VTT TECHNICAL RESEARCH CENTRE OF FINLAND LTD Tool for evaluation of operating economy and ecology in ship concept design Modelling and Optimization of Ship Energy Systems October 23-25, 2017. EPFL Sion, Switzerland Saara Hänninen VTT Technical Research Centre of Finland Ltd
Contents VTT Ltd in brief Tool for evaluation of operating economy and ecology in ship concept design 2
VTT Technical Research Centre of Finland Ltd VTT is one of the leading research and technology organisations in Europe. We use our scientific and technological excellence to provide innovation services for our domestic and international customers and partners. * Loikkanen, T. et al. Roles, effectiveness, and impact of VTT. Towards broad-based impact monitoring of a research and technology organisation. 2013. VTT, Espoo. VTT Technology 113. 106 p. + app. 5 p. Net turnover and other operating income 269 M (VTT Group 2016) Unique research and testing infrastructure Personnel 2,414 (VTT Group 2016) Wide national and international cooperation network 3
VTT on the map VTT s locations in Finland JYVÄSKYLÄ ESPOO SODANKYLÄ KAJAANI OULU KUOPIO TAMPERE OUTO- KUMPU Personnel by location VTT Group Espoo 1,674 Oulu 315 Tampere 249 Jyväskylä 92 Sodankylä 29 Kuopio 26 Other locations 29 Total 2,414 VTT s international research units Seoul (South Korea) VTT s marketing and networking offices Brussels (Belgium) 4
VTT s status as performer of R&D work BASIC RESEARCH UNIVERSITIES APPLIED RESEARCH VTT DEVELOPMENT INDUSTRY 5
VTT s R&D infrastructure an essential part of the national research infrastructure 6
Facilities for ship and arctic technology, engines and emissions Towing tank (130m) Manoeuvring basin (40 m x 40 m) Ship simulator Engine lab (Wärtsilä Vasa 4R32 mediumspeed engine) Propulsion unit test centre Fire testing laboratory Cold room 7
Tool for evaluation of operating economy and ecology in ship concept design Summary Analysis tool for economic and environmental performance Potential tool upgrades Conclusions 8
Summary MS Excel & Visual Basic application enables comparison of various ship and machinery concepts and operating scenarios focuses on vessel operating phase impacts predicts fuel consumption and costs, and exhaust gas emissions of a vessel for the specified operating profile and associated operating modes indicates optimal engine loads in each operating mode regarding minimum total fuel consumption, fuel cost, or exhaust gas emissions (CO 2 ) simple enough to be used in the early conceptual design phase enables more accurate calculations in later design phases if detailed information/data is available 9
Tool structure Enforces the user to follow a predefined step-wise process. Allows preliminary analyses as well as advanced analyses. 10
Main menu Starting the tool opens the Main Menu worksheet which describes the step-wise process adopted in the tool for data input and case assessment. 11
Fuel consumption and cost calculations The cost calculations are based on the calculated annual consumptions of different types of fuels and lube oils and the unit prices specified for the types. 12
Emission calculations Emission volumes from fuel combustion are calculated for CO2, NOx, SOx, CH4, N2O and PM (TSP) emissions. 13
Reporting By the button Results by engine types will be created a pre-defined document which contains summary of emissions from fuel combustion, fuel oil consumption and lubrication oil consumption. Summary is also shown by figures. The button Results by modes opens a dialog box in which user can select parameters to be shown in the report. 14
Potential tool upgrades Improving accuracy of the emission calculations Introducing new fuels, e.g. methanol Introducing of battery powered hybrid propulsion Integrating of waste heat recovery 15
Conclusions The tool allows predicting the annual fuel consumption, fuel costs, and the exhaust gas emissions of a vessel equipped with a specified machinery configuration for propulsion and electrical power generation, used according to a specified operating profile. Reflecting the increasing level of detail in the system design process, the evaluations can be either preliminary or advanced. The created tool enables the calculations to be performed efficiently in a half working day, or even in one hour. 16
Acknowledgements The Ship s Energy Efficiency and Environment project was promoted by FIMECC Ltd (Finnish Metals and Engineering Competence Cluster) and funded by Tekes (Finnish Funding Agency for Technology and Innovation) The partners in the project included: 17
Saara Hänninen Senior Scientist, Naval Architect, M.Sc. Ship and Arctic Technology VTT Technical Research Centre of Finland Ltd saara.hanninen@vtt.fi