JP2010054306A - Zero cross detection circuit, and image forming device including zero cross detection circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a zero cross detection circuit dispensing with an excess power consumption in order to detect the point of time when a voltage of an AC power source crosses 0V, and an image forming device including the zero cross detection circuit. <P>SOLUTION: The image forming device 150 includes a main CPU 300 for realizing a general function as an image forming device; a main power source 318 connected to a breaker 330, for supplying power during a normal mode; a sub-power source 316 connected to the breaker 330, for supplying power during a power saving mode; a power source control part 314 for controlling supply of the power from the main power source 318 in response to a reset command from the power saving mode into the normal mode; and the zero cross detection circuit 342 connected to the breaker 330, for outputting a zero cross timing when the voltage of the AC power source 334 crosses 0V as a zero cross detection signal to both the power source control part 314 and the main CPU 300 through a bus 336. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a zero-cross detection circuit, and more particularly to a zero-cross detection circuit that detects a point where the voltage of an AC power supply crosses 0 V, and an image forming apparatus including the zero-cross detection circuit.

  In recent years, various devices are equipped with a zero-cross detection circuit for detecting a point where the voltage of an AC power supply passes 0V.

  Such a zero-cross detection circuit is used, for example, to detect a power failure. A device is connected to an AC power supply and is operating, and includes a zero cross detection circuit connected to the AC power supply. When the AC power supply is operating normally, the zero cross detection circuit detects zero cross timing, which is a point at which the voltage of the AC power supply passes 0 V at a predetermined time interval. For example, the predetermined time is 1/120 second.

  However, if a power failure occurs and the operation of the AC power supply is stopped, the zero cross detection circuit does not detect the zero cross timing. If a power outage occurs, the equipment needs to be shut down safely and immediately. Therefore, if the zero cross timing is not detected for a certain period of time (for example, 1 second), if the device is safely stopped, a failure of the device can be avoided.

  Patent Document 1 discloses such a zero-cross detection circuit. FIG. 1 is a diagram illustrating a zero cross detection circuit 50 disclosed in Patent Document 1 and connected to an AC power supply 54. Referring to FIG. 1, a zero-cross detection circuit 50 includes a diode 56 whose anode is connected to one end of an AC power supply 54, a diode 58 whose anode is connected to the other end of the AC power supply 54, and a cathode that is an AC power supply. 54 includes a diode 60 connected to one end of 54, and a diode 62 whose cathode is connected to the other end of AC power supply 54.

  The zero-cross detection circuit 50 is further connected to a photocoupler 66 composed of a light emitting diode 68 and a transistor 70, one end connected to the cathode of the diode 56 and the cathode of the diode 58, and the other end connected to the anode of the light emitting diode 68. A resistor 64. The other end of the light emitting diode 68 is connected to the anode of the diode 60 and the anode of the diode 62. The emitter of the transistor 70 is connected to the ground potential.

  The zero cross detection circuit 50 further includes a resistor 72 having one end and the other end connected to the power supply potential and the collector of the transistor 70, respectively. It is assumed that the connection point between the other end of the resistor 72 and the collector of the transistor 70 is connected to a CPU (Central Processing Unit) of the device including the zero cross detection circuit 50.

  The zero cross detection circuit 50 further has one end connected to one end of the AC power supply 54 and the anode of the diode 56, and the other end connected to the other end of the AC power supply 54 and the anode of the diode 58, not shown. A switching power supply 52 for supplying power to the motor of the apparatus.

  The zero cross detection circuit 50 operates as follows.

  When the voltage of the AC power supply 54 is not 0 V, a current flows from the AC power supply 54 to the resistor 64 and the light emitting diode 68 via either one of the diodes 56 and 58, and the light emitting diode 68 emits light. While the light emitting diode 68 emits light, the collector and the emitter of the transistor 70 are brought into conduction, and the potential at the connection point between the other end of the resistor 72 and the collector of the transistor 70 becomes a low level.

  When the voltage of the AC power supply 54 crosses 0 V, almost no current flows through the resistor 64 and the light emitting diode 68, and the light emitting diode 68 does not emit light. Therefore, the collector and emitter of the transistor 70 are not conducted, and the potential at the connection point between the other end of the resistor 72 and the collector of the transistor 70 becomes high level.

The CPU detects the zero-cross timing by determining whether or not the potential at the connection point between the other end of the resistor 72 and the collector of the transistor 70 is at a low level.
JP 2001-218450 A

  Comparing the time when the AC power supply is not 0 V and the time crossing 0 V, the time that is not 0 V is usually much longer. In the zero cross detection circuit described in Patent Document 1, current always flows through the resistor 64 while the AC power supply 54 is not 0V. Meanwhile, the loss of the resistor 64 becomes very large. In particular, since the standby power of the set has recently reached a level of several watts, even if the power consumption of the resistor 64 is about 1 watt, the overall power consumption is greatly affected.

  Reducing standby power that consumes power for a long time has a significant effect on reducing power consumption of the entire set, and thus reducing power consumption of the resistor 64 is an important issue.

  Accordingly, an object of the present invention is to provide a zero-cross detection circuit that does not require extra power consumption to detect when the voltage of the AC power supply crosses 0 V, and an image forming apparatus including the zero-cross detection circuit. .

  The zero cross detection circuit according to the first aspect of the present invention is a circuit that detects a zero cross timing of an input AC waveform and outputs a detection signal to an external device. The zero-cross detection circuit accumulates power when the absolute value of the AC waveform voltage and the AC waveform voltage is greater than a predetermined voltage, and discharges power to the input of the photocoupler when the absolute value of the AC waveform voltage is less than the predetermined voltage. And a driving circuit for providing.

  The drive circuit accumulates electric power when the absolute value of the AC waveform voltage is larger than a predetermined voltage, and discharges the electric power when the absolute value of the AC waveform voltage is smaller than the predetermined voltage to be applied to the input of the photocoupler. When it is desired to detect the zero cross timing of the AC waveform, the value of the predetermined voltage may be set to a value close to zero. Comparing the time when the voltage of the AC waveform is smaller than the predetermined voltage and the larger time, the time larger than the predetermined voltage is considerably longer. Since the drive circuit gives an input to the photocoupler when the voltage of the AC waveform is smaller than the predetermined voltage, the time for giving the input to the photocoupler is short. Therefore, the power consumption for detecting the zero cross timing of the AC waveform can be considerably reduced. As a result, it is possible to provide a zero-crossing detection circuit that does not require extra power consumption in order to detect when the voltage of the AC power supply crosses 0V.

  Preferably, the drive circuit is rectified by the rectifying means for rectifying the AC waveform, the switching means that is turned on or off according to whether the voltage rectified by the rectifying means is equal to or higher than a predetermined threshold, and the rectifying means. A capacitive element having one end connected to receive the voltage and the other end connected to the reference voltage. One input of the photocoupler is connected to one end of the capacitive element. The drive circuit further includes a switching element having a control terminal connected to one end of the capacitive element, a one-way terminal connected to the other input of the photocoupler, and another terminal connected to the reference voltage.

  More preferably, the switching element includes a transistor having a base connected to one end of the capacitive element, a collector connected to the other input of the photocoupler, and an emitter connected to a reference voltage.

  More preferably, the switching means includes a voltage dividing means for dividing the voltage rectified by the rectifying means at a predetermined voltage dividing ratio, a gate connected to receive the voltage divided by the voltage dividing means, and the rectifying means. And a MOSFET having a drain connected to the output and a source connected to a reference voltage.

  An image forming apparatus according to a second aspect of the present invention includes the zero cross detection circuit described above.

  Since the image forming apparatus includes the above-described zero-cross detection circuit, it is possible to perform various processes according to the detection signal detected by the zero-cross detection circuit and does not consume extra power. As a result, it is possible to provide an image forming apparatus that does not require extra power consumption in order to detect when the voltage of the AC power supply crosses 0V.

  Preferably, the image forming apparatus further includes a fixing device and means for controlling the temperature of the fixing device in response to the zero cross detection circuit outputting a detection signal.

  More preferably, the image forming apparatus is stored in the volatile storage device in response to the volatile storage device, the nonvolatile storage device, and the zero cross detection circuit not outputting a detection signal for a predetermined time. Control means for copying the data to the non-volatile storage device.

  More preferably, the image forming apparatus operates by receiving power from the first power supply and operates in response to a start signal, and power from a second power supply different from the first power supply. In response to the fact that the detection signal is not output for a predetermined time by the zero cross detection circuit and the new detection signal is output after the predetermined time has passed, the activation signal is sent to the control means. Power supply control means for outputting.

  As described above, according to the present invention, the power consumption for detecting the zero-cross timing of the AC waveform can be considerably reduced. As a result, it is possible to provide a zero-crossing detection circuit that does not require extra power consumption and an image forming apparatus including the zero-crossing detection circuit in order to detect when the voltage of the AC power supply crosses 0V.

  In the following description of the embodiments, the same parts are denoted by the same reference numerals. Their functions and names are also the same. Therefore, detailed description thereof will not be repeated.

[Overall Configuration of Image Forming Apparatus 150]
FIG. 2 is a perspective view showing an appearance of image forming apparatus 150 according to the embodiment of the present invention. FIG. 3 is a diagram showing a simplified internal configuration of the image forming apparatus 150.

  2 and 3, image forming apparatus 150 according to the present embodiment is a digital multi-function peripheral, and is a copy mode in which an image of a document is read and printed on recording paper, and an image of the document is read and transmitted. In addition, a facsimile mode in which an image of a document is received and printed on a recording sheet, and a printer mode in which an image received from an information terminal device (not shown) through a network is printed on a recording sheet can be selectively performed.

  The image forming apparatus 150 includes a document reading unit 152, an image forming unit 154, a paper feeding unit 156, and a paper discharge processing device 158.

  Here, the internal configuration of the image forming apparatus 150 will be described by explaining the operation in the copy mode.

  When a document is set on document set tray 162 of document reading unit 152, document detection sensor 164 detects that the document is set. When the user operates the operation device 166 of the document reading unit 152, the print paper size, the scaling factor, and the like are input and set. Thereafter, an instruction to start copying is given according to the operation content of the operation device 166.

  In response to the operation of the operation device 166, the document reading unit 152 pulls out each document on the document setting tray 162 one by one by the pickup roller 200, and the document is moved through the platen glass 202 and the conveying roller 204 through the platen glass. The document is fed out to 206 and conveyed in the sub-scanning direction on the platen glass 206 and discharged to the document discharge tray 208.

  At this time, the first reading unit 210 reads the surface (lower side) of the document. The first scanning unit 212 of the first reading unit 210 is moved and positioned at a predetermined position, and the second scanning unit 214 is positioned at a predetermined position. The exposure lamp of the first scanning unit 212 irradiates the surface of the document through the platen glass 206, and the reflected light of the document is imaged by the reflecting mirrors of the first scanning unit 212 and the second scanning unit 214. Then, the reflected light of the original is condensed on a CCD (Charge Coupled Device) 218 by an imaging lens 216, and an image on the surface of the original is formed on the CCD 218 to read the image on the surface of the original.

  The second reading unit 220 reads the back surface (upper side surface) of the document. The second reading unit 220 is disposed above the platen glass 206. The second reading unit 220 includes an LED (Light Emitting Diode) array, a fluorescent lamp, and the like, an exposure lamp that irradiates the back surface of the document, a lens array that collects reflected light of the document for each pixel, and the lens array. A contact image sensor (CIS) that photoelectrically converts the reflected light of the original received through and outputs an analog image signal.

  Further, it is possible to open the upper housing of the document reading unit 152, place the document on the platen glass 206, and read the surface of the document by the first reading unit 210 in this state. In this case, the first scanning unit 212 and the second scanning unit 214 are moved in the sub-scanning direction while maintaining a predetermined speed relationship with each other, and the original on the platen glass 206 is exposed by the first scanning unit 212. Then, the first scanning unit 212 and the second scanning unit 214 guide the reflected light from the document to the imaging lens 216, and the imaging lens 216 forms an image of the document on the CCD 218.

  When one or both sides of a document are read, image data indicating an image on one or both sides of the document is input to a main CPU 300 including a microcomputer shown in FIG. 4, and various image processing is performed on the image data. The image data is output to the image forming unit 154.

  The image forming unit 154 prints an image of a document indicated by image data on a recording sheet. The image forming unit 154 includes a photosensitive drum 222, a charging device 224, a laser scan unit (hereinafter referred to as “LSU”) 226, and development. A device 228, a transfer device 230, a cleaning device 232, a fixing device 234, a static elimination device (not shown), and the like are provided.

  The image forming unit 154 is provided with a main transport path 236 and a reverse transport path 238, and the recording paper fed from the paper feed unit 156 is transported along the main transport path 236. The paper feeding unit 156 pulls out the recording paper stored in the paper cassette 240 or the recording paper placed on the manual feed tray 242 one by one and sends the recording paper to the main conveyance path 236 of the image forming unit 154.

  While the recording paper is being conveyed along the main conveyance path 236 of the image forming unit 154, the recording paper passes between the photosensitive drum 222 and the transfer device 230, and further passes through the fixing device 234 to be recorded. Printing on paper is performed.

  The photosensitive drum 222 rotates in one direction, and its surface is cleaned by the cleaning device 232 and the static eliminator and then uniformly charged by the charging device 224.

  The LSU 226 modulates the laser beam based on the image data from the document reading unit 152, and repeatedly scans the surface of the photosensitive drum 222 in the main scanning direction with this laser beam, thereby causing the electrostatic latent image on the surface of the photosensitive drum 222. Form.

  The developing device 228 supplies toner to the surface of the photosensitive drum 222 to develop the electrostatic latent image, and forms a toner image on the surface of the photosensitive drum 222.

  The transfer device 230 transfers the toner image on the surface of the photosensitive drum 222 onto a recording sheet that passes between the transfer device 230 and the photosensitive drum 222.

  The fixing device 234 includes a heating roller 248 for heating the recording paper and a pressure roller 250 for pressing the recording paper. The recording sheet is heated by the heating roller 248 and pressed by the pressure roller 250, whereby the toner image transferred onto the recording sheet is fixed on the recording sheet.

  A branching claw 244 is disposed at a connection position between the main conveyance path 236 and the reverse conveyance path 238. When printing is performed only on one side of the recording paper, the branch claw 244 is positioned, and the recording paper from the fixing device 234 is guided to the paper discharge tray 246 or the paper discharge processing device 158 by the branch claw 244.

  On the other hand, when printing is performed on both sides of the recording paper, the branching claw 244 is rotated in a predetermined direction to guide the recording paper toward the reverse conveyance path 238. Then, the recording sheet passes through the reverse conveyance path 238, is turned upside down, and is conveyed again to the main conveyance path 236, and printing on the back surface is performed during the conveyance of the main conveyance path 236 again. Then, the paper is guided toward the paper discharge tray 246 or the paper discharge processing device 158.

  The recording paper printed as described above is guided toward the paper discharge tray 246 or the paper discharge processing device 158 and discharged to the paper discharge tray 246, or on each paper discharge tray 168 of the paper discharge processing device 158. It is discharged to either.

  The paper discharge processing device 158 performs processing for sorting and discharging a plurality of recording papers to each paper discharge tray 168, processing for punching each recording paper, and processing for stapling each recording paper. For example, when creating a plurality of printed materials, each recording sheet is sorted and discharged to each paper discharge tray 168 so that a part of the printed material is allocated to each paper discharge tray 168. In addition, a punching process or a stapling process is performed on each recording sheet on the discharge tray 168 to create a printed matter.

[Hardware Configuration of Image Forming Apparatus 150]
FIG. 4 is a block diagram illustrating a hardware configuration of the image forming apparatus 150.

  Referring to FIG. 4, the image forming apparatus 150 digitally processes the document reading unit 152 capable of reading the document image and the image signal read by the document reading unit 152, converts the image signal into a digital signal, and outputs the digital signal. And an image forming unit 154 that performs print output to reproduce the color of the image read by the document reading unit 152 by the electrophotographic formation process and form the image on a sheet.

  The image forming apparatus 150 further communicates between an image memory 310 for storing image data digitally processed by the image processing unit 304 and a PC (Personal Computer) 332 via a LAN (Local Area Network) 338. A network interface card (NIC) 312 for performing the operation, and an operation device 166 that is used when the user operates the image forming apparatus 150 and is an operation panel including the display unit 172 and the operation unit 170 are included.

  The image forming apparatus 150 further includes a bus 336 connected to the document reading unit 152, the image processing unit 304, the image forming unit 154, the image memory 310, the NIC 312, and the operation device 166, and an image connected to the bus 336. Main CPU (Central Processing Unit) 300 for realizing general functions as a forming apparatus, ROM (Read Only Memory) 306 for storing programs executed by the main CPU 300, and storage areas for various programs RAM (Random Access Memory) 308 and HDD (Hard Disk Drive) 340 which is a non-volatile storage device capable of storing various programs and data even when the power is turned off.

  The image forming apparatus 150 further includes a breaker 330 operated by a user to turn on or off the supply of power from the AC power source 334 and a power source connected to the breaker 330 and supplied from the AC power source 334 to a DC power source. A main power source 318 for supplying power in the normal mode, and a power source connected to the breaker 330 for converting the power source supplied from the AC power source 334 to a DC power source for supplying power in the power saving mode A sub power source 316, a power source control unit 314 for controlling the supply of power from the main power source 318 in response to an instruction to return from the power saving mode to the normal mode by an operation of the operation device 166 by the user, and a breaker 330, and the power supply control is performed with the zero-crossing timing as a zero-crossing detection signal when the voltage of the AC power supply 334 crosses 0V. Through 314 and the bus 336 and a zero-cross detection circuit 342 for outputting to both the main CPU 300.

  The main CPU 300 governs overall control of the image forming apparatus 150. Note that the main CPU 300 controls the document reading unit 152, the image processing unit 304, the image forming unit 154, the NIC 312, the image memory 310, the operation device 166, the ROM 306, and the RAM 308.

  The main CPU 300 includes a timer (not shown) for measuring time. The main CPU 300 executes processing to be described later, which outputs a command for controlling the temperature of the fixing device 234 to the sub CPU 320 according to the time counted by the timer.

  The operation unit 170 of the operation device 166 is a switch operated by a user to switch between the normal mode and the power saving mode, and outputs a locker that outputs whether the switch is turned on or off to the power supply control unit 314. A switch 176 is included.

  When the rocker switch 176 is on, it indicates the normal mode, and when the rocker switch 176 is off, it indicates the power saving mode.

  The image forming unit 154 heats the heating roller 248 and outputs the temperature of the heating roller 248 as an analog signal, and converts the analog signal of the temperature of the heating roller 248 output by the fixing device 234 into a digital signal. And an A / D conversion unit 326 that outputs the data.

  The image forming unit 154 further receives a driver 322 that is a control circuit for controlling the heating roller 248 of the fixing device 234 to heat, and a digital signal output by the A / D conversion unit 326, and receives a power control unit. The sub CPU 320 transmits a heater control signal instructing the driver 322 to heat the heating roller 248 of the fixing device 234 in cooperation with the driver 322.

  The fixing device 234 is connected to the driver 322 and includes a fixing heater 324 for heating the heating roller 248 and a fixing temperature sensor 328 for reading the temperature of the heating roller 248 and outputting it as an analog signal.

  In the normal mode, the main power supply 318 includes the main CPU 300, the document reading unit 152, the image processing unit 304, the operation device 166, the image memory 310, the ROM 306, the RAM 308, the HDD 340, the NIC 312, and the sub CPU 320 of the image forming unit 154, the driver 322, Power is supplied to the A / D converter 326 and the fixing temperature sensor 328. The main power supply 318 stops supplying power in the power saving mode.

  The sub power source 316 supplies power to the power control unit 314 in the power saving mode, and stops supplying power in the normal mode.

  Since the sub power source 316 converts the AC power source into the DC power source, the sub power source 316 includes a rectifying element for rectifying the voltage of the AC power source and a capacitive element such as an electrolytic capacitor for smoothing the voltage rectified by the rectifying element. In order to rectify and smooth the voltage of the AC power supply, how the rectifying element and the capacitive element are connected is a well-known technique, and therefore it will not be described in detail here.

  In response to the rocker switch 176 being switched from off (power saving mode) to on (normal mode), the power control unit 314 supplies a power control signal to the main power source 318 to supply power to the main power source 318. Output.

  Normally, when the user turns off the breaker 330 in the power saving mode, the supply of power from the sub power supply 316 is stopped, and the supply of power to the power supply control unit 314 is also stopped. Thereafter, when the user turns on the breaker 330 after a certain period of time, the power supply control unit 314 is activated and outputs an activation signal so that the main CPU 300 operates in the normal mode. Accordingly, when the breaker 330 is turned off and turned on at a long time interval, the image forming apparatus 150 is activated in the normal mode.

  It is assumed that the user turns off the breaker 330 in an attempt to put the image forming apparatus 150 operating in the power saving mode into a state operating in the normal mode. When the user turns on the breaker 330 shortly thereafter, the power supply control unit 314 continues to operate for a few seconds due to the charge stored in the capacitive element of the sub power supply 316. Therefore, in the power saving mode, if the breaker 330 is turned off and turned on within a short time interval, the power saving mode is maintained and the normal mode may not be entered.

  This is because the operation of the image forming apparatus 150 differs between when the breaker 330 is turned off and when it is turned on for a long time, and the user may be confused.

  Therefore, the power supply control unit 314 outputs an activation signal for activating the main CPU 300 in the normal mode to the main CPU 300 when the breaker 330 is turned off and turned on during a predetermined time interval in the power saving mode. . Details of the processing will be described later. Hereinafter, the predetermined time interval is referred to as “waiting time”, and the waiting time is assumed to be about 10 seconds. However, the waiting time is not limited to 10 seconds, and may be freely determined according to the use of the user. The power supply control unit 314 includes a timer (not shown) for measuring time. The power supply control unit 314 outputs an activation signal according to the time counted by the timer.

[Circuit configuration]
FIG. 5 is a circuit diagram of the zero cross detection circuit 342. Referring to FIG. 5, the zero-cross detection circuit 342 includes a diode 370 and a diode 372 whose anodes are respectively connected to one end and the other end of the AC power source 334, and each cathode thereof is one end of the AC power source 334. And a diode 374 and a diode 376 connected to the other end.

  The zero-cross detection circuit 342 further includes a resistor 380 and a resistor 378, one end of which is connected to the cathode of the diode 370 and the cathode of the diode 372, one end of which is connected to the other end of the resistor 380, and the other end of the diode 374. A resistor 384 connected to the anode of the diode 376 and an anode connected to the other end of the resistor 384 and a cathode connected to the other end of the resistor 380 and one end of the resistor 384. Including.

  The zero-cross detection circuit 342 further includes a resistor 388 having one end connected to the other end of the resistor 378, a gate, a drain, and a source, respectively, the cathode of the Zener diode 382, the other end of the resistor 388, and the anode of the Zener diode 382. An electrolytic capacitor in which a positive electrode is connected to the other end of the resistor 378 and one end of the resistor 388, and a negative electrode is connected to the source of the MOSFET 386, which is connected to the MOSFET (Metal Oxide Semiconductor Field Effect Transistor) 386 392.

  The zero-cross detection circuit 342 further includes a photocoupler 396 including a light emitting diode 398 and a transistor 402, one end of which is connected to the other end of the resistor 378, one end of the resistor 388, and a positive electrode of the electrolytic capacitor 392, and the other end. A resistor 390 connected to the anode of the diode 398, its base connected to the other end of the resistor 388 and the drain of the MOSFET 386, and a collector and an emitter connected to the cathode of the diode 398 and the negative electrode of the electrolytic capacitor 392, respectively. The transistor 394 includes a power supply potential and a resistor 400 connected to the collector of the transistor 402 at one end and the other end. Note that the emitter of the transistor 402 is connected to the ground potential. A connection point between the other end of the resistor 400 and the collector of the transistor 402 is connected to the main CPU 300 via the power supply control unit 314 and the bus 336.

  FIG. 6 is a circuit diagram of the driver 322 and the fixing heater 324. Referring to FIG. 6, driver 322 has one end connected to resistor 450 connected to main power supply 318, photocoupler 452 including diode 454 and triac 456, and a heater control signal from sub CPU 320. A transistor 458 having a base and a cathode of a diode 454, and a collector and an emitter respectively connected to ground potential.

  The driver 322 further includes a triac 460 having a gate connected to one end of the triac 456 and one end of the terminal excluding the gate connected to the other end of the triac 456, and one end connected to one end of the triac 456. The other end includes a resistor 462 connected between one end of the AC power supply 334 and the other end of the terminals other than the gate of the triac 460.

  The fixing heater 324 has one end connected to the other end of the triac 456 and one end of the terminals of the triac 460 excluding the gate, and the other end connected to the other end of the AC power source 334. including.

  Here, the heater control signal output from the sub CPU 320 to the driver 322 is a current, and by outputting these signals, a current flows through the base of the transistor 458.

Software configuration
7 and 8 are flowcharts showing a control structure of a program executed by the image forming apparatus 150. FIG.

  FIG. 7 is a flowchart illustrating a control structure of a program executed by the main CPU 300 when the image forming apparatus 150 is activated. Referring to FIG. 7, this program determines whether or not a zero-cross detection signal is output from zero-cross detection circuit 342 after step 506 for resetting the timer and after step 506, and the flow of control according to the determination result And step 508 which outputs a command for controlling the fixing device 234 to the sub CPU 320 and returns the control to step 506 when the determination result in step 500 is YES. In step 508, when the sub CPU 320 receives a command from the main CPU 300, the sub CPU 320 controls the fixing device 234 to maintain a predetermined temperature.

  FIG. 9 is a diagram illustrating a relationship between the zero cross detection signal and the timing at which the main CPU 300 outputs a command. Referring to FIG. 9, a waveform curve 560 shows the AC voltage of the AC power source 334 that varies with time. Points 562 to 570 on the time axis are points at which the AC voltage crosses 0V. At each of the points 562 to 568, the main CPU 300 sends a command for driving the fixing heater 324 to the sub CPU 320 during a time period 572 to 578 from a point slightly after the point to a point that crosses 0V. Output. The sub CPU 320 performs control so that the fixing heater 324 maintains a predetermined temperature in the time period 572 to 578.

  The program further determines whether or not the time counted by the timer is equal to or longer than a predetermined time when the determination result in step 500 is NO and branches the control flow according to the determination result. Including. If the determination result in step 504 is NO, the control returns to step 500. The predetermined time in step 504 may be any time as long as it is a time for detecting whether the breaker 330 is turned off or the AC power source 334 is stopped. Normally, the AC power supply 334 crosses 0 V approximately every 1/120 seconds, so the zero cross detection circuit 342 outputs a zero cross detection signal every 1/120 seconds. Therefore, when the zero cross detection circuit 342 does not output the zero cross detection signal for a time considerably longer than 1/120 seconds, it is assumed that the breaker 330 is turned off or the AC power source 334 is stopped. In the present embodiment, the predetermined time is defined as 1 second.

  This program further includes a step 504 of copying the data stored in the RAM 308 to the HDD 340 and returning the control to the step 500 when the determination result in the step 502 is YES.

  FIG. 8 shows a control structure of a program executed by the power supply control unit 314 in the power saving mode. Referring to FIG. 8, this program determines whether or not a zero-cross detection signal is output by zero-cross detection circuit 342 after step 532 for resetting the timer and step 532, and the flow of control according to the determination result Branching 530. If the determination result in step 530 is YES, the control returns to step 532.

  The program further determines whether or not the time measured by the timer exceeds a predetermined time when the determination result in step 530 is NO, and branches the control flow in accordance with the determination result. Including. If the determination result of step 534 is NO, the control returns to step 532. The determination processing in step 530 and step 534 described above is processing for determining whether the AC power source 334 is out of order or whether the breaker 330 is off.

  The program further determines whether or not the time measured by the timer is shorter than the standby time when the determination result in step 534 is YES, and branches the control flow according to the determination result; And a step 538 of determining whether or not a zero cross detection signal is output from the zero cross detection circuit 342 when the determination result of 536 is YES and branching the control flow according to the determination result.

  If the determination result in step 536 is NO, this program ends. If the determination result of step 538 is NO, the control returns to step 536.

  The determination processing in step 536 and step 538 is processing for determining whether or not the breaker 330 is turned on before the standby time elapses after the breaker 330 is turned off in the power saving mode.

  The program further includes a step 540 of outputting a start signal to the main CPU 300 and returning the control to the step 532 when the determination result of step 538 is YES.

  When the main CPU 300 receives the activation signal, the main CPU 300 operates the image forming apparatus 150 in the normal mode.

[Operation]
2 to 9, image forming apparatus 150 having the above-described configuration operates as follows.

  When the image forming apparatus 150 is activated, power is supplied from the AC power source 334 to the zero cross detection circuit 342, the main power source 318, and the sub power source 316 via the breaker 330.

(Operation of the zero cross detection circuit 342)
Hereinafter, the operation of the zero cross detection circuit 342 when the voltage of the AC power supply 334 is not 0 V will be described.

  A current from the AC power supply 334 flows through either the diode 370 or the diode 372. The current flows separately from both the resistor 380 and the resistor 378 from the connection point between the cathode of the diode 370 and the cathode of the diode 372.

  The current flowing through the resistor 380 is divided into the resistor 384 and the base of the MOSFET 386 and flows. Since current flows through the resistor 380 and the resistor 384, the voltage of the AC power supply 334 is divided by the resistor 380 and the resistor 384.

  If a voltage higher than a predetermined value is applied to the gate of the MOSFET 386, the MOSFET 386 may break down. The predetermined value is determined by the performance of the MOSFET 386. However, since the Zener diode 382 is connected to the gate of the MOSFET 386, when a voltage higher than a predetermined value is likely to be applied to the gate of the MOSFET 386, the current flowing from the resistor 380 is not limited to the base of the resistor 384 and the MOSFET 386. The zener diode 382 also flows. By doing so, the voltage of the gate of the MOSFET 386 is kept so as not to exceed a predetermined value. As a result, failure of the MOSFET 386 can be prevented.

  The current flowing through the resistor 378 flows through the drain and source of the MOSFET 386 through the resistor 388. In this case, the current flowing through the gate of MOSFET 386 causes the resistance between the drain and source of MOSFET 386 to be much smaller than the resistance between the base and emitter of transistor 402. Therefore, most of the current flowing through the resistor 388 flows to the drain and source of the MOSFET 386. Since almost no current flows through the base of the transistor 394, almost no current flows from the resistor 378 through the resistor 390.

  As a result, when the voltage of the AC power supply 334 is not 0 V, the zero cross detection circuit 342 does not flow much current through the resistor 390, so that the diode 398 of the photocoupler 396 does not emit light. In that case, the potential at the other end of the resistor 400 is at a high level.

  Hereinafter, the operation of the zero cross detection circuit 342 when the voltage of the AC power supply 334 crosses 0V will be described.

  When the voltage of the AC power supply 334 is close to 0 V, no current flows through any of the diode 370 and the diode 372, and no current flows through the resistor 380, the resistor 384, and the gate of the transistor 402.

  In this case, the current flowing from the positive electrode of the electrolytic capacitor 392 flows to the resistor 388.

  Since no current flows through the gate of the MOSFET 386, the current flowing through the resistor 388 flows through the base of the transistor 394 as it is.

  The current flowing from the positive electrode of the electrolytic capacitor 392 is divided into a resistor 388 and a resistor 390, and the diode 398 emits light. The collector and the emitter of the transistor 402 are brought into conduction, and the potential at the other end of the resistor 400 is at a low level.

  As described above, when the voltage of the AC power supply 334 is not 0V, the potential of the other end of the resistor 400 is at a high level, and when the voltage of the AC power supply 334 is close to 0V, the potential of the other end of the resistor 400 is at a low level.

  Each of the main CPU 300 and the power supply control unit 314 always determines whether or not the potential of the other end of the resistor 400 of the zero cross detection circuit 342 is at a high level. When the potential at the other end of the resistor 400 becomes a low level, the main CPU 300 and the power supply control unit 314 consider that the zero-cross detection circuit 342 outputs a zero-cross detection signal.

  Since the period in which the AC voltage of the AC power supply 334 crosses 0 V is approximately 1/120 seconds, the zero-cross detection circuit 342 outputs a zero-cross detection signal every 1/120 seconds.

  Hereinafter, the operation of the main CPU 300 will be described.

  When the image forming apparatus 150 is activated, the main CPU 300 outputs a command for controlling the temperature of the fixing device 234 to the sub CPU 320 every time the zero cross detection circuit 342 outputs a zero cross detection signal (see FIG. 7). Step 508), and the timer is reset (Step 506 shown in FIG. 7).

  When the sub CPU 320 receives the command, it controls the temperature of the fixing device 234. When the temperature of the heating roller 248 has not reached the predetermined temperature, the sub CPU 320 outputs a heater control signal to the driver 322.

  Referring to FIG. 6, as a result, a current flows through the base of transistor 458 of driver 322.

  When a current flows through the base of the transistor 458, a current flows from the main power source 318 to the resistor 450 and the diode 454 of the photocoupler 452, and the diode 454 emits light. Due to the light emission of the diode 454, a current flows through the triac 456 and the triac 460, and a current flows through the resistor 464 of the fixing heater 324. As a result, the resistor 464 generates heat. Due to the heat generated by the resistor 464, the temperature of the heating roller 248 increases.

  Assume that the user turns off the breaker 330.

  When a predetermined time elapses after the breaker 330 is turned off, the main CPU 300 confirms that the time counted by the timer is equal to or longer than the predetermined time (for example, 1 second) (step 502 shown in FIG. 7). In step S504 shown in FIG. 7, the data stored in the RAM 308 is copied to the HDD 340.

  Assume that the user switches the operation mode of the image forming apparatus 150 to the power saving mode.

  Hereinafter, the operation of the power control unit 314 in the power saving mode will be described.

  After shifting to the power saving mode, the power supply control unit 314 resets the timer each time the zero cross detection circuit 342 outputs a zero cross detection signal (step 532 shown in FIG. 8). It is assumed that the user turns off the breaker 330 by some mistake, and then turns on the breaker 330 again after a predetermined time has elapsed and the standby time has elapsed.

  When the breaker 330 is turned on, the zero cross detection circuit 342 outputs a zero cross detection signal.

  After confirming that the zero-cross detection signal is output (YES in step 538 shown in FIG. 8), the power supply control unit 314 outputs an activation signal to the main CPU 300 (step 540 shown in FIG. 8).

  When the main CPU 300 receives the activation signal from the power control unit 314, the main CPU 300 operates the image forming apparatus 150 in the normal mode.

[Effects of the present embodiment]
As is apparent from the above description, by using the image forming apparatus 150 according to the present embodiment, the zero-cross detection circuit 342 allows the light emitting diode 398 of the photocoupler 396 only when the voltage of the AC power supply 334 is 0V. , And outputs a zero cross detection signal to the main CPU 300 and the power supply control unit 314. Compared with Patent Document 1, it is possible to considerably reduce the power consumption for detecting a point crossing 0V of the AC power supply.

  Further, the image forming apparatus 150 can shift to a power saving mode in which power is mainly supplied to the main CPU 300 and the like, and power supply to the document reading unit 152, the image processing unit 304, the image forming unit 154, and the like is stopped. Suppose that The power saving mode is mainly set for the user outside the working hours of the company, and the function for forming an image on the sheet is not used by the image forming apparatus 150 during that time period. In this case, even if a power failure occurs suddenly, if important data is stored in the RAM 308, it is necessary to copy it to a nonvolatile storage device such as the HDD 340. In the present embodiment, whether or not a power failure has occurred is determined based on the output of the zero cross detection signal. Therefore, it is desirable to operate the zero cross detection circuit 342 even in the power saving mode. In the power saving mode, it is desired to reduce the power consumption as much as possible. Therefore, if the zero cross detection circuit 342 according to the present embodiment is used, the power consumption for detecting the zero cross timing can be greatly reduced even in the power saving mode. Can do.

[Modification]
In the above-described embodiment, the zero-cross detection circuit 342 is included in the image forming apparatus 150. However, the present invention is not limited to such an embodiment, and the zero cross detection circuit 342 may be included in various devices in addition to the image forming apparatus 150.

  In the above-described embodiment, the zero cross detection circuit 342 includes the electrolytic capacitor 392. However, the present invention is not limited to such an embodiment, and any capacitor may be used as long as it is a capacitor in which charges are stored in advance, instead of the electrolytic capacitor 392.

  The embodiment disclosed herein is merely an example, and the present invention is not limited to the above-described embodiment. The scope of the present invention is indicated by each claim in the claims after taking into account the description of the detailed description of the invention, and all modifications within the meaning and scope equivalent to the wording described therein are intended. Including.

It is a figure which shows the circuit diagram of the zero cross detection circuit 50 described in patent document 1. FIG. 1 is a perspective view illustrating an appearance of an image forming apparatus 150 according to an embodiment of the present invention. FIG. 3 is a diagram showing a simplified internal configuration of an image forming apparatus 150 shown in FIG. 2. FIG. 3 is a block diagram functionally dividing the hardware configuration of the image forming apparatus 150 shown in FIG. 2. FIG. 5 is a circuit diagram of a zero cross detection circuit 342 shown in FIG. 4. FIG. 5 is a circuit diagram of a driver 322 and a fixing heater 324 shown in FIG. 4. It is a flowchart which shows the control structure of the computer program which implement | achieves the function of main CPU300 shown in FIG. It is a flowchart which shows the control structure of the computer program which implement | achieves the function of the power supply control part 314 shown in FIG. FIG. 6 is a diagram for describing an operation of the image forming apparatus 150 when a zero-cross timing is detected.

Explanation of symbols

150 Image Forming Device 152 Document Reading Unit 154 Image Forming Unit 166 Operation Device 170 Operation Unit 172 Display Unit 176 Rocker Switch 234 Fixing Device 300 Main CPU
304 Image processing unit 306 ROM
308 RAM
310 Image memory 312 NIC
314 Power supply control unit 316 Sub power supply 318 Main power supply 320 Sub CPU
322 Driver 324 Fixing heater 326 A / D converter 328 Fixing temperature sensor 330 Breaker 332 PC
334 AC power supply 340 HDD
342 Zero cross detection circuit 370, 372, 374, 376 Diode 378, 380, 384, 388, 390, 400 Resistance 382 Zener diode 386 MOSFET
392 Electrolytic capacitor 394 Transistor 396 Photocoupler 398 Light emitting diode 402 Transistor

Claims (8)

A zero-cross detection circuit that detects the zero-cross timing of an input AC waveform and outputs a detection signal to an external device,
A photocoupler,
A drive circuit that stores electric power when the absolute value of the voltage of the AC waveform is larger than a predetermined voltage, and discharges the electric power when the absolute value of the voltage of the AC waveform is smaller than a predetermined voltage and applies the input to the input of the photocoupler. Zero cross detection circuit. The drive circuit is
Rectifying means for rectifying the AC waveform;
Switching means for turning on or off according to whether or not the voltage rectified by the rectifying means is equal to or higher than a predetermined threshold value;
A capacitive element having one end connected to receive the voltage rectified by the rectifying means and the other end connected to a reference voltage;
One of the inputs of the photocoupler is connected to the one end of the capacitive element,
The drive circuit further includes a control terminal connected to the one end of the capacitive element, a one-way terminal connected to the other input of the photocoupler, and a second terminal connected to the reference voltage. The zero cross detection circuit according to claim 1, comprising:   The switching element includes a transistor having a base connected to the one end of the capacitive element, a collector connected to the other input of the photocoupler, and an emitter connected to the reference voltage. The zero cross detection circuit described in 1. The switching means includes
Voltage dividing means for dividing the voltage rectified by the rectifying means at a predetermined voltage dividing ratio;
4. A MOSFET having a gate connected to receive a voltage divided by the voltage dividing means, a drain connected to the output of the rectifying means, and a source connected to the reference voltage. The zero-cross detection circuit described.   An image forming apparatus comprising the zero-cross detection circuit according to claim 1. A fixing device;
The image forming apparatus according to claim 5, further comprising means for controlling a temperature of the fixing device in response to the zero cross detection circuit outputting the detection signal. A volatile storage device;
A non-volatile storage device;
Control means for copying data stored in the volatile storage device to the nonvolatile storage device in response to the zero cross detection circuit not outputting the detection signal for a predetermined time; The image forming apparatus according to claim 5, further comprising: A main control circuit that operates in response to power supply from a first power source and that starts in response to a start signal;
A new detection signal that operates by receiving power from a second power supply different from the first power supply, and that the detection signal is not output for a predetermined time or more by the zero-cross detection circuit and the predetermined time has elapsed. The image forming apparatus according to claim 5, further comprising: a power supply control unit for outputting the activation signal to the main control circuit in response to the output of.

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