JP2010262202A - Image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent wasteful overheat of a heating roller from occurring in an image forming apparatus. <P>SOLUTION: When the number of runaway times of an IH control part that performs heating control of a fixing device is equal to or more than a predetermined number of times, a body side control part does not perform heating control for the IH control part. Therefore, the heating roller is not heated. When the number of runaway times is less than the predetermined number and a flag of a runaway flag storage part showing the past runaway of the IH control part is '0', the body side control part performs heating control. Even when the flag is '1', if the flag becomes '0' by power supply reset of the image forming apparatus, the body side control part performs heating control. When the flag is kept as '1', the body side control part does not perform heating control. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an image forming apparatus that fixes a toner image on a recording medium by heating and pressurizing the toner image on the recording medium.

  An image forming apparatus using an electrophotographic process, such as a copying machine, a facsimile, or a laser printer, includes a fixing device that melts and fixes a toner image formed on a sheet. Such a fixing device is configured such that a heating roller and a pressure roller are arranged to face each other. Then, the paper on which the toner image is formed is nipped and conveyed by a nip formed between the heating roller and the pressure roller, so that the toner image is heated while being pressed to melt and fix the toner image on the paper. It is supposed to be.

  As a heater for the heating roller, an electromagnetic induction heating (IH) type heater is known. In such an electromagnetic induction heating type heating roller, an exciting coil is disposed inside a cylindrical roller body made of a conductive material. A high-frequency current flows through the exciting coil under the control of the IH control unit, an induced eddy current is generated in the heating roller body by the high-frequency magnetic field generated thereby, and Joule heat is generated by the resistance of the heating roller body.

  In such an image forming apparatus, when the IH control unit runs away due to a software bug or the like, the main body side control unit that controls the IH control unit forcibly shuts off the heater and then resets the operation of the IH control unit. Measures are taken to prevent unnecessary heating of the heating roller.

JP 2004-355984 A

  However, in the case of the above countermeasure, there is a possibility that the IH control unit may run away again, and the heater ON → IH control unit runaway → heater OFF → IH control unit reset is repeated. That is, even if the IH control unit is reset due to runaway, there is a possibility that the IH control unit will run away again and the temperature of the heating roller cannot be controlled, and power is wasted. Further, Patent Document 1 describes a method of performing control so that the heater is not turned on by detecting an abnormal temperature of the heater, but is regarded as operating normally until the abnormal temperature of the heater is detected. Therefore, useless overheating of the heater cannot be completely prevented.

  SUMMARY An advantage of some aspects of the invention is that it provides an image forming apparatus that prevents useless overheating of a heater.

  An image forming apparatus according to a first aspect of the present invention includes: a current supply unit that supplies a high-frequency current; a fixing unit that heats the image on the recording medium by heat by the high-frequency current supplied from the current supply unit; A fixing side control unit that controls a current supplied from the current supply unit to the fixing unit; and a main body side control unit that controls the fixing side control unit. The main body side control unit includes the fixing side control unit. Monitoring means for monitoring the abnormal state, first storage means for storing whether or not the monitoring means has detected an abnormal state of the fixing-side control means, and the storage contents of the first storage means are stored in the monitoring means A current interruption instruction means for outputting a current interruption instruction signal to the fixing side control means when indicating an abnormal state of the fixing side control means, and the fixing side control hand Receives the current blocking instruction signal from the current interrupting instruction means performs a control to stop the supply of the high-frequency current to the current supply means.

  Conventionally, when a control unit that performs heating control of the fixing device runs away due to a software bug or the like, the operation of the control unit is reset and supply control of high-frequency current is performed again by the control unit. That is, heater ON → control section runaway → heater OFF → control section reset was repeated. In this case, since a current is supplied to the heater until the runaway of the control unit is detected, the temperature rises during that time. Therefore, there is a possibility that the inside of the apparatus is excessively heated.

  Therefore, if the stored contents of the first storage means indicate that the monitoring means has detected an abnormality in the fixing-side control means (that is, if the fixing-side control means has run out of control in the past), the current interruption instruction The means outputs a current interruption instruction signal to the fixing side control means. The fixing-side control means receives this current interruption instruction signal, performs current interruption control on the current supply means, and stops the high-frequency current supplied to the fixing means. In other words, if an abnormality in the fixing-side control means is detected even once, no high-frequency current is supplied to the fixing means (the fixing means is not heated), thereby preventing unnecessary overheating of the fixing means and wasteful power. Consumption can be prevented.

  Here, the abnormal state of the fixing side control means means that the fixing side control means runs out of control due to a bug in the software executed by the fixing side control means, and the fixing side control means cannot control the current supply means. To tell.

  A second aspect of the present invention is the image forming apparatus according to the first aspect, wherein the first storage unit is a volatile memory, and at the same time the power of the image forming apparatus is turned off, the first storage is performed. The stored contents of the means are reset to the stored contents indicating that the abnormal state of the fixing side control means is not detected.

  In some cases, the runaway of the fixing side control means is resolved by resetting the power supply of the image forming apparatus, and then the fixing side control means continues normal operation without running away. Despite the fact that the runaway of the fixing side control means is resolved by resetting the power supply of the image forming apparatus, the heating control is not performed due to the runaway of the fixing side control means once and the user needs to be repaired. Will be inconvenient.

  Therefore, the first storage means is a volatile memory, and the stored contents of the first storage means are reset by resetting the power of the image forming apparatus. As a result, even if an abnormal state of the fixing-side control unit is detected, the current can be supplied to the fixing unit again by resetting the power of the image forming apparatus.

  A third aspect of the present invention is the image forming apparatus according to the first or second aspect, wherein the image forming apparatus is a non-volatile memory, and stores the number of times that the monitoring unit detects an abnormal state of the control unit. Storage means and display control means for controlling display of the display unit, and when the number of times stored in the second storage means is equal to or greater than a predetermined number, the current cutoff instruction means sends current to the control means. A blocking instruction is given, and the display control means displays a warning message on the display unit.

  If the number of times the abnormal state of the fixing-side control means is detected exceeds a predetermined number, it is considered that there is a problem with the software executed by the fixing-side control means, and the current interruption instruction is issued regardless of the contents stored in the first storage means. The means outputs a current interruption instruction signal to the fixing side control means. In other words, the abnormal state of the fixing side control unit that is eliminated by resetting the power of the image forming apparatus is overlooked, but the abnormal state of the fixing side control unit repeatedly occurs even when the power is reset, and the number of times exceeds the predetermined number. When this occurs, the current interruption instruction means outputs a current interruption instruction signal. Thereby, it is possible to prevent unnecessary overheating in the image forming apparatus. Further, the display control unit displays a warning message on the display unit, so that the user can know that there is a problem with the fixing unit.

  When the stored contents of the first storage means indicate that the monitoring means has detected an abnormality of the fixing side control means (that is, when the runaway of the fixing side control means has occurred in the past), the current interruption instruction means A current interruption instruction signal is output to the fixing side control means. The fixing-side control means receives this current interruption instruction signal, performs current interruption control on the current supply means, and stops the high-frequency current supplied to the fixing means. That is, when an abnormality of the fixing-side control unit is detected, the high-frequency current is not supplied to the fixing unit (the fixing unit is not heated), thereby preventing unnecessary overheating of the fixing unit.

FIG. 3 is a side view schematically showing an internal configuration of the image forming apparatus. FIG. 3 is a block diagram for explaining operation functions of a fixing device and a main body side control unit. 7 is a flowchart showing a flow of fixing processing by a main body side control unit and an IH control unit. The figure which showed the presence or absence of heating control according to the case.

  Hereinafter, an embodiment of an image forming apparatus according to the present invention will be described with reference to the drawings. FIG. 1 is a side view schematically showing an internal configuration of an image forming apparatus 1 according to the present embodiment. The image forming apparatus 1 may be a copying machine, a printer, a facsimile machine, or the like, and may be any image forming apparatus having a process for fixing a toner image placed on a sheet by pressing and heating. The image forming apparatus 1 includes a main body unit 2, a stack tray 3 disposed on the left side of the main body unit 2, a document reading unit 4 disposed on the top of the main body unit 2, and a document reading unit 4. A document feeder 5 is provided.

  An input operation unit 6 is provided on the front part of the image forming apparatus 1. The input operation unit 6 displays a power key, a start key for a user to input a print execution instruction, a numeric keypad for inputting the number of copies to be printed, operation guide information for various copying operations, and the like. For example, the display unit 9 includes a liquid crystal display having a touch panel function.

  The document reading unit 4 includes an image sensor such as a CCD (Charge Coupled Device) and a CMOS (Complementary Metal Oxide Semiconductor), a scanner unit 13 including an exposure lamp, a document table 14 formed of a transparent member such as glass, and a document reading slit. 15. The scanner unit 13 is configured to be movable by a drive unit (not shown). When reading a document placed on the document table 14, the scanner unit 13 is moved along the document surface at a position facing the document table 14, and the document image is displayed. Image data acquired while scanning is output to an image memory (not shown). When reading the document fed by the document feeding unit 5, the document is moved to a position facing the document reading slit 15 and synchronized with the document feeding operation by the document feeding unit 5 via the document reading slit 15. The image of the original is acquired and the image data is output to the image memory.

  The document feeder 5 includes a document placement unit 16 for placing a document, a document discharge unit 17 for discharging a document whose image has been read, and one document placed on the document placement unit 16. A document transport mechanism 18 including a paper feed roller, a transport roller (not shown), and the like for feeding the paper one by one to a position facing the document reading slit 15 and discharging it to the document discharge section 17 is provided.

  Further, the document feeding unit 5 is provided so as to be rotatable with respect to the main body unit 2 so that the front side thereof can move upward. By moving the front side of the document feeder 5 upward to open the upper surface of the document table 14, the user can place a read document, for example, a book in a spread state, on the upper surface of the document table 14. ing.

  The main body 2 forms a plurality of paper feed cassettes 19, a paper feed roller 20 that feeds paper from the paper feed cassette 19 one by one and transports it to the image forming unit 21, and forms an image on the paper transported from the paper feed cassette 19. The image forming unit 21 is provided.

  The image forming unit 21 outputs a laser beam or the like based on the image data acquired by the scanner unit 13 to expose the photosensitive drum 22, and forms an electrostatic latent image on the surface of the photosensitive drum 22. A developing unit 24 that forms a toner image by attaching toner to the surface of the photosensitive drum 22 on which the electrostatic latent image is formed, a transfer unit 25 that transfers the toner image on the photosensitive drum 22 to a sheet, and a toner image A fixing device 28 provided with a heating roller 26 and a pressure roller 27 for heating and transferring the toner image to the paper by fixing the transferred paper, and a paper transport path in the image forming unit 21, and the paper in the stack tray 3. Alternatively, a pair of conveyance rollers 30 and 31 that convey to the discharge tray 29 are provided.

  When images are formed on both sides of a sheet, the image forming unit 21 forms an image on one side of the sheet, and then the sheet is nipped between the pair of conveying rollers 30 on the discharge tray 29 side. In this state, the conveyance roller pair 30 is reversed to switch back the sheet, and the conveyance roller pairs 38 and 39 convey the sheet to the sheet conveyance path 32 and convey it again to the upstream area of the image forming unit 21. After the image is formed on the other side, the paper is discharged to the stack tray 3 or the discharge tray 29.

  FIG. 2 is a block diagram for explaining the operation functions of the fixing device 28 and the main body side control unit 51 that controls the fixing device 28. The main body side control unit 51 is configured by a CPU (Central Processing Unit) or the like, reads a program in accordance with an instruction signal or the like input from each component of the image forming apparatus 1, and executes processing. The image forming apparatus 1 is comprehensively controlled by outputting an instruction signal to the functional unit.

  Further, the main body side controller 51 calculates the amount of power that the drive circuit 42 should supply to the exciting coil 43 so that the heating roller 26 maintains a predetermined temperature according to the detected temperature output from the temperature sensor 44. Output to the IH control unit 41.

  The main body control unit 51 includes a runaway monitoring unit 511, a runaway flag storage unit 512, a runaway number storage unit 513, and a current interruption instruction unit 514. The runaway monitoring unit 511 monitors the runaway of the IH control unit 41 that controls the heating of the heating roller 26 (the IH control unit 41 operates abnormally due to a bug in the software while the software is being executed). The runaway monitoring unit 511 is configured using a watchdog timer or the like.

  The runaway flag storage unit 512 stores a flag = “0” at the time of default, and when the runaway monitoring unit 511 detects a runaway of the IH control unit 41, the main body side control unit 51 sets a flag and stores “1”. . Further, the runaway flag storage unit 512 includes a volatile memory. When the power of the image forming apparatus 1 is turned off, the stored contents of the runaway flag storage unit 512 are lost, and then the power of the image forming apparatus 1 is turned on. Then, flag = '0' is written by the main body side control unit 51.

  The runaway number storage unit 513 stores the number of times that the runaway monitoring unit 511 detects the runaway of the IH control unit 41. The runaway number storage unit 513 includes a non-volatile memory, and the stored contents are retained even when the image forming apparatus 1 is turned off.

  The current interruption instruction unit 514 outputs a current interruption instruction signal to the IH control unit 41 when the flag of the runaway flag storage unit 512 is “1”. When the IH control unit 41 receives a current interruption instruction signal from the current interruption instruction unit 514, the IH control unit 41 performs current interruption control on the drive circuit 42. Thereby, the current supply to the exciting coil 43 is stopped, and the heating roller 26 is not heated.

  Here, when the flag of the runaway flag storage unit 512 is “1”, it indicates that the IH control unit 41 has runaway during the execution of software in the past. This runaway of the IH control unit 41 may occur again even if execution is reset. In the conventional method, the excitation coil ON → IH control unit runaway → excitation coil OFF → IH control unit reset is repeated. Become. That is, a high-frequency current is caused to flow through the exciting coil 43 until the runaway of the IH control unit 41 is detected, and the heating roller 26 is unnecessarily overheated.

  Therefore, when the flag of the runaway flag storage unit 512 is “1”, that is, when the runaway of the IH control unit 41 has occurred in the past, the current cutoff instruction unit 514 sends a current cutoff instruction signal to the IH control unit 41. Is output. Thereby, since the supply of the high frequency current to the exciting coil 43 is stopped, the heating roller 26 is not heated, and it is possible to prevent the heating roller 26 from being overheated.

  Further, the runaway of the IH control unit 41 is resolved by resetting the power supply of the image forming apparatus 1, and thereafter the IH control unit 41 may continue normal operation without running away. Even though the runaway of the IH control unit 41 is resolved by resetting the power supply of the image forming apparatus 1, the heating control is not performed by the runaway of the IH control unit 41 once, and a repair by a service person is required. This will inconvenience the user.

  Therefore, the runaway flag storage unit 512 is a volatile memory, and the main body side control unit 51 sets the flag of the runaway flag storage unit 512 to “0” when the power of the image forming apparatus 1 is reset. As a result, even if the IH control unit 41 runs away, heating control can be performed again by resetting the power of the image forming apparatus 1.

  In addition, when the runaway frequency of the IH control unit 41 exceeds a predetermined number, there is a problem with the software executed by the IH control unit 41, and the heating control of the heating roller 26 is performed under control of the IH control unit 41. There is a risk that the inside of the apparatus will be overheated unnecessarily. Therefore, when the number of runaways stored in the runaway number storage unit 513 is equal to or greater than the predetermined number, the main body side control unit 51 does not perform heating control on the IH control unit 41 and displays a message prompting maintenance of the fixing device 28. This is displayed on part 9. That is, the runaway of the IH control unit 41 that is eliminated by resetting the power of the image forming apparatus 1 is overlooked. However, when the runaway that repeats even after the power is reset exceeds a predetermined number of times, the current cutoff instruction unit 514 instructs the current cutoff The useless overheating in the image forming apparatus 1 can be prevented.

  The fixing device 28 includes a heating roller 26, a pressure roller 27 (not shown in FIG. 2), an IH control unit 41, a drive circuit 42, an excitation coil 43, and a temperature sensor 44. The exciting coil 43 is disposed inside a cylindrical heating roller 26 made of a conductive material. The drive circuit 42 is driven by the control of the IH control unit 41 and supplies a high frequency current to the excitation coil 43. An induction eddy current is generated in the main body of the heating roller 26 by the high-frequency magnetic field generated in the exciting coil 43 by this current supply, and the heating roller 26 generates heat.

  The IH control unit 41 is configured by a CPU or the like, and controls the drive circuit 42 according to an instruction signal output from the main body side control unit 51. Specifically, when the fixing instruction signal is output from the main body side control unit 51, the IH control unit 41 determines that the excitation coil 43 is based on the amount of power calculated by the main body side control unit 51 based on the temperature detected by the temperature sensor 44. The frequency of the high-frequency current supplied to is calculated and output to the drive circuit. Further, when a current interruption instruction signal is output from the main body side control unit 51, the IH control unit 41 performs current interruption control on the drive circuit 42. By this current interruption control, the drive circuit 42 stops the supply of the high frequency current to the exciting coil 43.

  FIG. 3 is a flowchart showing a flow of fixing processing by the main body side control unit 51 and the IH control unit 41. First, the main body control unit 51 determines whether or not the number of runaways in the runaway number storage unit 513 is equal to or greater than a predetermined number (step S31). When the number of times is equal to or greater than the predetermined number (step S31; YES), the main body side control unit 51 displays a message for prompting maintenance of the fixing device 28 on the display unit 9 (step S40), and the IH control unit 41 has already performed the heating control. If so, the current interruption instruction unit 514 outputs a current interruption instruction signal (step S37), and the main body side control unit 51 ends the heating process.

  When the current cut-off signal is received (step S11; YES), the IH control unit 41 performs current cut-off control on the drive circuit 42 (step S17). As a result, the drive circuit 42 stops the high-frequency current supplied to the exciting coil 43. Then, the IH control unit 41 ends the heat treatment.

  If the number of runaways in the runaway number storage unit 512 is less than the predetermined number (step S31; NO) and the runaway monitoring unit 511 detects a runaway of the IH control unit 41 (step S32; YES), the main body side control unit 41 The flag of the runaway flag storage unit 512 is rewritten to “1”, and the runaway number of the runaway number storage unit 513 is incremented by 1 (step S33). When the runaway monitoring unit 511 does not detect the runaway of the IH control unit 41 (step S32; NO), the main body control unit 51 shifts the processing to step S34.

  Then, the main body control unit 51 determines whether or not the flag of the runaway flag storage unit 512 is “1” (step S34). When the flag is ‘1’ (step S <b> 34; YES), the current interruption instruction unit 514 outputs a current interruption instruction signal (step S <b> 37), and the main body side control unit 51 ends the heating process.

  When the current cut-off signal is received (step S11; YES), the IH control unit 41 performs current cut-off control on the drive circuit 42 (step S17). As a result, the drive circuit 42 stops the high-frequency current supplied to the exciting coil 43. Then, the IH control unit 41 ends the heat treatment.

  When the flag is “0” (step S34; NO), the main body side control unit 51 causes the drive circuit 42 to keep the heating roller 26 at a predetermined temperature based on the detected temperature output from the temperature sensor 44. The amount of power to be supplied to the exciting coil 43 is calculated (step S35), and a fixing instruction signal is output to the IH control unit 41 (step S36).

  When the IH control unit 41 receives a fixing instruction signal from the main body side control unit 51 (step S12; YES), the IH control unit 41 calculates the frequency of the high frequency current supplied to the excitation coil 43 based on the amount of power calculated by the main body control unit 51. (Step S13) and output to the drive circuit 42 (Step S14). As a result, the drive circuit 42 supplies a high-frequency current to the exciting coil 43 and the heating roller 26 is heated.

  The main body control unit 51 repeats the above process until the fixing process is completed. When the fixing process is finished (step S38; YES), the main body side control unit 51 outputs an end signal to the IH control unit 41 (step S39), and the heating process is finished. Upon receipt of this end signal (step S15; YES), the IH control unit 41 stops the current supply to the excitation coil 43 with respect to the drive circuit 42 (step S16), and ends the heating process.

  FIG. 4 shows the presence or absence of heating control for each case. First, when the number of runaways in the runaway number storage unit 513 is equal to or greater than a predetermined number, the main body side control unit 51 does not perform heating control. When the number of runaways is less than the predetermined number and the flag of the runaway flag storage unit 512 is “0”, the main body side control unit 51 performs heating control. Even if the flag is ‘1’, if the power of the image forming apparatus 1 is reset, the flag becomes ‘0’, and the main body side control unit 51 performs the heating control. When the flag remains “1”, the main body side control unit 51 does not perform the heating control.

  As described above, when the flag of the runaway flag storage unit 512 is “1”, that is, when the runaway of the IH control unit 41 has occurred in the past, the current interruption instruction unit 514 To output a current interruption instruction signal. As a result, the IH control unit 41 performs current interruption control on the drive circuit 42, and the high frequency current is not supplied to the exciting coil 43. Therefore, it is possible to prevent the heating roller 26 from being overheated and wasteful. Power consumption can be prevented.

  Further, the runaway of the IH control unit 41 is resolved by resetting the power supply of the image forming apparatus 1, and thereafter the IH control unit 41 may continue normal operation without running away. Even though the runaway of the IH control unit 41 is resolved by resetting the power supply of the image forming apparatus 1, the heating control is not performed by the runaway of the IH control unit 41 once, and a repair by a service person is necessary. This will inconvenience the user.

  Therefore, the runaway flag storage unit 512 is a volatile memory, and the flag of the runaway flag storage unit 512 is reset by resetting the power of the image forming apparatus 1. As a result, even if the IH control unit 41 runs away, heating control can be performed again by resetting the power of the image forming apparatus 1.

  However, when the number of times of runaway of the IH control unit 41 exceeds a predetermined number, it is considered that there is a problem with the software executed by the IH control unit 41, and the main body side control is performed regardless of the flag state of the runaway flag storage unit 512. The unit 51 does not perform heating control on the IH control unit 41. That is, the runaway of the IH control unit 41 that is eliminated by resetting the power of the image forming apparatus 1 is overlooked. However, when the runaway that repeats even after the power is reset exceeds a predetermined number of times, the current cutoff instruction unit 514 instructs the current cutoff Thus, it is possible to prevent the image forming apparatus 1 from being overheated.

1 Image forming apparatus 26 Heating roller (fixing means)
28 Fixing Device 41 IH Control Unit (Fixing Side Control Unit)
42 Drive circuit (current supply means)
43 Excitation coil (fixing means)
44 temperature sensor 51 main body side control part (main body side control means)
511 Runaway monitoring section (monitoring means)
512 Runaway flag storage unit (first storage means)
513 Runaway Number Storage Unit (Second Storage Unit)
514 Current interruption instruction section (current interruption instruction means)

Claims (3)

Current supply means for supplying a high-frequency current;
Fixing means for heating and fixing an image on a recording medium by high-frequency current supplied from the current supply means;
Fixing-side control means for controlling the current supplied by the current supply means to the fixing means;
A main body side control means for controlling the fixing side control means;
The main body side control means comprises:
Monitoring means for monitoring an abnormal state of the fixing side control means;
First storage means for storing whether or not the monitoring means has detected an abnormal state of the fixing-side control means;
When the stored content of the first storage means indicates that the monitoring means has detected an abnormal state of the fixing side control means, a current interruption instruction for outputting a current interruption instruction signal to the fixing side control means Means,
And the fixing-side control means receives the current interruption instruction signal from the current interruption instruction means and performs control to stop the supply of high-frequency current to the current supply means. .   The first storage means is a volatile memory, and at the same time the power of the image forming apparatus is turned off, the storage contents of the first storage means indicate that an abnormal state of the fixing-side control means is not detected. The image forming apparatus according to claim 1, wherein the image forming apparatus is reset to contents. A non-volatile memory, a second storage means for storing the number of times the monitoring means has detected an abnormal state of the fixing side control means;
Display control means for controlling display of the display unit;
When the number of times stored in the second storage means is equal to or greater than a predetermined number, the current cutoff instruction means issues a current cutoff instruction to the fixing side control means, and the display control means includes the display section. The image forming apparatus according to claim 1, wherein a warning message is displayed.

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