Economic valuation of an offshore wind farm in Greece: the role of individual’s base-state influences and beliefs in the value formation process

The increased concern for the impacts of climate change on the environment, along with the growing industry of renewable energy sources, and especially wind power, has made the valuation of environmental services and goods of great significance. Offshore wind energy is being exploited exponentially and its importance for renewable energy generation is increasing. We apply a double-bound dichotomous Contingent Valuation Method analysis in order to both a) estimating the Willingness to Pay (WTP) of Greek residents for green electricity produced by offshore wind farm located between the islands of Tinos and Andros and b) identifying factors behind respondents’ WTP including individual’s behaviour toward environment and individual’s views on climate change and renewable energy. A total of 141 respondents participated in the questionnaire. Results show that the respondents are willing to pay on average 20€ every two months through their electricity bill in return for carbon-free electricity and water saving from the wind farm. Respondents’ environmental consciousness and their perception towards climate change and renewable energy have a positive effect on their WTP.

The role of subsidy in ensuring the sustainability of small-scale anaerobic digesters in Odisha, India

Small-scale anaerobic digester installation has been a development objective of the Indian government to provide rural households clean fuel. Anaerobic digester installation is heavily subsidised. Depending on caste, the rate of subsidy offered for the smallest system available (1m3) varies between 32.35% and 41.18% of the total installation price. Yet, there are gaps in knowledge regarding the usefulness of such subsidies from a sustainability perspective. A cost-benefit analysis was conducted to evaluate the circumstances required for digester sustainability. The analysis used household data collected from 115 cattle owning households in Odisha, India to evaluate profitability at three levels of subsidy (none, General caste subsidy, and Schedule Caste/Schedule Tribe subsidy). Additional analyses considered the effect of; taking a loan, replacing electric lighting with biogas lighting, and the wealth level of the household. The results indicated that access to subsidy improved profitability. Yet, profitability could be achieved without the use of subsidy. The level of benefit accrued by households was similar independent of wealth. However, the provision of subsidy was essential for ensuring profitability for those households required to take a loan to meet the expense of installation. Such findings highlight the importance of subsidy as a means of including the poor.

Ratios of UV, PAR and NIR components to global solar radiation measured at Botucatu site in Brazil

The relationships between the four radiant fluxes are analyzed based on a 4 year data archive of hourly and daily global ultraviolet (I(UV)), photosynthetically active-PAR (I(PAR)), near infrared (I(NIR)) and broadband global solar radiation (I(G)) collected at Botucatu, Brazil. These data are used to establish both the fractions of spectral components to global solar radiation and the proposed linear regression models. Verification results indicated that the proposed regression models predict accurately the spectral radiant fluxes at least for the Brazilian environment. Finally, results obtained in this analysis agreed well with most published results in the literature. (c) 2010 Elsevier Ltd. All rights reserved.

A Genetic Algorithm for Solar Boat

Genetic algorithm has been widely used in different areas of optimization problems. Ithas been combined with renewable energy domain, photovoltaic system, in this thesis.To participate and win the solar boat race, a control program is needed and C++ hasbeen chosen for programming. To implement the program, the mathematic model hasbeen built. Besides, the approaches to calculate the boundaries related to conditionhave been explained. Afterward, the processing of the prediction and real time controlfunction are offered. The program has been simulated and the results proved thatgenetic algorithm is helpful to get the good results but it does not improve the resultstoo much since the particularity of the solar driven boat project such as the limitationof energy production

Facade integration of polymeric solar collectors

The present paper examines building integrated solar collectors with absorbers of polymeric materials. Efficiency measurements of façade-integrated collectors with non-selective black and spectrally selective coloured absorbers are carried out. The performance of the polymeric absorber was compared with solar glass and polycarbonate twin-wall sheets as collector cover. Simulations demonstrate a high solar fraction for a solar combisystem with façade collectors for a well-insulated house in a Nordic climate. Two examples of house concepts with façade collectors are presented which address a new type of customer than the solar enthusiasts with special interest in renewable energy

PV-Wind Hybrid Systems for Swedish Locations

PV-Wind-Hybrid systems for stand-alone applications have the potential to be more cost efficient compared to PV-alone systems. The two energy sources can, to some extent, compensate each others minima. The combination of solar and wind should be especially favorable for locations at high latitudes such as Sweden with a very uneven distribution of solar radiation during the year. In this article PV-Wind-Hybrid systems have been studied for 11 locations in Sweden. These systems supply the household electricity for single family houses. The aim was to evaluate the system costs, the cost of energy generated by the PV-Wind-Hybrid systems, the effect of the load size and to what extent the combination of these two energy sources can reduce the costs compared to a PV-alone system. The study has been performed with the simulation tool HOMER developed by the National Renewable Energy Laboratory (NREL) for techno-economical feasibility studies of hybrid systems. The results from HOMER show that the net present costs (NPC) for a hybrid system designed for an annual load of 6000 kWh with a capacity shortage of 10% will vary between $48,000 and $87,000. Sizing the system for a load of 1800 kWh/year will give a NPC of $17,000 for the best and $33,000 for the worst location. PV-Wind-Hybrid systems are for all locations more cost effective compared to PV-alone systems. Using a Hybrid system is reducing the NPC for Borlänge by 36% and for Lund by 64%. The cost per kWh electricity varies between $1.4 for the worst location and $0.9 for the best location if a PV-Wind-Hybrid system is used.

Borlänge och Falun Brundtland städer

Development of an infrastructure for Brundtland Renewable Energy Network - BREN är ettEuropean Commission Alterner Project med Contract no XVII/4. 1030/Z96-032.Projektet har sitt ursprung i UN rapporten “Our Common Future” 1989. Grundläggande för att nå de mål som rapporten föreslog var att förändra och minska användningen av energi. I Danmark tog man fram en handlingsplan för hur energiförbrukningen skulle kunna minskas “Energi 2000 - Handlingsplan för en bäredygtig udvikling”. De danska och schleswigholstenske energiministrarna överenskom att starta vars ett energisparprojekt i en mindre stad. Projektet kallades “Brundtlandby” och de två första var Toftlund i Sönderjylland och Bredstedt i Nordfriesland. Efter en kort tid anslöt sig ytterligare två tyska städer, Rheinsberg och Viernheim, samt Rajec i Slovakien. Mellan städerna formades ett nätverk för att utbyta information. Nätverket, Brundtland City Project, var inspirerande för de ingående städerna i det fortsatta arbetet med energisparåtgärder. Brundtland City Project presenterades på en internationell konferens “Cities and Energy” i Trondheim, Norge, december 1995. Projektet väckte intresse och det föreslogs att nätverket, som ett pilotprojekt, skulle utvecklas i norra Europa för att senare utökas med andra europeiska länder. En ledningsgrupp tillsattes medrepresentanter från de nordiska länderna.En ansökan sändes till European Commission, Alterner Program, och denna beviljades i juli 1996. Projektet indelades i (9 Activities. Aktivitet 1, var att sammanfatta erfarenheterna av Brundtland City Project i Toftlund, Danmark och Brundtland Cities Nätverket i Sovakien, Tyskland och Danmark. Den nordiska delen startar med Aktivitet 2, vilket var att engagera kommuner/städer i Finland, Norge och Sverige. Som samordnade för den svenska delen utsågs Solar Energy Research Center SERC vid Högskolan Dalarna. Projektet presenterades vid ett seminarium den 30 september för representanter för Borlänge och Falu kommuner. Den 10 december 1996 accepterade de två kommunerna inbjudan att ingå i det nordiska nätverket. Uppgiftslämnare i Borlänge kommun har varit Pelle Helje, Borlänge Energi och i Falu kommun Anders Goop, stadsbyggnadskontoret samt för underlag till Newsletter Jan Kaans, fastighetskontoret.Rapportering till Brundtland Center Danmark av arbetet i Borlänge och Falu kommuner har skett vid tre tillfällen, Aktiviteterna 2-5, 1997-12-16, Aktivitererna 6-7 inkluderande delar av aktiviterna 8-9, 1998-05-03 samt underlag till Newsletter, 1998-07-01. De nordiska rapporterna har sammanställts vid Brundtland Center Danmark för rapportering till European Commission. Gemensamt språk har varit engelska. Efter rapportering av aktiviterna 2 - 5 inbjöds till ett projektmöte och en studiedag vid Brundtland Center den 23 och 24 mars 1998. Det var första tillfället deltagarna i projektet strålade samman och nätverket tog därmed en mera konkret form. Man beslutade också att nästa projektmöte skulle hållas i Borlänge i augusti 1998 med Borlänge Energi och Solar Energy Research Center SERC som organisatörer. Beroende på att Brundtland Centre Danmark upplösts av ekonomiska skäl blev projektmötet i Borlänge inställt.Sammanställning av Final Report, October 1998, har utförts av Esbensen Consultants.Framtida utveckling av nätverketArbetet med Brundtland City Network avses fortsätta som ett “EU Thermie B-project” och nätverket kommer att utökas med fyra nya Brundtlandstäder från Österrike, Tyskland Italien och Storbritanien. Dessutom kommer samhället Putja i Estland att ingå i nätverket men detta financieras av EU-Phare programme.

Borlänge and Falun Brundtland cities

Development of an infrastructure for Brundtland Renewable Energy Network - BREN is a European Commission Alterner Project with Contract no XVII/4. 1030/Z96-032.The project has its origin in the UN-report “Our Common Future”, 1989. A change in and reduction of the use of energy was fundamental in order to reach the goals which the report proposed. Denmark decided on an action plan on how energy consumption could be reduced “Energi 2000 - Handlingsplan för en bäredygtig udvikling”. The ministries of energy in Denmark and Schleswig Holstein both agreed to start an energy saving project in a smaller town. The project was called “Brundtlandby” and the two first were Toftlund in South Jutland and Bredstedt in North Friesland. After a short period a further two German Cities, Rheinsberg and Viernheim, and Rajec in Slovakia joined the group. A network for the exchange of knowledge and experience between the cities was formed. The network, Brundtland City Project, inspired the participating cities in the continuing work with energy saving measures. The Brundtland City Project was presented at an international conference “Cities and Energy” in Trondheim, Norway,in December 1995. Great interest was shown in the project and it was decided that a network should be developed in northern European countries as a pilot project to be enlarged with other European countries later on. A steering committee was formed with representatives from the nordic countries.An application was sent to the European Commission, Alterner Program, and was approved in Juli 1996. The project was subdivided into nine activities. Activity 1, consisted of summarising the experiences of the Brundtland City Project in Toftlund, Denmark and the Brundtland Cities network in Slovakia, Germany and Denmark. The Scandinavian part started with Activity 2, to engage municipalities/cities in Finland, Norway and Sweden in the project. The Solar Energy Research Center, SERC, Högskolan Dalarna was appointed as co-ordinator for the Swedish part. The project was presented at a seminar on the 30th September for representatives from the municipalities of Borlänge and Falun. On the 10th of December 1996 the two municipalities accepted the invitation to join the Northern network. Pelle Helje, Borlänge Energi, has been informant for the municipality of Borlänge and Anders Goop, Department of Urban Planninginformant for the municipality of Falun with Jan Kaans, Estates department providing information to the basis for the Newsletter.Reports on the work in Borlänge and Falun municipalities have been made to Brundtland Center Denmark on three occasions; Activities 2-5, 16-12-1997, Activities 6-7, including parts of activities 8-9, 03-03-1998, and the basis for the Newsletter, 01-07-1998. The Nordic reports have been compiled at the Brundtland Center Denmark for submission to the European Commission. English has been the common language. After the report of activities 2 - 5 the participants wereinvited to a project meeting and a workshop at Brundtland Center the 23rd and 24th March 1998.This was the first occasion the participants in the project met and the network thus took a moreconcrete form. It also was decided that the next meeting should be in Borlänge in August 1998,with Borlänge Energi and Solar Energy Research Center SERC as organisers. As BrundtlandCentre Denmark was wound up for financial reasons, the project meeting in Borlänge wascancelled.Compilation of the Final Report was carried out by Esbensen Consultants in October 1998Future development of the networkIt is intended to continue the work with the Brundtland City Network as an “EU Thermie Bproject”and the network will be enlarged with the addition of four new Brundtland Cities from Austria, Germany, Italy and Great Britain. In addition the village of Putja in Estonia will join the network but this will be financed by the EU-Phare programme.