Anaerobic digestion - renewable heat, electricity, waste disposal and fertiliser production!

When people think of renewable energy they think mostly of wind power and photovoltaics. Any discussion of renewable electricity policy tends to refer to these and criticise them, and by implication all renewable energy, because they are unpredictable and variable and need backup.

There is an astonishing ignorance even at high government level over the potential of other kinds of renewable power generation. So I want to redress this balance with occasional posts looking at different technologies. Recent posts have referred to marine current turbines, for example.

This post is about the unsexily named anaerobic digestion. Mostly it's about small, farm-scale versions, and I hope to get around to talking about larger scale ones soon.

However, it's worth mentioning right up front that larger plants are able to produce gas for the mains and for vehicles running on gas.

A chief worry if we don't rely on nuclear power, is where will all the power come from to decarbonise transport? Well, here's one answer.

A new income stream - and more - for farmers

A survey last December found that 80% of farmers in the UK wanted to have solar photovoltaics on their roofs within the next three years - and yet the fact is, that in terms of the carbon saving and other benefits anaerobic digestion (AD) provides better value for money than solar PV.

For example, farmer Clive Pugh (above) at Bank Farm, Mellington, near Churchstoke, Wales, put in his first AD plant 20 years ago. He now has a state-of-the-art, three chamber unit that provides all of the farm's own energy needs, and that for two homes and the farm dairy, as well as generating an income of up to £10,000 a month from supplying the National Grid - without the new FiTs subsidy, because he was an 'early adopter' and so the scheme is excluded from it.

“We initially went for an anaerobic set-up because we needed a new slurry store and it was something we had been looking into for some years,” says Mr Pugh.

“It revolves around using the slurry from our 140-cow dairy herd. In order to keep the gas production fairly constant throughout the year, we also use poultry manure, silage effluent, waste silage, discarded milk and whatever other green waste we can get hold of.”

While 10 cows are needed to produce 1kw of energy, in fertiliser value terms 1,000 gallons of separated liquid will provide around 30 units of nitrogen, 40 units of potash and 12 units of phosphate.

“The quality of our grass is certainly most noticeable these days, and our need for phosphate and potash is now nil. We also only need top-up units of nitrogen depending on the type of crops being grown,” says Mr Pugh.

How does it work?

In a typical plant, vats ferment farm slurry and crop waste (and can also process food waste) in the absence of oxygen to produce gas which can be used to generate heat and power.



The facility would normally be owned and operated by the farmer/farm business, but might sometimes be part of a co-operative venture. They often would not be approved to accept animal by-products at this scale.

The biogas produced in AD is a mixture of methane (65%) and carbon dioxide (35%) which can be used to generate heat through a boiler, or heat and power through a combined heat and power (CHP) system. In addition, following further processing, biogas is also a suitable fuel source for vehicles.

Hot water may be used on site, for example to heat polytunnels or greenhouses for market gardening. Some farms use AD to power a generator for the digester and pasteurisation. Other benefits include:

• it avoids landfilling of organic wastes;
• the biogas can be burnt as a fuel;
• there is a reduction in the use of fossil fuels, offsetting carbon dioxide emissions;
• it is a predictable and reliable source of electricity and energy, unlike wind power and PV;
• the digestate products return nutrients to the land, reducing dependence on inorganic fertilisers;
• there are economic benefits from reduced fuel and fertiliser use, as well as the subsidy;
• farms can become more self-sufficient, with socio-economic opportunities, e.g., gate fees can be charged for waste taken in and electricity, biogas, fertiliser and soil conditioner can be sold;
• odour is reduced by around 80% compared to farm slurry;
• methane (a greenhouse gas) emissions are reduced;
• a range of organic waste materials can be processed - the highest gas yields come from the co-digestion of fatty (food processing wastes), liquid wastes (animal slurries) and green wastes;
• the amount of farm slurry sprayed onto farmland - and of run-off and pollution of waterways - is reduced;
• harmful bacteria and viruses are destroyed, reducing the spread of harmful disease causing pathogens.

The energy generating potential is determined by the size of the digester and waste feedstock composition.

A typical farm installation might be up to 0.5MW. A small farm using farm waste can produce enough heat to warm the digester and meet domestic heating requirements. If electricity is generated through CHP of 10kWe capacity, enough electrical energy could be generated to supply up to 13 homes.

A brand new installation can cost anything from £150,000 for a fairly basic liquid-only unit to more than £375,000 for an all-embracing 120 kw producing version.

Better payback than PV

This high initial cost is why the technology needs support at this stage. Without support, simple economic payback is approximately 20 years.

Factoring in savings made in waste disposal, according to the Carbon Trust, mean that payback times for installations tend to be under 5 years.

Compare this to solar PV in much of the UK, which is 40 to 60 years without subsidy.

Larger plants

A range of AD scales exists, from single on-farm digesters through to large centralised anaerobic digesters (CAD) collecting waste from a larger surrounding area.

These CADs will usually accept animal by-product wastes for digestion. The gas produced at this scale can also be used for other purposes, for example to power vehicles or be injected into the National Grid.

AD at this scale is economically viable and requires little support. Most plants operate as co-digestion plants with slurries, in additional to wastes from the food, brewing and other industries.

This recent post contains other examples.

This website is a useful source of further information, although slightly out of date.

In Germany there are more than 3,000 on-farm anaerobic digesters - in the UK perhaps around 50.

Unsexy renewable energy technology is turned on... and will one day beat solar and wind in the UK

It's not as sexy as solar power or controversial and high profile like wind power. But a 'new' form of renewable technology is going to take off this year – the first of a series of plants was commissioned this week – and eventually it will be better value for money, more reliable and even contribute more energy to the UK's needs.

Its developers are now urging the Government to match the level of support offered to other renewable energy technologies such as wind and solar, through Feed-in Tariffs.

What is it? Well, unpleasant as it sounds, it's anaerobic digestion (AD) and it is a multiple-win technology that is set to revolutionise waste processing and energy generation.

AD also helps to divert waste from landfill, and reduce air and water pollution. Byproducts include transport fuel and renewable sources of soil nutrients and manures. These processes will all additionally create new employment.

The Coalition Government also believes AD can help the UK meet its climate change objectives by reducing greenhouse gases from waste and producing energy - including renewable heat - without significant land use changes.

AD makes power from the methane generated by composting organic food, sewage and crop waste without oxygen being present. As these materials are in abundant and continuous supply, it is more reliable than wind and solar power.

The National Grid has said that it believes that within 20 years, half the gas in the grid could come from this source. The gas can be burnt to make electricity and used to power vehicles too.

Pioneer plant opens

One of the first anaerobic digestion projects funded through the Government’s Environmental Transformation Fund was officially opened on Thursday.

The plant, at Staples Vegetables in Boston, Lincolnshire, one of the biggest producers of vegetables in the UK, will produce 11 million kilowatt hours of electricity per year by processing 40,000 tonnes of unusable vegetables and waste.

The digestate (what's left over after the composting) from the Staples plant will replace artificial inorganic fertiliser (which creates emissions) and be better for the soil (because of the organic matter it contains), the heat will be captured for office heating, innovative heat absorption coolers will chill the processing areas, and the electricity generated will power the plant.

Vernon Read, Managing Director at Staples says there is an additional benefit: “The project is giving us control not only over future pricing of power, but also over power security.”

There are three more Government-supported AD facilities opening this spring and over 30 in the planning stage. Some examples are highlighted towards the end of this article.

The National Grid has talked of the biogas from AD eventually replacing a significant proportion of fossil fuel gas in the mains in the future.

But before this can happen markets need to be created for the fertiliser, and for the gas as a fuel in transport. Different sectors, such as the water sector, need to be encouraged to process sewage this way. This was the subject of a Defra consultation last December, whose results have not yet been published.

AD is also subsidised through Feed-in Tariffs (FITs). In order to increase uptake, there is a study into the take-up of FITs for farm-based AD plants going on now at DECC, parallel to the review of Feed-in Tariffs and "solar farms".

Climate change minister Greg Barker believes there is "a huge opportunity" for farm-based AD but had been disappointed by the take-up so far. Developers agree and hope it will become eligible for FIT subsidies soon.

Pioneering AD plants

Because it is not yet cheap to set up. Gary Jones is the owner of a plant at Langage Farm, near Plymouth in Devon. He says that the project couldn't have happened without support from the ETF. "Due to the new concept involved with anaerobic digestion in the UK, the start up costs are very prohibitive.

″Hopefully when there are a few more established sites around the UK, the authorities concerned in the build and running of the sites have a better understanding, and good technology providers can be found locally the cost will reduce and the plants will become profitable without grant funding."

Several other exciting projects are nearing completion, funded by the Environmental Transformation Fund.

United Utilities and National Grid are expanding the already existing anaerobic digestion plant at United Utilities' Davyhulme Waste Water Treatment Works in Greater Manchester. Work is almost complete on converting 250 cubic metres per hour of biogas to grid quality biomethane. Half will be used to fuel a fleet of tankers and half injected into National Grid’s gas distribution network - sufficient to provide heating and cooking needs for around 500 homes.

In Driffield, East Yorkshire, anaerobic digestion company GWE Biogas Limited is constructing a plant to convert up to 50,000 tonnes of organic waste each year sourced from local authorities, food manufacturers and supermarkets, to generate approximately 2MW of electricity for export to the grid. The long term objective is to upgrade gas to bio-methane to supply a private heat and wire network for new housing.

Like Langage Farm, BV Dairy (pictured) in Dorset, which processes around 35 million litres of milk per year, is building an anaerobic digestion plant to process liquid waste and provide renewable electricity and heat for its site.

WRAP, with support from the Carbon Trust, is delivering the Anaerobic Digestion Demonstration Programme under the Environmental Transformation Fund particularly because of its role in cutting waste in the food chain. It's also supporting a Staffordshire-based AD project through its Advantage West Midlands (AWM) Programme, with an animal rendering and food waste collection business.

There is every reason to believe the claim of the Anaerobic Digestion and Biogas Association (ADBA) in ten years' time the UK will have a mature anaerobic digestion industry.

[PS - let's see how popular this post is - with words like sexy and turned on in the heading! - I noticed my post about naked supporters of Amen Awel Tawe windfarm making a calendar is my most popular so far!]