JP5627306B2 - Guide light device - Google Patents

Description

  The present invention relates to a light emitting device that lights a light source such as an LED.

When a switch is provided between the DC power source and the light source and the light source is turned on and off by turning the switch on and off, a surge current may flow when the switch is turned on and the light source may be destroyed.
There is a technique for suppressing surge current by providing a surge current suppression circuit.

International Publication No. 2009-96414

If the surge current suppression circuit is provided, the number of parts increases and the circuit becomes complicated, so that the parts cost and assembly cost increase, and the reliability decreases.
The present invention has been made to solve the above-described problems, for example, and an object thereof is to efficiently suppress a surge current while suppressing an increase in the number of parts and a complicated circuit.

  The light emitting device according to the present invention is interposed between a lighting circuit that generates DC power, a light source circuit that includes a light source that is lit by DC power generated by the lighting circuit, and between the lighting circuit and the light source circuit, DC power supplied from the lighting circuit to the light source circuit can be cut off, and when transitioning from the cut-off state to the conductive state, the impedance gradually decreases from the impedance in the cut-off state to the impedance in the conductive state. And a switch circuit.

  According to the light emitting device of the present invention, since the switch circuit itself suppresses the surge current, the surge current can be efficiently suppressed while suppressing an increase in the number of components and the complexity of the circuit.

FIG. 3 is a perspective view showing an appearance of a guide lamp device 800 in the first embodiment. FIG. 3 is a circuit diagram illustrating a configuration of the lighting device 100 and the like in the first embodiment. FIG. 4 is a timing chart showing an example of the operation of the guide lamp device 800 in the first embodiment. FIG. 6 is a timing chart showing another example of the operation of the guide light device 800 in the first embodiment. FIG. 6 is a flowchart showing a flow of a lighting process S500 in the first embodiment. FIG. 3 is a timing chart showing voltages at various parts when the microcomputer 160 in the first embodiment turns on a switch circuit 140; The timing diagram which shows the voltage etc. of each part in a comparative example.

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

FIG. 1 is a perspective view showing an appearance of a guide light device 800 according to this embodiment.
The guide light device 800 includes a main body 810, a light source unit 820, and a display unit 830.
The main body 810 is a casing of the guide light device 800 and incorporates a lighting device 100, a storage battery 200, and the like which will be described later.
The light source unit 820 includes a light source circuit 300 described later.
The display unit 830 displays an evacuation guidance graphic. The display unit 830 is illuminated by the light source of the light source circuit 300.

FIG. 2 is a circuit diagram showing the configuration of the lighting device 100 and the like in this embodiment.
The light source circuit 300 includes one or more light sources 310. The light source 310 is, for example, an LED. The light source 310 is electrically connected in series, for example. The light source 310 emits light by DC power supplied from the lighting device 100.
The lighting device 100 is supplied with power from an AC power source AC such as a commercial power source during normal times, and generates DC power to be supplied to the light source circuit 300. In addition, the lighting device 100 receives supply of power from the storage battery 200 in an emergency such as a power failure and generates DC power to be supplied to the light source circuit 300.
Storage battery 200 (battery) is charged with electric power supplied from AC power supply AC through a charging circuit (not shown) in normal times. The electric power charged in the storage battery 200 is used for operating the lighting device 100 and lighting the light source 310 in an emergency.

  The lighting device 100 is a guide lamp power supply unit. The lighting device 100 includes a rectifier circuit 110, two DC / DC conversion circuits 120 and 220, two control power supply circuits 130 and 230, two switch circuits 140 and 240, a current detection circuit 150, a microcomputer 160, And a power failure detection circuit 170.

  The rectifier circuit 110 rectifies AC power supplied from the AC power supply AC, and makes the voltage waveform pulsate. The rectifier circuit 110 has a diode bridge DB, for example. The diode bridge DB is a circuit in which four diodes are bridge-connected. The diode bridge DB performs full-wave rectification on the input AC power.

  The power failure detection circuit 170 is electrically connected to the output side of the rectifier circuit 110. The power failure detection circuit 170 monitors the voltage waveform of the power rectified by the rectifier circuit 110 and detects whether AC power is supplied from the AC power source AC (energized state) or not (power failure state). The power failure detection circuit 170 generates a power failure detection signal representing the detected result. The power failure detection circuit 170 outputs the generated power failure detection signal to the microcomputer 160 through a signal transmission circuit such as a photocoupler (not shown) while maintaining electrical insulation. The power failure detection signal represents, for example, a “power failure state” when the 0 level is maintained, and a “energization state” otherwise.

The DC / DC converter circuit 120 (lighting circuit) converts the power rectified by the rectifier circuit 110 to generate DC power. The DC / DC converter circuit 120 adjusts the current value of the generated DC power based on the feedback signal generated by the current detection circuit 150. Accordingly, the DC / DC conversion circuit 120 operates as a constant current circuit that supplies a constant current to the light source circuit 300. The DC / DC converter circuit 120 is a regular circuit that operates with AC power supplied from an AC power supply AC.
The DC / DC conversion circuit 120 is, for example, a flyback converter circuit. The DC / DC converter circuit 120 includes a control IC 121, a switching element Q22, two windings L23 and L24, a diode D25, and a smoothing capacitor C26. The winding L23 is a primary winding of the transformer T1. The winding L24 is a secondary winding of the transformer T1. The two windings L23 and L24 are electromagnetically coupled. The smoothing capacitor C26 is, for example, an electrolytic capacitor.
The control IC 121 is a constant current control circuit. The control IC 121 controls switching of the switching element Q22. The control IC 121 generates a drive signal for turning on / off the switching element Q22 at a high frequency. The control IC 121 inputs a feedback signal while maintaining electrical insulation via a signal transmission circuit such as a photocoupler (not shown). The control IC 121 adjusts the current value of the DC power generated by the DC-DC converter circuit 120 by changing the duty ratio and frequency of the drive signal based on the input feedback signal.
The switching element Q22 is, for example, an enhancement type NMOS field effect transistor (FET). The switching element Q22 and the winding L23 are electrically connected in series. For example, the drain terminal of the switching element Q22 and one end of the winding L23 are electrically connected. The switching element Q22 is driven by a drive signal generated by the control IC 121. When the switching element Q22 is turned on, the power rectified by the rectifier circuit 110 is supplied to the winding L23, and the current flowing through the winding L23 increases. When the switching element Q22 is turned off, the current flowing through the winding L23 becomes zero.
Winding L24, diode D25, and smoothing capacitor C26 are electrically connected in series with each other to form a closed circuit (load power supply circuit). The direction of the diode D25 is a direction in which the diode D25 is turned off when the switching element Q22 is turned on. When the switching element Q22 is on, a voltage proportional to the voltage applied to both ends of the winding L23 is generated at both ends of the winding L24. At this time, since the diode D25 is turned off, no current flows through the winding L24. When the switching element Q22 is turned off, a current proportional to the current flowing through the winding L23 flows through the winding L24, and the diode D25 is turned on. The direction of the smoothing capacitor C26 is the direction charged by the current flowing through the diode D25.
The DC / DC conversion circuit 120 outputs the energy accumulated in the smoothing capacitor C26 in this way as DC power.
Note that the DC / DC converter circuit 120 is not limited to a flyback converter circuit, and may be, for example, another switching converter circuit such as a buck converter circuit or a forward converter circuit, or a circuit having another configuration.

The control power supply circuit 130 generates a power supply for the microcomputer 160. The control power supply circuit 130 generates DC power supply power for operating the microcomputer 160. The control power supply circuit 130 is an ordinary circuit that operates with AC power supplied from the AC power supply AC.
The control power supply circuit 130 includes, for example, a winding L31, a diode D32, and a smoothing capacitor C33. The winding L31 is a tertiary winding of the transformer T1. The winding L31 is electromagnetically coupled to the winding L23 and the winding L24. The smoothing capacitor C33 is, for example, an electrolytic capacitor.
Winding L24, diode D32, and smoothing capacitor C33 are electrically connected in series with each other to form a closed circuit. The direction of the diode D32 is a direction in which the diode D32 is turned off when the switching element Q22 is turned on. The direction of the smoothing capacitor C33 is the direction charged by the current flowing through the diode D32.
The operation of the control power circuit 130 is the same as that of the secondary circuit (load power circuit) of the DC / DC converter circuit 120. Due to the difference in the number of turns between the winding L24 and the winding L31, there is a difference between the voltage across the smoothing capacitor C26 of the DC / DC conversion circuit 120 and the voltage across the smoothing capacitor C33 of the control power supply circuit 130.

The current detection circuit 150 (load current detection circuit) is electrically connected in series with the light source circuit 300. The current detection circuit 150 detects the current flowing through the light source circuit 300 and generates a feedback signal representing the value of the detected current. The feedback signal generated by the current detection circuit 150 indicates whether the value of the current flowing through the light source circuit 300 is larger or smaller than the target current value. For example, the feedback signal indicates that the value of the current flowing through the light source circuit 300 is equal to the target current value at a predetermined voltage value. When the voltage value is higher than the predetermined voltage value, the value of the current flowing through the light source circuit 300 is larger than the target current value. Conversely, when the voltage value is lower than the predetermined voltage value, it indicates that the value of the current flowing through the light source circuit 300 is smaller than the target current value.
The current detection circuit 150 includes, for example, a resistor R51, a resistor R52, and a switching element Q53. The resistor R51 and the resistor R52 are electrically connected in series with each other. The switching element Q53 is electrically connected in parallel with the resistor R51. The switching element Q53 is turned on / off according to the current switching signal generated by the microcomputer 160. The current detection circuit 150 outputs the total voltage of the voltage generated at both ends of the resistor R51 and the voltage generated at both ends of the resistor R52 as the voltage value of the feedback signal. When the switching element Q53 is off, the current flowing through the light source circuit 300 flows through the resistor R51 and the resistor R52, and the voltage value of the feedback signal is the sum of the resistance value of the resistor R51 and the resistance value of the resistor R52, and the light source circuit It is the product of the value of the current flowing through 300. When the switching element Q53 is on, both ends of the resistor R51 are short-circuited, so that the voltage across the resistor R51 is 0, and the voltage value of the feedback signal is the resistance value of the resistor R52 and the current flowing through the light source circuit 300. The product of the value. Therefore, even when the currents flowing through the light source circuit 300 are the same, the voltage value of the feedback signal is lower when the switching element Q53 is on than when the switching element Q53 is off. This means that the target current value is larger when the switching element Q53 is on than when the switching element Q53 is off.
The current detection circuit 150 may have another configuration as long as the combined resistance value changes according to the current switching signal from the microcomputer 160. When there is no need to switch the target current value, a configuration in which the resistance value does not change, such as a mere fixed resistance, may be used.

The switch circuit 140 is interposed between the DC / DC conversion circuit 120 and the light source circuit 300. The switch circuit 140 blocks the DC power supplied from the DC / DC conversion circuit 120 to the light source circuit 300 based on the normal switching signal (first switch control signal) generated by the microcomputer 160. When the switch circuit 140 transitions from an off state (cut-off state) to an on state (conduction state), the impedance gradually decreases from a large impedance in the off state to a small impedance in the on state.
The switch circuit 140 includes, for example, a switching element Q41, a resistor R42, and a delay circuit 149. The delay circuit 149 includes a switching element Q43, a capacitor C44, a charging resistor R45, a discharging resistor R46, and a diode D47.
The switching element Q41 is, for example, an enhancement type PMOSFET. The switching element Q41 is electrically connected to the output of the DC / DC conversion circuit 120. When the switching element Q41 is turned on, the DC power generated by the DC / DC conversion circuit 120 is supplied to the light source circuit 300. When the switching element Q41 is turned off, the DC power generated by the DC / DC conversion circuit 120 is not supplied to the light source circuit 300.
The resistor R42 is electrically connected between the gate terminal and the source terminal of the switching element Q41, for example. When the voltage across the resistor R42 is high, the switching element Q41 has a low impedance (for example, several Ω [ohm]) and is turned on. When the voltage across the resistor R42 is low, the switching element Q41 has a high impedance (for example, several hundred MΩ [mega ohms]) and is turned off. When the voltage across the resistor R42 is intermediate, the switching element Q41 enters an intermediate state having an intermediate impedance between the on state and the off state.
The switching element Q43 is, for example, an enhancement type NMOSFET. The switching element Q43 is electrically connected in series with the resistor R42. When the switching element Q43 is off, no current flows through the resistor R42, so the voltage across the resistor R42 is 0 and the switching element Q41 is also off. When the switching element Q43 is on, a current flows through the resistor R42, so that a voltage is generated across the resistor R42 and the switching element Q41 is turned on. When the switching element Q43 is in an intermediate state between the on state and the off state, since the current flowing through the resistor R42 is small, the switching element Q41 is also in an intermediate state between the on state and the off state.
The capacitor C44 is electrically connected, for example, between the gate terminal and the source terminal of the switching element Q43. When the voltage across the capacitor C44 is high, the switching element Q43 is turned on. When the voltage across the capacitor C44 is low, the switching element Q43 is turned off. When the voltage across the capacitor C44 is intermediate, the switching element Q43 is in an intermediate state between the on state and the off state.
The charging resistor R45 is electrically connected in series with the capacitor C44. The charging resistor R45 converts the normal switching signal generated by the microcomputer 160 into a current for charging the capacitor C44. In this example, the regular switching signal generated by the microcomputer 160 indicates ON when the potential is high (for example, 5 V [volt]), and OFF when the potential is low (for example, 0 V). When the normal switching signal changes from a low potential to a high potential, the capacitor C44 is charged by the current flowing through the charging resistor R45, and the voltage across the capacitor C44 gradually increases. Thereby, switching element Q43 is slowly turned on through the intermediate state from the off state. Similarly, the switching element Q41 is slowly turned on through an intermediate state from the off state.
The discharge resistor R46 and the diode D47 are electrically connected in series with each other, and are electrically connected in parallel with the charge resistor R45. The direction of the diode D47 is such that it is turned off when the common switching signal is at a high potential, and is turned on when the common switching signal is at a low potential. When the normal switching signal changes from a high potential to a low potential, the diode D47 is turned on, and a current for discharging the capacitor C44 flows through the discharge resistor R46 and the diode D47. Since the capacitor C44 is discharged by the current flowing through the charging resistor R45 and the current flowing through the discharging resistor R46 and the diode D47, the capacitor C44 is discharged faster than at the time of charging. Thereby, switching element Q43 is quickly turned off from the on state. Similarly, the switching element Q41 is quickly turned off from the on state.

The DC / DC conversion circuit 220 (lighting circuit) is electrically connected to the storage battery 200. The DC / DC conversion circuit 220 operates using the storage battery 200 as a power source. The DC / DC conversion circuit 220 converts the power charged in the storage battery 200 to generate DC power. The DC / DC conversion circuit 220 adjusts the voltage value of the generated DC power based on the feedback signal generated by the current detection circuit 150. Accordingly, the DC / DC conversion circuit 220 operates as a constant current circuit that supplies a constant current to the light source circuit 300. The DC / DC converter circuit 220 is an emergency operation circuit that operates only during a power failure in accordance with an emergency operation signal generated by the microcomputer 160.
The DC / DC conversion circuit 220 is, for example, a boost converter circuit. The DC / DC conversion circuit 220 includes a control IC 221, a switching element Q82, a winding L83, a diode D85, and a smoothing capacitor C86. Winding L83 is a primary winding of transformer T2. The smoothing capacitor C86 is, for example, an electrolytic capacitor.
The control IC 221 (step-up constant current control circuit) controls switching of the switching element Q82. The control IC 221 generates a drive signal for turning on / off the switching element Q82 at a high frequency. The control IC 221 adjusts the voltage value of the DC power generated by the DC / DC conversion circuit 220 by changing the duty ratio and frequency of the drive signal based on the feedback signal.
The switching element Q82 is, for example, an enhancement type NMOSFET. Switching element Q82 and winding L83 are electrically connected in series. The switching element Q82 is driven by a drive signal generated by the control IC 221. When switching element Q82 is turned on, the output voltage of storage battery 200 is applied to winding L83, and the current flowing through winding L83 increases.
The diode D85 and the smoothing capacitor C86 are electrically connected in series with each other, and are electrically connected in parallel with the switching element Q82. The direction of the diode D85 is a direction in which the diode D85 is turned off when the switching element Q82 is turned on. The direction of the smoothing capacitor C86 is the direction charged by the current flowing through the diode D85. When the switching element Q82 is turned off, the diode D85 is turned on, and the smoothing capacitor C86 is charged with the current flowing through the winding L83. If the voltage across the smoothing capacitor C86 is greater than the voltage of the storage battery 200, a reverse voltage is applied to the winding L83, and the current flowing through the winding L83 decreases.
The DC / DC conversion circuit 220 outputs the energy accumulated in the smoothing capacitor C86 in this way as DC power.
Note that the DC / DC conversion circuit 220 is not limited to the boost converter circuit, and may be, for example, another switching converter circuit such as a flyback converter circuit or a forward converter circuit, or a circuit having another configuration.

The control power supply circuit 230 (second control power supply) generates a power supply for the microcomputer 160 during a power failure when the DC / DC conversion circuit 220 is operating. The control power circuit 230 generates direct current power for operating the microcomputer 160.
The control power supply circuit 230 includes, for example, a winding L36, a diode D37, and a smoothing capacitor C38. The winding L36 is a secondary winding of the transformer T2. Winding L36 is electromagnetically coupled to winding L83. The smoothing capacitor C38 is, for example, an electrolytic capacitor.
Winding L36, diode D37, and smoothing capacitor C38 are electrically connected in series with each other to form a closed circuit. The direction of the diode D37 is a direction in which the diode D37 is turned off when the switching element Q82 is turned on. The direction of the smoothing capacitor C38 is the direction charged by the current flowing through the diode D37.
The operation of the control power supply circuit 230 is the same as that of the secondary side circuit of the DC / DC conversion circuit 120 and the control power supply circuit 130. The control power supply circuit 230 operates when the DC / DC conversion circuit 220 operates and the switching element Q82 is turned on / off at a high frequency.

The switch circuit 240 is interposed between the DC / DC conversion circuit 220 and the light source circuit 300. The switch circuit 240 cuts off the DC power supplied from the DC / DC conversion circuit 220 to the light source circuit 300 based on the emergency switching signal (second switch control signal) generated by the microcomputer 160. When the switch circuit 240 transitions from an off state (blocking state) to an on state (conducting state), the impedance gradually decreases from a large impedance in the off state to a small impedance in the on state.
The configuration and operation of the switch circuit 240 are almost the same as the configuration of the switch circuit 140. The switch circuit 240 includes, for example, a switching element Q91, a resistor R92, a delay circuit 249, and a diode D98. The delay circuit 249 includes a switching element Q93, a capacitor C94, a charging resistor R95, a discharging resistor R96, and a diode D97.

The diode D98 prevents the smoothing capacitor C86 of the DC / DC conversion circuit 220 from being charged by the DC power generated by the DC / DC conversion circuit 120 in a normal state. As will be described later, since the target current value at the time of emergency lighting is smaller than the target current value at the time of normal lighting, the voltage value of the DC power generated by the DC / DC conversion circuit 220 is the DC value generated by the DC / DC conversion circuit 120. Lower than the voltage value of power.
If there is no diode D98, a reverse voltage is applied to the switching element Q91 in a normal state, the protection diode inside the switching element Q91 is turned on, and a current for charging the smoothing capacitor C86 of the DC / DC conversion circuit 220 is generated. Flowing. As a result, the voltage across the smoothing capacitor C86 becomes substantially equal to the voltage across the smoothing capacitor C26. When switching to emergency lighting in this state, the same current as the target current value during normal lighting flows through the light source circuit 300 until the voltage across the smoothing capacitor C86 decreases.

The microcomputer 160 controls the operations of the DC / DC conversion circuits 120 and 220, the switch circuits 140 and 240, and the current detection circuit 150. The microcomputer 160 operates using the DC control power generated by the control power circuit 130 and the control power circuit 230 as a power source. The microcomputer 160 receives the power failure detection signal generated by the power failure detection circuit 170 and generates the above-described emergency operation signal, current switching signal, regular switching signal, and emergency switching signal.
For example, the microcomputer 160 includes a ground terminal 161, a power input terminal 162, a power failure detection input terminal 163, a current switching output terminal 164, a regular switching output terminal 165, an emergency switching output terminal 166, and an emergency operation output terminal 167. And have.
The ground terminal 161 is electrically connected to a ground wiring having a reference potential in the lighting device 100. The power supply input terminal 162 is electrically connected to the control power supply circuit 130 and the control power supply circuit 230 and inputs DC control power.
The power failure detection input terminal 163 is electrically connected to the power failure detection circuit 170 and inputs a power failure detection signal.
The current switching output terminal 164 is electrically connected to the current detection circuit 150 and outputs a current switching signal. The common switching output terminal 165 is electrically connected to the switch circuit 140 and outputs a common switching signal. The emergency switching output terminal 166 is electrically connected to the switch circuit 240 and outputs an emergency switching signal. The emergency operation output terminal 167 is electrically connected to the control power supply circuit 230 and outputs an emergency operation signal.

Although not shown, the microcomputer 160 includes a processing device, an input device, an output device, and a storage device.
The microcomputer 160 implements the functions described below when the processing device executes the program stored in the storage device. If equivalent functions can be realized, the following functions are realized not by the microcomputer 160 but by other configurations such as electronic circuits such as digital circuits and analog circuits, other electrical configurations, and mechanical configurations. Also good.

When determining that the microcomputer 160 is in the energized state, the normal switching signal for turning on the switch circuit 140, the emergency switching signal for turning off the switch circuit 240, the emergency operation signal for stopping the DC / DC conversion circuit 220, A current switching signal for generating a target current value of the current detection circuit 150 at a normal value is generated.
When it is determined that the energized state has changed to the power failure state, the microcomputer 160 first generates a normal switching signal for turning off the switch circuit 140 and a current switching signal for setting the target current value of the current detection circuit 150 to an emergency value. Generate. After a predetermined time (for example, 0.5 seconds) elapses, the microcomputer 160 generates an emergency switching signal for turning on the switch circuit 240 and an emergency operation signal for operating the DC / DC conversion circuit 220.
When it is determined that the power supply state has returned from the power failure state, the microcomputer 160 firstly sets the emergency switching signal for turning off the switch circuit 240, the emergency operation signal for stopping the DC / DC conversion circuit 220, and the target current of the current detection circuit 150. A current switching signal for generating a normal value is generated. After a predetermined time (for example, 0.5 seconds) elapses, the microcomputer 160 generates a regular switching signal that turns on the switch circuit 140.

FIG. 3 is a timing chart showing an example of the operation of the guide lamp device 800 in this embodiment.
The horizontal axis represents time. The vertical axis represents the brightness of the light source 310.
In the conductive state, the guide lamp device 800 causes the light source circuit 300 to pass a current having a normal target current value, and turns on the light source 310 with the normal brightness (normal lighting mode).
If a power failure occurs at time 701, the guide lamp device 800 temporarily stops power supply to the light source circuit 300 and temporarily turns off the light source 310. At a time 702 when a predetermined time has passed since then, the guide lamp device 800 supplies the light source circuit 300 with the current of the emergency target current value, and lights the light source 310 with the emergency brightness (emergency lighting mode). Since the target current value at the time of emergency is smaller than the target current value at normal time, the light source 310 is lit darker than normal.
Thereafter, at time 703, if the power failure ends and power is restored, the guide lamp device 800 temporarily stops power supply to the light source circuit 300 and temporarily turns off the light source 310. At a time 704 when a predetermined time has passed since then, the guide lamp device 800 supplies a current having a target current value in the normal state to the light source circuit 300 and turns on the light source 310 to return to the normal brightness.

FIG. 4 is a timing chart showing another example of the operation of the guide light device 800 in this embodiment.
The horizontal axis represents time. The vertical axis represents the brightness of the light source 310.
If the power does not recover even after a predetermined time (for example, 1 hour) has elapsed after the occurrence of a power failure, the energy stored in the storage battery 200 is used up, and the microcomputer 160 and the control power supply circuit 230 stop operating at time 705. As a result, the light source 310 is turned off.

FIG. 5 is a flowchart showing the flow of the lighting process S500 in this embodiment.
In the lighting process S500, the guide light device 800 turns on the light source 310. The lighting process S500 includes a normal system operation step S501, a power failure determination step S502, a normal system stop step S503, an emergency system operation step S504, a power recovery determination step S505, and an emergency system stop step S506.

When the guide lamp device 800 is supplied with power from the AC power supply AC and the DC / DC conversion circuit 120 starts operating, the control power circuit 130 generates DC control power, and the microcomputer 160 starts operating.
In the normal operation step S501, the microcomputer 160 turns off the normal switching signal for turning on the switch circuit 140, the current switching signal for setting the target current value of the current detection circuit 150 to a normal value, and the switch circuit 240. An emergency switching signal and an emergency operation signal for stopping the DC / DC conversion circuit 220 are generated. As a result, the emergency circuits such as the DC / DC conversion circuit 220 and the control power supply circuit 230 stop operating. On the other hand, the DC power generated by the DC / DC conversion circuit 120 is supplied to the light source circuit 300 via the switch circuit 140. The DC / DC conversion circuit 120 adjusts the current value of the DC power generated based on the feedback signal generated by the current detection circuit 150, and the current of the target current value in the normal state flows through the light source circuit 300.
In the power failure determination step S502, when the microcomputer 160 determines that the energized state continues, the microcomputer 160 repeats the power failure determination step S502.
If it is determined that a power failure has occurred, the microcomputer 160 proceeds to the regular system stop step S503.

In the normal system stop step S503, the microcomputer 160 generates a normal switching signal for turning off the switch circuit 140 and a current switching signal for setting the target current value of the current detection circuit 150 to an emergency value. Since the DC / DC conversion circuit 120 stops operating due to a power failure, there is no need for the microcomputer 160 to actively stop the operation of the DC / DC conversion circuit 120, but the energy accumulated in the smoothing capacitor C26 remains. The light source 310 is not turned off unless the switch circuit 140 is turned off. By turning off the switch circuit 140, the light source 310 is turned off.
The microcomputer 160 waits for a predetermined time to elapse. As the operation of the DC / DC converter circuit 120 stops, the control power supply circuit 130 stops operating. The microcomputer 160 operates using the energy stored in the smoothing capacitor C33. Therefore, the capacitance of the smoothing capacitor C33 is set so that the energy stored in the smoothing capacitor C33 is not used up before the predetermined time has elapsed.
After the predetermined time has elapsed, the microcomputer 160 proceeds to the emergency system operation step S504.

In the emergency system operation step S504, the microcomputer 160 generates an emergency switching signal for turning on the switch circuit 240 and an emergency operation signal for operating the DC / DC conversion circuit 220. As a result, the DC / DC conversion circuit 220 starts operating. The DC power generated by the DC / DC conversion circuit 220 is supplied to the light source circuit 300 via the switch circuit 240. The DC / DC conversion circuit 220 adjusts the voltage value of the DC power to be generated based on the feedback signal generated by the current detection circuit 150, and the current of the target current value in an emergency flows through the light source circuit 300. As the DC / DC converter circuit 220 starts operating, the control power circuit 230 starts operating to generate DC control power, and the microcomputer 160 operates using the DC control power generated by the control power circuit 230 as a power source. continue.
In the power recovery determination step S <b> 505, the microcomputer 160 determines whether the power failure continues or is restored based on the power failure detection signal generated by the power failure detection circuit 170.
If it is determined that the power failure continues, the microcomputer 160 repeats the power recovery determination step S505. If the power is not restored as it is, the energy stored in the storage battery 200 is used up and the guide lamp device 800 stops its operation.
If it is determined that the power has been restored, the microcomputer 160 proceeds to the emergency system stop step S506.

In the emergency system stop step S506, the microcomputer 160 sets the emergency switching signal for turning off the switch circuit 240, the emergency switching signal for stopping the operation of the DC / DC conversion circuit 220, and the target current value of the current detection circuit 150 in a normal state. And a current switching signal to generate a value. Although the DC / DC conversion circuit 120 starts operating due to the power recovery, the light source 310 is turned off because both the switch circuit 140 and the switch circuit 240 are off.
The microcomputer 160 waits for a predetermined time to elapse. As the operation of the DC / DC converter circuit 220 stops, the control power circuit 230 also stops operating. However, as the operation of the DC / DC converter circuit 120 starts, the control power circuit 130 also starts operating. The microcomputer 160 operates with DC control power generated by the control power supply circuit 130.
After the predetermined time has elapsed, the microcomputer 160 returns the process to the normal operation step S501.

FIG. 6 is a timing chart showing voltages at various parts when the microcomputer 160 in this embodiment turns on the switch circuit 140.
The horizontal axis represents time. The vertical axis represents voltage or resistance or current. The resistance is a logarithmic scale.
A voltage value 731 indicated by a solid line is a voltage across the smoothing capacitor C26. A voltage value 732 indicated by a thin broken line is a voltage across the smoothing capacitor C26 before the switch circuit 140 is turned on. A voltage value 733 indicated by a thin broken line is a voltage across the smoothing capacitor C26 when the current flowing through the light source circuit 300 matches the target current value.
A voltage value 734 indicated by a solid line is a potential of the regular switching signal generated by the microcomputer 160. A voltage value 735 indicated by a dotted line is a gate-source voltage of the switching element Q43. A voltage value 736 indicated by a broken line is a source-gate voltage of the switching element Q41.
A resistance value 741 indicated by a solid line is a source-drain resistance (impedance) of the switching element Q41. A resistance value 742 indicated by a thin broken line is a source-drain resistance when the switching element Q41 is in an OFF state. A resistance value 743 indicated by a thin broken line is a source-drain resistance when the switching element Q41 is in an ON state.
A current value 751 indicated by a solid line is a current flowing through the light source circuit 300. A current value 752 indicated by a thin broken line is a target current value of a current flowing through the light source circuit 300.

  It is assumed that when the switch circuit 140 is off, the voltage across the smoothing capacitor C26 has a voltage value 732 higher than the originally required voltage value 733 for some reason. For example, when the DC-DC converter circuit 120 starts operating before the switch circuit 140 is turned on, a current for charging the smoothing capacitor C26 flows. Since the switch circuit 140 is off, there is no path for discharging the smoothing capacitor C26, and the voltage across the smoothing capacitor C26 increases. In addition, since no current flows through the light source circuit 300, the current detection circuit 150 does not generate a feedback signal. Since there is no feedback signal, the DC / DC converter circuit 120 operates in a direction to increase the voltage value of the generated DC power. When the voltage across the smoothing capacitor C26 increases to a predetermined voltage, the DC-DC converter circuit 120 temporarily stops operating due to the protection operation, but there is no path for discharging the smoothing capacitor C26. The voltage remains high.

At time 711, the microcomputer 160 generates a regular switching signal that turns on the switch circuit 140. The voltage value 734 of the normal switching signal increases, and the capacitor C44 is gradually charged by the current flowing through the charging resistor R45. The charging time constant (the product of the resistance value of the charging resistor R45 and the capacitance of the capacitor C44) at this time is a fairly large value, for example, about 1 second.
As the gate-source voltage value 735 of the switching element Q43 increases, the source-drain resistance value decreases. The voltage value 736 between the source and gate of the switching element Q41 is obtained by dividing the voltage value 731 of the smoothing capacitor C26 by the resistance between the source and drain of the switching element Q43 and the resistance R42. As the drain-to-drain resistance value decreases, the source-gate voltage value 736 of switching element Q41 increases.
As the gate-source voltage of switching element Q41 increases, resistance value 741 between the source and drain of switching element Q41 decreases. At time 712, the resistance value 741 between the source and the drain of the switching element Q41 decreases to about several times the resistance value 743 between the source and the drain when the switching element Q41 is in the ON state. The elapsed time from time 711 to time 712 is, for example, about 50 milliseconds.

Between time 711 and time 712, since the resistance value 741 between the source and drain of the switching element Q41 is relatively large, the current flowing through the light source circuit 300 is limited. However, since the smoothing capacitor C26 has a discharge path, the voltage value 731 of the smoothing capacitor C26 drops and becomes substantially the same as the voltage value 733 at time 712.
Thereby, the peak of the surge current flowing through the light source circuit 300 can be suppressed low.

  Similarly, when the microcomputer 160 turns on the switch circuit 240, the peak of the surge current flowing through the light source circuit 300 can be kept low.

  As a comparative example, consider a configuration in which the switch circuit 140 does not have the delay circuit 149 and the normal switching signal generated by the microcomputer 160 is directly input to the gate terminal of the switching element Q43.

FIG. 7 is a timing chart showing the voltage of each part in the comparative example.
The horizontal axis represents time. The vertical axis represents voltage or resistance or current. The resistance is a logarithmic scale. The reference numerals are the same as those in FIG.

At time 711, the microcomputer 160 generates a regular switching signal that turns on the switch circuit 140. Since the common switching signal is directly input to the switching element Q43, the switching element Q43 is immediately turned on completely. As a result, the voltage value 736 between the source and gate of the switching element Q41 becomes substantially equal to the voltage value 731 of the smoothing capacitor C26, and the resistance value 741 between the source and drain of the switching element Q41 suddenly decreases, turning on. The state resistance value 743 is obtained.
Since the voltage value 731 of the smoothing capacitor C26 is high, the current value 751 of the current flowing through the light source circuit 300 becomes very large.

  As a result of an experiment using the circuit of the comparative example, a surge current flows in the light source circuit 300 for about 50 microseconds, and the peak may reach about 20 times the target current value.

  On the other hand, as a result of experiments with the circuit of this embodiment, when the delay time constant of the delay circuit 149 is set to 1 second, the peak of the current flowing through the light source circuit 300 is less than about twice the target current value. It was suppressed.

  If the charging time constant of the delay circuit 149 is further increased, the time required until the light source 310 is turned on again becomes longer.

Thus, by gradually changing the internal resistance of the switching element Q41 of the switch circuit 140 from infinity to 0, the current can be limited by the internal resistance, and the surge current can be suppressed.
By suppressing the peak of the surge current below the maximum pulse current of the light source 310 or below the maximum rated current, destruction of the light source 310 can be prevented.

The regular switching signal generated by the microcomputer 160 is a rectangular wave, but the delay circuit 149 is tempered to turn on the switching element Q41 slowly via the switching element Q43.
In addition, since the delay circuit 149 includes the discharge resistor R46 and the diode D47, when the switching element Q41 is turned off, the delay circuit 149 is quickly turned off. This prevents the occurrence of a turn-off delay.

  Note that the switch circuit 140 may be located anywhere as long as it is in a path through which a current flows from the DC / DC conversion circuit 120 to the light source circuit 300. Similarly, the switch circuit 240 may be located anywhere as long as it is in a path through which a current flows from the DC / DC conversion circuit 220 to the light source circuit 300.

  Further, when the output device of the microcomputer 160 has a digital-analog conversion circuit or the like and can output a signal having an arbitrary voltage value within a predetermined range, the microcomputer 160 generates a regular switching signal having a distorted waveform. It may be. In that case, the delay circuit 149 may be omitted. The same applies to the emergency switching signal. If the microcomputer 160 is configured to generate an emergency switching signal with a distorted waveform, the delay circuit 249 may be omitted. If it does so, the number of parts which comprise lighting device 100 will decrease, parts cost and assembly cost can be reduced, and reliability can be improved. Further, since the impedance of the switching element Q41 can be finely controlled, the delay time can be minimized while suppressing the peak of the surge current.

  In the DC / DC conversion circuit 120, a switching element may be added in a closed circuit including the winding L24, the diode D25, and the smoothing capacitor C26. By turning off the added switching element, it is possible to prevent the smoothing capacitor C26 from being charged even when the DC-DC converter circuit 120 is operating. Thereby, the peak of surge current can be further suppressed. The added switching element is driven by a normal switching signal generated by the microcomputer 160, for example, and is configured to be on when the switch circuit 140 is on and off when the switch circuit 140 is off. Unlike the switch circuit 140, the added switching element may be configured to turn on and off quickly.

  Moreover, the structure which has the check lighting mode for inspecting the storage battery 200 may be sufficient as the guide light apparatus 800. For example, the guide light device 800 has a mode switching button operated by the user, and the microcomputer 160 enters the check lighting mode when detecting that the user has pressed the mode switching button. In the inspection lighting mode, the microcomputer 160 turns off the switch circuit 140, operates the DC / DC conversion circuit 220, and turns on the switch circuit 240 in the same manner as when a power failure is detected. Thereby, the light source 310 is turned on with the energy accumulated in the storage battery 200 as in the case of a power failure. Note that, unlike the power failure, the DC / DC converter circuit 120 can continue to operate, and therefore, the control power circuit 130 generates the power source of the microcomputer 160.

  100 lighting device, 110 rectifier circuit, 120, 220 DC / DC converter circuit, 121, 221 control IC, 130, 230 control power circuit, 140, 240 switch circuit, 149, 249 delay circuit, 150 current detection circuit, 160 microcomputer, 161 Ground terminal, 162 Power input terminal, 163 Power failure detection input terminal, 164 Current switching output terminal, 165 Regular switching output terminal, 166 Emergency switching output terminal, 167 Emergency operation output terminal, 170 Power failure detection circuit, 200 Storage battery, 300 Light source circuit, 310 Light source, 701, 702, 703, 704, 705, 711, 712 Time, 731, 732, 733, 734, 735, 736 Voltage value, 741, 742, 743 Resistance value, 751, 752 Current value, 800 Guide light device 810 body, 820 light Unit, 830 display unit, AC AC power supply, C26, C33, C38, C86 smoothing capacitor, C44, C94 capacitor, D25, D32, D37, D47, D85, D97, D98 diode, DB diode bridge, L23, L24, L31, L36, L83 winding, Q22, Q41, Q43, Q53, Q82, Q91, Q93 switching element, R42, R51, R52, R92 resistance, R45, R95 charging resistance, R46, R96 discharging resistance, T1, T2 transformer.

Claims (2)

In the guide lamp device that illuminates the display panel with the light source while turning on the light source with power supplied from the AC power
A constant current circuit with a smoothing capacitor at the output;
A light source circuit comprising the light source to be turned by a constant current the constant current circuit is generated,
When an energization state in which power is supplied from the AC power supply is detected, an energization switching signal for conducting the constant current supplied from the constant current circuit to the light source circuit is sent, and power supply from the AC power supply is performed. Upon detecting a power failure state that stops, a microcomputer that sends a power failure normal switching signal that cuts off the constant current,
Interposed between the constant current circuit and the light source circuit is capable of blocking the constant current supplied from the constant current circuit to the light source circuit, when receiving the civil time switching signal the current from the microcomputer , from the impedance in a state in which the constant current is interrupted, impedance is gradually reduced, Ri optimum impedance in a state in which the constant current is conductive, when receiving the civil time switching signals the power failure from said microcomputer, the power failure A switch circuit that cuts off the constant current immediately after receiving the regular switching signal ;
Guide light device characterized in that it comprises a. The switch circuit is
A first switching element; a second switching element connected to the gate terminal of the first switching element; and a delay circuit connected to the gate terminal of the second switching element;
The delay circuit is
A diode, a first resistor connected in series to the diode, a second resistor connected in parallel to the diode and the first resistor, and a series connected to the first resistor and the second resistor And a capacitor connected to the gate terminal of the second switching element, and when the energization switching signal is received, the capacitor is gradually charged through the second resistor, and the power failure switching signal is 2. The guide lamp device according to claim 1, wherein when receiving, the capacitor is discharged through the second resistor and the diode.

Images