[0001] This invention relates to a circuit arrangement for ignition of a high intensity
discharge lamp. In general the circuit arrangement is formed by a ballast for the
HID lamp. It is also possible that the circuit arrangement is formed by a separate
ignitor.
[0002] An HID lamp generally refers to a family of lamps including high pressure mercury,
high pressure sodium, metal halide and low pressure sodium. A HID lamp has during
ignition a glow mode, in which a glow discharge is developed in the lamp before a
full arc discharge takes place. A conventional ballast for powering an HID lamp includes
an ignitor. The ignitor provides high voltage ignition pulses applied to the lamp
for starting the latter.
[0003] The energy from the high voltage pulses generated by the ignitor are provided to
the lamp prior to the lamp entering its glow mode. At the time that the lamp begins
to enter its glow mode, the ignitor is shut off. No high voltage pulses are generated
during the glow mode. When ignition is successful, the lamp proceeds rapidly through
the glow mode to a steady state condition, that is, from a glow discharge to an arc
discharge condition between the lamp's electrodes. Such circuits arrangements are
known from US-A-4 695 771 and US-A-4 678 968.
[0004] The amount of energy required for successful ignition varies and depends on factors
such as, but not limited to, partial pressures of the gasses within the lamp. When
an insufficient amount of energy is delivered to the HID lamp to ignite the latter,
the lamp can become stuck in its glow mode and never reach a steady state (full arc)
condition.
[0005] Repeated exposure to prolonged periods within the glow mode can damage the HID lamp
electrodes. Destruction of the lamp can result.
[0006] Accordingly, it is desirable to provide an improved HID ignitor having more reliable
HID ignition properties. The ignitor, in particular, should avoid prolonged periods
of time within the glow mode.
[0007] Generally speaking, in accordance with a first aspect of the invention, a circuit
arrangement for ignition of a high intensity discharge lamp, having during ignition
a glow mode, includes output terminals and an ignitor for production at igniting the
lamp of ignition pulses prior to and at least substantially throughout the glow mode
of the high intensity discharge lamp. The ignitor includes a voltage sensor for sensing
the voltage across the output terminals and is responsive to the voltage sensor in
its production of ignition pulses.
[0008] The circuit arrangement avoids remaining the lamp within the glow mode for an extended
period of time by production of ignition pulses not only prior to but also substantially
throughout the glow mode of the high intensity discharge lamp. The ignition pulses
produced prior to and substantially throughout the glow mode provide sufficient energy
for successful takeover, that is, for the lamp to move from a glow discharge to arc
discharge operating condition. Damage of the lamp electrodes and consequent lamp destruction
based on prolonged duration of operation within the glow mode during start-up is substantially
eliminated.
[0009] Preferably, the ignitor includes a bilateral switching device such as, but not limited
to, a SIDAC having a breakover voltage chosen to correspond to the voltage across
the lamp at about the end of the lamp's glow mode. The ignitor preferable also includes
a capacitor coupled to the bilateral switching device through which the capacitor
discharges at breakover of the bilateral switching device.
[0010] Still other objects and advantages of the invention, will, in part, be obvious, and
will, in part, be apparent from the specification.
[0011] The invention accordingly comprises several steps in the relation of one or more
such steps with respect to each of the others, and the device embodying features of
construction, combination of elements and arrangements of parts which are adapted
to effect such steps, all is exemplified in the following detailed disclosure, and
the scope of the invention will be indicated in the claims.
[0012] For a fuller understanding of the invention, reference is had to the following description
taken in connection with the accompanying drawing which is a circuit arrangement in
accordance with the invention.
[0013] As shown in the drawing the circuit arrangement comprises a ballast 10 which is connected
through a pair of input terminals 33 and 36 to an A.C. source 20. Ballast 10 provides
power through a pair of output terminals 39 and 42 to an HID lamp 40.
[0014] Ballast 10 includes an autotransformer 60 having a primary winding 60 with a tap
63. Winding 60 is connected to input terminals 33 and 36. A capacitor 66 is connected
between tap 63 and one end of a ballast winding 65. Ballast winding 65 which is magnetically
coupled to primary winding 60 includes a first tap 76 and a second tap 77. The portion
of ballast winding 65 between taps 76 and 77 is commonly referred to as an ignitor
winding 79. The other end of ballast winding 65 is connected to output terminal 39.
[0015] Ballast winding 65 serves to limit/control the level of current flowing through lamp
40 when the latter is lit. A SIDAC 89 and a capacitor 92 are connected respectively
to taps 76 and 77. SIDAC 89 and capacitor 92 are also connected through the serial
combination of an inductor 95 and a resistor 96 to the junction joining primary winding
60, input terminal 36 and output terminal 42 together. Ignitor winding 79, SIDAC 89,
capacitor 92, inductor 95 and resistor 96 serve together as an ignitor (i.e., starting
circuit) 80. Ignitor 80 can be integrally connected to ballast winding 79. Alternatively,
SIDAC 89 and capacitor 92 can be detachably connected to tap points 76 and 77, respectively.
[0016] Ballast 10 operates as follows. Power is supplied from A.C. source 20 to input terminals
33 and 36 of ballast 10. The voltage produced by A.C. source 20 is insufficient to
ignite/start lamp 40, the latter of which requires ignition (starting) pulses. The
ignition pulses are provided by ignitor 80. More particularly, as current flows through
capacitor 92, inductor 95 and resistor 96, capacitor 92 charges to the breakover voltage
of SIDAC 89.
[0017] The breakover voltage is chosen so as to correspond to the characteristic glow discharge
voltage of lamp 40, that is to say equal to or just below the glow discharge voltage
of the lamp 40, but well above the voltage of the steady arc of the lamp. The glow
discharge voltage will differ for different types of HID lamps and depend amongst
others on whether the lamp has electrodes with or without emitter. For lamps having
electrodes with emitter the glow discharge voltage will be significantly lower than
in case of comparable lamps having electrodes without emitter. For a person skilled
in the art the glow discharge voltage of a lamp can easily be determined experimentally.
In other words, the breakover voltage is chosen as to correspond to the voltage across
the lamp at about the end of the lamp glow mode.
[0018] Once the breakover voltage is reached, SIDAC 89 switches from its previous OFF-state
to its ON-state. Capacitor 92 now discharges through ignitor winding 79 and SIDAC
89 resulting in a voltage pulse produced across ignitor winding 79. Through transformer
action (i.e. ballast 65 acting as an autotransformer), a high voltage pulse is developed
across output terminals 39, 42. The cyclical charging and discharging of capacitor
92 produces a series of high voltage pulses across output terminals 39, 42. By associating
the breakover voltage of SIDAC 89 with the glow mode of lamp 40, ignition pulses are
provided by ignitor 80 prior to and substantially throughout the glow mode of lamp
40. During transition from glow discharge to full arc discharge, the voltage across
lamp 40 temporarily increases. Following transition into a full arc condition (discharge),
the voltage across lamp 40 sufficiently drops to turn OFF SIDAC 89. Accordingly, after
transition to full arc discharge, ignitor 80 is shut OFF.
[0019] SIDAC 89 serves as a voltage sensor for sensing the voltage across output terminals
39 and 42 of ballast 10. Ignitor 80, in response to SIDAC 89 cyclically turning ON
and OFF, provides a sufficient amount of energy for successful takeover of lamp 40.
In particular, the continuous production of ignition pulses prior to and at least
substantially throughout the glow mode avoids lamp 40 remaining within the glow mode
for an extended period of time. Damage of the lamp electrodes and consequent lamp
destruction based on prolonged duration within the glow mode is substantially eliminated.
[0020] For example, when lamp 40 is of a metal halide type, nominally rated at 150 watts,
95 volts with SIDAC 89 having a breakover voltage of between about 110-125 volts,
a voltage pulse of about 110-125 volts is applied across ignitor winding 79. A voltage
of about 1800 to 3500 volts is developed across output terminals 39, 42 for starting
the lamp. The SIDAC breakover of about 110-125 volts corresponds to a lamp voltage
of between 150v - 200v, respectively. The cycle of charging capacitor 92 until reaching
the SIDAC breakover voltage resulting in the generation of a high voltage pulse applied
to lamp 40 is repeated prior to and at least substantially throughout the glow mode
of lamp 40. Ignitor 80 is shut OFF at the end of the glow mode.
[0021] More particularly, once lamp 40 is lit, the voltage across SIDAC 89 drops below its
breakover voltage. Ignitor 80 is no longer able to produce a voltage pulse across
ignitor winding 79. In other words, as long as lamp 40 remains lit, ignitor 80 will
produce no additional voltage pulses.
[0022] In accordance with the preferred embodiment of the invention, ballast 30 is a 150
watt metal halide constant wattage autotransformer (CWA) available from Advance Transformer
Company of Rosemont, Illinois as part no. 71A5486. Capacitor 66 is nominally rated
at 22.5
µF, 240 volts. SIDAC 89 is available from Shindengen Electric Mfg. Co., Ltd. as Part
No. K1V12 and has a nominally rated breakover voltage of about 110-125 volts. Capacitor
92 is nominally rated at about 0.33 microfarads. Lamp 40 is a high intensity discharge
type, such as but not limited to, a 150 watt, 95 volt metal halide type. Inductor
96 typically includes two serial connected coils, each nominally rated at 22 millihenries.
Resistor 95 is nominally rated at 3.5 kohm.
[0023] As now can be readily appreciated, the invention provides an improved ignition in
which ignition pulses are produced prior to and at least substantially throughout
the glow mode of lamp 40. Prolonged periods of time of lamp operation within the glow
mode are substantially eliminated by providing sufficient energy for successful takeover
of the lamp 40.
1. A circuit arrangement for ignition of a high intensity discharge lamp (40) having
during ignition a glow mode, comprising:
output terminals (39, 42) and
an ignitor (80) for production at igniting the lamp of ignition pulses prior to the
glow mode, said ingnitor having a voltage sensor (89) for sensing the voltage across
the output terminals and being responsive to the voltage sensor in the production
of ignition pulses, charachterized in that the ignitor is designed for production
of ignition pulses also substantially throughout the glow mode.
2. The circuit arrangement of Claim 1, wherein the ignitor includes a bilateral switching
device (89) having breakover voltage chosen to correspond to the voltage across the
lamp at about the end of the lamp glow mode.
3. The circuit arrangement of Claim 2, wherein the ignitor includes a capacitor (92)
coupled to the bilateral switching device and through which the capacitor discharges
at breakover of the bilateral switching device.
4. The circuit arrangement of Claim 3, wherein the bilateral switching device is a SIDAC.
1. Schaltungsanordnung zur Zündung einer Entladungslampe (40) mit hoher Intensität, welche
einen Glimmzustand während der Zündung vorsieht, mit:
Ausgangsklemmen (39, 42) und
einem Ignitor (80), um bei Zünden der Lampe vor dem Glimmzustand der Entladungslampe
hoher Lichtstärke Zündimpulse zu erzeugen, wobei der Ignitor einen Spannungssensor
(89) aufweist, um die Spannung an den Ausgangsklemmen zu erfassen und bei der Erzeugung
von Zündimpulsen auf den Spannungssensor anspricht, dadurch gekennzeichnet, dass der Ignitor so ausgelegt ist, dass er Zündimpulse ebenfalls im Wesentlichen während
des Glimmzustands erzeugt.
2. Schaltungsanordnung nach Anspruch 1, wobei der Ignitor ein bilaterales Schaltelement
(89) mit einer Kippspannung aufweist, welche so ausgewählt ist, dass sie der Spannung
an der Lampe etwa am Ende des Glimmzustands der Lampe entspricht.
3. Schaltungsanordnung nach Anspruch 2, wobei der Ignitor einen Kondensator (92) aufweist,
welcher an das bilaterale Schaltelement gekoppelt ist, über welches sich der Kondensator
bei Schalten des bilateralen Schaltelementes entlädt.
4. Schaltungsanordnung nach Anspruch 3, wobei das bilaterale Schaltelement durch einen
SIDAC dargestellt ist.
1. Dispositif de circuit servant à l'amorçage d'une lampe à décharge à haute intensité
(40) présentant un mode d'incandescence pendant l'amorçage et comprenant:
des bornes de sortie (39, 42) et
un amorceur (80) servant à la production d'impulsions d'amorçage pendant l'amorçage
de la lampe avant le mode d'incandescence, ledit amorceur présentant un élément capteur
de tension (89) permettant de capter la tension se produisant aux bornes de sortie
et répondant à l'élément capteur de tension dans la production d'impulsions d'amorçage,
caractérisé en ce que l'amorceur est conçu pour la production d'impulsions d'amorçage également essentiellement
pendant le mode d'incandescence.
2. Dispositif de circuit selon la revendication 1, dans lequel l'amorceur est muni d'un
dispositif de commutation bilatérale (89) présentant une tension de claquage choisie
pour correspondre à la tension se produisant aux bornes de la lampe à environ la fin
du mode d'incandescence de la lampe.
3. , Dispositif de circuit selon la revendication 2, dans lequel l'amorceur est muni
d'un condensateur (92) couplé au dispositif de commutation bilatérale et par l'intermédiaire
duquel le condensateur se décharge à la tension de claquage du dispositif de commutation
bilatérale.
4. Dispositif de circuit selon la revendication 3, dans lequel le dispositif de commutation
bilatérale est constitué par un thyristor diode bidirectionnel.