Aims and Scope Energy Conversion Mechanical Engineering Journal
Aims
The Energy Conversion Mechanical Engineering Journal aims to provide a dedicated platform for the presentation and dissemination of scientific research that advances the understanding of core and related topics in mechanical engineering, particularly in the fields of heat and fluid sciences. The journal focuses on both analytical and experimental research works, with an emphasis on studies that contribute to a fundamental understanding of mechanical, thermal, and fluid phenomena and their practical applications to engineering problems.
The Energy Conversion Mechanical Engineering Journal covers a broad range of topics in mechanical engineering—including heat transfer, fluid mechanics, aerospace, manufacturing, dynamics, vibration, control, materials, and design—with a particular focus on thermal–fluid systems and energy conversion processes.
The types of manuscripts published by the journal include:
- Original Research Articles
- Review Papers
- Research Notes
- Technical Notes
Vision
The journal aspires to become a leading reference in advancing the standards of discussion, analysis, and evaluation within the field of mechanical engineering. The Energy Conversion Mechanical Engineering Journal welcomes original and significant research contributions across all areas of mechanical engineering and its practical applications.
Scope
The journal’s scope covers a wide range of topics in mechanical engineering, with particular emphasis on heat transfer, fluid mechanics, and energy conversion, including but not limited to:
• Thermal effects on aerospace structures
• Plasma applications
• Analytical methods in heat and fluid mechanics
• Heat in metal forming processes
• Thermal phenomena in biomechanics
• Thermal aspects of casting
• Computational fluid dynamics (CFD)
• Combined heat and power (CHP) systems
• Combustion processes
• Heat transfer in composites
• Compressible flows
• Control systems
• Creep behavior
• Fracture mechanics
• Dynamics and vibration
• Elasticity and plasticity
• Building energy systems
• Energy systems management
• Environmental considerations in thermal systems
• Experimental fluid mechanics and heat transfer
• Fatigue and fracture
• Finite element methods (FEM)
• Fluid mechanics and thermodynamics
• Fuel cells
• Gas dynamics
• Heat and mass transfer
• Hydraulic and pneumatic systems
• Impact mechanics
• Industrial manufacturing methods
• Instrumentation and measurement |
