Design and Propulsion offerings. BULKFORUM, 14/2-2011 Integrerte 23.05.2013 fremdriftssystem S.N. Klokk - muligheter og utfordringer Rolls-Royce Marine - S N Klokk Februar 2015
2 Content Introduksjon, Rolls-Royce Marine Integrerte fremdriftssystem leveringsomfang Muligheter og utfordringer
Rolls-Royce at a glance 3 Aerospace Land & Sea Civil Defence Marine Energy & Nuclear Power Systems Aero engines Helicopter engines Aero engines Helicopter engines Equipment systems Ship Design Gas turbines UK s nuclear powered subs Marine and land based power systems 55,000 people - in 45 countries
Rolls-Royce in the Nordics 4... in total abt. 4300 employees Ålesund Ulsteinvik Brattvåg Ship design, Ship design, Deck Machinery DP/Automation Thrusters & Gears Steering Gears Ålesund Hjørungavåg Longva Training Centre Seismic & Subsea Automation & Controls Bergen Engines Steering Gears Power Electric Systems Kristinehamn Propellers/thrusters (POD) Waterjets Kokkola Waterjets Rauma Deck Machinery Azimuth thrusters
Customer offerings 5 Ship design and integrated ship systems Diesel and gas engines Gas turbines Automation and control (including DP) Propulsion systems Steering systems Electrical podded propulsors Azimuth thrusters Tunnel thrusters Waterjets Stabilising systems Winch systems
6 Opportunities Marine LNG Fuelled Power Systems Trigged by Fuel costs (HFO/MD versus LNG), emission legislation (IMO), availability of efficient and reliable engines and a growing gas infrastructure, the market for LNG fuelled systems is increasing. LNG fuelled solutions, mature technology. Rolls-Royce Marine is currently offering: Propulsion product supplies - that includes the Bergen C and B Gas engine and MTU engine versions Integrated, LNG fuelled ship power systems and Vessel building specifications/designs for a variety of Offshore, Merchant and Naval vessels
Gas Fuelled Propulsion Systems an integrated part of the Environship Concept 7 Rolls-Royce Wave Piercing Technology Rolls-Royce PROMAS Rolls-Royce HSG Hybrid Shaft Generator Rolls-Royce Gas Engines & LNG Systems
Gas Fuelled Engines 8 First lean-burn, spark plug ignited gas engine delivered in 1991 Gas engines for marine propulsion in service since 2006 More than 600 gas engines sold world wide. Power range 1400 kw to 8500 kw Machinery spaces are designed gas safe in all conditions, i.e.. inherently safer design Enclosure on all gas-carrying pipes In case of leakages in inner pipe gas is collected in outer enclosure and ventilated to mast Indication (Alarm) given to the operator or shutdown of the relevant engine depending on leakage size (% of LEL)
Gas Engines 9 Bergen Lean Burn gas engines 92% reduced NOx emission 22% reduced GHG emission 98-100% reduced SOx emission 98% reduced particulates Gas consumption & NOx for variable versus fixed RPM MJ/kWh propellercurve MJ/kWh 1000 rpm g/kwh NOx propellercurve NOx 1000 rpm 18 12 15 9 Fast load response Robust and reliable MJ/kWh 12 6 g/kwh NOx Emissions [g/kwh] ISO Energy cosp. [MJ/kWh] 11 10 9 8 7 6 5 4 3 B3540V12 emissions 750 rpm constant speed BMEP = 18.1 bar@mcr, Energy cosp.= 7630 kj/kwh, Methane number = 81,2 600 500 400 300 200 CO2 [g/kwh] Cycle averaged values E2: Spec. NOx: Spec. CO: Spec. Methane: Spec. CO2: [g/kwh] 1,02 1,12 3,76 419 9 3 6 0 0 % 20 % 40 % 60 % 80 % 100 % Engine Power % 2 1 100 0 0 20 30 40 50 60 70 80 90 100 110 Engine load [%] Specific NOx Specific CO Specific CH4 Energy consumption [MJ/kWh] Specific CO2 ROLLS-ROYCE GAS ENGINE AND SYSTEMS
LNG Fuel Systems 10 A LNG Fuel System in our context comprise a storage tank (liquid gas) and a system for gas conditioning i.e. evaporation and temperature adjustment of the gas to the consumers (gas engines). Related to the above RRM also supply ACON GAS, for LNG Control and LNG Safety. Main design requirements as per the IGC code (IMO) and Regulations of Class.
LNG Fuelled Propulsion System-Typical Configuration 11 Helicon - X3 Integrated Automation System ACON Gas, Control & Safety Control Power Gas Aux. Gen. Set MDO Aux. Gen. Set MDO Power Control and Distribution System LNG Bunkering Station HSG Aux. Gen. Set MDO Steering gear PTO/PTH Tank Connect. Space Shaft generator/motor TT TT Promas Reduction Gear Bergen B32:40V12P System solution building blocks: Compliant with regulations for redundant machinery systems
12 Challenges System Design Realization Commissioning Operation
13 Challenges, System Design System Integration, A&C IMO and Regulations of Class set minimum standards for safety (and quality). Interpretation and following up varies. Verified system integration that includes all relevant system building blocks (internal and external) and interfaces safeguard in-service performance. Software development and validation control HIL testing is one option. Failure rate/life time expectancy for critical A&C components our approach through RRM Common Controls. Environmental factors (e.g. vibrations, temperature).
14 Challenges, System Design LNG Fuel Systems RRM is relying on thrusted suppliers but evident that marine experience is still lacking. Substantial efforts required: Technical Requirement Specification project based. Prequalifying process implemented for thrusted suppliers. Enhanced support and monitoring/logging. Low LNG temperatures and choppy sea - a challenge for gravity feed LNG systems. Mitigation strategies includes: Operational procedures. Cryogenic pump option on a when needed basis (patent pending). LNG storage tank designs (patent pending).
15 Challenges, Realization Power and control cabling quality, routing, shielding and termination by Yard can be a challenge. Min. requirements of Class and Owner not always aligned to specifications of OES. Completion of documentation and functional testing of the LNG fuel system processes as part of FAT enhance commissioning.
16 Challenges, System Commissioning RRM systems performance heavily impacted by Yard deliveries. Restricted time available for harbor and sea trials can be a challenge. Adaptions/Improvements of traditional commissioning planning and execution to reflect the complexity of the systems delivered are necessary. Experiences of gas installations by many Yards are restricted.
17 Challenges, Operation A highly efficient and flexible integrated propulsion systems impact the skills required for operating personnel. Dedicated training is necessary Simulator connected training in a true environment, now available. Restricted group size. Training for normal operation and fault troubleshooting in addition to gas basics. 24/7 In-Service support Parts Service and operational support through multi-disciplined teams of service engineers, that can be instantly mobilized for on-site troubleshooting and fault rectification. Energy Optimisation Services growing.
RRM, Training philosophy 18 E-Learning Classroom Workshop/Technical room Theoretical training for fundamental basic knowledge Ideal course preparation Theoretical training Ideal for larger groups Detailed system overview including drawings and functionality Maintenance training on actual products Practical training with focus on maintenance and troubleshooting Provides holistic view of complete systems Simulators Operator training Provides simulator experience of real life scenarios occuring at sea Blended learning
RRM Training Locations 19 Bergen Aalesund RTC Kokkola Rauma Singapore RTC Brasil RTC Kristinehamn ROLLS-ROYCE TRAINING CENTRES
Where do you find out more? 20 http:/www.rolls-royce.com training.marine@rolls-royce.com Play
Thank You for Your Attention! 21