JP6456112B2 - Street light equipment - Google Patents

Description

  The present invention relates to a street lamp device that is arranged at predetermined intervals along a street and is automatically turned on by an alternating current supplied from an external AC power source at night.

  In general, a street light device is a device that lights an illumination tool such as an LED or a lamp at night. For example, as in Patent Document 1, a battery is charged by solar power generation means during the day, and at night. There has been proposed a lighting device that is lit by supplying power from the battery. In this configuration, the power generated by the solar power generation means in the daytime is used for lighting at night, so that energy can be saved. Furthermore, in the configuration of Patent Document 1, a circuit system that is lit by a commercial power source (external power source) is provided separately from a circuit system that is lit by a battery, and when battery charging by solar power generation means is insufficient, Lights with commercial power. Thereby, even when the battery cannot be charged sufficiently due to bad weather or the like, it can be stably lit at night.

JP 2011-199963 A

  By the way, in the street lamp device using the solar power generation means as in the conventional configuration described above, even when the power supply from the commercial power supply is stopped due to a disaster or the like (when a power failure occurs), it is lit at night from the daytime charging. There is an advantage that you can. However, in this conventional configuration, since the amount of charge of the battery changes depending on the weather, sunshine hours, etc., it may not be possible to stably light the battery alone. For example, in an area where there is a lot of snow, battery charging by solar power generation means tends to be extremely small in winter, so there is a possibility that it cannot be lit at night when a commercial power source cannot be used during a disaster or the like. This problem varies depending on the region. On the other hand, in any region, if it is not possible to use a commercial power source in the event of a disaster, etc. for several consecutive days, it may not be possible to charge by solar power generation means, and it may not be possible to light at night .

In addition, commercial power sources (external power sources) that supply power to street lamp devices can be broadly divided into two. That is, there are a pay-as-you-go system in which costs are generated according to the amount used, and a flat-rate system in which a fixed amount is generated regardless of the amount used, both of which have advantages. In the case of street lamps that use commercial power, it is necessary to supply power only at night, and it is cheaper than the pay-as-you-go system. Is used. When such a flat-rate system is used, an automatic flasher is disposed between the commercial power source and the street lamp device. The automatic flasher detects ambient brightness, and automatically switches between power supply from a commercial power source and supply stop according to the detected brightness.
In the street light device using the photovoltaic power generation means of the conventional configuration described above, the amount of charge of the battery changes depending on the weather, the daylight hours, etc., so that it is necessary to use a commercial power source, and when the commercial power source is used Its usage changes. Therefore, when using a commercial power source with the above-mentioned flat-rate system, the battery can be sufficiently charged by the solar power generation means, and even if the amount of the commercial power source used is reduced, it is disadvantageous because a certain cost is generated. . On the other hand, when a commercial power source is used on a pay-as-you-go basis, the price increases as the usage amount of the commercial power source increases. These cost problems vary greatly between areas with long sunshine hours and areas with short sunshine hours.

  The present invention is an attempt to solve the above-described problems, and proposes a street lamp device that can be stably lit at night even when a commercial power source (external power source) fails due to a disaster or the like. .

  The present invention is connected to an external AC power source through an automatic flasher that detects an ambient brightness and energizes only when the brightness is below a predetermined brightness level, and is lit by an AC current supplied from the external AC power source. In a street light device equipped with a lighting fixture, a storage device that stores DC electric current by inputting a direct current, and a rectifier that converts alternating current into direct current, and from an external AC power supply via the automatic flasher The supplied AC current is branched into an input to the rectifier and an output to the luminaire, and a DC current converted by the rectifier is output to the capacitor to charge the capacitor, and the luminaire is A first energization circuit to be lit, an illuminance sensor for detecting ambient brightness, an energization switch that is energized only when the brightness detected by the illuminance sensor is equal to or lower than a predetermined brightness, and a direct current An alternating current converted into an alternating current, and the direct current supplied from the capacitor is input to the inverter only when the current is less than a predetermined brightness by the energization switch, and the alternating current converted by the inverter When the AC current is supplied from the external AC power supply through the second energization circuit that outputs the current to the lighting fixture and turns on the lighting fixture, and the automatic flasher, the first switching circuit is switched to, A street lamp device comprising: circuit switching means for switching to the second energization circuit when an alternating current is not supplied from an external alternating current through the automatic flasher.

  Here, as the energization switching device of the second energization circuit, it is possible to use the same configuration as the automatic flashing device, or it is possible to use another configuration. In addition, the predetermined brightness to be energized by the automatic blinker and the predetermined brightness to be energized by the energization switch are preferably set to the same brightness, but can be set to different brightnesses.

  In such a configuration, since the alternating current is normally supplied from the external alternating-current power supply via the automatic flasher when the ambient brightness is equal to or lower than the predetermined brightness, the first energizing circuit causes the storage battery to Charging and lighting fixtures. On the other hand, even if the ambient brightness is less than or equal to the predetermined brightness, if the AC current is not supplied from the external AC power source due to a power failure or the like, it is supplied from the storage device via the energization switch by the second energizing circuit. Lighting equipment is turned on by converting direct current to alternating current. Here, the charging of the capacitor is performed by converting the AC current supplied from the external AC power source into the DC current in parallel with the output to the lighting fixture, so that the capacitor can be charged stably, and the capacitor is relatively Can easily fill up. When the supply from the external AC power supply is stopped due to a power failure or the like, the direct current is stably supplied from the thus charged capacitor, so that the lighting fixture can be lit stably for a relatively long time. it can. That is, the configuration of the present invention charges the battery with an alternating current supplied from an external alternating current power source at normal times, so that unlike the conventional solar power generation described above, the emergency use is stable regardless of the weather, daylight hours, etc. Can be stored in the battery. For this reason, in a region where relatively much snow falls, it can be lit stably at night when a power failure occurs in winter. Further, in any region, when the bad weather is continuously interrupted, it can be lit stably in the same manner.

  In this configuration, when the ambient brightness is brighter than the predetermined brightness, an AC current is not supplied from the external AC power supply, so that the second energization circuit is effective. Since the energization switch is not energized, an alternating current is not output to the luminaire, and the luminaire is not lit.

  In addition, since the configuration of the present invention operates with an alternating current supplied from an external alternating current power supply via an automatic flasher, the commercial power supply contracted on a flat rate basis is used as the external alternating current power supply. Is preferred. That is, if an alternating current is supplied from an external AC power source only at night by an automatic flasher, the lighting fixture can be turned on at night while suppressing running costs by the rating system. And since the electrical storage device can be stably charged as described above by the alternating current supplied only at night, the lighting fixture can be stably turned on in the event of a power failure or the like. In addition, when the external AC current is not supplied (in the daytime), the operation check and inspection of the second energization circuit that is effective in an emergency can be performed easily and reliably by covering the illumination sensor of the energization switch Is possible. This is because the second energization circuit determines whether or not the lighting apparatus is energized by an energization switch, and the energization switch is provided as a separate member from the automatic flasher that controls energization from the external AC power supply. Due to

  Furthermore, the configuration of the present invention is a configuration in which the luminaire and the capacitor are connected to the first energization circuit, the second energization circuit, and the circuit switching means, and can be realized with a relatively simple circuit configuration. There is also an advantage that changes and addition of devices can be performed relatively easily.

  In the above-described street lamp device of the present invention, the circuit switching means is connected to the first input terminal for inputting the alternating current supplied from the external alternating current power supply via the automatic blinker, the lighting fixture and the rectifier, A first output terminal that outputs the AC current, a capacitor is connected, a second input terminal that inputs a DC current supplied from the capacitor, and an inverter is connected via an energization switch to output the DC current A second output terminal that connects the first input terminal and the first output terminal and disconnects the second input terminal and the second output terminal when an alternating current is supplied from the external AC power source. Switch to the first energization circuit, and when the AC current is not supplied from the external AC power source, the second input terminal and the second output terminal are connected and the first input terminal and the first output terminal are disconnected. Circuit switching to switch to double-carrying circuit Configuration is proposed is made comprises a.

  In the circuit switching device having such a configuration, when an alternating current is supplied from an external AC power source via an automatic flasher, switching to the first energizing circuit, and when no AC current is supplied from the external AC power source, Since it switches to a 2nd electricity supply circuit, as above-mentioned, lighting of the lighting fixture by a 1st electricity supply circuit, charging of a capacitor | condenser, and lighting of the lighting fixture by a 2nd electricity supply circuit can be performed stably. Therefore, according to this structure, the effect of this invention mentioned above can be exhibited stably and reliably.

  In the above-described street lamp device of the present invention, the circuit switching means illuminates the alternating current when the alternating current is started to be supplied from the external alternating current power supply via the automatic flashing device and is switched to the first energization circuit. When the supply of alternating current from the external AC power supply via the first delay device and the automatic flashing device through the automatic flashing device is stopped and switched to the second energizing circuit, the timing of starting output to the appliance is delayed by a predetermined time. The structure provided with the 2nd delay device which delays the timing which starts the output of an alternating current from an inverter to a lighting fixture by predetermined time is proposed.

  In such a configuration, when the first delay device and the second delay device start to output a current to the lighting fixture, it is possible to prevent a sudden electrical load from acting on the lighting fixture. Here, a general lighting fixture is mainly provided with a capacitor inside in order to maintain stable lighting. When this general lighting fixture is applied, electric charge may be stored in the capacitor at the start of lighting, and when an electrical load acts suddenly as described above, There is a risk of failure. For this reason, in the present configuration, a sudden electrical load is prevented from acting by the first delay device and the second delay device, and the failure prevention effect of the lighting fixture is enhanced.

  As described above, according to the street lamp device of the present invention, the lighting device is turned on and the capacitor is charged by the AC current supplied from the external AC power source via the automatic flasher, so that the capacitor is stabilized. Can be recharged and filled up relatively easily. Therefore, in the event of a power failure due to a disaster or the like (emergency), a direct current can be stably supplied from the capacitor thus charged, and the lighting fixture can be lit stably for a relatively long time. Such an effect can be stably generated even in the case of winter in a region where a lot of snow falls or when the weather is unsatisfactory for several days as compared with the conventional configuration using solar power generation. In addition, since the second energization circuit is provided with an energization switcher separately from the automatic flashing device, this configuration covers the energization switcher when it is bright such as in the daytime. Operation check and inspection can be performed easily and reliably.

1 is a wiring diagram showing a circuit of a street lamp device 1. FIG. It is explanatory drawing which shows the circuit aspect of the daytime of the street lamp apparatus. It is explanatory drawing which shows a circuit aspect when supply of alternating current from the external alternating current power supply 5 is started. It is explanatory drawing which shows the circuit aspect in the state by which the alternating current is stably supplied from the external alternating current power supply 5. FIG. It is explanatory drawing which shows a circuit aspect when supply of alternating current from the external alternating current power supply 5 stops at night. It is explanatory drawing which shows the circuit mode in the state in which the direct current is stably supplied from the electrical storage device at night. It is explanatory drawing which shows the installation state of the street lamp apparatus.

Embodiments according to the present invention will be described according to the following examples.
FIG. 1 is a wiring diagram illustrating a circuit of a street lamp device 1 according to the present embodiment. 2 to 6 are wiring diagrams similar to FIG. 1, but in each figure, a wiring through which an alternating current or a direct current passes is shown by a solid line, and a wiring through which the alternating current or the direct current does not pass is shown by a two-dot chain line. It shows by. Therefore, in the circuit mode of FIGS. 4 and 5, the lighting fixture 11 is turned on, and in the circuit mode of FIGS. 2, 3, and 5, the lighting fixture 11 is not turned on.

  The street lamp device 1 of FIG. 1 is disposed on a support pillar 91 (see FIG. 7) standing on the ground at predetermined intervals along a street, and is provided with one or a plurality of LEDs. A lighting fixture 11 is connected. And LED of the said lighting fixture 11 is lighted by the alternating current supplied from the external alternating current power supply 5 as a commercial power source. Here, the street lamp device 1 is connected to an external AC power source 5 via an automatic flasher 6, and the automatic flasher 6 is externally connected only when the ambient brightness is not more than a predetermined brightness. The AC power supply 5 and the street lamp device 1 are energized so that an AC current can be supplied from the external AC power source 5 to the street lamp device 1 (see FIGS. 3 and 4). The automatic flasher 6 includes an illuminance sensor (not shown) that detects ambient brightness as illuminance, and when the illuminance detected by the illuminance sensor is equal to or less than a predetermined threshold, the external AC power supply 5 and the street lamp device 1 Is supplied to the street lamp device 1, and when the detected illuminance is higher than a predetermined threshold, the external AC power source 5 and the street lamp device 1 are deenergized and supplied to the street lamp device 1. The operation is controlled to stop. In this embodiment, the illuminance is set to indicate ambient brightness, and the threshold is set to a value that is determined as night when the illuminance is less than this. That is, since the illuminance detected by the illuminance sensor is higher than the threshold between before and after sunrise (hereinafter referred to as daytime), the automatic flasher 6 supplies AC current from the external AC power source 5. (See FIG. 2), and at night, the illuminance detected by the illuminance sensor is equal to or less than the threshold value, so that an alternating current is supplied from the external AC power source 5 (see FIGS. 3 and 4). Since the automatic flasher 6 can be applied to a configuration that has been used conventionally, the details thereof will be omitted.

  As described above, the street lamp apparatus 1 is limited to the nighttime when the AC current is supplied from the external AC power source 5 by the automatic flasher 6 mainly at night. It can be a flat-rate system for the public street light that is the purpose. In this contract, since the automatic blinker 6 maintains the external AC power supply 5 and the street lamp device 1 in a non-energized state during the daytime, no AC current is supplied from the external AC power supply 5 and the lighting fixture 11 is turned on. No (see Figure 2). Note that an AC current of 100 V is supplied from the external AC power supply 5.

  The street lamp device 1 includes a terminal device 15 in which a plurality of a pair of conductive terminals are arranged in parallel. The terminal device 15 is connected to the positive electrode and the negative electrode of the luminaire 11 described above, and is connected to the positive electrode and the negative electrode of the external AC power source 5 via the automatic flasher 6 described above. Yes. Further, the street lamp device 1 includes a capacitor 12 that can input and output a DC current of 12 V, and a positive electrode and a negative electrode of the capacitor 12 are connected to the terminal device 15, respectively.

  The negative pole of the external AC power source 5 connected via the automatic flasher 6 is connected to the rectifier 21 via the terminal unit 15, and the positive pole of the external AC power source 5 is connected to the terminal unit 15. Is connected to the first input terminal a1 of the circuit switch 22. A first output terminal a <b> 2 of the circuit switcher 22 is connected to the rectifier 21. Here, the circuit switching device 22 is configured by a so-called relay circuit, and the positive electrode and the negative electrode of the external AC power source 5 are connected to the electromagnet (coil) 23 of the relay circuit via the terminal device 15, respectively. Has been. In the state where the alternating current is not supplied from the external AC power source 5 by the automatic flashing device 6, the circuit switcher 22 maintains the first input terminal a 1 and the first output terminal a 2 in a disconnected state. When an alternating current is supplied, the first input terminal a1 and the first output terminal a2 are connected (see FIGS. 3 and 4).

  The rectifier 21 converts 100V AC current supplied from the external AC power source 5 into 12V DC current. The rectifier 21 is connected to the charge / discharge controller 24 and causes the converted DC current to be input to the charge / discharge controller 24. The charge / discharge controller 24 is connected to the battery 12 via the terminal 15, and the direct current converted by the rectifier 21 is output to the battery 12 via the charge / discharge controller 24. In this way, the circuit from the external AC power supply 5 to the battery 12 via the circuit switch 22, the rectifier 21, and the charge / discharge controller 24 is connected, so that a direct current can be input to the battery 12 to charge the battery 12. The charge / discharge controller 24 is for protecting the battery 12 by preventing overcharge and overdischarge of the battery 12. Since the rectifier 21 and the charge / discharge controller 24 having a conventionally known configuration can be applied, details thereof are omitted.

  The negative pole of the external AC power source 5 is connected to the negative pole of the lighting fixture 11 via the terminal device 15 via the automatic flasher 6. Further, the positive pole of the luminaire 11 is connected to the first output terminal a <b> 2 of the circuit switcher 22 via the terminal device 15 and the first delay device 25. The first delay device 25 has a timer function. When the first input terminal a1 and the first output terminal a2 of the circuit switch 22 are connected as shown in FIG. The timing at which the supplied alternating current starts to be output to the lighting fixture 11 is delayed by a predetermined time from the supply start point of the alternating current. Specifically, the first delay device 25 is configured by a relay circuit having a timer function, and the first output terminal a2 of the circuit switch 22 is connected to the electromagnet 26 and the input terminal c1 of the relay circuit. The positive pole of the luminaire 11 is connected to the output terminal c2 of the relay circuit via the terminal device 15, and the negative pole of the external AC power source 5 is connected to the electromagnet 26. In the first delay device 25, when an alternating current is input to the electromagnet 26 via the circuit switch 22, after a predetermined delay time (for example, 1 to 5 seconds) has elapsed, the first delay device 25, as shown in FIG. The input terminal c1 and the output terminal c2 are connected. As a result, a circuit from the external AC power source 5 to the lighting fixture 11 is connected via the circuit switch 22 and the first delay device 25, and an AC current is output to the lighting fixture 11 to be lit. Since the first delay unit 25 having a conventionally known timer function can be applied, details thereof are omitted.

  As described above, in the street lamp device 1, the AC power supplied from the external AC power source 5 via the automatic flasher 6 is supplied from the rectifier 21 to the battery 12 via the circuit switch 22 as shown in FIG. 4. A first energization circuit according to the present invention is provided that outputs and charges, and outputs to the luminaire 11 through the first delay device 25 to light it. In the first energization circuit, when an alternating current is supplied from the external AC power source 5 by the automatic flasher 6 described above at night, the circuit switch 22 connects the first input terminal a1 and the second output terminal a2. The lighting device 11 is turned on and the battery 12 is charged. On the other hand, since no alternating current is supplied from the external AC power source 5 by the automatic flasher 6 as shown in FIG. 2 during the daytime, the circuit switch 22 does not connect the first input terminal a1 and the second output terminal a2. Therefore, the lighting fixture 11 is kept in the off state and the battery 12 is not charged.

  On the other hand, the circuit switcher 22 includes a second input terminal b1 and a second output terminal b2 that are converted into connection and non-connection according to the intermittent connection of the alternating current to the electromagnet 23. Specifically, as shown in FIG. 2, the second input terminal b <b> 1 and the second output terminal b <b> 2 are connected in a state where no alternating current is supplied from the external AC power supply 5 to the electromagnet 23 by the automatic flasher 6. As described above, in a state in which an alternating current is supplied from the external alternating-current power supply 5 to the electromagnet 23, the second input terminal b1 and the second output terminal b2 are disconnected. That is, the circuit switch 22 connects the second input terminal b1 and the second output terminal b2 and connects the first input terminal a1 and the first output terminal a2 in a state where no AC current is supplied from the external AC power source 5. The second input terminal b1 and the second output terminal b2 are disconnected and the first input terminal a1 is not connected (see FIGS. 2, 5, and 6), and an AC current is supplied from the external AC power supply 5. Are connected to the first output terminal a2 (see FIGS. 3 and 4).

  As shown in FIGS. 5 and 6, the second input terminal b <b> 1 of the circuit switch 22 is connected to the charge / discharge controller 24, and is connected to the positive electrode of the battery 12 via the charge / discharge controller 24. The second output terminal b <b> 2 is connected to the inverter 30 via the energization switch 31. Here, the energization switch 31 includes an input terminal d1 and an output terminal d2, the input terminal d1 is connected to the second output terminal b2 of the circuit switch 22, and the output terminal d2 is connected to the inverter 30. Connected with. The energization switch 31 includes an illuminance sensor (not shown) that detects ambient brightness as illuminance, and when the illuminance detected by the illuminance sensor is equal to or less than a predetermined threshold value, its input terminal d1 and output terminal The second output terminal b2 and the inverter 30 are energized with d2 connected. On the other hand, when the illuminance detected by the illuminance sensor is higher than a predetermined threshold, the energization switch 31 sets the input terminal d1 and the output terminal d2 in a disconnected state, and the second output terminal b2 and the inverter 30. Are turned off (see FIG. 2). Here, the threshold value of the energization switching device 31 can be set to the same value as the threshold value set in the automatic blinker 6 described above, and the second output terminal b2 and the inverter 30 are maintained in a non-energized state during the daytime. (Refer to FIG. 2) At night, the second output terminal b2 and the inverter 30 are kept energized. In addition, the same thing as the automatic blinker 6 mentioned above can be applied to this energization switching device 31.

  The inverter 30 is also connected to the negative pole of the battery 12 via the charge / discharge controller 24. The inverter 30 converts the 12V DC current supplied from the battery 12 into a 100V AC current. The negative output terminal (not shown) of the inverter 30 is connected to the negative pole of the luminaire 11 via the terminal device 15, and the positive output terminal (not shown) is connected to the second delay device 35 (switching). Device 38).

  The second delay device 35 has a timer function, is connected to the second input terminal b1 and the second output terminal b2 of the energization switching circuit 22 and is connected to the input terminal d1 and the output terminal of the energization switching device 31. When d2 is connected, the timing for starting the output of alternating current from the inverter 30 to the lighting fixture 11 is delayed by a predetermined time from the start of supplying direct current from the capacitor 12. The second delay unit 35 includes a timer unit 36 and a switching unit 38. The timer unit 36 is configured by a relay circuit having a timer function, and the switching unit 38 is configured by a relay circuit. In the timer 36, the output terminal d2 of the energization switch 31 is connected to the electromagnet 37 and the input terminal e1 of the relay circuit, and the negative pole of the storage battery 12 is connected to the electromagnet 37. The output terminal e2 of the timer unit 36 is connected to the electromagnet 39 of the switch 38, and the negative pole of the storage battery 12 is also connected to the electromagnet 39. A positive output terminal of the inverter 30 is connected to the input terminal f1 of the switch 38, and the lighting fixture 11 is connected to the output terminal f2 of the switch 38 via the terminal device 15. . When such a second delay unit 35 inputs a direct current from the capacitor 12 to the electromagnet 37 of the timer unit 36 via the energization switching unit 31, a predetermined delay time (for example, 1 to 5 seconds) elapses. The input terminal e1 and the output terminal e2 of the timer device 36 are connected. Along with this, a direct current is input to the electromagnet 39 of the switch 38 via the output terminal e2 of the timer 36, and therefore the input terminal f1 and the output terminal f2 of the switch 38 are connected, and the inverter 30 The lighting fixture 11 is energized. Thereby, the circuit from the battery 12 to the lighting fixture 11 is connected via the charge / discharge controller 24, the circuit switch 23, the energization switch 31, the inverter 30, and the second delay device 35 (switch 38). An alternating current is output to the instrument 11 and lights up. Note that since a conventionally known relay circuit can be applied to the timer unit 36 and the switch 38 constituting the second delay unit 35, details thereof are omitted.

  As described above, in the street light device 1, as shown in FIG. 6, the DC current supplied from the battery 12 is input from the circuit switch 22 to the inverter 30 via the energization switch 31 and converted by the inverter 30. A second energization circuit according to the present invention is provided in which the direct current is output to the lighting fixture 11 via the second delay device 35 and turned on. In the second energization circuit, when no alternating current is supplied from the external AC power source 5 described above at night, the energization switching unit 22 connects the second input terminal b1 and the second output terminal b2 and is supplied from the capacitor 12. The direct current is input to the inverter 30 via the energization switch 31, and the lighting fixture 11 is turned on by the alternating current converted by the inverter 30. Further, even at night, when an AC current is supplied from the external AC power source 5, the second input terminal b1 and the second output terminal b2 of the energization switch 22 are disconnected from each other. 11 is not supplied with current from the storage battery 12 (see FIG. 4). On the other hand, during the daytime, the second input terminal b1 and the second output terminal b2 of the energization switch 22 are connected as shown in FIG. 2, but the energization switch 22 does not connect the input terminal d1 and the output terminal d2. Therefore, the extinguishing state of the lighting fixture 11 is maintained.

  The energization switch 31 is connected to the battery 12 through the terminal 15 and is operated by electric power supplied from the battery 12 (not shown). Since the amount of power used by the energization switch 31 is extremely small, the amount of power stored in the battery 12 is also extremely small. Therefore, the amount of consumption by the energization switch 31 is extremely small compared to the amount of power used from the capacitor 12 to turn on the lighting fixture 11, and there is almost no influence on the lighting of the lighting fixture 11.

Next, the operation | movement aspect of the street lamp apparatus 1 mentioned above is demonstrated.
The street lamp device 1 is built in the case 92 together with the battery 12 and is disposed on a support pillar 91 erected on the ground as shown in FIG. And the lighting fixture 11 is arrange | positioned at the upper part of the support pillar 91, and this lighting fixture 11 is connected to the street lamp apparatus 1 in the case 92. FIG. Furthermore, as described above, the external AC power source 5 is connected to the street lamp device 1 via the automatic flasher 6. The case 92 containing the street lamp device 1 has a window 93 formed in the lower portion thereof, and an illuminance sensor (not shown) of the energization switch 35 constituting the street lamp device 1 is directly inside the window 93. Is provided. This illuminance sensor detects ambient brightness (illuminance) through the window 93.

  In the daytime from before and after sunrise to before and after sunset (while the surroundings are bright), the ambient illuminance is higher than a predetermined threshold value. Therefore, as shown in FIG. Is maintained in a non-energized state, the street lamp device 1 is not supplied with an alternating current from the external alternating current power source 5. Thereby, in the circuit switch 22, the second input terminal b1 and the second output terminal b2 are connected, and the first input terminal a1 and the first output terminal a2 are disconnected. In the energization switch 31, the input terminal d <b> 1 and the output terminal d <b> 2 are not connected, so that no current is supplied from the capacitor 12 to the lighting fixture 11. Thus, in the daytime, the lighting fixture 11 is maintained in a state of being turned off.

  Before and after sunset, when the ambient illuminance falls below a predetermined threshold and at night, the external AC power source 5 and the street lamp device 1 are energized by the automatic flasher 6, and the street lamp device 1 is supplied from the external AC power source 5. Is supplied with an alternating current. Accordingly, in the circuit switcher 22, as shown in FIG. 3, the first input terminal a1 and the first output terminal a2 are connected, and the second input terminal b1 and the second output terminal b2 are not connected. Become. As a result, the alternating current supplied from the external alternating-current power supply 5 is input to the first delay device 25 and the rectifier 21. The rectifier 21 converts an alternating current into a direct current and outputs the direct current to the battery 12. Thereby, the battery 12 is charged. On the other hand, as shown in FIG. 4, the first delay device 25 starts output to the lighting fixture 11 with a delay of a predetermined time (for example, 1 to 5 seconds) from the input time point. In this way, when the alternating current is output to the lighting fixture 11, the lighting fixture 12 is turned on. Here, by delaying the output timing to the luminaire 11 by the first delay device 25, it is possible to suppress a sudden electrical addition from acting on the luminaire 11, and to prevent a failure of the luminaire 11. More specifically, the general lighting apparatus 11 includes a capacitor therein, and there is a possibility that the device will fail when a sudden electrical load is applied in a state where electric charges are stored in the capacitor. It is to do.

  Further, when the AC current from the external AC power supply 5 is stopped due to a power failure or the like at night described above, the circuit switcher 22 can connect the first input terminal a1 and the first output terminal a2 as shown in FIG. The second input terminal b1 and the second output terminal b2 are connected to each other. As a result, charging of the battery 12 stops and discharge starts, and the direct current supplied from the battery 12 is input to the energization switch 31 via the circuit switch 22. Here, since the energization switch 31 is at night, its input terminal d1 and output terminal d2 are connected. Therefore, the direct current supplied from the battery 12 is input to the inverter 30 and the timer device 36 of the second delay device 35 through the energization switch 31. Then, it is converted into an alternating current by the inverter 30 and input to the switch 38 of the second delay device 35. On the other hand, the timer 36 delays the connection between the input terminal f1 and the output terminal f2 of the switch 38 by a predetermined time (for example, 1 to 5 seconds) from the time when the input from the energization switch 31 is started. As a result, as shown in FIG. 6, the input terminal f <b> 1 and the output terminal f <b> 2 of the switch 37 are connected with a predetermined time delay, and the alternating current input from the inverter 30 to the switch 38 is output to the lighting device 11. Thus, when the alternating current from the external alternating current power supply 5 stops, a direct current is supplied from the battery 12 and the lighting device 11 is turned on by the alternating current converted from the direct current. Note that the second delay device 35 delays the timing at which the output of the alternating current from the inverter 30 to the lighting fixture 11 is delayed in order to exert the same effect as the first delay device 25 described above.

  Here, since the battery 12 is normally charged by the alternating current supplied from the external alternating current power supply 5 at night, the charge amount is maintained almost full. Therefore, the lighting fixture 11 can be lit for a sufficient time during a power failure or the like.

  In addition, when the nighttime occurs in the state where a power failure or the like occurs in the daytime, since the AC current is not supplied from the external AC power supply 5, the lighting fixture 11 is caused by the DC current supplied from the battery 12 as described above. Is turned on (see FIGS. 5 and 6).

  According to the street lamp device 1 of this embodiment described above, the lighting fixture 11 is turned on by the alternating current supplied from the external supply power source 5 at night, and the emergency storage battery 12 is charged. Can be stably charged, and can be filled up relatively easily and maintained in a full state. In the event of an emergency such as a disaster, when the supply of alternating current from the external power supply 5 is stopped due to a power failure, the direct current can be stably supplied from the storage battery 12 charged at the normal time as described above. Can be lit stably for a relatively long time. Here, the electric power necessary for lighting the luminaire 11 in an emergency is charged with the electric power supplied from the external supply power source 5 at the normal time. Therefore, compared to the configuration using the conventional solar power generation described above, Since the battery 12 is not affected by the weather or sunshine hours, the battery 12 can be stably charged.

  Further, as described above, the street lamp device 1 is disposed in the case 92 and attached to the support pillar 91, and the illuminance sensor of the energization switch 31 detects the ambient brightness through the window 93. Therefore, the operation check operation can be performed by covering the window 93 in the daytime. More specifically, the illuminance sensor of the energization switch 31 detects the illuminance below a predetermined threshold by covering the window 93 during the daytime when no alternating current is supplied from the external AC power supply 5, and thus operates normally. In this case, as described above, the direct current supplied from the battery 12 is input to the inverter 30 via the circuit switch 22 and the energization switch 31, and is converted into a direct current. The lighting fixture 11 is turned on (see FIGS. 5 and 6). As described above, the operation can be confirmed by performing a comparatively simple work of covering the window 93 of the case 92 without opening the case 92 and performing work such as confirmation of energization of the circuit. Therefore, the time and cost required for the operation check operation can be suppressed as much as possible.

  In this invention, it is not limited to the Example mentioned above, About the structure other than the above-mentioned Example, it can change and implement suitably within the range of the meaning of this invention.

DESCRIPTION OF SYMBOLS 1 Street lamp apparatus 5 External alternating current power supply 6 Automatic blinker 11 Lighting fixture 12 Accumulator 21 Rectifier 22 Circuit switching device 25 First delay device 30 Inverter 31 Energization switching device 35 Second delay device a1 First input terminal a2 First output terminal b1 Second input terminal b2 Second output terminal

Claims (2)

A lighting fixture that is connected to an external AC power source through an automatic flasher that is energized only when the ambient brightness is detected and is below a predetermined brightness, and that is lit by an AC current supplied from the external AC power source. In the street light device provided,
A battery that receives and stores a direct current; and
A rectifier that converts an alternating current into a direct current is provided, and an alternating current supplied from an external alternating current power source via the automatic flasher is branched into an input to the rectifier and an output to the lighting fixture And outputting a direct current converted by the rectifier to the capacitor to charge the capacitor and to turn on the lighting fixture;
An illuminance sensor that detects ambient brightness, an energization switch that is energized only when the brightness detected by the illuminance sensor is less than or equal to a predetermined brightness, and an inverter that converts direct current to alternating current The direct current supplied from the capacitor is input to the inverter only when the energization switch has a predetermined brightness or less, and the alternating current converted by the inverter is output to the lighting fixture. A second energizing circuit for lighting the lighting fixture;
When an alternating current is supplied from an external AC power source via the automatic flasher, the second energization circuit is switched to, and when no alternating current is supplied from the external alternating current via the automatic flasher, the second Circuit switching means for switching to an energization circuit ,
Furthermore, the circuit switching means includes
A first input terminal for inputting an alternating current supplied from an external alternating current power supply via an automatic flasher, a lighting fixture and a rectifier are connected, a first output terminal for outputting the alternating current, and a capacitor are connected, A second input terminal for inputting a DC current supplied from the capacitor, and an inverter connected via an energization switch, and a second output terminal for outputting the DC current, wherein an AC current is supplied from the external AC power source. When supplied, the first input terminal and the first output terminal are connected and the second input terminal and the second output terminal are disconnected and switched to the first energization circuit, and an AC current is supplied from the external AC power supply. A circuit switch that connects the second input terminal and the second output terminal and switches the first input terminal and the first output terminal to the second energization circuit when the first input terminal and the first output terminal are disconnected from each other. Characteristic street light device. The circuit switching means is
A first delay device that delays the timing at which the AC current starts to be output to the lighting fixture when switching to the first energization circuit when an AC current is started to be supplied from an external AC power supply via an automatic flasher When,
When the supply of alternating current from the external alternating-current power supply via the automatic flasher is stopped and switched to the second energization circuit, the timing for starting the output of alternating current from the inverter to the lighting fixture is delayed by a predetermined time. The street light device according to claim 1, further comprising a second delay device.

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