JP5243873B2 - Lighting control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lighting control system which can be realized with a simple circuit constitution easily executed and can establish in a lot a plurality of lighting apparatuses in a desired operation mode. <P>SOLUTION: The lighting control system is provided with a plurality of guide lamps 2, a guide lamp signal device 1 which integrally controls the plurality of guide lamps 2, and a switch SW1 which is opened and closed by a pulse signal from the guide lamp signal device 1. Two power supply lines 3, 3 connected to a commercial power supply AC and one signal line 4 connected to one phase of the commercial power supply AC via the switch SW1 are respectively connected to each guide lamp 2. Further, each guide lamp 2 has at least three operation modes respectively, and is established in a lot to any of the operation modes according to the switching pattern of the switch SW1 by the pulse signal from the guide lamp signal device 1. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a lighting control system.

  Conventionally, various guide lights used as a lighting fixture for disaster prevention have been provided. This guide light displays information related to the evacuation route and evacuation direction at the time of a disaster in various simple characters and figures (for example, a figure where people are running). It is required by law to install in key areas. In general, a plurality of guide lights are installed in a building, and these guide lights are always turned on in principle. However, in some facilities such as movie theaters, they are always turned off. Is supposed to be.

  Further, a guide light control system configured to be able to centrally control a plurality of guide lights has also been provided conventionally. For example, FIG. 13 shows an example of a three-wire guide light used in this system, and a commercial power supply AC Two power supply lines 3 and 3 connected to each other and one signal line 4 for an on / off signal of the lamp 21 incorporated in the guide lamp 2 are wired. In this guide light 2, when the switch SW <b> 1 is turned off by a control signal from a guide light signal device (not shown), the switch element Q <b> 1 is turned on by the determination unit 20 a configuring the control unit 20 and supplied via the lighting circuit unit 22. The lamp 21 is turned on by the lighting power. On the other hand, when the switch SW1 is turned on by the control signal, the switch elements Q1 and Q2 are both turned off by the determination unit 20a, and the lamp 21 is turned off. That is, in the present guide light control system, a plurality of guide lights 2 can be turned on / off in a batch by an on / off signal from the switch SW1.

  Here, the above-mentioned guide light 2 and emergency light (not shown) are obliged to be inspected by the Fire and Disaster Management Agency notification and the Building Standard Law, etc., 20 minutes or 60 minutes for the guide light, 30 minutes for the emergency light, respectively. The lamp must be effectively lit by a secondary battery. Therefore, in the case of the guide light control system described above, a weight is hung on a pulling wheel of an inspection switch (not shown) for each guide light 2 in order to keep each guide light 2 urgently lit for a predetermined time. It was necessary to put it in the inspection state, which was a very time-consuming work. Therefore, in this system, in order to save labor in the inspection work, for example, a system that can be automatically inspected by a control signal from a guide light signal device can be considered. However, the signal line 4 lights the lamp 21. In this case, it is necessary to increase the number of signal lines to a four-wire system, resulting in a problem that workability is deteriorated.

  Similarly, there has also been proposed an inspection work that saves labor by automating the inspection work (see, for example, Patent Documents 1 and 2). These lighting systems are composed of a plurality of lighting devices and a control device that exchanges data with each lighting device via a communication line, and periodically (for example, 3) from the control device to each lighting device. The inspection processing is started by the inspection start command data transmitted once a month), and the inspection result of each lighting device is returned to the control device. That is, in the present lighting system, the inspection result of each lighting device can be grasped by the control device without going to the installation location of each lighting device and performing the inspection.

Furthermore, as shown in FIG. 14, there has been proposed one in which the inspection work is automated by a control signal superimposed on an AC power source (see, for example, Patent Document 3). In this guide light control system, a control signal emitted from the control unit 106 of the guide light signal device 102 is superimposed on the AC power supply line 101 via the transmission unit 107 and the control signal transmitted via the AC power supply line 101 is transmitted. An automatic inspection is performed on the received guide light 108 side.
JP 2004-119151 A (paragraph [0064] -paragraph [0068] and FIGS. 13 and 14) JP 2004-111347 A (paragraph [0062] -paragraph [0074] and FIGS. 1 to 3) JP 7-193531 A (paragraph [0030] -paragraph [0065] and FIGS. 1 and 2)

  In the lighting systems shown in Patent Documents 1 and 2 described above, inspection work can be periodically performed on a plurality of lighting devices, and the inspection results can be grasped collectively by the control device. However, workability was not good.

  In addition, in the guide light control system shown in Patent Document 3, since a control signal is superimposed on the AC power supply, separate wiring such as a communication line is unnecessary as in the illumination systems shown in Patent Documents 1 and 2, In addition, although a plurality of guide lights can be inspected collectively, in order to superimpose a control signal on the AC power supply, it is necessary to incorporate a high-frequency generator, a modulator, a filter, etc. in the transmitter constituting the control device. In particular, the circuit configuration becomes complicated.

  The present invention has been made in view of the above-described problems, and an object of the present invention is a system that is easy to construct and can be realized with a simple circuit configuration. The object is to provide a lighting control system that can be collectively set.

The invention of claim 1 includes a plurality of lighting fixtures, and a control unit for centrally controlling a multiple luminaire, and a switch portion which is opened and closed by a pulse signal from the controller, a commercial power source to each lighting fixture Two connected power lines are connected to one signal line connected to one phase of the commercial power supply via the switch unit, and each lighting fixture has at least three operation modes. , One of the operation modes is set at a time according to the opening / closing pattern of the switch unit by the pulse signal from the control device , the plurality of lighting fixtures are composed of a plurality of guide lights, and the control device centrally controls the plurality of guide lights. Each guide light includes a light source, a secondary battery that supplies lighting power to the light source in an emergency, a control signal detection unit that detects a pulse signal due to an opening / closing operation of the switch unit, System Control means for switching the operation mode based on the pulse signal detected by the signal detection unit, and determining whether or not the secondary battery is normal by turning on the light source with the secondary battery for a predetermined inspection time or more as the operation mode At least a check mode, a constant lighting mode for turning on the light source with electric power supplied from a commercial power source, and a constant light-off mode for turning off the light source, and the control means responds to the pulse signal detected by the control signal detection unit. wherein the switching Rukoto least inspection mode, either always on mode or always off mode Te.

The invention of claim 2 is characterized in that when the operation mode is switched to the inspection mode, the control means of each guide light performs the inspection operation by shifting the time in a preset order.

In the invention of claim 3 , the plurality of guide lights are composed of a plurality of types of guide lights having different functions, and each type of guide light has a plurality of types of operation modes, and each of them is in accordance with an opening / closing pattern of the switch unit. The operation mode is collectively set.

The invention of claim 4 is characterized in that a plurality of types of guide lights are housed in a single housing, and the control means controls the plurality of types of guide lights.

  According to the first aspect of the present invention, it is only necessary to set the opening / closing pattern of the switch unit according to the type of operation mode, so that a signal line is added compared to the three-wire guide light control system shown in the conventional example. Instead, it is possible to collectively set a plurality of lighting fixtures in a predetermined operation mode. In addition, a communication line is not required as compared with the illumination systems shown in Patent Documents 1 and 2, and it is not necessary to add a signal line as compared with the above-described three-wire guide light control system. In addition, since a transmitter having a complicated circuit configuration is not required as in the case of superimposing a control signal on an AC power supply, it is possible to realize an illumination control system capable of collectively controlling a plurality of lighting fixtures with a simple circuit configuration. There is an effect that can be done.

In addition , there is an effect that it is possible to provide an illumination control system that can set a plurality of guide lights in a predetermined operation mode by a pulse signal from the guide light signal device.

In addition , each guide light can be set to any of the inspection mode, the always-on mode, or the always-off mode according to the pulse signal detected by the control signal detection unit. There is an effect that a possible lighting control system can be realized.

According to the second aspect of the present invention, in the inspection mode, the plurality of guide lights are not inspected at a time, but are inspected by shifting the time in a preset order, so that all the guide lights are secondary at the end of the inspection. Since the battery never discharges, for example, even if a power failure occurs during inspection or immediately after the inspection, it is possible to prevent all of the guide lights from illuminating so that they function reliably as a guide light during a power failure. There is an effect that can be made.

According to the invention of claim 3 , each type of guide light can be collectively set to a predetermined operation mode by one guide light signal device, so compared to the case where a system is provided for each type of guide light. A lighting control system with reduced costs can be realized. In addition, even when a different type of guide light from the existing guide light is installed later, it can be installed without increasing the wiring from the guide light signal device, so that the construction is easy and the cost is reduced. There is an effect that can be.

According to the fourth aspect of the present invention, a plurality of types of guide lights are housed in one housing and controlled by one control unit, so that the control unit is simplified as compared with the case where a control unit is provided for each type. As a result, the cost can be reduced.

  Embodiments of a lighting control system according to the present invention will be described below with reference to the drawings. The illumination control system according to the present invention is used as a guidance system when evacuating from a building connected to a plurality of guide lights installed in a public building such as a movie theater.

(Embodiment 1)
FIG. 1A shows the illumination control system according to the first embodiment, and a plurality (three in FIG. 1A) of guide lights 2 (lighting fixtures) and a guide light signal device that centrally controls the plurality of guide lights 2. 1 (control device) and a switch SW1 (switch unit) that is opened and closed by a pulse signal from the guide light signal device 1. In addition, the conventionally well-known thing is employ | adopted about the guide light signal apparatus 1, and it abbreviate | omits about detailed description.

  The guide light 2 is a three-wire guide light, and as shown in FIG. 1 (b), the two power lines 3, 3 connected to the commercial power source AC and a piece of the commercial power source AC through the switch SW1. One signal line 4 connected to the phase is connected.

  Further, as shown in FIG. 1B, the guide lamp 2 includes a lamp 21 (for example, a discharge lamp or a light-emitting diode), a secondary battery 26 for supplying power to the lamp 21 in the event of a power failure, and a commercial power supply AC. The power supply unit 23 for stepping down and stabilizing the AC power supplied from the power source 23 to obtain a desired DC power supply, the charging unit 24 for charging the secondary battery 26 with the DC power output from the power supply unit 23, and the lamp 21 A lighting circuit section 22 for supplying lighting power to the switch, a switch element Q1 for opening and closing a power supply path from the power supply section 23 to the lighting circuit section 22, and a power supply path from the secondary battery 26 to the lighting circuit section 22 A control signal conversion unit 25 for converting an AC voltage signal input when the switch SW1 is turned on / off into a DC voltage signal, and a control unit 20.

  Further, the control unit 20 includes a power failure detection unit 20d that detects a power failure or power recovery of the commercial power supply AC based on an output signal from the power supply unit 23, a voltage detection unit 20b that detects a battery voltage of the secondary battery 26, and a charging unit. 24 based on the detection results of the charge detection unit 20c for detecting the charge state of the secondary battery 26, the control signal detection unit 20e for detecting the control signal from the control signal conversion unit 25, and the detection units 20b to 20e. And a determination unit 20a that executes various types of operation control.

  Here, the guide lamp 2 of the present embodiment includes an inspection mode for determining whether the secondary battery 26 is normal by forcibly lighting the lamp 21 with the secondary battery 26 for a predetermined inspection time, and the lamp 21. Is always turned on and the secondary battery 26 is charged by the power supplied from the commercial power source AC, and the lamp 21 is turned off and the secondary battery 26 is charged by the power supplied from the commercial power source AC. The determination unit 20a is configured to set one of the operation modes according to the opening / closing pattern of the switch SW1 by the pulse signal from the guide light signal device 1. In addition, the guide lamp 2 of this embodiment makes the lamp 21 emergency light by the discharge power of the secondary battery 26 at the time of a power failure.

  Next, operation | movement of the illumination control system of this embodiment is demonstrated. First, when a predetermined pulse signal is output from the guide light signal device 1, the switch SW1 is turned on / off according to the pulse signal. When the switch SW1 is turned on / off, an AC voltage signal corresponding to the open / close pattern of the switch SW1 is input to the control signal converter 25, and the control signal converter 25 converts the AC voltage signal into a DC voltage signal. Is output to the control signal detector 20e constituting the unit 20. When the control signal detector 20e detects the DC voltage signal, the control signal detector 20e outputs the signal to the determination unit 20a. The determination unit 20a sets one of the operation modes according to the input DC voltage signal (pulse signal).

  For example, as shown in FIG. 2A, when the pulse signal V1 from the control signal detection unit 20e is detected twice in 3 seconds, the determination unit 20a checks the operation mode of the secondary battery 26. 2B, when the pulse signal V1 is continuously detected for 3 seconds or more as shown in FIG. 2 (b), the mode is always set to the extinguishing mode, and in cases other than FIGS. 2 (a) and 2 (b) Set to the always-on mode. Note that the above-mentioned 3 seconds are set based on “Starting the operation within 3 seconds upon receiving an operation signal from the guide light signal device” in the technical guide for lighting fixtures (JIL5502).

  For example, when the operation mode is set to the inspection mode, the determination unit 20a determines whether or not the inspection operation is possible based on the detection signal from the charge detection unit 20c, and if the inspection operation is possible, the switch element Q1. Is turned off and the switch element Q2 is turned on to create a pseudo power failure state, and the secondary battery 26 is inspected. At this time, the lamp 21 is turned on. Here, whether or not the inspection operation is possible is determined by whether or not the secondary battery 26 is charged for a predetermined time (for example, 24 hours or more), and the inspection of the secondary battery 26 is a battery detected by the voltage detection unit 20b. This is done based on voltage. Here, the control unit is configured by the determination unit 20a. In this embodiment, when the operation mode is set to the inspection mode, a pulse signal is transmitted to all the guide lights 2, and the inspection operation is performed on all the guide lights 2 at the same time. Yes.

  Thus, according to the present embodiment, it is only necessary to set the opening / closing pattern of the switch SW1 according to the type of operation mode, so that a signal line is added compared to the three-wire guide light control system shown in the conventional example. The plurality of guide lights 2 can be collectively set to a predetermined operation mode without doing so. In addition, a communication line is not required as compared with the illumination systems shown in Patent Documents 1 and 2, and it is not necessary to add a signal line as compared with the above-described three-wire guide light control system. Furthermore, since a transmitter having a complicated circuit configuration is not required as in the case of superimposing a control signal on an AC power supply, a lighting control system capable of collectively controlling a plurality of guide lights 2 with a simple circuit configuration is realized. Can do.

  In this embodiment, when the pulse signal V1 is detected twice in 3 seconds, the inspection mode is set, and when the pulse signal V1 is detected continuously for 3 seconds or more, the always-off mode is set. However, the pulse signal pattern is not limited to the present embodiment, and other modes can be used as long as they can distinguish between the inspection mode, the always-on mode, and the always-off mode. It may be a pattern.

Further, in the present embodiment, the case where the operation mode is the three patterns of the inspection mode, the always-on mode, and the always-off mode has been described as an example, but it is sufficient that the operation mode has at least three patterns of operation modes. There may be.

(Embodiment 2)
FIG. 3 is a block diagram of the guide light 2 used in the lighting control system of the second embodiment. In the first embodiment, all the guide lights 2 are inspected at the same time. An address storage unit 20f is provided in each of the control units 20 of the lamps 2, and the inspection operation of each guide lamp 2 is configured to be performed with a time shift in order of preset addresses. Other configurations are the same as those of the first embodiment, and the same components are denoted by the same reference numerals and description thereof is omitted.

  In the guide light 2 of the present embodiment, an address storage unit 20f is provided in the control unit 20, and the determination unit 20a of each guide light 2 is stored in the address storage unit 20f when the operation mode is set to the inspection mode. The inspection operation is performed by shifting the time in the order of the stored addresses.

For example, when there are _three guide lights (guide lights 2 ₁ to 2 ₃ ) connected to the illumination control system, when the inspection signal Si is input as shown in FIG. 4 (that is, the pulse signal V1 is When detected twice for 3 seconds), the check operation is performed first in the induction lamp 2 _1, inspection operation in the induction lamp 2 ₂ then the inspection operation of the induction lamp 2 ₁ to 24 hours is performed, further the induction inspection operation of the induction lamp 2 ₃ is executed from the inspection operation of the lamp 2 ₂ to 24 hours.

Thus, according to the present embodiment, in the inspection mode, the inspection operation is not performed at the same time in the plurality of guide lights 2 ₁ to 2 ₃ , but the inspection is performed by shifting the time in the order of preset addresses, since the secondary battery 26 of all induction lamp 2 ₁ to 2 ₃ during inspection ends does not become a discharged state, all the guide lights 2 ₁ to 2 _3, even when, for example, becomes a power failure immediately after inspection and during inspection It is possible to prevent the emergency lighting from being stopped, and to reliably function as a guide light at the time of a power failure.

  In the present embodiment, the case where there are three guide lights has been described as an example, but two guide lights may be connected to the present system, or four or more guide lights may be used. Moreover, in this embodiment, although the time from the inspection operation of one guide light to the inspection operation of the next guide light is set to 24 hours, arbitrary time may be sufficient. Further, with respect to a method for storing the address in the address storage unit 20f in the control unit 20, for example, the address storage unit 20f may be configured to read the address using a remote controller, or the address may be read using a dip switch or the like. You may comprise.

(Embodiment 3)
FIG. 5 shows a lighting control system according to the third embodiment. In the first embodiment, the lighting control system is configured by a plurality of guide lights 2 having the same function as the guide light signal device 1. An illumination control system is configured by the apparatus 1 and a plurality of types of guide lights 2A and 2B having different functions. Other configurations are the same as those of the first embodiment, and the same components are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIG. 5, the illumination control system of this embodiment includes a plurality of types (two types in this embodiment) of guide lights 2A and 2B having different functions, and a guide light signal device 1 that centrally controls the guide lights 2A and 2B. And a switch SW2 that is opened and closed by a pulse signal from the guide light signal device 1, and a transfer terminal 6a provided in the automatic fire alarm facility 6 is connected to the guide light signal device 1.

  The transfer terminal 6a is closed in a normal state, and is opened when an abnormality such as a fire occurs. When the transfer terminal 6a is in an open state, the guide light signal device 1 is configured to determine that an abnormality such as a fire has occurred, and to block the pulse signals to the guide lights 2A and 2B.

  The guide light 2A is a turn-off guide light that can be turned on / off by a control signal, such as an evacuation guide light connected to a commercial power supply, and is a lamp 21 (for example, a discharge lamp or a light emission) as shown in FIG. A secondary battery 26 for supplying power to the lamp 21 in the event of a power failure, and a power source unit 23 for stepping down and stabilizing the AC power supplied from the commercial power source AC to obtain a desired DC power source. A charging unit 24 that charges the secondary battery 26 with DC power output from the power supply unit 23, a lighting circuit unit 22 that supplies lighting power to the lamp 21, and a power supply path from the power supply unit 23 to the lighting circuit unit 22. A switching element Q1 for opening and closing, a switching element Q2 for opening and closing a power supply path from the secondary battery 26 to the lighting circuit unit 22, and an AC voltage input when the switch SW2 is turned on / off And a control signal converting unit 25 for converting a DC voltage signal, and a control unit 20 to issue.

  Further, the control unit 20 includes a power failure detection unit 20d that detects a power failure or power recovery of the commercial power supply AC based on an output signal from the power supply unit 23, a voltage detection unit 20b that detects a battery voltage of the secondary battery 26, and a charging unit. 24 based on the detection results of the charge detection unit 20c for detecting the charge state of the secondary battery 26, the control signal detection unit 20e for detecting the control signal from the control signal conversion unit 25, and the detection units 20b to 20e. And a determination unit 20a that executes various types of operation control.

  The guide light 2A includes a check mode for determining whether or not the secondary battery 26 is normal by forcibly turning on the lamp 21 with a secondary battery 26 for a predetermined check time, and turning on the lamp 21 and a commercial power supply. There are three operation modes: an always-on mode in which the secondary battery 26 is charged by the power supplied from the AC, and an always-off mode in which the lamp 21 is turned off and the secondary battery 26 is charged by the power supplied from the commercial power source AC. The determination unit 20a is configured to set one of the operation modes according to the opening / closing pattern of the switch SW2 by the pulse signal from the guide light signal device 1. Here, in this lighting control system, energy saving can be achieved by setting the operation mode to the always-off mode. However, in this case, it is necessary to set after confirming that there are no people in the building.

  Next, the guide light 2B is a flashing type guide light provided with a flashing circuit for flashing the lamp in the event of an abnormality such as a fire, and as shown in FIG. 7, a lamp 27 (for example, a discharge lamp or a light emitting diode), A secondary battery 26 for supplying power to the lamp 27, a power source unit 23 for stepping down and stabilizing the AC power source supplied from the commercial power source AC, and obtaining a desired DC power source, and output from the power source unit 23 A charging unit 24 for charging the secondary battery 26 with DC power, a flashing circuit unit 28 for flashing the lamp 27, and an AC voltage signal input when the switch SW2 is turned on / off is converted into a DC voltage signal. The control signal conversion unit 25 and the control unit 20 are provided.

  Further, the control unit 20 includes a voltage detection unit 20b that detects a battery voltage of the secondary battery 26, a charge detection unit 20c that detects a charging state of the secondary battery 26 by the charging unit 24, and a control signal conversion unit 25 A control signal detection unit 20e that detects a control signal and a determination unit 20a that executes various operation controls based on the detection results of the detection units 20b, 20c, and 20e are provided.

  The guide light 2B includes a check mode for determining whether or not the secondary battery 26 is normal by blinking the lamp 27 with the secondary battery 26 for a predetermined check time and a lamp 27 in an abnormal state (for example, fire). There are three operation modes: a blinking mode for blinking, and an extinguishing mode for turning off the lamp 27 and charging the secondary battery 26 with power supplied from the commercial power supply AC, and a switch based on a pulse signal from the guide light signal device 1 The determination unit 20a is configured to set one of the operation modes according to the open / close pattern of SW2.

  Here, Table 1 shows the operation modes of the guide lights 2A and 2B of the present embodiment. For example, as shown in FIG. 8A, the pulse signal V1 from the control signal detection unit 20e is detected twice in 3 seconds. In the case of the guide light 2A, the operation mode is set to the inspection mode by the determination unit 20a, and the inspection operation of the secondary battery 26 is performed. At this time, in the guide lamp 2B, the operation mode is set to the extinguishing mode by the determination unit 20a, the lamp 27 is extinguished and the secondary battery 26 is charged.

  Also, as shown in FIG. 8B, when the pulse signal V1 from the control signal detection unit 20e is detected three times in 3 seconds, the state before the signal is input is maintained in the guide light 2A. (For example, if the inspection mode is set as in this example, the inspection operation is continued). In the guide light 2B, the determination unit 20a sets the operation mode to the inspection mode, and the inspection operation of the secondary battery 26 is performed. To be implemented. Further, as shown in FIG. 8C, when the pulse signal V1 from the control signal detector 20e is detected four times in 3 seconds, the guide lamp 2A is always in the extinguishing mode and the guide lamp 2B is in the extinguishing mode. The lamps 21 and 27 are both turned off.

  Here, the L signal in Table 1 indicates a signal from the transfer terminal 6a, and when a fire occurs, the transfer terminal 6a is opened, so that the guide light 2A, the guide light 2A, The pulse signal to 2B is cut off, and the switch SW2 is turned off. In the guide light 2A, the determination unit 20a sets the operation mode to the always-on mode and turns on the lamp 21, and in the guide light 2B, the determination unit 20a sets the blinking mode and causes the lamp 27 to blink. At this time, in the guide light 2A, when the commercial power supply AC is supplied, the lamp 21 is turned on by the power supplied from the commercial power supply AC, and when the commercial power supply AC is not supplied (that is, during a power failure). The lamp 21 is turned on by the power supplied from the secondary battery 26. Further, in the guide light 2B, the lamp 27 is blinked by the power supplied from the built-in secondary battery 26.

  Thus, according to the present embodiment, each type of guide light 2A, 2B can be collectively set to a predetermined operation mode by one guide light signal device 1, so that a system is provided for each type of guide light. It is possible to realize an illumination control system with reduced cost compared to the case where it is provided. Further, for example, when the guide light 2B (or the guide light 2A) is installed later on an illumination control system to which only the guide light 2A (or the guide light 2B) is connected, the wiring from the guide light signal device 1 is not provided. Since it can install without increasing, construction is easy and cost reduction can be aimed at.

  In the present embodiment, the operation mode is set according to the number of pulse signals V1 detected in 3 seconds. However, the operation mode setting method is not limited to the present embodiment, and each operation mode is set. As long as the can be distinguished. For example, as shown in FIG. 9, the inspection signal of the guide light 2A (that is, a signal for setting the guide light 2A to the inspection mode) is a signal synchronized when the phase of the commercial power supply AC is 90 °, and the guide light The inspection signal 2B is a signal that is synchronized when the phase of the commercial power supply AC is 0 °, and the turn-off signal of the guide light 2A (that is, a signal for setting the guide light 2A to the always-off mode) is the commercial power supply AC. When the phase of the signal is 45 °, the operation mode can be set and the input signal can be distinguished from external noise.

(Embodiment 4)
FIG. 10 shows a guide light 5 used in the illumination control system of the fourth embodiment. In the third embodiment, the extinguished guide light 2A and the blinking guide light 2B are provided separately. A turn-off guide light 2A and a blinking guide light 2B are housed in a single housing to constitute one guide light 5. Other configurations are the same as those of the third embodiment, and the same components are denoted by the same reference numerals and description thereof is omitted.

  FIG. 11 shows a block diagram of the guide light 5 of the present embodiment. In the casing, there is a turn-off guide light 2A (light-off guide light lighting device 29A (hereinafter abbreviated as lighting device 29A), lamp 21 and A secondary battery 26), a flashing guide lamp 2B (a flashing guide lamp lighting device 29B (hereinafter, referred to as a lighting device 29B), a lamp 27 and a secondary battery 26) are housed. Further, the signal line 4 whose one end is connected to the commercial power supply AC via the switch SW2 is connected only to the lighting device 29A, and the lighting device 29A and the lighting device 29B are connected by the signal line 7.

  FIG. 12 shows a more detailed block diagram of the guide light 5. Compared to the guide lights 2A and 2B described in the third embodiment, the control signal conversion unit 25 for detecting a signal from the switch SW2 and The difference is that the control signal detection unit 20e is provided only in the lighting device 29A and that the control unit 20 of the lighting device 29A and the control unit 20 of the lighting device 29B are connected by the signal line 7.

  Next, operation | movement of the guide light 5 of this embodiment is demonstrated. First, when a pulse signal resulting from the opening / closing operation of the switch SW2 is input to the lighting device 29A, the determination unit 20a of the lighting device 29A determines which pattern the pulse signal is. Here, examples of the pulse signal include those shown in FIG. 8 described above. For example, when the pulse signal V1 is detected twice in 3 seconds, the determination unit 20a of the lighting device 29A performs the inspection on the side of the guide light 2A. It is determined that the mode is selected, and the secondary battery 26 is inspected. When the pulse signal V1 is detected three times in 3 seconds, the determination unit 20a of the lighting device 29A determines that the inspection mode is on the guide light 2B side, and controls the lighting device 29B via the signal line 7. A predetermined signal (a signal corresponding to the inspection mode on the guide light 2B side) is transmitted to the unit 20. When the determination unit 20a of the lighting device 29B receives the signal, the determination unit 20a determines that the inspection mode is on the guide light 2B side, and performs the inspection operation of the secondary battery 26.

  Further, when the pulse signal V1 is detected four times in 3 seconds, the determination unit 20a of the lighting device 29A determines that it is in the always-off mode, turns off the lamp 21, and turns on the lighting device via the signal line 7. A predetermined signal (a signal corresponding to the extinguishing mode) is transmitted to the control unit 20 of 29B. When the determination unit 20a of the lighting device 29B receives the signal, the determination unit 20a determines that it is in the extinguishing mode and turns off the lamp 27. Further, when a fire occurs and the switch SW2 is turned off, the determination unit 20a of the lighting device 29A determines that the constant lighting mode is set, turns on the lamp 21, and controls the lighting device 29B via the signal line 7. A predetermined signal (a signal corresponding to the blinking mode) is transmitted to 20. When the determination unit 20a of the lighting device 29B receives the signal, the determination unit 20a determines that it is in the blinking mode and causes the lamp 27 to blink.

  Thus, according to the present embodiment, a plurality of types of guide lights 2A and 2B are accommodated in one housing, and both guide lights 2A and 2B are connected to one control means (in this embodiment, via the signal line 7). By controlling with the control part 20 of the connected guide light 2A and the control part 20) of the guide light 2B, the control means can be simplified as compared with the case where the control means is provided for each type, and as a result, the cost. You can go down.

  In the present embodiment, the case where the control unit 20 of the lighting device 29A and the control unit 20 of the lighting device 29B are provided separately has been described as an example. For example, the function of the control unit 20 of the lighting device 29B is changed to the lighting device 29A. It is good also as a structure which abbreviate | omits the control part 20 of the lighting device 29B by giving to the control part 20 of this.

  Moreover, although Embodiment 1-4 demonstrated the case where a guide light was used as a lighting fixture as an example, a lighting fixture is not limited to this embodiment, and is centrally controlled via a control apparatus. Anything is acceptable.

(A) is a schematic system diagram which shows the illumination control system of Embodiment 1, (b) is a schematic block diagram of the guide light used for the same as the above. (A), (b) is a pattern figure of the control signal input into the guide light used for the same as the above. It is a schematic block diagram of the guide light used for the illumination control system of Embodiment 2. It is a time chart figure explaining operation | movement same as the above. FIG. 5 is a schematic system diagram illustrating an illumination control system according to a third embodiment. It is a schematic block diagram of the extinguishing type | mold guide light used for the same as the above. It is a schematic block diagram of the blinking type | mold guide light used for the same as the above. (A)-(c) is a pattern figure of the control signal input into each guide light used for the same as the above. It is a time chart figure which shows another control signal input into each guide light used for the same as the above. It is an external appearance perspective view of the guide light used for the illumination control system of Embodiment 4. It is a schematic block diagram of the guide light used for the same as the above. It is a detailed block diagram of the guide light used for the same as the above. It is a schematic block diagram of the guide light used for the guide light control system of a prior art example. It is a schematic system diagram of a guide light control system showing another example of the conventional example.

Explanation of symbols

1 Guide light signal device (control device)
2 Guide lights (lighting fixtures)
3 Power line 4 Signal line AC Commercial power SW1 Switch (Switch part)

Claims (4)

Comprising a plurality of lighting fixtures, and a control unit for centrally controlling a plurality of lighting fixtures, and a switch portion which is opened and closed by a pulse signal from the control device,
Each of the lighting fixtures is connected to two power lines connected to a commercial power source and one signal line connected to one phase of the commercial power source via the switch unit,
Each of the lighting fixtures has at least three operation modes, and is collectively set to one of the operation modes according to the opening / closing pattern of the switch unit by a pulse signal from the control device ,
The plurality of lighting fixtures are composed of a plurality of guide lights, and the control device is composed of a guide light signal device that centrally controls the plurality of guide lights,
Each of the guide lights includes a light source, a secondary battery that supplies lighting power to the light source in an emergency, a control signal detection unit that detects a pulse signal due to an opening / closing operation of the switch unit, and the control signal detection unit Control means for switching the operation mode based on the detected pulse signal,
As the operation mode, an inspection mode for determining whether or not the secondary battery is normal by turning on the light source with the secondary battery for a predetermined inspection time and the light source is turned on by electric power supplied from a commercial power source. And at least the inspection mode, the always-on mode, or the always-on mode according to the pulse signal detected by the control signal detection unit. lighting control system according to claim switch either to a turn-off mode. 2. The illumination control system according to claim 1 , wherein when the operation mode is switched to the inspection mode, the control unit of each of the guide lights performs the inspection operation by shifting the time in a preset order. . The plurality of guide lights are composed of a plurality of types of guide lights having different functions, and each type of guide light has a plurality of types of operation modes, and each of the guide lights is collectively set to any one of the operation modes according to the switching pattern of the switch unit. lighting control system according to claim 1 or 2, characterized in that it is set. 4. The illumination control system according to claim 3 , wherein the plurality of types of guide lights are housed in a single housing, and the plurality of types of guide lights are controlled by the control means .

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