Technology/Knowledge Transfer Cases

Chipper

One aim of the GREBE project is to promote knowledge sharing and information exchange between actors in renewable energy supply and demand. Transnational sharing of knowledge is a key element of GREBE and special focus of working package 7 in order to facilitate transnational effective knowledge transfer and collaboration in the RE business sector. Two more case reports are now available on the transfer of technology and knowledge in the NPA:

Ecohog – Technology for the waste and recycling sector

Ecohog Ltd. is a family owned equipment manufacturer located in Co Tyrone, Northern Ireland. Although a small and medium-sized enterprise (SME), Ecohog is operating in a global scale and have over 20 years’ experience supplying equipment to the waste and recycling sector.

Worldwide, there is a greater focus on minimising waste, reducing landfill waste and recycling in general. Therefore the need to integrate efficient waste separation and processing technology is a growing global concern. Also in Finland, the recovery of waste has become increasingly important. The technology transferred to Finland provides an alternative to manual sorting which is both exhausting and expensive. The technology allows customers to incorporate air separation into new or existing processing configurations that experience contaminates in the materials.

This is available on the GREBE Renewable Business Portal: www.renewablebusiness.eu and can be downloaded here: Ecohog – Technology for the waste and recycling sector

Innovative Hybrid Chipper for Forest Chip Production – a theoretical technology transfer case study

This report is about the innovative hybrid chipper for forest chip production and is a pure theoretical technology transfer case based on a simulation study using input data from the literature.

Several parameters to improve knowledge towards the transferring of the technology and applying it in other partner regions were the focus of this study on an innovative hybrid technology chipper. The focus was on the knowledge on fuel supply costs and supply system requirements for this technology in order to supports market access of new technology and to reduce the risks relating to long-term performance and costs for such technology through the used method. The method used was discrete-event simulation with the simulation of one year performance.

This is available on the GREBE Renewable Business Portal: www.renewablebusiness.eu and can be downloaded here: Innovative Hybrid Chipper for Forest Chip Production

All technology and knowledge transfer cases are supporting the activity towards a guideline supporting enterprises in introducing new to market energy solutions.

Supporting the transnational transfer of knowledge and technology, the Renewable Business Portal provides a platform to demonstrate the full potential of the renewable energy (RE) sector and showcase innovations in RE technology.

Energy Efficiency and Entrepreneurship

AR Blog

Becoming an entrepreneur can be challenging, therefore it’s important to stay ahead of the curve. Most business owners now recognise the importance of energy efficiency measures and sourcing renewable energy where possible. This is due to the cost savings these options can offer, allowing businesses to reinvest in other activities. Saving 20% on your energy bills can generate returns which are equivalent to a 5% increase in sales1.. Additionally, as consumers are becoming more environmentally aware, there are increasing expectations on suppliers, across all sectors, to demonstrate their commitment to sustainability, particularly in relation to renewable energy.

A survey completed by Orsted, highlighted that 73% 2. of consumers would choose a retailer that used renewable energy over one that didn’t. Improving your reputation and becoming environmentally conscious needn’t be something that will interrupt or hinder your businesses operations – it can significantly increase your competitiveness.

Committing to renewable energy:

  • Businesses who want to commit to renewable energy can do so through Power Purchase Agreements (PPA) either from an electricity supplier or direct engagement with a renewable electricity generator, in more recent times this has been referred to as a Corporate Power Purchase Agreement.
  • Alternatively, a business can invest in renewable technology to generate renewable electricity, which satisfies either part or all the businesses electricity demand. On a global scale, RE100 is a collaborative initiative, which some of the world’s most influential companies have joined and committed to 100% renewable electricity. Companies who have committed to RE100 primarily adopt the methods mentioned above to ensure they achieve their targets.

With a steady uptake of ‘green procurement’, which focuses on sourcing and purchasing products and services that use fewer resources and minimises their impact on the environment, there is certainly reason to get your business ‘going green’. In Northern Ireland, the ‘Sustainable Development strategy’ recognises the importance of responsible procurement in the public sector to ensure the effective and efficient use of resources. This was developed to select suppliers who have a sound environmental standing. Therefore, with environmental awareness and targets only set to increase in the future, it stands to sense for businesses to begin exploring their options in relation to sourcing renewable energy, if they have not already done so. This will enable them to ensure business operation remains competitive.

1 https://www.carbontrust.com/resources/guides/energy-efficiency/better-business-guide-to- energy-saving/

2 https://www.energyvoice.com/otherenergy/176726/orsted-claim-73-of-customers-prefer-renewable-energy-retailer/

3 http://there100.org/re100

Advice Notes on Energy Storage Economics for the NPA Region

Energy Storage

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.

Full details are available on the GREBE website:

http://grebeproject.eu/wp-content/uploads/2018/04/Advice-Notes-Energy-storage-2-3.pdf

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.

Some of the renewable energy resources are classified as intermittent in nature, meaning that the corresponding technologies produce electricity/heat depending on the availability of the resource. Two of the main drawbacks are the short-term variability and low predictability inherent to renewable sources. Thus, when the wind is not blowing and the sun is not shining, the clean technologies cannot match the demand. However, when the resources are available, it is often the case that they produce more energy than required. By storing the energy produced and supplying it on demand, these technologies can continue to power the businesses even when the sun has set and the air is still, creating a continuous, reliable stream of power throughout the day. Furthermore, energy storage systems can shift consumption of electricity from expensive periods of high demand to periods of lower cost electricity during low demand.

battery storage

This can be over different timescales, from intra-day (when energy is shifted from low value to high value periods within the same 24-hour period) to inter-seasonal, where energy is stored in summer when demand is lower and used in winter when demand is greater. Contingent on elements such as a facility’s location, utility rates, and electrical load, energy storage can be an apt solution for facilities to cut energy bills. The use of energy storage can also allow greater returns on investment to be made from deployed renewable energy technologies. Storage technologies could decrease the need to invest in new conventional generation capacity, resulting in financial savings and reduced emissions especially from electricity generation. Utilisation of storage also means fewer and cheaper electricity transmission and distribution system upgrades are required.

Advice Notes on Hydro Technology Economics for the NPA Region

Hydro

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.

Full details are available on the GREBE website:

http://grebeproject.eu/wp-content/uploads/2018/07/GREBE-Advice-Notes-Hydro.pdf

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.

Hydro2

Hydropower is of the most reliable and cost-effective methods to generate electricity, as it can immediately respond to variations in electricity demand meeting both base-load and peak-load demand. The key advantage is that hydro power provides a steady and secure source of electricity supply. Furthermore, it very highly efficient (from 70 to 90%), has a long life span and attractive energy pay-back ratio. Other benefits of hydro are that it is a largely predictable resource of renewable energy (the annual generation can be predicted using historical rainfall data/catchment flow data).When considering the payback period for SHP, account should be taken of the lifespan of the system.

A general SHP project cost level is very difficult to predict as they are very project specific contingent on the local surroundings, hydro-technical constructions, turbines and electrical equipment. Small-scale hydropower uses water flowing through a turbine to drive a generator that produces electricity. The amount of a hydropower installation’s potential power output (kW) is directly related to two key variables:

Head – The vertical distance between the water level at the intake point and where the water passes through the turbine. Hydro projects can be categorized into three categories according to the existing head.

  • Low head – up to 10m
  • Medium head – 10m to 50m
  • High head – greater than 50m.

Flow rate – the volume of water flowing through the turbine per second, measured in litres/second (l/s), or cubic metres/second (m3 /s).

Advice Notes on Solar Thermal Technology Economics for the NPA Region

Solar Thermal

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.

Full details are available on the GREBE website:

http://grebeproject.eu/wp-content/uploads/2017/10/GREBE-Advice-Notes-SOLAR-Thermal.pdf

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.

ST

Solar thermal systems use solar collectors to absorb energy from the sun and transfer it, using heat exchangers, to heat water. Solar thermal delivers hot water at temperatures of between 55ºC and 65ºC. This is a comparatively mature technology and many installations date back to the 1970s. There are two main types of solar heating collectors:

  • Flat-plate collectors – a sheet of black metal, that absorbs the sun’s energy, encases the collector system. Water is fed through the system in pipes, which conduct the heat to the water.
  • Evacuated tubes – a series of parallel glass heat tubes grouped together. Each tube contains an absorber tube enclosed within a vacuum. Sunlight passing through the outer glass tube heats the absorber tube contained within it, and in doing so, the heat is transferred to a liquid flowing through the tubes.

Evacuated tubes are the most efficient type of solar water collector at around 80% efficiency (compared to around 70% for flat plate collectors). Correspondingly, they also cost more to manufacture; thus, they are more expensive. Modern solar thermal technologies are dependable, efficient and completely safe. Solar thermal technology can have up to 80% efficiency rate in delivering heat to your business.

 

CHP project of Kuittila Power – Case Study

The CHP project of Kuittila Power was initiated by the entrepreneur/farmer interested to decrease the energy costs and produce own energy for the farm and co-located company. One of his staff and a development company introduced the solution. The reference site and a manufacturer were visited, after which a feasibility study was carried out.

As there was positive result, the investment project was initiated and 35% co-financing negotiated from the local authority. The manufacturer provided the technical planning, and investor took care of micro DH network construction and required connections (with the electricity company). A local constructor made the building construction.

The investment initiated in April, was ready in October 2012. The first winter included only test-runs, as there was no available high quality wood fuel. In spring, own fuel supply (with dryer solutions from the reference site) was established and plant started operating.

The first year included technical operations to improve the performance; technical support was received through the manufacturer. The plant is operating now a 3 year at a roll, and received significant status of small-scale CHP demonstration in the region, nationally and internationally.

For more details see:

Click to access Small-Scale-Biomass-CHP-Kuittila-Power-Finland.pdf

 

 

New scheme encouraging homeowners to install solar panels launched today

solarPanelsRoofInstall_large

A new scheme encouraging homeowners to install solar panels has been launched this morning. The pilot scheme offers grants for the installation of solar panels and extra funds to install battery storage systems.  Environment Minister Denis Naughten says the scheme will allow people to turn their home into their very own “renewable power station.” He said homeowners can save around €220 in electricity costs every year by taking advantage of the scheme.

Announcing the grants for homeowners, Minister for Communications, Climate Action and Environment, Denis Naughten TD said: “Turning your home into a renewable power station is now one step closer. Microgeneration is an incredibly exciting space that will allow citizens in local communities to generate their own electricity and contribute towards Ireland’s climate action targets. With this grant that I am announcing today, a typical 3-bed semi-detached house would spend about €1,800 on a solar panel system and would save approximately €220 per year on their electricity bills.”

The Minister added: “The pilot scheme will be subject to a 6-month review at which time the costs of installation will be assessed and further opportunities to broaden this scheme to other groups and other technologies will be explored.” The scheme will be funded by the Department of Communications, Climate Action and Environment and administered by the Sustainable Energy Authority of Ireland (SEAI). The grant is available for homes built and occupied before 2011 and details of eligibility criteria and how to apply are set out here. A registered solar PV installer must be used and a full list of registered installers is also available on the SEAI website.

https://www.irishexaminer.com/

Government approves scheme to diversify green energy

DNaughten

A new scheme designed to diversify the State’s renewable energy production and boost its chances of meeting key EU targets has been approved by the Government. The Renewable Electricity Support Scheme (RESS) is designed to help the State meet its renewable pledges up to 2030. Its first priority is to boost renewable energy production quickly to help turn 16 per cent of the State’s energy needs “green” by 2020. The scheme will incentivise the introduction of sufficient renewable electricity generation by promoting investment by community groups in green projects. Offshore wind and tidal projects will be central if the State is to meet its targets, while it is expected to also support an immediate scale-up of solar projects. Projects looking for support under the scheme will need to meet pre-qualification criteria, including offering the community an opportunity to invest in and take ownership of a portion of renewable projects in their local area.

Auction system

The RESS scheme introduces a new auction system where types of energy will bid for State support. It is proposed that the scheme be funded through the Public Service Obligation Levy, which is a charge on consumers to support the generation of electricity from renewable sources. Individual projects will not be capped, but the Government will limit the amount that a single technology, such as wind or tidal, can win in a single auction. The auctions will be held at frequent intervals throughout the lifetime of the scheme to allow the State to take advantage of falling technology costs. The first auction in 2019 will prioritise “shovel-ready projects”. “By not auctioning all the required capacity at once, we will not be locking in higher costs for consumers for the entirety of the scheme,” Minister for the Environment Denis Naughten said. In effect it should make it easier for solar and offshore wind to get investment, yielding multiple billions for green projects over the next 15 years.

2020 vision

It is hoped renewable energy will represent 40 per cent of the State’s gross electricity consumption by 2020, and 55 per cent by 2030, subject to determining the cost-effective level that will be set out in the draft National Energy and Climate Plan, which must be approved by the EU and in place by the end of 2019. In addition the scheme is intended to deliver broader energy policy objectives, including enhancing security of supply. “This scheme will mark a shift from guaranteed fixed prices for renewable generators to a more market-oriented mechanism [auctions] where the cost of support will be determined by competitive bidding between renewable generators,” said Mr Naughten. The next step for the Government is to secure EU approval for the package, which typically takes six to nine months. It is estimated that the first auction will be in the second half of next year.

https://www.irishtimes.com/news/environment/government-approves-scheme-to-diversify-green-energy-1.3575492

Advice Notes on Wind Technology Economics for the NPA Region

Biomass

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.

Full details are available on the GREBE website:

http://grebeproject.eu/wp-content/uploads/2018/07/GREBE-Advice-Notes-Biomass.pdf

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.

The economics of a biomass system are governed by the capital cost, the biomass fuel cost, the offset fuel costs and the incentives available. The capital cost of a biomass boiler is dependent upon the size, fuel type used and level of automation of the system.

Biomass is the world’s fourth largest energy source, contributing to nearly 14% of the world’s primary energy demand. The most common fuel is wood, which can be supplied in three forms; logs, chips and compressed wood pellets. However, biomass energy also includes energy crops, food waste streams, agricultural residues, industrial wastes and residues which can be used for heating in certain, specific circumstances. A range of biomass boilers are available, in sizes to suit homes, small businesses, community buildings through to large hospitals and industrial processes. A reliable feedstock supply chain is vital for the economic viability of a biomass boiler system.

Fuel costs are central when considering the levelled cost of electricity, since ongoing running costs far outweigh capital investment. Thus, it is imperative before considering investment in a biomass boiler system to ensure that the right fuel can be sourced locally. Economic benefits of biomass include relatively inexpensive resources; locally distributed energy sources provide constancy and reliability, price stability and generation of employment opportunities in rural communities. Risks included price volatility and availability of feedstock.

EcoSmart External Insulation Ltd – Case Study

EcoSmart External Insulation Ltd. is an energy efficiency company based in Castlerea, Co. Roscommon in the West of Ireland. EcoSmart External Insulation Ltd. provides external insulation services nationwide to all parts of Ireland. The owners of EcoSmart External Insulation Ltd. are both from an engineering and architectural background and initially formed a partnership in 2009, after working together since 2007 on construction projects using Insulated Concrete Formwork (ICF).

As a result of the economic downturn and subsequent changes in the construction industry in Ireland, the partners decided to continue working together and focus on renewable energy technologies and energy efficiency in construction. In 2011, they formed a partnership with a UK construction company and formed a new company Cara EcoSmart Ltd. where they were worked on projects in the UK funded by the Green Deal Scheme. Cara EcoSmart Ltd. required a robust quality assurance system, and adopted and modified one which was used by other partners in the company. This knowledge transfer proved very valuable when tendering for contracts in Ireland.

In 2013, they formed EcoSmart External Insulation Ltd., and the construction sector slowly started recovering in early 2014 with people investing more on home improvements. The SEAI reintroduced and increased grant funding to approximately €4,500. This depended on the scale of energy efficiency measures undertaken. The availability of this grant made a very big difference in the mentality of people and they were prepared to undertake energy efficiency upgrades.

Click to access Energy-Efficiency-EcoSmart-External-Insulation-Ireland.pdf