JP7327186B2 - Power supply circuit and image forming apparatus - Google Patents

Description

The present invention relates to a power supply circuit and an image forming apparatus.

2. Description of the Related Art Conventionally, in a power supply device using switching elements, a power factor correction circuit has been used to prevent a decrease in power factor.

In the power factor correction circuit, power loss accompanies the power factor correction operation, so the power conversion efficiency is degraded. For example, power is wasted if the power factor correction circuit operates even in a light load mode in which the power factor does not need to be improved, such as when the electrical equipment is on standby.

On the other hand, in the power supply device described in Patent Document 1, in the light load mode, by turning off the power supply to the power factor improvement control IC (Integrated Circuit) of the power factor improvement circuit, the power factor improvement circuit operation is stopped to save power in light load mode.

JP 2005-168146 A

However, in the conventional power supply device, even if the power supply to the power factor correction control IC is turned off in the light load mode, the resistor for detecting the output voltage of the power factor correction circuit is connected to the circuit after rectification. Therefore, even if the operation of the power factor correction circuit is stopped, current continues to flow through the resistor, resulting in unnecessary power consumption.

Accordingly, it is an object of one or more aspects of the present invention to reduce the power consumption of a power supply circuit having a power factor correction circuit in the light load mode.

A power supply circuit according to an aspect of the present invention is a power supply circuit that operates in at least a first load mode and a second load mode having a load lower than that of the first load mode, the power supply circuit receiving an AC voltage a rectifying and smoothing circuit for converting the AC voltage into a converted DC voltage that is a DC voltage; and improving a power factor given to the AC voltage when the converted DC voltage is used in the first load mode. and outputs a first DC voltage, and in the second load mode, a state in which the power factor given to the AC voltage when the converted DC voltage is used is lower than the improved power factor. a power factor correction circuit that outputs a second DC voltage; and a main voltage that, in the first load mode, converts the first DC voltage into the DC voltage required in the first load mode. a conversion circuit, in the second load mode, converting the second DC voltage into an operating DC voltage that is a DC voltage required for operation in the power factor correction circuit and the main voltage conversion circuit; A sub-voltage conversion circuit that converts the first DC voltage into the operating DC voltage in one load mode, and the power factor correction circuit and the main voltage conversion circuit for the operating DC voltage in the second load mode. a power supply switching circuit that cuts off the supply to the power supply and supplies the operating DC voltage to the power factor correction circuit and the main voltage conversion circuit when switching from the second load mode to the first load mode. a power factor improvement control circuit for receiving an input of the operating DC voltage and controlling the power factor improvement circuit; connecting a resistor for feedback to a circuit and a path for supplying the output from the power factor correction circuit to the resistor in the first load mode and disconnecting the path in the second load mode; and a resistance switching circuit.

An image forming apparatus according to an aspect of the present invention includes the above power supply circuit.

According to one or more aspects of the present invention, power consumption of a power supply circuit having a power factor correction circuit can be reduced in a light load mode.

FIG. 1 is a longitudinal sectional view schematically showing the configuration of an image forming apparatus 100 according to an embodiment. FIG. 2 is a circuit diagram showing a schematic configuration of the low-voltage power supply 110 and the main controller 190 in the image forming apparatus 100. As shown in FIG. FIG. 3 is a schematic circuit diagram of the resistance switching circuit 160. As shown in FIG. FIG. 4 is a schematic circuit diagram of the power supply switching circuit 170. As shown in FIG. FIG. 5 is a flow chart showing the operation from when the commercial power supply is supplied until the image forming apparatus 100 is activated.

FIG. 1 is a longitudinal sectional view schematically showing the configuration of an image forming apparatus 100 according to an embodiment.
The image forming apparatus 100 is an example of a color image forming apparatus that forms a color image by superimposing and printing toners that are developers of four colors of black, yellow, magenta, and cyan. However, the image forming apparatus 100 according to the embodiment is not limited to such an example, and may be a monochrome image forming apparatus using only black or a color image forming apparatus using other colors.
In FIG. 1, capital letter "K" means black, capital letter "Y" means yellow, capital letter "M" means magenta, and capital letter "C" means cyan.

As illustrated, the image forming apparatus 100 includes photosensitive drums 2K, 2Y, 2M and 2C, chargers 3K, 3Y, 3M and 3C, exposure devices 4K, 4Y, 4M and 4C, developing devices 5K, 5Y, 5M and 5C.

Further, the image forming apparatus 100 includes transfer rollers 6K, 6Y, 6M, 6C, a transfer belt 8, a drive roller 9, an idle roller 10, a fixing device 11, a first conveying roller pair 12-1, 12- 2, a second conveying roller pair 13-1, 13-2, an ejection roller pair 14-1, 14-2, a hopping roller 15, a writing sensor 16, an ejection sensor 17, a support plate member 18, A spring 19 is provided.

Furthermore, the image forming apparatus 100 includes a low-voltage power supply 110 and a main control section 190 .
In addition, below, the main control unit 190 is also simply referred to as a control unit. The low-voltage power supply 110 is also called a power supply unit.

Here, in the image forming apparatus 100, the part other than the low-voltage power supply 110 and the main control section 190 is also called an image forming apparatus main body. The low-voltage power supply 110 supplies power to the image forming apparatus main body via the main control section 190 , the main control section 190 controls the image forming apparatus main body, and the image forming apparatus main body is controlled by the main control section 190 . to form an image on the media according to

each of the photosensitive drums 2K, 2Y, 2M, and 2C; each of the chargers 3K, 3Y, 3M, and 3C; each of the exposure devices 4K, 4Y, 4M, and 4C; each of the developers 5K, 5Y, 5M, and 5C; Since the transfer rollers 6K, 6Y, 6M, and 6C are configured in the same manner except that the colors of the toners used are different, the photosensitive drum 2K, the charger 3K, the exposure device 4K, and the development device 5K are used here. and the transfer roller 6K.

The photosensitive drum 2K is an image carrier that carries an image for transfer. Here, the image for transfer is a toner image, which is a toner image.

The charger 3K negatively charges the photosensitive drum 2K.
The exposure device 4K forms an electrostatic latent image on the photosensitive drum 2K.
The developing device 5K forms and visualizes a toner image by attaching negatively charged toner to the electrostatic latent image on the photosensitive drum 2K.

The transfer roller 6K is arranged inside a transfer belt 8 formed in the shape of an endless belt. The transfer roller 6K is urged by an elastic member (not shown) such as a spring so as to be pressed against the photosensitive drum 2K with the transfer belt 8 interposed therebetween. The transfer roller 6K transfers the toner image formed on the photosensitive drum 2K onto paper as a medium conveyed by the transfer belt 8 by applying a bias having a polarity opposite to that of the toner.

The transfer belt 8 is supported by the outer peripheral surfaces of the drive roller 9 and the idle roller 10 . The transfer belt 8 is pulled between the drive roller 9 and the idle roller 10 so that the surfaces of the photosensitive drums 2K, 2Y, 2M, and 2C and the transfer belt 8 are flat. there is Then, the transfer belt 8 conveys the paper to which the toner image is transferred.

The drive roller 9 is connected to a driving device (not shown) and rotates about its axis.
When the transfer belt 8 moves due to the rotation of the drive roller 9 , the idle roller 10 rotates in the same direction as the drive roller 9 in conjunction with the movement of the transfer belt 8 .

The fixing device 11 includes a fixing roller 11b having a heater 11a therein as a heat source, a backup roller 11c urged toward the fixing roller 11b by an urging means, and a thermistor 11d for detecting the temperature of the fixing device 11. Prepare. The fixing device 11 fixes the toner image onto the paper to which the toner image has been transferred by heat and pressure.

The heater 11a is used to heat the paper onto which the toner image has been transferred.
The thermistor 11d detects the temperature of the fixing device 11 and notifies the main controller 190 of the detected temperature. Based on the temperature, the main control unit 190 controls turning on and off of the heater 11a so as to keep the temperature of the fixing device 11 constant.

A dashed line in FIG. 1 indicates a paper transport path. Along the transport path, first transport roller pairs 12-1 and 12-2, second transport roller pairs 13-1 and 13-2, and writing sensor 16 are arranged upstream of transfer belt 8. The discharge sensor 17 and the pair of discharge rollers 14 - 1 and 14 - 2 are arranged downstream of the fixing device 11 .

The writing sensor 16 and the ejection sensor 17 detect a predetermined position of the paper when the paper is transported along the transport path, and give the detection signal to the main control section 190 . Here, the writing sensor 16 detects the leading edge position of the paper, and the discharge sensor 17 detects the trailing edge position of the paper.

Paper is placed on the upper surface of the support plate member 18 . A spring 19 is provided below the support plate member 18 as a biasing member for pushing the support plate member 18 upward. The paper placed on the upper surface of the support plate member 18 is pressed against the hopping roller 15 by the biasing force of the spring 19, and the hopping roller 15 rotates in the direction to push the paper onto the transport path, thereby pushing the paper onto the transport path. be

FIG. 2 is a circuit diagram showing a schematic configuration of the low-voltage power supply 110 and the main controller 190 in the image forming apparatus 100. As shown in FIG.
It should be noted that FIG. 2 shows a circuit of the low-voltage power supply 110 and the main control unit 190, which is an excerpt of the features of the first embodiment.

The low-voltage power supply 110 is a power supply circuit that operates at least in a first load mode and a low load mode, which is a second load mode with a lower load than the first load mode. Here, the first load mode is a mode in which the image forming apparatus 100 is activated, in other words, a mode in which the image forming apparatus 100 is powered on. The second load mode is a mode in which commercial power is supplied to the image forming apparatus 100 but the image forming apparatus 100 is powered off, in other words, a mode in which the image forming apparatus 100 is not activated. . Note that the first load mode and the second load mode are not limited to the above examples.

An AC (Alternating Current) inlet 20 is connected to a commercial power supply (AC power supply) via a power cord. AC inlet 20 is connected to AC input section 21 of low-voltage power supply 110 .

The AC input section 21 is an input section that receives an AC voltage input.
The LINE side of the AC input unit 21 is connected to one end of the Fuse A111.
The other end of the Fuse A 111 is connected to one end of the input side of the filter 112 , and the NEUTRAL side of the AC input section 21 is connected to the other end of the input side of the filter 112 .

One end of the output side of the filter 112 is connected to one end of the Fuse B 113 and the LINE side of the heater AC output section 22 .
The other end of FuseB 113 is connected to one end of the rectifying bridge 114 on the input side.
Furthermore, the other end of the output side of the filter 112 is connected to the other end of the rectifying bridge 114 input side, the other end of the triac 115 and the other end of the resistor 116 .

The rectifying bridge 114 and the capacitor 117 are a rectifying and smoothing circuit that converts the AC voltage input to the AC input section 21 into a DC voltage. The DC voltage converted by the rectifying bridge 114 and the capacitor 117 is also called a converted DC voltage.
The + output side of the rectifying bridge 114 is connected to one end of the capacitor 117 and one end of the primary side of the transformer 118 .
One end of the triac 115 is connected to one end of the resistor 124 and the NEUTRAL side of the heater AC output section 22 .
The other end of the resistor 124 is connected to the gate of the triac 115 and one output end of the phototriac 119 .
One end of the resistor 116 is connected to the other end on the output side of the phototriac 119 .

A cathode of the phototriac 119 is connected to GND of the low-voltage power supply 110 .
The anode of the phototriac 119 is connected to the ACON-N signal terminal 120 of the low voltage power supply 110 .

The negative output side of the rectifying bridge 114 is connected to the other end of the capacitor 117 and one end of the secondary side of the transformer 118 .
The other end of the transformer 118 on the primary side is connected to the anode of the diode 121 .
Also, the other end of the secondary side of the transformer 118 is connected to one end of the resistor 122 .
The other end of resistor 122 is connected to one end of capacitor 123 .

The OUT pin of the power factor correction circuit control IC 125 that is the control IC for the power factor correction circuit 180 to be described later is connected to the gate of the FET 126 .
The drain of FET 126 is connected to the anode of diode 121 .
The source of the FET 126 is connected to the IS pin of the power factor correction circuit control IC 125 and one end of the resistor 127 .

The FB pin of the power factor correction circuit control IC 125 is connected to the other end of the resistor 128 and one end of the resistor 129 .

The other end of the capacitor 123 , the other end of the resistor 129 , the other end of the resistor 127 , and the GND pin of the power factor correction circuit control IC 125 are connected to the − output side of the rectifying bridge 114 .
The cathode of the diode 121 is connected to one end of the primary side of the main transformer 130 , one end of the primary side of the sub-transformer 131 , the + side of the electrolytic capacitor 132 and one end of the resistor 133 .

The OUT pin of the main power control IC 134 , which is a control IC for controlling the main power, is connected to the gate of the FET 135 .
The other end of the primary side of the main transformer 130 is connected to the drain of the FET 135 . The source of the FET 135 is connected to the IS pin of the main power control IC 134 and one end of the resistor 136 .
The FB pin of the main power control IC 134 is connected to the collector of the photocoupler 137 .
The GND pin of the main power control IC 134 , the other end of the resistor 136 , the − side of the electrolytic capacitor 132 and the emitter of the photocoupler 137 are connected to the − output side of the rectifying bridge 114 .

The connection point C1 of the resistance switching circuit 160, which is a power factor improvement circuit voltage detection resistance switching unit for switching ON and OFF of the current to the resistors 128 and 129 used to detect the voltage of the power factor improvement circuit 180, is The VCC pin of the main power supply control IC 134, the VCC pin of the power factor correction circuit control IC 125, and the connection point C6 of the power supply switching circuit 170, which is the control IC power supply switching unit, are connected.

A connection point C2 of the resistance switching circuit 160 is connected to the −output side of the rectifying bridge 114 .
A connection point C3 of the resistance switching circuit 160 is connected to one end of the resistance 128 .
A connection point C<b>4 of the resistance switching circuit 160 is connected to the cathode of the diode 121 .

FIG. 3 is a schematic circuit diagram of the resistance switching circuit 160. As shown in FIG.
A connection point C<b>1 of the resistance switching circuit 160 is connected to the other end of the resistor 161 , and one end of the resistor 161 is connected to the base of the transistor 162 .

The emitter of transistor 162 is connected to connection point C2 of resistance switching circuit 160 .
The collector of transistor 162 is connected to one end of resistor 163 .
The other end of resistor 163 is connected to the base of transistor 164 and one end of resistor 165 .
A collector of the transistor 164 is connected to the connection point C3 of the resistance switching circuit 160 .
The other end of the resistor 165 is connected to the emitter of the transistor 164 and the connection point C4 of the resistor switching circuit 160 .

As described above, the resistance switching circuit 160 is provided on the paths R1 and R2 shown in FIG. A second switch that connects the paths R1 and R2 to the transistor 164 when the DC voltage is supplied from 170, and disconnects the paths R1 and R2 when the supply of the DC voltage is cut off. and a transistor 162 .

Returning to FIG. 2, the OUT pin of the sub power supply control IC 138 that controls the sub power supply is connected to the gate of the FET 139 .
The other end of the sub-transformer 131 on the primary side is connected to the drain of the FET 139 .
The source of the FET 139 is connected to the IS pin of the sub power control IC 138 and one end of the resistor 140 .

The FB pin of the sub power control IC 138 is connected to the collector of the photocoupler 141 .
The VIN pin of the sub power control IC 138 is connected to the other end of the resistor 133 .
The VCC pin of the sub power control IC 138 is connected to the + side of the electrolytic capacitor 142 and the cathode of the diode 143 .

The anode of diode 143 is connected to one end of the auxiliary winding of sub-transformer 131 .
The GND pin of the sub-power supply control IC 138, the other end of the resistor 140, the - side of the electrolytic capacitor 142, the emitter of the photocoupler 141, and the other end of the auxiliary winding of the sub-transformer 131 are the - output side of the rectifying bridge 114. connected to

FIG. 4 is a schematic circuit diagram of the power supply switching circuit 170. As shown in FIG.
A connection point C5 of the power switching circuit 170 is connected to one end of the resistor 171 and the collector of the transistor 172 .
The other end of resistor 171 is connected to the collector of photocoupler 173 .
The emitter of photocoupler 173 is connected to the base of transistor 172 .
A connection point C6 of the power switching circuit 170 is connected to the emitter of the transistor 172 .

The anode of photocoupler 173 is connected to one end of resistor 174 .
The other end of the resistor 174 is connected to the connection point C7 of the power switching circuit 170 .
The cathode of photocoupler 173 is connected to the collector of transistor 175 .

The base of transistor 175 is connected to one end of resistor 176 .
The other end of the resistor 176 is connected to the connection point C8 of the power switching circuit 170 .
The emitter of the transistor 175 is connected to the connection point C9 of the power switching circuit 170 .

As described above, the power supply switching circuit 170 has power supply paths R3 and R4 for supplying the DC voltage from the sub-voltage conversion circuit 182, which will be described later, to the power factor correction circuit 180, which will be described later, and the main voltage conversion circuit 181, which will be described later. (see FIG. 2), a third switch transistor 172 for disconnecting or connecting the power supply paths R3, R4 and the operation for switching modes between the first load mode and the second load mode. When the mode switching signal POWER SAVE-N signal indicates to switch to the first load mode, transistor 172 connects the power supply paths R3, R4 and the POWER SAVE-N signal switches to the second load mode. and a fourth switch transistor 175 that connects the power supply paths R3 and R4 to the transistor 172 when switching is indicated.

Returning to FIG. 2, the connection point C5 of the power supply switching circuit 170 is connected to the VCC pin of the IC 138 for sub-power supply control.

One end of the secondary side of the main transformer 130 is connected to the anode of the diode 144 .
The cathode of diode 144 is connected to the + side of electrolytic capacitor 145 , the other end of resistor 146 , one end of resistor 147 , and +24V terminal 148 of low-voltage power supply 110 .

The other end of the secondary side of main transformer 130 is connected to the anode of variable shunt regulator 149 , the negative side of electrolytic capacitor 145 , and the other end of resistor 150 .

The anode of photocoupler 137 is connected to one end of resistor 146 .
The cathode of photocoupler 137 is connected to the cathode of variable shunt regulator 149 .
The reference of variable shunt regulator 149 is connected to the other end of resistor 147 and one end of resistor 150 .

One end of the secondary side of the sub-transformer 131 is connected to the anode of the diode 151 .
The cathode of the diode 151 is connected to the + side of the electrolytic capacitor 152, the other end of the resistor 153, one end of the resistor 154, the connection point C7 of the power supply switching circuit 170, and the +5V terminal 155 of the low voltage power supply 110.

The other end of the secondary side of the subtransformer 131 is connected to the anode of the variable shunt regulator 156, the minus side of the electrolytic capacitor 152, the other end of the resistor 157, and the connection point C9 of the power switching circuit 170.

The anode of photocoupler 141 is connected to one end of resistor 153 .
The cathode of photocoupler 141 is connected to the cathode of variable shunt regulator 156 .
The reference of variable shunt regulator 156 is connected to the other end of resistor 154 and one end of resistor 157 .

A connection point C8 of the power supply switching circuit 170 is connected to the POWER SAVE-N signal terminal 158 of the low voltage power supply 110 .
The +24V terminal 148 of the low-voltage power supply 110 is connected to the input side of the voltage conversion section 191 of the main control section 190 .
The +5V terminal 155 of the low-voltage power supply 110 is connected to the input side of the power control section 192 of the main control section 190 .
GND terminals 159 A and 159 B of the low-voltage power supply 110 are connected to the GND of the voltage conversion section 191 of the main control section 190 and the power control section 192 .

A voltage converted by the voltage converter 191 in the main controller 190 is supplied to each circuit of the main controller 190 .
The ACON-N signal terminal 120 of the low voltage power supply 110 is connected to the heater control section 193 in the main control section 190 . The heater control section 193 is connected to a thermistor 11 d that detects the temperature of the fixing device 11 inside the fixing device 11 .

In the above configuration, the power factor improvement circuit 180 is configured by the transformer 118, the diode 121, the resistor 122, the capacitor 123, the power factor improvement circuit control IC 125, the FET 126, the resistor 127, the resistor 128, the resistor 129, and the resistor switching circuit 160. Configured.

Main voltage conversion is performed by main transformer 130, electrolytic capacitor 132, main power control IC 134, FET 135, resistor 136, photocoupler 137, diode 144, electrolytic capacitor 145, resistor 146, resistor 147, variable shunt regulator 149 and resistor 150. A circuit 181 is configured.

Further, a sub-transformer 131, a resistor 133, a sub-power supply control IC 138, an FET 139, a resistor 140, a photocoupler 141, an electrolytic capacitor 142, a diode 143, a diode 151, an electrolytic capacitor 152, a resistor 153, a resistor 154, a variable shunt regulator 156 and a resistor 157 constitute a sub-voltage conversion circuit 182 .

The power factor correction circuit 180 improves the power factor given to the input AC voltage when using the DC voltage converted by the rectifying bridge 114 and the capacitor 117 in the first load mode, which is a high load mode. . The DC voltage whose power factor is improved by the power factor correction circuit 180 and which is output from the diode 121 is also referred to as a first DC voltage.

In addition, in the second load mode, which is a low-load mode, the power factor correction circuit 180 uses the DC voltage converted by the rectifying bridge 114 and the capacitor 117, and the power applied to the input AC voltage is not improve the rate. Therefore, the power factor is lower in the second load mode than in the first load mode. The DC voltage output from the diode 121 without being improved in power factor by the power factor correction circuit 180 is also called a second DC voltage.

In the first load mode, the main voltage conversion circuit 181 converts the first DC voltage output from the power factor correction circuit 180 into the main DC voltage required in the first load mode. . The main DC voltage is, for example, a DC voltage required by the main control section 190 to control each section of the image forming apparatus 100 . Here, the DC voltage of +24 V smoothed by the electrolytic capacitor 145 becomes the main DC voltage.

In the second load mode, the sub-voltage conversion circuit 182 converts the second DC voltage output from the power factor correction circuit 180 into a sub-DC voltage which is a DC voltage required by the main control unit 190 to control the power supply. Convert to voltage. Here, the DC voltage of +5V smoothed by the electrolytic capacitor 152 becomes the sub-DC voltage.
Sub-voltage conversion circuit 182 also converts the first DC voltage output from power factor correction circuit 180 into a sub-DC voltage in the first load mode. Again, the +5 V DC voltage smoothed by the electrolytic capacitor 152 is the sub-DC voltage.

Furthermore, in the second load mode, the sub voltage conversion circuit 182 converts the second DC voltage output from the power factor correction circuit 180 to the sub power supply control IC 138, the power factor correction circuit 180, and the main voltage conversion circuit 181. It converts to the operating DC voltage, which is the DC voltage required for the operation of the Here, the DC voltage smoothed by the electrolytic capacitor 142 becomes the operating DC voltage.
Also in the first load mode, the sub-voltage conversion circuit 182 converts the first DC voltage output from the power factor correction circuit 180 into the operating DC voltage. Here too, the DC voltage smoothed by the electrolytic capacitor 142 becomes the operating DC voltage.

FIG. 5 is a flow chart showing the operation from when the commercial power supply is supplied until the image forming apparatus 100 is activated.
By connecting the AC inlet 20 to a commercial power supply via a power cord, a voltage of AC 100V, for example, is supplied (S10).
The supplied AC voltage is applied to the rectifying bridge 114 via the FuseA111, the filter 112 and the Fuse113.

The AC voltage is rectified by the rectifying bridge 114 and smoothed by the capacitor 117 to be converted to a DC voltage. The DC voltage is supplied to the VIN pin of the sub-power control IC 138 via the transformer 118, the diode 121 and the resistor 133. As a result, the operation of the sub power control IC 138 is started, and voltage is output from the OUT pin of the sub power control IC 138, whereby the switching operation of the FET 139 is started.

When the switching operation of the FET 139 is started, a voltage is generated in the auxiliary winding of the sub-transformer 131 . The generated voltage is converted into a DC voltage by a diode 143 and an electrolytic capacitor 142 as a smoothing capacitor. This DC voltage is supplied to the VCC pin as the power supply voltage of the IC 138 for sub-power supply control, and power is stably supplied to the IC 138 for sub-power supply control.

An AC voltage is also generated on the secondary side of the sub-transformer 131 due to the switching operation of the FET 139 . This AC voltage is rectified to DC by a diode 151 and an electrolytic capacitor 152 as a smoothing capacitor. The rectified DC voltage is monitored by a resistor 154, a resistor 157, a variable shunt regulator 156, a resistor 153, and a photocoupler 141, and transmitted to the FB pin of the IC 138 for sub power control. As a result, the switching time of the FET 139 connected to the OUT pin of the sub power control IC 138 is controlled, and the DC voltage output from the +5V terminal 155 is kept constant. Here, the FET 139 is controlled so that its output voltage becomes 5V.
As described above, the DC voltage of 5 V is supplied from the low-voltage power supply 110 to the power control section 192 of the main control section 190 (S11).

The operation up to this point is performed while the low-voltage power supply 110 is in the OFF mode, in other words, the image forming apparatus 100 is also in the OFF mode. At this time, although the low-voltage power supply 110 is outputting a DC voltage of 5V, the image forming apparatus 100 is not in operation, so the DC voltage of 5V is in a state of almost no load.

In order to operate the image forming apparatus 100 by outputting a DC voltage of +24 V from the low-voltage power supply 110, the user presses the main soft switch 23 to set the POWER SAVE-N signal output from the power control unit 192 to High level. need to be If the main soft switch 23 is not pressed, the low-voltage power supply 110 remains in the OFF mode, and the POWER SAVE-N signal remains at Low level.

When the POWERSAVE-N signal is at a low level, no current flows through the base of the transistor 175 of the power switching circuit 170 shown in FIG. 4, so the transistor 175 remains OFF. When the transistor 175 is off, no current flows through the light emitting diode 173a of the photocoupler 173, so the phototransistor 173b of the photocoupler 173 also remains off.

When the phototransistor 173b of the photocoupler 173 is OFF, the transistor 172 is also OFF, and as a result, from the auxiliary winding of the sub-transformer 131 shown in FIG. 142 is not applied to the VCC pin of the main power control IC 134 and the VCC pin of the power factor correction circuit control IC 125, the +24V output from the main transformer 130 cannot be obtained.

Furthermore, in this case, no voltage is applied to the base of the transistor 162 of the resistance switching circuit 160 shown in FIG. When the transistor 162 is turned off, the transistor 164 is also turned off, so the connection point C3 and the connection point C4 of the resistance switching circuit 160 are also turned off, and the cathode of the diode 121 and one end of the resistor 128 are turned off. be liberated. Therefore, current can be prevented from flowing from the cathode of the diode 121 to the resistors 128 and 129 .

Here, when the main soft switch 23 is pressed (Yes in S12), the power control section 192 switches the POWER SAVE-N signal to High level. When the POWERSAVE-N signal is high, a voltage is applied to the base of transistor 175 shown in FIG.

When the transistor 175 is ON, a current flows through the light emitting diode 173a of the photocoupler 173, and the phototransistor 173b of the photocoupler 173 is turned ON. When the phototransistor 173b of the photocoupler 173 is turned on, the transistor 172 is turned on. As a result, the voltage generated from the auxiliary winding of sub-transformer 113 shown in FIG. , and the VCC pin of the IC 125 for controlling the power factor correction circuit.

As a result, the main power supply control IC 134 and the power factor improvement circuit control IC 125 operate to output a DC voltage of +24V. At this time, voltage is applied to the base of the transistor 162 of the resistance switching circuit 160 shown in FIG. 3, and base current flows through the transistor 162, so that the transistor 162 is turned ON.

When the transistor 162 is ON, the transistor 164 is also ON, so that the connection point C3 and the connection point C4 of the resistance switching circuit 160 are ON, and the cathode of the diode 121 and one end of the resistor 128 shown in FIG. is connected.
As described above, the output voltage can be monitored by the power factor correction circuit control IC 125, and the power factor correction circuit 180 operates normally (S13).

The DC voltage of +24 V is supplied to the voltage conversion section 191 of the main control section 190, converted by the voltage conversion section 191 into various voltages necessary for the main control section 190, and supplied to each circuit. Accordingly, the image forming apparatus 100 is activated (S14).

As described above, the power supply switching circuit 170 cuts off the supply of the operating DC voltage to the power factor correction circuit 180 and the main voltage conversion circuit 181 in the second load mode, and switches from the second load mode to the first load mode. When switching to the mode, the operating DC voltage is supplied to the power factor correction circuit 180 and the main voltage conversion circuit 181 .

Power factor improving circuit 180 also receives an input of an operating DC voltage, and controls IC 125 for power factor improving circuit, which is a power factor improving control circuit for controlling power factor improving circuit 180 . Resistors 128, 129 for feeding the output back to the control IC 125 for the power factor correction circuit, and paths R1, R2 for feeding the output from the power factor correction circuit 180 to the resistors 128, 129 in the first load mode. , and disconnects the paths R1 and R2 in the second load mode.
Therefore, according to the embodiment, when the load is light, the resistance switching circuit 160 cuts off the connection to the detection resistors 128 and 129 for detecting the output voltage of the power factor correction circuit 180. The current flowing through the detection resistors 128 and 129 of the power factor correction circuit voltage that is not used at times can be reduced. Therefore, it is possible to reduce power consumption during light load.

In the embodiment described above, an example in which image forming apparatus 100 is a color printer has been described, but image forming apparatus 100 is not limited to a color printer. For example, the image forming apparatus 100 may be a monochrome printer, a copier, or a multi-function printer using a switching power supply with a power factor correction circuit 180 .

100 image forming apparatus 21 AC input unit 110 low voltage power supply 160 resistance switching circuit 170 power supply switching circuit 180 power factor correction circuit 181 main voltage conversion circuit 182 sub voltage conversion circuit 190 main control unit.

Claims (4)

A power supply circuit that operates in at least a first load mode and a second load mode having a lower load than the first load mode,
an input unit for receiving an AC voltage input;
a rectifying and smoothing circuit that converts the AC voltage into a converted DC voltage that is a DC voltage;
Improving a power factor given to the AC voltage when using the converted DC voltage in the first load mode, outputting a first DC voltage, and improving the power in the second load mode a power factor correction circuit that outputs a second DC voltage in a state where the power factor given to the AC voltage when the converted DC voltage is used is lower than the factor;
a main voltage conversion circuit that, in the first load mode, converts the first DC voltage into a DC voltage required in the first load mode;
In the second load mode, the second DC voltage is converted into an operating DC voltage that is a DC voltage required for operation in the power factor correction circuit and the main voltage conversion circuit, and the first load mode is performed. a sub-voltage conversion circuit for converting the first DC voltage into the operating DC voltage;
In the second load mode, when cutting off the supply of the operating DC voltage to the power factor correction circuit and the main voltage conversion circuit and switching from the second load mode to the first load mode, the a power supply switching circuit that supplies an operating DC voltage to the power factor correction circuit and the main voltage conversion circuit;
The power factor correction circuit includes:
a power factor correction control circuit that receives the input of the operating DC voltage and controls the power factor correction circuit;
a resistor for feeding back the output from the power factor correction circuit to the power factor correction control circuit;
a resistor switching circuit that connects a path for supplying the output from the power factor correction circuit to the resistor in the first load mode and disconnects the path in the second load mode. A power supply circuit characterized by: The resistance switching circuit is
a first switch provided on the path for disconnecting or connecting the path;
a second switch that causes the first switch to connect the path when the operating DC voltage is supplied, and causes the first switch to disconnect the path when the operating DC voltage is not supplied; 2. The power supply circuit according to claim 1, comprising: The power switching circuit is
a third switch provided in a power supply path for supplying the operating DC voltage from the sub-voltage conversion circuit to the power factor correction circuit and the main voltage conversion circuit, for disconnecting or connecting the power supply path;
When the operation mode switching signal for switching modes between the first load mode and the second load mode indicates switching to the first load mode, the third switch switches the a fourth switch that connects a power supply path and causes the third switch to disconnect the power supply path when the operation mode switching signal indicates switching to the second load mode. 3. A power supply circuit according to claim 1 or 2. An image forming apparatus comprising the power supply circuit according to claim 1 .

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