JP5047093B2 - Fluorescent lamp lighting device - Google Patents

Description

  The present invention relates to a lighting device for a hot cathode fluorescent lamp, and more particularly to a lighting device that realizes a dimming operation with a fixed inverter driving frequency required in a backlight lighting device for a liquid crystal display.

  In the liquid crystal display, a backlight for illuminating the liquid crystal panel from the back is required. Conventionally, it has been common to use a cold cathode fluorescent lamp having a long life as a backlight. However, a hot cathode fluorescent lamp is particularly useful for large displays because of the advantage that it can be operated more efficiently than a cold cathode fluorescent lamp. May be used.

  As a general method for lighting a hot cathode fluorescent lamp, a high frequency lighting method is used in which AC power is output from a DC power source by a current resonance type inverter to stabilize the lamp current.

  Regarding the dimming of the hot cathode fluorescent lamp, a method of controlling the lamp current by changing the drive frequency of the current resonance type inverter is general for general lighting applications. In addition, PWM dimming is also used to change the dimming level by repeating the lighting state and dimming state alternately according to the external dimming PWM signal and changing the time ratio (duty) of each state. Yes.

  In the backlight of the liquid crystal display, when the inverter driving frequency is changed, it interferes with the operating frequency of the liquid crystal panel, and thus problems such as screen flickering or generation of interference fringes occur.

  In order to avoid the above problem, the backlight inverter is required to be always driven at a constant frequency including the lighting state and the dimming state.

  In order to realize the dimming at the fixed frequency, for example, an inverter described in Patent Document 1 is used. This inverter is provided with various chopper circuit functions of step-up, step-up / step-down, and step-down, and the chopper circuit and the inverter circuit share a single switching element. In this inverter, although the drive frequency is fixed, the DC link voltage of the inverter can be controlled by changing the on-time duty of the switching element, and the lamp current can be controlled, that is, dimmed.

Japanese Patent No. 3261829

  In the hot cathode fluorescent lamp, thermoelectrons generated by applying a preheating current to the filament contribute to light emission. In the dimming of the hot cathode fluorescent lamp, unless the filament current is properly controlled as well as the lamp current, the lamp life is shortened due to filament damage. In particular, in PWM dimming that frequently repeats the lighting state and the dimming state, the control of the filament current is very important. Specifically, when reducing the lamp current during dimming, it is necessary to flow a sufficient filament current in order to stabilize the lamp current and reduce the burden on the filament during relighting. On the other hand, during normal lighting with a large lamp current, the lamp current preheats the filament to some extent, so the filament current may be small. Excessive filament current increases the filament loss due to evaporation of the emission applied to the filament. This leads to a decrease in luminous efficiency and a shortened lamp life. That is, it is necessary to control the filament current to be small when the lamp current is large and to increase the filament current when the lamp current is small.

  In the inverter described in Patent Document 1, a capacitor current is connected in parallel with the hot cathode fluorescent lamp to secure a path for filament current. At this time, if the duty of the switching element is changed during dimming and the DC link voltage of the inverter is lowered, the filament current becomes small as well as the lamp current. Conversely, if the DC link voltage of the inverter is increased during relighting, both the lamp current and the filament current will increase. That is, the filament current increases or decreases in contradiction to the appropriate control of the filament current described above, and as a result, the lamp life may be shortened due to damage to the filament.

  An object of the present invention is to provide a lighting device capable of appropriately controlling not only the lamp current but also the filament current when dimming a hot cathode fluorescent lamp at a fixed frequency. Specifically, the present invention provides a lighting device capable of increasing the filament current when reducing the lamp current in the dimming state and increasing the lamp current and decreasing the filament current when shifting to the lighting state again. .

A DC power supply, a first chopper circuit that generates a first DC link voltage by DC / DC conversion of the DC power supply voltage, and a first upper and lower arm that is a series body of two switching elements, the first DC link voltage is DC / a first inverter circuit for supplying a hot cathode fluorescent lamp AC conversion to a lamp lighting circuit having, a second chopper circuit for generating a first 2DC link voltage to DC / DC conversion of the DC power supply voltage, two a filament preheating circuit having a second inverter circuit for supplying a filament of hot cathode fluorescent lamp first 2DC link voltage having a second upper and lower arms are series body DC / AC conversion to the switching element, the first a chopper circuit and a first inverter circuit, together with a second chopper circuit and the second inverter circuit is driven at a fixed frequency, the first chopper circuit and the second chopper Comprising a control means for driving the on-time dut y obtained by inverting the circuit together, the.

  Also, one switching element in the first upper and lower arms of the first inverter circuit is shared as a boosting switching element or a step-up / down switching element of the first chopper circuit, and one of the switching elements in the second upper and lower arms of the second inverter circuit is shared. The switching element is shared as a step-up switching element or a step-up / step-down switching element of the second chopper circuit.

  The control means outputs a pulsed control signal for simultaneously turning on / off the upper switching element of the first upper and lower arms of the first inverter circuit and the lower switching element of the second upper and lower arms of the second inverter circuit. A signal output means; an inversion control signal output means for outputting an inversion control signal obtained by inverting the control signal for simultaneously turning on / off the lower switching element of the first upper and lower arms and the upper switching element of the second upper and lower arms; It has a control circuit for outputting a control signal to the control signal output means and the inverted control signal output means based on a dimming PWM signal given from a host device.

  Further, the control circuit of the control means outputs a pulsed control signal for switching the lighting state and the dimming state of the hot cathode fluorescent lamp based on the dimming PWM signal given from the host device, and the pulsed state in the lighting state The on-time duty in the dimming state is set smaller than the on-time duty of the control signal.

  Further, the first upper and lower arms of the first inverter circuit are provided with capacitors in parallel, the output terminals of the first upper and lower arms are provided with a resonance circuit composed of a resonance choke coil and a resonance capacitor, The capacitor connected in series and the primary winding of the transformer are connected in parallel, and the hot cathode fluorescent lamp is connected to the secondary winding of the transformer via the capacitor, and the output terminal of the first upper and lower arms and the DC power source And a choke coil for chopper and a diode connected in series.

  The second upper and lower arms of the second inverter circuit are provided with capacitors in parallel, and the output terminals of the second upper and lower arms are connected in series with the choke coil connected in series and the primary winding of the transformer in parallel. Comprises at least two secondary windings, to which the filament of the hot cathode fluorescent lamp is connected via a capacitor, and is connected in series between the output terminal of the second upper and lower arms and the DC power supply. It is characterized by comprising a choke coil for a chopper and a diode.

  Further, a capacitor connected in series is connected in parallel to the first upper and lower arms of the first inverter circuit, and the resonance choke coil and the primary of the transformer are connected between the output terminal of the first upper and lower arms and the connection point of the capacitor. A resonance circuit composed of a winding is provided, and the hot cathode fluorescent lamp is connected to the secondary winding of the transformer via a capacitor, and is connected in series between the output terminal of the first upper and lower arms and the DC power source. It is characterized by comprising a choke coil for a chopper and a diode.

  Furthermore, a series body of a capacitor and a diode is connected to the first upper and lower arms of the first inverter circuit, the lower switching element of the first upper and lower arms and both ends of the diode constitute an output terminal, and the output terminal is used for resonance. A resonance circuit including a choke coil and a resonance capacitor is provided. A capacitor connected in series and a primary winding of a transformer are connected in parallel to the resonance capacitor, and the secondary winding of the transformer is connected via a capacitor. The hot cathode fluorescent lamp is connected, and includes a chopper choke coil and a diode connected in series between a lower switching element and the DC power supply, and the chopper choke coil and the diode connected in series at an output terminal. And another diode connected in series.

  Further, a series body of a capacitor and a diode is connected to the second upper and lower arms of the second inverter circuit, the lower switching element of the second upper and lower arms and both ends of the diode constitute an output terminal, and the output terminals are connected in series. The choke coil and the primary winding of the transformer are connected in parallel, the transformer is provided with at least two secondary windings, and the filament of the hot cathode fluorescent lamp is connected to the secondary winding via a capacitor. In addition, a chopper choke coil and a diode connected in series are provided between the lower switching element and the DC power source, and another choke coil and a diode connected in series are connected in series to the output terminal. A diode is connected.

  According to the present invention, in dimming the hot cathode fluorescent lamp at a fixed frequency, the filament current is increased in accordance with the decrease in the lamp current, thereby preventing the lamp life from being shortened.

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

  FIG. 1 is a circuit diagram of a lighting device showing a first embodiment of the present invention. In the lighting device of FIG. 1, a lamp lighting circuit 200 and a filament preheating circuit 300 are connected in parallel to the DC power supply 100. An output terminal of the lamp lighting circuit 200 is connected to the hot cathode fluorescent lamp 101, and two output terminals of the filament preheating circuit 300 are connected to the filaments 102 and 103 of the hot cathode fluorescent lamp 101, respectively. In addition, based on the dimming PWM signal from the upper control system, the lamp lighting circuit 200 and the single control means 400 that generates the gate signal of the switching element in the filament preheating circuit 300 are provided. In FIG. 1, a power MOSFET is used as a switching element, but a transistor or an IGBT can also be used.

  The lamp lighting circuit 200 has a configuration of a SEPP current resonance type inverter circuit (first inverter circuit) having a step-up chopper function, and a choke coil 204, a diode 203, and a power MOSFET 202 are connected in series to the DC power source 100. Has been. A series body of a power MOSFET 201 and a smoothing capacitor 205 is connected between the drain and source of the power MOSFET 202, and these power MOSFETs 201 and 202 operate as upper and lower arms of the inverter. The power MOSFET 202 serves as both a boost chopper switch and an inverter lower arm switch. A series body of a resonance choke coil 206 and a resonance capacitor 207 is also connected between the drain and source of the power MOSFET 202. Connected between terminals of the resonance capacitor 207 are a primary winding 210 of a transformer 209 and a series body of a capacitor 208 for removing a DC component from a current flowing therethrough. Connected between terminals of the secondary winding 211 of the transformer 209 is a series structure of a hot cathode fluorescent lamp 101 and a capacitor 212 for removing a DC component from a current flowing therethrough.

  Next, like the lamp lighting circuit 200, the filament preheating circuit 300 has a configuration of a SEPP inverter circuit (second inverter circuit) having a boost chopper function, and the power MOSFET 302 includes a boost chopper switch and an inverter lower arm. It plays the role of both switches. A choke coil 304, a diode 303, and a power MOSFET 302 are connected to the DC power source 100 in series. A series body of a power MOSFET 301 and a smoothing capacitor 305 is connected between the drain and source of the power MOSFET 302, and these power MOSFETs 301 and 302 operate as upper and lower arms of the inverter. A series body of a choke coil 306 and a primary winding 308 of a transformer 307 is also connected between the drain and source of the power MOSFET 302. It is possible to use the leakage inductance of the transformer 307 as the inductance of the choke coil 306. In this case, the choke coil 306 is unnecessary. The transformer 307 has two secondary windings 309 and 310. Between the terminals of the secondary winding 309, the filament 103 of the hot cathode fluorescent lamp 101 and a capacitor for removing a DC component from the current flowing therethrough. 311 is connected in series, and between the terminals of the secondary winding 310, the filament 102 of the hot cathode fluorescent lamp 101 and a capacitor 312 for removing a DC component from the current flowing therethrough are connected in series. ing.

  The control unit 400 includes a control circuit 401, a control signal output unit A, and an inverted control signal output unit B. The control circuit 401 only outputs a pulse-shaped control signal having a fixed frequency based on a dimming PWM signal from a host control device such as a computer. The control signal output means A has a driver 403 for receiving a control signal from the control circuit 401 and outputting a gate signal for driving the power MOSFET 201 and a driver 406 for outputting a gate signal for driving the power MOSFET 302.

  On the other hand, the inversion control signal output means B includes an inverter 402 that inverts the branched control signal to generate an inversion control signal, and a driver 404 that receives the inversion control signal and outputs a gate signal for driving the power MOSFET 202. And a driver 405 for outputting a gate signal for driving the power MOSFET 301.

FIG. 2 is an operation waveform diagram showing the operation waveforms of the circuit of FIG. 1 divided into a normal lighting state (a) and a dimming state (b). Here, as the positive / negative of the current in FIG. 2, the current flowing from top to bottom or from left to right in each element in FIG. 1 is positive. Next, the operation will be described in the order of the lamp lighting circuit 200, the filament preheating circuit 300, and the dimming control, using the operation waveforms of FIG.
[Lamp lighting circuit]
The lamp lighting circuit 200 operates as a boost chopper in the following manner. When the upper arm power MOSFET 201 is turned off and the lower arm power MOSFET 202 is turned on, initially, a current flows through the path of the DC power supply 100, the choke coil 204, the diode 203, the choke coil 206, and the capacitor 207. Energy is stored. The current flowing through the choke coil 204 increases almost linearly as shown in FIG. Thereafter, when the current flowing through the choke coil 204 becomes larger than the circulating current flowing through the choke coil 206, the current flowing through the choke coil 204 flows through the DC power supply 100, the choke coil 204, the diode 203, and the power MOSFET 202 while changing the path. Further, energy is continuously stored in the choke coil 204.

  After that, when the power MOSFET 202 is turned off and the upper-arm power MOSFET 201 is turned on, current flows through the path of the DC power supply 100, the choke coil 204, the diode 203, the power MOSFET 201, and the smoothing capacitor 205 by the energy stored in the choke coil 204. The smoothing capacitor 205 is charged. From FIG. 2, it can be confirmed that the current flowing through the choke coil 204 starts to decrease, and the current starts flowing in the power MOSFET 201 in the negative direction. Thereafter, when the polarity of the current flowing through the choke coil 206 is reversed, the current flowing through the choke coil 204 is added to the path of the DC power supply 100, the choke coil 204, the diode 203, the choke coil 206, and the capacitor 207 in addition to the path that has been flowing so far. Will also shunt.

  Next, when the current flowing through the choke coil 204 decreases and becomes equal to the current flowing through the choke coil 206, the smoothing capacitor 205 starts discharging, and the DC power source 100, choke coil 204, diode 203, choke coil 206, Current flows only through the path of the capacitor 207. By repeating the above switching operation at a constant frequency, an operation as a step-up chopper is performed, and the smoothing capacitor 205 is charged with a high voltage. By controlling the on-time duty of the power MOSFETs 201 and 202 by the control circuit 401, the voltage across the smoothing capacitor 205 can be controlled.

  By alternately turning on and off the power MOSFETs 201 and 202 as described above, the lamp lighting circuit 200 operates as a current resonance type SEPP inverter in which the voltage between the terminals of the smoothing capacitor 205 is a DC link voltage.

  When the power MOSFET 201 is turned on while the power MOSFET 202 is off, initially, a reflux current flows through the path of the choke coil 206, the power MOSFET 201, the smoothing capacitor 205, and the capacitor 207 by the energy stored in the choke coil 206. This can be confirmed from the polarity of the current flowing through the choke coil 206 and the power MOSFET 201 in FIG.

  After the energy is released from the choke coil 206, a resonance current flows through the path of the smoothing capacitor 205, the power MOSFET 201, the choke coil 206, and the capacitor 207, and energy is stored in the choke coil 206 again. This can be confirmed from the fact that the polarity of the current flowing through the choke coil 206 and the power MOSFET 201 in FIG. 2 changes during the ON period of the power MOSFET 201.

  When the power MOSFET 201 is turned off and the power MOSFET 202 is turned on, initially, a reflux current flows through the path of the choke coil 206, the capacitor 207, and the power MOSFET 202 by the energy stored in the choke coil 206. This circulating current charges the capacitor 207, and the energy of the choke coil 206 moves to the capacitor 207.

  Thereafter, a circulating current flows through the path of the capacitor 207, the choke coil 206, and the power MOSFET 202 due to the energy stored in the capacitor 207. This can be confirmed from the fact that the polarity of the current flowing through the choke coil 206 and the power MOSFET 202 in FIG. 2 changes during the ON period of the power MOSFET 202.

As the lamp lighting circuit 200 operates as a current resonance type inverter in the manner described above, a voltage is generated in the capacitor 207, and an alternating current flows through the capacitor 208 to the primary winding 210 of the transformer 209. This current induces a voltage in the secondary winding 211 of the transformer 209, so that an alternating lamp current flows through a closed circuit including the secondary winding 211, the capacitor 212, and the fluorescent lamp 101, and the fluorescent lamp 101 is stably lit. Keep state. Since the lamp lighting circuit 200 operates at a fixed frequency, the magnitude of the lamp current is controlled by the on-time duty of the power MOSFETs 201 and 202, that is, the DC link voltage of the inverter.
[Filament preheating circuit]
The filament preheating circuit 300 operates as a step-up chopper in the same manner as the lamp lighting circuit 200 and charges the smoothing capacitor 305 with a high voltage. The terminal voltage of the smoothing capacitor 305 can be controlled by the on-time duty control of the power MOSFETs 301 and 302.

  The filament preheating circuit 300 operates as a SEPP inverter in which the voltage between the terminals of the smoothing capacitor 305 is a DC link voltage by the on / off operation of the power MOSFETs 301 and 302. When the power MOSFET 301 is on, a current flows through a closed circuit composed of the smoothing capacitor 305, the power MOSFET 301, the choke coil 306, and the primary winding 308 of the transformer 307. When the power MOSFET 302 is on, the choke coil 306, power A current flows in a closed circuit composed of the primary winding 308 of the MOSFET 302 and the transformer 307.

A voltage is generated in each of the two secondary windings 309 and 310 of the transformer 307 by the current flowing through the primary winding 308 of the transformer 307, and the filament 103 of the secondary winding 309, the capacitor 311, and the hot cathode fluorescent lamp 101. And the filament 102 and 103 are preheated by the alternating filament current flowing through the closed circuit comprising the secondary winding 310, the capacitor 312, and the closed circuit comprising the filament 102 of the hot cathode fluorescent lamp 101, respectively. Since the driving frequency of the filament preheating circuit 300 is always fixed to the same frequency as that of the lamp lighting circuit 200, the magnitude of the filament current is controlled by the on-time duty of the power MOSFETs 301 and 302, that is, by the DC link voltage of the inverter. .
[Lamp dimming control]
Next, the dimming of the hot cathode fluorescent lamp at a fixed frequency will be described while comparing the (a) lighting state and (b) dimming state of FIG.

  As already described, all the power MOSFETs included in the lamp lighting circuit 200 and the filament preheating circuit 300 are always driven at a constant frequency regardless of the lighting state and the dimming state. Further, as can be seen from the control signal output means A, the inverted control signal output means B of the control means 400 shown in FIG. 1, and the gate signal of the power MOSFET shown in FIG. 2, the power MOSFETs 201 and 302 are simultaneously turned on or off, The power MOSFETs 202 and 301 are also turned on or off at the same time. That is, the power MOSFETs of the upper and lower arms in the lamp lighting circuit 200 and the filament preheating circuit 300 are driven at a duty ratio that is inverted with respect to each other.

  In the lighting state of FIG. 2A, the on-time duty of the power MOSFETs 202 and 301 is made larger than the on-time duty of the power MOSFETs 201 and 302. At this time, regarding the step-up chopper operation of the two circuits already described, the lamp lighting circuit 200 has a higher step-up ratio, whereby the DC link voltage of the inverter of the lamp lighting circuit 200 is also higher than that of the filament preheating circuit 300. By operating the two circuits in this manner, a large lamp current and a small filament current flow as shown in FIG. 2A, and the lamp maintains a stable lighting state.

  In the dimming state of FIG. 2B, the on-time duty of the power MOSFETs 201 and 302 is made larger than the on-time duty of the power MOSFETs 202 and 301, contrary to the lighting state. At this time, in the lamp lighting circuit 200, the step-up ratio is smaller than that in the lighting state, and the DC link voltage of the inverter is also lowered. On the other hand, in the filament preheating circuit 300, the step-up ratio is larger than that in the lighting state, thereby increasing the DC link voltage of the inverter. As a result, as shown in FIG. 2B, the lamp current decreases compared to the lighting state, and the filament current increases conversely.

  FIG. 3 shows (a) the inverter DC link voltage of each circuit and (b) the lamp current and the filament current when the power MOSFET 201 of the lamp lighting circuit 200 and the power MOSFET 302 of the filament preheating circuit 300 are changed with the same duty. FIG. 6 is a graph showing values normalized with a duty of 0.5 as 1. FIG. As shown in FIG. 3A, when the lighting state transitions to the dimming state, that is, when the on-time duty of the power MOSFETs 201 and 302 is changed from the small state to the large state, the lamp lighting circuit 200 uses the DC link voltage. It can be confirmed that the DC link voltage increases in the filament preheating circuit 300. As a result, as shown in FIG. 3 (b), the lamp current decreases and the filament current increases conversely.

  As shown in the waveform diagram of FIG. 4, PWM dimming is performed by switching the lighting state and dimming state by a dimming PWM signal provided to the control means 400 from the host controller. That is, the dimming level is controlled by the on-time duty of the dimming PWM signal.

  The frequency of the dimming PWM signal is several hundred Hz, which is sufficiently lower than the driving frequency of the two inverter circuits. When the dimming PWM signal is at the H level, the power MOSFETs 201, 202, 301, and 302 in the two inverter circuits are driven with the on-time duty as the lighting state when the dimming PWM signal is at the L level and the dimming state when the L level. . This can be achieved simply by the control circuit 401 in the control means 400 in the dimming state by increasing the ON time duty of the control signal compared to the lighting state.

  With the above operation, in the dimming of the hot cathode fluorescent lamp at a fixed frequency, the filament current is kept small in the lighting state, that is, the lamp current is large, and the filament current is dimmed in the dimming state, that is, the lamp current is small. Can be increased. By controlling the filament current during dimming in this way, the life of the lamp can be extended. Moreover, since the power MOSFET is shared between the boost chopper and the inverter in the two inverter circuits, and only one control circuit is required for the two inverter circuits, the cost is reduced by reducing the number of components, and Space saving can be realized.

  FIG. 5 is a lighting device showing a second embodiment of the present invention. 5 is different from the first embodiment in that a lamp lighting circuit 220 shown in FIG. 5 is connected in place of the lamp lighting circuit 200. The filament preheating circuit 300 is the same as that shown in FIG. Further, although not shown in FIG. 5, the same control means 400 as that shown in FIG. 1 is separately provided.

  The lamp lighting circuit 220 connects the primary winding 210 of the transformer 209 between the choke coil 206 and the capacitor 207, and the smoothing capacitor 205 between the connection point of the primary winding 210 and the capacitor 207 and the drain of the power MOSFET 201. It is the circuit which connected. As the inductance of the choke coil 206, the leakage inductance of the transformer 209 can be used. In this case, the choke coil 206 is unnecessary.

The lighting device shown in FIG. 5 operates in the same manner as the lighting device shown in FIG. 1 except for the lamp lighting circuit 220 described above. Hereinafter, only the operation of the lamp lighting circuit 220 will be described. The circuit operation described below can also be confirmed from the operation waveform shown in FIG. Here, as the positive / negative of the current in FIG. 6, the current flowing from top to bottom or from left to right in each element in FIG. 1 or FIG. 5 is positive.
[Lamp lighting circuit]
The lamp lighting circuit 220 operates as a boost chopper in the same manner as the lamp lighting circuit 200 described above. When the power MOSFET 202 is turned on while the power MOSFET 201 is turned off, first, a current flows through the path of the DC power supply 100, the choke coil 204, the diode 203, the choke coil 206, the primary winding 210 of the transformer 209, and the capacitor 207. Energy is stored in the coil 204.

  After that, when the current flowing through the choke coil 204 becomes larger than the circulating current flowing through the choke coil 206, the current flowing through the choke coil 204 changes its path to the DC power source 100, the choke coil 204, the diode 203, and the power MOSFET 202. And continue to store energy in the choke coil 204.

  When the power MOSFET 202 is turned off and the power MOSFET 201 is turned on, current flows through the path of the DC power supply 100, the choke coil 204, the diode 203, the power MOSFET 201, the smoothing capacitor 205, and the capacitor 207 by the energy stored in the choke coil 204, The capacitor 205 is charged.

  After that, when the polarity of the current flowing through the choke coil 206 is reversed, the current flowing through the choke coil 204 is added to the path that has been flowing up to that point, one of the DC power supply 100, the choke coil 204, the diode 203, the choke coil 206, and the transformer 209. The current is also diverted to the path of the next winding 210 and the capacitor 207.

  When the current flowing through the choke coil 204 decreases and becomes equal to the current flowing through the choke coil 206, the smoothing capacitor 205 starts discharging, and the DC power supply 100, choke coil 204, diode 203, choke coil 206, transformer Current flows only through the path of the primary winding 210 and the capacitor 207 of 209. By repeating the above switching operation at a constant frequency, an operation as a step-up chopper is performed, and the smoothing capacitor 205 is charged with a high voltage. The terminal voltage of the smoothing capacitor 205 can be controlled by the on-time duty control of the power MOSFETs 201 and 202.

  By alternately turning on and off the power MOSFETs 201 and 202 as described above, the lamp lighting circuit 220 operates as a current resonance type SEPP inverter in which the voltage between the terminals of the smoothing capacitor 205 is a DC link voltage.

  When the power MOSFET 202 is turned on while the power MOSFET 202 is off, initially, the energy stored in the choke coil 206 is used in the path of the choke coil 206, the power MOSFET 201, the smoothing capacitor 205, and the primary winding 210 of the transformer 209. A reflux current flows. After the energy is released from the choke coil 206, a current flows through the path of the smoothing capacitor 205, the power MOSFET 201, the choke coil 206, and the primary winding 210 of the transformer 209, and the energy is stored in the choke coil 206 again.

  The current path at this time does not include the resonance capacitor 207. Therefore, the current flowing through the choke coil 206 is not a resonance current but continues to increase.

  When the power MOSFET 201 is turned off and the power MOSFET 202 is turned on, initially, the circulating current flows through the choke coil 206, the primary winding 210 of the transformer 209, the capacitor 207, and the power MOSFET 202 by the energy stored in the choke coil 206. Flows. This circulating current charges the capacitor 207, and the energy of the choke coil 206 moves to the capacitor 207. Thereafter, a resonance current flows through the path of the capacitor 207, the primary winding 210 of the transformer 209, the choke coil 206, and the power MOSFET 202 by the energy stored in the capacitor 207.

  As described above, the lamp lighting circuit 220 operates as a current resonance type inverter, and an alternating current flows through the primary winding 210 of the transformer 209, whereby a voltage is induced in the secondary winding 211 of the transformer 209. As a result, an alternating lamp current flows through a closed circuit composed of the secondary winding 211, the capacitor 212, and the fluorescent lamp 101, and the fluorescent lamp 101 maintains a stable lighting state. Since the lamp lighting circuit 220 operates at a fixed frequency, the magnitude of the lamp current is controlled by the on-time duty of the power MOSFETs 201 and 202, that is, by the DC link voltage of the inverter.

  In addition to the above-described operation of the lamp lighting circuit 220, the filament lighting circuit 300 and the control means 400 operate in the same manner as in the first embodiment, thereby adjusting the hot cathode fluorescent lamp at a fixed frequency as shown in FIG. Light can be used, and the same effect as in the first embodiment can be obtained.

  As already described, in the lamp lighting circuit 220, when the power MOSFET 201 is on, the current flowing through the choke coil 206 is not a resonance current but continues to increase in the positive direction defined by FIG. That is, no matter how much the on-time duty of the power MOSFET 201 is increased, the polarity of the current flowing through the choke coil 206 is not reversed negatively, that is, the current resonance type inverter does not operate in the phase advance mode. Accordingly, it is possible to prevent a large reverse recovery current from flowing through the parasitic diode of the power MOSFET 201 and increase the switching loss in a dimming state in which the on-time duty of the power MOSFET 201 is particularly large.

  On the other hand, since the on-time duty of the power MOSFET 202 becomes large in the lighting state, the current flowing through the resonance choke coil 206 may change its polarity to positive again. In this case, a general current resonance type inverter operates in a phase advance mode, and a current flows through a parasitic diode of the power MOSFET 202. As a result, when the power MOSFET 201 is turned on, a large reverse recovery current flows and switching loss increases.

  However, in this embodiment, even if the polarity of the current flowing through the choke coil 206 becomes positive again, the current flowing through the choke coil 204 is shunted to the choke coil 206 and the power MOSFET 202, so that a current flows through the parasitic diode of the power MOSFET 202. Will not flow.

  FIG. 7 shows a lighting device according to a third embodiment of the present invention. 7 is different from the first embodiment in that a lamp lighting circuit 230 and a filament preheating circuit 330 are connected in place of the lamp lighting circuit 200 and the filament preheating circuit 300, respectively. Further, a lighting device using only one of the lamp lighting circuit 230 or the filament preheating circuit 330 instead of the lamp lighting circuit 200 or the filament preheating circuit 300 is also conceivable as an embodiment of the present invention. Although not shown in FIG. 7, the same control means 400 as that shown in FIG. 1 is provided.

  The lamp lighting circuit 230 has a configuration of a SEPP current resonance type inverter having a step-up / step-down chopper function, and the power MOSFET 202 serves as both a step-up / step-down chopper switch and an inverter lower arm switch. Connected to the DC power supply 100 are a series body of a choke coil 204, a diode 203, and a power MOSFET 202, and a series body of a diode 231 and a diode 232, respectively. At this time, the cathode of the diode 231 is connected to the + side of the DC power supply 100, and the anode of the diode 232 is connected to the − side of the DC power supply 100.

  Between the drain of the power MOSFET 202 and the cathode of the diode 232, a series body of the power MOSFET 201 and the smoothing capacitor 205 and the diode 233 are connected. A series body of a resonance choke coil 206 and a resonance capacitor 207 is also connected to the diode 233.

  Connected between terminals of the resonance capacitor 207 are a primary winding 210 of a transformer 209 and a series body of a capacitor 208 for removing a DC component from a current flowing therethrough. Connected between terminals of the secondary winding 211 of the transformer 209 is a series structure of a hot cathode fluorescent lamp 101 and a capacitor 212 for removing a DC component from a current flowing therethrough.

  Similar to the lamp lighting circuit 230, the filament preheating circuit 330 has a SEPP inverter configuration having a step-up / step-down chopper function, and the power MOSFET 302 serves as both a boost chopper switch and an inverter lower arm switch. .

  Connected to the DC power supply 100 are a series body of a choke coil 304, a diode 303, and a power MOSFET 302, and a series body of a diode 331 and a diode 332, respectively. At this time, the cathode of the diode 331 is connected to the + side of the DC power supply 100, and the anode of the diode 332 is connected to the − side of the DC power supply 100. Between the drain of the power MOSFET 302 and the cathode of the diode 332, a series body of the power MOSFET 301 and the smoothing capacitor 305 and the diode 333 are connected. A series body of the choke coil 306 and the primary winding 308 of the transformer 307 is also connected to the diode 333.

  Note that the leakage inductance of the transformer 307 can be used as the inductance of the choke coil 306. In this case, the choke coil 306 is unnecessary. The transformer 307 has two secondary windings 309 and 310. Between the terminals of the secondary winding 309, the filament 103 of the hot cathode fluorescent lamp 101 and a capacitor for removing a DC component from the current flowing therethrough. 311 is connected in series, and between the terminals of the secondary winding 310, the filament 102 of the hot cathode fluorescent lamp 101 and a capacitor 312 for removing a DC component from the current flowing therethrough are connected in series. ing.

  The power MOSFETs 201, 202, 301, and 302 included in the lamp lighting circuit 230 and the filament preheating circuit 330 are driven at a fixed frequency by control means (not shown) as in the first and second embodiments.

FIG. 8 shows operation waveforms of the circuit shown in FIG. 7 divided into a normal lighting state (a) and a dimming state (b). Here, as the positive / negative of the current in FIG. 8, the forward direction is assumed for the diode, and the current flowing from top to bottom or from left to right in FIG. 7 is positive for the other elements. The operation will be described in the order of the lamp lighting circuit 230 and the filament preheating circuit 330 using the operation waveforms of FIG.
[Lamp lighting circuit]
The lamp lighting circuit 230 operates as a step-up / down chopper in the following manner. When the power MOSFET 202 is turned on while the power MOSFET 201 is off, a current flows through the path of the DC power supply 100, the choke coil 204, the diode 203, and the power MOSFET 202, and energy is stored in the choke coil 204.

  Thereafter, when the power MOSFET 202 is turned off and the power MOSFET 201 is turned on, current flows in the path of the choke coil 204, the diode 203, the power MOSFET 201, the smoothing capacitor 205, and the diode 231 by the energy stored in the choke coil 204, and the smoothing capacitor 205 To charge. From FIG. 8, it can be confirmed that the current flowing through the choke coil 204 starts decreasing, and at the same time, the current starts flowing in the power MOSFET 201 in the negative direction and the diode 231 in the forward direction.

  Thereafter, when the polarity of the current flowing in the choke coil 206 is reversed, the current flowing in the choke coil 204 is added to the paths of the choke coil 204, the diode 203, the choke coil 206, the capacitor 207, and the diode 231 in addition to the path that has been flowing so far. Will also shunt.

  When the current flowing through the choke coil 204 decreases and becomes equal to the current flowing through the choke coil 206, the smoothing capacitor 205 starts discharging, and the choke coil 204, the diode 203, the choke coil 206, the capacitor 207, and the diode 231. Current flows only through the path. By repeating the above switching operation at a constant frequency, the operation as a step-up / step-down chopper is performed, and the voltage between the terminals of the smoothing capacitor 205 can be controlled by the on-duty of the power MOSFETs 201 and 202.

  By alternately turning on and off the power MOSFETs 201 and 202 as described above, the lamp lighting circuit 230 operates as a current resonance type SEPP inverter in which the voltage between the terminals of the smoothing capacitor 205 is a DC link voltage.

  When the power MOSFET 202 is turned on while the power MOSFET 202 is turned off, initially, a reflux current flows through the path of the choke coil 206, the power MOSFET 201, the smoothing capacitor 205, and the capacitor 207 by the energy stored in the choke coil 206. This can be confirmed from the polarity of the current flowing through the choke coil 206 and the power MOSFET 201 in FIG.

  After the energy is released from the choke coil 206, a resonance current flows through the path of the smoothing capacitor 205, the power MOSFET 201, the choke coil 206, and the capacitor 207, and energy is stored in the choke coil 206 again. This can be confirmed from the fact that the polarity of the current flowing through the choke coil 206 and the power MOSFET 201 in FIG. 8 changes during the ON period of the power MOSFET 201.

  When the power MOSFET 201 is turned off and the power MOSFET 202 is turned on, initially, a reflux current flows through the path of the choke coil 206, the capacitor 207, and the diode 233 by the energy stored in the choke coil 206. From FIG. 8, it can be confirmed that current starts to flow through the diode 233 at the same time as the power MOSFET 202 is turned on. This circulating current charges the capacitor 207, and the energy of the choke coil 206 moves to the capacitor 207.

  Thereafter, a circulating current flows through the path of the capacitor 207, the choke coil 206, the power MOSFET 202, and the diode 232 due to the energy stored in the capacitor 207. From FIG. 8, it can be confirmed that during the ON period of the power MOSFET 202, the polarity of the current flowing through the choke coil 206 changes, and at the same time, the current starts flowing through the diode 232 and the current flowing through the power MOSFET 202 increases.

By operating the lamp lighting circuit 230 as a current resonance type inverter in the manner described above, a lamp current flows through the fluorescent lamp 101 in the same manner as the lamp lighting circuit 200, and the fluorescent lamp 101 maintains a stable lighting state. Since the lamp lighting circuit 230 operates at a fixed frequency, the magnitude of the lamp current is controlled by the on-time duty of the power MOSFETs 201 and 202, that is, by the DC link voltage of the inverter.
[Filament preheating circuit]
The filament preheating circuit 330 operates as a step-up / step-down chopper in the same manner as the lamp lighting circuit 230, and can control the voltage between the terminals of the smoothing capacitor 305 according to the on-time duty of the power MOSFETs 301 and 302.

  The filament preheating circuit 330 operates as a SEPP inverter using the voltage between the terminals of the smoothing capacitor 305 as a DC link voltage by the on / off operation of the power MOSFETs 301 and 302.

  When the power MOSFET 301 is on, a current flows through the path of the smoothing capacitor 305, the power MOSFET 301, the choke coil 306, and the primary winding 308 of the transformer 307. When the power MOSFET 302 is on, the choke coil 306, the power MOSFET 302 , Current flows through the path of the diode 332 and the primary winding 308 of the transformer 307, or the path of the choke coil 306, the primary winding 308 of the transformer 307, and the diode 333, respectively.

  By operating the filament preheating circuit 330 as an inverter in the manner described above, a filament current flows to the filaments 102 and 103 of the fluorescent lamp 101 via the two secondary windings 309 and 310 of the transformer 307, respectively. 102 and 103 are preheated.

Since the driving frequency of the filament preheating circuit 330 is always fixed to the same frequency as that of the lamp lighting circuit 230, the magnitude of the filament current is controlled by the on-time duty of the power MOSFETs 301 and 302, that is, by the DC link voltage of the inverter. .
[Dimming control of fluorescent lamp]
Next, dimming of the hot cathode fluorescent lamp at a fixed frequency will be described while comparing (a) the lighting state and (b) the dimming state of FIG.

  As already described, all the power MOSFETs included in the lamp lighting circuit 230 and the filament preheating circuit 330 are always driven at a constant frequency regardless of the lighting state and the dimming state. Further, as can be seen from the configuration of the control means 400 in FIG. 1 and the gate signal of the power MOSFET in FIG. 8, the power MOSFETs 201 and 302 are simultaneously turned on or off, and the power MOSFETs 202 and 301 are also simultaneously turned on or off. In other words, the power MOSFETs of the upper and lower arms in the lamp lighting circuit 230 and the filament preheating circuit 330 operate at duty ratios that are reversed with respect to each other.

  In the lighting state of FIG. 8A, the on-time duty of the power MOSFETs 202 and 301 is made larger than the on-time duty of the power MOSFETs 201 and 302. At this time, regarding the step-up / step-down chopper operation of the two circuits already described, the lamp lighting circuit 230 performs a step-up operation, and the filament preheating circuit 330 performs a step-down operation. As a result, the DC link voltage of the inverter is higher in the lamp lighting circuit 230 than in the filament preheating circuit 330. When the two circuits operate as described above, a lamp current and a filament current flow as shown in FIG. 8A, and the lamp maintains a stable lighting state.

  In the dimming state of FIG. 8B, the on-time duty of the power MOSFETs 201 and 302 is made larger than the on-time duty of the power MOSFETs 202 and 301, contrary to the lighting state. At this time, contrary to the lighting state, the lamp lighting circuit 230 performs a step-down operation, and the filament preheating circuit 330 performs a step-up operation.

  Therefore, in the lamp lighting circuit 230, the DC link voltage of the inverter is low, and in the filament preheating circuit 330, the DC link voltage of the inverter is high compared to the lighting state. As a result, as shown in FIG. 8B, the lamp current decreases compared to the lighting state, and the filament current increases conversely.

  In addition to the above circuit operation, the control means (not shown) operates in the same manner as in the first and second embodiments, so that the hot cathode fluorescent lamp can be dimmed at a fixed frequency as shown in FIG. Thus, the same effect as in the first embodiment can be obtained.

  FIG. 9 shows (a) the inverter DC link voltage of each circuit and (b) the lamp current and the filament current when the power MOSFET 201 of the lamp lighting circuit 230 and the power MOSFET 302 of the filament preheating circuit 330 are changed with the same duty. FIG. 6 is a graph showing values normalized with a duty of 0.5 as 1. FIG. From FIG. 9, it can be confirmed that when the duty of the power MOSFETs 201 and 302 is changed, the DC link voltage, the lamp current, and the filament current of each circuit change as in FIG.

  However, in FIG. 3 and FIG. 9, the change rates of the DC link voltage, the lamp current, and the filament current are different when the duty is changed by the same amount. This is because, in FIG. 3, that is, in the first embodiment, two inverters have a boost chopper function, whereas in FIG. 9, that is, in the third embodiment, two inverter circuits have a step-up / step-down chopper function. Therefore, by using the lamp lighting circuit 230 and the filament preheating circuit 330 in place of the lamp lighting circuit 200 and the filament preheating circuit 300, the increase / decrease of the lamp current and the filament current with respect to the change of the duty can be adjusted in a wide range according to the circuit requirements. can do.

It is a circuit diagram in the 1st example of the present invention. It is an operation | movement waveform diagram of the circuit in the 1st Example of this invention. It is a graph showing the operation | movement of the circuit in 1st Example of this invention. It is a wave form diagram showing PWM dimming operation of the circuit in the 1st example of the present invention. It is a circuit diagram in the 2nd example of the present invention. It is an operation | movement waveform diagram of the circuit in the 2nd Example of this invention. It is a circuit diagram in the 3rd example of the present invention. It is an operation | movement waveform diagram of the circuit in the 3rd Example of this invention. It is a graph showing the operation | movement of the circuit in the 3rd Example of this invention.

Explanation of symbols

100: DC power supply 101: Hot cathode fluorescent lamp 102, 103: Hot cathode fluorescent lamp filament 200, 220, 230: Lamp lighting circuit 201, 202, 301, 302: Switching element 203, 231, 232, 233, 303, 331 332, 333: Diodes 204, 206, 304, 306: Choke coils 205, 207, 208, 212, 305, 311, 312: Capacitors 209, 307: Transformers 210, 308: Transformer primary windings 211, 309, 310 : Transformer secondary winding 300, 330: Filament preheating circuit 400: Control means 401: Control circuit 402: Inverter A: Control signal output means B: Inversion control signal output means 403, 404, 405, 406: Gate driver

Claims (10)

A DC power source, a first chopper circuit for generating a first 1DC link voltage to DC / DC conversion of the DC power supply voltage, the first 1DC link voltage has a first upper and lower arms in series of two switching elements a first inverter circuit for supplying a hot cathode fluorescent lamp converts DC / AC, and a lamp lighting circuit having,
A second chopper circuit for generating a first 2DC link voltage to DC / DC conversion of the DC power supply voltage, a DC / AC two of said first 2DC link voltage has a second upper and lower arms in series unit of a switching element a filament preheating circuit having a second inverter circuit to be supplied to the filament of the hot cathode fluorescent lamp conversion to,
The first chopper circuit and the first inverter circuit, wherein with the second chopper circuit and the second inverter circuit is driven at a fixed frequency, the first chopper circuit and the second chopper circuit inverted on time dut y together in fluorescent lamp lighting apparatus characterized by comprising a control means for driving.   2. The fluorescent lamp lighting device according to claim 1, wherein one switching element in the first upper and lower arms of the first inverter circuit is shared as a boosting switching element or a step-up / down switching element of the first chopper circuit, The fluorescent lamp lighting device characterized in that one switching element in the second upper and lower arms of the second inverter circuit is shared as a boosting switching element or a step-up / down switching element of the second chopper circuit. 3. The fluorescent lamp lighting device according to claim 1, wherein the control means includes an upper switching element of a first upper and lower arm of the first inverter circuit and a lower switching element of a second upper and lower arm of the second inverter circuit. Control signal output means for outputting a pulse-like control signal for simultaneously turning on and off, and the control signal for simultaneously turning on and off the lower switching element of the first upper and lower arms and the upper switching element of the second upper and lower arms. the inverted control signal output means for outputting the inverted control signal obtained by inverting a control circuit on the basis of the PWM signal given dimming from the host device, outputs a control signal to said control signal output means and the inverted control signal output means , fluorescent lamp lighting apparatus characterized by having.   4. The fluorescent lamp lighting device according to claim 3, wherein the control circuit of the control means switches the lighting state and dimming state of the hot cathode fluorescent lamp based on a dimming PWM signal provided from a host device. The fluorescent lamp lighting device is characterized in that the on-time duty in the dimming state is set smaller than the on-time duty of the pulsed control signal in the lighting state.   5. The fluorescent lamp lighting device according to claim 1, wherein a capacitor is provided in parallel with the first upper and lower arms of the first inverter circuit, and a resonance choke is provided at an output terminal of the first upper and lower arms. A resonance circuit including a coil and a resonance capacitor is provided, and a capacitor connected in series and a primary winding of the transformer are connected in parallel to the resonance capacitor, and a secondary winding of the transformer is connected via a capacitor. A fluorescent lamp lighting device comprising: a hot-cathode fluorescent lamp; and a chopper choke coil and a diode connected in series between an output terminal of the first upper and lower arms and the DC power source.   5. The fluorescent lamp lighting device according to claim 1, wherein a capacitor is provided in parallel with the second upper and lower arms of the second inverter circuit, and is connected in series with an output terminal of the second upper and lower arms. The choke coil and the primary winding of the transformer are connected in parallel, and the transformer has at least two secondary windings, and the filament of the hot cathode fluorescent lamp is connected to the secondary winding via a capacitor. A fluorescent lamp lighting device comprising a chopper choke coil and a diode connected in series between an output terminal of the second upper and lower arms and the DC power source.   5. The fluorescent lamp lighting device according to claim 1, wherein a capacitor connected in series is connected in parallel to the first upper and lower arms of the first inverter circuit, and an output terminal of the first upper and lower arms. And a connecting point of the capacitor, a resonance circuit comprising a resonance choke coil and a primary winding of the transformer is provided, and the hot cathode fluorescent lamp is connected to the secondary winding of the transformer via a capacitor A fluorescent lamp lighting device comprising a chopper choke coil and a diode connected in series between an output terminal of the first upper and lower arms and the DC power source.   5. The fluorescent lamp lighting device according to claim 1, wherein a series body of a capacitor and a diode is connected to the first upper and lower arms of the first inverter circuit, and the lower switching of the first upper and lower arms is performed. Both ends of the element and the diode constitute an output terminal, and the output terminal is provided with a resonance circuit including a resonance choke coil and a resonance capacitor. The resonance capacitor is connected in series with a primary of a capacitor and a transformer. Winding is connected in parallel, the hot-cathode fluorescent lamp is connected to the secondary winding of the transformer via a capacitor, and is connected in series between the lower switching element and the DC power supply A choke coil and a diode, and another one in series with the chopper choke coil and the diode connected in series to the output terminal. Diode fluorescent lamp lighting apparatus, characterized in that is connected.   5. The fluorescent lamp lighting device according to claim 1, wherein a series body of a capacitor and a diode is connected to the second upper and lower arms of the second inverter circuit, and lower switching of the second upper and lower arms. Both ends of the element and the diode constitute an output terminal, a choke coil connected in series and a primary winding of the transformer are connected in parallel to the output terminal, and the transformer includes at least two secondary windings, A filament of the hot cathode fluorescent lamp is connected to a secondary winding via a capacitor, and a chopper choke coil and a diode connected in series are provided between the lower switching element and the DC power source, and the output The terminal is connected with another diode in series with the choke choke coil and diode connected in series. Lighting device of the light lamp.   The fluorescent lamp provided with the lighting device of the fluorescent lamp of any one of Claim 1 thru | or 9.

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