DOCSLIB.ORG

Institutt for Energite|<Nikk

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Institutt for Energite|<Nikk NO9700102 \ FE/IFE/kR/E-96/008 Cosmic radiation and airline pilots. Exposure patterns of Norwegian SAS-pilots 1960 to 1994 February 1997 Institutt for energite|<nikk Institute for Energy Techri&logy IFE/IFE/KR/E-96/008 COSMIC RADIATION AND AIRLINE PILOTS. EXPOSURE PATTERNS OF NORWEGIAN SAS-PILOTS 1960 TO 1994 BY ULFTVETEN February 1997 INSTITUTE FOR ENERGY TECHNOLOGY KJELLER, NORWAY Performing Organisation Document no.: Date Institutt for energiteknikk IFE/KR/E-96/008 February 1997 Kjeller Project/Contract no. and name Client/Sponsor Organisation and reference: E-483 EU-prosjekt Title and subtitle Cosmic radiation and airline pilots. Exposure patterns of Norwegian SAS-pilots 1960 to 1994. Author(s) Approv6d/^^'-^-J UlfTveten Gordon Christensen Gordon Christensen Institute for Energy Technology, Kjeller Abstract The work which is presented in this report is part of a Norwegian epidemiological project, carried out in cooperation between Institute for Energy Technology (1FE), the Norwegian Cancer Registry (NCR) and the Norwegian Radiation Protection Authority (NRPA). The project has been partially financed by the Norwegian Research Council. Originating from the Norwegian project, a number of similar projects have been started or are in the planning stage in a number of European countries. The present report lays the ground for estimation of individual exposure histories to cosmic radiation of pilots employed by the Scandinavian Airline System (SAS). The results presented in this report (radiation doserates for the different types of aircraft in the different years) will, in a later stage of the project, be utilized to estimate the individual radiation exposure histories. The major sources of information used as basis for this work is the collection of old SAS time tables found in the SAS Museum at Fornebu Airport in Oslo, and information provided by members of the Pilots Associations. Key Words Cosmic radiation, Cancer, Aviation ISSN ISBN Numbers of Pages 0333-2039 82-7017-160-3 106 Supplementary Data ACKNOWLEDGEMENTS The author wants to express his gratitude for the valuable help given by the Norwegian Pilots Association, the SAS (Scandinavian Airlines System) Pilots Association, the SAS Museum, and in particular the flight captains Odd Iversen and Olav Eide and copilot Stein Gilhuus. He also wants to thank Wallace Friedberg of the Civil Aviation Institute, Oklahoma City for providing the computer program CARI-3N, which has been used to calculate the radiation doses presented in this report. TABLE OF CONTENTS 1 Introduction 1 2 The epidemiological project 1 3 Alternative approaches to radiation dose estimates 2 4 Information from the SAS time tables 3 5 Aircraft types and pilots per aircraft 5 6 Distribution of pilot-hours on different types of routes 6 7 Flight profiles for different routes 6 8 Heliocentric potential over the time period considered 7 9 Change of airport locations 8 10 Calculation of the radiation dose and doserate along specific flight legs, using the CARI-3N computer program 8 11 Typical radiation doserate on specific aircraft types over the years 1960 to 1994 9 Appendix A Flight-hours per week flown by Norwegian SAS-pilots 10 Appendix B Flight profiles for SAS routes 17 Appendix C Radiation doses and doserates to Norwegian SAS-pilots on specific flights 59 1 Introduction The work which is presented in this report has been performed as part of a Norwegian epidemiological project entitled «Exposure to low level ionizing radiation and incid- ence of cancer in airline pilots and crew», carried out in cooperation between Institute for Energy Technology (IFE), the Norwegian Cancer Registry (NCR) and the Norwe- gian Radiation Protection Authority (NRPA). IFE was initiator of the project, and acts as project leader. The project has been partially financed by the Norwegian Research Council. Originating from the Norwegian project, a number of similar projects have been star- ted or are in the planning stage in a number of European countries. Interest has also been expressed from institutions in the USA and Canada. Attempts to form a European project combining all these efforts failed twice to obtain funding from the European Union. Other means of financing the project work and meetings, in order to obtain a satisfactory level of coordination and cooperation between the national projects are presently being sought. The present report lays the ground for estimation of individual exposure histories to cosmic radiation of pilots employed by the Scandinavian Airline System (SAS). The results presented in this report (radiation doserates for the different types of aircraft in the different years) will, in a later stage of the project, be utilized to estimate the indivi- dual radiation exposure histories. The major sources of information used as basis for this work is the collection of old SAS time tables found in the SAS Museum at Fornebu Airport in Oslo, and informa- tion provided by members of the Pilots Associations. 2 The epidemiological project The present project is based upon a concept conceived in 1981 by the author of the present report in cooperation with Georg Petersen, MD, then at the Oslo Health Coun- cil, presently United Nations Expert stationed in Cambodia. The concept was further developed in 1982, and subsequently submitted as a project proposal to the Norwegian Research Council. Although the proposed project won the approval of the Civil Avia- tion Administration and was granted the necessary permissions from the Cancer Regis- ter and the Data Inspectorate, adequate funding was not obtained, and the project was dormant until 1992, when a renewed and extended project proposal was submitted to the Commission of the European Communities' Radiation Protection Programme (RPP). In addition to the institutions mentioned in Chapter 1, the planned project par- ticipants were the German Cancer Research Center, Heidelberg and the Wageningen University, Department of Epidemiology and Public Health, Netherlands. The project was subsequently approved by the RPP. A feasibility study was funded, which should include airline pilots and, if feasible, cabin crew licensed in Norway, and was carried out by the Norwegian participants in the project proposal. The Norwegian cohort has now been established by NCR, and extensive quality con- trol and evaluation of the completeness of the cohort has been carried out. The cohort consists of all pilots and cabin crew in the registers of the Norwegian Aviation Admini- stration since 1 January 1946 for the pilots and from 1 January 1950 for cabin crew and up till 18 February 1994. There are about 3,800 pilots and 3,000 cabin crew in the cohort. 3 Alternative approaches to radiation dose estimates In the initial stages of the project several alternative approaches were considered. The flight hours of the individual pilots between licence renewals are registered in the Nor- wegian Aviation Administration and have been entered into the cohort data base. This, however, has to be seen in conjunction with information on the type of routes flown. One reason for this is that the reported flight hours include the taxing time (time from departure from the gate until take-off and time from touch-down to arrival at the gate). For short flights the taxing time, when no excess radiation is received, is a much larger proportion of the flight time than for long flights. It was found that in the Norwegian material the aircraft type was available for the majority of the pilots. If this had not been the case, use of a typical career pattern was considered. Typically a commercial pilot starts as co-pilot on short flights, advance to continental routes and finally to intercontinental routes, before advancing to captain on short routes etc. For cabin crew it does not appear that historic data on flight hours are available. The dose history then has to be based on the information available, e.g. duration of employ- ment. Further investigations on availability of data are on-going. In the present project it has been chosen to make detailed estimation of the individual dose exposure histories, based on information on aircraft type, for all pilots within the cohort employed by SAS. A similar effort ought to have been carried out for pilots employed by the other larger Norwegian airlines (Braathens SAFE, Wider0e and per- haps a few others), but this has not been possible on the funds available. At least for the time being the exposure histories of these pilots will be estimated in the same manner as for SAS pilots flying the same type of aircraft. Very early in the project period it was decided to base the dose calculations on the computer program CARI-3N, developed at the US Federal Aviation Administration. See ref. (Friedberg et al) for information about this program. The program is widely used for calculations of this type. The program calculates doses along defined flight routes, but the question remained: how to choose the flight routes for the individual pilots in the cohort. The files of the Aviation Administration contain a large number (several hundred) of types of aircraft flown by pilots within the cohort. All types of aircraft not used by SAS have been assembled in classes according to typical cruise altitude, typical flight profile as well as route (departure and destination airports) have been defined, and calcula- tions of doserates for each "altitude class" has been carried out. This task could not have been carried out without the invaluable assistance of a number of commercial pilots, and coordinated by co-pilot Stein Gilhuus of SAS and co-pilot Peter Bull of Braathens SAFE. The calculations of doses and doserates for aircrafts not used by SAS will be presen- ted in a separate report. 4 Information from the SAS time tables All routes from the SAS time tables were entered in tables in an ACCESS data base.
Load more

Recommended publications
  • Mulighetsstudie Veteranflysenter Kjeller
    1 MULIGHETSSTUDIE VETERANFLYSENTER KJELLER UTARBEIDET AV KJELLER FLYHISTORISKE KULTURPARK, KFK DESEMBER 2015 2 INNHOLDSFORTEGNELSE 0. FORORD ................................................................................................................................... 3 1. SAMMENDRAG ....................................................................................................................... 4 2. OPPGAVEFORSTÅELSE ...................................................................................................... 5 3. ORGANISASJON .................................................................................................................... 6 Tradisjon, behov og referanser .............................................................................................. 7 4. DAGENS SITUASJON .......................................................................................................... 10 Dagens bygningsmasse........................................................................................................ 17 AIM ........................................................................................................................................... 18 Behov for kulturtiltak på Kjeller, arealer: ............................................................................. 19 5. LØSNINGSFORSLAG .......................................................................................................... 22 Grunnlagsdata .......................................................................................................................
    [Show full text]
  • IFE ANNUAL REPORT 2018 1 Årsrapport for Institutt for Energiteknikk
    Research for a better future YEAR www.ife.no IFE ANNUAL REPORT 2018 1 Årsrapport for Institutt for Energiteknikk. Med forbehold om trykkfeil. Grafisk design og trykk: CopyCat AS Foto: Mick Tully, Image Communication Layout: Copycat AS 2 RESEARCH FOR A BETTER FUTURE Contents 04 About IFE 05 Key figures 07 From the President 11 Organisation chart 12 IFE’s strategic research focus 16 Materials and Process Technology 20 Centres for Environment-friendly Energy Research (FME) 23 Fluid Flow and Environmental Technology 26 Digital Systems 28 Radiopharmacy 31 IFE’s nuclear research activities 34 Nuclear Waste Management and Decommissioning 38 Environment and safety 41 Innovation and commercialisation 42 Income statement 43 Report of the Board of Directors IFE ANNUAL REPORT 2018 3 About IFE The Institute for Energy Technology (IFE) conducts research for a better future. Since 1948, we have been a frontrunner in international energy research. The knowledge we have developed has saved the petroleum industry several hundred billion kroner. We have contributed to the development of ground-breaking cancer medicine, new solutions in renewable energy, more energy-efficient industrial processes, zero-emission transport solutions and future-oriented energy systems. Our research and expertise have led to safer use of nuclear power, and we have developed methods for verifying the disarmament of nuclear weapons. The research at IFE has created jobs in Norway, facilitated business development and generated important expertise for the Norwegian trade and industry sector. At IFE, we build bridges between research, education and industry. We have extensive infrastructure and full-scale laboratories where theoretical models are transformed into commercial activities.
    [Show full text]
  • 3Rd OECD Roundtable on Cities and Regions for Sdgs 16-17 November 2020 Virtual Conference List of Participants
    3rd OECD Roundtable on Cities and Regions for SDGs 16-17 November 2020 Virtual Conference List of Participants # Name Institution 1 Abra Walsh Onavance 2 Adnane Founoun Université Hassan 2 3 Adriana Agrimi Puglia Regione 4 Adriana Domingos Tribunal de Contas do Estado do Paraná 5 Adriano Greco da Fonseca Adriano Greco da Fonseca 6 Afsane Moeeni DOE 7 Agnes Lüdicke DeLoG 8 Agnes Rivet City and Eurometropolis of Strasbourg 9 Agustín Castillo-Martínez Ayuntamiento de Granada 10 Aissata M.B. Camara City of New York 11 Aïssatou N'Diaye-Sydnei European Commission (DG DEVCO) 12 Akrem Haddad H-Corp 13 Alessandra Norcini Regione Lombardia 14 Alessandro Santini Università IUAV di Venezia 15 Alessia Secci Università Iuav di Venezia 16 Alexander Hay University of Toronto 17 Alexander Trepelkov UN DESA 18 Alexandra Descôteaux #Meet4Impact 19 Alexandra Posypanková City of Bratislava 20 Alexandra Van Milink sciencespo 21 Alexandre Cesar Motta de Castro Procompetence Consultoria 22 Alexandre Gross 23 Alexandre Mohamedaly Ecorys 24 Ali Belgith 25 Alice Siragusa EC JRC 26 Alina Barysnikova Viken fylkeskommune Ministry of Public Works, Development and 27 Alina Huzui-Stoiculescu Administration 28 Aline Calefi Lima Fiep 29 Alys Solly Politecnico di Torino 30 Amalie Hilde Viken 31 Amie Figueiredo UNECE 32 Amit Yagur-Kroll Central Bureau of Statistics Israel 33 Ana Figueirôa Permanent Delegation of Portugal to the OECD 34 Ana Maria Mouro de Oliveira Gomes 1 Ana Rita Duarte Vacas Unidade Avaliação 35 Secretaria Ministério Ambiente - POSEUR e Monitorização 36
    [Show full text]
  • NO9600038 Organization Chart/Department Heads: January 1996
    NO9600038 Organization Chart/Department Heads: January 1996 Board Halden Board Managing Director Haiden Ass. Managing Programme Group Director Adm. and Tech. Support Project Manager Ass. Project Manager Process Adm. and Physics Simulation Tech. Support Arne Skjeltorp Arild Ek Man-Machine Test Rig Design Energy Isotope Communication and Production Systems Laboratories Kjell Haugset Olav Aarrestad PerO. Finden Per 0. Bremer Control Room Experiment Reservoir- and Materials Systems Engineering Exploration Technology Technology Thorbjorn J Bjorlo Yoji Minagawa Tor Bjornstad Knut Lunde Simulation and Data Production Fluid Flow- and Health System Engineering and Evaluation Corrosion Technology and Safety Age Sten Solie Erik Kolstad Liv Lunde Gordon Christensen Electric Reactor Operation Power Systems and Engineering Reactor Operation Kjell Caspersen Knut H. Johansen Rune Oyan Radiation Protection Evelyn Foshaug IFEs Board of Management and Executives Tlie Board Arve Jolinscn (Chairman) Page Lawyer I/A I Roll Wicdswaiifj; (I ice Chairman) from the Board 4 Manaptiji Director Eurokraft iSor^e a.s and lo-s account 16 Anna In^cr Kidc Section Head Oljedirektoratet activities Ellen Morch lhialand in ll 20 Special Advisor Saga Petroleum a.s IU">'*;arrh am vide* Trond T. Olscn .si hjHSf*r 26 Section Head, HE Jon P. Ramba'k a\ publications and Section Head, HE 32 John Rokstad Professor, I i() Management Kjell TT. Bemliksrn Managing Director A me Raheim Assistant Managing Director ''$.,•< >i.-!ff- WvrncUM KieJl H. Bendiksen, flalden Froiect Jtiii Olav Ber}; war- Mnna};iiifl Director i <si<i \;\H\,/.U 4»vi»tari| Managing Dirucior Arne Raheim. till lie (lied in april I')1*,"). The Halden Project Carlo Vitanza l^oject Manager Iridtjov Owre Assistant Project Manager Information Roll 0.
    [Show full text]
  • High-Ozone Layers in the Middle and Upper Troposphere Above Central Europe: Potential Import from the Stratosphere Along the Subtropical Jet Stream
    Atmos. Chem. Phys., 11, 9343–9366, 2011 www.atmos-chem-phys.net/11/9343/2011/ Atmospheric doi:10.5194/acp-11-9343-2011 Chemistry © Author(s) 2011. CC Attribution 3.0 License. and Physics High-ozone layers in the middle and upper troposphere above Central Europe: potential import from the stratosphere along the subtropical jet stream T. Trickl1, N. Bartsch-Ritter¨ 2, H. Eisele1, M. Furger2, R. Mucke¨ 1, M. Sprenger3, and A. Stohl4,* 1Karlsruher Institut fur¨ Technologie, Institut fur¨ Meteorologie und Klimaforschung (IMK-IFU), Kreuzeckbahnstr. 19, 82467 Garmisch-Partenkirchen, Germany 2Paul Scherrer Institut, Labor fur¨ Atmospharenchemie,¨ 5232 Villigen PSI, Switzerland 3Eidgenossische¨ Technische Hochschule (ETH) Zurich,¨ Institut fur¨ Atmosphare¨ und Klima, Universitatsstr.¨ 16, 8092 Zurich,¨ Switzerland 4Lehrstuhl fur¨ Okoklimatologie,¨ Technische Universitat¨ Munchen,¨ Am Hochanger 13, 85354 Freising-Weihenstephan, Germany *now at: Norwegian Institute for Air Research, P.O. Box 100, Instituttveien 18, 2027 Kjeller, Norway Received: 28 July 2010 – Published in Atmos. Chem. Phys. Discuss.: 15 December 2010 Revised: 14 July 2011 – Accepted: 30 August 2011 – Published: 9 September 2011 Abstract. Specific very dry high-ozone layers, starting important mechanism for stratosphere-to-troposphere trans- roughly two days after the onset of high-pressure periods port (STT) and also confirm the model predictions of pro- during the warm season, have been reproducibly observed nounced and persistent STT along the subtropical jet stream. in the middle and upper troposphere with the ozone lidar in Garmisch-Partenkirchen (Germany). These episodes, previ- ously not understood, were recently analysed based on ex- 1 Introduction tending backward simulations with the FLEXPART particle dispersion model to as many as twenty days and on jet-stream Very dry air masses with peak ozone mixing ratios of 80 analyses including calculations with the LAGRANTO trans- to 150 ppb were consistently detected in all six ozone lidar port model.
    [Show full text]
  • Sydhavna (Sjursøya) – an Area with Increased Risk
    REPORT Sydhavna (Sjursøya) – an area with increased risk February 2014 Published by: Norwegian Directorate for Civil Protection (DSB) 2015 ISBN: 978-82-7768-350-8 (PDF) Graphic production: Erik Tanche Nilssen AS, Skien Sydhavna (Sjursøya) – an area with increased risk February 2014 CONTENTS Preface ............................................................................................................................................................................................................................................ 7 Summary ...................................................................................................................................................................................................................................... 8 01 Introduction ........................................................................................................................................................................................ 11 1.1 Mandat .............................................................................................................................................................................................. 12 1.2 Questions and scope ............................................................................................................................................................... 13 1.3 Organisation of the project ................................................................................................................................................. 13 1.4
    [Show full text]
  • Kjeller Flyplass Er Norges Eldste Flyplass Og Er Et Unikt Kulturmiljø Som Utdannelsesinstitusjon, Flyfabrikk Og Operativ Base for Hærens Flyvåpen
    SAMMENDRAG Kjeller flyplass er Norges eldste flyplass og er et unikt kulturmiljø som utdannelsesinstitusjon, flyfabrikk og operativ base for Hærens flyvåpen. Flyplassen har bevart utviklingstrekk fra alle utbyggingsfaser og speiler endringer i samfunnet og teknologi. Kjeller flyplass representerer mesteparten av historien til norsk bemannet stridsflygning. Riksantikvaren KJELLER FLYPLASS Vernevurdering 19.september 2017 1 Innhold Innledning ................................................................................................................................................ 4 Oppdrag ............................................................................................. Feil! Bokmerke er ikke definert. Avgrensing og metode......................................................................................................................... 4 Kilder ................................................................................................................................................... 4 Oppsummering og konklusjon ............................................................................................................ 4 Kjeller i dag .............................................................................................................................................. 4 Plassering og beskrivelse av areal ....................................................................................................... 4 Drift .....................................................................................................................................................
    [Show full text]
  • Gridded Global Surface Ozone Metrics for Atmospheric Chemistry Model Evaluation
    Earth Syst. Sci. Data, 8, 41–59, 2016 www.earth-syst-sci-data.net/8/41/2016/ doi:10.5194/essd-8-41-2016 © Author(s) 2016. CC Attribution 3.0 License. Gridded global surface ozone metrics for atmospheric chemistry model evaluation E. D. Sofen1, D. Bowdalo1, M. J. Evans1,2, F. Apadula3, P. Bonasoni4, M. Cupeiro5, R. Ellul6, I. E. Galbally7, R. Girgzdiene8, S. Luppo9, M. Mimouni10, A. C. Nahas11, M. Saliba6, and K. Tørseth12 1Wolfson Atmospheric Chemistry Laboratories, Department of Chemistry, University of York, Heslington, York, YO10 5DD, UK 2National Centre for Atmospheric Sciences, University of York, Heslington, York, YO10 5DD, UK 3Ricerca sul Sistema Energetico – RSE, via R. Rubattino 54, 20134, Milan, Italy 4Institute of Atmospheric Sciences and Climate, Italian National Research Council (ISAC-CNR), Bologna, Italy 5Servicio Meteorológico Nacional, Ushuaia GAW Station, Tierra del Fuego, Argentina 6Department of Geosciences, University of Malta, Msida MSD 2080, Malta 7CSIRO Oceans and Atmosphere Flagship, Aspendale Vic. 3195, Australia 8State Research Institute Center for Physical Sciences and Technology, Savanoriu˛ave. 231, 02300 Vilnius, Lithuania 9Universidad Nacional de Tierra del Fuego, ICPA, Tierra del Fuego, Argentina 10Algerian Meteorology Service, P.O. Box 31, Tamanrasset, Algeria 11Global Atmosphere Watch (GAW) Station Bukit Kototabang, The Indonesian Agency for Meteorological, Climatological, and Geophysics (BMKG), Jl. Raya Bukittinggi – Medan Km. 17 Palupuh, Agam, West Sumatera, Indonesia 12NILU – Norwegian Institute for Air Research, P.O. Box 100, 2027 Kjeller, Norway Correspondence to: E. D. Sofen ([email protected]) and M. J. Evans ([email protected]) Received: 1 July 2015 – Published in Earth Syst. Sci.
    [Show full text]
  • Inspired by the Future AGENDA
    Inspired by the future AGENDA Akershus Energi in brief Business overview ESG Financial policy Akershus Energi In brief 1918 - 1922 Construction of Rånåsfoss I and regional infrastructure 1950 - 1970 Oppland, Usta and Nes 1975 Funnefoss 1978 Bingsfoss 1983 Rånåsfoss II 1990 Energy legislation – formerly duty of coverage 1990 - 1998 Distribution grid in Romerike and Follo 1999 Bøhnsdalen power plant 2000 Sold distribution infrastructure 2003 Skotfoss og Klosterfoss - Skien 2003 Tistedalsfoss and Skonningsfoss - Halden 2005 Expansion into district heating 2011 Akershus EnergiPark opens 2013 Norway’s first solar heating installation 2016 Opening Rånåsfoss III Introduction to the company • Akershus Energi is an innovative company for Production mix 2025 Production mix 2020 renewable energy and green infrastructure 5% 10% 8% • In addition to hydropower, Akershus Energi is growing 20% within other renewable energy sources, e.g. bioenergy, 65% 92% district heating, solar power, wind and hydrogen • 100 % owned by the county of Viken Hydropower Hydropower Wind District heating District heating Solar power • BBB/stable rating from Scope Our vision Akershus Energi is an innovative company for renewable energy and green infrastructure Our core values Safety Unity Innovative Organization and partners District New renewable and Hydro power Wind power Solar power Energy trading heating/cooling infrastructure Soleie AS Legal structure Key credit strengths Diversified portfolio Infrastructure investment mitigate business volatility and lower volatility
    [Show full text]
  • Utredning Av Permanent Løsning for Småflyvirksomheten I Østlandsområdet
    Utredning av permanent løsning for småflyvirksomheten i Østlandsområdet Utarbeidet for Samferdselsdepartementet Om Oslo Economics Oslo Economics utreder økonomiske problemstillinger og gir råd til bedrifter, myndigheter og organisasjoner. Våre analyser kan være et beslutningsgrunnlag for myndighetene, et informasjonsgrunnlag i rettslige prosesser, eller et grunnlag for interesseorganisasjoner som ønsker å påvirke sine rammebetingelser. Vi forstår problemstillingene som oppstår i skjæringspunktet mellom marked og politikk. Oslo Economics er et samfunnsøkonomisk rådgivningsmiljø med erfarne konsulenter med bakgrunn fra offentlig forvaltning og ulike forsknings- og analysemiljøer. Vi tilbyr innsikt og analyse basert på bransjeerfaring, sterk fagkompetanse og et omfattende nettverk av samarbeidspartnere. Om Vista Utredning Vista Utredning er et frittstående rådgivningsfirma med tverrfaglig bemanning. Vi gir råd innen universell utforming, arealplanlegging og trafikkplanlegging samt luftfartstilknyttet aktivitet. Innenfor disse feltene omfatter arbeidet både utredninger og utarbeidelse av planer og handlingsprogrammer. Utredning av permanent løsning for småflyvirksomheten i Østlandsområdet/OE-rapport 2018-47 © Oslo Economics, 21. desember 2018 Kontaktperson: Rolf Sverre Asp / Senior Partner [email protected], Tel. +47 996 28 812 Innhold Sammendrag og konklusjoner ______________________________________________ 4 1. Bakgrunn og mandat __________________________________________________ 7 1.1 Historisk bakgrunn __________________________________________________
    [Show full text]
  • IFE ANNUAL REPORT 2017 1 Annual Report for the Institute for Energy Technology
    ANNUAL REPORT 2017 IFE.NO RESEARCH FOR A BETTER FUTURE IFE ANNUAL REPORT 2017 1 Annual report for The Institute for Energy Technology. Graphic design: CopyCat AS Photo: Mick Tully, Image Communication 2 RESEARCH FOR A BETTER FUTURE Contents 04 About IFE 05 Key figures 07 From the CEO 11 Organisation chart 12 IFE’s strategic research focus 16 Materials and Process Technology 20 Centres for Environment-friendly Energy Research (FME) 23 Fluid Flow and Environmental Technology 26 Digital systems 28 Radiopharmaceuticals 32 IFE’s nuclear research activities 38 Nuclear Waste Management and Decommissioning 42 Environment and safety at IFE 44 Greater EU drive 47 Innovation and commercialisation 48 Income statement 49 Report of the Board of Directors IFE ANNUAL REPORT 2017 3 About IFE The Institute for Energy Technology (IFE) conducts research for a better future. Since 1948, we have been an international leader in energy research. The knowledge we have developed has saved the petroleum industry several hundred billion kroner. We have contributed to the development of ground-breaking cancer medicine, new solutions in renewable energy, more energy-efficient industrial processes, zero-emission transport solutions and future-oriented energy systems. Our research and expertise have led to safer use of nuclear power, and we have developed methods for verifying the disarmament of nuclear weapons. The research at IFE has created jobs in Norway, facilitated business development and generated important expertise for the Norwegian trade and industry sector. At IFE, we build bridges between research, education and industry. We have extensive infrastructure and full-scale laboratories where theoretical models are transformed into commercial activities.
    [Show full text]
  • Arena H2cluster
    Cross-Sectoral - Value Chain THE NORWEGIAN HYDROGEN CLUSTER - H2CLUSTER H2Cluster c/o Kjeller Innovasjon Gunnar Randers vei 24 2007 Kjeller Norway E: [email protected] W: www.h2cluster.com H2Cluster – The Norwegian Hydrogen Cluster is a ABOUT H2CLUSTER national cluster. The aim is to strengthen the position for our partners by facilitating What We Do collaboration Ÿ amongst our partners Ÿ across sectors/ market segments Ÿ through the entire value chain Ÿ with regional/ international clusters and organizations H2Cluster is working on several projects aiming to accelerate the development of new business opportunities within the hydrogen industry. WORLD LEADER Vision The Norwegian hydrogen industry is a world leader in technology, business models and solutions for the production, transport, storage, application and export of hydrogen. INNOVATION ARENA Mission The hydrogen cluster’s mission is to create a national innovation arena where companies collaborate on innovation, competence building, market development and positioning. INCREASED VALUE CREATION Our Main Goals Increased value creation among the companies in the Hydrogen cluster, through intensified c o o p e r a t i o n o n R & D , c o m p e t e n c e enhancement, business models, market development and positioning nationally and internationally. Air Liquide Norway AS Air Liquide is one of the main players behind the rapidly growing part of the energy sector that uses hydrogen as an energy source. They have expertise in the entire hydrogen supply chain, i.e., production, distribution, and storage of hydrogen, as well as fuel cells and filling stations. Hydrogen in combination with oxygen in the air can be converted into electricity using fuel cells, Mail: customerservice.norway and with clean water as the only residual product.
    [Show full text]