TW201336343A - Led lighting device - Google Patents

Abstract

To provide an LED lighting device that efficiently suppresses a flicker by stably operating a phase control type dimmer. The LED lighting device having a rectification circuit for converting a phase-controlled AC supply voltage to a rectified voltage, a capacitor connected to a DC output of the rectification circuit via a diode to smooth the rectified voltage into a DC voltage, a DC-DC conversion circuit for converting the DC voltage to feed a light emitting diode (hereafter referred to as LED) load, and a current setting circuit for outputting a current setting value for the DC-DC conversion circuit on the basis of the rectified voltage includes: a variable resistance circuit connected to the DC output of the rectification circuit; and a resistance value setting circuit for varying a resistance value of the variable resistance circuit on the basis of the rectified voltage. The resistance value setting circuit is configured to increase the resistance value of the variable resistance circuit when the rectified voltage is higher than a desired reference voltage.

Description

Light-emitting diode lighting device

The present invention relates to an LED (Light Emitting Diode) lighting device.

LEDs are attracting attention as environmentally friendly light sources, and LED lighting is also being used as general lighting for homes or offices. Among the LED lighting, there is a bulb-shaped LED illumination, which has the same metal mouthpiece as the incandescent bulb, and is installed in an incandescent bulb device, and there is also a phase control mode dimmer (hereinafter abbreviated as a dimmer). The dimmer has long been used as a dimming method for incandescent bulbs.

Many dimmers are turned on and off between the AC power supply and the load by turning on and off the triode AC switch of the semiconductor component (TRIAC). After the three-pole AC switch is turned on (point arc), if there is no current that is larger than the specified current value (called holding current), it will be turned off again (extrude arc). Many dimmers are designed with the load as an incandescent bulb. If the load is an incandescent light bulb, the three-pole AC switch will remain in the ON state from the time when the three-pole AC switch is turned on until the zero point near the zero cross of the AC power source. . However, if the load is changed to the LED illumination of the LED, the current is smaller than that of the incandescent bulb. From the time when the three-pole AC switch is turned on until the time point near the zero crossing of the AC power source, the current is not large enough to keep the current large enough. Current, so before the zero crossing of the AC power supply, the phenomenon that the three-pole AC switch is turned off may be issued. Health. The phenomenon is hereinafter referred to as a false arc. In particular, in the case where the false arc suppression occurs randomly or when the time of the false arc suppression is uneven, the operation of the LED lighting device becomes unstable, and the lighting causes flicker.

As a means for solving the above problems, an LED lighting device can be considered which has a function of preventing a false arc extinction when a three-pole AC switch always flows a current higher than a holding current. As such an LED lighting device, for example, there is a device described in Patent Document 1. In this device, a DC-DC converter that supplies power to an LED is connected in parallel with a virtual load such as a constant current circuit, so that a current flows through the virtual load, thereby causing a current flowing through the three-pole AC switch to be larger than a holding current. Further, the current is caused to flow through the dummy load, and the timer circuit of the dimmer is reset, so that the three-pole AC switch that is turned OFF is turned on again.

[Previous Technical Literature] [Patent Literature]

[Patent Document 1] Japanese Patent Laid-Open Publication No. 2010-140824

In the technique described in Patent Document 1, by providing a dummy load, a current of a holding current or more is always distributed. In this way, although the above problems can be solved, the holding current varies depending on the dimmer, and many dimmers require a current of 30 mA or more to maintain the ON state of the three-pole AC switch. In particular, a circuit using a capacitor input method is used to constitute an LED lighting device. In the case, during the discharge of the smoothing capacitor, the input current becomes slightly zero, so that the current larger than the holding current needs to flow to the virtual load. Here, when the voltage effective value applied to the virtual load is 100V and the current flowing through the dummy load is 30 mA, the loss of the virtual load may be 3W. Most of the bulb-shaped LED lighting that has been commercialized consumes less than 10W of power. If this is considered, the virtual load will cause 3W loss, which is not ideal from the viewpoint of efficiency.

It is an object of the present invention to achieve an efficient LED lighting device that can stabilize the dimmer and suppress flicker.

In order to solve the above problem, an LED lighting device can be constructed, comprising: a rectifier circuit that converts a phase-controlled AC power source voltage into a rectified voltage; and a capacitor that is connected to a DC output of the rectifier circuit through a diode to rectify the rectifier The voltage is smoothed to generate a DC voltage; and a DC-DC conversion circuit converts the DC voltage to supply power to the LED (hereinafter referred to as LED) load; and a current setting circuit outputs the current of the DC-DC conversion circuit according to the rectified voltage The LED lighting device is characterized by comprising: a variable resistance circuit connected to the DC output of the rectifier circuit; and a resistance value setting circuit, wherein the resistance value of the variable resistance circuit can be made according to the rectified voltage The resistance value setting circuit increases the resistance value of the variable resistance circuit when the rectified voltage is higher than a required reference voltage.

According to the LED lighting device of the present invention, it is possible to realize an efficient LED lighting device which can stabilize the dimmer and suppress flicker.

Embodiments of the present invention will be described with reference to the drawings.

1 is a block diagram of an LED lighting device of the present invention. In Fig. 1, the LED lighting device of the present invention is counted from the rectifier circuit 102 to the right side. The rectifier circuit 102 rectifies the AC power supply voltage that is phase-controlled by the dimmer 101 to generate a rectified voltage. The DC output of the rectifier circuit 102 is connected to the capacitor 104 through the diode 103. The capacitor 104 smoothes the rectified voltage to generate a DC voltage. That is to say, the LED lighting device of the present embodiment is a circuit of a capacitor input mode. Thereby, the ripple of the DC voltage is reduced, and it becomes easy for the DC-DC conversion circuit 105 of the subsequent stage to suppress the ripple of the current flowing through the LED. The DC-DC conversion circuit 105 converts the DC voltage and supplies power to the LED load 106. Regarding the LED load 106, the number of LEDs or the connection form is not limited, and an LED module including a built-in protection element or the like may be included.

A variable resistance circuit 107 is connected to the DC output of the rectifier circuit 102. The resistance value setting circuit 108 outputs a resistance value setting signal in accordance with the rectified voltage to make the resistance value of the variable resistance circuit 107 variable. The variable resistance circuit 107 and the resistance value setting circuit 108 control the ON and OFF states of the three-pole AC switch of the dimmer 101 in response to the rectified voltage. It has the function of resetting the timer circuit of the dimmer 101 to turn the three-pole AC switch on again. The current setting circuit 109 outputs the current setting value of the DC-DC conversion circuit 105 in accordance with the rectified voltage. By the current setting circuit 109, LED current control corresponding to the operation of the dimmer 101, that is, dimming, can be performed.

Before explaining the specific operation, the dimmer 101 will be described. Fig. 2 is a schematic diagram showing the internal circuit of the dimmer 101 using the phase control method of the three-pole AC switch. As shown in FIG. 2, the three-pole AC switch 110 is connected between the AC power source 100 and the load 115. Further, in parallel with the three-pole AC switch 110, a resistor 111 and a series body of the variable resistor 112 and the capacitor 113, that is, a timer circuit, are connected. The connection point between the variable resistor 112 and the capacitor 113 is connected to the gate of the three-pole AC switch 110 through a Diode AC switch (DIAC) 114.

FIG. 3 shows the waveforms of the ON and OFF states of the three-pole AC switch 110, the load voltage, and the load current in the case where the incandescent bulb is connected as the load 115. During the ON period of the three-pole AC switch 110, the load voltage is almost the same as the voltage of the AC power source 100. Since the incandescent bulb is almost purely resistive, the waveform and voltage of the load current will be similar. Near the zero crossing of the AC power source 100, when the load current becomes smaller than the holding current of the three-pole AC switch 110, the three-pole AC switch 110 is turned off. In the OFF period of the three-pole AC switch 110, a small current flows from the AC power supply 100 to the path of the resistor 111, the variable resistor 112, the capacitor 113, and the load 115, and charges are accumulated in the capacitor 113. The impedance of the dimmer 101 is much larger than that of an incandescent bulb, so the load voltage is slightly zero. When capacitor 113 When the voltage rises and the two-pole AC switch 114 turns ON, the three-pole AC switch 110 is turned on again. If the resistance value of the variable resistor 112 is increased by the operation of the dimmer 101, the time required for the three-pole AC switch 110 to be turned on again becomes longer. As a result, the load power is reduced, and in the case of an incandescent light bulb, the light output is reduced.

In the present invention, the load 115 of Fig. 2 is the LED lighting device of Fig. 1, which is different from the characteristics of the incandescent bulb. In particular, the impedance is higher compared to incandescent bulbs and is not necessarily a pure resistance as an incandescent bulb. Therefore, the motion waveform is not necessarily the same as that of FIG.

4 is a view showing an example of the configuration of a variable resistance circuit 107 and a resistance value setting circuit 108 of the LED lighting device of the present invention. The resistance value setting circuit 108 is composed of the resistors 116 and 117, the comparator 118, and the DC voltage source 119. When the rectified voltage is higher than the required reference voltage, the resistance value setting signal that becomes the L level is output.

The variable resistor circuit 107 is composed of a resistor 120 and a series body of a switching element, that is, a MOSFET 122, and a resistor 121 connected in parallel to the series. The resistance value can be doubled by turning on and off the MOSFET 122. Alternatives to the MOSFET 122 may also use other types of switching elements such as bipolar transistors or IGBTs.

When the rectified voltage is higher than the reference voltage, the MOSFET 122 is turned OFF, the resistor 120 is isolated, and the resistance value of the variable resistor circuit 107 becomes high. Further, the resistance value of the variable resistance circuit 107 is not necessarily two kinds of values, and may be configured to continuously change by rectifying the voltage. In addition, the variable resistance circuit 107 and the resistance value can be realized by any of the actions described below. The specific configuration of the setting circuit 108 is not limited.

Fig. 5 is an operation waveform of the LED lighting device of the present invention, showing the waveforms of the rectified voltage, the direct current voltage, and the rectified current, and the resistance value of the variable resistance circuit 107. Here, the DC voltage is the voltage of the capacitor 104 as described above. The rectified current refers to the DC output current of the rectifying circuit 102, and is almost the same waveform as the rectified current flowing through the dimmer 101.

When the three-pole AC switch 110 is turned on, the rectified voltage rises to almost the same voltage level as the AC power source 100. Further, the rectified voltage becomes higher than the reference voltage, and the resistance value of the variable resistance circuit 107 increases. Further, since the current that charges the capacitor 104 flows from the AC power source 100 through the dimmer 101, the rectifier circuit 102, and the diode 103, the rectified current also increases sharply. The current that charges the capacitor 104 will decrease as the capacitor 104 is charged, the DC voltage rises, and the rectified current will gradually decrease.

When the DC voltage becomes the maximum value and the vicinity of the time point at which the capacitor 104 is completed (hereinafter, abbreviated as the completion of charging), the rectified current and the current flowing through the variable resistance circuit 107 almost coincide. At this point of time, the resistance value of the variable resistance circuit 107 is set in advance so that the rectified current becomes smaller than the required reference current. Further, if the reference current is set to be smaller than the holding current of the three-pole AC switch 110 in advance, the three-pole AC switch 110 is turned off. The holding current will vary with the dimmer, but it will also be 5 mA minimum. Therefore, if the reference current is set to less than 5 mA, the three-pole AC switch can be surely turned off at the completion of charging for almost all dimmers.

The resistance value of the variable resistance circuit 107 at this time is set based on the reference current and the maximum value of the rectified voltage that is assumed. For example, if the AC power supply voltage is used at 100Vac, the rectified voltage at the completion of charging is a maximum of 141V. Therefore, when the rectified voltage is 141V, the resistance value is set to be larger than 28.2kΩ (= 141V ÷ 5 mA), so that the rectified current is smaller than the reference current of 5 mA.

Of course, if the resistor 121 is not connected to the variable resistor circuit 107 of FIG. 4, when the rectified voltage is higher than the reference voltage, the variable resistor circuit 107 is turned off, and the charging is completed for almost all the dimmers. The three-pole AC switch can be reliably turned off. However, strictly speaking, the resistors 116 and 117 in the elements of the resistance value setting circuit 108 in FIG. 4 can also be considered as a part of the variable resistor circuit 107. For these reasons, the variable resistor circuit 107 is completely disconnected. Difficulties. Therefore, even in the case where the resistor 121 is not connected, the resistance values of the resistors 116 and 117 must be set in the above manner.

After the three-pole AC switch 110 is turned off, the rectified voltage will decrease as shown in FIG. At the time when the rectified voltage becomes lower than the reference voltage, the resistance value of the variable resistance circuit 107 is reduced. The AC power source 100 passes through the timer circuit of the dimmer 101 and the rectifier circuit 102 to cause a current to flow to the variable resistor circuit 107, resets the timer circuit, and turns the three-pole AC switch 110 back on. Further, even when the three-pole AC switch 110 is OFF, the DC-DC conversion circuit 105 is stably operated by the energy stored in the capacitor 104.

The subject of the LED lighting device to date is that each week of the AC power supply During the period, the situation of the three-pole AC switch accidentally arc-extinguishing and the situation that the arc-free arc is not accidentally occurs randomly, or the time of the false arc-extinguishing is uneven, and the action of the dimmer becomes unstable. In this way, if the operation of the dimmer becomes unstable, the LED load will flicker.

The countermeasure to date is to connect the virtual load to the DC output of the rectifier circuit to prevent the arc extinguishing of the three-pole AC switch, thereby making the dimmer stable. In this mode, if the current flowing through the virtual load is made larger, it is expected to be suitable for a wider variety of dimmers. However, it is not practical to consider the decrease in efficiency caused by the increase in the loss of the virtual load.

On the other hand, in the present invention, when the capacitor 104 is charged, that is, at the same time point, the three-pole AC switch 110 is intentionally turned off. In this manner, the dimmer 101 and the DC-DC conversion circuit 105 can also be stably operated to prevent flicker. In addition, the mode of the present invention is more efficient than the way in which a current that is larger than the holding current is circulated by the virtual load.

FIG. 6 shows another example of the variable resistance circuit 107 and the resistance value setting circuit 108. In the circuit of Fig. 6, the regulator circuit 126 is constituted by a resistor 123, a Zener diode 124, and a MOSFET 125. Alternatives to the MOSFET 125 may also use other types of semiconductor elements such as bipolar transistors. The regulator circuit 126 is a component of both the variable resistance circuit 107 and the resistance value setting circuit 108 of FIG. Therefore, the variable resistance circuit 107 and the resistance value setting circuit 108 are not distinguished by a broken line as shown in FIG.

The regulator circuit 126 is clamped to the desired voltage value as shown in FIG. Rectified voltage. The clamping voltage can be set by the Zener voltage of the Zener diode 124. The comparator 127 compares the output voltage of the regulator circuit 126 with a desired threshold to indirectly determine whether the rectified voltage is higher than the reference voltage. The threshold can be set by the voltage value of the DC voltage source 128. Further, the comparator 127 outputs a resistance value setting signal that becomes an L level when the rectified voltage is higher than the reference voltage. By lowering the level of the rectified voltage in advance by the regulator circuit 126, the comparison accuracy of the comparator 127 is not impaired even in the case where the reference voltage is a low number of V to tens of V.

The output of the regulator circuit 126 is connected in parallel with a resistor 129 and a switching element, that is, a series body of the MOSFET 131, and a resistor 130. Alternatives to the MOSFET 131 may also use other types of switching elements such as bipolar transistors or IGBTs. When the rectified voltage becomes higher than the reference voltage, the resistance value setting signal becomes the L level, and the MOSFET 131 turns OFF. The resistor 130 is isolated, and the resistance value of the variable resistor circuit 107 becomes high.

As shown in FIG. 7, when the rectified voltage is higher than the Zener voltage of the Zener diode 124, the output voltage of the regulator circuit 126 becomes almost equal to the Zener voltage. Further, when the MOSFET 131 is turned off, the current flowing through the variable resistance circuit 107 is a value determined by the Zener voltage and the resistor 130. Here, when the capacitor 104 is charged, if the rectified current is smaller than the reference current, the Zener voltage and the resistance value of the resistor 130 are determined so that the current value determined by the Zener voltage and the resistor 130 becomes a reference. The current is still small. When the reference current is 5 mA and the Zener voltage is 10 V, the resistance value of the resistor 130 is set to be 2 kΩ (=10 V ÷ 5 mA). Still big.

Fig. 8 specifically discloses the configuration of the rectifier circuit 102 and the DC-DC converter circuit 105 in the LED lighting device shown in Fig. 1. In Fig. 8, a full-wave rectifying circuit composed of a diode bridge 133 is equivalent to the rectifying circuit 102 of Fig. 1. Further, the diode 134, the switching element, that is, the MOSFET 135, the choke coil 136, the capacitor 137, the current detecting resistor 138, the control circuit 139, and the control circuit power supply circuit 140 are configured as a step-down section. The wave circuit is equivalent to the DC-DC conversion circuit 105 of FIG. Further, a resistor 132 for preventing inrush current is added, which is a component not shown in FIG. In addition to this, a fuse or a filter capacitor can be added. Depending on the voltage of the LED load 106, a buck-boost or a boost chopper can be used without using a buck chopper; in addition, a flyback converter can be used for insulation. Alternatives to the MOSFET 135 may also use other types of switching elements such as bipolar transistors or IGBTs.

In FIG. 8, the control circuit 139 controls the current output from the DC-DC conversion circuit 105 to the LED load 106 in accordance with the current set value. Specifically, a control may be considered in which MOSFET 135 is turned ON before the current flowing through MOSFET 135 reaches the current set value. The current flowing through the LED load 106 can be indirectly controlled by controlling the current flowing through the MOSFET 135. Such a control circuit 139 can be easily configured by using a commercially available LED control IC. Of course, it is also possible to combine a discrete component such as a comparator without using a control IC, or It is composed of software using a microcomputer or a digital signal processor.

The control circuit power supply circuit 140 is connected to the cathode of the diode 103, converts the DC voltage of the capacitor 104, and generates the power supply voltage of the control circuit 139. Specifically, the operating voltages of the control IC, the comparator, the operational amplifier, and the like in the control circuit 139 are generated. Although the wiring (connection) is omitted in FIG. 8, the control circuit power supply circuit 140 generates a power supply voltage such as the resistance value setting circuit 108 or the current setting circuit 109 as needed.

As shown in FIG. 9, a specific configuration of the control circuit power supply circuit 140 can be considered as a regulator circuit using the resistor 141, the Zener diode 142, and the MOSFET 143. Alternatives to MOSFET 143 may also use other types of components such as bipolar transistors. In addition to FIG. 9, other types of regulator circuits such as a 3-terminal regulator may be constructed.

Here, a configuration may be considered in which the control circuit power supply circuit 140 is connected to the anode of the diode 103, and converts the rectified voltage before the capacitor 104 is smoothed to generate a power supply voltage of the control circuit. For example, in the case where the variable resistance circuit 107 and the resistance value setting circuit 108 of FIG. 6 are to be formed, the output voltage of the regulator circuit 126 is smoothed, and the power supply voltage of the control circuit can be generated. However, in this case, when the capacitor 104 is charged, the rectified current is increased by the amount of current flowing through the control circuit power supply circuit 140, which violates the intention of making the rectified current smaller than the reference current. In other words, it is equivalent to reducing the resistance value of the variable resistance circuit 107 by the resistance value of the power supply circuit 140 for the control circuit. Therefore, in the LED lighting device of the present invention, such a configuration is not suitable.

On the other hand, if the power supply circuit for the control circuit is connected as shown in FIG. 140, the control circuit power supply circuit 140 is in a state of being isolated from the AC power supply 100 during the period from the completion of charging of the capacitor 104 to the charging of the capacitor 104 again, that is, during the discharge of the capacitor 104. That is, when the capacitor 104 is charged, the current flowing through the power supply circuit 140 for the control circuit does not increase the rectified current. Therefore, it can be said that it is an effective connection method that makes the rectified current smaller than the reference current.

In addition to the power supply circuit 140 for controlling the circuit as shown in FIG. 8, the voltage generated by the DC-DC conversion circuit 105 can be used to generate the power supply voltage of the control circuit. For example, a method of providing an auxiliary coil to the choke coil 136 can be considered. This method also converts the DC voltage of the capacitor 104 to generate the power supply voltage of the control circuit. This is the same as the method of FIG. 8, and the same effect can be achieved.

100‧‧‧AC power supply

101‧‧‧Dimmer

102‧‧‧Rectifier circuit

103, 134‧‧‧ diode

104, 113, 137‧‧ ‧ capacitor

105‧‧‧DC-DC converter circuit

106‧‧‧LED load

107‧‧‧Variable resistance circuit

108‧‧‧resistance setting circuit

109‧‧‧ Current setting circuit

110‧‧‧Three-pole AC switch

111, 116, 117, 120, 121, 123, 129, 130, 132, 138, 141 ‧ ‧ resistance

112‧‧‧Variable resistor

114‧‧‧2-pole AC switch

115‧‧‧load

118, 127‧‧‧ comparator

119, 128‧‧‧ DC voltage source

122, 125, 131, 135, 143‧‧‧ MOSFET

124, 142‧‧ ‧ Zener diode

126‧‧‧Regulator circuit

133‧‧ ‧ diode bridge

136‧‧‧Current coil

139‧‧‧Control circuit

140‧‧‧Power circuit for control circuit

Fig. 1 is a block diagram of an LED lighting device of the present invention.

[Fig. 2] An internal circuit diagram of a phase control mode dimmer.

[Fig. 3] An operation waveform when an incandescent bulb is connected to a phase control mode dimmer.

Fig. 4 is a view showing an example of the configuration of a variable resistance circuit and a resistance value setting circuit of the LED lighting device of the present invention.

Fig. 5 is a view showing an example of an operation waveform of the LED lighting device of the present invention.

Fig. 6 shows an example of the configuration of a variable resistance circuit and a resistance value setting circuit of the LED lighting device of the present invention.

[Fig. 7] Output voltage waveform of the regulator circuit.

Fig. 8 is a view showing an example of a specific circuit configuration of an LED lighting device of the present invention.

Fig. 9 is a power supply circuit for a control circuit of the LED lighting device of the present invention.

100‧‧‧AC power supply

101‧‧‧Dimmer

102‧‧‧Rectifier circuit

103‧‧‧ diode

104‧‧‧ capacitor

105‧‧‧DC-DC converter circuit

106‧‧‧LED load

107‧‧‧Variable resistance circuit

108‧‧‧resistance setting circuit

109‧‧‧ Current setting circuit

Claims (7)

An LED (Light Emitting Diode) lighting device comprising: a rectifying circuit that converts a phase-controlled AC power supply voltage into a rectified voltage; and a capacitor connected to a DC output of the rectifying circuit through a diode, the rectified voltage Smoothing to generate a DC voltage; and a DC-DC conversion circuit for converting the DC voltage to supply power to the LED load; and a current setting circuit for outputting a current setting value of the DC-DC conversion circuit according to the rectified voltage; the LED lighting device, The method is characterized in that: a variable resistance circuit is connected to the DC output of the rectifier circuit; and a resistance value setting circuit is configured to change a resistance value of the variable resistance circuit according to the rectified voltage; and the resistance value setting circuit is When the rectified voltage is higher than a required reference voltage, the resistance value of the variable resistance circuit is increased. The LED lighting device of claim 1, wherein the DC output current of the rectifier circuit is smaller than a required reference current when the capacitor is charged. The LED lighting device of claim 1 or 2, wherein the variable resistance circuit includes a series body of a resistor and a switching element, and the resistance value setting circuit is configured to be higher when the rectified voltage is higher than the reference voltage The aforementioned switching element is turned off. The LED lighting device of claim 3, wherein the series system is connected to a DC output of the rectifier circuit. For example, the LED lighting device of claim 3, wherein The resistor value setting circuit includes: a regulator circuit that clamps the rectified voltage with a desired voltage value; and a comparator that indirectly determines whether the rectified voltage is indirectly by comparing an output voltage of the regulator circuit with a required threshold value It is higher than the aforementioned reference voltage; the aforementioned series system is connected to the output of the aforementioned regulator circuit. The LED lighting device of claim 5, wherein the regulator circuit is provided with a resistor and a semiconductor element and a Zener diode, and clamps the aforementioned Zener voltage of the Zener diode Rectified voltage. The LED lighting device according to any one of claims 1 to 6, wherein the DC-DC conversion circuit includes: a control circuit that controls a current output to the LED load according to the current setting value; and a control circuit The power supply circuit converts the DC voltage to generate a power supply voltage of the control circuit, the resistance value setting circuit, and the current setting circuit.