Solid-state hid lamp dimmer

Lighting control apparatus for controlling the light intensity of high-intensity-discharge (HID) lamps operated from an AC source while eliminating the tendency for such lamps to extinguish during the dimming thereof. The apparatus comprises a variable reactive ballast controlled with respect to its reactance by a solid-state switching device which is responsive to a timed control signal provided by a signal generating device operating from the same AC source. A lamp voltage sensing device develops a feedback signal which varies in accordance with the voltage drop across the lamps being ballasted. A signal sensing and overriding device combines the feedback signal and the timed controlled signal and causes the feedback signal to override the timed control signal before the lamp voltage reaches such value as might cause the lamp to extinguish. In this manner, when the lamp is dimmed and its voltage tends to rise, the voltage rise is automatically compensated for by an increase in power to the lamp which in turn decreases the voltage drop across the lamp so that the tendency of the lamp to extinguish during dimming thereof is eliminated.

CROSS-REFERENCES TO RELATED APPLICATIONS

In copending application Ser. No. 559,463, filed Mar. 18, 1975, by the same inventor and owned by the same assignee, is described a high-pressure-discharge lamp dimmer for two such lamps connected in series across a ballasting device which supplies twice the normal ballast output voltage and in which the dimmer is preferably current feedback stabilized. This series connected lamp combination allows a greater dimming range, since when the voltage is impressed after both lamps have been off for some fraction of a half-cycle, the voltage tends to appear primarily across one of the lamps, starting that lamp. The voltage across the lamp which has started then quickly drops and the available voltage then predominantly appears across the other lamp, starting it as well. This action provides reliable operation at relatively low power levels where the lamps are intended to be off for a significant portion of each half cycle.

In copending application Ser. No. 558,109, filed Mar. 13, 1975, by J. C. Engel and owned by the same assignee, is described a dimmer for high-pressure-discharge lamps using a variable duty cycle photocoupler. The circuit described in this copending application provides isolation of the low voltage demand circuitry from the higher voltage lamp circuitry by means of an LED and a photosensitive resistor and avoids the non-linearity problems normally associated with such photocouplers by using an ON/OFF duty cycle rather than proportional signals.

BACKGROUND OF THE INVENTION

This invention relates to lighting systems which control the level of illumination of one or more lamps, such as in a stage lighting system or in other lighting applications where varying intensities of lighting are desired. In particular, this present invention relates to controlling the intensity of light from high-pressure-discharge lamps, rather than incandescent or low-pressure-discharge lamps such as those of the tubular fluorescent type.

If high-pressure-discharge lamps are used with a dimmer which is not specifically designed for such lamps, the performance is generally unsatisfactory. Solid-state dimmers generally control the portions of each half cycle during which voltage from an AC voltage source is supplied to the lamp load. High-pressure-discharge lamps can extinguish when the voltage remains off for a significant portion of a half cycle and the normal ballasting which is used typically will not reestablish the arc once it is extinguished. Several prior art systems have minimized this problem by the use of a ballast which has two portions, such that the series inductance can be changed by means of a solid-state switch, typically a switch of the so-called triac design. This can be accomplished with a parallel reactor portion and a solid-state switch in series with one of the reactor portions to disconnect it for a portion of each half cycle. This can also be accomplished with two reactor portions in series and a solid-state switch which shorts out one of the reactor portions for a part of each half cycle. U.S. Pat. No. 3,816,794 issued June 11, 1974 to Snyder is one example of such a system.

Because of the difficulties of control, typically only one or two discharge lamps are operated from a single dimmer. This leads to a relatively expensive dimming system because of the number of dimmers involved and also because of the expense of running conduits both for power and for low voltage control wiring to each fixture. In addition, problems generally have been encountered in obtaining a wide range of light intensities from discharge lamps. At the lower intensity end, the lamps are somewhat hard to control and tend to drop out, i.e. extinguish, and once having dropped out, the lamps are difficult to restart and generally require several minutes to cool prior to restarting. At the higher intensity end, difficulties are often encountered due to the trigger pulse to the solid-state switch arriving prematurely, i.e., before current reversal. Because the circuit is inductive, the current is lagging and premature trigger pulses will be ineffective. This results in no power being supplied during that particular half cycle with the result that either the lamp will blink or more probably will drop out and cannot be restarted until the lamp has cooled.

SUMMARY OF THE INVENTION

There is provided a lighting control apparatus which is responsive to a variable and controllable demand signal to control the power input to high-pressure-discharge lamp devices and thus vary the light output therefrom while preventing the lamp devices from extinguishing because of a too-rapid reduction in power input thereto. The apparatus comprises a ballasting means which is connectable in series with the ballasted lamps and an AC power source. The ballasting means comprises a reactance which is variable between a minimum value which causes the lamp to operate at a maximum light output and a maximum reactance value which causes the lamp to operate with a minimum light output. A solid-state switching device connects to the ballasting device to controllably vary the reactance of the ballasting device in response to a timed control signal which varies in a controllable fashion the power input to the lamps and thus varies the light output therefrom. A signal generating device is responsive to the demand signal to generate a control signal timed to occur at a variable and controllable point in each half cycle of the AC power source and the output of the signal generating device is connected to the input of the solid-state switching device. In this fashion the generated timed control signal renders the solid-state switching device conductive for a variable and controllable portion of each half cycle of the AC power source. In order to prevent lamp drop out during dimming, a lamp voltage sensing device develops a feedback signal which varies in accordance with the voltage drop across the lamp and it has been found that when the lamp is dimmed, its voltage tends to rise. When the voltage rises to a value greater than the input voltage available, the lamp drops out. To overcome this tendency, there is provided a signal sensing and overriding device which senses the magnitude of the feedback signal and causes the feedback signal to override the control signal during such time that the voltage drop across the operating lamp is excessive. Since the feedback signal overrides the control, the power input to the operating lamp is increased which causes the voltage drop across the lamp again to decrease. Thus the rate of lamp dimming is controlled so that the voltage rise across the lamp which is encountered during dimming is never sufficiently great that the lamp will be extinguished.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the invention, reference may be had to the preferred embodiments, exemplary of the invention, shown in the accompanying drawings, in which:

FIG. 1 is a block diagram illustrating the basic relationships of the circuit components, including the lamp voltage sensing device;

FIG. 2 is a block diagram of the preferred lamp ballast embodiment wherein the ballast reactor includes two portions, one of which is adapted to be bypassed by the actuated solid-state switch;

FIG. 3 is a block diagram of the preferred embodiment illustrating the use of a master-slave arrangement with a single line voltage control signal;

FIG. 4 is a schematic diagram showing a preferred embodiment of a master controller device for generating a master control signal; and

FIG. 5 is a schematic diagram of a preferred embodiment of a slave circuit, one or many of which can be used with the single master controller device as shown in FIG. 4.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

In FIG. 1 there is shown in block diagram the lighting control apparatus for providing a variable light intensity for HID lamps, such as high-pressure mercury-vapor lamps, while simultaneously preventing lamp drop out due to a rapid reduction of power to accomplish lamp dimming. The entire lighting control apparatus and the lamps being ballasted are all operated from a single AC supply which as an example can be 480 volts, 60 cycle. The initial control of lighting level is accomplished by a manually operated rheostat, for example, which operates with a control signal generator which produces a control signal timed to occur at a variable and controllable point in each half cycle of the AC power source. The control signal generator has its output fed into a signal override device and the output of a lamp voltage sensing device is also fed into the signal override device. As described hereinbefore, when a discharge lamp is dimmed, its voltage tends to rise and this rise in voltage is converted into a signal which will override the generated control signal if the lamp voltage appreciably exceeds its normal operating voltage. This in turn increases the power to the lamp which decreases the lamp voltage to prevent its extinguishing. The output of the signal override device controls the solid-state switch which in turn controls the variable reactance of the lamp ballast in order to control the power consumed by the discharge lamp load.

In the embodiment as shown in FIG. 1, the lamp ballast preferably comprises an inductive reactor of variable inductance. In its preferred form, the reactor comprises two portions which may be connected in parallel or in series and the individual reactor portions can be physically connected together or separated. If two reactor portions are provided, the ability to effectively remove one of the portions for a part of a half cycle provides a very efficient manner for controlling the power to the lamp.

If the two reactor portions are in parallel, a relatively low current from one of the reactor portions is supplied during the first portion of the half cycle with the solid-state switch acting to block the current through the other portion. For the remainder of the half cycle, a higher current is supplied through both reactor portions with the solid-state switch conducting.

If the reactor portions are placed in series, a low current which is limited by the sum of the inductances is supplied for the first portion of the half cycle and a higher current which is limited only by one inductance is supplied for the remainder of the half cycle when the solid-state switch conducts and bypasses the second reactor portion. Other arrangements which effectively change inductance from the high impedance to a low impedance for a portion of the half cycle can also be used.

Considering further the block diagram as shown in FIG. 1, the lamp voltage sensing device, which senses excessive voltage and increases the power to the lamp, is different from the normal feedback signal which normally is used to decrease the power to the load to offset a rise in voltage. In the case of HID lamps, however, by increasing the power to the lamp load, the voltage thereacross is decreased which in turn prevents lamp drop out due to a too-rapid reduction in power input to the load. The actual reduction in lamp load or in intensity of the lighting is quite slow and with such a slow reduction, a decrease in power of from 100% to about 5% is possible and this normally will require several minutes. It should be noted that it is generally impractical to manually reduce the power consumed by the lamp steadily over a period of several minutes and such a manual power reduction will normally result in lamp drop out at some point in the dimming operation.

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In FIG. 2 is illustrated the preferred ballasting arrangement, in block diagram, wherein two separate reactor portions are connected in series and the solid-state switch bypasses the second reactor portion when the switch is actuated. This arrangement is convenient in that a commercially available ballast can be used for both reactor portions. For a 400 watt mercury lamp, for example, a 100 watt lamp ballast can be used for the second reactor portion. When this second reactor portion is not shorted out by the solid-state switch, the current to the discharge lamp load is limited to a low level; for example, at steady state with both reactor portions in the circuit at all times, the discharge lamp is limited to about 5% of its maximum light output. A 400 watt lamp ballast is used with a 400 watt mercury lamp for the first reactor portion. When the solid-state switching device is conducting continuously, the second reactor portion is completely out of the circuit and the discharge lamps operate at full intensity. Thus by varying the portion of the half cycle for which the solid-state switch is conductive, lamp intensities of from 5% of maximum to 100% output can be provided.

In FIG. 3 is shown a block diagram of a preferred embodiment illustrating the use of a master-slave arrangement wherein a single master device which generates a timed control signal can be used to actuate a plurality of slave arrangement. Each slave arrangement constitutes an individual lamp and its associated ballast, together with the individual signal override device and solid-state switch so that each lamp is carefully controlled on an individual basis. It is important that the master controller device and the slave systems all operate from the same AC power source since the phase must be maintained the same.

In FIG. 4 there is shown the circuit diagram for the preferred embodiment of a master signal generator wherein the line voltage is supplied across transformer T1 with the output therefrom being rectified through the diode rectifier D1-D4. The resistors R3 and R14 function to sense the zero line voltage and the transistors Q1 and Q2 function as zero reset transistors, in order to reset each half cycle every time the line voltage passes through zero. The capacitor C.sub.1 is charged to a variable ramp voltage depending upon the magnitude of the demand signal input and this causes the programmed unijunction transistor (PUT) to fire at varying times to generate a pulse in the pulse transformer T4. This in turn gates the triac S2 with the output thereof serving to gate the triac S3 to generate a line control signal voltage which energizes the slave units. A large number of different slave units, as many as several hundred if desired, can be operated from the single master control and once the triac S3 is triggered, there will be generated a continuous signal for the duration of the remainder of the half cycle.

The Zener diode Z1 regulates the voltage across C2 and the Zener diodes Z2 and Z3 minimize the voltage requirements for triac S2. By varying the potentiometer RV2, the magnitude of the demand signal is changed in order to vary the time during the half cycle in which the line voltage control signal is generated. The circuit of the master controller is quite similar to those which are conventionally used in conjunction with incandescent lamp dimmers.

The following Table I lists the master controller component values for a 480 volt installation.

                  TABLE I
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    ITEM              DESCRIPTION
    ______________________________________
    R1                75K, 2W, 5 %
    R2                75K, 2W, 5 %
    R3                33K, 1/2W, 5 %
    R4                33K, 1/2W, 5 %
    R5                33K, 1/2W, 5 %
    R6                33K, 1/2W, 5 %
    R7                33K, 1/2W, 5 %
    R8                33K, 1/2W, 5 %
    R9                33K, 1/2W, 5 %
    R10               33K, 2W, 5 %
    R11               33K, 2W, 5 %
    R12               100r, 1/2W, 5 %
    R13               270r, 1/2W, 5 %
    R14               33K, 1/2W, 5 %
    D1                1N645A
    D2                1N645A
    D3                1N645A
    D4                1N645A
    D5                1N645A
    D6                1N645A
    D7                1N645A
    D8                1N645A
    Q1                2N4123
    Q2                2N4123
    Q3                2N4126
    PUT               2N6027
    C1                .15/50V
    C2                125MFD/50V
    Z1                1N9708
    Z2                1N4756
    Z3                1N4756
    S2                T2300A(40525)
    S3                T6410N(40926)
    T1                P8394
    T2                P8394(117V/12(2))
    T3                11Z2000
    RV1               100K POT
                      PCBO, 1001C93
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                  TABLE II
    ______________________________________
    ITEM              DESCRIPTION
    ______________________________________
    R21               150K, 2W, 5 %
    R22               47, 1/2W, 5 %
    R23               2.7 MEG, 1/2W, 5 %
    R24               1.0 MEG, 1/2W, 5 %
    R25               270, 1/2W, 5 %
    R26               10K, 1/2W, 5 %
    R27               33K, 2W, 5 %
    R28               1.5K, 1W, 5 %
    R29               100, 1/2W, 5 %
    R30               33K, 2W, 5 %
    D21               1N645A
    D22               1N645A
    Z21               1N4756
    Z22               1N4756
    Z23               1N4756
    Z24               1N4756
    Q21               2N1711
    Q22               2N2905A
    S21               1N5761A
    S22               T2300A
    S23               T6410N(40926)
    C22               .047/50V
    C23               .1/1000V
    T21               P8394
                      PC8D, 1001C92
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