3.3 Feedstock C:N ratio - Humanitarian Sanitation Hub

Biogas Sanitation

Biogas Sanitation: Course at a Glance
1 Basics of Anaerobic Digestion
14 Topics | 8 Quizzes
1.1 What is anaerobic digestion?
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1.2 What is biogas?
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1.3 Methane and Contribution to global warming
Quiz 1
Quiz 2
1.4 Feedstock Materials and Biogas Production
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1.4.1 Biodegradability of various feedstock
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1.5 Process of anaerobic digestion
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1.6 What are the benefits and limitations of anaerobic digestion?
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1.7 What are the possible applications for biogas?
1.7.1 Cooking
1.7.2 Lighting
1.7.3 Electricity Generation
1.7.4 Cooling
1.7.5 Biomethane Fuel
1.7.6 Thermal Application
2 Digestion Technologies and Types
9 Topics | 8 Quizzes
2.1 Digestion Technologies and Types
2.2 General Classifications
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2.3 Overview of different digesters
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2.3.1 Fixed Dome Digester
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2.3.2 Floating Dome Digester
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2.3.3 Balloon-Type Digester
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2.4 Overview of different types of biogas sanitation units
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2.4.1 Anaerobic baffled reactor with biogas capture
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2.4.2 Anaerobic Lagoon
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3 Process Parameters
13 Topics | 12 Quizzes
3.1 The Process Parameters
3.2 Temperature
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3.3 Feedstock C:N ratio
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3.4 TS and VS, COD and BOD
3.4.1 Total and Volatile Solids
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3.4.2 Chemical Oxygen Demand (COD) & Biochemical Oxygen Demand (BOD)
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3.4.3 pH
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3.4.4 Organic loading rate
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3.4.5 Hydraulic and solid retention time
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3.5 What is biological methane potential, and why is it important?
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3.6 What is the difference between biomethane potential, methane yield, and methane production?
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3.7 What is the biogas potential of various substrates?
3.8 How to measure or estimate the biogas or biomethane potential?
Quiz 1.1
Quiz 1.2
Quiz 2
4 Biogas Installation Planning
10 Topics | 2 Quizzes
4.1 Social acceptance
4.2 Feedstock availability
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4.3 Feedstock quality
4.4 Biogas Plant Design: An Exercise
4.4.1 Potential Biogas Generation, Utilisation and treatment
4.4.2 Sizing of the digester
4.4.3 Sizing of gasholder
4.4.4 Planning Effluent Management
4.4.5 What is to be done if there is no available space for post-treatment?
4.4.6 Planning Sludge Management
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5 Operation and Maintenance
4 Topics | 2 Quizzes
5.1 Initial Testing
5.2 Startup
5.3 O&M Tasks
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5.4 Safety
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6 Sanitation Biogas Plants in Rohingya Refugee Camp
10 Topics | 9 Quizzes
6.1 Biogas Generation
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6.1.1 Biogas Potential
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6.2 Use of Biogas
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6.3 Treatment Performance
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6.4 Identified Challanges and Possible Solutions
6.4.1 Clogging
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6.4.2 Accumulation of Condensed Water Within the Gas Pipes
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6.4.3 Hydrogen Sulphide
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6.4.4 Gas Leakages
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6.4.5 Effluent Management
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3.3 Feedstock C:N ratio

Biogas Sanitation 3 Process Parameters 3.3 Feedstock C:N ratio
       Video: https://youtu.be/l8tLHLBuzMc

Carbon (C) and Nitrogen (N) are both essential nutrients for anaerobic digestion. Carbon is a key component of organic matter and acts as an energy source for the microorganisms involved in anaerobic digestion (AD), while Nitrogen is an essential nutrient for microbial growth and reproduction.

The ratio of carbon to nitrogen, known as the C:N ratio, is a critical parameter in AD. It determines the balance between carbon availability and nitrogen content in the feedstock. An optimal C:N ratio between 16 and 25, ensures that there is enough carbon for energy production while providing an adequate nitrogen supply for microbial growth. If the C:N ratio is unbalanced, either too high or too low, it can negatively impact the AD process, leading to reduced gas production, inhibition of microbial activity, or process instability.

The following table presents C:N ratios for different organic materials.

Organic materialC:NSource
Human excreta6 – 14:1(Oxfam , 2011)
Faecal sludge5:1(Warda J. B., 2021)
Vegetable residue 12 – 30:1(Oxfam , 2011)
Cow manure6 – 14:1(Oxfam , 2011)
Chicken droppings5 – 9:1(Oxfam , 2011)
Fresh grass12 – 30:1(Oxfam , 2011)
C:N ratio of Different Feedstocks

While a C:N ratio for excreta and faecal sludge is generally considered low for optimal AD, the process works because of the ability of methanogenic bacteria to adapt to high concentrations of ammonia. However, biogas production may be less efficient than the optimal C:N ratio. If higher biogas yields are desired, it is generally recommended to aim for a higher C:N ratio by introducing additional organic waste with a higher C:N ratio, such as food waste or agricultural residues, to increase the overall C:N.

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