KR940001185B1 - Electronic stabilizer to control a large number of fluorescent lamp - Google Patents

Abstract

The stablizer comprises a fuse (F1) preventing the over load; a capacitor (C4) killing the power source noise, and connected with a capacitor (C3); transistors (Q1,Q2,Q3,Q4) whose collectors being connected with the diode (D8,D9,D10) and emitters are connected with the anodes of the diodes (D8,D9,D10); a transformer (T) which provides the feedback current path connected with the transistors (Q1,Q2); heater resonant capacitors (CB1-N); and switches (SW1-N).

Description

Ballast for electronic fluorescent lamps lighting and controlling N (multiple) fluorescent lamps.

1 is a circuit diagram of the present invention.

2 is a switch operation circuit diagram of FIG.

3 is an embedded circuit diagram.

4 is a partial output waveform diagram of the present invention.

5 is a bridge rectification circuit diagram.

6 is a waveform shaping equivalent circuit diagram.

7 and 8 are equivalent circuit diagrams.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electronic fluorescent ballast for lighting and controlling N (multiple) fluorescent lamps that can control lighting of a large number of fluorescent lamps in one place.

Conventional fluorescent ballasts are coiled on silicon steel sheets and can only serve a fixed role, so they cannot actively cope with all adverse conditions such as external input voltage changes, temperature changes, and currents. Due to high energy consumption, it is uneconomical and causes a lot of problems due to high heat generation and excessive noise.In addition, one or two lamps are placed in the lampshade to light up each fluorescent lamp, so a lot of time and expense are required during installation and repair. Since it takes a lot of inconvenience in the actual use as well as the existing fluorescent light emits by the frequency of 60KHZ, there was a problem that eyesight fatigue due to flickering of the lamp is a problem.

The present invention has been invented to solve such a conventional problem, the ballast does not simply turn on the fluorescent lamp, but also controls the fluorescent lamp by itself in the event of abnormal conditions such as overvoltage due to input voltage change, temperature change and circuit failure. The built-in automatic control circuit to enable stable light emission at all times to be concentrated in one place, which will be described in detail with reference to the accompanying drawings.

As shown in FIG. ₁ , the bridge rectifier circuit BD composed of diodes D ₁ , D ₂ , D ₃ , and D ₄ through an overload protection fuse F ₁ and a current damping resistor R ₁ . Connect to the input terminal respectively, and supply both ends of + part (C ⁺ ) and-part (E) of the output terminal to the operating power of the circuit, connect the cathode of diode (D ₅ ) to the point (C ⁺ ) and connect the diode in series. the direction equalize the diode (D ₆₎ (D ₇₎ for connection to (E) delivered leads to the point, and (C ⁺⁾ point and the diode (D ₆₎ and the utilization of flat power between the connection of the (D ₇₎ condenser (C ₂ ) by connecting them in parallel and connecting the electrolytic capacitor (C ₁ ) in parallel between the junction of diode (D ₅ ) and diode (D ₆ ) and the point (E). Reduce the power supply noise by connecting capacitor (C ₃ ) across + part (C ⁺ ) and-part (E), connect collector of transistor (Q ₁ ) to + part (C ⁺ ), and transistor (Q ₁ ) Of The collector of transistor Q ₂ is connected to the emitter and the emitter of transistor Q ₂ is connected to the negative part E. In the same order, the transistors Q ₃ and Q _{4 are} connected to the positive part C. ^A bridge circuit form is formed by connecting in series across both the ⁺ part and the-part (E), and a diode (D ₈ ) (D ₉ ) (is connected to the collector of each transistor (Q ₁ ) (Q ₂ ) (Q ₃ ) (Q ₄ ) Connect the cathodes of D ₁₀ ) (D ₁₁ ) in order and connect the emitters of transistors Q ₁ (Q ₂ ) (Q ₃ ) (Q ₄ ) to diodes (D ₈ ) (D ₉ ) (D ₁₀ ) ( Connect the anode of D ₁₁ ) and protect the transistor from reverse induced voltage, connect the current feedback transformer (T) to the connection point of transistor (Q ₁ ) and transistor (Q ₂ ) and connect one end of it to (F) point. If the connection point of the transistor (Q ₃ ) and the transistor (Q ₄ ) is (G), the heaters H _{1 at} both ends of the current feedback transformer (T _{1 to N} ) fluorescent lamps at both the (F) and (G) points. _{~ N)} for the resonant capacitor _{(C B1 ~ N) (C} A1 ~ N), The position (SW _{1 ~ N)} were connected in series.

The circuit connected in series in the order of F point, T ₁ , L _A1 , H ₁ , CB ₁ , H ₁ , L _B1 , CA ₁ , SW ₁ , and G point is called the first branch, and F point, T ₂ , L _A2 , H ₂ , CB ₂ , H ₂ , L _B2 , CA ₂ , SW ₂ and G are connected in series in the order of the second branch, F point, T _N , L _AN , H _N , CB _N , H _N , L _{When the} N-th branch is connected in series with _BN , CA _N , SW _N , and G points, connect N circuits from the F and G points to the N circuit in parallel with the first circuit. SW _{1 ~ N} ) is configured to allow the current to flow or cut in various ways as the ON-OFF, the operation circuit of the switch (SW ₁ ) is the same as the second figure, each switch of the switch (SW _{1 ~ N} ) Operates on the same principle as (SW ₁ ), with the same circuit consisting of N switches.

Supplying separate operating power (B ⁺ ) to the circuit of FIG. 2 and turning on the switch (SW ₁ ) when magnetic power is generated when the operating power (B ⁺ ) is supplied, and turning off the switch (SW ₁ ) when the operating power is cut off. connecting the coil of the relay (RY ₁₎ having a structure to connect the collector of the transistor (TR ₁₎ to the other terminal of the coil is connected to the emitter of the transistor (TR ₁₎ to the point (E) and the operating power supply (B ⁺ ), Connect the current damping resistor (RA ₁ ), connect the switch (PB ₁ ) that can be turned on and off from the outside at the opposite end, and connect the other end to the base of the transistor (TR ₁ ) to connect the switch (PB ₁ ). When pressed, the transistor TR ₁ is turned on and the operating power is applied to both ends of the relay RY ₁ to turn on the switch SW ₁ to flow a current through the first branch to turn on the fluorescent lamp LP ₁ , and the current to the first branch. When it flows, current is induced in the secondary side (T _S1 ) of the current feedback transformer (T ₁ ) T _S1 ) generates a voltage of V _RA2 = i _{TS1R A2} at both ends of resistor R ₂ connected in parallel at both ends, and one side of (T _S1 ) is connected to the point (E) and the other is diode (D Half-wave rectified by connecting to the anode of _A1 ) and connecting the smoothing capacitor (C _m1 ) between the cathode of diode (D _A1 ) and-(E) point, and LED protection resistor (R _A3 ) and LED ₁ in the forward direction. Connect in series and connect in parallel with capacitor (C _A1 ) to monitor for short circuit, contact failure, overload, etc., and connect current damping resistor (R _A4 ) to cathode of diode (D _A1 ) to connect OP AMP connected to the inverting input terminal and the voltage by connecting a resistor between the OP AMP inverting input terminal and an operating power supply (B ⁺⁾ were connected to a resistance (R ₅₎ between the inverting input terminal of the OP AMP, and (E) point (R ₆₎ based on Supply voltage to the output terminal of the OP AMP by constructing a voltage comparison circuit that compares the magnitude of the non-inverting input voltage Connecting a resistor (R ₇₎ for attenuation and the other end of the SCR gates is connected to the Kane methods by connecting between the cake and the SCR gate Sword (R _A8) and (C _A2) in parallel to the point (E) by connecting the node to the base of the transistor (TR ₁₎ to when the SCR is the oN and OFF the transistor (TR ₁₎ to turn OFF the switch (SW ₁₎ was composed of the protection circuit to shut off power to the lamp, the third In the figure, the circuit configuration is simplified by using a single IC for the circuit in the dotted line, and a separate operation power supply (A ⁺ ) is supplied to pin 12 to supply a static power supply device REF embedded in the IC ₁ . Supply the operating power to all circuits inside 1C ₁ , connect (R ₁₁ ) to pin (6) of IC ₁ , connect it to point (E), and connect (C ₄ ) to pin (5) ( Oscillation frequency of oscillator OSC inside IC ₁ is connected to E) point F _OSC Set the oscillation frequency to 40KHz, connect (R ₁₂ ) to pin 4, connect it to the point (E), and connect (C ₅ ) to pin 4, which is the operating power output of IC ₁ (14) When the power is first supplied by connecting to the burner pin, a voltage inversely proportional to the CR charging voltage of (C ₅ ) (R ₁₂ ) is supplied to the pin (4) so that the output of the internal OP AMP (OP ₁ ) is gradually increased so that the power is turned on. the unit (E) connected to the resistance (R ₂₎ (R ₃₎ between points in series and a resistance (R ₂₎ and the resistor (R ₃₎ - eliminates any possible malfunction has occurred in the initial supply voltage (a ⁺⁾ and between the part (E) point - a connection point 1C ₁ (1) connects to the pin 1C ₁ in the OP AMP (OP ₃₎ a non-set-inverting input voltage and first-degree power supply of + portion (C ⁺⁾ and of Connect resistor (R ₄ ) (R ₅ ) in series, connect resistor (R ₆ ) to the connection point of resistor (R ₄ ) and resistor (R ₅ ), and connect the opposite end to pin (2) of IC ₁ (2) Burn Pin and (3) Burn Pin A (C ₆₎ (C _8), the connection in series, and thereby connecting in parallel (R ₇₎ to the internal IC ₁ OP AMP (OP _3), four standard-setting voltage input (1) pin and the output voltage detection input (2 It is composed of voltage comparator which compares voltage difference between pins.Connect pin (16), which is the non-inverting input terminal of OP AMP (OP ₄ ) inside IC ₁ , to point (E) and inverting input terminal (15) Condenser (C ₇ ) was connected to burner pin (3) and (OP ₄ ) was configured as an integrator, and (R ₉ ) (R ₁₀ ) (C ₈ ) was placed between pin (15) and-(E). Connect in series, connect the cathode of (D ₁ ) to the connection point of (R ₉ ) and (R ₁₀ ), and connect (R ₁ ) between the anode of (D ₁ ) and the point of (E) (R ₁ ) Connect the secondary coil (T _S ) of the current feedback transformer in parallel with the circuit to increase the amount of current induced in (T _S ) when the current suddenly increases due to a fault in the circuit or short circuit. To regulate the supply to protect the circuit Was Castle, the emitter of 9 times (10) the collector outputs of (8 in the connecting pin to the (E) point, and (Q ₅₎ (Q ₆₎ of the IC ₁ inside the transistor (Q ₅₎ (Q ₆₎ of Connect both ends of primary coil of oscillation transformer (MT ₁ ) to pins (11) and (11), and connect (R ₁₃ ) between the middle terminal of primary coil and (A ⁺ ) to (Q ₅ ) (Q ₆ ) oN-OFF according to the operating oscillating the primary side voltage in the each direction in the coil flows opposite to the current proportional thereto of the transformer (MT ₁₎ is induced in the secondary coil, the secondary side (MT ₁₎ "dot" of There are coils of (LQ ₁ ) and (LQ ₄ ) on the top and coils of (LQ ₂ ) and (LQ ₃ ) on the bottom of "dot" and coils of (LQ ₁ ) and (LQ ₄ ) on the Connect (R ₁₄ ) and (R ₁₆ ) to the respective terminals and connect the series circuit of (C ₉ ) (R ₁₅ ) and (C ₁₀ ) (R ₁₇ ) to both ends of (R ₁₄ ) and (R ₁₆ ). Connect the circuits in parallel, and connect their endpoints to the bases of (Q ₁ ) and (Q ₄ ) in Fig. ₁ , respectively, and (LQ ₁ ) and (LQ _4). ) "Dot" of the terminals with no (Q ₁₎ with (respectively connected to the emitter and (LQ ₂₎ and the coil (R ₁₈ to the terminals without the "dot" of (LQ ₃₎ of Q ₄₎₎ and ( R ₂₀ ) and connect the series circuit of (C ₁₁ ) (R ₁₉ ) and the series circuit of (C ₁₂ ) (R ₂₁ ) to both ends of (R ₁₄ ) and (R ₁₆ ) in parallel, respectively. Are connected to the bases of (Q ₂ ) and (Q ₃ ) of FIG. 1, respectively, and the terminals with "dot" of (LQ ₂ ) and (LQ ₃ ) are respectively connected to the emitters of (Q ₂ ) and (Q ₃ ). Inverter circuits (Q ₁ ) and (Q ₄ ) turn on and off at the same time and (Q ₂ ) and (Q ₃ ) turn off at the same time. Separate power supply (B ⁺ ) and (A ⁺ ) Connect a separate power transformer (T _A ) to the AC input power and connect it to the input terminal of the bridge diode (BD ₁ ) on the secondary side, connect the (-) output part to the (E) point, and connect the (+) output part and (E Connect the smoothing capacitor (C ₁ ) between) points to smooth the bridge rectified DC power supply, and connect the (+) output part to (B ⁺ ) operating power. And supply (B ⁺ ) power to the input terminal of the electrostatic source (IC) (IC ₂ ) and connect the ground terminal of (IC ₂ ) to the point (E) to stabilize the static voltage of the output terminal of (IC ₂ ) It is configured to supply to the operating power of the whole circuit by supplying with (A ⁺ ) power.

Referring to the features and effects of the present invention as described above are as follows.

In the circuit of FIG. 1, the AC commercial power input to the circuit is composed of diodes D ₁ (D ₂ ) (D ₃ ) (D ₄ ) through an overcurrent protection fuse (F ₁ ) and a current damping resistor (R ₁ ). supplied to the input terminal of the bridge rectifier (BD) and a bridge rectifier circuit, an output section (E) that as and when La + output section (C ⁺⁾ of the bridge rectifier circuit (C ⁺⁾ and (E) that the bridge rectifier circuit When the waveform is formed into a waveform circuit consisting of the rectified DC voltage of (D ₅ ) (D ₆ ) (D ₇ ) (C ₁ ) (C ₂ ), it is supplied to (C ⁺ ) power, which is the operating power of this circuit. In the equivalent circuit of FIG. 7, when the switches SW ₁ and SW ₄ are turned on at the same time and (SW ₂ ) and (SW ₃ ) are turned off, the current flows in the direction of (i ₁ ) to the RLC series resonant circuit (+). Direction voltage is induced and this time, when switch (SW ₁ ) and (SW ₄ ) are turned off and switch (SW ₂ ) and (SW ₃ ) are turned on at the same time, current flows in the direction of (i ₂ ). Lowa Since the voltage in the negative direction is induced, if the above operation is repeated at the same speed as the RLC resonant frequency, a resonant current (1 ₀ ) flows through both ends of the RLC to generate a resonant voltage at each end.

The switch (SW ₁₎ in the equivalent circuit 7 degrees _{(SW 2) (SW 3)} (SW 4) transistor (Q ₁₎ that can instead have a similar performance to the switch to control the lesser arc (Q ₂₎ (Q ₃₎ Replace (Q ₄ ) with the equivalent circuit of FIG. 8 and supply the square wave pulse signal to the base of each transistor at the same time, and supply the square wave pulse signal of HLH to (Q ₂ ) (Q ₃ ) at the same time as FIG. ₁ ) and (Q ₄ ) are supplied with the opposite LHL square wave pulse signal, so that (Q ₁ ) and (Q ₄ ) are at the same time "H", and (Q ₂ ) and (Q ₃ ) are at the same time "L" In this state, (Q ₁ ) and (Q ₄ ) are turned on to perform the same operation as that of the switch SW ₁ (SW ₄ ) in the equivalent circuit of FIG. 7 (Q ₂ ) and (Q ₃ ). Becomes OFF and becomes the same as when the switch is OFF, so current flows in the direction (i ₁ ), (Q ₁ ) and (Q ₄ ) are simultaneously in the "L" state, and (Q ₂ ) and (Q ₃ ) are simultaneously " In the H "state, (Q ₂ ) and (Q ₃ ) Is turned on, (Q ₁ ) and (Q ₄ ) are turned off, and current flows in the direction of (i ₂ ), so the switch (SW ₂ ) (SW ₃ ) is turned ON in the equivalent circuit of FIG. In the case of continuous repetition, again, in Fig. ₁ , the connection point between (F) and (Q ₃ ) and (Q ₄ ), which is one end of the current feedback transformer (T) connected to the connection point of (Q ₁ ) and (Q ₂ ), In the first "branch" of circuits connected in series in the order of T ₁ , L _A1 , H ₁ , C _B1 , H ₁ , L _B1 , C _A1 , SW ₁ instead of the RLC series resonant circuit of FIG. 8 between points (G), N "branches" are connected in parallel, and each branch is connected to or disconnected from the circuit according to the ON-OFF state of the switches SW _{1 to} N, and the transistors Q ₁ (Q ₂ ) (Q ₃ ) (Q ₄ ) If the switch SW ₁ is turned on when the operation continues as shown in FIG. 8, current flows to the first branch (T ₁ ) (C _B1 ) (C _A1 ) to induce a resonance voltage, and the heater of the fluorescent lamp (H ₁ ) the current flows to the heater (H ₁₎ is In the heat and emits electrons (C _B1) of N-1 of "Branch" is an organic resonance voltage is supplied to the fluorescent lamp to the opposite ends of the (LP ₁₎ light the fluorescent lamp and connected in parallel with the (SW ₂₎ (SW ₃ )… When the switch of the (SW _N ) is turned on, the fluorescent lamp (LP ₂ ) (LP ₃ )... When (LP _N) ON any of the switches (PB ₁₎ of the switch capable of ON-OFF at the N external designed hagekkeum the lighting, in a second-degree circuit (PB ₁ ~ _N) to (SCR ₁₎ is the gate If the signal voltage does not come on, it is always off, so the current flows from the (B ⁺ ) power supply through (RA ₁ ) to the base of the transistor (TR ₁ ), turning on (TR ₁ ) and turning on (TR ₁ ) the collect and emit The resistance between them is close to "O" so that current flows through the collector coil and the emitter of relay coil (RY ₁ ) and (TR ₁ ) from power supply (B) to turn on switch (SW ₁ ) and switch (SW ₁ ) to ON. When current flows, the signal current proportional to the current flowing is induced in the transformer secondary coil of the current feedback signal transformer T ₁ , and the signal current is detected and the second coil of the current feedback signal transformer in the circuit of FIG. T _S1 ) connects resistors R ₂ in parallel to V _R2 = i _TS1 · R ₂ As a result, a voltage V _R2 is generated in which the signal current i _TS1 induced across (R ₂ ) is proportional, and thus the signal voltage is half-wave rectified through the rectifying diode D ₁ and smoothed through C ₁ . It is supplied to the LED through the LED protection resistor (R ₃ ) to indicate that the fluorescent lamp is lighting normally, and this voltage is also attenuated to the non-inverting input terminal of the OP AMP (OP ₁ ) composed of the voltage comparison circuit in FIG. Is supplied through the resistor (R ₄ ) and divided into (R ₅ ) (R ₆ ) from the (B ⁺ ) power supply, and the normal lighting of the fluorescent lamp is compared with the comparison set voltage supplied to the inverting input terminal of (OP ₁ ). of when and duration (OP ₁₎ when the output of the voltage is "O" is a current increase in the leakage of the excessive aging and circuit of the fluorescent lamp, or the abnormal condition occurs, such as (T _S1) of trans-outlet side for current feedback of More current is induced across (R ₂ ) and is phased to voltage V _R2 across The output of (OP ₁ ) is inverted so that the voltage close to (B ⁺ ) appears, and this voltage is divided into (R ₇ ) (R ₈ ) and supplied to the gate (GATE) of (SCR ₁ ). and (SCR ₁₎ the oN and the SCR is the resistance value of the collect and the emitter root ends of turns oN in this is closer (TR ₁₎ to the "O" potential difference between the base and emitter root of _{(TR 1) OFF (TR 1} ) Close to "∞" (infinity), so little current flows to the relay coil, so the switch (SW ₁ ) is turned off, the first branch circuit is cut off, and no current is induced in the secondary coil (T _S1 ). The LED, which is an indicator lamp, is also turned OFF, indicating that the fluorescent lamp has flickered due to an abnormal state of the circuit. When the SCR turns ON once the gate signal comes in, the SCR keeps ON even if the gate signal does not come on, so the external push switch (PB ₁ ) Before OFF Which still has to maintain the ON state and continues to turn OFF the switch (SW _1), a (PB ₁₎ to OFF and check the presence of error in the circuit when removing the cause and ON again (PB ₁₎ circuit is again operating Done.

The circuit of FIG. ₃ is a circuit configured to continuously supply square wave pulses to the base of transistors Q ₁ , Q ₂ , Q ₃ and Q ₄ to the circuit of FIG. ) and the pin (6) which is connected to the pin (C ₄₎ and (R ₁₁₎ is the oscillation frequency of the internal oscillator, the oscillation frequency adjustment of an oscillator (OSC) that is embedded in the interior of the F 1C _{1 OSC} (A) of FIG. 4 (a) generated at both ends of (c ₄ ) is supplied to the inverting input of (op ₁ ) and (op ₂ ) composed of a voltage comparison circuit as a comparison set voltage (a) Connect to pin (4), which is the non-inverting input terminal of (OP ₁ ), through (C ₅ ) and (R ₁₂ ) composed of differential circuits from the power supply. When the voltage is generated and the initial output of (OP ₁ ) is reduced and the power is turned on for the first time, there is a time delay of about 0.5 seconds until all circuits are stabilized in the normal operation state. And split (A ⁺ ) power into (R ₂ ) (R ₃ ) to pin (1) which is the non-inverting input terminal of OP AMP (OP ₂ ) built in IC ₁ Split the (C ⁺ ) power supply into (R ₄ ) (R ₅ ) to pin (2), the inverting input terminal, and divide the divided voltage through (R ₆ ). Connect to pin (2) and connect (C ₆ ) and (R ₈ ) at both ends of pin (2) and pin (3) at the output terminal, and connect (R ₇ ) in parallel to connect the voltage of (C ⁺ ). Detecting the change and connecting the detected voltage to pin (3), the non-inverting input terminal input of (OP ₂ ) which is composed of voltage comparator, and detecting the total current flowing to each "branch" in the circuit of FIG. If a current proportional to the current flowing in both ends of (T _S ), the secondary coil of the current feedback transformer (T), is induced, V _R1 is connected across the resistance (R ₁ ) connected in parallel across (T _S ) in FIG. 3. = i Since a voltage (V _R1 ) proportional to _TS · R ₁ is generated, it is half-wave rectified through the diode (D ₁ ), and through (R ₉ ), the inverting input terminal of (OP ₄ ) built in IC ₁ through (R ₉ ) (15 ) giving applied a signal for current detection pin 15. pin and (OP ₄₎ grounding the output terminal of 3 in 16 non-inverted input terminal of the connecting (C _7), the pin and (OP ₄₎ pin of the to the (OP ₄₎ Composed of a branch by detecting changes in the electric current feedback signal by (OP ₃₎ and (OP ₄₎ summing the output of (IC ₁₎ and a non-inverting input the signal supplied to the A (OP ₂₎ built into the detection amount of the voltage and current According to this, the output of (OP ₂ ) is configured as (B) of Fig. 4 so that the circuit is cut off when voltage exceeding the set value is supplied or excessive current flows due to short circuit or overload, etc. It is composed of PWM (PULSE, WIDTH, MODOULATION) circuit that adjusts the width of the output stage pulse of (OP ₂ ) in response to changes in load conditions such as occurrence, etc., and output pulses of (OP ₁ ) and (OP ₂ ) Connect one of the output pulses of (A ₁ ) to (A ₄ ) and (A ₅ ) by connecting them to each of the two inputs of circuit (A ₁ ), and also to the CLOCK signal CK of D FLIP FLOP and supply the D FLIP FLOP Invert output of DATA input D Data input by connecting to resistor (R) Output stage (Q) which inverts from "L" state to "H" state and from "H" state to "L" state whenever it is supplied to the output of CK and input is changed from "L" state to "H" state. Is the same as (c) of FIG. 4 and inverts from the "H" state to the "L" state and from the "L" state to the "H" state ( ), As shown in (d) of FIG. 4, two output terminals are connected to the input terminals of two AND circuits (A ₂ ) and (A ₃ ) one by one, and the other input terminal of (A ₂ ) and (A ₃ ) is a power source. Connected to, always keep "H" so that the output of (Q) is equal to the output of (A ₂ ), and ) Be the equal to the output of the (A ₃₎ and (A ₂₎ and the input of the (A _3), each NOR circuit (A ₄₎ and connected to the remaining one input terminal of the (A ₅₎ (A ₁₎ the output of the Compared with, the outputs of (A ₄ ) and (A ₅ ) are as shown in (e) of FIG. During the period (T), the ON-OFF output transistors Q ₁ and Q ₂ are operated alternately without the moment that both outputs are ON at the same time, and the emitter terminals of the transistors Q ₁ and Q ₂ ( 9) Ground pins (10) and ground pins, and connect both ends of the primary coil of the oscillation trace (MT ₁ ) one by one to the respective collector terminals (8) and (11) and connect the resistor (R ₁₃ ) to the middle terminal. When the transistor (Q ₆ ) is turned off and (Q ₅ ) is turned on by supplying (A ⁺ ) power through, the current flows from (R ₁₃ ) through the middle terminal of (MT ₁ ) without "dot" ( When Q ₅ ) flows through (Q ₅ ) and OFF (Q ₆ ) turns on, current flows through (R ₁₃ ) from the middle terminal of (MT ₁ ) to the absence of "dot" and through (Q ₆ ) since flow (Q ₅₎ the secondary side coil 4 of the oscillation transformer (MT ₁₎ since when the oN (Q ₆₎ is oN, when the oscillation transformer (MT ₁₎ the coil is different, direction of the current flowing in the Each "dot" according to the direction (±) pulse is organic in the coils of the (QB ₁₎ and the coil of (QB ₄₎ is on "dot" point, (QB ₂₎ and (QB _3), the "dot" Is at the bottom, so when (Q ₅ ) is ON and current flows from the middle terminal of the primary coil to the "dot" side, voltage rise occurs from the side without "dot" to the "dot" side of the secondary coil, so that (QB ₁ ) and The positive voltage is induced on the "dot" side of (QB ₄ ), and the voltage induced on (QB ₁ ) is paralleled to the SPEED-UP capacitor (C ₉ ) and (R ₁₅ ) in series circuit (R ₁₄ ). through the base circuit of the connection (Q ₁₎ is coupled to the base of the first-degree transistor (Q ₁₎ side do not have a "dot" coil is connected to the emitter of the (Q ₁₎ and oN the transistor (Q ₁₎ base circuit (C ₁₀₎ a (QB ₄₎ (Q ₄₎ the voltage induced in the coil is composed of the same structure as the base circuit of the (Q ₁₎ of the (R ₁₇₎ a first-degree (Q ₄ through a (R ₁₆₎ ) Coil on the base and without "dot" The same structure as the base circuit of ₍₂ QB) (Q ₄₎ an emitter connected to and ON the transistor (Q ₄₎ with (QB ₃₎ is a coil side without a "dot" (QN) (C 11) Base circuits consisting of (R ₁₉ ) (R ₁₈ ) and (C ₁₂ ) (R ₂₁ ) (R ₂₀ ) are connected respectively to the bases of (Q ₂ ) and (Q ₃ ) in FIG. 1 and the "dot" the coil is (Q ₂₎ and it is connected to the emitter of the (Q ₃₎ (QB ₂₎ and has both ends of the (QB ₃₎ with (-) a (Q ₂₎ and (Q _3), so the pulse organic OFF side, and with a third degree transistor (Q ₅₎ is OFF, and (Q ₆₎ is turned oN when the current is "dot" is to flow into the not have 2 primary coil "dot" at an intermediate terminal of the (MT ₁₎ "dot" The voltage rises toward () and (+) pulses are induced in the coils of (QB ₁ ) and (QB ₄ ) and (+) pulses are induced in the coils of (QB ₂ ) and (QB ₃ ). Q ₁ ) and (Q ₄ ) are turned off and (Q ₂ ) and (Q ₃ ) are turned on so that (Q ₂ ) and (Q ₃ ) are turned off simultaneously. -OFF and (Q ₁ ) and (Q ₄ ) continue ON-OFF-ON simultaneously to apply the square wave pulses as in the circuit of FIG. 8 to each transistor Q ₁ (Q ₂ ) (Q ₃ ) (Q ₄ ) It is designed to continue stable oscillation by supplying to each base, and separate power supply (B ⁺ ) and (A ⁺ ) bridge rectified output voltage to (BD ₁ ) by connecting a separate transformer (T _A ) to AC power supply ( C ₁ ) is smoothed and supplied as (B ⁺ ) operating power supply, and (B ⁺ ) power is supplied again through constant voltage IC ₂ to more stable power supply (A ⁺ ) power supply so that the operating voltage of the circuit does not change even when the external power supply changes. It is.

Thus, the present invention has a simple and stable configuration of a switching oscillation circuit that is complex and easy to operate using a single IC, and minimizes the number of parts by integrating the parts for controlling the lighting of N fluorescent lamps into a single operation circuit. It is the most efficient configuration of protection circuit for all abnormal conditions occurring in use and it is not a high voltage lighting method but a lighting method by high oscillation frequency of 4OKHZ, which eliminates the need for a start lamp and visual acuity due to flickering with continuous and stable light emission. It has completely solved the problem of, and has a very efficient configuration resonated by the LC resonant circuit of the output stage, which reduces the line noise and can save 30% more than the conventional ballast. (Where the switch is attached, such as a wall surface) Installation and maintenance time and cost can be significantly reduced, and since any number of N (multiple) fluorescent lights are controlled by one controller, ballasts are not built in fluorescent lamp shades, resulting in noise from ballasts or fire caused by heat. All the problems caused by the built-in ballast in the fluorescent lamp shade are solved, and even though overvoltage and overcurrent flows through the ballast and wiring, it operates under stable conditions so that the fluorescent lamp can continue to emit stable light. It is a groundbreaking invention.

Claims (1)

As shown in FIG. ₁ , the bridge rectifier circuit BD composed of diodes D ₁ , D ₂ , D ₃ , and D ₄ through an overload protection fuse F ₁ and a current damping resistor R ₁ . Connect to the input terminal respectively, and supply both ends of + part (C ⁺ ) and-part (E) of the output terminal to the operating power of the circuit, connect the cathode of diode (D ₅ ) to the point (C ⁺ ) and connect the diode in series. the direction is the same diode (D ₆₎ (D ₇₎ for connection with leads to the point (E) and, (C ⁺⁾ utilizing flat power between the connection point and the diode (D ₆₎ and (D ₇₎ electrolytic capacitors ( C ₂ ) are connected in parallel, and the electrolytic capacitor (C ₁ ) is connected in parallel between the junction of diode (D ₅ ) and diode (D ₆ ) and the point (E) to divide the charge / discharge current of the electrolytic capacitor differently. giving + portion (C ⁺⁾ and - connecting the collector of the unit (E) the transistor (Q ₁₎ to the capacitor (C ₃₎ connected to reduce the power source noise + portion (C ⁺⁾ to the both ends, and the transistor (Q ₁₎ Of Connecting the collector of the transistor (Q ₂₎ on a meter, and the emitter of the transistor (Q ₂₎ - was connected to the unit (E), + the same order as the transistor (Q ₃₎ and a transistor (Q ₄₎ portion (C ⁺ ) And-in part (E) are connected in series to form a bridge circuit form, and diodes (D ₈ ) (D ₉ ) (D in the collector of each transistor (Q ₁ ) (Q ₂ ) (Q ₃ ) (Q ₄ ) ₁₀ ) Connect the cathodes of (D ₁₁ ) in order and connect the diodes (D ₈ ) (D ₉ ) (D ₁₀ ) (D to the emitters of transistors Q ₁ ) (Q ₂ ) (Q ₃ ) (Q ₄ ) ₁₁ ) connect the anode and protect the transistor from reverse induced voltage, connect the current feedback transformer (T) to the connection point of transistor (Q ₁ ) and transistor (Q ₂ ), and one end is called (F) point. If the connection point of the transistor Q ₃ and the transistor Q ₄ is (G), heaters H _{1 to N at} both ends of the current feedback transformer (T _{1 to N} ) fluorescent lamps at both ends of the (F) and (G) points. ) Resonant Capacitor (C _{B1 ~ N} ) (C _{A1 ~ N} ), Switch Values SW _{1 to N} are connected in series. The circuit connected in series in the order of F point, T ₁ , L _A1 , H ₁ , CB ₁ , H ₁ , L _B1 , C _A1 , SW ₁ , and G point is called first branch, and F point, T ₂ , L _A2 , The circuit connected in series in the order of H ₂ , CB ₂ , H ₂ , L _A2 , C _A2 , SW ₂ and G is called the second branch, and F point, T _N , L _AN , H _N , CB _N , H _N , L _{When the N-type} circuits connected in series in the order of _BN , C _AN , SW _N , and G point are referred to as N-th branches, N switches connected to N-th circuits in parallel with the first circuit are connected to both ends of F- and G-points. SW _{1 ~ N} ) is configured to allow current to flow or cut off in each branch as ON-OFF, the operation circuit of switch SW ₁ is the same as the second figure and each switch of SW _{1 ~ N} Operates on the same principle as (SW ₁ ), with the same circuit consisting of N switches. Supplying separate operating power (B ⁺ ) to the circuit of FIG. 2 and turning on the switch (SW ₁ ) when magnetic power is generated when the operating power (B ⁺ ) is supplied, and turning off the switch (SW ₁ ) when the operating power is cut off. connecting the coil of the relay (RY ₁₎ having a structure to connect the collector of the transistor (TR ₁₎ to the other terminal of the coil is connected to the emitter of the transistor (TR ₁₎ to the point (E) and the operating power supply (B ⁺ ), Connect the current damping resistor (R _A1 ) and connect the switch (PB ₁ ) that can be turned on and off from the outside at the opposite end, and connect the other end to the base of the transistor (TR ₁ ) to connect the switch (PB ₁ ). When pressed, the transistor TR ₁ is turned on and the operating power is applied to both ends of the relay RY _{1. The} switch SW ₁ is turned on to flow a current through the first branch to turn on the fluorescent lamp LP ₁ , and the current flows through the first branch. The current is induced in the secondary side T _S1 of the current feedback transformer T ₁ , and (T One of _S1) to the ends of the resistor (R ₂₎ connected in parallel to both ends V _RA2 = i _TS1 · the generation voltage of R _A2 and (T _S1) of the access point (E) and the other diode (D _A1 Half-wave rectified by connecting to the anode of Connect the smoothing capacitor (C ₁ ) between the cathode and-(E) points of the _circuit , and connect the LED protection resistor (R _A3 ) and LED ₁ in series in the forward direction and connect them in parallel with the capacitor (C _A1 ) to short-circuit the circuit. , poor contact, or monitoring the overload and so on, and a diode (D _A1) Kane methods connecting the current damping resistance (R _A4) for the accesses to the non-inverting input terminal of the OP AMP, and the OP AMP inverting input terminal and an operating power of (B ⁺ The resistance (R ₅ ) is connected between), and the resistance (R ₆ ) is connected between the inverting input terminal of OP AMP and the point (E) to supply a reference voltage. Configure a voltage comparison circuit to compare and connect the current damping resistor (R ₇ ) to the output of the OP AMP, connect the other end to the gate of the SCR, and between (R _A8 ) and (C _A2 ) between the gate of the SCR and the cathode. ) In parallel, connect the cathode to point (E), and connect the anode to the base of transistor (TR ₁ ). When it is turned on instead of SCR, the transistor TR ₁ is turned off and the switch SW ₁ is turned off to configure the protection circuit to cut off the power supply to the lamp. It was the simplicity of construction of the circuit, using, 12 to supply a separate operating power supply (a ⁺⁾ to the pin action to all of the circuitry within the IC ₁ by the electrostatic power supply (REF) which is integrated into the IC ₁ Supply power and connect (R ₁₁ ) to pin (6) of IC ₁ to (E) point, and (C ₄ ) to pin (5) to (E) to connect to oscillator inside IC ₁ OSC oscillation frequency is F _OSC Since the oscillation frequency is set to 40KHZ, connect (R ₁₂ ) to pin 4 to connect to (E) point, and (C ₅ ) to pin 4 to connect the operating power output of IC ₁ (14) When the power is first supplied by connecting to the burner pin, a voltage inversely proportional to the CR charging voltage of (C ₅ ) (R ₁₂ ) is supplied to the pin (4) so that the output of the internal OP AMP (OP ₁ ) is gradually increased so that the power is turned on. the unit (E) connected to the resistance (R ₂₎ (R ₃₎ between points in series and a resistance (R ₂₎ and the resistor (R ₃₎ - eliminates any possible malfunction has occurred in the initial supply voltage (a ⁺⁾ and between the part (E) point-connected to the connection point of the IC ₁ (1) pin by setting the non-inverting input voltage of the OP AMP (OP ₃₎ in the IC ₁ and the supply 1 degree power + portion (C ⁺⁾ and Connect resistor (R ₄ ) (R ₅ ) in series, connect resistor (R ₆ ) to the connection point of resistor (R ₄ ) and resistor (R ₅ ), and connect the opposite end to pin (2) of IC ₁ Between pin (2) and pin (3) Connect (C ₆ ) (C ₈ ) in series and (R ₇ ) in parallel to this so that OP AMP (OP ₃ ) inside IC ₁ is connected to the reference set voltage input (1) and output voltage detection input (2 It is composed of voltage comparator which compares voltage difference between pins.Connect pin (16), which is the non-inverting input terminal of OP AMP (OP ₄ ) inside IC ₁ , to point (E) and inverting input terminal (15) Condenser (C ₇ ) is connected to pin 3 and pin (3) to configure (OP ₄ ) as an integrator. (R ₉ ) (R ₁₀ ) (R ₈ ) between pin (15) and-(E) connected in series, and (R ₉₎ and connected to the (R ₁₎ between the node and the (E) point on the connecting Kane method of the (D ₁₎ to the connection point of the (R ₁₀₎ and (D ₁₎ and (R ₁ (T _S ), which is the secondary coil of the current feedback transformer, is connected in parallel with each other, and the amount of current induced in (T _S ) increases when the current suddenly increases due to a fault in the circuit or short circuit. To regulate the current supply to protect the circuit (9) pins (10), which are emitters of transistors (Q ₅ ) (Q ₆ ) inside IC ₁ , are connected to the (E) point, and the collector output of (Q ₅ ) (Q ₆ ) is (8). ) Connect both ends of the primary coil of the oscillation transformer (MT ₁ ) to pins (11) and (11) and connect (R ₁₃ ) between the middle terminal of the primary coil and (A ⁺ ) to (Q ₅ ) (Q ₆ ) oN-OFF according to the operating oscillating the primary side voltage in the each direction in the coil flows opposite to the current proportional thereto of the transformer (MT ₁₎ is induced in the secondary coil, the secondary side (MT ₁₎ "dot" of There are coils of (LQ ₁ ) and (LQ ₄ ) on the top and coils of (LQ ₂ ) and (LQ ₃ ) on the bottom of "dot" and coils of (LQ ₁ ) and (LQ ₄ ) on the Connect (R ₁₄ ) and (R ₁₆ ) to the respective terminals and connect the series circuit of (C ₉ ) (R ₁₅ ) and (C ₁₀ ) (R ₁₇ ) to both ends of (R ₁₄ ) and (R ₁₆ ). Connect the circuits in parallel, respectively, and connect their endpoints to the bases of (Q ₁ ) and (Q ₄ ) in Fig. ₁ , respectively, and (LQ ₁ ) and (LQ). ₄ ) connect the terminals without "dot" to the emitters of (Q ₁ ) and (Q ₄ ) respectively, and the coils of (LQ ₂ ) and (LQ ₃ ) connect to terminals without "dot" (R ₁₈ ). And (R ₂₀ ) are connected respectively, and the series circuit of (C ₁₁ ) (R ₁₉ ) and the series circuit of (C ₁₂ ) (R ₂₁ ) are connected in parallel at both ends of (R ₁₄ ) and (R ₁₆ ), respectively. Connect the end points to the bases of (Q ₂ ) and (Q ₃ ) in Fig. ₁ , respectively, and connect the terminals with "dot" of (LQ ₂ ) and (LQ ₃ ) to the ends of (Q ₂ ) and (Q ₃ ). respectively connected to the emitter to the transistor (Q ₁₎ and (Q ₄₎ at the same time, oN-OFF, and (Q ₂₎ and (Q ₃₎ to configure the inverter circuit at the same time OFF-oN and a separate power source (B ⁺⁾ and ( A ⁺ ) connects a separate power transformer (T _A ) to the AC input power and connects it to the input terminal of the bridge diode (BD ₁ ) on the secondary side, and connects the (-) output part to the (E) point and the (+) output part. and (E) by connecting a smoothing capacitor (C ₁₎ between the bridge points to smooth the rectified DC power source (+) an output section (B ⁺⁾ operating power supply And supply (B ⁺ ) power to the input terminal of the electrostatic source (IC) (IC ₂ ) and connect the ground terminal of (IC ₂ ) to the point (E) to stabilize the static voltage of the output terminal of (IC ₂ ) Ballasts for electronic fluorescent lamps that turn on and control N (multiple) fluorescent lamps configured to be supplied as (A ⁺ ) power to supply the operating power of the entire circuit.