Tag: biomass energy

Forests, sustainability and biomass – the expert’s view

It was a forestry catastrophe that first inspired Matthew Rivers’ interest in forests.

Dutch Elm trees, an iconic part of the UK landscape for over 250 years were becoming infected with a fatal and fast-spreading disease. The race was on to save them.

A schoolboy in North London at the time, Rivers joined the after curricular school team tasked with saving its trees – first by injecting them with insecticide, and when that didn’t work, by felling and replanting them. It was an early foundation in how forests work and the challenges of keeping them healthy.

Decades later, Rivers is Director of Corporate Affairs at Drax. It’s a role he finds himself in following a career as a forester, helping to manage forestry businesses, and supporting the setting up of wood product manufacturing plants.

His own estimation of his working life is a humble one, however. “I think I’m probably a failed farmer,” he says.

“A forester always plants in hope.”

Rivers studied forestry at university in Scotland before taking up jobs in the forestry industry across the UK, Uruguay and Finland. Working in this industry, he says, is one that requires patience.

“In the UK we’re talking about 30- or 40-year growth cycles. The trees I planted at the start of my career are only just coming to maturity now,” he explains.

But more than the long investment of time, being a forester relies on faith. “A forester always plants in hope,” he says. When a forester plants a tree, he or she most commonly does not know who the end customer will be.

So when the call came from Drax for a forestry expert to help guide the company through an important transformation – upgrading the power station from coal to biomass – the challenge was one he was ready to take.

“Drax already had ambitions of converting three boilers to run on biomass. That would mean consuming tonnes of compressed wood pellets,” he says. The business needed a supply, and Rivers was drafted in to set this up.

As part of the supply solution, and Chaired by Rivers, Drax set up Drax Biomass, a pellet manufacturing business in the USA that makes and supplies compressed wood pellets to Drax Power Station.

Setting up its own manufacturing plant not only means Drax needs to rely on fewer external suppliers, but also that it can use the learnings about the technologies, the economics and the sourcing of the process to continually hone its supply chain.

To operate responsibly and receive governmental support, Drax has to be sustainable, and this is particularly important when it comes to where and how it sources its fuel. This comes with its own challenges.

No universal definition of sustainability

“To my understanding, there is no universal definition of sustainability,” says Rivers. So how do you proof your business for an unclear entity?

“At its heart, sustainability is about not doing anything today that would prejudice doing the same thing for the next generation or generations to come.”

A responsibly managed forest is one that is as healthy, productive, diverse and useful in 100 or 500 years’ time as it is today. They key to this, is to think of forests as a whole.

Rivers explains: “Think about a single tree – you fell it and use it to heat your home over one winter. But it’s going to take perhaps 30 years for that tree to grow back,” he says. “What do you do for the next 30 years?”

“In a sustainably managed forest you have all different ages of tree represented – one thirtieth devoted to each age- and, when you use an older tree to warm you in winter, you plant a replacement. That way, for every year you’ll have trees reaching maturity ready to provide your power.” It’s a cycle that, if managed responsibly, keeps delivering a useful resource as well as maintaining the health of the forest.

Rivers continues: “Sustainability is the very nature of what a forester does; because if we don’t take care of our forests, and ensure we have a crop to harvest year after year, we lose our livelihood.”

forests_trees_growing_for_winter_heating_smh4nj

Becoming a private forester

Two decades ago, Rivers completed a loop he started decades ago amidst the Dutch Elm crisis and became a forest owner himself. In Scotland, he bought, and now manages, his own private forest.

“We’ve had kids’ birthday parties, we’ve dug out a pond, we harvest chanterelles in the autumn – there’s a millennium capsule buried somewhere,” he says.

It’s not only a family heirloom. It’s a place for him to exercise a passion – maintaining and managing a responsible and healthy forest.

 

A solution for cheaper, cleaner power

Senior couple checking their bills

Britain has some big energy targets ahead of it – namely an 80% reduction in carbon emissions by 2050 compared to 1990 figures. A renewable energy future is not an optimistic target, it is a necessary one.

But for this picture to also be a practical one it needs to be affordable. A study from NERA and Imperial College London, commissioned by Drax, suggests there are ways for renewable technology to be cheaper than it currently is.

In fact, in one scenario they looked at, there could be savings to the tune of £2.2 billion.

Incentivising decarbonisation

It’s a positive and necessary support mechanism. However, some renewable technologies, like compressed wood pellets, a form of biomass, are excluded from participating in upcoming the auctions scheduled between 2017-20. Why is this?

Missing the bigger picture

Currently, CfD support is based on how much a particular type of electricity costs combined with how much it takes to build and maintain the facility used to generate it. This figure is what’s called the ‘levelised cost of energy’ (LCOE). The spanner in the works comes in that not all costs are considered in making this judgement.

Powering a country requires more than just a power source. We need ancillary services like backup power to get the country back on the rails in the event of large-scale blackouts, and voltage control to ensure electronic devices continue to work and that power can move around the network. The costs associated with these services – system integration costs (SICs) – are excluded from the CfD equation.

Sources like wind and solar, being intermittent, can’t offer most of these on-demand ancillary services but we still need them to play a part in the UK’s energy supply. Biomass facilities can provide a number of these itself, meaning it actually has a negative SIC cost.

However, in the current pricing system – ignoring these associated costs – biomass is considered more expensive than onshore wind and solar. With the high SIC costs for wind and solar included, biomass is in fact the cheapest option.

Finding the right mix

This is not to say that solar and wind are not an integral part of a more renewable future. A truly flexible low carbon, high voltage electricity grid should be a mix of elements. Current rules do not look at the full picture, and are ruling out important alternatives, but there are possible solutions. One could be unifying the markets.

There are four markets that feed into the UK’s electricity supply and there’s little transparency or cohesion between them. This leads to inefficiencies.

Jens Price Wolf, Regulations and Market Director at Drax, explains: “Solar is the cheapest renewable, diesel is the cheapest option in the capacity market and gas will be the cheapest for energy production.”

By considering each market as separate you end up buying the cheapest solution for that individual purpose rather than considering its performance across all. This misses out solutions that can benefit the whole system.

“Biomass might be the second cheapest option in each field,” says Wolf. “So supporting investment to upgrade existing coal power stations with biomass technology satisfies multiple needs and leads to it being ultimately cheaper than the old mix.”

A single market approach that treats all technologies and generation methods in the same way could lead to significant cost savings, and those savings could be passed on to bill payers in households and businesses.

While this could be a longer-term solution, there are ways short-term actions that can make a difference. If the government were to include biomass in the mix for the next round of CfD auctions it could bring about savings of over £2 billion over the next 15 years, or a £85 saving per household over the same period. And, it would do this while ensuring the grid remains adaptable without sacrificing emissions targets.

This is how you make a biomass wood pellet

Compressed wood pellets

Wood has been used as fuel for tens of thousands of years, but this wood – a compressed wood pellet – is different. It’s the size of a child’s crayon and weighs next to nothing, but when combined with many more it is a smart solution to generating cleaner electricity compared to coal.

Wood pellets like these are being used at Drax Power Station to generate electricity and power cities. Not only are they renewable and sustainable, but because they are compressed, dried and made from incredibly fine wood fibres, they’re also a very efficient fuel for power stations.

This is how a compressed wood pellet is made at the Drax Biomass Amite BioEnergy Pellet Plant in Mississippi.

The wood arrives to the yard

Wood arrives at the plant via truck and is sent to one of four places: the wood storage yard, the wood circle (where wood is primed for processing), the piles of sawdust and woodchip, or straight into processing.

Bark is removed and kept for fuel

Logs are fed into a debarker machine, which beats the logs together inside a large drum to remove the bark. The bark is put aside and used to fuel the woodchip dryer, used later in the process.

Thinned wood stems become small chips

The logs – low-value fibre from sustainably managed working forests – need to be cut down into even smaller pieces so they can then be shredded into the fine material needed for creating pellets. Inside the wood chipper multiple blades spin and cut the logs into chips roughly 10mm long and 3mm thick. The resulting chips are fed into the woodchip pile, ready for screening.

Chips are screened for quality and waste is removed

Chipped down wood can include waste elements like sand, remaining bark or stones that can affect pellet production. The chips are passed through a screener that removes the waste, leaving only ideal sized wood chips.

The biggest hairdryer you’ve ever seen

The wood chips need to have a moisture level of between 11.5% and 12% before they go into the pelleting process. Anything other than this and the quality of the resulting pellets could be compromised. The chips enter a large drum, which is blasted with hot air generated in a heater powered by bark collected from the debarker. The chips are moved through the drum by a large fan, ready for the hammer mill.

Wood pellet Hammer Mill

Small woodchips become even smaller woodchips

Inside the hammer mill there’s a spinning shaft mounted with a series of hammers. The wood chips are fed into the top of the drum and the spinning hammers chip and shred them down into a fine powdery substance that is used to create the pellets.

Putting the chips under pressure – a lot of pressure

The shredded woodchip powder is fed into the pellet mill. Inside, a rotating arm presses the powdered wood fibre through a grate featuring a number of small holes. The intense pressure heats up the wood fibre and helps it bind together as it passes through the holes in a metal ring dye, forming the compressed wood pellets.

Resting and cooling down

Fresh pellets from the mill are damp and hot, and need to rest and cool before transporting off site. They’re moved to large storage silos kept at low temperatures so the pellets can cool and harden, ready for shipping.

One of the biggest domes you’ve ever seen

This is the final stage before shipping. Specially designed and constructed storage domes are used to store the wood pellets after they are transported to the Mississippi River, Louisiana and before they make their way across the Atlantic to the UK.

The 4 most common myths about renewables

Renewables make up more of the world’s energy mix than ever before. And yet, misconceptions about these new or alternative technologies – such as biomass, solar and wind – are common.

Some of these concerns are – for the time being – partly justified, some completely subjective, and some are demonstrably wrong. Here’s a closer look at the most pervasive myths and what truth there is behind them.

Renewables are unpredictable

An oft-repeated misconception is that renewables aren’t a full-time solution to our power needs. It’s true that solar isn’t generated at night and wind turbines don’t operate in still weather, but the canon of renewables is bigger than its two most well-known technologies.

Tidal power still depends on environmental factors, but tides are much more predictable than wind or sunlight. For countries lucky enough to have ready access, geothermal power – which uses heat from the earth’s core to power generators – is even more reliable.

Biomass solutions, such as compressed wood pellets, are a fuel-based power source, meaning they are flexible so can be used to generate electricity on demand and operate as a base-load power option, much like coal or gas. At Drax Power Station renewable electricity is generated on demand using compressed wood pellets and delivered to the National Grid 24-hours-a-day.

Now, thanks to advances in weather forecasting, the National Grid can plan ahead to balance the system with other renewable and low carbon technologies when the sun isn’t shining and the wind isn’t blowing. Just a few years ago the primary fall back was relying on coal power stations to pick up any slack.

It might not be possible to power the world entirely with one renewable source, but the right mix of technologies could provide an answer to the question of how to ensure a stable and secure low carbon energy supply.

Heavenly Scene Stormy Skies

Renewables are expensive

There is some truth in this, but it’s important to note that these costs are falling. Many of the high costs associated with renewables have been down to a lack of infrastructure investment.

A number of the components required in construction of structures like wind turbines and solar panels are expensive. And, as many renewable facilities need to be located in different areas to existing traditional facilities, extensive power grid extension is often needed. But these are problems that once set up, should bring down the costs of renewables such as solar and wind.

Setting up biomass-powered facilities is considerably cheaper. Compressed wood pellets can be used in upgraded coal power stations, so there’s no need for expensive new connections to the high-voltage electricity transmission system.

There are even ways renewables could bring about cheaper power for consumers. Research commissioned by Drax and published by NERA Economic Consulting and Imperial College London found that, if the same government support offered to some renewable technologies (i.e. wind and solar) were open to all (such as biomass), consumers could see potential savings of £2 billion on their energy bills.

Renewables are ugly

While this isn’t necessarily an opinion shared by everyone, it is one that is often cited. Onshore wind farms often draw the most ire, but they aren’t alone. Large investments are being made in offshore wind farms, which are both more discrete and better positioned to take advantage of stronger offshore currents.

And hydropower projects like dams and tidal barrages can in the long term create whole new habitats, ecosystems and leisure facilities in the form of artificial lakes and surrounding forests.

Nobody uses renewables

In 2015, 99% of Costa Rica’s electricity came from renewable sources, including hydro, geothermal, wind, biomass and solar. Closer to home, Sweden draws more than 50% of its electricity from renewable sources, including 22% from bioenergy – 90% of which comes from forestry.

In the UK, renewables use is steady and rising, accounting for 25% of all electricity generated domestically in 2015. In the first half of 2016, 20% of the UK’s renewable power was supplied by Drax. Contrast those figures against coal, which in the UK declined from supplying 30.8% of UK power needs in Q1 2015 to just 15.8% in Q1 2016, and our increasing use of renewables is even more evident.

Consumers have been buying 100% renewable electricity tariffs from companies such as Good Energy for more than a decade. Businesses are increasingly getting in on the act too. Two thirds of the power generated by Drax in the first half of 2016 was sold directly to companies via Drax Group’s business electricity supplier, Haven Power.

And with campaigns such as RE100 challenging the world’s biggest firms to commit to renewable-only power, household brands such as Ikea, M&S and Google are either already 100% renewable or only a few years away.

Misconceptions about renewables will remain as long as we’re still in the transition out of fossil fuel use. But the industry has made huge strides from where it was just 10 years ago.

Thanks to better, more affordable technology, an increasingly friendly corporate sector, and a greater awareness of environmental issues at large, these products and services will continue to improve, grow and increasingly becoming more mainstream.

An alternative way to heat your home

Beautiful old village landscape nestled amongst hills in Lake District

There are things we, as a modern society, expect in our homes: running water, electricity at the touch of a button, heating for when temperatures drift south.

All are ubiquitous in the UK, serviced by large networks that deliver these resources on demand. But there are some areas in the country that exist apart. In the UK there remains a large proportion of homes off the gas grid.

Without the benefits of easy-to-access gas and gas boilers, these households rely on other forms of heating often fuelled by expensive and high-carbon fuels like oil or liquid petroleum gas (LPG).

But there are alternatives to these, and of those fuels, biomass is not only an increasingly affordable one, but a cleaner one, too.

How do you heat your home with biomass?

Biomass boilers work in much the same way that a gas powered one does. They use fuel to generate a heat source that then heats water which is passed through radiators and into your household’s hot water supplies. Whereas the majority of boilers in the UK use gas as a fuel source, biomass boilers run on natural wood products, such as compressed wood pellets.

It’s an efficient and effective way of heating homes and in Europe it’s a common one. In Sweden, 1,400,000 tonnes of pellets were used in 2014 for heating.

Compare that with the UK’s 300,000 – in a country with six times the population – and the difference is stark. Biomass covers more of Europe’s energy requirements than any other, but in the UK we’re falling behind continental averages.

A cleaner, cheaper alternative

Wood is a simple renewable fuel. A growing tree absorbs carbon dioxide out of the atmosphere, which is released when the wood is used to generate energy in the form of heat or electricity. New trees are planted to replace the old ones and the carbon dioxide is absorbed all over again. Thanks to this cyclical process, biomass fuel is sustainable.

This makes compressed wood pellets a more climate-friendly fuel source than the fossil fuels of the past such as diesel and oil. As well as being renewable, there are financial benefits too: a wood-fuelled biomass boiler offers significant savings when compared with electric heating.

Support towards a cleaner future

The Government has recognised the importance of technologies such as biomass-fuelled boilers in achieving a lower carbon future. The Renewable Heat Inventive (RHI) programme was introduced to provide incentives to homeowners, landlords and commercial customers for installing generators of renewable heat such as wood pellet boilers.

Its objective is to try to achieve the target of ensuring that 12% of the UK’s heating comes from renewable sources by 2020. Currently it makes up just 5% of the total.

But with improving technology and a more regular supply of biomass fuel – such as that offered by AMP Clean Energy [previously Billington Bioenergy] to domestic customers – domestic wood pellet heating could become something that’s not just a niche option, but a serious alternative to off grid homes.

Inside the dome

There are four storage domes at Drax Power Station and each of them can hold 80,000 tonnes of compressed wood pellets. It’s these biomass pellets, a sustainable fuel, that Drax is being upgraded to run on and produce renewable electricity.

Wood pellets are an incredible fuel that can match coal for efficiency – the challenge is you just need more of them as the density and calorific value of coal is greater. However, storing such large quantities in a confined space presents risks that have to be managed, 24/7.

Atmospheric control

The crucial difficulty with storing the pellets is their chemical volatility. Wood, which the pellets are made from, emit carbon monoxide (CO). In a confined space such as the storage dome, this CO can build up and – due to CO’s extreme flammability – require the entire internal atmosphere to be regulated by a set of highly sophisticated engineering solutions.

As long as materials are emitting more heat into the atmosphere than they are storing in themselves, there is no risk of combustion. A single wood pellet in a fuel store poses no fire risk. Nor does a small pile. But when thousands upon thousands are piled together, the pressure builds up and causes the pellets to heat up.

Gradually, the rate of temperature increase speeds up, and before you know the flashpoint threshold has been crossed and there’s potential for danger.

However, remove or limit the oxygen supply in the silo and purge the CO that’s emitted from the pellets, and the risk of a thermal event is substantially reduced. The challenge for the engineers at Drax constructing the domes was finding a way to manage temperatures within the dome.

Neutral nitrogen

To do this they created a system to automatically inject nitrogen into the storage dome. While nitrogen isn’t a truly inert gas, it is much less reactive than CO and oxygen.  With this pumped into the dome’s atmosphere it is a much safer environment.

To get a steady supply of nitrogen, regular air from our atmosphere – which is 78% nitrogen – is passed through a molecular filter, which removes the larger oxygen molecules. The gas collected at the other end is 96% nitrogen.

This nitrogen-rich air is then injected from underneath the dome and continually distributed around it. Not only is this a fire prevention method, but also a firefighting one that can be pumped in larger quantities in the event of combustion. Separate to the above measures which are there to manage fuel temperatures, the dome is also fitted with a carbon dioxide (CO2) injection system and water deluge system which are there as fire extinguishing precautions.

The big ear inside the dome

The next problem facing the designers was how to accurately monitor the quantity of compressed wood pellets inside the dome. To achieve this, each dome is fitted with a sonar system – which sounds a bit like a chirping bird – that provides continuous feedback on how full the dome is.

The sonar monitoring system provides level, profile and volume information which is translated into a 3D image of the stored biomass. This method of volumunetric measurement allows the operators to view and monitor in ‘real time’ the effects of their actions when filling and unloading domes, so they can target specific areas particularly when unloading and for fuel accounting purposes.

Other tools and tricks

Five thermocouple arrays measure the pile temperature and provide feedback in real time to the operators to allow them to assess the status of the dome and effectively plan material filling and reclaim. Gas monitors measure the levels of CO and CO2 as well as O2 depletion within the head space of the dome.

A dome breather vent (a two way acting valve, which as its name suggests, allows the dome to breathe) is fitted to the top of the dome and acts as a vacuum breaker maintaining a relatively even pressure allowing air in during unloading and releasing head space gasses during nitrogen inserting.

The final piece of the atmospheric control puzzle is regulating pressure. At the top of each dome is a controllable aperture called a slide gate which is closed unless the dome is being filled to allow material to enter. A dome aspiration system is installed here to filter and remove displaced air from within the head space during filling, but also allow a route for CO and other offgassing products to escape.

All the hidden systems within these four huge white domes allow the operator to effectively control their atmospheric conditions and crucially to store massive amounts of potentially volatile biomass safely on site.

Find out more about these giant storage domes – read the story about how they were constructed

How does Europe use biomass?

Family on summer Senja coast (Norway, polar day)

At the heart of Norse folklore is a figure called Yggdrasil that connects its nine worlds and gods. It’s an immensely important and holy icon, but it is not a god itself – it is an ash tree.

That the central figure of mythical Scandinavian cosmology should be something as humble as a tree is no surprise, Scandinavia is a heavily forested region. Sweden, the largest country in the area, is more than 68% forest. Wood is an inherent part of life there. For thousands of years it’s been used as a resource and a fuel, and today is no different.

Throughout much of Europe the same is true. But, while historically wood was used only for cooking, heating and light, today its use as a form of energy also includes generating electricity and heat when formed into compressed wood pellets.

Europe and wood pellets

Nearly 22 million tonnes (Mt) of wood pellets were used in the European Union in 2015, making the region the leading wood pellet consumer in the world. It is also the world’s leading producer, creating roughly half of the world’s global output – largely from European trees.

A report from the Standing Forestry Committee, set up to represent the forestry industries in EU countries, found that just 4% of the woody biomass used in the EU was imported.

Of the 22Mt used across Europe, 10.5Mt was used for heating, while 11.5Mt was used for industrial uses like fueling power plants. But in the UK, the level of wood used for fuel falls some way behind EU averages. Thanks in large part to Drax and its transition from coal to renewable wood pellet-powered electricity generation, that’s changing, but the UK still has a way to go to catch the continental average.

Where is the UK falling behind and how is wood being used to power the rest of the continent? Here, we look at some of the largest consumers and producers of biomass in Europe and how it’s being used.

Sweden

Sweden is the third highest consumer of wood as a source of energy in Europe, trailing only Finland and Latvia in its use. A key use of biomass in Sweden is powering district heating systems. In a district heating system, rather than each building or home having its own boiler, whole areas of cities are heated through a single central plant distributing heat to buildings. These plants can be powered by a variety of fuels, but many run on wood pellets or distribute the waste heat captured at power plants.

rax_europe_biomass_sweden

Germany

In 1713, an accountant and mining administrator, Hans Carl von Carlowitz, published what is considered the first ever book to look in depth at forestry management, effectively kickstarting the modern idea of sustainable forestry. In the 300 years that have passed, Germany has embraced the cultivation of wood and has made wood and biomass a fixed part of its energy makeup.

More recently, the Renewable Energy Heating Act and Market Incentive Programme was passed in 2009, which requires new building owners to provide a percentage of their heat from renewable sources, including wood-fired boilers. The aim is to increase the country’s share of renewable heat to 14% by 2020.

Europe, Biomass, Germany

Finland

Nearly three quarters of Finland is forestland, making it one of the most forested countries in the world, let alone Europe. As a result, wood plays a large part in Finnish culture. Stora Enso, one of the world’s leading paper and packaging manufacturers is Finnish and more than 20% of the country’s exports are from wood and wood products. Coupled with a strong focus generating much of its energy from renewables, energy derived from wood and products made from wood is high.

drax_europe_biomass_finland

United Kingdom

In 2013, less than 10% of all energy used in the UK was generated from wood and wood products. This places it some way behind countries like Germany and Sweden, in part owing to a lack of infrastructure for providing heating derived from wood and wood biomass.

This could change if the government continues to back technologies equally in initiatives like the Renewable Heat Incentive (RHI). Available to homeowners, landlords and commercial customers, RHI provides incentives for installing generators of renewable heat such as wood pellet boilers.

To reach climate goals, the then Department of Energy and Climate Change noted that both biomass-driven electricity generation and heating should continue to increase in the UK. And with the upgrade of Drax and Lynemouth power stations from coal to compressed wood pellets, there are positive signs the UK can catch up to the European biomass average. In doing so, renewable biomass electricity generation can also help increase wind and solar power generation in the UK, and help create a more sustainable energy future.

drax_europe_biomass_united_kingdom

Mind the gap

Later today the EDF Board is expected to give the go-ahead for a new nuclear power station at Hinkley. This will provide some long overdue clarity for Britain’s energy sector, but we now need to quickly move on and make the right decisions to secure the best mix of power generation.  The drawn out debate around Hinkley Point C has diverted attention away from the sector’s biggest challenge.

The Government has made it clear that coal must come off the system by 2025.  But coal still provides up to one fifth of the UK’s electricity, and plugging that gap will be far from easy.  Nor will doing so in a way that allows the country to meet its carbon targets while supporting the technologies that will deliver a modern energy system fit for the 21st century. The Government’s intention is absolutely right, but how does it intend to meet its target?

Let’s be clear, a positive Hinkley Point C decision will play an important role in the necessary energy mix but will provide no silver bullet. By most estimates, when finally complete, the nuclear plant will provide seven percent of the UK’s electricity needs.  However, this isn’t expected to come ‘on grid’ much before 2030, and let’s remember that in 2030 all but one of the UK’s current operating nuclear reactors are scheduled to be closed. Hinkley will therefore be replacing only some of the lost nuclear capacity, not providing ‘new’ energy to replace coal.

The last few years have seen a huge and welcome expansion in renewable sources of generation like wind and solar in the UK, but they are intermittent and cannot fill the gap alone. They still need to be supported by a constant supply of electricity that can be flexed up and down when the wind does not blow and the sun does not shine – a regular scenario on these shores.

As a form of low-carbon baseload generation, nuclear will undoubtedly be part of the answer. However, as we’ve already seen with Hinkley Point C, planning, funding and building new power stations can be a long and costly process. It has taken over a decade to reach today’s decision. In the past year alone, more than 5 gigawatts (GW) of coal power generation– Hinkley Point C is set to provide 3.2 GW – has come off grid well before the Government’s target of 2025. We don’t have the luxury of time: every day lost adds to the cost of addressing this challenge.

Gas will play a role but many, including the Institution of Mechanical Engineers (IMechE) have pointed out the huge number of gas-fired power stations we’ll need to plug the gap that ending coal creates. IMechE estimates 30 will be required which is clearly unrealistic, since the UK has built just four in the last 10 years.

At Drax, we have developed a solution to these challenges. We have used state of the art technology to upgrade some of our coal facilities to generate electricity from biomass in place of coal.  These facilities are already providing a reliable and flexible flow of electricity that also helps the UK meet its carbon targets.  The biomass we use is compressed wood pellets which perform in much the same way as coal and deliver an 80% CO2 saving.

Our biomass facilities are already powering three million homes and with the right support we can double this, helping to plug the energy gap that old plant coming off and delays to new build will leave us with.

Using biomass is more cost-effective than other renewables. This was illustrated by a recent study from Imperial College and economic consultancy NERA when they analysed the hidden costs of the back-up needed to meet demand created by intermittent renewables. Our biomass facilities can provide all of the electricity services required to keep the UK electricity system stable. Providing these services is set to become increasingly important in the years ahead as a greater need to back-up and balance the system will be required.

Finding the right mix of power generation will not be easy, but it is important we make every effort to get it right. Like Hinkley Point C, biomass is not a silver bullet, but it can and must play its part in helping the country transform to a low-carbon future.

Sustainable Biomass Program – proving biomass is sustainable

I was honoured to be able to accept the Excellence in Bioenergy award recently. Not for myself, but on behalf of all my colleagues at Drax who have worked so hard to make a reality of our shared plan to generate reliable, renewable electricity. Our achievements are truly a team effort.

In 2015, Drax became a predominantly biomass-fuelled power station.

We now generate more electricity at Drax power station from compressed low-grade wood pellets than from coal – between three and four per cent of the UK’s entire demand every day.

It’s a major triumph for all the brilliant engineers involved in converting the plant and everyone who has helped secure the incredibly complex supply chain that keeps it running.

But we truly believe that this is only the beginning for sustainable biomass.

Sustainable biomass is the ideal fuel to help the world decarbonise in an affordable and reliable way. It can support other renewables like wind and solar when the elements are against them and backup power is needed.

Because it can be created by upgrading existing coal-fired power stations, it can be added to the electricity grid in a fraction of the time and for a fraction of the cost of building new power stations. Why should the UK only build brand-new gas and nuclear power stations when existing coal power stations can be upgraded to low carbon, renewable tech? At Drax, we have shown how engineers working at what once was the biggest coal power station in western Europe can use their expertise to work with compressed wood pellet power generation.

And it can save bill payers billions of pounds when the true costs of bringing other renewables on stream are taken into account.

The industry’s greatest challenge right now is in proving that all the biomass we use is truly sustainable.

At Drax we have proven the sustainability of the biomass we use time and time again. But we can and will do more to ensure that standards right across the industry are always equally high.

We cannot underestimate the importance of sustainability. No corners can be cut. We must all join together and meet this challenge. Because without sustainable biomass there will be no industry at all. Without sustainable biomass in a balanced energy system with other renewables and low carbon technologies, the Paris climate change summit commitments may not be reached.

This is why the Sustainable Biomass Program is so important. The SBP has developed a certification framework  to provide assurance that woody biomass is sourced from legal and sustainable sources.

By working with the SBP, all of us in the industry alongside hard working families and businesses stand to benefit. Which is why all of us at Drax welcome its inception, and look forward to working with the SBP to help build a growing and healthy industry that helps our society transition to the renewable fuels of the future.

May 2017 update: the SBP has changed its name to the Sustainable Biomass Program — you can read its first annual report here.