The Toolkit outlines best practice techniques for assessing biomass resource potentials as a foundation for a biomass resource assessment. Biomass resource assessment is indispensable in estimating the bioenergy potential in a given location, the social and environmental impacts accompanying the resources production and the economic viability of biomass utilization scenarios.
The scope of the Toolkit covers:
Resource potential – theoretical, technical, economic or implementation potential
Approaches for estimation of resource potential – (resource focused, demand driven or integrated approach)
General principles, techniques and methods when undertaking a biomass resource assessment
Forest biomass and methods for resource assessment
Energy crops and methods for resource assessment
Agricultural residues and methods for resource assessment
Organic waste and methods for resource assessment
Global and country specific tools to make preliminary resource assessment and how to use them
The classification in types of biomass potentials is the first and most important step when undertaking a biomass resource assessment as it provides insight into explicit conditions, assumptions and limitation made in the assessment. The potential of the resource will define the feasibility of the project, return on investments, environmental considerations, coupled with social and political frameworks.
Details of the Resource Assessment Toolkit for Biomass Energy may be downloaded here:
Forestry felling licenses are taking up to a year to process farmers are being warned by the IFA. National Farm Forestry Chairman, Pat Collins said that the latest IFA Timber Price report shows that palletwood prices have increased by up to 15pc since February, while average sawlog prices are in excess of €85/tonne. Pat Collins said, “With demand for timber predicted to remain high at a domestic and global level, it is a good time to consider forestry. There are several options available under the Afforestation and Woodland Creation scheme to suit the soil, size, location and management objectives”.
He said that the size of a viable forest from a timber perspective is very location specific, for example a small forest that is near a road and easy to work can generate comparable timber incomes per hectare as a larger forests, particularly if managed as part of a harvesting cluster. “For those who have already planted, but who have not managed the forest or have timber in hard-to-access locations – now is the time to have your asset valued and look at realising a good price”. A farmer is legally required to apply to the Forest Service for a felling license before they can fell a tree in his plantation. If you are planning to apply for a felling licence, approvals can take up to 12 months to issue.
“Farmers are very concerned with the delays in getting felling licence approval”, said Mr. Collins. “The introduction of a single 10 year felling licence and the new public consultation process, although welcomed, is causing further delays”. He said that the Department must work to reduce the turnaround time for felling licence approvals so farmers can avail of the strong timber prices.
The Advice Notes aim to provide introductory material for entrepreneurs, startups and SME’s, considering to enter into the renewable energy sphere and based in the NPA regions partners to GREBE. The scope of the Advice Note covers regional, trade and industry, renewable energy (RE), technology information from Ireland, Northern Ireland, Scotland, Iceland and Finland. Different partner regions have different level of deployment of the various RE technologies covered by the Advice Notes. Thus, the level of information will vary depending on the level of deployment for each technology. For example, wind is not deployed on a large scale in North Karelia (Finland); however, it is widely deployed in Scotland, Ireland and Northern Ireland.
The focus of the Advice Notes is on regional information of some of the main economic characteristics sited as imperative, when making an informed choice, regarding which RE technology may be the optimal choice for a new business venture:
Costs and economics associated with the relevant technology
Support schemes available, relevant to the technology
Government allowance/exemptions, relevant to the technology
Funding available for capital costs of the relevant technology
List of the relevant to the technology suppliers/developers, with focus on local/regional, suppliers/developers and the products and services they offer.
Combined heat and power (CHP) is a method that delivers both heat and power on site in a single, highly efficient process, normally over 80% efficiency. CHP creates electricity and as a by-product of the generation process it produces heat. Wood biomass is fed into the CHP system similar to a normal biomass boiler and the produced gas is then fed to an engine which is connected to a generator generating electricity while the heat produced, can be fed into a heating system. Biomass is the world’s fourth largest energy source, contributing to nearly 14% of the world’s primary energy demand.
Small scale (<100kW) and micro-scale (<15kW) biomass CHP are particularly suitable for applications in commercial buildings, such as hospitals, schools, industrial premises, office building blocks, and domestic buildings. Optimum system design and implementation is crucial for cost-effective operation and it is established that the best economic performance come about with high load factors when the maximum amount of both electricity and heat sold on-site is maximised.
The Rural development programme co-financed Power from Biomass project completed its work in June 2018 after three years of renewable energy development in North Karelia, Finland. The project cooperating closely with GREBE in North Karelia, resulted in several new investments including two solar PV and energy storage systems in community buildings of Höljäkkä and Haikola in Nurmes. Project also established a regional network of 15 renewable energy demonstration sites.
The final seminar held in Joensuu, presented projects main outputs, latest developments in renewable electricity production, biomass-based small-scale combined heat and power, solar energy project of heat enterprises, and intelligent solar PV systems.
Project manager Antti Niemi from Pielinen Karelia Development Company PIKES Ltd. summarized the project results. The project established a regional demonstration network with 15 sites demonstrating renewable energy production systems. The Energiaraitti website presents the technical and economic information and live-information of solar PV systems. New production units established were mostly solar PV and some energy storages systems in farms, other rural enterprises and community buildings. The biomass-based renewable energy had a challenging business environment due to low price of fossil fuel oil. Despite, also some new biomass-based energy systems were established.
Project manager Kim Blomqvist from Karelia UAS presented the solar PV systems integrated into biomass-based district heating plants. Investments were made for 7 district heating plants with total annual production of 52 MWh. The heating plans were considered suitable for the solar PV as they have balanced electricity demand.
Marketing and product development manager Kimmo Tolvanen, representing regional energy company PKS, presented an in-depth overview of the energy system development in Finland and North Karelia. The main game changers in the energy system are expected to consist of wind and solar power production, energy storages and digitalization working all effectively together. The energy grid changes toward decentralised, intelligent and adaptive systems are evident. In addition, electricity markets are in transition, and new service developments are expected throughout the system from production to consumption.
Project coordinator Anssi Kokkonen from Karelia UAS presented the technical solutions of biomass-based combined heat and power production. The solutions included woodchip gasification plant (Volter Ltd.), Nano-chp Stirling engine (9 kWth + 0.6 kWe), fuelled by wood pellets (Ökofen). Both solutions are demonstrated at Sirkkala Energy Park by Karelia UAS.
Project manager Toni Hannula from energy company ESE (Etelä-Savon Energia, Mikkeli) presented intelligent solar power systems. The smart energy transition project by Lappeenranta Technological University has generated an overview of the systems change. The ESE has been successful in establishing biogas fuel stations, and piloting intelligent solar PV systems with 48 hours production forecast and directing the production optimally depending on energy price (electricity spot-price optimizing) and production and consumption loads. The system is piloted in Lumme Energia Oy estates.
The Power from Biomass project developed as a diverse renewable energy project and delivered several new services and RE production sites were established. The project had an international element through cooperation and networks of the GREBE project.
Another record in Finland: “Record-high consumption of wood fuels last year”
“In 2016, heating and power plants consumed a total of 19.3 million solid cubic metres of solid fuelwoods, representing an increase of 6 per cent from the previous year, and more than ever before. The total consumption of wood fuels reached an all-time record as well.
In 2016, wood fuels were the most important source of energy in Finland, accounting for 26 per cent of the total energy consumption.
Forest chips used as in the previous year
The most significant solid wood fuel used by heating and power plants was forest chips, the consumption of which increased by one per cent year-on-year to 7.4 million cubic metres.
The use of forest chips in the combined production of heat and power continued to decrease, shrinking by 6 per cent year-on-year to 4.5 million cubic metres, says Senior Statistician Esa Ylitalo of Natural Resources Institute Finland.
However, the use of forest chips in the generation of heat only increased by 14 per cent, to 2.9 million cubic metres. Together with the forest chips burned in small-scale housing, total consumption reached 8.1 million cubic metres.
Small-sized trees the most significant raw material of forest chips
More than half, or 3.9 million cubic metres, of the forest chips consumed by the plants were manufactured from small-sized trees, i.e. pruned small-diameter stems and unpruned small-sized trees. The second most common source, 2.5 million cubic metres, was logging residues. The use of stumps as raw material for forest chips came to 0.8 million cubic metres, and that of large-sized timber, not suitable for the manufacturing of forest industry products, to 0.3 million cubic metres.
The use of solid by-products for energy generation on the rise
Plants consumed 8 per cent more forest industry by-products and wood residues than in the previous year, a total of 10.9 million cubic metres. The main material used in burning was bark, accounting for almost 70 per cent, or 7.3 million cubic metres, of by-product wood. The use of nearly all types of solid wood fuels increased from the previous year. Proportionally, the greatest increase (+31%) was seen in the consumption of wood pellets and briquettes, and recycled wood (+29%).
The consumption of solid wood fuels was highest in the Central Finland region, while most forest chips were burned in Uusimaa and most forest industry by-products and wood residues in South Karelia.
Record-high amounts of wood used in energy generation in 2016
Based on preliminary data by Statistics Finland, the consumption of wood fuels in energy generation was record-high in 2016, a total of 96 terawatt-hours (TWh). Of the total consumption of wood fuels, solid wood fuels of heating and power plants covered 37 TWh, the combustion of black liquor 41 TWh, the small-scale combustion of wood 17 TWh and other wood fuels 2 TWh. Wood fuels were the most important source of energy, accounting for 26 per cent of the total energy consumption.” (Luke News)
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