KR910001947Y1 - Discharge lamp apparatus with ac and de power - Google Patents

Abstract

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Description

Fluorescent lamp lighting circuit for AC and DC

1 is a block diagram of a fluorescent lamp lighting circuit for both alternating current and direct current.

2 is a circuit diagram of the present invention.

3 is a conventional circuit diagram.

The present invention relates to a fluorescent lamp lighting circuit that is used for both AC and DC. If the AC power is cut off while the power is used as AC power, the DC power charged in the charging battery inside the circuit The circuit is designed to turn on a fluorescent lamp, and this circuit is particularly related to an alternating current and direct current fluorescent lamp lighting circuit which is used for evacuation induction lamps of buildings and can also be used for emergency or outdoor use.

In the lighting of fluorescent lamps, the fluorescent lamps are usually turned on by using an AC power source and charged using a battery (nickel cadmium battery) that can be charged at the same time. To turn on the fluorescent lamp.

In other words, in the proper circuit arrangement of the electrical and electronic components, it can be used for evacuation induction lighting, emergency outdoor use of buildings.

In the conventional alternating current and direct current fluorescent lamp lighting circuit configured to achieve such a function, the lamp is lit with a current consumption of 1400 mA or more at a voltage of 7.2 V to light a fluorescent lamp of about 20 W.

In particular, only one transistor is used in the oscillation unit, so it is not possible to obtain stable current, and to turn on the fluorescent lamp only when a high voltage and current flows. It is relatively low as compared to.

Due to this problem, it is possible to turn on using a rechargeable battery (Nickel Cadmium battery is mainly used) that has a relatively expensive voltage of about 7.2V. It is.

The purpose of the present invention is to construct a fluorescent lamp lighting circuit for both AC and DC, which enables the battery to be lit under a low voltage of about 5V and to use a battery having a relatively low voltage of about 6V. In this state, the circuit is stabilized so that continuous charging and discharging can be achieved, and high illuminance and luminous flux ratio can be obtained even at low voltage and low current.

When described in detail with reference to the accompanying drawings the configuration capable of elevating the purpose of the present invention is as follows.

The power supply unit 1 having the rectifying diodes D ₁ (D ₂ ) and the battery monitoring unit 2 having the battery BA connected to the light emitting diodes LED have an oscillation transformer T ₂ and a fluorescent lamp FL-20. In an alternating current (DC) fluorescent lamp lighting circuit connected to an oscillator (3) consisting of a transistor (Q ₂ ), the secondary coil of the power supply (1) transformer (T ₁ ) and the emitter connected to one end of the battery (BA) are connected to each other. Each collector side of Q ₃ ) is connected to the primary coil L ₁ of the oscillation transformer T ₂ , and their respective bases are connected to the oscillation transformer T ₂ through resistors R ₆ and R ₅ . And one end of the ring coil Lx connected to the relay Ry ₁ at the same time as the primary side coil L ₁ , and the base side of the transistor Q ₂ and Q ₃ is oscillated transformer T ₂ ) Connect directly to the primary side coil (L ₁ ) and _one end (b ₁ ) of the secondary side coil (L ₃ ) of the oscillation transformer (T ₂ ) to the relay (Ry ₃ ) through the collector (C ₄ ) its other end ₍₃ b) is con Standing (C ₅₎ a through glue starter (Gs) and the fluorescent lamp (FL-20), and connected to, its center tap (b ₂₎ is described in detail with the subject innovation action and advantage as consisting hayeoseo directly connected to the relay (Ry ₂₎ Is as follows.

In the figure, these description symbols F ₁ , F ₂ fuses, CH is a ballast, S is a switch.

The AC power is applied to the primary side of the transformer (T ₁₎ transformer (T ₁₎ it becomes the voltage of AC 14V occurs on the secondary side of the rectifier onions them with a diode (D ₁₎ (D ₂₎ the rectified voltage The battery BA is charged by adjusting the current with the charging resistor R ₁ through the diode D ₃ .

In addition, the rectified voltage is applied to the relay Ry through the diode D ₄ to operate the relay Ry. When the relay Ry is operated, the AC power is connected to the relay Ry ₂ (Ry ₃ ), respectively, and the fluorescent lamp (FL-20) lights up.

The DC power monitoring device turns on the LED when the battery (BA) cannot be charged, when the battery (BA) is not available, when the fuse is disconnected, or when the specified voltage is not reached, and the charging resistance (R ₁ ) and the resistance (R) when the AC power is supplied. ₃ ) Since the voltage input through the zener diode (ZD) does not trigger the transistor (Q ₁ ), the light emitting diode (LED) is turned on through the resistors (R ₁ ) and (R ₂ ), respectively.

However, when the battery BA is charged and the DC voltage is sufficiently high, the transistor Q ₁ is triggered by applying the t voltage to the base of the transistor Q ₁ through the resistor R ₃ and the zener diode ZD. When (Q ₁ ) is triggered, the power that flowed to the light emitting diode (LED) through the resistor (R ₃ ) flows to the transistor (Q ₁ ), so the light emitting diode (LED), which is a battery (BA) monitoring device, is turned off and the battery (BA) ), The light emitting diode (LED), which is a monitoring device of the battery (BA), lights up when the battery is not charged, the fuse is disconnected, and the specified voltage is missed.

When AC power is cut off, the fluorescent lamp (FL-20) is turned on by battery (BA) .When AC power is cut off, the relay (Ry) stops working and returns to its original state.When the relay (Ry) is restored, the next relay ( The voltage of the battery BA is applied to the oscillation part 3 by the contact of Ry ₁ ).

At this time, when the battery (BA) voltage is applied to the oscillator (3), the (+) power supply through the ring coil (LX) passes through the resistors (R ₅ ) and (R ₆ ) to the transistors (Q ₂ ) and (Q ₃ ). When applied, transistors Q ₂ and Q ₃ are alternately turned on.

The coil L ₂ connected to the bases of the transistors Q ₂ and Q ₃ is connected to the oscillation transformer T ₂ so that a positive electrode is applied to the base of the transistor Q ₂ . ) polarity is applied, and to turn on the transistor (Q ₂₎ transistors (Q _2), the coil at the time of turn-on (L _1, a) (on-coil) electrode is applied so (L ₂ Q (the base of ₃₎ ) Will reverse the polarity.

Therefore, a positive (+) pole is applied to the coil (L ₂ a) to turn on the transistor (Q ₃ ), and a negative (-) pole is applied to the coil (L ₂ b) to turn off the transistor (Q ₂ ). The transistors Q ₂ and Q ₃ are alternately triggered in succession with each other repeatedly.

At this time, the suppression of the (+) pole is applied to the oscillation transformer (T ₂ ) through the ring coil (Lx), and the transistor (Q ₂ ) and (Q ₃ ) are alternately triggered repeatedly so that the (-) pole voltage alternately oscillates. trans soon as is applied to the (T ₂₎ at the same time, the oscillating voltage is remarkably a frequency of about 20KHZ so that the voltage ttuin the frequency of 20KHZ applied to the oscillation transformer (T ₂₎ the oscillation transformer of about 300V for about the secondary side coils of the (T ₂₎ Voltage is generated.

That is, when applying a voltage of 6V to the primary coil (L ₁₎ in the secondary coil (L ₃₎ to an AC voltage of about 300V occurs. The generated voltage is applied to the fluorescent lamp FL-20 through the relay Ry ₂ (Ry ₃ ) via the capacitors C ₄ and C ₅ and is turned on instantaneously.

When the fluorescent lamp is turned on, the capacitor (C ₅ ) acts as a stabilizer so that a stable voltage is applied to the fluorescent lamp (FL-20), and the battery is turned on until the battery (BA) is consumed. -20) turns on and the battery is charged and the fluorescent lamp (FL-20) turns on as the battery (BA) is repeatedly charged and discharged according to the AC power input.

As described above, the circuit of the present invention can be turned on even under low voltage, and the current consumption is 1400mAh or less while using a rechargeable battery such as a nickel-cadmium battery for 6V. In addition, the ratio of luminous flux of more than 36% can be obtained, and the circuit is stabilized to prolong the life of the parts and lower the voltage of the battery.

Claims (1)

The power supply unit 1 having the rectifying diodes D ₁ (D ₂ ) and the battery monitoring unit 2 having the battery BA connected to the light emitting diodes LED have an oscillation transformer T ₂ and a fluorescent lamp FL-20. In the alternating current (DC) fluorescent lamp lighting circuit connected to the oscillation unit (3) consisting of a transistor (Q ₂ ) is connected to the secondary coil of the power supply (1) transformer (T ₁ ) and the emitter connected to one end of the battery (BA) Each collector side of Q ₃ ) is connected to the primary coil L ₁ of the oscillation transformer T ₂ , and their respective bases are connected to the oscillation transformer T ₂ through resistors R ₆ and R ₅ . And one end of the ring coil Lx connected to the relay Ry ₁ at the same time as the primary side coil L ₁ , and the base side of the transistor Q ₂ and Q ₃ is oscillated transformer T ₂₎ directly connected to the primary coil (L ₂₎ of the one end of the secondary coil (L ₃₎ of the oscillating transformer (T ₂₎ (b ₁₎ is via a capacitor (C ₄₎ connected to a relay (Ry ₃₎ and its other end ₍₃ b) is Condenser (C ₅₎ via glue starter (GS) and a fluorescent lamp and connected to the (FL-20), its center tap (b ₂₎ is a relay (Ry ₂₎ directly to hayeoseo consisting of alternating current (AC) and direct current (DC) Combine the Fluorescent lamp lighting circuit.