Rigorous thermohydraulics and mechanical integrity
Validating physical laws across scales, from high-consequence nuclear reactor thermal management to micro-level biomedical devices.
Primary Engineering Disciplines
Dr. Senda's academic and industrial investigations target high-efficiency thermal systems and precise fluid dynamics.
Thermal Management
Fluid Mechanics
Biomedical Devices
Developing advanced waste heat recovery systems, regenerative heat exchangers, and lumped parameter models for energy conversion.
Analyzing fluctuating flow regimes, multiphase transport, and dynamic behavior within high-consequence environments.
Investigating mechanical integrity and filtration characteristics of membrane modules for extracellular vesicle isolation.
Selected Peer-Reviewed Literature
Mechanical integrity investigation of membrane filter modules used for extracellular vesicles' bulk isolation
Aspects of conceptualization, development, and simulation of a bulk isolation device
A rigorous structural and dynamic analysis of filtration characteristics under fluctuating fluid regimes.
Engineering design parameters for high-purity isolation of extracellular vesicles for therapeutic use.
Lumped Parameter Modelling and Testing of a Free Piston Stirling Engine Heat Exchanger
Aspects of waste heat recovery and utilisation in pebble bed modular Reactor technology
Utilizing laminated woven copper wire mesh as high-performance heat transfer surface areas.
Investigating high-temperature thermodynamic cycles for power generation and industrial heat use.
Bridging physical laws and physical validation
Partner with Dr. Senda for independent technical advisory services, peer-review validation, or complex thermohydraulic modeling.