DOCSLIB.ORG

Available and Future Methods of Energy Storage Report 2020

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Available and Future Methods of Energy Storage Report 2020 POLAND AVAILABLE AND FUTURE METHODS OF ENERGY STORAGE REPORT 2020 AVAILABLE AND FUTURE METHODS OF ENERGY STORAGE commissioned by WWF Poland Warsaw 2020 The report was prepared by the following team: Adrian Chmielewski, Institute of Vehicles and Construction Machinery Engineering, Warsaw University of Technology, Narbutta 84 Str., 02-524 Warsaw, Poland, [email protected] Jakub Kupecki, Department of High Temperature Electrochemical Processes (HiTEP), Institute of Power Engineering, Augustowka 36 Str., 02-981 Warsaw, Poland, [email protected] Łukasz Szabłowski, Institute of Heat Engineering, Warsaw University of Technology, 21/25 Nowowiejska Str., 00–665, Warsaw, Poland, [email protected] Karol Jan Fijałkowski, Centre of New Technologies, University of Warsaw, Banacha 2c Str., 02-097 Warszawa, Poland, [email protected] Jakub Zawieska, Warsaw School of Economics, Institute of Infrastructure Transport and Mobility, Madalinskiego 6/8 Str., 02-513 Warsaw, Poland Krzysztof Bogdziński, Institute of Vehicles and Construction Machinery Engineering, Warsaw University of Technology, Narbutta 84 Str., 02-524 Warsaw, Poland, [email protected] The chapters were prepared by: • Executive Summary: Adrian Chmielewski, Łukasz Szabłowski, Krzysztof Bogdziński, Karol Jan Fijałkowski, Jakub Kupecki • List of definitions: Adrian Chmielewski, Łukasz Szabłowski, Krzysztof Bogdziński, Karol Jan Fijałkowski, Jakub Kupecki • List of abbereviations: Adrian Chmielewski, Łukasz Szabłowski, Karol Jan Fijałkowski, Jakub Kupecki • Preface: Tobiasz Adamczewski, Oskar Kulik, WWF Poland • Introduction: Adrian Chmielewski, Łukasz Szabłowski, Karol Jan Fijałkowski, Jakub Zawieska, Krzysztof Bogdziński, Jakub Kupecki • Pumped Hydroelectric Storage (PHS): Adrian Chmielewski, Łukasz Szabłowski, Karol Jan Fijałkowski • Compressed Air Energy Storage (CAES): Łukasz Szabłowski, Adrian Chmielewski • Liquid air Energy Storage (LAES): Łukasz Szabłowski • Flywheel Energy Storage (FES): Adrian Chmielewski, Karol Jan Fijałkowski • Chemical Energy Storage – hydrogen (H2): Jakub Kupecki, Karol Jan Fijałkowski, Adrian Chmielewski • Chemical Energy Storage – other PtG products: Jakub Kupecki, Karol Jan Fijałkowski • Galvanic cells – Battery Energy Storage (BES): Adrian Chmielewski, Karol Jan Fijałkowski, Jakub Zawieska • Flow Cells (VRFB): Adrian Chmielewski, Karol Jan Fijałkowski • Superconducting Magnetic Energy Storage (SMES): Adrian Chmielewski, Karol Jan Fijałkowski • Ultracaoacitors (UC): Adrian Chmielewski • Phase-change materials / Molten Salts (PCM / MS): Adrian Chmielewski, Karol Jan Fijałkowski • Heat Storage (low-medium-high temperature) and cold storage (TES): Łukasz Szabłowski • Summary: Adrian Chmielewski, Łukasz Szabłowski, Krzysztof Bogdziński, Karol Jan Fijałkowski, Jakub Kupecki • Bibliography: Adrian Chmielewski, Łukasz Szabłowski, Krzysztof Bogdziński, Karol Jan Fijałkowski, Jakub Zawieska, Jakub Kupecki Citation: Chmielewski A., Kupecki J., Szabłowski Ł., Fijałkowski K.J., Zawieska J., Bogdziński K., Kulik O. and Adamczewski T., Currently available and future methods of energy storage, WWF Poland, ISBN: 978-83-60757-56-7, 2020. This report may not be reproduced in whole or in part in any way without stating the title and publisher source as the copyright holder. © 2020 WWF All rights reserved. The copyright holder permits reproduction of this publication for educational and other non-commercial purposes without prior written consent, while the WWF does require written notice and the appropriate acknowledgement. It is prohibited to reproduce this publication for commercial purposes without obtaining prior written consent from the copyright holder. AVAILABLE AND FUTURE METHODS OF ENERGY STORAGE 2 TABLE OF CONTENTS Preface .......................................................................................................................... 6 Executive Summary ........................................................................................................ 7 List of definitions ......................................................................................................... 31 List of abbreviations (Alphabetical) .............................................................................. 34 1. Introduction .............................................................................................................. 37 1.1. European Policy ............................................................................................................................. 37 1.2. Overview of energy storage techniques ........................................................................................ 38 2. Pumped hydroelectric storage (PHS) ....................................................................... 48 2.1. Introduction .................................................................................................................................. 48 2.2. PHS development perspective and environmental impact .......................................................... 51 2.3. Raw material restrictions .............................................................................................................. 53 2.4. Technological barriers and scalability .......................................................................................... 53 2.5. Energy storage costs in PHS ......................................................................................................... 55 2.6. Main applications of PHS ............................................................................................................. 57 2.7. Conclusions: advantages, disadvantages and recommendations for PHS................................... 57 3. Compressed air energy storage (CAES) ..................................................................... 58 3.1. Introduction .................................................................................................................................. 58 3.2. CAES development perspective and environmental impact ....................................................... 60 3.3. Resource restrictions ................................................................................................................... 60 3.4. Technological barriers and scalability .......................................................................................... 61 3.5. Energy storage costs in CAES ....................................................................................................... 61 3.6. Main CAES applications .............................................................................................................. 62 3.7. Conclusions: advantages, disadvantages and recommendations for CAES ................................ 62 4. Liquid air energy storage (LAES) ..............................................................................64 4.1. Introduction .................................................................................................................................. 64 4.2. LAES development perspective and environmental impact ....................................................... 66 4.3. Resource restrictions .................................................................................................................... 67 4.4. Technological barriers and scalability .......................................................................................... 67 4.5. Energy storage costs in LAES ....................................................................................................... 67 4.6. Main LAES applications .............................................................................................................. 69 4.7. Conclusions: advantages, disadvantages and recommendations for LAES ................................ 69 5. Flywheel Energy Storage (FES) ................................................................................. 70 AVAILABLE AND FUTURE METHODS OF ENERGY STORAGE 3 5.1. Introduction .................................................................................................................................. 70 5.2. FES development perspective and environmental impact ........................................................... 71 5.3. Resource restrictions ..................................................................................................................... 73 5.4. Technological barriers and scalability .......................................................................................... 73 5.5. Energy storage costs in FES .......................................................................................................... 74 5.6. Main applications of FES .............................................................................................................. 75 5.7. Conclusions: advantages, disadvantages and recommendations for FES ................................... 75 6. Chemical energy storage – hydrogen (H2) ................................................................. 76 6.1. Introduction – hydrogen: production, storage, utilization .......................................................... 76 6.2. Development perspective and environmental impact ................................................................ 86 6.3. Resource restrictions ................................................................................................................... 90 6.4. Technological barriers and scalability ........................................................................................
Load more

Recommended publications
  • Energy Storage Policy Best Practices from New England: Ten Lessons from Six States
    Energy Storage Policy Best Practices from New England TEN LESSONS FROM SIX StATES AUGUST 2021 Todd Olinsky-Paul Clean Energy Group Clean Energy States Alliance Group Group ABOUT THIS REPORT this report, prepared by Clean energy group (Ceg) and the Clean energy states alliance (Cesa), presents energy storage policy best practices and examples of innovative policies from the new england states. the report describes what has worked best and provides a list of recommendations to guide states looking to expand energy storage markets with effective programs and policies. it is available online at https://www.cesa.org/resource-library/resource/energy-storage-policy-best- practices-from-new-england. ABOUT THE AUTHOR todd olinsky-paul is senior project director for Ceg and Cesa. He directs Cesa’s energy storage and technology advancement partnership (ESTAP), a federal-state funding and information sharing project that aims to accelerate the deployment of electrical energy storage technologies in the united states. todd also works on Ceg’s resilient power project, supporting solar+storage behind the meter for critical infrastructure energy resiliency, and leads Ceg and Cesa on energy storage policy and program development at the state level. todd has a M.s. in environmental policy from Bard College and a B.a. from Brown university. ACKNOWLEDGMENTS the author wishes to express his sincere thanks to representatives of the new england states for their input on this report; and to colleagues at Ceg and Cesa who made this a better report through their insightful review comments, including Warren leon, Maria Blais Costello, samantha Donalds, lew Milford, and seth Mullendore.
    [Show full text]
  • High Performance Stallions Standing Abroad
    High Performance Stallions Standing Abroad High Performance Stallions Standing Abroad An extract from the Irish Sport Horse Studbook Stallion Book The Irish Sport Horse Studbook is maintained by Horse Sport Ireland and the Northern Ireland Horse Board Horse Sport Ireland First Floor, Beech House, Millennium Park, Osberstown, Naas, Co. Kildare, Ireland Telephone: 045 850800. Int: +353 45 850800 Fax: 045 850850. Int: +353 45 850850 Email: [email protected] Website: www.horsesportireland.ie Northern Ireland Horse Board Office Suite, Meadows Equestrian Centre Embankment Road, Lurgan Co. Armagh, BT66 6NE, Northern Ireland Telephone: 028 38 343355 Fax: 028 38 325332 Email: [email protected] Website: www.nihorseboard.org Copyright © Horse Sport Ireland 2015 HIGH PERFORMANCE STALLIONS STANDING ABROAD INDEX OF APPROVED STALLIONS BY BREED HIGH PERFORMANCE RECOGNISED FOREIGN BREED STALLIONS & STALLIONS STALLIONS STANDING ABROAD & ACANTUS GK....................................4 APPROVED THROUGH AI ACTION BREAKER.............................4 BALLOON [GBR] .............................10 KROONGRAAF............................... 62 AIR JORDAN Z.................................. 5 CANABIS Z......................................18 LAGON DE L'ABBAYE..................... 63 ALLIGATOR FONTAINE..................... 6 CANTURO.......................................19 LANDJUWEEL ST. HUBERT ............ 64 AMARETTO DARCO ......................... 7 CASALL LA SILLA.............................22 LARINO.......................................... 66
    [Show full text]
  • Electrical Energy Storage
    08 Fall BACKGROUND The Energy Systems Toolkit (the „Toolkit‟) is aimed at organisations, community groups or businesses, at different stages in the project development process, whether exploring ideas to develop into a project or additional options to include in a current project. The Toolkit aims to provide further information to organisations on energy systems topics that will help determining whether a project idea is viable or highlight alternative options that should be considered. The Toolkit also provides support through the development process to construction, highlighting any support available to them. This could include: Signposting businesses or communities to additional support (technical or financial) in developing their project, to potential project partners or to potential sources of funding; Provide detail on key considerations and barriers across different technology projects; or Highlight different technology projects and themes that have been developed successfully across Scotland. For each of the topics, the guidance provided will be informative and will indicate the actions to be taken and the next steps the organisations should take to progress. The Toolkit links to other relevant guidance documents, such as the CARES Toolkit, which can be used in parallel. INTRODUCTION TO ELECTRICAL ENERGY STORAGE Electrical energy storage can provide a range of grid support services that can help maintain a stable and reliable electricity supply. Working in tandem with smart grid technology, the functions that it can provide include: Enabling the integration of more renewables into the energy mix. Storing energy from renewables to smooth variable supply. Helping energy consumers to manage their energy demand. Stabilising voltage and frequency on power networks.
    [Show full text]
  • The Impacts of Storing Solar Energy in the Home to Reduce Reliance on the Utility
    ARTICLES PUBLISHED: XX MONTH XXXX | VOLUME: 2 | ARTICLE NUMBER: 17001 The impacts of storing solar energy in the home to reduce reliance on the utility Robert L. Fares* and Michael E. Webber There has been growing interest in using energy storage to capture solar energy for later use in the home to reduce reliance on the traditional utility. However, few studies have critically assessed the trade-os associated with storing solar energy rather than sending it to the utility grid, as is typically done today. Here we show that a typical battery system could reduce peak power demand by 8–32% and reduce peak power injections by 5–42%, depending on how it operates. However, storage ineciencies increase annual energy consumption by 324–591 kWh per household on average. Furthermore, storage operation indirectly increases emissions by 153–303 kg CO2, 0.03–0.20 kg SO2 and 0.04–0.26 kg NOx per Texas household annually. Thus, home energy storage would not automatically reduce emissions or energy consumption unless it directly enables renewable energy. 1 n recent years, there has been growing interest in storing energy lead-acid batteries used with solar panels in the UK would increase 41 25 2 produced from rooftop photovoltaic panels in a home battery both primary energy consumption and carbon dioxide emissions . 42 1 3 Isystem to minimize reliance on the electric utility . A number In this paper we critically assess the trade-offs of using lithium- 43 4 of vendors have sought to capture this emerging market, including ion battery storage to capture solar energy and minimize reliance on 44 5 electric vehicle market leader Tesla and German home energy the utility.
    [Show full text]
  • A Low-Visibility Force Multiplier Assessing China’S Cruise Missile Ambitions
    Gormley, Erickson, and Yuan and Erickson, Gormley, A Low-Visibility Force Multiplier ASSESSING CHINA’s CRUISE MISSILE AMBITIONS Dennis M. Gormley, Andrew S. Erickson, and Jingdong Yuan and Jingdong Yuan Jingdong and S. Erickson, Andrew Dennis M. Gormley, Center for the Study of Chinese Military Affairs The Center for the Study of Chinese Military Affairs (China Center) was established as an integral part of the National Defense University’s Institute for National Strategic Studies on March 1, 2000, pursuant to Section 914 of the 2000 National Defense Authorization Act. The China Center’s mission is to serve as a national focal point and resource center for multidisciplinary research and analytic exchanges on the national goals and strategic posture of the People’s Republic of China and to focus on China’s ability to develop, field, and deploy an effective military instrument in support of its national strategic objectives. Cover photo: Missile launch from Chinese submarine during China-Russia joint military exercise in eastern China’s Shandong Peninsula. Photo © CHINA NEWSPHOTO/Reuters/Corbis A Low-Visibility Force Multiplier A Low-Visibility Force Multiplier ASSESSING CHINA’s CRUISE MISSILE AMBITIONS Dennis M. Gormley, Andrew S. Erickson, and Jingdong Yuan Published by National Defense University Press for the Center for the Study of Chinese Military Affairs Institute for National Strategic Studies Washington, D.C. 2014 The ideas expressed in this study are those of the authors alone. They do not represent the policies or estimates of the U.S. Navy or any other organization of the U.S. Government. All the resources referenced are unclassified, predominantly from non-U.S.
    [Show full text]
  • Slides from Sonoma Clean Power Residential Energy Storage
    Residential Energy Storage Presentation Chris Calwell, Ecos Research 10/14/2020 Background • Ecos Research is a small consulting firm based in San Luis Obispo, CA focused on achieving breakthrough reductions in greenhouse gas emissions through technology and policy- driven improvements to consumer products. • Most of our work to date has focused on energy efficient consumer electronics and appliances, residential energy storage and PV, and electric vehicles. • I joined the research team at CSIRO in Newcastle, Australia to conduct testing and research on residential energy storage research efforts in Feb-March 2019 through Fulbright Specialist funding from the US State Department. • This presentation is a distillation of my findings from that research and our subsequent work for EPA ENERGY STAR, PG&E, Portland General Electric, and Arizona Public Service on the residential energy storage topic. Key Topics We’ll Cover • Market trends - what’s happening to sales? • Why residential battery sales are rising and how they're typically used • Key challenges in understanding their performance claims, specifications and warranties • The good, the bad and the ugly from early measurements of battery performance and efficiency • Safety considerations • Economics - Why it is challenging to get them to pay for themselves now, but won’t be in the future Australia is a post card from the future for us Percentage of homes with rooftop PV by post code Australian market conditions support one of the most robust residential battery markets in the world. Why?
    [Show full text]
  • Introduction & Overview of Aceon's Virtual Power Plant Model
    Building Resilience and Strengthening Communities Overview of AceOn’s Virtual Power Plant: RENEWERGY ® APSE CENTRAL REGION – 15 December 2020 AceOn Group +44 (0)1952 293 388 Unit 9B “Offering solutions today for [email protected] tomorrow’s world” Stafford Park 12 Telford www.aceongroup.com TF3 3BJ ACEON - WORKING IN PARTNERSHIP NATIONALLY & INTERNATIONALLY AceOn have a unique combination of a wealth of public and private experience as well as in-depth knowledge of the battery storage and energy sectors. AceOn have been chosen as the national partner of both the Association of Public Service Excellence and the National Housing Federation. We work in direct partnership with leading national and international manufacturers of Electric Vehicle Chargers, Domestic and Commercial Battery Storage Systems, Solar PV Panels, and Air Source Heat Pumps. Partners Association for Public Service Excellence - Exclusive Approved Energy Storage Partner to 114 member councils National Housing Federation - Exclusive Energy Storage Sector Supplier to 800 Housing Associations Microgeneration Certification Scheme (MCS) - Helped create and develop the Battery Storage Standard (MIS 3012) Solar Trade Association - Influential member and partner shaping government policy “The Telford Company Taking on Tesla” ACEON WORKING IN PARTNERSHIP – ONE STOP SOLUTION PROVIDER DOMESTIC BATTERY ENERGY STORAGE SYSTEMS – For New-Build & Retrofit VIRTUAL POWER PLANT – RENEWERGY Smart Energy Management Platform: Optimisation, Aggregation and Trading ROOF-INTEGRATED SOLAR PANEL
    [Show full text]
  • EDB Eurasian Integration Yearbook 2011
    Munich Personal RePEc Archive EDB Eurasian Integration Yearbook 2011 Vinokurov, Evgeny Euirasian Development Bank 2011 Online at https://mpra.ub.uni-muenchen.de/49178/ MPRA Paper No. 49178, posted 22 Aug 2013 07:48 UTC EDB EURASIAN I N T E G R A T I O N YEARBOOK 2011 Eurasian Integration Yearbook 2011 Annual publication of the Eurasian Development Bank УДК 339.7 ББК 65.012.3 Е 91 Eurasian Integration Yearbook 2011. – Almaty, 2011. – p. 352 ISBN 978–601–7151–21–8 Annual publication of the Eurasian Development Bank Edited by Evgeny Vinokurov The Eurasian Development Bank is an international financial institution established to promote economic growth and integration processes in Eurasia. The Bank was founded by the intergovernmental agreement signed in January 2006 by the Russian Federation and the Republic of Kazakhstan. In 2009–2010 Armenia, Tajikistan, Belarus became full members of the Bank. Electric power, water and energy, transportation infrastructure and high-tech and innovative industries are the key areas for Bank’s financing activity. As part of its mission the Bank carries out extensive research and analysis of contemporary development issues and trends in the region, with particular focus on Eurasian integration. The Bank also hosts regular conferences and round tables addressing various aspects of integration. In 2008, the Bank launched an annual EDB Eurasian Integration Yearbook (in English) and quarterly Journal of Eurasian Economic Integration (in Russian). Both publications are available online at: www.eabr.org. The Bank’s Strategy and Research Department publishes detailed Industry and Country Analytical Reports and plans to undertake a number of research projects.
    [Show full text]
  • Electrical Energy Storage – a Lexicon
    January 2016 Technology Advisory Electrical Energy Storage – A Lexicon Electrical energy storage is an increasingly important topic in discussions about the future of the grid. The purpose of this document is to provide a common vocabulary for talking about electrical energy storage systems. It is focused on grid-connected systems, but many of the terms also apply to off-grid systems. Technical Terms Battery An electrochemical energy storage device which is usually DC. This is one part of an energy storage system. Battery Cell This is the smallest individual electrical component of a battery. It may be a separate physical device (such as an “18650” cell commonly used with lithium batteries), or it may be part of a larger package, yet electrically isolated (a 12V lead acid car battery actually has six two-volt cells connected via bus bars). Battery Management System This is a system which manages and monitors the battery to ensure even charging and discharging. This may be part of a system controller or may be a separate subsystem controller. Charge Rate The ratio of the charge power to the energy capacity of an energy storage system. For example, a 2 MWh system being recharged at 400 kW would have a charge rate of 0.2C (or C/5), while the same battery being charged at 8 MW would have a charge rate of 4C. There are often limits as to how fast a system can be charged / discharged. Copyright © 2016 by the National Rural Electric Cooperative Association. All Rights Reserved. January 2016 Depth of Discharge This is the inverse of Battery State-of-Charge (BSOC), and is usually abbreviated as DOD.
    [Show full text]
  • Introducing Aceon and Launching Our Virtual Power Plant
    Introducing AceOn And Launching Our Virtual Power Plant APSE Webinar 10 November 2020 AceOn Group +44 (0)1952 293 388 Unit 9B “Offering solutions today for [email protected] tomorrow’s world” Stafford Park 12 Telford www.aceongroup.com TF3 3BJ 1 INTRODUCING THE ACEON & RENEWERGY TEAM Richard Partington – Managing Director of AceOn Energy. Previously over 30 years in local government including 8 years as Managing Director of Telford & Wrekin Council. Mark Thompson – Director. Over 30 years’ experience in Battery Energy Storage and the design, manufacture and supply of batteries and battery packs. Loic Hares – Partner. Over 6 years’ experience working for ‘Big 6’ energy providers, acting as a consultant in the UK energy industry, and helping energy start-ups build successful operations Alex Thompson – Sales Director. 8 years’ experience in Energy storage, batteries and battery packs “AceOn and Renewergy have a unique combination of a wealth of experience across the public and private sectors as well in-depth knowledge of the battery storage and energy sectors” CONTENTS OF TODAY’S WEBINAR THE FORMAL LAUNCH OF RENEWERGY – ACEON’S VIRTUAL POWER PLANT 1. Overview of the Electricity Market, Issues, Challenges & Opportunities – Dr Neil Williams 2. Overview of AceOn & Introducing RENEWERGY, Our Virtual Power Plant – Richard Partington 3. How RENEWERGY Works In Detail – Loic Hares 4. Explaining The Hardware Behind RENEWERGY – NOT ALL BATTERIES ARE THE SAME! – Alex Thompson 5. Summary of The Benefits of RENEWERGY – Richard Partington 6. Questions 3 DR NEIL WILLIAMS Our Special Guest today – DR NEIL WILLIAMS Neil is an investor and advisor in the energy, cleantech and mobility sectors.
    [Show full text]
  • Worldwide Equipment Guide
    WORLDWIDE EQUIPMENT GUIDE TRADOC DCSINT Threat Support Directorate DISTRIBUTION RESTRICTION: Approved for public release; distribution unlimited. Worldwide Equipment Guide Sep 2001 TABLE OF CONTENTS Page Page Memorandum, 24 Sep 2001 ...................................... *i V-150................................................................. 2-12 Introduction ............................................................ *vii VTT-323 ......................................................... 2-12.1 Table: Units of Measure........................................... ix WZ 551........................................................... 2-12.2 Errata Notes................................................................ x YW 531A/531C/Type 63 Vehicle Series........... 2-13 Supplement Page Changes.................................... *xiii YW 531H/Type 85 Vehicle Series ................... 2-14 1. INFANTRY WEAPONS ................................... 1-1 Infantry Fighting Vehicles AMX-10P IFV................................................... 2-15 Small Arms BMD-1 Airborne Fighting Vehicle.................... 2-17 AK-74 5.45-mm Assault Rifle ............................. 1-3 BMD-3 Airborne Fighting Vehicle.................... 2-19 RPK-74 5.45-mm Light Machinegun................... 1-4 BMP-1 IFV..................................................... 2-20.1 AK-47 7.62-mm Assault Rifle .......................... 1-4.1 BMP-1P IFV...................................................... 2-21 Sniper Rifles.....................................................
    [Show full text]
  • Defence Economic Outlook 2020 Per Olsson, Alma Dahl and Tobias Junerfält
    Defence Economic Outlook 2020 Per Olsson, Alma Dahl and Tobias Junerfält Tobias and Dahl Alma Olsson, Per 2020 Outlook Economic Defence Defence Economic Outlook 2020 An Assessment of the Global Power Balance 2010-2030 Per Olsson, Alma Dahl and Tobias Junerfält FOI-R--5048--SE December 2020 Per Olsson, Alma Dahl and Tobias Junerfält Defence Economic Outlook 2020 An Assessment of the Global Power Balance 2010-2030 FOI-R--5048--SE Title Defence Economic Outlook 2020 – An Assessment of the Global Power Balance 2010-2030 Titel Försvarsekonomisk utblick 2020 – En bedömning av den glo- bala maktbalansen 2010-2030 Rapportnr/Report no FOI-R--5048--SE Månad/Month December Utgivningsår/Year 2020 Antal sidor/Pages 86 ISSN 1650-1942 Customer/Kund Ministry of Defence/Försvarsdepartementet Forskningsområde Försvarsekonomi FoT-område Inget FoT-område Projektnr/Project no A112007 Godkänd av/Approved by Malek Finn Khan Ansvarig avdelning Försvarsanalys Bild/Cover: FOI, Per Olsson via Mapchart Detta verk är skyddat enligt lagen (1960:729) om upphovsrätt till litterära och konstnärliga verk, vilket bl.a. innebär att citering är tillåten i enlighet med vad som anges i 22 § i nämnd lag. För att använda verket på ett sätt som inte medges direkt av svensk lag krävs särskild över- enskommelse. This work is protected by the Swedish Act on Copyright in Literary and Artistic Works (1960:729). Citation is permitted in accordance with article 22 in said act. Any form of use that goes beyond what is permitted by Swedish copyright law, requires the written permission of FOI. 2 (86) FOI-R--5048--SE Summary The global military and economic power balance has changed significantly during the past decade.
    [Show full text]