The present invention relates to a lighting control apparatus for a discharge lamp such as Xenon lamp or the like, and to a lamp current supply method for the same.
In discharge lamps such as xenon lamps and the like, in each tube thereof, there are provided two electrodes consisting of an anode and a cathode; and after the lamp is turned on an arc discharge occurs between the electrodes when a breakdown takes place caused by an igniter or the like. Brightness of the lamp is proportional to a magnitude of a lamp current that results from the arc discharge, and a lamp voltage depends on a distance between the electrodes and a state of a gas in the discharge lamp.
On the other hand, in a discharge lamp lighting control apparatus, in order to keep the brightness of the discharge lamp constant, a constant-current control is performed over the lamp current. Further, in this control apparatus, a constant-power control is also performed through setting of a power limit value (limiter) so that an output power of a power supply portion may not exceed a rated value.
For example, in Patent Literature 1 which is a prior art, a constant-current control is performed at a lamp turn-on stage where the lamp voltage is low, and a constant-power control is performed when the lamp voltage rises up to a certain value to reach a rated power.
When the discharge lamp is turned on, the lamp voltage rises as the state of the gas in the lamp is unstable in an initial state, and then a rise change value of the lamp voltage decreases gradually. After that, as the state in the lamp stabilizes, the lamp voltage also stabilizes. At this stage, stable states of both the gas and the arc are maintained in the lamp. Nevertheless, a phenomenon such as fluctuation of an arc-path or the like is apt to arise; so that, a slight rise of the lamp voltage occurs accordingly. In a case where the lamp is brought under the constant-current control continuously from its initial lighting stage, if the rise value of the lamp voltage is large when the lamp voltage is somewhat high already, it follows that the output power of the power supply portion becomes large enough to exceed the rated value.
Thus, in the lighting control apparatus shown in the prior art, control mode is switched from the constant-current control mode to the constant-power control mode if the lamp voltage rises to reach the rated power after the discharge lamp is turned on.
In the constant-power control mode, since the output power of the power supply portion never exceeds the rated value, load to neither the lamp nor the power supply portion becomes excessive.
[Patent Literature 1]
JP 2005-32711 A
However, the conventional discharge lamp lighting control apparatus that performs both the constant-current control and the constant-power control as described above has problems as below.
In the constant-power control mode, if the lamp voltage rises due to changes of the state of the gas and/or the state of the arc in the lamp, a control circuit causes the lamp current to decrease so that the output power (lamp power) of the power supply portion may not exceed the power limit value (limiter value). At this time, since the lamp current decreases, the brightness of the lamp also changes accordingly. When the change occurs, whether periodically or non-periodically, it results in being sensed as so-called flicker phenomenon. For a while from the initial stage of the lamp lighting, because the lamp voltage changes drastically and periods of the flicker phenomenon are long, flickering is intense during this period of time. Therefore, in this period of time, the lamp is used after the lamp voltage stabilizes to some degree. Although the flicker phenomenon with very short periods occurs even when the lamp voltage stabilizes, such an occurrence does not cause a problem because it cannot be perceived by a human naked eye. However, when the flicker phenomenon with periods of a degree that can be sensed by a human naked eye occurs, it is perceived as flickering. This flickering can not only cause tired eyes, but also cause interference fringes when the lamp is used as a backlight for shooting.
The following is an explanation of the above-mentioned phenomenon that is made referring to
In
When such a phenomenon occurs every several 10 ms, which can be detected by a naked eye, since the lamp current fluctuates periodically, it follows that this is observed by a naked eye as the flicker phenomenon. Such a flicker phenomenon is often observed in an early stage of the stable state of the lamp voltage.
The present invention is directed to providing a discharge lamp lighting control apparatus capable of constant-current control even in a stable state of a lamp without increasing a rated output value of a power supply.
A discharge lamp lighting control apparatus of the present invention comprises:
The control circuit performs a control in such a manner as to be capable of constant-current control by decreasing the current command value when the discharge lamp reaches a stable state. This makes it possible to prevent the lamp current from decreasing when the lamp voltage rises in the stable state.
In a preferred embodiment, the control circuit performs a constant-power control by which an output power becomes a constant power when the output power exceeds a predetermined power limiter value, and outputs a power command value to perform the constant-power control to the inverter circuit.
In a more preferred embodiment of the present invention, the control circuit performs the following control in the order shown below until the lamp voltage stabilizes after the discharge lamp is turned on:
(1) performing the constant-current control using a predetermined first current command value in a first state after the discharge lamp is turned on.
(2) performing the constant-power control at a stage of becoming a second state in which the output power exceeds the power limiter value due to a rise of the lamp voltage after the first state.
(3) performing the constant-current control using a second current command value that is smaller than the first current command value when the output power exceeds the power limiter value due to a rise of the lamp voltage, at a stage of becoming a third state in which a rise change value of the lamp voltage becomes less than a certain value after the second state.
(4) performing the constant-current control in the third state by changing the second current command value to a smaller value every time the output power exceeds the power limiter value due to a rise of the lamp voltage.
(5) performing the constant-current control when a fourth state in which the lamp voltage stabilizes commences after the third state, using the second current command value having been changed right before then.
When the discharge lamp is turned on, the lamp voltage starts to rise, and the constant-current control is performed based on a predetermined first current command value that is set beforehand by the user (first state). Thereafter, when the output power reaches the power limiter value, the constant-power control is performed (second state). After that, during the constant-power control, a stable state of the lamp in which the rise change value of the lamp voltage is less than a certain value commences (third state). In an early stage of the stable state of the lamp, the current command value is changed from the first current command value having been used until then to the second current command value that is smaller by a predetermined value than the former when the output power exceeds the power limiter value as a result of a rise of the lamp voltage by ΔV due to the fluctuation of the arc current path as shown in
With the above-mentioned control, in the third state, the constant-current control is performed continuingly by making the second current command value smaller little by little depending on the rise of the lamp voltage. In the fourth state, as well, the constant-current control is performed. This means that from the third state onward the constant-current control is performed, unlike the constant-power control as in a conventional manner. Thus, even when the lamp voltage fluctuates due to arc shaking, there is no occurrence of the flickering phenomenon.
Moreover, since the current command value is decreased from the third state onward, there is no need to increase power capacity. Besides, since the power supplied to the lamp never becomes large, there is no risk of reducing the lamp service life.
In a furthermore preferred embodiment, in the third state, the control circuit carries out a change of the current command value gradually over a predetermined time.
By carrying out the change of the current command value gradually over a predetermined time, since such a command value change never becomes sudden, flicker generation is suppressed further.
Even after the discharge lamp comes in the stable state, since the constant-current control is maintained, flicker generation can be prevented. Further, since there is no need to increase power capacity, it is possible to prevent the enlargement of the power supply portion; and also, there is no risk of reducing the lamp service life.
The discharge lamp lighting control apparatus includes: a first rectification circuit 2 for rectifying an AC voltage inputted to a commercial power supply input terminal 1; a PFC circuit (power factor improvement circuit) 3 for improving a power factor by modifying a current waveform of a rectification output from the first rectification circuit 2; a PFC control circuit 4 for controlling the PFC circuit 3; a switching circuit 5; a transformer for performing a voltage conversion of an output from the switching circuit 5; a second rectification circuit 7 for rectifying a voltage-transformed output; a high voltage transformer 8 and a starting circuit 9 that superimpose a turn-on high voltage pulse onto a rectification output from the second rectification circuit 7; a lamp current detector 10 for detecting an output current (lamp current); and a main control circuit 11 for supplying a control PWM signal to the switching circuit 5 that performs a constant-current control and a constant-power control based on the lamp current and a lamp voltage. A discharge lamp 12 such as xenon lamp or the like is connected to an output side of the high voltage transformer 8.
The main control circuit 11 inputs a difference between a detected lamp current I and a current command value and a difference between a lamp power and a power command value to an error amplifier in a PWM generation circuit 110. The PWM generation circuit 110 performs a constant-current control so as to cause the difference between the lamp current I and the current command value to become zero. Further, the PWM generation circuit 110 performs a constant-power control that decreases the output current so as to cause the difference between the lamp power and the power command value to become zero when the lamp power is about to exceed a power limiter value, namely, the power command value.
In the constant-current control and in the constant-power control, the PWM control is performed in both controls. The main control circuit 11 includes a control portion 111 that performs a control shown in a flow chart described later. Further, instead of the main control circuit 111, the PWM control may be performed using the arithmetic processing and/or a conversion table for the lamp current and the lamp voltage.
In this embodiment, the constant-current control is performed using a first current command value after the discharge lamp 12 is turned on (first state), and is switched over to the constant-power control when the lamp voltage V rises and an output power that is calculated from the first current command value and the lamp voltage V exceeds a predetermined power limiter value, e.g. a rated power (second state). In the constant-power control, when a rise change value of the lamp voltage V decreases gradually to move into a stable state of the lamp in which the lamp voltage V stabilizes, fluctuation of the lamp voltage is monitored (third state). When the third state is moved in, in an early stage of the stable state of the lamp, there is a period of time in which the lamp voltage V increases slightly. In this period of time, when the lamp voltage rises and the output power exceeds the power limiter value, the current command value is changed from the first current command value to a second current command value that is smaller by a predetermined value than the former. Using this second current command value, the constant-current control is performed. Further, even after that, the second current command value is changed to a smaller value every time the output power exceeds the power limiter value as a result of the rise of the lamp voltage, and the constant-current control is performed using the changed second current command value.
After the third state, when a fourth state in which the lamp voltage completely stabilizes commences, the constant-current control is performed using the second current command value having been changed right before then.
This means that after the third state onward the constant-current control is performed using the second current command value having been set most recently.
Operations of the discharge lamp lighting apparatus according to this embodiment and the conventional discharge lamp lighting apparatus are explained, referring to
In
In the conventional discharge lamp lighting control apparatus, an operation proceeds as described below, as shown in
When the discharge lamp 12 is turned on at to, a constant-current control is performed using a first current command value that corresponds to a preset rated current (first state). From an initial stage of lighting A after the lamp is turned on with the preset rated current, the lamp voltage keeps on rising. At the time t1 when a constant-power limiter operates as the lamp voltage reaches a rated power Wlimit, the constant-current control is switched over to a constant-power control that uses a constant power command value.
From t1 onward, the constant-power control is performed. In other words, control is performed in such a manner that the lamp current is decreased depending on a rise of the lamp voltage (second state).
The constant-power control is maintained even when the state moves into the third state where the rise change value of the lamp voltage becomes less than a certain value at t2. The constant-power control is still maintained even when the state moves into the fourth state after t3 in which the lamp voltage completely stabilizes. The operation characteristic diagram of the above-mentioned control is as shown in
In the discharge lamp lighting control apparatus according to this embodiment, an operation proceeds as described below, as shown in
In
From t1 onward, the constant-power control is performed. As in the case of
From t0 to t2, the operation proceeds in the same manner as in the case of
At a stage of becoming a third state that is an early stage of the lamp stable state in which the rise change value of the lamp voltage becomes less than a certain value at t2, the first current command value is changed to the second current command value that is smaller than the former when the output power exceeds a predetermined power limiter value due to a rise of the lamp voltage. Using this second current command value, the constant-current control is performed. Further, the second current command value is changed to a smaller value every time the output power exceeds a predetermined power limiter value as a result of a rise of the lamp voltage, and the constant-current control is performed using the second current command value.
In
As shown in
Further, in the fourth state that comes after the third state, since the lamp voltage becomes a completely stable state, the constant-current control is performed using the second current command value having been changed right before t3. After t3, as well, since the constant-current control is performed, there is no flicker generation.
As stated above, in the discharge lamp lighting control apparatus according to this embodiment, during the period of time from t3 at which the rise change of the lamp voltage becomes slow to t4 onward where the lamp voltage stabilizes, the constant-current control is performed with the current command value being decreased depending on the rise of the lamp voltage so that the constant-power control may not be performed.
On this account, flicker generation can be prevented, as shown by the right part of
In the following, a concrete explanation of the above-mentioned control content is made, referring to
When the discharge lamp 12 is turned on, at ST1 of
At t2 when the third state commences in which the rise change value of the lamp voltage becomes less than a certain value (ST5), transition to the control operation of
At ST10, an initial value of the second current command value Iref2(n) is taken as the value of the first current command value Iref1. At ST11 when the output power exceeds the constant-power limiter Wlimit (Iref2(n)>Wlimit/Vdet(n)), that is, when the lamp voltage Vdet(n) rises, from ST12 onward, a control to change the second current command value Iref2(n) to a smaller value is performed. This correction is carried out at ST13 and ST14 taking a predetermined time. Namely, at ST13, the current value is calculated by dividing the constant-power limiter Wlimit value by the lamp voltage Vdet(n) at that time, and is used as the second current command value Iref2(n) to update. Then, at subsequent ST14, the second current command value is changed gradually from the previous second current command value Iref2(n−1) to the present second current command value Iref2 (n) (the second current command value Iref2 (n) that is obtained at ST12) for a time period of a correction cycle T2. Thereafter, at ST15, using the second current command value Iref2(n), the constant-current control is started.
The above-mentioned control operation is performed as long as the rise of the lamp voltage persists (for the period of time between t2 to t3).
By the way, as shown in
From the relationship above, the cycle, which is a time period of a correction cycle T2 for which at ST14 the second current command value is changed gradually from the previous second current command value Iref2(n−1) to the presently set second current command value Iref2 (n), is longer than the control cycle. For this reason, as shown by the solid line in the lamp current diagram of
In the control operation of Pattern 2, when the lamp voltage Vdet(n) is judged stable at ST16, the fourth state that is after t3 onward commences, and transition to the control operation after ST20 onward of
At ST20, the constant-current control is performed using the second current command value Iref2(n) having been updated last time in Pattern 2. Even if the lamp voltage rises due to the change of the state of the gas and/or the state of the arc in the lamp while the constant-current control is performed, there is no flicker generation because of the constant-current control that is in progress.
When the lamp power supply is turned off at ST21, the control finishes.
With the above-mentioned operations, even when the rise of the lamp voltage occurs in the stable state of the lamp voltage after t2 onward, the state of constant-current control can be maintained by decreasing the second current command value. Therefore, flicker can be prevented from occurring. Also, the constant-current control can be maintained in the state where the lamp voltage is stable without increasing the power supply capacity. Thus, enlargement of the power supply portion can be prevented, and since there is no chance that a power not less than a rated value is supplied to the discharge lamp, there is no risk of reducing the lamp service life.
In the above-mentioned embodiment, a detailed control is performed from the first state to the fourth state; however, the present invention is reducible to performing a constant-current control by changing a current command value to a smaller value in a stable state. Therefore, the present invention includes, for example, another embodiment in which only the control performed in the third state that is shown in the above-mentioned embodiment is performed.
Further, in the above-mentioned embodiment, as an example of the situation where the output power calculated from the first current command value and the lamp voltage V exceeds a predetermined power limiter value, it was shown that the output power exceeds the rated power. However, instead, a predetermined power limiter value may be a power specified by the user.
Moreover, although in
Number | Date | Country | Kind |
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JP2017-188612 | Sep 2017 | JP | national |
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PCT/JP2018/020918 | 5/31/2018 | WO | 00 |
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WO2019/064695 | 4/4/2019 | WO | A |
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