JP3567995B2 - Lighting brightness control device - Google Patents

Description

[0001]
[Industrial applications]
The present invention relates to an illuminating lamp for controlling variation in luminance due to a difference in use time of an illuminating lamp such as a metal halide lamp used in a commercial display device, such as an overhead projector in a bowling alley. And a brightness control device.
[0002]
[Prior art]
Conventionally, in bowling alleys and the like, a large-screen overhead projector has been installed for each lane, and data indicating the results of the competition and the like are displayed on this display screen. It is configured. Illumination lamps such as metal halide lamps used for the display screen of this overhead projector have a large luminance at the start of use, as shown in FIG. Thereafter, the brightness decreases, becomes almost constant in a steady state after a certain period of time, and rapidly decreases as the life time approaches. As described above, the brightness, that is, the brightness differs and varies depending on the difference in the use start time.
[0003]
As shown in FIG. 5, the voltage current from the AC power supply 1 is converted into a DC voltage current by the rectifier circuit 2 and applied to the voltage adjustment circuit 3. Part of the output of the voltage adjustment circuit 3 is input to the AC conversion circuit 4.
In the AC conversion circuit 4, the frequency of the AC power supply 1 is converted to a predetermined frequency, and the power converted to the predetermined frequency is applied to the illuminating lamp 5 as driving power and driven. On the other hand, the brightness of the illumination lamp fluctuates due to a change in the supplied power.
[0004]
Therefore, in order to make the brightness of the illumination lamp 5 constant, the output of the voltage adjustment circuit 3 is feedback-controlled via a power measurement circuit 6 controlled by a power regulator 7. As described above, since constant power is always applied to the AC conversion circuit 4, the illumination lamp 5 is configured to be driven with constant drive power.
[0005]
[Problems to be solved by the invention]
However, in general, as shown in FIG. 2, the illumination lamp 5 such as a metal halide lamp, during the time t _T from the initial state brightness at the start of use t ₀ to the steady state brightness after a certain period of time, becomes The brightness suddenly decreases, and then gradually decreases.
As described above, the luminance of the illumination lamp 5 increases in the early stage of use. The reason is that a metal and a gas are generally sealed inside the lamp 5, and when the lamp 5 is turned on, the metal inside is heated and evaporated, and after a certain time, this metal is vaporized. Adheres to the surface of the glass to reduce the brightness, and the brightness becomes a steady state. The other cause is considered to be that the luminous efficiency is deteriorated due to oxidation of the electrode portion.
[0006]
As described above, since the brightness of the illumination lamps 5 differs depending on the time of replacement, the brightness of the display screens arranged in large numbers on the same plane varies, and there is a problem that it is difficult to see. In addition, the low-intensity lamp 5 appears to have deteriorated. In particular, since the luminance at the start of use is higher than the luminance in the steady state, there is a problem that the illumination lamp 5 in the normal normal state appears to have deteriorated in any way.
[0007]
[Means for solving the problem]
The present invention relates to an illumination lamp luminance control device that controls the luminance of an illumination lamp by using an illumination lamp driven by a predetermined driving power via a voltage adjustment circuit and a power measurement circuit that feedback-controls the output of the voltage adjustment circuit. A microcomputer having a memory for storing a standard luminance decay time characteristic of a lighting lamp and a timer function; a D / A converter for converting an output corresponding to luminance read from the memory into an analog luminance signal; A power measuring circuit is provided with a compensating circuit including a current-to-resistance conversion element for converting a luminance signal into a current and converting the current fluctuation into a resistance fluctuation. until time t _T in which the luminance becomes the same in the steady state, to control the driving power of the lamp, until the time t _T in which the luminance of the lamp is in a steady state, Ma under the control of the timer A code signal corresponding to the luminance is output from the CPU of the computer, and the code signal is D / A converted and applied to the current-to-resistance conversion element. Is controlled .
[0008]
The present invention relates to an illumination lamp luminance control device that controls the luminance of an illumination lamp by using an illumination lamp driven by a predetermined driving power via a voltage adjustment circuit and a power measurement circuit that feedback-controls the output of the voltage adjustment circuit. The compensation circuit provided in the power measurement circuit stores a standard luminance decay time characteristic of the lamp, a maximum luminance level, a minimum luminance level, and a threshold level serving as a reference luminance in a memory, and has a micro computer having a timer function. , A D / A converter, a current-to-resistance conversion element, a photodetector for detecting the light of the lamp and performing photoelectric conversion, and converting the luminance signal of the lamp from the photodetector into a digital luminance signal. And an A / D converter for conversion. A digital luminance signal from the A / D converter is input to a microcomputer, and a threshold level stored in a memory is input to the microcomputer. And the result of comparison by the CPU are output as a code signal, and this code output is converted into an analog luminance signal by a D / A converter and applied to a current-resistance conversion element to switch the illumination lamp to a threshold level. This is to maintain the reference luminance.
[0009]
[Action]
When the illumination lamp 5 is replaced, the CPU 13, is controlled by the clock signal from the timer 12, the time t _1, t ₂ ···, U corresponds to the time t _T of the steady state - de signal digital It is output as a luminance signal. This code output is converted by the D / A converter 17 into an analog luminance signal corresponding to each time, and is input to the primary side of the current-resistance conversion element 19. The value is converted into a value, and the current flowing through the power measurement circuit 6 is controlled.
[0010]
Accordingly, the voltage that is fed back to the voltage adjustment circuit 3 is reduced, and the result is transmitted to the AC conversion circuit 4 via the voltage adjustment circuit 3, so that the driving power of the illumination lamp 5 is reduced and this power is reduced. 5 is applied, the brightness is reduced.
[0011]
First Embodiment of the Invention
A first embodiment of the present invention will be described in detail with reference to FIGS.
FIG. 1 is a configuration diagram showing a first embodiment of the present invention, and FIG. 2 is a standard luminance decay time characteristic diagram showing a relationship between the luminance of the illumination lamp 5 and a use time t. The same components as those in the conventional example are denoted by the same names and numbers, and description thereof is omitted.
In FIG. 1, in this embodiment, a metal halide lamp is used as the illuminating lamp 5, and the output of the voltage adjusting circuit 3 is converted into a frequency of about 250 to 280 Hz in the AC conversion circuit 4, and the power is used as driving power. It is configured to be applied to the illumination lamp 5.
[0012]
Reference numeral 10 denotes a compensation circuit having a built-in microcomputer 11 having a timer function. The compensation circuit 10 controls the luminance of the illumination lamp 5 at an early stage of use. As shown in FIG. It has a CPU 13, a memory 14, and an input / output board (hereinafter referred to as an I / O board) 15. In the memory 14, the standard luminance decay time characteristic of the illumination lamp 5 is coded and stored.
[0013]
Reference numeral 16 denotes an input / output device (hereinafter, referred to as an I / O device), and 17 denotes a D / A converter. A digital luminance signal from the microcomputer 11 is converted into an analog luminance signal via the I / O device 16. You. Reference numeral 18 denotes a transistor, and 19 denotes a current-resistance conversion element whose resistance value on the secondary side fluctuates due to current flowing on the primary side, such as a bidirectional linear output photocoupler.
[0014]
Microcomputer - motor 11 is controlled by a timer 12, as shown in FIG. 2, the co at time t ₀ - de A, Koh at time t ₁ - De B, when the time t ₂ co - D co when de C time t ₃ - de ... is, I / O board - and output through the leads 15, following this way T co is at time t _T of the steady state - de Is stored in the memory 14 so as to output.
[0015]
In the current-resistance conversion element 19, an element having a substantially proportional relationship between the current flowing on the primary side and the resistance value on the secondary side is used. When the current on the primary side increases, the resistance value on the secondary side increases. , The current flowing through the power measuring circuit 6 becomes small, and the feedback voltage to the voltage adjusting circuit 3 becomes small.
[0016]
Next, the operation will be described.
The brightness of the illumination lamp 5 varies depending on the driving power. Therefore, the voltage current from the AC power supply 1 is converted into a DC voltage current by the rectifier circuit 2 and applied to the voltage adjustment circuit 3 so that a constant luminance is obtained. A part of the output of the voltage adjusting circuit 3 is fed back through the power measuring circuit 6 controlled by the compensating circuit 10 to control the driving power of the illuminating lamp 5 applied to the AC converting circuit 4, The illumination lamp 5 is configured to have a constant luminance.
[0017]
Now, when the illumination lamp 5 is replaced with a new one, as shown in FIG. 2, the brightness becomes large during the time t _T from the start of use t ₀ to the steady state.
Therefore, first, when the illumination lamp 5 is replaced, a clock signal of the time t ₀ , t ₁ , t ₂ , t _3, ... Is input from the timer 12 to the CPU 13, and the CPU 13 controls the clock signal. has been, a co when the time t ₀ - de, the B co at time t ₁ - de, C co at time t ₂ - de, D co when the time t ₃ - de ..., steady At the time t _T when the state is reached, the T code is output together with the clock signal from the I / O device 16 via the I / O board 15 as a digital luminance signal.
[0018]
In this way, the code outputs sequentially output from the microcomputer 11 are converted by the D / A converter 17 into analog luminance signals corresponding to respective times.
When each analog luminance signal from the D / A converter 17 is input to the base of the transistor 18, the transistor 18 is driven and a current flows from the collector to the emitter. To the primary side of.
[0019]
The emitter current input to the primary side of the current-resistance conversion element 19 is converted into a resistance value corresponding to the current value, and the current flowing through the power measurement circuit 6 is controlled by the resistance value.
That is, when the luminance of the illumination lamp 5 is large, the current on the primary side of the current-resistance conversion element 19 is large, so that the resistance value on the secondary side is large and the current of the power measuring circuit 6 is small. .
[0020]
Therefore, the voltage that is fed back to the voltage adjustment circuit 3 is reduced, and the result is transmitted to the AC conversion circuit 4 via the voltage adjustment circuit 3 and the driving power applied to the illumination lamp 5 is reduced. Drops.
In this way, the driving power of the illumination lamp 5 is reduced until the time t _T when the luminance of the illumination lamp 5 reaches a steady state, and the luminance is reduced.
[0021]
[Example 2 of the invention]
A second embodiment of the present invention will be described in detail with reference to FIGS.
FIG. 3 is a configuration diagram showing a second embodiment of the present invention, and FIG. 4 is a standard luminance decay time characteristic diagram showing the relationship between the luminance of the illumination lamp 5 and the use time t.
[0022]
In FIG. 3, in this embodiment, a metal halide lamp is used as the illuminating lamp 5 as in the first embodiment, and the output of the voltage adjusting circuit 3 is supplied to the AC converting circuit 4 at a frequency of about 250 to 280 Hz. Is configured to be applied to the illumination lamp 5.
[0023]
Numeral 10 denotes a compensation circuit for controlling the driving power applied to the illumination lamp 5 so as to be always constant, so as to maintain the luminance of the illumination lamp 5 constant. The luminance setting switches S ₁ , S ₂ , S ₃ and microcomputer 11, I / O device 16, D / A converter 17, transistor 18, current-resistance converter 19, photodetector 20, amplifier 21, A / D converter 22 It consists of.
[0024]
The memory 14, as shown in FIG. 4, and the standard luminance decay over time characteristic diagram, a constant reference brightness set by the switch S ₁ Suresho - Rudoreberu x _S, the lamp 5 is set on the switch S ₂ highest luminance level x _H in the initial condition of the start t _0, is set and the minimum value luminance level x _L which is set by the switch S ₃ is co - are de reduction has been stored. CPU 13 is input clock signal from the timer 12 as a control for, in CPU 13, co corresponding to time _{t 1, t 2, t 3} ··· by the clock signal - is programmed to de-outputs .
[0025]
Reference numeral 20 denotes a photodetector, which detects the light of the illuminating lamp 5, performs photoelectric conversion, and outputs the electric signal. Reference numeral 21 denotes an amplifier, 22 denotes an A / D converter, and an optical signal detected by the photodetector 20 is converted into a digital luminance signal and input to the I / O board 15 via the I / O device 16. Stored in the memory 14.
[0026]
Next, the operation will be described.
When replaced with a new illumination lamp 5, as shown in FIG. 2, the time t _T from start of use time t ₀ until a steady state, the brightness is large.
Therefore, first, when the illumination lamp 5 is replaced, a clock signal at times t ₁ , t ₂ , t _3, ...
[0027]
On the other hand, the light from the illuminating lamp 5 is detected by the photodetector 20, photoelectrically converted, amplified by the amplifier 21, and then converted by the A / D converter 22 into a digital luminance signal corresponding to each optical signal. , From the I / O device 16 to the I / O board 15 and stored in the memory 14.
[0028]
The luminance signal at each time t ₁ , t _2, ... Of the illuminating lamp 5 stored in the memory 14 is read out by the CPU 13, controlled by the clock signal from the timer 12, and compared with the threshold level x _S. The code output of the difference is output from the I / O board 15 via the I / O device 16.
[0029]
Thus, sequentially outputted by Suresho from CPU 13 - Rudoreberu x _S and the compared co - de output is converted into an analog luminance signal by respective D / A converter 17.
Each analog luminance signal from the D / A converter 17 is input to the base of a transistor 18 as in the first embodiment, and the transistor 18 is driven to cause a current to flow from the collector to the emitter. The output is input to the primary side of the current-resistance conversion element 19.
[0030]
The emitter current input to the primary side of the current-resistance conversion element 19 is converted into a resistance value corresponding to the current value, and the current flowing through the power measurement circuit 6 is controlled by the resistance value.
That is, the power applied to the lamp 5, Suresho - Rudoreberu x _S such that the corresponding reference luminance, current - current in the primary side of the resistive conversion element 19 is controlled, it as the secondary side of the resistance Fluctuates, and the current of the power measurement circuit 6 is controlled.
[0031]
Thus, applied to the illuminating lamp 5 via alternating current circuit 4 a voltage fed back to the voltage regulator circuit 3 is controlled, the driving power Suresho - Rudoreberu x _S to be the driving power of the corresponding reference luminance , And its brightness is kept constant.
Since the minimum luminance level x _L is set, the luminance does not follow the luminance even if the luminance of the illuminating lamp 5 is deteriorated due to the service life. In this way, the brightness of the illumination lamp 5 is controlled so as to be always constant irrespective of a change with time, so that the variation in the brightness due to the use time can be completely eliminated.
[0032]
【The invention's effect】
The present invention relates to an illumination lamp luminance control device that controls the luminance of an illumination lamp by using an illumination lamp driven by a predetermined driving power via a voltage adjustment circuit and a power measurement circuit that feedback-controls the output of the voltage adjustment circuit. A microcomputer having a memory for storing a standard luminance decay time characteristic of a lighting lamp and a timer function; a D / A converter for converting an output corresponding to luminance read from the memory into an analog luminance signal; A power measuring circuit is provided with a compensating circuit including a current-to-resistance conversion element for converting a luminance signal into a current and converting the current fluctuation into a resistance fluctuation. and until the time t _T in which the luminance becomes the same in the steady state, to control the driving power of the lamp, until the time t _T in which the luminance of the lamp is in a steady state, Mai under the control of the timer By outputting a code signal corresponding to the luminance from the CPU of the local computer, D / A converting the code signal and applying the D / A to the current-resistance conversion element, the luminance at the time of use of the illumination lamp is obtained. Since the control is performed, the luminance of the illuminating lamp in the steady state after a certain period can be made the same, and the variance of the luminance of the illuminating lamp due to the difference in the use time can be eliminated.
[0033]
In addition, the standard luminance decay time characteristic of the lamp, the maximum luminance level, the minimum luminance level, and the threshold level as the reference luminance are stored in a memory, and a microcomputer having a timer function and the light of the lamp are detected. A photodetector for converting the luminance signal of the illumination lamp from the photodetector into a digital luminance signal. The digital luminance signal from the A / D converter is It is input to a computer and the result of comparing the threshold level stored in the memory with the CPU is output as a code signal, and this code output is converted into an analog luminance signal by a D / A converter. As a result, the luminance of the illuminating lamp is always maintained at a constant level corresponding to the threshold level by applying the voltage to the current-resistance conversion element. It can be maintained at a constant.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing a first embodiment of the present invention.
FIG. 2 is a standard luminance decay time characteristic diagram showing a relationship between the luminance of the illumination lamp 5 and a use time t.
FIG. 3 is a configuration diagram showing a second embodiment of the present invention.
FIG. 4 is a standard luminance decay time characteristic diagram showing the relationship between the luminance of the illumination lamp 5 and the use time t, and is an explanatory diagram for controlling the luminance.
FIG. 5 is a configuration diagram showing a conventional example.
[Explanation of symbols]
3 Voltage adjustment circuit 4 AC conversion circuit 5 Illumination lamp 6 Power measurement circuit 10 Compensation circuit 11 Microcomputer Data timer 12 Timer 13 CPU
14, a memory 17, a D / A converter 19, a current-resistance conversion element 20, a photodetector 22, an A / D converter

Claims (2)

An illumination lamp driven by a predetermined driving power through a voltage adjusting circuit;
A power measurement circuit that feedback-controls the output of the voltage adjustment circuit, in a brightness control device for a lighting lamp that controls the brightness of the lighting lamp;
A microcomputer having a memory for storing a standard luminance decay time characteristic of the lamp and a timer function in the power measuring circuit; and a D / D converter for converting an output corresponding to the luminance read from the memory into an analog luminance signal. A compensating circuit comprising an A converter and a current-resistance converting element for converting the analog luminance signal into a current, and converting a change in the current into a change in a resistance value;
Until said time t _T in which the luminance becomes the same luminance of the illumination lamp in the luminance and the steady state at start of use, to control the driving power of the lamp, the microcomputer under control of the timer - motor A code signal corresponding to the luminance is output from the CPU, and the code signal is D / A converted and applied to the current-resistance conversion element, thereby controlling the luminance according to the time of use of the illumination lamp. brightness control circuit of the illumination lamp, characterized in <br/> that. An illumination lamp driven by a predetermined driving power through a voltage adjusting circuit;
A power measurement circuit that feedback-controls the output of the voltage adjustment circuit, in a brightness control device for a lighting lamp that controls the brightness of the lighting lamp;
The compensating circuit provided in the power measuring circuit includes:
A microcomputer having a timer function as well as storing a standard luminance decay time characteristic, a maximum luminance level, a minimum luminance level, and a threshold level serving as a reference luminance of the illumination lamp in a memory;
Said D / A converter;
Said current-resistance conversion element;
A photodetector that detects light from the illumination lamp and performs photoelectric conversion;
An A / D converter for converting the luminance signal of the lamp from the photodetector into a digital luminance signal;
The digital luminance signal from the A / D converter is input to the microcomputer, and the result of comparing the threshold level stored in the memory with the CPU is output as a code signal. Wherein the D / A converter converts the output to an analog luminance signal and applies the analog luminance signal to the current-to-resistance conversion element to maintain the illumination light at the reference luminance of the threshold level. Control device.

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