JP2013229233A - Emergency lighting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an emergency lighting device capable of reliably protecting a light emitting element.SOLUTION: An emergency lighting device 11 has a power supply unit 13 for lighting a light emitting element 12 by an external power source e during non-blackout of the external power source e. The emergency lighting device 11 has a battery B. The emergency lighting device 11 has an emergency lighting circuit 24 for lighting the light emitting element 12 by the battery B during blackout of the external power source e. The emergency lighting device 11 has a relay Ry switched to connect the power supply unit 13 to the light emitting element 12 during non-blackout of the external power source e, and connect the emergency lighting circuit 24 to the light emitting element 12 during blackout of the external power source e. The emergency lighting device 11 has an overcurrent limit circuit 28 for limiting an overcurrent flowing through the light emitting element 12 when connection of the light emitting element 12 is switched from the power supply unit 13 to the emergency lighting circuit 24 by the relay Ry.

Description

  Embodiments of the present invention relate to an emergency lighting device including a switching unit that selectively connects a light-emitting element to either a constant lighting circuit or an emergency lighting circuit in response to a power failure or non-power failure of an external power source. .

  Conventionally, an emergency lighting device equipped with a constant lighting circuit that lights a light source with an external power source such as a commercial power source (commercial AC power source) and an emergency lighting circuit that lights a light source with a backup power source such as a battery in the event of a power failure of the external power source There is.

  Such an emergency lighting device monitors the external power supply, and when it detects a power failure of the external power supply, it switches the connection from the always-on circuit to the emergency lighting circuit for the light source. It is possible to turn on the light source in case of emergency.

JP 2006-210238 A JP 2006-269408 A

  When the external power supply fails, the connection from the always-on circuit to the emergency lighting circuit is switched to the light source or the load is removed, so that the load changes suddenly when viewed from the emergency lighting circuit side, causing overcurrent. May flow.

  In recent years, a light-emitting element such as an LED light source is sometimes used as a light source. Such a light-emitting element has low durability against overcurrent, and sufficient protection against overcurrent is required.

  In order to prevent such overcurrent, for example, it is conceivable to suppress the overcurrent by providing a sequence circuit including a delay circuit when the emergency lighting circuit or the constant lighting circuit is switched. However, such an operation sequence has a problem that the configuration becomes complicated.

  The problem to be solved by the present invention is to provide an emergency lighting device capable of reliably protecting a light emitting element.

  The emergency lighting device according to the embodiment includes a constant lighting circuit that turns on the light emitting element with the external power supply when the external power supply is not powered. The emergency lighting device has a backup power source. Furthermore, this emergency lighting device has an emergency lighting circuit for lighting the light emitting element with a backup power source in the event of a power failure of the external power source. In addition, this emergency lighting device is connected so that the lighting circuit is always connected to the light emitting element when the external power source is not powered and the emergency lighting circuit is connected to the light emitting element when the external power source is powered down. Part. The emergency lighting device includes an overcurrent limiting circuit that limits an overcurrent flowing through the light emitting element when the switching unit switches the connection of the light emitting element from the always-on lighting circuit to the emergency lighting circuit.

  According to the present invention, the overcurrent flowing through the light emitting element is limited by the overcurrent limiting circuit when the switching unit switches the connection of the light emitting element from the constant lighting circuit to the emergency lighting circuit. It can be expected to protect.

It is a block diagram which shows the emergency lighting device of one Embodiment.

  The configuration of one embodiment will be described below with reference to FIG.

  In FIG. 1, 11 is an emergency lighting device, and this emergency lighting device 11 is used for an emergency instrument such as a guide light or an emergency light.

  The emergency lighting device 11 has a light emitting element 12 detachable, and a power supply unit as a constant lighting circuit for lighting the light emitting element 12 when an external power source e such as a commercial power source (commercial AC power source) is not powered. 13, a battery B as a backup power source, and an emergency light unit 14 as an emergency circuit for lighting the light emitting element 12 in the event of a power failure of the external power source e.

  The light emitting element 12 is, for example, an LED light source, and is configured by connecting a plurality of elements, LEDs 16, in series. The light emitting element 12 can be attached to and detached from the emergency equipment (the power supply unit 13 and the emergency light unit 14) via the socket 17.

  The battery B is a battery pack in which a plurality of DC power supplies are connected in series, and has a capacity capable of maintaining the lighting state of the light emitting element 12 (LED 16) with a predetermined light flux for a predetermined time during a power failure of the external power source e. doing.

  Further, the power supply unit 13 turns on the light emitting element 12 (LED 16) by the external power source e when the external power source e is not powered down. The power supply unit 13 can have any circuit configuration as long as the light emitting element 12 (LED 16) can be lit with a predetermined light flux by the external power source e. For example, a microcomputer as a control means (not shown) can be used. It is controlled by the lighting control circuit provided, and is configured to output a constant current for lighting the light emitting element 12 (LED 16). Further, the power supply unit 13 is electrically connected to the external power source e through a power switch SW1 and an inspection switch SW2 as inspection switching means.

  The power switch SW1 is installed on, for example, a wall surface, and is manually operated to switch on / off the light emitting element 12 (LED 16).

  The inspection switch SW2 is used when inspecting the charging state and life of the battery B. Specifically, the inspection switch SW2 is a normally closed switch, and is electrically disconnected from the external power source e, the power source unit 13, and the emergency light unit 14 by being opened when the battery B is inspected, and is simulated. A power failure state is created, and the light-emitting element 12 (LED 16) is lit by the emergency light unit 14 by the battery B, so that it can be inspected whether the light-emitting element 12 (LED 16) is lit for a predetermined time while maintaining a predetermined luminous flux. It is configured.

  The emergency light unit 14 has an input side circuit 21 electrically connected to the external power source e via the inspection switch SW2, and a state of the external power source e electrically connected to the input side circuit 21, that is, A power supply monitoring circuit 22 that monitors power outages and non-power outages, a charging circuit 23 that is electrically connected to the power supply monitoring circuit 22 and charges the battery B, and a light emitting element that is electrically connected to the charging circuit 23 12 includes an emergency lighting circuit 24 for lighting 12 and a relay Ry as a switching unit for selectively electrically connecting one of the emergency lighting circuit 24 and the power supply unit 13 to the light emitting element 12. ing. For example, a smoothing capacitor is connected between the power supply monitoring circuit 22 and the charging circuit 23 (not shown).

  Although not shown, the input side circuit 21 includes, for example, a filter circuit (noise prevention circuit) that removes noise from the external power source e side, and a rectifier circuit that rectifies the external power source e (full wave).

  The charging circuit 23 is configured to charge the battery B with the external power source e.

  The emergency lighting circuit 24 turns on the light emitting element 12 (LED 16) using the battery B as a power source in the event of a power failure of the external power source e. The emergency lighting circuit 24 can have any circuit configuration as long as the battery B can light the light emitting element 12 (LED 16) with a predetermined light flux for a predetermined time or longer. Be controlled.

  Specifically, the emergency lighting circuit 24 includes, on the output side, a series circuit 27 of a resistor R1 as a plurality of impedance elements and a Zener diode ZD as a constant voltage element, and an overcurrent flowing through the light emitting element 12 (LED 16). And an overcurrent limiting circuit 28 for limiting the current.

  The series circuit 27 is electrically connected in parallel to the relay Ry (light emitting element 12) in a state where the emergency lighting circuit 24 is electrically connected to the light emitting element 12 by the relay Ry.

  Further, the overcurrent limiting circuit 28 includes an FET Q1 as a (first) switching element and, for example, an NPN transistor Q2 as a (second) switching element and a detection resistor R2 constituting the switch unit 29. The FET Q1 forms a series circuit with the detection resistor R2 and is electrically connected in series with the relay Ry. The gate terminal, which is the control terminal of the FET Q1, is electrically connected to the connection point between the resistor R1 and the cathode of the Zener diode ZD. Further, the transistor Q2 has a collector terminal electrically connected to the gate terminal of the FET Q1, a base terminal electrically connected to a connection point between the FET Q1 and the detection resistor R2, and an emitter terminal connected to the detection resistor R2 and the Zener. It is electrically connected to the anode of the diode ZD. Therefore, the detection resistor R2 is connected between the base terminal and the emitter terminal of the transistor Q2, and the gate potential of the FET Q1 is set to a predetermined constant voltage by the Zener diode ZD.

  In the emergency lighting circuit 24, when the light emitting element 12 is removed from the socket 17 (the light emitting element 12 is removed), the overcurrent limiting circuit 28 is opened, and a constant voltage (open voltage) is applied across the series circuit 27. ), And in a state where the light emitting element 12 is connected to the socket 17 (attached state of the light emitting element 12), the light emitting element 12, the FET Q1, and the detection resistor R2 are electrically connected to the series circuit 27. A constant current for turning on the light emitting element 12 (LED 16) is supplied by forming a parallel series circuit.

  The relay Ry is a so-called 2c contact type having two-pole switching contacts Ry1 and Ry2, and a power source unit 13 and an emergency lighting circuit 24 (emergency light unit 14) are connected to the light emitting element 12. Either one can be selectively switched. Further, the relay Ry has, for example, a coil electrically connected to the lighting control circuit, and when the power supply monitoring circuit 22 detects a power failure of the external power source e, the coil is energized and the switching contacts Ry1 and Ry2 operate. Is set to Specifically, in this embodiment, the relay Ry is in a state in which the power supply unit 13 is connected to the light emitting element 12 when the external power source e is in a non-power failure state. The emergency lighting circuit 24 (emergency light unit 14) is connected to 12.

  Next, the operation of the one embodiment will be described.

  In a state where the power switch SW1 is turned on and the external power source e is supplied, that is, when there is no power failure, the external power source e supplies power to the power unit 13 and the lighting control circuit, and the power unit 13 whose operation is controlled by the lighting control circuit. Thus, a constant current is supplied to the light emitting element 12 (LED 16), and the light emitting element 12 (LED 16) is lit with a predetermined light flux (normal lighting). In the emergency light unit 14, the external power source e removes noise such as high-frequency components by the input side circuit 21 and is rectified, smoothed by a capacitor, and supplied to the charging circuit 23. Charge.

  On the other hand, when the external power source e fails, that is, when the power source monitoring circuit 22 detects a power failure of the external power source e, the lighting control circuit switches the switching contacts Ry1 and Ry2 of the relay Ry (shown by the imaginary line in the figure), and the light emission For the element 12, the connection is switched from the power supply unit 13 to the emergency lighting circuit 24 (emergency light unit 14). The battery B supplies power to the emergency lighting circuit 24 and the lighting control circuit, and the emergency lighting circuit 24 whose operation is controlled by the lighting control circuit supplies a constant current to the light emitting element 12 (LED 16). The element 12 (LED 16) is turned on with a predetermined luminous flux (emergency lighting). The current for lighting the light emitting element 12 (LED 16) has a potential difference less than a potential difference (for example, 0.7 V) corresponding to a predetermined ON voltage between both ends of the detection resistor R2, that is, between the base terminal and the emitter terminal of the transistor Q2. The transistor Q2 is in an off state because of the extent of generation. Therefore, when the light emitting element 12 (LED 16) is lit, the gate potential of the FET Q1 is set to a predetermined constant potential by the Zener diode ZD, and the FET Q1 is turned on.

  Here, when the connection from the power supply unit 13 to the emergency lighting circuit 24 (emergency light unit 14) is switched with respect to the light emitting element 12 by the switching contacts Ry1 and Ry2 of the relay Ry, the emergency lighting circuit 24 ( When the load changes suddenly as viewed from the emergency light unit 14 side, that is, it becomes lighter instantaneously, an overcurrent of about several A is generated. At this time, in the overcurrent limiting circuit 28, when this overcurrent flows through the detection resistor R2, a potential difference corresponding to a predetermined ON voltage (for example, between the both ends of the detection resistor R2, that is, between the base terminal and the emitter terminal of the transistor Q2) When a potential difference of 0.7V or more is generated, a base current flows and the transistor Q2 is immediately turned on to short-circuit the gate potential of the FET Q1. That is, in the switch unit 29, the switching operations of the FET Q1 and the transistor Q2 are switched from the normal lighting state. As a result, the FET Q1 is turned off, the light emitting element 12 is opened to the emergency lighting circuit 24, and the overcurrent flowing through the light emitting element 12 is blocked (limited).

  In addition, during emergency lighting, for example, when the light emitting element 12 is once removed from the socket 17 and remounted, the load is momentarily reduced as viewed from the emergency lighting circuit 24 (emergency light unit 14) side. An electric current is generated. For this reason, the overcurrent limiting circuit 28 performs the same protection operation as described above to prevent (limit) the overcurrent.

  According to the embodiment described above, the overcurrent flowing through the light emitting element 12 when the connection is switched from the power supply unit 13 to the emergency lighting circuit 24 with respect to the light emitting element 12 by the relay Ry is caused by the overcurrent limiting circuit 28. Thus, the light emitting element 12 having low durability against overcurrent can be reliably protected.

  Specifically, the overcurrent limiting circuit 28 includes a detection resistor R2 that detects a current flowing through the light emitting element 12 connected to the emergency lighting circuit 24, and the magnitude of the current flowing through the detection resistor R2 is a predetermined value or more. When switching operation of FETQ1 and transistor Q2 of the switch unit 29 is sometimes switched, the light emitting element 12 is opened to the emergency lighting circuit 24 and the overcurrent is prevented. Can be reliably protected against.

  That is, by providing the above-described overcurrent limiting circuit 28, for example, a general operation sequence such as stopping the operation of the power supply unit after the light emitting element is turned on by the emergency lighting circuit so as not to cause overcurrent, and A configuration that can reliably protect the light emitting element 12 against an overcurrent can be easily realized without performing complicated design changes such as performing different operation sequences.

  In addition, after the light emitting element 12 is detached from the emergency lighting circuit 24, the light emitting element 12 is once removed in a state where the emergency lighting circuit 24 is connected to the light emitting element 12 (emergency lighting state). The overcurrent flowing when reattached can be limited by the overcurrent limiting circuit 28, and the socket 17 is not damaged by the overcurrent.

Since the overcurrent limiting circuit 28 is provided, overcurrent is unlikely to occur even when the open voltage (voltage across the series circuit 27) is relatively high as the emergency light unit 14 (emergency lighting circuit 24). Thus, a design with a high open-circuit voltage is possible. Therefore, a design that is less dependent on the voltage drop (V _f ) of the light emitting element 12 (LED 16), in other words, a design corresponding to various light emitting elements 12 having different voltage drops is facilitated.

  In the embodiment described above, the light emitting element 12 has a plurality of LEDs 16 connected in series. However, for example, one LED 16 may be used.

  Further, the light emitting element 12 may not necessarily be detachable from the emergency lighting circuit 24.

  Further, as the light emitting element 12, an organic EL or an inorganic EL may be used instead of the LED.

  And although one Embodiment of this invention was described, this embodiment is shown as an example and is not intending limiting the range of invention. The novel embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. This embodiment and its modifications are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

11 Emergency lighting device
12 Light emitting element
13 Power supply unit as a constant lighting circuit
24 Emergency lighting circuit
28 Overcurrent limit circuit
29 Switch B Battery for backup power e External power
R2 sense resistor
Relay as Ry switching part

Claims (3)

A constant lighting circuit that turns on the light emitting element with the external power supply when the external power supply is not powered;
With backup power supply;
An emergency lighting circuit that turns on the light-emitting element with a backup power supply in the event of a power failure of the external power supply;
A switching unit that is connected to the light emitting element when the external power supply is not interrupted, and that is switched to connect the emergency lighting circuit to the light emitting element when the external power supply is interrupted;
An overcurrent limiting circuit for limiting an overcurrent flowing through the light emitting element when the switching unit switches the connection from the constant lighting circuit to the emergency lighting circuit for the light emitting element;
An emergency lighting device comprising: The overcurrent limit circuit is
A detection resistor for detecting a current flowing in the light emitting element connected to the emergency lighting circuit;
A switch unit that prevents overcurrent by opening the light emitting element to the emergency lighting circuit by switching the switch operation when the magnitude of the current flowing through the detection resistor is a predetermined value or more. The emergency lighting device according to claim 1. The emergency lighting device according to claim 1 or 2, wherein the light emitting element is detachable from at least the emergency lighting circuit.

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