KR0130292Y1 - Mode-setting circuit of mounter - Google Patents

Abstract

The present invention relates to a power supply for a monitor, and more particularly, to a mode setting circuit of a monitor that can reduce the power consumption by controlling the transformer at a high speed when the monitor is set to the suspend mode or the off mode. The mode switching signal output unit of the present invention applies the auxiliary voltage of the auxiliary power generating unit directly to the control unit as a feedback voltage by the mode switching signal processed when the monitor suspend mode or off mode is set, so that the mode switching of the monitor can be performed at high speed. It is configured to be made.

Description

Mode setting circuit of monitor

1 is a view showing the configuration of a power supply of a general monitor.

2 is a view showing the configuration of a monitor mode setting circuit according to the present invention.

* Explanation of symbols for main parts of the drawings

10: input voltage rectifier 20: first output unit

30: second output unit 40: voltage recognition unit

50: voltage control unit 60: auxiliary power generating unit

70: power receiving unit 80: mode switching signal output unit

90 control part R81-R84 resistance

Q81, Q82: transistor C81: capacitor

D81: Diode T81: Transformer

The present invention relates to a power supply device for a monitor, and more particularly, to a mode setting circuit of a monitor which can reduce power consumption by controlling transformers at a high speed when the monitor is set to a suspend mode or an off mode.

As shown in FIG. 1, a power supply of a general monitor is composed of a bridge diode (BD) and a condenser (Cin), and after rectifying and rectifying the input AC power (AC), the smoothing of the transformer (T) 1 It consists of an input voltage rectifier 1 applied to the differential coil, a diode Do1, and a capacitor Co1, and smoothes the load after half-wave rectifying the excitation voltage of the secondary coil 1 of the transformer T. The first output unit 2 to be applied to the LD1, the diode Do2, and the capacitor Co2 is smoothed after half-wave rectification of the excitation voltage of the secondary coil 1 of the transformer T. By the output voltage of the second output unit 3 to be applied to the load LD2, the voltage recognition unit 4 that recognizes the output voltage of the first output unit 2, and the voltage recognition unit 4. By the voltage control unit 5 for controlling the output voltage of the output unit 3 and the mode switching signal CL input when the monitor suspend mode or the off mode is set; A mode switching signal switching signal output section 6, a diode D71, and a resistor R71 for processing the output current of the pressure sensing section 4 to be transmitted, and the bridge diode BD of the input voltage rectifying section 1 It consists of an auxiliary power generator 7 for smoothing the output voltage after half-wave rectifying and outputting it to the auxiliary power supply Vcc, and a resistor R81 and a phototransistor PT81. A control signal is generated according to the power receiver 8, which receives the magnitude and controls the output voltage of the auxiliary power generator 7, and the output voltages of the power receiver 8 and the auxiliary power generator 7, The transistor is switched by the control signal, and the control unit 9 controls the current flowing in the primary coil of the transformer T.

Here, the voltage recognizer 4 receives a resistor R41 through which the output voltage of the first output unit 2 is biased, and an output voltage of the resistor R41 to pass the output current of the first output unit 2. A photodiode PD41 for transmission and a resistor R42 for protecting the photodiode PD41.

On the other hand, the mode switching signal output section 6 includes a resistor (R61) (R62) to which the input mode switching signal CL is distributed, and a transistor (Q61) switched by the divided voltage of the resistor (R61) (R62) and Compared to the switching state of the transistor Q61, the output voltage of the photodiode PD41 of the voltage recognition unit 4 is half-wave rectified by the switching state of the transistor Q62 and the transistor Q62, and then the transistor Q62 is applied to the transistor Q62. It consists of a diode D61 to apply.

In the general monitor power supply configured as described above, first, the AC power input is full-wave rectified by the bridge diode BD of the input voltage rectifying unit 1, and the output voltage of the bridge diode BD is a capacitor. It is applied to (Cin) to remove the ripple component.

The output voltage of the capacitor Cin is applied to the primary coil of the transformer T to excite the first coil L1 and the second coil L2 of the transformer T to excite the first coil L1. The excitation voltage of) is half-wave rectified by the diode Do1 and the capacitor Co1 of the first output unit 2, and then the ripple component is removed and applied to the load LD1.

On the other hand, the excitation voltage of the second coil L2 is half-wave rectified by the diode Do2 and the capacitor Co2 of the second output unit 3, and then the ripple component is removed and applied to the second load LD2.

The output voltage of the first output unit 2 is applied to the phototransistor PD41 through the resistor R41 of the voltage recognition unit 4 so that an output current is remotely transmitted to the first output unit 2. The output voltage of the phototransistor PT41 is applied to the capacitor C41 and charged.

The discharge voltage of the capacitor C41 is applied to the voltage control unit 5 to control the output voltage of the second output unit 3 according to the magnitude of the discharge voltage of the capacitor C41.

In addition, the output voltage of the bridge diode BD of the input voltage rectifier 1 is applied to the diode D71 of the auxiliary power generator 7 and half-wave rectified, and the output voltage of the diode D71 is resistor R71. The control unit 9 is driven through the control unit 9 through the control unit 9. That is, a control signal for controlling the current flowing through the one-side coil of the transformer T is generated by the auxiliary power supply Vcc input to the controller 9 to control the current applied to the primary coil of the transformer T. do.

On the other hand, the mode switching signal CL, which is applied to the high potential state when the monitor is switched to the suspend mode or the off mode, is divided by the resistors R61 and R62 of the mode switching output unit 6, and the resistor R61. The division voltage of R62 is applied to the transistor Q61 so that the transistor Q61 is turned on.

In addition, the transistor Q62 is turned on by the switching state of the transistor Q61, and the output current of the phototransistor PT41 of the voltage recognizer 4 half-wave rectified by the diode D61 is a transistor ( It is raised by the switching state of Q62).

At this time, the output current of the phototransistor PT41 increased by the mode switching signal CL input in the high potential state is received by the phototransistor PT81 of the power receiver 8 so that the phototransistor PT81 is turned on. The output voltage Vcc of the auxiliary power generator 6 is applied to the controller 9 through the resistor R81 and the phototransistor PT81 by the turn-on state of the phototransistor PT81.

That is, when the auxiliary power supply (Vcc) is applied to the control unit (9) as a feedback voltage (Vfb), the feedback voltage (Vfb) is raised, so that the control signal output from the control unit (9) is always output in a high potential state, A control signal in a high potential state is applied to the controller 9 so that the current of the primary coil of the transformer T cannot be controlled.

As described above, the mode setting circuit of the general monitor has a problem in that the time taken for the transformer to be controlled when switching the off mode or the suspend mode is complicated, and the monitor can not be short and thin.

Therefore, the present invention is to solve such a problem, an object of the present invention is to apply the auxiliary power of the auxiliary power generating unit directly to the control unit as a feedback voltage, thereby reducing the time for switching the monitor to the set mode to a minimum Therefore, the present invention aims to provide a mode setting circuit of a monitor capable of light and short and short since the circuit configuration is simple.

The object of the present invention as described above is that the mode switching signal input during the mode switching is processed by the mode switching signal output unit, the output current of the voltage recognition unit is variable, the control output from the control unit by the output current of the variable voltage recognition unit In the monitor in which the signal is variable and the amount of current flowing in the primary coil of the transformer is controlled, the auxiliary voltage generator outputs the auxiliary voltage by the mode switching signal that is output when the output unit is set to the monitor suspend mode or the off mode. It can be achieved by providing a mode setting circuit of the monitor, characterized in that the mode switching of the monitor is made to be applied at a high speed by applying directly to the control unit with a feedback voltage.

Hereinafter, an embodiment of a mode setting circuit of a monitor according to the present invention will be described in more detail with reference to the accompanying drawings.

2 is a view showing the configuration of the mode setting circuit of the monitor according to the present invention, as shown in the figure, consisting of a bridge diode (BD) and a capacitor (Cin), the AC power input AC is rectified It is composed of an input voltage rectifier 10, a diode Do1, and a capacitor Co1, which are then smoothed and applied to the primary coil of the transformer T, and the excitation of the secondary coil of the transformer T, the first coil L1. It is composed of a first output unit 20 for smoothing the voltage half-wave rectified and applying it to the load LD1, a diode Do2 and a capacitor Co2, and the secondary coil first coil L2 of the transformer T. And a second output unit 30 for smoothing and applying the excitation voltage to the load LD2, the resistors R41, R42, the photodiode PD41 and the capacitor C41. The output voltage of the second output unit 30 is controlled by the voltage recognizer 40 that recognizes the output voltage of the output unit 20 and the output voltage of the voltage recognizer 40. Comprising a voltage control unit 50, a diode (D61) and a resistor (R61), the output voltage of the bridge diode (BD) of the input voltage rectifier 10 is half-wave rectified and smoothed to output to the auxiliary power supply (Vcc) The auxiliary power generator 60, a resistor R71 and a phototransistor PT71, and a power receiver 70 for receiving the output current of the voltage recognizer 40, and the monitor suspend mode or off mode. After the mode switching signal CL inputted at the time of processing is switched, the mode switching signal output unit 80 and the auxiliary power supply Vcc of the auxiliary power generating unit 60 are applied to the feedback voltage Vfb. Control unit 90 for switching the transistor by the control signal generated to control the current flowing in the primary coil of the transformer (T) in accordance with the output pressure of the power generator 60 and the mode switching signal output unit 80 It is composed.

Here, the mode switching signal output unit 80 includes a transistor Q81 switched by the input mode switching signal CL, a resistor R81 for controlling the output current of the transistor Q81, and a transistor Q81. A capacitor (C81) and a resistor (R82) for shaping the output signal, a transformer (T81) in which the output signals of the capacitor (C81) and the resistor (R82) are applied to the primary coil to excite the secondary coil, and the transformer (T81) Is controlled by an output signal of the diode D81 and the diode D81, and the output voltage Vcc of the auxiliary power generator 60 is controlled by the feedback voltage Vfb. Is applied to the transistor Q82 in which the mode of the monitor is set to the off mode or the suspend mode, a resistor R83 for controlling the driving of the transistor Q82, and a resistor for controlling the output current of the transistor Q82 ( R84).

In the mode setting circuit of the monitor according to the present invention configured as described above, first, the AC power input is full-wave rectified by the bridge diode BD of the input voltage rectifying unit 10, and the bridge diode BD is output. The voltage is applied to the capacitor Cin to remove the ripple component.

The output voltage of the capacitor Cin is applied to the primary coil of the transformer T to excite the first coil L1 and the second coil L2 of the transformer T to excite the first coil L1. ), The excitation voltage is half-wave rectified by the diode Do1 and the capacitor Co1 of the first output unit 920, and then the ripple component is removed and applied to the load LD1.

On the other hand, the excitation voltage of the second coil L2 is half-wave rectified by the diode Do2 and the capacitor Co2 of the second output unit 30, and then the ripple component is removed and applied to the second load LD2.

The output voltage of the first output unit 20 is applied to the photodiode PD41 through the resistor R41 of the voltage recognizer 40 so that the output current of the first output unit 20 is transmitted remotely. The output voltage of the photodiode PD41 is applied to the capacitor C41 and transmitted.

The discharge voltage of the capacitor C41 is applied to the voltage controller 50 to control the output voltage of the second output unit 30 according to the magnitude of the discharge voltage of the capacitor C41.

The output voltage of the bridge diode BD of the input voltage rectifier 10 is half-wave rectified by the diode D61 of the auxiliary power generator 60 and then applied to the controller 90 through a resistor R61. The current flowing in the primary coil of the transformer T is controlled.

When the monitor is set to the on mode, the mode switching signal CL outputted in the low potential state is applied to the transistor Q81 of the mode switching signal output unit 80 so that the transistor Q81 is switched to the turn-off state. The output signal of the transistor Q81 outputted at the low potential state by the turn-off state of the transistor Q81 is shaped by the capacitor C81 and the resistor R82.

The output signals of the capacitor C81 and the resistor R82 are applied to the primary coil of the transformer T81 so that the secondary coil of the transformer T81 is excited, and the secondary excitation voltage of the transistor Q81 is a diode ( Half-wave rectified by D81).

The excitation voltage of the transformer T81 output from the diode D81 in the low potential state is applied to the transistor Q82 so that the transistor Q82 is switched to the turn-off state.

At this time, the output current of the photodiode PD41 of the voltage recognizer 40 is received by the phototransistor PT71 of the power receiver 70, and the feedback voltage determined by the received current amount of the phototransistor PT71 Vfb) is applied to the controller 90 to drive the controller 90.

That is, the control signal generated by the control unit 90 by the feedback voltage Vfb is applied to the transistor of the control unit 90 so that the transistor is switched, and the switching state of the transistor is applied to the primary coil of the transformer T. The amount of current flowing is controlled.

On the other hand, when the monitor is set to the suspend mode or the off mode, the mode switching signal CL outputted in the high potential state is applied to the transistor Q81 of the mode switching signal output unit 80 so that the transistor Q81 is turned on. The output signal of the transistor Q81 which is switched to and is output in a high potential state by the turn-on state of the transistor Q81 is shaped by the capacitor C81 and the resistor R82.

The output signals of the capacitor C81 and the resistor R82 are applied to the primary coil of the transformer T81 so that the secondary coil of the transformer T81 is excited, and the secondary excitation voltage of the transformer T81 is a diode ( Half-wave rectified by D81).

The excitation voltage of the transformer T81 drawn out from the diode D81 in the high potential state is applied to the transistor Q82 so that the transistor Q82 is switched on, and the auxiliary power is generated by the turned on state of the transistor Q82. The output voltage Vcc of the unit 80 is input to the feedback voltage Vfb.

That is, when the monitor mode is set to the suspend mode or the off mode, the feedback voltage Vfb of the control unit 90 rises to the auxiliary power supply Vcc, so that the control signal of the control unit 90 returns to the high potential state. A control signal in a high potential state is output to a transistor of the controller 90 (not shown) so that the transistor is always turned on.

In addition, since the current flowing through the primary coil of the transformer T is not controlled by the turn-on state of the transistor, the excitation voltage of the transformer T is lowered.

As described above, in the mode setting circuit of the monitor according to the present invention, the feedback voltage determined by the received current amount of the voltage recognition unit and the power receiver is not applied to the control unit, and the auxiliary power supply is directly fed back by the mode switching signal. Since the voltage is applied to the controller, the control of the transformer is quickly performed when setting the mode, thereby reducing power consumption to a minimum.

Claims (2)

Since the mode switching signal CL input during the mode switching is processed by the mode switching signal output unit 80, the output current of the voltage recognition unit 40 is variable and is output from the controller by the output current of the variable voltage recognition unit. In a monitor in which a control signal is varied so that the amount of current flowing in the primary coil of the transformer is controlled, the mode switching signal output unit 80 is applied to the mode switching signal CL processed when the monitor is set to the suspend mode or the off mode. The mode setting circuit of the monitor, characterized in that the mode switching of the monitor is configured to be applied at a high speed by applying the auxiliary voltage of the auxiliary power generating unit 60 to the control unit 90 as a direct feedback voltage. The mode switching signal output unit 80 includes a transistor Q81 switched by an input mode switching signal CL, a capacitor C81 and a resistor controlling the output current of the transistor Q81. (R82), the output signal of the capacitor (C81) and the resistor (R82) is applied to the primary coil, the transformer T81 to excite the secondary coil and the diode for half-wave rectifying the excitation voltage of the transformer (T81) (D81) and the output signal of the diode (D81) is switched to apply the output voltage (Vcc) of the auxiliary power generator 60 to the control unit 90 as a feedback voltage (Vfb) to turn off the monitor mode. A transistor Q82 set in a mode or suspend mode, a resistor R83 for controlling the driving of the transistor Q82, and a resistor R84 for controlling the output current of the transistor Q82. Mode change signal of the monitor.