JP2008172914A - Power supply device and image forming device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power supply device which can reduce wasteful power consumed in a zero-cross detection part, and an image forming device using the power supply device. <P>SOLUTION: The power supply device comprises: DC power supply parts 103, 104 which convert AC inputs into direct currents; a first converter 105 which converts the output power of the DC power supply parts to the DC power of a voltage different from that of the output power, and operates even at the standby of a load; a second converter 401 which is connected to the DC power supply parts, converts the output power of the DC power supply parts to the DC power of a voltage different from that of the output power, and stops at the standby of the load; and the zero-cross detection part 201 which detects a zero-cross point of the AC input by receiving power supply from the second converter. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a power supply device with a zero-cross detection circuit suitable for an image forming apparatus, and more particularly to reduction of power consumption of the zero-cross detection circuit. The zero cross detection circuit is a circuit that detects a zero cross point of the AC power source, that is, a timing of 0 degrees and 180 degrees of the AC phase, and is also referred to as a phase detection circuit.

Recently, power consumption during standby of an image forming apparatus has been standardized as an international energy saving standard such as Blue Angel or Energy Star.
Reducing standby power consumption is a major theme when developing an image forming apparatus, and is a factor that significantly increases the commercial value of the image forming apparatus.

FIG. 9 is a diagram illustrating an example of a power supply device and a zero-cross detection circuit in a conventional image forming apparatus. Hereinafter, this conventional apparatus and circuit will be referred to as Conventional Example 1.
In the figure, 101 is an AC inlet, 102 is a common mode coil, 103 is a rectifier diode bridge, and 104 is a primary smoothing electrolytic capacitor.

Reference numeral 105 denotes a converter A power source. As an example, a flyback power supply is illustrated.
The converter A power source 105 includes the following components.
106 is a starting resistor, 107 is a switching FET, 108 is a power supply IC, 109, 110, 111, 121, 122, 125 and 126 are resistors, 112 and 119 are diodes, and 113 and 123 are capacitors. 114 is a transformer, 115 is a primary winding of the transformer, 116 is an auxiliary winding of the transformer, 117 is a secondary winding of the transformer, 120 is a smoothing capacitor, 118 is a photocoupler, and 124 is a shunt regulator.

201 is a zero cross detection circuit.
The zero cross detection circuit 201 includes the following components.
Reference numerals 202, 203, 204, 207, and 208 denote resistors, 205 denotes a capacitor, 206 denotes an NPN transistor, 209 denotes a photocoupler, and 210 denotes an output terminal of a zero-cross detection signal.

Reference numeral 301 denotes a stop signal circuit of the converter B.
The stop signal circuit 301 of the converter B includes the following components.
Reference numerals 302 and 306 denote NPN transistors; 303, 305, 307 and 308, resistors; 304, a photocoupler; and 309, an input terminal for a converter B stop signal.

401 is a converter B power supply. A forward type power supply is illustrated as an example.
Converter B power supply 41 includes the following components.
Reference numeral 402 denotes a power supply IC, 403, 405, 413, 414, 417 and 418 are resistors, 404 is a switching FET, 406 is a transformer, 407 is a primary winding of the transformer, and 408 is a secondary winding of the transformer. 409 is a diode array, 410 is a choke coil, 411 is a smoothing capacitor, 412 is a photocoupler, 415 is a capacitor, and 416 is a shunt regulator.

As a normal operation, the commercial AC power input from the AC inlet 101 passes through the common mode coil 102 and the rectifier diode bridge 103 and is full-wave rectified and smoothed to the primary smoothing electrolytic capacitor 104.
Apart from this, for the converter A, the commercial AC power source that has passed through the common mode coil 102 passes through the starting resistor 106, starts the power source IC 108, operates the switching FET 107, and operates by passing a current through the transformer 114. To start.

When the transformer 114 operates, the power supply voltage generated by the auxiliary winding 116 of the transformer is supplied to the power supply IC 108, and the power supply IC 108 can continue to operate. As a result, the switching FET I07 can be switched, and the transformer 114 can continue to operate stably.
Further, the secondary voltage output from the secondary winding 117 of the transformer 114 is rectified by the rectifier diode 119, smoothed by the smoothing capacitor 120, and the DC output Va can be output.

The voltage control of the DC output Va is performed as follows.
By inputting a voltage obtained by dividing the DC output Va by the resistor 125 and the resistor 126 to the shunt regulator 124, a current flows from the DC output Va to the LED of the photocoupler 118 via the resistor 121.
Thus, a collector current can flow to the phototransistor side of the photocoupler 118, and a feedback potential is created by changing the terminal voltage of the power supply IC 108 to which the photocoupler 118 is connected.
This change in the feedback potential becomes a main trigger for changing the switching duty and switching frequency of the switching FET 107, and the stable DC output Va can be controlled.
The resistor 122 and the capacitor 123 perform phase compensation in the series of feedback loops described above.
The operation of the converter A power source 105 has been described above.

Next, the operation of converter B power supply 401 will be described.
The power supply IC 402 is activated via the transistor 302 using the transformer auxiliary winding 116 of the converter A power supply 105 as a power supply source.
When the power supply IC 402 is activated, the switching FET 404 is operated, and a current is passed through the transformer 406, so that the operation can be started and a stable operation can be continued.
Further, the secondary voltage output from the secondary winding 408 of the transformer 406 is rectified by the diode array 409, smoothed by the smoothing capacitor 411, and the DC output Vb can be output.

The voltage control of the DC output Vb is performed as follows.
By inputting a voltage obtained by dividing the DC output Vb by the resistors 417 and 418 to the shunt regulator 416, a current flows from the DC output Vb to the LED of the photocoupler 412 via the resistor 413.
Thus, a collector current can be allowed to flow to the photodiode side of the photocoupler 412, and a feedback potential is created by changing the terminal voltage of the power supply IC 402.
This change in the feedback potential becomes a main trigger for changing the switching duty and switching frequency of the switching FET 404, and the stable DC output Vb can be controlled.
The resistor 414 and the capacitor 415 perform phase compensation in the series of feedback loops described above.

Next, the zero cross detection circuit 201 performs the following operation.
In the zero-cross detection circuit 201, the AC voltage before rectification of the rectifier diode bridge 103 is a power source to be detected.
This power supply is divided by the resistor 202 and the resistor 203, passes through the CR filter composed of the resistor 204 and the capacitor 205, is supplied to the base of the transistor 206, and allows the collector current to flow or cut off. It becomes.
From this, it is also possible to flow the current on the LED side of the photocoupler 209 or to cut it off. Further, upon receiving the light on the LED side of the photocoupler 209, the phototransistor side of the photocoupler 209 can flow the collector current or shut off, and as a result, it can output a zero cross detection signal. Become.
At this time, the power source of the transistor 206 is a power source composed of the auxiliary winding 116 of the transformer 114 of the converter A power source 105.
Further, the power source of the collector current on the phototransistor side of the photocoupler 209 is the DC output Va of the converter A power source 105.

  Next, the converter B stop signal circuit 301 is a circuit that enables the converter B to be operated or stopped by an external signal outside the power supply apparatus when the converter A power source 105 is operating.

  An outline of circuit operation when the converter B power supply 401 is stopped / outputted will be described below.

When stopping the output of the converter B power source 401, the converter B stop signal input terminal 309 in the converter B stop signal circuit 301 is set to the GND level.
By doing so, the collector current cannot flow through the transistor 306, the LED of the photocoupler 304 is caused to emit light, and the collector current flows through the phototransistor side of the photocoupler 304.
As a result, the transistor 302 cannot pass the collector current, and the power supply to the power supply IC 402 of the converter B power supply 401 is stopped. As a result, the converter B power supply 401 stops outputting.
Note that a terminal to which the emitter side of the transistor 302 and the power supply IC 402 are connected is a power supply terminal of the power supply IC 402.

When the converter B power supply 401 is output, the converter B stop signal input terminal 309 is set to the HI level.
In this case, the input terminal 309 for the converter B stop signal needs to have an HI level that allows the collector current of the transistor 306 to flow.
By doing so, the transistor 306 causes a collector current to flow, and the LED of the photocoupler 304 is not illuminated.
As a result, the transistor 302 can flow a collector current, the converter B power supply 401 can be fed to the power supply IC 402, and the converter B power supply 401 performs an output operation.

As a supplement, the image forming apparatus of Conventional Example 1 uses an electrophotographic process to transfer a toner image onto a recording material such as paper, and heat-fixes the transferred image with a fixing roller. Device.
For this reason, when the transfer image is heat-fixed by the fixing roller, the commercial AC phase control is used to control the temperature of the fixing heater in the fixing roller. Therefore, the zero cross detection signal for detecting the zero cross point of the commercial AC voltage is a necessary signal. is there.
Also, the zero cross detection signal is a signal that is not necessary during standby for image formation.

The converter B power supply is a power supply that is not necessary when the image forming apparatus is in standby for image formation, and it is assumed that the converter B power supply operates during image formation and is stopped during standby for image formation.
The purpose of stopping is to reduce power consumption during standby for image formation.

FIG. 10 shows the configuration of the laser beam printer of Conventional Example 2. First, an image forming operation will be described.
The AC voltage supplied from the commercial AC power supply 1 is supplied to the low voltage power supply 3, the zero cross detection circuit 8, and the fixing power supply 6 through the main switch 2.

The low-voltage power supply 3 transforms commercial AC voltage into DC voltages Vs and Vp.
Vs is a power supply voltage for the control unit 5, and Vp is a power supply voltage for the drive unit 4.
The control unit 5 includes an image processing device that modulates image data supplied from the outside into a laser emission pattern, a logical operation device that controls an actuator, and the like.
The drive unit 4 includes an actuator such as a motor that performs paper conveyance and image forming operations, a high-voltage power source that develops a latent image drawn by a laser into a toner image, and transfers the toner image onto a paper surface.

  The zero-cross detection circuit 8 is a module that detects the voltage phase of the commercial AC voltage, and the output signal ZEROX is supplied to the control unit 5. The control unit 5 controls the driving timing of the fixing power source 6 based on the ZEROX signal.

The fixing power source 6 turns on / off commercial alternating current and supplies it to the fixing device 7.
In the fixing device 7, two opposing fixing rollers 9, 10 are arranged.

In the fixing roller 9, a heater 11 as a heating resistor and a temperature sensor (not shown) for detecting the temperature of the fixing roller 9 are arranged. The output signal of the temperature sensor is supplied to the control unit 5. A heater drive signal FSRD is supplied from the controller 5 to the fixing power source 6. Based on the output signal of the temperature sensor, the control unit 5 turns on / off the output of the fixing power source 6 in order to keep the temperature of the fixing roller 9 constant.
The toner image transferred on the paper surface is melted by the opposing pressure of the fixing rollers 9 and 10 and heat, and is fixed on the paper surface.

Hereinafter, the detailed configuration and operation of each module will be described.
The low-voltage power supply 3 will be described.
When the user turns on the switch 2, a commercial AC voltage is supplied to the diode bridge 12. The diode bridge 12 rectifies the commercial AC voltage and supplies it to the primary smoothing capacitor 13 at the subsequent stage.
The primary smoothing capacitor 13 smoothes this voltage and supplies it to the FET 16 via the primary winding 15p1 of the transformer 15. On the other hand, the terminal voltage of the primary smoothing capacitor 13 is also supplied to the startup terminal Vst of the PWM module 17 via the starting resistor 14.
When a voltage is supplied to the startup terminal Vst, the PWM module 17 starts switching of the FET 16. Then, a pulse voltage is induced in the secondary winding 15s of the transformer 15 and the auxiliary winding 15p2.

The pulse voltage induced in the secondary winding 15s is rectified and smoothed by the diodes 28 and 29 and the secondary smoothing capacitors 30 and 31, and becomes DC voltages Vp and Vs.
On the other hand, the pulse voltage induced in the auxiliary winding 15p2 is rectified and smoothed by the diode 18 and the capacitor 20 to become a DC voltage Vic. This Vic is supplied to the power supply terminal Vcc of the PWM module 17. Generally, when the terminal voltage of Vcc reaches a specified value or more, the PWM module cuts off the current flowing from the startup terminal Vst inside the module.

The zero cross detection circuit 8 will be described.
The commercial AC voltage is supplied to the base terminal of the transistor 25 via the resistor Rin (21). A DC voltage Vic is supplied to the collector terminal of the transistor 25 via the resistor 24. On the other hand, the collector terminal of the transistor 25 is connected to the anode terminal of the LED in the photocoupler 26.

  The emitter terminal of the transistor 25 and the cathode terminal of the LED in the photocoupler 26 are connected to the negative terminal of the primary smoothing capacitor 13. The secondary side terminal of the photocoupler 26 is supplied to the control unit 5 as a ZEROX signal.

  In the circuit configuration described above, when the commercial AC voltage Vac is positive (FIG. 11, t1 to t2), the transistor 25 is turned on, and the emitter-collector voltage becomes substantially zero. As a result, the terminal voltage of the LED in the photocoupler 26 is also substantially zero, so the LED is turned off. Therefore, the ZEROX signal becomes H level.

  When the commercial AC voltage Vac is negative (FIG. 11, t2 to t3), the transistor 25 is turned off. Then, the current that has been flowing to the transistor 25 until then flows into the LED in the photocoupler 26, and the LED emits light. As a result, the ZEROX signal becomes L level.

  That is, the rising edge of the ZEROX signal represents the phase of commercial AC power supply voltage 0 °, and the falling edge represents the phase of commercial AC power supply voltage 180 °. Such phase information is used for ON / OFF control of the fixing power source 6 described later (Patent Document 1).

The fixing power source 6 will be described.
The commercial AC L1 phase is directly connected to the heater 11. The other end of the heater 11 is connected to the T2 terminal of the triac 34. The T1 terminal of the triac 34 is connected to the L2 phase of commercial AC. A resistor 33 and a phototriac coupler 35 are connected between the T2 and G terminals of the triac 34. A transistor 38 is connected to the LED side of the phototriac coupler 35. The heater drive signal FSRD is supplied from the control unit 5 to the base of the transistor 38 via the resistor 37.

When the control unit 5 sets the FSRD signal to the H level in the above circuit, the transistor 38 is turned on, the LED of the phototriac coupler 35 emits light, and the phototriac coupler 35 is turned on.
Then, the voltage divided by the resistors 32 and 33 is applied to the G terminal of the triac 34, and the triac 34 is turned on. As a result, a commercial AC voltage is applied to the heater 11 (t1 in FIG. 12).

  Conversely, when the control unit 5 sets the FSRD signal to the L level, the phototriac coupler 35 is turned off, and the G terminal of the triac 34 is pulled down to the T1 terminal by the resistor 32. However, since the triac 34 is a thyristor element, once it is turned on, it cannot be turned off while the current is flowing (t2 in FIG. 12). It turns OFF when the phase of the commercial AC voltage is around 0 ° and the current becomes almost zero (the holding current value or less). As a result, energization of the heater 11 is stopped (t3 in FIG. 12).

The controller 5 adjusts the ON time of the fixing power source 6 so as to keep the temperature of the fixing roller 9 constant.
Specifically, the phase angle of the commercial AC voltage supplied to the heater 11 is controlled. In order to perform this energization phase angle control, the aforementioned ZEROX signal is used.
JP 2006-126657 A

An image forming apparatus equipped with a power supply device having a zero-crossing detection circuit that is capable of stopping and operating one converter with an external signal using the two-converter system as described in the conventional example 1 is not required when waiting for image formation. The image forming apparatus consumes a large amount of power.
This is because the zero-cross detection circuit continues to operate even when one converter is stopped during image formation standby, even though the zero-cross detection signal is unnecessary.

The conventional example 2 also has the following problem.
For example, as described above, a low-voltage power supply configured to cut off a current flowing from the start-up terminal Vst when the voltage of the power supply terminal Vcc of the PWM module 17 reaches a predetermined value or more is well known.
Commercial AC voltage is a relatively high voltage. Therefore, the power consumption at the starting resistor 14 is relatively large. By cutting off the current flowing from the start-up terminal Vst after starting the low-voltage power supply, useless power consumption at the starting resistor 14 can be suppressed.

However, in the commercial AC voltage zero-cross detection circuit, power consumption at the input resistor Rin (21) always occurs.
As shown in FIG. 11, the half-wave voltage of the commercial AC power supply is always applied to Rin (21). Commercial AC voltage is a relatively high voltage. Therefore, the power consumption at Rin (21) is relatively large.

  For example, the commercial AC voltage in Europe is about AC 240 Vrms, and a resistance element of about 100 KΩ is generally used for the input resistance Rin (21). Therefore, in Rin (21), about 0.3 W of power (= 240 V × 240 V ÷ 100 KΩ / 2) is always consumed.

  SUMMARY An advantage of some aspects of the invention is that it provides a power supply device that can reduce wasteful power consumed by a zero-cross detection unit and an image forming apparatus using the power supply device. To do.

  In order to solve the above problems, in the present invention, the power supply device is configured as described in the following (1) to (3), and the image forming device is configured as described in the following (4).

  (1) A DC power supply unit that converts AC input to DC, and connected to the DC power supply unit, converts the output power of the DC power supply unit to DC power of a voltage different from the voltage, and operates even during standby of a load A first converter that is connected to the DC power supply unit, converts the output power of the DC power supply unit into DC power of a voltage different from the voltage, and stops during standby of the load; A power supply device comprising: a zero cross detection unit that receives power supply from the second converter and detects a zero cross point of the AC input.

  (2) A DC power supply unit that rectifies an AC input by a rectifier diode bridge and converts it to DC, and a converter that is connected to the DC power supply unit and converts output power of the DC power supply unit into DC power having a voltage different from the voltage. And a series circuit of a diode, a current detection element, and a DC constant voltage source connected in parallel to one side of the rectifier diode bridge, and a zero cross point of the AC input based on the current detected by the current detection element And a zero cross detection unit for detecting a power supply.

  (3) A DC power supply unit that rectifies an AC input by a rectifier diode bridge and converts it into DC, and is connected to the DC power supply unit, and converts output power of the DC power supply unit into DC power having a voltage different from the voltage. A first converter that operates even during standby of a load, and is connected to the DC power supply unit, and converts output power of the DC power supply unit to DC power having a voltage different from the voltage, and stops during standby of the load. A second converter; and a series circuit of a diode, a current detection element, and a DC constant voltage source connected in parallel to one side of the rectifier diode bridge, the power source of the current detection element and the DC constant voltage source being A power supply apparatus comprising: the second converter; and a zero-cross detection unit that detects a zero-cross point of the AC input based on a current detected by the current detection element.

  (4) An image forming apparatus including the power supply device according to any one of (1) to (3) and a fixing device whose temperature is controlled by a thyristor element, wherein the thyristor element is the zero-cross detection unit. An image forming apparatus in which the conduction phase angle is controlled with reference to the zero cross point detected in step 1.

  ADVANTAGE OF THE INVENTION According to this invention, the effect of an energy saving can be raised by suppressing the unnecessary power consumption in the power supply device with a zero cross detection part.

  Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to an embodiment of an image forming apparatus.

  FIG. 1 is a circuit diagram illustrating a configuration of a power supply device in an “image forming apparatus” according to a first embodiment.

  In the figure, the operation outline of each of converter A power supply 105, converter B power supply 401, zero cross detection circuit 201, and converter stop signal circuit 301 is the same as that described in the conventional example 1, and therefore description thereof will not be repeated. To.

Prior to the description of FIG. 1 showing the main part of the present embodiment, the configuration of the image forming apparatus will be briefly described with reference to FIG.
FIG. 2 is a cross-sectional view schematically illustrating a configuration of the entire image forming apparatus according to the first embodiment.
In the figure, 1101 is an image forming apparatus, 1127 is a manual paper feed tray, 1102 is a paper cassette, 1103 is a paper feed roller, 1104 is a transfer belt driving roller, 1105 is a transfer belt, and 1106 to 1109 are yellow, magenta, cyan, and black. It is a photosensitive drum. Reference numerals 1110 to 1113 denote transfer rollers, 1114 to 1117 denote yellow, magenta, cyan, and black cartridges, and 1118 to 1121 denote yellow, magenta, cyan, and black optical units. Reference numerals 1122 and 1123 denote fixing pressure rollers of the fixing unit, 1124 denotes a registration shutter, 1125 denotes a recording material, and 1208 denotes an operation panel unit.

The image forming apparatus 1101 transfers an image of yellow, magenta, cyan, and black on a recording material 1125 using an electrophotographic process, and heat-fixes the toner image with fixing rollers 1122 and 1123 based on temperature control.
The optical units 1118 to 1121 for each color are configured to form a latent image by exposing and scanning the surfaces of the photosensitive drums 1106 to 1109 with a laser beam. In a series of these image forming operations, scanning control is performed in synchronization so that an image is transferred from a predetermined position on the recording material 1125 being conveyed.

  Further, the image forming apparatus 1101 includes a paper feed motor that feeds and conveys the recording material 1125, a transfer belt drive motor that drives the transfer belt drive roller, and a photosensitive drum drive motor that drives each color photosensitive drum and the transfer rollers 1110 to 1113. I have. Further, a fixing drive motor for driving the fixing pressure roller 123 is provided.

A control CPU (not shown) provided in the image forming apparatus 1101 applies a desired amount of heat to the recording material 1125 by the fixing unit, thereby fusing and fixing the toner image on the recording material 1125.
As option settings, an option cassette 1126 and a duplex option 1128 are provided.

  In FIG. 2, the display of the power supply unit is omitted, but the power supply unit supplies power to the first converter that supplies power to the control CPU or the like that operates even during standby, and the image forming unit that stops during standby. A second converter is provided.

Next, referring to FIG. 1, a power supply apparatus, which is a main part of the present embodiment, will be described. The circuit components changed or added as compared with the conventional example 1 shown in FIG. 9 are as follows.
-Transformer 501 of the changed component converter B power supply 401 (primary winding 502, auxiliary winding 503, secondary winding 504)
・ Additional parts capacitor 505, resistor 506, diode 507

  The feature of the first embodiment is that the transformer 501 of the converter B power supply has an auxiliary winding 502 unlike the conventional example 1, and rectifies the power generated by the auxiliary winding 502 by the diode 507 and charges the potential charged by the capacitor 505. The power source of the zero cross detection circuit 201 is used. Further, it is also characterized in that the DC output Vb of the converter B power supply is used as a power supply for the collector current flowing through the photocoupler 209 of the zero cross detection circuit 201.

That is, the zero-cross circuit 201 that uses the converter A power source 105 as the power source in the first conventional example is changed to use the converter B power source 401 as the power source in the first embodiment.
With such a configuration, when the operation of the converter B power supply 401 is stopped, the power supplied by the converter B power supply 401 among the power supply used for the zero cross detection circuit 201 is stopped.

  In this way, it is possible to reduce the following power among the power consumed by the zero cross detection circuit 201.

  Power consumption due to current flowing from the resistor 207 to the photocoupler 209 (LED side) or from the resistor 207 to the transistor 206. Further, power consumption due to a current flowing through the resistor 208 to the photocoupler 209 (phototransistor side). These can be suppressed.

  However, in the first embodiment, since the power consumption due to the current flowing through the voltage dividing resistor of the resistor 202 and the resistor 203 cannot be reduced from the commercial AC power supply, the power consumption of the zero cross detection circuit 201 has not been completely reduced.

Next, taking the conventional example 1 as an example, the power consumed unnecessarily when the converter B power supply 401 is stopped will be roughly estimated.
In FIG. 9, the voltage generated in the auxiliary winding 116 and stored in the capacitor 113 is 20 V, the resistor 207 is 4.7 KΩ, the DC output Va of the converter A power source 105 is 3.3 V, and the resistor 208 is 1 KΩ. Also, the current flowing out of the output terminal 210 of the zero cross detection signal is ignored, the duty ratio of the zero cross detection circuit is 50%, the forward voltage on the LED side of the photocoupler 209 is 1 V, and the conversion efficiency from the primary circuit to the secondary circuit is increased. Approximate the power when 70%.
The power consumption in terms of primary power is (primary circuit: 83 mW) + (secondary circuit: 11 mW → primary circuit conversion 15.7 mW) = 98.7 mW≈100 mW.

  In the first embodiment, such unnecessary power can be reduced, and as a result, power consumption can be suppressed.

  As described above, according to this embodiment, when the operation of the converter B is stopped during standby for image formation, it is possible to partially reduce the power consumed unnecessarily by the zero cross detection circuit. Become.

FIG. 3 is a circuit diagram illustrating a configuration of the power supply device in the “image forming apparatus” according to the second embodiment.
The difference from Example 1 is that
-The transistor 302 which is a component of the converter B stop signal circuit is deleted.
The power supply IC 402 of the converter B power supply 401 is a type having an operation stop signal terminal.
These are two points.
Further, as a feature of the second embodiment, by controlling the operation stop signal of the power supply IC 402 of the converter B power supply 401 by the converter B stop signal, the output stop / output operation of the converter B power supply 401 is controlled by an external signal. It is possible to control.
In FIG. 3, when one terminal of the power supply IC 402 to which the collector side of the phototransistor of the photocoupler 601 is connected is an input terminal for the operation stop signal of the power supply IC 402 and the operation stop signal is at the GND level, the operation of the power supply IC 402 is performed. Stops. On the other hand, when it is not at the GND level, the operation of the power supply IC 402 does not stop and operates normally.

Next, the operation outline of the second embodiment will be described below by dividing it into output stop / output operation of the converter B power supply.
When stopping the output of the converter B power supply 401, the converter B stop signal input terminal 309 of the converter B stop signal circuit 301 is set to the GND level.
By doing so, the collector current cannot flow through the transistor 306, but the LED of the photocoupler 601 emits light, and the collector current flows through the phototransistor side of the photocoupler 601.
As a result, the operation stop signal terminal of the power supply IC 402 becomes the GND level, and the converter B power supply 401 stops outputting.
When the converter B power supply 401 is output, the converter B stop signal input terminal 309 is set to the HI level.
In this case, the input terminal 309 for the converter B stop signal needs to have an HI level that allows the collector current of the transistor 306 to flow.
By doing so, the transistor 306 passes a collector current, and the LED of the photocoupler 601 does not emit light.
As a result, the operation stop signal terminal of the power supply IC 402 is not at the GND level, and the converter B power supply 401 performs an output operation.
The power that can be reduced in the second embodiment is substantially the same as that in the first embodiment, and the same effect as in the first embodiment can be obtained.

FIG. 4 is a circuit diagram illustrating a configuration of a power supply device in the “image forming apparatus” according to the third embodiment. The third embodiment is different from the first embodiment in a zero cross detection circuit 946.
A current flowing from a DC constant voltage source (hereinafter also referred to as a DC constant voltage source Vic) of a voltage Vic obtained by rectifying and smoothing the output of the transformer auxiliary winding 503 in the converter B power source 401 toward a commercial AC power source input from the AC inlet 101 Is detected using the transistor 942. Thus, the voltage phase of the commercial AC power supply is detected, while the current flowing from the commercial AC power supply is blocked by the diode 940.

  Since the output of the converter B is feedback controlled by the shunt regulator 416, it is a constant voltage. Therefore, the voltage obtained by rectifying and smoothing the output of the transformer auxiliary winding 503 with the diode 507 and the capacitor 505 is a constant voltage, and constitutes a DC constant voltage source Vic. The DC constant voltage source Vic is supplied to the emitter terminal of the transistor 942. The base terminal of the transistor 942 is connected to the L1 phase of the commercial AC power supply via the resistor Rin (941) and the diode 940. The collector terminal of the transistor 942 is connected to the anode terminal of the LED in the photocoupler 944 via the resistor 943. The cathode terminal of the LED in the photocoupler 944 is connected to the low-side output terminal of the bridge diode. The secondary terminal of the photocoupler 944 is output as a zero cross detection signal (ZEROX).

  In the above circuit configuration, when the commercial AC voltage Vac is larger than the voltage of the DC constant voltage source Vic, the diode 940 is reverse-biased. Accordingly, the base current of the transistor 942 does not flow, and the transistor 942 is turned off. Thereby, the forward current of the LED in the photocoupler 944 is also cut off, and the LED is turned off. Therefore, the ZEROX signal is at the HI level.

On the other hand, when the commercial AC voltage Vac is smaller than the voltage of the DC constant voltage source Vic,
A current flows in a route of “DC constant voltage source Vic → emitter of transistor 942 → base of transistor 942 → resistor Rin (941) → diode 940 → L1 phase of commercial AC power supply 101”. Then, the transistor 942 is turned on, a forward current flows through the LED in the photocoupler 944, and the LED emits light. As a result, the ZEROX signal becomes LOW level.

  That is, the rising edge of the ZEROX signal is the timing when the commercial AC voltage Vac exceeds the voltage of the DC constant voltage source Vic. On the other hand, the falling edge is the timing when the commercial AC voltage Vac falls below the voltage of the DC constant voltage source Vic.

The voltage phase φ of the commercial AC power supply 1 at this time is approximately expressed by the following equation using the maximum value Vacpk of the commercial AC voltage.
φ = sin ^ -1 (Vic / Vacpk)
Here, since the voltage Vic of the DC constant voltage source and the maximum value Vacpk of the commercial AC voltage are known values, the phase of the commercial AC power supply can be known from the edge timing of the ZEROX signal.
For example, if Vic = 20V, the maximum value ACacpk of the commercial AC voltage is about 340V (= AC240Vx√2) in Europe, so φ = sin ^ −1 (20V / 340V) = 3 ° and 177 °.
That is, the timing of the rising edge of the ZEROX signal represents the vicinity of 3 ° of the commercial AC voltage, and the timing of the falling edge of the ZEROX signal represents the vicinity of the phase of 177 ° of the commercial AC voltage.

By the way, in the series of operations described above, the voltage applied to the resistor Rin (941) is the voltage value Vic of the DC constant voltage source formed by the output of the transformer auxiliary winding 503 because the diode bridge 103 exists. It is as follows.
The voltage Vic of the DC constant voltage source is preferably set to around 20V. This is very small compared to commercial AC voltage. Therefore, the power consumed by the resistor Rin (941) can also be kept very small. Rin (941) is preferably set to several tens KΩ to several hundreds KΩ in consideration of the direct current amplification factor of the transistor 942. If Rin (941) is 100 KΩ, the power consumed by Rin (941) is about 0.002 W (= 20 V × 20 V ÷ 100 KΩ / 2).

Further, by using the circuit as described above, when the operation of the converter B power supply 401 is stopped, the DC constant voltage source Vic is stopped. Then, since the diode 940 is always reverse-biased regardless of the voltage of the commercial AC power supply 101, the power consumption at the resistor Rin (941) in the zero-cross detection circuit 946 becomes substantially zero.
As a result, when the operation of the converter B is stopped, it is possible to further reduce the power consumed unnecessarily by the zero cross detection circuit.

  As described above, according to the present embodiment, it is possible to greatly reduce the power consumed unnecessarily in the zero cross detection circuit.

FIG. 5 is a diagram illustrating a configuration of an “image forming apparatus” according to the fourth embodiment.
In addition, the same code | symbol is attached | subjected to the item demonstrated in the prior art example 2, and description here is abbreviate | omitted.
The feature of this embodiment resides in the zero cross detection circuit 46.
A voltage Vic obtained by rectifying and smoothing the output of the transformer auxiliary winding 15p2 is used as a DC constant voltage source. A transistor 42 is used to detect a current flowing from the DC constant voltage source Vic toward the L1 phase of the commercial AC power supply 1. Thereby, the voltage phase of the commercial AC power supply 1 is detected. On the other hand, the current flowing from the commercial AC power supply 1 is blocked by the diode 40.

  The DC constant voltage source Vic is supplied to the emitter terminal of the transistor 42. The base terminal of the transistor 42 is connected to the L1 phase of the commercial AC power supply 1 via the resistor Rin (41) and the diode 40. The collector terminal of the transistor 42 is connected to the anode terminal of the LED in the photocoupler 44 via the resistor 43. The cathode terminal of the LED in the photocoupler 44 is connected to the negative terminal of the primary smoothing capacitor 13. The secondary side terminal of the photocoupler 44 is supplied to the control unit 5 as the phase detection signal ZEROX.

  In the above circuit configuration, when the commercial AC voltage Vac is larger than the DC constant voltage source Vic (FIG. 6, t1 to t2), the diode 40 is reverse-biased. Therefore, the base current of the transistor 42 does not flow, and the transistor 42 is turned off. Thereby, the forward current of the LED in the photocoupler 44 is also cut off, and the LED is turned off. Therefore, the ZEROX signal becomes H level.

On the other hand, when the commercial AC voltage Vac is smaller than the DC constant voltage source Vic (FIG. 6, t2 to t3),
Current flows through a route of “DC constant voltage source Vic → emitter of transistor 42 → base of transistor 42 → resistor Rin (41) → diode 40 → L1 phase of commercial AC power supply 1”. Then, the transistor 42 is turned on, a forward current flows through the LED in the photocoupler 44, and the LED emits light. As a result, the ZEROX signal becomes L level.

That is, the rising edge of the ZEROX signal is the timing when the commercial AC voltage Vac exceeds the voltage of the DC constant voltage source Vic. On the other hand, the falling edge is the timing when the commercial AC voltage Vac falls below the voltage of the DC constant voltage source Vic.
The voltage phase φ of the commercial AC power supply 1 at this time is approximately expressed by the following equation using the maximum value Vacpk of the commercial AC voltage.
φ = sin ^ -1 (Vic / Vacpk)
Here, since the voltage Vic of the DC constant voltage source Vic and the maximum value Vacpk of the commercial power supply voltage are known values, the phase of the commercial AC power supply can be known from the edge timing of the ZEROX signal.

For example, if Vic = 20V, the maximum value ACacpk of the commercial AC voltage is about 340V (= AC240Vx√2) in Europe, so φ = sin ^ −1 (20V / 340V) = 3 ° and 177 °.
That is, the timing of the rising edge of the ZEROX signal represents the vicinity of 3 ° of the commercial AC voltage, and the timing of the falling edge of the ZEROX signal represents the vicinity of the phase of 177 ° of the commercial AC voltage.
The control unit 5 controls the conduction phase angle of the triac based on the phase information, and controls the phase angle of the commercial AC voltage supplied to the heater 11.

  Incidentally, as shown in FIG. 6, the voltage applied to the resistor Rin (41) in the above-described series of operations is equal to or less than the voltage value of the DC constant voltage source Vic because the diode bridge 12 exists. .

Generally, the power supply voltage Vcc of the PWM module 17 is around 20V. Therefore, the DC constant voltage source Vic is also around 20V, which is very small compared to the commercial AC voltage. Therefore, the power consumed by the resistor Rin (41) can be kept very small. Rin (41) is preferably set to several tens KΩ to several hundreds KΩ in consideration of the direct current amplification factor of the transistor 42. If Rin (41) is 100 KΩ, the power consumed by Rin (41) is about 0.002 W (= 20 V × 20 V ÷ 100 KΩ / 2).
As described above, the input resistance Rin (21) of the conventional zero cross detection circuit 8 consumes about 0.3 W of power. The power consumption of Rin (41) in this embodiment is about 0.002 W, which is very small compared to the conventional case.

  As described above, according to the present embodiment, in the zero cross detection unit, the current flowing from the commercial AC power source having a relatively high voltage is cut off, and the zero cross point is detected by the current flowing from the DC constant voltage source to the commercial AC power source. Detection is in progress. Since the voltage of the DC constant voltage source can be set lower than the commercial AC power supply voltage, wasteful power consumed by the zero cross detection circuit can be greatly reduced.

FIG. 7 is a diagram illustrating a configuration of an “image forming apparatus” according to the fifth embodiment.
In addition, the same code | symbol is attached | subjected to the item demonstrated in the prior art example 2, and description here is abbreviate | omitted.

  The feature of the present embodiment resides in the zero-cross detection circuit 54, which is that the transistor 42 used for AC phase detection in the fourth embodiment is omitted, and detection is performed directly using the LED in the photocoupler.

  That is, the voltage Vic obtained by rectifying and smoothing the output of the transformer auxiliary winding 15p2 is used as the DC constant voltage source. The current flowing from the DC constant voltage source Vic toward the L1 phase of the commercial AC power supply 1 is detected using the LED in the photocoupler 52, and the voltage phase of the commercial AC power supply 1 is detected. On the other hand, the current flowing from the commercial AC power supply 1 is blocked by the diode 50.

  The DC constant voltage source Vic is connected to the anode terminal of the LED in the photocoupler 52. The cathode terminal of the LED in the photocoupler 52 is connected to the L1 phase of the commercial AC power supply 1 via the resistor Rin (51) and the diode 50. The secondary side terminal of the photocoupler 52 is supplied to the control unit 5 as the phase detection signal ZEROX.

  In the circuit configuration described above, when the commercial AC voltage Vac is higher than the DC constant voltage source Vic (FIG. 6, t1 to t2), the diode 50 is reverse-biased. Therefore, the forward current of the LED in the photocoupler 52 does not flow, and the LED is turned off. Therefore, the ZEROX signal becomes H level.

On the other hand, when the commercial AC voltage Vac is smaller than the DC constant voltage source Vic (FIG. 6, t2 to t3),
Current flows through a route of “DC constant voltage source Vic → anode of LED in photocoupler 52 → cathode of LED in photocoupler 52 → resistance Rin (51) → diode 50 → L1 phase of commercial AC power supply 1”. Then, the LED in the photocoupler 52 emits light. As a result, the ZEROX signal becomes L level.

  That is, the rising edge of the ZEROX signal is the timing when the commercial AC voltage Vac exceeds the voltage of the DC constant voltage source Vic. On the other hand, the falling edge is the timing when the commercial AC voltage Vac falls below the voltage of the DC constant voltage source Vic.

The voltage phase φ of the commercial AC power supply 1 at this time is approximately expressed by the following equation using the maximum value Vacpk of the commercial AC voltage.
φ = sin ^ -1 (Vic / Vacpk)
Here, since the voltage Vic of the DC constant voltage source and the maximum value Vacpk of the commercial power supply voltage are known values, the phase of the commercial AC power supply can be known from the edge timing of the ZEROX signal.

For example, if Vic = 20V, the maximum value ACacpk of the commercial AC voltage is about 340V (= AC240Vx√2) in Europe, so φ = sin ^ −1 (20V / 340V) = 3 ° and 177 °.
That is, the timing of the rising edge of the ZEROX signal represents the vicinity of 3 ° of the commercial AC voltage, and the timing of the falling edge of the ZEROX signal represents the vicinity of the phase of 177 ° of the commercial AC voltage.

  The control unit 5 controls the conduction phase angle of the triac 34 based on the phase information, and controls the phase angle of the commercial AC voltage supplied to the heater 11.

  By the way, as shown in FIG. 8, the voltage applied to the resistor Rin (51) in the above-described series of operations is equal to or less than the voltage value of the DC constant voltage source Vic.

  Generally, the power supply voltage Vcc of the PWM module 17 is around 20V. Therefore, the DC constant voltage source Vic is also around 20V, which is very small compared to the commercial AC voltage. Therefore, the power consumed by the resistor Rin (51) can be kept very small.

  Rin (51) is preferably set to several hundred Ω to several tens KΩ in consideration of the light conversion efficiency (CTR) of the photocoupler 52. If Rin (51) is 4.7 KΩ, the power consumed by Rin (51) is about 0.04 W (= 20 V × 20 V ÷ 4.7 KΩ / 2).

  As described above, the input resistance Rin (21) of the zero-cross detection circuit 8 of the conventional example 2 consumes about 0.3 W of power, but the power consumption of Rin (51) in this embodiment is about 0.04 W. Thus, it is much smaller than the conventional example 2.

Circuit diagram of power supply device in embodiment 1 Sectional drawing which shows schematic structure of Example 1. FIG. Circuit diagram of power supply device in embodiment 2 Circuit diagram of power supply device in embodiment 3 Circuit diagram of power supply device in embodiment 4 Waveform diagram of zero-cross detection circuit in the fourth embodiment Circuit diagram of power supply device in embodiment 5 Waveform diagram of zero-cross detection circuit in embodiment 5 Circuit diagram of conventional example 1 Circuit diagram of Conventional Example 2 Waveform diagram of zero cross detection circuit in Conventional Example 2 Illustration of conduction phase angle control

Explanation of symbols

103 Rectifier diode bridge 104 Smooth electrolytic capacitor 105 Converter A power supply 201 Zero cross detection circuit 401 Converter B power supply

Claims (5)

A DC power supply unit that converts AC input to DC,
A first converter that is connected to the DC power supply unit and converts the output power of the DC power supply unit to DC power of a voltage different from the voltage, and that operates even during standby of a load;
A second converter that is connected to the DC power supply unit and converts the output power of the DC power supply unit to DC power of a voltage different from the voltage, and stops when the load is on standby;
A zero-cross detector that receives power from the second converter and detects a zero-cross point of the AC input;
A power supply device comprising: The power supply device according to claim 1,
The second converter includes a power supply control IC,
The power supply device is characterized in that the power supply control IC is stopped by an external signal when the load is on standby. A DC power supply unit that rectifies an AC input by a rectifier diode bridge and converts it to DC;
A converter that is connected to the DC power supply unit and converts the output power of the DC power supply unit into DC power of a voltage different from the voltage;
A series circuit of a diode, a current detection element, and a DC constant voltage source, connected in parallel to one side of the rectifier diode bridge, detects the zero cross point of the AC input based on the current detected by the current detection element. A zero-cross detector
A power supply device comprising: A DC power supply unit that rectifies an AC input by a rectifier diode bridge and converts it to DC;
A first converter that is connected to the DC power supply unit and converts the output power of the DC power supply unit to DC power of a voltage different from the voltage, and that operates even during standby of a load;
A second converter that is connected to the DC power supply unit and converts the output power of the DC power supply unit to DC power of a voltage different from the voltage, and stops when the load is on standby;
A series circuit of a diode, a current detection element, and a DC constant voltage source connected in parallel to one side of the rectifier diode bridge, wherein the power source of the current detection element and the DC constant voltage source is the second converter; A zero-cross detection unit that detects a zero-cross point of the AC input based on the current detected by the current detection element;
A power supply device comprising: An image forming apparatus comprising: the power supply device according to claim 1; and a fixing device whose temperature is controlled by a thyristor element.
The image forming apparatus according to claim 1, wherein the thyristor element is subjected to conduction phase angle control with reference to a zero cross point detected by the zero cross detection unit.

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