JPH0574583A - Lighting apparatus of hid lamp - Google Patents

Abstract

PURPOSE:To increase the lighting efficiency of a lamp by setting a standard according to the difference between the consumed power and a set power of an HID lamp, and controlling the feeding power value to the lamp according to the difference between the standard value and the lamp current value. CONSTITUTION:When a specific current flows to an HID lamp L, a voltage is generated at the contact of the resistances 61 and 62 of a voltage detecting means 60, its voltage signal is A/D converted 22, and a current signal is generated at both ends of a resistance R and it is A/D converted 23. Depending on the converted values, a microprocesser PC 21 operates the consumed power value, generates a standard value according to the difference between the consumed power value and a set power value, and delivers it to an A/D converter circuit 24. The difference between the lamp current and the standard value detected by the resistance R is detected 30, and when the detected difference output value is larger than a serrate wave from a circuit 41, the current is fed to the lamp L by the output of a comparison circuit 42. The output current value of a transistor (an amplifier circuit) 43 is controlled according to the amount of the current value of the lamp L, and the current of the lamp is stabilized and the lighting efficiency is improved.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lighting device for an HID lamp, and more particularly to a lighting device for a HID lamp which is small and lightweight and has high lighting efficiency.

[0002]

BACKGROUND ART HID (High I
ntensity Discharge) When controlling the lighting of the lamp, in order to make the entire circuit compact, the voltage applied to the lamp is detected, and the voltage across the lamp is controlled according to the detected voltage. It is possible to use a microprocessor for these controls.

That is, a reference voltage is generated by a predetermined reference voltage source, and the difference between this reference voltage and the detected lamp voltage is calculated by a differential amplifier. In addition, a thyristor is connected between the output of the AC power supply that has been rectified and smoothed, and the lamp. The lower the value, the larger the distribution angle (longer pulse width) and the higher its output voltage, while the higher the detection voltage is higher than the reference voltage, the smaller the distribution angle (pulse width). To shorten the output voltage. By doing so, the power consumption of the lamp is maintained at a desired value.

[0004]

However, the use of the above background art has a problem that the lighting probability is low.
That is, for example, when the detected voltage is higher than the reference voltage, the thyristor controls the output voltage to be low, and the voltage across the lamp is low. Therefore,
The power consumption of the lamp should be reduced by the amount of the voltage drop across it, and should approach the desired power consumption. However, in reality, not only the voltage across the lamp decreases, but also the impedance of the lamp increases as the voltage across the lamp decreases, and the power consumption decreases due to the decrease in the voltage across the lamp and the power consumption decreases due to the increase in the impedance of the lamp. It is considered that the power consumption of the lamp sharply decreases due to the synergistic effect with.

In the above case, immediately after that, even if the output voltage of the thyristor is controlled to be high in order to increase the power consumption, at that time, the lamp is often turned off. That is, it is considered that the microprocessor cannot follow the rapid power reduction in the lamp and the lighting probability is low.

It is an object of the present invention to provide a lighting device for an HID lamp which can maintain the power consumption of the HID lamp constant and has a high lighting efficiency.

[0007]

The present invention detects the value of a lamp current flowing through an HID lamp and also detects the value of the voltage across the HID lamp, and based on the detected value of the lamp current and the voltage across the terminal. The power consumption of the HID lamp is calculated, a reference value is generated according to the difference between the calculated power consumption and the set power, and a current value supplied to the HID lamp according to the difference between the lamp current value and the reference value. Is to control.

[0008]

According to the present invention, the value of the lamp current flowing through the HID lamp is detected, the value of the voltage across the HID lamp is detected, and the power consumption of the HID lamp is calculated based on the detected value of the lamp current and the voltage across the HID lamp. Since a reference value is generated according to the difference between the calculated power consumption and the set power, and the current value supplied to the HID lamp is controlled according to the difference between the lamp current value and the reference value, the HID The power consumption of the lamp can be maintained constant and the lighting efficiency of the HID lamp is high.

[0009]

1 is a circuit diagram showing an embodiment of the present invention.

In this figure, the current detecting means 10 detects the value of the lamp current flowing through the HID lamp L, the reference value generating means 20 generates a predetermined reference value, and the detected lamp current and the reference value are The difference detection means 30 detects the difference between the two, and the current control means 40 controls the current value supplied to the HID lamp L in accordance with this difference. The current control means 40 is
It is composed of a sawtooth wave generation circuit 41, a comparison circuit 42 that outputs a “High signal” when the output value of the difference detection means 30 is larger than the sawtooth wave, and a current amplification circuit 43. The power consumption of the HID lamp is calculated based on the value of the lamp current and the voltage across the lamp L, and the reference value is generated according to the difference between the calculated power consumption and the preset power setting. To be done.

FIG. 2 is a circuit diagram showing the above embodiment more specifically.

The AC voltage from the AC power supply 51 is rectified by the diode 52 and smoothed by the capacitor 53. In the current control means 40, a transistor is used as the current amplification circuit 43, a transformer 44 is connected between the comparison circuit 42 and the transistor 43, and the primary winding of the transformer 44 is connected to the output terminal of the comparison circuit 42 and the ground. The secondary winding of the transformer 44 is connected between the base and the emitter of the transistor 43. The output of the current control means 40 is smoothed by the choke coil 54 and the capacitor 55 and supplied to the HID lamp L. Also,
A commutation diode 56 is provided to sustain the current in the lamp L by releasing the energy stored in the choke coil 54 via the lamp L.

The current detecting means 10 is composed of a resistor R connected in series with the lamp L, and detects the current flowing through the lamp L based on the voltage generated across the resistor R.

The voltage detecting means 60 is composed of a series circuit of resistors 61 and 62, the series circuit is connected in parallel with the lamp L, and the signal at the connection point of the resistors 61 and 62 depends on the voltage across the lamp L. It is a signal.

The reference value generating means 20 comprises a microprocessor 21, A / D conversion circuits 22 and 23, and a D / A conversion circuit 2.
4, the A / D conversion circuit 22 converts the output signal of the voltage detection means 60 (a signal corresponding to the voltage across the lamp L) into a digital signal.
3 is a lamp L according to the voltage generated across the resistor R
It is to detect the value of the current flowing in. The microprocessor 21 calculates the power consumption of the lamp L according to the output signals of the A / D conversion circuits 22 and 23, and generates a reference value according to the difference between the calculated power consumption and the set power. Is. The value of the set power is stored in advance in a memory (not shown). D / A conversion circuit 24
Is for converting a digital signal corresponding to the reference value calculated by the microprocessor 21 into an analog signal.

Next, the operation of the above embodiment will be described.

First, at the same time when the power is turned on, the transistor 43 is turned on by a starting circuit (not shown), and a predetermined current flows through the HID lamp L. At this time, the voltage detection means 60
A voltage corresponding to the voltage across the lamp L is generated at the connection point of the resistors 61 and 62 of the, and this voltage signal is sent to the input port of the microprocessor 21 via the A / D conversion circuit 22.
A signal corresponding to the current flowing through the lamp L is generated at both ends of the resistor R, and this current signal is sent to the input port of the microprocessor 21 via the A / D conversion circuit 23.
In the microprocessor 21, the power consumption of the lamp L at that time is calculated according to the voltage signal and the current signal.

Then, the microprocessor 21 generates a reference value according to the difference between the calculated power consumption value and the set power value, outputs this reference value to the D / A conversion circuit 24, and outputs the D value. The / A conversion circuit 24 converts the reference value into an analog signal. The value of the set power is a value determined by the rating of the lamp L and other conditions, is set in advance before the lamp L is turned on, and the set value is stored in a memory (not shown). The relationship between the calculated power consumption value and the reference value is stored in a memory (not shown).

On the other hand, the difference detecting means 30 detects the difference between the lamp current detected by the resistor R and the reference value, and outputs a signal corresponding to this difference.

The sawtooth wave generation circuit 41 repeatedly outputs the same sawtooth, and when the output value of the difference detecting means 30 is larger than the sawtooth wave, the comparison circuit 42 outputs a "High signal", and this comparison circuit. The output signal of 42 is sent to the base of the transistor 43 via the transformer 44,
3 performs current amplification. This amplified current is supplied to the lamp L.

Here, when the current flowing through the lamp L is small, the difference signal output by the difference detecting means 30 is large, so the width of the pulse output by the comparison circuit 42 is wide (the distribution angle is large), and therefore, The value of the output current of the transistor 43 increases. On the contrary, when the current flowing through the lamp L is large, the difference signal output by the difference detecting means 30 is small, so that the width of the pulse output by the comparison circuit 42 is narrow (the distribution angle is small). The output current value is small. By repeating these controls, the current of the lamp L becomes stable and the lighting probability increases. As described above, when the current flowing through the lamp L is small, the output current value of the transistor 43 is large, and when the current flowing through the lamp L is large, the transistor 43 is large.
Since the value of the output current of the lamp L becomes small, it seems that there is one current-voltage characteristic curve of the lamp L in the above-mentioned embodiment, but in reality, there are a plurality of characteristic curves.
This will be described with reference to FIG.

FIG. 3 is a diagram for explaining the operation of the above embodiment.
It is a figure which shows the current-voltage characteristic of the lamp L. In the sloped portion of this characteristic, as the value of the current flowing through the lamp L increases, the value of the voltage applied to the lamp L decreases. The voltage of the lamp L corresponds to the average voltage of the output voltage of the transistor 43.

Further, there are a plurality of characteristics of the inclined portion, and three representative examples thereof are shown. In reality, more than three characteristics exist. These characteristics, and change according to the amount of power consumption of the lamp L. In other words, the microprocessor 21 calculates the power consumption of the lamp L, and the characteristics, according to the difference between the calculated power consumption and the set power,
, Will be selected automatically. The characteristics are
This is a characteristic selected when the actual power consumption of the lamp L is relatively larger than the set power (a characteristic selected when the power consumption is to be reduced), and the characteristic is the actual power consumption of the lamp L. Is a characteristic that is approximately the same as the set power (a characteristic that is selected when the power consumption is not so changed), and the characteristic is that the actual power consumption of the lamp L is the set power. Characteristics when the power consumption is relatively smaller than (Characteristics selected when trying to increase power consumption)
Is.

For example, consider the case where the currents flowing through the lamp L are the same current i. If the power consumption in the lamp L is smaller than the set value, the value of the-input signal of the difference detection circuit 30 becomes small and its characteristic becomes, and the voltage across the lamp L becomes v3 according to this characteristic, The power consumption of the lamp L is increased.
On the contrary, if the power consumption in the lamp L becomes larger than the set value, the value of the-input signal of the detection circuit 30 becomes large and its characteristic becomes as follows.
The voltage between both ends becomes v1, and the power consumption of the lamp L decreases. Further, if the power consumption in the lamp L becomes the same as the desired value, the value of the-input signal of the detection circuit 30 does not change and its characteristic becomes, and the voltage across the lamp L becomes v2 according to this characteristic. Therefore, the power consumption of the lamp L is maintained in the current state.

According to the above embodiment, since the microprocessor 21 controls the power consumption of the lamp L to be the set power, the power consumption of the lamp L can be maintained constant and the current of the lamp L can be changed. Since not only the supply current is controlled but also the current is controlled according to the power consumption of the lamp L, there is an advantage that the lighting efficiency of the lamp L is high. That is, if the current supplied to the lamp L is controlled using only the current of the lamp L as a parameter, the impedance change of the lamp L cannot be tracked (it cannot be tracked because the microprocessor 21 is used). Even when the lamp L is turned off, in the above-described embodiment, the supply current to the lamp L is controlled using the power consumption of the lamp L as a parameter.
Even if the microprocessor 21 is used, it is possible to follow the impedance change of the lamp L, and therefore the lighting efficiency of the lamp L is high.

[0026]

According to the present invention, the power consumption of the HID lamp can be kept constant and the lighting efficiency of the HID lamp is high.

[Brief description of drawings]

FIG. 1 is a circuit diagram showing an embodiment of the present invention.

FIG. 2 is a circuit diagram more specifically showing the embodiment.

FIG. 3 is an operation explanatory diagram of the above-described embodiment, and is a diagram showing a current-voltage characteristic of the lamp L.

[Explanation of symbols]

 10 ... Current detection means, R ... Current detection resistance, 20 ... Reference value generation means, 21 ... Microprocessor, 30 ... Difference detection means, 40 ... Current control means, 41 ... Sawtooth wave generation means, 42 ... Comparison circuit, 60 ... Voltage detecting means, L ... HID lamp.

Claims (2)

[Claims] 1. A current detection means for detecting a value of a lamp current flowing through an HID lamp; a voltage detection means for detecting a value of a voltage across the HID lamp; a lamp current value and a value of the voltage across the HID lamp. A reference value generating means for calculating the power consumption of the HID lamp on the basis of the calculated power consumption and a reference value in accordance with the difference between the calculated power consumption and the set power; A HID lamp including: a difference detecting unit that detects a difference; and a current control unit that controls a current value supplied to the HID lamp according to a difference between the lamp current value and the reference value. Illuminator. 2. The microprocessor according to claim 1, wherein the microprocessor executes a calculation of power consumption of the HID lamp or a calculation of a reference value according to a difference between the calculated power consumption and the set power. HID lamp illuminator.