Vaasa Conference April 2016 HYBRIDIZATION OF SHIPS INGVE SØRFONN MARINE SOLUTION E & A 1 Wärtsilä
The overall challenge Shipping burns approx. 335 million ton of fuel per year, while transporting 85% of the worlds goods The associated emission of CO2 is around 1 billion tonnes of CO2 per year BAU improvements in fleet efficiency expected to be more than offset by growth Emission doubling or trebling by 2050 likely consequence Reference DNV, IMO 2 Wärtsilä
IMO regulations 3 Wärtsilä
Future steps in energy optimization Energy Efficient Program operation Environmental fleet management system Increasted automation level to meet optimization and remote services Energy optimization of onbord process and aux systems Next generation engines Hybrid Power generation Energy recovery Battery support New fuels Clean shore power Propeller hull interaction optimization Hull / Propulsion concepts 4 Wärtsilä
Hybrid system configuration A flexible and efficient energy system with energy storage FUEL SYSTEM ENGINE GEN-SET RENEWABLES ENERGY STORAGE HEAT RECOVERY POWER GRID & HYBRID CONTROL ENERGY FROM SHORE HOTEL LOAD PROPULSION 5 Wärtsilä
Energy Storage - drivers ENVIRONMENT REDUCED EMISSIONS LOW NOISE / VIBRATION NEW REGULATIONS COST EFFICIENT OPERATIONS REDUCED RUNNING HRS LESS ENGINE POWER INCENTIVES LOW ENERGY COST RENEWABLE ENERGY INCREASED FLEXIBILITY & SAFETY ENERGY FLEXIBILITY INCREASED REDUNDANCY BACK-UP POWER 6 Wärtsilä
Energy storage benefits hybrid operation Engine Specific Fuel Consumption Optimized engine operation Energy storage support operation of engines at optimal specific fuel consumption Reduced engine transients Energy storage will be used to reduce transient loads in engines. Transients will increase fuel consumption and emissions. Maintenance cost will be reduced SFC [%] 125 120 115 110 105 100 95 0 20 40 60 80 100 120 Engine Load [%] Increased redundancy and efficient operations Power redundancy requirements requires engines to run at low loads. When energy storage is accepted as redundant power the engine will operate more efficient on higher loading and secure back-up in case of trip of engine. 7 Wärtsilä
Battery integration Battery Cell Battery String Battery assembly Dow Kokam, Panasonic, LG Chem, Xalt, Saft Wartsila E&A Hybrid System supplier - DC grid with power electronics - Hybrid control system - Charging concepts 8 Wärtsilä
Battery cost predictions maritime systems 1500 USD/kWh 1000 USD/kWh 500 USD/kWh 9 Wärtsilä
Electrical configuration Power electronics Configurable hardware, firmware and sw Ultra fast fault clearance Grid stability control Hybrid Control Energy Management Power Management Battery Management Battery safety Charging Control Automatic connection Automatic charging Automatic disconnection 10 Wärtsilä
High redundant power system - LLC Battery Battery G G 690V G G LLC Unit Bus A1 Bus B1 LLC Unit Bus A2 690V Bus B2 450V Battery Battery M M M M Thruster 1 Thruster 2 Thruster 3 Thruster 4 11 Wärtsilä 17.April 2015 General presentation Electric & Hybrid Systems
Fellowship program 12 Wärtsilä
PSV operation with energy storage Annual fuel costs $ 3,000,000 Savings potential 15% Annual savings $ 500,000 Expected payback time 4 years 15% reduction in fuel consumption yearly 20-30% reduction in emissions Short pay-back time (4-5 years) Silent and emission free operation in harbours (using batteries) Can be installed on new builds and as retrofits Support green operations in the oil & gas industry Need incentives to start investment in an industry where the oil companies pays the fuel bill Payback time is based on a new build and an actual operational conditions where the energy storage is used as redundant source and as peak shaving. 13 Wärtsilä
DP operation Today- two engines in operation due to redundancy requirements Hybrid operation - one engine and battery in operation Conventional = gas electric operation Hybrid = engine + battery 14 Wärtsilä
Folgefonn project low and ZERO emission energy systems DESIGN 2012-2013 Renewable energy 15 Wärtsilä Storage of energy QUALIFICATION, TESTING & DEMO 2014-2015 Demo ferry - Folgefonn
The new flexible, safe and efficient ferry The first ferry that can operate seamless between different modes of operation Diesel electric mode (as today) A multiple of hybrid modes with or without charging from shore (15-25% fuel saving) Pure electrical mode with charging renewable energy from shore (no fossile fuel used) reduce energy cost with more then 50%. 16 Wärtsilä
Hybrid ferries flexible and modular design HYBRID (+ PLUG-IN HYBRID) Batteries combined with engine to optimize performance with variable operation profiles ALL-ELECTRIC Batteries used as only power source all the time during operations 17 Wärtsilä
Wärtsilä induction charging Graphic impression Wärtsilä induction charging technology Safe, fast, reliable and efficient battery charging Inductive pick-up Magnetic coil Grid 18
Automated Mooring & Charging Charging system with Induction technology by Wärtsilä Zero emission Automated mooring system with Vacuum technology by Cavotec Fast charging during loading and unloading of vehicles Transfer of >1 MW power Reduced operation time and more efficient energy transfer Improved safety during operation Reduced maintenance 19 Wärtsilä
Future Market 2000 1500 NUMBER OF SHIPS 1000 MERCHANT Breakthrough technologies 500 OFFSHORE Hybrid market 0 2016 2017 2018 2019 2020 2021 2022 2023 2024 2025 2026 PILOTS 20 Wärtsilä
LOW POTENTIAL HIGH POTENTIAL Hybrid market potential 21 Wärtsilä TIMELINE
Conclusions Results from operations concludes the benefits of energy storage and hybrid operations Electrical plug-in operation reduce operational cost substansial Plug-in hybrid operation is attractive for many ships due to flexibility and fuel saving Hybrid operation with variable operational profiles reduce operational cost Large reduction of emissions due to more efficient energy production Improvement in performing safe operations Reduced maintenance cost Energy storage systems(ess) has documented reliable and safe operation and new class notation are already in place Understanding the operational needs is of critical for design of the ESS and the overall control philosophy 22 Wärtsilä