JP2013114140A - Image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image forming apparatus capable of detecting malfunction of a flag for detecting a length of a sheet in a width direction.SOLUTION: A first detecting section 130A detects passage of a sheet by detecting a conveyance detecting sensor flag 117 which rotates when being pressed by the sheet on which a toner image is fixed. Further, when a sheet is conveyed having a length not less than a prescribed length in a width direction, a second detecting section 131A detects that the passing sheet has the length not less than the prescribed length in the width direction by detecting a link member 122 which rotates when both right and left sheet width sensor flags 120 and 121 are rotated. Then, before the sheet is conveyed, and when at least either one of the right and left sheet width sensor flags 120 and 121 is rotated, the conveyance detecting sensor flag 117 is rotated interlocked with the rotating flags 120 and 121 to allow detection by the first detecting section 130A.

Description

  The present invention relates to an image forming apparatus, and more particularly to a configuration for preventing excessive temperature rise in a non-sheet passing portion of a fixing device.

  Some conventional image forming apparatuses such as a copying machine, a laser printer, an LED printer, a factory, a word processor, and a composite machine thereof form an image on a sheet using an electrophotographic system. In an image forming apparatus using such an electrophotographic system, when an image is formed on a sheet, an electrostatic latent image is first formed on the surface of an image carrier such as a photosensitive drum by a known electrophotographic process, and then a static image is formed. The electrostatic latent image is developed with toner to form a toner image. Next, the toner image is electrostatically transferred to a sheet such as recording paper directly or via an intermediate transfer member, and the transferred toner image is fixed on the sheet by a fixing device.

  By the way, as such a fixing device, a heating body that generates heat by energization, a heat-resistant film that slides on the heating body, and a pressurization that presses the heating body across the film to form a film and a fixing nip portion. There is a film heating type having a member. In such a fixing device, the heating member is heated and temperature-controlled to a predetermined temperature, and the sheet on which the unfixed toner image is transferred is nipped and conveyed by the fixing nip portion. Then, the toner image is fixed on the sheet by applying heat from the heating body and pressure from the pressure member to the toner image on the sheet in the conveying process.

  FIG. 13 is a diagram showing the configuration of such a conventional fixing device. In FIG. 13, 10 is a pressure roller, 11 is a fixing heater as a heating element, and 18 is a heat-resistant film. Further, 13 is a conveyance guide for guiding the sheet S after fixing, 17 is a conveyance detection sensor for detecting the sheet S, and 14 is a discharge roller pair for discharging the sheet S after fixing.

  By the way, in such a fixing device, a sheet such as an envelope or a postcard that is narrow with respect to the width of the heat generation area in the longitudinal direction of the fixing heater 11 may be nipped and conveyed by the fixing nip portion. At this time, the amount of heat taken away from the fixing heater 11 differs greatly between a region through which the sheet S passes (paper passing region) and a region through which the sheet S does not pass (non-paper passing region).

  Accordingly, when the narrow sheet S is continuously nipped and conveyed at the fixing nip portion, the heat is not taken away by the sheet S in the non-sheet passing area, so that the temperature in that area gradually increases as the number of conveyed sheets S increases. A so-called non-sheet passing portion temperature rise that rises and exceeds the set temperature occurs. And when excessive temperature rise of the non-sheet passing portion significantly exceeding the set temperature occurs, there is a risk of damaging components such as the heat-resistant film 18 and the pressure roller 10 to reduce the device life (durability life). is there.

  Therefore, in order to prevent such excessive temperature rise of the non-sheet passing portion, for example, a sheet width detecting portion that detects the length in the width direction perpendicular to the sheet conveying direction of the sheet conveyed in the non-sheet passing portion region. There is something that has been set up. Then, the sheet width detection unit detects the length of the conveyed sheet in the width direction, and when the sheet is a narrow sheet, the power supply to the heating body is temporarily reduced or the throughput is changed. The control which performs is performed (refer patent document 1). Here, the sheet width detection unit needs to be arranged at both ends in the width direction of the sheet conveyance path. This is not only when a narrow sheet is conveyed, but also when the sheet is forcibly moved toward one side of the sheet conveyance path and is not fed to the fixing nip end on the side where no sheet exists. This is because partial temperature rise occurs.

  As such a sheet width detection unit, there is one that detects the length in the width direction of the sheet by a temperature detection element installed in the fixing device, but the temperature detection element is very expensive. For this reason, many printers that place importance on cost use a sheet width detection sensor using a photo interrupter and a sensor flag. Also, the sensor flag is generally arranged at both ends in the width direction, in the vicinity of the downstream side of the roller nip that performs sheet conveyance in the sheet conveyance direction, and in the vicinity of the conveyance detection sensor that detects the sheet. It is. This is because the posture of the sheet is stable immediately after the roller nip and the sheet can be detected stably, and the conveyance detection sensor is also arranged in the vicinity for the same reason. Further, when the conveyance detection sensor and the sheet width detection sensor are arranged in the vicinity, there is a merit that the detection timing is easily determined.

  By the way, as a sheet width detection sensor, if it can detect that the width of the sheet is narrow (both sensor flags are not operating) or that the sheet is being conveyed just one side (the sensor flag is operating only on one side) good. For this reason, the cost can be reduced by adopting a configuration in which a single photo interrupter is used, the photo interrupter is shielded when the sensor flags on both sides operate, and only one side or both do not operate. There is something to plan.

  FIG. 14 is a diagram illustrating a configuration of a sheet width detection unit that detects the operation of two sensor flags with one photo interrupter. In FIG. 14, 17 is a conveyance detection sensor flag for detecting the sheet S passing through the fixing device, and this conveyance detection sensor flag 17 has a width so that it can detect any size sheet that can be conveyed. It is arrange | positioned in the direction center part vicinity.

  Reference numeral 20 denotes a right sheet width sensor flag positioned on the right side in the width direction of the fixing device so as to detect the length (size) of the conveyed sheet, and reference numeral 21 denotes a left sheet width sensor flag positioned on the left side in the width direction of the fixing device. It is. Here, when a sheet S wider than a predetermined amount is conveyed to the outer ends in the width direction of the right and left sheet width sensor flags 20 and 21, a contact piece (not shown) that contacts the sheet is provided. The connecting portions 20A and 21A are provided at the end on the center side in the width direction. When the conveyed sheet S comes into contact with the contact piece, and then the contact piece is pressed by the sheet S, the right and left sheet width sensor flags 20 and 21 rotate.

  Reference numeral 22 denotes a link member. At both ends of the link member 22 in the width direction, connecting portions 22A and 22B that contact the connecting portions 20A and 21A of the right and left seat width sensor flags 20 and 21 are formed. Yes. The link member 22 is restricted from rotating by the connecting portions 20A and 21A of the sheet width sensor flags 20 and 21 until the right and left sheet width sensor flags 20 and 21 are rotated. When the sheet width sensor flags 20 and 21 are rotated, the sheet width sensor flags 20 and 21 are rotated in conjunction therewith.

  Reference numeral 23 denotes a photo interrupter substrate. The photo interrupter substrate 23 includes a photo interrupter (not shown) that is shielded by the conveyance detection sensor flag 17 to detect the sheet, and a photo interrupter (not shown) that is shielded by the rotating end 22a of the link member 22 and detects the size of the sheet. An interrupter is attached. Reference numeral 13 denotes a conveyance guide that guides the sheet and supports the right and left sheet width sensor flags 20 and 21 and the conveyance detection sensor flag 17.

  FIG. 15A is a diagram illustrating a state when a wide sheet is conveyed by the sheet width detection unit having such a configuration. When a wide sheet is conveyed, the right and left sheet width sensor flags 20 and 21 are rotated by the contact piece being pressed by the sheet. When the right and left seat width sensor flags 20 and 21 are simultaneously rotated, the connecting portions 20A and 21A that stop the rotation of the link member 22 are tilted, whereby the link member 22 is a spring (not shown). It rotates in the direction of the arrow by the force of.

  When the link member 22 rotates in this way, the size detection photo interrupter is shielded from light by the rotation end 22a. Further, the conveyance detection sensor flag 17 is also pressed and rotated by the sheet to shield the photo interrupter for conveyance detection. That is, when a wide sheet is conveyed, the link member 22 is pressed by the sheet via the right and left sheet width sensor flags 20 and 21 and is rotated to the detection position by the photo interrupter. By detecting the rotation of the link member 22 in this way, it can be detected that a wide sheet has been conveyed.

  FIG. 15B shows a case where a narrow sheet is conveyed by one-sided movement, and one of the right and left sheet width sensor flags 20, 21 is pressed by the sheet and the link member 22 is moved to the detection position. It shows the state. In this case, since the link member 22 contacts the connecting piece of the sheet width sensor flag on the side at the standby position, the link member 22 cannot rotate, and the photo interrupter for size detection cannot be shielded. FIG. 15B shows a state in which the right sheet width sensor flag 20 is rotated. At this time, the connecting portion 20A of the right sheet width sensor flag 20 has moved to the position where it has fallen, but the left sheet width sensor flag 21 on the opposite side does not rotate, so the link member 22 rotates to the detection position. Not done.

  When one of the right and left sheet width sensor flags 20 and 21 does not rotate as described above, the link member 22 is prevented from rotating so that the narrow sheet is conveyed in a one-sided manner. Can be detected. Even when both the right and left sheet width sensor flags 20 and 21 do not rotate, the link member 22 does not rotate to the detection position. In this case, a narrow sheet is conveyed based on the center. Can be detected. By adopting such a configuration, it is possible to detect that a narrow sheet is being conveyed by one photo interrupter.

JP 2008-083329 A

  By the way, in the conventional image forming apparatus provided with such a sheet width detection unit, for example, a jammed sheet fragment may enter the sensor unit, and in this case, the sheet width sensor flag does not move at the rotated position. Here, in the case of one photo interrupter, even if the sheet width sensor flag on one side stops moving, if the sheet width sensor flag on the opposite side rotates as the sheet is conveyed, the signal from the photo interrupter It is the same as that in which the sensor flag is operating.

  For example, when a sheet is moved closer to the side opposite to the sheet width sensor flag that has stopped operating, the sheet width sensor flag on the opposite side rotates even if the sheet width sensor flag on one side stops moving. In this case, since the signal from the photo interrupter is the same as when both sheet width sensor flags are operated, the control unit does not convey the wide sheet even if the narrow sheet is conveyed. As a result, the temperature rise of the non-sheet passing portion occurs.

  That is, when the sheet width sensor flag malfunctions, it may not be possible to detect the sheet misalignment. In this case, the temperature rise of the non-sheet passing portion may occur, and the fixing device may be damaged. If both sheet width sensor flags malfunction, it is determined that a wide sheet is being conveyed even if a narrow sheet is being conveyed. Occur.

  Accordingly, the present invention has been made in view of such a situation, and an object of the present invention is to provide an image forming apparatus capable of detecting a malfunction of a flag for detecting the length in the width direction of a sheet. To do.

  The present invention provides an image forming apparatus including a fixing device that heats and fixes a toner image transferred onto a sheet, and is pressed against the sheet conveyance path through which the sheet passes and the sheet on which the toner image is fixed. A first detection unit that has a first flag provided in the rotating sheet conveyance path and detects the passage of the sheet by detecting the rotated first flag, and a width orthogonal to a predetermined sheet conveyance direction When a sheet having a length greater than or equal to the length in the direction is conveyed, the two second flags and the two second flags provided at both ends in the width direction of the sheet conveying path that are pressed by the sheet and rotated respectively. A link member that rotates in conjunction with the second flag when both of the two flags rotate, and a sheet that passes by detecting the rotated link member is longer than a predetermined length in the width direction. A sheet having a thickness A second detection unit for detecting, and when at least one of the two second flags is rotated before the sheet is conveyed, the first detection unit is configured to detect the first flag. The first flag is rotated in conjunction with the rotating second flag so as to detect this.

  When at least one of the two second flags for detecting the length in the width direction of the sheet is rotated before the sheet is conveyed as in the present invention, the first flag is rotated. By doing so, it is possible to detect a malfunction of the second flag.

1 is a diagram illustrating a schematic configuration of an electrophotographic printer which is an example of an image forming apparatus according to a first embodiment of the present invention. FIG. 2 is a perspective view showing a fixing device of the printer. FIG. 3 is a diagram illustrating the configuration of first and second detection units of the fixing device. The figure which shows a state when the sheet | seat of the said 1st and 2nd detection part is conveyed. The figure which shows a state when the narrow sheet | seat of the said 1st and 2nd detection part is conveyed. The figure which shows the state at the time of moving the sheet | seat of the said 1st and 2nd detection part close to one side. FIG. 6 is a diagram illustrating the configuration of first and second detection units of a fixing device according to a second embodiment of the present invention. The figure which shows a state when the wide sheet | seat of the said 1st and 2nd detection part is conveyed. The figure which shows a state when the narrow sheet | seat of the said 1st and 2nd detection part is conveyed. FIG. 10 is a diagram illustrating the configuration of first and second detection units of a fixing device according to a third embodiment of the present invention. The figure which shows a state when the wide sheet | seat of the said 1st and 2nd detection part is conveyed. The figure which shows a state when the narrow sheet | seat of the said 1st and 2nd detection part is conveyed. FIG. 6 is a cross-sectional view showing a fixing device of a conventional image forming apparatus. FIG. 3 is a diagram illustrating a configuration of a sheet width detection unit of the fixing device. The figure explaining the sheet width detection operation | movement of the said sheet width detection part.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings. FIG. 1 is a diagram showing a schematic configuration of an electrophotographic printer which is an example of an image forming apparatus according to a first embodiment of the present invention. In FIG. 1, 1 is an electrophotographic printer, 1A is a printer main body, 1B is provided in the printer main body 1A, an image forming unit for forming an image by an electrophotographic method, and 1C feeds a sheet S to the image forming unit 1B. This is a sheet feeding unit. 8 is a scanner unit that emits and scans a laser beam, 12 is a fixing device including a fixing heater 11, a heat-resistant film 18, and a pressure roller 10 facing the fixing heater 11, and R is a sheet feeding device. This is a sheet conveyance path through which a sheet from the feeding unit 1C passes.

  Reference numeral 1D denotes a paper discharge unit which is a sheet discharge unit for discharging the sheet S to the paper discharge stacking unit 15 after fixing. The paper discharge unit 1D includes a paper discharge roller 14a and a paper discharge roller 14b which can be rotated forward and backward. A pair of paper discharge rollers 14 is provided. Reference numeral 1E denotes a re-conveying unit for re-conveying a sheet having an image formed on one side thereof to the image forming unit 1B. The re-conveying unit 1E includes a reverse conveying path 16 that reverses the sheet S on which an image is formed and conveys the sheet S again to the image forming unit 1B. Reference numeral 1F denotes a control unit that controls the image forming operation of the printer 1, the determination of the sheet size, and the heating temperature of the fixing heater 11.

  The image forming unit 1B includes a photosensitive drum 6 that forms a toner image, a developing device, and the like. The process cartridge 9 that is detachably attached to the printer main body 1A and the toner image formed on the photosensitive drum 6 are transferred to the sheet S. The transfer roller 7 is provided. The sheet feeding unit 1C is provided in the printer main body 1A, and includes a sheet feeding roller 3 that is a sheet feeding member that feeds the sheet S stored in the sheet stacking table 2 including the intermediate plate 2a, and a sheet feeding roller 3. A separation pad 4 is provided in pressure contact therewith. Reference numeral 13 denotes a curved conveyance guide that forms the sheet conveyance direction downstream side of the fixing device 12 in the sheet conveyance path R and guides the sheet on which the image is formed to the sheet discharge unit 1D.

  Next, an image forming operation in the printer 1 having such a configuration will be described. After the sheet S is set on the sheet stacking table 2, when a print start command is input from a computer or an image reader (not shown), the paper feed roller 3, the transport roller 5, the photosensitive drum 6 and the like are driven. . Here, when the paper feed roller 3 rotates in the direction of the arrow, the sheet S is sent out by friction with the paper feed roller 3. At the same time as the sheet feeding roller 3 rotates, the uppermost sheet S is separated from the next sheet by the separation pad 4.

  As a result, only the uppermost sheet is conveyed to the image forming unit 1B by the conveying roller 5. A top sensor (not shown) for detecting the leading edge of the sheet is provided in the vicinity of the center of the conveying roller 5, and the position of the sheet is detected by the top sensor. Based on this detection, the scanner unit 8 detects the photosensitive drum. 6 is irradiated with a laser beam. By this laser light irradiation, an electrostatic latent image is formed on the photosensitive drum 6 whose surface is uniformly charged, and this electrostatic latent image is developed with toner by a developing device and is visible. Image. Thereafter, the toner image on the photosensitive drum 6 that has been visualized is transferred onto the sheet at the transfer portion when the sheet S is conveyed to a transfer portion constituted by the photosensitive drum 6 and the transfer roller 7. Transcribed.

  Next, the sheet S to which the toner image has been transferred is conveyed to the fixing device 12, and when passing through the fixing device 12, the heat from the fixing heater 11 transmitted through the heat-resistant film 18 and the pressure from the pressure roller 10. The toner image is heated and pressed to be permanently fixed on the sheet S. When the sheet S on which an image is formed on one side is discharged, the sheet S on which the toner image is fixed is discharged to the outside of the printer body by the discharge roller pair 14 through the conveyance guide 13 and then the printer body. The paper is stacked on the paper discharge stacking unit 15 provided on the upper surface.

  On the other hand, when images are formed on both sides of the sheet, before the paper discharge roller pair 14 completely discharges the sheet on which the image is formed on one side, the rear end of the sheet is reversed by the reverse conveyance path 16 by a paper discharge sensor flag (not shown). It is detected that it has come to a position where it can be transported. Based on this detection, the paper discharge roller pair 14 is reversed, and the sheet S is conveyed to the re-conveying unit 1E. Thereafter, the sheet S conveyed to the reconveying unit 1E is conveyed to a reversing junction point provided between the paper feeding roller 3 and the conveying roller 5 by a double-sided conveying roller 16a provided in the reverse conveying path 16. . Thereafter, the sheet S is subjected to image formation on the second surface from the reverse joining point toward the image forming unit 1B. The sheet S on which the image on the second side has been formed passes through the conveyance guide 13 and is discharged out of the printer main body by the discharge roller pair 14 and is stacked on the discharge stacking unit 15.

  FIG. 2 is a perspective view of the fixing device 12, and in FIG. 2, reference numeral 117 denotes a conveyance detection sensor flag that is a first flag located at the center in the width direction orthogonal to the sheet conveyance direction of the fixing device 12. Here, the conveyance detection sensor flag 117 is for detecting a sheet passing through the fixing device 12, and is arranged at the center in the width direction so that any size sheet that can be conveyed can be detected. Has been.

  Reference numeral 120 denotes a right sheet width sensor flag located on the right side in the width direction of the fixing device 12 (sheet conveyance path R) so as to detect the size in the width direction of the conveyed sheet, and reference numeral 121 denotes a left located on the left side in the width direction of the fixing device 12. This is a sheet width sensor flag. Here, connecting pieces 120A and 121A are provided at the center side end portions of the right and left seat width sensor flags 120 and 121, which are two second flags, and the outer end portions of the right and left seat width sensor flags 120 and 121 are provided. Is provided with a contact piece (not shown) that contacts the sheet. When the sheet comes into contact with the contact piece (not shown), the right and left sheet width sensor flags 120 and 121 are rotated by being pressed by the sheet, and accordingly, the connecting pieces 120A and 121A are also rotated. Reference numeral 113 denotes a guide member that rotatably supports the right and left sheet width sensor flags 120 and 121 and the like.

  Reference numeral 122 denotes a link member held by the guide member 113 so as to be rotatable. The link member 122 includes contact portions 122A at both ends in the width direction, and the contact portions 122A are pressed against the connecting pieces 120A and 121A of the right and left seat width sensor flags 120 and 121 by a spring (not shown). I am letting. Note that the rotation of the link member 122 is restricted by the connecting pieces 120A and 121A of the sheet width sensor flags 120 and 121 until the link member 122 is pressed by the sheet and the right and left sheet width sensor flags 120 and 121 rotate. Yes.

  Incidentally, as shown in FIG. 3, the conveyance detection sensor flag 117 has a connecting portion 117A that is recessed below the connecting pieces 120A and 121A of the right and left sheet width sensor flags 120 and 121. When either one of the sheet width sensor flags 120 and 121 is pressed by the sheet and rotated, the connecting portion 117A is pressed downward by the connecting pieces 120A and 121A that are the pressing portions. As a result, the conveyance detection sensor flag 117 is rotated to a detection position for detecting the passage of the sheet.

  Since the conveyance detection sensor flag 117 needs to be detected even when conveying a small size sheet, even if the right and left sheet width sensor flags 120 and 121 are not operated, the conveyance detection sensor flag can be operated alone. So that they are connected. That is, the conveyance detection sensor flag 117 is configured to freely rotate when both the right and left sheet width sensor flags 120 and 121 are in a standby position where they do not rotate. Thereby, when a small size sheet is conveyed, it is pressed and rotated by the sheet.

  Reference numeral 123 denotes a photo interrupter substrate. When the transport detection sensor flag 117 is rotated on the photo interrupter substrate 123, the photo interrupter substrate 123 is shielded from light by the light shielding portion 117a provided in the transport detection sensor flag 117 shown in FIG. A first photo interrupter 130 is provided. The conveyance detection sensor flag 117 and the first photo interrupter 130 constitute a first detection unit 130A that detects the passage of the sheet.

  Further, when the link member 122 is rotated in conjunction with the rotation of the sheet width sensor flags 120 and 121, the substrate 123 is shielded from light by the rotation end 122 a of the link member 122 and rotates the link member 122. A second photo interrupter 131 to be detected is attached. The sheet width sensor flags 120 and 121, the link member 122, and the second photo interrupter 131 are used to detect that the passing sheet is a sheet having a length equal to or longer than a predetermined length in the width direction. Is configured.

  Here, the right and left sheet width sensor flags 120 and 121 are attached so as to be rotated by being pressed by a sheet when a wide sheet having a length equal to or longer than a predetermined width direction is conveyed. It has been. As a result, when a wide sheet is conveyed, the right and left sheet width sensor flags 120 and 121 rotate simultaneously as shown in FIG. When the right and left sheet width sensor flags 120 and 121 are simultaneously rotated in this way, the connecting pieces 120A and 121A are also integrally rotated downward. Thereby, the locking by the connecting pieces 120A and 121A is released, and the link member 122 is rotated by the force of a spring (not shown) to shield the second photo interrupter 131 from light. Thus, in the present embodiment, one second photo interrupter 131 detects that a passing sheet is a sheet having a length equal to or longer than a predetermined width direction length.

  When the sheet is conveyed, the conveyance detection sensor flag 117 is rotated by being pressed by the sheet, and moves from the position shown in FIG. 3B to the detection position shown in FIG. One photo interrupter 130 is shielded from light. Then, the first and second photo interrupters 130 and 131 are shielded from light by the link member 122 and the conveyance detection sensor flag 117 in this way, so that the control unit 1F detects that the wide sheet S is conveyed. .

  FIG. 5 is a diagram illustrating a state in which the narrow sheets of the first and second detection units 130A and 131A are being conveyed. Here, when the narrow sheet S is conveyed, the conveyance detection sensor flag 117 performs a detection operation, but the right and left sheet width sensor flags 120 and 121 do not contact the sheet and do not rotate. Thereby, the control unit 1F indicates that the conveyance detection sensor flag 117 is at the detection position and the right and left sheet width sensor flags 120 and 121 are at the standby position based on the signals from the first and second photo interrupters 130 and 131. Detect that. Then, based on the detection that the conveyed sheet is a narrow sheet, the control unit 1 </ b> F performs control for protecting the fixing device 12.

  FIG. 6 is a diagram illustrating a state where only one of the right and left sheet width sensor flags 120 and 121 is rotated when the sheet is conveyed while being moved to one side. Here, when only one of the right and left sheet width sensor flags 120 and 121 is rotated, the link member 122 is connected to the connecting piece 120A of one of the sheet width sensor flags 120 and 121 at the standby position. Contact 121A. As a result, the link member 122 cannot rotate. When the link member 122 does not rotate in this way, the second detection unit detects that the sheet is a narrow sheet, and based on this, the control unit 1F protects the fixing device 12. Take control.

  In this case as well, since the conveyance detection sensor flag 117 is pressed by the sheet and is in a position to shield the first photo interrupter 130, the control unit 1F detects the passage of the sheet. As described above, when the second photo interrupter 131 does not detect the link member 122 and the first photo interrupter 130 detects the rotation of the conveyance detection sensor flag 117 when the sheet is conveyed while being moved to one side, the control unit 1F. Performs control for protecting the fixing device 12.

  By the way, for example, a piece of a sheet generated during the JAM processing may enter the attachment portion of the right and left sheet width sensor flags 120 and 121. In this case, one side of the sheet width sensor flags 120 and 121 is the same as in FIG. It becomes a fixed state. In FIG. 6, the right sheet width sensor flag 120 on the side opposite to the sheet approaching side is fixed.

  Here, when the narrow sheet is conveyed in a state where one side is fixed in this way, the left sheet width sensor flag 121 on the side to which the sheet is moved is pressed by the sheet and rotated. Accordingly, the link member 122 rotates. As a result, the second photo interrupter 131 is shielded from light, and the second detector 131A outputs a signal waveform that is the same as when both the right and left sheet width sensor flags 120 and 121 are rotating. When such a signal waveform is output, the control unit 1F determines that the passing sheet is a sheet having a length equal to or longer than a predetermined width direction length.

  That is, even when the narrow sheet is conveyed by being shifted, if the same waveform as the signal waveform when the wide sheet is conveyed is output from the second detection unit 131A, the control unit 1F It is not possible to detect that the narrow sheet is being conveyed. In this way, when one second photo interrupter 131 is used, when at least one of the right and left sheet width sensor flags 120 and 121 is stacked (hooked) at the rotation position, the conveyed sheet is a narrow sheet. Even in this case, this cannot be detected. As a result, there is a possibility that the offset transport is performed without reducing the throughput and the fixing device 12 is damaged.

  However, in the present embodiment, when one of the right and left sheet width sensor flags 120 and 121 is stacked, the detection is detected by the connecting pieces 120A and 121A on the side where the connecting portion 117A of the conveyance detection sensor flag 117 is stacked. Held in position. That is, when one of the right and left sheet width sensor flags 120 and 121 is stacked, the conveyance detection sensor flag as shown in FIG. 117 is held at the detection position.

  Here, normally, after the sheet is conveyed, the control unit 1F determines that the sheet JAM has occurred when the conveyance detection sensor flag 117 is in the detection position even after a predetermined time has elapsed. However, in the present embodiment, when the conveyance detection sensor flag 117 is in the detection position before the sheet is conveyed, the control unit 1F determines which of the right and left sheet width sensor flags 120 and 121 is not JAM. Judges that is stuck. In this case, the control unit 1 </ b> F performs control for protecting the fixing device 12.

  In other words, in the present embodiment, when a stack occurs in the right and left sheet width sensor flags 120 and 121, the right and left sheet width sensor flags 120 are moved by moving the conveyance detection sensor flag 117 to the detection position. , 121 are detected. When the stack of the right and left sheet width sensor flags 120 and 121 is detected in this way, control for protecting the fixing device 12 is performed.

  As described above, when the right and left sheet width sensor flags 120 and 121 are stacked, the right and left sheet width sensor flags 120 and 121 are indirectly moved by moving the conveyance detection sensor flag 117 to the detection position. Can be detected. In other words, when at least one of the right and left sheet width sensor flags 120 and 121 is rotated before the sheet is conveyed, the right and left sheet width sensors are rotated by rotating the conveyance detection sensor flag 117. A malfunction of the flags 120 and 121 can be detected. As a result, even when one photo interrupter 131 is used, it is possible to detect the stack of the right and left sheet width sensor flags 120 and 121, and to prevent damage to the fixing device 12 at low cost.

  Next, a description will be given based on the second embodiment of the present invention. FIG. 7 is a diagram illustrating the configuration of the first and second detection units of the fixing device according to the present embodiment. In FIG. 7, the same reference numerals as those in FIGS. 3 and 5 described above indicate the same or corresponding parts.

  In the present embodiment, as shown in FIG. 7, the rotation center position of the conveyance detection sensor flag 117 is downstream of the rotation center position of the right and left sheet width sensor flags 120 and 121 by a distance m in the sheet conveyance direction. Are arranged as follows. With this arrangement, the timing at which the conveyance detection sensor flag 117 contacts the leading edge of the sheet is later than the timing at which the contact pieces of the right and left sheet width sensor flags 120 and 121 contact the leading edge of the sheet. It is trying to become. Also, the timing at which the conveyance detection sensor flag 117 is separated from the trailing edge of the sheet is set to be later than the timing at which the contact pieces of the right and left sheet width sensor flags 120 and 121 are separated from the trailing edge of the sheet.

  FIG. 8 is a diagram illustrating a state where a wide sheet has been conveyed by the first and second detection units 130A and 131A having the above-described configuration. When the wide sheet S is conveyed, a contact piece (not shown) is pressed against the sheet S, whereby the right and left sheet width sensor flags 120 and 121 are rotated, and the link member 122 is rotated accordingly. Move.

  Here, as described above, the rotation center position of the conveyance detection sensor flag 117 is disposed downstream of the rotation center positions of the right and left sheet width sensor flags 120 and 121 in the sheet conveyance direction. Yes. For this reason, the conveyance detection sensor flag 117 is rotated by the connecting portion 117A being pressed by the connecting portions 120A and 121A of the right and left sheet width sensor flags 120 and 121 before the sheet S is pushed and rotated. Move to the detection position. The control unit 1F detects that the wide sheet is being conveyed by detecting that the link member 122 and the conveyance detection sensor flag 117 have moved to the detection position.

  Thereafter, when the sheet passes, first, the right and left sheet width sensor flags 120 and 121 first move away from the sheet to the standby position, and thereafter, the conveyance detection sensor flag 117 moves away from the sheet and waits. Move to. That is, the timing at which the conveyance detection sensor flag 117 is separated from the sheet is later than the timing at which the contact pieces of the right and left sheet width sensor flags 120 and 121 are separated from the sheet.

  FIG. 9 is a diagram illustrating operations of the first and second detection units 130A and 131A when a narrow sheet is conveyed. When the narrow sheet S is conveyed, the conveyance detection sensor flag 117 is rotated, but the right and left sheet width sensor flags 120 and 121 are not in contact with the sheet S and do not rotate. Does not move. The control unit 1F detects that the conveyance detection sensor flag 117 is at the detection position and the link member 122 is not rotated and is at the standby position by the first and second detection units 130A and 131A. It is detected that the sheet S is being conveyed. In this case, the control unit 1 </ b> F performs control for protecting the fixing device 12.

  On the other hand, when the sheet is conveyed toward one side, as described above, only one of the right and left sheet width sensor flags 120 and 121 rotates, so that the link member 122 cannot rotate, and the second photo interrupter 131 The rotation of the link member 122 is not detected. Also in this case, since the conveyance detection sensor flag 117 is in a position where the first photo interrupter 130 is shielded, the control unit 1F detects the passage of the sheet.

  As described above, when the sheet is conveyed while being moved to one side, the control unit 1F detects that the sheet width sensor flags 120 and 121 are in the standby position, and thus the same detection as when the narrow sheet is conveyed. It becomes a state. Therefore, in this case, that is, when the second photo interrupter 131 does not detect the link member 122 and the first photo interrupter 130 detects the conveyance detection sensor flag 117, the control unit 1F performs control for protecting the fixing device 12. I do.

  In addition, as described above, for example, a piece of a sheet generated during the jam processing enters the attachment portion of the right and left sheet width sensor flags 120 and 121, and one side of the right and left sheet width sensor flags 120 and 121 is in a rotational position. It may be in a fixed state. However, also in the present embodiment, the conveyance detection sensor flag 117 is held at the detection position by the connecting portions 120A and 121A of the right and left sheet width sensor flags 120 and 121 on the stacked side. When the control unit 1F determines that the conveyance detection sensor flag 117 is in the detection position before the sheet is conveyed, it is determined that one of the right and left sheet width sensor flags 120 and 121 is stacked. Judgment and control for protecting the fixing device 12 are performed.

  As described above, the timing at which the conveyance detection sensor flag 117 is separated from the trailing edge of the sheet is later than the timing at which the contact pieces of the right and left sheet width sensor flags 120 and 121 are separated from the trailing edge of the sheet. That is, in the present embodiment, when the trailing edge of the sheet passes, the right and left sheet width sensor flags 120 and 121 move to the standby position, and then the conveyance detection sensor flag 117 moves to the standby position.

  Here, for example, when the sheet is switched back during double-sided printing, the accuracy of sheet trailing edge detection is required. Therefore, when the sheet is switched back in this way, the right and left sheet width sensor flags 120 and 121 are moved to the standby position and then the conveyance detection sensor flag 117 is moved to the standby position as in the present embodiment. By doing so, the trailing edge detection accuracy can be increased.

  That is, as in the present embodiment, the timing at which the first detection unit 130A no longer detects the conveyance detection sensor flag 117 is delayed from the timing at which the second detection unit 131A no longer detects the link member 122. The trailing edge detection accuracy can be increased.

  Next, a description will be given based on the third embodiment of the present invention. FIG. 10 is a diagram illustrating the configuration of the first and second detection units of the fixing device according to the present embodiment. 10, the same reference numerals as those in FIGS. 3 and 5 described above indicate the same or corresponding parts.

  In the present embodiment, as shown in FIG. 10, the rotation center position of the conveyance detection sensor flag 117 is upstream by the distance n from the rotation center known position of the right and left sheet width sensor flags 120 and 121 by the distance n. It is arranged to be. By arranging in this way, the timing at which the conveyance detection sensor flag 117 comes into contact with the leading edge of the sheet is made earlier than the timing at which the contact pieces of the right and left sheet width sensor flags 120 and 121 come into contact with the sheet. I have to.

  FIG. 11 is a diagram illustrating a state where a wide sheet has been conveyed by the first and second detection units 130A and 131A having the above-described configuration. When the wide sheet S is conveyed, a contact piece (not shown) is pushed by the sheet S, whereby the right and left sheet width sensor flags 120 and 121 are rotated, and the link member 122 is rotated accordingly. To do.

  Here, as described above, the rotation center position of the conveyance detection sensor flag 117 is disposed upstream of the rotation center positions of the right and left sheet width sensor flags 120 and 121 in the sheet conveyance direction. Yes. For this reason, the conveyance detection sensor flag 117 rotates to the detection position earlier than the right and left sheet width sensor flags 120 and 121 rotate. The control unit 1F detects that the wide sheet is being conveyed by detecting that the link member 122 and the conveyance detection sensor flag 117 have moved to the detection position.

  Thereafter, the trailing edge of the sheet exits the conveyance detection sensor flag 117. At this time, the right and left sheet width sensor flags 120 and 121 are moved to the rotation positions. For this reason, the conveyance detection sensor flag 117 is in a state in which the connecting portion 117A is pushed by the connecting portions 120A and 121A of the right and left sheet width sensor flags 120 and 121 even when the rear end of the sheet passes. It cannot return to the standby position.

  As a result, the conveyance detection sensor flag 117 returns to the standby position when the right and left sheet width sensor flags 120 and 121 return to the standby position. That is, the conveyance detection sensor flag 117 returns to the standby position for the same time as the right and left sheet width sensor flags 120 and 121 return to the standby position.

  FIG. 12 is a diagram illustrating operations of the first and second detection units 130A and 131A when a narrow sheet is conveyed. When the narrow sheet S is conveyed, the conveyance detection sensor flag 117 is rotated, but the right and left sheet width sensor flags 120 and 121 are not in contact with the sheet S and do not rotate. Does not move. The control unit 1F detects that the conveyance detection sensor flag 117 is at the detection position and the link member 122 is not rotated and is at the standby position by the first and second detection units 130A and 131A. It is detected that the sheet S is being conveyed.

  On the other hand, when the sheet is conveyed toward one side, as described above, only one of the right and left sheet width sensor flags 120 and 121 rotates, so that the link member 122 cannot rotate, and the second photo interrupter 131 The rotation of the link member 122 is not detected. Also in this case, since the conveyance detection sensor flag 117 is in a position where the first photo interrupter 130 is shielded, the control unit 1F detects the passage of the sheet. Therefore, in this case, the control unit 1F performs control for protecting the fixing device 12.

  Also in the present embodiment, when one side of the right and left sheet width sensor flags 120 and 121 is fixed at the rotational position, the conveyance detection sensor flag 117 is held at the detection position. ing. Accordingly, the control unit 1F determines that one of the right and left sheet width sensor flags 120 and 121 is stacked, and performs control for protecting the fixing device 12.

  As described above, the timing at which the conveyance detection sensor flag 117 is pressed by the leading edge of the sheet is earlier than the timing at which the contact pieces of the right and left sheet width sensor flags 120 and 121 are pressed by the sheet. That is, in this embodiment, the right and left sheet width sensor flags 120 and 121 move to the standby position after the conveyance detection sensor flag 117 moves to the standby position by being pressed by the sheet that has passed through the fixing unit of the fixing device 12. To do.

  Here, for example, when detecting JAM detection of a sheet winding around the fixing device 12, early tip detection is required. Therefore, when detecting such a sheet winding JAM detection, as in the present embodiment, the configuration in which the second detection unit 131A performs the detection operation after the detection operation of the first detection unit 130A is completed. However, the tip detection can be accelerated. That is, as in the present embodiment, the timing at which the first detection unit 130A detects the conveyance detection sensor flag 117 is earlier than the timing at which the second detection unit 131A detects the link member 122, so that the sheet It is possible to speed up the detection of the tip.

DESCRIPTION OF SYMBOLS 1 ... Printer, 1A ... Printer main body, 1B ... Image forming part, 1F control part, 12 ... Fixing device, 117 ... Conveyance detection sensor flag, 117A ... Connection part, 120 ... Right sheet width sensor flag, 121 ... Left sheet width sensor Flag, 120A, 121A ... connecting portion, 122 ... link member, 122A ... contact portion, 130 ... first photo interrupter, 130A ... first detecting portion, 131 ... second photo interrupter, 131A ... second detecting portion, R ... Sheet transport path, S ... sheet

Claims (6)

In an image forming apparatus including a fixing device that heats and fixes a toner image transferred to a sheet on the sheet,
A sheet conveyance path through which the sheet passes;
A first detection unit that includes a first flag provided in the sheet conveyance path that is rotated by being pressed by the sheet on which the toner image is fixed, and that detects the passage of the sheet by detecting the rotated first flag. When,
2 provided at both ends in the width direction of the sheet conveying path that is pressed by the sheet and rotates when a sheet having a length equal to or greater than the length in the width direction orthogonal to the predetermined sheet conveying direction is conveyed. A sheet having a link member that rotates in conjunction with the second flag when both the two second flags and the two second flags rotate, and a sheet that passes by detecting the rotated link member; A second detection unit that detects that the sheet has a length equal to or greater than a predetermined length in the width direction,
When at least one of the two second flags is rotated before the sheet is conveyed, the first detection unit is rotated so as to detect the first flag. An image forming apparatus, wherein the first flag is rotated in conjunction with the second flag. A controller for controlling the heating temperature of the fixing device,
When the control unit determines that the sheet is not a sheet having a length equal to or longer than a predetermined width direction based on a signal from the second detection unit, and before the sheet is conveyed, the first detection unit 2. The image forming apparatus according to claim 1, wherein when the first flag is detected, the heating temperature of the fixing device is controlled to be lowered.   3. The image forming apparatus according to claim 1, wherein the two second flags include a pressing portion that presses and rotates the first flag when rotating.   The image forming apparatus according to claim 3, wherein the link member is rotated along with the rotation of the pressing portions of the two second flags when both of the second flags are rotated.   5. The timing at which the first detection unit does not detect the first flag is set to be later than the timing at which the second detection unit does not detect the link member. The image forming apparatus according to any one of the above.   5. The timing according to claim 1, wherein the timing at which the first detection unit detects the first flag is earlier than the timing at which the second detection unit detects the link member. The image forming apparatus according to claim 1.

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