Philips Electromagnetic Lamp manual 147, Non-standard conditions, Short-circuiting of the lamp

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3.18 Circuit breakers, fusing and earth leakage

Information on what lighting load a certain MCB can handle may be given by the MCB supplier, provided information about the cabling lay-out, lamp type and circuit is available.As a guide, a practical value for the figure (1) of the 10 A MCB type C represents 1500 W lighting load with the conventional gear.

2 Non-standard conditions

A fluorescent lamp circuit normally consists of four parts: lamp, ballast, starter and compensating capacitor.

The effects of short-circuiting one of these parts are:

1) Short-circuiting of the lamp

This has been described above: in the inductive circuit the mains current will be approx. 1.5 times the nominal value, which means an extra temperature rise of the ballast and cabling by a factor 1.52.There is no immediate damage or danger and the situation can continue to exist for days.Tested in a complete luminaire at 110 % Vmains the ballast temperature must be lower than 232 ºC, which guarantees a minimum lifetime of the ballast of 20 days in this situation. In most cases the mains fuse will not blow and the situation can only be solved by good maintenance.

In a capacitive circuit the current is even lower than the nominal value when the lamp is short-circuited. So then the described effects are not noticeable.

2) Short-circuiting of the ballast

As there is no current limit in this case, the lamp current will rise immediately to an undefined high value in the inductive circuit. If the current is not switched off by the mains fuse, the lamp will normally become an open circuit because (one of) the lamp electrodes will melt. In most cases this process is so quick that there will be no extra danger or damage. In practice, however, it happens that the ballast is partly short-circuited inside the copper coil, for example at the end of the ballast lifetime.This results in a higher ballast temperature and a higher lamp power.This process is cumulative and normally the mains fuse will not blow, while the ballast gets hotter and hotter until a fatal earth or winding breakdown occurs. For this reason, the ballast must be mounted in such a way that it can cause no danger during end-of-life failure.

Good maintenance can prevent blown-up lamps and burned-out ballasts. When in a capacitive circuit the ballast is short-circuited, the lamp

is only stabilised by the series capacitor. In most cases the lamp will extinguish, as the remaining impedance is too high ( lZc l = 2. lZL l).

In those cases where the lamp continues to work, the high capacitive peak currents through the lamp, will rapidly damage the lamp electrodes.The lamp will blacken at the lamp ends and sooner or later a lamp electrode will break, resulting in an open circuit.

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Contents Stabilisation Main ballast functionsIgnition and re-ignition 107108 Types of ballastsIgnition and re-ignition Resistor ballastsTypes of ballasts 109Capacitor ballasts Inductive ballasts or chokes110 Ballast specification and marking111 Maximum coil temperature tw and ΔTBallast specification and marking 112 Watt lossesMain starter function Glow-switch startersStarter types 113Starter types 114Components Lifetime115 Electronic starters116 CapacitorsComponents Discharge tube Starter Capacitor Ballast Thermal protector117 IEC Filter coilsCapacitors Filter coils Power factor correction119 120 Power factor correctionLamp factor = lamp wattage / lamp voltage . lamp current Sin121 Placed in series with one of the ballasts 122123 Series connection of lamps124 Neutral interruption and resonanceSeries connection of lamps Good neutral is essentialNeutral interruption and resonance 125126 Electrical diagramsPL-TSC 4-pins 127 Electrical diagramsPL-S, PL-C starter incorporated ‘TL’D, PL-LHarmonic distortion Mains voltage interruptions and short-circuiting128 Mains voltage interruptions and short-circuitingHarmonic distortion 129Ninth harmonic 130Reinforce each other Electromagnetic interference131 Electromagnetic interference 132Ambient and operating temperatures Ambient and operating temperaturesMinimum temperatures Lamps 133134 Maximum temperatures LampsGear LuminairesStarters 135Ballasts 136 Effects of mains voltage fluctuations137 Electrical wiringSee IEC 598, section Electrical wiring138 139 HumDimming Dimming140 Coil in series and by a thyristor 141142 Stroboscopic effect and striationsStroboscopic effect and striations For this subject, see also section Lamps143 144 Standard conditions Circuit breakers, fusing and earth leakage145 According to CEE-19-2ndedition L, U and K 146Main circuit breakers work on two principles Non-standard conditions 147Short-circuiting of the lamp Short-circuiting of the ballastShort-circuiting of the ignitor 148Short-circuiting of the parallel compensating capacitor Short-circuiting of the series capacitorCircuit breakers, fusing and earth leakage Fault finding149 1AVisual inspection of lamps150 Electrical tests Fault finding Fault IV lamp flickers151 152 Fault findingType ballast should be used Installation aspects153 Non-standard supply voltages Maintenance154 Non-standard supply voltages

Electromagnetic Lamp specifications

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