Philips Electromagnetic Lamp manual 122, Placed in series with one of the ballasts

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5

3.4 Power factor correction

L2

L1

‘TL’

S

1

 

Fig. 115. Duo-circuit with the capacitor

C

‘TL’

S

2

 

placed in series with one of the ballasts.

0

The series capacitor has an impedance which is twice the normal ballast impedance, resulting in a power factor of approx. 0.5 capacitive for one branch.Together with the power factor of 0.5 inductive for the other branch, the total power factor of the two branches is approx. 0.95. With a normal 230 V supply, the voltage across the capacitor is about 400 V.To fulfil all relevant requirements, the tolerance on the capacitor capacitance value has to be within +/- 4 %.The nominal value of the capacitance is depending on the mains supply voltage, the applied ballast impedance and the lamp wattage.Typical values are 3.4 µF for a 36 W and 5.3 µF for a 58 W lamp.

Compared with the mono-compensation the advantages of this way of compensation are:

-only one capacitor is required for two lamps, instead of two,

-the capacitive branch is less sensitive to supply voltage deviations, as it has a constant current characteristic,

-in case of actadis signals (see section 5.3.3: Filter coils) these signals are not influenced, so no filter coil is needed.

Disadvantages of duo-compensation are:

-series capacitors are more expensive than parallel capacitors,

-the lamp power and so the light output from the capacitive branch is slightly higher than that from the inductive branch.

In some countries, practically all multi-lamp luminaires have built-in duo-circuits for each pair of lamps (also called a ‘dual-lamp’ or ‘lead-lag’ circuit). Mono-compensation, on the other hand, is generally left to the installer, although there are also single-lamp luminaires available with the compensation built in.

The capacitive circuit has a so-called ‘constant current characteristic’. This can be explained by the non-linearity of the inductive ballast. Suppose that the impedance of the ballast is 400 Ω , which varies, say 10 per cent when the ballast voltage changes 10 per cent (see Fig. 116). With the inductive ballast the resulting (lamp) current at 90 per cent mains voltage will be lower:

A:as result of the lower mains voltage,

B:as result of the higher impedance.

With the capacitive ballast combination, the resulting impedance of inductive ballast and capacitor is reacting in just the opposite way: at lower mains voltage the total impedance is also lower.This results in a nearly constant current.

122

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Contents Main ballast functions StabilisationIgnition and re-ignition 107Types of ballasts 108Ignition and re-ignition Resistor ballasts109 Types of ballastsCapacitor ballasts Inductive ballasts or chokesBallast specification and marking 110Ballast specification and marking Maximum coil temperature tw and ΔT111 Watt losses 112Glow-switch starters Main starter functionStarter types 113114 Starter typesLifetime Components115 Electronic startersCapacitors 116Components Discharge tube Starter Capacitor Ballast Thermal protector117 Capacitors Filter coilsIEC 119 Power factor correctionFilter coils Power factor correction 120121 SinLamp factor = lamp wattage / lamp voltage . lamp current 122 Placed in series with one of the ballastsSeries connection of lamps 123Neutral interruption and resonance 124Series connection of lamps Good neutral is essential125 Neutral interruption and resonancePL-TSC 4-pins Electrical diagrams126 Electrical diagrams 127PL-S, PL-C starter incorporated ‘TL’D, PL-LMains voltage interruptions and short-circuiting Harmonic distortion128 Mains voltage interruptions and short-circuiting129 Harmonic distortion130 Ninth harmonic131 Electromagnetic interferenceReinforce each other 132 Electromagnetic interferenceAmbient and operating temperatures Ambient and operating temperaturesMinimum temperatures Lamps 133Maximum temperatures Lamps 134Gear LuminairesBallasts 135Starters Effects of mains voltage fluctuations 136Electrical wiring 137138 Electrical wiringSee IEC 598, section Hum 139140 DimmingDimming 141 Coil in series and by a thyristorStroboscopic effect and striations 142Stroboscopic effect and striations For this subject, see also section Lamps143 144 145 Circuit breakers, fusing and earth leakageStandard conditions Main circuit breakers work on two principles 146According to CEE-19-2ndedition L, U and K 147 Non-standard conditionsShort-circuiting of the lamp Short-circuiting of the ballast148 Short-circuiting of the ignitorShort-circuiting of the parallel compensating capacitor Short-circuiting of the series capacitorFault finding Circuit breakers, fusing and earth leakage149 1AVisual inspection of lamps150 151 Fault finding Fault IV lamp flickersElectrical tests Fault finding 152153 Installation aspectsType ballast should be used Maintenance Non-standard supply voltages154 Non-standard supply voltages

Electromagnetic Lamp specifications

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