KR100715282B1 - Charging control apparatus of battery for emergency lamp - Google Patents

Abstract

The present invention can be charged by the power supply of a short time between frequent blackouts by adjusting the charging time to prevent accidents that the emergency lighting does not light due to uncharged in emergency, and the product is compact, light weight, low power consumption with a simple configuration It is an object of the present invention to provide a charging control device for an emergency lighting battery that can be used for a long time with a minimum failure rate.

       Emergency lighting, rechargeable battery, charging time, relay, thyristor.

Description

Charging control device of battery for emergency lighting lamps {CHARGING CONTROL APPARATUS OF BATTERY FOR EMERGENCY LAMP}

1 is a detailed circuit diagram illustrating a charging control device for a battery for emergency lighting according to the present invention.

<Explanation of symbols for the main parts of the drawings>

T: Transformer RY: Relay

RY _S : Relay switch IC: Integrated circuit

SCR: Thyristor L1 ~ L3: LED

Q: Transistor BT: Rechargeable Battery

LP: Lamp (Emergency Lighting)

The present invention relates to a charging control device for a battery for emergency lighting, such as installed in the stairs, evacuation passages of apartments or buildings so that safe and smooth evacuation activities in the event of fire, power outage, or other emergency. Regarding the charging control device of the emergency lighting battery that can control the charging time of the built-in rechargeable battery so that it is not possible to light by uncharging when a power failure occurs due to a fire lamp within 48 hours after being discharged due to a power failure. will be.

In general, the light used for stairs and evacuation passages of apartments or buildings uses energy-saving three-wavelength bulbs to save power, but it is expensive, and most of them are turned on for a certain time only when a person passes by using an automatic operation switch of the sensor unit. Have been. However, the sensor lamp is not turned on all the time for 24 hours, which saves electricity. However, the lighting is repeatedly turned on and off, which may cause an evacuation in case of an emergency. In addition, when electricity is cut off due to fire, many people are injured in case of fire because they do not fully play the role of emergency lighting so that people can evacuate safely from stairs or emergency passages in case of emergency. .

In view of this situation, emergency lighting has been developed that lights a lamp with a rechargeable battery during a power failure. That is, emergency lighting, which is provided for safe and smooth evacuation activities and continuous work in case of power failure or other emergency due to fire, is usually equipped with a rechargeable battery secondary battery for emergency use. Therefore, it is usually designed to be turned on through a commercial power source and then switched to an emergency power source to be used as an alternative to the above-described secondary charging battery when the commercial power source is out of power.

Therefore, when a power failure or other emergency occurs due to a fire while the rechargeable battery secondary battery is well charged, the emergency light is turned on by the power of the rechargeable battery, enabling safe and smooth evacuation in an emergency. .

However, these emergency lights are fully lit when they last for more than 20 minutes, and they meet current fire methods that must be recharged within 48 hours. However, most emergency lights, such as fire, are out of power and the rechargeable batteries of emergency lights are discharged. After the wake up within the time that can not be recharged, the emergency light is not lit, the reality is that it is useless. In other words, when a power failure occurs frequently due to the aging of Hanok, Daldongne, or other electrical facilities, the power of the rechargeable battery is discharged by the lighting of the emergency lighting caused by the first blackout, and the power is recharged when the rechargeable battery is not charged again. In this case, since the rechargeable battery does not turn on the emergency light, the problem occurs that the emergency light does not function at all in an emergency situation.

In general, since charging of the rechargeable battery takes a long time of 12 to 15 hours, the rechargeable battery is well charged only when the commercial power is stably supplied to the rechargeable battery during this time. However, not only are the risks of an emergency occurring in each business, home or factory that uses emergency lighting, but also the frequency of power outages caused by the emergency is different. It is necessary to adjust the charging time of the rechargeable battery because the emergency lighting cannot be turned on due to the occurrence of a power outage due to various emergencies such as fire or other factors when the charging battery of the emergency lamp is not charged. .

Therefore, the present invention has been made in order to solve the problems occurring in the use of the conventional general emergency lighting, the object of the present invention is that the emergency lighting does not light due to the non-charging of the rechargeable battery in the emergency to turn on the emergency lighting. An object of the present invention is to provide a charging control device for an emergency lighting battery that can prevent accidents.

Another object of the present invention is to provide a charge control device for an emergency lighting battery that can easily charge a rechargeable battery in a place where a power failure occurs frequently by adjusting the charging time of the rechargeable battery to correspond to the chargeable time according to the electrostatic environment. It is.

Still another object of the present invention is to provide a charging control apparatus for a battery for emergency lighting, which can be used semi-permanently for a long time by simplifying circuit configuration, reducing unnecessary power consumption and minimizing failure rate while reducing the size and weight of a product.

In order to achieve the above object, the charging control device for an emergency lighting battery of the present invention includes: a transformer (T) for converting an AC power source connected to an input terminal of a supply power source; Diodes D1 and D2 for rectifying the AC power converted by the transformer T; Connected to the cathode connection points of the diodes D1 and D2 through a relay switch RYS and connected to a charge battery BT charged by a charge current output from the diodes D1 and D2 and to an input terminal of a supply power source. A relay RY for intermittently operating the movable contact of the relay switch RYS when the charging battery BT is fully charged or not charged; An integrated circuit (IC) connected to the cathode connection points of the diodes (D1 and D2) through a diode (D3) and a capacitor (C2) to receive an operating power and adjust a charging current; When the charging of the battery BT is completed and the non-charging time is turned on by the current flowing through the resistor R10 by the control of the variable resistor VR output from the integrated circuit IC, the integrated circuit IC is turned on. Resistance of the LED L1 indicating completion of charging and non-charging of the battery BT and a charge control signal output from the integrated circuit IC at the completion of charging and non-charging of the battery BT. A transistor (Q) for receiving a bias voltage through the base (R4, R6, R7) and conducting it to bypass the charging current to ground; LED L2 connected to the collector and emitting light through the resistor R11 at the cathode connection point of the diodes D1 and D2 when the transistor Q is connected, and a charging current when the transistor Q is connected. Is at a predetermined level or more, the cathode is grounded to bypass the charging current of a predetermined level or more to ground, and the gate is connected to the cathode connection point of the diodes D1 and D2 via a resistor R9 and a zener diode ZD. A thyristor (SCR) connected to the transistor (Q) and the LED (L3) which emits light when the thyristor (SCR) is connected to indicate that a charging current of a predetermined level or more is bypassed to ground. It is characterized by consisting of).

In the drawings, reference numeral LP denotes an emergency lighting lamp which is lit according to the switching on of the on / off switch S at the time of power failure, F denotes a fuse, and S denotes a switch for turning on / off the emergency lighting LP.

Hereinafter, the emergency lighting of the present invention will be described in detail with reference to the accompanying drawings.

1 is a detailed circuit diagram showing a charging control device for an emergency lighting battery according to an embodiment of the present invention, the charging control device for an emergency lighting battery of the present invention 110/110 to the input terminal to which the AC power (AC) is applied. The primary side of the transformer (T) which can be used as a 220V power supply is connected, and the relay (RY) is connected, and one end of the resistor (R1) is connected to the relay (RY) and the other end is connected to the ground terminal, respectively. have.

In addition, the secondary side of the transformer T is connected to the cathodes of the diodes D1 and D2, and the diode D3, the resistor R2, and the capacitor C2 are connected to a connection point where the cathodes of the diodes D1 and D2 are connected to each other. One end of the integrated circuit IC is connected to each other, a capacitor C1 and a resistor R3 are connected between the connection point of the resistor R2 and the capacitor C2 and the ground terminal, respectively, and the capacitor C2 is connected to each other. ) And a resistor R5 are connected between the connection point of the integrated circuit IC and the ground terminal.

Meanwhile, one end of the resistor R4 and the resistor R8 are connected to one end of the integrated circuit IC, and the other end of the resistor R4 is connected to the base of the transistor Q through the resistor R6 and the resistor R7. The other end of the resistor R8 is connected to the integrated circuit IC through the variable resistor VR and the capacitor C3, respectively.

In addition, the connection point of the capacitor C3 and the integrated circuit IC is connected to the collector of the transistor Q through a resistor R10 and to the anode of the LED L1, and the cathode of the LED L1 is grounded. It is connected to the stage.

The gate of the thyristor SCR is connected to the cathode connection point of the diodes D1 and D2 through the resistor R9 and the zener diode ZD, and the transistor Q of the transistor Q is connected through the resistor R11 and the LED L2. The collector is connected, the anode of the thyristor SCR is connected to the connection point of the resistor R11 and the LED L2 through the LED L3, and the cathode of the thyristor SCR is connected to the ground terminal. diodes (D1, D2) emergency lighting lamp (LP) via a relay switch (RY _S) and the emergency lighting switch (S) with a through a relay switch (RY _S) charging the battery (BT) is connected to a cathode connection point of the It is connected.

According to the present invention configured as described above, when the relay RY is operated by the supplied AC power source AC, the movable contact a and the fixed contact b of the relay switch RY _S are connected, and the integrated circuit IC is connected. A bias voltage is applied from the resistors R4, R6, and R7 to the base of the transistor Q, and the transistor Q is turned on, so that the constant current outputted through the diodes D1 and D2 is divided to relay switch RY _S. At the same time as being applied to the charge battery (BT) through the resistor (R11) is charged with the charge battery (BT). In this case, since the current flowing through the resistor R11 flows to the ground through the LED L2 and the transistor Q, the LED L2 emits light to indicate that the charging battery BT is being charged.

When the variable resistor VR is adjusted when the charging battery BT is charged, the current applied from the integrated circuit IC to the collector of the transistor Q is adjusted. That is, when the amount of current applied from the integrated circuit IC to the collector of the transistor Q increases, the current flowing through the resistor R11 to the transistor Q decreases, and the current applied to the charging battery BT is decreased. As a result, the charging time of the charging battery BT is shortened.

Here, the variable resistor VR may change the resistance value in 10 steps to adjust the amount of current applied from the integrated circuit IC to the collector of the transistor Q in a maximum and a minimum of 10 steps, and the LED L1 is charged. This indicates the charging speed of the battery BT. For example, when the battery charges at the fastest speed and the time required for charging is minimized, the battery blinks quickly. When the battery charge time is normal, the battery speed is usually fast. Blinking, and if the charging time is the slowest and the time required for charging is maximized, it blinks the slowest to indicate the charging state of the charging battery BT.

As described above, when the charging battery BT is charged and fully charged, the voltage applied from the cathode connection point of the diodes D1 and D2 to the emitter of the transistor Q is passed through the resistor R11 and the LED L2. It becomes equal to the voltage of BT, and at this time, since the bias voltage is not applied from the integrated circuit IC to the base of the transistor Q, the transistor Q is turned off, and from the integrated circuit IC to the transistor ( Since no current is applied to the collector and LED L1 of Q), the LEDs L1 and L2 are turned off to indicate that the charging battery BT is not being charged.

At the same time, the trigger signal is applied to the gate of the thyristor SCR through the resistor R9 and the zener diode ZD to conduct the thyristor SCR, and the cathode of the thyristor SCR through the resistor R11 and the LED L3. Since the current flows in the LED (L3) is turned on to indicate the fully charged state of the charge battery (BT).

When a power failure occurs due to an emergency such as a fire or other causes, the AC power AC is not applied to the relay RY, and thus the relay RY does not operate. Accordingly, the operation of the relay switch RY _S is performed. Since (a) is connected to the fixed contact point (c), the power supply of the charging battery BT is applied to the lamp LP, which is the emergency light, through the switch S, the emergency light LP is turned on, and the emergency light LP If no lighting is required, the switch S is turned off to turn off the emergency lighting LP.

As described above, the charging control device for the emergency lighting battery of the present invention can adjust the charging time according to the chargeable time of the rechargeable battery. Even if it is possible to turn on the emergency lighting by good charging of the rechargeable battery has the advantage of safe and smooth evacuation activities.

In addition, the present invention is to prevent accidents in which the emergency lighting does not light due to the uncharged battery in emergency situations in which emergency lighting should be turned on even when used in places where power failure occurs frequently due to the aging of Hanok, Daldongne or electric facilities. Not only can the charging time of the rechargeable battery be adjusted to correspond to the chargeable time according to the power failure environment, the rechargeable battery can be easily charged even in the case of frequent blackouts, and the circuit configuration is simplified to make the product small. In addition, it has the advantage that it can be used semi-permanently for a long time by reducing the weight consumption while minimizing unnecessary power consumption and minimizing the failure rate.

Claims (2)

A transformer (T) connected to the input terminal of the supply power and converting the input AC power; Diodes D1 and D2 for rectifying the AC power converted by the transformer T; Connected to the cathode connection points of the diodes D1 and D2 through a relay switch RYS and connected to a charge battery BT charged by a charge current output from the diodes D1 and D2 and to an input terminal of a supply power source. A relay RY for intermittently operating the movable contact of the relay switch RYS when the charging battery BT is fully charged or not charged; An integrated circuit (IC) connected to the cathode connection points of the diodes (D1 and D2) through a diode (D3) and a capacitor (C2) to receive an operating power and adjust a charging current; When the charging of the battery BT is completed and the non-charging time is turned on by the current flowing through the resistor R10 by the control of the variable resistor VR output from the integrated circuit IC, the integrated circuit IC is turned on. Resistance of the LED L1 indicating completion of charging and non-charging of the battery BT and a charge control signal output from the integrated circuit IC at the completion of charging and non-charging of the battery BT. A transistor (Q) for receiving a bias voltage through the base (R4, R6, R7) and conducting it to bypass the charging current to ground; LED L2 connected to the collector and emitting light through the resistor R11 at the cathode connection point of the diodes D1 and D2 when the transistor Q is connected, and a charging current when the transistor Q is connected. Is at a predetermined level or more, the cathode is grounded to bypass the charging current of a predetermined level or more to ground, and the gate is connected to the cathode connection point of the diodes D1 and D2 via a resistor R9 and a zener diode ZD. A thyristor (SCR) connected to the transistor (Q) and the LED (L3) which emits light when the thyristor (SCR) is connected to indicate that a charging current of a predetermined level or more is bypassed to ground. Charge control device for an emergency light battery, characterized in that consisting of. The apparatus of claim 1, wherein the time required for charging the charging battery BT is adjusted by adjusting the resistance value of the variable resistor VR.

Images