the transport of biomass from the place of the attack to biogas plant according to the invention innovative tractors and trucks that are operated with greenhouse gas free, preferably with greenhouse gas-negative bio methane or with a mixture of fossil diesel, greenhouse gas-free or greenhouse gas-negative bio-methane and fossil Natural gas or with a corresponding natural gas or energy equivalent (cf claim 1) .The greenhouse gas pollution of the process step "transport" is therefore very low, even if the bio methane and natural gas are mixed with fossil diesel, preferably the GHG pollution of the fuel used even back to zero. In addition, it has a positive effect that the means of transport are covered during transport of the biomass, except when transporting straw. In the process step "substrate acceptance and intermediate substrate storage", as with the substrate storage, care is taken to avoid emissions of methane or nitrous oxide, which is possible, for example, if the substrate assumption in the biogas plant is in a completely enclosed acceptance area The buffer is also completely enclosed, and both areas are connected to a negative pressure vent, which in turn vented into the combustion air flow of CHP.Recovery processes are as far as possible prevented, so that as far as possible no C0 _{2 is} released.

For the use of solid manure, in particular poultry manure, the process or its main product "BioMethan" even GHG credits are attributed, because by the utilization of ammonia- and ammonium-containing poultry manure otherwise occurring exhalations of nitrous oxide (N ₂ 0) are avoided In this respect, this substrate selection is even better than the substrate selection "organic waste" in terms of the GHG effect.

Of course, straw and straw-containing substrates can also be added to the starting materials already listed. The desired GHG effect is greatest when the proportion of straw or straw-containing starting materials is as high as possible (cf claim 3). FIG. 6 shows a positive development of the method described in FIG. When using straw or straw-containing substances, it is gas-yielding to subject these fermentation substrates to a pretreatment. This is done in the optional process step "pretreatment" (see claim 4) .A higher gas yield per tonne of input means that ultimately more fossil energy sources are being replaced and thus an increased amount of greenhouse gases is avoided.

Pretreatments include, in particular, the mechanical pretreatment of the milling, the chemical pretreatment of the soaking in acidic solutions, the thermochemical pretreatment with saturated steam, the thermomechanical pretreatment by means of steam explosion, the thermochemical pretreatment by means of thermal pressure hydrolysis and the chemical pretreatment by means of mixing with solid manure or manure and the addition of exo-enzymes in question (see claim 4). In any case, the pretreatment of the straw and the straw-containing feedstocks takes place in such a way that the energy expenditure used in this process step is smaller than the additional energy yield attributable to the pretreatment. Preferably, low-THG, particularly preferably THG-free, energy or energy carriers are used in this process step.

In the event that the advent of straw and / or straw-containing materials is insufficient or that the fermentation processes run better with them, also low-THG and high-THG-rich NawaRo can be included in the fermentation substrate mixture (see claim 3). The higher substrate efficiency resulting from a better fermentation of the substrate mixture then more than compensates for the negative effects on the THG balance of the process attributable to the use of THG-rich NawaRo. This variant is shown in FIG. If in the design of the overall procedure (use of the other optional

Procedural steps) should show that the resulting product "bio methane" is greenhouse gas negative, and the target is a GHG-free CBM, then the proportions of cultivated biomass with a lower GHG load than corn or possibly also greenhouse gas loaded corn at the fresh mass input until the greenhouse gas balance of the CBM just now does not change from a negative emission value (GHG load <0 gC0 ₂ -equivalent / kWh) to a positive emission value (GHG load> 0 gC0 ₂ -equivalent / kWh). If the other fermentation substrates are not available in sufficient quantities, it may be advantageous if the proportion of NawaRo is as high as possible, because they are always available for purchase.

FIG. 8 shows the possibility of using any substance from the range of straw, straw-containing feedstocks, organic waste, low-GHG NawaRo and THG-rich NawaRo as fermentation substrate in the process. It should be expressly pointed out that the process described in this embodiment can in principle be carried out with other fermentation substrates than the listed starting materials and without the process steps "compression" and / or "feed". In the process step "substrate transport" are used in the transport of biomass from the place of the attack to biogas plant according to the invention innovative tractors and trucks that are operated with greenhouse gas free, preferably with greenhouse gas-negative bio methane or with a mixture of fossil diesel, greenhouse gas-free or greenhouse gas-negative bio-methane and fossil Natural gas or equivalent natural gas equivalents (see claim 1) The various masticates are loaded immediately after their removal from the barn and brought into a BGA-internal, enclosed and provided with a vacuum venting intermediate storage The greenhouse gas pollution of the process step "substrate transport" falls This means that even when mixing the (GHG-negative) bio methane and the natural gas with fossil diesel very low, preferably the GHG load of the fuel used even goes back to zero. Another positive factor is that the

Means of transport are covered during transport of the biomass except when transporting straw.

In the process step "substrate acceptance / intermediate storage", as in the process step of substrate storage, care is taken to ensure that no methane or nitrous oxide evaporates, for example if the substrate assumption in the biogas plant is in a completely enclosed acceptance area The buffer is also completely enclosed, and both areas are connected to a negative pressure vent, which in turn vented into the combustion air flow of CHPs.Restation processes are as far as possible prevented, so that as far as possible no C0 _{2 is} released.

For the GHG balance of the product CBM, it is important, especially in the case of the supply of biogas from external sources, that the biogas to be treated as little as possible

Greenhouse gases is contaminated. Therefore it should also be subsumed here that in all procedural Steps in which electricity or heat are used, they come from renewable sources or have particularly low, preferably no GHG emissions (see claim 1).

It is also possible in this process variant to omit the pretreatment of the straw and / or the straw-containing feedstocks and / or to distribute the bio-methane not in the natural gas network, but in mobile tanks. These tanks can be liquefied gas tanks or pressure tanks. It is also possible to distribute BioMethane using a dedicated BioMethan line.

The goal of GHG reduction is also achieved if there is no optimization with regard to greenhouse gas effects at each individual process step or in each individual sub-process. The use of GHG-free or GHG-reduced energies in one or more process steps can also be dispensed with. The effect resulting from the sequestering of the regenerative C0 ₂ alone is sufficient with almost complete CO ₂ deposition, recuperation and sequestering to negate the THG exposure of the CBM (which results in a positive THG effect overall). , The design element of the C0 ₂ sequestration can - but not necessarily - be supplemented by other elements with the effect of a GHG reduction or avoidance or be replaced by other design elements. This is shown by the further exemplary embodiments, in which the GHG balance of the BioMethane is further improved in each case. In the embodiment variant of FIG. 9, in addition to or alternatively to the "compression" method step, the GHG-reduced BioMethane 1 originating from the process steps "biogas scrubbing / CO ₂ precipitation" and "CO ₂ recuperation" is already present in the process step "non-grating mixing" Feed into the natural gas network mixed with natural gas (cf claim 2). This off-grid mixing can take place at different pressure levels: a) without pressure, ie at the level of ambient air, b) at the pressure level of the natural gas extracted from a natural gas network, and c) at any pressure level between a) and b).

It is advantageous to proceed according to b) and to keep the CNG taken from the natural gas network at its pressure level, first to compress only the bio-methane and to make a net-intermixing of the two gases at this pressure level. This saves you the energy associated with relaxation for the recompression of natural gas.

Thus, the pre-compressed BioMethane is physically mixed with the CNG extracted from the natural gas network and not decompressed. After mixing outside the network, the precompressed mixed gas is compressed a little further so that it can be fed into the natural gas network against the pressure. The energies used in this process step should originate from regenerative sources, which are preferably low in greenhouse gas and particularly preferably free from greenhouse gas.

This process step of the net-external mixing of greenhouse-gas-reduced bio-methane and CNG can be incorporated as an independent process step in any other embodiment of the process, for example in a process in which the BioMethan is not generated by a C0 ₂ -Abscheidung from the biogas, but by a reforming of the C0 ₂ component contained in the biogas (see below). In this respect, it is also immaterial whether or not further method steps or modules are added to the embodiments listed above.

In the embodiment variant of FIG. 10, the GHG-reduced biogas from the anaerobic bacterial fermentation is supplemented or alternative to the process steps "biogas scrubbing / C0 ₂ separation" and "C0 ₂ -recuperation" in a process step "C0 ₂ - reforming". to produce THG-reduced, synthetic BioMethan 2 (SynMethan) or to THG-reduced synthetic BioMethanol SynMethanol) (see claim 1) In order to produce SynMethane, regenerative, preferably electrolytically generated, hydrogen is fed to the CO ₂ contained in the biogas According to the well-known Sabatier process, substances react under pressure to form methane (CH ₄ ) .This process can also be used to produce synthetic methanol (CH ₃ OH) under pressure.Owing to the regenerative feedstock, methane is converted into bio methane and methanol BioMethanol or SynMethanol The synthetic bio-methanol is preferably used as a GHG-reduced fuel component friend.

The GHG-reduced BioMethan 2 (SynMethan) is either mixed with or replaced by the BioMethane 1 originating from the "Biogas scrubbing / C0 ₂ separation" process step, ie the BioMethan 2 is mixed with either CNG instead of the BioMethan 1 in the latter case and fed into the natural gas grid or pure or mixed with propane and / or butane highly compressed to slightly above the pressure level of a natural gas network and then fed into this natural gas network. The use is the same as described in FIG.

For the reforming of C0 ₂ to methanol (CH ₃ OH), the process of steam reforming in other applications has proven itself. The use of this method is relatively risk-free in terms of functionality and equipment expense and therefore advantageous.

If large quantities of greenhouse gas-reduced or greenhouse-gas-free energy carriers, especially of electricity, are available at low cost (eg during periods of high wind), it may be advantageous not to include as much of the biogas as possible in the "biogas scrubbing / CO ₂ separation / C0 ₂ -Rekuperation ", but in the production line and process step" C0 ₂ -Reformierung "(see claim 7).

The amounts of electricity and heat required in process step "C0 ₂ reforming" are preferably covered by regenerative or at least low greenhouse gas energy sources (see claim 1) .Co ₂ reforming also has volume effects (scale effects), so that it is advantageous is when the volume flow of the supplied C0 _{2 is} as large as possible (see claim 7.) For the GHG balance of the energy produced by C0 ₂ reforming, it is particularly advantageous if the supplied biogas is as little as possible burdened with GHG emissions If biogas production and C0 ₂ reforming plants are located farther apart - as is the case, for example, with biogas parks, or if several smaller biogas plants supply a larger separation unit with biogas - transport of the biogas is required Advantage, because it is less expensive technically and economically, if this transport over a biogas line he follows (see claim 7). The same applies to the separation and reforming of regenerative C0 ₂ . Should the plants for the separation of regenerative C0 ₂ and for the reforming of the regenerative C0 _{2 be} further apart - as is the case, for example, in biogas parks or if several smaller gas scrubbers or deposition plants supply a larger reforming unit with regenerative C0 ₂ - then there is one Transport of C0 ₂ required. Advantageous because less technically and economically, it is when this transport via a special C0 ₂ -Leitung takes place. In order to be able to carry out a reforming of C0 ₂ in the process step "C0 ₂ Reformation" (C0 ₂ is contained in the biogas at about 40% to 47% or in almost pure form from the process steps "Biogaswäsche / C0 ₂ -Abscheidung" and supplied "C0 ₂ -Rekuperation"), hydrogen must be added in sufficient quantity. in order to obtain the good GHG balance of the input materials of the process step "C0 ₂ reforming" upright, this hydrogen should come from renewable sources and not with GHG Emissions are polluted. The use of fossil sources and / or energy sources is therefore prohibited. It is advantageous to obtain the required hydrogen by means of electrolysis, wherein the current used for this purpose should preferably come from renewable sources. In principle, any electricity suitable for electrolysis is reduced to <100 gC0 ₂ equivalents / kWhei greenhouse gas. Preferably, electricity is used from wind or hydroelectric power or from geothermal energy or from solar plants or electricity obtained by means of photovoltaics. In this case also comes electricity, which was generated according to the method disclosed here (see Figure 13 f.) And atomic and fusion current (see claim 1). Under certain circumstances, it may make sense to accept GHG emissions, for example if the electricity required for the electrolysis is particularly favorable.

When BioMethan 2 (SynMethan) or BioMethanol substitute fossil fuels, GHG prevention occurs. In the context of the substitution quantities, this means that the substituted fossil energy source (s) are not used and thus no further fossil C0 _{2 is released} into the environment. In this case, no C0 _{2 is} permanently removed from the C0 ₂ cycle, but substitution of fossil energy carriers prevents additional fossil C0 _{2 from being released} into the atmosphere.

In FIG. 11, based on the method described in FIG. 10, an advantageous embodiment variant is described in which sequencing of the recuperated C0 _{2 is not} (yet) possible or even meaningful with sufficient volumes. With regard to the GHG

Balance and / or production costs, it is particularly advantageous if the largest possible amount of the deposited and recuperated C0 _{2 is passed} into the C0 ₂ reforming, where from the regenerative C0 ₂ a regenerative energy source is produced, which substitutes fossil fuels (cf claim 1). In the embodiment of the figure 12 comes as a further form of use of the process steps "wash biogas / C0 ₂ capture" and "C0 ₂ -Rekuperation" secluded and recuperated regenerative C0 ₂ to the two options "C0 ₂ -Sequestierung" and "C0 ₂ "Reformulation" as a third option, the process step "Substitution of fossil C0 ₂ " (see claim 1.) results in a GH avoidance effect, if CO ₂ from fossil sources, such as dry ice, produced in the process step "Substitution Substitution of fossil C0 ₂ "is replaced by regenerative C0 ₂ from the process disclosed herein. The unneeded fossil C0 ₂ is no longer generated, which relieves the environment. This GHG effect is attributed to the bio methane. Preferably, larger amounts of regenerative C0 _{2 are used} in the industry when the other two options are not available. The simplest is the substitution of dry ice, which can be produced by Kxyo-V experienced without special effort already in this process step as a finished product.

With regard to the combination of the additional process step "Material substitution of fossil C0 ₂ " with the other process steps, embodiments without the C0 ₂ reforming and / or without the C0 ₂ sequestration and / or without the "compression" process step should also be protected.

FIG. 13 shows a method step which can be integrated into all variants of embodiment: partial or complete conversion of the greenhouse gas reduced biogas produced by anaerobic bacterial fermentation. By using greenhouse gas-reduced biogas, the electricity generated is also reduced by GHG. If the volumes of electricity produced from the biogas meet the needs of the process, the process becomes energy self-sufficient. As long as the C0 ₂ capture and C0 ₂ reforming options are unavailable, it is beneficial to exhale all biogas. Since BioMethan, which was produced according to the method disclosed here, is usually more valuable than effluent biogas - especially when used as a fuel - it may be advantageous to minimize the biogas content that goes into the process step "power generation" in that the Bio gasver flow is limited to its own use (see claim 5). It has been proven that the generation of electricity from biogas causes scale effects. The larger the generator sets (CHP) or fuel cells or ORC systems, the higher the electrical efficiency. It is therefore advantageous if the power plants have a certain minimum size, in particular if, for whatever reason, the amounts of biogas contained in the string "biogas scrubbing / C0 ₂ separation / C0 ₂ -reecuperation" and / or the strand "C0 ₂ Reformation "and / or the strand" Substitution Substantial Fossil C0 ₂ "go back and most of the biogas is used in the power generation It is also advantageous if only power plants with the highest electrical efficiencies are used If the biogas fed into the "electricity generation" line is at least greenhouse gas-reduced, the electricity generated in this line and the heat generated in this line also have good to very good THG values (see above). These good to very good GHG values are quasi added to the self-generated electricity and the self-generated heat when used in-house, thereby reducing the process steps in which this GHG-reduced or GHG-free stream and this GHG-reduced or GHG-free Heat are used and relieved of their GHG values.

14 includes the additional process step "liquefaction." As an alternative to a gaseous discharge, the bio-methane produced according to the process can also be delivered in a liquid state In liquid form, the energy density is much greater, which reduces the transport costs.To achieve the liquid state, the gases are cooled in this process step (see claim 1.) The energies used for this purpose should originate from renewable sources, preferably are low greenhouse gas and particularly preferably greenhouse gas free (cf claim 1.) The cooling can also be carried out according to the process of regenerative C0 ₂ produced dry ice, possibly via heat exchangers.

In the event that certain GHG values are to be achieved, CNG can be added to the greenhouse gas-reduced bio methane before or during liquefaction. Per kWh BioMethan can be mixed between 0,1 kWh and 20 kWh CNG (see above). The liquefied greenhouse gas-reduced bio-methane or the liquefied bio-methane / CNG mixture is preferably used as a THG-reduced or THG-free fuel. The process step "liquefaction" can be integrated including the provision of any CNG necessary in each embodiment of the method and thus all the above variants.

In this embodiment variant, the user of the process can decide as follows: a) which feedstocks are used in which fractions, b) whether or not they should be pretreated, c) with which proportion the GHG-reduced biogas goes into which recycle line, i ) with which share the recuperated C0 ₂ in which recovery strand is, e) whether the greenhouse gas reduced BioMethan generated is to be liquefied or not, f) if the gaseous greenhouse gas reduced BioMethan is mixed in the natural gas network or outside the network with natural gas and g) if the "CBM "is to be used as GHG-free or as GHG-reduced fuel, ie in what ratio it is mixed with CNG.

As already mentioned, the protection should not only cover the complete process, but also changes and modifications to the disclosed process, its variants and the disclosed biogas plant. In this respect, embodiments are also protected his, which lack individual process steps, e.g. the process variant shown in Figure 13 without the process step "nets external mixing" or without the process step "pretreatment" or without the process steps "compression" and "feed". FIG. 15 shows an alternative embodiment of the method described in FIG. 8, the fermentation residues occurring during anaerobic bacterial fermentation being used as a mineral fertilizer substitute (cf claim 1). The substitution of mineral fertilizer avoids additional GHG emissions associated with the production and application of the mineral fertilizer. This avoidance of GHG emissions is attributed to the main product of the process, the CBM. Both the GHG balance sheet of the process and the GHG balance sheet of CBM improve considerably.

In FIG. 16, the process step "nutrient extraction" and the process step "fertilizer production" are added to the process described in FIG. The vegetable nutrients contained in the fermentation residues are extracted. This is done by first mechanically dehydrating the fermentation residues, preferably with at least one

Screw press. While the solid phase goes back to the field as a mineral fertilizer substitute, the liquid phase is dehydrated a second time, preferably with at least one decanter. In order not to clog the membranes in the ultrafiltration, the liquid phase of the decanter is first subjected to an ultrafiltration before a pre-filtration and only then ultrafiltration. The permeate from the ultrafiltration is subjected either to a precipitation or to a reverse osmosis. In both cases organic nutrients are extracted, mainly nitrates, potassium and phosphates, possibly also magnesium and various salts.

The extracted nutrients can - but need not - be led into the process step "fertilizer production", where from them fertilizers and / or fertilizer components are produced (see claim 1.) These substitute mineral fertilizers, which resulting from the production and application of the mineral fertilizer GHG emissions are avoided The positive effect on GHG emissions is attributed to the main product of the process, BioMethan or CBM.

This GHG effect becomes even more positive if energies from regenerative sources are used in one or both process steps, which are preferably low in greenhouse gases and particularly preferably free of greenhouse gas (cf. claim 1).

Since in the case of anaerobic bacterial fermentation fermentation residues are produced in every case, the process steps "nutrient extraction" and "fertilizer production" can be integrated into each of the variants already described and into any other embodiment. The embodiment of Figure 17 corresponds to that of Figure 16, but supplemented by the process step "fuel production." The solid phase from the mechanical dehydrogenation 1 is no longer used untreated as a mineral fertilizer substitute, but dried, crushed and pelletized to digestate pellets Process step low greenhouse gas and particularly preferably greenhouse gas-free energies and E- nergieträger used, which reduces the C0 ₂ -Fußabdruck the process.

The fuel pellets replace fossil fuel (heating oil, coal or natural gas), thus avoiding large amounts of GHG emissions. This GHG prevention is ascribed to the process or the main product GHG-reduced bio methane or CBM, which further improves the GHG balance sheets. It is advantageous for each embodiment in terms of energy, to integrate the fuel production in the process - which is quite possible and should be protected hereby.

17 corresponds to the process described in FIG. 17, but supplemented by the process step "ashes recuperation." The ashes of the spent fermentation residual pellets are recuperated and fed to a fertilizer production as a valuable fertilizer component (see claim 1) soluble phosphorous, which is of great importance, since the high-grade phosphorus deposits still available worldwide will still be used up in the oil reservoirs.The advantages of energetic utilization are the great advantages of a virtually closed nutrient cycle.

The fuel pellets continue to replace fossil fuel (heating oil, coal or natural gas). It is advantageous for each embodiment variant to integrate the recuperation of the fermentation residue and its utilization in the respective process variant - e.g. This is quite possible and should be protected as well as the integration of the two process steps "fuel production" and "ash recovery" in any other variant.

The GHG balances of the process or of the CBM can still be improved by a whole series of process modifications. Thus, in the process step "conversion" according to the invention only low-GHG or greenhouse gas-free energies can be used, preferably self-generated greenhouse gas-free electricity and self-generated greenhouse gas-free heat (cf claim 1.) The process step "conversion" thus also contributes little or no greenhouse gas effects a poor greenhouse gas balance of the biogas produced, the other energy sources generated (bio-methanol, alternative fuel) and the energy generated (electricity, heat).

Preferably, in all process steps in which heat is needed, with greenhouse gas-free heat, preferably working with self-generated heat, so that these steps, the GHG balance of the product BioMethan not or hardly burden with greenhouse gases (see claim 1). From all the conversion processes that are available for the conversion of biomass into generally usable energy sources, the method was selected according to the invention, which has the highest conversion rates and the lowest equipment costs, ie the best combination of substrate efficiency and system efficiency and thus the best overall efficiency. This is the anaerobic bacterial fermentation (see claim 1). In order to avoid the initially high greenhouse gas pollution of cultivated biomass, in a first process step "substrate selection" fermentation substrates are selected which do not have this greenhouse gas pollution or only to a small extent: greenhouse-gas-free residues, including solid manure (see claim 3), greenhouse gas-poor organic waste ( see claim 3) and renewable raw materials (NawaRo), which are preferably low greenhouse gas in the process step "cultivation" (see claim 3).

It is advantageous for the anaerobic bacterial fermentation of straw, straw-containing solid manure and organic waste to use the process of solid-state fermentation in percolated garage furnaces (compare claims 1 and 6). However, this process is not absolutely necessary, the various wet processes can also be used.

Finally, if the overall process and all of its process steps are designed so that the BioMethan ultimately becomes greenhouse gas negative (eg by using the optional process steps "nutrient extraction" and / or "fuel production" or by an appropriate selection of the energies to be used in the various process steps) Energy carriers or by a corresponding division of the biogas in the step "Biogasaufteilung" or by the use of the process step "C0 ₂ sequestration"), and if the target is a GHG-free CBM, then the proportion of greenhouse gas-intensive NawaRo can be increased to the fresh mass So far, until the greenhouse gas load of the product "CBM" just does not tilt from the negative to the positive, that is, then corn and green rye as fermentation substrate in question, because corn and green rye have the benefits of high yields per hectare and high availability.

In particular, if the conversion of straw and straw-containing feedstocks uses the (sub-) experience of solidification by means of percolated garages (see below), the "internal transport" step can be a significant source of greenhouse gas pollution GHG-negative bio-methane or a corresponding natural gas equivalent is used as fuel for the wheeled or telescopic loader, so that the greenhouse gas emissions of the likewise used natural gas and diesel fuels are compensated (see claim 1). Stationary conveyors are electrically operated. For this purpose, use is made of THG-reduced, preferably THG-free, current (cf claim 1).

In the process step "Biogasaufteilung" as shown above, a division of the biogas produced in the biogas plant and possibly supplied from external sources biogas on the 3 utilization strands and process steps "power generation", "Biogaswäsche / C0 ₂ - deposition / C0 ₂ -Rekuperation" and " C0 ₂ reforming "(not explicitly shown in FIGS. 1 to 18). Among other things, it is decided with the distribution, which equipment expenditure and which further energy use is to be carried out under which framework conditions. With changing market prices for used energy and generated energy sources, it may make more sense technically and / or economically to pass the greenhouse gas-reduced biogas into the utilization line "Biogas laundry / C0 ₂ - Separation / C0 ₂ recuperation", another time it is makes more sense to cause it to a large proportion as possible in the recovery train "C0 ₂ reforming" and in a third case, the technical parameters and / or the contribution to be highest when the highest possible proportion is exudes on the biogas (see FIG. to claim 7 ). Quite possible is also the case that a very specific percentage distribution of biogas on the three utilization strands in the technical and / or economic sense is optimal. By integrating the process step "biogas distribution" into the overall process, a flexible control or regulation of the respective biogas components is possible, so that the generation of the various energy sources can be adapted to the changing conditions.Technically, the biogas flow is controlled by simple valves in the corresponding gas lines.

If the plants for the production of biogas and for the separation of C0 ₂ from biogas are further apart, as is the case for biogas parks, for example, or if several smaller biogas plants supply a larger separation unit with biogas, transport of the biogas is required. It is advantageous because it is less complicated technically and economically if this transport takes place via a biogas line. It is also possible to transport by tank.

Possibly. The gases "BioMethan" and "Regeneratives C0 ₂ " are required in a gaseous state. This is the case with BioMethan, for example, when there is no natural gas grid. Since there is (still) no public C0 ₂ network, it is necessary to then fill and deliver these two gases in pressure tanks. This happens with power-intensive compressors in the Again, greenhouse-gas-reduced electricity is used, preferably low-greenhouse gas electricity, particularly preferably greenhouse-gas-free electricity and, in particular, greenhouse gas-negative electricity.

In the "Distribution" step, the distribution of the gases "BioMethan" and "Regeneratives C0 ₂ " takes place either via gas pipelines or, as in the case of BioMethanol, with mobile tanks If trucks are to be used for the distribution of the gases, they should be treated with greenhouse gas-free or greenhouse gas-negative BioMethane or with a mixture of fossil diesel, greenhouse-gas-free or greenhouse-gas-negative bio methane and fossil natural gas or with a corresponding natural gas equivalent, the greenhouse gas load of the process step "distribution" is then very low, even if bio-methane and natural gas are mixed with fossil diesel to form a mixed fuel If necessary, the greenhouse gas emissions of the fuel mixture are even reduced to almost zero due to the greenhouse gas neutrality of the fuel mixture.

As already mentioned, volume effects (scale effects or economies of scale) occur in several process steps. It is therefore in each embodiment of advantage to build the largest possible biogas plants and operate (see claim 7).

If it is realized with all steps, then with the method disclosed here GHG-reduced, preferably low-GHG, particularly preferably GHG-free and especially GHG-negative BioMethan can be produced whose GHG reduction effect compared. Natural gas (CNG) is at least 100 gC0 ₂ -equivalent / kWh _B i ₀ methane or 180 gC0 ₂ -equivalent / kWh-methane or 236 gC0 ₂ -equivalent / kWh-3-methane and 336 gC0 ₂ -equivalent / kWh-3-methane, respectively. The preferably GHG-negative BioMethan can then be mixed with fossil and thus greenhouse gas-loaded natural gas (CNG, THG load well-to-wheel at 236 gC0 ₂ -equivalent / kWhcNG) that the resulting mixed gas any GHG Load between -468 gC0 ₂ -equivalent / kWhMisch as and +236 gC0 ₂ -equivalent / kWliMischgas exhibits. Thus, with the new method both a whole range of mixed gases with different GHG reduction can be generated as well as a completely GHG-free mixed gas and even various GHG-negative mixed gases. These mixed gases can be used as fuel in traffic or in power generation. When marketing the fuel, it is necessary and important to be able to present catchy and manageable GHG effects. A GHG reduction of, for example, 85% is more intuitive and clearer to end users than a GHG reduction of 82%. GHG reduction effects are therefore also rounded up or down to 5 percentage points in the legislation. Accordingly, it is of particular economic advantage to be able to offer mixed gases whose GHG reduction effect falls within the 5% classification.

The block diagram of FIG. 19 shows the simplest embodiment variant of the system according to the invention. It represents the common modules of a biogas plant, but with an additional conditioning module for separating regenerative C0 ₂ from the produced biogas, an additional conditioning module for the recuperation of the deposited regenerative C0 ₂ (in the figures 19 ff., The conditioning module "C0 ₂ "Recuperation" is not shown separately, but together with the plant module "Biogas Laundry / C0 ₂ - Separation"), an additional, remote geological repository for sequestering the recovered and recuperated renewable C0 ₂ and using the greenhouse gas reduced BioMethans produced in the plant as GHG-reduced or THG-free gas fuel (see claim 8).

By sequestering the regenerative C0 ₂ , as explained above, removal of regenerative C0 ₂ from the "short-term" C0 ₂ cycle takes place (the "long-term" C0 ₂ cycle involves the long-term fossil storage of carbon in geological formations). The removal of regenerative C0 ₂ from the short-term C0 ₂ cycle is attributed to the remaining energy source, ie the bio-methane. According to new findings by the inventor, this effect is so great that the GHG burden of BioMethane calculated according to the EU directive "Renewable Energy Directive (RED) 2009/28 / EC" of 23 April 2009 is negative depend on how much of the contained in the biogas C0 ₂ is deposited and how much of the separated C0 ₂ is recuperated. the higher both parts are, the higher is the C0 ₂ reduction and the better the GHG balance of the resulting bio-methane ( By the described combination of a biogas plant with a gas scrubbing plant, with devices for separation and recuperation of the regenerative C0 ₂ , with appropriate means of transport for transporting the recuperated regenerative C0 ₂ to a geological repository and finally with the sequestration of the regenerative C0 _second In these geological repositories, GHG-contaminated biogas will at least produce GHG-reduced bio methane (g EU-RED calculated LCA value will be <137 g C0 ₂ -equivalent / kWh _B joMethaji), Preferably GHG free BioMethan (according to EU-RED LCA calculated value at 0 g C0 ₂ - equivalent / kWhßioMethan) (and especially preferably GHG negative BioMethan according to EU-RED calculated LCA-value <0 g C0 ₂ equivalents / kWh _B i ₀ methane) -

As explained above, the GHG negativity of BioMethane makes it possible to mix the GHG negative bio methane with natural gas, without the GHG balance of the mixed gas exceeding the zero line, ie 0 gC0 ₂ -equivalent / kWl mixing gas. Therefore, especially the system arrangements according to the invention for mixing greenhouse gas-reduced bio-methane with (fossil) natural gas are to be protected, in particular plant arrangements for mixing greenhouse-gas-negative bio-methane with (fossil) natural gas (see claim 9). The corresponding embodiment variants are described in FIGS. 29 et seq. It is expressly understood, however, that the additional plant modules described in these figures may be added to any embodiment of the plant.

Subvariants of the embodiment of the system described in Figure 19 may consist in that the BioMethan is not reduced greenhouse gas, but even greenhouse gas or greenhouse gas negative, or that the bio methane is not used as fuel, but quite generally as a greenhouse gas reduced or greenhouse gas free or greenhouse gas negative energy source or in that the bio-methane is used as fuel in traffic (see claim 10).

In this simplest embodiment variant of the plant, no changes to a conventional biogas plant are provided in the selection of starting materials, it is still relatively rich in greenhouse gas NawaRo used. Also, a specially designed storage for environmentally friendly storage of the starting materials is not (yet) used in this embodiment, ie it is (initially) not paid attention to whether the stored feedstocks exude methane or ammonia or nitrous oxide. Also, rotting processes are (initially) allowed. For the transport of the input materials from the place of the seizure to the biogas plant, (initially) conventional means of transport (tractors and trucks) are used. Also in the plant area provided for the substrate assumption and the substrate interim storage, as in the case of substrate storage, care is still not taken to ensure that any emissions of methane or ammonia or nitrous oxide occur. The conversion of biomass into biogas is carried out as previously practiced by the industry in conventional, single-stage fermenters. Since initially the starting materials are unchanged remain, has the resulting biogas (yet) no GHG reduction (see Figure 19).

The (still) conventionally produced, biogas loaded with GHG and possibly supplied biogas from external sources are processed to bio methane in the plant modules _u Biogas scrubbing / C0 ₂ separation "and" C0 ₂ recuperation ": the biogas is treated in a gas treatment plant "Washed", ie the CO ₂ contained in the biogas with approx .. 39 - 47% and other gases (sulfur, ammonia, nitrogen, oxygen, which together contain about 5% in biogas) are separated in conventional plants (inter alia, with pressure swing technology) or with systems for carrying out the pressure-free amine scrubbing, but preferably with refrigeration technology (cryo-technology, see claim 11)., However, the deposited, regenerative C0 ₂ is not released into the atmosphere as usual, but according to the invention in a plant module "C0 ₂ -requirement" collected and stored in pressure tanks or in liquid tanks or in heat-insulated containers or rooms or in a Kühlanl age or fed into a gas line (see. Claim 8). The utilization options of the recuperated regenerative C0 ₂ include the geological disposal (sequestration, see plant variant of FIG. 19), its reforming (see embodiment of FIG. 32) and the substitution of fossil C0 ₂ (see embodiment of FIG.

It is advantageous if plants are used for C0 ₂ capture where methane slip and GHG emissions are very low (methane is 23 times more polluting than carbon dioxide). This is the case with systems for pressureless amine scrubbing (cf claim 1). If the transport or use of the C0 ₂ or the resulting bio-methane is to take place in liquid form, it is advantageous to use systems that work with cold and can bring the C0 ₂ in liquid form with relatively little additional energy expenditure for the Cooling.

It has been shown that biogas scrubbing or C0 ₂ separation results in scale effects. With a doubling of the capacity of the systems used, the expenditure on equipment increases only minimally. As a result, the unit costs or the costs per m ^{3 of} biogas fall sharply. It is therefore advantageous if the volume flows conducted in the plant modules "plants for biogas scrubbing / C0 ₂ separation" and "plants for recuperation of regenerative C0 ₂ " have certain minimum sizes (cf claim 1 1). While the separation and recuperation of regenerative C0 _{2 is carried out} in the plant modules "biogas scrubbing / C0 ₂ capture" and "CC recuperation", the final disposal of the (regenerative) C0 _{2 takes place} in a remote geological repository. Since the sequestering of the recuperated regenerative C0 ₂ produces better greenhouse gas effects than reforming the recuperated C0 ₂ to methane (CH ₄ ) or methanol (CH3OH) and also better greenhouse gas effects than substituting fossil C0 ₂ by the trapped renewable C0 ₂ , it is advantageous if the largest possible proportion of the biogas in the plant strand "biogas scrubbing / C0 ₂ separation / C0 ₂ -Rekuperation" is passed (see claim 1 1), of which the largest possible part is deposited and collected ( see claim 11) and of which the greatest possible part is sequestered, since it could also be routed into the reforming (see embodiment of FIG. 32) or into the flow (see embodiment of FIG. 31).

Since the C0 ₂ can be stored geologically only at selected locations, it usually has to be transported from the deposition and recuperation device to the sequestering location. This is done cooled in liquid tanks or gaseous in pressure tanks or in solid form as dry ice or gaseous via a C0 _{2 line} . Except for transport by means of dedicated gas line, trucks and / or ships which use GHG-free fuel are preferably used as means of transport.

FIG. 20 shows as a block diagram that the GHG load or the GHG balance of the BioMethane produced in the plant can be further improved solely by selecting the starting materials according to the invention. If the conventional, GHG-rich fermentation substrates corn, cereal crop, beets and cereal grains are not used, but GHG poor substrates such. Landscaped land, the cultivation of extensively cultivated land, grass and miscanthus, reduces the GHG burden on the biogas produced. Conventional biogas thus becomes GHG-reduced biogas. The GHG reduction is greater, the higher the proportion of low-GHG renewable raw material in the total fresh mass input.

The selection of the starting materials comprises in the embodiment of Figure 21 exclusively greenhouse gas-free straw and greenhouse gas-free agricultural residues (including straw-containing farmyard manure). These feedstocks eliminate the GHG-intensive substrate cultivation and the likewise GHG-intensive substrate harvest. For example, straw only needs to be pressed into bales and collected, and the straw-laden solid manure eliminates the need to squeeze it just has to be collected. Regarding the greenhouse gas pollution of the biogas is compared with this selection. All NawaRo (greenhouse gas-rich and greenhouse gas-poor NawaRo) achieved a first lead, that is, up to and including the substrate harvest is operated with a zero or zero GHG load. As mentioned above, there are even GHG credits for the use of ammonia-containing manure. These are particularly high for poultry manure, because poultry manure contains relatively much ammonia and ammonium, from which the particularly environmentally harmful nitrous oxide forms (see above). The various mats are picked up immediately after their removal from the barn and brought to the biogas plant. If the proportion of poultry manure in the input materials is sufficiently high, the biogas produced in the fermenters can be used together with the reductions of the

GHG emission during substrate storage and substrate transport may even be negatively affected by GHG.

During substrate storage care is taken to ensure that the stored feedstock does not exude methane, ammonia, C0 ₂ or nitrous oxide. Also, rotting processes are possibly suppressed because the oxidation processes taking place are connected with the production of C0 ₂ . For example, the straw is stored dry, so that no (aerobic) rotting processes can take place and thus no C0 ₂ enters the atmosphere.

In the substrate transport of biomass from the place of the attack to biogas plant according to the invention innovative tractors and trucks are used, which are operated with greenhouse gas free, preferably with greenhouse gas negative BioMethan or with a mixture of fossil diesel, greenhouse gas or greenhouse gas negative BioMethan and fossil natural gas or with a corresponding natural gas equivalent (see claim 1). The greenhouse gas load on the transport is therefore very low, even if bioMethane and natural gas are mixed with fossil diesel. Preferably, the GHG load of the fuel used for the biomass transport even goes back to zero. In addition, it has a positive effect that the means of transport are covered during transport of the biomass, except when transporting straw.

Of course, straw and straw-containing substrates can also be added to the starting materials already listed. The desired GHG effect is greatest when the proportion of straw or straw-containing starting materials is as high as possible (see claim 13). The block diagram of FIG. 22 depicts an advantageous development of the system described in FIG. The biogas plant will be given a facility called "substrate acceptance / storage", which will be equipped with facilities that capture and neutralize emissions of methane or nitrous oxide, for example if the substrate assumption in the biogas plant is completely enclosed Acceptance area takes place, the buffer is also completely housed, and both areas are connected to a vacuum venting, which in turn vented into the combustion air flow of CHP .. Also rotting processes are prevented by appropriate ventilation or dry storage as possible, so that if possible no C0 _{2 is} released. Figure 23 shows a positive development of the plant described in Figure 22. When using straw or straw-containing substances, it is gas-yielding to subject these fermentation substrates to a pretreatment, which is done in optional plants for the pretreatment or digestion of straw Gas yield per tonne of input means that ultimately more fossil fuels will be replaced and thus an increased amount of greenhouse gases will be avoided.

As plants for the pretreatment of straw and / or straw-containing feedstocks are in particular mills (hammer mills, ball mills) into consideration, for soaking the straw or the straw-containing feedstocks in acidic solutions tank and container for the pre-treatment of the straw with a shredding of the straw Saturated steam Pre-treatment plants using steam explosion and pretreatment plants using thermal pressure hydrolysis and pretreatment of the straw by mixing with solid manure or areas with liquid manure or silo facilities and spraying or distribution facilities for the addition of exo-enzymes. The plants for the pretreatment of the straw and the straw-containing feedstocks are selected and configured such that the final energy input used in these plants is less than the additional final energy yield from the feedstocks due to the use of these additional plants. Furthermore, preference is given to using GHG-reduced energy sources and energies, particularly preferably GHG-free energy carriers and energies, and in particular GHG-negative energy carriers and energies (cf claim 8). In an advantageous further development variant for the system configuration described in FIG. 23, FIG. 24 shows a system with which the GHG balance can be determined by the use of organic waste (the organic portion of household waste and commercial waste) as a fermentation substrate is kept low (see claim 13). The use of organic waste in the biogas plant is advantageous if in the catchment area of the biogas plant not enough straw and straw-containing feed materials are to be found. Since organic waste is hardly contaminated with GHG emissions, an improvement in the GHG value of the biogas is achieved solely by switching from NawaRo to organic waste. Together with the C0 ₂ already shown in FIGS. 19 to 23 -

Separation, recuperation and sequestration, and with the resulting GHG effects, the GHG balance of the plant remains low even if straw and straw-based feedstocks can not be obtained in sufficient quantities. The higher the proportion of organic waste in the fresh mass is, the stronger the GHG effect resulting from this substrate selection is (see claim 13).

FIG. 25 shows the possibility of using any substance from the range of straw, straw-containing feedstocks, organic waste, low-GHG renewable raw materials and THG-rich NawaRo as a fermentation substrate in the plant. It should be expressly pointed out that the plant described in this embodiment can in principle also be operated with organic fermentation substrates other than the listed starting materials and without the plant modules "acceptance area and intermediate storage" and / or "pretreatment plants".

When transporting the biomass from the place of the seizure to the biogas plant, according to the invention innovative tractors and trucks are used that are operated with greenhouse-gas-free, preferably greenhouse-gas-negative bio methane or with a mixture of fossil diesel, greenhouse gas-free or greenhouse gas-negative bio methane and fossil natural gas or with a corresponding natural gas equivalent (cf claim 1). The various mats are loaded immediately after their removal from the barn and brought into a BGA-internal, enclosed and provided with a vacuum vent interim storage (s.u.). The greenhouse gas load caused by the means of transport is therefore very low, even if biomethane and natural gas are mixed with fossil diesel, and the GHG burden of the fuel used is preferably even zero. Another positive factor is that the means of transport are covered when transporting the biomass except when transporting straw.

For the GHG balance of the product "Ggü. It is important, especially in the case of the supply of biogas from external sources, that the biogas to be treated is minimally contaminated with greenhouse gases, because then the resulting from the C0 ₂ capture, -Rekuperation and -Sequestierung C0 ₂ reduction gets even better to bear.

In this and the following embodiment, it should also be subsumed that in all plant modules, in which electricity or heat are used, these come from renewable sources or have particularly low GHG emissions (see claim 1).

In the embodiment of the figure 26 comes as an alternative use of the system modules "biogas scrubbing / C0 ₂ capture" and "C0 ₂ -Rekuperation" secluded and recuperated C0 ₂ to the option "C0 ₂ -Sequestierung" select "Stoffliches substitution fossil C0 ₂ "(see claim 1). If material CO ₂ from fossil sources, eg dry ice produced from natural gas, is replaced by CO ₂ from the plant configuration described, a THG-avoidance effect results. The unneeded fossil C0 ₂ is no longer generated, which relieves the environment. This effect is attributed to the bio methane.

Preferably, larger amounts of regenerative C0 _{2 are used} in the industry when the alternative of C0 ₂ sequestering is not available. The simplest method is the substitution of dry ice with dry ice, which can be produced by Cryo technique without any further additional effort after the C0 ₂ -reecuperation.

With regard to the combination of the additional use option "Substance substitution of fossil C0 ₂ " with the respectively provided plant modules, variants without C0 ₂ sequestration and / or without the plant modules "pretreatment plants" and / or "acceptance area and intermediate storage" should also be protected.

FIG. 27 shows an advantageous embodiment of the system configuration described in FIG. 26, wherein the fermentation residues accumulating in the at least one fermenter are used as a mineral fertilizer substitute. The substitution of mineral fertilizer avoids additional GHG emissions associated with the production and application of the mineral fertilizer. This avoidance of GHG emissions is attributed to the main product of the plant, BioMethan, whose GHG balance sheet is significantly improved.

FIG. 28 shows an advantageous development of the system configuration listed in FIG. The fermentation residues from the at least one fermenter are fed into at least one additional secondary fermenter, whereby additional greenhouse gas reduced biogas is produced. Additional biogas from the same input amount means an increase in substrate efficiency. To produce the same amount of GHG-reduced gas fuel, fewer feedstocks are required at a higher substrate efficiency. This is for the operator of the facilities of considerable advantage. The system module "secondary fermenter" can also be integrated into all other system configurations, that is also into the system configurations described in Figures 19 to 26. These combinations should also be protected.

The system configuration shown in FIG. 29 is an advantageous further development of the embodiment variant of the system described in FIG. The plant will be improved by distributing the GHG-reduced BioMethane after it has been fed in via a natural gas grid.

The resulting from the gas scrubbing GHG reduced bio methane is compressed by means of at least one compressor module to a slightly higher pressure level, as in the natural gas network section prevails, in which it is to be fed. Compressors are usually power-intensive. However, the relative, related to a certain amount of gas power consumption decreases with increasing size of the compressor module. It is therefore not least of advantage for the GHG balance if the feed-in quantity is as large as possible (cf claim 1 1). As a current as possible GHG-reduced, preferably GHG-free stream is used in this system module (see claim 1). Compression turns the pressureless or moderately pressurized BioMethan into so-called "Compressed BioMethane" (also referred to below as CBM).

The CBM will be fed into the designated section of a natural gas or bio-methane network. In the physical or virtual-statistical transport of the fed and compared. Conventional BioMethane greenhouse gas reduced CBM to the consumer, the fed BioMethan mixes with the natural gas in the network, it can not physically be separated from the natural gas. This mixing is intentional, because it is not intended to market pure CBM, but just a mixture of CBM and natural gas (CNG) or a corresponding natural gas equivalent.

The additional compressor module can be integrated in any of the above embodiments of the system. This optional integration should also be protected. The system configuration shown in the block diagram in FIG. 30 is an advantageous further development of the embodiment variant of the system described in FIG. Due to the impossible physical separation of CBM and CNG, gas fed in is compared with the gas fed in via energy equivalents or with the same energy content of the gases over standard quantities (Nm ³ ). When the quantities of energy fed out and fed in are equal, the outgassing quantities can be termed "pure CBM." If the amounts of energy expelled are greater than the amounts of energy supplied, then the outgassed gas is a "CBM" / CNG mixture.

From the natural gas or bio methane network into which the CBM has been fed, an energy-equivalent quantity of natural gas can be produced at any exit point of the network.

BioMethane ("CBM" gas), which is "loaded" by virtual statistical offsetting with exactly the same (negative) GHG values as the injected CBM. Although the extracted gas is not physically identical to the CBM fed in, other than the natural gas consumer connected to the dedicated exit point, it uses the injected gas to a greater or lesser extent without knowing it

CBM. When using the extracted mixed gas they emit correspondingly lower amounts of long-term, fossil C0 ₂ . Stoeoperometrically, the resulting C0 ₂ quantity remains unchanged, but only a certain proportion comes from the "short-term" C0 ₂ cycle and not from the long-term, fossil C0 ₂ cycle, if the gas fed out fed in exactly the same amount of energy If the amount of feed in Nm ³ measured is greater than the CBM feed, then a dilution of the GHG effect will occur instead of. This dilution can be continued until the desired THG value is reached. For example, if the GHG "load" of the injected CBM is -468 gC0 ₂ -

Equivalent / kWhc _BM and a TGH-free mixed gas is to be fed, can be fed at a dedicated exit point a total of 2.98 kWh (1 kWhc _BM with a GHG load of -468 gC0 ₂ -eq / kWh _CB M and 1, 98 kWhc _NG with a GHG load of +236 gC0 ₂ -eq / kWhcNG) - The common or average GHG load is then 0 gC0 ₂ -equivalent / kWh _AuS feedgas- This exit gas can be used as GHG or GHG -free fuel can be used. The dilution can also go so far that a GHG value 0-235 GC0 ₂ eq / is achieved kWliAus feed gas or 0-301 GC0 ₂ eq / kWh _A u _S feed gas. These exit gases then apply in the first case as compared to. Natural gas (CNG) GHG reduced and in the second case as compared to. Gasoline GHG reduced. BioMethan is considered to be Conventional bio-methane GHG-reduced if its GHG value (bio methane produced from corn according to latest studies approx. 140 - 234 gC0 ₂ -equivalent / kWh-methane) is undercut.

If the GHG load of the exhaust gas at 0 gC0 is ₂ equivalents / kWhcBM or below, then the discharged CBM can be designated and used as a non-GHG fuel and if it is above 0 gC0 for the discharged CBM ₂ -equivalent / kWhcBM, but still below 236 gC0 ₂ -equivalent / kWhcBM, then the fed-out "CBM" can be referred to as greenhouse gas reduced energy carrier or fuel compared to natural gas The same applies to fed-out "CBM" / CNG mixtures: if their GHG pollution is between 1 and 235 gC0 ₂ equivalents / kWl mixing gas, the mixed gas is Natural gas GHG reduced; if the GHG load is 0 gC0 ₂ equivalents / kWl mixed gas, then it is GHG-free mixed gas, if it is lower, then the mixed gas is GHG negative.

It is advantageous to use the fed-out "CBM" and the "CBM" / CNG mixtures as greenhouse gas-reduced or greenhouse gas-free fuels, preferably in commerce (see claims 10 and 16). Since in Germany with approx. While 0.2% of car ownership today is hardly ever powered by CNG-powered gas vehicles, and thus every new CBM-powered gas vehicle replaces a gasoline or diesel vehicle, the effective GHG reduction is the difference between the GHG emissions of Gasoline and the respective THG load of the "CBM" or the "CBM" / CNG mixed gas. At a GHG load of the "CBM" / CNG mixed gas of, for example, 40 gC0 ₂ equivalents / kWh _M i _SC hgas, the GHG reduction compared to gasoline is 262 gC0 ₂ equivalents / kWh or approximately 87%, at A GHG load of the "CBM" / CNG mixed gas of 0 gC0 ₂ equivalents / kWh _M ischgas 302 gC0 ₂ - equivalents / kWh mixed gas or approx. 100%.

FIG. 31 shows a system configuration that can be integrated into all variants of the embodiment: the partial or complete generation of power of the greenhouse gas-reduced biogas produced in the biogas plant. By using greenhouse gas reduced biogas, the electricity generated and the heat generated are also reduced by GHG. As far as the electricity is concerned, the system becomes energy self-sufficient. As long as the options of C0 ₂ capture and the C0 ₂ -Reformierung are not available, it is advantageous to flow the entire biogas (see claim 11).

Since BioMethan, which was produced in one of the embodiments described here, is usually more valuable than effluent biogas, especially as a fuel, it may be advantageous to minimize the proportion of biogas that goes into the power plants. This happens u.a. in that the biogas power generation is limited to its own use.

It has been proven that the generation of electricity from biogas causes scale effects. The larger the generator sets (CHP) or fuel cells or ORC systems, the higher the electrical efficiency. It is therefore advantageous if the power plants have a certain minimum size, in particular if, for whatever reason, the amounts of biogas contained in the plant string "biogas scrubbing / C0 ₂ separation / C0 ₂ -requirement" and / or the plant strand "C0 ₂ - Reforming "(see below) and / or the" Substitution of Substances fossil C0 ₂ "line must be reduced and most of the biogas goes into the power plants It is also advantageous to use only power plants with the highest electrical efficiencies Since the biogas fed into the "power generation" system is at least greenhouse gas reduced, the electricity generated in this line also has good to very good THG values (see above). These good to very good GHG values are as it were given to the self-generated electricity and the self-generated heat when used internally by the system, whereby the system modules in which this GHG-reduced or GHG-free electricity and the GHG-reduced or GHG-free Heat are used and relieved of their GHG values.

In the embodiment variant of FIG. 32, which represents an advantageous development of the plant described in FIG. 31, the GHG-reduced biogas from the at least one fermenter and the at least one post-fermenter is supplemented or optionally added to the plant modules "biogas scrubbing / CO ₂ precipitation". and "C0 ₂ -reecuperation" as well

"CHP / ORC / fuel cell" in a plant module "C0 ₂ -Reformierung" out and processed there to GHG-reduced B10-CH ₄ (SynMethan) or to GHG-reduced bio-methanol (syn-methanol). For this purpose, hydrogen is added to the CO ₂ contained in the biogas in the reforming plant (see claim 1). These two substances react with the addition of pressure according to the known Sabatier process to methane (CH ₄ ) or according to the known steam reforming to methanol (CH ₃ OH). Due to the at least GHG-reduced Starting materials and the at least GHG-reduced energy carriers or energies used in the various plant modules are also at least THG-reduced in the SynMethan and the SynMethanol. The SynMethanol is preferably used as a GHG-reduced fuel component. The at least GHG-reduced SynMethan is either mixed with or replaced by the BioMethane originating from the "biogas scrubbing / C0 ₂ capture" and "C0 ₂ recuperation" plant modules, ie in the latter case, the SynMethane changes to bio methane instead The pressure level of a natural gas or BioMethannetzes highly compressed and fed into the natural gas grid. The use is the same as described in FIG.

For the reforming of C0 ₂ to methanol (CH ₃ OH), steam reforming plants have proved their worth. The use of this system technology is relatively risk-free in terms of functionality and equipment expense and therefore advantageous.

If large quantities of greenhouse gas-reduced or greenhouse-gas-free energy carriers are available at low cost, in particular for electricity, it may be advantageous not to include as much of the biogas as possible in the "biogas washing / C0 ₂ capture / C0 ₂ recuperation" line. but in the production line "C0 ₂ -Reformierung" (see claim 11).

The quantities of electricity and heat required in the "C0 ₂ Reformation" system module are preferably covered by regenerative or at least low-GHG energy sources (see claim 1) .Co ₂ reforming also has volume effects (scale effects), which makes it an advantage is, if the volume flow of the supplied gases is as large as possible (see claim 1 1).) For the GHG balance of the energy generated by C0 ₂ reforming, it is advantageous if the supplied biogas minimized burden with GHG emissions Therefore, the implementation of each of the listed measures to reduce GHG emissions is advantageous or mandatory.

If the plants for the production of biogas and C0 ₂ -Reformierung of biogas are further apart - as is the case for example in biogas parks or if several smaller biogas plants supply a larger biogas upgrading plant with biogas - then a transport of biogas from the biogas plant to Biogas upgrading plant required borrowed. Of advantage, because technically and economically less expensive, it is when this transport via a biogas line takes place (see claim 12). The same applies to the separation and reforming of regenerative C0 ₂ . Should the plants for the separation of regenerative C0 ₂ and for the reforming of the regenerative C0 _{2 be} further apart from each other - as is the case, for example, with biogas parks or if several smaller gas scrubbers are used. Separators to supply a larger reforming unit with regenerative C0 ₂ - then a corresponding transport of C0 _{2 is} required. Of advantage because less technically and economically, it is when this transport via a special C0 _{2 line} takes place (see claim 12). In order to be able to carry out a reforming of C0 ₂ in CH ₄ in the "C0 ₂ Reformation" plant module (C0 ₂ is contained in the biogas at approx. 40% to 47% or is extracted in almost pure form from the plant module "Biogaswashing / C0 ₂ - Depositing / C0 ₂ -Rekuperation "supplied), sufficient hydrogen must be added. In order to maintain the good GHG balance of the input materials of the "C0 ₂ Reformulation" plant module, this hydrogen should come from renewable sources or not be contaminated with GHG emissions, which prohibits the use of fossil sources and / or energy sources It is advantageous to generate the required hydrogen by means of electrolysis, wherein the current used for this purpose should preferably originate from regenerative sources (cf claim 1) .In principle, each current is suitable for electrolysis, which in accordance with LCA <100 gC0 ₂ - equivalent / kWh _e is greenhouse gas reduction i Preferably, electricity from wind or water power or geothermal or solar panels or by means of photovoltaic recovered stream or produced from biomass stream is used in question here is also current that was generated by the presently disclosed system configuration.. (see Figures 31 et seq.) And atomic and fusion current (see claim 1.) Under certain circumstances it may sense mac to accept GHG emissions, eg if the electricity required for the electrolysis is particularly favorable.

When the greenhouse gas reduced SynMethane (referred to as "B10-CH4" in Figures 19 et seq.) Or the greenhouse gas reduced SynMethanol (referred to as Bio-CH ₃ OH in Figures 32 et seq.) Substitute fossil energy carriers, THG avoidance occurs. In the context of the substitution amounts, this means that the substituted fossil energy source (s) are not used and thus no further fossil C0 _{2 is released} into the environment, in which case no C0 _{2 is} permanently removed from the C0 ₂ cycle but Substitution of fossil fuels prevents additional fossil C0 _{2 from} entering the atmosphere.

In FIG. 33, based on the plant configuration described in FIG. 32, an advantageous embodiment variant is described in which the recuperated C0 _{2 is} not completely guided into a geological repository, but rather into the CO ₂ reforming plant. With regard to the GHG balance and / or the manufacturing costs and / or the economic contribution margin, it may be advantageous if the largest possible amount of the deposited and recuperated C0 _{2 is passed} into the C0 ₂ reforming, where from the regenerative C0 ₂ a regenerative energy source is produced that substitutes fossil fuels (see above).

In the advantageous embodiment variant of FIG. 34, in addition to or as an alternative to the compressor system, the GHG-reduced bio-methane originating from the plant modules "biogas scrubbing / CO ₂ precipitation" and "C0 ₂ recuperation" is led into a plant module for off-grid mixing, where it already exists the feed into the natural gas network with natural gas, preferably with compressed natural gas (CNG) is mixed. This off-grid mixing can take place at different pressure levels: a) without pressure, ie at the level of ambient air, b) at the pressure level of the natural gas extracted from a natural gas network, and c) at any pressure level between a) and b). It is advantageous to proceed according to b) and to leave the CNG taken from the natural gas network at its pressure level, to compress only the bio-methane and to mix the two gases at this pressure level. So you save the energy associated with a relaxation energy use for the recompression of natural gas.

Thus, the pre-compressed BioMethane is physically mixed with the CNG extracted from the natural gas network and not decompressed. After mixing outside the network, the precompressed mixed gas is compressed a little further so that it can be fed into the natural gas network against the pressure. The energy used in this plant module should come from renewable sources, which are preferably low greenhouse gas and particularly preferably greenhouse gas free.

This system module for the net external mixing of greenhouse-gas-reduced bio-methane and CNG can also be installed as an independent system module in any other system combination listed so far, for example in a system in which the BioMethan is not isolated from the biogas in a C0 ₂ -Abscheidevorrichtung, but the C0 ₂ - proportion of biogas is reformed in a reforming plant to BioMethan, so that the entire biogas is BioMethan. In this regard, it is also immaterial whether the installation variants listed above are added or not. The advantageous embodiment of Figure 35 corresponds to the system described in Figure 34, but also includes the system module "liquefaction." As an alternative to a gaseous delivery, the BioMethan generated in the system can also be dispensed in a liquid state when using this system module It makes sense to use GHG-reduced bio methane as a fuel in regions without a gas grid connection.The energy density in liquid form is considerably higher, which reduces the transport effort.To achieve the liquid state, the gases in the system module are cooled (cf. The energy carriers or energy used for this purpose are to originate from regenerative sources, which are preferably low in greenhouse gases and particularly preferably free from greenhouse gases. Cooling can also be carried out with dry ice produced in the plant from regenerative C0 ₂ , possibly via heat exchangers.

In the event that the liquid BioMethane gas to be supplied is to have certain GHG values, CNG may be added to the GHG-reduced BioMethan before or during liquefaction. Per kWh BioMethan between 0,1 kWh and 20 kWh CNG can be added (see above). The liquefied greenhouse-gas-reduced bio-methane or the liquefied bio-methane / CNG mixture or their natural gas equivalent is preferably supplied to the market for use as a THG-reduced or THG-free fuel (cf claim 16).

The "Condensing" system module, including the provision of any necessary CNG, can be integrated into every variant of the system and thus also in all the above versions.

In this embodiment, the operator of such a plant can decide the following: a) which ingredients are used in which proportions, b) whether they should be pretreated or not, c) with what proportion of the GHG-reduced biogas is fed into which utilization strand, d ) is the proportion with which the recuperated out C0 ₂ in which recovery strand, e) whether the greenhouse gas reduced BioMethan generated is to be liquefied or not, f) if the gaseous BioMethan greenhouse gas reduced in G) whether the "CBM" is to be used as GHG-free or GHG-reduced fuel, ie in what proportion it is mixed with CNG.

As already mentioned, the protection should not only include the complete plant configuration but also changes and modifications to the disclosed plant configuration and its variants. In this respect, variants of execution are also to be protected which lack individual system modules, e.g. In the figure 36, the plant module "nutrient extraction" is added to the plant configuration described in Figure 35. The plant module "nets outside mixing" or the plant module "pretreatment" or the plant module "compressor plant." In this plant module, the plant nutrients contained in the liquid phase of the digestate are extracted in several stages. This is done by first mixing the fermentation residues with water in a post-fermenter and then mechanically dehydrating them in a screw press or a comparable device (other suitable presses, extruders). While the solid phase as a mineral fertilizer substitute goes back to the field, the liquid phase is dehydrated a second time, preferably with at least one decanter. In order not to clog the membranes in the ultrafiltration, the liquid phase of the decanter is first passed through a pre-filter before being fed into the ultrafiltration plant and only then into the ultrafiltration plant. The permeate of the ultrafiltration plant is either fed into a precipitation plant or into a reverse osmosis plant. In both strands, the organic nutrients are extracted, essentially nitrates, potassium and phosphates, possibly also magnesium and various salts.

The organic nutrients substitute mineral fertilizer or mineral fertilizer components, thereby avoiding the GHG emissions resulting from the production and application of the mineral fertilizer. The positive effect on GHG emissions is attributed to the plant's main product, BioMethan or CBM.

The GHG effect is even more positive if energies from renewable sources are used in this plant module, which are preferably low in greenhouse gases and particularly preferably free of greenhouse gases. The plant module "Nutrient Extraction" can be integrated into any of the previously described variants as well as any other variant.

FIG. 37 shows an advantageous embodiment variant of the system configuration described in FIG. The extracted organic nutrients are additionally fed into a fertilizer plant, where fertilizers and / or fertilizer components are produced from them. These substitute mineral fertilizers, thereby avoiding the GHG emissions resulting from the production and application of the mineral fertilizer. The positive effect on GHG emissions is attributed to the plant's main product, BioMethan or CBM. The GHG effect is even more positive if, in the production of fertilizers, energies from regenerative sources are used, which are preferably low in greenhouse gases and particularly preferably free of greenhouse gases.

The plant module "fertilizer plant" can be integrated into any of the variants already described, as well as into any other embodiment variant. [0043] The variant of FIG. 38 corresponds to that of FIG. 37, but advantageously supplemented by the plant module "fuel production". The solid phase from the mechanical dehydrogenation 1 (which is made with a screw press or similar device) is no longer used untreated as Mineraldüngersubstitut, but in a dryer (belt or drum dryer) guided, dried there, then in a crushing device (hammer or Ball mill), crushed there and finally fed into a pellet press to be pelletized there to fermentation residue pellets. Preferably in this plant module low-GHG and particularly preferably propellant gas-free energies and energy sources are used, which reduces the C0 ₂ -Fußabdruck the plant or the BioMethans considerably. The digestate pellets replace fossil fuel (heating oil, coal or natural gas), thus avoiding large amounts of GHG emissions. This GHG prevention is ascribed to the process or the main product GHG-reduced bio methane or CBM, which further improves the GHG balance sheets. It is also possible to mix the fermentation residues with crushed wood (sawdust, shredded woodchips) before feeding them into the pelleting press so that mixed pellets are produced whose quality is in line with that of wood pellets and that of digestate pellets lies. A mixing of wood and digestate for fuel production is particularly advantageous if only so the statutory emissions can be met.

It is an advantage in terms of energy from the point of view of any embodiment variant with fermentation residue utilization to integrate the production of fuel into the process - which is entirely possible and should be protected.

The embodiment of Figure 39 corresponds to the system described in Figure 38, but supplemented by the recuperation of the ash of the digestate pellets or the mixed pellets. The ash of the spent fermentation residual pellets and / or the mixed pellets is collected and fed as a valuable fertilizer component of a fertilizer production (see claim 1). As a result, especially in the (dried) solids contained, little soluble phosphorus in the nutrient cycle, which is of great importance, because the world still available high-grade phosphorus deposits will be exploited still the oil deposits. The advantages of energetic use are thus the great advantages of an almost closed nutrient cycle. The fuel pellets continue to replace fossil fuel (heating oil, coal or natural gas).

It is advantageous for any embodiment variant with fermentation residue utilization to integrate the plants for the production of fermentation residue pellets and for recuperation of the digestate residue and their utilization in the respective plant variant - e.g. in the system configuration of Figure 27. This is quite possible and shall be protected as well as the integration of this system module in any other variant with digestate use.

Preferably, in plant modules where heat is needed, with greenhouse gas-free heat, preferably worked with self-generated heat, so that these systems modules the GHG balance of the product BioMethan or hardly burdened with greenhouse gases (see claim 1).

From all the conversion plants that are available for the conversion of biomass to generally usable energy sources, the plants were selected according to the invention, which have the highest conversion rates and the lowest capital expenditure, ie the best combination of substrate efficiency and system efficiency and thus the best overall efficiency. These are the plants for anaerobic bacterial fermentation (see claim 8). To the To avoid initially high greenhouse gas pollution of cultivated biomass, substrate substrates are already selected for fermentation substrates which do not or only to a minor extent have greenhouse gas emissions: greenhouse gases-free residues, including solid manure, low-greenhouse bio-waste and renewable raw materials, which are preferably greenhouse-friendly during cultivation. are low in gas (see claims 13).

It is advantageous to use for the anaerobic bacterial fermentation of the residues straw, straw-containing solid manure and organic waste solid fermentation plants, preferably percolated Garagenfermenter (see claim 1). However, these systems are not absolutely necessary, various wet systems can also be used. Finally, if the entire plant with all its plant modules is designed so that the BioMethan ends up being greenhouse gas negative (eg by using the optional plant modules "nutrient extraction" and / or "fuel production" or by an appropriate selection of the energy and energy sources to be used in the various plant modules or by dividing the biogas into the 3 utilization strands or by using the "C0 ₂ sequestration" system module) and the aim is "greenhouse gas-free CBM", then the proportion of greenhouse gas-intensive renewable resource can be increased to the fresh mass, so far Until the greenhouse gas load of the product "BioMethan" just does not tilt from negative to positive, that means maize and green rye are also suitable as a fermentation substrate, because corn and green rye have the advantages of high yields per hectare and high availability.

In particular, if percolated garage fermenters are used to convert the biomass into biogas, in-house transport by wheeled or telescopic loaders can be a significant source of greenhouse gas emissions. According to the invention, GHG-negative bio-methane or a corresponding natural gas equivalent produced by this process is used as fuel for the wheeled or telescopic loader used, so that the greenhouse gas emissions of the likewise used fuels natural gas and diesel are compensated (cf claim 1) ). Stationary conveyors are electrically operated. THG-reduced, preferably THG-free, current is used for this purpose (compare claim 1). At the control and regulating station "Biogasaufteilung" (not explicitly shown in the figures) takes place as already mentioned above, a division of the generated in the biogas plant and if necessary, biogas supplied from external sources to the three treatment and utilization strands "power generation", "biogas scrubbing / C0 ₂ separation / C0 ₂ -requirement" and "C0 ₂ - reforming" With changing market prices for used energy and generated energy sources, it can make more sense technically and / or economically, the greenhouse gas reduced biogas in the utilization strand "Biogaswäsche / C0 ₂ -Abscheidung / C0 ₂ -Rekuperation At other times, it makes more sense to lead it into the recovery strand "C0 ₂ reformation" as much as possible, and in a third case, the technical parameters and / or the contribution margin are the highest, if the largest possible proportion It is also quite possible that a very specific percentage distribution d biogas is optimally adapted to the three plant and utilization strands in the technical and / or economic sense. By drawing in the diverter "biogas distribution" into the overall plant, a flexible control or regulation of the respective biogas components is possible, so that the generation of the various energy sources can be adapted to the changing conditions.Technically, the control of the biogas flow by simple valves in the corresponding gas lines.

The distribution and distribution of the gases "BioMethan" and "Regeneratives C0 ₂ " takes place either via gas pipes or, as with BioMethanol, with mobile tanks. If trucks are to be used for the distribution of the gases, they are to be powered by greenhouse-gas-free or greenhouse-gas-negative BioMethane or a mixture of fossil diesel, greenhouse-gas-free or greenhouse gas-negative bio methane and fossil natural gas or a corresponding natural gas equivalent (see claim 1). The resulting from the "distribution" greenhouse gas pollution then falls even with a mixture of bio methane and natural gas with fossil diesel to a mixed fuel very low, possibly the GHG load due to a greenhouse gas neutrality of the fuel mixture even back to zero.

As already mentioned, volume effects (scale effects or economies of scale) occur in the case of several plant modules. It is therefore in each embodiment of advantage to build the largest possible biogas plants and operate (see claim 1 1).

If implemented with all steps, then with the plant configurations disclosed herein, GHG-reduced, preferably GHG-poor, especially GHG- free and in particular GHG-negative BioMethan be produced whose GHG reduction effect compared. Natural gas (CNG) is at least 100 or 180 or 236 or 336 gC0 ₂ - equivalents / kWh of methane. The GHG negative bio methane can then be mixed with fossil and thus greenhouse gas loaded natural gas (CNG; THG load well-to-wheel at 236 gC0 ₂ -equivalent / kWhcNG) so that the resulting mixed gas can handle any GHG pollution between -468 gC0 ₂ -equivalent / kWli ischgas and +236 gC0 ₂ -equivalent / kWliMischgas has. As a result, the new plants can produce a whole range of mixed gases with different GHG reductions as well as an absolutely GHG-free mixed gas and even various GHG-negative mixed gases. These mixed gases can be used as fuel in traffic.

When marketing the fuel derived from the systems according to the invention, it is necessary and important to be able to present catchy and easily manageable GHG effects. A GHG reduction by e.g. 85% is more catchy and clear to consumers than 82% GHG reduction. GHG mitigation effects are therefore associated with e.g. also rounded off in the legislation to 5 percentage points. Accordingly, it is of particular economic advantage to be able to offer mixed gases whose GHG reduction effect falls within the 5% categorization.

Claims

claims

1. A process for the production of greenhouse gas reduced energy from biomass according to the method of anaerobic bacterial fermentation preferably after

Solid fermentation process (dry fermentation) in a biogas plant with at least one fermenter, preferably at least one percolated

Garagenfermenter, gekennzei with at least one system module for Biogaswäsche / separation of regenerative C0 ₂ and at least one plant module for recuperation of renewable C0 ₂ , characterized s, at least 5% of the biogas produced, preferably at least 20%, especially

preferably at least 50% and in particular at least 85% are passed into a process step "biogas scrubbing / C0 ₂ separation", of the C0 ₂ portion of the biogas conducted in the process step "biogas scrubbing / C0 ₂ separation" at least 5%, preferably at least 20% %, particularly preferably at least 50% and in particular at least 85% of the deposited regenerative C0 ₂ at least 5%, preferably at least 20%, particularly preferably at least 50% and in particular at least 85% in one

Process step "C0 ₂ -Rekuperation" passed and collected there (recuperated), the recuperated regenerative C0 ₂ in the gaseous state in at least one unpressurized container or in at least one pressure vessel or in liquid form in at least one liquid tank or in solid form in at least one thermally insulated Container or room is temporarily stored or the recuperative regenerative C0 ₂ without

Caching is fed into a gas or liquid gas line or for the production of liquid or solid C0 ₂ in a cooling system, from the recuperated regenerative C0 ₂ in the subsequent use at least 5%, preferably at least 20%, more preferably at least 60% and especially at least 95% sequestered (geologically stored) or electrolytically according to the Sabatier process preferably with the addition of regenerative or atomic current converted hydrogen into synthetic methane or reformed to methanol according to one of the known methods or substitute fossil C0 ₂ , the calculated according to the EU Directive "Renewable Energy Directive RED 2009/28 / EC of 23 April 2009" greenhouse gas pollution of the resulting BioMethans due to the selection of GHG-reduced feedstocks and / or due to the selection of GHG-reduced transport of the input materials and / or GHG-reduced storage of the input materials and / or due to the selection of regenerative power sources and / or the GHG-reduced ones heat sources for the treatment of the biogas and / or the selection of GHG-free electricity sources for the compression and feeding of BioMethan and / or the substitution of mineral fertilizers by fermentation residues from the biogas plant and / or the substitution of mineral fertilizers by nutrients derived from Fermentation residues were extracted, and / or due to the substitution of fossil fuels by alternative, produced from digestate of the biogas plant

Fuels and / or due to the substitution of mineral fertilizers by recuperated ash from fuel produced from digestates and / or due to the substitution of fossil fuels by the synthetic methane and / or due to the material substitution of fossil C0 ₂ by the recuperated regenerative C0 ₂ and / or due to the GHM-reduced distribution of BioMethan and / or due to the

Sequestration of the recuperated, regenerative C0 ₂ in a geological repository the LifeCycleAnalysis (LC A) value of 100 gC0 ₂ -equivalents / kWhßioMethan, preferably the LCA value of 50 gC0 ₂ -equivalent / kWhßioMethan, particularly preferably the LCA value of 5 gC0 ₂ -equivalents / kWh-methane, and in particular the LCA-value of -100 gC0 ₂ -equivalent / kWh-methane, and / or the resulting greenhouse-gas-reduced bio-methane is preferably mixed with natural gas to give a greenhouse gas reduced mixed gas, particularly preferably such that the the bio-methane content of the mixed gas exceeds 4% or the mixed gas reaches an LCA of <75 gC0 ₂ -equivalent / kWh, and in particular that the energetic content of the bio-methane or bio-methane-enriched biogas exceeds 30% % or the mixed gas reaches an LCA value of <5 gC0 ₂ - equivalents / kWh.

2. The method of claim 1, wherein the resulting greenhouse gas reduced

BioMethan pure or mixed with propane and / or butane and / or natural gas is fed into a natural gas or BioMethannetz or in which the produced BioMethan and / or a physical or a statistical / virtual BioMethan- / natural gas mixture or a

corresponding natural gas equivalent is taken from the grid and is used as an energy source reduced to <196 gC0 ₂ -eq / kWh, preferably as a low-GHG energy source with a GHG load of <120 gC0 ₂ -equivalent / kWh, particularly preferably as GHG-free energy sources a GHG load of <0.1 gC0 ₂ -equivalent / kWh and in particular as

greenhouse gas-negative energy sources with a GHG burden of <0 gC0 ₂ - equivalents / kWh, whereby the calculation of the greenhouse gas load according to the EU Directive "Renewable Energy Directive RED 2009/28 / EC of 23 April 2009" and after the Life Cycle Analysis method is performed and the amount withdrawn from the network results from the target GHG exposure of the withdrawn gas.

3. The method of claim 1, wherein as a fermentation substrate low greenhouse gas renewable resources (NawaRo), preferably organic waste, particularly preferably solid manure or manure or manure and in particular straw and / or straw-containing residues are used as fermentation substrates, said GHG arm in this context, a GHG Value of total <55 gC0 ₂ -equivalents / kWhT of _substance for cultivation, harvesting, storage and transport or in which the dry matter content of the raw material straw is at least 10% of that of

Dry matter content of the total fresh mass used is preferably at least 20%, more preferably at least 35% and in particular at least 50% or in which the straw-containing residues of solid manure and / or a mixture of manure and straw and / or poultry dry manure and the dry matter content of these Starting materials amounts to at least 10% of the dry matter content of the total fresh mass used, preferably to at least 20%, particularly preferably to at least 35% and in particular to at least 50% or at which the dry matter content of the organic waste used at least 10% of

Dry matter content of the total fresh mass used is preferably at least 35%, more preferably at least 50% and in particular at least 75% or in which the dry matter content of NawaRo used is at least 10% of the dry matter content of the total fresh mass used, preferably at least 35%, particularly preferably at least 50 % and in particular at least 75%.

4. The method according to any one of claims 1 and 3, wherein the straw or the

straw-containing residues for the purpose of digesting the lignin structures of a

Pretreatment, preferably the mechanical pretreatment of the grinding or the chemical pretreatment of soaking in acidic

Solutions or the thermochemical pretreatment with saturated steam or the

thermomechanical pretreatment by means of steam explosion or thermochemical pretreatment by means of thermal pressure hydrolysis or chemical pretreatment by means of mixing with solid manure or with manure or the biochemical pretreatment with exo-enzymes.

5. The method according to any one of claims 1 and 2, wherein the pure bio methane and / or a mixture of bio methane / butane / propane / natural gas or a corresponding natural gas equivalent as compared. Petrol or diesel fuel or natural gas is used in transport or in power generation, preferably as low-GHG fuel with a GHG load of LCA <50 gC0 ₂ - equivalents / kWh, particularly preferably as greenhouse gas-free fuel and in particular as greenhouse gas-negative fuel.

6. The method of claim 1, wherein the anaerobic bacterial fermentation by the method of solid fermentation (dry fermentation) takes place, preferably in fermenters of the percolated garage type and particularly preferably with post-fermentation in a digestate bunker and in particular so that during the fermentation a spatial separation into one first hydrolysis and acidification stage and a second methanation stage takes place.

7. The method of claim 1, wherein the generated in the at least one fermenter biogas or supplied from external sources biogas or a gas mixture consisting of these two gases with a proportion of at least 30%, preferably at least 50%, more preferably at least 75% and In particular, at least 90% in the strand "biogas scrubbing / C0 ₂ -Abscheidung" with "recuperation of the regenerative C0 ₂ " is performed or in which in the strand "Biogaswäsche / C0 ₂ separation / C0 ₂ -Rekuperation" guided biogas volume flow of reaches at least 100 Nm ³ / h, preferably of at least 500 Nm ³ / h, particularly preferably of at least 1,000 Nm ³ / h and in particular of at least 2,000 Nm / h or at the in the process step "C0 ₂ -Reformierung" conducted biogas Volume flow reaches at least 100 Nm / h, preferably at least 500 Nm / h, especially

preferably at least 1,000 Nm ³ / h and in particular at least 2,000 Nm ³ / h or at which the C0 ₂ - volumetric flow rate fed into the process step "C0 ₂ reforming"

3 3

at least 100 Nm / h, preferably at least 500 Nm / h, particularly preferably at least 1,000 Nm / h and in particular at least 2,000 Nm / h or at the in the step "electricity" directed, from biomethane and / or SynMethan existing gas stream at least 100 Nm / h, preferably at least 500 Nm / h, particularly preferably at least 1000 Nm / h and in particular at least 2000 Nm ³ / h or at which the volume of biomethane to be compressed and fed reaches at least 100 Nm ³ / h, preferably at least 500 Nm ³ / h, particularly preferably from

3 3

at least 1,000 Nm / h and in particular at least 2,000 Nm / h or in the case of biogas which is included in the string "biogas washing / C0 ₂ capture" incl.

"Recuperation of the regenerative C0 ₂ " is performed, regenerative C0 ₂ with the method of pressure swing absorption (PSA) is deposited and collected (recuperated), preferably with the method of pressureless amine scrubbing and particularly preferably with a refrigeration method (cryogenic method).

8. The method according to any one of claims 1 to 7, wherein a generated gas according to the method is fed into a natural gas or BioMethannetz or a natural gas or BioMethannetz virtual / statistically attributed and this gas or

Energy equivalent by gas stations, preferably by non-public

Home Filling Stations and / or non-public

Service stations / public service stations and / or by means of non-public

Community Filling Stations, from the Natural Gas or

BioMethannetz taken and delivered to consumers.

9. Biogas plant for the production of greenhouse gas reduced energy sources

Biomass according to the method of anaerobic bacterial fermentation, preferably by the Feststoffvergärungsverfahren (dry fermentation) comprising: at least one fermenter, preferably at least one percolated Garagenfermenter, which is connected to at least one plant module for Biogaswäsche / separation of regenerative C0 ₂ , which in turn is associated with at least a plant module for recuperation of the regenerative C0 ₂ , characterized gekennzei chnet s s at least 5% of the biogas produced, preferably at least 20%, more preferably at least 50% and in particular at least 85% from the at least one fermenter in the at least one plant module "Biogaswäsche / C0 ₂ -Abscheidung "be deducted from the C0 ₂ - share of the biogas in the plant module" Biogaswäsche / C0 ₂ - deposition "conducted biogas at least 5%, preferably at least 20%, more preferably at least 50% and in particular at least 85%, separated from the NEN regenerative C0 ₂ at least 5%, preferably at least 20%, particularly preferably at least 50% and in particular at least 85% im

Plant module "C0 ₂ -Rekuperation" be collected (recuperated), the plant module "C0 ₂ -Rekuperation" via one or more gas lines with a plant for reforming the regenerative C0 ₂ in synthetic methane and / or with a plant for converting the regenerative C0 ₂ in synthetic methanol and / or with a C0 ₂ -intermediate storage and or is connected to a C0 ₂ gas network and / or to a cooling system for producing liquid or solid C0 ₂ , the recuperated regenerative C0 ₂ in gaseous state in at least one unpressurised container or in at least one pressure vessel or in liquid form in at least one Liquid tank or stored in solid form in at least one thermally insulated container or room or the collected regenerative C0 ₂ without

Buffering is fed into a gas or liquefied gas network or to produce liquid or solid C0 ₂ in a cooling system, of the recuperated regenerative C0 ₂ in the subsequent use at least 5%, preferably at least 20%, more preferably at least 60% and in particular at least 95th % sequestered (geologically stored) or converted according to the Sabatier process preferably with the addition of regenerative or atomic electricity electrolytically generated hydrogen in synthetic methane or reformed according to one of the known methods to methanol or substitute fossil C0 ₂ material, according to the EU Directive "Renewable Energy Directive RED 2009/28 / EC of 23 April 2009" calculated greenhouse gas emissions of the resulting BioMethane due to the selection of GHG-reduced input materials and / or the selection of GHG -reduced transport of the input materials and / or due to the GHG -reduced storage of the input materials and / or due to the selection of regenerative power sources and / or the GHG-reduced heat sources for the treatment of the biogas and / or due to the selection of GHG-free power sources for the compression and feeding of BioMethans and / or Substitution of mineral fertilizers by fermentation residues from the biogas plant and / or substitution of mineral fertilizers by nutrients extracted from digestate, and / or substitution of fossil fuels with alternative digestate from the biogas plant

Fuels and / or substitution of mineral fertilizers by recuperated ash from fuel produced from digestate and / or on the basis of Substitution of fossil fuels by the synthetic methane and / or due to the material substitution of fossil C0 ₂ by the recuperated, regenerative C0 ₂ and / or due to the GHG-reduced distribution of BioMethans and / or due to the

Sequesting the recuperated, regenerative C0 ₂ in a geological repository the LCA value of 100 gC0 ₂ equivalents / kWh, preferably the LCA value of 50 gC0 ₂ - equivalents / kWh, particularly preferably the LCA value of 5 gC0 ₂ equivalents / kWh and in particular the LCA value of -100 gC0 ₂ -equivalents-th / kWh and / or the resulting greenhouse gas-reduced BioMethan or BioMethan enriched, greenhouse gas reduced residual biogas preferably with natural gas to one

mixed greenhouse gas reduced mixed gas, more preferably such that the energetic content of the bio-methane or bio-methane-enriched biogas is more than 4% or more, the mixed gas has an LCA of <75 gC0 ₂ -equivalents / kWh, and in particular, that the energy content of the bio-methane or bio-methane-enriched biogas in the mixed gas is more than 30% or that the mixed gas has an LCA value of <5 gC0 ₂ -equivalent / kWh.

10. biogas plant according to claim 9, in which the resulting greenhouse gas reduced BioMethan pure or mixed with propane and / or butane and / or natural gas is fed into a natural gas or BioMethannetz or filled in liquefied gas tanks or in pressure tanks or in which the mixing of the treated BioMethans with natural gas ( CNG) or the bio methane / butane / propane mixture with natural gas (CNG) so that the bio methane or the bio methane / butane / propane mixture is fed into a natural gas network, there mixed with the natural gas and as energy equivalent to a Any exit point is taken from the network, wherein the removal amount resulting from the GHG target load of the extracted gas.

11. Biogas plant according to one of claims 9 and 10, wherein the produced BioMethan and / or a BioMethan / propane / butane / natural gas mixture or a corresponding

Natural gas equivalent as used to <196 gC0 ₂ -equivalent / kWh greenhouse gas reduced energy use, preferably as low-GHG energy sources with a GHG load of <120 gC0 ₂ -equivalent kWh, particularly preferably as GHG-free energy and especially as greenhouse gas-negative energy sources, the Calculation of the greenhouse gas load according to the EU directive "Renewable Energy Directive RED 2009/28 / EC of 23 April 2009" and using the Life Cycle Analysis method.

12. Biogas plant according to claim 9, wherein the deposition of the regenerative C0 _{2 is} preferably carried out by the method of pressure swing absorption (PSA), particularly preferably with the process of pressureless amine scrubbing and in particular with a refrigeration process (cryogenic process) or in the conditioning module "biogas wash / C0 ₂ - deposition" reaches out biogas a volume flow of at least 100 Nm / h, preferably of at least 500 Nm / h, more preferably of at least 1,000 Nm ³ / h and in particular of at least 2,000 Nm ³ / h or when in the system module "C0 ₂ -Rekuperation" led C0 ₂ -Volumenstrom at least 100 Nm ³ / h achieved, preferably at least 500 Nm ³ / h, especially

preferably of at least 1,000 Nm / h and in particular at least 2,000 Nm fh or in which the C0 ₂ volume flow conducted into the geological repository reaches an annual average value of at least 100 Nm ³ / h, preferably at least 500 Nm ³ / h, particularly preferably of at least 1,000 Nm / h and in particular at least 2,000 Nm ³ / h or at which the CBM volume flow conducted into the "compressor" system module reaches a value of at least 100 Nm / h, preferably at least 500 Nm / h, especially

3 3

preferably of at least 1,000 Nm fh and in particular at least 2,000 Nm / h or in the at least one of the at least one plant module "power generation" led out of

Biomethane and / or SynMethan existing gas flow reaches at least 100 Nm ³ / h,

3 3 preferably at least 500 Nm / h, particularly preferably at least 1,000 Nm / h and in particular at least 2,000 Nm ³ / h or in which the biogas fed into the at least one plant module "C0 ₂ -Reformierung"

3 3

Flow rate reaches at least 100 Nm / h, preferably at least 500 Nm / h, particularly preferably at least 1,000 Nm ³ / h and in particular at least 2,000 Nm ³ / h or at which the C0 ₂ volume flow passed into the at least one "C0 ₂ reforming" system module reaches at least 100 Nm / h, preferably at least 500 Nm / h, particularly preferably at least 1,000 Nm / h and in particular at least 2,000 Nm / h.

13. Biogas plant according to claim 9, wherein the fermentation of the starting materials or the separation of the regenerative C0 ₂ from the biogas or the recuperation of the regenerative C0 ₂ or the reforming of the regenerative C0 _{2 take place} to synthetic methane or to synthetic methanol in spatially separated locations, and the regenerative C0 ₂ to be reformed is therefore transported from the biogas plant to a separate reforming plant, preferably by means of liquid gas tanks, particularly preferably by means of pressure tanks and in particular by means of a gas line, wherein spatially separated in this context means a distance of more than 50 m.

14. Biogas plant according to claim 9, in which as Gärsubstrat treibhausgasarme

renewable raw materials (NawaRo), preferably organic waste, particularly preferably solid manure or manure or liquid manure and in particular straw and / or straw-containing residues are used as fermentation substrates, with low-GHG arm in this context, a total of <55 gC0 ₂ -equivalents / kWhDrockensubstanz for cultivation, harvesting, storage and transport or in which the dry matter content of the raw material straw is at least 10% of the

Dry matter content of the total fresh mass used is preferably at least 20%, more preferably at least 35% and in particular at least 50% or in which the straw-containing residues of solid manure and / or a mixture of manure and straw and / or poultry dry manure and the dry matter content these starting materials amounts to at least 10% of the dry matter content of the total fresh mass used, preferably to at least 20%, particularly preferably to at least 35% and in particular to at least 50% or in which the dry matter content of the biological waste used is at least 10% of the dry matter content of the total fresh mass used, preferably at least 35%, particularly preferably at least 50% and in particular at least 75% or at which the dry matter content of the NawaRo used at least 10% of the dry matter content of the total fresh mass used is preferably at least 35%, more preferably at least 50% and especially at least 75%.

15. biogas plant according to claim 9, in which the straw or the straw-containing residues for the purpose of digestion of the lignin undergo means for pretreatment, preferably for mechanical pretreatment facilities for

Milling or chemical pretreatment Soaking in acidic solutions or for thermochemical pretreatment Facilities operating with saturated steam or for thermomechanical pretreatment

Steam explosion plants or extruders or for thermochemical pretreatment

Thermodruckhydrolyseanlagen or for chemical pretreatment Facilities that mix straw with solid manure or manure, or for biochemical pretreatment

Facilities for adding exo-enzymes to the straw-containing fresh mass or the straw-containing digestate.

16. biogas plant according to claim 9, wherein the fermentation residues from the fermenters are applied as fertilizer on agricultural or forestry land and replace mineral fertilizer or washed out in a plant module "nutrient extraction" plant nutrients from the digestate or from the feedstock and recuperated , the

replace mineral fertilizer or in the additional optional process step "fertilizer production" recuperated plant nutrients to organic fertilizer or organic

Fertilizer components are processed and this fertilizer or fertilizer components preferably mineral, greenhouse gas-loaded fertilizer or equivalent

Substitute fertilizer components or in which in a plant module "fuel production" fermentation residues from the anaerobic bacterial fermentation are processed to alternative fuels, preferably to fuel pellets or fuel briquettes and more preferably to fuel pellets or fuel briquettes, the fossil, greenhouse gas releasing fuel oil or fossil, greenhouse gas releasing natural gas or fossil, greenhouse gas releasing coal

substitute or in which a mixture of digestate and crushed wood to fuel pellets or fuel briquettes are processed, preferably to fuel pellets or

Fuel briquettes, the fossil, greenhouse gas-releasing fuel oil or fossil fuel,

Greenhouse gas releasing natural gas or fossil, greenhouse gas releasing coal

Substitute or in which the recuperated nutrients ash from the combustion of gärresthaltigen

Include fuels, preferably ash from fermentation residue-containing fuel pellets or fermentation residue-containing fuel briquettes and in which the ashes of the spent fuel pellets or fuel briquettes recuperated and fed to a fertilizer production.