CUTEC GEMIS-Training Bangkok, March 2012 Dipl.-Ing., M.sc.agr. Werner Siemers.

Slides:

Advertisements

Similar presentations

Chapter 4 Module 9 Environmental systems analysis methodology Can totally different sanitation systems be fairly compared? How are environmental impacts.

Advertisements

Canada-U.S. Binational EIO-LCA Model Jonathan Norman Heather L. MacLean Department of Civil Engineering University of Toronto LCA of Oil Sands Technology.

Energy Management– Life cycle and energy in Transports 2 st semester 2013/2014 Carla Silva Principal.

Biofuels: Environmental Friend or Foe? Presentation to 1 st Year Environmental Engineering Students Deniz Karman.

Innledning LCA- metodikk ISO- standarder Miljøvare deklarasjoner Avslutning A systematic mapping and evaluation of health, ecological and resource impact.

Waste Reduction, Recycling and Climate Change The use of the Life Cycle Analysis tool WRATE Dr Peter Olsen Scottish Environment Protection Agency UCCCfS:

© OECD/IEA 2013 Annual Renewables Questionnaire Overview IEA Energy Statistics Training Paris, 4–8 March 2013 Rachael Hackney, Georgios Zazias Annual Renewables.

University College London Complex Built Environment Systems Bartlett School of Graduate Studies 1 Using ESDS data for Energy and Environment Modelling.

Focusing on Life Cycle Cost (LCC) and Life Cycle Assessment (LCA) in GPP Green Public Procurement (GPP) - Lead the change National Conference George Jadoun,

The sole responsibility for the content of this presentation lies with the Clean Fleets project. It does not necessarily reflect the opinion of the European.

Margaret K. Mann National Renewable Energy Laboratory Golden, Colorado USA A Comparison of the Environmental Consequences of Power from Biomass, Coal,

Applying Greenhouse Gas Emissions Lifecycle Assessment Jennifer L. Christensen WISE Intern 2009 August 5, 2009.

Delivering sustainable solutions in a more competitive world Carbon Footprinting: Methodological Approaches, Challenges & Opportunities Simon Aumônier.

Environmental life cycle assessment. Why Sustainable Construction?  Social progress, which recognises the needs of everyone  Effective protection of.

Life Cycle Assessment (LCA)

© J. Yan Towards a Sustainable Energy Future Sustainable Energy Systems and Challenges of Energy Utilization Jinyue Yan Lecture.

………………………. A perspective of life cycle thinking We believe in decision making based life cycle thinking. It results in: -no trade-offs in life cycle phases.

Final Project Renewable Energy System : Biomass Iberian Partnership for Technician Excellence, Summer 2012.

1 Wageningen University “Consultation on THE WORLD BANK GROUP ENVIRONMENT STRATEGY” Ekko C. van Ierland January 2010 Environmental Economics and Natural.

An Introduction to Life Cycle Analysis (LCA) and Life Cycle Thinking (LCT) Adam de Eyto-PhD, BDes (Hons) Industrial Design Lecturer/Sustainable Design.

Institute of Chemical Engineering page 1 Achema 2012 Chemical Process Engineering Research Group Zero Emission Technologies Contact: Dipl.-Ing. Dr. Tobias.

A lifecycle approach GREENHOUSE GAS EMISSIONS OF INFANT FORMULA PRODUCTION Melissa Tinling; Dr. Miriam Labbok; Dr. Jason West University of North Carolina.

Environmental Profiling and EN15804 EPDs

Energy Analysis and Environmental Impacts of Ethanol in Thailand

Life Cycle Analysis. Topics  Definition  Use  Process  Limitations.

1 Comparison of energy systems: On methods, parameters and system boundaries Leif Gustavsson Mid-Sweden University September.

Co-benefits of Integrated Approach to Air Quality Management and Climate Change Mitigation Role of Integrated Assessment Methods in SEA Dr. Vladislav.

Asahi Kasei AWP LCA study. Background for the LCA analysis Global demand of reducing Greenhouse Gas （ GHG) emission First introduction to the flexo printing.

Low carbon scenarios for the UK Energy White Paper Peter G Taylor Presented at “Energy, greenhouse gas emissions and climate change scenarios” June.

5-5. GLOBAL WARMING Introduction  Definition:  Rise in the average temperature of the Earth’s surface (mainly air T).  From the Environmental.

Life Cycle Analysis of energy systems used in residential buildings Manoudis Alexandros Supervisor: Dr. Anastaselos Dimitrios SCHOOL OF SCIENCE & TECHNOLOGY.

Energy Conservation Physics /24/03. Reducing energy consumption may help alleviate environmental problems: Conserve fossil fuel resources Reduce.

CESI Barcelona May 2003 R.BERTI IT Session 1 – Block 2 1 Product Environmental Profile and Benefits for Electrical Utilities R. Berti CESI.

AIR QUALITY GOVERNANCE AND CLIMA EAST: OPPORTUNITIES FOR COOPERATION Dr. Mikhail Kozeltsev, Key Expert 24 April 2014, Batumi, 4th Workshop IPPC and Permitting.

Earth’s Changing Environment Lecture 15 Energy Conservation.

MED-Impact Decision-support instrument to promote renewable energy investments in the Mediterranean

05/11/2015 Workshop Ecolizer The methodology behind the Ecolizer 2.0 An Vercalsteren, Ann Van der Linden 25 February 2011.

Life Cycle Assessment of the proposed Waste2Go approach Brussels, 14 th September 2015 Dipl.-Ing. Florian Gehring.

NON-FOOD OPTIONS at FARM LEVEL Greenhouse Gas Accounting for Non-Food Options (A web-based approach of LCA modelling) Hannes Peter Schwaiger JOANNEUM RESEARCH.

Setting the Boundaries Stephen Boyle, Principal Consultant, Climate Change and Policy 11 th March 2009 A world leading energy and climate change consultancy.

Life Cycle Assessment: Framework. Goal: Life cycle THINKING Many “centers” on campus have seminars with lunch and drinks provided. How should drinks be.

Energy Consumption Calculations Group 4a. Contents 1.Introduction 2.Methods 3.Tools 4.Country specific variations a.Finland b.Other Nordic countries c.Italy.

Life Cycle Assessment (LCA)

LIFE CYCLE ASSESSMENT (LCA). As corporations seek to improve their environmental performance they require new methods and tools. LCA is one such tool.

1 Seema Thakur (st107641) Advisor: Dr. Weerakorn Ongsakul Optimal Generation Scheduling of Cascaded Hydro-thermal and Wind Power Generation By Particle.

Session 2 Buildings and Measurements. Buildings Sector Accounts for About 40% of U.S. Energy, 72% of Electricity, 34% of Natural Gas, 38% of Carbon, 18%

CALIFORNIA ENERGY COMMISSION Technology: Stationary Sources and Demand-Side Management Session Two Air Pollution as Climate Forcing: A Workshop Honolulu,

A.Ricci - 17/02/09 Introduction to NEEDS SIXTH FRAMEWORK PROGRAMME [6.1] [ Sustainable Energy Systems] Andrea Ricci, ISIS Brussels,

© Federal Statistical Office Germany, Environmental-Economic Accounting 2009 Federal Statistical Office Germany Input-Output Analysis in the Environmental-

JOANNEUM RESEARCH Forschungsgesellschaft mbH LIFE CYCLE ASSESSMENT OF ELECTRIC VEHICLES – Austrian Results in an International Context Gerfried Jungmeier.

Georgia, April 2016Mr. Christian Angerbauer, Mr. Roland Oberwimmer Basis for management decisions Environmental Controlling.

The value of environmental footprints Euro-Mediterranean Conference on Digital integration, energy and resource efficiency: opportunities in textile and.

Global Warming And the U.S.. What is Global Warming? *An increase in the average temperature of the Earth *Recent debate, but has been looked at by scientists.

Chapter 11 Life-Cycle Concepts, Product Stewardship and Green Engineering.

Contract: EIE/07/069/SI Duration: October 2007 – March 2010Version: Nov. 30, 2009 Calculation of the integrated energy performance of buildings.

Jeremy Rix NORTH ENERGY ASSOCIATES LTD Life Cycle Assessment for AB Systems Wetland Biomass to Bioenergy.

Jeremy Rix NORTH ENERGY ASSOCIATES LTD Life Cycle Assessment for AB Systems Wetland Biomass to Bioenergy.

Research Group Process Evaluation Ecological Footprint calculation using SPIonWeb Kollmann René Graz University of Technology Institute for Process and.

Life Cycle Assessment Assessing local impacts María del Mar Pintor

3rd International Scientific Conference on "Energy and Climate Change"

Energy Sources and Sustainability

C-accounting and the role of LCA in waste management

Development and use of Environmental Performance Indicators

Multidisciplinary nature of environmental studies Lecture #1

ABB and sustainable development

ABB and sustainable development

“Life Cycle Assessments of Wind Energy and Other Renewables”…

Climfoot training session

J. Cofala Z. Klimont CIAM/IIASA

Carbon Footprint.

Presentation transcript:

CUTEC GEMIS-Training Bangkok, March 2012 Dipl.-Ing., M.sc.agr. Werner Siemers

CUTEC Objective What is GEMIS What GEMIS delivers How to operate GEMIS Examples Tips and Tricks, Q&A

CUTEC GEMIS GEMIS = Global Emission-Model of Integrated Systems Data bank application Balance for analysis/summary and comparison No proof for correct figures As with other simulations and data banks Garbage in = garbage out

CUTEC Introduction LCA Life-cycle-analysis of energy-, material- and transport-processes Energy and material flow from cradle to grave Calculation, summing up and descriptive figures Evaluation and comparison Analysis of effects Here: emissions from product or process Inclusion of cost aspects

CUTEC Principle LCA

CUTEC Features of GEMIS GEMIS assesses the final utilization based on the used resources Calculation of life cycles incl. construction and disposal (if wanted) Including transport, process energy, support energy, materials etc. Project „Standard“ contains checked figures Own processes to add or look up known processes Problem: non-linear relations, loops

CUTEC Basics Emission calculation Separate lecture Climate change gases CO2 equivalent  CO2, CH4, N2O, refrigerants SO2 equivalent  Air emissions  Or individual figures TOPP equivalent  Ozone precursor substances

CUTEC Main elements Products Energy resources  Complete data  Needed for exact emission calculation Materials  Costs and environmental impact Resources  Renewable and non-renewable Emissions

CUTEC

CUTEC Processes Example combustion  Connection to process energy delivery  Definition of efficiency  Main and additional products/by-products  Costs  White cells can be edited, grey cells are calculated by GEMIS  Calculation of emissions  Evaluation of emission reduction measures Example Energy conversion

CUTEC

CUTEC

CUTEC Results from calculation Whole chain  Resource-Transport-Conversion-Final Energy  kWh electricity or fuel Technologies and sources as defined before

CUTEC Energy benefit ratio kWh of fossil energy per 1 kWh of final energy Ratio of output energy / fossil input energy

CUTEC Scenarios  Comparison of energy demand  Comparison of options More features Export of data Explanations Global switch  Scope of analysis Allocations

CUTEC Own experience A bit tricky Do not believe and re-calculate/estimate Input and output in additional excel sheets Effort, allocate time and concentration

CUTEC Thank you very much for your attention!! Further Contact: Thank you very much for your attention!! Further Contact: