Energy modelling in GaBi 2017 edition. Oliver Schuller (Dr.-Ing.) Principal Consultant and Team Lead Oil & Gas and Energy & Utilities

Energy modelling in GaBi 2017 edition Oliver Schuller (Dr.-Ing.) Principal Consultant and Team Lead Oil & Gas and Energy & Utilities

Agenda 1. Overview electricity model 2. Individual modules energy carriers 3. Individual modules energy conversion 4. Electricity mixes 27.01.2017 2

Environmental assessment of energy supply chains Extraction & Production Transport Conversion Transmission & Distribution 27.01.2017 3

Source: http://visibleearth.nasa.gov/ Energy systems / generic modelling To provide a comprehensive range of LCI data sets, a large amount of data has to be handled How do we handle large amounts of data and generate consistent datasets? Challenge Development of a model, which allows the adaptation to various country- and technology- specific boundary conditions Approach Generic, parameterized, adaptable models 27.01.2017 4

Energy generation (fossil) - example Conversion parameter Energy Conversion Unit: Plant type (direct, CHP etc) Combustion technology Efficiency Type of cooling system Flue gas cleaning technologies Allocation method Fuel parameter Calorific value Carbon content Sulphur content etc. LCI Auxiliary materials Emissions (CO 2, NOx) Waste heat 27.01.2017 5

Parameterized models electricity grid mix Hard coal supply Hard coal power plant Lignite supply Lignite Supply of coal gases Coal gases Natural gas supply Natural Gas HFO supply Heavy Fuel Oil (HFO) Biomass supply Biogas supply Biomass power plant Biogas power plant Power Grid Mix Transmission Waste supply Waste incineration plant Uranium supply Nuclear power plant Hydropower plant Wind Converter Photovoltaic units 27.01.2017 6

Parameterized models electricity grid mix System boundary Imported Electricity Hard coal Hard (Country coal A) Hard (Country coala) Country A Natural Gas Natural (Country Gas A) Natural (Country Gas A) Country A Transports Transport (Country A) Transport Country A n Transports Transport (Country A) Transport Country A n Mix Mix Hard coal power plant Natural gas power plant Transmission... Energy carrier production Energy carrier transport and mix Electricity conversion (production & transmission) 27.01.2017 7

Conclusions Generic models offer the adaptability to various country and boundary conditions micro, macro and global level Results are comparable due to consistent approach and system boundaries Allows comprehensive LCI, LCIA, carbon footprint and water footprint analysis Complex models with a large amount of data, but reduced number of key parameters are easy to manage and adapt High quality data with acceptable time effort reduces costs Supports scenario modeling and outlooks Creating, maintaining and updating the GaBi databases since 1990 27.01.2017 8

Agenda 1. Overview electricity model 2. Individual modules energy carriers 3. Individual modules energy conversion 4. Electricity mixes 27.01.2017 9

Crude oil & natural gas supply chain Crude oil / natural gas production Crude oil / natural gas transport Crude oil / natural gas consumption mix NG Crude oil Crude oil refining (downstream) Refinery products 27.01.2017 10

Crude oil & natural gas - production technologies Crude oil production technologies Conventional crude oil production technologies (onshore, offshore) Unconventional crude oil production technologies (onshore) Primary crude oil production Oil sands (in-situ, open-pit) Secondary crude oil production Oil shale (in-situ, open-pit, underground) Tertiary crude oil production (EOR) Steam injection Nitrogen injection CO 2 -Injection Natural gas injection Solvent injection 27.01.2017 11

Crude oil production GaBi screenshot Ressources Flaring and venting Thermal energy Electrical energy Mechanical energy Main unit process (production and processing) Waste water and waste 27.01.2017 12

Crude oil & natural gas production model parameters Calculation of energy consumption depending on: Reservoir depth Water-oil-ratio (at well) Steam-oil-ratio and steam quality (if any) Amount of injected media (water, steam, etc.) Efficiency (pumps, generators etc.) Quality of natural gas (concentration of water, H 2 S, CO 2 ) Data from literature for: Flaring and venting rates Solid waste Waste water Share of onshore-/ offshore-production Produced amount of crude oil/ natural gas/ NGL (allocation according to net calorific value) 27.01.2017 13

Crude oil & natural gas production model parameters Technology used (primary, secondary, tertiary production) Energy supply (source / efficiency / type of conversion) Share of produced crude oil, natural gas and NGL Drilling / reservoir depth Water-oil ratio Flaring and venting rates Share of onshore / offshore production 27.01.2017 14

Crude oil consumption mix GaBi screenshot Countryspecific production International transportation Parameterized mixing process National transportation 27.01.2017 16

Crude oil & natural gas consumption mix key parameters Consumption mix by country of origin Transport type (pipeline, tanker, LNG tanker) Transport distances Distribution losses Efficiency and distances between compressor stations (pipeline) Energy supply of compressors (pipeline) 27.01.2017 17

Crude oil & natural gas consumption mix main data sources Mix information based on International Energy Agency (IEA) statistics Transport distance from literature and web calculators Tanker vessel and pipeline models in GaBi 27.01.2017 18

Crude oil based fuels refinery system boundary Inputs and outputs Crude oil Natural gas (for energy supply/ H 2 production) Electricity Methanol / Ethanol (octane number increase) Water Crude oil refining Products Emissions Waste water Hydrogen 27.01.2017 20

Crude oil based fuels refinery system boundary Petroleum refineries are complex plants. The combination and sequence of the processes is usually very specific to the characteristics of the crude oil and the products to be manufactured. Due to the interlinkages within the refinery, all refinery products have to be considered. What technologies and processes are used within the refinery? Possible approaches regarding level of detail of analysis: Refinery as black box model Detailed refinery analysis (every single process) Hybrid approach Level of detail in dependency of scope, level of data availability, etc. Every refinery is individual 27.01.2017 21

Crude oil based fuels Refinery GaBi screenshot Inputs Main unit process mass balance Outputs 27.01.2017 22

Crude oil based fuels Refinery GaBi screenshot Inputs Outputs Complex models for the calculation of environmental profiles can be set up and managed 27.01.2017 23

Crude oil based fuels refinery approach Method: Detailed modeling of the refinery mass and energy balance Emissions of the total refinery (black box) are allocated to the products But allocation factors are modeled precise (due to detailed mass & energy balance) Consequence: Clear, relatively precise, but no environmental analysis of single processes possible Which data are required? Input and output flows of refinery Output spectrum, i.e. 20% diesel, 10% naphtha, 30% gasoline, 2% refinery gas, Amount of purchased energy from external sources (outside refinery) Process capacities (incl. utilization) of each process detailed flow chart including figures to model the mass balance Environmental impacts, i.e. emissions of the whole refinery (black box, bubble) Feedstock and product properties (net calorific value, sulphur content, ) Energy demand of each single process 27.01.2017 24

Agenda 1. Overview electricity model 2. Individual modules energy carriers 3. Individual modules energy conversion 4. Electricity mixes 27.01.2017 25

Hard coal power plant Conversion parameter Energy Conversion Unit: Plant type (direct, CHP etc) Combustion technology Efficiency Type of cooling system Flue gas cleaning technologies Allocation method Fuel parameter Calorific value Carbon content Sulphur content etc. LCI Auxiliary materials Emissions (CO 2, NOx) Waste heat 27.01.2017 26

Hard coal power plant Basis for all combustion models Efficiency, share of CHP/direct, own consumption Data is calculated based on statistics and directly used in the power plant models. Data sources: International Energy Agency (IEA), Electricity Information, Paris, France International Energy Agency (IEA), Energy Statistics of Non-OECD Countries, Paris, France International Energy Agency (IEA), Energy Balances of Non-OECD Countries, Paris, France Emissions Relevant emissions (CO 2, CO, NO X, SO 2, dust, NMVOC, N 2 O, CH 4, Dioxin) are derived country-specific from literature/databases. Data is used directly and partly indirectly (used to determine e.g. efficiency for desulphurization or dedusting in the model. Data sources: European Environment Agency (EEA): Plant-by-Plant emissions of SO 2, NO X and dust and energy input to large combustion plants National Inventory reports (CO 2, CH 4, N 2 O) For complete list compare provided Excel file 27.01.2017 27

Hard coal power plant Basis for all combustion models Emissions Other emissions like heavy metals, consumption of air, water in flue gas etc. are calculated based on combustion calculation and fuel properties: F. Brandt: Brennstoffe und Verbrennungsrechnung, 2. Auflage, 1991 DGMK - Deutsche wissenschaftliche Gesellschaft für Erdöl, Erdgas und Kohle e.v.ansatzpunkte und Poteniale zur Minderung des Treibhauseffekts aus Sicht der fossilen Energieträger - Forschungsbericht EIA - Energy Information Administration (US Energy department): C.5 Gross Heat Content of Dry Natural Gas Production, 1980-2004 & C.3 Gross Heat Content of Crude Oil, 1980-2003, 2005 (Oil & gas) 20 additional literature sources Energy input Input of energy carriers is calculated based on efficiency, allocation and NCV of energy carrier Waste/secondary products (bottom ash, fly ash, gypsum etc.) Calculation based on fuel properties and combustion calculation (transfer coefficients) 27.01.2017 28

Hydro power plant Run-of-river plants Production of base load electricity from hydropower Efficiency η 93 % Low-pressure plant (low head) Kaplan-turbines Storage plants Production of average and peak load electricity from hydropower Efficiency η 85 % Medium- or high-pressure plant (medium or high head) Two types of dams Concrete dam Earth-/rockfill dam Francis-turbines (medium or high head), Pelton-turbines (high head) 27.01.2017 29

Hydro power plant Pumped storage plants Efficiency η 75 % (storage of base load energy) Often combined with storage plants (pumped-storage plants with natural inflow) Medium- or high-pressure plant (medium or high head) Two types of dams Concrete dam Earth-/rockfill dam Francis-turbines (medium or high head), Pelton-turbines (high head), combined with pumps 27.01.2017 30

Hydro power plant Greenhouse gas emissions during the operation of run-of-river, storage and pumped-storage plants As a result of degradation of biomass in the dammed water depending on Climatic boundary conditions Climatic cold and moderate regions: Increasing CO2-emissions from aerobic degradation of biomass in the first years of operation, then temporary decreasing within the first 10 years of operation Climatic tropical regions: Increasing CH4-emissions from anaerobic degradation of biomass in the first years then slower temporary decreasing, which can be longer than the first 10 years of operation Vegetal boundary conditions (amount of inundated biomass) Sub polar lea, Cultivated land, Steppe, Boreal forest, Rain forest Used values of emissions are arithmetic mean values over 100 years of operation and are based on gross greenhouse gas emissions (problem of absorbed CO2 from atmosphere), net emissions are estimated to be 30 50 % lower Greenhouse gas emissions of run-of-river plants are minimal since the water is not stored for a long time 27.01.2017 31

Hydro power plant Input options of the hydro power LCA-models Country-specific distribution of electricity production by hydropower [%] Country-specific relation between consumed electricity and generated electricity by pumped- storage [kwh/kwh] Country-specific greenhouse gas emissions from operation [kg CO 2 eq. / kwh] Plant-specific efficiency [%] Country-specific plant life span and life spans of components [a] Country-specific share of concrete dams as a part of storage and pumped storage plants [%] 27.01.2017 32

Wind power plant Data Source: Vestas EPD, 2006 for 1,65 MW turbine. Wind Park with 182 turbines including infrastructure (cables, transformer station) Manufacturing considered main components (Foundation, Tower, Nacelle Rotor), transports included Use phase: full load hours determined by Power produced from wind from IEA statistics divided by installed capacity from World Wind report Maintenance considered according to Vestas data End-of-Life: recycling potential for metals, incineration of polymers, foundation not recycled, inert materials to landfill 27.01.2017 33

Agenda 1. Overview electricity model 2. Individual modules energy carriers 3. Individual modules energy conversion 4. Electricity mixes 27.01.2017 34

Electricity consumption mix GaBi screenshot Imports Energy carrier supply and processing Power plants Parameter ized mixing process Product output Auxiliary materials 27.01.2017 35

Modelling of electricity consumption mixes 27.01.2017 36

Used data - basis for all electricity mixes Energy mix, net losses, imports (annual average) International Energy Agency (IEA), Electricity Information, Paris, France International Energy Agency (IEA), Energy Statistics of Non-OECD Countries, Paris, France International Energy Agency (IEA), Energy Balances of Non-OECD Countries, Paris, France Eurostat: Eurostat Energy Statistics imports (by country of origin) electricity annual data Infrastructure FFE München: Ganzheitliche energetische Bilanzierung 27.01.2017 37