Oil Boom is an equipment used for efforts to overcome the oil spills that occur in the sea. The function of the Oil Boom itself is to limit the oil spill so that it doesn't spread too wide. The hydraulic system is a system that utilizes pressurized liquid fluid as the actuator drive media. The concept of the technical analysis of this system is the design of the winch system using a hydraulic motor which is a driving device as well as a roller of an oil boom that has a length of 2 kilometers and then stored into the drum that has been designed. All components are in a container package that has been designed to place the position and layout. To see the advantages and disadvantages of the system design, technical analysis is carried out. From the results of data processing it can be calculated for the torque moment of the drum which is equal to 9,344.416 Nm and weighs 242.697 kg. BLACKBRUIN BBC05 type hydraulic motor has been determined which has a torque of 10,360-13,305 Nm and a pressure of 350-400 bar. After the total air demand for oil boom as long as 2 km is known, which is equal to 552,951 cm3, the next step is to select the right compressor. Selected type TANABE TASK-25110 compressor with a capacity of 1,020 m3/hour. That way, it can be determined the air filling time for the oil boom is 0.542 hours = ±35-40 minutes.

Container; Drum; Hydraulic; Oil Boom; Winch

D. S. Etkin, “Modeling oil spill response and damage costs.” Freshwater spills symposium 2004. United States Environmental Protection Agency, Washington, D.C., USA. 2004.

M. F. Fingas, “The basics of oil spill cleanup.” 3rd Edition. Taylor and Francis Group, Boca Raton, Florida, USA. 2012.

P. Herrington, G. Ball, and K. O’Halloran. “Aquatic ecotoxicity of cutback bitumen.” Land Transport New Zealand, Wellington, New Zealand. 2006.

Marine Pollution 73/78

American Petroleum Institute. “Oil spill response: options for minimizing adverse ecological impacts.” American Petroleum Institute, Washington, D.C., USA. 1985.

British Columbia Ministry of Environment (BC-MOE). “British Columbia marine oil spill response plan.” Provincial document. British Columbia Ministry of Environment, Victoria, British Columbia, Canada. 2013.

International Energy Agency (IEA). “World Energy Outlook 2010.” International Energy Agency, Paris, France. 2010.

T. Nyman, “Evaluation of methods to estimate the consequence costs of an oil spill.” SKEMA Seventh Framework Programme, Athens, Greece. 2009.

A. Nelson-Smith, “Oil pollution and marine ecology.” Plenum, New York, USA. 1973

Port Metro Vancouver. “Tanker traffic: oil tanker movement.” Port Metro Vancouver, British Columbia, Canada. 2013.

M. Boulton, “Financial vulnerability assessment: who would pay for oil tanker spills associated with the Northern Gateway pipeline?” University of Victoria, Environmental Law Centre, Victoria, British Columbia, Canada. 2010.

British Columbia Government. “Requirements for British Columbia to consider support for heavy oil pipelines.” Provincial document. British Columbia Government, Victoria, British Columbia, Canada. 2012.

Conversations for Responsible Economic Development. “Assessing the risks of Kinder Morgan’s proposed new Trans Mountain pipeline.” Conversations for Responsible Economic Development, Vancouver, British Columbia, Canada. 2013.

E. J. Danielson, “A study of the economic impact of the Deepwater Horizon oil spill - Part 3: public perception.” Greater New Orleans, Inc., New Orleans, Louisiana, USA. 2011.

David Suzuki Foundation. “Oil spill scenarios.” Video. David Suzuki Foundation, Vancouver, British Columbia, Canada. 2013.