KR20020052826A - Frequency Detection Circuit for SMPS - Google Patents

Abstract

PURPOSE: An external frequency detection circuit for SMPS is provided to achieve an improved reliability for product by detecting the state of input power in a rapid and accurate manner. CONSTITUTION: An external frequency detection circuit comprises an input power unit(S10) for removing noise from the power applied from an external source; a bridge rectifier unit(S20) for full-wave rectifying the power applied from the input power unit; a voltage reducing unit(S30) for converting the power applied from the bridge rectifier unit into a drive source for each component unit; a frequency sensing unit(S50) for converting the power input to the input power unit, into a square wave signal; and a control unit(S40) for judging the state of frequency of power by sensing the square wave signal applied from the frequency sensing unit.

Description

External Frequency Detection Circuit for SMPS {Frequency Detection Circuit for SMPS}

The present invention relates to an external frequency sensing circuit for an SMPS, and more particularly, to an external frequency sensing circuit for an SMPS for directly detecting an input power source.

SMP is one of power circuits that converts AC power into DC power, and converts input AC power into DC power, and converts the DC power into pulse width modulation (PWM) to obtain DC power through smoothing circuit again. to be.

In spite of the complicated conversion process as described above, the reason for using SMP is because of the advantages of obtaining high quality power and the ability to modify and output any desired power within a predetermined range.

Next, a frequency sensing circuit of the prior art will be described with reference to FIG. 1.

The conventional SMP circuit of FIG. 1 includes an input power supply unit S1, a bridge rectifying unit S2, a voltage reducing unit S3, a control power supply unit S4, and a frequency sensing unit S5 as shown in FIG. It is configured by.

First, the components constituting each component and the connection structure will be described.

As shown in FIG. 1, the input power source S1 to which power supplied from the outside is input includes a choke coil CC10 for removing noise or a miscellaneous signal of a commercial AC power input.

The bridge rectifying unit S2 uses a bridge diode D10 for full-wave rectification of AC power, rectifying capacitors C10 and C20, and a coil L10 to form a full-wave rectifying circuit.

The capacitor C10 terminal is connected to the output terminal of the bridge diode D10, the coil L10 is connected to one terminal of the capacitor C10, and the capacitor C20 is connected to the other terminal of the coil L10. Configure by connecting the other terminal of.

The power rectified by the bridge diode D10 is supplied to each component through the capacitor C20 via the capacitor C10 and the coil L10.

The voltage decompression unit S3 includes a transformer TR10 for reducing the input voltage and rectifying diodes D11, D12, D13, and D14 for converting an AC voltage into a direct current.

The primary side terminal of the transformer TR10 is connected to the input power supply unit S1, and the secondary side terminal is connected to the input terminals of the rectifying diodes D11, D12, D13, and D14 to perform full-wave rectification of the reduced AC power.

The control power supply unit S4 includes capacitors C30, C40 and C50 and a constant voltage element M10, and converts the full-wave rectified DC power into a safer DC power and supplies it to each component.

The DC power is applied to the smoothing capacitors C30 and C40 connected to the rectifying diodes D11, D12, D13, and D14 to remove the AC component.

The capacitor C40 is connected to the input terminal of the constant voltage element M10, and thus, the DC power is applied to the constant voltage element M10.

A capacitor C50 is connected to the output terminal of the constant voltage element M10 to transfer more stable power output from the constant voltage element M10 to each component through the capacitor C50.

The frequency detector S5 includes a resistor R10, a capacitor C60, a diode D14, and a transistor TS10 for generating a square wave.

The capacitor C60 connected to the secondary terminal of the transformer TR10 of the voltage reducing unit S3 is connected to the resistors R10 and R20 constituting a voltage divider circuit.

The resistor R20 is connected in parallel with the diode D15 and the diode D15 is connected to the base terminal and the emitter terminal of the transistor TS10 so that the AC voltage is supplied to the base terminal.

A resistor R30 is connected to the collector terminal of the transistor TS10, and the resistor R30 is connected to a controller to transfer a frequency signal of an input power output from the collector terminal.

As described above, in the prior art, the frequency sensing unit is connected to the voltage reducing unit, and configured to detect the frequency of the power reduced in the voltage reducing unit and supply it to the control unit.

The following describes the operation process of the external frequency sensing circuit for SMP according to the prior art.

First, when externally supplied power is applied to the input power source unit S1, the power source unit S1 is simultaneously supplied to the bridge rectifying unit S2 and the voltage reducing unit S3 via a choke coil CC10 for removing noise.

The bridge rectifying unit S2 converts the AC voltage supplied from the input power source S1 into a DC voltage and converts the AC power into a DC power using a full-wave rectifying circuit composed of a rectifying diode D10. .

Since the ripple, which is an AC component, remains in the DC power source rectified by the bridge rectifying unit S2, the ripple is removed using the capacitor C10 and the coil L10, and a more stable DC voltage is output.

The DC voltage thus output is not shown, but is supplied to each component in the product requiring a power source.

The voltage decompression unit S3 is a component that lowers the voltage of the power supplied from the input power source S1 to a predetermined size or less, and decompresses the commercial AC power input using the transformer TR10.

The reduced AC power is applied to the rectifier diodes D11, D12, D13, and D14 to convert the DC power into DC power.

The control power supply unit S4 is a component supplying driving power to a control unit composed of elements sensitive to power characteristics such as a microprocessor. The control power supply unit S4 connects the DC power supplied from the voltage reducing unit to the terminals of the capacitors C30 and C40. To remove the AC component contained in the DC power supply. The DC power source is converted into a more stable DC power source capable of driving the control unit by using the constant voltage element M10.

The frequency detecting unit S4 is connected to the secondary terminal of the transformer TR10 of the voltage reducing unit S3 to detect a state of the depressed input power and transmits the state of the input voltage to the controller.

In the frequency sensing unit, the AC voltage decompressed through the transformer TR10 is reduced in a voltage divider circuit including a capacitor C60 and resistors R10 and R20, and the diode D15 is applied to the base terminal of the transistor TS10. Is authorized. The AC power applied to the base terminal operates the transistor TS10 as a switch so that the power applied to the collector terminal is controlled on / off. Accordingly, a square wave having a phase opposite to that of an input power is output to the collector terminal, and the signal is transmitted to the controller to detect the square wave.

If the square wave signal of the collector terminal does not occur for more than 60HZ (16.7m) or more than 50HZ (20m), the control unit recognizes that the input power is unstable or the power supply is stopped, and the SMP is safely Perform a predetermined operation to operate.

That is, in the prior art, the frequency sensing unit detects the state of the input power applied to the transformer secondary terminal of the voltage reducing unit, converts the frequency of the input power into a square wave, and transmits the frequency to the control unit.

The controller is configured to detect an abnormality of the input power by detecting a frequency of the input power, that is, a square wave output from the frequency detector.

As described above, the conventional external frequency sensing circuit for SMP is configured to sense the input power applied to the transformer secondary terminal of the voltage reducing unit in order to detect the state of the input power supplied from the outside.

Therefore, when the input power is detected, there is a problem that the input power is distorted or an error occurs according to the transformer performance of the voltage reducing unit, and the input power is influenced by the load of the control power supply unit.

In addition, the abnormal voltage or noise included in the input power through the frequency detection unit is included in the square wave signal and has a problem of being transmitted to the controller.

Accordingly, an object of the present invention is to provide an external frequency sensing circuit for SMP that can directly detect the input power to quickly and accurately determine the state of the input voltage.

1 is a SMP circuit diagram according to the prior art,

2 is an SMP circuit diagram according to the present invention.

Explanation of symbols on the main parts of the drawings

TR10, TR100: Transformer PS10, PS100: Power

TS10: transistor M10, M100: constant voltage device

L10, L100: Coil DD140, DD150: Light Emitting Diode

IC100: Switching element CC10, CC20: Choke coil

ZD100, ZD200, ZD300: Zener Diodes

DD140, DD150: light emitter of photocoupler P140, P150: light receiver of photocoupler

D10, D11, D12, D13, D14, D15, D100, D110, D120: Diode

R10, R20, R30 R100, R200, R300, R400, R500, R600, R800: Resistor

C10, C20, C30, C40, C50, C100, C200, C300, C400, C500, C600, C700, C800, C900: Capacitor

External frequency sensing circuit for SMP according to the present invention for achieving the above object is an input power supply for removing the noise of the power applied from the outside; A bridge rectifier for full-wave rectifying the power applied from the input power source; A pressure reducing unit for converting the power applied from the bridge rectifying unit into a driving source of each component unit; A frequency sensing unit converting the power applied to the input power unit into a square wave signal; And a controller configured to detect the square wave signal applied by the frequency detector to determine a frequency state of the power supply.

The frequency sensing unit according to the present invention includes: a resistor for reducing the input power; A zener diode that is energized only when the voltage applied to the resistor is greater than or equal to a predetermined voltage; The signal supplied from the zener diode is characterized in that for transmitting to the control unit using a photocoupler.

Hereinafter, an external frequency sensing circuit for SMP according to the present invention will be described with reference to the accompanying drawings.

2 is a schematic diagram of an SMP circuit according to the present invention.

As shown in FIG. 2, the present invention includes an input power supply unit S10, a bridge rectifying unit S20, a voltage reducing unit S30, a control power supply unit S40, and a frequency detection unit S50.

First, the input power supply unit S10 includes a choke coil CC20 and is connected to the bridge rectifier to apply power supplied from the outside to the bridge rectifier S20.

The bridge rectifying unit S20 is a component for converting an input AC power into a DC power source and connects a rectifier diode D100, capacitors C100 and C200, and a coil L100 to form a circuit, and the capacitor The voltage output from C200 is supplied to the voltage decompression unit S30.

The voltage decompression unit S30 is a component that converts into various voltages by using the power supplied from the bridge rectifying unit S20 and supplies them to a driving source of each component.

The voltage decompression unit S30 is fixed to the resistor R900 for adjusting the voltage of the DC power supplied from the bridge rectifier S20 and the diode D110 and the transformer TR100 to prevent the current direction from flowing in the reverse direction. A Zener diode ZD100, a capacitor C700, and a diode D130 for supplying a voltage or more are included.

In addition, a switching device IC100 for generating a high frequency signal, a rectifier diode D120, capacitors C200, C300, and C500, and a light receiving transistor P140 of a photocoupler for sensing power output from the voltage decompression unit. It is configured to include.

The photocoupler is a semiconductor device capable of transmitting a signal while electrically blocking a circuit, and is configured by pairing a light receiving unit and a light emitting unit capable of transmitting and receiving optical signals.

In the present invention, the photo coupler is configured in the voltage reducing unit S30, the control power supply unit S40, and the frequency detecting unit S50 to transmit and receive a signal.

The control power supply unit S40 is a component supplying power to a device requiring a stable power source such as a microprocessor, and converts an input voltage into a stable power source using the constant voltage device M100 and the capacitor C400.

The control power supply unit S40 includes a light emitting diode DD140 of a photocoupler, senses a voltage supplied from the voltage reduction unit S30, converts it into a signal, and receives a light receiving transistor P140 of the voltage reduction unit S30. To pass on.

The signal transmitted to the light receiving transistor of the voltage reducing unit S30 is transmitted to the switching device IC100 so that the switching device IC100 can supply a constant power to the control power supply.

The frequency detecting unit S50 is a component for detecting the state of the input power and transmitting the power to the control unit. The input power detecting unit S50 detects the input power, converts the input power into a predetermined signal, and transmits the same to the control unit.

The frequency sensing unit S50 includes a voltage divider circuit including resistors R200, R300, and R400 to depressurize the input power, a zener diode ZD300 conducting at a predetermined voltage or more, and a photocoupler for supplying a signal to the controller. DD150 and P150 and a bypass capacitor C600.

The resistors R200, R300, and R400 constituting the voltage divider circuit are connected to a power source of the input power supply unit to reduce the input voltage, and a zener diode ZD300 and a light emitting diode of the photocoupler are connected to the resistors R200, R300, and R400. The reduced voltage is applied to the light emitting diode DD150 of the photocoupler.

The light receiving unit P150 of the photocoupler is connected to the resistors R600 and R700 and the capacitor C600, and one terminal of the capacitor C600 is connected to the control unit so that the light receiving unit P150 of the light emitting diode DD150 is connected. When the signal is transmitted to, the frequency signal of the commercial power is applied to the controller through the resistors R600 and R700 and the capacitor C600.

As described above, in the present invention, one terminal of the frequency sensing unit S50 is connected to the input power unit S10 so that the input power can be directly detected.

In addition, the input voltage signal sensed by using the zener diode ZD300 in the frequency detecting unit S50 is configured to transmit a signal to the control unit when the predetermined voltage is higher than or equal to a predetermined voltage.

The following describes the operation process of the present invention.

The user applies power supplied from the outside to the input power source to drive the SMP.

The input power supplied to the input power supply unit S10 is supplied to the rectifying diode D100 of the bridge rectifying unit S20 and converted into DC power, and is applied to the switching driving element IC100 of the voltage reducing unit S30.

The switching driving device IC100 converts the DC power into a high frequency and applies it to the primary terminal of the transformer TR100, and converts the AC voltage output from the secondary terminal of the transformer TR100 into a diode D120 and a capacitor C200. , C300) to half-wave rectification.

The half-wave rectified power is supplied to the constant voltage element M100 of the control power supply unit to be converted into a more stable DC power supply, and is supplied to the control unit or another component.

The half-wave rectified power is supplied to the input terminal of the constant voltage device M100 of the control power supply unit S40 and the photocoupler DD140 operates to feed back the state of the half-wave rectified power to the switching device IC100 of the voltage reduction unit. do.

Therefore, the switching device IC100 senses the state of the output voltage so that the voltage supplied to the control power supply unit S40 is maintained at a constant voltage.

Meanwhile, power is applied to the input power supply unit S10 and power is also applied to the frequency detection unit S50. The input power applied to the frequency detector S50 is reduced in pressure through a voltage divider circuit composed of resistors R200, R300, and R400, and is supplied to the zener diode ZD300.

Since the zener diode ZD300 is conducted only when the voltage is higher than or equal to a predetermined voltage, the AC power applied to the zener diode ZD300 is converted into a constant square wave and supplied to the photocoupler DD150.

The signal generated by the photocoupler DD150 is supplied to the controller to be decompressed while passing through the resistors R700 and R600, and then transferred to the microprocessor (not shown) through the bypass capacitor C600.

If the square wave signal does not occur during the period of 50HZ (20m) to 60HZ (16.7m), the microprocessor regards the input power as unstable or considers the power supply to be cut off, and protects the SMS circuit. Perform the set operation.

In this process, the microprocessor may determine the applied square wave signal, accurately determine the state of the input power applied to the input power unit, and operate by controlling other components according to the state of the input power.

In the present invention, the frequency sensing unit is configured to directly detect the input voltage applied to the input power supply unit to supply the state of the input voltage to the control unit.

In addition, in the frequency sensing unit according to the present invention, a circuit is constructed using a zener diode to generate a square wave and supply it to the controller only when the supplied voltage is higher than or equal to a predetermined voltage.

According to the present invention as described above, it can be seen that the basic technical idea is to connect the frequency sensing unit to the input power supply to which external power is supplied so as to directly detect the state of the input power.

And it is a matter of course that various modifications are possible for a person having ordinary skill in the art within the scope of the grit of the present invention as described above.

As described above, since the present invention directly detects the frequency and voltage of the input power supply unit in the frequency sensing unit, it is possible to accurately grasp the frequency and power state of the input power source.

In addition, in the present invention, the zener diode is provided in the frequency sensing unit so that the signal is not supplied to the controller until the voltage is constant, thereby safely operating the abnormal signal or noise, thereby increasing the reliability of the product.

Claims (2)

An input power supply unit for removing noise of a power source applied from the outside; A bridge rectifier for full-wave rectifying the power applied from the input power source; A pressure reducing unit for converting the power applied from the bridge rectifying unit into a driving source of each component unit; A frequency sensing unit converting the power applied to the input power unit into a square wave signal; And an external frequency sensing circuit configured to detect a square wave signal applied by the frequency sensing unit to determine a frequency state of a power source. The method of claim 1 wherein: The frequency sensing unit includes a resistor for reducing a voltage of an input power source; A zener diode that is energized only when the voltage applied to the resistor is greater than or equal to a predetermined voltage; And an external frequency sensing circuit for transmitting the signal energized by the zener diode to a controller using a photo coupler.