KR20040066985A - Circuit for control power on switch line - Google Patents

Abstract

PURPOSE: A control power circuit for a switching line is provided to obtain constantly the electric power by using a common bridge diode to pass the unloading current and the load current. CONSTITUTION: A control power circuit for a switching line includes a first switching element, a bridge diode, a second switching element, and a control circuit. The first switching element is used for supplying AC power to a load. The bridge diode is used for applying the unloading current to a capacitor when the first switching element and the load are turned off. In addition, the bridge diode is used for receiving the load current when the first switching element and the load are turned on. The second switching element is used for controlling the flow of the rectified current supplied to the load. The control circuit(22) is used for controlling the second switching element.

Description

Circuit for control power {Circuit for control power on switch line}

The present invention relates to a switch line control power supply circuit for directly supplying power required for a control element from a switch line. More specifically, the present invention always provides a constant power regardless of the magnitude of the load current and the no-load current resulting from turning on and off an electric device. A switch line control power supply circuit is provided.

There are many types of switches used to turn on and off lights or electric devices, and recently, various types of switches that have various functions by configuring electronic circuits are used.

Electronic circuits used in ON-OFF or dimmer switches require power to operate and various methods are used to obtain this power from the switch line. Circuitry for "and circuitry for obtaining operating power when on".

In the method of obtaining the operating power when it is turned off, when a small current flows, the lamp may appear to be turned on even when a small load is turned off or the lamp may actually turn on, and there are various methods such as using a capacitor in parallel with the lamp to prevent it. Is being mobilized. In addition, in a circuit to obtain operating power when it is turned on, if it is always operated under a small load, there is a problem such that a large current flows in a large load and heat is generated. There are many problems such as malfunction of the switch due to failure to obtain operating power.

1 is a circuit diagram illustrating a conventional power supply circuit with a switch line. When the lamp is off, current i1 flows through capacitor C1 and bridge diode BD1. At this time, the current is designed so that a small current flows so that the lamp does not turn on. DC power obtained through the bridge diode BD1 is stabilized through the electrolytic capacitor C2 and the zener diode ZD1 and then used as a power source for the control circuit through the diode D1. On the other hand, when the lamp is turned on, the triac T1 is turned on so that the load current (i2) flows, and a constant voltage drop occurs due to the diodes D2 to D5. Done. Here, a constant voltage drop occurs in the diodes D2 to D5 to obtain a predetermined power supply.

The disadvantages of the conventional switch line power supply circuit will be described in detail with reference to FIG.

When the lamp or electric appliance is off. Even if the small current (i1) is designed to flow through the capacitor C1, if a load smaller than the design standard load (lamp or electric equipment, etc.) is used, the small current flows to the load, so the load is turned on or appears to be turned on. There is concern about quality. In addition, the use of significantly larger loads than the design criteria can overheat the zener diode ZD1 due to the large current. In addition, since the zener diode is used in FIG.

When the lamp or electric appliance is turned on. When triac T1 is turned on and the lamp or electrical device is turned on, current i2 flows through T1 and D2 through D5. In D2 ~ D5, voltage drop of about 1.2V always occurs and it is designed to get constant power through transformer T1. The voltage converted by the transformer T1 is rectified and used as a DC power supply through the bridge diode BD2 and the capacitor C2. However, when a load smaller than the reference load designed in this circuit is used, a small current flows, and thus the power required for driving the electronic circuit cannot be obtained, thereby causing the electronic circuit to malfunction. Therefore, the lower limit of the use load is determined, and a lower load cannot be used. On the other hand, if a load larger than the designed load is used, a large current flows and the diodes D2 to D5 may overheat and be damaged.

Accordingly, the Applicant completes the present invention according to the necessity of a switch line power circuit that can always obtain a constant power by detecting a minute current when the lamp or electric equipment is turned off and a large current when the lamp is turned on and responding accordingly. Was done.

SUMMARY OF THE INVENTION An object of the present invention is to provide a switch line power supply circuit configured to detect a current in a switch line and to turn on and off a switching element appropriately according to the magnitude of the current regardless of a load current and a no-load current to always obtain a constant power. will be.

1 is a conventional switch line power supply circuit.

2 is a switch line power supply circuit according to the present invention.

3 is a circuit diagram of the embodiment modified in FIG.

4 is a circuit diagram of another embodiment modified in FIG.

5 is a configuration of the control circuit of FIGS. 2, 3, and 4;

6 is a configuration of a control circuit of FIGS. 2, 3, and 4;

7 and 8 are examples of actual configuration of the control circuit.

2 shows a newly designed switch line power supply circuit according to the present invention. The present invention provides a switch line power supply circuit for performing ON / OFF control of a load such as a lamp or an electric device in a switch line, comprising: a first switching element for supplying a load by controlling an AC input ON / OFF; When the first switching device is turned off and the load is turned off, a quiescent current i3 not passing through the first switching device is applied through a capacitor C4, and when the first switching device is turned on and the load is turned on, the switching device is turned on. A bridge diode BD3 to which a load current i4 flowing therethrough is applied; A second switching element rectifying through the bridge diode BD3 to interrupt a flow of current supplied to a load; Control circuit to turn on / off the second switching element, but when the current flows to the BD3 to a predetermined voltage or more, the power supply is turned off to stop the power supply, and when the voltage is low, the second switching element is turned off to supply power again. It consists of.

Referring to FIG. 2, a triac T2 connected between an AC input terminal and an input terminal of a bridge diode BD3 may be used as the first switching device, and the field effect transistor turned on / off by a control circuit as the second switching device. FET1 can be used.

3 and 4, the first and second switching elements may be installed at an input terminal of the bridge diode to control AC directly. As the first switching element, field effect transistors Q1 and Q2 may be used. They can be connected in parallel or in series.

The configuration and operation of the present invention will be described in more detail.

The circuit of Figure 2 is a simplified circuit using a common bridge diode BD3, when the load is off, no-load current (i3) flows through the capacitor C4 is applied to the bridge diode BD3, when the load is on triac T2 The load current i4 flows through and is applied to the bridge diode BD3. In either case, in obtaining a control power supply from the switch line, the no load current and the load current share the bridge diode BD3 in common.

When the control circuit 22 controls the FET1 to turn off when the current flows through the commonly used bridge diode BD3, the AC input is converted into a DC power source through D6 and C5 and output. When the output voltage exceeds a certain voltage, the signal from the control circuit 22 turns on FET1 again, short-circuits both ends of the bridge diode BD3, and drops the DC voltage. Therefore, when large current flows regardless of load current and no load current, the time that FET1 is turned on through the control circuit is small, and when small current flows, the time that is turned on is relatively long, so that constant power is maintained regardless of the large or small current. Can get

In addition, since the pulse width of the control circuit 22 is changed according to the magnitude of the load current, the pulse width can be inferred by reading the value of the pulse width, and the processor reads it to cut off the load when an overcurrent flows. Configuration is possible. In the absence of a processor, an overcurrent protection circuit can also be configured by controlling the triac T2 by configuring a control circuit based on the pulse width.

The condenser C4 is used for flowing a no-load current at no load. In addition, the capacitor C4 is commonly used as a snobber circuit in triac ON-OFF control.

It is also possible to configure the present invention by controlling the AC input with the FET. Figure 3 illustrates a circuit for controlling at AC with a FET. In the circuit of FIG. 3, since the loss may occur in the bridge diode BD and heat may be generated, FETs Q1 and Q2 are installed at the external input terminal of the bridge diode BD to eliminate heat generated in the bridge diode BD, thereby reducing the current capacity of the bridge diode BD. It is a shortened circuit. Since the load current flows through the diodes D1 and D2 and the FETs Q1 and Q2, the current flows only for half a cycle, so that the heat generated from the diodes and the FETs can also be dispersed.

As a variant of the circuit of Fig. 3, the FETs Q1 and Q2 can be configured in series as in Fig. 4. In Fig. 4, the load current is configured to flow through one FET Q1 and then through a diode embedded inside the other FET Q2. In addition, the current flowing through the FET Q2 also flows through the diode built in the FET Q1.

5 and 6 illustrate internal configuration diagrams of the control circuits of FIGS. 2 to 4, wherein FIG. 5 is a control circuit using a comparator and FIG. 6 shows a control circuit using an error amplifier.

In Fig. 5, a circuit for sensing a part of the input voltage by the voltage sensing means 61, comparing the reference voltage with the comparison means 63, and controlling the driving circuit 65 according to the comparison result is shown.

Similarly, in FIG. 6, a part of the input voltage is sensed by the voltage sensing means 71, and the error amplifier 73 is compared with the reference voltage to perform PWM control through the pulse width modulator 74. A circuit for controlling the drive circuit 75 is shown. The control circuit of FIG. 6 may also serve as an overcurrent control circuit if the triac T2 is configured to infer the magnitude of the load current flowing in accordance with the magnitude of the output pulse width. The pulse width modulator 74 of the control circuit shown in FIG. 6 includes an oscillation circuit, which may be constituted by a pulse frequency modulator (PFM) whose pulse width is constant and whose frequency varies.

The construction and operation of the control circuit described above are obvious to those skilled in the art.

7 and 8 show a circuit diagram for practically implementing the schematic configuration of FIGS. 5 and 6. Fig. 7 shows a control circuit using "TL431" which is one type of comparator IC, and Fig. 8 shows a control circuit using OP-amp.

As described above, according to the present invention, in obtaining a control power supply from a switch line, a no-load current and a load current are passed using a common bridge diode, so that when a lamp or an electric device is turned off, or a minute current is turned on, The large current of can be detected and responded accordingly. Therefore, unlike conventional switch line power supply circuits, not only constant power can be obtained at all times, but also proper control power can be obtained even in a very small load.

Claims (8)

In a circuit that performs ON / OFF control of loads such as lamps and electrical equipment on a switch line, A first switching device for supplying a load by controlling an AC input ON / OFF, When the first switching device is turned off and the load is turned off, a quiescent current i3 not passing through the first switching device is applied through a capacitor C4, and when the first switching device is turned on and the load is turned on, the switching device is turned on. Bridge diode BD3 to which a load current i4 flowing through is applied, A second switching element rectified through the bridge diode BD3 to interrupt a flow of current supplied to a load; A control circuit configured to control ON / OFF of the second switching element, and to control the turn-on / turn-off time of the second switching element according to the magnitude of the current of the BD3. Line power circuit. The method according to claim 1, The first switching element is a triac T2 connected between an AC input terminal and an input terminal of the bridge diode BD3, And the second switching element is a field effect transistor FET1 turned on / off by a control circuit. The switch line of claim 2, wherein the capacitor C4 serves to apply a no-load current to the bridge diode BD3 at no load, and at the same time, serves as a snorkeler when the triac T2 is turned on / off. Power circuit. The method of claim 1, wherein the first switching element and the second switching element is a field effect transistor Q1, Q2 for controlling the input terminal of the bridge diode BD3 is turned on / off by the control circuit is connected in parallel with each other. A switch line power supply circuit. The method of claim 1, wherein the first switching element and the second switching element is a field effect transistor Q1, Q2 which is turned on / off by the control circuit to control the input terminal of the bridge diode BD3, it is connected in series with each other. A switch line power supply circuit. The method of claim 1, wherein the control circuit Voltage sensing means for detecting an output current of the bridge diode BD3; Comparison means for comparing the sensed voltage with a reference voltage, And a driving circuit for turning on / off the second switching element in accordance with the comparison voltage output from the comparing means. 7. The switch line power supply circuit according to claim 6, wherein said comparing means is a comparator IC. The method of claim 6, wherein the comparison means is an error amplifier, the control circuit further comprises a pulse width modulator for controlling the output signal of the drive circuit by changing the pulse width in accordance with the magnitude of the comparison value output from the error amplifier A switch line power supply circuit, characterized in that.