Information
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Patent Grant
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6674249
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Patent Number
6,674,249
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Date Filed
Wednesday, October 25, 200024 years ago
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Date Issued
Tuesday, January 6, 200420 years ago
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Inventors
-
Original Assignees
-
Examiners
Agents
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CPC
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US Classifications
Field of Search
US
- 315 58
- 315 61
- 315 62
- 315 49
- 315 66
- 315 205
- 315 209 R
- 315 289
- 315 290
- 315 DIG 5
- 315 247
- 315 92
- 315 276
- 315 287
- 315 291
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International Classifications
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Abstract
A circuit and method for running a metal halide arc discharge lamp from an AC power source. The circuit includes a rectifier for producing a DC voltage. The lamp is resistively ballasted by a current limiting filament connected in series with the lamp. The circuit includes a switch that closes during start up of the lamp so that the resistive filament is energized to provide immediate light prior to the lamp entering the normal run mode.
Description
BACKGROUND OF THE INVENTION
The present invention is directed to gaseous discharge lamps. More particularly, the invention is directed to resistively ballasted gaseous discharge lamp operating circuits and methods of operation.
A gaseous discharge lamp, e.g., a metal halide gaseous discharge lamp, may be characterized as having three modes of operation, i.e., an initial high voltage breakdown mode, a glow-to-arc transition mode, and a steady state run mode. The typical circuit operating the lamp provides about 2-4 kilovolts to achieve initial breakdown in the lamp and then sufficient “open circuit voltage” (OCV) to effect a glow-to-arc transition in the lamp and stabilize the lamp in a steady state run mode.
Metal halide gaseous discharge lamps are typically constructed to run from direct current (DC) in order to give more consistent light and color rendition. To operate such lamps from standard 120 volt alternating current (AC) power sources it is necessary to rectify the AC power source to supply direct current to the lamp. The lamps are typically designed to operate at a certain fixed voltage across the lamp terminals and are biased to operate at a specific wattage by controlling the current that passes through the lamp. Gaseous-discharge lamp circuits must include a means for limiting the current through the lamp.
Some conventional circuits use an ordinary resistor to limit the current through the lamp. Other circuits include an incandescent lamp filament to provide resistance. In such circuits, the resistance of the lamp filament increases as the current through the lamp increases, thereby opposing the increase in current through the lamp. As a result, the resistive lamp filament maintains the overall current through the lamp approximately constant. The characteristics of the current limiting filament lamp are selected to provide the proper operating current for the arc discharge lamp.
The basic lamp running circuit includes a DC arc discharge lamp connected in series with an incandescent filament lamp. The arc discharge lamp is powered by DC provided to the lamp by rectifying the standard 120 volt AC supplied to the circuit from the AC power source. In addition to meeting the specifications for running the lamp in the steady state run mode, the lamp operating circuit must also provide for the other two transient modes of operation (i.e. the initial high voltage breakdown mode and the glow-to-arc transition mode).
The voltage obtained by using a typical full-wave bridge-rectifier configuration and a capacitor or storage filter operating from 120 volt AC is sufficient to operate the lamp in the steady state run mode. However, the rectified voltage is less than the OCV required to effect a glow-to-arc transistion in the lamp. Therefore, the rectified voltage (i.e., the DC line voltage) must be temporarily boosted during lamp startup to effect the glow-to-arc transition. Once the lamp is in the run mode, the lamp develops a terminal voltage that is less than the DC line voltage. Thus a current limiting means, such as an incandescent lamp filament, is placed in series with the rectified power source and the gaseous discharge lamp to maintain the lamp in a steady state run mode at the terminal voltage of the lamp.
The OCV required to effect the glow-to-arc transition in the lamp may be provided by a voltage doubler. Conventional DC lamp operating circuits include voltage doublers to boost the voltage during the lamp starting process. However, in these operating circuits the voltage doubler remains in operation during the steady state run mode of the lamp resulting in wasted energy, i.e. excess energy must be dissipated in the filament lamp during the run mode. In addition, conventional voltage doublers are by necessity “half-wave” and, therefore, require a larger filter capacitor to eliminate the “ripple” effects which cause lamp flicker.
Many prior art lamp operating circuits include complex electronic circuits to control the lamp current. This type of electronic ballast provides greater efficiency than ballasts including a lamp filament as a current limiter. However, this type of electronic ballast typically includes several high-frequency magnetic components in the form of inductors, transformers and other ferrite-core devices. As a result, the electronic ballast is expensive and also generates electromagnetic interference requiring the use of filters to meet FCC standards.
A filament ballast is less complex and thus less expensive than an electronic ballast. A filament ballasted lighting unit may be produced for about ten percent of the cost of a comparable unit with an electronic ballast. The filament ballasted lamp produces negligible electromagnetic interference (EMI) during the run mode, and only a minimal amount of interference during lamp startup. As a result, there is no need to use EMI filters.
However, the economy of a filament ballasted lamp may be further improved by simplifying the circuit and making multiple use of components to improve the overall efficiency of the filament ballasted lamp circuit.
Accordingly, it is an object of the present invention to provide a novel and improved gaseous discharge lamp operating circuit and method.
It is another object of the present invention to provide a novel arc discharge lamp operating circuit and method including a current-limiting lamp filament.
It is still another object of the present invention to provide a novel arc discharge lamp operating circuit and method for doubling the voltage of the DC line voltage to effect an arc condition in the lamp.
It is yet another object of the present invention to provide novel arc discharge lamp operating circuits and methods for providing immediate light during startup of the lamp.
It is another object of the present invention to provide a novel arc discharge lamp operating circuit and method wherein an incandescent lamp filament is illuminated only during a half-cycle of the AC power source during startup of the arc lamp.
It is another object of the present invention to provide a novel arc discharge lamp operating circuit and method for doubling the DC line voltage of the circuit and isolating a rectifier bridge storage capacitor from the DC voltage applied to the lamp to establish an arc condition during lamp startup.
It is yet a further object of the present invention to provide a novel method of operating an arc discharge lamp circuit with a bridge rectifier and storage capacitor that includes isolating the storage capacitor from the voltage required to cause the lamp to pass through the glow-to-arc transition mode.
It is a further object of the present invention to provide a novel circuit and method for operating an arc discharge lamp powered by a three phase AC power source that eliminates the need for a storage capacitor.
It is still a further object of the present invention to provide a novel method of operating an arc discharge lamp by resistively ballasting the lamp during the steady state mode with an incandescent lamp filament which also illuminates during startup of the arc discharge lamp.
These and many other objects and advantages of the present invention will be readily apparent to one skilled in the art to which the invention pertains from a perusal of the claims, the appended drawings, and the following detailed description of the preferred embodiments.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a schematic circuit diagram of one embodiment of a resistively ballasted metal halide arc discharge lamp circuit according to the present invention.
FIG. 2
is a schematic circuit diagram of another embodiment of a resistively ballasted metal halide arc discharge lamp circuit.
FIG. 3
is a schematic circuit diagram of one embodiment a resistively ballasted metal halide arc discharge lamp circuit according to the present invention wherein the ballast resistor functions as the immediate light filament.
FIG. 4A
is a schematic circuit diagram of a prior art circuit showing a conventional voltage doubler connected to a resistively ballasted metal halide lamp.
FIG. 4B
is a schematic circuit diagram showing one embodiment of a voltage doubler for providing the OCV for a resistively ballasted metal halide lamp on the negative half-cycle.
FIG. 4C
is a schematic circuit diagram showing one embodiment of a voltage doubler for providing the OCV for a resistively ballasted metal halide lamp on the positive half-cycle.
FIG. 5
is a schematic circuit diagram of one embodiment of a resistively ballasted metal halide arc discharge lamp circuit according to the present invention wherein the ballast resistor functions as the immediate light filament.
FIG. 6
is a schematic circuit diagram of one embodiment of a resistively ballasted metal halide arc discharge lamp circuit according to the present invention including a packaged bridge rectifier and voltage doubler for the positive half-cycle.
FIG. 7
is a schematic circuit diagram of a resistively ballasted metal halide arc discharge lamp circuit according to the present invention connected to a three phase AC power supply.
FIG. 8
is a circuit diagram of the circuit shown in
FIG. 3
during the negative half cycle of the AC power supply prior to lamp startup.
FIG. 9
is a simplified circuit diagram of the circuit shown in
FIG. 3
during the positive half cycle of the AC power supply prior to lamp startup.
FIG. 10
is a simplified circuit diagram of the circuit shown in
FIG. 3
during the steady state run mode.
DESCRIPTION OF PREFERRED EMBODIMENTS
With reference to
FIG. 1
, the present invention is directed to a metal halide lamp operating circuit
10
including a resistive filament R
404
in series with a metal halide DC arc discharge lamp
500
operating from a full-wave bridge rectifier
100
with a capacitor filter C
101
. The circuit
10
may be powered by a nominal 120 volt 50-60 Hz. AC power source and may include a negative-side voltage doubler
110
A and a positive-side voltage doubler
110
B to provide the OCV required during startup of the lamp
500
.
The circuit
10
includes a conventional relaxation-type starter circuit
200
that may comprise a sidac Q
201
, capacitors C
201
, C
202
, charging resistor R
201
, and ferrite-core pulse transformer T
201
. The ferrite-core pulse transformer T
201
must accommodate the DC lamp run current that passes through it and also provide inductance and resistance that is sufficiently low so as not to impede impulse currents that flow during the starting process.
Once the lamp
500
is warmed up and operating in a stable arc mode, i.e. the steady state run mode, the voltage breakover device Q
201
(e.g. the sidac) in the relaxation starter circuit
200
assumes a non-conductive state and disconnects the components of the starter circuit
200
from the lamp circuit. As a result, the running lamp circuit comprises only the arc discharge lamp
500
and the series current limiting or ballast filament R
404
, thereby eliminating electromagnetic interference that results from ferrite core switching components.
FIG. 1
shows one embodiment of a ballast circuit according to the present invention. A bridge rectifier
100
comprises four diodes D
101
-D
104
which feed a capacitor storage element C
101
. A capacitor C
103
and diode D
106
form a low-energy boost (i.e. voltage doubler) circuit
110
A during the negative half-cycle and capacitor C
102
and diode D
105
form a low energy boost circuit
110
B during the positive half-cycle. The boost circuits
110
A,
110
B produce half-cycle voltage pulses thus providing the OCV required for starting the lamp
500
.
The resistor R
101
is a bleeder resistor for the storage discharge capacitor C
101
when the circuit is switched off or disconnected from the AC power source. The capacitor C
101
may retain charge for up to several weeks. The resistor R
101
enables the capacitor C
101
to discharge to a safe value within a short time after power is removed so that an unknowing user does not receive an electrical shock from the charges capacitor. Optimally, the resistor R
101
is sized with the capacitor C
101
to discharge the capacitor C
101
to less than 48 volts in a relatively short time, for example, about 15 seconds.
The filament R
304
illuminates during lamp startup to provide immediate light while an arc is established in the lamp
500
. The immediate light filament R
304
may also be energized during periods when power is available to the circuit
10
but the lamp
500
is extinguished, such as following lamp failure or during a “hot restart” following a brief power interruption.
Illumination of the immediate light filament R
304
is controlled by the immediate light control circuit
300
. A triac Q
301
is gated to provide current to the filament R
304
when the circuit
300
senses that the lamp
500
is not illuminated, i.e. no current is flowing through the lamp
500
. The diode D
302
, the resistors R
301
, R
302
, R
303
and sidac Q
302
operate to control the triac Q
301
. The capacitors C
302
and C
303
provide noise filtering. The capacitor C
301
provides a time delay so that current is provided to the filament R
304
for a period of time following the establishment of current through the lamp
500
thus providing auxiliary illumination until the lamp
500
is at full brightness.
Prior to establishing an arc in the lamp
500
, the full voltage appears across the terminals of the lamp
500
. The voltage feeds into the diode D
302
and the resistor R
303
causing the sidac Q
302
to become conductive. The capacitor C
301
charges causing a bias current to flow through the resistor R
302
to gate on the triac Q
301
. When the triac Q
301
is gated on, current flows through the filament R
304
thus illuminating the filament during both half-cycles of the AC power.
When an arc is established in the lamp
500
, the voltage across the lamp initially drops to approximately 20 volts causing the sidac Q
302
to become non-conductive. The capacitor C
301
discharges through the resistors R
302
and R
301
causing the triac Q
301
to become non-conductive thus preventing current from passing through the filament R
304
. Thus the filament R
304
is no longer illuminated. As the temperature of the lamp
500
rises, the voltage across the lamp rises to about a range of 75-90 volts, but remains below the breakover voltage of the sidac Q
302
. Thus the triac Q
301
remains non-conductive and the filament R
304
remains dark.
The lamp circuit
10
includes a relaxation-type starter circuit which produces the high voltage to initially break down the lamp
500
during lamp startup. The starter circuit
200
includes a capacitor C
201
with a first terminal tapped off a third terminal on the transformer T
201
. The second terminal of the capacitor C
201
is connected to a node D. A sidac Q
201
is connected at a first terminal to a node BF and at a second terminal thereof to the node D. A resistor R
201
is connected at a first terminal to the node D and at the second terminal thereof to a node C. A capacitor C
202
is connected at a first terminal to the node BF, and at the second terminal thereof to the node C. The capacitor C
202
acts as a filter to attenuate the EMI generated by the igniter circuit
200
.
During startup of the lamp
500
, the capacitor C
201
charges as current flows through the resistor R
201
. When the voltage across the capacitor C
201
exceeds the breakover voltage of the sidac Q
201
, the sidac switches from a non-conducting to conducting state, causing the capacitor C
201
to discharge through the tapped portion of the winding of transformer T
201
. The transformer winding from the node BF to the tap comprises the primary winding of an autotransformer configuration. The current discharge through the transformer winding generates a high voltage pulse across the winding of the transformer T
201
from the node BF to the node H. The capacitor C
202
forms a low-impedance path for the first terminal of the transformer T
201
relative to the node C, thereby causing the high voltage pulse to appear in its entirety at the first terminal of the lamp
500
relative to the circuit reference node C. The high voltage pulse causes the initial breakdown of the lamp
500
.
The transformer T
201
does not follow the conventional step-up ratio that applies to sinusoidal waveforms in the derivation of the conventional autotransformer. The transformer T
201
operates similar to a tapped inductor having an inductance “L”, wherein the voltage “V” developed across the inductor is equal to (L)di/dt, where di/dt is the rate of change of current. The rate of change of current depends upon the rate of build-up and collapse of the magnetic field produced by the discharge of the capacitor C
201
via the sidac Q
201
, which is limited by many factors including the internal resistance of the sidac Q
201
.
After the initial breakdown in the lamp
500
, the lamp
500
proceeds through the glow-to-arc transition stage to a steady state run mode. The voltage across the capacitor C
101
is equal to the peak of the line voltage, i.e. approximately 170 volts DC which is less than the OCV required to effect the glow-to-arc transition in the lamp
500
. However, the boost circuits
110
A,
110
B provide the additional voltage to attain the required OCV for the lamp to effect the transition.
In operation, the diode D
106
causes the capacitor C
103
to charge further negative by an additional 170 Volts and the diode D
105
causes the capacitor C
102
to charge further positive so that the voltage across the lamp
500
during a portion of each half-cycle is approximately 340 volts (i.e. high enough to effect glow-to-arc transition in the lamp). The capacitors C
102
and C
103
are sized to discharge sufficient stored energy into the lamp to initiate the arc. This discharge causes the terminal voltage of the lamp
500
to fall below the voltage across the capacitor C
101
and thus is instantly followed up by the larger current available from the capacitor C
101
, whereupon the voltage and current from the capacitor C
101
is sufficient to subsequently maintain the arc.
Once an arc is established and current flows through the lamp
500
, the run circuit for the lamp
500
includes the four rectifier diodes D
110
-D
104
. The run current flows from the positive terminal of the capacitor C
101
through the diode D
105
, the ballast filament R
404
, the starting transformer T
201
, and the lamp
500
. The run current continues through the boost diode D
106
to the negative terminal of capacitor C
101
. The run current is limited and held substantially constant by the resistance of the filament R
404
.
The boost voltage from only one of the boost circuits
110
A,
110
B is sufficient to meet the OCV required for the lamp
500
, thus either boost circuit
110
A or boost circuit
110
B may be removed from the operating circuit
10
and the circuit
10
will remain capable of starting and operating the lamp
500
.
FIG. 2
illustrates an embodiment of the circuit
10
wherein the boost circuit
110
B comprising the capacitor C
102
and the diode D
105
have been removed.
The size of the capacitor C
101
is determined by the size of the lamp
500
. For example, the lamp circuit
10
shown in
FIGS. 1 and 2
including the capacitor C
101
having a capacitance of approximately 220 uF may operate a lamp
500
of up to about 150 watts.
The filament R
404
may be a 120 volt AC incandescent lamp typically having a rated wattage at twice the rated wattage of the lamp
500
. Thus if the lamp
500
is rated at 150 watts, the filament R
404
may be the lamp filament of a 120 volt AC incandescent lamp rated at 300 watts.
In a lamp operating circuit
10
as shown in
FIGS. 1 and 2
operated from a 120 volt AC power source, the steady state DC voltage is around 170 volts DC. The lamp
500
may be designed to operate with a terminal voltage within a range as high as 75-90 volts or approximately one half of the steady state DC voltage. In the preferred embodiment of the present invention, the lamp
500
operates with a terminal voltage within the range of 65-75 volts.
FIG. 3
illustrates another embodiment of the present invention. In the operating circuit
20
, the filament R
404
provides both the ballasting resistance and illumination when power is available to the circuit
20
but an arc is not established in the lamp
500
. During startup of the lamp
500
, the filament R
404
provides illumination. However, continuous illumination of the filament R
404
during both half cycles would “steal” away voltage from the lamp
500
preventing an arc from being established in the lamp
500
during lamp startup. The SCR Q
501
fires only during the negative half cycle of the AC input line cycle, so that on the positive AC line cycle, the filament R
404
is bypassed so that voltage available from capacitor C
103
is provided to start the lamp
500
.
The illumination of the filament R
404
when power is available to the circuit
20
but an arc is not established in the lamp
500
is controlled by the immediate light control circuit
300
. The control circuit
300
includes a one-turn winding T
201
/B which is added to the transformer T
201
. With power available and no current passing through the lamp
500
, pulses trigger the SCR Q
501
so that current passing through diode D
102
illuminates filament R
404
during each negative half-cycle. The resistor R
302
limits the current drawn from the winding T
201
to prevent excessive current from being drawn which may dampen the discharge of the capacitor C
201
and reduce the high voltage pulse required for initial breakdown of the lamp
500
. When an arc is established in the lamp
500
, the SCR Q
501
is no longer pulsed and thus becomes non-conductive.
The circuit
20
illustrated in
FIG. 3
also includes a modified starting circuit connection. The bottom end of resistor R
201
and the capacitor C
202
are connected to the negative terminal of the storage capacitor C
101
as opposed to connecting to the higher negative voltage at the node C. Thus the voltage drop across the resistor R
201
is reduced thereby reducing the power dissipation in the resistor R
201
allowing the use of a less expensive component. The sidac Q
201
is reduced to 130 volts in order to trigger from the 170 volts available across C
101
. In order to develop the required breakdown voltage, the transformer T
201
in the circuit
20
must have more turns than the transformer T
201
in the circuit
10
shown in
FIGS. 1 and 2
. For example, the transformer T
201
which may be used with sidacs in the range of about 200 volts to about 240 volts includes approximately 80 turns, with a 4-turn primary winding. The transformer T
201
which may be used with sidacs of about 130 volts includes approximately 120 turns.
As shown in
FIG. 3
, the starting circuit
200
operates in cooperation with the immediate light control circuit
300
. In order for the immediate light control circuit
300
to be triggered during the negative half-cycle, the starter circuit
200
must be running even though the lamp
500
will not start because of power dissipation in the filament R
404
. The starting circuit
200
is connected across the main storage capacitor C
101
and thus may be run during both half-cycles of the AC voltage supply from the filtered DC power.
The present invention provides further economic advantages over the prior art by employing a voltage doubler circuit which includes only the components necessary to provide sufficient OCV for the lamp.
FIG. 4A
illustrates a typical voltage doubler circuit employed in prior art circuits. With reference to
FIG. 4A
, the negative half-cycle current I
1
flows through diode D
1
and charges the capacitor C
2
to the peak value of the AC line voltage. For a nominal 120 volt AC line, the peak value is determined by multiplying the 120 volt RMS value by 1.414, yielding approximately 170 volts DC. When the line goes positive (L
1
relative to L
2
), the voltage on the capacitor C
1
“rides up” or adds to the line voltage. This causes current I
2
to flow through diode D
2
charging the capacitor C
2
to a value of about two times the peak voltage. In this example, the capacitor charges to a value of about 340 volts DC. The voltage across capacitor C
2
is maintained by selecting a sufficient value for capacitor C
2
to produce a smooth output with low ripple.
When starting an arc discharge lamp, it is not necessary that the terminal voltage of the lamp be held constant, only that the terminal voltage exceed the OCV of the arc discharge lamp for a period of time sufficient to effect the glow-to-arc transition in the lamp. Therefore, the diode D
2
and the capacitor C
2
are not required in the voltage doubler circuit shown in
FIG. 4A
to effect arc discharge lamp startup.
FIGS. 4B and 4C
each illustrate an embodiment of a voltage doubler circuit according to the present invention. With reference to
FIG. 4B
, the voltage potential across the capacitor C
1
rises during the positive half-cycle of the AC line voltage resulting in a sinusoidal shaped half-wave with a maximum value of 340 volts. The typical arc discharge lamp operated from a 120 volts AC power source requires an OCV of about 215 volts to achieve glow-to-arc transition in the lamp. The transition may not occur within one half-cycle, but usually occurs after several successive half-cycles as a result of the repetition of the half-wave sinusoidal 340 volt pulse.
With reference to
FIG. 4C
, the voltage potential across the capacitor C
1
rises during the negative half-cycle of the AC line voltage resulting in a sinusoidal shaped half-wave with a maximum value of 340 volts. This voltage potential is sufficient to effect a glow-to-arc transition within the arc discharge lamp usually after several successive pulses.
FIG. 8
illustrates the operation of the circuit of
FIG. 3
during the negative half-cycle of the 120 volt AC power supply. With reference to
FIG. 8
, and using the terminal WH, or neutral terminal, as a reference, when the voltage at terminal BK, or main side terminal, swings negative the capacitor C
103
charges from the terminal WH through the diodes D
106
and D
103
back to the terminal BK so that the voltage at the node C follows the power line down to the maximum negative voltage of 170 volts. The capacitor C
103
charges to a negative 170 volts at the node C. The capacitor C
101
charges to positive 170 volts at the node BU. Thus a voltage potential of 340 volts appears across the series combination of the filament R
404
and the arc lamp
500
. During the negative half-cycle the SCR Q
501
is ON and the voltage at the node BF is negative 170 volts, so that the filament R
404
is illuminated with current flowing through the diode D
102
to provide immediate light during startup of the lamp
500
. The current drawn by the filament R
404
prevents the startup of the lamp
500
.
FIG. 9
illustrates the operation of the circuit of
FIG. 3
during the negative half-cycle of the 120 volt AC power supply. With reference to
FIG. 9
, an arc is established in the lamp
500
during the positive half-cycle of the 120 volt AC power supply due to the the voltage potential across the lamp
500
created by the negatively charged capacitor C
103
.
FIG. 10
illustrates the operation of the circuit of
FIG. 3
in the steady state run mode. When current flows through the lamp
500
, the igniter circuit
200
stops pulsing and the SCR Q
501
becomes non-conductive and is removed from the circuit. The full voltage across the storage capacitor C
101
remains available to the lamp
500
on a continuous basis, i.e. it is no longer interrupted at half-cycle intervals by current dissipation in the filament R
404
prior to current flowing through the lamp
500
.
FIG. 5
illustrates an alternative embodiment of the intermediate light control circuit
300
. The novel switching means used to illuminate the immediate light filament R
404
eliminates the need for the extra single-turn winding T
201
/B on the transformer T
201
as shown in FIG.
3
. During the negative half-cycle of the 120 volt AC power supply, a current path is established from the terminal WH through the diode D
102
, through the filament R
404
, through the sidac Q
301
, and through the diode D
301
to the terminal BK. A resistor R
301
is connected at one end to the junction of the sidac Q
301
and the diode D
301
, and at the other end to the junction of diode D
106
and the capacitor C
103
. During the negative half-cycle the voltage at the terminal BK becomes negative, the voltage across the sidac Q
301
exceeds its breakover voltage and the sidac Q
301
becomes conductive for the remainder of the half-cycle. Thus the filament R
404
is illuminated for the remainder of the half-cycle. The diode D
301
prevents current from flowing directly from the terminal BK through the lamp
500
during the positive half-cycle without passing through a current limiting means, i.e. the filament R
404
. A DC bias across the sidac Q
301
may be maintained by providing a current path from one end of the sidac Q
301
to the terminal WH through resistor R
301
. The other end of the sidac Q
301
is connected to the positive terminal BU through the filament R
404
. This arrangement ensures that the sidac Q
301
will trigger predictably, and allows Q
301
to trigger sooner in the negative half-cycle.
With further reference to the circuit of
FIG. 5
, the filament R
404
illuminates at an RMS line voltage of about 90 volts and above. The lamp
500
will start and operate at an RMS line voltage of about 105 volts and above.
FIG. 6
illustrates yet another embodiment of the present invention. With reference to
FIG. 6
, the second terminal of the resistor R
301
is connected to the negative terminal of the storage capacitor C
101
. Thus the voltage drop across the resistor R
301
is reduced and therefore the power dissipation across the resistor R
301
is reduced allowing the use of a less expensive component. In this embodiment, the filament R
404
illuminates at an RMS line voltage of about 100 volts and above.
For the alternative immediate light control circuits
300
shown in
FIGS. 5 and 6
, once current flows through the lamp
500
, a voltage drop occurs across the filament R
404
and the voltage at the node A drops below the breakover voltage of the sidac Q
301
. The resistor R
301
defines the voltage that appears across the sidac Q
301
to ensure that the breakover voltage of the sidac Q
301
is not exceeded so that the sidac Q
301
remains nonconductive while current is flowing through the lamp
500
.
FIG. 6
also illustrates that the individual diodes D
101
-D
104
may be replaced with a common bridge rectifier assembly shown as bridge assembly BR
101
. The capacitor C
202
provides a filter to attenuate the electromagnetic noise generated by the igniter circuit
200
. Similarly, the capacitor C
002
attenuates such noise and prevents the noise from interfering with the AC power line.
The circuit shown in
FIG. 6
does not require operation of the transformer T
201
during the negative half cycle to trigger the sidac Q
301
. Therefore, the igniter circuit
200
may employ a sidac Q
201
having a higher breakover voltage in the range of about 200 to 340 volts. This reduces the number of turns required on the transformer T
201
thereby reducing the cost.
The disclosed circuits provide for operation of a resistively ballasted DC arc lamp of a metal halide type from an AC power source having a peak rectified voltage below the OCV of the lamp. However, the present invention relates to the operation of all types of arc discharge lamps. Further, the various triggering methods described herein for the immediate light filament may also be used in other circuits operating DC arc lamps from higher AC power supply voltages and other AC frequencies including but not limited to 50 Hz to 400 Hz.
A resistively ballasted arc lamp may also be operated from a three-phase power line, as shown in
FIG. 7. A
three-phase, full-wave bridge rectifier configuration produces a ripple frequency six times the power line frequency. The waveform comprises three overlapping full-wave single-phase rectified waveforms offset by 120 degrees. The voltage remains greater than the voltage of the lamp and thus the storage capacitor C
101
may be eliminated. A three-phase power supply is typically available at a line voltage of 208 volts which eliminates the need for an OCV boost circuit.
FIG. 7
shows the basic circuit wherein the peak DC line voltage is about 265 volts DC for an input AC voltage of 208 volts AC. In such a circuit, a higher voltage sidac may be used with the advantage that the transformer T
201
may include fewer turns.
While preferred embodiments of the present invention have been described, it is to be understood that the embodiments described are illustrative only and the scope of the invention is to be defined solely by the appended claims when accorded a full range of equivalence, many variations and modifications naturally occurring to those of skill in the art from a perusal hereof.
Claims
- 1. A circuit comprising:an arc discharge lamp; an AC power source supplying an AC line voltage having a rectified peak voltage less than the voltage required to effect a glow-to-arc transition of the arc discharge lamp; a full wave bridge rectifier for rectifying the AC line voltage into a DC voltage; a voltage doubler for boosting the rectified voltage; a storage capacitor connected across the bridge and capable of sustaining the rectified line voltage; a current limiting filament connected in series with said lamp; a switch device connected in series with said current limiting filament and in parallel with said arc discharge lamp; a starter circuit that runs to break down said lamp; and a switch control circuit that closes said switch device when the starter circuit is running so that said filament is energized to provide immediate light prior to said lamp entering the normal run mode.
- 2. The circuit of claim 1 wherein said switch device comprises a triac.
- 3. The circuit of claim 1 wherein said switch device comprises an SCR.
- 4. The circuit of claim 1 wherein said switch control circuit includes a one-turn transformer.
- 5. The circuit of claim 1 wherein said switch control circuit closes said switch device for a predetermined time after an arc is established in said lamp to thereby provide a time delay between establishing an arc in said lamp and de-energizing the filament.
- 6. A circuit comprising:an arc discharge lamp; an AC power source supplying an AC line voltage having a rectified peak voltage less than the voltage required to effect a glow-to-arc transition of the arc discharge lamp; full wave bridge rectifier for rectifying the AC line voltage into a DC voltage; a storage capacitor connected across the bridge and being capable of sustaining the rectified line voltage; a current limiting incandescent lamp filament connected in series with said arc discharge lamp; and a voltage doubler circuit for boosting the DC voltage to a voltage sufficient to effect the glow-to-arc transition in said arc discharge lamp, said voltage doubler comprising a diode connected between said rectifier and said arc discharge lamp and a doubler capacitor connected between said AC power source and said arc discharge lamp, said voltage doubler circuit isolating said storage capacitor from the voltage applied to the lamp.
- 7. The circuit of claim 6 further comprising an immediate light incandescent lamp filament for providing illumination during startup of the arc discharge lamp.
- 8. The circuit of claim 7 wherein said immediate light incandescent lamp filament is connected in parallel with said arc discharge lamp across said power source.
- 9. The circuit of claim 6 wherein said current limiting incandescent lamp filament provides illumination during startup of said arc discharge lamp.
- 10. The circuit of claim 6 further comprising a switch device connected in series with said current limiting incandescent lamp filament, said switch operating to provide electrical current to said current limiting incandescent lamp filament during only the negative half-cycle of the AC line voltage when no current is flowing through said arc discharge lamp so that said filament provides illumination while establishing an arc in said arc discharge lamp.
- 11. The circuit of claim 10 wherein said switch device comprises an SCR.
- 12. A circuit comprising:an arc discharge lamp; an AC power source supplying an AC line voltage having a rectified peak voltage less than the voltage required to effect a glow-to-arc transition of the lamp; a full wave bridge rectifier for rectifying the AC line voltage into a DC line voltage; a storage capacitor connected across the bridge and being capable of sustaining the rectified DC line voltage; a current limiting incandescent lamp filament connected in series with said arc discharge lamp; an immediate light incandescent lamp filament connected in parallel with said arc discharge lamp across said power source; and a voltage doubler circuit comprising a diode connected between said rectifier and said arc discharge lamp and a capacitor connected between said AC power source and arc discharge said lamp.
- 13. In a circuit comprising an arc discharge lamp connected in series with a current-limiting filament across an AC power source supplying an AC line voltage to a rectifier that produces a DC line voltage less than the voltage required to establish an arc condition in said lamp, the improvement comprising:a voltage doubler circuit including a diode connected between said rectifier and said arc discharge lamp and a capacitor connected between said AC power source and said arc discharge lamp, said doubler circuit boosting said line voltage to thereby establish an arc condition in said lamp by effecting a glow-to-arc transition of said lamp.
- 14. The circuit of claim 13 further comprising a switch device connected in series with said current limiting filament across the AC power supply and connected in parallel with the arc discharge lamp, said switch device operating in conductive state during the negative half-cycle of the AC line voltage when no current is flowing through the arc discharge lamp to thereby effect illumination of said filament, said switch device operating in a non-conductive state during the positive half-cycle of the AC line voltage.
- 15. In a circuit comprising an arc discharge lamp connected in series with a current-limiting incandescent lamp filament across an AC power source supplying an AC line voltage, the improvement comprising:a switch device connected in series with said current limiting filament across the AC power supply and connected in parallel with the arc discharge lamp, said switch device operating in conductive state during the negative half-cycle of the AC line voltage when no current is flowing through the arc discharge lamp to thereby effect illumination of said filament, said switch device operating in a non-conductive state during the positive half-cycle of the AC line voltage.
- 16. The circuit of claim 15 wherein said switch device comprises a sidac.
- 17. The circuit of claim 15 wherein said switch device comprises an SCR.
- 18. A circuit comprising an arc discharge lamp connected in series with a current-limiting ballast powered by a three phase AC power source, the circuit comprising:a full wave bridge rectifier for rectifying the power source and supplying DC line voltage and current to power the lamp, the DC voltage being greater than the voltage required to establish an arc condition in said lamp and the DC current being sufficiently stable so that said circuit does not include a storage capacitor.
- 19. A method of operating an arc discharge lamp comprising the steps of:(a) providing an arc discharge lamp; (b) providing an AC power source that supplies an AC line voltage; (c) rectifying the AC line voltage using a bridge circuit to provide a DC line voltage less than the voltage required to effect a glow-to-arc transition in the arc discharge lamp; (d) illuminating an immediate light incandescent lamp filament when the AC line voltage is present and no current is flowing through the arc discharge lamp; (e) igniting the arc discharge lamp by applying a breakdown voltage to the lamp; (f) boosting the DC line voltage to effect the glow-to-arc transition in the arc discharge lamp by using a voltage doubler circuit comprising a capacitor connected between a termination of the AC power source and the arc discharge lamp and a diode connected between the arc discharge lamp and the bridge circuit; and (g) running the arc discharge lamp in the steady state mode from the unboosted DC line voltage.
- 20. In a method of operating an arc discharge lamp including the steps of providing a rectified DC line voltage less than the voltage required to effect glow-to-arc transition of the lamp; igniting the lamp by applying a breakdown voltage to the lamp; energizing an immediate light filament prior to running the lamp in a steady state mode; boosting the DC line voltage to cause the lamp to pas through the glow-to-arc transition mode; and running the lamp in a stead state mode, the improvement comprising the step of:isolating the storage capacitor from the boosted DC line voltage by providing a voltage boost circuit comprising a capacitor connected between a terminal of the power supply and the lamp and a diode connected between the lamp and the bridge circuit.
- 21. In a circuit comprising an arc discharge lamp connected in series with a current-limiting filament across an AC power source supplying an AC line voltage to a full wave bridge rectifier that produces a DC line voltage less than the voltage required to establish an arc condition in said lamp, the rectifier including a storage capacitor, the improvement comprising:a voltage doubler circuit operable to isolate said storage capacitor from the voltage applied to the lamp to establish an arc condition.
- 22. The circuit of claim 21 further comprising a switch device connected in series with said current limiting filament across the AC power supply and connected in parallel with the arc discharge lamp, said switch device operating in conductive state during the negative half-cycle of the AC line voltage when no current is flowing through the arc discharge lamp to thereby effect illumination of said filament, said switch device operating in a non-conductive state during the positive half-cycle of the AC line voltage.
US Referenced Citations (17)