JPH02109109A - Electronic equipment - Google Patents

Abstract

PURPOSE:To prevent the malfunctions of an electronic equipment when a power supply is switched on and off by raising the power supply voltage of a drive circuit up to a drive enable voltage level after the power supply voltage of a control circuit and then a drive signal to be applied to the drive circuit from the control circuit are fixed or setting the drive signal in an unfixed state after the power supply voltage of the drive circuit becomes undrivable. CONSTITUTION:The AC power is supplied to a DC power supply consisting of a line filter 4, a rush current preventing circuit 5, a diode bridge 5, and an electrolytic capacitor 11 via a socket 1, a switch 2, and a fuse 3. The output voltage of the DC power supply is supplied to a PWM control circuit 7 via the resistances 9 and 10. The circuit 7 controls the ON/OFF of a MOSFET 8 based on the information on a phototransistor TR 15 and inputs the information to a transformer 14. The power is surely supplied to the circuit 7 via a coil 16 of the transformer 16. While the intermittent power supplied to the secondary side of the transformer 14 is rectified and smoothed by the diodes 17 and 18, a choke coil 19, and a capacitor 20 and supplied to a drive circuit 30 after the control state is checked by a photocoupler 21.

Description

Detailed Description of the Invention [Industrial Application Field] The present invention relates to an electronic device having a drive circuit that outputs a drive signal required for a predetermined drive section and a drive control circuit that controls the drive circuit. The present invention relates to an electronic device, and particularly to an electronic device equipped with a mechanism for controlling the power supply voltage supplied to each of the circuits.

[Prior Art] Conventionally, in an electronic device having the above-mentioned drive circuit and drive control circuit, when sequentially controlling the power supply voltage supplied to each circuit, the power supply voltage of the drive control circuit is controlled in order to prevent the drive circuit from malfunctioning. After this is determined, the drive control circuit outputs a signal for starting the drive power supply, and the power supply for the drive circuit is started only after that signal is output. Furthermore, when turning down the power supply, the signal causes the drive circuit power supply to be turned down faster than the control circuit TL source.

[Problems to be Solved by the Invention] As described above, in the conventional electronic device 6, it is necessary to separately provide a power supply for the drive circuit and a power supply for the drive control circuit.
One drawback was that the configuration was complicated and expensive.

Therefore, in view of the above points, an object of the present invention is to provide an electronic device that includes a drive circuit and a drive control circuit, with a configuration of power supply supplied to each circuit. +1 It is an object of the present invention to provide an electronic device θ which is simple and does not require any translational operation of a drive circuit.

[Means for Solving the Problems] In order to achieve the above object, the present invention provides a drive means for outputting a drive signal required for a predetermined drive section, and a drive control means for controlling the drive means. In the electronic device having the above, as the power supply voltage of the drive means rises, the electric FA voltage of the control means rises R1, and the drive control means becomes l1i11.
# As soon as it becomes possible, set the power supply voltage of the drive means to a predetermined value! ! ! The device is equipped with power supply voltage control means for increasing the voltage.

[Function J] According to the present invention, after the power supply voltage of the drive control means is determined and the control signal from the drive control means to the drive means is determined,
This is to raise the power supply voltage of the driving means to a voltage level that allows driving.

[Example] An embodiment of the present invention will be described below.

FIG. 1 shows a power supply section of an image forming apparatus to which the present invention is applied. In this power supply section, A
The C power supply passes through a switch 2, a fuse 3, a line filter 4, an inrush current prevention circuit 5, and a diode bridge 6.
and an electrolytic capacitor 11 to provide a DC power source.

The above-mentioned DC power is supplied to the PWM control circuit 7 through a resistor 9.10, and the MOS FET 8 is controlled on/off based on information from the phototransistor side 15 of the photocoupler, and the power is intermittently supplied to the secondary side via the transformer 14. to supply power. When this operation starts, an electromotive force is generated in the coil 16 wound around the transformer 14, and a reliable power supply is performed as a control power source for the PWM control circuit 7.

Note that the diode 12 and Zener diode 13 are
This is a circuit for making the electromotive force generated when the power MOS FET 8 turns off to a level higher than the withstand voltage of the power MOS FET.

The intermittent power supplied to the secondary side is connected to the diode 17.1
8, a Duke coil 19, and a capacitor 20 to rectify and smooth the signal, and serve as a driving power source 17. The voltage of this drive power source is divided by the variable resistor 23 and resistors 24, 25, and 26, and is input to the reference terminal of the shunt regulator 22. The shunt regulator 22 controls the voltage between the cathode and the anode based on the voltage information of the reference terminal. As a result, the current on the light emitting diode side 21 of the photocoupler is controlled, and voltage information of the drive power source on the secondary side is fed back to the PWM control circuit 7, so that the
The voltage of the drive power source on the secondary side is controlled to be constant.

On the other hand, the drive power source is choke coil 3 and capacitor 32.
, and is turned on and off by the transistor 34.

Furthermore, it is smoothed by a diode 35, a choke coil 3, and a capacitor (16), and becomes a control power source.The voltage of this control power source is fed back to a PWM control circuit 33, and changes the on/off ratio (decoding) of a transistor 34. As a result, the power of the control power source is controlled to be kept constant.

Furthermore, the control power is passed through the Zener diode 29]
・Fjl and l are connected to the base of transistor 27.

When the voltage of the control voltage exceeds the voltage that can be controlled by the control device, the current of the Zener diode 29 increases, the voltage across the resistor 28 and the capacitor 39 rises, and the base current of the transistor 27 flows. This results in resistance 26
The voltage across the transistor 27 drops to the saturation voltage between the collector and emitter of the transistor 27.

As a result, the reference terminal voltage of the shunt regulator 22 drops. In order to compensate for this drop, the voltage of the drive power supply is increased.

The above series of operations will be explained in more detail based on FIG. 2.

In the time-varying jljo, when the switch 2 is turned on, the voltage 102 of the drive power source and the voltage 101 of the control TrL source are "-
Start shoulders.

At time [1, the voltage 102 of the drive power supply is applied to the variable resistor 2
The voltage is controlled by the voltage divided by 3 and resistors 24, 25, and 26. However, at this time, the voltage 1[11 of the control power supply has not yet reached a voltage at which the $lJ control device can be controlled.

At time t, the voltage +01 of the control power supply is applied to the control device 3.
When the controllable tt voltage of 8 is reached, the transistor 27 is turned on as described above, and the drive power supply starts again in the upper layer, and the variable resistor 23 and the resistor 24.25 and the saturation voltage between the collector and emitter of the transistor 7 The voltage increases to the voltage controlled by the voltage divided by the voltage.

At time t, the drive device exceeds the threshold voltage Va,I that enables driving, but at this time the control power supply voltage 1 has already been exceeded.
01 is a voltage that can be controlled by the $11 control device 38.

At time aJL, when the switch 2 is turned off, the voltage 102 of the drive power source starts to fall.

At time [5, the driving device 30 becomes driveable threshold voltage vyu or lower, but at this time, the voltage 101 of the control power source is still at a voltage that can be controlled by the control device.
At time t6, the voltage +01 of the $IJ power supply starts to fall.

FIG. 3 shows a threshold circuit of the drive device. The voltage 102 of the driving power supply is the threshold voltage V. 1. When the voltage becomes higher, the N current of the Zener diode 3201 increases, and when both e4 voltages of the resistor 202 rise, the base current of the transistor 203 flows. Then, the transistor 2 is connected through the resistor 204.
The base current of No. 05 flows, the transistor 205 is turned on, and the solenoid 207 and motor 209 can be driven, and operate in response to drive No. 15 from the control device.

When the threshold voltage VTI+ is higher than the threshold voltage VTI+, the transistor 203
, 205 are in the off state, and even if drive No. 15 is manually operated from the control device, the solenoid 207. Motor 209 does not operate.

Further, the threshold voltage v14. The voltage of solenoid 207
, it goes without saying that a threshold circuit as shown in FIG. 3 is unnecessary if the voltage is set to a sufficiently low level that the motor 209 cannot be driven.

FIG. 4 shows a second embodiment to which the present invention is applied. On the tree layer side, the AC power input from socket]・1 passes through switch 302 and fuse 303, and then connects to lance 3.
04. On the secondary side of the transformer 304, a driving power source is created by a diode bridge 305 and a capacitor 306.

This power supply is for driving solenoids, motors, etc.
Constant voltage is not so necessary. Furthermore, the driving power supply is used to create a control power supply through a transistor 307. The transistor 307 is connected to the driving power source 401 based on the voltage determined by the Zener diode 309 and the resistor 308.
It operates more as a series dropper.

The sequential operation of the power supply constructed in this way will be explained based on FIG. 5.

Time t. When the switch 302 is turned on, the driving voltage 402 becomes -)==. Along with this, the control voltage 401 also increases.

At time 12, resistor 308. zener diode 30
When the drive voltage 402 is applied to the voltage determined by the resistor 308.9, the control voltage is applied to the resistor 308. It is clamped to a voltage determined by a Zener diode 30.

When the time is reached, the odor C and the driving voltage 402 are at the threshold voltage V.
Although it exceeds TI+, at this time the control pressure 401 has already reached a voltage that can be controlled by the control device 311.

At time t4, when switch 302 is turned off, drive voltage 402 begins to fall.

At time [5], the drive device 312 becomes driveable and becomes equal to or lower than the threshold voltage vT□, but at this time the control voltage 401
is still at a voltage that can be controlled by the control device, and at time L
At 6, the control voltage 401 begins to fall.

[Effects of the Invention] As described above, according to the present invention, after the power supply voltage of the control circuit is determined and the drive signal from the control circuit to the drive circuit is determined, the drive! After the voltage of the I'JJ circuit increases to +8 to a driveable voltage level and the power supply voltage of the drive circuit becomes undriveable, the following drive is performed.

Since the signal is uncertain, it is possible to prevent malfunctions of the power on/off switch, the motor, etc.

Furthermore, as described as an embodiment of the present invention, by providing the threshold voltage circuit in the drive circuit, complicated sequential control of the power supply is eliminated and the power supply configuration is made into components.
A low-cost electronic device θ can be obtained.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram showing an embodiment of a power supply section in an image forming apparatus to which the present invention is applied, FIG. 2 is a diagram showing the operation of FIG. 1, and FIG. 3 is an example of a threshold circuit. FIG. 4 is a circuit diagram showing another embodiment of a power supply unit included in an image forming apparatus to which the present invention is applied, and FIG. 5 is a diagram showing the operation of FIG. 4. I...Socket 1-2...Switch, 3...Fuse, 4...Line filter, 5...Inrush current prevention circuit, 6...Diode bridge, 7...PWM control circuit , 8...B'7-MOS FET. 9, IO...Resistor, 11...Capacitor, 12...Diode, 13...Zener diode, 14...Transformer, 15...Photocoupler (photodiode side), 16...
・Winding, 17...Diode, 18...Diode, 19...Choke transformer, 20...Capacitor, 2]...Ho 1~Cobra (light emitting diode side), 22...
... Shunt regulator, 23... Variable resistor, 24.25.26... Resistor, 27... Transistor, 28... Resistor, 29... Zener diode, 30... Drive equipment, 31 ...Choke transformer, 32...Capacitor, 33...PWM control circuit, 34...Transistor, 35...Diode, 36...Capacitor, 37...Choke] Lance, 38... -Control device, 39... Capacitor, 101... Control voltage, +02... Drive voltage, ... 1. ...Zener diode I, ...1st generation resistor, ...l-Linsistor, ...resistor, ...Linsistor, ...Dior-1, ...・)ノL/, Noid, ... Transistor, ... Dryer, ...] Synister, ... Socket, ... Switch, ... Hikozu, ... Transformer, ... Bridge, ... capacitor, ... 1-transistor, ... resistor, ... Zener diode, ... capacitor, ... control device, ... drive device -1 ... ffJI electric sweat, ... drive voltage, ... 1 threshold' Holo-9

Claims (1)

[Scope of Claims] 1) An electronic device having a drive means for outputting a drive signal required for a predetermined drive unit, and a drive control means for controlling the drive means, wherein the power supply voltage of the drive means is power supply voltage control means for raising the power supply voltage of the drive means above a predetermined reference voltage when the power supply voltage of the drive control means rises and the drive control means becomes controllable. An electronic device featuring: 2) Once the power supply voltage of the drive means becomes equal to or higher than the reference voltage, the drive control means controls the power supply voltage of the drive control means until the power supply voltage of the drive means becomes equal to or less than the reference voltage. 2. An electronic device as claimed in claim 1, characterized in that the electronic device is held in such a way that it can be held in place. 3) The electronic device according to claim 1, wherein the power supply voltage of the control means is formed based on the power supply voltage of the drive means.