JP2014096938A - Power source device and image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To ensure safety during melting of a current fuse, and reduce power consumption in a zero-cross detection circuit.SOLUTION: A power source device includes: an X capacitor C1 that is connected between a hot-side line and a neutral-side line to which an AC voltage is input from an AC power source; a bridge diode BD1 and a capacitor C2 that perform full-wave rectification on the AC voltage input from the AC power source and smooth the AC voltage; a current fuse FU 202 that is provided between a contact point of the hot-side line and X capacitor C1, and the bridge diode; discharge resistors R1 and R201, and a diode D201 that are connected with the hot-side line at one ends; and a discharge resistor R2 that is connected with the neutral-side line at one end. When the current fuse FU 202 is melted, and the potential of the hot-side line is lower than the potential of the neutral-side line, the X capacitor C1 is discharged through the discharge resistors R2 and R1, and the diode D201.

Description

  The present invention relates to an electrophotographic copying machine, an image forming apparatus such as a printer, and a power supply device mounted on the image forming apparatus.

  A fixing device mounted on a copying machine or the like that heats and fixes toner on a recording material to the recording material includes an endless belt, a ceramic heater that contacts the inner surface of the endless belt, and a ceramic heater and a fixing nip via the endless belt. It is comprised from the pressure roller etc. which form a part. As a means for controlling the supply of power to the fixing device, a method of phase-controlling the power supplied from the AC power source by using a triac or the like is widely used. In the phase control of the power supplied from the AC power supply, it is necessary to accurately detect the timing at which the AC voltage becomes 0 V (hereinafter referred to as “zero cross timing”), which is the reference timing for phase control. For this reason, the power supply device is provided with a zero-cross detection circuit that detects the zero-cross timing. For example, as disclosed in Patent Document 1, in a power supply device, a capacitor (hereinafter referred to as a “Y capacitor”) is provided between the potential after full-wave rectification of the AC voltage and the frame ground as a countermeasure against terminal noise. It has been. However, when the capacitance of the Y capacitor increases, the zero cross detection circuit cannot detect the exact zero cross timing due to the CR delay. Therefore, in order to accurately detect the zero cross timing, a resistor for discharging the Y capacitor is provided.

JP 2003-199343 A

  In recent years, power saving is desired in various electronic devices. Accordingly, further power saving is desired for the power supply of electronic devices. Therefore, in order to reduce the power consumption in the sleep state of the image forming apparatus, it is necessary to cut the current flowing through the resistor for discharging the zero-cross detection circuit and the Y capacitor in the power supply device to reduce the power consumption.

  In the power supply device, a capacitor (hereinafter referred to as “X capacitor”) is provided as a countermeasure against noise generated between power supply lines from the AC power supply. When the power supply cable for supplying power to the power supply apparatus is disconnected, the X capacitor may be charged with an AC power supply. If the power supply cable is accidentally touched, there is a risk of electric shock. Therefore, a discharge resistor for discharging the charge charged in the X capacitor is required. By providing the discharge resistor, the electric charge charged in the X capacitor is discharged via a discharge diode and a bridge diode that is provided at the subsequent stage of the X capacitor and rectifies the input AC voltage in full wave. However, when a current fuse for preventing overcurrent is arranged in the discharge path connecting the bridge diode and the X capacitor, the discharge path is interrupted when the current fuse is blown, and discharge via the bridge diode cannot be performed. The discharge time of the capacitor becomes longer. As a result, when the power cable is pulled out, there is a problem that an electric shock is caused if the power cable outlet terminal is accidentally touched.

  The present invention has been made under such circumstances, and an object thereof is to ensure safety when a current fuse is blown and to reduce power consumption in a zero-cross detection circuit.

  In order to solve the above-described problems, the present invention is configured as follows.

  (1) A first capacitor connected between a first line to which an AC voltage is input from an AC power source and a second line, and the first capacitor and the second line are input. Rectifying and smoothing means for full-wave rectifying and smoothing the AC voltage, and provided between the first line and the connection point of the first capacitor and the rectifying and smoothing means, and cuts off the input of the AC voltage. A shut-off means, one end connected to the first line, the other end connected to the low-voltage side output end of the rectifying and smoothing means, a first discharge part for discharging the first capacitor, and one end A second discharge unit connected to the second line, having the other end connected to the low-voltage side output end of the rectifying / smoothing means, and discharging the first capacitor, from the connection point by the blocking means The AC voltage input to the rectifying and smoothing means is If the potential of the first line is lower than the potential of the second line when disconnected, the first capacitor is connected to the first discharge part via the second discharge part. The power supply device is characterized by being discharged from.

  According to the present invention, it is possible to ensure safety when the current fuse is blown and to reduce power consumption in the zero cross detection circuit.

Sectional drawing of the electrophotographic image forming apparatus of Examples 1 and 2 Circuit diagram of power supply device of embodiment 1 Waveform diagram of input voltage and zero-cross signal of the zero-cross detection circuit of the first embodiment 6 is a flowchart illustrating a control sequence of the power supply device according to the first embodiment. Circuit diagram of power supply device of embodiment 2

  Hereinafter, the form for implementing this invention is demonstrated in detail by an Example.

[Outline of image forming apparatus]
FIG. 1 is a cross-sectional view of an electrophotographic image forming apparatus according to this embodiment. In FIG. 1, only one sheet of recording material loaded on the paper feed cassette 11 is sent out from the paper feed cassette 11 by the pickup roller 12 and conveyed toward the registration roller 14 by the paper feed roller 13. Further, the recording material is conveyed to the process cartridge 15 by the registration roller 14 at a predetermined timing. The process cartridge 15 includes a charger 16, a developing roller 17, a cleaner 18, and a photosensitive drum 19 that is a photosensitive member. The surface of the photosensitive drum 19 is uniformly charged by the charger 16, and then exposure based on the image signal is performed by the scanner unit 21 which is an exposure unit. Laser light emitted from the laser diode 22 in the scanner unit 21 scans the photosensitive drum 19 through the rotating polygon mirror 23 and the reflecting mirror 24, and an electrostatic latent image is formed on the photosensitive drum 19. The electrostatic latent image on the photosensitive drum 19 is visualized as a toner image by the developing roller 17, and the toner image is transferred by the transfer roller 20 to the recording material conveyed from the registration roller 14.

  The recording material to which the toner image has been transferred is heated and pressurized when conveyed to the image heating apparatus 100, and the toner image is fixed to the recording material. Then, the recording material is discharged out of the image forming apparatus main body by the intermediate paper discharge roller 26 and the paper discharge roller 27, and the series of image forming operations is completed. The image heating apparatus 100 is subjected to power supply control by a control method such as phase control based on zero cross timing described later. The power supply device 200 receives power supply from an external power supply unit 40 such as a commercial power supply via a power cable 50 and supplies necessary power to each device in the image forming apparatus. The motor (M) 30 applies driving force to each device in the image forming apparatus including the image heating apparatus 100.

[Outline of power supply]
FIG. 2 is a circuit diagram of the power supply apparatus 200 including the zero cross detection circuit 202 of the present embodiment. In FIG. 2, the power supply device 200 is a part framed by a one-dot chain line, the zero cross detection circuit 202 is a part framed by a broken line, and the external power supply unit 40 is a part framed by a two-dot chain line. is there. The external power supply unit 40 includes an AC power supply (AC) 201 that supplies power to the power supply device 200 and a ground ground (hereinafter referred to as “GND”). The AC power supply 201 outputs an AC voltage between two lines, a hot (HOT) side line as a first line and a neutral (NUTRAL) side line as a second line. In the following description, an example in which the neutral line is grounded to GND in the external power supply unit 40 will be described, but the effect of the present embodiment is the same even when the hot line is grounded to GND. Further, even when the frame ground (indicated as “FG” in the figure) of the image forming apparatus is not connected to the GND line, the detection accuracy of the zero cross timing described later is not affected. In the present embodiment, the external power supply unit 40 and the power supply device 200 are connected by three lines on the hot side, neutral side, and GND side via the power cable 50, and the frame ground (FG) of the image forming apparatus is Are connected to the GND line.

  The AC voltage input from the AC power supply 201 is full-wave rectified by the bridge diode BD1 which is a rectifying and smoothing means, and smoothed by the capacitor C2. Of the potential of the direct current (DC) voltage smoothed by the capacitor C2, the potential on the low voltage side output end of the capacitor C2 is DCL, and the potential on the high voltage side output end of the capacitor C2 is the higher potential. This is DCH. The converter 1 connected to the subsequent stage of the bridge diode BD1 is an isolated DC / DC converter, and outputs a DC voltage V1 to the secondary side from a DC (direct current) voltage input to the primary side.

  The current fuse FU201 (hereinafter referred to as “fuse FU201”) is used to cut off the power supply from the AC power supply 201 when the current supplied to the entire image forming apparatus exceeds a predetermined current value. The current fuse FU202 (hereinafter referred to as “fuse FU202”) is used to cut off the power supply when an excessive current exceeding a predetermined current value flows through the converter 1. Since only the current supplied to the converter 1 flows through the fuse FU202 as compared with the fuse FU201 through which the current supplied to the entire image forming apparatus flows, a current fuse having a fusing current value lower than that of the fuse FU201 is included in the fuse FU202. Can be used. By providing the two fuses FU201 and FU202 on the power supply path, the power supply to the converter 1 is cut off at a lower current value compared to the case where only the fuse FU201 is provided. Can be increased.

  Capacitors C3 and C4 are Y capacitors for noise countermeasures, which are second capacitors. The resistors R3 and R4 are discharge resistors of the Y capacitor used for discharging the Y capacitors C3 and C4. The diodes D1 and D2 are diodes provided to prevent current from flowing backward, and the anode-side terminals of the diodes D1 and D2 are connected to the hot-side line and the neutral-side line, respectively. The diode D1 and the resistor R3 constitute a third discharge part, and the diode D2 and the resistor R4 constitute a fourth discharge part. The transistor Q1, which is a switching element, is a high voltage transistor used to cut off the current flowing through the discharge resistors R3 and R4 of the Y capacitor, and is turned on / off by the voltage Vcc as described later. In this embodiment, a high-breakdown-voltage bipolar transistor is used as the transistor Q1, but other switching elements such as FETs (field effect transistors) may be used. The resistor R9 is a pull-up resistor for driving the transistor Q1, and the resistor R8 is a resistor for protecting the transistor Q1. Even when only one of the Y capacitors C3 and C4 is provided, the effect of the discharge resistance of the Y capacitor described in the present embodiment can be obtained.

  Capacitors C1 and C201 are X capacitors for countermeasures against noise generated between power supply lines from the AC power supply, and one end is connected to the hot side line and the other end is connected to the neutral side line. Coil L200 is a common mode choke coil used to reduce noise. In order to reduce noise from the image heating apparatus 100, the X capacitor C <b> 1 and the common mode choke coil L <b> 200 that are the first capacitors need to be disposed between the image heating apparatus 100 and the AC power supply 201. If a fuse FU202 having a lower fusing current value than the fuse FU201 is provided between the X capacitor C1 and the AC power supply 201, a current supplied to the image heating apparatus 100 flows through the fuse FU202. The fuse FU202 is blown. Therefore, it can be seen that in the noise filter configuration using the X capacitor C1, the common mode choke coil L200, and the X capacitor C201, the fuse FU202 having a low fusing current value cannot be disposed in front of the X capacitor C1.

  The resistors R1, R201, and R2 are discharge resistors used for discharging the X capacitor C1. In addition, when the fuse FU202 is blown, the diode D201 that forms the discharge path of the X capacitor C1 is connected in parallel with the discharge resistor R201 of the X capacitor C1. The cathode side of the diode D201 is connected to the terminal connected to the hot side line which is the first line side among the terminals of the discharge resistor 201. Note that the combined resistance value of the resistor R1 and the resistor R201 connected in series and the resistance value of the resistor R2 are substantially the same or equal.

(Circuit operation when the fuse is not blown)
Next, the circuit operation of the power supply apparatus 200 when the power cable 50 is pulled out when the fuse FU202 is not blown will be described. When the power cable 50 is pulled out from the external power supply unit 40, the current paths of the three lines on the hot side, neutral side, and GND side of the external power supply unit 40 and the power supply device 200 are cut off. At this time, the X capacitor C1 may be charged, and the X capacitor C1 is charged when the power cable 50 is pulled out in order to prevent an electric shock by touching the terminal of the power cable 50 or the like. A means for discharging the generated electric charge is required. When the charged state of the X capacitor C1 is positive (the potential of the hot side line is higher than that of the neutral side line), the charge of the X capacitor C1 is discharged from the discharge resistors R201 and R1, which are the first discharge parts, and the bridge. It is discharged through the discharge path of the diode BD1. On the other hand, when the charge state of the X capacitor C1 is negative (the potential of the hot side line is lower than that of the neutral side line), the charge of the X capacitor C1 is discharged from the discharge resistor R2, which is the second discharge part, Discharge occurs through the discharge path of the resistor R5 and the bridge diode BD1.

  Here, when “the discharge resistance of the X capacitor” is defined as a resistance element that works to discharge the electric charge charged in the X capacitor when the power cable 50 is pulled out, the resistors R1, R201, and R2 are described above. Thus, the discharge resistance of the X capacitor. The resistor R5 is a resistor for adjusting the operation timing of the transistor Q2, and does not contribute to discharging the charge charged in the X capacitor. Further, since no current flows through the discharge resistances R3 and R4 of the Y capacitor when the transistor Q1 is in an off state, the charge charged in the X capacitor cannot be discharged, and the X capacitor is discharged as a resistance. Does not work. Therefore, the discharge resistances R3 and R4 of the Y capacitor do not function as the discharge resistance of the X capacitor used for preventing electric shock.

  However, the discharge resistances R1, R201, and R2 of the X capacitor can discharge the charges charged in the Y capacitors C3 and C4. However, since the resistance value is not sufficiently small with respect to the capacitances of the Y capacitors C3 and C4, CR delay occurs. As a result, as will be described with reference to FIG. 3 (described later), the detection accuracy of the zero cross timing is lowered due to the CR delay. Therefore, in order not to cause CR delay, the resistance values of the discharge resistances R3 and R4 of the Y capacitor are the resistance values of the discharge resistance R2 of the X capacitor that supplies current to at least the zero cross detection circuit 202 among the discharge resistances of the X capacitor. Smaller than that. That is, the magnitude relationship between the resistance values of the discharge resistors R2, R3, and R4 is (resistance value of the discharge resistor R2)> (resistance value of the discharge resistor R3), and (resistance value of the discharge resistor R2)> (discharge resistor R4). Resistance value). In the configuration of the present embodiment shown in FIG. 2, the resistor R2 has two functions of a zero-cross detection resistor of the zero-cross detection circuit 202 and a discharge resistor of the X capacitor C1. Here, by reducing the value of the resistor R2, the power consumption when the zero-cross detection circuit 202 operates can be reduced as compared with the conventional configuration.

[Outline of zero-cross detection circuit]
The zero cross detection circuit 202 will be described. The zero cross detection circuit 202 detects the timing at which the AC voltage of the AC power supply 201 crosses 0 V (volt), and outputs a zero cross signal to the CPU 203. Based on the zero-cross signal from the zero-cross detection circuit 202, the CPU 203 controls the power supply to the image heating apparatus 100 by power control means using a semiconductor switch such as a triac.

  When the potential of the neutral side line input from the AC power supply 201 is higher than the potential of the hot side line, the potential of the hot side line is the same as the reference potential DCL. Therefore, the resistors R2, R5, bridge diode from the neutral side line Current flows to BD1. Therefore, a current flows through the zero-cross detection circuit 202 via the zero-cross detection resistor R2 that is also the discharge resistance of the X capacitor. As a result, when a voltage corresponding to the voltage generated at both ends of the zero-cross detection resistor R2 is applied to the base terminal of the transistor Q2 of the zero-cross detection circuit 202, the transistor Q2 is turned on. When the transistor Q2 is turned on, no current flows through the LED of the photocoupler PC1, and the phototransistor of the photocoupler PC1 is turned off. When the phototransistor of the photocoupler PC1 is turned off, the output voltage V1 of the converter 1 increases the voltage of the zero cross signal via the pull-up resistor R7, and the high level zero cross signal is input to the CPU 203. . The resistor R5 and the capacitor C5 are used for adjusting the operation timing of the transistor Q2.

  On the other hand, when the potential of the neutral side line input from the AC power supply 201 is lower than the potential of the hot side line, the potential of the neutral side line is the same as the reference potential DCL, so that the resistors R201, R1,. A current flows to the bridge diode BD1. Accordingly, no current flows through the zero-crossing detection resistor R2, so that no voltage is applied to the base terminal of the transistor Q2, and the transistor is turned off. When the transistor Q2 is turned off, a current flows from the voltage Vcc through the pull-up resistor R6 to the LED of the photocoupler PC1, so that the phototransistor of the photocoupler PC1 is turned on. When the phototransistor of the photocoupler PC1 is turned on, a current flows from the voltage V1 to the phototransistor via the resistor R7, so that the zero cross signal input to the CPU 203 becomes a low level. The waveform of the zero cross signal will be described with reference to FIG.

  A CPU 203 illustrated in FIG. 2 controls the power supply apparatus 200 and the entire image forming apparatus. The CPU 203 has ROM and RAM (not shown) inside. The ROM is a memory that stores programs and data for controlling the power supply device 200 and the image forming apparatus, and the RAM is a memory that is used by the control program executed by the CPU 203 to temporarily store information. Details of the control sequence of the image forming apparatus by the CPU 203 will be described with reference to FIG.

[Circuit operation of zero cross detection circuit]
In FIG. 2, a voltage Vcc is a voltage supplied from the auxiliary winding of the converter 1 and is supplied to drive the zero-cross detection circuit 202 and the transistor Q1 via the phototransistor of the photocoupler PC2. Further, the CPU 203 generates a standby signal for controlling the power consumption of the zero-cross detection circuit 202 according to the operation mode of the image forming apparatus, and the photocoupler PC2 that intermittently supplies power to the zero-cross detection circuit 202. Output to. The CPU 203 outputs a high-level standby signal when the operation mode of the image forming apparatus is in the standby state, and low when the operation mode of the image forming apparatus is in the energy saving state. A level standby signal is output.

  When the standby signal output from the CPU 203 is in a high level state, a current flows through the LED of the photocoupler PC2, and the phototransistor of the photocoupler PC2 is turned on. As a result, the voltage from the auxiliary winding of the converter 1 is output, and the voltage Vcc is in a high state (a state in which the auxiliary winding voltage is output). On the other hand, when the standby signal output from the CPU 203 is in a low level state, no current flows through the LED of the photocoupler PC2, and the phototransistor of the photocoupler PC2 is turned off. As a result, the voltage from the auxiliary winding of converter 1 is not output, and voltage Vcc is in the low state (the same potential as reference potential DCL).

(Circuit operation during sleep)
In an energy saving state (first state) in which power consumption is suppressed, such as when the image forming apparatus is in a sleep state, the standby signal output from the CPU 203 is in a low level state, so that the voltage Vcc is also in a low level state as described above. When the voltage Vcc is in the low level state, as described above, no current flows through the resistor R6 of the zero-cross detection circuit 202, the LED of the photocoupler PC1, and the collector terminal of the transistor Q2, and the power consumption in the zero-cross detection circuit 202 is suppressed. be able to. Further, since the voltage Vcc is in the low level state, no voltage is applied to the base terminal of the transistor Q1, and the transistor Q1 is turned off. Therefore, the current flowing from the hot side line via the resistor R3 and the current flowing from the neutral side line via the resistor R4 are cut off because the transistor Q1 is in an off state, so that power consumption can be suppressed. Note that when the standby signal is in the low level state, the phototransistor of the photocoupler PC1 is always in the off state, so that the zero cross signal output to the CPU 203 is always at the high level, and the zero cross cannot be detected.

(Circuit operation during standby and image formation)
Next, in a state where the AC power supply zero-crossing timing can be detected (second state), such as when the image forming apparatus is on standby or during image formation, the standby signal output by the CPU 203 is in a high level state. The voltage Vcc is in a high level state. Since the voltage Vcc is in a high level state, a current flows through the resistor R6, the LED of the photocoupler PC1, and the collector terminal of the transistor Q2. Therefore, the zero cross detection circuit 202 is in a state where the zero cross timing of the input AC voltage can be detected, and the power consumption of the zero cross detection circuit 202 increases. Further, since the voltage Vcc is in the high level state, a voltage is applied to the base terminal of the transistor Q1, and the transistor Q1 is turned on. Therefore, the current flowing from the hot side line via the resistor R3 and the current flowing from the neutral side line via the resistor R4 flow into the zero cross detection circuit 202 via the transistor Q1, and the power consumption of the zero cross detection circuit 202 increases. . Therefore, in a state where the zero-cross timing can be detected (second state), the power consumed in the power supply device 200 is increased instead of detecting the zero-cross timing of the input AC voltage.

[Zero cross signal waveform]
FIG. 3 is a waveform diagram of a zero cross signal when a simulation is performed to explain the influence of the discharge resistances R3 and R4 of the Y capacitor of this embodiment on the detection accuracy of the zero cross timing. As the set values at the time of simulation, X capacitors C1 and C201 were 0.56 μF (microfarad) and 0.22 μF, respectively, and C3 and C4 of Y capacitor were 2200 pF (picofarad), respectively. Further, the simulation was performed by setting the discharge resistances R1, R201, and R2 of the X capacitor to 10 kΩ, 990 kΩ, and 1000 kΩ, respectively, and the discharge resistances R3 and R4 of the Y capacitor to 150 kΩ, respectively.

  FIG. 3A shows an input voltage waveform of the AC power supply 201 having a power supply frequency of 50 Hz (Hertz) and an effective value voltage of 220 V (volts), and the vertical axis shows the voltage (unit: V (volt)). The axis indicates time (unit: msec (millisecond)). FIG. 3A shows that one cycle of the input voltage waveform 301 is 20 msec since the power supply frequency is 50 Hz. Zerox1, Zerox2, Zerox3, and Zerox4 indicated by arrows in FIG. 3A indicate zero-cross timings at which the input voltage becomes 0 V in the input voltage waveform 301, respectively.

  FIG. 3B is a diagram showing a zero-cross signal waveform 302 in a state (second state) in which the current flowing through the discharge resistors R3 and R4 of the Y capacitor flows through the zero-cross detection circuit 202. In FIG. 3B, the vertical axis represents voltage (unit: V (volt)), and the horizontal axis represents time (unit: msec (millisecond)). It can be seen that the zero-cross signal falling timings Zerox1 and Zerox3 in the waveform 302 coincide with the zero-crossing timings Zerox1 and Zerox3 of the input voltage waveform 301 shown in FIG. Further, the CPU 203 can predict the timing of the zero cross timing Zerox4 by the following method. First, in order to calculate the period of the power supply frequency of the AC power supply 201, the time from the zero cross timing Zerox1 to Zerox3 is measured (in FIG. 3B, the power supply frequency is 50 Hz, so it is 20 msec). Next, it is possible to predict the timing of the zero cross timing Zerox4 by adding the time (10 msec) corresponding to the half cycle of the calculated power supply frequency cycle (20 msec) to the time of Zerox3 which is the falling timing of the zero cross signal. it can. As described above, the CPU 203 can predict both the rising and falling zero-cross timings when either the falling timing or the rising timing of the zero-cross signal is known.

  FIG. 3C is a diagram showing a zero-cross signal waveform 303 in a state where the current flowing through the discharge resistors R3 and R4 of the Y capacitor is interrupted. In FIG. 3C, the vertical axis represents voltage (unit: V (volt)), and the horizontal axis represents time (unit: msec (millisecond)). 3C shows that the rising and falling timings of the zero cross signal in the waveform 303 do not coincide with the zero cross timing of the input voltage waveform 301 shown in FIG. This error is caused by a difference in time required for the electric charges charged in the Y capacitors C3 and C4 to be discharged through the discharge resistor. That is, in the zero cross detection circuit 202 of FIG. 3B, the electric charge charged in the Y capacitor is discharged through the discharge resistances R3 and R4 of the Y capacitor. On the other hand, in the zero-crossing detection circuit 202 of FIG. 3C, the charge charged in the Y capacitor is not via the discharge resistances R3, R4 of the Y capacitor but via the discharge resistances R1, R201, or R2 of the X capacitor. Discharged. The combined resistance value of the discharge resistances R1 and R201 of the X capacitor or the resistance value of R2 set at the time of the simulation of FIG. 3 is 1000 KΩ, respectively, compared with 150Ω which is the resistance value of the discharge resistances R3 and R4 of the Y capacitor, The resistance value is large. For this reason, the above-described zero cross timing error occurs due to the CR delay with the Y capacitors C3 and C4. In the zero cross detection circuit 202 of FIG. 3B, the charges charged in the Y capacitors C3 and C4 are discharged through the discharge resistors R3 and R4 of the Y capacitor. Further, since the resistance values of the discharge resistors R3 and R4 of the Y capacitor are small, the CR delay is also smaller than in the case of FIG. 3C, and the accuracy of the zero cross timing can be improved.

  In addition, the error of the zero cross timing in the state of FIG. For this reason, it is difficult to accurately detect the zero-cross timing based on the zero-cross signal in FIG. 3C, but the power frequency (power source) of the AC power source 201 is determined based on the rising or falling timing and the number of times of the zero-cross signal waveform 303. Period) can be predicted.

[Power supply control sequence]
FIG. 4 is a flowchart for explaining a control sequence of the power supply apparatus 200 when the power supply of the image forming apparatus is turned on.

  When the power of the image forming apparatus is turned on, processing in step 401 (hereinafter referred to as S401) is performed. In step S401, the CPU 203 sets the image forming apparatus to the sleep state (first state) by setting the standby signal to the low level state and outputting it. As a result, the image forming apparatus enters an energy saving state, the current to the discharge resistances R3 and R4 of the Y capacitor is cut off, and the zero cross detection circuit 202 cannot detect the zero cross. In S402, the CPU 203 determines whether or not there is a request to shift the image forming apparatus to the power-off state by operating the power switch. If there is a request, the process ends. If there is no request, the process proceeds to S403. In S403, the CPU 203 determines whether there is a request to shift the image forming apparatus from the sleep state to the standby state. If there is a request, the process proceeds to S404, and if there is no request, the process returns to S402.

  In step S <b> 404, the CPU 203 sets the image forming apparatus to a standby state (second state) by setting and outputting a standby signal in a high level state. As a result, a current flows through the discharge resistors R3 and R4 of the Y capacitor, and power is supplied to the zero-cross detection circuit 202. In S <b> 405, the CPU 203 detects the zero cross timing of the input voltage of the AC power supply 201 based on the zero cross signal output from the zero cross detection circuit 202. In the present embodiment, adjustment is performed so that the falling timing of the zero cross signal coincides with the zero cross timing. When adjustment is performed so that the rising timing of the zero cross signal coincides with the zero cross timing, the zero cross timing of the input voltage of the AC power supply 201 may be detected based on the rising timing of the zero cross signal. In step S406, the CPU 203 determines whether there is a request to shift the image forming apparatus to the sleep state. If there is a request, the process returns to step S401, and if there is no request, the process returns to step S405. As described above, the CPU 203 can switch between the standby state in which the zero-cross detection circuit 202 can detect zero-crossing and the sleep state in which power consumption can be reduced by setting the output level of the standby signal to high level or low level. it can.

[Operation of power supply according to current fuse status]
(Operation before the current fuse is blown)
Next, the power consumed by the discharge resistance of the X capacitor before the fuse FU202 is blown by an overcurrent will be described. In FIG. 2, when the charged state of the X capacitor C1 is positive (the potential of the hot side line is higher than that of the neutral side line), the neutral side line and the DCL side line have the same potential. Therefore, the electric charge charged in the X capacitor C1 is discharged from the hot side line via the discharge resistances R201 and R1 and the bridge diode BD1 of the X capacitor. In this case, the diode D201 is turned off because the current is in the reverse direction, and the power consumed by the discharge resistance of the X capacitor is the power consumed by the combined resistance of the resistors R1 and R201.

  On the other hand, when the charged state of the X capacitor C1 is negative (the potential of the hot side line is lower than that of the neutral side line), the hot side line and the DCL side line have the same potential. Therefore, the charge charged in the X capacitor C1 is discharged from the neutral side line via the discharge resistance R2, resistance R5, and bridge diode BD1 of the X capacitor. As a result, the power consumed by the discharge resistor of the X capacitor is the power consumed by the discharge resistor R2. Note that the resistor R5 is not the discharge resistance of the X capacitor as described above.

(Operation when the current fuse is blown)
Next, a method for discharging the charge charged in the X capacitor in order to prevent an electric shock when the power cable is pulled out in a state where the fuse FU202 is blown by an overcurrent will be described. In this case, since the fuse FU202 provided between the connection point of the X capacitor C1 and the hot side line and the bridge diode BD1 is blown by overcurrent, the current path between the hot side line and the bridge diode BD1 is cut off. ing.

  In FIG. 2, when the fuse FU202 is blown and the charge state of the X capacitor C1 is positive (the potential of the hot side line is higher than that of the neutral side line), the discharge resistances R201, R1, X, It is discharged via the bridge diode BD1. However, when the fuse FU202 is blown and the charged state of the X capacitor C1 is negative (the potential of the hot side line is lower than that of the neutral side line), the discharge resistance R2 of the X capacitor and the bridge diode BD1 from the neutral side line. Discharge through the can not be. In this case, the electric charge of the X capacitor C1 is discharged through a path from the neutral side line to the discharge resistor R2, the resistor R5, the discharge resistor R1, the diode D201, and the hot side line. Since it passes through the discharge resistors R2 and R1, the discharge time becomes longer by the resistance value of the discharge resistor R1 than before the fuse FU202 is blown. Therefore, the combined resistance value of the discharge resistors R1 and R201 is left as it is, the resistance value of the discharge resistor R201 is increased, and the resistance value of the discharge resistor R1 is decreased. Thereby, the CR delay caused by the X capacitor C1 and the discharge resistor R1 can be reduced, and the discharge time of the X capacitor C1 can be shortened. In the state where the fuse FU201 is blown, the X capacitors C1 and C201 are blocked by the fuse FU201, so that an electric shock when the power cable is disconnected can be prevented.

  As described above, according to the present embodiment, it is possible to ensure safety when the current fuse is blown and to reduce power consumption in the zero cross detection circuit. In this embodiment, the current fuse is used as the current interrupting means. However, the present invention is not limited to the current fuse, and the same effect can be obtained even when other current interrupting means is used. Is possible.

  In the first embodiment, the embodiment of the power supply device 200 including the X capacitor and the Y capacitor for noise suppression has been described. In the second embodiment, as a modification of the first embodiment, a power supply device 600 including an X capacitor as a noise countermeasure will be described. The description of the same configuration as in the first embodiment is omitted.

[Outline of power supply]
FIG. 5 is a circuit diagram of the power supply apparatus 600 of the present embodiment. Compared with the power supply device 200 of the first embodiment, the power supply device 600 of FIG. 5 has Y capacitors C3 and C4 for noise suppression of FIG. 2, discharge resistors R3 and R4 of the Y capacitor, and discharge resistors R3 and R4 of the Y capacitor. The difference is that there is no transistor Q1 used to cut off the current to.

  Also in the power supply device 600 of FIG. 5, as in the power supply device 200 of the first embodiment, when the standby signal output from the CPU 203 is at a high level, power is supplied to the zero cross detection circuit 202 and a zero cross signal is output to the CPU 203. Is done. On the other hand, when the standby signal output from the CPU 203 is at a low level, no power is supplied to the zero-cross detection circuit 202, and power consumption in the zero-cross detection circuit can be suppressed.

  In FIG. 5, resistors R <b> 201, R <b> 1, and R <b> 2 are discharge resistors of the X capacitor C <b> 1, and the resistor R <b> 2 is also a zero-cross detection resistor of the zero-cross detection circuit 202. When the fuse FU202 is not blown and the potential of the hot side line is higher than that of the neutral side line, the charge charged to the X capacitor C1 is discharged from the hot side line to the discharge resistances R201, R1, It is discharged via the bridge diode BD1. On the other hand, when the potential of the hot side line is lower than that of the neutral side line, the charge charged in the X capacitor C1 passes through the discharge resistance R2, resistance R5, and bridge diode BD1 of the X capacitor from the neutral side line. Discharged.

  Next, in a state where the fuse FU202 is blown, if the potential of the hot side line is lower than that of the neutral side line, the charge charged in the X capacitor C1 cannot be discharged via the bridge diode BD1. . Therefore, when the potential of the hot side line is lower than that of the neutral side line, the charge of the X capacitor C1 is transferred from the neutral side line to the discharge resistor R2, resistor R5, discharge resistor R1, diode D201, and hot side line. Discharged.

  Further, also in this embodiment, the combined resistance value of the discharge resistors R1 and R201 is kept as it is, and the resistance value of the discharge resistor R201 is increased and the resistance value of the discharge resistor R1 is decreased, so that the CR delay is reduced as described above. The discharge time of the X capacitor C1 can be shortened. Even in the configuration without the Y capacitor as described above, the power consumed by the X capacitor discharge resistor can be reduced by having the diode as the third discharge path in the state where the current fuse is blown.

  As described above, according to the present embodiment, it is possible to reduce power consumption in the zero cross detection circuit and to ensure safety when the current fuse is blown. In the above-described embodiments, the description has been made on the assumption that the image forming apparatus forms a monochrome image. However, the present invention can also be applied to a color image forming apparatus. As a color image forming apparatus, a photosensitive drum as an image carrier for forming an image of each color of yellow, magenta, cyan, and black is arranged side by side, and an image is transferred from each photosensitive drum to a recording material or an intermediate transfer member. The present invention can be applied to a color image forming apparatus of a system for transferring the image. Further, the present invention can be applied to a color image forming apparatus in which images of respective colors are sequentially formed on one image carrier (photosensitive drum), a color image is formed on an intermediate transfer member, and transferred to a recording material.

BD1 Bridge diode C1 X capacitor C2 capacitor D201 Diode FU202 Current fuse R1, R2, R201 Discharge resistance

Claims (10)

A first capacitor connected between a first line to which an AC voltage is input from an AC power source and a second line;
Rectifying and smoothing means for full-wave rectifying and smoothing the AC voltage input via the first line and the second line;
A blocking means provided between a connection point between the first line and the first capacitor and the rectifying and smoothing means, and blocking the input of the AC voltage;
One end connected to the first line, the other end connected to the low-voltage side output end of the rectifying and smoothing means, and a first discharge unit for discharging the first capacitor;
One end connected to the second line, the other end connected to the low-voltage side output end of the rectifying and smoothing means, and a second discharge unit for discharging the first capacitor;
With
In a case where the potential of the first line is lower than the potential of the second line when the AC voltage input from the connection point to the rectifying and smoothing unit is blocked by the blocking unit, The one capacitor is discharged from the first discharge part through the second discharge part. The first discharge unit includes two resistance elements having different resistance values connected in series, and a diode connected in parallel to a resistance element having a larger resistance value of the two resistance elements. Have
2. The power supply device according to claim 1, wherein a terminal on a cathode side of the diode is connected to a terminal on the first line side of a resistance element to which the diode is connected. The second discharge part has a resistance element,
The power supply device according to claim 2, wherein a resistance value of the resistance element included in the second discharge unit is equal to a combined resistance value of two resistance elements included in the first discharge unit.   The power supply apparatus according to claim 1, wherein the interrupting unit is a current fuse. A detecting means for detecting a zero cross of the AC voltage input from the AC power supply;
5. The power supply device according to claim 3, wherein the detection unit detects a zero cross based on a voltage generated at both ends of the resistance element included in the second discharge unit.   The power supply apparatus according to claim 5, further comprising a switch unit that inputs and blocks the AC voltage to the detection unit. A second capacitor having one end connected to the high-voltage side output end and the low-voltage side output end of the rectifying and smoothing means, and each other end grounded;
A third discharge part having one end connected to the first line and discharging the second capacitor;
A fourth discharge part having one end connected to the second line and discharging the second capacitor;
One end is connected to the other ends of the third and fourth discharge units, the other end is connected to the low-voltage side output end of the rectifying and smoothing means, a switching element that is controlled on and off by the switch means,
Have
The switching element is turned on when the AC voltage is input to the detection means by the switch means, and the current from the third and fourth discharge parts flows, and the detection is performed by the switch means. 7. The power supply device according to claim 6, wherein when the input of the AC voltage to the means is cut off, the power supply device is turned off to cut off the currents of the third and fourth discharge units. The third and fourth discharge parts each have a diode and a resistance element connected in series,
The anode side terminal of the diode of the third discharge part is connected to the first line,
The anode side terminal of the diode of the fourth discharge part is connected to the second line,
The power supply device according to claim 7, wherein one end of the resistance element of each of the third and fourth discharge units is connected to the switching element.   The second capacitor is discharged by the first and second discharge sections when the input of the AC voltage to the detection means is blocked by the switch means. Item 9. The power supply device according to Item 7 or 8. An image forming apparatus having image forming means for forming an image on a recording material,
An image forming apparatus comprising the power supply device according to claim 1, wherein power is supplied to the image forming apparatus.

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