JP2012083416A - Image formation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image formation device capable of making a fixing speed higher than a transfer speed for forming an image on a sheet, which can solve the problem of low productivity in conventional image formation devices with multiple conveyance belts between a transfer nip and a fixing nip because time taken to convey a sheet from the transfer nip to the fixing nip is long.SOLUTION: While maintaining a setting of the peripheral speed of a first conveyance belt to the transfer speed and the peripheral speed of a second conveyance belt provided on the downstream side of the first conveyance belt in the sheet conveyance direction to the fixing speed higher than the transfer speed, a sheet having a toner image transferred by a transfer nip is conveyed. The sheet extending over the first conveyance belt and the second conveyance belt is conveyed at a high speed by being pulled by the second conveyance belt while sliding on the first conveyance belt.

Description

  The present invention relates to an image forming apparatus that forms an image on a sheet.

  As a conventional image forming apparatus, a toner image formed on an image carrier such as a photoreceptor or an intermediate transfer member is transferred onto a sheet by a transfer unit, and the toner image transferred onto the sheet is heated and fixed at a fixing unit. This is known.

  Here, the amount of heat applied to the sheet by the fixing unit, which is suitable for melting the toner in the fixing unit and fixing it to the sheet, varies depending on the type of the sheet. Therefore, there is an apparatus that changes the amount of heat applied to the sheet according to the sheet type by changing the sheet conveyance speed in the fixing unit according to the sheet type.

  Patent Document 1 discloses an image forming apparatus in which the sheet conveyance speed of the fixing unit is higher than that of the transfer unit when the sheet is plain paper (a sheet having a normal thickness). In this image forming apparatus, two transport belts are arranged in the transport direction between the transfer section and the fixing section. The two conveying belts suck and convey the sheet in order to convey the sheet holding unfixed toner to the fixing unit. Here, the lengths of the two conveying belts in the sheet conveying direction are both larger than the maximum usable sheet length. And in the structure described in patent document 1, a sheet | seat is conveyed as follows.

  The upstream transport belt driven at the transfer speed at the transfer section receives the sheet fed from the transfer section, and the upstream transport belt is also driven at the transfer speed at the transfer section. The sheet is conveyed to the conveyance belt. Before the leading edge of the sheet reaches the fixing unit and when the trailing edge of the sheet reaches the downstream conveying belt, the conveying speed of the downstream conveying belt is changed to the fixing speed. Then, the sheet is conveyed to the fixing unit by the downstream conveying belt driven at the fixing speed.

  In other words, since the length of the downstream conveying belt in the sheet conveying direction is longer than the maximum usable sheet length, the sheet may be carried and conveyed only by the downstream conveying belt. Change the belt transport speed to the fixing speed.

JP 2006-251441 A

  However, in the above-described image forming apparatus, after the trailing edge of the conveyed sheet reaches the downstream conveying belt, the conveying speed of the downstream conveying belt is changed to a high fixing speed. That is, the sheet is conveyed at a low transfer speed until the trailing edge of the conveyed sheet is separated from the upstream conveying belt. Therefore, the timing at which the sheet conveyance speed is changed to a high fixing speed is late. Since the timing at which the speed of the sheet proceeding from the transfer section is changed to a high speed is late, it takes a long time for the sheet proceeding from the transfer section to reach the fixing section, resulting in low productivity.

  The object of the present invention is to reduce the time until the sheet that has traveled from the transfer section reaches the fixing section in an image forming apparatus capable of forming an image on the sheet in a state where the fixing speed is higher than the transfer speed. Shorten and increase productivity.

  The present invention includes a transfer nip that transfers a toner image onto a sheet that is being conveyed at a transfer speed, a first conveyance belt that conveys a sheet on which the toner image is transferred at the transfer nip, and a sheet that is more than the first conveyance belt. A second conveying belt that conveys the sucked sheet, and is provided downstream of the second conveying belt in the sheet conveying direction and conveys the toner image on the sheet while conveying the sheet. An image forming apparatus having a high-speed fixing mode in which a toner image is fixed to a sheet while the fixing nip conveys the sheet at a speed higher than the transfer speed. In the mode, the peripheral speed of the first transport belt is set to the first speed for receiving the sheet traveling from the transfer nip, and the peripheral speed of the second transport belt is set to the sheet. The sheet is transported from the transfer nip to the fixing nip with the second speed higher than the first speed that causes the end to enter the fixing nip, and the first transport belt and the second transport are conveyed. The image forming apparatus is characterized in that a sheet straddling the belt is pulled by the second transport belt so as to slide on the first transport belt and is transported at a speed higher than the first speed.

  According to the present invention, productivity can be improved in an image forming apparatus capable of forming an image on a sheet in a state where the fixing speed is higher than the transfer speed.

1 is a schematic configuration diagram of an image forming apparatus according to the present invention. FIG. 3 is an enlarged view from a secondary transfer unit to a fixing unit in the first embodiment. It is a top view of the 2nd conveyance belt part in a 1st embodiment. 6 is a table showing a relationship between a fixing speed, a sheet type, and a basis weight. 3 is a block diagram for explaining a control unit of the image forming apparatus according to the first embodiment. FIG. 3 is a flowchart for explaining the operation of the image forming apparatus according to the first embodiment. 6 is a flowchart for explaining large-size conveyance control in the image forming apparatus according to the first embodiment. FIG. 6 is a diagram illustrating an operation when a large-size sheet is conveyed in a mode in which a fixing speed is higher than a transfer speed in the first embodiment. FIG. 6 is a diagram illustrating an operation when a small-size sheet is conveyed in a mode in which a fixing speed is faster than a transfer speed in the first embodiment. In the first embodiment, the transfer speed and the fixing speed are in the same speed mode, and are diagrams illustrating an operation when a large-size sheet is conveyed. FIG. 9 is an enlarged view from a secondary transfer unit to a fixing unit in the second embodiment. It is a top view of the 2nd conveyance belt part in a 2nd embodiment. It is a perspective view of the 2nd conveyance belt part in a 2nd embodiment. It is a block diagram for demonstrating the control part of the image forming apparatus which concerns on 2nd Embodiment. 10 is a flowchart for explaining the operation of the image forming apparatus according to the second embodiment. 10 is a flowchart for explaining large-size conveyance control in an image forming apparatus according to a second embodiment. FIG. 10 is a diagram illustrating an operation when a large-size sheet is conveyed in a mode in which a fixing speed is faster than a transfer speed in the second embodiment. FIG. 10 is a diagram illustrating an operation when a large-size sheet is conveyed in a mode in which a fixing speed is faster than a transfer speed in the second embodiment.

(First embodiment)
FIG. 1 is a cross-sectional view of a first embodiment of an image forming apparatus according to the present invention. First, a schematic configuration of the image forming apparatus will be described with reference to FIG.

  The image forming apparatus 100 includes a feeding unit 110 that feeds a stored sheet, an image forming unit 920 that forms a toner image on the sheet fed by the feeding unit 110, and a toner image formed thereon. A belt conveyance unit 904 that conveys the sheet to the fixing unit 50. Further, the image forming apparatus 100 includes a rear conveyance unit 903 that conveys the sheet on which the toner image is fixed by the fixing unit 50.

  The feeding unit 110 includes a sheet cassette 111 that stores sheets, a pickup roller 112 that picks up a sheet from the sheet cassette 111, and a separation device 113 that separates and feeds the sheet picked up by the pickup roller 112. Further, the feeding unit 110 includes a feeding roller 114 and a registration roller 115 that transport the sheet in a feeding path 901 in which the sheet separated and fed by the separation device 113 is transported.

  The image forming unit 920 is a tandem type image in which image forming stations 200Y, 200M, 200C, and 200K corresponding to respective colors of Y (yellow), M (magenta), C (cyan), and K (black) are arranged in series. Forming part. Each of the image forming stations 200Y, 200M, 200C, and 200K includes a photosensitive drum 120, a primary charging device 121, an exposure device 122, and a developing device 123.

  The image forming unit 920 further includes an intermediate transfer belt 125 to which the toner images visualized by the image forming stations 200Y, 200M, 200C, and 200K are transferred. The intermediate transfer belt 125 is supported around a driving roller 126, a tension roller 127, and a counter roller 128, and is driven by the driving roller 126 to rotate in the direction of arrow R2.

  Reference numeral 131 denotes a secondary transfer roller that presses against the intermediate transfer belt 125 supported from the inside by the opposing roller 128 and forms a secondary transfer nip N2 with the intermediate transfer belt 125. A secondary transfer unit 130 is configured by the secondary transfer roller 131, the intermediate transfer belt 125, and the opposing roller 128. The belt cleaning device 129 removes residual toner, paper dust, and the like remaining on the surface of the intermediate transfer belt 125 that has passed through the secondary transfer nip N2 by sliding the cleaning web against the intermediate transfer belt 125.

  The fixing unit 50 disposed downstream of the secondary transfer unit 130 in the sheet conveying direction fixes the toner image on the sheet by heat and pressure. The fixing unit 50 includes a heating roller 52 and a pressure roller 53 each having a heater therein. The fixing unit 50 includes a heating roller temperature sensor 70 for detecting the surface temperature of the heating roller 52, and a pressure roller temperature sensor 71 for detecting the surface temperature of the pressure roller 53. The heating temperature sensor 70 and the pressure roller temperature sensor 71 are provided to maintain the surface temperatures of the heating roller 52 and the heating roller 52 at appropriate temperatures, respectively.

  A belt transport unit 904 is disposed between the secondary transfer unit 130 and the fixing unit 50. The belt conveyance unit 904 includes a first belt conveyance unit 10 disposed on the upstream side in the conveyance direction and a second belt conveyance unit 20 disposed on the downstream side. The configuration of the belt conveyance unit 904 will be described in detail later.

  The rear conveying unit 903 includes a discharge roller 911 that discharges the sheet discharged from the fixing unit 50 to the outside of the apparatus. The post-conveying unit 903 further includes a reversing roller 912 that reversely conveys the sheet, and a double-sided conveying path 913 that conveys the sheet reversed by the reversing unit and joins the feeding path 901 on the downstream side.

  An outline of operations related to image formation in the image forming apparatus 100 will be described.

  The exposure device 122 exposes the photosensitive drum 120 to form an electrostatic latent image on the photosensitive drum 120. The electrostatic latent image on the photosensitive drum 120 is developed by the developing device 123 and is visualized as a toner image.

  The toner image carried on the surface of the photosensitive drum 120 is sequentially superposed on the intermediate transfer belt 125 by the primary transfer device 124 for primary transfer. The toner image on the intermediate transfer belt 125 on which all the colors Y, M, C, and K are primarily transferred is then fed to the sheet S fed by the feeding unit 110 at the secondary transfer nip N2 as a transfer nip. Secondary transferred onto The intermediate transfer belt 125 is driven to rotate by a driving roller 126 that rotates at a constant speed, and is rotated while its peripheral speed is maintained at a constant transfer speed. Accordingly, the sheet onto which the toner image is transferred is conveyed at the transfer speed by the secondary transfer nip N2. In this embodiment, the transfer speed is set to 300 mm / sec. The transfer speed is the speed of the sheet when the toner image is transferred.

  The registration roller 115 of the feeding unit 110 receives and waits for the sheet S in a stopped state, and sends the sheet S to the secondary transfer nip N2 in synchronization with the toner image on the intermediate transfer belt 125.

  The sheet S carrying the toner image transferred at the secondary transfer nip N <b> 2 is conveyed to the fixing unit 50 by the belt conveyance unit 904. In the fixing unit 50, the sheet S is sandwiched at the fixing nip N, and heat and pressure are applied to an unfixed toner image to fix the sheet on the sheet. The sheet S sent out from the fixing unit 50 after finishing the fixing process is discharged out of the apparatus by the discharge roller 911.

  When images are formed on both sides, the sheet fed from the fixing unit 50 is conveyed to the reverse roller 912, reversed by the reverse roller 912, and then guided to the feeding path 901 via the double-sided conveyance path 913. A toner image is formed on the second surface of the sheet in the same manner as the first surface.

  Next, referring to FIG. 2 which is an enlarged view showing the secondary transfer unit 130, the belt conveyance unit 904, and the fixing unit 50 and FIG. 3 which is a top view of the belt conveyance unit 904, the belt conveyance unit 904 and its surroundings are used. The detailed configuration will be described.

  The belt conveyance device 904 is disposed on the downstream side of the secondary transfer nip N2 in the sheet conveyance direction, on the downstream side of the first belt conveyance unit 10 and on the upstream side of the fixing nip N. The second belt conveying unit 20 is provided.

  A transfer guide 951 is provided between the belt conveyance unit 904 and the secondary transfer nip N2 to guide the sheet traveling from the secondary transfer nip N2 to the belt conveyance unit 904. Between the belt conveyance unit 904 and the fixing nip N, a pre-fixing guide 952 for guiding the sheet conveyed by the belt conveyance unit 904 to the fixing nip N is provided.

  The first belt conveyance unit 10 includes an endless first conveyance belt 11 provided with a large number of holes, and a first drive roller 12 and a driven roller 13 that stretch the first conveyance belt 11. The first belt conveyance unit 10 includes a first conveyance belt drive motor 14 that rotates the first conveyance belt 11 via a first drive roller 12. On the inner side of the first conveyor belt 11, a sheet conveyed by the first conveyor belt 11 is adsorbed to the circumferential surface of the first conveyor belt 11 through a number of holes formed in the first conveyor belt 11. A first suction fan 15 as one suction device is arranged. That is, the first suction fan 15 sucks air from the upper surface side of the first conveyance belt 11 and adsorbs the conveyed sheet to the upper surface of the first conveyance belt 11. The first conveying belt drive motor 14 is set so that the peripheral speed V1 of the first conveying belt 11 (hereinafter referred to as the conveying speed V1 of the first belt conveying unit 10) is 300 mm / sec, which is the same speed as the transfer speed VT. Driving.

  The second belt conveyance unit 20 has substantially the same configuration as the first belt conveyance unit 10 described above. An endless second conveying belt 21 provided with a large number of holes as shown in FIG. 3 and a second driving roller 22 and a driven roller 23 that stretch the second conveying belt 21 are connected to the second belt conveying device 20. Has. The second belt conveyance unit 20 includes a second conveyance belt drive motor 24 that rotates the second conveyance belt 21 via the second drive roller 22. Inside the second conveyance belt 21, the sheet conveyed by the second conveyance belt 21 is adsorbed to the peripheral surface of the second conveyance belt 21 through a large number of holes formed in the second conveyance belt 21. A second suction fan 25 is disposed as a second suction device. That is, the second suction fan 25 sucks air from the upper surface side of the second conveyance belt 21, and the conveyed sheet is adsorbed on the upper surface of the second conveyance belt 21. The second transport belt drive motor 24 can change the peripheral speed V2 of the second transport belt 21 (hereinafter referred to as the transport speed V2 of the second belt transport unit 20).

  A sheet leading edge detection sensor 26 that detects the leading edge of the sheet at a detection position P that is upstream of the fixing nip N is provided on the fixing unit 50 side of the second conveyance belt 21. The detection position P at which the sheet leading edge detection sensor 26 detects the sheet is set to a position where the trailing edge of the sheet has already passed through the secondary transfer nip N2 when the leading edge of the sheet reaches the detection position P. Yes. In this embodiment, the distance from the secondary transfer nip N2 to the detection position P is the length L of the sheet S having the longest length in the transport direction that can be used by the image forming apparatus (hereinafter referred to as the maximum sheet length). Longer than set. In the present embodiment, the detection position P where the sheet leading edge detection sensor 26 detects the sheet is set at the downstream end of the second transport belt 21.

  In the fixing unit 50, the heating roller 52 is rotationally driven by a heating roller driving motor 54 (for example, a DC brushless motor). The peripheral speed of the heating roller 52 (hereinafter referred to as the fixing speed VF) can be changed. Here, the fixing speed is the speed of the sheet when the sheet on which the toner image is fixed by the fixing unit 50 is conveyed. The sheet S conveyed at the fixing nip N formed between the heating roller 52 and the pressure roller 53 is conveyed at a fixing speed VF.

  The length of the sheet conveyance path between the secondary transfer nip N2 and the fixing nip N is set to be longer than the maximum sheet length L. The length LB of the sheet conveyance path from the sheet leading edge detection sensor 26 to the fixing nip N is set to be longer than the distance necessary for changing the speed of the second conveyance belt 21.

  Further, the length B in the sheet S conveyance direction of the first conveyance belt 11 and the second conveyance belt 21 is the same, and is slightly smaller than half the length L of the maximum sheet. In the present embodiment, the first conveyor belt 11 and the second conveyor belt 21 have the same configuration in order to use common parts. However, the present invention is not limited to the first conveyor belt 11 and the second conveyor belt 21 having the same length (same configuration). For example, the length of the first transport belt 11 in the transport direction is set to 2/3 of the maximum sheet length L, and the length of the second transport belt 21 in the transport direction is 1/3 of the maximum sheet length L. It may be.

  FIG. 5 is a block diagram illustrating a control relationship of the image forming apparatus 100. The control unit 170 includes a circuit that exchanges data with an arithmetic processing unit including a CPU, a memory, and the like, and an I / O port, a communication interface, and the like. The control unit 170 controls the operation of the image forming apparatus by sequentially executing a plurality of programs stored in the memory according to the situation.

  The control unit 170 controls each unit such as the feeding unit 110 and the image forming unit 920 in accordance with a print job sent from an external device. An operation unit is connected to the control unit 170, and information on the sheet type (basis weight, size, plain paper or coated paper) is sent from the operation unit. The information sent as a print job from the external device also includes information regarding the sheet type. Here, the coated paper is a resin-coated sheet. A signal from the sheet leading edge detection sensor 26 is input to the control unit 170. The controller 170 controls the operations of the first and second conveyor belt drive motors 14 and 24, the first and second suction fans 15 and 25, and the heating roller drive motor 54.

  The controller 170 receives signals from the heating roller temperature sensor 70 and the pressure roller temperature sensor 71 of the fixing unit 50. The controller 170 also controls the temperature of the heating roller 52 and the pressure roller 53. That is, the control unit 170 controls the energization to the heater provided inside the heating roller 52 based on the output from the heating roller temperature sensor 70 through the temperature adjustment unit, thereby the surface of the heating roller 52. The temperature is controlled to be a preset temperature. Based on the output from the pressure roller temperature sensor 71, the controller 170 controls the energization of the heater inside the pressure roller 53, so that the surface temperature of the pressure roller 53 becomes a preset temperature. The temperature is controlled through the temperature control unit. In the present embodiment, the controller 170 adjusts the temperature so that the surface temperature of the heating roller 52 becomes 170 ° C. and the surface temperature of the pressure roller 53 becomes 100 ° C.

  Here, the control unit 170 controls the heating roller drive motor 54 of the fixing unit 50 so that the fixing speed is changed according to the basis weight and the type (plain paper or coated paper) in the information on the sheet type. Control the behavior. FIG. 4 is a table showing the correspondence between the type of sheet S, the basis weight of the sheet, and the set fixing speed VF. In mode 2, the amount of heat given to the sheet by the fixing unit 50 per unit area of the sheet is larger than in mode 1 in FIG. In mode 3, the amount of heat applied to the sheet by the fixing unit 50 per unit area of the sheet is greater than in mode 2. In mode 4, the amount of heat applied to the sheet by the fixing unit 50 per unit area of the sheet is greater than in mode 3.

  As shown in the table of FIG. 4, for example, a plain paper of about 60 gsm has a fixing speed set to 480 mm / sec. A plain paper of about 60 gsm has a smaller heat capacity than, for example, a plain paper of about 200 gsm. Therefore, when fixing an image on plain paper of about 60 gsm, the fixing speed is set to 480 mm / sec, which is faster than 300 mm / sec set for plain paper of about 200 gsm, and the sheet S passes through the fixing nip N. The time you are doing is small. Thus, when fixing an image on plain paper of about 60 gsm, the amount of heat received by the sheet per unit area is made smaller than when fixing an image on plain paper of about 200 gsm.

  As the basis weight of the sheet increases, the heat capacity increases. Therefore, as the basis weight of the sheet increases, the amount of heat required per unit area of the sheet increases as the sheet is heated to a temperature at which the toner is fixed to the sheet. growing. Therefore, as shown in FIG. 4, the larger the basis weight, the slower the fixing speed and the greater the amount of heat given per unit area of the sheet. Further, since the amount of heat required for fixing an image per unit area of the sheet is larger in the coated paper than in the plain paper, the fixing speed is changed depending on whether the paper is plain paper or coated paper as shown in the table of FIG.

  Further, the control unit 170 adjusts the conveyance speed V2 of the second conveyance belt unit 20 in the range of 300 to 480 mm / sec in correspondence with the speed adjustment of the fixing speed VF. The conveyance speed V <b> 2 of the second conveyance belt unit 20 is performed by the control unit 170 controlling the second conveyance belt drive motor 24.

  In the following, regarding the sheet conveyance control and operation from the secondary transfer nip N2 to the fixing unit 50, the flowcharts of FIGS. 6 and 7 and the operation explanatory diagrams of FIGS. 8 to 10 showing the sheet conveyance state will be used. Will be described in detail.

  In the flowchart of FIG. 6, the control unit 170 determines which mode in FIG. 4 from the type and basis weight of the information related to the sheet input from the operation unit or the like. That is, the control unit 170 refers to the table of FIG. 4 to determine whether or not the transfer speed and the fixing speed are the same mode (mode 4) (step 1 (hereinafter, step is abbreviated as S)). .

  If it is a mode other than mode 4 (high-speed fixing mode in which the fixing speed is faster than the transfer speed) (NO in S1), the sheet size is large or small based on the size information among the information regarding the sheet type. The control unit 170 determines whether or not (S2). In this embodiment, the length of the conveyed sheet in the conveyance direction is shorter than the length from the secondary transfer nip N2 to the upstream end of the second conveyance belt 21 and from the downstream end of the first conveyance belt 15 to the fixing nip N. When it is shorter than the length, it is determined that it is a small size. When the control unit 170 determines that the size is not small in S2, the control unit 170 executes the large size transport control shown in FIG. FIG. 8 is a time-series explanation of the sheet conveyance operation when the control is performed in a mode in which the fixing speed is higher than the transfer speed and the sheet size is large (hereinafter, large size conveyance control). FIG.

  In the large size conveyance control shown in FIG. 7, the control unit 170 controls the heating roller drive motor 54 so as to achieve the fixing speed VF shown in FIG. 4 according to the type and basis weight of the sheet (S21). Then, the controller 170 stops (OFF) the operation of the first suction fan 15 and rotates the second suction fan 25 (ON). In addition, the control unit 170 is configured so that the conveyance speed V1 of the first belt conveyance unit 10 is 300 mm / sec, which is the same as the transfer speed, which is the first speed when the sheet traveling from the transfer nip N2 is received. The first conveyor belt drive motor 14 is controlled. The controller 170 sets the second belt conveyance unit 20 so that the conveyance speed V2 is 300 mm / sec, which is the same as the transfer speed, which is the first speed when the sheet traveling from the transfer nip N2 is received. The conveyor belt drive motor 24 is controlled (S21).

  Here, the first speed of the first belt transport unit 10 and the second belt transport unit 20 when receiving the sheet traveling from the transfer nip N2 is exemplified here as being equal to the transfer speed. . However, the first speed of the first belt conveyance unit 10 and the second belt conveyance unit 20 is a speed at which the sheet traveling from the transfer nip N2 can be smoothly conveyed with little influence on the transfer of the toner image. It does not have to be consistent with the transfer speed. For example, the first speed when receiving a sheet traveling from the transfer nip N2 may be about 4% faster than the transfer speed. This is because the sheet is nipped and conveyed by the transfer nip N2, and the first conveying belt 11 and the second conveying belt 12 and the sheet can be conveyed while sliding. Further, even if the first speed is set to a speed slightly lower than the transfer speed, it may be a level that does not affect the transfer.

  In such an operation state, the sheet fed from the secondary transfer nip N2 is conveyed by the first belt conveyance unit 10. Then, the first belt conveyance unit 10 sends the sheet to the second belt conveyance unit 20, and the leading end side of the sheet is conveyed by the second belt conveyance unit 20. At this time, the peripheral speed of the first transport belt 11 (the transport speed V1 of the first belt transport unit 10) is the first speed when receiving a sheet traveling from the transfer nip N2 (in this embodiment, the transfer speed). It is set to the same speed as a certain 300 mm / sec). Further, the peripheral speed of the second transport belt 21 (the transport speed V2 of the second belt transport unit 20) is also set to the first speed (300 mm / sec) when the sheet traveling from the transfer nip N2 is received. Therefore, as shown in FIG. 8A, the sheet S1 is on the first conveyance belt 11 and the second conveyance belt 21, while the rear end side of the sheet S1 is still nipped by the secondary transfer nip N2. Even in the state, the sheet S1 is smoothly conveyed. Since the sheet is smoothly conveyed, the transfer of the toner image at the secondary transfer nip N2 is favorably performed.

  Then, the control unit 170 determines whether the leading edge of the sheet conveyed by the first belt conveying unit 10 and the second belt conveying unit 20 has been detected by the sheet leading edge detection sensor 26 (S22). FIG. 8B shows a state when the leading edge of the sheet conveyed by the first belt conveying unit 10 and the second belt conveying unit 20 reaches the sheet leading edge detection sensor 26.

  When the leading edge of the sheet conveyed by the first belt conveyance unit 10 and the second belt conveyance unit 20 reaches the detection position P (YES in S22), the control unit 170 conveys the conveyance speed V2 of the second belt conveyance unit 20. The second conveying belt drive motor is controlled so that the fixing speed VF is the second speed at which the leading edge of the sheet enters the fixing nip N from 300 mm / sec as the first speed (S23). Note that the fixing speed VF here is a speed set according to the type and basis weight of the sheet with reference to the table of FIG. 4 as described above.

  Here, the second speed of the second belt conveyance unit 20 when the leading edge of the sheet enters the fixing nip N is exemplified here as being equal to the fixing speed. However, the second speed of the second belt conveyance unit 20 may be a speed that can be conveyed so that the toner image is well fixed when the leading edge of the sheet enters the fixing nip N. It does not necessarily need to match. For example, the second speed when the leading edge of the sheet enters the fixing nip N may be a speed that is several percent slower or several percent faster than the fixing speed. When the second speed of the second conveyor belt 21 is set to a speed several percent faster than the fixing speed, the second conveyor belt 21 and the fixing nip N are conveyed along with the conveyance after the leading edge of the sheet enters the fixing nip N. In this way, the sheet is bent. When the second speed of the second transport belt 21 is several percent lower than the fixing speed, the sheet is transported while sliding the second transport belt 21 during transport after the leading edge of the sheet enters the fixing nip N. Will go.

  As described above, the detection position P at which the sheet leading edge detection sensor 26 detects the leading edge of the sheet has already passed the secondary transfer nip N2 at the trailing edge of the sheet when the leading edge of the sheet reaches the detection position P. It is set to such a position. Therefore, when the conveyance speed of the second belt conveyance unit 20 is increased from 300 mm / sec to the second speed (the fixing speed VF in this embodiment), the trailing edge of the sheet has already passed through the secondary transfer nip N2. Therefore, there is no influence on the transfer of the toner image onto the sheet caused by raising the conveyance speed of the second belt conveyance unit 20 from the first speed to the second speed. The detection position P is set to a position where the second belt conveyance unit 20 can complete the increase from the first speed to the second speed until the leading edge of the sheet S1 reaches the fixing nip N of the fixing unit 50. ing.

  Here, in the first embodiment, the operation of the first suction fan 15 is stopped and the second suction fan 25 is operated, whereby the sheet is conveyed as follows. That is, since the first suction fan 15 is stopped, the sheet is not sucked to the peripheral surface of the first transport belt 11, and the second suction fan 25 is operated, so that the sheet is placed on the peripheral surface of the second transport belt 21. Sucked. Therefore, the transport force of the second transport belt 21 is larger than the transport force of the first transport belt 11. Therefore, the sheet is conveyed at the second speed while sliding on the first conveyor belt 11 by the second conveyor belt 21 that has been changed to a second speed that is faster than the peripheral speed of the first conveyor belt 11. The leading edge reaches the fixing nip N.

  In addition, while the sheet is being conveyed by the second conveying belt 21 while being slid on the first conveying belt 11, as shown in FIG. 8C, the subsequent image conveyed by the secondary transfer nip N2. The sheet S2 is transported by the first transport belt 11. Since the transport speed of the first belt transport unit 10 is set to the first speed (transfer speed), the succeeding sheet S2 is transported stably. In other words, since the peripheral speed of the first transport belt 11 is maintained at the first speed (transfer speed), the distance between successive sheets can be shortened and transported, so that the productivity of image formation is high. As described above, the leading end side of the succeeding sheet S2 is positioned on the first transport belt 11 in a state where the fixing nip N fixes the toner image on the preceding sheet S1 whose rear end is on the first transport belt 11. This is done while realizing stable conveyance. Therefore, the productivity is high because the distance between the trailing edge of the preceding sheet S1, the trailing sheet S2, and the leading edge can be shortened while the sheet is stably conveyed.

  Further, when the leading edge of the sheet S1 conveyed by the second belt conveying unit 20 reaches the fixing nip N, the sheet S1 moves at a second speed when the leading edge of the sheet enters the fixing nip N (in the present embodiment). It is conveyed at a fixing speed VF). If the conveyance speed of the second belt conveyance unit 20 and the fixing speed VF at the fixing nip N are greatly different when the leading edge of the sheet enters the fixing nip N, a fixing failure occurs. Since the sheet conveyed while sliding on the first conveying belt 11 by the second belt conveying unit 20 is conveyed at the second speed (fixing speed VF) when the leading edge of the sheet enters the fixing nip N, the toner No problems occur when fixing an image.

  Thereafter, after the control unit 170 determines that the leading edge of the sheet has reached the fixing nip N (YES in S24), the control unit 170 sets the conveying speed of the second belt conveying unit 20 to the fixing speed VF that is the second speed. The second conveyor belt drive motor 24 is controlled so that the first speed is 300 mm / sec (S25). The controller 170 determines whether or not the leading edge of the sheet has reached the fixing nip N as follows. That is, the control unit 170 receives a signal indicating that the leading edge of the sheet has been detected from the sheet leading edge detection sensor 26. A timer 666 measures whether a predetermined time required for the leading edge of the sheet to reach the fixing nip N after receiving a signal from the sheet leading edge detection sensor 26, and the leading edge of the sheet reaches the fixing nip N. Whether or not the control unit 170 determines.

  Thus, after the leading edge of the sheet is nipped by the fixing nip N, the conveying speed of the second belt conveying unit 20 is reduced to the transfer speed that is the first speed after the leading edge of the sheet is nipped by the fixing nip N. This is because the auxiliary belt is sufficient for the functions required for the second belt conveyance unit 20. After the conveyance speed of the second belt conveyance unit 20 is reduced to the transfer speed, the sheet conveyed by the fixing nip N is conveyed while sliding on the second conveyance belt 21. This is because the conveying force of the fixing unit 50 is stronger than the conveying force of the second conveying belt 21 because the clamping pressure at the fixing nip N is high.

  Thus, after the leading edge of the sheet is nipped by the fixing nip N and the rear side of the sheet is on the second conveying belt 21, the conveying speed of the second belt conveying unit 20 is a transfer that is the first speed. There are additional reasons for slowing down to speed: That is, when the preceding sheet S1 is being conveyed by the fixing nip N, the leading edge of the succeeding sheet S2 can be made to reach the second conveying belt 21. Accordingly, the interval between successive sheets can be shortened and conveyed, so that an image forming apparatus with high productivity can be provided. Although the trailing edge of the succeeding sheet is in the secondary transfer nip N2, the peripheral speeds of the first conveyor belt 11 and the second conveyor belt 21 are both the first speed when receiving the sheet traveling from the transfer nip N2. As a result, the succeeding sheet S2 can be stably conveyed, and the occurrence of transfer failure is prevented.

  The controller 170 decelerates the conveyance speed of the second belt conveyance unit 20 to 300 mm / sec, which is the first speed, in S25, and then determines whether the job is completed (S26), and the job is completed. If not, the process returns to S22. If the job is completed, the process returns to S3 in FIG. 6 and ends.

  If it is determined in S1 of FIG. 6 that the mode is 4, that is, if the controller 170 determines that the fixing speed VF is the same as the transfer speed VT, the process proceeds to S4. In S4, the control unit 170 operates (ON) the first suction fan 15 and operates (ON) the second suction fan 25. Further, the control unit 170 controls the first conveyance belt drive motor 14 so that the conveyance speed of the first belt conveyance unit 10 becomes the first speed (300 mm / sec equivalent to the transfer speed). Further, the control unit 170 controls the second conveyance belt drive motor 24 so that the conveyance speed of the second belt conveyance unit 20 becomes the first speed (300 mm / sec equivalent to the transfer speed). In this state, continuous sheets are conveyed. FIG. 10 shows the state when the large-size sheet is conveyed in a time series in the case where the fixing speed is the same as the transfer speed.

  In S1 of FIG. 6, when the mode is not mode 4 (when the fixing speed is faster than the transfer speed) and the sheet size is a small size (YES in S2), the process proceeds to S5. In S5, the control unit 170 operates (ON) the first suction fan 15 and operates (ON) the second suction fan 25. Further, the control unit 170 controls the first conveyance belt drive motor 14 so that the conveyance speed of the first belt conveyance unit 1011 becomes the first speed (300 mm / sec equivalent to the transfer speed). The control unit 170 controls the second transport belt drive motor 24 so that the transport speed of the second belt transport unit 20 becomes the second speed (a speed equivalent to the fixing speed VF). In this state, continuous sheets are conveyed.

  FIG. 9 is a diagram showing operations in time series when the fixing speed is faster than the transfer speed and small-size sheets are continuously conveyed. As described above, the small size means that when the leading edge of the sheet reaches the second conveyance belt 21, the trailing edge of the sheet has passed through the secondary transfer nip N2, and the leading edge of the sheet is the fixing nip N. The trailing edge of the sheet passes through the first conveyor belt 11. Hereinafter, a conveyance state when the fixing speed is faster than the transfer speed and the conveyed sheet is a small size will be described with reference to FIG.

  In FIG. 9A, the sheet on which the toner image is transferred in the transfer nip N2 is conveyed by the first conveyance belt 11 in which the peripheral speed is set to the transfer speed VT and the suction operation is performed. Indicates the state.

  Before the leading edge of the sheet conveyed by the first conveying belt 11 reaches the second conveying belt 11, the trailing edge of the sheet moves away from the transfer nip N2 (see FIG. 9B). That is, when the leading end side of the sheet comes into contact with the second conveying belt 21 rotating at the second speed higher than the transfer speed and being suctioned, the toner already in the secondary transfer nip N2 to the sheet The image transfer is complete. Therefore, even if the second conveyance belt 21 to which the sheet is sucked is kept at the second speed higher than the transfer speed, the second conveyance belt 21 does not adversely affect the transfer of the toner image.

  FIG. 9C shows a transient state after the leading edge of the sheet reaches the second conveying belt 21 and the sheet is conveyed across the first conveying belt 11 and the second conveying belt 21. Yes. In the initial stage of this transient state, that is, in a state where most of the sheet is on the first conveying belt 11 and a part of the leading end side of the sheet is in contact with the second conveying belt 21, the sheet is conveyed as follows. . The sheet is adsorbed by the first conveying belt 11 and conveyed by the first conveying belt 11 at the first speed, and the second conveying belt 21 rotating at a high second speed and a part of the leading end side of the sheet slide. Thereafter, when the sheet is conveyed and the area of the sheet in contact with the second conveyance belt 21 is increased, the sheet is adsorbed to the second conveyance belt 21 and slid on the first conveyance belt 11. The sheet is conveyed by being pulled by the conveying belt 21. Since the sheet is conveyed at high speed by the second conveying belt 21 at an early timing before the trailing end of the sheet passes the downstream end of the first conveying belt 11, the sheet traveling from the transfer nip N2 reaches the fixing nip N. Shorter time and higher productivity.

  Thereafter, after the trailing edge of the sheet passes the first conveying belt 11, the leading edge of the sheet reaches the fixing nip N (see FIG. 9D). When the leading edge of the sheet reaches the fixing nip N, the trailing edge of the sheet has already passed through the downstream edge of the first conveying belt 11, so that the second conveying belt 21 does not affect the first conveying belt 11. The sheet is conveyed at two speeds.

  By the way, in the above-described embodiment, in the large size transport control, the rotation of the first suction fan 15 of the first belt transport unit 10 is stopped (OFF), and the second suction fan 25 of the second belt transport unit 20 is turned off. It is operating (ON). As a result, the sheet S conveying force of the second conveying belt 21 acts more than the sheet S conveying force of the first conveying belt 11 and is pulled by the second conveying belt 21 so as to slide on the first conveying belt 11. The sheet was conveyed while being conveyed. However, for example, when the first suction fan 15 is rotated at a half speed and the second suction fan 25 is rotated at a full speed, a difference in suction force is provided between the first suction fan 15 and the second suction fan 25, and the first transport belt. The conveying force of the second conveying belt 21 may be made larger than the conveying force of 11, and the sheet may slide on the first conveying belt 11. Further, instead of a mode in which the rotation of the first suction fan 15 is stopped, a shutter may be provided between the first suction fan 15 and the first transport belt 11. That is, in order to reduce the conveying force of the first conveying belt 11, the conveying force of the first conveying belt 11 is reduced by blocking the air flow by the first suction fan 15 by the shutter and reducing the suction force of the sheet by the first conveying belt 11. To reduce.

  Further, in the large size conveyance control, the sheet conveyance force of the second conveyance belt 21 is set to be greater than the sheet conveyance force of the first conveyance belt 11 by configuring the following while the second suction fan 25 is operated. The sheet may be slid on the first conveying belt 11 by increasing the size. For example, by adjusting the number of holes and the size of the holes formed in the first conveyor belt 11 and the second conveyor belt 21, that is, the aperture ratio, the respective conveyance forces are adjusted at the time of design. May be. That is, by making the aperture ratio of the second conveyor belt 21 larger than the aperture ratio of the first conveyor belt 11, the first suction fan 25 sucks the sheet into the first conveyor belt 11 and the second suction fan 25 2. A difference is provided in the force for sucking the sheet to the conveying belt 21. Accordingly, the sheet conveying force of the second conveying belt 21 may be made larger than the sheet conveying force of the first conveying belt 11 so that the sheet slides on the first conveying belt 11. Further, by making the friction coefficient of the conveyance surface of the first conveyance belt 11 smaller than the friction coefficient of the conveyance surface of the second conveyance belt 11, the sheet conveyance force of the first conveyance belt 11 in the state where the sheet is sucked is set. The sheet conveying force of the second conveying belt 21 in the state of sucking the sheet may be increased and the sheet may be slid on the first conveying belt 11 by being pulled by the second conveying belt 21. For example, by applying a coating with Teflon (registered trademark) on the sheet conveying surface of the conveying belt, the friction coefficient of the sheet conveying surface may be reduced from about 1.0 to 1.2 to about 0.3 to 0.4. it can. Therefore, the sheet conveying surface of the first conveying belt 11 is coated with Teflon (registered trademark), while the second conveying belt is made of rubber having a high friction coefficient, for example. Thus, the friction coefficient of the sheet conveyance surface of the first conveyance belt 11 is set to be smaller than the friction coefficient of the sheet conveyance surface of the second conveyance belt 21. With this configuration, the sheet conveying force of the second conveying belt 21 in the state of sucking the sheet is larger than the sheet conveying force of the first conveying belt 11 in the state of sucking the sheet, and the second conveying is more reliably performed. The sheet may be conveyed by being pulled by the belt 21 so that the sheet slides on the first conveying belt 11.

  By the way, the aperture ratio of the 1st conveyance belt 11 and the 2nd conveyance belt 21 is adjusted as mentioned above. Alternatively, the friction coefficient of the first conveyance belt 11 is set to be smaller than the friction coefficient of the second conveyance belt 21. With this configuration, the fixing speed is higher than the transfer speed, which is advantageous when a small-size sheet is conveyed. At an early stage in a transient state (see FIG. 9C) in which the sheet is conveyed across the first conveyance belt 11 and the second conveyance belt 21, the sheet speed depends on the high-speed second conveyance belt 21. It becomes like this. Therefore, the sheet from the transfer nip N2 reaches the fixing nip N earlier. Note that when a small-size sheet is conveyed in a mode in which the fixing speed is higher than the transfer speed, the sheet conveying force of the first conveying belt 11 is reduced by reducing the suction by the first suction fan 15 of the first belt conveying unit 10. It may be controlled so as to be small. Even with this control, the sheet speed depends on the high-speed second conveying belt 21 at an earlier time in the transient state (see FIG. 9C).

  In the above-described embodiment, in the large size conveyance control, the timing at which the second belt conveyance unit 20 conveyance speed is changed from the first speed (transfer speed) to the second speed (fixing speed VF) The controller 170 determines whether the leading edge is detected by the sheet leading edge detection sensor 26. However, the timing at which the conveyance speed of the second belt conveyance unit 20 is increased from the first speed to the second speed may be any time after the trailing edge of the conveyed sheet has passed through the secondary transfer nip N2. It is not restricted to such a structure. For example, a sensor for detecting a sheet is provided in the vicinity of the registration roller 115. Then, the timer 666 measures whether or not the time required for the trailing edge of the sheet to reach the secondary transfer nip N2 after receiving the signal from the sensor. In this way, the control unit 170 may determine that the trailing edge of the sheet has passed through the secondary transfer nip N2. In addition, a sensor is provided between the transfer nip N2 and the first conveyance belt 11 to detect that the trailing edge of the sheet has passed through the transfer nip N2, and based on a signal from the sensor, the second belt conveyance unit 20 The conveyance speed may be changed.

  The first embodiment described above has the following effects.

  (1) The fixing speed VF is changed according to the type and basis weight of the sheet S. For this reason, the fixing unit can give an appropriate amount of heat to the sheet according to the basis weight and type of the sheet while keeping the temperature of the fixing unit at a constant temperature control temperature.

  (2) The first belt conveyance unit 10 and the second belt conveyance unit 20 arranged in the conveyance direction are provided between the secondary transfer nip N2 and the fixing nip N. The conveyance speed V1 of the first belt conveyance unit 10 is set to a first speed for receiving the sheet traveling from the transfer nip N2. The conveyance speed V2 of the second belt conveyance unit 20 is variable between a first speed and a second speed at which the leading end of the sheet faster than the first speed enters the fixing nip N. Therefore, the sheet S can be smoothly conveyed from the secondary transfer nip N2 to the fixing nip N. Since the conveyance speed of the sheet S is switched between the secondary transfer nip N2 and the fixing nip N, the transfer speed VT can be kept constant regardless of the setting value of the fixing speed VF.

  (3) Even in the case where the fixing speed VF is higher than the transfer speed and the large size is transported, the sheet can be transported stably with high productivity using a transport belt having a short length in the transport direction.

  That is, the sheet is moved at a high second speed while sliding on the first conveyance belt 11 whose peripheral speed is the first speed by the second conveyance belt 21 set at the second speed at which the leading edge of the sheet enters the fixing nip. In this state, the leading edge of the sheet reaches the fixing nip N. Therefore, the sheet speed is increased while the second transport belt 21 is downsized so that the length of the transport path from the downstream end of the first transport belt 11 to the fixing nip N is smaller than the length of the transported sheet. Can be made. Then, the second conveying belt 21 is reduced in size and the sheet speed is changed to a high second speed before the trailing end of the sheet leaves the first conveying belt 11, so that the second transfer belt N 21 can be used. The traveling sheet reaches the fixing nip N quickly. Therefore, the length between the secondary transfer nip N2 and the fixing nip N can be reduced, the image forming apparatus can be downsized, and the productivity is high.

  Further, the preceding sheet straddling the first conveying belt 11 and the second conveying belt 21 is conveyed from the secondary transfer nip N2 while being conveyed at the second speed (fixing speed) by the second conveying belt 21. The sheet can be received by the first conveyor belt 11 that rotates at the first speed. Therefore, the productivity is high because the distance between the continuously conveyed sheets is narrow while the transfer of the toner image is satisfactorily performed.

  Further, in order to reduce the length of the conveyance path from the transfer nip N2 to the upstream end of the second conveyance belt 21 and realize downsizing of the image forming apparatus, in the case of a large size sheet, the trailing edge of the sheet Until the toner passes through the transfer nip N2, the peripheral speed of the second conveyor belt 21 is set to the first speed, and then the peripheral speed of the second conveyor belt 21 is increased. In this way, the length of the conveyance path from the transfer nip N2 to the upstream end of the second conveyance belt 21 is reduced, and the sheet is further advanced at a timing earlier than the trailing end of the sheet is detached from the downstream end of the first conveyance belt 11. Is changed to a high speed, the time required for the sheet to reach the fixing nip N from the transfer nip N2 is short.

  As described above, the length between the secondary transfer nip N2 and the fixing nip N is small, and when the fixing speed VF is higher than the transfer speed VT, the sheet can be smoothly conveyed with high productivity. It becomes possible.

  (4) In the case of a small size sheet shorter than the length from the transfer nip N2 to the upstream end of the second conveying belt 21 and shorter than the length from the downstream end of the first conveying belt 12 to the fixing nip N, the fixing speed is Even in a mode faster than the transfer speed, the following control is performed. That is, the sheet is conveyed without changing the peripheral speed or suction state of the first and second conveying belts during conveyance of the sheet. Therefore, in this case, without requiring complicated control in the sheet conveyance process, the sheet speed is changed to a higher speed at an earlier timing, and the productivity is high.

  (5) The distance between the secondary transfer nip N2 and the fixing nip N is longer than the length of the maximum size sheet that can be conveyed. Therefore, the sheet S1 carrying the unfixed toner image reaches the fixing nip N after the trailing end of the sheet S1 passes through the secondary transfer nip N2 as shown in FIG. 9B, for example. . Therefore, even if a shock is generated when the thick paper enters the fixing nip N, the trailing edge of the sheet S1 passes through the secondary transfer nip N2, so that image defects can be suppressed.

(Second Embodiment)
In the first embodiment, the conveyance speed of the second belt conveyance unit 20 is changed during sheet conveyance in the large size conveyance control, and the first suction fan 15 and the second suction are performed during sheet conveyance in the large size conveyance control. The suction operation of the fan 25 is not changed. In the second embodiment described below, in the large size conveyance control, the first belt conveyance unit 10 and the second belt conveyance unit 20 do not change the conveyance speed of the second belt conveyance unit 20 during conveyance of the sheet. This is different from the first embodiment in that the suction operation is changed. Detailed description of the same configuration of the first embodiment will be omitted, and differences from the first embodiment will be described in detail.

  FIG. 11 is an enlarged view from the secondary transfer unit 131 to the fixing unit 50 in the image forming apparatus of the second embodiment. As shown in FIG. 11, an upstream sheet leading edge detection sensor 16 that detects the leading edge of the sheet at the upstream detection position P <b> 1 is provided on the fixing unit 50 side of the first conveyance belt 11.

  Next, a configuration for sucking a sheet onto the conveyance belt in the first and second belt conveyance units 10 and 20 will be described in detail with reference to FIGS. 12 and 13. Since the configurations of the first belt conveyance unit 10 and the second belt conveyance unit 20 are the same, only the second belt conveyance unit 20 will be described here, and a detailed description of the first belt conveyance unit 10 will be omitted.

  FIG. 13 is a perspective view of the second belt conveyance unit 20 in a state in which the drawing of the second conveyance belt 21 is omitted for easy understanding of the configuration. A frame 951 including the second suction fan 25 is provided inside the second transport belt 21. A pair of suction ports 25 a is formed on the upper surface of the frame 951. A pair of second shutters 27 are held by a frame 951 so as to be slidable between the second conveyor belt 21 and the second suction fan 25. The second shutter 27 has a position where the suction port 25a is opened (see FIGS. 12A and 13A) and a position where the suction port 25a is closed (see FIGS. 12B and 13B). )) Is held by a frame 951 so as to be slidable.

  That is, by sliding the second shutter 27 that constitutes the second suction device together with the second suction fan 25 and the frame 951, the suction state of the sheet with respect to the second transport belt 21 can be changed in the second belt transport unit 20. It is like that. In the following, the position of the second shutter 27 when the suction port 25a is opened (see FIGS. 12A and 13A) is referred to as an open position, and the second shutter 27 closes the suction port 25a. The position (see FIGS. 12B and 13B) is called a closed position. When the second shutter 27 is in the open position shown in FIGS. 12A and 13A, the sheet is sucked to the second conveying belt 21, and the second shutter 27 is connected to the second shutter 27 in FIG. When the sheet is in the closed position shown in FIG. 13B or FIG. 13B, the sheet is not sucked by the second conveyor belt 21.

  Each second shutter 27 is provided with a rack gear. By transmitting the driving force from the second shutter drive motor 30 to the second shutter 27 via the pinion gear 28 that meshes with the rack gear, the second shutter 27 is slid in the sheet width direction, and the second suction fan 25 is moved. The suction port 25a is opened and closed.

  Each second shutter 27 is provided with a flag 27b. When the second shutter 27 is moved to the open position as shown in FIGS. 12A and 13A, the following is performed. That is, the second shutter drive motor 30 is driven, and the second shutter drive motor 30 is driven when the flag 28b blocks the optical axis of the second shutter detection sensor 29 and the signal from the second shutter detection sensor 29 changes from OFF to ON. 30 is stopped. Conversely, when the second shutter 27 is moved to the closed position as shown in FIGS. 12B and 13B, the second shutter drive motor 30 is rotated reversely by a predetermined number of pulses.

  The first belt conveyance unit 10 and the second belt conveyance unit 20 are the same for the shutter and the mechanism for moving the shutter. That is, a first shutter that constitutes a first suction device together with the first suction fan 15 is provided inside the first transport belt 11 and between the first suction fan 15 and the first transport belt 11. . The first shutter is slid by a first shutter drive motor.

  As shown in FIG. 14, in the second embodiment, signals from the upstream side leading edge detection sensor 16 and the sheet leading edge detection sensor 26 are input to the control unit 1170. The controller 1170 controls the operations of the first and second transport belt drive motors 14 and 24 and the heating roller drive motor 54. Signals from the first shutter detection sensor 19 and the second shutter detection sensor 29 are input to the control unit 1170. The control unit 1170 operates the first and second shutter drive motors 31 and 30 based on the signals from the first shutter detection sensor 19 and the second shutter detection sensor 29 to set the shutter between the closed position and the open position. Control to move between. That is, the control unit 1170 includes the first suction device including the first suction fan 15, the first shutter drive motor 31, and the first shutter 17, the second suction fan 25, the second shutter drive motor 30, the second shutter 27, and the like. The suction operation of the suction means constituted by the second suction device including the is controlled.

  Further, the control unit 1170 controls the second speed, which is the transport speed of the second belt transport unit 20, to change within the range of 300 to 480 mm / sec in response to the speed adjustment of the fixing speed VF. The change in the conveyance speed of the second belt conveyance unit 20 is performed by the control unit 1170 controlling the second conveyance belt drive motor 24.

  Hereinafter, the sheet conveyance operation and control from the secondary transfer nip N2 to the fixing unit 50 will be described with reference to the flowcharts of FIGS. 15 and 16 and the operation explanatory diagrams of FIGS. 17 and 18 illustrating the sheet conveyance state. Detailed description.

  The control unit 1170 determines which mode in FIG. 4 from the type and basis weight of the information regarding the sheet input from the operation unit or the like. That is, the control unit 170 refers to the table of FIG. 4 to determine whether or not the transfer speed and the fixing speed are the same mode (mode 4) (step 101 (hereinafter step is abbreviated as S)). .

  If it is a mode other than mode 4 (a mode in which the fixing speed is faster than the transfer speed) (NO in S101), whether or not the sheet size is a small size is controlled from the size information among the information regarding the sheet type. The unit 1170 determines (S102). In this embodiment, the length of the conveyed sheet in the conveyance direction is shorter than the length from the secondary transfer nip N2 to the upstream end of the second conveyance belt 25 and from the downstream end of the first conveyance belt 15 to the fixing nip N. When it is shorter than the length, it is determined that it is a small size. If it is not the small size, the control unit 1170 executes the large size conveyance control shown in FIG. FIGS. 17 and 18 show, in a time series, the sheet conveyance operation when control is performed in a mode in which the fixing speed is faster than the transfer speed and the sheet size is large (hereinafter, large size conveyance control). It is explanatory drawing shown.

  In the large size conveyance control shown in FIG. 16, the controller 1170 controls the heating roller drive motor 54 so as to achieve the fixing speed VF shown in FIG. 4 according to the type and basis weight of the sheet (S121). In addition, the control unit 1170 sets the first belt conveyance unit 10 so that the conveyance speed of the first belt conveyance unit 10 is 300 mm / sec, which is the same as the transfer speed, as the first velocity for receiving and conveying the sheet traveling from the transfer nip N2. The one conveyor belt drive motor 14 is controlled (S121). The controller 170 controls the second conveyor belt drive motor so that the conveyance speed of the second belt conveyance unit 20 is the same as the fixing speed VF as the second speed when the leading edge of the sheet enters the fixing nip N. 24 is controlled (S121). Then, the control unit 1170 controls (ON) the first belt conveyance unit 10 so that the sheet is sucked to the first conveyance belt 11. Specifically, the control unit 1170 controls the operation of the first shutter drive motor 31 so that the first suction fan 15 moves the first shutter 17 to the open position so that the first conveying belt 11 sucks the sheet. On the other hand, the control unit 1170 performs control so that the sheet is not attracted to the second conveyance belt 21 in the second belt conveyance unit 20 (OFF). That is, the controller 1170 controls the operation of the second shutter drive motor 30 so as to move the second shutter 27 to the closed position so that the second suction fan 25 does not suck the sheet to the second transport belt 21 (S121). ).

  Here, the first speed of the first belt transport unit 10 when receiving and transporting the sheet traveling from the transfer nip N2 is exemplified here as the same speed as the transfer speed. The first speed of the one-belt transport unit 10 may be a speed at which the sheet traveling from the transfer nip N2 can be smoothly transported with little influence on the transfer of the toner image, and does not necessarily match the transfer speed. This is not necessary as in the first embodiment described above.

  In addition, the second speed of the second belt conveying unit 20 when the leading edge of the sheet enters the fixing nip N is exemplified here as being equal to the fixing speed VF. However, the second speed of the second belt conveyance unit 20 may be a speed that can be conveyed so that the toner image is well fixed when the leading edge of the sheet enters the fixing nip N. The fixing speed It is the same as in the first embodiment described above that does not necessarily coincide with VF.

  In the operation state set in S121, the sheet sent out from the secondary transfer nip N2 is conveyed by the first belt conveyance unit 10. At this time, the peripheral speed of the first transport belt 11 (the transport speed of the first belt transport unit 10) is the first speed when the sheet traveling from the transfer nip N2 is received and transported (in this embodiment, the transfer speed). Since the speed is set to the same speed as 300 mm / sec) and the suction to the first transport belt 11 is performed, the sheet is smoothly transported (see FIG. 17A).

  Eventually, the first belt conveyance unit 10 sends the sheet to the second belt conveyance unit 20, and the leading end side of the sheet reaches the second belt conveyance unit 20 (see FIG. 17B). Here, the sheet is not sucked onto the second conveyance belt 21. Therefore, the conveyance force of the first conveyance belt 11 of the first belt conveyance unit 10 in which the suction operation is performed is larger than the conveyance force of the second conveyance belt 21 of the second belt conveyance unit 20. Therefore, the leading end side of the sheet straddling the first conveying belt 11 and the second conveying belt 21, and the peripheral surface of the second conveying belt 21 whose peripheral speed is set to a second speed higher than the transfer speed. Slips, and the sheet itself is conveyed at a first speed that is the peripheral speed of the first conveyor belt 11. In this way, although the leading edge side of the sheet on which the toner image is being transferred in the secondary transfer nip N2 is in contact with the second conveying belt 21 that is at the second speed higher than the first speed, The sheet is conveyed at the first speed by the first conveying belt 11. Therefore, the transfer of the toner image at the secondary transfer nip N2 is favorably performed. By controlling the operation of the suction means, the conveyance force of the second belt conveyance unit 20 is made smaller than the conveyance force of the first belt conveyance unit 10, and the first conveyance belt 21 and the sheet are slid. Hereinafter, the state of conveyance at the peripheral speed of the conveyance belt 11 is referred to as a first suction state.

  Thereafter, the control unit 1170 determines whether the leading edge of the sheet conveyed by the first belt conveying unit 10 and the second belt conveying unit 20 is detected by the sheet leading edge detection sensor 26 at the detection position P (S122). When the leading edge of the sheet conveyed by the first belt conveying unit 10 and the second belt conveying unit 20 is detected by the sheet leading edge detection sensor 26 (YES in S122), the process proceeds to S123. In S123, the control unit 1170 controls the operation of the first shutter drive motor 31 to move the first shutter 17 to the closed position so that the sheet is not attracted to the first conveyance belt 11. Further, the control unit 1170 controls the operation of the second shutter drive motor 30 so that the sheet is attracted to the second conveyance belt 21 and moves the second shutter 27 to the open position.

  In this state, the sheet is not sucked to the first transport belt 11 and the sheet is sucked to the second transport belt 21 (second suction state). Therefore, the conveyance force of the second conveyance belt 21 of the second belt conveyance unit 20 in which the suction operation is performed is larger than the conveyance force of the first conveyance belt 11 of the first belt conveyance unit 10. In FIG. 17C, the leading edge of the sheet conveyed by the first belt conveying unit 10 and the second belt conveying unit 20 reaches the second sheet leading edge detection sensor 26, and the change of the operation state of the sheet suction is completed. Shows the state.

  Here, the detection position P is set such that when the leading edge of the sheet reaches the detection position P, the trailing edge of the sheet has already passed through the secondary transfer nip N2. Therefore, when the sheet suction operation state is changed from the first suction state to the second suction state, the trailing edge of the sheet has already passed through the secondary transfer nip N2. Therefore, there is no influence on the transfer of the toner image onto the sheet caused by changing the suction state to the second suction state. The detection position P is a position where the first shutter 17 can be moved to the closed position and the second shutter 27 can be moved to the open position until the leading edge of the sheet S1 reaches the fixing nip N of the fixing unit 50. Is set.

  Here, when the sheet is not sucked to the first transport belt 11 and the sheet is sucked to the second transport belt 21, the sheet is transported as follows. That is, the transport force of the second transport belt 11 that is performing the suction operation is greater than the transport force of the first transport belt 11 that is not performing the suction operation. Therefore, the sheet on the first conveyor belt 11 and the second conveyor belt 21 is second by the second conveyor belt 21 whose peripheral speed is set to a second speed higher than the peripheral speed of the first conveyor belt 11. While being pulled by the conveying belt 21 and sliding on the outer periphery of the first conveying belt 11, the sheet is conveyed at a second speed (the fixing speed VF in this embodiment) when the leading edge of the sheet enters the fixing nip N. Then, the sheet reaches the fixing nip N at the second speed while being pulled by the second conveying belt 21 and sliding on the outer periphery of the first conveying belt 11.

  Thus, when the leading edge of the sheet S1 being conveyed by the second conveying belt 21 reaches the fixing nip N, the sheet is second when the leading edge of the sheet enters the fixing nip N by the second conveying belt 21. Transported at speed. If the sheet speed and the fixing speed at the fixing nip N are greatly different when the leading edge of the sheet enters the fixing nip N, a fixing failure occurs. The sheet pulled while being slid on the first conveyor belt 11 by the second conveyor belt 21 is conveyed at the second speed (fixing speed VF) when the leading edge of the sheet enters the fixing nip N. Thus, no trouble occurs when the toner image is fixed.

  Next, the control unit 1170 determines whether or not the leading edge of the sheet has reached the fixing nip N (S24). After the leading edge of the sheet reaches the fixing nip N (YES in S124), the control unit 1170 controls the operation of the first shutter drive motor 31 so that the sheet is attracted to the first conveyance belt 11, and the first shutter drive motor 31 is controlled. 1 The shutter 17 is moved to the open position (S125). In this embodiment, the control unit 1170 determines whether the leading edge of the sheet has reached the fixing nip N as follows. That is, the control unit 1170 receives a signal indicating that the leading edge of the sheet has been detected from the sheet leading edge detection sensor 26. The control unit 170 measures, with the timer 666, whether a predetermined time required for the leading edge of the sheet to reach the fixing nip N has elapsed after receiving the signal from the sheet leading edge detection sensor 26. In this way, the control unit 1170 determines whether or not the leading edge of the sheet has reached the fixing nip N.

  After the leading edge of the sheet is nipped by the fixing nip N, the sheet nipped by the fixing nip N is sucked by the first conveying belt 11 rotating at a first speed lower than the fixing speed (see FIG. 18 (a)). However, since the clamping pressure at the fixing nip N is high, the conveyance force of the fixing unit 50 is stronger than the conveyance force of the first conveyance belt 11. Therefore, even if a back tension is temporarily applied to the fixing nip N by the first conveying belt 11 rotating at the first speed lower than the fixing speed VF, the fixing unit 50 stably conveys the sheet at the fixing speed VF. Therefore, fixing failure does not occur.

  In addition, after the leading edge of the sheet is nipped by the fixing nip N and the rear side of the sheet is on the first conveying belt 11, the sheet is sucked to the first conveying belt 11 as follows. There are additional reasons. That is, the leading edge of the succeeding sheet S2 can reach the first conveying belt 11 while the preceding sheet S1 is being conveyed by the fixing nip N (see FIG. 18A). . That is, the succeeding sheet S2 held in the secondary transfer nip N2 is set to the first speed when the sheet is sucked and the sheet traveling from the transfer nip N2 is received and conveyed. Since it is transported by the first transport belt 11, the succeeding sheet S2 can be transported stably and no transfer failure occurs. Accordingly, the interval between successive sheets can be shortened and conveyed, so that an image forming apparatus with high productivity can be provided.

  Next, the control unit 1170 determines whether or not the leading edge of the succeeding sheet S2 has reached the upstream detection position P1 based on a signal from the upstream sheet leading edge detection sensor 16 (S126). When the leading edge of the succeeding sheet S2 reaches the upstream side detection position P1 (YES in S126), the control unit 1170 moves the second shutter 27 to the closed position in order to prevent the sheet from being sucked by the second conveyance belt 21. Then, the operation of the second shutter drive motor 30 is controlled (S127).

  In this way, after the leading edge of the preceding sheet is nipped by the fixing nip N and the part of the sheet is on the second conveying belt 21, the sheet is not sucked by the second conveying belt 21. (First suction state). This is because after the leading edge of the sheet is nipped by the fixing nip N, the auxiliary conveyance is sufficient for the function required for the second conveyance belt 21. That is, the clamping pressure at the fixing nip N is high, and the sheet is conveyed by the fixing nip N at the fixing speed VF, so that no fixing defect occurs.

  In order to control the second conveyance belt 21 so that the sheet is not sucked in the state where the rear side of the sheet nipped in the fixing nip N is on the second conveyance belt 21, the following is performed. There is a reason. This is because the leading edge of the succeeding sheet S2 can reach the second conveying belt 21 when the preceding sheet S1 is being conveyed by the fixing nip N. Accordingly, the interval between successive sheets can be shortened and conveyed, so that an image forming apparatus with high productivity can be provided. That is, since the trailing edge of the succeeding sheet S2 is in the secondary transfer nip N2 and the leading edge of the succeeding sheet S2 is placed on the second conveying belt 21, the sheet is not sucked to the second conveying belt 21. Since the succeeding sheet S2 can be stably conveyed at the first speed by the first conveyance belt 11, the occurrence of transfer failure is prevented.

  Thereafter, the control unit 1170 determines whether or not the job has ended (S128). If the job has not ended, the process returns to S122. If the job has ended, the process returns to S103 in FIG. 15 and ends.

  As described above, it is possible to provide a device in which the length of the first transport belt 11 and the second transport belt 21 in the transport direction is reduced to reduce the size of the device. Even when the fixing speed VF is higher than the transfer speed VT, the sheet is stably conveyed by changing the suction state of the sheet to the first conveying belt 11 and the second conveying belt 21 and conveying the sheet. Transport is realized. Further, by changing the suction state of the sheet to the first conveyance belt 11 and the second conveyance belt 21, the distance between the trailing edge of the preceding sheet S1 and the trailing sheet S2 is reduced, and the sheet is conveyed. It becomes possible.

  If it is determined in S101 of FIG. 15 that the mode is 4, that is, if the control unit 1170 determines that the fixing speed is the same as the transfer speed, the process proceeds to S104. In step S <b> 104, the control unit 1170 controls the first and second shutter drive motors 30 and 31 so that the sheet suction operation is performed in the first belt conveyance unit 10 and the second belt conveyance unit 20. Further, the control unit 1170 controls the first conveyance belt drive motor 14 so that the conveyance speed of the first belt conveyance unit 10 becomes the first speed (in this embodiment, 300 mm / sec, which is equivalent to the transfer speed). To do. The control unit 1170 controls the second conveyance belt drive motor 24 so that the conveyance speed of the second belt conveyance unit 20 becomes the first speed (in this embodiment, 300 mm / sec equivalent to the transfer speed). In this state, the sheet is continuously conveyed. Since the transport state at this time is the same as the state in FIG. 10 in the first embodiment described above, description thereof is omitted.

  In S101 of FIG. 15, when the mode is not mode 4 (when the fixing speed is faster than the transfer speed) and the sheet size is a small size (YES in S102), the process proceeds to S105. In step S105, the control unit 1170 controls the first and second shutter drive motors 30 and 31 so that the sheet suction operation is performed in the first belt conveyance unit 10 and the second belt conveyance unit 20. Further, the control unit 1170 controls the first conveyance belt drive motor 14 so that the conveyance speed of the first belt conveyance unit 10 becomes the first speed (300 mm / sec equivalent to the transfer speed). Further, the control unit 1170 controls the second transport belt drive motor 24 so that the transport speed of the second belt transport unit 20 becomes the second speed (a speed equivalent to the fixing speed VF). In this state, continuous sheets are conveyed. The transport state at this time is the same as the state described with reference to FIG. 9 in the first embodiment described above, and a description thereof will be omitted.

  In the above-described embodiment, in the first belt conveyance unit 10, the first shutter 17 in the closed position almost completely covers the opening between the first suction fan 15 and the first conveyance belt 11. The second shutter 27 in the closed position covers the opening almost completely. However, in the large-size conveyance control, during the transfer of the toner image to the sheet, the conveyance force of the first conveyance belt 11 is larger than the conveyance force of the second conveyance belt 21, and the sheet and the second conveyance belt 21 The first suction device and the second suction device only need to operate so as to slide. Further, when the transfer of the toner image onto the sheet is completed and the sheet enters the fixing nip N, the conveyance force of the second conveyance belt 21 becomes large and the conveyance force of the first conveyance belt 11 increases. The first suction device and the second suction device may be operated so that the belt 11 and the sheet slide. Therefore, for example, the first shutter 17 does not completely cover the opening at the closed position, but covers the majority of the opening, and in the second belt conveying device 20, the second shutter 27 does not completely cover the opening at the closed position. You may make it cover the majority.

  Further, in the second embodiment, the mode in which the suction state of the sheet is changed using the shutter in the first belt conveyance unit 10 and the second belt conveyance unit 20 is exemplified. However, the first belt conveyance unit 10 and the second belt conveyance unit 20 may be configured to change the suction state of the sheet by controlling the rotation of the first suction fan 15 and the second suction fan. For example, in the large-size conveyance control, during the transfer of the toner image to the sheet, the first suction fan 15 is rotated at the maximum speed and the rotation of the second suction fan 25 is stopped (or at the maximum half speed). Rotate). When the toner image is finished on the sheet and the sheet enters the fixing nip N, the second suction fan 15 is rotated at the maximum speed and the rotation of the first suction fan 25 is stopped or the half speed of the maximum speed is rotated. Let

  In the large size conveyance control, whether the leading edge of the sheet is detected by the sheet leading edge detection sensor 26 when the first belt conveying unit 10 and the second belt conveying unit 20 are switched from the first suction state to the second suction state. Thus, the control unit 1170 determines. However, the timing of switching to the second suction state is not limited to the above-described configuration, as long as it is after the trailing edge of the conveyed sheet has passed through the secondary transfer nip N2. For example, a sensor for detecting a sheet is provided in the vicinity of the registration roller 115. Then, a timer 666 measures whether or not the time required for the trailing edge of the sheet to pass through the secondary transfer nip N2 has elapsed since the signal from the sensor was received. In this way, the control unit 1170 may determine that the trailing edge of the sheet has passed the secondary transfer nip N2. In addition, a sensor is provided between the transfer nip N2 and the first conveyance belt 11 to detect that the trailing edge of the sheet has passed through the transfer nip N2, and the suction state is changed to the first suction state based on the signal from the sensor. May be changed to the second suction state.

  Similarly, in the large-size conveyance control, an example is shown in which the suction operation in the second belt conveyance unit 20 is eliminated and the first suction state is returned at the timing when the leading edge of the subsequent sheet is detected by the upstream sheet leading edge detection sensor 16. However, it is not limited to this. The timing at which the suction state of the first belt conveyance unit 10 and the second belt conveyance unit 20 is returned to the first suction state may be earlier than the time when the subsequent sheet S2 reaches the second conveyance belt 21. For example, a sensor for detecting a sheet is provided in the vicinity of the registration roller 115, and the suction operation in the second belt conveyance unit 20 is eliminated at an earlier timing before reaching the second conveyance belt 21 based on a signal from the sensor. The suction state may be returned to the first suction state.

  The second embodiment described above has the following effects.

  (1) The fixing speed VF is changed according to the type and basis weight of the sheet S. The fixing unit can give an appropriate amount of heat to the sheet according to the sheet type while keeping the temperature of the fixing unit at a constant temperature control temperature.

  (2) The first belt conveyance unit 10 and the second belt conveyance unit 20 arranged in the conveyance direction are provided between the secondary transfer nip N2 and the fixing nip N. Then, the conveyance speed V1 of the first belt conveyance unit 10 is set to the first speed for receiving the sheet traveling from the transfer nip N2. On the other hand, the conveyance speed V2 of the second belt conveyance unit 20 is changed according to the fixing speed VF. Therefore, the sheet can be conveyed while keeping the transfer speed VT constant irrespective of the set value of the fixing speed VF that is changed according to the type of the sheet and the basis weight.

  (3) Even in the case where the fixing speed VF is higher than the transfer speed and the large size is transported, the sheet can be transported stably with high productivity using a transport belt having a short length in the transport direction.

  That is, when the sheet on which the toner image is transferred in the secondary transfer nip N2, the conveyance force of the first conveyance belt 11 is larger than the conveyance force of the second conveyance belt 21, and the sheet and the second conveyance are conveyed. The belt 21 slides. (First suction state). Therefore, since the sheet S on which the toner image is being transferred, which is in a state straddling the first conveyance belt 11 and the second conveyance belt 21, can be conveyed at the first speed, the sheet of the toner image Transfer to is carried out satisfactorily.

  Then, after the trailing edge of the sheet passes through the secondary transfer nip N2, the conveying force of the second conveying belt 21 is larger than the conveying force of the first conveying belt 11, and the sheet and the first conveying belt 11 slip. (Second suction state). Therefore, the conveyance speed of the sheet that has been transferred from the toner image and is in a state straddling the first conveyance belt 11 and the second conveyance belt 21 can be set to the second speed. Then, the leading edge of the sheet straddling the first conveying belt 11 and the second conveying belt 21 can reach the fixing nip N while being conveyed at the second speed.

  As described above, the length from the transfer nip N2 to the upstream end of the second conveyance belt 21 and the length of the conveyance path from the downstream end of the first conveyance belt 11 to the fixing nip N are made smaller than the maximum sheet length. The equipment can be downsized. Even in such a small apparatus configuration, the sheet can be conveyed at the first speed during the transfer of the toner image, and the sheet can be stably conveyed at the second high speed after the transfer.

  Further, after the leading edge of the preceding sheet reaches the fixing nip N, the first suction is performed so that the sheet is attracted to the first conveying belt 11 while the rear side of the sheet is still on the first conveying belt 11. The operation of the apparatus is controlled (see FIG. 18A). With this control, even when the rear side of the preceding sheet being conveyed at the fixing nip N is on the first conveyance belt 11, the subsequent sheet sent from the secondary transfer nip N 2 is transferred to the first conveyance belt 11 by the first conveyance belt 11. It can be transported stably at a speed. Accordingly, while the transfer of the toner image to the succeeding sheet is performed satisfactorily, the interval between the continuously conveyed sheets is narrowed, and the productivity can be improved.

  Further, after the leading edge of the preceding sheet reaches the fixing nip N, the rear side of the preceding sheet is still on the second conveying belt 21 and before the succeeding sheet S2 reaches the second conveying belt 21. The suction state is controlled to be changed to the first state (see FIG. 18B). That is, the respective suction states are changed so that the conveyance force of the first belt conveyance unit 10 is larger than the conveyance force of the second belt conveyance unit 20. With this control, the succeeding sheet fed from the secondary transfer nip N2 is straddled across the first transport belt 11 and the second transport belt 21 even when the rear side of the preceding sheet is on the second transport belt 21. In the state, it can be stably conveyed at the first speed. Accordingly, while the transfer of the toner image to the succeeding sheet is performed satisfactorily, the interval between the continuously conveyed sheets is narrowed, and the productivity can be improved.

  As described above, the image forming apparatus according to the present exemplary embodiment is a small apparatus, and even when the fixing speed VF is higher than the transfer speed VT, the distance between the trailing edge of the preceding sheet and the leading edge of the succeeding sheet. It is possible to smoothly convey the sheet in a small state.

  (4) When the sheet after the transfer of the toner image is transported across the first transport belt 11 and the second transport belt 21, the rear end side of the sheet and the first transport belt 11 are slid. 2 The sheet is conveyed at a speed higher than the transfer speed while the sheet is pulled by the conveying belt. Therefore, the sheet speed is changed to a higher speed at a timing earlier than the trailing end of the sheet is released from the downstream end of the first conveying belt 11. Therefore, the time required for the sheet traveling from the transfer nip N2 to reach the fixing nip N is short, and the productivity is high.

  (5) The distance between the secondary transfer nip N2 and the fixing nip N is longer than the length of the maximum size sheet that can be conveyed. Therefore, the sheet S1 carrying the unfixed toner image reaches the fixing nip N after the trailing edge of the sheet S1 passes through the secondary transfer nip N2, as shown in FIG. 10B, for example. . Therefore, even if a shock is generated when the thick paper enters the fixing nip N, the trailing edge of the sheet S1 passes through the secondary transfer nip N2, so that image defects can be suppressed.

  (6) Further, in the embodiment in which the suction by the suction fan 15 of the first belt conveyance unit 10 is performed to open and close the shutter 17, and the shutter 27 is used in the second belt conveyance device 20, the following effects are further obtained. That is, the suction state by the suction fan can be changed with good responsiveness.

  Further, in the embodiment in which the suction state of the sheet to the first and second transport belts 11 and 21 is changed by controlling the rotation operation of the first and second suction fans without using the shutters 17 and 27, the suction state is changed. Since there is no need to add a separate device for the change, the cost is low.

  In the first and second embodiments described above, an image forming apparatus that forms a full-color toner image on a sheet has been described as an example, but the present invention can also be applied to an image forming apparatus that forms a monochrome image.

N2 Secondary transfer nip 11 First transport belt 11
15 First suction fan 21 Second transport belt 25 Second suction fan 50 Fixing unit 170, 1170 Control unit

Claims (5)

A transfer nip for transferring a toner image to a sheet conveyed at a transfer speed;
A first conveying belt that conveys a sheet onto which a toner image has been transferred in the transfer nip;
A second conveyor belt that is provided downstream of the first conveyor belt in the sheet conveyance direction and conveys the sucked sheet;
A fixing nip provided downstream of the second conveying belt in the sheet conveying direction and fixing a toner image on the sheet while conveying the sheet;
An image forming apparatus having a high-speed fixing mode for fixing a toner image to a sheet while the fixing nip conveys the sheet at a speed higher than the transfer speed,
In the high-speed fixing mode, the peripheral speed of the first transport belt is set to a first speed for receiving the sheet traveling from the transfer nip, the peripheral speed of the second transport belt is set, and the leading end of the sheet enters the fixing nip. The sheet is conveyed from the transfer nip to the fixing nip with the second speed being higher than the first speed, and the sheet straddling the first conveyance belt and the second conveyance belt is An image forming apparatus, wherein the image forming apparatus is pulled by the second conveying belt so as to slide on the first conveying belt and is conveyed at a speed higher than the first speed.   In the high-speed fixing mode, when a sheet having a length in the transport direction longer than the length from the transfer nip to the upstream end of the second transport belt is transported, the sheet passes through the transfer nip and the second The second conveying belt is set so that the peripheral speed of the conveying belt is set to the first speed, the trailing edge of the sheet leaves the transfer nip, and the leading edge of the sheet reaches the fixing nip. 2. The image forming apparatus according to claim 1, wherein the peripheral speed is changed from the first speed to the second speed. A suction means for sucking a sheet to each of the first transport belt and the second transport belt;
A control unit for controlling the suction operation of the suction means,
In the high-speed fixing mode, when a sheet having a length in the transport direction longer than the length from the transfer nip to the upstream end of the second transport belt is transported, the sheet is passing through the transfer nip and the first A sheet suction operation to the transport belt is performed and the sheet suction operation to the second transport belt is not performed, and the rear end of the sheet is removed from the transfer nip and the front end of the sheet is The controller controls the suction operation of the suction unit so that the sheet suction operation to the second transport belt is not performed before the fixing nip is reached, without performing the sheet suction operation to the first transport belt. The image forming apparatus according to claim 1.   When a sheet having a length in the conveying direction longer than the length from the downstream end of the first conveying belt to the fixing nip is conveyed, the sheet is pulled by the second conveying belt so as to slide on the first conveying belt. The image forming apparatus according to claim 1, wherein the leading edge of the sheet reaches the fixing nip while the sheet is conveyed. A suction means for sucking a sheet to each of the first transport belt and the second transport belt;
A friction coefficient of the peripheral surface of the second transport belt is configured to be larger than a friction coefficient of the peripheral surface of the first transport belt, and the second transport belt in which the sheet is sucked by the suction unit is provided. 5. The image forming apparatus according to claim 1, wherein the sheet is conveyed while being slid on the first conveying belt on which the sheet is sucked by the suction unit.

Images