JP4952973B2 - Discharge lamp lighting device and lighting apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a discharge lamp lighting device allowing a cumulative operation time of a high-frequency lighting device to be obtained and capable of correcting illuminance; and to provide a luminaire. <P>SOLUTION: This discharge lamp lighting device 1 is provided with: the high-frequency lighting device 2 for energizing a discharge lamp 3; a timer means 6 for cumulatively counting the operation time of the high-frequency lighting device; a nonvolatile storage means 7 for storing the cumulative operation time of the high-frequency lighting device cumulatively counted by the timer means; a dimming signal generation means 8 for generating a dimming signal based on the cumulative operation time and the cumulative operation time in the latest lamp replacement; and a control means 9 for controlling the high-frequency lighting device according to the dimming signal. <P>COPYRIGHT: (C)2006,JPO&amp;NCIPI

Description

The present invention relates to a discharge lamp lighting device and a lighting fixture having a dimming function.

In order to compensate for the decrease in light output due to aging of the discharge lamp and the decrease in light output due to contamination due to long-term use, the accumulated lighting time of the discharge lamp is measured after the replacement of the discharge lamp, and this accumulated lighting time is Lighting devices that increase the dimming level based on them are known. Each time the discharge lamp is replaced, the cumulative lighting time is reset. Here, there has been proposed an illumination device that detects the end of life of a discharge lamp and automatically resets the cumulative lighting time or manually resets the cumulative lighting time (see, for example, Patent Document 1).
Japanese Patent Laid-Open No. 2001-15276 (page 8, FIG. 14)

  Since the lighting device of Patent Document 1 only resets the cumulative lighting time of the discharge lamp each time the end of life of the discharge lamp is detected or each time the discharge lamp is replaced, the lighting device for the discharge lamp (Inverter device) may not be able to keep track of its life and may be used beyond that life. As a result, a malfunction may occur in the discharge lamp lighting device, and the discharge lamp may not exhibit predetermined electrical characteristics. In addition, the actual life of the discharge lamp lighting device cannot be grasped.

The present invention is a available a total operation time of the discharge lamp lighting device, and an object thereof is to provide a discharge lamp lighting device and a lighting fixture can be performed illuminance correction.

Invention of the lighting device according to claim 1, the discharge lamp a high-frequency lighting device for lighting a; timer means for cumulative counting the operation time of the high frequency lighting device and; cumulative operation time of the cumulative timed high frequency lighting device by timer means And a non-volatile storage means for storing a cumulative operation time when the latest discharge lamp is replaced; a difference between the cumulative operation time and a cumulative operation time when the latest discharge lamp is replaced; and a dimming signal based on the difference And a control means for controlling the high-frequency lighting device in accordance with the dimming signal.

In the present invention and each of the following inventions, each configuration is as follows unless otherwise specified. The operating time of the lighting device may be the lighting time of the discharge lamp . This is because when the lighting device is operating, it is considered that the discharge lamp is substantially lit. For example, when the switch of the discharge lamp lighting device is turned on, a timer circuit that manages the filament preheating time, the discharge time, and the lighting time operates to operate the lighting device.

In the filament preheating time, since the discharge lamp is not yet lit, the operating time of the high frequency lighting device and the lighting time of the discharge lamp are not exactly the same. However, the filament preheating time is several milliseconds, for example, a time that can be ignored with respect to the life time of the discharge lamp (12,000 hours). The operating time of the discharge lamp also means substantially the same thing. Furthermore, it can be considered that the operating time of the discharge lamp lighting device including the lighting device is substantially the same as the operating time of the lighting device and the lighting time of the discharge lamp.

  The dimming signal may be, for example, a rectangular wave voltage or a DC voltage.

  According to the present invention, the operation time of the lighting device is accumulated by the timing means and stored in the nonvolatile storage means. Further, during the operation of the lighting device, the difference between the cumulative operation time of the lighting device and the cumulative operation time at the latest lamp replacement is calculated, and a dimming signal based on the difference is generated, and according to the dimming signal The lighting device is controlled. Then, the dimming level of the lamp is changed by the dimming signal.

A discharge lamp lighting device according to a second aspect of the present invention is the discharge lamp lighting device according to the first aspect, wherein the dimming signal generating means compensates for the light flux that decreases in accordance with the discharge lamp lighting time. Based on this, the dimming signal is generated so as to increase the dimming level of the discharge lamp from the initial dimming level.

According to the invention, the dimming signal is generated so as to increase the dimming level of the discharge lamp from the initial dimming level based on the difference between the cumulative operation time of the lighting device and the cumulative operation time at the time of the latest discharge lamp replacement. Therefore, the lighting device increases the dimming level of the discharge lamp from the initial dimming level according to the operation time from when the discharge lamp is replaced. As a result, the light flux that decreases according to the lighting time of the discharge lamp is compensated.

Invention of the lighting device according to claim 3, in the discharge lamp lighting apparatus according to claim 1 or 2, wherein the discharge lamp connection detecting means for detecting a connection state between the high frequency lighting device and the discharge lamp; comprises a discharge When the lamp connection detecting means detects the disconnection between the high-frequency lighting device and the discharge lamp , the cumulative operation time of the high-frequency lighting device counted by the timing means is set to the cumulative operation time when the latest discharge lamp is replaced. It is characterized by that.

“The discharge lamp connection detecting means detects the disconnection between the lighting device and the discharge lamp ” includes not only replacement with a new discharge lamp but also cleaning of the discharge lamp and the lighting fixture. When the discharge lamp and the lighting fixture are cleaned, a predetermined brightness is ensured even if the dimming level of the discharge lamp is the initial dimming level. Further, by detecting the naturally disconnection discharge lamp connection detecting means that the lighting device and the discharge lamp, a discharge lamp replacement, even a discharge lamp removably in the discharge lamp cleaning can be detected.

According to the present invention, after the discharge lamp connection detecting means detects the disconnection between the lighting device and the discharge lamp , when the discharge lamp is connected to the lighting device, the dimming level of the discharge lamp is set to the lighting at the time of the connection. It is increased from the initial dimming level depending on the operating time of the device.

The invention of the lighting fixture according to claim 4 comprises the discharge lamp lighting device according to any one of claims 1 to 3; and the lighting fixture main body on which the discharge lamp lighting device is disposed. Lighting equipment characterized by

According to the present invention, the cumulative operation time of the lit devices with available, luminaire light beam decreases in accordance with the lighting time of the lamp each time the lamp replacement is corrected are provided.

According to the first aspect of the present invention, the cumulative operation time of the high-frequency lighting device can be obtained by reading the cumulative operation time of the high-frequency lighting device stored in the nonvolatile storage means. In addition, a dimming signal based on the difference between the cumulative operation time of the high frequency lighting device and the cumulative operation time at the time of the latest discharge lamp replacement is generated, and the high frequency lighting device is controlled according to the dimming signal. The high-frequency lighting device can perform illuminance correction according to the operation time after lamp replacement, and can obtain a substantially constant luminous flux from the discharge lamp .

According to the invention of claim 2, high frequency lighting device, since according to the operation time from the discharge lamp replacement increases the dimming levels of the discharge lamp from the initial dimming level, decreases according to the lighting time of the discharge lamp to be able to compensate for the light beam, up to the exchange of life or a discharge lamp of the discharge lamp, it is possible to obtain a substantially constant light flux from the discharge lamp.

According to the invention of claim 3, when the discharge lamp is connected to the high frequency lighting device, the dimming level of the discharge lamp is increased from the initial dimming level according to the operation time of the high frequency lighting device from the connection time. because, it is possible to compensate for the light beam decreases in accordance with the lighting time of the discharge lamp, it is possible to obtain a substantially constant light flux from the discharge lamp.

According to the invention of claim 4, it is possible to provide a lighting apparatus that can obtain the cumulative operation time of the high-frequency lighting device and can correct the light flux that decreases according to the lighting time of the discharge lamp .

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. First, a first embodiment of the present invention will be described. 1 to 3 show a first embodiment of the present invention, FIG. 1 is a block diagram including a partial circuit diagram of a discharge lamp lighting device, and FIG. 2 shows control of a dimming level of the discharge lamp. 2 (a) is a change diagram of the dimming level with respect to the cumulative operation time of the inverter circuit, FIG. 2 (b) is a change diagram of the dimming signal with respect to the cumulative operation time of the inverter circuit, and FIG. 3 is a dimming level of another discharge lamp. FIG. 3A is a variation diagram of the dimming level with respect to the cumulative operation time of the inverter circuit, and FIG. 3B is a variation diagram of the dimming signal with respect to the cumulative operation time of the inverter circuit.

  The discharge lamp lighting device 1 includes a high frequency lighting device 2, a fluorescent lamp 3 as a discharge lamp, a lamp connection detection circuit 4 as a lamp connection detection means, and a control circuit 5. The control circuit 5 includes a timer 6 as a timer, a nonvolatile memory 7 as a nonvolatile memory, a dimming signal generator 8 as a dimming signal generator, and a main controller as a controller. 9. In addition, a life detection circuit 10 that detects the end of life of the fluorescent lamp 3 is provided.

  The high-frequency lighting device 2 includes a rectifying / smoothing circuit 11, an active filter circuit 12, and an inverter circuit 13. The rectifying / smoothing circuit 11 rectifies and smoothes the AC voltage of the commercial AC power supply Vs and inputs the DC voltage to the active filter circuit 12. The active filter circuit 12 is, for example, a step-up chopper circuit, and converts the input DC voltage into a predetermined output voltage and inputs it to the inverter circuit 13.

  The inverter circuit 13 is formed in a half-bridge shape using field effect transistors FET1 and FET2 so as to convert the DC voltage output from the active filter circuit 12 into a high-frequency voltage and output it. That is, a series circuit of a field effect transistor FET1 and a field effect transistor FET2 is connected to the output side of the active filter circuit 12, and a current limiting and resonance inductor L1, a DC cut capacitor C1 between the drain and source of the field effect transistor FET2, and A starting and resonance capacitor C2 (shown in the lamp connection detection circuit 4) is connected in series. The starting and resonance capacitor C <b> 2 is connected between the filament electrodes 3 a and 3 b on the non-power supply side of the fluorescent lamp 3. Both ends of the filament electrodes 3a and 3b of the fluorescent lamp 3 are connected to output terminals 14a, 14b, 15a and 15b of the high-frequency lighting device 2 (inverter circuit 13). The starting and resonance capacitor C <b> 2 is connected between the output terminals 14 b and 15 b of the high-frequency lighting device 2.

  The gates of the field effect transistors FET 1 and FET 2 are connected to the drive circuit 16, and the drive circuit 16 is connected to the main control unit 9 of the control circuit 5. The drive circuit 16 alternately switches the field effect transistors FET1 and FET2 at a predetermined frequency when the fluorescent lamp 3 is preheated, started, and turned on according to the control signal of the main control unit 9.

  The high-frequency lighting device 2 configured as described above outputs a high-frequency voltage to the output terminals 14a, 14b, 15a, and 15b by the switching operation of the field effect transistors FET1 and FET2. At this time, based on the dimming signal output from the dimming signal generation unit 8, the main control unit 9 can output a control signal to the drive circuit 16 so that the fluorescent lamp 3 is dimmed. The fluorescent lamp 3 is energized by the high-frequency lighting device 2 with both ends of the filament electrodes 3a and 3b being connected to output terminals 14a, 14b, 15a and 15b via lamp sockets (not shown).

  In addition, the life detection circuit 10 is connected between the output terminals 14 a and 15 a of the high-frequency lighting device 2. The life detection circuit 10 includes a series circuit of a resistor R1 and a resistor R2 connected between the output terminals 14a and 15a, a comparator CP1, and a reference power source Vref1. The resistors R1 and R2 divide the lamp voltage of the fluorescent lamp 3.

  The comparator CP1 has an inverting input terminal connected to the reference power supply Vref1, and a non-inverting input terminal connected to the middle point A of the resistors R1 and R2. That is, in the comparator CP1, the reference voltage of the reference power supply Vref1 is input to the inverting input terminal, and the voltage at the midpoint A is input to the non-inverting input terminal. The negative side of the reference power supply Vref1 is connected to the substrate ground E. The substrate ground E is connected to the source side of the field effect transistor FET2. The output terminal of the comparator CP1 is connected to the main controller 9 of the control circuit 5.

  The comparator CP1 outputs a high signal to the main control unit 9 when the voltage at the midpoint A (the voltage across the resistor R2) becomes equal to or higher than the reference voltage of the reference power supply Vref1. That is, the life detection circuit 10 detects a lamp voltage and no-load voltage (unsatisfactory) when the fluorescent lamp 3 has reached the end of its life, and outputs a detection signal to the main control unit 9.

  The lamp connection detection circuit 4 includes resistors R3 to R6, capacitors C3 and C4, diodes D1 to D3, a P-type bipolar transistor Tr1 and an N-type bipolar transistor Tr2. That is, a resistor R3 is connected between the drain of the field effect transistor FET1 and the output terminal 14a of the high-frequency lighting device 2, a capacitor C3 is connected between the output terminals 14a and 14b, and a resistor R4 is connected between the output terminals 14b and 15b. A capacitor C4 is connected between the output terminals 15a and 15b, and a series circuit of a diode D1 and a resistor R5 is connected between the output terminal 15a and the source of the field effect transistor FET2. A series circuit of a resistor R6, an emitter and a collector of a bipolar transistor Tr1, a diode D2 and a base and an emitter of a bipolar transistor Tr2 are connected between the output terminal 14a and the source of the field effect transistor FET2. The base of the bipolar transistor Tr1 is connected to the middle point B of the diode D1 and the resistor R5 via the diode D3, and the collector of the bipolar transistor Tr2 is connected to the main control unit 9 of the control circuit 5. The collector of the bipolar transistor Tr2 forms the output terminal of the lamp connection detection circuit 4.

  When the filament electrodes 3a, 3b of the fluorescent lamp 3 are connected to the output terminals 14a, 14b, 15a, 15b of the high-frequency lighting device 2 (inverter circuit 13), the electric field effect of the inverter circuit 13 during the operation of the active filter circuit 12 Current flows from the drain side of the transistor FET1 through the resistor R3, the filament electrode 3a of the fluorescent lamp 3, the resistor R4, the filament electrode 3b of the fluorescent lamp 3, the diode D1, the resistor R5, and the source-side path of the field effect transistor FET2. At this time, the resistance values of the resistors R3 to R6 are set in advance so that the potential at the midpoint B of the diode D1 and the resistor R5 is higher than the potential on the emitter side of the bipolar transistor Tr1. As a result, since the bipolar transistor Tr1 is not turned on, the bipolar transistor Tr2 is not turned on, and the main control unit 9 of the control circuit 5 is not connected to the substrate ground.

  If the filament electrode 3a of the fluorescent lamp 3 is not connected to the output terminals 14a and 14b of the high-frequency lighting device 2, the direct current flowing from the drain side of the field effect transistor FET1 through the resistor R3 is cut by the capacitor C3. The If the filament electrode 3b of the fluorescent lamp 3 is not connected to the output terminals 15a and 15b, the direct current from the drain side of the field effect transistor FET1 is cut by the capacitor C4. That is, if at least one of the filament electrodes 3a, 3b of the fluorescent lamp 3 is not connected to the output terminals 14a, 14b, 15a, 15b of the high frequency lighting device 2, no current flows through the resistor R5. At this time, the potential at the midpoint B of the diode D1 and the resistor R5 is set in advance to be lower than the potential on the emitter side of the bipolar transistor Tr1. this

As a result, current flows from the drain side of the field effect transistor FET1 through the resistor R3, the resistor R6, the emitter and base of the bipolar transistor Tr1, the middle point B, the resistor R5, and the source side path of the field effect transistor FET2. Turns on.

  When the bipolar transistor Tr1 is turned on, the input voltage of the inverter circuit 13 (output voltage of the active circuit 12) is dropped by the resistors R3 and R6 and applied to the base of the bipolar transistor Tr2, and the bipolar transistor Tr2 is turned on. When the bipolar transistor Tr2 is turned on, the main controller 9 of the control circuit 5 is connected to the substrate ground E via the collector and emitter of the bipolar transistor Tr2. Here, the main control unit 9 is configured to stop the drive power supply when connected to the substrate ground E. That is, the main control unit 9 cannot control the switching operation of the field effect transistors FET1 and FET2 of the inverter circuit 13, and the operation of the inverter circuit 13 stops.

  Thus, the lamp connection detection circuit 4 detects the connection state of the high-frequency lighting device 2 (inverter circuit 13) and the fluorescent lamp 3. That is, when the bipolar transistor Tr2 is turned on, the connection between the high-frequency lighting device 2 and the fluorescent lamp 3 is detected, and when the bipolar transistor Tr2 is turned off, the connection between the high-frequency lighting device 2 and the fluorescent lamp 3 is detected. . When the lamp connection detection circuit 4 detects the disconnection of the high-frequency lighting device 2 and the fluorescent lamp 3, the switching operation of the field effect transistors FET1 and FET2 by the main control unit 9 of the control circuit 5 is stopped, and the output terminal The high frequency voltage is not output to 14a, 14b, 15a, 15b.

  The control circuit 5 includes a main control unit 9. The main control unit 9 is connected to the timing unit 6, the nonvolatile storage unit 7, and the dimming signal generation unit 8. The timekeeping unit 6 counts the operation time of the inverter circuit 13 under the control of the main control unit 9. That is, the time is measured when the main control section 9 sends a control signal to the drive circuit 16 to switch the field effect transistors FET1 and FET2. The accumulated operation time of the inverter circuit 13 is overwritten and stored in the nonvolatile storage unit 7. The timekeeping unit 6 and the main control unit 9 form timekeeping means.

  The non-volatile storage unit 7 stores the cumulative operation time of the inverter circuit 13 that is cumulatively counted by the timer unit 6. Further, the cumulative operation time at the time of lamp replacement is stored. Further, a preset lifetime (for example, 12000 hours) of the fluorescent lamp 3 is stored.

  The dimming signal generator 8 generates a dimming signal for dimming the fluorescent lamp 3 based on the cumulative operation time of the inverter circuit 13 (high frequency lighting device 2) and the cumulative operation time at the time of the latest lamp replacement. The optical signal is output to the main controller 9. For example, the difference between the cumulative operation time of the inverter circuit 13 and the cumulative operation time at the time of the latest lamp replacement is calculated, and a dimming signal is generated based on the difference. The accumulated operation time of the inverter circuit 13 is added according to the operation when the inverter circuit 13 is operated. Further, the cumulative operation time at the time of the latest lamp replacement is read from the nonvolatile storage unit 7 by the main control unit 9. Therefore, during the operation of the inverter circuit 13, the cumulative operation time of the inverter circuit 13 increases according to the operation of the inverter circuit 13, and the difference also increases.

  The dimming signal generation unit 8 detects the fluorescence when the lamp connection detection circuit 4 detects the connection between the high-frequency lighting device 2 and the fluorescent lamp 3, that is, when the fluorescent lamp 3 is connected to the high-frequency lighting device 2. A dimming signal for lighting the lamp 3 at an initial dimming level (for example, 70%) is output, and then a dimming signal for increasing the dimming level of the fluorescent lamp 3 from the initial dimming level according to the difference is output. To do. Then, after a preset lifetime (for example, 12000 hours), a dimming signal is output so that the dimming level of the fluorescent lamp 3 becomes almost 100% (all light). That is, the dimming signal generation unit 8 calculates and outputs a PWM dimming signal according to the difference using a preset function. For example, a PWM dimming signal with an on-duty of 30% is output at the initial dimming level (70%), the on-duty value is decreased according to the difference, and the dimming level 100 reaches the lifetime of the fluorescent lamp 3. A PWM dimming signal with an on-duty of 0% is output at% (all light).

  The main control unit 9 changes the switching frequency of the field effect transistors FET1 and FET2 in accordance with the dimming signal from the dimming signal generation unit 8. As a result, the fluorescent lamp 3 has its light control level increased from the initial light control level (70%) according to the difference, and is lit at a light control level of 100% (all light) after the lifetime of the fluorescent lamp 3. . That is, a decrease in light output due to aging of the fluorescent lamp 3 and a decrease in light output due to dirt associated with long-term use are corrected, and a substantially constant luminous flux is output from the fluorescent lamp 3.

  In this way, the dimming signal generation unit 8 increases the dimming level of the fluorescent lamp 3 according to the difference so as to supplement the main control unit 9 with a light flux that decreases according to the lighting time of the fluorescent lamp 3. It is controlled to let you. The dimming signal generation unit 8 may generate the dimming signal based on the accumulated operation time of the inverter circuit 13 (high-frequency lighting device 2) and the accumulated operation time at the latest lamp replacement, in addition to the difference. Good.

  The main control unit 9 includes a CPU (central processing unit) that performs arithmetic processing, a ROM that stores a program, and a RAM that stores various data, and performs various controls based on the program.

  The main control unit 9 is connected to the drive circuit 16 of the inverter circuit 13 and switches the field effect transistors FET1 and FET2 of the inverter circuit 13 in accordance with the dimming signal output from the dimming signal generation unit 8. A control signal for changing the frequency is transmitted.

  The main control unit 9 is connected to the life detection circuit 10 and receives a detection signal (high signal) for detecting the end of life of the fluorescent lamp 3. That is, when the lamp voltage of the fluorescent lamp 3 rises to a predetermined value or more, or when the fluorescent lamp 3 becomes unsatisfactory, a detection signal (high signal) of the life of the fluorescent lamp 3 is input.

  The main control unit 9 is connected to the lamp connection detection circuit 4, and the drive power supply is stopped when the high-frequency lighting device 2 and the fluorescent lamp 3 are not connected.

  Then, the main control unit 9 detects the reconnection after the lamp connection detection circuit 4 detects the non-connection between the high-frequency lighting device 2 and the fluorescent lamp 3, and the high-frequency lighting device timed by the time measuring unit 6 when the reconnection is detected. The accumulated operation time 2 is set to the accumulated operation time at the time of the latest lamp replacement, and is stored in the nonvolatile storage unit 7.

  Next, the operation of the first embodiment of the present invention will be described. In a state where the lamp connection detection circuit 4 detects the connection between the high frequency lighting device 2 and the fluorescent lamp 3, that is, the filament electrodes 3a of the fluorescent lamp 3 are connected to the output terminals 14a, 14b, 15a, 15b of the high frequency lighting device 2. When the commercial AC power supply Vs is turned on with the 3b connected, the field effect transistors FET1 and FET2 of the inverter circuit 13 perform a switching operation under the control of the main control unit 9 of the control circuit 5. Then, the high frequency voltage of the inverter circuit 13 is output to the output terminals 14a, 14b, 15a, 15b, and the fluorescent lamp 3 is lit.

  When the field control transistors FET1 and FET2 are switching-operated, the main control unit 9 causes the time measuring unit 6 to totalize the operation time of the inverter circuit 13 (high frequency lighting device 2), and the total operation time to be non-volatile. Store in the storage unit 7. Further, the accumulated operation time at the time of lamp replacement or lamp reconnection is stored in the nonvolatile storage unit 7.

  Then, when the fluorescent lamp 3 is connected to the high-frequency lighting device 2 and the lamp connection detection circuit 4 detects the connection, the dimming signal generation unit 8 performs PWM with an on-duty of 30% as shown in FIG. The dimming signal is output to the main control unit 9. The main controller 9 changes the switching frequency of the field effect transistors FET1 and FET2 according to the PWM dimming signal. As a result, the high frequency voltage of the inverter circuit 13 output to the output terminals 14a, 14b, 15a, and 15b changes, and the fluorescent lamp 3 is lit at the initial dimming level of 70% as shown in FIG. .

  Then, the dimming signal generation unit 8 uses the preset function over the preset lifetime of the fluorescent lamp 3 (for example, 12000 hours) to set the on-duty value of the PWM dimming signal to the difference. Decrease. The main control unit 9 changes the switching frequency of the field effect transistors FET1 and FET2 according to the PWM dimming signal. Thereby, the dimming level of the fluorescent lamp 3 increases according to the difference from the initial dimming level of 70%.

  When the fluorescent wrap 3 reaches the end of its life and the lamp voltage increases, a detection signal (high signal) of the life of the fluorescent lamp 3 is input from the life detection circuit 10 to the main controller 9. At this time, the main controller 9 stops the switching operation of the field effect transistors FET1 and FET2 of the inverter circuit 13 and turns off the fluorescent lamp 3. Alternatively, the main control unit 9 notifies the dimming signal generation unit 8 of the input of the detection signal. The dimming signal generation unit 8 outputs to the main control unit 9 an on-duty (30%) PWM dimming signal that sets the fluorescent lamp 3 to the initial dimming level (70%), as shown in FIG. To do. As shown in FIG. 2A, the main control unit 9 turns on the fluorescent lamp 3 at an initial dimming level of 70% in accordance with a PWM dimming signal with an on-duty (30%). Thereby, the light flux radiated | emitted from the fluorescent lamp 3 reduces.

  The fluorescent lamp 3 has a light output (light beam) that decreases due to secular change, and a light output (light beam) that is caused by dirt associated with long-term use. However, as described above, by increasing the dimming level of the fluorescent lamp 3 according to the operation time of the high-frequency lighting device 2, the light flux that decreases according to the lighting time of the fluorescent lamp 3 is corrected. A substantially constant luminous flux can be obtained from the fluorescent lamp 3 over the lifetime.

  When the high-frequency lighting device 2 and the fluorescent lamp 3 are not connected in the middle of the lifetime of the fluorescent lamp 3 (for example, 12000 hours) and the high-frequency lighting device 2 and the fluorescent lamp 3 are connected again, the main controller 9 As shown in FIG. 2B, the dimming signal generation unit 8 is controlled to return the fluorescent lamp 3 to the initial dimming level (70%). Then, the dimming signal generation unit 8 outputs to the main control unit 9 an on-duty (30%) PWM dimming signal that sets the fluorescent lamp 3 to the initial dimming level (70%) under the control of the main control unit 9. To do. As shown in FIG. 2A, the main control unit 9 turns on the fluorescent lamp 3 at an initial dimming level of 70% in accordance with the PWM dimming signal from the dimming signal generation unit 8.

  The high frequency lighting device 2 and the fluorescent lamp 3 are not connected in the middle of the lifetime of the fluorescent lamp 3 when, for example, the fluorescent lamp 3 and the lighting fixture are cleaned. When the fluorescent lamp 3 and the lighting fixture are cleaned, a predetermined brightness is secured from the lighting fixture even if the dimming level of the fluorescent lamp 3 is set to the initial dimming level (70%) again. In the same manner as described above, even if the dimming level of the fluorescent lamp 3 is increased according to the difference, the end of life is reached by the life detection circuit 10 until the life time of the fluorescent lamp 3 (for example, 12000 hours) is reached. Since it is detected, the dimming level may not be 100% (total light).

  The life detection circuit 10 may include a detection circuit that detects a half-wave voltage in addition to detecting the lamp voltage of the fluorescent lamp 3. That is, the life detection circuit 10 only needs to be configured to detect the end of life of the fluorescent lamp 3.

  Then, when the discharge lamp lighting device 1 is replaced or when the lighting fixture is replaced, the inverter circuit 13 is read by reading the cumulative operation time of the inverter circuit 13 stored in the nonvolatile storage unit 7. Can be obtained. Further, the history of the fluorescent lamp 3 can be obtained by reading the cumulative operation time of the inverter circuit 13 at the time of lamp replacement. From this history, the actual lifetime of each fluorescent lamp 3 can be grasped.

  As shown in FIG. 3B, the dimming signal generator 8 is replaced or reconnected, and the on-duty 70 is used when the fluorescent lamp 3 is lit at the initial dimming level (for example, 70%). % PWM dimming signal is output, the on-duty value is increased in accordance with the difference between the cumulative operation time of the inverter circuit 13 and the cumulative operation time at the time of the latest lamp replacement, and the dimming reaching the lifetime of the fluorescent lamp 3 A PWM dimming signal with an on-duty of 100% may be output when the level is 100% (all light).

  Then, as shown in FIG. 3A, the main control unit 9 changes the dimming level of the fluorescent lamp 3 from the initial dimming level (70%) in accordance with the dimming signal from the dimming signal generation unit 8. You may comprise so that it may increase according to the said difference to the light control level 100% (all light).

  The PWM dimming signal output from the dimming signal generator 8 to the main controller 9 is an output voltage that gradually increases from the initial dimming level (70%) of the fluorescent lamp 3 to the dimming level 100% (all light). In addition, since the main control unit 9 forms a control signal in which the DC voltage increases, the connection circuit between the main control unit 9 and the dimming signal generation unit 8 is simplified. That is, as shown in FIG. 2, the main control unit 9 responds to the PWM dimming signal of the output voltage that gradually decreases from the initial dimming level (70%) of the fluorescent lamp 3 to the dimming level 100% (all light). If a control signal for increasing the DC voltage is formed, the inverter circuit for the output voltage is required, for example, and the circuit configuration becomes complicated.

  Further, the main control unit 9 causes the timer unit 6 to count the total lighting time of all the fluorescent lamps 3 connected to the high-frequency lighting device 2 instead of the cumulative operation time of the inverter circuit 13, and the nonvolatile storage unit 7. You may make it memorize. The accumulated lighting time of the fluorescent lamp 3 is measured, for example, when the main control unit 9 is switching the field effect transistors FET1 and FET2 and no high signal is output from the life detection circuit 10. Can do. Further, it can be performed when the light output of the fluorescent lamp 3 is detected by the optical sensor and the optical sensor detects the light output of the fluorescent lamp 3.

  The dimming signal generation unit 8 may generate a dimming signal according to the difference between the cumulative lighting time of the fluorescent lamp 3 and the cumulative lighting time at the time of the latest lamp replacement. Even in this case, the same operation and effect as those for the cumulative operation time of the inverter circuit 13 can be obtained.

  Next, a discharge lamp lighting device according to a second embodiment of the present invention will be described with reference to the drawings. Note that components that are the same as or correspond to those in the first embodiment are denoted by the same reference numerals and description thereof is omitted.

  FIG. 4 is a block diagram including a partial circuit diagram of a discharge lamp lighting device showing a second embodiment of the present invention. In the figure, first, the lamp connection detection circuit 4 includes a resistor R3, a current limiting and resonance inductor L1, a filament electrode 3a, a resistor R4, a filament electrode 3b, a resistor R10, a bipolar transistor Tr10, a resistor 11 and a main control of the fluorescent lamp 3. The unit 9 is configured to be included.

  If the fluorescent lamp 3 is connected to the output terminals 14a, 14b, 15a, 15b of the high-frequency lighting device 2, a current flows through the circuit and a voltage is generated at the base of the bipolar transistor Tr10. When turned on, the lamp connection detection circuit 4 determines that the lamp is connected. On the other hand, if the fluorescent lamp 3 is disconnected from any of the output terminals 14a, 14b, 15a, and 15b of the high-frequency lighting device 2, no current flows, so the bipolar transistor Tr10 is turned off, and the lamp connection detection circuit 4 Judge that it is not connected.

  Next, the life detection circuit 10 includes a resistor R12, a capacitor C11, a resistor 13, and a main control unit 9. When the fluorescent lamp 3 is half-wave discharged, the capacitor C11 is charged through the resistor R12. The voltage of the capacitor C11 increases and decreases depending on the direction of the half-wave discharge. The main control unit 9 checks whether or not the voltage is within a predetermined range. If the voltage is out of the predetermined range, the main control unit 9 determines that the life of the fluorescent lamp 3 is due to half-wave discharge or the like. The control contents including other circuit operations are the same as those of the discharge lamp lighting device of the first embodiment, and the description thereof is omitted.

  Next, a third embodiment of the present invention will be described.

  FIG. 5 is an external view of a luminaire showing a third embodiment of the present invention. Note that the same parts as those in FIG.

  A lighting fixture 17 shown in FIG. 5 is a direct-mounted lighting fixture installed on a construction such as a ceiling, and a lighting fixture body 18 is attached to the construction. The lighting fixture body 18 is provided with a cover 19 having a reflective surface 19a, and a pair of lamp sockets 20 and 20 are provided at both ends thereof. Moreover, the lighting fixture body 18 has a discharge lamp lighting device 21 disposed in a cover 19. The discharge lamp lighting device 21 is obtained by removing the fluorescent lamp 3 from the discharge lamp lighting device 1 shown in FIG. The fluorescent lamp 3 is mounted on the lamp sockets 20 and 20.

  In order to compensate for a decrease in light output (light beam) due to secular change of the fluorescent lamp 3, a decrease in light output (light beam) due to contamination due to long-term use, and a decrease in reflection efficiency due to contamination of the cover 19. The dimming level is increased from the initial dimming level (70%) to 100% (all light) over the lifetime (12000 hours) according to the operation time of the inverter circuit 13 from the time of lamp replacement. The lighting fixture 17 can illuminate with substantially constant brightness.

  When the fluorescent lamp 3 reaches the end of its life, the life detection circuit 10 detects the life of the fluorescent lamp 3, and the fluorescent lamp 3 is turned off or the fluorescent lamp 3 is controlled to the initial dimming level (70%). Therefore, the lighting fixture 17 is turned off or the brightness of the lighting fixture 17 becomes dark, and the life of the fluorescent lamp 3 is notified. Thereby, the fluorescent lamp 3 can be replaced | exchanged rapidly.

  Further, if maintenance work such as cleaning of the fluorescent lamp 3 and the lighting fixture 17 is performed before the lifetime of the fluorescent lamp 3, the dimming level of the fluorescent lamp 3 is controlled to the initial dimming level (70%). The lighting fixture 17 can obtain a predetermined brightness and can save power.

  And the lighting fixture 17 is the inverter circuit 13 (high frequency lighting device) memorize | stored in the non-volatile memory | storage part 7, when the lighting device 21 for discharge lamps is replaced | exchanged, or when the lighting fixture 17 itself is discarded. The accumulated operation time of 2) can be read out, whereby the life time and actual use time of the inverter circuit 13 (high frequency lighting device 2) can be obtained. Further, by reading the cumulative operation time of the inverter circuit 13 at the time of lamp replacement, the history of the fluorescent lamp 3 can be obtained, and the actual lifetime of each fluorescent lamp 3 can be grasped.

1 is a block diagram including a partial circuit diagram of a discharge lamp lighting device showing a first embodiment of the present invention. Similarly, control of the dimming level of the discharge lamp is shown, (a) is a change diagram of the dimming level with respect to the cumulative operation time of the inverter circuit, (b) is a change diagram of the dimming signal with respect to the cumulative operation time of the inverter circuit. Similarly, the control of the dimming level of the other discharge lamps is shown, (a) is a change diagram of the dimming level with respect to the cumulative operation time of the inverter circuit, (b) is a change diagram of the dimming signal with respect to the cumulative operation time of the inverter circuit. . The block diagram including the partial circuit diagram of the discharge lamp lighting device which shows the 2nd Embodiment of this invention. The external view of the lighting fixture which shows the 3rd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Discharge lamp lighting device, 2 ... High frequency lighting device, 4 ... Lamp connection detection circuit as a lamp connection detection means, 6 ... Time measuring part as a time measuring means, 7 ... Nonvolatile Non-volatile storage unit as storage unit, 8... Dimming signal generation unit as dimming signal generation unit, 9... Main control unit as control unit, 17. lighting equipment

Claims (4)

A high-frequency lighting device for lighting a discharge lamp ;
Clocking means for counting the operating time of the high-frequency lighting device;
Non-volatile storage means for storing the cumulative operation time of the high-frequency lighting device that has been cumulatively counted by the clock means and the cumulative operation time at the time of the latest discharge lamp replacement;
A dimming signal generating means for calculating a difference between the total operating time and the total operating time when the latest discharge lamp is replaced, and generating a dimming signal based on the difference;
Control means for controlling the high-frequency lighting device according to the dimming signal;
A discharge lamp lighting device comprising: Dimming signal generating means to generate a dimming signal to increase the dimming level of the discharge lamp based on the difference so as to compensate for the light beam decreases in accordance with the lighting time of the discharge lamp from the initial dimming level The discharge lamp lighting device according to claim 1. Discharge lamp connection detecting means for detecting a connection state between the high-frequency lighting device and the discharge lamp ; and when the discharge lamp connection detecting means detects a disconnection between the high-frequency lighting device and the discharge lamp , 3. The discharge lamp lighting device according to claim 1, wherein the accumulated operation time of the measured high-frequency lighting device is set to a cumulative operation time at the time of the latest discharge lamp replacement. A discharge lamp lighting device according to any one of claims 1 to 3;
A lighting fixture body provided with the discharge lamp lighting device;
The lighting fixture characterized by comprising.

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