JPH0648638B2 - Inverter for EL lamp - Google Patents

Description

Detailed Description of the Invention [Industrial applications]

The present invention relates to a DC-AC inverter for lighting an EL lamp.

2. Description of the Related Art EL lamps are lit by alternating current. The alternating current for lighting the EL lamp is usually adjusted to a voltage of several tens to several hundreds of volts and a frequency of several hundreds to several KHz. The inverter for lighting the EL lamp is 100V-6.
It can be driven with 0 Hz AC or several volts DC. Therefore, the inverter for lighting the EL lamp needs to convert the supplied power into the lighting voltage of the EL lamp and the frequency. An EL lamp lighting inverter that is commonly used at present uses a well-known RCC type booster circuit or a Royer type booster circuit to convert the AC voltage generated on the secondary side of the transformer into an E voltage.
It is designed to be supplied to the L lamp. By the way, the EL lamp deteriorates with time, and the brightness gradually decreases. This is because the luminous body deteriorates and the brightness decreases. Furthermore, the current flowing through the EL lamp decreases as it deteriorates. This also causes a decrease in brightness. The current decreases due to EL over time.
The reason is that the capacitance of the lamp is reduced. Therefore, the EL lamp has a drawback that when it is driven by a constant voltage and constant frequency power source, the brightness is significantly reduced in a short time. In order to prevent this drawback, an inverter has been developed in which the power supply frequency applied to the EL lamp is increased as it is used. This inverter effectively utilizes the characteristics of an EL lamp that becomes brighter when the frequency of the supplied power is increased. This inverter prevents the decrease in brightness of the EL lamp that occurs over time by increasing the frequency supplied to the EL lamp as it is used. An inverter that realizes this is the patent application published in Showa 6
It is disclosed in Japanese Patent No. 502009. In this inverter, a reactor is connected to the EL lamp and the EL lamp is used as an oscillating element. Therefore, when the EL lamp deteriorates and the capacitance decreases, the oscillation frequency is adjusted to a high value. In this type of inverter, as the EL lamp deteriorates,
Since the power supply frequency of the EL lamp is adjusted to a high value, the EL lamp can be brightly lit for a long period of time.
However, this type of inverter has a drawback that when the electrostatic capacity of the EL lamp decreases, the voltage applied to the EL lamp becomes extremely high, and the EL lamp easily causes dielectric breakdown. The reason is that when the EL lamp deteriorates, the Q of the series resonant circuit of the EL lamp and the reactor becomes high. The Q of the series resonance circuit composed of the EL lamp and the reactor increases in proportion to the frequency. In addition, Q increases even if the equivalent parallel resistance of the EL lamp increases. EL
As the equivalent parallel resistance of the lamp increases and the frequency increases, the Q of the series resonant circuit increases. The voltage applied to both ends of the EL lamp increases in proportion to Q of the resonance circuit composed of the EL lamp and the reactor. The capacitance of EL lamps decreases as they are used,
The resistance connected in parallel in the equivalent circuit increases. Therefore,
In this inverter, as the EL lamp deteriorates, the oscillation frequency increases and the resistance increases, so that the Q gradually increases. Therefore, the voltage applied to both ends of the EL lamp becomes extremely high, which causes dielectric breakdown. The present inventor has developed an inverter that controls the oscillation frequency by slightly shifting it from the resonance frequency of the EL lamp and the reactor. This inverter does not specify the frequency at which the oscillation circuit oscillates only by the resonance frequency between the EL lamp and the reactor, but does not determine the frequency at which the oscillation frequency of the oscillation circuit and the resonance frequency between the EL lamp and the reactor occur. You can control the frequency of the applied power. Therefore, this EL lamp uses a multi-vibrator or the like having a free-running oscillation frequency for the oscillation circuit, and the oscillation frequency of this multi-vibrator is controlled by the series resonance circuit of the EL lamp and the reactor. This EL lamp can control the amount of change in the free-running oscillation frequency by adjusting the amount of feedback from the resonance circuit of the EL lamp and the reactor. When the amount of feedback is increased, the oscillation frequency of the oscillation circuit is more strongly drawn to the resonance frequency of the EL lamp and the reactor than the free-running oscillation frequency. When the feedback is reduced, the oscillation frequency of the oscillation circuit approaches the free-running oscillation frequency. Therefore, the inverter having this structure can control the deviation of the oscillation frequency of the oscillation circuit by adjusting the feedback from the resonance circuit including the EL lamp and the reactor.
Therefore, this inverter can control the amount of change in frequency to control the voltage applied to the deteriorated EL lamp. This is because the Q of the resonance circuit can be controlled by controlling the amount of change in frequency. However, this inverter has a drawback that the distortion of the alternating current supplied to the EL lamp increases due to the feedback from the resonance circuit. This is because the duty of the rectangular wave that is the output waveform of the oscillation circuit deviates from 50% as the oscillation frequency changes due to the feedback from the resonance circuit. The present invention was developed with the object of solving these drawbacks of conventional inverters for EL lamps. An important object of the present invention is to be able to brightly light an EL lamp for a long period and Another object of the present invention is to provide an inverter for an EL lamp that can bring the duty ratio of the alternating current supplied to the lamp close to 50%.

[Means for solving problems]

In order to achieve the above-mentioned object, the inverter of the present invention comprises:
It has the following configuration. (A) The inverter includes a voltage adjustment circuit that converts an input voltage into an EL lamp lighting enable voltage and converts the input voltage into a direct current. The inverter also converts the output of the voltage regulation circuit into alternating current to illuminate the inverter brightly, DC-AC.
It has a conversion circuit. (B) The DC-AC conversion circuit includes an oscillation circuit and an output circuit. (C) The oscillator circuit is an oscillator circuit that oscillates a rectangular wave, such as a multivibrator. (D) The oscillator circuit oscillates at a specific frequency even if a trigger signal is not input from the outside. RC or the like is provided to specify the oscillation frequency. Adjust the constant such as RC to set the oscillation frequency of the oscillation circuit to 20.
It is specified in the range of 0 to 5000 Hz. (E) The output circuit includes switching elements such as transistors and FETs that are turned on and off by the output rectangular wave of the oscillation circuit. (F) A series resonance circuit of the reactor and the EL lamp is connected as a load to the output side of the output circuit so that the sine wave is supplied to the EL lamp. (G) The connection point between the EL lamp and the reactor connected in series is connected to the input side of the oscillation circuit so that the frequency of the alternating current applied to the EL lamp increases as the EL lamp deteriorates. Feedback from the series resonance circuit of the reactor and the EL lamp shifts the oscillation frequency of the oscillation circuit to the resonance frequency of the EL lamp and the reactor. (H) The connection point between the EL lamp and the reactor connected in series is connected to the input side of the power amplification switching circuit,
The resonance signal between the EL lamp and the reactor is fed back to the input side of the power amplification switching circuit to bring the duty of the alternating current supplied to the EL lamp close to 50%.

[Operation effect]

In the inverter for an EL lamp of the present invention, the input voltage is adjusted by the voltage adjusting circuit to a voltage capable of lighting the EL lamp. The voltage-adjusted direct current is converted into alternating current by the DC-AC conversion circuit, and this is supplied to the EL lamp. The DC-AC conversion circuit supplies AC power to the series resonance circuit of the reactor and the EL lamp connected to the output side, and E
Turn on the L lamp. The oscillation circuit of the DC-AC conversion circuit oscillates at the free-running oscillation frequency when not fed back from the resonance circuit of the EL lamp and the reactor. In the actual operating state, the oscillation circuit is fed back from the resonance circuit of the EL lamp and the reactor. Feedback from the resonance circuit of the EL lamp and the reactor causes the oscillation frequency of the oscillation circuit to deviate from the free-running oscillation frequency. The oscillating frequency of the oscillating circuit is specified as the frequency obtained by drawing the free-running oscillating frequency into the resonance frequency of the EL lamp and the reactor. An oscillation circuit whose oscillation frequency is pulled to the resonance frequency of the EL lamp and the reactor has a higher oscillation frequency as the EL lamp deteriorates. This is because the capacitance decreases as the EL lamp deteriorates. Feedback from the resonance circuit of the EL lamp and the reactor increases the oscillation frequency of the oscillation circuit with time,
The decrease in brightness of the EL lamp is reduced. The oscillation circuit is EL
The duty of the oscillating rectangular wave is 5 by being fed back from the resonance circuit of the lamp and the reactor.
It deviates from 0%. When a rectangular wave whose duty is deviated from 50% is input to the output circuit, the waveform of the alternating current supplied to the EL lamp is distorted. However, the inverter of the present invention feeds back from the resonance circuit of the EL lamp and the reactor to the input side of the output circuit. This feedback adjusts the timing of turning on and off the switching element of the output circuit,
The duty of the output wave is approached to 50%. Therefore, the feedback input here has the effect of bringing the supply waveform for energizing the EL lamp closer to a sine wave with less distortion. An EL lamp to which a sine wave with little distortion is supplied has the characteristics that the luminous efficiency is high and that the noise level due to the vibration of the EL lamp can be lowered. That is, the inverter for the EL lamp of the present invention is
By the feedback from the resonance circuit of the L lamp and the reactor, the EL lamp can be brightly lit for a long period of time, and the feature that it can be efficiently lit is realized.

[Preferred embodiment]

Embodiments of the present invention will be described below with reference to the drawings. The EL lamp lighting inverter shown in FIG. 2 includes a voltage adjusting circuit that boosts an input voltage to an EL lamp lighting available voltage and converts the voltage into direct current. The voltage adjustment circuit includes a booster circuit and a rectifier circuit. A booster circuit and a rectifier circuit use a Royer circuit including transistors Q ₁ and Q ₂ , an oscillation transformer T ₁ , rectifying diodes D ₁ and D ₂ , reactors L ₁ and L ₂ , a resistor R ₁ , and a capacitor C _3. is doing. As the booster circuit, another known circuit capable of boosting the supply voltage V ₁ to the EL lamp lighting voltage V ₂ can be used. This circuit boosts the supply voltage V ₁ to V ₂ . The boosted AC is rectified by the diodes D ₁ and D ₂ and converted into a smooth DC by the reactor L ₂ and the capacitor C ₃ . The DC-AC conversion circuit includes an oscillation circuit and an output circuit. The output circuit is controlled by the output signal of the oscillating circuit to switch the output voltage V ₂ of the voltage adjusting circuit into an alternating current supplied to the EL lamp. The oscillation circuit for lighting the EL lamp is a transistor Q ₃ ,
Q _4, resistors _{R 3, R 4, R 5} , R 6, R 7, is composed of a multivibrator composed of the capacitor C _4, C _5. Multivibrator, the free-running oscillation frequency is determined by the resistor R _4, R _5, and a condenser C _4, C _5. Resistance R ₄ ,
The free-running oscillation frequency specified by R ₅ and the capacitors C ₄ and C ₅ is adjusted in the range of 200 to 5000 Hz.
If the oscillation frequency of the oscillation circuit is lower than 200 Hz, E
I cannot turn on the L lamp brightly. Further, if the EL lamp is turned on at a frequency higher than 5000 Hz, the life will be shortened. The oscillation circuit, which is a multivibrator, oscillates a rectangular wave. This oscillating circuit oscillates at the free-running oscillating frequency when the feedback from the resonance circuit of the EL lamp and the reactor cannot be applied. The output circuit is composed of the transistors _{Q 5, Q 6, Q 7} , Q 8 which is a switching element, a resistor _{R 8, R 9, R 10} , R 11. In this circuit, when the transistor Q ₄ of the oscillation circuit is repeatedly turned on and off, the transistors Q ₅ and Q _{6 of} the output circuit are repeatedly turned on and off, and the resistors R ₈ , R ₉ , and R ₁₀ ,
The transistors Q ₇ and Q ₈ are alternately turned on and off at R ₁₁ . A reactor L ₃ is connected to the connection point of the transistors Q ₇ and Q ₈ , and an EL lamp is connected to this. That is, the EL lamp and the reactor L ₃ are connected in series, and this is connected as the load of the output circuit. The transistors Q ₇ and Q ₈ of the output circuit alternately repeat the on / off operation. Therefore, the output circuit outputs a square wave output
Supply to the resonance circuit of the lamp and the reactor L ₃ . The square wave Palace voltage supplied from the transistors Q ₇ and Q ₈ causes series resonance between the capacitive EL lamp and the reactor L ₃ and a sine wave is applied to the EL lamp. The inductance of the reactor L ₃ is specified in consideration of the capacitance of the EL lamp and the oscillation output circuit of the oscillation circuit. Usually, the inductance of the reactor L ₃ is adjusted so that the series resonance frequency with the EL lamp is higher or lower than the oscillation frequency of the oscillation circuit by several hundreds to several kHz. Feedback is applied to the oscillation circuit from the connection point between the EL lamp and the reactor L ₃ forming the series resonance circuit in order to pull the oscillation frequency of the oscillation circuit into the resonance frequency of the resonance circuit. The inverter shown in FIG. 1 has a reactor L ₃
From the connection point of the EL lamp and the EL lamp, feedback is applied to the oscillation circuit via the resistor R ₁₂ and the capacitor C ₆ . The feedback amount from the resonance circuit of the EL lamp and the reactor L ₃ can be adjusted by the resistor R ₁₂ . If the resistance R ₁₂ is small, the feedback becomes strong, and the oscillation frequency of the oscillation circuit is more strongly pulled to the resonance frequency. On the contrary, if the resistance R ₁₂ is large, the amount of feedback from the resonance circuit of the EL lamp and the reactor L ₃ is small, the pull-in from the resonance circuit is small, and the oscillation circuit oscillates at a frequency close to the free-running oscillation frequency. . Adjust the resistance R ₁₂ to adjust the feedback amount from the resonance circuit of the EL lamp and the reactor L ₃ to the oscillation circuit,
By adjusting the deviation between the resonance frequency determined by the resonance circuit of the EL lamp and the reactor L ₃ and the actual oscillation frequency of the oscillation circuit, the optimum frequency is always applied to the EL lamp. When the EL lamp deteriorates and changes with time, the capacitance component decreases, and along with the change, the resonance frequency increases and moves to a new optimum point. Therefore, the frequency and voltage of the EL lamp gradually increase, and the decrease in brightness can be suppressed for a long time. Further, in the inverter of FIG. 1, feedback is also applied to the input side of the output circuit from the connection point between the EL lamp and the reactor L ₃ which form the series resonance circuit. The feedback comprises a resistor ₁₂ and a capacitor C ₇ . Feedback is applied to the bases of the transistors Q ₅ and Q ₆ on the input side of the output circuit from the connection point between the EL lamp and the reactor L ₃ via the resistor ₁₂ and the capacitor C ₇ connected in series. The resistor ₁₂ and the capacitor C ₇ feed back a part of the sine wave from the resonance circuit of the EL lamp and the reactor L ₃ to the bases of the transistors Q ₅ and Q ₆ of the output circuit. This feedback adjusts the timing at which the transistors Q ₇ and Q ₈ are alternately turned on and off, and the reactor L ₃
A rectangular wave with a duty of 50% is supplied to the load of the resonance circuit including the EL lamp and the EL lamp. A rectangular wave with a duty approaching 50% was supplied.
The resonance circuit of the L lamp and the reactor L ₃ is energized by a sine wave with less distortion, enhances the resonance effect, and causes the EL lamp to efficiently emit light.

[Brief description of drawings]

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

Claims (1)

[Claims] 1. An inverter for an EL lamp having the following structure. (A) A voltage adjusting circuit that changes an input voltage into a voltage that can be used to light an EL lamp and converts it into a direct current, and a DC-AC converting circuit that converts an output of the voltage adjusting circuit into an alternating current. (B) The DC-AC conversion circuit includes an oscillation circuit and an output circuit that power-amplifies the output signal of the oscillation circuit. (C) The oscillation circuit is a rectangular wave oscillation circuit. (D) The oscillation frequency of the oscillation circuit is 200 to 5000 Hz
Is in the range. (E) The output circuit includes a switching element that turns on and off. (F) The switching element of the output circuit is turned on / off by being controlled by the rectangular wave which is the output wave of the oscillation circuit. (G) A series resonance circuit of the reactor and the EL lamp is connected as a load to the output side of the output circuit. (H) The connection point between the EL lamp and the reactor forming the series resonance circuit is connected to the input side of the oscillation circuit, and the resonance signal between the EL lamp and the reactor is fed back to the oscillation circuit. (I) The connection point between the EL lamp and the reactor forming the series resonance circuit is connected to the input side of the output circuit, and the resonance signal between the EL lamp and the reactor is fed back to the input side of the output circuit.