EP2875116A2

EP2875116A2 - Method for operating a biogas system and a biogas system operated in such a manner

Info

Publication number: EP2875116A2
Application number: EP13736931.0A
Authority: EP
Inventors: Peter Lutz
Original assignee: Bekon Holding AG
Current assignee: Bekon Holding AG
Priority date: 2012-07-17
Filing date: 2013-07-16
Publication date: 2015-05-27
Also published as: US20150147745A1; CA2877577A1; WO2014012952A3; DE102012212505A1; CN104508112A; WO2014012952A2

Abstract

The invention relates to a method for operating a biogas system (1) according to the principle of dry fermentation with a plurality of biogas fermenters (2a-2d) that are run in batch mode. At least one of the biogas fermenters (2a-2d) has just been loaded with fresh biomass and the other biogas fermenter or fermenters (2a-2d) are in the state of producing more highly concentrated biogas. The method provides for closure of the at least one biogas fermenter (2a-2d) loaded with fresh biomass and connection of the at least one biogas fermenter (2a-2d) loaded with fresh biomass to at least one of the other biogas fermenters (2a-2d) producing biogas. In addition, there is a return of the biogas mixture from the at least one freshly loaded biogas fermenter (2a-2d) to at least one of the other biogas fermenters (2a-2d) producing biogas. After expiration of a defined time duration, the return of the biogas mixture from the freshly loaded biogas fermenter (2a-2d) is stopped. The invention also relates to a biogas system (1) which is suitable for operation in accordance with the method of the invention.

Description

Method for operating a biogas plant and such operated

biogas plant

The invention relates to a method for operating a biogas plant having the features of claim 1 and to a biogas plant having the features of claim 8.

From practice and for example from EP 0 934 998 A2 it is known that in the so-called dry fermentation, the material to be fermented is not converted into a liquid phase, as is the case, for example, in the liquid fermentation of biowaste. Instead, the fermentation substrate introduced into the biogas fermenter is kept constantly moist by withdrawing the percolate from the bottom of the fermenter and then spraying it again over the biomass. This will be optimal

Living conditions for the bacteria needed for fermentation achieved. In addition, the recirculation of the percolate can be used to regulate the temperature, and it is possible to add additives for process optimization.

Dry fermentation is necessary, for example, for very dry or particularly fibrous fermentation substrates.

For example, it is known from DE 10 2008 059 803 A1 that bioreactors or biogas plants which operate on the principle of dry fermentation are frequently operated in so-called batch mode. The term "batch operation" denotes a process principle in which no further material is added or removed during the fermentation process Fermenter, the fermenter is completely emptied and then refilled.The disadvantage of batch operation is that the operation of the biogas fermenter must at least then be interrupted, if the fermenter room has to be emptied and filled with fresh fermentation substrate. In order that a sufficient amount of biogas can be continuously fed to a cogeneration plant serving to generate electricity and / or heat, a plurality of fermentation tanks are operated at different times in the biogas plant.

DE 10 2008 059 803 A1 addresses the problem described above - namely that the batch operation necessitates a shutdown of the individual biogas fermenters for emptying and filling, ie. H. that biogas production at least one

Biogas fermenter must be stopped. Because, as described above, then first the already fermented biomass must be removed from the respective biogas fermenter, filled the fresh biomass in the biogas digester and the

Biogas production to be resumed. When starting up a freshly loaded biogas fermenter, the proportion of methane in the biogas produced is initially so low and the proportions of carbon dioxide and nitrogen are so high that direct use of the biogas in a combined heat and power plant is not possible. To counter this problem, DE 10 2008 059 803 A1 proposes to partially separate the non-methane components of this gas mixture, also referred to as lean gas, and to recycle the remaining gas mixture with a higher methane content back to the biogas fermenter until the methane content is high enough is. The disadvantage of this, however, is that the gas mixture is enriched in this way only very slowly and the process is thus not very efficient. It is also disadvantageous that a complicated separation of the non-methane components is necessary in each case.

From DE 10 2010 028 707 A1 a process for the process control of percolators or fermenters in two-stage biogas production process is known, wherein a biogas plant according to the principle of dry fermentation, is specified with a plurality of fermenters, which are run in batch mode. In this case, a time schedule is given, which provides an exhaust air operation at the beginning of the percolation to remove CO2 rich hydrolysis gas from the fermenter. This CO2 rich and not energetically usable hydrolysis gas can then be used to displace methane-containing hydrolysis gas in a percolator, which before the end of the

Percolation stands to be used. This process is controlled by the methane gas content. Although a, according to DE 10 2010 028 707 A1 constructed biogas plant, Biogas with constant and high methane content available, however, reduces the efficiency of the exhaust air operation during the beginning of percolation

Equipment, or the CO2-rich gas must be post-processed in a gas utilization plant.

A comparable process, in which, however, the CO ₂ -containing purge gas is passed through the substrate, EP 2 251 408 A1.

DE 10 2009 025 329 B4 specifies a method for gas exchange between two or more bioreactors, wherein gas from the gas space of one or more

Bioreactors in the gas space of one or more bioreactors is passed. For this purpose, the measured values of H2S, CO2, CH4 and O2 from all bioreactors are constantly queried and the exchange between two and more bioreactors regulated.

Pressure and sulfur are used as values to determine when a bioreactor is ready for replacement with one or more other bioreactors. The procedure specified in D4 indicates an increase in the efficiency of a biogas plant, but it also requires a considerable use of measuring and control technology.

The object of the present invention is therefore to provide a method for operating a biogas plant and a biogas plant operated in this manner, in which the efficiency in batch operation is significantly increased using structurally simple means and the continuous output of usable biogas is improved.

This object is achieved by a method for operating a biogas plant having the features of claim 1 and by a biogas plant operated in this way with the features of claim 8. Advantageous developments of the invention are specified in the subclaims.

The invention relates to a method for operating a biogas plant according to the principle of dry fermentation with a plurality of biogas digesters, which are driven or operated in batch mode. At least one of the biogas fermenters has just recently been loaded with fresh biomass, and at least one of the remaining biogas digesters is in a state in which it is entering methane-containing, ie better usable, biogas produced. In the method, the following method steps are provided:

Closing the at least one laden with fresh biomass

Biogas fermenter,

- Connecting the at least one loaded with fresh biomass

Biogas fermenter with at least one of the other biogas producing biogas fermenters,

- Transfer of the biogas mixture from the at least one freshly loaded biogas fermenter in at least one of the remaining biogas-producing

Biogas fermenter,

- Ending the transfer of the biogas mixture from the freshly loaded

Biogas fermenter, after a certain period of time.

The biogas from the freshly loaded biogas fermenter, the so-called lean gas, is converted into a single or at the same time into several other, currently operated and usable biogas biogas with high methane concentration-generating

Biogas fermenter recycled. By mixing the lean gas with the methane-containing biogas of one or more of the remaining biogas digester, the variation of the methane concentration in the mixed biogas from all biogas digesters and the rate of change of the methane concentration can be reduced in a simple manner. Often the biogas produced in the biogas fermenters is fed to a CHP with gas engine. The gas engine is preceded by a so-called gas mixer, which mixes the biogas with the necessary air for combustion and ensures at different methane concentrations in the biogas for a combustible biogas / air mixture. These gas mixers have a certain inertia, so that in the event of rapid and / or strong fluctuations in the methane concentration in the biogas, under certain circumstances, a biogas / air mixture which is no longer combustible is fed to the gas engine and the gas engine dies. By the gas transfer according to the present invention is

Variation of the methane concentration is reduced and in addition, the change of the methane concentration in the mixed biogas flows from all biogas fermenters slower, so that the gas mixer can always provide a combustible biogas / air mixture for the gas engine despite its inertia. The period of time determined depends on the size of the biogas plant or the number of individual biogas fermenters, the size of the individual biogas fermenters and / or the type of biomass to be fermented and is based on empirical values. The period is chosen so that after switched biogas utilization devices, eg. B. CHP with gas engine, gas treatment equipment, etc., can be supplied continuously with recyclable biogas.

Preferably, the determined period of time during which the transfer of the

Biogas mixture from the freshly loaded biogas fermenter takes place, so in one

Control device deposited that the time period parameterizable, i. manually changeable by an operator or automatically by a technical device is. For example, the length of time, depending on the size of the entire biogas plant - number of biogas digesters - and depending on the size of the biogas digester changed or

be set. The fact that the control device controls the transfer and / or the termination of the transfer depending on the specific period of time, the biogas plant can be operated very flexible and efficient.

The biogas plant can be operated even more flexibly if the specific period of time can also be influenced by further parameters and / or manually by an operator while the biogas plant is in operation. For example, the concentration of certain proportions of biogas, in particular the methane concentration, could be measured and, depending on this, the specific period shortened or extended in order to optimize the operation time and / or quality.

In order to increase the reliability of the biogas plant, it can be provided that after closing the at least one loaded with fresh biomass

Biogas fermenter an oxygen-free or at least as low oxygen scavenging gas is introduced into the biogas fermenter. The biogas fermenter is purged before opening until it is ensured that when the biogas fermenter is opened by the incoming air no explosive biogas / air mixture can arise more. The risk of accidents is considerably reduced. The process is particularly simple, since the transfer of the

Biogas mixtures of the at least one freshly loaded biogas fermenter by a pressure gradient takes place, which results in the mere addition of biogas fermenter loaded with fresh biomass - ambient pressure - with the other biogas fermenters - slightly increased pressure by the biogas produced. As a result, no further aids, in particular no funding necessary.

In an advantageous embodiment variant of the method, the methane concentration in the biogas mixture from all biogas fermenters in a biogas collecting line is measured to determine the specific period of time. The duration of the transfer of the lean gas into one or more biogas-producing

Biogas fermenter is chosen so that the methane concentration in the

Biogas manifold does not fall below a predetermined by the downstream biogas utilization device minimum value. If the methane concentration in the biogas collecting line is measured continuously or at intervals, a particularly accurate and efficient operation of the entire biogas plant is achieved since all measures for transferring the biogas can also be carried out or controlled as a function of the measured methane concentration.

In a further advantageous embodiment, it is provided that the at least one freshly loaded biogas fermenter connected not only with a single, but with several of the remaining biogas fermenter, so that its biogas mixture is converted according to several biogas digesters. As a result, the efficiency of the process can be significantly increased again.

It is also very convenient if the transfer or introduction of the biogas to be enriched, i. of the lean gas, at a location of the remaining biogas fermenter takes place, which is as far away from the point at which the biogas produced in the respective biogas fermenter is withdrawn or removed.

As a result, the residence time for enriching the lean gas is extended in a structurally simple manner. A biogas plant which is suitable for carrying out the method described above has a plurality of biogas fermenters which operate on the principle of dry fermentation, each biogas fermenter having at least one

Biogasauslass and at least one gas inlet. Next has the

Biogas plant via at least one gas transfer line with a valve device through which the biogas outlet of a Biogasfermenters with the gas inlet of another is connectable for a certain period of time. This biogas plant is advantageously suitable to increase the methane content of the lean gas of a freshly loaded biogas fermenter in a particularly simple manner and the

To reduce hydrogen sulfide content, since the biogas is not led out of the biogas plant, but distributed within the biogas plant on at least one other biogas fermenter and thus the residence time of the lean gas in the

Biogas plant is extended.

A particularly advantageous embodiment of the biogas plant according to the invention has a measuring device for detecting the methane concentration in a biogas collecting line in which the biogas from all biogas digesters together.

It is expedient for the control device to control and / or regulate the connection of the gas outlet of the at least one freshly loaded biogas fermenter to the gas inlet of at least one of the remaining biogas fermenters by means of the gas transfer line. In this case, the control / regulation only depending on the particular

Duration and / or depending on one or more parameters of the biogas plant. In particular, the methane concentration in the biogas collecting line can be taken into account for this purpose.

Ideally, the gas inlet for the transferred lean gas and the

Biogas outlet for enriched or ready-to-use biogas in the

Biogas fermenters as far apart as possible. In particular, these can be arranged at opposite ends of the respective biogas fermenter. As a result, it can be achieved that the methane enriched lean gas in addition to prolonged stay must also deny the longest possible transport route.

The gas inlet can be arranged in the bottom region of the respective biogas fermenter. As a result, the lean gas must flow through the biomass and the

Dwell time of the lean gas in the respective biogas fermenter is extended. Consequently, a particularly effective mixing results between lean gas and biogas produced in the biogas fermenter with high methane concentration.

An advantageous embodiment of the invention provides that the

Connect gas inlets to a source with low-oxygen purge gas. This allows a biogas fermenter to be flushed with flushing gas before it is opened and reloaded and the formation of an explosive biogas / air mixture can be safely prevented.

In the following, advantageous embodiments of the invention will be explained in more detail with reference to a drawing. In detail show:

Figure 1 is a highly schematic plan view of an inventive

Biogas plant with a large number of biogas fermenters

Figure 2 is a schematic plan view of an embodiment variant

the biogas plant according to the invention,

Figure 3 is a schematic plan view of an embodiment variant

the biogas plant according to the invention, and

Figure 4 is a schematic plan view of an embodiment variant

the biogas plant according to the invention.

The same components are provided throughout the figures with the same reference numerals. Figure 1 shows a highly schematic plan view of a biogas plant 1 according to the invention, which operates on the principle of dry fermentation. The biogas plant 1 shown here has several biogas fermenters 2a to 2d to

Fermenting or fermentation of pourable fermentation substrates or biomass. In this embodiment, exactly four biogas fermenters 2a to 2d are shown, and the invention is also applicable to less or more biogas digesters.

The biogas fermenters 2a to 2d are operated in so-called batch mode, that is to say that the biomasses to be fermented remain within the biogas fermenters 2a to 2d during the entire fermentation process and the biogas fermenters 2a to 2d are operated at different times. Each of the biogas fermenters 2a to 2d has in each case a gas inlet 3a to 3d for introducing lean gas from a freshly loaded biogas fermenter or oxygen-poor purging gas, the gas inlets 3a to 3d preferably being arranged in the bottom region or near-bottom region of the biogas fermenters 2a to 2d. At a location that is as far away as possible from the gas inlets 3a to 3d, each biogas fermenter 2a to 2d has a gas outlet 4a to 4d for biogas removal. The position or position of the

Gas outlets 4a to 4d to the biogas fermenters 2a to 2d is selected so that the transport path of the introduced lean gas from the respective gas inlet 3a to 3d to the gas outlet 4a to 4d is as long as possible.

The gas outlets 4 a to 4 d of the biogas fermenters 2 a to 2 d are combined via at least one gas line 5 in a gas collecting line 6. About the

Gas collecting line 6 becomes the biogas produced in the biogas plant

Biogas utilization device 6a, such as a cogeneration unit 6a supplied. The combined heat and power plant 6a is connected via an exhaust pipe 6b with the

Gas inlets 3a to 3d connectable. Thus, individual biogas fermenters can selectively exhaust gas as the CHP 6a are supplied as purge gas.

As shown in Figure 1, the biogas plant 1 further has a control device 7. This is in each case via data lines 8a to 8d with a valve device 9a to 9d, which regulates the respective gas inlet at each of the gas inlets 3a to 3d,

connected and is for actuation of the valve means 9a to 9d set up. Next, the control device 7 is in each case by means of further data lines 10a to 10d to a further valve means 1 1 a to 1 1 d, the respective

Gas outlet at each of the gas outlets 4a to 4d regulates, connected and is set up for a corresponding actuation of the valve means 1 1 a to 1 1 d.

The biogas plant 1 also has at least one further valve device 12 which is connected to the control device 7 via a further data line 13. Furthermore, at least one gas transfer line 14 is provided in the biogas plant 1. The gas transfer line 14 can be connected by means of the valve device 12 with one end to at least one of the gas outlets 4a to 4d and with another end to at least one of the gas inlets 3a to 3d of the biogas fermenters 2a to 2d. This means that at least one of the gas outlets 4a to 4d of the

Gas manifold 6 can be separated and instead connected to the gas transfer line 14. In this embodiment, the gas outlet 4 a is connected to the gas inlet 3 b by means of the gas transfer line 14.

The control device 7 is adapted to the gas inlets 3a to 3d, the

Gas outlets 4a to 4d and the valve device 12 for connecting and disconnecting the gas transfer line 14 to control and / or to regulate. In particular, the

Valve device 12 adapted to connect or disconnect the gas transfer line 14 as needed and the respective gas outlet 4a to 4d instead of the

Disconnect or couple gas manifold 6. The needs-based coupling of

Gas transfer takes place by the control device 7, which controls or regulates this process in a time-controlled manner and / or as a function of further parameters. The data for the timing and / or the other parameters are parameterizable, i.

programmable.

The operation of the biogas plant 1 according to the invention can proceed as described below.

The biogas fermenter 2a shown in FIG. 1 was shut down, switched off, emptied after the complete fermentation of a biomass contained therein and is now in a state in which it reacts with a fresh biomass to be fermented loaded or filled. After renewed commissioning of the biogas fermenter 2a, it takes some time until the biogas forming during fermentation has a methane content or a methane concentration which is a meaningful or efficient one

Reuse in a downstream biogas utilization device permits.

Therefore, according to the invention, a transfer takes place in the freshly loaded one

Biogsfermenter 2a produced biogas with low methane content, so-called

Low gas to at least one of the remaining biogas fermenters 2b to 2d. In the control device 7 can be precisely determined for this purpose, whether, when and for how long, i. for what period of time, a compound and / or a transfer of the lean gas from the freshly loaded biogas fermenter 2a in the rest

Biogas fermenter should be made.

If the freshly loaded fermenter 2a is put into operation, controls the

Control device 7 to the gas outlet 4a and the valve device 12 to separate the gas outlet 4a of the gas manifold 6 and instead connect to the gas transfer line 14. The gas transfer line 14 is therefore connected at one end to the gas outlet 4a of the freshly charged biogas fermenter 2a and at the other end to the gas inlet 3b of the biogas fermenter 2b, which produces comparatively higher concentrated biogas. That's how it works

Low gas from the biogas fermenter 2a transferred to the biogas fermenter 2b. This transfer takes place for the time specified in the control device 7. In the freshly loaded biogas fermenter 2a prevails immediately after closing

Ambient pressure while in the biogas with high methane concentration

producing biogas fermenter a slight overpressure prevails. This

Pressure difference causes biogas with high methane concentration flows into the freshly loaded biogas fermenter 2a. While biogas fermenters 2a and 2b are interconnected in this manner, biogas production begins in freshly loaded biogas fermenter 2a and the pressure in freshly loaded biogas fermenter 2a increases until it is greater than the pressure in biogas fermenter 2b. Consequently, first the gas mixture of lean gas and inflowing biogas and finally only the lean gas flows into the biogas fermenter 2b. After expiration of the time period defined in the control device 7, it can be assumed that the biogas produced in the freshly loaded biogas fermenter 2a has a sufficiently high methane concentration so that the gas transfer can be ended. If now the biogas fermenter 2a again connected directly to the biogas manifold 6, the biogas quality or the methane concentration in the biogas manifold remains sufficiently high, ie it is above a certain threshold, the downstream of the

Biogas utilization device depends. If the biogas utilization device is a CHP, the methane content, depending on the gas engine used may not be lower than z. B. fall 40%. The biogas plant 1 is now in normal operation, in which the biogas of all biogas fermenters 2a to 2d of the gas manifold 6 is supplied.

Starting from the illustrated embodiment, can be

Modify process according to the invention and the biogas plant according to the invention in many ways.

A possible modification is shown in FIG. 2, which shows a schematic plan view of the biogas plant 1 according to the invention. Thus, it is possible for the gas outlet 4a of the biogas fermenter 2a to be simultaneously or stepwise connected to the two gas inlets 3b and 3c, i. with more than a single gas inlet the

Biogas fermenter 2b to 2d, is connected. This means that the lean gas from the biogas fermenter 2a can be divided into several of the remaining biogas fermenters 2b to 2d.

Another possible configuration of the biogas plant 1 is shown in FIG. 3, which likewise shows a schematic plan view of the biogas plant 1. According to this embodiment, it is provided that, in addition to the above-described time-dependent control of the biogas transfer, a measurement of certain biogas components also takes place. For this purpose, a measuring device 15 for measuring the concentration of the biogas components of the biogas mixture, in particular the methane concentration, in the biogas collecting line 6 is provided in the gas collecting line 6. The measuring device 15 is connected to the control device 7 by means of a data line 16. Thus, the gas transfer of the freshly loaded biogas fermenter 2a also depending on methane concentration in the biogas manifold 6, controlled and / or regulated. For example, the time determined for the gas transfer can be shortened or extended depending on the measured biogas components. It is also conceivable that the gas transfer is interrupted and resumed.

FIG. 4 shows an alternative embodiment of the biogas plant 1 in one

schematic plan view shown. To construct the biogas plant 1 and in particular the biogas fermenter 2a to 2d structurally simple, is in this

Embodiment provided that the gas transfer line 14 is to be connected to the gas inlets 3a to 3d. In this way, the routing of the

Gas transfer line 14 considerably simplified. In this case, the valve devices 9a to 9d are designed as 3-way valves. In addition, all the valves 10a to 10d can also be designed as 3-way valves, as a result of which the number of components required can be further reduced. Overall, this embodiment represents the simplest and least expensive variant of the biogas plant 1 according to the invention.

When connecting the loaded with fresh biomass biogas fermenter 2a with the gas transfer line 14 initially flows biogas with high methane concentration from the other biogas fermenters 2b to 2d in the biogas fermenter 2a. The biogas production (initially lean gas) in the freshly loaded biogas fermenter 2a starts and the gas pressure in the freshly loaded biogas fermenter 2a increases, so that biogas or lean gas flows from the freshly loaded biogas fermenter 2a into the already biogas-producing biogas fermenter 2 b to 2 d and the lean gas, biogas with low methane concentration, mixes with biogas with high methane concentration. Due to the longer residence time of the lean gas in the biogas plant before it reaches the biogas manifold 6, the change takes place

Methane concentration in the biogas manifold 6 slower, so that the

Gas mixer of a switched after BHKWa 6a with gas engine more time to

Setting a combustible biogas / air mixture has.

In Fig. 4, the freshly loaded biogas fermenter 2a is connected via the gas transfer line 14 with all three remaining Biogasfermentern 2b to 2d. About the Control device 7, it is also possible to connect the freshly loaded biogas fermenter 2a only with one or two of the other three biogas fermenter 2b to 2d.

In the case of a biogas plant with a larger number of biogas fermenters, it is also conceivable that two or more of the biogas fermenters or only with a slight time deviation are refilled with fresh biomass and the

Gas transfer then distributed to the remaining, not freshly filled

Biogas fermenter takes place.

LIST OF REFERENCE NUMBERS

1 biogas plant

2a to 2d biogas fermenter

3a to 3d gas inlets

4a to 4d biogas outlets

5 gas line

6 Biogas pipeline

6a CHP

7 control device

8a to 8d data lines

8a to 9d valve devices

10a to 10d data lines

1 1 a to 1 1 d valve devices

12 valve device

13 data line

14 gas transfer line

15 methane sensor

16 data line

Claims

claims

1 . A method for operating a biogas plant (1) according to the principle of dry fermentation with a plurality of biogas fermenters (2a to 2d), which are run in batch mode, wherein at least one of the biogas digester (2a to 2d) was just loaded with fresh biomass and the or the remaining biogas fermenters (2a to 2d) are in the state of production of higher concentrated biogas, with the process steps:

a) closing the at least one laden with fresh biomass

Biogas fermenter (2a to 2d),

b) connecting the at least one loaded with fresh biomass

Biogas fermenter (2a to 2d) with at least one of the remaining biogas producing biogas fermenters (2a to 2d),

c) recycling the biogas mixture from the at least one fresh

loaded biogas fermenter (2a to 2d) into at least one of the remaining biogas producing biogas fermenters (2a to 2d),

d) terminating the return of the biogas mixture from the freshly loaded biogas fermenter (2a to 2d), after a certain period of time.

2. The method according to claim 1, characterized in that the particular

Programmable duration is stored in a control device (7) and the return and / or termination of the return of the biogas mixture in dependence on this time duration is controlled by the control device (7).

3. The method according to claim 1 or 2, characterized in that the

at least one loaded with fresh biomass biogas fermenter (2a to 2d) is rinsed after closing with a low-oxygen purge gas.

4. The method according to claim 3, characterized in that the purge gas exhaust gas from a biogas fermenters (2a to 2d) downstream

Blockheizkraftwerk (6a) or a gas treatment device is supplied.

5. The method according to any one of the preceding claims, characterized in that the return of the biogas mixture by an adjusting pressure gradient between the at least one freshly loaded biogas digester (2a to 2d) and the at least one of the remaining

Biogas fermenter (2a to 2d) takes place.

6. The method according to any one of the preceding claims, characterized

characterized in that for determining the particular period of time

Methane concentration in the biogas mixture from all biogas fermenters (2a to 2d) is measured.

7. The method according to any one of the preceding claims, characterized in that between the point at which the at least one remaining biogas fermenter (2a to 2d), the biogas mixture from the at least one freshly loaded biogas digester (2a to 2d) is supplied, and the body, at which the more highly concentrated biogas is removed from the at least one remaining biogas fermenter (2a to 2d), the greatest possible distance is provided.

8. biogas plant (1), in particular for carrying out the method according to one of the preceding claims, with a plurality of working on the principle of dry fermentation biogas digester (2a to 2d) for the production of biogas in batch operation, each biogas fermenter a biogas outlet (4a to 4d) and a gas inlet (3a to 3d), and the biogas outlet (4a to 4d) of at least one biogas fermenter (4a to 4d) by means of a

Gas return line (14) and a valve device (12) with the biogas inlet (3a to 3d) of at least one further biogas fermenter (2a to 2d) for a certain period of time is connectable.

9. biogas plant according to claim 8, characterized in that the

Biogas outlets (4a to 4d) are combined in a biogas manifold and that in the biogas manifold a methane concentration sensor is provided.

10. biogas plant according to one of claims 8 or 9, characterized by a control device (7) for controllably connecting the gas return line (14) of one of the biogas digester (2a to 2d) with the gas inlet (3a to 3d) of at least one of the remaining biogas digester ( 2a to 2d).

1 1. Biogas plant according to one of claims 8 to 10, characterized in that the gas inlet (3a to 3d) and the biogas outlet (4a to 4d) of the

Biogas fermenter (2a to 2d) as far apart as possible and

in particular at opposite ends of the respective biogas fermenter (2a to 2d) are arranged.

12. Biogas plant according to one of claims 8 to 1 1, characterized in that the gas inlet (3a to 3d) in the bottom region of the respective biogas fermenter (2a to 2d) is arranged.

13. Biogas plant according to one of claims 8 to 12, characterized in that the at least one loaded with fresh biomass biogas fermenter (2a to 2d) is connectable to a source of oxygen-poor purge gas.