MINI-EESF Modul Pelatihan Energi Fotovoltaic. (Versi lengkap)

PHOTOVOLTAIC SOLAR ENERGY MODULAR UNIT (COMPLETE VERSION) - MINI-EESF

SISTEM INOVATIF

Photovoltaic Solar Energy Modular Unit (Complete Version), "MINI-EESF", is a laboratory scaled unit designed to study all the parameters involved in the solar radiation direct conversion into electricity.

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BERITA TERKAIT

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Photovoltaic Solar Energy Modular Unit (Complete Version), "MINI-EESF", is a laboratory scaled unit designed to study all the parameters involved in the solar radiation direct conversion into electricity.

The unit is based on some application modules and photovoltaic solar panels assembled in mobile structures.

It is specially designed for the theoretical and practical study of the electrical installations with photovoltaic solar energy, the typical configurations used in photovoltaic installations and the operation of the different elements involved in the conversion.

The power obtained from the solar energy can be:

  • Regulated to obtain a DC power to charge a battery, studying parameters such as solar module´s current output charge level, battery voltage, etc.
  • Delivered to DC loads, studying parameters such as solar module´s current output and current consumption by the loads.
  • Converted to AC power to be delivered to AC loads, studying parameters such as current consumption by the loads.
  • Injected to the public grid, studying parameters such as output current and voltage of the simulated solar module, power supplied to the public grid, frequency and voltage of the grid, etc.

Two different versions are available with different practical possibilities and levels of difficulty: MINI-EESF/M and MINI-EESF/B.

LATIHAN DAN PRAKTEK PEDOMAN

LATIHAN PRAKTIS YANG DIANDAL TERMASUK DALAM PANDUAN

  1. Determination of the constituent material of the solar cell.
  2. Determination of the I-V first quadrant curve without illuminating the solar cell.
  3. Determination of the inverse (or saturation) current of the cell without illumination.
  4. Determination of parallel and series resistance of a solar cell without illumination.
  5. Dependency of the open circuit voltage (Voc) with lumens (luminous flux).
  6. Determination of the parameters that describe the quality of a solar cell.
  7. Solar energy measurement.
  8. Measurement of the solar panel voltage with no load.
  9. Determination of the disposition of cells in a solar panel.
  10. Familiarisation with the regulator parameters.
  11. Loads connection to 12 VDC.
  12. Loads connection to 220 VAC.
  13. Study of the inverter with grid connection.
  14. Battery charging.
  15. Practices of serial and parallel panel configuration (minimum two MINI-EESF units).
  16. Study of the hybrid inverter’s grid connection procedure: correct sequence of battery and grid switches (EE-HYB-KIT).
  17. Study of the hybrid inverter configuration (EE-HYB-KIT).
  18. Study of the hybrid inverter in grid connection mode (EE-HYB-KIT).
  19. Study of the hybrid inverter in island mode (EE-HYB-KIT).
  20. Study of the behavior of the hybrid inverter in the event of a blackout (EE-HYB-KIT).
  21. Study of the charging process of the battery from the laboratory grid through the hybrid inverter (EE-HYB-KIT).
  22. Study of the battery charging process from a renewable energy source (EE-HYB-KIT).
  23. Study of the power flows of the battery and the grid under variations of the energy demand with the variable resistive load (EE-HYB-KIT).
  24. Study of the response of the hybrid inverter when the critical discharge point of the battery is reached (EE-HYB-KIT).
  25. Study of the energy balance between the battery-charge-grid by means of the analog ammeters and voltmeters incorporated in the kit (EE-HYB-KIT).

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