Difference between revisions of "Anaerobic digestion"
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=== Process === | === Process === | ||
There are three basic anaerobic digestion processes, namely psychrophilic, mesophilic, and thermophilic, which take place over different temperature ranges. Psychrophilic digestion is a low temperature (<20°C) process. Mesophilic digestion takes place between 20 and 45°C, which can take a month or two to complete, and thermophilic digestion between 45 and 65°C, which is faster, but its micro-organisms are more sensitive. The majority of the agricultural biogas plants are operated at mesophilic temperatures. Thermophilic temperatures are applied mainly in large-scale centralised biogas plants with co-digestion<ref>{{Cite web|year=2021|title=Anaerobic digestion|e-pub date=2021|date accessed=6/9/2021|url=https://www.eubia.org/cms/wiki-biomass/anaerobic-digestion/}}</ref>. | There are three basic anaerobic digestion processes, namely psychrophilic, mesophilic, and thermophilic, which take place over different temperature ranges. Psychrophilic digestion is a low temperature (<20°C) process. Mesophilic digestion takes place between 20 and 45°C, which can take a month or two to complete, and thermophilic digestion between 45 and 65°C, which is faster, but its micro-organisms are more sensitive. The majority of the agricultural biogas plants are operated at mesophilic temperatures. Thermophilic temperatures are applied mainly in large-scale centralised biogas plants with co-digestion<ref>{{Cite web|year=2021|title=Anaerobic digestion|e-pub date=2021|date accessed=6/9/2021|url=https://www.eubia.org/cms/wiki-biomass/anaerobic-digestion/}}</ref>. The process of anaerobic digestion takes place through four successive stages: hdyrolysis, fermentation, acetogenesis, and methanogenesis.<ref>{{Cite journal|author=Junye Wang|year=2014|title=Decentralized biogas technology of anaerobic digestion and farm ecosystem: opportunities and challenges|journal=Fronties in Energy Research|volume=2|page=|doi=10.3389/fenrg.2014.00010}}</ref> In the hydrolysis step, the feedstock is broken down into soluble substrates (e.g., sugar and amino acids) by enzymes. Fermentation involves the conversion of sugar, amino acids, and fatty acids into ammonia, organic acids, hydrogen (H<sub>2</sub>) and CO<sub>2</sub>. In the acetogenesis step, volatile fatty acids are broken down into acetic acids, CO<sub>2</sub> and H<sub>2</sub>. Finally, methanogenesis step converts acetate, formaldeyde, and H<sub>2</sub> to CH<sub>4</sub> and water<ref>{{Cite journal|author=Jay N. Meegoda, Brian Li, Kush Patel, Lily B. Wang|year=2018|title=A review of the Processes, Parameters, and Optimization of Anaerobic Digestion|journal=International Journal of Environmental Research and Public Health|volume=15|page=|doi=10.3390/ijerph15102224}}</ref>. | ||
[[File:Anaerobic stages.png|thumb|Simplified scheme of pathways in anaerobic digestion (not own work)]] | |||
Usually, the produced biogas must be dried and drained for condense water and biological or chemical cleaned for H<sub>2</sub>S, NH<sub>3</sub> and trace elements. Further upgrading of the biogas to increase the CH<sub>4</sub> content could be realized by membrane separation of CO<sub>2</sub> and pressurising the biogas. | |||
== Product == | == Product == | ||
Anaerobic digestion produces two valuable outputs, namely biogas and digestate. Biogas is composed of methane (CH<sub>4</sub>), which is the primary component of natural gas, at a relatively high percentage (50 to 75%), carbon dioxide (CO<sub>2</sub>), hydrogen sulfide (H<sub>2</sub>S), water vapor, and trace amounts of other gases. The energy in biogas can be used like natural gas to provide heat, generate electricity, and power cooling systems. Biogas can also be purified by removing the inert or low-value constituents (CO<sub>2</sub>, water, H<sub>2</sub>S, etc.) to generate renewable natural gas (RNG). This can be sold and injected into the natural gas distribution system, compressed and used as vehicle fuel, or processed further to generate alternative transportation fuel or other advanced biochemicals and bioproducts. | Anaerobic digestion produces two valuable outputs, namely biogas and digestate. Biogas is composed of methane (CH<sub>4</sub>), which is the primary component of natural gas, at a relatively high percentage (50 to 75%), carbon dioxide (CO<sub>2</sub>), hydrogen sulfide (H<sub>2</sub>S), water vapor, and trace amounts of other gases. The energy in biogas can be used like natural gas to provide heat, generate electricity, and power cooling systems. Biogas can also be purified by removing the inert or low-value constituents (CO<sub>2</sub>, water, H<sub>2</sub>S, etc.) to generate renewable natural gas (RNG). This can be sold and injected into the natural gas distribution system, compressed and used as vehicle fuel, or processed further to generate alternative transportation fuel or other advanced biochemicals and bioproducts. |
Revision as of 12:33, 6 September 2021
Anaerobic digestion is a process through which micro-organisms break down organic matter, such as animal manure, wastewater biosolids, and food wastes, in the absence of oxygen. Anaerobic digestion intended for biogas production takes place in a sealed tank (called an anaerobic digester), which is designed and constructed in various shapes and sizes specific to the site and feedstock conditions. These sealed vessels contain complex microbial communities that break down the waste and produce biogas and digestate (i.e., the solid and liquid material end-products of the process).
Feedstock
Process and technologies
Process
There are three basic anaerobic digestion processes, namely psychrophilic, mesophilic, and thermophilic, which take place over different temperature ranges. Psychrophilic digestion is a low temperature (<20°C) process. Mesophilic digestion takes place between 20 and 45°C, which can take a month or two to complete, and thermophilic digestion between 45 and 65°C, which is faster, but its micro-organisms are more sensitive. The majority of the agricultural biogas plants are operated at mesophilic temperatures. Thermophilic temperatures are applied mainly in large-scale centralised biogas plants with co-digestion[1]. The process of anaerobic digestion takes place through four successive stages: hdyrolysis, fermentation, acetogenesis, and methanogenesis.[2] In the hydrolysis step, the feedstock is broken down into soluble substrates (e.g., sugar and amino acids) by enzymes. Fermentation involves the conversion of sugar, amino acids, and fatty acids into ammonia, organic acids, hydrogen (H2) and CO2. In the acetogenesis step, volatile fatty acids are broken down into acetic acids, CO2 and H2. Finally, methanogenesis step converts acetate, formaldeyde, and H2 to CH4 and water[3].
Usually, the produced biogas must be dried and drained for condense water and biological or chemical cleaned for H2S, NH3 and trace elements. Further upgrading of the biogas to increase the CH4 content could be realized by membrane separation of CO2 and pressurising the biogas.
Product
Anaerobic digestion produces two valuable outputs, namely biogas and digestate. Biogas is composed of methane (CH4), which is the primary component of natural gas, at a relatively high percentage (50 to 75%), carbon dioxide (CO2), hydrogen sulfide (H2S), water vapor, and trace amounts of other gases. The energy in biogas can be used like natural gas to provide heat, generate electricity, and power cooling systems. Biogas can also be purified by removing the inert or low-value constituents (CO2, water, H2S, etc.) to generate renewable natural gas (RNG). This can be sold and injected into the natural gas distribution system, compressed and used as vehicle fuel, or processed further to generate alternative transportation fuel or other advanced biochemicals and bioproducts.
The digestate can be used in many beneficial applications provided that is is appropriately treated post processing. This could be in form of animal bedding, nutreint-rich fertilizer, organic-rich compost, or as soil amendment.
Technology providers
CCS
CCS Enegie-advies together with Greenmac developed the Bio-UP technology which is able to upgrade the produced biogas into green gas. CCS offers the Bio-UP technology via lease contracts or turn-key. The Bio-UP is a proven concept which already operates at "melkveeproefbedrijf De Marke".
Biogas Plus
General information | |||
Company: | Biogas Plus | Webpage: | https://www.biogasplus.nl |
Location: | Venray (NL) | Business-Model: | |
TRL: | 9 | Patent: | |
Technology name: | Compact Plus | Technology category: | |
Technology and process details | |||
Reactor: | Isolated concrete tank with double-membrane isolated roof. Two agitators | Heating: | |
Atmosphere: | Pressure: | bar | |
Capacity: | 18.000 tons (input), 320.000 Nm3 green gas/year (output). | Temperature: | °C |
Catalyst: | Other: | ||
Feedstock and product details | |||
Feedstock: | Animal manure | Product: | Green gas |
Pre-treatments: | Post-treatments: | Biogas upgrading (integrated) |
Host
Planet Biogas
Envitec
References
- ↑ , 2021: Anaerobic digestion 2021, Last access 6/9/2021. https://www.eubia.org/cms/wiki-biomass/anaerobic-digestion/
- ↑ Junye Wang, 2014: Decentralized biogas technology of anaerobic digestion and farm ecosystem: opportunities and challenges. Fronties in Energy Research, Vol. 2, . doi: https://doi.org/10.3389/fenrg.2014.00010
- ↑ Jay N. Meegoda, Brian Li, Kush Patel, Lily B. Wang, 2018: A review of the Processes, Parameters, and Optimization of Anaerobic Digestion. International Journal of Environmental Research and Public Health, Vol. 15, . doi: https://doi.org/10.3390/ijerph15102224