JP5914728B2 - Lighting device and lighting system - Google Patents

Description

  The present invention relates to an illumination device and an illumination system that illuminate indoors or outdoors, and more particularly, to an illumination device and an illumination system that can automatically detect a power failure and can be switched to battery operation.

  Conventionally, various facilities have installed emergency lights that automatically detect power outages caused by disasters, accidents, and the like and are lit by a battery to indicate an evacuation route or the like. In general, the emergency light is configured to charge only a battery as a backup power source during a normal time (non-power failure), and is turned on only when a power failure is detected. Therefore, a general emergency light needs to be installed as emergency lighting separately from the normal illumination used at normal times, which requires installation costs and limits the installation location.

  On the other hand, there has also been proposed an illumination device that can be used as normal illumination but can be automatically lit by battery drive when a power failure is detected (see, for example, Patent Document 1 or 2). Thus, by adding a function equivalent to that of an emergency light to normal lighting, it is possible to reduce the installation cost and not limit the installation location.

JP 2014-82910 A JP 2014-2904 A

  However, when a function equivalent to an emergency light is added to normal lighting, it is necessary to detect a power failure separately from ON / OFF of a lighting switch provided on a wall or the like, and the control configuration becomes complicated or convenient. There was a problem of getting worse.

  For example, in the lighting device described in Patent Document 1, a reference voltage of a normal AC power supply (commercial power supply) is measured and stored, the voltage state of the AC power supply is monitored and compared with the reference voltage state, and a power failure is detected. Therefore, the control configuration is complicated and expensive.

  Further, in the illumination device described in Patent Document 2, a power failure is detected relatively easily by changing the operation of turning off the illumination switch in a normal state to a special operation of turning OFF → ON → OFF. Therefore, the daily operation of turning off the lighting switch is very troublesome and unusable.

  In view of such a situation, the present invention is intended to provide a lighting device and a lighting system that can detect a power failure more easily and can be switched on and driven by a battery.

(1) The present invention includes a light emitting unit that emits light when energized, a battery that stores electric power, a power supply switching unit that switches a power supply source to the light emitting unit between an external AC power source and the battery, and the AC A power failure detection unit that transmits a signal when a power failure is detected, and a power supply source to the light emitting unit is switched from the AC power source to the battery based on reception of the signal from the power failure detection unit. A control unit that controls the power supply switching unit; and a detection function expansion unit that expands a detection function of the power failure detection unit. The power failure detection unit includes a primary coil connected to the AC power source and the control unit. It comprises a high frequency transformer having a connection to the secondary coil, the detection function expansion unit, the auxiliary capacitor or complement than the power failure detecting section is connected in parallel with the primary coil in the AC power supply side A resistor, which is connected to the auxiliary capacitor or the auxiliary resistor in series, characterized in that it comprises a detection switch for switching the connection and disconnection of the auxiliary capacitor or the auxiliary resistor and the primary coil, which is a lighting device.

( 2 ) The present invention also includes a communication unit that receives a signal transmitted from the outside, a detection switch switching unit that switches connection and disconnection of the detection switch based on a reception state of the signal from the outside in the communication unit, The illuminating device according to ( 1 ) above, comprising:

( 3 ) The present invention is also based on the detection of the interruption of power supply from the AC power supply, and the detection of the power failure based on the detection of the interruption of the power supply by the interruption detection unit. A device disconnecting unit that disconnects a function expansion unit from a system connected to the AC power supply. The illumination device according to ( 2 ) above.

( 4 ) The present invention also provides the illumination device according to any one of (1) to ( 3 ) above, further including a main body connectable to a socket for a fluorescent lamp or a bulb.

( 5 ) The present invention also provides a main body connectable to a socket for a fluorescent lamp or a bulb, and when the main body is connected to the socket, the detection switch is turned off, and the main body is removed from the socket. The illumination device according to any one of ( 1 ) to ( 3 ), further comprising: a removal detection unit that brings the detection switch into a connected state when the detection switch is connected.

( 6 ) According to the present invention, the control unit switches the power supply source to the light emitting unit from the AC power source to the battery when reception of a signal from the power failure detection unit continues for a certain period of time. The lighting device according to any one of (1) to ( 5 ), wherein the power supply switching unit is controlled.

( 7 ) In the present invention, the power failure detection unit may include a bidirectional diode or resistor connected in parallel with the primary coil, and one side of the primary coil on the AC power supply side of the bidirectional diode. (1) to ( 6 ), comprising: a capacitor connected in series; and a resistor connected in series to the other side of the primary coil on the AC power supply side of the bidirectional diode. ).

( 8 ) The present invention also includes the illumination device according to ( 2 ) or ( 3 ) above, and an auxiliary power failure detection device provided separately from the illumination device, and the auxiliary power failure detection device includes the illumination device. Connected to the AC power source through a separate system, an auxiliary power failure detection unit that detects the power failure, an auxiliary device side communication unit that transmits a signal to the communication unit, and the auxiliary power failure detection unit is the power failure And an auxiliary device control unit that controls transmission of a signal by the auxiliary device-side communication unit so that the detection switch is set to a connected state based on the detection of the detection switch.

( 9 ) In the present invention, the auxiliary power failure detection device further includes an illuminance detection unit that detects ambient illuminance, and the auxiliary device control unit detects the power failure by the auxiliary power failure detection unit, and detects the illuminance. The transmission of the signal by the auxiliary device side communication unit is controlled so that the detection switch is connected based on the ambient illuminance detected by the unit being less than or equal to a predetermined threshold value, It is an illumination system as described in ( 8 ).

( 10 ) The present invention also includes the illumination device according to ( 2 ) or ( 3 ) above, and an auxiliary power failure detection device provided separately from the illumination device, and the auxiliary power failure detection device includes the AC power source. An illuminance detection unit for detecting ambient illuminance, and an auxiliary device for transmitting a signal toward the communication unit, which are arranged at a position that constantly receives at least one of light and sunlight emitted by a device that uses a power supply source Control of signal transmission by the auxiliary device side communication unit so that the detection switch is in a connected state based on the side communication unit and the ambient illuminance detected by the illuminance detection unit being below a predetermined threshold And an auxiliary device control unit.

  According to the illumination device and the illumination system according to the present invention, it is possible to achieve an excellent effect that it is possible to detect a power failure more easily and switch on the battery drive to turn on.

It is the schematic which showed the structure of the illuminating device which concerns on the 1st Embodiment of this invention. It is the block diagram which showed the circuit structure of the illumination device. (A) It is the block diagram which showed the circuit structure of the illuminating device which concerns on the 2nd Embodiment of this invention. (B) It is the schematic which showed the nozzle | cap | die periphery of the illumination device. It is the block diagram which showed the circuit structure of the illumination system which concerns on the 3rd Embodiment of this invention. It is the block diagram which showed the circuit structure of the illumination system which concerns on the 4th Embodiment of this invention. (A) And (b) It is the block diagram which showed the example of the connection condition which increases possibility that a lighting switch will be erroneously detected as a power failure. It is the block diagram which showed the circuit structure of the illumination system which concerns on the 5th Embodiment of this invention. It is the block diagram which showed the circuit structure of the illumination system which concerns on the 6th Embodiment of this invention.

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

  First, the illumination device 1 according to the first embodiment will be described. FIG. 1 is a schematic diagram illustrating a configuration of the illumination device 1, and FIG. 2 is a block diagram illustrating a circuit configuration of the illumination device 1. As shown in these drawings, the lighting device 1 includes a main body 10, a light emitting unit 20, an AC / DC converter 30, a power supply switching unit 40, a battery 50, a charge / discharge switching unit 60, and a power failure detection unit. 70 and a control unit 80.

  The main body 10 accommodates each part such as the light emitting unit 20 and the AC / DC converter 30, and in this embodiment, is configured to have substantially the same size and shape as an existing straight tube fluorescent lamp. That is, the illuminating device 1 of this embodiment is configured to be used as an alternative to a straight tube fluorescent lamp by connecting to an existing socket for a straight tube fluorescent lamp.

  That is, the main body 10 is formed in a rod shape having substantially the same length as an existing straight tube fluorescent lamp, and a base 11 having an appropriate standard is provided at both ends, and an external AC is connected through the base 11. Electric power from a power source (commercial power source) 100 is supplied to each part of the lighting device 1. Further, ON / OFF (lighting / non-lighting) of the lighting device 1 at the normal time (non-power failure) is performed by a lighting switch 110 provided on a wall or the like.

  The upper part of the main body 10 is a support member 12 having appropriate strength and rigidity, and each part such as the light emitting part 20 and the base 11 are attached to the support member 12. The lower portion of the main body 10 is a semitransparent cover member 13 having a substantially arc-shaped cross section, and the light emitting portion 20 is covered with the cover member 13.

  The light emitting unit 20 includes a plurality of LED elements 22 arranged on the substrate 21 and emits light when energized. The substrate 21 is fixed to the lower side of the support member 12 with the LED element 22 facing downward, and the light emitted from the LED element 22 is appropriately diffused by passing through the cover member 13. Yes.

  The AC / DC converter 30 converts AC power supplied from the AC power supply 100 into DC power having a predetermined voltage. The output side of the AC / DC converter 30 is connected to the power supply switching unit 40 and the charge / discharge switching unit 60. The DC power converted by the AC / DC converter 30 is supplied to the light emitting unit 20 through the power supply switching unit 40 as power for driving the LED element 22. The DC power converted by the AC / DC converter 30 is also supplied to the battery 50 via the charge / discharge switching unit 60 as power for charging the battery 50.

  The power supply switching unit 40 is controlled by the control unit 80 and switches the DC power supplied to the light emitting unit 20 between the DC power from the AC / DC converter 30 and the DC power from the charge / discharge switching unit 60. That is, the power supply switching unit 40 switches the power supply source to be supplied to the light emitting unit 20 between the AC power supply 100 and the battery 50.

  The battery 50 is a secondary battery that can be charged by the AC power supply 100, and functions as a power supply source to the light emitting unit 20 during a power failure. The charge / discharge switching unit 60 is controlled by the control unit 80 and switches between charging and discharging of the battery 50 (that is, supply of electric power to the light emitting unit 20).

  The main body 10, the light emitting unit 20, the AC / DC converter 30, the power supply switching unit 40, the battery 50, and the charge / discharge switching unit 60 can employ known appropriate configurations. Detailed description is omitted.

  The power failure detection unit 70 detects a power failure of the AC power supply 100 and includes a high-frequency transformer 71, a bidirectional diode 72, a capacitor 73, and a resistor 74. In the high-frequency transformer 71, the primary coil 71 a is connected to the AC power supply 100, and the secondary coil 71 b is connected to the control unit 80. The bidirectional diode 72 is connected in parallel with the primary coil 71 a of the high-frequency transformer 71. The capacitor 73 is connected in series to one side of the primary coil 71 a on the AC power supply 100 side of the bidirectional diode 72. The resistor 74 is connected in series to the other side of the primary coil 71 a on the AC power supply 100 side than the bidirectional diode 72.

  In this embodiment, the power failure detection unit 70 is configured in this manner, so that a power failure of the AC power supply 100 can be easily detected. Specifically, by providing a high-frequency transformer 71 between the AC power supply 100 and the control unit 80, the AC power having a normal frequency of 50 or 60 Hz is cut off and not transmitted to the control unit 80. It is possible to output (transmit) a weak high-frequency current (for example, several hundred Hz to several tens kHz) generated by impedance and reactance between the two power cables 101 and 102 to the control unit 80.

  That is, by providing the high-frequency transformer 71, a signal is not output to the control unit 80 during normal times, and a signal can be output to the control unit 80 only during a power failure. Further, by using the above-described circuit configuration in which the high-frequency transformer 71, the bidirectional diode 72, the capacitor 73, and the resistor 74 are combined, a desired frequency component (for example, several kHz) of the high-frequency weak current generated at the time of a power failure can be obtained. It is possible to extract and output to the control unit 80.

  In this embodiment, assuming that the voltage of the AC power supply 100 is 90 to 260 V including the voltage of a general commercial power supply, the high frequency transformer 71 has an inductance of 25 mH, and the bidirectional diode 72 has a forward voltage. Two diodes of 3.7V are used as the capacitor 73 having a capacity of 3300 pF, and the resistor 74 having a resistance value of 1.8Ω, but it goes without saying that the specifications of each component are not limited to these. Nor. Further, instead of the bidirectional diode 72, a resistor having an appropriate resistance value may be used.

  The control unit 80 is configured by a known microcomputer or the like, and controls each unit of the lighting device 1. When the signal is not input (received) from the power failure detection unit 70, that is, in the normal state, the control unit 80 sets the power supply switching unit 40 to supply the direct-current power from the AC / DC converter 30 to the light emitting unit 20. . As a result, the light emitting unit 20 is turned on by the power supplied from the AC power source 100 and can be turned on / off by the illumination switch 110. That is, the illumination device 1 can be used as normal illumination.

  In addition, the control unit 80 does not input a signal from the power failure detection unit 70, and when the charge amount of the battery 50 is equal to or less than a predetermined lower limit, It is assumed that the battery 50 is supplied. Accordingly, the battery 50 is charged by the AC power source 100 when the illumination switch 110 is ON, that is, when the light emitting unit 20 is lit.

  Thereafter, the control unit 80 stops charging when the amount of charge of the battery 50 reaches a predetermined upper limit value, and starts charging when the amount of charge of the battery 50 decreases to a predetermined lower limit value due to natural discharge or the like. Repeat control. Thereby, the charge amount of the battery 50 will be hold | maintained more than a predetermined | prescribed lower limit.

  The control unit 80 also determines that a power failure has occurred in the AC power source 100 when the input of the signal from the power failure detection unit 70 continues for a certain time (for example, 3 seconds), and sets the charge / discharge switching unit 60 from the battery 50. While the DC power is in a state of being supplied to the power supply switching unit 40, the power supply switching unit 40 is in a state of supplying the DC power from the charge / discharge switching unit 60 to the light emitting unit 20. As a result, the light emitting unit 20 is turned on by the battery 50.

  In this embodiment, when the control unit 80 determines that a power failure has occurred when a signal is continuously input from the power failure detection unit 70 for a certain time as described above, instantaneous power failures that occur relatively frequently in the commercial power supply are detected. The power outage detection accuracy is improved by excluding it.

  In the present embodiment, when the illumination switch 110 is OFF, the weak current does not flow through the power failure detection unit 70, so the power failure detection unit 70 sends a signal to the control unit 80 even if the AC power supply 100 is out of power. Do not send. That is, in this embodiment, when the light emitting unit 20 is not lit when a power failure occurs, the light emitting unit 20 is not lit even after a power failure occurs. By doing so, for example, it is possible to eliminate the waste that the lighting device 1 is lit by the battery 50 even though the room or the entire facility is unattended when a power failure occurs.

  Even after the occurrence of a power failure, since the weak current flows in the power failure detection unit 70 by turning the illumination switch 110 from OFF to ON, the light emitting unit 20 can be turned on by the battery 50. Moreover, the light emission part 20 can be light-extinguished by turning off the illumination switch 110 again. That is, in this embodiment, it is possible to turn on / off the lighting device 1 by the lighting switch 110 even during a power failure.

  When AC power supply 100 returns from a power failure, power failure detection unit 70 does not output a signal to control unit 80. The control unit 80 determines that the AC power supply 100 has recovered from the power failure when the signal input from the power failure detection unit 70 is not continuously performed for a certain time (for example, 3 seconds), and the charge / discharge switching unit 60 is connected to the battery. 50 is in a chargeable state, and the power supply switching unit 40 is in a state of supplying DC power from the AC / DC converter 30 to the light emitting unit 20. As a result, the light emitting unit 20 is turned on by the AC power supply 100. Moreover, when the charge amount of the battery 50 has fallen below the predetermined lower limit value, charging of the battery 50 is started.

  Thus, according to the present embodiment, it is possible to easily detect a power failure and switch the power supply source to the light emitting unit 20 to the battery 50 without adopting a complicated control configuration. In the present embodiment, when the lighting switch 110 is OFF, the light emitting unit 20 is not turned on even if a power failure occurs. Further, the lighting device 110 is turned on / off by the lighting switch 110 even during a power failure. Since it can be turned off, the lighting device 1 can be used efficiently.

  The electric power for operating the control unit 80 and the like may be supplied from the battery 50, or a dedicated battery may be provided separately. Further, the main body 10 may be configured to be connectable to a socket for a light bulb, and the lighting device 1 may be configured to be usable as an alternative to a light bulb.

  Next, the lighting device 2 according to the second embodiment will be described. The illuminating device 2 according to the present embodiment is obtained by adding a detection function expanding unit 90 and a removal detecting unit 91 to the illuminating device 1 according to the first embodiment, and other configurations are the same as those of the illuminating device 1. Therefore, in the following description, parts common to the lighting device 1 are denoted by the same reference numerals, description thereof is omitted, and only different parts are described.

  FIG. 3A is a block diagram illustrating a circuit configuration of the illumination device 2, and FIG. 3B is a schematic diagram illustrating the periphery of the base 11 of the illumination device 2. In the present embodiment, by providing the detection function expansion unit 90 and the removal detection unit 91, when the power failure of the AC power supply 100 is detected, the power supply source is automatically switched to the battery 50 and the light emitting unit 20 is turned on. However, even when the main body 10 is removed from the fluorescent lamp socket, the power supply source is automatically switched to the battery 50 and the light emitting unit 20 is turned on. Thereby, the illuminating device 2 of this embodiment functions also as an electric lamp which can be carried at the time of a power failure.

  The detection function expansion unit 90 extends the function of the power failure detection unit 70 and enables the power failure detection unit 70 to output a signal according to various conditions other than the detection of the power failure. As shown in FIG. 3A, the detection function expansion unit 90 is connected in parallel with the power failure detection unit 70 on the AC power supply 100 side of the power failure detection unit 70, and the auxiliary capacitors 90a connected in series with each other. And a detection switch 90b. Therefore, the auxiliary capacitor 90a is connected in parallel with the primary coil 71a of the power failure detection unit 70 when the detection switch 90b is ON (connected state), and is disconnected from the primary coil 71a when the detection switch 90b is OFF (disconnected state). It has come to be.

  That is, the detection function expansion unit 90 turns on the detection switch 90b and connects the auxiliary capacitor 90a in parallel with the primary coil 71a to generate a weak high-frequency current as in the case of a power failure. As a result, the power failure detection unit 70 is configured to output a signal to the control unit 80. Therefore, the control unit 80 supplies the DC power from the battery 50 to the power supply switching unit 40 even when the detection switch 90b is continuously turned on for a certain time (for example, 3 seconds). At the same time, the power supply switching unit 40 is brought into a state of supplying DC power from the charge / discharge switching unit 60 to the light emitting unit 20. In the present embodiment, the auxiliary capacitor 90a having a capacitance of 0.1 μF is used, but it goes without saying that the capacitance of the auxiliary capacitor 90a is not limited to this.

  The removal detection unit 91 is for detecting that the main body 10 has been removed from the socket. As shown in FIG. 3B, the removal detection unit 91 is provided on the base 11, and when the base 11 is connected to the socket, the detection switch 90 b is turned OFF by being pressed by the socket, and the base 11 is turned off. Is removed from the socket and the pressing is released to turn on the detection switch (automatically return to ON). Accordingly, the power failure detection unit 70 outputs a signal to the control unit 80 even when the main body 10 is removed from the socket, and the light emitting unit 20 is connected to the battery after a predetermined time has elapsed from the removal of the main body 10 from the socket. 50 automatically lights up.

  Thus, in this embodiment, by providing the detection function expansion unit 90 and the removal detection unit 91, the lighting device 2 can be turned on and carried without requiring a switch operation in the dark during a power failure. Is possible. Further, in the present embodiment, the detection function expansion unit 90 and the removal detection unit 91 are configured so that a signal is transmitted from the power failure detection unit 70 to the control unit 80 in the same manner as during a power failure even when the main body 10 is removed from the socket. Since it is configured, it is possible to detect the removal of the main body 10 from the socket without complicating the control configuration.

  Further, in the present embodiment, it is possible to turn off the light emitting unit 20 that has been turned on by the battery 50 by removing it with a finger or the like and pressing the detection unit 91 for a certain time while the main body 10 is removed from the socket. It has become. That is, the removal detection unit 91 functions as an ON / OFF switch for turning on or off the light emitting unit 20 when the lighting device 2 is carried and used, and is excellent in usability.

  When the lighting device 2 is stored, an appropriate cap or the like that presses the removal detection unit 91 is attached to the base 11 so that the detection switch 90b is maintained in the OFF state so that the light emitting unit 20 is not turned on. Can be. Further, an auxiliary resistor having an appropriate resistance value may be provided instead of the auxiliary capacitor 90a.

  Next, the lighting system 3 according to the third embodiment will be described. The illumination system 3 according to the present embodiment includes the illumination device 4 and the auxiliary power failure detection device 120. The illumination device 4 includes the detection function expansion unit 90 in the illumination device 1 according to the first embodiment, and A communication unit 92 and a detection switch switching unit 93 are added. Therefore, in the following description, the same reference numerals are given to the parts common to the lighting device 1 or 2, and the description thereof is omitted, and only different parts will be described.

  FIG. 4 is a block diagram showing a circuit configuration of the illumination system 3. The communication part 92 with which the illuminating device 4 is provided communicates with the auxiliary | assistant power failure detection apparatus 120 by transmission / reception of infrared rays or an electromagnetic wave, for example. The detection switch switching unit 93 has a known configuration such as a relay, for example. When the communication unit 92 receives a signal transmitted from the auxiliary power failure detection device 120, the detection switch 90b of the detection function expansion unit 90 is turned on. The detection switch 90b of the detection function expansion unit 90 is turned OFF when the communication unit 92 does not receive a signal from the auxiliary power failure detection device 120.

  That is, the lighting device 4 of the present embodiment is configured such that the power failure detection unit 70 outputs a signal to the control unit 80 even when a signal transmitted from the external auxiliary power failure detection device 120 is received. Therefore, even when the control unit 80 continuously receives a signal from the auxiliary power failure detection device 120 for a certain period of time (for example, 3 seconds), the control unit 80 sends the DC power from the battery 50 to the power supply switching unit 40. At the same time, the power supply switching unit 40 is brought into a state of supplying DC power from the charge / discharge switching unit 60 to the light emitting unit 20.

  The auxiliary power failure detection device 120 is connected to the AC power supply 100 via a system (power cables 103 and 104) that does not have a switch such as the illumination switch 110, and detects a power failure separately from the power failure detection unit 70 of the illumination device 4. Is to do. The auxiliary power failure detection device 120 includes an auxiliary device side communication unit 121, an auxiliary power failure detection unit 122, and an auxiliary device control unit 123.

  The auxiliary device side communication unit 121 communicates with the communication unit 92 of the lighting device 4. The auxiliary power failure detection unit 122 is connected to the AC power source 100 and detects a power failure of the AC power source 100 by detecting, for example, a voltage drop caused by the power failure. In the auxiliary power failure detection device 120, since no switch exists between the auxiliary power failure detection unit 122 and the AC power supply 100, it is possible to detect a power failure by a simple method such as detection of a voltage drop. The auxiliary power failure detection unit 122 outputs a signal to the auxiliary device control unit 123 when detecting a power failure of the AC power supply 100.

  The auxiliary device control unit 123 is configured by a known microcomputer or the like, and controls each unit of the auxiliary power failure detection device 120. The auxiliary device control unit 123 transmits a signal toward the lighting device 4 by controlling the auxiliary device side communication unit 121 when the auxiliary power failure detection unit 122 detects a power failure. Moreover, the auxiliary device control part 123 controls the auxiliary device side communication part 121 not to transmit a signal, when the auxiliary power failure detection part 122 has not detected the power failure.

  Accordingly, the control unit 80 of the lighting device 4 determines that a power failure has occurred in the AC power supply 100 when the auxiliary power failure detection unit 122 of the auxiliary power failure detection device 120 detects a power failure continuously for a certain time (for example, 3 seconds). The charging / discharging switching unit 60 is in a state of supplying DC power from the battery 50 to the power supply switching unit 40, and the power switching unit 40 is in a state of supplying DC power from the charging / discharging switching unit 60 to the light emitting unit 20. . As a result, the light emitting unit 20 is turned on by the battery 50.

  As described above, according to the present embodiment, for example, the state of the power cables 101 and 102 that connect the AC power supply 100 and the lighting device 4, the influence of other devices connected to the power cables 101 and 102, etc. Even when a weak current is unlikely to occur, the auxiliary power failure detection device 120 can reliably detect a power failure. In addition, since the auxiliary power failure detection device 120 only needs to be always connected to an outlet near the lighting device 4 or the like, it is possible to reliably detect a power failure while maintaining simplicity.

  Although not shown, the auxiliary power failure detection device 120 converts the AC power from the battery as a power supply source for operating the auxiliary device control unit 123 and the like and the AC power source 100 for charging. An AC / DC converter that supplies DC power to the battery, and a charge / discharge switching unit that is controlled by the auxiliary device control unit 123 and switches between charging and discharging of the battery are provided.

  Moreover, the illumination system 3 of this embodiment may have a plurality of illumination devices 4, and in this case, the auxiliary power failure detection device 120 may be provided for each illumination device 4, or a plurality of illumination devices may be provided. One auxiliary power failure detection device 120 may be provided for the device 4. Further, the detachment detector 91 may be provided in the illumination device 4.

  Further, the transmission of the signal from the auxiliary device side communication unit 121 may be transmitted continuously during the period in which the auxiliary power failure detection unit 122 detects the power failure as described above, or the auxiliary power failure may be transmitted. When the detection unit 122 detects a power failure, a signal for turning on the detection switch 90b is transmitted, and when the auxiliary power failure detection unit 122 detects a return from the power failure, a signal for turning off the detection switch 90b is transmitted. May be.

  Further, the auxiliary power failure detection device 120 transmits a signal from the auxiliary device side communication unit 121 continuously or intermittently during normal time (non-power failure), and does not transmit a signal from the auxiliary device side communication unit 121 during a power failure. In addition, the detection switch switching unit 93 is turned off when the communication unit 92 receives a signal from the auxiliary power failure detection device 120, and the communication unit 92 turns off the signal from the auxiliary power failure detection device 120. If not received, the detection switch 90b may be turned on. In this case, the configurations of the auxiliary power failure detection unit 122 and the auxiliary device control unit 123 are further simplified, and the battery can be omitted from the auxiliary power failure detection device 120.

  Next, an illumination system 5 according to the fourth embodiment will be described. The illumination system 5 according to the present embodiment is obtained by replacing the illumination device 4 with the illumination device 6 in the illumination system 3 according to the third embodiment, and the illumination device 6 includes a blocking detection unit 94 and the illumination device 4. An apparatus separating unit 95 is added. Therefore, in the following description, parts common to the illumination system 3 are denoted by the same reference numerals, description thereof is omitted, and only different parts are described.

  FIG. 5 is a block diagram showing a circuit configuration of the illumination system 5. The interruption detection unit 94 included in the lighting device 6 is connected to the AC power supply 100 on the AC power supply 100 side of the detection function expansion unit 90, and the power supply from the AC power supply 100 is interrupted by a simple method such as detection of a voltage drop. Is detected. That is, the interruption detection unit 94 detects the interruption of power supply from the AC power supply 100 to the illumination device 6 without distinguishing between a power failure and a state where the illumination switch 110 is OFF (interruption state).

  The device disconnection unit 95 connects the power failure detection unit 70 and the detection function expansion unit 90 to the power cable 102 (i.e., the AC power supply 100) based on the fact that the interruption detection unit 94 detects the interruption of the power supply from the AC power supply 100. It is to be disconnected from the connected system). Specifically, the device disconnection unit 95 includes a known configuration such as a relay together with a disconnection switch 95a provided between the detection function expansion unit 90 and the disconnection detection unit 94 on the power cable 102 side. The switch 95a is turned ON (connected state) when the power supply cutoff is not detected, and the switch 95a is turned OFF (shut off state) when the cutoff detector 94 detects the power supply cutoff. It is configured as follows.

  As a result, in the lighting system 5, a weak high-frequency current generated due to the impedance and reactance between the power cables 101 and 102 at the time of a power failure is cut by the device disconnection unit 95, and the power failure detection unit 70 is detected by the detection function expansion unit 90. A signal is output to the control unit 80 based only on the high-frequency weak current generated by. That is, in the illumination system 5, a power failure is detected only by the auxiliary power failure detection device 120. By setting it as such a structure, it becomes possible to reduce significantly the possibility that the lighting switch 110 will be erroneously detected as a power failure regardless of the connection state between the lighting device 6 and the AC power supply 100.

  FIGS. 6A and 6B are block diagrams illustrating an example of a connection situation in which the possibility that the lighting switch 110 is erroneously detected as a power failure is increased. For example, when a plurality of illumination devices 6 are connected to the same system (power cables 101 and 102) as shown in FIG. 6A, or as shown in FIG. When the device 130 is connected to the same system, the closed circuits L1 to L4 that connect the illumination devices 6 or between the illumination device 6 and other devices exist in the system. In such closed circuits L1 to L4, a high-frequency weak current is likely to be generated due to interference between devices when the power supply is interrupted. Therefore, a high-frequency weak current may be generated even when the illumination switch 110 is OFF. Will increase. That is, the possibility that the state in which the illumination switch 110 is OFF is erroneously detected as a power failure increases.

  For this reason, in the illumination system 5 of the present embodiment, the power failure detection unit 70 and the detection function expansion unit 90 are disconnected from the power cable 102 in both cases where a power failure occurs and the illumination switch 110 is OFF, The weak high-frequency current generated in the closed circuits L1 to L4 is prevented from flowing into the power failure detection unit 70, and the power failure is detected only by the auxiliary power failure detection device 120. By doing in this way, it becomes possible to raise the precision of a power failure detection irrespective of the connection condition of the illuminating device 6 and AC power supply 100. FIG. Moreover, since it is not necessary to change the power failure detection part 70, it is possible to implement highly accurate power failure detection easily and inexpensively. It goes without saying that the disconnect switch 95a may be provided on the power cable 101 side.

  Next, an illumination system 7 according to the fifth embodiment will be described. The illumination system 7 according to this embodiment is obtained by replacing the auxiliary power failure detection device 120 with the auxiliary power failure detection device 120a in the illumination system 5 according to the fourth embodiment, and the auxiliary power failure detection device 120a is an auxiliary power failure detection device. An illuminance detection unit 124 is added to the device 120. Therefore, in the following description, parts common to the illumination system 5 are denoted by the same reference numerals, description thereof is omitted, and only different parts are described.

  FIG. 7 is a block diagram showing a circuit configuration of the illumination system 7. As described above, the illuminance detection unit 124 included in the auxiliary power failure detection device 120a is configured by a known illuminance sensor (light sensor), and detects ambient illuminance (brightness). And the auxiliary device control part 123 with which the auxiliary power failure detection apparatus 120a of this embodiment is equipped is detected when the auxiliary power failure detection part 122 detects a power failure, and the surrounding illumination intensity which the illumination intensity detection part 124 detected is below a predetermined threshold value. Then, the auxiliary device side communication unit 121 is controlled to transmit a signal toward the lighting device 6. In addition, the auxiliary device control unit 123 outputs a signal when the ambient illuminance detected by the illuminance detection unit 124 is larger than a predetermined threshold regardless of whether the auxiliary power failure detection unit 122 detects a power failure. The auxiliary device side communication unit 121 is controlled so as not to transmit.

  By doing in this way, it becomes possible to improve the precision of a power failure detection. That is, at the time of a power failure of the AC power supply 100, all the surrounding lighting devices and the like that use the AC power supply 100 as the power supply source are turned off. However, local troubles in the power supply system or interruption of power supply by the breaker In this case, since there is a high possibility that a lighting device or the like that is lit is present in the surroundings, it is possible to detect a power failure by detecting the illuminance around the auxiliary power failure detection device 120 arranged at an appropriate position. And can be detected separately.

  Further, in the present embodiment, by using the illumination device 6 including the interruption detection unit 94 and the device separation unit 95, a power failure can be detected with high accuracy even when the illumination switch 110 is in an OFF state. When there is no need to turn on the light emitting unit 20 because the surroundings are sufficiently bright, such as a power failure, the light emitting unit 20 can be prevented from being turned on. Thereby, it is possible to prevent the battery 50 of the lighting device 6 from being wasted.

  In addition, when arrange | positioning the illumination intensity detection part 124 in the position which receives the light which the light emission part 20 of the illuminating device 6 receives, for example, the surrounding illumination intensity which the auxiliary power failure detection part 122 detected the power failure and the illumination intensity detection part 124 detected is After the state that is equal to or less than the predetermined threshold value continues for a certain time (for example, 3 seconds), the ON / OFF of the detection switch 90b of the detection function expansion unit 90 is based only on whether or not the auxiliary power failure detection unit 122 detects a power failure. What is necessary is just to control transmission of the signal by the auxiliary | assistant apparatus side communication part 121 so that OFF may be switched. Needless to say, the lighting device 4 may be used instead of the lighting device 6.

  Next, an illumination system 8 according to the sixth embodiment will be described. The illumination system 8 according to this embodiment is obtained by replacing the auxiliary power failure detection device 120a with the auxiliary power failure detection device 120b in the illumination system 7 according to the fifth embodiment, and the auxiliary power failure detection device 120b is configured to detect auxiliary power failure. The auxiliary power failure detection unit 122 is omitted from the device 120a. Therefore, in the following description, parts common to the illumination system 7 are denoted by the same reference numerals, description thereof is omitted, and only different parts are described.

  FIG. 8 is a block diagram showing a circuit configuration of the illumination system 8. Since the auxiliary power failure detection unit 122 is omitted in the auxiliary power failure detection device 120b of the present embodiment, the auxiliary device control unit 123 assists when the ambient illuminance detected by the illuminance detection unit 124 is equal to or less than a predetermined threshold. The apparatus side communication part 121 is controlled and a signal is transmitted toward the illuminating device 6. In addition, the auxiliary device control unit 123 controls the auxiliary device side communication unit 121 not to transmit a signal when the ambient illuminance detected by the illuminance detection unit 124 is larger than a predetermined threshold.

  By doing in this way, it becomes possible to detect a power failure more simply. That is, by arranging the illuminance detection unit 124 at a position that always receives at least one of light emitted from a device using the AC power source 100 as a power supply source and sunlight, a power failure can be detected only by detecting ambient illuminance. It becomes possible to detect. Specifically, for example, the illuminance detection unit 124 may be arranged at a position where it receives sunlight from the daytime and receives light from a nightlight or a streetlight at night.

  In addition, when the lighting device 6 included in the lighting system 8 is used as a nightlight, a streetlight, or the like, the illuminance detection unit 124 may be disposed at a position that receives light emitted from the light emitting unit 20 of the lighting device 6. In this case, for example, after the ambient illuminance detected by the illuminance detection unit 124 is less than or equal to a predetermined threshold value continues for a certain period of time (for example, 3 seconds), the detection switch 90b of the detection function expansion unit 90 remains constant. The transmission of signals by the auxiliary device side communication unit 121 may be controlled so as to continue for a time (for example, 30 minutes) or until a manual reset operation is performed.

  In addition, since the auxiliary power failure detection device 120b of the present embodiment does not necessarily need to be connected to the AC power supply 100, the auxiliary power failure detection device 120b may be connected to another power source, or the auxiliary power failure detection device is detected only by the battery. The device 120b may be driven. In addition, since the illuminance detection unit 124 is disposed at a position that always receives light during normal times, the battery may be charged by a solar cell (solar cell). That is, in this embodiment, since arrangement | positioning of the auxiliary power failure detection apparatus 120b is not restrict | limited by the structure of the alternating current power supply 100, it is possible to arrange the auxiliary power failure detection apparatus 120b in an appropriate position.

  As described above, the illuminating devices 1, 2, 4, and 6 according to the above embodiments have the light emitting unit 20 that emits light when energized, the battery 50 that stores electric power, and the power supply source to the light emitting unit 20 as an external device. Power supply switching unit 40 that switches between AC power supply 100 and battery 50, power failure detection unit 70 that transmits a signal when a power failure of AC power supply 100 is detected, and reception of a signal from power failure detection unit 70, A power supply switching unit 40 for switching the power supply source to the light emitting unit 20 from the AC power supply 100 to the battery 50, and the power failure detection unit 70 is a primary coil connected to the AC power supply 100. A high-frequency transformer 71 having a secondary coil 71b connected to 71a and the control unit 80 is provided.

  With such a configuration, high-frequency weak current generated by impedance and reactance between the two power cables 101 and 102 at the time of a power failure while interrupting normal AC power and not transmitting it to the control unit 80. Can be output to the control unit 80, so that a power failure can be easily detected without adopting a complicated control configuration, and the power supply source to the light emitting unit 20 can be switched to the battery 50 and turned on.

  The lighting devices 2, 4, and 6 include a detection function expansion unit 90 that extends the detection function of the power failure detection unit 70, and the detection function expansion unit 90 is closer to the primary coil 71 a on the AC power supply 100 side than the power failure detection unit 70. And an auxiliary capacitor 90a or an auxiliary resistor connected in parallel with each other, and a detection switch 90b connected in series with the auxiliary capacitor 90a or the auxiliary resistor, and switching between connection and disconnection of the auxiliary capacitor 90a or the auxiliary resistor and the primary coil 71a. Yes. By doing so, it is possible to cause the power failure detection unit 70 to output a signal based on various conditions such as removal from the socket and reception of an external signal, and to turn on the light emitting unit 20 with the battery 50. The usability and versatility of the lighting devices 2, 4 and 6 can be improved without complicating the control configuration.

  In addition, the illumination devices 4 and 6 detect the communication unit 92 that receives a signal transmitted from the outside, and the detection unit 90b is switched from the cutoff state to the connected state based on the reception state of the signal from the outside in the communication unit 92. A switch switching unit 93. By doing so, the power failure detection unit 70 can output a signal based on the reception state of the signal from the outside, and the light emitting unit 20 can be turned on by the battery 50, thus complicating the control configuration. The usability and versatility of the lighting devices 4 and 6 can be improved.

  In addition, the lighting device 6 includes the interruption detection unit 94 that detects the interruption of the power supply from the AC power supply 100, and the power failure detection unit 70 and the detection function expansion based on the detection of the interruption of the power supply by the interruption detection unit 94. A device separating unit 95 for separating the unit 90 from the system connected to the AC power source 100. By doing in this way, since it becomes possible to detect a power failure only by the auxiliary power failure detection device 120, the accuracy of power failure detection can be improved regardless of the connection state between the lighting device 6 and the AC power source 100. In addition, it is possible to actually provide highly accurate power failure detection without complicating the control configuration.

  Moreover, the illuminating devices 1, 2, 4, and 6 include a main body 10 that can be connected to a socket for a fluorescent lamp or a bulb. By doing in this way, since it becomes possible to use as an alternative of the existing fluorescent lamp or an electric light bulb, installation of the illuminating devices 1, 2, and 4 can be made easy, and versatility can be improved.

  Further, the lighting device 2 has a main body 10 that can be connected to a socket for a fluorescent lamp or a light bulb, and when the main body 10 is connected to the socket, the detection switch 90b is cut off and the main body 10 is removed from the socket. And a detachment detection unit 91 that brings the detection switch 90b into a connected state. By doing in this way, since it becomes possible to light and carry the illuminating device 2 without requiring the switch operation in the dark at the time of a power failure, the usability of the illuminating device 2 can be improved.

  Further, the control unit 80 controls the power supply switching unit 40 to switch the power supply source to the light emitting unit 20 from the AC power supply 100 to the battery 50 when the power failure detection by the power failure detection unit 70 continues for a certain time. . By doing in this way, the power failure detection accuracy can be improved by excluding the instantaneous power failure.

  Further, the power failure detection unit 70 is connected in series to one side of the primary coil 71a on the AC power supply 100 side of the bidirectional diode 72 and the bidirectional diode 72 or resistor connected in parallel with the primary coil 71a. The capacitor | condenser 73 and the resistance 74 connected in series with the other side of the primary coil 71a in the alternating current power supply 100 side rather than the bidirectional | two-way diode 72 are provided. By doing in this way, since it becomes possible to extract the desired frequency component of the high frequency weak electric current which arises at the time of a power failure, and to output it to the control part 80, a power failure can be detected simply.

  The illumination systems 3, 5, and 7 according to the embodiment include the illumination device 4 or 6, and the auxiliary power failure detection device 120 or 120 a provided separately from the illumination device 4 or 6, and the auxiliary power failure detection device 120. Alternatively, 120a is connected to the AC power supply 100 via a separate system from the lighting device 4 or 6, and the auxiliary power failure detection unit 122 that detects a power failure and the auxiliary device side communication unit 121 that transmits a signal toward the communication unit 92. And an auxiliary device control unit 123 that controls transmission of a signal by the auxiliary device side communication unit 121 so that the detection switch 90b is connected based on the detection of the power failure by the auxiliary power failure detection unit 122. Yes.

  By adopting such a configuration, the power supply source to the light emitting unit 20 can be detected reliably without being affected by the connection state between the lighting device 4 and the AC power source 100 even though it is a simple control configuration. The battery 50 can be switched on to light up.

  The auxiliary power failure detection device 120a of the illumination system 7 includes an illuminance detection unit 124 that detects ambient illuminance. The auxiliary device control unit 123 detects the power failure by the auxiliary power failure detection unit 122, and the illuminance detection unit 124 Based on the detected ambient illuminance being equal to or less than a predetermined threshold, transmission of signals by the auxiliary device side communication unit 121 is controlled so that the detection switch 90b is in a connected state. By doing in this way, it becomes possible to detect a power failure separately from other malfunctions, etc., so that the accuracy of power failure detection can be improved. Moreover, since it becomes possible not to light up the light emission part 20 when the circumference | surroundings are sufficiently bright, the useless consumption of the battery 50 can be prevented.

  Moreover, the illumination system 8 according to the embodiment includes the illumination device 4 or 6 and the auxiliary power failure detection device 120b provided separately from the illumination device 4 or 6, and the auxiliary power failure detection device 120b includes the AC power source 100. An illuminance detector 124 for detecting ambient illuminance, and an auxiliary device that transmits a signal toward the communication unit 92, and is disposed at a position that always receives at least one of light and sunlight emitted from a device serving as a power supply source. The transmission of signals by the auxiliary device side communication unit 121 is controlled so that the detection switch 90b is connected based on the surrounding illuminance detected by the side communication unit 121 and the illuminance detection unit 124 being equal to or less than a predetermined threshold. And an auxiliary device control unit 123.

  By setting it as such a structure, since it becomes possible to detect a power failure only by detection of surrounding illumination, a power failure can be detected more simply. Moreover, since it is not necessary to connect the auxiliary power failure detection device 120b to the AC power supply 100, the auxiliary power failure detection device 120b can be disposed at an appropriate position.

  Although the embodiments of the present invention have been described above, the lighting device and the lighting system of the present invention are not limited to the above-described embodiments, and various modifications are made within the scope not departing from the gist of the present invention. Of course you get. For example, the shape of the main body 10 and the arrangement configuration of each part are not limited to those shown in the above embodiment, and any shape and arrangement configuration can be adopted.

  Moreover, in the said embodiment, although the example at the time of comprising the main body 10 so that connection to the socket for fluorescent lamps or the socket for light bulbs was shown, this invention is not limited to this, Other various sockets, It may be connected to the AC power supply 100 via a terminal or the like. Moreover, in the said embodiment, although the example at the time of comprising integrally each part of illuminating device 1, 2, 4, and 6 was shown, some parts, such as the battery 50 and the charging / discharging switching part 60, are separated separately, for example. You may make it comprise.

  Moreover, in the said embodiment, although the example at the time of providing the light emission part 20 provided with the LED element 22 as a light source was shown, this invention is not limited to this, For example, the light emission part 20 is a fluorescent lamp, Other light sources such as a heat-generating bulb or an organic EL may be provided. Needless to say, the arrangement of the light sources is not limited, and a plurality of light sources may be arranged separately.

  In addition, the functions and effects shown in the above embodiment are merely a list of the most preferable functions and effects resulting from the present invention, and the functions and effects of the present invention are not limited to these.

  The lighting device and lighting system of the present invention can be used in various lighting fields and disaster prevention and security fields.

DESCRIPTION OF SYMBOLS 1, 2, 4, 6 Illuminating device 3, 5, 7, 8 Illumination system 10 Main body 20 Light emission part 40 Power supply switching part 50 Battery 70 Power failure detection part 71 High frequency transformer 71a Primary coil 71b Secondary coil 72 Bidirectional diode 73 Capacitor 74 Resistance 80 Control Unit 90 Detection Function Expansion Unit 90a Auxiliary Capacitor 90b Detection Switch 91 Removal Detection Unit 92 Communication Unit 93 Detection Switch Switching Unit 94 Blocking Detection Unit 95 Device Disconnection Unit 100 AC Power Supply 120, 120a, 120b Auxiliary Power Failure Detection Device 121 Auxiliary device side communication unit 122 Auxiliary power failure detection unit 123 Auxiliary device control unit 124 Illuminance detection unit

Claims (10)

A light emitting unit that emits light when energized;
A battery for storing power,
A power source switching unit that switches a power supply source to the light emitting unit between an external AC power source and the battery;
A power failure detection unit that transmits a signal when a power failure of the AC power supply is detected;
Based on reception of the signal from the power failure detection unit, a control unit that controls the power supply switching unit to switch the power supply source to the light emitting unit from the AC power supply to the battery;
A detection function expansion unit that extends the detection function of the power failure detection unit ,
The power failure detection unit includes a high-frequency transformer having a primary coil connected to the AC power source and a secondary coil connected to the control unit ,
The detection function extension unit
An auxiliary capacitor or auxiliary resistor connected in parallel with the primary coil on the AC power supply side from the power failure detection unit,
A detection switch that is connected in series with the auxiliary capacitor or the auxiliary resistor, and that switches connection and disconnection between the auxiliary capacitor or the auxiliary resistor and the primary coil .
Lighting device. A communication unit for receiving a signal transmitted from the outside;
A detection switch switching unit that switches connection and disconnection of the detection switch based on a reception state of a signal from the outside in the communication unit,
The lighting device according to claim 1 . An interruption detection unit for detecting interruption of electric power supply from the AC power supply;
And a device disconnecting unit that disconnects the power failure detection unit and the detection function expansion unit from the system connected to the AC power source based on the detection of the power supply interruption by the interruption detection unit. ,
The lighting device according to claim 2 . A main body that can be connected to a socket for a fluorescent lamp or a light bulb is provided.
Lighting device according to any one of claims 1 to 3. A main unit that can be connected to a socket for a fluorescent lamp or a bulb;
A detachment detecting unit configured to turn off the detection switch when the main body is connected to the socket and to connect the detection switch when the main body is detached from the socket. And
Lighting device according to any one of claims 1 to 3. The control unit controls the power supply switching unit to switch a power supply source to the light emitting unit from the AC power source to the battery when reception of a signal from the power failure detection unit continues for a certain period of time. Characterized by the
Lighting device according to any one of claims 1 to 5. The power failure detection unit is
A bidirectional diode or resistor connected in parallel with the primary coil;
A capacitor connected in series to one side of the primary coil on the AC power supply side than the bidirectional diode;
A resistor connected in series to the other side of the primary coil on the AC power supply side than the bidirectional diode,
Lighting device according to any one of claims 1 to 6. A lighting device according to claim 2 or 3 ,
An auxiliary power failure detection device provided separately from the lighting device,
The auxiliary power failure detection device is
An auxiliary power failure detection unit that is connected to the AC power supply via a separate system from the lighting device and detects the power failure,
An auxiliary device side communication unit for transmitting a signal toward the communication unit;
An auxiliary device control unit that controls transmission of a signal by the auxiliary device side communication unit so that the detection switch is connected based on the fact that the auxiliary power failure detection unit detects the power failure. And
Lighting system. The auxiliary power failure detection device includes an illuminance detector that detects ambient illuminance,
The auxiliary device control unit detects that the auxiliary power failure detection unit has detected the power failure, and the ambient light detected by the illuminance detection unit is equal to or lower than a predetermined threshold value, and the detection switch is connected to the connected state. So as to control the transmission of the signal by the auxiliary device side communication unit,
The lighting system according to claim 8 . A lighting device according to claim 2 or 3 ,
An auxiliary power failure detection device provided separately from the lighting device,
The auxiliary power failure detection device is
An illuminance detection unit that is disposed at a position that constantly receives at least one of light and sunlight emitted by a device that uses the AC power supply as a power supply source, and detects ambient illuminance;
An auxiliary device side communication unit for transmitting a signal toward the communication unit;
An auxiliary device control unit that controls transmission of a signal by the auxiliary device side communication unit so that the detection switch is connected based on the ambient illuminance detected by the illuminance detection unit being equal to or less than a predetermined threshold value And comprising:
Lighting system.

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