A New Technique to Equalize Branch Currents in Multiarray LED Lamps Based on Variable Inductors

A New Technique to Equalize Branch Currents in Multiarray LED Lamps Based on Variable Inductors

In this paper, a new technique to equalize light-emitting diode (LED) currents in multiarray LED lamps is proposed. The current through the LEDs is controlled by changing the inductance of a variable inductor. The proposed technique can be employed to control the current through each LED branch inde...

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Veröffentlicht in:IEEE transactions on industry applications 2016-01, Vol.52 (1), p.521-530
Hauptverfasser: Adaime Pinto, Rafael, Marcos Alonso, J., Perdigao, Marina S., da Silva, Marcelo F., do Prado, Ricardo N.
Format: Artikel
Sprache:eng
Schlagworte:
Arrays
Converters
current control
current equalization
DC-to-DC converter
Design engineering
Diodes
Inductance
Inductors
Lamps
LED drive
LED lamps
Light-emitting diodes
Mathematical analysis
multi-array LED lamps
Prototypes
variable inductor
Voltage control
Windings
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Beschreibung
Zusammenfassung:In this paper, a new technique to equalize light-emitting diode (LED) currents in multiarray LED lamps is proposed. The current through the LEDs is controlled by changing the inductance of a variable inductor. The proposed technique can be employed to control the current through each LED branch independently. The operation principle of this technique and a design example of the proposed system are presented in detail in this paper. As an example, a forward converter has been selected to supply the LED branches, which can be designed to operate with one or several outputs. The component values of the converter as well as the LED current control circuit are also calculated as a design example. A prototype of the circuit has been implemented. The experimental results obtained at the laboratory are satisfactory and in accordance to the proposed design methodology. The proposed technique can prove to be very cost-effective for LED drivers in the range of 100 W and beyond with multiple independent LED arrays.
ISSN:0093-9994
1939-9367
DOI:10.1109/TIA.2015.2483596