JP2019197701A - El light-emitting circuit and control method thereof - Google Patents

Abstract

To provide an EL light-emitting circuit and a control method thereof that radically eliminates the cause of unnecessary Joule heat generation through a driving transistor, maximizes energy efficiency, and automatically corrects the luminance reduction of the EL light-emitting body due to a power supply voltage drop, and maintains the brightness at the required level.SOLUTION: In a case in which an EL light-emitting body 7 is turned on through an EL light-emitting circuit including complementary transistors 2 and 3, a control unit, a DC power supply 5, a shunt resistor 4, and a step-up transformer 6, when the control unit outputs a drive signal to the complementary transistor, the complementary transistor causes a current to flow through the step-up transformer, an AC voltage equivalent to 100 Vrms is generated in the secondary coil of the step-up transformer, and the EL light-emitting body is turned on with the AC voltage.SELECTED DRAWING: Figure 1

Description

The present invention relates to an EL light emitting circuit and a method for controlling the EL light emitting circuit that increases energy efficiency and maintains luminance at a necessary level even when a power supply voltage fluctuates.

  EL is an abbreviation for electroluminescence, and EL includes an inorganic light emitter (also referred to as “inorganic EL”) and an organic light emitter (also referred to as “organic EL”). Inorganic EL is an AC-driven light-emitting element that uses zinc sulfide or the like as a substrate and applies a voltage to an inorganic compound phosphor produced by adding a material that emits monochromatic light such as copper to emit light. It is thin and lightweight and has uniform surface emission that does not have high brightness, so it can be used as an auxiliary light at night and as a display illumination for portable electronic devices.

The EL light emitter is an equivalent capacitor, so that it does not react to the DC power supply at all due to the characteristics of the capacitor and emits light only when an AC voltage is applied. To do.
Therefore, it depends on how much time should be given to the voltage change section in order to cause the EL light emitter to emit light efficiently.

The waveform of the conventional EL inverter is shown in FIG.
The conventional EL light emitting circuit is of an analog drive type, and has a disadvantage that Joule heat is generated in the rising and falling intervals of the current flowing through the transistor, resulting in a decrease in energy efficiency.
In addition, since the conventional EL inverter does not take measures when the voltage drops, there is a problem that when the battery voltage is lowered, the current consumption is reduced and the brightness is drastically lowered.

For example, a conventional EL light emitting circuit described in Patent Document 1 will be described. FIG. 3 is a circuit diagram of a conventional EL light emitting circuit. As shown in FIG. 3, the conventional EL light emitting circuit includes one transistor (9), bias resistors (10, 11), a capacitor (12), a step-up transformer (6), a DC power source (5), and EL light emission. It consists of a body (7).
The connection relationship of the conventional EL light emitting circuit configuration will be described. The Plus (+) side of the DC power source (5) is connected to the collector C of the transistor (9), and the bias resistor (10) and the bias resistor (11) are connected. ) Is connected to the base B of the transistor (9), and the emitter E of the transistor (9) is connected so that the primary coil (64) and the base coil (65) of the step-up transformer (6) meet each other, In the Minus (−) of the DC power source (5), the primary coil (64), the EL light emitter (7), and the ground (8) of the step-up transformer (6) are equally connected.
The capacitor (12) has one end connected to the resistor (10) and the resistor (11) to the QC, and the other end connected to the base coil (65) and the secondary coil (66) of the step-up transformer (6). The other end of the secondary coil (66) of the step-up transformer (6) is connected to the other end of the EL light emitter (7).

Next, each part of the conventional EL light emitting circuit will be described.
In FIG. 3, a base bias current flows between the base B and the emitter E of the transistor (9) by the bias resistors (10, 11), and flows to the emitter E at the collector C of the transistor (9). The emitter current has escaped to ground through the primary coil (64) of the step-up transformer (6).
When a current passes through the primary coil (64) of the step-up transformer: trans (6), a voltage is also induced in the base coil: base coil (65), and one end of the base coil (65) and one end of the capacitor (12). When the voltage at the terminal connected to the capacitor rises, the potential difference of the capacitor (12) is phased, and further proceeds, the potential difference between the emitter E and the base B of the transistor: transistor (9) also disappears. The base B of (9) is rather reverse biased: bias, and eventually the transistor (9) is turned off (Turn Off).
When the transistor (9) is turned off (Turn Off), a back electromotive force is generated in the primary coil (64) of the step-up transformer (6), and the emitter E of the transistor (9) returns to the minus (−) direction. Then, it returns to the plus (+) direction through the-apex. In this process, the capacitor (12) maintains a reverse bias at the base E of the transistor (9) while charging the maximum value while the emitter E voltage of the transistor (9) drops to the minus (−) peak. The transistor (9) remains in the turn-off (Turn Off) state. On the other hand, when the back electromotive force of the primary coil (64) of the step-up transformer (6) gradually disappears after the-apex and recovers in the plus (+) direction, the capacitor (12) starts discharging, and is constant. When the time has elapsed, the base B bias of the transistor (9) is reversed and turned positive. When the base B of the transistor (9) is again positively biased, a current flows again to the emitter E at the collector C of the transistor (9), and such a series of operations is repeated, and the step-up transformer (6) An AC voltage of about 100 Vrms level is generated in the secondary coil (66), and the EL light emitter (7) is turned on.

As described above, the conventional EL light emitting circuit is entirely analog in driving method. In the analog circuit, Joule heat is generated in the rising and falling intervals of the current flowing through the transistor, and the energy efficiency is greatly reduced.
Joule heat (J) = Vce × Ic × t
Vce: voltage between the collector and emitter of the transistor.
Ic: current that flows to the emitter at the collector of the transistor.
t: Transistor operating time.
Here, Ic is defined as the current flowing through the transistor, but strictly speaking, it is limited to the gradient period (rise and fall) of the transistor current.

Small and thin EL light emitting circuits that mainly use dry batteries as a power source are the most important issues for improving energy efficiency and extending the life of dry batteries. However, conventional analog EL light emitting circuits of the analog method are transistors and joules. Heat (J) is generated and it is physically impossible to prevent energy loss.
Further, in the conventional EL light emitting circuit, when the power supply voltage is lowered, the current consumption is also proportionally reduced, thereby lowering the secondary coil voltage of the step-up transformer, and there is a problem that the luminance of the EL light emitter is lowered. There is no provision for reducing the brightness.

Patent Document 2 discloses a lighting circuit that has a variable output inverter and performs constant current control of an EL element, and a DC conversion circuit that converts a pulse signal for dimming control into a DC signal corresponding to its duty ratio. A dimming circuit that performs dimming by changing the input to the transformer of the inverter according to the DC signal, and a detection circuit that detects an abnormality of the EL element from a change in the output of the switching element connected to the transformer of the inverter And an EL element lighting control device provided with a non-lighting prevention circuit.
However, since this patent is a lighting control device having a circuit for judging / detecting a load abnormality, interruption or short circuit, if each circuit is operated, current consumption should be considerably required. As an effect of the patent, it is described that the power consumption is small, that is, the efficiency is high. However, as described for the efficiency related to the analog system, Joule heat (J) is generated in the transistor to prevent energy loss. There is still the problem of being physically impossible.
The focus of this patent is that the luminance is maintained by using a constant current to obtain a stable luminance, whereas in the present invention, the power consumption is kept constant even when the power supply voltage is lowered. In particular, the present invention is designed to obtain a constant illuminance by controlling the current value (drive signal) for that purpose, and therefore means (configuration) for maintaining the luminance is different.

The EL light emitting circuit of the present invention is an invention pursuing the best efficiency that does not require a circuit for judging / detecting. Furthermore, according to the present invention, the EL drive consumption current is almost the same as the in-circuit consumption current, and the energy efficiency is at the highest level.
In particular, it is a circuit that pursues the timing at which a drive signal is output in order to improve the energy loss of a conventional analog system and further reduce the current consumption to increase the efficiency.
Especially in inverters using dry cells, if the voltage drops, the illuminance also decreases. Conventionally, it is a completely new system that can obtain a constant illuminance even if the voltage drops. It has the potential to spread to many inverters. Yes.

The EL illuminant is equivalently expressed by a capacitor (CAPACITOR) and, due to the characteristics of the capacitor, does not react to the DC power supply at all and emits light only when an AC voltage is sensed. That is, light is emitted only in the voltage change section.
The conventional EL light emitting circuit is of an analog drive type, and has a disadvantage that Joule heat is generated in the rising and falling intervals of the current flowing through the transistor, resulting in a decrease in energy efficiency.
In addition, when the voltage of the power source battery drops, the conventional EL light emitting circuit does not have a measure for complementing the decrease in luminance of the EL light emitter. When operated with a dry battery, the voltage of the power source battery drops. The current consumption also decreases in the same way, and there is a problem that the luminance is lowered.

In the present invention, when the EL light emitter is charged with the output voltage of the secondary coil of the step-up transformer, the control unit tracks the gradient of the output voltage E01 of the secondary coil and outputs the drive signal of the transistor from the optimum viewpoint. The highest energy efficiency. That is, an object of the present invention is to provide an EL light emitting circuit that automatically increases current consumption and corrects a decrease in luminance of an EL light emitter when the voltage of a power supply used drops, and a control method thereof.

  In the present invention, since the EL light emitter is turned on through an EL light emitting circuit composed of a complementary transistor, a control unit, a DC power source, and a step-up transformer, the control unit sends drive signals T_ON_A, T_OFF_A, When T_ON_B and T_OFF_B are output, the complementary transistor causes an electric current to flow through the step-up transformer, an AC voltage equivalent to 100 Vrms is generated in the secondary coil of the step-up transformer, and an EL light-emitting circuit that lights the EL light-emitting body with the AC voltage and its control Is the method.

The present invention provides an EL light-emitting circuit that corrects a decrease in luminance of the EL light emitters of the following (1) to (2) and a control method thereof. That is,
(1) When a current is passed, a step-up transformer that raises a low voltage to a high voltage, a complementary transistor for driving the step-up transformer, and a drive signal necessary for operating the complementary transistor are output. For the purpose of measuring the control unit, the EL light emitting element that is turned on in response to the input of AC voltage, the DC power supply necessary for circuit operation, and the current consumption, the current flowing through the transistor is converted into a voltage and converted to a control unit. An EL light emitting circuit comprising a shunt resistor to be returned;
When charging the EL light emitter with the output voltage of the step-up transformer, the control unit tracks the gradient of the output voltage and determines the optimum viewpoint at the moment when the polarity of the voltage gradient is going to change in the opposite direction. Drive signal T_ON_A or T_ON_B, and
The controller senses an emitter current of the complementary transistor measured by the shunt resistor, calculates a power consumption value obtained by adding the emitter current to a power supply voltage, and adjusts the width of the drive signal T_ON_A or T_ON_B. An EL light emitting circuit characterized in that the luminance of the EL light emitter can be maintained at a required level by changing the output voltage.
(2) When operating the complementary transistor for driving the step-up transformer, the timing of the drive signal output from the control unit to the complementary transistor follows the output voltage gradient of the step-up transformer, and the polarity of the voltage gradient The method for controlling an EL light emitting circuit according to (1), characterized in that it is performed at the moment when is going to change in the opposite direction.

According to the present invention, when charging the output voltage E01 of the secondary coil of the step-up transformer and the EL light emitter, the control unit tracks the gradient of the output voltage E01 of the secondary coil so that the transistor drive signal is optimally viewed. By providing the control method for outputting the power, the energy efficiency is maximized.
In addition, the control unit performs A / D conversion on the voltage value measured through the shunt resistor in real time, converts it to a current consumption value, and multiplies the power supply voltage by P = EI (where P is power consumption) The value of E, the voltage value, and I the current consumption value) are adjusted so that the width of the drive signal is always the same, and the luminance of the EL luminous body is maintained at a necessary level.

1 is a circuit diagram of an EL light emitting circuit of the present invention. The chart which shows the timing of the important part of EL light emission circuit of this invention. The circuit diagram of the conventional EL light emitting circuit. The chart which shows the timing of the important part of the conventional EL light emission circuit.

In the EL light emitting circuit, the present invention provides an EL light emitting device that emits light by an alternating voltage, a direct current power source that supplies a voltage to the EL light emitting device, a step-up transformer that increases a secondary coil voltage when a current is passed through the primary coil, A transistor that drives the step-up transformer, a shunt resistor that converts the current flowing through the transistor into a voltage and returns it to the control unit for the purpose of measuring current consumption, and T_ON_A, T_OFF_A, T_ON_B, and T_OFF_B An EL light emitting circuit comprising a control unit that outputs a drive signal.
Hereinafter, although the present invention is explained in detail based on one embodiment, the present invention is not limited to this.

The present invention will be described with reference to FIG.
In the EL light emitting circuit according to the embodiment of the present invention, when the output voltage E01 of the secondary coil (63) of the step-up transformer (6) and the EL light emitter are charged, the control unit (1) has the secondary coil (63). ) Of the output voltage E01 is output, and the drive signal of the transistor (2, 3) is output from the optimum viewpoint, so that the highest energy efficiency can be obtained.
Another feature of the present invention is that the emitter current of the transistor is actually the main current consumption of the EL light emitting circuit. Therefore, the emitter current is sensed by the control unit, and this is calculated as the power supply voltage. It can have the function of maintaining the brightness of the body at the required level.

When the control unit (1) of the EL light emitting circuit outputs the drive signal T_ON_A, the transistor (2) is turned on (Turn On), a current flows through the primary coil (61) of the step-up transformer (6), and the step-up transformer The output voltage E01 of the secondary coil (63) in (6) rises to + Vpp. Next, the drive signal T_OFF_A is supplied to the transistor (2), and the transistor (2) is turned off. At this time, the output voltage E01 of the secondary coil (63) of the step-up transformer (6) drops to the-side, but passes through the-apex and is captured again by the control unit (1), which is inverted in the + direction. Then, the drive signal T_ON_B is output, and the transistor (3) is turned on (Turn On). When the transistor (3) is turned on (Turn On), a current flows through the primary coil (62) of the step-up transformer (6), and the output voltage E01 of the secondary coil (63) of the step-up transformer (6) is -Vpp. Descend to Next, the drive signal T_OFF_B is supplied to the transistor (3), and the transistor (3) is turned off. At this time, the output voltage E01 of the secondary coil (63) of the step-up transformer (6) rises to the + side, but passes through the + apex and is inverted again in the-direction by the control unit (1). It captures and outputs drive signal T_ON_A. Such a series of operations is repeated, and E01, an AC voltage corresponding to 100 Vrms is generated in the secondary coil (63) of the step-up transformer (6), and this is supplied to the EL luminous body (7) to generate EL. The light emitter (7) is turned on.
As described above, when the transistor is turned off (Turn Off), the output voltage E01 of the secondary coil of the step-up transformer rises or falls, and at a certain point, the rise or fall speed slows down and the curve becomes gentle. Changes to. The reason is that the charging operation performed by the EL light emitter corresponding to the load of the output voltage E01 of the secondary coil of the step-up transformer ends. An EL light emitter is equivalent to a capacitor.

When passing through “+ vertex (or −vertex)” and reversing in the − direction (or + direction) again, the control unit (1) captures this and outputs the drive signal T_ON_A (or T_ON_B) This is because turning the transistor on when turning the direction again after passing through the apex is the best way to increase energy efficiency. The “vertex” is the time when the electric energy generated by the step-up transformer is transferred to the subordinate EL emitter (7), so it is important not to miss this time but to output the next drive signal and connect the operation. A key point to maximize energy efficiency.
For example, when the next drive signal is output before “vertex” and the transistor is turned on (Turn On), the output energy of the step-up transformer going to the apex from that time is the moment when the transistor is turned on (Turn On). It will disappear with heat. In other words, energy efficiency is reduced.

Another point in the embodiment of the present invention is that the emitter current of the transistor is effectively the consumption current of the EL light emitter, so that the emitter current is sensed by the control unit, and this is added to the power supply voltage, so that the EL light emission is achieved. It can have the function of maintaining the body brightness at the required level.

The current flowing between the collector C and the emitter E of the transistors (2) and (3) eventually flows through the shunt resistor (4) to the ground. If a current flows through the shunt resistor (4), a potential difference is generated in one of the shunt resistors (4), and the value is A / D converted by the control unit (1). Is increased or decreased to adjust the luminance of the EL light emitter (7). In order to increase the luminance of the EL light emitter (7), the secondary coil voltage E01 of the step-up transformer (6) may be increased. To increase the secondary coil voltage E01 of the step-up transformer (6), the control unit (1 ) Increases the conduction times T_ON_A and T_ON_B of the transistors (2) and (3).

Conversely, in order to reduce the luminance of the EL light emitter (7), the secondary coil voltage E01 of the step-up transformer (6) may be reduced, but in order to reduce the secondary coil voltage E01 of the step-up transformer (6). The control unit (1) reduces the conduction times T_ON_A and T_ON_B of the transistors (2) and (3).
The control unit (1) performs A / D conversion on the voltage value measured through the shunt resistor (4) in real time, converts it to a current consumption value, and calculates this to the power supply voltage. Power consumption: P = The width of the drive signal T_ON_A and the drive signal T_ON_B is adjusted so that the EI always becomes the same value, and the luminance of the EL light emitter is maintained at a necessary level.

  Since the EL light emitting circuit and the control method thereof according to the present invention increase the energy efficiency and maintain the luminance at a required level even when the power supply voltage fluctuates in the EL light emitting circuit, the inorganic EL light emitting body As the brightness of the battery is compensated for and the life of the battery reaches the end of its life, the brightness can be maintained at a constant level, which improves usability and saves resources. Therefore, the use of lighting fixtures using inorganic EL emitters with brightness compensation is possible. This contributes to the development of the technical field of lighting fixtures using inorganic EL light emitters.

1: Control unit (drive signal A, drive signal B, A / D conversion, control microprocessor).
2, 3, 9: transistor 4: shunt resistor 5: DC power supply 6: step-up transformers 61, 62, 64: primary coil 65 of the step-up transformer: base coils 63, 66: secondary coil 7 of the step-up transformer: EL light emitter 8: grounding (waveform measurement reference point)
10, 11: Bias resistor 12: Capacitor

JP-A-8-88081 JP-A-2-288187

Claims (2)

A step-up transformer that raises a low voltage to a high voltage when a current flows, a complementary transistor for driving the step-up transformer, and a control unit that outputs a drive signal necessary to operate the complementary transistor; An EL light emitting circuit that is lit by receiving an AC voltage input, a DC power source necessary for circuit operation, and a shunt resistor that converts a current flowing through the transistor into a voltage and returns it to the control unit. And
When charging the EL light emitter with the output voltage of the step-up transformer, the control unit tracks the gradient of the output voltage and determines the optimum viewpoint at the moment when the polarity of the voltage gradient is going to change in the opposite direction. Drive signal T_ON_A or T_ON_B, and
The controller senses an emitter current of the complementary transistor measured by the shunt resistor, calculates a power consumption value obtained by adding the emitter current to a power supply voltage, and adjusts the width of the drive signal T_ON_A or T_ON_B. The EL light emitting circuit is characterized in that the luminance of the EL light emitter can be maintained at a required level by changing the output voltage. When operating the complementary transistor for driving the step-up transformer, the timing of the drive signal output from the control unit to the complementary transistor tracks the output voltage gradient of the step-up transformer, and the polarity of the voltage gradient is reversed. 2. The method of controlling an EL light emitting circuit according to claim 1, wherein the control is performed at the moment of changing.