Top-class biofuel from the depths of the forest

Tops and branches from tree-felling sites are reborn in the laboratory as compact pellets. However, the energy industry will not act until the price is right.

A SINTEF project led by senior scientist Øyvind Skreiberg is transforming the chopped-off branches and tops of felled spruce trees into a fine powder that is then pressed into high-energy pellets. Photo: SINTEF / Gry Karin Stimo

   
   

We have all seen it when we walk in the forest after the lumberjacks have been there. When the logging machinery moves on, what it usually leaves behind are piles of branches and tops.

Norway possesses major unexploited energy resources in the form of these branches and tops – known in their Norwegian acronym as GROT (see Fact-box).

Samples of this logging waste regularly arrive at SINTEF to be transformed into fuel.


Extreme "sauna" for timber

In the raw form in which the biomass arrives at the laboratory, it is regarded as a problematic and therefore low-value fuel.

But when the scientists and technicians have finished processing it, they are left with a valuable source of heat – ready for use in industrial heating furnaces that are currently fuelled with wood pellets or chips, and for domestic pellet stoves.

The transformation is effected via a process called torrefaction, a sort of extreme sauna for timber and vegetation.


Torrefaction concentrates the energy content of biofuels. Left: chopped-up branches and tops. Right: this type of raw material has been subjected to torrefaction before being ground into a fine-grained mass, which is then pressed into pellets. This contains about 70 per cent of the original mass, while keeping 90 per cent of its energy. Photo: SINTEF / Gry Karin Stimo

Problematic raw material

“This is what the raw material looks like when it comes to us!”

Senior scientist Øyvind Skreiberg shows Gemini a fistful of fragments of wood with an admixture of spruce needles. It looks just like the sort of debris that litters the pavement around the Christmas tree stands on Christmas Eve. This is chopped-up GROT from spruce logging.

“Cheap fuel, and Norwegian logging sites are full of it. But it is a poor-quality fuel, because it is so variable in composition,” says Skreiberg.

If the GROT is tipped into the furnace, the woody component of the mixture may burn in one instant, bark and needles in the next.

“This mixture means that the efficiency and characteristics of the combustion process are extremely variable. In the worst case, they can destroy a combustion chamber,” says Skreiberg. Then he opens his other fist and shows us the evidence that the problem is capable of being solved.


Fibre broken down

In this hand, the scientist holds a fine-grained brownish-black mass, which he has taken from the steel apparatus that stands behind him. This is a laboratory reactor, in which the chopped-up GROT has been subjected to torrefaction.

On its way through the highly insulated steel cylinders of the laboratory rig, the raw material has been heated to 275 oC. The heat treatment has broken down the fibrous structure of the biomass. According to Skreiberg, this has two benefits.

“In the first place, the torrefied material can easily be crushed into the powder that you can see here, which can be stirred around to form a homogeneous, and therefore combustion-friendly, mass."

"Secondly, this powder can be pressed into pellets with a high energy content per unit of weight and volume; in other words, it is also a transport- and storage-friendly fuel. Pellets of torrefied biomass can withstand getting wet, just like coal, and are very stable under storage."


 Plenty of raw material
  • Branches and tops (GROT) belong to the biofuel “family”.
  • Such sources of heat are regarded as being carbon-neutral, because in principle, the CO2 that is liberated when a tree is burnt is bound up again when a new tree has grown.
  • Norway utilises GROT much less than its neighbour Sweden.
  • GROT left lying on Norwegian logging sites contains enough energy to provide between five and six Terawatt hours (TWh) of energy a year.
  • This is equivalent to the heat from five to six million 1000 W panel heaters, each switched on for 1000 hours (nearly 42 days).

Source: Øyvind Skreiberg, SINTEF Energy Research

Inexpensive raw material

“But doesn’t torrefaction make the fuel too expensive?”

“This technique improves a biofuel that is cheap but problematic in terms of combustion technology, and makes it much easier to handle. There is already a market price for GROT, which is well below that of wood chips."

"We hope that the method will be competitive, precisely because of the low price of the raw material and the reduced transport costs that the saving in weight and volume make possible.”

“What about the heat that is used in the torrefaction process? How much energy does that steal from a load of biomass?”

“Not much, in fact. The volatile components that are released as gases from the raw material are combusted, to maintain the ideal process temperature, and as much as 90 per cent of the energy in the raw material is retained by the torrefied material.”


“Green” coal

A race to develop torrefied material for fuels is under way in both Europe and North America, driven by a desire for a new timber-based fuel that can be burnt alongside coal in thermal power stations.

Many coal-fired power stations are already combining traditional wood pellets with the coal, with the aim of reducing greenhouse gas emissions.

According to Skreiberg, the reason why torrefied biomass pellets are interesting for this sector is that the combustion characteristics of the torrefied material are much more close to coal than biomass.

Senior engineer Willy Georg Horrigmo tips a bucketful of chopped-up branches and tops into the top of the laboratory reactor, while research scientist Roger Khalil waits for the results to emerge at the bottom of the processing equipment.Photo: SINTEF / Gry Karin Stimo

“Do you envisage coal-fired power stations as a potential market for torrefied Norwegian GROT?”

“Yes; these are another potential market.”

“Would that bring us any climatic benefits?”

“Yes, because branches and tops are a CO2-neutral raw material that would otherwise have rotted on the ground and partly turned into methane, which is a greenhouse gas.”


Price a decisive factor

SINTEF scientist Skreiberg believes that torrefied GROT will find a place in the Norwegian energy supply system, as fuel for both households and industrial heating furnaces. But what does the energy sector think?

Morten Fossum, business development manager in Statkraft Varme, answers that it is impossible to predict the future of this energy source until it is clear what the cost of producing the fuel will be.

“Everything is a matter of price. If this fuel is cheap enough, it would be suitable for small and medium-sized combustion plants that use dry fuel.”


Nutrients

Fossum does not hide the fact that the quality of Norwegian GROT is poorer than it is in Sweden, where it is used as fuel much more than in Norway. He believes that the difference is largely due to the way in which the raw material is harvested and treated.

“If large-scale harvesting of GROT gets under way in Norway, this will mean that nutrients are also being removed from forest soil. In that case, we ought to look at the possibility of bringing its ash back to the forest. But at present, that is not permitted in Norway,” says Statkraft’s Morten Fossum.


by Svein Tønseth

National green team
  • SINTEF’s research on torrefaction is financed via a cost-sharing scheme.
  • The biggest share of our research funding comes from the Research Council of Norway’s competence building project STOP (STable OPerating conditions for biomass and biomass residues combustion plants).
  • But industry is also making its contribution as a member of the Norwegian “national biofuel team”, CenBio. This is one of 11 research centres for environmentally friendly energy set up by the Research Council of Norway.
  • The NOK 2 million laboratory rig is wholly financed by SINTEF Energy Research.



 

 


 

 

 

 

 

 


Published May 21, 2013