The stable atmospheric boundary layer a challenge for wind turbine operatio...ndkelley
An overview presentation of the impact and challenge of the stable atmospheric boundary layer on wind turbine dynamics presented to AGU Fall Meeting 2008
The stable atmospheric boundary layer a challenge for wind turbine operatio...ndkelley
An overview presentation of the impact and challenge of the stable atmospheric boundary layer on wind turbine dynamics presented to AGU Fall Meeting 2008
Vibration Energy Harvesting in Action: Real World Case StudiesKarim El-Rayes
This is the slides for my talk at Sensors Expo & Conference 2018 in San Jose, California, on commercial and research applications of vibrations energy harvesting in the fields of medical implants, wearables, structural health monitoring, green buildings and many other. #Sensors18
Electricity from vibration & its impactSagardwip das
With the growing demands of human needs the utilisation of conventional energy has increased tremendously. Consequently environmental issues like global warming etc. have risen. Keeping these facts in view this model has been prepared to present an idea on how the daily energy requirement can be fulfilled in a more practical, feasible and economical way by converting mechanical energy of vibration into electric energy
1. I deal " RENEWABLE ENERGIES " ELECTRICAL OSCILLATING MACHINE. DIRECT EXPLOITATION (DEVELOPMENT) OF THE WAVE ENERGY " THEMATIC BLOCK. ENERGY OF THE MAR
2. MÁQUINA ELÉCTRICA OSCILANTE EXPLOTACIÓN DIRECTA DE LA ENERGÍA DEL OLEAJE I DESIGN NEW ELECTRICAL MACHINE OSCILLATORY STRUCTURE REQUEST OF CLEAR DECEMBER, 2004 ELECTRICAL OSCILLATING MACHINE DIRECT EXPLOITATION (DEVELOPMENT) OF THE WAVE ENERGY SPECIFIC APPLICATION
3. ELECTRICAL OSCILLATING MACHINE Rose of the winds Source: www.dama.gov.co Rose of the surge Source: M.T. Pontes y elaboración propia P (kW/m)
4. ANNUAL POWER OF THE SURGE. NORTH-EAST OF THE ATLANTIC OCEAN ELECTRICAL OSCILLATING MACHINE Potential annual energy 350 MWh/m CANTABRIA The levels of power are expressed I n kW/m Source: WERATLAS (Atlas Europeo de la Energía del Oleaje) y elaboración propia
5. HISTOGRAM OF THE PROBABILITY OF POWER OF THE SURGE. COAST SANTOÑA's WEST. I HIBERNATE ELECTRICAL OSCILLATING MACHINE Probabilidad de exceso de potencia P (kW/m) Source: M.T. Pontes
6. ELECTRICAL OSCILLATING MACHINE COST CURVE OF THE LEARNING Source G. Hagerman; Virginia Tech. Research Institute, Alexandria, USA. Tiempo Coste / Potencia first second tirth forth fifth COST ESTIMATED WITH INCOMPLETE INFORMATION PERIOD OF COST ESTIMATE TECHNOLOGICAL MATURITY
7. ELECTRICAL OSCILLATING MACHINE DPARABOLIC ISPOSITIVO 500 kW. Port Kembla. New South Wales. Source : Energetech Australia Pty. Ltd. 2000.
14. STRUCTURE OF THE MACHINE MÁQUINA ELÉCTRICA OSCILANTE DEVELOPED DESIGNS IT ALLOWS RELATIVE MOVEMENT OF THE BODIES HOUSING ELECTRICAL CIRCUITS machine CYLINDRICAL ASYMMETRIC CYLINDRICAL BALLASTED esferic CUERPO 1 CUERPO 2