KR101364252B1 - Power supply circuit for LED leading lights - Google Patents

Abstract

The present invention is to provide a power supply circuit such as an LED induction lamp that is provided with its own charging circuit to prepare for power outage and maintain the illuminance of the appropriate line for a predetermined time even during a power outage, which is provided at the input of a commercial AC power source. A power input unit 100; SMPS unit (200,200 ') for receiving the power from the power input unit 100 to output a stable power to the LED induction lamp; A charging circuit unit (300,300 ') for receiving a power supply from the output terminal of the SMPS unit (200, 200') to charge the battery (BT1); And a preliminary power supply unit 400 supplying a preliminary power to the LED induction lamp in case of power failure. And a control unit.

Description

LED induction light power supply circuit {Power supply circuit for LED leading lights}

The present invention relates to a power supply circuit of an LED induction lamp, and more particularly, to an LED induction lamp power supply circuit for maintaining a high illuminance for a predetermined time during a power failure for reasons such as fire.

Recently, due to the rapid development of LED devices, attempts to use LED devices are also underway, and lighting lamps (hereinafter, referred to as 'induction lamps') used in the guidance light of the underground parking lot or the guide plate are in progress. The heat dissipation problem is almost solved.

However, induction lamps must be supplied with power while maintaining proper illuminance for a certain period of time, even in the event of a power outage, and especially in an emergency such as a fire, it is necessary to maintain higher illuminance due to the turn off of smoke or underground lighting. .

The present invention is to solve the above problems of the prior art, an object of the present invention, by providing a self-charging circuit to prepare for power failure, LED induction lamp to make the power supply while maintaining the illuminance of the appropriate line for a certain time even during power failure To provide a power supply circuit.

Moreover, according to another object of the present invention, it is possible to charge a high voltage, but in the event of an emergency such as a fire, it is necessary to maintain a higher illuminance due to the extinguishment of smoke or underground lighting, so when the power outage of commercial power It is to provide a power supply circuit such as an LED induction lamp that can provide high voltage power.

In order to achieve the object of the present invention, the LED induction lamp power supply circuit according to an aspect of the present invention, the power input unit 100 is provided in the input terminal of the commercial AC power; SMPS unit (200,200 ') for receiving the power from the power input unit 100 to output a stable power to the LED induction lamp; A preliminary power supply unit 400 including a battery BT1 for supplying a preliminary power supply to the LED induction lamp in case of power failure; A charging circuit unit (300,300 ') for charging the battery (BT1) by receiving power from an output terminal of the SMPS unit (200, 200'); And a reserve power amplifier 600 amplifying the output power of the reserve power unit 400 in an emergency. And a control unit.

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Preferably, the preliminary power amplifier 600 includes switching elements Q7 to Q8 for converting the control resistance value Req in response to the voltage of the high output driver IC U3 and the control power source C +. In the event of power failure, the switching element Q8 is 'turned on' by the control power source C + to increase the power output to the LED + terminal.

Also preferably, the preliminary power supply abnormality display unit 500 indicating that the preliminary power supply unit 400 operates without abnormalities; And further comprising:

Also preferably, the preliminary power supply unit 400, one side is connected to the control power supply (C +), the other side is connected to the output terminal (LED +) of the LED unit through the backflow prevention diode (D7), the voltage of the control power supply According to the present invention, the mobile terminal is configured to include a switching element (Q4 ~ Q6) for turning on / off the + terminal of the battery.

Also preferably, the DC-DC converter is inserted into the charging circuit unit 300 ′.

Also preferably, an AC power indicator circuit 210 is added to the output of the SMPS unit 200 ′.

As described above, according to the LED induction lamp power supply circuit according to the present invention, by providing a self-charging circuit to prepare for power failure, the power supply of the LED induction lamp to supply power while maintaining the illuminance of the appropriate line for a predetermined time even during a power failure This becomes possible.

Moreover, according to another embodiment of the present invention, by adding a DC-DC converter circuit, charging to a higher voltage is possible.

In addition, according to another embodiment of the present invention, it is possible to provide a higher voltage power in order to maintain a higher illuminance than usual commercial power in an emergency such as a fire.

Other objects and advantages of the present invention in addition to the above object will be apparent from the detailed description of the embodiments with reference to the accompanying drawings.

1 is an external view of a guide plate having an LED induction lamp associated with the present invention.
2 is a cross-sectional view of a guide plate having an LED induction lamp associated with the present invention.
3 is a detailed circuit diagram of the LED induction lamp power supply circuit according to the first embodiment of the present invention.
4 is a detailed circuit diagram of an LED unit connected to the LED induction lamp power supply circuit according to the first embodiment of the present invention.
5 is a detailed circuit diagram of an LED induction lamp power supply circuit according to a second embodiment of the present invention.

Hereinafter, described with reference to the accompanying drawings a preferred embodiment of the present invention.

1 is an external view of a guide plate having an LED induction lamp according to the present invention, FIG. 2 is a cross-sectional view of a guide plate having an LED induction lamp according to the present invention, and FIG. 3 is an LED induction lamp power supply circuit according to a first embodiment of the present invention. 4 is a detailed circuit diagram of an LED unit connected to an LED induction lamp power supply circuit according to a first embodiment of the present invention, and FIG. 5 is a detail of an LED induction lamp power supply circuit according to a second embodiment of the present invention. It is a circuit diagram.

First, with reference to Figs. 1 and 2, a brief description of the guide plate having the LED guidance light according to the present invention, the guide plate 1, such as an apartment parking lot is suspended from the ceiling of the parking lot, etc. by the anchor 2, the apartment Or guide the vehicle or customer visiting the mall or to guide in a certain direction.

More specifically, the guide plate 1 is a light guide plate support 10 for supporting the lighting PC 40 as a light guide plate having a light-transmitting film on the surface, and the light guide plate support 10 is embedded in the light guide plate support 10, It consists of an LED substrate 20 and a plurality of LED induction lamps 30 for supplying light for illumination.

For reference, the light guide plate support 10 fastens the left and right side frames 12 and 12 'with the fastening part 15 such as the upper frame 11 and the fastening bolt, and the anchor 2 is fastened to the upper frame. The power supply circuits such as the circuit board 14, the SMPS unit 18, and the battery 13 are embedded in the space between the left and right side frames 12 and 12 ', and the slider binding groove 17 ) So that the LED substrate 20 is fitted into the slider binding groove 17 by sliding.

Reference numeral 16 denotes an operation indicator light, 15 'is a first auxiliary binding part for supporting a circuit board, 15 "is a second auxiliary binding part for supporting an indicator light, and 17' is a supporting PC auxiliary wing 41 for lighting. It is auxiliary wing binding groove.

Now, an LED induction lamp power supply circuit according to an embodiment of the present invention will be described in detail with reference to FIGS.

(Embodiment 1)

First, the LED induction lamp power supply circuit according to the first embodiment of the present invention, as shown in Figure 1, the power input unit 100 provided in the input terminal of the commercial AC power; SMPS unit 200 for receiving the power from the power input unit 100 to output a stable power to the LED induction lamp; A charging circuit unit 300 for charging the battery BT1 by receiving power supply from the output terminal of the SMPS unit 200; A preliminary power supply unit 400 for charging the battery BT1 by the operation of the charging circuit unit 300 and supplying a preliminary power to the LED during a power failure; A preliminary power supply abnormality display unit 500 indicating that the preliminary power supply unit 400 operates without error; And a reserve power amplifier 600 amplifying the output power of the reserve power unit 400 in an emergency. .

In more detail for each unit, the power input unit 100, the fuse (F1), varistor (VAR1), thermistor (TH1), line filter (L1) and capacitors (C1 ~ C4) located in the AC commercial power supply terminal EMI filter circuit consisting of; And a rectifier circuit composed of the bridge diode BD1 and the smoothing capacitors C5 and C6.

The SMPS unit 200 transfers the high-voltage DC rectified by the power input unit 100 in a switching element Q1 such as a MOSFET to transfer to the high frequency ferrite transformer T1, and transmits the high frequency ferrite transformer T1. The secondary voltage passed to the secondary side is supplied to each LED of the LED unit (L1 to L84 of FIG. 4) through the output circuits D3, D4, and C12 to C15 each consisting of a diode and a smoothing circuit. In this case, one end of the output circuit outputs the control voltage of the control power source C + described later.

On the other hand, according to the change in load, the voltage variation is fed back from the feedback circuits U2, R15 to 18, C11 and input to the INV terminal of the SMPS controller IC U1 through the photocoupler PC1 for isolation from the primary side. The oscillation (approximately 1 MHz) voltage of the changed amplitude according to the variation of the output voltage (secondary side) is switched to the FET switching element Q1. Since the high frequency transformer T1 is connected to the drain terminal of the FET switching element Q1. The voltage induced to the secondary side is output.

The surge voltage suppressor circuits R1, C7, and D1 have been configured since a high voltage surge voltage is generated when the transformer T1 is driven.

The power supply circuits R2, C16, D2, and D8 of the SMPS controller IC U1 are circuits for supplying a power voltage for the operation of the U1. The overvoltage input prevention circuits R2, C16, and D8 and the rectifier circuit D2 are provided. It is supplied as a power source for stable operation of U1.

In addition, since the SMPS unit 200 is not significantly different from the conventional SMPS, a detailed description thereof will be omitted.

Now, the charging circuit unit 300 and the preliminary power supply unit 400 which are the core of the present invention will be described in detail. The charging circuit unit 300 connected to the output circuits D3, D4, and C12 to C15 of the SMPS unit receives the output power rectified by the secondary rectifier circuits D5 and C13 and the battery BT1 of the preliminary power supply unit 400. ) To charge the battery.

The preliminary power supply unit 400 including the battery BT1 has one side connected to the control power source C +, and the other side connected to the output terminal LED + of the LED unit through a backflow prevention diode D7. The switching element Q6 for turning on / off the + terminal of the battery according to the voltage of the power supply (only outputted when the alternating power is applied) and the switching element Q6 is turned on only when the AC power is turned off. It consists of auxiliary circuits (Q4, Q5, R25 ~ R29, C20).

Referring to the operation of the preliminary power supply unit 400,

Usually, since the control power source C + connected to the base of the fourth transistor Q4 is 'high', the fourth transistor Q4 is in an 'on' state, and thus the fifth transistor Q5 is in an 'off' state. As a result, since the sixth MOSFET Q6 is kept in the 'off' state, the + terminal of the battery that has passed the protective fuse (F2) is disconnected from the LED output terminal (in the charged state).

At the time of power failure, since the control power source C + connected to the base of the fourth transistor Q4 is 'low', the fourth transistor Q4 is in an 'off' state, and thus the fifth transistor Q5 is 'on'. Therefore, since the sixth MOSFET Q6 is 'turned on', the terminal of the battery is connected to the LED output terminal, thereby illuminating the LED with the spare power of the battery (discharge state).

On the other hand, the display terminal 500 is connected to the + terminal of the battery BT1, and if the preliminary power supply abnormality display unit 500 is normal, and the battery voltage Vb is 'high', the second transistor Q2 is turned on. 'State, and thus, the third transistor Q3 is' off', and thus the indicator L2 having a standby power abnormality emits light.

However, when the spare power supply is not normal or the battery is completely discharged and the battery voltage Vb is' low ', the second transistor Q2 is in an' off 'state, and thus the third transistor Q3 is' ON ', and thus, the standby power indicator L2 does not emit light.

Finally, the spare power amplifier 600 is described in detail, the switching element Q8 for converting the control resistance value (Req) in response to the high output driver IC (U3) (for example, DW8501) and the control voltage (C +) and This is made up of the additional elements (Q7, R30 ~ R36, C21).

 A resistor R36 (1.3 kΩ, for example) and R34 (2.2 kΩ, for example) are connected in parallel to the Rs terminal of the IC U3, and R34 is again connected in series with the transistor Q8, and the transistor Q8 is It is turned on / off by the control power supply.

Therefore, since the control power source C + connected to the base of the seventh transistor Q7 is 'high' in normal times, the seventh transistor Q7 is in an 'on' state, and thus the eighth MOSFET Q8 is 'off'. As a result, only the resistor R36 is connected to the Rs terminal of the IC U3. For example, a control resistance of only 1.3 kΩ is applied. In this case, only about 60% of the power is finally output to the LED + terminal. Set to output (at low power output state).

However, at the time of power failure, since the control power source C + connected to the base of the seventh transistor Q7 is 'low', the seventh transistor Q7 is in an 'off' state, and thus the eighth MOSFET Q8 is 'turned on'. As a result, a resistor R36 and a resistor R34 are connected in parallel to the Rs terminal of the IC U3, so that the resistance value of the parallel resistor (Req = R36∥R34 = (1.3 * 2.2) / (1.3 + 2.2) = 0.81). In this case, the output current is increased so that 100% of power is finally output to the LED + terminal (high power output state).

This is because most of the other lights go out except the emergency light in the emergency, and even if the power failure for reasons such as fire, because of the smoke or gas, it is necessary to brighten the brightness of the guide plate or induction light.

(Second Embodiment)

Meanwhile, a second embodiment of the present invention will now be described in detail with reference to FIG. 5.

The circuit of the second embodiment differs from the circuit of the first embodiment only in the SMPS portion 200 'and the charging circuit portion 300', the remaining circuit portions are the same, and the SMPS portion 200 'also emits light in the output circuit. Only the addition of the AC power indicator circuit 210 consisting of the diode LD1 and the resistor R37 is different from the case of the first embodiment, and the charging circuit section 300 'also has a DC- between the output circuit of the SMPS section. Since only the point at which the DC converter is inserted is different, only this point will be described, and the remaining circuits are assigned the same member numbers to the devices having the same function, and detailed description thereof will be omitted.

First, the AC power indicator circuits L1 and R37 will be described. If the voltage Va of the output terminal of the output circuit of the SMPS unit is normal (for example, 24V), the green LED indicator connected in series with the resistor R37 will be described. (L1) is to be turned on, and if the AC power supply is abnormal for reasons such as power failure, otherwise the LED indicator (L1) is not lit.

On the other hand, the charging circuit unit 300 'in the second embodiment will be described. As shown in the first embodiment, the charging circuit unit 300' is composed of the rectifying diode D5, the capacitor C13, and the charging resistor R19. The DC-DC converters U4, R39 to R43, L2 and C22 are inserted between the RLC rectifier circuit and the output terminal of the output circuit of the SMPS part. The converter circuit converts the output voltage Va of the SMPS part to the charging circuit voltage Vc. After stepping up (for example, from 24V to 36V), the battery BT1 is charged to a higher voltage battery voltage Vb through the second rectifying circuits D5 and C13 and the charging resistor R19.

The reason for doing this is, for example, that when the output voltage Va is 24V, if the battery is charged as it is, as in the first embodiment, only about 21V is charged. Likewise, if the battery is charged after boosting to 36V, it can be charged up to about 31V.

Although the present invention has been described with reference to the drawings in connection with specific embodiments, these are merely exemplary, and those skilled in the art will understand that various modifications and equivalent embodiments thereof are possible. . Therefore, the true technical protection scope of the present invention will be defined only by the appended claims.

100: power input unit 200,200 ': SMPS unit
300,300 ': charging circuit 400: spare power supply
500: Reserve power abnormality display unit 600: Reserve power amplifier

Claims (7)

A power input unit 100 provided at an input terminal of a commercial AC power source;
SMPS unit (200,200 ') for receiving the power from the power input unit 100 to output a stable power to the LED induction lamp;
A preliminary power supply unit 400 including a battery BT1 for supplying a preliminary power supply to the LED induction lamp in case of power failure;
A charging circuit unit (300,300 ') for charging the battery (BT1) by receiving power from an output terminal of the SMPS unit (200, 200'); And
A reserve power amplifier 600 amplifying the output power of the reserve power supply 400 in an emergency;
LED induction lamp power supply circuit comprising a. delete The method of claim 1,
A preliminary power supply abnormality display unit 500 indicating that the preliminary power supply unit 400 operates without error; LED induction lamp power supply circuit further comprising. The method of claim 1,
The preliminary power supply unit 400, one side is connected to the control power supply (C +), the other side is connected to the output terminal (LED +) of the LED unit through the backflow prevention diode (D7), according to the voltage of the control power supply + An LED induction lamp power supply circuit comprising a switching element (Q4 ~ Q6) for turning on / off the terminal. The method of claim 1,
The preliminary power amplifier 600 includes switching elements Q7 to Q8 for converting the control resistance value Req in response to the voltages of the high output driver IC U3 and the control power source C +. Switching element (Q8) is 'turned on' by the control power (C +) LED induction lamp power supply circuit characterized in that it is made to increase the power output to the LED + terminal. The method of claim 1,
LED charging lamp power supply circuit, characterized in that the DC-DC converter is inserted into the charging circuit unit 300 '. The method of claim 1,
LED power supply circuit, characterized in that the AC power indicator circuit 210 is added to the output of the SMPS unit 200 '.

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