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IEA-ETSAP Technology Collaboration Programmeand Modelling Tools
Annex XIV: Understanding & Facilitating the Energy Transition to Achieve the ‘Well Below 2OC’ Goal
Prof. Brian Ó GallachóirChair IEA ETSAP TCP Executive Committee
IEA ETSAP Workshop on Energy Models & Applications Research Centre for Gas Innovation, Universidade de São Paulo, Brazil
Jan 30 2017
What is IEA ETSAP?
• One of 39 IEA Technology Collaboration Programmeswww.iea.org/tcp/
• 40 years international cooperation on energy systems modelling (since first oil crisis)
• Developing and maintaining (MARKAL and TIMES) tools • Assisting policy decisions by modelling possible future energy
pathways • Focus on key role of technology to meet goals • Biannual workshops and training
www.iea-etsap.org
ETSAP Activity
Unique network of Energy Modelling teams from almost 70 countries use MARKAL & TIMES models analyse energy systems and support decision making in energy policy.
ParticipantsAustralia CSIRO Japan IEEJ
Belgium VITO/SPW/Brussels Kazakhstan NURIS
Denmark DEA Korea KEA
EC JRC Netherlands ECN
Finland TEKES/VTT Norway IFE
France ADEME/DGEMPEDAD/EDMP Russia ERI-RAS
Germany IER Spain CIEMAT
Greece CRES Sweden STEM
Ireland SEAI Switzerland PSI
Italy ENEA UK DBEIS
Sponsor Enel Foundation US DOE/BNL
Sponsor GE Global Research
Annexes (Work Progs)XIV 2017-19 Understanding & Facilitating the Energy Transition to
Achieve the well below 2OC GoalXIII 2014-16 Tools for Analysis of a Future Energy RevolutionXII 2011-13 Policy Analyses Tools for Global SustainabilityXI 2008-11 JOint STudies for New & Mitigated Energy Systems X 2005-07 Global Energy Systems and Common AnalysesIX 2003-05 Energy Models User's GroupVIII 2002-05 Exploring Energy Technology PerspectivesVII 1999-01 Contributing to the KYOTO ProtocolVI 1996-98 Dealing with uncertainty togetherV 1993-95 Energy options for sustainable developmentIV 1990-92 Greenhouse gases and national energy optionsIII 1987-89 International forum on energy environment studiesII 1984-86 Information exchange projectI 1981-83 Energy technology systems analysis programme
1978-80 MARKAL Model generator development (BNL, KFA)1976-77 Analysis of tools for evaluating R&D strategies
Annex XIV – well below 2OCResearch and Development
ETSAP will support research and development activities in order to advance the state-of the art of energy systems analysis. A non-exhaustive list of topics includes:1. Climate mitigation responding to the policy ambition aiming for “well below 2o C”;2. Incorporating impacts of R&D in TIMES to capture the role of innovation;3. Exploring the interplay between differences in long term and short term policy
ambition;4. Energy Technology Data Source (E-TechDS) updates;5. Improved modelling of variable renewables and short term system operational issues
in long term energy systems modelling;6. New approaches for integrating human behaviour into energy systems modelling; and7. Improved modelling of the interactions between the energy system and the economy
Depicting reality in an ESM
RealityModel
structureMathematicaldescription
P PO P
Q P
BHKW S BHKW Coal BHKW
BHKW CO Coal BHKW
BHKW H BHKW Coal BHKW
_ _
_ _
_ _ _
= ⋅
= ⋅
= ⋅
η
ε
η2
2
Model results
0
10
20
30
PJ
1990 2000 2010 2020
HouseholdTransportIndustry
Data
4a Entwicklung der Kernenergiekapazitäten (Netto-Engpassleistung am Jahresende) in Deutschland bis 2030 (Basis
Energieträger Einheit 2000 2010e 2020e 2025e 2030e4a.1 Kernenergie MW 21273 16340 1269 0 0
4b Entwicklung der Kernenergiekapazitäten (Netto-Engpassleistung am Jahresende) in Deutschland bis 2030 (Basis
Energieträger Einheit 2000 2010e 2020e 2025e 2030e4b.1 Kernenergie MW 21273 17125 9308 0 0
5 Entwicklung der Kapazitäten und der Erzeugung aus regenerativen Energiequellen (Mindestmengen) in Deutsch
Energieträger Einheit 2000 2010e 2020e 2025e 2030e5.1a Sonne GW 0,11 0,71 1,31 1,61 1,915.1b Sonne TWh p.a. 0,07 0,60 1,00 1,28 1,525.2a Wind GW 6,11 23,10 25,60 26,90 28,105.2b Wind TWh p.a. 9,50 43,54 57,96 64,02 70,085.3a Biomasse GW 0,59 0,80 1,00 1,10 1,205.3b Biomasse TWh p.a. 1,63 2,55 3,60 4,20 4,80
6 Energie- und Umweltpolitik in Deutschland bis 2030
Größe Einheit 2000 2010e 2020e 2025e 2030e
6,1 CO2-Zertifikatehandel (Strom u. Industrie) nein ja ja ja ja
6,2 CO2-Zertifikatepreis €2000/tCO2 - 3,00 9,00 12,00 14,00
Model Scope
Optimiser(CPLEX/MINOS/CONOPT/XPRESS/etc.)
Cross-checking results with reality. Feedback
TIMES Model
• linear programming bottom-up energy model • integrated model of the entire energy system • medium to long term prospective analysis (20 - 50 years)
– Demand driven (exogenous) in physical units • partial and dynamic equilibrium (perfect market) • optimal technology selection • minimize the total system cost• environmental constraints• energy and emission permits trading• price-elastic demands
Net Social Surplus
∑∑∈
−
=
•+=YEARSy
yREFYRyr
R
ryrANNCOSTdNPV ),()1( ,
1
where:NPV is the net present value of the total cost (the OBJ);ANNCOST(y) is the total annual cost in year y;dr,y is the general discount rate;REFYR is the reference year for discounting (2005);YEARS is the set of years for which there are costs in the horizonr is the region
Minimise System Costs
• Capital Costs incurred for investing and dismantling plant;• Fixed and variable Operation and Maintenance (O&M) Costs;• Costs for exogenous imports and for domestic resource production; • Revenues from exogenous exports;• Delivery costs for required fuels consumed by plant; • Taxes and subsidies associated with fuel flows and plant activities;• Salvage value of plant at the end of the planning horizon; • Welfare loss resulting from reduced end-use demands.
Total System Cost
ETSAP Tools
Given…• technology data (e.g. 1300)• service demands (e.g. 73)• import fuel prices• Supply curves• emission constraints• other parameters
– discount rate– time horizon definition– time slice definition
Models provide…• technology investments• technology activities• emission trajectories• adjusted demands• marginal energy prices• imports/exports• total system cost
In Summary …
Cost and emissions balance
GDP
Process energy
Heating area
Population
Light
Communication
Power
Person kilometers
Freight kilometers
Service Demands
Coal processing
Refineries
Power plantsand
Transportation
CHP plantsand district
heat networks
Gas network
Industry
Commercial and Public Services
Households
Transportation
Final energyPrimary energy
Domesticsources
Imports
Dem
andsEn
ergy
pric
es, R
esou
rce
avai
labi
lity
TIMES Model
Annex XII Report > 300 publications 2011-2013 (including 110 peer-review papers) from:i) Global Models: incl. IEA ETP model, original TIMES Integrated Assessment Model (TIAM),
derived TIAM models, ETSAP-TIAM model
ii) Regional Models: Pan-European TIMES model, MARKAL-TIMES Models for Europe, Asia andNorth America.
iii) National Models of 32 countries (including China).
iv) Sub-National Models: Western China, Reunion Island (France), Lombardy (Italy), Pavia (Italy), and Kathmandu Valley (Nepal).
v) Local Models for rural areas and cities in Austria, Germany and Italy, other bigger cities such as Madrid (Spain), Beijing, Guangdong and Shanghai (China), Johannesburg (South Africa) and New York City (United States).
http://iea-etsap.org/finreport/ETSAP_Annex_XII_Final%20Report.pdf
Multi-regional models
ETSAP Outputs
ETSAP Recent Outputs
www.springer.com/gp/book/9783319165394
• Methodologies and case studies • Demonstrating use of energy systems models • Support energy and climate policy• Critical analysis of rich and varied applications• Includes diverse global case studies• Role of technology in energy systems
ETSAP TIAM
• Global model (ETSAP-TIAM) now available in addition to modelling tools (TIMES)• 15 Region global TIMES model available to ETSAP Contracting Parties • Developed by GERAD and currently updated by ETSAP Collaborative Project• Includes several thousand technologies and models climate forcing
ETSAP-TIAM
• distributed to 10 ETSAP Contracting Parties • available on request by participants• several projects have used TIAM:
– EMF-22, EMF-24 (Stanford, US)– Low Carbon Society (NIES, Japan, UK-ERC, …)– IPCC-IAMC, special report on Renewable Scenarios– IEA-RETD, Achieving Climate and Energy Security (ACES)– EC-FP7, REACCESS on Energy Corridors for EU– Asian Modelling Exercise
• currently being updated and re-calibrated in ETSAP project led by DTU
Workshops & Training
• ≥ two workshops per annum on energy systems modelling– http://iea-etsap.org/index.php/workshops– Cork, Ireland May 30-31 2016– Madrid, Spain Nov 17-18 2016– Tokyo, Japan Dec 14 2016– Sao Paulo, Brazil Jan 30 2017– Maryland, USA July 10-11 2017
• joint organiser of IEW (International Energy Workshop), Maryland, USA, July 12-14 2017
• Deliver ≥ 2 training courses for the ETSAP tools biannually• Tokyo, Japan Dec 15-16 2016• Torino, Italy Jan 2017• Sao Paulo, Brazil Jan 31 – Feb 1 2017• Maryland, USA July 12-14 2017
ETSAP in summary …• ≥ Two workshops per year, one organized together with IEW• 3-5 TIMES model training sessions around the world• approx 200 teams involved from the whole world• access to support and discussion forums• jobs within TIMES modelling• new tools and analyses are shared• close collaboration with IEA, IRENA, Worldbank, etc.• documentation:
– Annex report - http://www.iea-etsap.org/finreport/ETSAP_Annex_XII_Final%20Report.pdf– Meetings - http://www.iea-etsap.org/index.php/community/official-documents– Projects - http://www.iea-etsap.org/index.php/etsap-projects– Model generator & user interface - http://www.iea-etsap.org/index.php/documentation– Technologies - http://www.iea-etsap.org/index.php/energy-technology-data
Brazil joining ETSAP ???
Advantages:• have the right to be represented at the Executive Committee and to
participate with one vote the all decisions;• free access to the ANSWER, VEDA-FE, VEDA-BE users’ interfaces, updates and
related preferential assistance to the IEA-ETSAP members;• access to the annual calls for proposals of IEA-ETSAP funded research projects;• access to the global multi-regional TIMES Integrated Assessment Model - TIAM
(with endogenous trade of energy and CO2 permits, stochastic variables andclimate equations) and continuous updates;
• free access to the training courses (offered at least twice a year);• increased chances to be part of consortia coordinated by IEA-ETSAP members
for submitting projects to International Funding Agencies (USAID, EC, etc.)Cost: €20 000 per annum
Brazil and IEA TCPs
• Ministry of Mines and Energy (MME) participates in three TCPs focusing onrenewables (bioenergy, concentrated solar and hydropower)
• Petrobras participates in IEA-GHG TCP (as a Sponsor)• Further TCPs are in dialogue with MME, the Funding Authority for Studies and
Projects (FINEP) and technology-specific research organisations (e.g. involvedin CCS, HEV, etc.)
• Prospects for Brazil to join IEA-ETSAP?
IEA-ETSAP Technology Collaboration Programmeand Modelling Tools
Annex XIV: Understanding & Facilitating the Energy Transition to Achieve the ‘Well Below 2OC’ Goal
Prof. Brian Ó GallachóirChair IEA ETSAP TCP Executive Committee
IEA ETSAP Workshop on Energy Models & Applications Research Centre for Gas Innovation, Universidade de São Paulo, Brazil
Jan 30 2017
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