Engineering
Organic Rankine Cycle
100%
Waste Heat Recovery System
56%
Liquefied Natural Gas
41%
Board Ship
30%
Power Engineering
26%
Performance Analysis
24%
Early Stage
24%
Ship Design
24%
Design Phase
24%
Energy Engineering
17%
Ports and Harbors
16%
Power Generation
15%
Economic Feasibility
14%
Technical Feasibility
14%
Backpressure
14%
Heat Recovery Unit
13%
Comparative Analysis
12%
Thermal Energy Storage
12%
Economic Potential
12%
Design Process
12%
Nonlinear Optimization
12%
Design Purpose
12%
Linear Programming
12%
Optimization Approach
12%
Bulk Carrier
12%
Main Engine
11%
Steam Rankine Cycle
10%
Electrical Efficiency
9%
Multiobjective Optimization
9%
Systems Performance
9%
Marine Applications
8%
Computational Time
8%
Heat Recovery Boiler
7%
Annual Energy Production
6%
Levelized Cost of Electricity
6%
Power Output
6%
Optimal Design
6%
Energy Production
6%
Exhaust Gas
6%
Exhaust Gas Recirculation
6%
Fuel Supply System
6%
Low-Temperature
6%
Part Load
6%
Heat Source
6%
Battery (Electrochemical Energy Engineering)
6%
Electric Propulsion
6%
Selective Catalytic Reactor
6%
International Maritime Organisation
5%
Keyphrases
Organic Rankine Cycle
36%
Liquefied Natural Gas
24%
Ship Machinery System
24%
Waste Heat Recovery
12%
Liquefied Natural Gas Cold Energy
12%
Nonlinear Programming
12%
Cold Energy Recovery
12%
Comparative Analysis
12%
Annual Performance
12%
Cycle Configuration
12%
Machinery System
12%
Emission Abatement Technology
12%
Performance Analysis
12%
Main Engine
8%
Fuel Saving
8%
Design Phase
8%
Ship Design
8%
Waste Heat Recovery Unit
8%
Fuel Supply System
7%
Unit Scheduling
7%
Operational Profile
6%
Cruise Ship
6%
Shore Power
6%
Large Cruise Ship
6%