DE102014222703B4 - Method for desulfurization of biogas and biofermenter comprising a device for desulfurization of biogas - Google Patents

Abstract

Process for the desulfurization of biogas, characterized in that during the anaerobic fermentation of biomass in a biogas fermenter (10) in a gas space (12) above a substrate space (14) a receiving system (11) is arranged, which with biodegradable carrier bodies (17) , which are inoculated with hydrogen sulfide-degrading microorganisms and / or are suitable for settling hydrogen sulfide-degrading microorganisms is filled, that the biogas formed by the fermentation flows through the receiving system (11) with the carrier bodies (17), which is desulfurized by the microorganisms, and in the biogas fermenter (10) air is registered.

Description

The invention relates to a process for the desulfurization of biogas and a biofermenter comprising a device for the desulfurization of biogas.

In the operation of biogas plants biogenic substrates are implemented, in addition to the desired biogas depending on the protein content of the substrate u.a. also hydrogen sulfide is formed. In a thermal utilization of biogas, the hydrogen sulfide is oxidized to sulfur dioxide, which is toxic and corrosive, so that as comprehensive as possible elimination of hydrogen sulfide and other sulfur-containing compounds from the biogas is sought.

There are known for desulfurization of biogas internal and external desulfurization process guides based on a biogas plant, wherein the oxygen required for the oxidation is usually introduced via an air flow in the biogas digester.

Also, the chemical sorption of hydrogen sulfide to iron salts is used for desulfurization. Here, the hydrogen sulfide is bound in the form of iron sulfide.

In the DE 102011081522 A1 describes a desulfurization process directly in a biogas fermenter during an anaerobic fermentation of biomass, wherein at the interface between the liquid and gas phase porous, biodegradable populated with sulfur-oxidizing microorganisms, floatable carrier body and form an artificial functional layer. The biogas formed in the anaerobic fermentation is desulfurized on site as it flows through the functional layer.

In some biogas plants, beamed ceilings or belt / grid constructions for sulfur bacteria serve as colonization surfaces. In DE 202011000577 U1 and DE 102012100893 A1 a gas-permeable surface element defined mesh size is described, which spans the interior of a biogas container. During the operation of the biogas plant, the underside of the surface element is colonized by bacteria, which decompose the sulfur contained in the biogas. In the DE 202007018608 U1 describes a biogas reactor made of concrete, in which the inner wall of the reactor is covered with a plastic film to protect the building substance, which serves as a colonization surface for a spontaneous settlement of hydrogen sulfide-degrading microorganisms.

Also known are fiber materials such as felts, wipes and nonwovens as materials for bacterial colonization of biological reactive filters, such as in the DE 102011050167 A1 described.

For external desulfurization various filter materials are still known, such as in the DE 102006035286 A1 and DE 202008003542 A1 disclosed. Further state of the art are the EP 1970434 A1 and DE 102011106309 A1 ,

It is an object of the invention to provide a method and a biofermenter comprising a device for desulfurization of biogas, which increases the biogas quality, supports the methane formation process and prolongs the life of a biogas fermenter.

This object is achieved by a method and a Biogasfermenter with the features of claim 1 or 4.

According to the invention, there is provided a process for the desulfurization of biogas, in which a receiving system is arranged in the gas space above the substrate space during the anaerobic fermentation of biomass in a biogas fermenter having a substrate space and a gas space arranged above it, with biologically degradable carrier bodies, which are inoculated with hydrogen sulfide degrading microorganisms and / or are suitable for the settlement of hydrogen sulfide-degrading microorganisms is filled. The biogas formed by the fermentation flows through the receiving system with the carrier bodies, wherein the biogas is desulfurized by the microorganisms. In addition, air is introduced into the biogas fermenter, preferably the gas space.

The introduction of oxygen into the gas phase takes place according to the stoichiometric demand for biological desulphurisation.

In the presence of atmospheric oxygen settle biogas fermenters on all available surfaces in the gas space hydrogen sulfide-degrading microorganisms, so that seeding of the carrier body is not absolutely necessary, but this can significantly accelerate the implementation of sulfur compounds in the initial phase of the process.

The biogas fermenter according to the invention has a device for the desulfurization of biogas, which has a receiving system which is arranged during the anaerobic fermentation of biomass in the biogas fermenter in a gas space above a substrate space and with biologically degradable carrier bodies, which are inoculated with hydrogen sulfide-degrading microorganisms and / or are suitable for the settlement of hydrogen sulfide-degrading microorganisms is filled.

The statements relate equally to the method according to the invention and the biogas fermenter according to the invention.

The subdivision of the biogas fermenter into a substrate space and a gas space results from the filling level of the biogas fermenter with substrate. Therefore, the substrate space and the gas space have variable sizes, with the sum of the volumes of the substrate space and the gas space always remaining the same.

The receiving system is preferably arranged exclusively in the gas space, but may, for example, by a corresponding level of the substrate space, the receiving system also partially protrude for advantageous embodiment of the method according to the invention in the substrate space.

The receiving system has a plurality of openings which are such that in the receiving system, a gas exchange is made possible and at the same time the carrier body therein are retained.

The pickup system is preferably subdivided into a plurality of picking systems to enable a needs-based design of the pickup system. The sub-recording systems each have the same features as described for the recording system.

Preferably, the receiving system and the sub-recording systems consist of hoses with a net-like structure. According to the selected suspension, the receiving system consists of at least one hose or a plurality of hoses arranged one above the other or a chain of interconnected hoses. The hoses can then be guided along the wall of the biogas fermenter, wherein a plurality of hose chains can be arranged one above the other and the diameter of the hoses can be varied.

If the hoses are fixed to a common bracket, they hang down individually in the gas space. Again, an arrangement along the wall can be made or distributed over the cross-sectional area of the gas space. Preferably, then the hoses at a distance from each other.

It is advantageous to design the receiving system such that it covers a larger portion of its cross-sectional area with increasing height of the gas space.

The diameter of a single tube and the size of the openings are preferably based on the geometry of the carrier body.

In addition, the receiving system preferably has an inlet and optionally an outlet opening, so that the carrier body can be introduced easily and also a refilling of carrier bodies is possible. In addition, carrier bodies consumed by the outlet opening can be brought into the substrate space and serve as a substrate for biogas production.

The receiving system is such that it fills the cross section of the gas space up to 90%. Thus, the biogas obtained can advantageously reach from all sides to the carrier body located in the receiving system, so that a rapid conversion of the sulfur compounds is made possible.

If the receiving system is subdivided into partial receiving systems, they preferably have a mutual spacing in order to offer the largest possible contact surface for the biogas.

The receiving system is preferably made of ferrous and / or biodegradable materials. Ferrous also means the presence of iron compounds which, like iron, allow for chemical sorption of hydrogen sulphide. Corresponding compounds are known from the prior art, as well as corresponding biodegradable materials.

The material of the recording system is otherwise designed so that it is suitable for a single or multiple use. In a single use of the recording system, the biodegradability is preferably adapted to the service life of the carrier body, wherein the material of the receiving system and the carrier body itself can serve as a substrate for biogas production.

The hydrogen sulfide adsorbing and / or biodegradable materials of the receiving system provide good conditions for the settling and growth of hydrogen sulfide degrading microorganisms due to the composition and the ability to absorb water and nutrients. The recording system thus complements the cleaning mechanisms of the carrier body.

The filling or replacement of the receiving system is controlled by a control value of the hydrogen sulfide concentration in the desulfurized biogas. For this purpose, appropriate facilities, such as sensors valves, control devices and the like are provided.

The biogas desulfurization according to the invention requires easily to flow through carrier body with the lowest possible pressure losses. The carrier body present in the receiving system has defined properties with regard to hydrogen sulfide elimination rate, grain size, porosity, volume surface ratio, mechanical strength and biodegradability.

Cellulose-containing materials or biodegradable plastics are used as biodegradable carrier body with various functional substances, which are described in detail in the DE 102011081522 A1 are described, the disclosure of which is part of this application.

The biodegradable carrier bodies are preferably made of renewable raw materials such as starch, in particular cereal, potato or corn starch, so that they can ultimately be converted into biogas in the biogas fermenter.

The carrier bodies are preferably mixed with a hydrophobing agent in order to limit the absorption of moisture in the gas space of the biogas fermenter, so that the carrier bodies remain loosely layered in the receiving system. Thus, a flow through the receiving system with biogas can be ensured with a very low flow resistance.
When the hydrophobing in the receiving system has subsided, the carrier bodies sink or collapse and, for example, also serve as a further substrate for the anaerobic fermentation in the case of direct contact of the receiving system with the substrate, as a result of which the carrier body can be removed free of residues.

The hydrophobing agent is preferably selected from acetylated starch, polystyrene, polyamide, polyethylene, polyester, polyester amide, polyester urethane, polyvinyl alcohol, polyhydroxy fatty acid, polylactic acid or mixtures thereof, wherein the water repellents preferably also biodegradable substances are used. Particularly preferred are acetylated starch or plastic recyclates such as polyamide or polystyrene.

The carrier bodies are preferably inoculated with chemolithoautotrophic microorganism strains, in particular with one or more of the strains Acidithiobacillus thiooxidans, Acidithiobacillus ferrooxidans, Thiobacillus thioparus and Sulfolobus speci ..

In a particularly advantageous embodiment, the carrier bodies may contain, in addition to the sulfur-oxidizing microorganisms, sorbents for the chemical sorption of the hydrogen sulfide.

The sorbents used are preferably metal compounds, preferably iron compounds which bind H ₂ S as sulfide. Iron compounds which are preferred for this purpose are, for the purposes of the invention, iron hydroxide, iron salts such as, for example, iron chloride or iron powder, very particularly preferably iron hydroxide.

Through these compounds, the hydrogen sulfide can be known to be bound as sulfide and in the presence of sulfur-oxidizing microorganisms, the sorbent, so for example, the iron hydroxide, advantageously partially regenerated.

In a further preferred embodiment of the carrier body, these may also contain antifoams and / or substances for pH regulation and / or nutrients for the microorganisms.

Advantageously, the metabolic products formed during the desulfurization, for example sulfur, reacted carrier bodies or materials of the receiving system reach the substrate space. Metabolites that are not converted anaerobically are removed from the fermenter with the digestate.

The invention provides more process reliability, economy, gas quality and safety.

Further advantageous embodiments of the invention are characterized in the subclaims.

• 1 in einer Seitenansicht ein Biogasfermenter mit einem horizontal angeordneten Aufnahmesystem,
• 2 in einer Aufsicht das Aufnahmesystem des Biogasfermenters gemäß 1, mit Trägerkörpern,
• 3 in einer Seitenansicht ein Biogasfermenter mit einem Aufnahmesystem aus mehreren vertikal angeordneten Teilaufnahmesystemen, und
• 4 in einer Seitenansicht ein Teilaufnahmesystem des Biogasfermenters gemäß 3.

The invention will be explained in more detail with reference to drawings. Show it

• 1 in a side view of a biogas fermenter with a horizontally arranged receiving system,
• 2 in a plan view of the biogas fermenter receiving system according to 1 , with carrier bodies,
• 3 in a side view of a biogas fermenter with a recording system of several vertically arranged parts receiving systems, and
• 4 in a side view of a partial receiving system of biogas fermenter according to 3 ,

In 1 is a biogas fermenter 10 shown, a horizontally oriented hose-like recording system 11 that is in the gas space 12 of the biogas fermenter 10 on the wall 13 of the biogas fermenter 10 is arranged circumferentially. The gas space 12 is located above the substrate space 14 in which the substrate used for biogas production, but which is not shown here, is located. The substrate boundary 15 between gas space 12 and substrate space 14 is dependent on the level of the biogas fermenter 10 variable with substrate. The recording system 11 consists of a hose that is in 2 is shown in detail. This one is with carrier bodies 17 filled by hydrogen sulfide degrading microorganisms. The hose is made of a ferrous and / or biodegradable material with a multitude of openings in 2 are not shown. By using several superimposed hoses remains a free area 18 that is not the recording system 11 is covered, so that arising biogas freely in the gas space 12 distribute and from all sides to the carrier body 17 can get.

Otherwise, the biogas digester points 10 usual facilities, with exemplified a gas line 19 with a valve 20 as well as a sensor 21 for measuring the concentration of hydrogen sulfide are shown. The in 3 illustrated biogas fermenter 10 corresponds to the design of the recording system 11 the in 1 shown biogas fermenter 10 , With regard to the matching features, reference is therefore made to the description of 1 directed. A detail of the recording system 11 of the biogas fermenter 10 according to 3 will be in detail in 4 shown. The recording system 11 consists of a large number of tubular part picking systems 22 (Hose chain ( 16 )), which are suspended in the gas space 12 are arranged. For suspension of the part pick-up systems 22 is a holder 23 provided, either at the edge of the gas space 12 circulating or over the entire gas space 12 is formed extending. The component receiving systems 22 can therefore be relatively arbitrary in the gas space 12 Arrange. The only thing that matters is that the recording system 11 not the cross section of the gas space 12 completely covers. Also advantageous is a distance between the sub-recording systems 22 in order not to inhibit the flow through the biogas as possible. The component receiving systems 22 consist of a chain of individual hoses (hose chain ( 16 )) from iron-containing and / or biodegradable materials that receive the carrier body 17 with the hydrogen sulfide-degrading microorganisms. In the submission systems 22 There are a variety of openings provided by a grid structure 24 , in the 4 is reproduced, are shown schematically. Depending on the substrate quality with respect to the sulfur constituents or the level of the filling level, the partial receiving systems 22 also in the substrate space 14 plunge.

LIST OF REFERENCE NUMBERS

biogas fermenter 10 recording system 11 headspace 12 wall 13 substrate space 14 substrate boundary 15 hose chain 16 support body 17 free area 18 gas pipe 19 Valve 20 sensor 21 Part recording system 22 bracket 23 lattice structure 24

Claims (15)

Process for the desulfurization of biogas, characterized in that during the anaerobic fermentation of biomass in a biogas fermenter (10) in a gas space (12) above a substrate space (14) a receiving system (11) is arranged, which with biodegradable carrier bodies (17) , which are inoculated with hydrogen sulfide-degrading microorganisms and / or are suitable for settling hydrogen sulfide-degrading microorganisms is filled, that the biogas formed by the fermentation flows through the receiving system (11) with the carrier bodies (17), which is desulfurized by the microorganisms, and in the biogas fermenter (10) air is registered. Method according to Claim 1 , characterized in that the receiving system (11) is arranged partially in the substrate space (14). Method according to Claim 1 or 2 , characterized in that the receiving system (11) occupies a maximum of 10% of the cross-sectional area of the gas space (12). Biogas fermenter comprising a device for the desulfurization of biogas, characterized in that the device comprises a receiving system (11) which is arranged during the anaerobic fermentation of biomass in the biogas fermenter (10) in a gas space (12) above a substrate space (14), which is filled with biodegradable support bodies (17) which are inoculated with hydrogen sulfide-degrading microorganisms and / or are suitable for the settlement of hydrogen sulfide-degrading microorganisms. Biogas fermenter after Claim 4 , characterized in that the receiving system (11) has a plurality of openings which allow a gas exchange and the carrier body (17) retain. Biogas fermenter after Claim 4 or 5 , characterized in that the receiving system (11) consists of several sub-recording systems (22). Biogas fermenter after one of Claims 4 to 6 , characterized in that the receiving system (11) or the sub-receiving systems (22) consist of hoses, which are combined into a chain, or which are fixed at one end to a holder (23), which in the gas space (12) is suspended are. Biogas fermenter after one of Claims 4 to 7 , characterized in that the receiving system (11) or the partial receiving systems (22) have an inlet and optionally an outlet opening. Biogas fermenter after one of Claims 4 to 8th , characterized in that the receiving system (11) or the partial receiving systems (22) consist of ferrous and / or biodegradable materials. Biogas fermenter after Claim 9 , characterized in that the biodegradable material of the carrier body (17) is starch, preferably cereal starch, potato starch, corn starch or mixtures thereof. Biogas fermenter after one of Claims 4 to 10 , characterized in that the carrier bodies (17) are provided with a hydrophobizing agent. Biogas fermenter after one of Claims 4 to 11 , characterized in that the carrier bodies (17) comprise metal compounds for the chemical sorption of hydrogen sulphide. Biogas fermenter after one of Claims 4 to 12 , characterized in that the carrier bodies (17) have antifoams and / or pH-regulating substances and / or nutrients for sulfur-oxidizing microorganisms. Biogas fermenter after one of Claims 4 to 13 , characterized in that the carrier bodies (17) are inoculated with chemolithoautotrophic microorganisms. Biogas fermenter according to claim 14, characterized in that the carrier bodies (17) are inoculated with a mixture of the microorganisms Acidithiobacillus thiooxidans and Acidithiobacillus ferrooxidans.

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