JP5327510B2 - Image forming apparatus - Google Patents

Description

  The present invention relates to an image forming apparatus that fixes a toner image transferred onto a recording sheet by a fixing unit heated by a heater, such as a printer apparatus, a facsimile apparatus, a copying machine, and a multifunction machine.

  An image forming apparatus for fixing a toner image transferred onto a recording sheet by a heated fixing unit includes a temperature sensor for detecting the temperature of the fixing unit, and a heater based on the temperature of the fixing unit detected by the temperature sensor. Control means for controlling the drive.

  The fixing unit includes a heating roller with a built-in heater and a pressure roller that presses the heating roller (see, for example, Patent Document 1). Such a fixing unit fixes the toner image transferred onto the recording paper by the heat of the heating roller by sandwiching the recording paper with a heating roller and a pressure roller.

  By the way, the heating roller and the pressure roller serving as fixing means are arranged so as to extend in the width direction of the recording paper, which is a direction perpendicular to the recording paper conveyance direction. As a result, an area where the recording paper passes and an area where the recording paper does not pass are generated.

  As described above, when the fixing unit is formed with an area where the recording paper passes and an area where the recording paper does not pass, temperature control is performed so that the heating roller is heated over the entire length in the axial direction. Then, the temperature of the portion of the heating roller where the recording paper does not pass rises higher than the temperature of the portion of the recording paper that passes, and there is a risk that part of the heating roller will melt and be welded or deformed. Further, when the toner image of the recording paper having a small size is fixed while the entire heating roller is heated, the entire portion through which the recording paper does not pass is heated, so that useless power consumption occurs.

Therefore, there has been proposed one in which a plurality of heaters are arranged in the width direction of the recording paper and the heaters are individually driven and controlled in accordance with the size of the recording paper (for example, see Patent Document 2). .
JP-A-10-301440 Japanese Patent Laid-Open No. 11-115175

  However, when the individual heaters are driven in accordance with the size of the recording paper, the end of the recording paper passage area in the heater is deprived of heat from the portion outside the low temperature passage area. Therefore, when the heater is warmed up due to the start of driving of the heater in the passing zone, it takes time for the temperature at the end of the passing zone to reach the fixing temperature.

  FIG. 5 is a graph showing a temperature change in the vicinity of the boundary of the passing region in the heating roller, and an explanatory diagram showing heater on / off control.

  In the graph of FIG. 5, the dotted lines (X1, Y1) indicate the temperature change when heat leaks at the end of the passing area of the heating roller, and the two-dot broken line (Z) indicates heat leak. There is no ideal temperature change. The heating roller preferably reaches the fixing temperature with a certain temperature rise from the start of driving of the heater.

  However, as shown by the two-dot broken line (Z), when the heating roller changes in an ideal temperature, the fixing temperature is reached at time t3, but as shown by the dotted line (X1, Y1), it passes through the heating roller. When heat leaks at the end of the region, the time reaches the fixing temperature after time t3, and it takes time to reach the fixing temperature. In particular, when the amount of heat leakage is large as indicated by the dotted line X1, it takes a very long time to reach the fixing temperature.

  Even if the temperature at the center of the passing area of the heating roller is the fixing temperature, if the fixing is performed while the temperature at the end of the passing area is lower than the fixing temperature, fixing unevenness may occur.

  Therefore, if it is attempted to warm up the fixing means so that the temperature of the entire pass band is constant, it is conceivable to drive all the heaters only during the warming up, but if all the heaters are driven at the same time, the inrush current will be very high. It gets bigger.

  SUMMARY OF THE INVENTION An object of the present invention is to provide an image forming apparatus that can solve the above-described problems and can perform warm-up so that the temperature of the entire passage area of the recording paper becomes constant in a short time. It is another object of the present invention to provide an image forming apparatus that can reduce inrush current as much as possible and can reduce power consumption as much as possible.

An image forming apparatus according to the first aspect of the present invention has two or more heaters divided in a direction perpendicular to the conveyance direction of the recording paper, and fixing means for heating and fixing the toner image transferred to the recording paper. And a temperature detecting means for detecting the temperature of the fixing means, and a temperature control means for controlling the temperature of the heater based on the detection result of the temperature detecting means . The fixing unit includes, as the heater, a heater in a passing region disposed in a passing region through which the recording paper passes, and a heater in a passing region disposed outside the passing region, and the temperature detecting unit includes the heater in the passing region. And a temperature sensor that detects a temperature outside the passband, and the temperature control means is configured to pass the temperature during warm-up to change the temperature in the passband from room temperature to a fixable temperature. Target temperature determining means for determining a target temperature of the out-of-passage heater based on a temperature detected by the in-area sensor, comparison means for comparing a slope of a temperature change detected by the out-of-passage sensor at the time of warming up with a threshold value, and Based on the comparison result of the comparison means, a reference point serving as a reference for heat leaking from the inside of the passing area of the fixing means to the outside of the passing area is determined. And a reference point determining means for constant for, after the target temperature has been determined by the target temperature determining means, the temperature of the passage outside the heater so that the target temperature by increasing the heating value of the pass outside heater And the target temperature determining means determines the target temperature by comparing slopes of changes in temperature detected by the in-passage sensor before and after the reference point.

  The image forming apparatus of the present invention detects the temperature in the passing zone at the time of warming up, determines the target temperature of the heater outside the passing zone based on the detection result, and sets the target temperature outside the passing zone to be the target temperature. Increase the heating value of the heater. As a result, even if the heat in the passing zone in the fixing means leaks outside the passing zone, it becomes possible to immediately bring the entire passing zone to a fixable temperature by increasing the amount of heat generated by the heater outside the passing zone. .

  Furthermore, according to the image forming apparatus of the present invention, the amount of heat generated by the heater outside the passband is increased after the temperature inside the passband is detected and the target temperature is determined. Electric power can be reduced as much as possible. In addition, since the target temperature is determined according to the amount of heat leaked from the fixing means, the heater outside the passing zone does not generate wasteful power consumption, and maintains the entire passing zone at the fixing temperature. Power consumption can be minimized. In addition, if the heater outside the passband is driven after detecting the temperature in the passband and determining the target temperature, the inrush current at the start of driving the heater in the passband can be reduced.

  The image forming apparatus according to the present invention determines the reference point serving as a reference for heat leaking from the inside of the passing region of the fixing unit to the outside of the passing region by comparing the inclination of the temperature detected by the sensor outside the passing region with the threshold value. Then, the target temperature is determined by comparing the slopes of changes in the detected temperature by the in-passage sensor before and after the reference point. As a result, the heat leak from the inside of the passband to the outside of the passband is detected based on the temperature change outside the passband, so that the heat leak can be reliably detected. Moreover, since the target temperature is determined based on the point in time when the heat leak is detected, the heater outside the pass band can be increased with an appropriate heat generation amount.

The image forming apparatus according to the second invention, in addition to the above structure, the target temperature determining means determines the target temperature within a certain time from the reference point, the temperature control means, a constant from the reference point Control is performed to increase the amount of heat generated by the out-of-passage heater so that the target temperature is reached after a lapse of time . The image forming apparatus of the present invention can appropriately determine the target temperature by detecting a temperature change in the passband within a predetermined time from the reference time.

  According to the image forming apparatus of the present invention, the target temperature of the heater outside the passband is determined based on the temperature change in the passband and outside the passband in the vicinity of the end of the passband, and the target temperature is set to the target temperature. Since the amount of heat generated by the heater outside the pass band is increased, even if the heat in the pass band leaks, the entire pass band can be immediately brought to a fixable temperature.

  Moreover, according to the image forming apparatus of the present invention, the amount of heat generated by the heater outside the pass band is increased after the temperature inside the pass band is detected and the target temperature is determined. Electric power can be reduced as much as possible. In addition, the image forming apparatus of the present invention can reduce the inrush current. Furthermore, since the target temperature is determined according to the amount of heat leaked from the fixing means, the heater outside the pass band does not generate wasteful power consumption, and can minimize power consumption.

  An image forming apparatus according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram illustrating a configuration example of an image forming apparatus according to an embodiment of the present invention, in which a multifunction machine 1 is illustrated as an example of the image forming apparatus. The multifunction device 1 can read an image from a paper document using the scanner 14, can perform various processing processes on the image data, and prints the image on a paper medium using the printer 15. be able to.

  The multi-function device 1 includes a control unit 10 composed of an MPU (Micro Processing Unit), a ROM (Read-Only Memory) 12 and a RAM (Random Access Memory) respectively connected to the control unit 10 via a parallel communication path 11. ) 13, a scanner 14, a printer 15, a codec 16, an image memory 17, an operation unit 18, a communication unit 19, a print control unit 20, and a temperature detection unit 5.

  The control part 10 controls each part which comprises this apparatus. The ROM 12 stores a computer program executed by the control unit 10, and necessary data is stored in the RAM 13 based on program processing of the control unit 10. The scanner 14 emits light toward the document and receives reflected light from the document, thereby outputting a signal corresponding to the amount of received light.

  The printer 15 includes a toner image forming unit 3 including a photosensitive drum 31, an exposure device 32, a charger 33, a developing device 34, a transfer roller 35, and the like, and a fixing device 4, and records based on image data. Print an image on paper. For example, in the copy mode, an image is printed on a recording sheet by the printer 15 based on image data of a document read by the scanner 14.

  The codec 16 encodes image data to be transmitted at the time of facsimile transmission / reception or e-mail transmission / reception, or composites reception image data. The image memory 17 stores various image data such as received image data received by facsimile or e-mail and image data read by the scanner 14. The operation unit 18 includes a plurality of operation keys and a touch panel for a user to perform input operations, and can perform operations for selecting various modes and various setting operations.

  Although not shown, the communication unit 19 is connected to another facsimile machine via a public communication line such as a telephone line, is connected to a mail server via a WAN (Wide Area Communication Network), and is connected to a LAN (Local Area Network). It is connected to other terminal devices via. Although not shown, the communication unit 19 includes interfaces connected to a public communication line, a WAN, and a LAN. As described above, the multifunction device 1 can perform facsimile transmission / reception with another facsimile apparatus via the public communication line, and can also transmit / receive electronic mail via the WAN and the mail server. Further, the communication unit 19 can perform data communication with a plurality of terminal devices via the LAN.

  The print control unit 20 performs print control when the printer 15 prints image data on recording paper. The print control unit 20 controls the drive of each unit such as the photosensitive drum 31, the exposure device 32, the charger 33, the developing device 34, the transfer roller 35, and the fixing device 4 of the printer 15. The print control unit 20 controls the heating of the fixing device 4 according to the size of the recording paper.

  The temperature detection unit 5 detects the temperature of the heating roller 41 of the fixing device 4 in the printer 15. The temperature detection unit 5 includes two or more temperature sensors 51, and detects two or more temperatures in a direction perpendicular to the recording paper conveyance direction of the heating roller 41.

  FIG. 2 is a block diagram illustrating a configuration example of the printer 15 in the multifunction machine 1 according to the present embodiment. A photosensitive drum 31 is disposed upstream of the recording paper conveyance direction, and a fixing device 4 is disposed downstream of the photosensitive drum 31.

  The photosensitive drum 31 has a photoconductive film on its outer peripheral surface and is rotated by a motor. Around the photosensitive drum 31, a charger 33, an exposure device 32, a developing device 34, and a transfer roller 35 are arranged.

  The charger 33 can be configured by a non-contact discharge type corotron type and a scorotron type, a contact type charging roller or a charging brush. In the present embodiment, a non-contact discharge type charger 33 is used. The charger 33 uniformly charges the outer peripheral surface of the photosensitive drum 31 to a predetermined voltage.

  The exposure device 32 can be configured using a laser or LED. In the present embodiment, the exposure device 32 is configured by arranging a large number of LEDs in parallel in a direction orthogonal to the conveyance direction of the recording paper so as to reach the full width of the recording paper of the largest size that can be printed by the multifunction device 1. ing. The exposure device 32 irradiates the outer peripheral surface of the photosensitive drum 31 with light based on the input image information, and forms an electrostatic latent image corresponding to the image information on the outer peripheral surface of the photosensitive drum 31.

  The developing device 34 includes a supply roller 34a and a developing roller 34b. The supply roller 34a supplies the toner to the developing roller 34b in a state where the toner is charged from a toner case (not shown) that stores the toner. A predetermined bias voltage is applied to the supply roller 34a. The developing roller 34b is disposed between the supply roller 34a and the photosensitive drum 31 in contact with these rollers. A predetermined bias voltage is applied to the developing roller 34 b and the toner is placed on the photosensitive drum 31.

  The transfer roller 35 is disposed so as to come into contact with the outer peripheral surface of the photosensitive drum 31, and the recording paper passes between the transfer roller 35 and the photosensitive drum 31. The transfer roller 35 is rotated by a motor, and a predetermined bias voltage is applied. A transfer roller 35 to which a bias voltage is applied transfers a mirror image of the toner on the photosensitive drum 31 onto a recording sheet.

  The fixing device 4 includes a heating roller 41 having two or more heaters 6 and a pressure roller 42. The heating roller 41 is formed by applying an insulating material such as polyimide on the inner surface side of a cylinder 41a made of glass or aluminum, and further applying a resistance heating element on the inner surface side thereof. In the present embodiment, this resistance heating element becomes the heater 6. When the heater 6 is supplied with power, it generates heat by resistance and heats the cylinder 41a.

  By using glass as the material constituting the cylinder 41a, the heat retention can be improved. Thus, by forming the cylinder 41a with glass, the heating roller 41 that has risen to the fixing temperature can maintain the fixing temperature for a while even if the heating by the heater is stopped.

  FIG. 3 is a schematic perspective view showing the fixing device 4 of the present embodiment. The heater 6 is provided with five heaters 6 inside the cylinder 41a so as to divide the axial direction of the cylinder 41a. Each heater 6 is arrange | positioned so that it may not mutually overlap. Each heater 6 is individually heated and controlled by the printing control unit 20.

  The axial length of the first heater 61 arranged at the central portion in the axial direction of the cylinder 41a is a length (a) corresponding to the size of the postcard-sized recording paper. The second heater 62 and the third heater 63 adjacent to the first heater 61 have the same axial length, and the total axial length (b) including the first heater 61, the second heater 62, and the third heater 63 is the same. The second heater 62 and the third heater 63 are formed so as to have a short width of the A4 size recording paper. The fourth heater 64 and the fifth heater 65 disposed at the axial end of the cylinder 41a have the same axial length, and the total axial length (c) including all of the first heater 61 to the fifth heater 65 is the same. The fourth heater 64 and the fifth heater 65 are formed to be slightly longer than the length of the long width of the A3 size recording paper.

  The fixing device 4 heats and presses the recording paper on which the toner image is transferred from the photosensitive drum 31 by the transfer roller 35 by the heating roller 41 and the pressure roller 42 to fix the toner image on the recording paper. In addition, by forming the cylinder 41a of the heating roller 41 from glass, the heat retaining property of the heating roller 41 can be improved and fixing can be performed well.

  As shown in FIG. 3, eight temperature sensors 51 constituting the temperature detecting unit 5 are arranged near the outer peripheral surface of the heating roller 41 on the side opposite to the pressure roller 42. A temperature sensor 51 is disposed at a portion of the heating roller 41 where the first heater 61, the fourth heater 64, and the fifth heater 65 are provided so as to correspond to both axial ends of the heaters. Further, a temperature sensor 51 is disposed at a portion of the heating roller 41 where the second heater 62 and the third heater 63 are provided, corresponding to the central portion in the axial direction of these heaters. The temperature detected by each temperature sensor 51 is input to the print control unit 20.

  In the present embodiment, for the first heater 61, the fourth heater 64, and the fifth heater 65 having a large width, the temperature sensor 51 is provided at the end in the width direction. Can be detected satisfactorily.

  Although not shown, the printer 15 is provided with a paper feed mechanism for taking out the paper cassette recording sheets one by one on the paper feed side.

  FIG. 4 is a block diagram illustrating the configuration of the print control unit 20, the printer 15, and the temperature detection unit 5. The print control unit 20 includes a recording paper size designation unit 71, a toner image formation control unit 72, and a fixing control unit 73.

  When the user operates the operation unit 18 to specify the size of the recording paper, the recording paper size designation unit 71 designates the recording paper size by the designation operation, and automatically scans the original image with the scanner 14. When the document is read by the printer, when the original on which the image is printed is set in the multi function device 1, the size of the recording paper to be automatically printed is detected and the recording paper size is designated. The recording paper size data designated by the recording paper size designation unit 71 includes a toner image formation control unit 72, a passage area heater selection unit 81 in the temperature control unit 8 of the fixing control unit 73, a passage area temperature detection unit 5a, and the like. It is input to the outside-passage temperature detector 5b.

  The toner image formation controller 72 drives and controls the photosensitive drum 31, the charger 33, the exposure device 32, the developing device 34, and the like of the toner image formation unit 3 in the printer 15.

  The fixing control unit 73 includes a temperature control unit 8 and a pressure roller control unit 9. The temperature control unit 8 controls the heating temperature of each heater 6, and the pressure roller control unit 9 controls the force with which the pressure roller 42 presses the recording paper according to the state of the toner image on the recording paper.

  The temperature control unit 8 further includes an in-passage temperature detecting unit 5a, an out-of-passage temperature detecting unit 5b, an in-passage heater selecting unit 81, and an in-passage region that calculates the inclination of the temperature change in the passing region through which the printed recording paper passes. Temperature gradient calculation unit 82, non-passage temperature gradient calculation unit 83 for calculating the gradient of the temperature change outside the passband through which the printed recording paper does not pass, the first comparison unit 84, the second comparison unit 85, and the reference point determination unit 86 , A target temperature determination unit 87, a passage-inside heater driving unit 88, and a passage-outside heater driving unit 89.

  The temperatures detected by the eight temperature sensors 51 of the temperature detector 5 are input to both the in-passage temperature detector 5a and the out-of-passage temperature detector 5b. Based on the size of the recording paper designated by the recording paper size designating unit 71, the in-passage temperature detecting unit 5a is a temperature arranged in the passing region through which the recording paper to be printed passes among the eight temperature sensors 51. The sensor 51 is selected to detect the temperature in the passband. Based on the size of the recording paper designated by the recording paper size designating unit 71, the outside-passage temperature detecting unit 5b is a temperature arranged outside the passing region through which the recording paper to be printed does not pass among the eight temperature sensors 51. The sensor 51 is selected to detect the temperature outside the passband. The detected temperature in the passband is input to the passband temperature gradient calculating unit 82 and the passband heater driving unit 88. Further, the detected temperature outside the passband is input to the passband outside temperature gradient calculating unit 83 and the passband outside heater driving unit 89.

  The in-passage heater selection unit 81 selects the heater 6 for fixing the toner image placed on the recording paper from among the five heaters 6 in accordance with the size of the recording paper designated by the recording paper size designation unit 71. . The heater 6 selected in the in-passage heater selection unit 81 becomes the in-passage heater 6a disposed in the passband through which the recording paper to be printed passes. Further, the remaining heaters 6 not selected as the in-passage heater 6a become the out-of-passage heater 6b.

  Information on the in-passage heater 6 a and the out-of-passage heater 6 b selected by the in-passage heater selection unit 81 is input to the in-passage heater driving unit 88 and the out-of-passage heater driving unit 89.

  For example, when fixing a postcard-sized recording paper, the first heater 61 disposed in the axial center of the heating roller 41 is heated until the surface of the cylinder 41a of the heating roller 41 reaches the fixing temperature. Selected as. At this time, the temperature sensor 51 provided corresponding to the first heater 61 is a temperature sensor in the passing region, and the remaining temperature sensors 51 are temperature sensors outside the passing region.

  When fixing A4 size or B5 size recording paper, the first heater 61 disposed in the axial center of the heating roller 41 and the second heater 62 and the third heater adjacent to the first heater 61 are provided. The heater 63 is selected as the in-passage heater 6a. At this time, the temperature sensor 51 provided corresponding to the first heater 61, the second heater 62, and the third heater 63 becomes a temperature sensor in the passing area, and the remaining temperature sensors 51 become temperature sensors outside the passing area.

  Further, when fixing B4 size or A3 size recording paper, all the heaters 6 become the in-passage heaters 6a. At this time, all the temperature sensors 51 become temperature sensors in the passband.

  The in-passage temperature gradient calculator 82 calculates the inclination of the change in temperature in the passband of the recording paper based on the temperature in the passband detected by the in-passage temperature detector 5a. This calculation result is input to the second comparison unit 85 at the time of warming up in which the temperature in the passband is changed from the normal temperature to the fixable temperature. The temperature detection result in the pass band is also input to the heater drive unit 88 in the pass band.

  Based on the temperature outside the passband detected by the passband outside temperature detector 5b, the passband outside temperature tilt calculator 83 calculates the slope of the temperature change outside the passband where the recording paper does not pass. The calculation result is input to the first comparison unit 84 at the time of warming up. The temperature detection result outside the pass band is also input to the heater outside the pass band driver 89.

  The first comparison unit 84 compares the temperature change gradient calculated by the outside-passage temperature gradient calculation unit 83 based on the temperature outside the passband detected during warm-up with a threshold value. In the present embodiment, the gradient of the temperature change that is considered that the heat in the passing region of the heating roller 41 leaks out of the passing region is determined as the threshold value. In the present embodiment, the first comparison unit 84 compares whether or not the detected slope of the temperature change outside the passband has become a threshold value. The comparison result is input to the reference point determination unit 86.

  For example, in the graph of FIG. 5, the lines (X1, Y1) indicated by dotted lines indicate the temperature change when heat leaks at the end in the passing area of the heating roller, and the outside of the passing area corresponding to the dotted line (X1). The temperature change detected by the temperature sensor 51 arranged at is indicated by a solid line (X3), and the temperature change detected by the temperature sensor 51 arranged outside the passband corresponding to the dotted line (Y1) is indicated by a solid line (Y3). .

  In the graph of FIG. 5, if the heat begins to leak at the end of the passing area of the heating roller 41 from time t1, the slope of the solid line (X3, Y3) increases from time t1 to time t2 over time. The solid lines (X3, Y3) indicate that the amount of heat leaked with time has increased.

  Based on the comparison result of the first comparison unit 84, the reference point determination unit 86 determines a reference point serving as a reference for determining that heat is leaking from the inside of the passing area to the outside of the passing area in the heating roller 41 of the fixing device 4. In the present embodiment, the time point at which the detected slope of the temperature change outside the passband becomes a threshold value is determined as the reference point. In the graph of FIG. 5, time t1 is the reference point. The reference point determined by the reference point determination unit 86 is input to the second comparison unit 85.

  The second comparison unit 85 compares the gradient of the temperature change calculated by the in-passage temperature gradient calculation unit 82 based on the temperature in the passband detected during warm-up before and after the reference point. The second comparison unit 85 compares whether the slope of the detected temperature change in the passband has changed before and after the reference point. This comparison result is input to the target temperature determination unit 87.

  In the graph of FIG. 5, the slopes of the dotted lines (X1, Y1) and the solid lines (X2, Y2) become smaller with the lapse of time between time t1 and time t2, which are the reference points. This indicates that a leak has occurred.

  The target temperature determination unit 87 determines the target temperature based on the comparison result by the second comparison unit 85. When the heat in the passing area of the heating roller 41 leaks out of the passing area, the slope of the temperature change after the reference point is higher than the slope of the temperature change before the reference point as shown in the graph of FIG. Get smaller. In the present embodiment, the target temperature determination unit 87 is based on the gradient of the temperature change before and after the reference point, and as the gradient of the temperature change after the reference point becomes smaller than the gradient of the temperature change before the reference point. The target temperature is determined so that the target temperature becomes high.

  In the present embodiment, the target temperature determination unit 87 determines the target temperature to be lower than the fixing temperature. By making the target temperature lower than the fixing temperature, the temperature outside the passing area of the heating roller 41 rises above the temperature inside the passing area, and a part of the heating roller 41 is melted and welded or deformed. I can stop.

  When warming up, the in-passage heater driving unit 88 controls the heating of the in-passage heater 6a based on the detected temperature in the passband so that the surface temperature of the cylinder 41a of the heating roller 41 reaches the fixing temperature. Further, during the printing operation, based on the detected temperature in the passing area, the heater 6 in the passing area is heated and controlled so that the temperature of the surface of the cylinder 41a where the heater 6a in the passing area is maintained at the fixing temperature.

  During warming up, the outside-passage heater driving unit 89 causes the surface temperature of the cylinder 41a where the outside-passage heater 6b is located to reach the target temperature determined by the target temperature determination unit 87 based on the detected temperature outside the passband. The heater 6b outside the pass band is controlled to be heated. Further, during the printing operation, based on the detected temperature outside the pass band, the heater outside the pass band 6b is controlled so that the temperature of the surface of the cylinder 41a where the heater 6b outside the pass area is maintained at the target temperature. When the out-of-passage heater 6b is heated at the target temperature, the temperature is adjusted by reducing the drive current as compared with the case of heating at the fixing temperature.

  In the multifunction device 1 of the present embodiment, in the toner image forming unit 3, the photosensitive drum 31 is charged to a predetermined voltage by the charger 33, and the electrostatic latent image corresponding to the image information is applied to the photosensitive drum 31 by the exposure device 32. And the toner is attracted to the electrostatic latent image on the photosensitive drum 31 by the developing device 34, and a toner image is formed on the photosensitive drum 31. Then, the toner image on the photosensitive drum 31 is transferred to the recording paper by the transfer roller 35.

  When the toner image is transferred to the recording paper, the fixing device 4 fixes the toner image. In the fixing device 4, the recording paper is heated and pressurized by the heating roller 41 and the pressure roller 42, and the toner image is fixed on the recording paper. The heating roller 41 heats the out-of-passage heater 6b to the target temperature in accordance with the amount of heat leaked in the pass-through area when warming up. By heating the out-of-passage heater 6b in this way, the temperature change in the portion corresponding to the pass-through area of the heating roller 41 can be changed as shown by the solid lines (X2, Y2) in FIG.

  Next, a specific example of controlling the heating of the heater 6 of the heating roller 41 according to the size of the recording paper will be described with reference to the drawings.

  FIG. 6 shows a state where the entire width of the heating roller 41 is heated to the fixing temperature. In FIG. 6, the temperature sensor 51 is a triangle shown below the first heater 61 to the fifth heater 65. In FIG. 6, the temperature sensor 51 is numbered 1 to 8 from the left end. Further, the solid line shown in the upper part of the first heater 61 to the fifth heater 65 in FIG. 6 indicates the temperature distribution in the axial direction of the heating roller 41. 7 and 8 similarly show the temperature distribution and temperature sensor 51 at the upper and lower portions of the heater. 6 to 8, the heater heated to the fixing temperature is indicated by fine cross hatching, and the heater heated at the target temperature is indicated by large cross hatching.

  According to FIG. 6, it can be seen that the temperature is lowered at the end of the heating roller 41 in the axial direction. In the present embodiment, the heating roll 41 is configured to pass the recording paper so that the end portion where the temperature is not lowered becomes the end portion of the recording paper. As a result, the recording paper can be fixed uniformly without causing uneven fixing.

  FIG. 7 shows a state where the portions of the heating roller 41 facing the first heater 61, the second heater 62, and the third heater 63 are heated to the fixing temperature. FIG. 7A shows a state in which only the first heater 61, the second heater 62, and the third heater 63 are heated to the fixing temperature, and the fourth heater 64 and the fifth heater 65 are not driven as in the prior art. Show. FIG. 7B shows a state in which the first heater 61, the second heater 62, and the third heater 63 are heated to the fixing temperature, and the fourth heater 64 and the fifth heater 65 are heated at the target temperature. ing.

  According to FIG. 7A, since the fourth heater 64 and the fifth heater 65 are not heated, the temperature of the portion corresponding to the end portions of the second heater 62 and the third heater 63 in the heating roller 41 decreases. ing. Therefore, if an A4 size recording sheet is fixed in this state, there is a possibility that uneven fixing occurs at the end.

  According to FIG. 7B, since the fourth heater 64 and the fifth heater 65 are heated to the target temperature, the temperature of the portion corresponding to the end portions of the second heater 62 and the third heater 63 in the heating roller 41. Has not declined. Accordingly, when A4 size recording paper is fixed in this state, the fixing can be performed uniformly. In addition, the fourth heater 64 and the fifth heater 65, which are the heaters 6b outside the passband, can be used for auxiliary heating to the heater 6a in the passband, so that the surface temperature in the passband of the heating roller 41 can be reduced in a short time when warming up. Can be raised to the fixing temperature.

  Further, since the target temperature of the fourth heater 64 and the fifth heater 65 is determined to be lower than the fixing temperature, the member of the heating roller 41 is not deformed even when the recording paper is not passed. Further, if the fourth heater 64 and the fifth heater 65 are heated at the target temperature, the fourth heater 64 and the fifth heater 65 are quickly raised to the fixing temperature when the entire width of the heating roller 41 is heated at the fixing temperature. Can be made.

  FIG. 8 shows a state where the portion of the heating roller 41 facing the first heater 61 is heated to the fixing temperature. FIG. 8A shows a state in which only the first heater 61 is heated to the fixing temperature and the second heater 62, the third heater 63, the fourth heater 64, and the fifth heater 65 are not driven as in the prior art. Show. FIG. 8B shows a state where the first heater 61 is heated to the fixing temperature and the second heater 62 and the third heater 63 are heated at the target temperature.

  According to FIG. 8A, since the heaters other than the first heater 61 are not heated, the temperature of the portion corresponding to the end of the first heater 61 in the heating roller 41 is lowered. Therefore, if a postcard-sized recording paper is fixed in this state, there is a possibility that fixing unevenness will occur at the edge.

  According to FIG. 8B, since the second heater 62 and the third heater 63 are heated to the target temperature, the temperature of the portion corresponding to the end of the first heater 61 in the heating roller 41 is not lowered. . Accordingly, when a postcard-sized recording sheet is fixed in this state, the fixing can be performed uniformly. In addition, since the second heater 62 and the third heater 63 that are the heaters 6b outside the passband can be used for auxiliary heating to the heater 6a in the passband, the surface temperature in the passband of the heating roller 41 can be reduced in a short time when warming up. Can be raised to the fixing temperature.

  Further, since the target temperatures of the second heater 62 and the third heater 63 are determined to be lower than the fixing temperature, the member of the heating roller 41 is not deformed even when the recording paper is not passed. In addition, if the second heater 62 and the third heater 63 are heated at the target temperature, the second heater 62 and the third heater 63 are fixed when the process proceeds to the fixing process for the A4 size recording paper, which is frequently processed. Can rise quickly to temperature.

  Next, the control of the heating roller in the fixing device when image data is printed on A4 size recording paper in the multifunction machine 1 will be described with reference to the flowchart shown in FIG.

  When the recording paper size designating unit 71 in the printing control unit 20 designates the size of the recording paper on which the image data is to be printed (step S101), the recording paper size information is obtained from the temperature control unit 8 of the printing control unit 20. It is sent to the in-passage heater selector 81, the in-passage temperature detector 5a, and the outside-passage temperature detector 5b.

  The in-passage heater selection unit 81 selects the in-passage heater 6a and the out-passage heater 6b that perform heating at the fixing temperature based on the size of the recording paper (step S102). When the in-passage heater 6a and the out-of-passage heater 6b are selected, the in-passage heater driving unit 88 controls the in-passage heater 6a to be heated from the room temperature to the fixing temperature (step S103). .

  Further, based on the temperature detected by the temperature sensor 51 every time a predetermined time has elapsed from the start of driving of the in-passage heater 6a, the in-passage temperature detector 5a and the out-of-passage temperature detector 5b change the temperature inside and outside the passband. Detected. Based on the detected temperatures inside and outside the passband, the slope of the temperature change inside the passband and the slope of the temperature change outside the passband when warming up are obtained (step S104). The calculation result of the gradient of each temperature change is temporarily stored in the RAM 13.

  Next, the slope of the temperature change outside the passband is compared with a threshold value (step S105). If the slope of the temperature change outside the pass band becomes a threshold value (Yes in step S105), that point is determined as a reference point (step S106). If the slope of the temperature change outside the passband is not the threshold value (No in step S105), the process returns to step S104, and steps S104 to S105 are repeated until the slope of the temperature change outside the passband reaches the threshold value.

  Next, the inclination of the temperature change in the passband before and after the reference point is compared (step S107). Based on the comparison result, the target temperature of the out-of-passage heater 6b is determined (step S108). After the predetermined target temperature is determined, the out-of-passage heater driving unit 89 drives the out-of-passage heater 6b, and heats the heating roller 41 to the target temperature based on the detected temperature outside the pass-through area (step S109).

  In the conventional heater 6, as shown in FIG. 5, the temperature change at the end of the heater 6 in the width direction changes so as to draw a dotted line (X1, Y1). Not reach. In the present embodiment, as shown by the dotted lines (X1, Y1), when heat leaks in the passband, the reference point (time t1) is set as the reference point when the heat leak in the passband starts. The target temperature (A1, A2) of the heater 6b outside the pass band is determined based on the temperature change in the front and rear pass zones, and the driving of the heater 6b outside the pass band is started so as to reach this target temperature (time t2).

  In FIG. 5, the target temperature (A2) is increased to compensate for the amount of heat leakage with respect to the temperature change of the dotted line (X1) where the amount of heat leakage is large. At this time, the temperature change of the heater 6b outside the passband is indicated by a solid line (X3), and the temperature change of the heater 6a inside the passband is indicated by a solid line (X2). Further, since the amount of heat leakage is smaller than the temperature change of the dotted line (X1) with respect to the temperature change of the dotted line (Y1), the target temperature (A1) is set lower than the target temperature (A2). At this time, the temperature change of the heater 6b outside the passband is indicated by a solid line (Y3), and the temperature change of the heater 6a inside the passband is indicated by a solid line (Y2). FIG. 5 shows a control for starting the driving of the out-of-passage heater 6b at time t2 and stopping the driving at the time t3 when controlling the heating of the out-of-passage heater 6b at the target temperature.

  As described above, the heater 6 according to the present embodiment has a temperature within the passage area when the temperature outside the passage area rises even though the heater 6b outside the passage area is not driven during the warm-up. It is determined that the heat is leaking outside the pass band, and control is performed so that the heater 6b outside the pass band is driven so as to reach the target temperature. As a result, even if the heat corresponding to the passage area in the heating roller 41 leaks outside the passage area, the entire passage area can be immediately brought to the fixing temperature.

  Furthermore, since the timing for driving the heater 6b outside the passband of the heater 6 according to the present embodiment is after the temperature in the passband is detected and the target temperature is determined, the power consumption of the heater outside the passband is reduced as much as possible. Can do. In addition, since the target temperature is determined according to the amount of heat leaked from the heating roller 41, the heater outside the passage area does not generate unnecessary power consumption, and the power consumption for maintaining the entire passage area at the fixing temperature is reduced. Can be minimized. Further, since the heater 6b outside the pass band is driven after detecting the temperature in the pass band and determining the target temperature, the inrush current at the start of driving the heater 6a in the pass band can be reduced.

  In this embodiment, after the target temperature is determined, the outside-passage heater 6b is driven, but at the same time when the inside-passage heater 6a starts to be driven, the control temperature is considerably lowered to drive the outside-passage heater 6b. In this way, the present invention can be applied.

  Further, in the above-described embodiment, the case where a multifunction device that performs printing, facsimile transmission, and e-mail transmission is used as the image forming device has been described. However, the image forming device of the present invention is not limited to a multifunction device, and The present invention can be applied to various image forming apparatuses that perform data print processing.

1 is a block diagram illustrating a configuration example of a multifunction peripheral as an image forming apparatus according to an embodiment of the present invention. 1 is a block diagram illustrating a configuration example of a printer in a multifunction machine according to an embodiment of the present invention. 1 is a schematic perspective view showing a fixing device of a printer according to an embodiment of the present invention. FIG. 3 is a block diagram illustrating configurations of a print control unit, a printer, and a temperature detection unit of the multifunction peripheral according to the embodiment of the present invention. It is a graph which shows the temperature change of the boundary part of the passage area in a heating roller, and explanatory drawing which shows on / off control of a heater. It is explanatory drawing which showed the state which heated the full width of the heating roller to fixing temperature. It is explanatory drawing which showed the state which heated the part facing the 1st heater, 2nd heater, and 3rd heater of a heating roller to fixing temperature. It is explanatory drawing which showed the state which heated the part facing the 1st heater of a heating roller to fixing temperature. 6 is a flowchart showing drive control of a heater in the fixing device of the multifunction peripheral according to the embodiment of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Multifunction machine 10 Control part 11 Parallel communication path 12 ROM
13 RAM
14 Scanner 15 Printer 16 Codec 17 Image memory 18 Operation unit 19 Communication unit 20 Print control unit 3 Toner image forming unit 31 Photosensitive drum 32 Exposure unit 33 Charger 34 Development device 34a Supply roller 34b Development roller 35 Transfer roller 4 Fixing device 41 Heating Roller 41a Cylinder 42 Pressure roller 5 Temperature detector 5a Passing zone temperature detector 5b Passing zone outside temperature detector 51 Temperature sensor 6 Heater 6a Passing zone heater 6b Passing zone heater 61 First heater 62 Second heater 63 Third heater 64 First 4 heater 65 5th heater 71 recording paper size designation unit 72 toner image formation control unit 73 fixing control unit 8 temperature control unit 81 in-passage heater selection unit 82 in-passage temperature gradient calculation unit 83 out-of-passage temperature gradient calculation unit 84 first comparison Unit 85 second comparison unit 86 reference point determination unit 87 target temperature determination unit 8 passband heater driving unit 89 passes outside the heater driving section 9 pressure roller controller

Claims (2)

A fixing unit having two or more heaters divided in a direction perpendicular to the conveyance direction of the recording paper, and heating and fixing the toner image transferred to the recording paper;
Temperature detecting means for detecting the temperature of the fixing means;
Temperature control means for controlling the temperature of the heater based on the detection result by the temperature detection means,
The fixing unit has, as the heater, a heater in the passband disposed in the passband through which the recording paper passes, and a heater in the passband disposed outside the passband,
The temperature detection means includes a sensor in the passband that detects the temperature in the passband, and a sensor outside the passband that detects a temperature outside the passband,
The temperature control means includes
Target temperature determining means for determining the target temperature of the heater outside the pass band based on the temperature detected by the sensor in the pass band at the time of warming up to change the temperature in the pass band from normal temperature to a fixable temperature ;
A comparison means for comparing the slope of the temperature change detected by the out-of-passage sensor at the time of warming up with a threshold;
A reference point determining means for determining a reference point serving as a reference for heat leaking from the inside of the passing area of the fixing means to the outside of the passing area based on the comparison result of the comparing means ;
After the target temperature is determined by the target temperature determining means, the heat generation amount of the out-of-passage heater is increased to control the temperature of the out-of-passage heater so as to become the target temperature ,
The target temperature determining means is
An image forming apparatus, wherein the target temperature is determined by comparing slopes of changes in temperature detected by the in-passage sensor before and after the reference point . The target temperature determining means determines the target temperature within a predetermined time from the reference point,
The image forming apparatus according to claim 1 , wherein the temperature control unit performs control to increase a heat generation amount of the out-of-passage heater so that the target temperature is reached after a predetermined time has elapsed from the reference point.

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