JP5733931B2 - Power supply device and lighting device - Google Patents

Description

  The present invention relates to a power supply device using an electrolytic capacitor and a lighting device using the same.

Among the components of the power supply device, the electrolytic capacitor has the shortest life, and the life of the electrolytic capacitor determines the life of the power supply device. Electrolytic capacitors have a reduced capacitance due to aging. When the ripple current increases due to the decrease in capacitance, the amount of heat generated inside the electrolytic capacitor increases and the electrolytic solution evaporates. When the pressure inside the electrolytic capacitor increases due to the evaporation of the electrolytic solution, the explosion-proof valve operates to prevent the electrolytic capacitor from exploding. When the explosion-proof valve is operated, water vapor (electrolytic solution) inside the electrolytic capacitor is released to the outside, and when this is viewed by the user, it may be mistaken for ignition. In addition, when the explosion-proof valve operates, the capacity of the electrolytic capacitor is completely lost, so that the power supply device cannot be used thereafter. For this reason, before the explosion-proof valve of the electrolytic capacitor operates, it is necessary to determine the life of the electrolytic capacitor and prompt the user to replace the power supply device.
There is a technique for determining the life of an electrolytic capacitor by measuring the discharge time constant of the electrolytic capacitor.

JP 2010-6568 A JP 2008-306850 A

In order to measure the discharge time constant of the electrolytic capacitor during the operation of the power supply device, it is necessary to disconnect the electrolytic capacitor from the circuit in operation, which complicates the circuit configuration.
Also, in order to measure the discharge time constant of the electrolytic capacitor after the power supply device stops operating, the measuring circuit needs to continue operating. The lighting device may have a configuration in which operation is stopped (that is, the light is turned off) by stopping power supply to the entire lighting device. In that case, since the power supply to the measurement circuit is also stopped, the discharge time constant of the electrolytic capacitor cannot be measured.
The present invention has been made to solve the above-described problems, for example, and has an object to determine the life of an electrolytic capacitor with a simple configuration.

  A power supply device according to the present invention is a power supply device that converts AC power supplied from an AC power source into DC power, an electrolytic capacitor, a voltage measuring circuit that measures the voltage across the electrolytic capacitor, and the AC power source. The control power supply circuit that generates the control power supply and the control power supply generated by the control power supply circuit operate until the predetermined time elapses after the supply of AC power is stopped, and the voltage measurement circuit measures the above A life determination circuit for determining whether or not the electrolytic capacitor is at the end of its lifetime based on a voltage across the electrolytic capacitor, and the life determination circuit is provided when the supply of AC power from the AC power supply is stopped. A voltage storage unit that stores the voltage across the electrolytic capacitor measured by the voltage measurement circuit, and a predetermined time after the supply of AC power from the AC power supply is stopped A quotient calculation unit that calculates a quotient obtained by dividing the voltage across the electrolytic capacitor measured by the voltage measurement circuit after the elapsed time by the voltage across the electrolytic capacitor stored in the voltage storage unit, and the quotient calculation unit calculates A life determining unit that determines whether the electrolytic capacitor has a lifetime based on the quotient.

  According to the power supply device of the present invention, the control power supply circuit generates the control power supply until a predetermined time elapses after the supply of AC power from the AC power supply is stopped. After the operation of the power supply device is stopped, the discharge time constant of the electrolytic capacitor can be measured to determine the life of the electrolytic capacitor.

FIG. 3 is a system configuration diagram showing an overall configuration of lighting apparatus 800 in the first embodiment. FIG. 3 is a circuit diagram illustrating a circuit configuration of lighting apparatus 800 according to Embodiment 1. FIG. 2 is a block configuration diagram showing a configuration of a control device 150 in the first embodiment. FIG. 6 is a flowchart showing a flow of a lighting process S500 in the first embodiment. FIG. 4 is a waveform diagram showing a voltage across the smoothing capacitor C34 in the first embodiment. FIG. 4 is a block configuration diagram illustrating a configuration of a control device 150 according to a second embodiment. The flowchart figure which shows the flow of lighting process S500 in Embodiment 2. FIG. FIG. 9 is a block configuration diagram illustrating a configuration of a control device 150 according to Embodiment 3. FIG. 10 is a flowchart showing a flow of a lighting process S500 in the third embodiment. FIG. 6 is a circuit diagram illustrating a circuit configuration of lighting apparatus 800 according to Embodiment 4. The flowchart figure which shows the flow of lighting process S500 in Embodiment 4. FIG.

Embodiment 1 FIG.
The first embodiment will be described with reference to FIGS.

FIG. 1 is a system configuration diagram showing an overall configuration of an illumination device 800 according to this embodiment.
The lighting device 800 is supplied with electric power from an AC power source AC such as a commercial power source and lights a light source such as an LED. The lighting device 800 includes a power supply device 100 and a light source circuit 810.
The power supply device 100 converts AC power supplied from the AC power supply AC into DC power supplied to the light source circuit 810. The power supply device 100 includes an AC / DC conversion circuit 110, a control power supply circuit 120, a voltage measurement circuit 130, a power supply detection circuit 140, and a control device 150.
The AC / DC conversion circuit 110 converts AC power into DC power. The AC / DC conversion circuit 110 is a circuit using an electrolytic capacitor. The electrolytic capacitor is used as a smoothing capacitor, for example.
The control power supply circuit 120 generates DC power (control power supply power) for operating the control device 150 and the AC / DC conversion circuit 110 from the AC power supplied from the AC power supply AC. The control power supply circuit 120 can store a certain amount of energy and supplies control power for operating the control device 150 for a predetermined time (for example, several seconds) after the power supply from the AC power supply AC is stopped. Can do. For example, the control power supply circuit 120 includes a smoothing capacitor having a large capacitance. For example, if the capacitance of the smoothing capacitor of the control power circuit 120 is 1000 μF, the voltage of the control power is 5 V, the operating voltage of the controller 150 is 3 V to 5 V, and the operating current of the controller 150 is 1 mA, the AC power source AC Since the voltage of the control power supply is maintained at 3 V or more for 2 seconds after the power supply from is stopped, the control device 150 can continue to operate for 2 seconds. When an electrolytic capacitor is used as the smoothing capacitor of the control power supply circuit 120, a capacitor having a longer life than the electrolytic capacitor of the AC / DC converter circuit 110 is used.
The voltage measurement circuit 130 measures the voltage across the electrolytic capacitor of the AC / DC conversion circuit 110. The voltage measurement circuit 130 generates a signal representing the measurement result and outputs the generated signal.
The power supply detection circuit 140 (AC power supply detection circuit) detects whether or not there is power supply from the AC power supply AC. The power supply detection circuit 140 generates a signal indicating the detected result and outputs the generated signal.
The control device 150 (life determination circuit) operates with the control power supply power generated by the control power supply circuit 120 and controls the operation of the AC / DC conversion circuit 110. The control device 150 operates the AC / DC conversion circuit 110 or stops the operation based on the voltage measured by the voltage measurement circuit 130, the presence / absence of power supply detected by the power supply detection circuit 140, and the like. Control device 150 generates a control signal representing the content of control and outputs the generated signal. The AC / DC conversion circuit 110 operates or stops operating in accordance with the control signal generated by the control device 150.

FIG. 2 is a circuit diagram showing a circuit configuration of lighting apparatus 800 according to this embodiment.
The light source circuit 810 (LED module) has a plurality of light sources 811. The light source 811 is an LED, for example, and emits light by direct current power. The light source circuit 810 is a circuit in which a plurality of light sources 811 are electrically connected in series, for example.
The AC / DC converter circuit 110 includes a full-wave rectifier circuit 111, an input capacitor C <b> 21, a power factor correction circuit 112, and a DC / DC converter circuit 115. The full-wave rectification circuit 111 performs full-wave rectification on the AC power input from the AC power supply AC, and converts the voltage waveform into pulsating power. The full-wave rectifier circuit 111 has a diode bridge DB, for example. The diode bridge DB is a circuit in which four rectifying elements are bridge-connected. The input capacitor C21 is a capacitor that is electrically connected in parallel to the output of the full-wave rectifier circuit 111, and absorbs the high-frequency current generated in the power factor correction circuit 112 so that it does not leak to the AC power supply AC side. The input capacitor C21 has a relatively small capacitance and is, for example, a film capacitor.
The power factor correction circuit 112 improves the power factor of the electric power input by the AC / DC conversion circuit 110 and brings it close to 1. The power factor correction circuit 112 converts the input power into DC power having a predetermined voltage. The power factor correction circuit 112 is, for example, a boost converter circuit, and includes a choke coil L31, a switching element Q32, a rectifying element D33, a smoothing capacitor C34, two voltage dividing resistors R41 and R42, a feedback circuit 114, and a control. Circuit 113. The choke coil L31 and the switching element Q32 are electrically connected in series to the output of the full-wave rectifier circuit 111. The rectifier element D33 and the smoothing capacitor C34 are electrically connected in series with each other and electrically connected in parallel with the switching element Q32. The two voltage dividing resistors R41 and R42 are electrically connected in series with each other, and are electrically connected in parallel with the smoothing capacitor C34. The smoothing capacitor C34 is an electrolytic capacitor. Both ends of the smoothing capacitor C34 are electrically connected to the input of the DC / DC conversion circuit 115 as outputs of the power factor correction circuit 112. The feedback circuit 114 (feedback unit) receives the voltage across the voltage dividing resistor R42 and generates a feedback signal. The control circuit 113 operates with the control power supply generated by the control power supply circuit 120, and based on the feedback signal generated by the feedback circuit 114 and the control signal generated by the control device 150, a drive signal for turning on and off the switching element Q32. Generate. The control circuit 113 may directly input the voltage across the voltage dividing resistor R42 as a feedback signal, and the feedback circuit 114 may not be provided.
The choke coil L31 limits the current input by the power factor correction circuit 112. The control circuit 113 adjusts the current input by the power factor correction circuit 112 by turning on and off the switching element Q32 at a high frequency (for example, several hundred kHz), and the input current waveform obtained by removing the high frequency component by the input capacitor C21 is The waveform is approximated to the voltage waveform obtained by full-wave rectification by the wave rectifier circuit 111. The two voltage dividing resistors R41 and R42 divide the voltage across the smoothing capacitor C34. The feedback circuit 114 generates a feedback signal indicating whether the voltage across the voltage dividing resistor R42 is higher or lower than a predetermined voltage. The control circuit 113 controls the voltage across the smoothing capacitor C34 to be a predetermined voltage (for example, 400V) based on the feedback signal generated by the feedback circuit 114. When the voltage across the smoothing capacitor C34 is higher than a predetermined voltage, the control circuit 113 increases the frequency at which the switching element Q32 is turned on or off, for example, reduces the on-duty of the switching element Q32, and the power factor correction circuit 112 inputs To reduce the current. As a result, the current for charging the smoothing capacitor C34 is reduced, and the voltage across the smoothing capacitor C34 is reduced. On the other hand, when the voltage across the smoothing capacitor C34 is lower than a predetermined voltage, the control circuit 113 reduces the frequency for turning on / off the switching element Q32 or increases the on-duty of the switching element Q32, for example, to increase the power factor improvement circuit. 112 increases the input current. Thereby, since the current for charging the smoothing capacitor C34 increases, the voltage across the smoothing capacitor C34 increases. In this way, the control circuit 113 brings the voltage across the smoothing capacitor C34 close to a predetermined voltage.

The DC / DC conversion circuit 115 generates DC power to be supplied to the light source circuit 810 from the DC power generated by the power factor correction circuit 112. The DC / DC conversion circuit 115 adjusts the voltage value of the generated DC power so that the current flowing through the light source circuit 810 becomes a predetermined current. The DC / DC conversion circuit 115 is, for example, a buck converter circuit, and includes a switching element Q51, a rectifying element D52, a choke coil L53, a smoothing capacitor C54, a current detection resistor R61, a feedback circuit 117, and a control circuit 116. Have. The switching element Q51 and the rectifying element D52 are electrically connected in series to the output of the power factor correction circuit 112. The choke coil L53, the smoothing capacitor C54, and the current detection resistor R61 are electrically connected in series with each other and electrically connected in parallel with the rectifying element D52. The smoothing capacitor C54 is an electrolytic capacitor. Both ends of the smoothing capacitor C54 are electrically connected to the light source circuit 810 as outputs of the DC / DC conversion circuit 115. The feedback circuit 117 (feedback unit) receives the voltage across the current detection resistor R61 and generates a feedback signal. The control circuit 116 operates with the control power supply generated by the control power supply circuit 120, and based on the feedback signal generated by the feedback circuit 117 and the control signal generated by the control device 150, a drive signal for turning on / off the switching element Q51. Generate. The control circuit 116 may directly input the voltage across the current detection resistor R61 as a feedback signal, and the feedback circuit 117 may not be provided.
The choke coil L53 limits the current for charging the smoothing capacitor C54. The control circuit 116 adjusts the current input to the DC / DC conversion circuit 115 by turning on and off the switching element Q51 at a high frequency. The rectifying element D52 flows through the return current when the switching element Q51 is off. The feedback circuit 117 smoothes the voltage across the current detection resistor R61 and generates a feedback signal indicating whether the smoothed voltage is higher or lower than a predetermined voltage. The control circuit 116 controls the current flowing through the light source circuit 810 to be a predetermined current based on the feedback signal generated by the feedback circuit 117. When the current flowing through the light source circuit 810 is larger than a predetermined current, the control circuit 116 increases the frequency at which the switching element Q51 is turned on or off, for example, reduces the on-duty of the switching element Q51, and the DC / DC conversion circuit 115 inputs the current. To reduce the current. As a result, the current for charging the smoothing capacitor C54 is reduced, and the voltage across the smoothing capacitor C54 is reduced. On the other hand, when the current flowing through the light source circuit 810 is less than the predetermined current, the control circuit 116 reduces the frequency for turning on / off the switching element Q51 or increases the on-duty of the switching element Q51, for example. 115 increases the input current. As a result, the current for charging the smoothing capacitor C54 increases, so that the voltage across the smoothing capacitor C54 increases. In this way, the control circuit 116 brings the current flowing through the light source circuit 810 close to a predetermined current.

The voltage measurement circuit 130 includes two voltage measurement circuits 130a and 130b. The voltage measurement circuit 130a measures the voltage across the smoothing capacitor C34. In the power factor correction circuit 112, the voltage dividing resistors R41 and R42 have a role of measuring the voltage across the smoothing capacitor C34. Therefore, the voltage dividing resistors R41 and R42 of the power factor correction circuit 112 are used as the voltage measuring circuit 130a. Use. The voltage measurement circuit 130a outputs the voltage across the voltage dividing resistor R42 as a result of measuring the voltage across the smoothing capacitor C34. Since the voltage across the smoothing capacitor C34 is divided by the two voltage dividing resistors R41 and R42, the voltage across the voltage dividing resistor R42 is proportional to the voltage across the smoothing capacitor C34.
The voltage measurement circuit 130b measures the voltage across the smoothing capacitor C54. The voltage measurement circuit 130b includes, for example, two voltage dividing resistors R71 and R72. The two voltage dividing resistors R71 and R72 are electrically connected in series with each other, and are electrically connected in parallel with the smoothing capacitor C54 and the current detection resistor R61. The voltage measurement circuit 130b outputs the voltage across the voltage dividing resistor R72 as a result of measuring the voltage across the smoothing capacitor C54. The two voltage dividing resistors R71 and R72 divide the total voltage of the voltage across the smoothing capacitor C54 and the voltage across the current detection resistor R61. When the control circuit 116 stops operating, the current for charging the smoothing capacitor C54 does not flow, so the voltage across the current detection resistor R61 becomes zero. For this reason, the voltage across the voltage dividing resistor R72 is proportional to the voltage across the smoothing capacitor C54.

FIG. 3 is a block diagram showing the configuration of the control device 150 in this embodiment.
The control device 150 is, for example, a microcomputer. The microcomputer includes a storage device, a processing device, an input device, an output device, and the like not shown. The storage device is, for example, a nonvolatile memory or a volatile memory, and stores a program executed by the processing device, data processed by the processing device, and the like. The processing device processes data by executing a program stored in the storage device, and controls the entire microcomputer. The input device is an analog-digital conversion circuit, for example, and inputs a signal from the outside of the microcomputer and converts it into data that can be processed by the processing device. The output device is, for example, a digital / analog conversion circuit, which converts data processed by the processing device or data stored in the storage device into a signal and outputs the signal to the outside of the microcomputer. A function block described below is realized by the processing device executing the program stored in the storage device. The control device 150 may be configured to implement the following functional blocks by other integrated circuits, electronic circuits such as digital circuits / analog circuits, and the like instead of the microcomputer.

  The control device 150 includes a power feeding determination unit 151, a time measurement unit 152, a voltage input unit 153, a voltage storage unit 154, a quotient calculation unit 155, a life determination unit 157, a determination result storage unit 158, and a life notification unit. 159. The power supply determination unit 151 receives a signal generated by the power supply detection circuit 140 and determines whether or not power is supplied from the AC power supply AC based on the input signal. Based on the determination result of the power supply determination unit 151, the timer unit 152 measures an elapsed time after the power supply from the AC power supply AC is stopped. The voltage input unit 153 receives signals generated by the two voltage measurement circuits 130a and 130b, and acquires voltages at both ends of the two smoothing capacitors C34 and C54 based on the input signals. Based on the determination result of the power supply determination unit 151, the voltage input unit 153 performs the first voltage acquisition when the power supply from the AC power supply AC is stopped. Further, the voltage input unit 153 obtains the second voltage acquisition at a time when a predetermined time (for example, 1 second) has elapsed since the power supply from the AC power supply AC is stopped based on the measurement result of the time measuring unit 152. carry out. The voltage storage unit 154 stores the both-end voltages of the two smoothing capacitors C34 and C54 acquired by the voltage input unit 153 for the first time. The quotient calculation unit 155 divides the voltage across the smoothing capacitor C34 acquired by the voltage input unit 153 for the second time by the voltage across the smoothing capacitor C34 acquired by the voltage input unit 153 stored in the voltage storage unit 154 for the first time. Calculate the quotient. Similarly, for the smoothing capacitor C54, the quotient calculation unit 155 obtains the voltage across the smoothing capacitor C54 acquired by the voltage input unit 153 for the second time and the smoothing acquired by the voltage input unit 153 stored by the voltage storage unit 154 for the first time. The quotient divided by the voltage across the capacitor C54 is calculated. The life determination unit 157 determines whether each of the two smoothing capacitors C34 and C54 has a lifetime based on the quotient calculated by the quotient calculation unit 155. The life determination unit 157 compares the quotient calculated for the smoothing capacitor C34 by the quotient calculation unit 155 with a predetermined threshold, and determines that the smoothing capacitor C34 has a lifetime if the quotient is smaller than the threshold. Similarly, for the smoothing capacitor C54, the quotient calculation unit 155 compares the quotient calculated for the smoothing capacitor C54 with a predetermined threshold, and determines that the smoothing capacitor C54 has a lifetime if the quotient is smaller than the threshold. The determination result storage unit 158 stores the determination result determined by the life determination unit 157. Based on the determination result stored in the determination result storage unit 158, the life notification unit 159 notifies the user when one of the two smoothing capacitors C34 and C54 has a lifetime. For example, the life notification unit 159 generates a control signal for stopping the operation of the two control circuits 113 and 116 so that the light source 811 is not turned on. Thereby, the user can be prompted to replace the lighting device 800. Alternatively, the life notification unit 159 operates the control circuit 113, generates a control signal that causes the control circuit 116 to repeatedly operate and stop at intervals of several seconds, and causes the light source 811 to blink. After the light source 811 blinks for a predetermined time, the life notification unit 159 generates a control signal for operating the two control circuits 113 and 116 and turns on the light source 811. Thereby, it is possible to continue using the lighting device 800 until the lighting device 800 is replaced. In addition, when the user continues to use the lighting device 800 without replacing it, the time for blinking the light source 811 may be gradually increased. Alternatively, the life notification unit 159 may be configured to display a message notifying abnormality using a display device or outputting a sound notifying abnormality using a sound output device.

  The life notification unit 159 may be configured to notify the life when the life determination unit 157 continuously determines that one of the two smoothing capacitors C34 and C54 has a predetermined life. In other words, there is a possibility of erroneous determination only with the life determination at one power-off. Therefore, when the life determination unit 157 repeatedly determines that the life is at the life determination at a plurality of power-offs, the life is determined. Notice. For example, the determination result storage unit 158 stores the number of times the life determination unit 157 determines that one of the two smoothing capacitors C34 and C54 has a life. The life determination unit 157 increases the number of times stored by the determination result storage unit 158 by 1 when determining that it is a life, and sets the number of times stored by the determination result storage unit 158 to 0 when it is determined that it is not a life. The life notification unit 159 notifies the life when the number of times stored in the determination result storage unit 158 is greater than a predetermined number.

FIG. 4 is a flowchart showing the flow of the lighting process S500 in this embodiment.
In the lighting process S500, the lighting apparatus 800 turns on the light source 811. The lighting process S500 includes a lifetime storage determination step S511, a lifetime notification step S512, a lighting step S521, a power supply determination step S523, a voltage storage step S533, a waiting step S534, a quotient calculation step S535, and a lifetime determination step S536. And have. When the power supply from the AC power supply AC is started, the control device 150 starts the process from the life storage determination step S511.
In the lifetime storage determination step S511, the lifetime notification unit 159 determines whether one of the two smoothing capacitors C34 and C54 is at the end of the lifetime based on the determination result stored in the determination result storage unit 158 or two smoothing capacitors C34 and C54. It is determined whether any of these is not a life. When it determines with it being a lifetime, the lifetime notification part 159 advances a process to lifetime notification process S512. When it determines with it not being a lifetime, the lifetime notification part 159 advances a process to lighting process S521.
In the lifetime notification step S512, the lifetime notification unit 159 notifies the user that it has been determined that the lifetime is reached. Thereafter, the life notification unit 159 ends the lighting process S500.
In the lighting step S521, the control device 150 generates a control signal for operating the two control circuits 113 and 116. As a result, the two control circuits 113 and 116 start operating, power is supplied to the light source circuit 810, and the light source 811 is turned on.
In the power supply determination step S523, the power supply determination unit 151 determines whether power supply from the AC power supply AC is continued or stopped based on the signal generated by the power supply detection circuit 140. When there is power supply from the AC power supply AC, the control device 150 returns to the lighting step S521. When power supply from AC power supply AC is lost, control device 150 advances the process to voltage storage step S533.
In the voltage storing step S533, the control device 150 generates a control signal for stopping the operations of the two control circuits 113 and 116. The timer unit 152 starts measuring the elapsed time after the power supply from the AC power supply AC is stopped. The voltage input unit 153 acquires the voltage across the smoothing capacitor C34 based on the signal generated by the voltage measurement circuit 130a. Further, the voltage input unit 153 acquires the voltage across the smoothing capacitor C54 based on the signal generated by the voltage measurement circuit 130b. The voltage storage unit 154 stores the voltage across the smoothing capacitor C34 and the voltage across the smoothing capacitor C54 acquired by the voltage input unit 153.
In the waiting step S534, the time measuring unit 152 continues to measure the elapsed time after the power supply from the AC power supply AC is stopped. When the elapsed time since the power supply from the AC power supply AC has stopped reaches a predetermined time, the voltage input unit 153 advances the processing to the quotient calculation step S535. In addition, when the power supply from AC power supply AC restarts before the elapsed time after the power supply from AC power supply AC stops reaching predetermined time, the electric power feeding determination part 151 performs a process to lighting process S521. return.
In the quotient calculation step S535, the voltage input unit 153 acquires the voltage across the smoothing capacitor C34 based on the signal generated by the voltage measurement circuit 130a. Further, the voltage input unit 153 acquires the voltage across the smoothing capacitor C54 based on the signal generated by the voltage measurement circuit 130b. The quotient calculation unit 155 calculates, for the smoothing capacitor C34, a quotient obtained by dividing the both-end voltage acquired by the voltage input unit 153 by the both-end voltage stored by the voltage storage unit 154. The quotient calculation unit 155 also calculates a quotient obtained by dividing the both-end voltage acquired by the voltage input unit 153 by the both-end voltage stored by the voltage storage unit 154 for the smoothing capacitor C54. The life determination unit 157 compares the quotient calculated by the quotient calculation unit 155 with respect to the smoothing capacitor C34 with a predetermined threshold, and determines that the smoothing capacitor C34 has a life when the quotient is smaller than the threshold. The life determination unit 157 also compares the quotient calculated by the quotient calculation unit 155 with the predetermined threshold for the smoothing capacitor C54, and determines that the smoothing capacitor C54 has a lifetime when the quotient is smaller than the threshold. The determination result storage unit 158 stores the determination result of the life determination unit 157. The control device 150 ends the lighting process S500.

FIG. 5 is a waveform diagram showing the voltage across the smoothing capacitor C34 in this embodiment.
A voltage 621 indicated by a solid line and a voltage 622 indicated by a broken line both represent the voltage across the smoothing capacitor C34. Voltage 621 is when the smoothing capacitor is new, and voltage 622 is when the smoothing capacitor deteriorates with age and the capacitance is reduced.
At time 611, power supply from the AC power supply AC is stopped. The power supply determination unit 151 determines this, and at time 612, the voltage input unit 153 acquires the voltage across the smoothing capacitor C34 based on the signal generated by the voltage measurement circuit 130a. The voltage across the smoothing capacitor C34 is gradually reduced by natural discharge. At a time 613 when a predetermined time has elapsed from the time 612, the voltage input unit 153 acquires the voltage across the smoothing capacitor C34 based on the signal generated by the voltage measurement circuit 130a. The quotient calculation unit 155 calculates a quotient obtained by dividing the both-end voltage acquired at time 613 by the both-end voltage acquired at time 612.
As described above, the lighting device 800 measures the rate of voltage drop due to spontaneous discharge of the electrolytic capacitor when the power is turned off. When the capacitance of the electrolytic capacitor decreases due to aging or the like, the voltage drop rate due to natural discharge increases. For this reason, the value of the quotient calculated by the quotient calculation unit 155 is reduced. The life determination unit 157 determines that the electrolytic capacitor has a life when the value of the quotient calculated by the quotient calculation unit 155 is smaller than a predetermined threshold value.

In order to determine the life after power supply to the lighting device 800 is stopped, the control device 150 needs to continue operating for several seconds after the power supply is stopped. For this reason, the control power supply circuit 120 accumulates electric energy that can keep the control device 150 operating for several seconds. Since the operation of the control circuits 113 and 116 is stopped immediately after the power supply is stopped, only the control device 150 consumes the electric energy accumulated by the control power supply circuit 120 thereafter. In addition, it is good also as a structure which does not discharge spontaneously an electrolytic capacitor but uses a discharge circuit to perform forced discharge. The discharge circuit discharges the electrolytic capacitor when the power supply from the AC power supply AC is stopped based on the detection result of the power supply detection circuit 140. By doing so, the waiting time until the second voltage measurement can be shortened, so that the amount of electrical energy that the control power supply circuit 120 should store can be reduced.
Moreover, it is good also as a structure which does not measure the both-ends voltage of two smoothing capacitors C34 and C54, but measures only the both-ends voltage (for example, smoothing capacitor C34). In this case, a smoothing capacitor that does not measure the voltage across the end uses a capacitor that has a longer life than the smoothing capacitor that measures the voltage across the end. Then, since the smoothing capacitor that measures the voltage at both ends reaches the end of its life earlier than the smoothing capacitor that does not measure the voltage at both ends, it is only necessary to monitor the capacitance of the smoothing capacitor that measures the voltage at both ends.
The AC / DC conversion circuit 110 in this example has a two-stage configuration of a power factor correction circuit 112 and a DC / DC conversion circuit 115, and has two electrolytic capacitors. The AC / DC conversion circuit 110 may have a single-stage configuration having only one electrolytic capacitor or a configuration having three or more electrolytic capacitors. When there are three or more electrolytic capacitors, the voltage across all electrolytic capacitors may be measured, or the voltage across one or a few electrolytic capacitors that are expected to have the shortest lifetime are measured. Otherwise, a configuration in which measurement is not performed may be used.
Further, the voltage input unit 153 may be configured not only to measure the voltage across the electrolytic capacitor twice, but also to measure three times or more. If the measurement interval is the same, the ratio of the next measurement voltage to each measurement voltage should be the same. For example, the quotient calculation unit 155 calculates a quotient obtained by dividing the second and subsequent measurement voltages by the previous measurement voltage, and calculates an average value of the calculated quotients. Thereby, the precision of the lifetime determination of an electrolytic capacitor can be improved.
Note that the first voltage measurement may not be performed immediately after the power supply from the AC power supply AC is stopped. For example, the voltage input unit 153 measures in advance while the power supply from the AC power supply AC is present. The voltage input unit 153 may be configured to perform voltage measurement for the first time after a predetermined time has elapsed after the supply of power from the AC power supply AC is stopped.

Embodiment 2. FIG.
The second embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 1, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 6 is a block configuration diagram showing the configuration of the control device 150 in this embodiment.
The control device 150 includes a threshold storage unit 156 in addition to the functional blocks described in the first embodiment. The threshold value storage unit 156 (threshold value calculation unit) calculates a threshold value for determining whether or not the electrolytic capacitor has a lifetime based on the quotient calculated by the quotient calculation unit 155, and stores the calculated threshold value. For example, the threshold storage unit 156 calculates a product obtained by multiplying the quotient initially calculated by the quotient calculation unit 155 at the start of use of the lighting apparatus 800 by a predetermined coefficient (for example, 0.8), and stores the product as a threshold. . The life determination unit 157 determines that the electrolytic capacitor has a lifetime when the quotient calculated by the quotient calculation unit 155 is smaller than the threshold stored in the threshold storage unit 156.

  In the first embodiment, the capacity reduction (that is, the lifetime) of the electrolytic capacitor is determined by comparing the voltage reduction rate of the electrolytic capacitor with a predetermined threshold value. However, the natural discharge amount (or forced discharge amount) of the electrolytic capacitor may vary. In this embodiment, first, the spontaneous discharge amount (or forced discharge amount) of the electrolytic capacitor is measured, and the threshold value is determined based on the measured amount. Thereby, the precision of lifetime determination becomes high.

FIG. 7 is a flowchart showing the flow of the lighting process S500 in this embodiment.
The lighting process S500 includes a threshold value storage step S537 in addition to the steps described in the first embodiment.
In the quotient calculation step S535, when the threshold value storage unit 156 has already stored the threshold value, the control device 150 advances the process to the life determination step S536. When the threshold value storage unit 156 has not yet stored the threshold value, the control device 150 proceeds to the threshold value storing step S537.
In the threshold storage step S537, the threshold storage unit 156 calculates a product obtained by multiplying the quotient calculated by the quotient calculation unit 155 in the quotient calculation step S535 by a predetermined coefficient. The threshold storage unit 156 stores the calculated product as a threshold. The control device 150 ends the lighting process S500.

  Note that the threshold storage unit 156 does not calculate a threshold based on the quotient calculated by the quotient calculation unit 155 when the power is turned off for the first time after the use of the illumination device 800 is started, but the first plurality after the start of use of the illumination device 800. The configuration may be such that the threshold value is calculated based on a plurality of quotients calculated by the quotient calculating unit 155 one by one when each power is turned off over the time of power-off. For example, the threshold storage unit 156 calculates an average value of the quotients calculated by the quotient calculation unit 155 for the first plurality of times, calculates a product obtained by multiplying the calculated average value by a predetermined coefficient, and uses the calculated product as a threshold value. Remember. For example, the threshold storage unit 156 stores the number of times that the quotient calculation unit 155 has calculated the quotient (initial value 0) and the total value of the quotients calculated by the quotient calculation unit 155 (initial value 0). When the stored number is less than the predetermined number, the threshold storage unit 156 adds the quotient calculated by the quotient calculation unit 155 to the stored total value, and adds 1 to the stored number. That is, the threshold storage unit 156 counts the number of times the power is turned off after the lighting device 800 is used. When the stored number of times reaches a predetermined number, the threshold value storage unit 156 calculates a quotient (that is, an average value) obtained by dividing the stored total value by the stored number of times, and multiplies the calculated average value by a predetermined coefficient. The product is calculated and stored as a threshold value. Since the threshold value is calculated based on the measurement results of a plurality of times, the influence of the measurement error is reduced and the accuracy of the life determination is increased.

Embodiment 3 FIG.
A third embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 1- Embodiment 2, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 8 is a block configuration diagram showing the configuration of the control device 150 in this embodiment.
The control device 150 includes an accumulated time storage unit 161 in addition to the configuration described in the second embodiment. Based on the determination result of the power supply determination unit 151, the time measuring unit 152 not only measures the elapsed time after the power supply from the AC power supply AC is stopped after the power supply from the AC power supply AC is stopped. While the power supply from the power supply AC continues, the elapsed time from the start of the power supply from the AC power supply AC is measured. The accumulated time storage unit 161 calculates the accumulated time when the lighting device 800 receives power supply from the AC power supply AC based on the elapsed time measured by the time measuring unit 152, and stores the calculated accumulated time.
When the accumulated time stored in the accumulated time storage unit 161 is shorter than a predetermined time (initial time), the threshold storage unit 156 is based on the average value of the quotients (first quotients) calculated by the quotient calculation unit 155 so far. The threshold value is calculated and stored. Thus, the quotient calculated by the quotient calculation unit 155 when the accumulated time is shorter than the initial time is set as the first quotient. The threshold storage unit 156 preliminarily calculates the total number (initial value) of the number of times the quotient (first quotient) is calculated by the quotient calculation unit 155 (initial value 0) and the quotient (first quotient) calculated by the quotient calculation unit 155. Value 0) is stored, and an average value of the quotient (first quotient) calculated by the quotient calculation unit 155 is calculated based on the stored total value and the number of times. The initial time that the threshold value storage unit 156 compares with the accumulated time is a time when it is certain that the electrolytic capacitor has not yet deteriorated over time. For example, if the predicted average life of the electrolytic capacitor is 40,000 hours, for example, about 1000 hours. Set to.
When the accumulated time stored in the accumulated time storage unit 161 is longer than a predetermined time (end time), the lifetime determining unit 157 stores the quotient (second quotient) calculated by the quotient calculating unit 155 in the threshold storage unit 156. It is determined whether or not the electrolytic capacitor has a lifetime compared with the threshold value. In this way, the quotient calculated by the quotient calculation unit 155 when the accumulated time is longer than the end time is set as the second quotient. The end time that the life determination unit 157 compares with the accumulated time is a time at which the electrolytic capacitor may reach the end of its life due to aging. For example, if the predicted average life of the electrolytic capacitor is 40,000 hours, for example, 2 Set to about 10,000 hours.

FIG. 9 is a flowchart showing the flow of the lighting process S500 in this embodiment.
The lighting process S500 includes an energization time accumulation step S522 and an accumulation time determination step S531 in addition to the steps described in the second embodiment.
In the lighting step S521, the time measuring unit 152 advances the process to the energization time accumulation step S522 every time a predetermined time (for example, 1 hour) has elapsed since the start of power supply from the AC power supply AC. In other cases, the time measuring unit 152 proceeds to the power feeding determination step S523.
In the energization time accumulation step S522, the accumulation time storage unit 161 adds 1 to the stored accumulation time and stores the updated accumulation time. Control device 150 advances the process to power supply determination step S523.
In the power supply determination step S523, when the power supply from the AC power supply AC is stopped, the control device 150 advances the process to the accumulated time determination step S531.
In the cumulative time determination step S531, the threshold storage unit 156 (an example of the cumulative time determination unit) compares the cumulative time stored in the cumulative time storage unit 161 with a predetermined initial time. When the accumulated time is shorter than the initial time, the control device 150 proceeds to the voltage storage step S533. When the accumulated time is longer than the initial time, the life determination unit 157 (an example of the accumulated time determination unit) compares the accumulated time stored in the accumulated time storage unit 161 with a predetermined end time. If the accumulated time is longer than the end time, the control device 150 proceeds to the voltage storage step S533. When the accumulated time is shorter than the end time, the control device 150 ends the lighting process S500.
In the quotient calculation step S535, when the accumulated time stored in the accumulated time storage unit 161 is shorter than the initial time, the control device 150 advances the process to the threshold value storing step S537. When the accumulated time is longer than the end time, the control device 150 proceeds to the life determination step S536.
In the threshold storage step S537, the threshold storage unit 156 adds the quotient (first quotient) calculated by the quotient calculation unit 155 in the quotient calculation step S535 to the stored total value, and stores the updated total value. The threshold storage unit 156 adds 1 to the stored number of times and stores the updated number of times. The threshold storage unit 156 calculates an average value by calculating a quotient obtained by dividing the stored total value by the stored number of times, calculates a product obtained by multiplying the calculated average value by a predetermined coefficient, and sets the calculated product as a threshold value. Remember as.

  As described above, when the cumulative energization time of the lighting device 800 is shorter than the predetermined end time, the power consumption of the lighting device 800 can be suppressed by not performing the life determination. In addition, since the lifetime determination threshold is calculated based on the average value of the quotients calculated by the quotient calculation unit 155 while the accumulated energization time of the lighting device 800 is shorter than the predetermined initial time, the accuracy of the lifetime determination can be improved. .

  Note that the accumulated time storage unit 161 may be configured to measure and store an elapsed time after the manufacture of the lighting device 800 instead of the accumulated time of the energization time. This is because the electrolytic capacitor may deteriorate over time even when it is not energized. In that case, the cumulative time storage unit 161 has its own power source such as a lithium battery, and measures the elapsed time after manufacture using a clock that operates with the power source.

Embodiment 4 FIG.
The fourth embodiment will be described with reference to FIGS.
In addition, about the part which is common in Embodiment 1- Embodiment 3, the same code | symbol is attached | subjected and description is abbreviate | omitted.

FIG. 10 is a circuit diagram showing a circuit configuration of illumination apparatus 800 according to this embodiment.
The control power supply circuit 120 obtains power from the output of the power factor correction circuit 112 instead of the output of the full-wave rectification circuit 111, and generates control power supply power. As a result, even after the power supply from the AC power supply AC is stopped, the control power supply power can be generated from the electrical energy stored in the smoothing capacitor C34. Therefore, it is not necessary to store the electrical energy in the control power supply circuit 120. . Therefore, a smoothing capacitor having a relatively small capacitance can be used for the control power supply circuit 120. The use of another type of capacitor such as a ceramic capacitor instead of an electrolytic capacitor as the smoothing capacitor of the control power supply circuit 120 ensures a longer lifetime than the smoothing capacitor C34 and the smoothing capacitor C54 that are electrolytic capacitors.
In addition, since the control power supply circuit 120 serves as a discharge circuit that discharges the smoothing capacitor C34, the waiting time until the voltage input unit 153 performs the second voltage measurement can be shortened. In addition, since the electric energy accumulated in the smoothing capacitor C34 is not wasted by simply discharging the smoothing capacitor C34, but is used for the operation of the control device 150, the power consumed by the lighting device 800 can be suppressed.

FIG. 11 is a flowchart showing the flow of the lighting process S500 in this embodiment.
The lighting process S500 includes a life storage process S532 in addition to the processes described in the third embodiment.
In the cumulative time determination step S531, when the cumulative time stored in the cumulative time storage unit 161 is longer than a predetermined end time, the control device 150 advances the process to the life storage step S532. When the accumulated time is shorter than the predetermined initial time, control device 150 advances the process to voltage storage step S533.
In the life storage step S532, the determination result storage unit 158 stores the determination result on the assumption that the life determination unit 157 determines that the electrolytic capacitor has a life.
In the life determination step S536, the determination result storage unit 158 stores a formal determination result by the life determination unit 157.

In lighting apparatus 800 in this embodiment, after power supply from AC power supply AC is stopped, control power supply circuit 120 generates control power supply power from the electrical energy stored in smoothing capacitor C34. When the capacitance of the smoothing capacitor C34 is reduced due to aging, the amount of electrical energy stored in the smoothing capacitor C34 is reduced. Therefore, before the waiting time until the second voltage measurement elapses, the control device 150 may not be able to continue operation. However, in this case, since the capacitance of the smoothing capacitor C34 is reduced, it can be determined that the smoothing capacitor C34 has a life without waiting for the determination by the life determination unit 157.
When the control device 150 stops operating during the execution of the waiting step S534 without reaching the lifetime determination step S536, the determination result storage unit 158 holds the contents stored in the lifetime storage step S532. That is, the determination result storage unit 158 stores a determination result that the electrolytic capacitor has a lifetime.

  As described above, even when the control device 150 cannot continue the operation for a predetermined time, it is determined that the smoothing capacitor C34 has a lifetime, so that the lifetime of the smoothing capacitor C34 can be correctly determined.

  DESCRIPTION OF SYMBOLS 100 Power supply device, 110 AC / DC conversion circuit, 111 Full wave rectification circuit, 112 Power factor improvement circuit, 113,116 Control circuit, 114,117 Feedback circuit, 115 DC / DC conversion circuit, 120 Control power supply circuit, 130 Voltage measurement circuit, 140 power supply detection circuit, 150 control device, 151 power supply determination unit, 152 timing unit, 153 voltage input unit, 154 voltage storage unit, 155 quotient calculation unit, 156 threshold storage unit, 157 life determination unit, 158 determination result storage unit, 159 Life notification unit, 161 cumulative time storage unit, 611-613 time, 621, 622 voltage, 800 lighting device, 810 light source circuit, 811 light source, AC AC power supply, C21 input capacitor, D33, D52 rectifier, C34, C54 smoothing capacitor DB diode bridge, L31, L53 h Yoke coil, Q32, Q51 switching element, R41, R42, R71, R72 voltage dividing resistor, R61 current detection resistor.

Claims (10)

In a power supply device that converts AC power supplied from an AC power source into DC power,
An electrolytic capacitor;
A voltage measuring circuit for measuring the voltage across the electrolytic capacitor;
A control power supply circuit that generates a control power supply until a predetermined time elapses after the supply of AC power from the AC power supply is stopped,
A life determination circuit that operates by the control power supply generated by the control power supply circuit and determines whether or not the electrolytic capacitor has a lifetime based on the voltage across the electrolytic capacitor measured by the voltage measurement circuit ;
A cumulative time storage unit that stores a cumulative time obtained by accumulating the energization time during which the supply of AC power from the AC power source continues ,
The lifetime judgment circuit is
When the supply of AC power from the AC power supply is stopped, it is determined whether or not the accumulated time is shorter than a predetermined initial time, and the accumulated time is a predetermined end time. An accumulated time determination unit that determines whether or not the end time is longer than the initial time;
When it is determined that the accumulated time is shorter than the initial time or the accumulated time is longer than the end time, the voltage measuring circuit measures immediately after the supply of AC power from the AC power supply is stopped . A voltage storage unit for storing the voltage across the electrolytic capacitor;
When it is determined that the accumulated time is shorter than the initial time or the accumulated time is longer than the end time, a predetermined time elapses after the supply of AC power from the AC power supply is stopped. A quotient calculation unit for calculating a quotient obtained by dividing the voltage across the electrolytic capacitor measured by the voltage measurement circuit by the voltage across the electrolytic capacitor stored in the voltage storage unit;
When it is determined that the accumulated time is longer than the end time , the first quotient calculated by the quotient calculating unit when the accumulated time is shorter than the initial time, and the accumulated time is the end time. A life determination unit that determines whether or not the electrolytic capacitor has a lifetime based on the second quotient calculated by the quotient calculation unit when the length is longer than the quotient .   The life determination circuit further includes
  When it is determined that the accumulated time is shorter than the initial time, a threshold value is calculated based on the first quotient calculated by the quotient calculation unit, and the calculated threshold value is stored in the threshold value storage unit. Part
  The life determination unit is
  2. The power supply device according to claim 1, wherein it is determined whether or not the electrolytic capacitor has a lifetime based on the threshold value and the second quotient stored in the threshold value storage unit.   The threshold calculation unit
  The number of times the threshold value calculation unit has calculated the quotient and the total value of the quotient values calculated by the threshold value calculation unit so far are acquired, and a value obtained by dividing the total value by the number of times is multiplied by a predetermined coefficient. The power supply device according to claim 2, wherein the product is calculated as the threshold value. The life determination unit is
When the second quotient calculated by the quotient calculation unit is compared with the threshold stored in the threshold storage unit, and the second quotient is smaller than the threshold, the electrolytic capacitor has a lifetime. The power supply device according to claim 2, wherein the power supply device is determined. The lifetime judgment circuit is
A determination result storage unit that stores the determination result determined by the lifetime determination unit;
The power supply device based on the determination result of the determination result storage unit and stored by, when the electrolytic capacitor is life, power according to any one of claims 1 to 4, characterized in that stopping the operation apparatus. The control power supply circuit uses the energy charged in the electrolytic capacitor, the power supply device according to claim 1, characterized in that to generate the control power. The life determination unit determines that the electrolytic capacitor has a life when the life determination circuit becomes inoperable before the quotient calculation unit calculates a quotient . The power supply device according to any one of 6 . The power supply device has at least one of a power factor correction circuit and a DC / DC conversion circuit,
The electrolytic capacitor, the power supply device according to claim 1, characterized in that it is a part of the power factor improvement circuit or the DC-DC converter circuit. A power supply device according to any one of claims 1 to 8 ,
An illumination device comprising: a light source that is lit by receiving supply of DC power converted by the power supply device. The lighting device is
The lighting device according to claim 9 , further comprising a life notification unit that blinks the light source when the life determination unit determines that the electrolytic capacitor has a lifetime.

Images