B i o g a s f o r a g r i c u l t u r e

Similar documents
ANEROBIC DIGESTION and BIOGAS

February Biogas as a grid stabilising power source

Bio-CNG plant. Spectrum Renewable Energy Limited, Kodoli, Kolhapur

NAWARO BioEnergie AG: a short introduction into our business for BiG>East: Biogas for Eastern Europe

Papapostolou 1, E. Kondili 1, J.K. Kaldellis 2

Sustainable production of biogas and bioethanol from waste

Biogas as transportation fuel

Energy from digester gas. Optimised biogas utilisation

EVALUATION OF BIOGAS PRODUCTION POTENTIAL FROM ELEPHANT DUNG

INTERIM TECHNICAL REPORT FIRST 18 MONTH PERFORMANCE SUMMARY FOR ANAEROBIC DIGESTION OF DAIRY COW SLURRY AT AFBI HILLSBOROUGH

Poultry manure as a substrate for methane fermentation: problems and solutions

Biogas. creating the future

The Value of Small Digester Technology

Biogas plant Venaria Reale (I) Reference Plant. Customer. Plant data. Commissioned: La Bellotta Soc. Semplice Agricola (I)

Lesson 6. BioMara gratefully acknowledges the following funders: Content Section - How Algae can be used to produce Biofuel.

Green Gases Practical concepts for reliable sustainable energy supply

SIX REASONS TO DRY BIOGAS To A LOW DEWPOINT BEFORE COMBUSTION IN A CHP ENGINE STEVEN SCOTT MARKET DEVELOPMENT MANAGER ALTERNATIVE ENERGIES

Biogas plants with decentralized bioenergy centres

Comparative study of biogas production from cow dung, cow pea and cassava peeling using 45 litres biogas digester

Subject: Life Science- Advanced Biology 2 Standard: Cellular Processes

Bio renewable Resources Platform. Ton Runneboom, Chairman

Holsworthy (Summerleaze) Biogas Plant

AP ENVIRONMENTAL SCIENCE 2009 SCORING GUIDELINES

Electricity: biogas may be used to generate electricity using a gas electric generator set or natural gas boiler system. Electricity may either be

Denmark Country Report

Biogas - Trends in Germany Biogas as a key in future energy systems

A Digester for the 125 Cow Dairy: Fact or Fiction?

Biogas. Biology Teams of 2 or 3. Grade LEARNING OUTCOMES DESCRIPTION MATERIALS READINESS ACTIVITIES. Science

Looking to the Future: 4 Danish scenarios for future farming

Zhangbei Green Data Center

Process Technology. Advanced bioethanol production and renewable energy generation from ligno-cellulosic materials, biomass waste and residues

Why Insurance Cost are Rising for Biogas Power Generation Plants

Alternative fuels. The way forward

Examples for financing of biogas projects in Italy

Anaerobic Digestion: Biology and Benefits

Introduction to Waste Treatment Technologies. Contents. Household waste

Large Biogas Plants in Denmark -technology and operation experience

Towards climate-smart agriculture

Consultation response: PPC Technical Guidance Note 35 Anaerobic Digestion

FACTS ABOUT CLIMATE CHANGE

Farm Animal Manure is an Important Sustainable Renewable Energy Resource

Business strategy: dal progetto Pro.E.Sa agli investimenti per la realizzazione degli impianti

Rainwater Harvesting

Renewable energy in transport

The Contribution of Global Agriculture to Greenhouse Gas Emissions

O 2. What is anaerobic digestion?

Biomass Renewable Energy from Plants and Animals

biogas Action Sheet 66

EnviTec Biogas Energy from Agricultural and Agro-Industrial Wastes. Eng. Marcello Barbato Sales Manager

an overview of trends and approaches

BIOREMEDIATION: A General Outline Mitchell E. Daniels, Jr.

Biogas in the Nordic countries

Protection of the South Baltic Sea through the reduction of emission coming from agricultural waste pollution.

Bottom-up: Responding to climate change through livestock in integrated agriculture

Harvesting energy with fertilizers

Power Generation from Biogas Energy Provider Perspective

Biogas production in Germany: Status quo and future trends M.Sc. Georg Friedl, German Biogas Association

Natural gas and renewable gases

Waste to Energy. Patrick Grange. Copyright CIBSE MNW Region 1. Rural, Business and Renewable Energy Consultants

November, 26 th 2009 EU-AGRO-BIOGAS Symposium. Energy Recovery and Reduction of GHG Emission by the Coverage

CAT CG132. Series Gas Generator Sets

EMISSIONS OF AIR POLLUTANTS IN THE UK, 1970 TO 2014

Community Renewable Energy

Bioremediation. Biodegradation

LANDFILL GAS TO ENERGY- COMBINED ENGINE AND ORC-PROCESS

An Introduction to Anaerobic Digestion of Organic Wastes

SEQ-CURE III EOG MEETING

Barriers to biogas market entry in the US the German experience

FAS Training Course on Energy Efficiency / Renewable Energy

Welcome to Kristianstad The Biogas City

Energy From Waste or Waste-to-Energy. Pyromex. The Solution to Multiple Energy & Environmental Issues James Pfeiffer, CEM

The economics of micro-algae production

Energy and Carbon Management

Gas Detection for Refining. HA University

DESIGN OF FIXED DOME DOMESTIC BIO DIGESTER FOR DEGRADATION OF KITCHEN WASTE USING MESOPHILIC & THERMOPHILIC REACTIONS (ANAEROBIC)

Biogas from Animal Waste and Organic Industrial Waste

GCSE BITESIZE Examinations

Intensification of anaerobic fermentation from proteinaceous industrial wastes by adapted microbes

1-Some related indicators: Total land area is 1 million Km 2. Only 3% of the land area is arable. The rest 97% is hyper arid desert. The whole lands a

Indonesia Biogas Asia Pacific Forum Developing A Biogas Hub In Commercialising Biogas For Asia. Opportunities for Biogas as a Vehicular Fuel

Thermal & Biogas Production In Egypt. By Prof. Dr. Ahmed Abd El-Ati Ahmed Egypt - GBEP Focal Point

BIOMASS: BIOGAS GENERATOR. Curriculum: Biomass Power (organic chemistry, chemical/carbon cycles, plants, energy resources/transformations)

with global applications Higher national employment Lower emissions of greenhouse gases More efficient use of resources

How To Make A Data Center Green

Make Value out of your Waste. Jørgen Fink Country Manager Xergi, UK & Denmark

State of affairs on Biomethane in the Netherlands National Roadmap

BLUE PLAINS - WASHINGTON DC NUTRIENT & ENERGY RECOVERY FACILITY

Sustainable Bio Energy technologies in the CDM market

DIY Poly Digester. What is Supplied in the Kit. Sketch of Arrangement

Indonesia: Tapping Indonesia's Agrowaste Potential with Innovative Technology

Strategies for Local Sustainable Economic Development

Landfill Gas In Ireland - The Facts

The regulators requirements for the operation of an AD facility. Gitty Ankers Senior Environment Officer Devon and Cornwall

From cow dung to biogas in Karnataka, India

WINGAS PRODUCTS GREEN NATURAL GAS. Climate neutral by carbon offsetting

The energy self-sufficient family home of the future

Liquid Biofuels for Transport

Reducing methane emissions through improved lamb production

BIOVALUE PROJECT 2 ANDERS PETER S. ADAMSEN AARHUS UNIVERSITY HEALTH 04 JUNE 2015

Fuel From Seaweed Project supported by the INTERREG IVA Programme managed by SEUPB

Transcription:

I G E R I N N O VAT I O N S 2 7 B i o g a s f o r a g r i c u l t u r e Phil Hobbs, Alastair Ward and Guillermo Pardo Biogas feedstock 44 Current research 44

I G E R I N N O VAT I O N S 2 7 B i o g a s f o r a g r i c u l t u r e Phil Hobbs, Alastair Ward and Guillermo Pardo The production of biogas as a fuel obtained from the fermentation of organic wastes has undoubted benefits for the environment. These benefits include both reduced methane emissions from livestock enterprises and the production of green energy which can be fed into the national electricity grid. The heat generated from biogas production can also be used locally for heating livestock buildings or hot water. Biogas is about 7% methane and 3% CO 2. The actual methane producers are microbes known as methanogens. These belong to some of the oldest groups of organisms on the planet, known as the Archaea. They are common in wetlands, where they are responsible for producing marsh gas, and are also commonly found in the gut of ruminants such as cattle, and in their faeces. In terms of biochemistry, there are four stages to the production of biogas by the anaerobic digestion of degradable organic materials. The early stages of breakdown require an acidic environment, whereas in the later stages, when the methane is actually produced, a neutral ph environment is advantageous. To facilitate this procedure in practice, therefore, in the UK we prefer a two-stage system to accommodate more efficient microbial activity that produces higher amounts of biogas. On the continent, however, a single-stage tank is used which simplifies the production process and reduces the initial capital costs of purchase. Biogas feedstock Livestock manure slurry is the main source of feedstock for biogas production, having a dry matter content of about 5-5% w/w, but potentially a wide range of organic wastes can be used as starter materials, ranging from fats and greases to vegetable wastes. Some potential sources, such as food and abattoir wastes, would need to be heat-treated before use as a biogas feedstock as a biosecurity measure, however, in order to prevent any contained pathogens escaping to reinfect farm livestock via grazing or other crop sources. Organic wastes imported onto the farm are also a good source of nutrients for spreading on the land and can significantly reduce artificial fertiliser use, both saving money and reducing the requirement for fossil fuels. In Europe, biomass in the form of maize has been used to supplement the feedstocks to produce larger quantities of biogas. The high nitrogen content of livestock manure when used alone does not provide enough carbon for efficient biogas production. This optimisation of biogas production is something IGER North Wyke is focusing on in a new EU AGRO-BIOGAS contract funded under Framework 6. Current research Even while premiums for the production of green electricity remain available in the UK, there is still some debate as to whether biogas production is 4 4

I G E R I N N O VAT I O N S 2 7 Fig.. Level of increasing alkalinity as the digestate travels from vessel to vessel 4 as the system achieves fermentation stability after an inoculation of organisms from a biogas digester. currently economical. A biogas plant can also be considered difficult to operate due to the complexity of the processes involved. New research at IGER funded by Defra and the EU Framework 6 Programme will address these two issues by improving the biogas production process. By doing so, we will not only be able to enhance the green electricity output, but also reduce capital costs through introducing more efficient and faster processes which will require less space. One of the major concerns for biogas production so far has been the lack of automatic and safe process controls at each stage of the procedure. By introducing appropriate and robust sensors to monitor the correct amounts of feedstock and nutrients for the biogas- producing microbes, together with the most efficient environmental conditions (e.g., alkalinity) for the organisms to break down the organic materials, the final chemical reactions that produce methane from acetic acid, or from hydrogen and CO 2, can be made much more efficient. Such process control will not be easy, however, because there is a lag time of about -2 days between the feedstock going in and the final biogas output, and hence there is an element of prediction required for best control throughout each stage. Modern modelling and statistical techniques can be used to overcome these problems, however, and we have initiated a new collaboration with Exeter University s Mathematics, Computing and Engineering Department which has a wide range of process control expertise to help achieve this. 4 5

I G E R I N N O VAT I O N S 2 7 Fig. 2. Old four-stage biogas experimental rig showing the sensor manifold, data processor and biogas recirculating pumps. Alkalinity can be determined indirectly from sensor data using these models. Work at IGER has identified that alkalinity at the methanogenesis stage of biogass production is important because the relevant microbes are highly sensitive to their environment, with reproduction rates which can slow to about 2.5 days. Current research has also demonstrated that when the fermentation becomes unstable, the alkalinity can be increased by reducing the waste loading rate or by adding alkali. Our microbial-orientated research observes the synergies between organisms and how they can best digest the waste together. To achieve this, we monitor both the Archaea organisms themselves and the extracellular polymeric substances that bind them together to allow them to improve the fermentation rate. To improve our understanding, we are building a 2m 3 biogas plant at North Wyke to determine the optimum mixing and loading rates of different amounts of organic waste types, process temperatures and the speed and frequency of the stirring process. The stirring process has proved important because the organisms need a regular supply of nutrients which the mixing helps to provide; however, over-mixing causes the methanogen organisms to be detached from their colonies and washed out of the digester. The study of 4 6

I G E R I N N O VAT I O N S 2 7 Overview Scheme Hydrolysis Tank Hydrolysis Graphs Methanogenesis Tank Tests Timer.5.8 Temp.6.4.2 Hydrolisys Reactor HRT (days) ph Cond Alkal.5.25.75.5.25 Methanogenesys Reactor HRT 2 (days).5 Temp 2 ph 2 Cond 2 Alkal 2 Digestate IBC 2 2 Biogas p (bar) flame Storage Gas Scrubber Gas Meter Gas Characterisation Fig. 3. Schematic of the process control interface for the new pilot plant showing status and sensor responses. mixing, known as the hydrodynamics of the digester, is also a valuable means of fault finding. The implications of our research for biogas production and the effects of the current economic climate on the financial viability of the process will be investigated in collaboration with Exeter University s Rural Studies Department. This collaboration will look both at farm-scale digesters and at more centralised larger-scale digesters that can more easily accept wastes, from a greater range of sources. phil.hobbs@bbsrc.ac.uk alastair.ward@bbsrc.ac.uk guillermo.pardo@bbsrc.ac.uk 4 7

2024 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information