JP6587665B2 - Image forming apparatus - Google Patents

Description

  The present invention relates to an image forming apparatus capable of forming images on both sides of a sheet.

  In order to form images on both sides of the sheet, the image forming apparatus includes an auxiliary conveyance path (sub-conveyance path) in addition to the main conveyance path (Patent Document 1). The sub-transport path is a transport path that branches off from the main transport path and joins the main transport path again, and is used to reverse the front and back of the sheet. The sheet on which the image is formed on the first surface is sent to the sub-conveying path where the traveling direction is reversed. As a result, the front and back sides of the sheet are switched, and the sheet is sent again to the image forming unit in the main conveyance path to form an image on the second surface.

JP 2002-12374 A

  In order to improve productivity when forming images on both sides of a large number of sheets, a plurality of sheets are continuously fed to form an image on the first side and an image is formed on the first side. Alternatively, image formation on the second surface of another sheet may be executed alternately. However, if the sub-conveyance path is lengthened to wait for a large number of sheets, the size of the image forming apparatus becomes large. It is also conceivable that the leading edge of the sheet conveyed from the main conveying path to the sub conveying path collides with the rear end of the sheet already waiting in the sub conveying path. Therefore, an object of the present invention is to reduce the length of the sub-transport path while avoiding contact between the preceding sheet and the succeeding sheet in an image forming apparatus capable of forming images on both sides of the sheet. .

The present invention is, for example,
A feeding means for feeding the sheet to the main conveyance path;
Changing the conveyance speed of the sheet fed from the feeding means from a first speed to a second speed, and conveying the sheet in the main conveyance path;
Image forming means for forming an image on the sheet conveyed at the second speed from the first conveying means;
After the image is formed by the image forming unit, the sheet conveyed from the main conveyance path is pulled in, and after the trailing edge of the sheet passes through a branch point between the main conveyance path and the sub conveyance path, the conveyance direction of the sheet Reversing means for reversing and feeding the sheet to the sub-transport path,
Second conveying means for conveying the sheet sent to the sub conveying path by the reversing means from the sub conveying path to the main conveying path again;
A driving source for driving the first conveying means and the second conveying means;
Control means for controlling the reversing means so that the first sheet fed into the sub conveying path by the reversing means is made to wait on the upstream side of the second conveying means in the sub conveying path;
When the waiting first sheet spans the branch point,
The control unit waits according to a timing at which the first transport unit completes a change in the transport speed of the second sheet following the first sheet from the first speed to the second speed. The first sheet is conveyed to the second conveying means by the reversing means, and the rear end of the first sheet is located downstream of the branch point before the second sheet reaches the branch point. An image forming apparatus that is moved is provided.

  According to the present invention, in an image forming apparatus capable of forming images on both sides of a sheet, it is possible to reduce the length of the sub-transport path while avoiding contact between the preceding sheet and the succeeding sheet. .

Schematic sectional view of the image forming apparatus Block diagram showing the control system The figure which shows the conveyance order of the sheet in duplex printing Conveyance path diagram showing a comparative example Diagram explaining sheet conveyance control Flow chart showing sheet conveyance control Timing chart showing sheet conveyance control Diagram showing the length of the sub-transport path Diagram showing the length of the sub-transport path Flow chart showing sheet conveyance control Timing chart showing sheet conveyance control Schematic sectional view of the image forming apparatus Block diagram showing the control system Diagram explaining sheet conveyance control Diagram explaining sheet conveyance control Flow chart showing sheet conveyance control Timing chart showing sheet conveyance control Timing chart showing sheet conveyance control Diagram showing the length of the sub-transport path

[Example 1]
Hereinafter, embodiments according to the present invention will be described in detail with reference to the drawings. However, the components described in this embodiment are merely examples, and the scope of the present invention is not intended to be limited only to them unless otherwise specified.

<Image forming apparatus>
FIG. 1 shows an electrophotographic image forming apparatus 100 for forming a multicolor image. Process stations (process cartridges) 5 </ b> Y, 5 </ b> M, 5 </ b> C, and 5 </ b> K are image forming units that can be attached to and detached from the image forming apparatus 100. The four process stations 5Y, 5M, 5C, and 5K have the same structure, but have different toner colors. YMCK given at the end of the reference symbol indicates the toner colors yellow, magenta, cyan, and black (K). Except for the case where a specific process station is described, the YMCK characters are omitted hereinafter. The toner container 23 is a container that holds toner. The photosensitive drum 1 is an image carrier that carries an electrostatic latent image or a toner image. The charging roller 2 uniformly charges the surface of the photosensitive drum 1. The exposure device 7 scans the surface of the photosensitive drum 1 with laser light corresponding to the input image data, and forms an electrostatic latent image corresponding to the image data on the surface of the photosensitive drum 1. The exposure device 7 is a narrowly defined image forming unit that forms an electrostatic latent image. Note that the timing at which the exposure device 7 starts forming an electrostatic latent image (image formation timing) is instructed by a controller described later. The developing roller 3 develops the electrostatic latent image by attaching the toner held in the toner container 23 to the electrostatic latent image, and forms a toner image. The primary transfer roller 6 transfers the toner image carried on the photosensitive drum 1 to the intermediate transfer belt 8. The intermediate transfer belt 8 is stretched between a driving roller 9 and a counter roller 10, and is rotated in the direction of arrow A by the driving roller 9. As the intermediate transfer belt 8 rotates, the opposing roller 10 is also driven to rotate.

  The paper feeding device 12 feeds the sheet P to the main transport path r1. The main conveyance path r1 is a conveyance path that extends from the paper feed cassette 13 to a reversal point 201 (also referred to as a branch point). The sheet feeding device 12 basically feeds the sheet so that the interval between the preceding sheet and the succeeding sheet is a constant interval. This is because the process station 5 forms the image transferred to the preceding sheet and the image transferred to the succeeding sheet on the intermediate transfer belt 8 at regular intervals. The paper feed roller 14 sends out the sheet P stored in the paper feed cassette 13 to the pair of transport rollers 15. The conveyance roller pair 15 sends the sheet P to the registration roller pair 16. The registration roller pair 16 is configured so that the timing at which the toner image conveyed by the intermediate transfer belt 8 arrives at the secondary transfer unit 80 coincides with the timing of the sheet P conveyed by the registration roller pair 16. Transport P.

  The secondary transfer roller 11 transfers the toner image carried on the intermediate transfer belt 8 to the sheet P. The secondary transfer roller 11 and the intermediate transfer belt 8 form a secondary transfer portion 80. Since the toner image is formed on the sheet P in the secondary transfer unit 80, the secondary transfer unit 80 is an image forming unit in a narrow sense. The sheet P sandwiched between the intermediate transfer belt 8 and the secondary transfer roller 11 is sent to the fixing device 17. The fixing device 17 includes a fixing roller 18 and a pressure roller 19 for pressing the fixing roller 18. The fixing roller 18 includes a fixing heater 30 and a temperature sensor 31 that measures the temperature of the fixing heater 30. The toner image is fixed on the sheet P by heating and pressurizing the sheet P. The sheet P on which image formation has been completed is guided by the flapper 55 to a paper discharge path r3 that is a conveyance path branched from the main conveyance path r1. The sheet P is discharged to the discharge tray 90 by the discharge roller 20 provided at the end (exit) of the discharge path r3.

  When an image is formed on the second surface of the sheet P, the flapper 55 guides the sheet P to the reversing unit 70. That is, the sheet P enters the reversing unit 70 from the reversing point 201 that is the exit of the main conveyance path r <b> 1 and heads toward the reversing roller pair 50. The inversion point 201 is also an entrance to the inversion unit 70. In FIG. 1, the reversing unit 70 is a conveyance path existing on the left side of the reversing point 201 and includes a reversing roller pair 50. The reversing roller pair 50 reverses to draw the sheet P from the main transport path r1 into the reversing unit 70. As a result, a part of the sheet P is discharged to the outside of the image forming apparatus 100. When the sheet sensor 61 detects the trailing edge of the sheet P, the reverse roller pair 50 stops. When the reversing roller pair 50 is rotated forward, the sheet P is sent to the sub-conveying path r2 through the reversing point 201. That is, the front and back of the sheet P are switched by changing the conveyance direction of the sheet P. The reversal point 201 is also the exit of the reversing unit 70 and the entrance of the sub transport path r2. That is, the reversal point 201 is a connection portion that connects the main transport path r1, the sub transport path r2, and the reversing unit 70. The sub-transport path r2 is also connected to the main transport path r1 at the junction 200. As described above, the sub-transport path r <b> 2 is an auxiliary transport path extending from the reversal point 201 to the junction 200. The junction 200 is also the exit of the sub-transport path r2. In the main conveyance path r1, the junction 200 is provided on the upstream side of the registration roller pair 16. When the reverse roller pair 50 starts normal rotation, the transport roller pair 51, the transport roller pair 52, and the transport roller pair 53 also start rotating. The sheet P is transported by the transport roller pair 51, the transport roller pair 52, and the transport roller pair 53, and travels toward the junction 200. The conveyance roller pair 53 may interrupt the conveyance of the sheet P before the leading edge of the sheet P reaches the joining point 200. When the conveyance roller pair 53 resumes conveyance of the sheet P, the sheet P passes through the junction 200 and reaches the registration roller pair 16. The sheet P whose conveyance timing is adjusted by the registration roller pair 16 is conveyed to the secondary transfer unit 80. When the second surface of the sheet P is in contact with the intermediate transfer belt 8, the toner image is transferred to the second surface. The fixing device 17 fixes the toner image on the second surface of the sheet P. The flapper 55 guides the sheet P on which double-sided printing has been completed to the paper discharge path r3. As a result, the sheet P on which images are formed on both sides is discharged to the discharge tray 90.

  Note that a sheet sensor 62 may be provided at the junction 200. When the leading edge of the sheet P arrives at the junction 200, the sheet sensor 62 switches the level of the detection signal from off to on. The sheet sensor 62 switches the level of the detection signal from on to off when the trailing edge of the sheet P passes the merging point 200. That is, the level of the detection signal is kept on while the sheet P passes through the sheet sensor 62. While the sheet P does not pass through the sheet sensor 62, the level of the detection signal is kept off. The sheet sensor 62 may be used as a sensor that detects that the sheet P has reached the registration roller pair 16. The sheet sensor 63 is a sensor for detecting that the sheet P has passed the registration roller pair 16 and has reached the speed stable point 202.

<Control system>
FIG. 2 shows a control system for controlling the image forming apparatus 100. The printer control unit 101 includes circuits such as a CPU 104, a ROM and a RAM (not shown), and controls various units included in the image forming apparatus 100. A control program is stored in the ROM. The CPU 104 is connected to the image forming unit 110, the motor driving unit 111, the flapper driving unit 112, and the sensor unit 113. The image forming unit 110 includes a fixing device 17, an exposure device 7, a process station 5, and the like. The motor drive unit 111 is a drive circuit that drives the motors M1, M2, and M3 in accordance with instructions from the CPU 104. The motor M1 drives the reverse roller pair 50. The motor M2 drives the conveyance roller pair 51, 52, 53. The conveyance roller pairs 51, 52, and 53 may be driven by different motors. The motor M3 drives the registration roller pair 16. Illustration of a motor for driving the drive roller 9 is omitted. The flapper driving unit 112 controls the flapper 55 in accordance with a control signal output from the CPU 104, thereby guiding the sheet P to the paper discharge path r3 or the sub-transport path r2. The sensor unit 113 is connected to the sheet sensors 61, 62, 63 and outputs detection signals output from the sheet sensors 61, 62, 63 to the CPU 104. Note that the CPU 104 may estimate the position of each sheet by counting the number of driving pulses supplied to each motor by the motor driving unit 111 instead of using these sheet sensors. The number of drive pulses, the rotation angle of the rotation shaft of the motor, and the rotation angle of each roller are in a proportional relationship. Accordingly, the conveyance distance of the sheet P is also proportional to the number of drive pulses.

  The controller 102 is a controller that converts the color space of the image data and instructs the printer control unit 101 to print. The controller 102 is connected to the host computer 103 via a network, a printer cable, or the like. The controller 102 receives image information and a print command from the host computer 103. The controller 102 analyzes the image information and converts it into bitmap data, and transmits the bitmap data to the printer control unit 101 in synchronization with the TOP signal transmitted from the printer control unit 101. The printer control unit 101 may be realized by the CPU 104 executing a control program. Some or all of the functions of the printer control unit 101 may be realized by a dedicated circuit (ASIC) for a specific application. Some or all of the functions handled by the CPU 104 may also be realized by hardware such as an ASIC or FPGA. FPGA is an abbreviation for field programmable gate array.

<Double-sided circulation>
The image forming apparatus 100 may have a plurality of duplex printing modes. Basically, when the image forming apparatus 100 continuously forms images on the first surface of N sheets, the image forming apparatus alternately executes image formation on the second surface of the sheet and image formation on the first surface of the sheet. To do. That is, the image forming apparatus 100 alternately performs image formation on a sheet fed from the sub-conveying path and image formation on a sheet newly fed from the sheet feeding cassette 13.

  FIG. 3A shows a case where N = 3. The image forming apparatus 100 continuously forms an image on each first surface of the third sheet from the first sheet and sends it to the sub-transport path r2. Thereafter, the image forming apparatus 100 alternately performs image formation on the second surface of the sheet re-feeded from the sub-transport path r2 and image formation on the first surface of the sheet fed from the paper feeding device 12. To run. That is, when the image forming apparatus 100 forms an image on the first surface of the third sheet, the image forming apparatus 100 then forms an image on the second surface of the first sheet. Further, the image forming apparatus 100 forms an image on the first surface of the fourth sheet, and then forms an image on the second surface of the second sheet. Further, the image forming apparatus 100 forms an image on the first surface of the fifth sheet, and then forms an image on the second surface of the third sheet. Finally, the image forming apparatus 100 forms an image on each second surface of the third sheet to the fifth sheet. As described above, the example shown in FIG. 3A is a three-sheet circulation mode in which three sheets circulate through the conveyance path in the image forming apparatus 100.

  FIG. 3B shows a two-sheet circulation mode. FIG. 3C shows the single sheet circulation mode. In the single sheet circulation mode, when the image forming apparatus 100 forms an image on the first surface of the sheet, the image forming apparatus 100 then forms an image on the second surface of the sheet. These circulation modes are selected according to the length of the sheet in the conveyance direction.

  The sheet on which the image is formed on the first surface reaches the secondary transfer unit 80 again via the sub-transport path r2, and an image is formed on the second surface. Accordingly, the time for which the sheet moves in the sub-conveying path r2 affects the productivity of image formation. If an image can be formed on the succeeding sheet while a certain preceding sheet moves on the sub-conveying path r2, the moving time is not wasted and the productivity is improved. Therefore, the two-sheet circulation mode and the three-sheet circulation mode have higher productivity than the single-sheet circulation mode. As described above, if the conveyance of the sheet in the sub conveyance path r2 is completed by the transfer timing of the toner image on the second surface, the productivity is improved. Note that the number of sheets that can be circulated through the circulation path formed by the main conveyance path and the sub conveyance path depends on the length of the sub conveyance path.

  The maximum size of the sheet P that can be printed by the image forming apparatus 100 of the present embodiment is assumed to be a Ledger size. The length of the sheet P in the conveyance direction of the Ledger size sheet P is 431.8 mm. In this case, the three-sheet circulation mode can be adopted for the sheet P of letter size (215.9 mm) or A4 size (210 mm). Further, in the Ledger / A3 size sheet P, the two-sheet circulation mode can be adopted.

<Transport control>
FIG. 4 shows a comparative example. The auxiliary conveyance path r2 of the comparative example is long enough that the three sheets P1, P2, and P3 can stand by from the reverse roller pair 50 to the junction point 200. In this embodiment, by shortening the sub-transport path r2, the number of sheets that can stand by on the sub-transport path r2 is reduced, so that the image forming apparatus 100 can be made compact. CPU104 is, when the trailing edge of the sheet P3 by the reverse rotation of the pair of reverse rollers 50 passes through the reversal point 201, starts the normal rotation of the pair of reverse rollers 50, even conveyance of the sheet P2, P 1 resumes.

5A to 5F illustrate the three-sheet circulation mode of this embodiment. All sheets are assumed to be Letter / A4 size sheets.
1. As illustrated in FIG. 5A, the image forming apparatus 100 conveys the first sheet P <b> 1 with the image formed on the first surface to the reversal point 201.
2. As illustrated in FIG. 5B, the image forming apparatus 100 reversely rotates the reversing roller pair 50 and pulls the sheet P1 into the reversing unit 70, and then rotates the reversing roller pair 50 in the normal direction. As a result, the image forming apparatus 100 sends the sheet P <b> 1 to the sub-transport path and transports it toward the junction 200. In parallel with this, the image forming apparatus 100 forms an image on the first surface of the second sheet P <b> 2 and conveys it to the inversion point 201.
3. As illustrated in FIG. 5C, the image forming apparatus 100 stops the sheet P <b> 1 at the standby position in front of the junction 200. The image forming apparatus 100 reversely rotates the pair of reversing rollers 50 and pulls the sheet P2 into the reversing unit 70, and then rotates the pair of reversing rollers 50 normally. As a result, the image forming apparatus 100 sends the sheet P <b> 2 to the sub-transport path r <b> 2 and transports it toward the junction 200. The image forming apparatus 100 causes the paper feeding device 12 to feed the third sheet P3 to the main transport path r1. Since the sheet P1 stands by upstream from the junction 200, it does not collide with the sheet P3.
4). As shown in FIG. 5D, while the image forming apparatus 100 forms an image on the sheet P3, the sheet P1 continues to stand by before the junction 200. The image forming apparatus 100 causes the sheet P2 to stand by by holding the rear end portion of the sheet P2 between the pair of reverse rollers 50. The vicinity of the center of the sheet P <b> 2 is sandwiched between the conveyance roller pair 51. The leading edge of the sheet P2 is stopped before the pair of conveying rollers 52. The image forming apparatus 100 conveys the sheet P3 toward the reversal point 201 while forming an image on the first surface. At the timing when the trailing edge of the sheet P3 passes the junction point 200, the image forming apparatus 100 resumes the conveyance of the sheet P1 and the sheet P2.
5. As shown in FIG. 5E, when the rear end of the sheet P2 passes the reversal point 201, the front end of the sheet P3 has not yet reached the reversal point 201. Therefore, the sheet P3 does not collide with the sheet P2. Further, the image forming apparatus 100 conveys the sheet P1 by the conveyance roller pair 53 and sends it to the main conveyance path r1.
6). As shown in FIG. 5F, when the sheet P1 passes through the registration roller pair 16, the image forming apparatus 100 stops the registration roller pair 16. As a result, the image forming apparatus 100 synchronizes the timing at which the toner image on the second surface from the intermediate transfer belt 8 arrives at the secondary transfer portion 80 and the timing at which the second surface of the sheet P1 arrives at the secondary transfer portion 80. Let Further, when the conveyance of the sheet P1 is stopped, the image forming apparatus 100 also stops the conveyance of the sheet P2. The sheet P2 waits in the sub conveyance path r2. Further, the image forming apparatus 100 conveys the sheet P3 toward the reversal point 201.

  As described above, when the sub-transport path length is short, the vicinity of the rear end of the sheet P2 closes the reversal point 201 when the rear end of the sheet P3 passes through the joining point 200. That is, the sheet P2 extends over the inversion point 201. However, with the trigger that the trailing edge of the sheet P3 has passed the merging point 200, the image forming apparatus 100 sends the sheet P1 from the merging point 200 to the main conveying path r1, and the sheet P2 also moves downstream in the sub conveying path r2. By doing so, the inversion part 70 and the inversion point 201 become empty. Accordingly, the three sheets can be circulated in the circulation path without the sheet P3 and the sheet P2 colliding at the reversal point 201. In the comparative example shown in FIG. 4, since the sub conveyance path length is sufficiently long, the leading sheet P1 is supplied to the main conveyance path r1 after the sheet P3 is drawn into the reversing unit 70. On the other hand, in the first embodiment, the leading sheet P1 is supplied to the main transport path r1 before the sheet P3 arrives at the reversing unit 70. Such a paper feeding method can be referred to as advance paper feeding.

  When the trailing edge of the sheet P3 passes through the joining point 200, the printer control unit 101 resumes the conveyance of the sheet P2 that has been held between the pair of reverse rollers 50. That is, by the time the leading edge of the sheet P3 reaches the reversal point 201, the rear end of the sheet P2 passes through the reversal point 201. Therefore, the sheet P2 and the sheet P3 do not collide at the reversal point 201. As shown in FIG. 5D, since the trailing edge of the sheet P2 stands by across the reverse roller pair 50 and the sub conveyance path r2, the length of the sub conveyance path r2 in this embodiment is the sub conveyance path r2 in the comparative example. It can be shorter than the length of.

  According to the present embodiment, the trailing end of the sheet P2 is more than the inversion point 201 within the time from when the trailing end of the sheet P3 passes the merging point 200 until the leading end of the sheet P3 reaches the inversion point 201. Must move downstream. Therefore, when the trailing edge of the sheet P3 passes the merging point 200, the distance from the leading edge of the sheet P3 to the inversion point 201 needs to be longer than the distance from the trailing edge of the waiting sheet P2 to the inversion point 201. There is. However, the conveyance speeds of the sheets P2 and P3 are the same. This embodiment is based on the premise that the length of the sheet on which an image is formed is shorter than the distance from the reversal point 201 to the junction point 200 along the sub-transport path r2. For example, in the case of a Ledger size sheet, the rear end of the sheet cannot pass through the merging point 200 until the leading end of the sheet reaches the reversal point 201, and thus this embodiment cannot be applied.

<Flowchart>
FIG. 6 is a flowchart illustrating sheet conveyance control executed by the CPU 104 to execute double-sided printing. Here, it is assumed that double-sided printing is performed on M sheets. Further, the image forming apparatus 100 can execute the N-sheet circulation mode (M and N are natural numbers, and M> N holds). The length of the sub-transport path r2 is a length that allows N-1 sheets to stand by at the maximum. The last sheet is held between the pair of reverse rollers 50 and waits. That is, the last sheet waits across the pair of reversing rollers 50 and the sub conveyance path r2. The controller 102 receives the print instruction transmitted from the host computer 103. The controller 102 instructs the printer control unit 101 to execute double-sided printing according to the print instruction.

  In step S <b> 601, the CPU 104 controls the image forming unit 110, the motor driving unit 111, the flapper driving unit 112, and the like to form images on the first surfaces of the first to N−1 sheets. The sheets up to the (N-1) th sheet are sent to the sub-transport path r2 and waited. If N = 3, the CPU 104 feeds the first sheet P1 to the sheet feeding device 12, and when the first sheet P1 reaches the registration roller pair 16, the motor M3 is stopped to stop the registration. The pair of ration rollers 16 is stopped. When the rotational speed of the registration roller pair 16 can be variably controlled, it is not essential to stop the registration roller pair 16. The CPU 104 resumes the rotation of the motor M3 in synchronization with the image formation timing of the image forming unit 110, rotates the registration roller pair 16, conveys the sheet P1 to the secondary transfer unit 80, and the first surface of the sheet P1. The toner image is transferred to. The CPU 104 controls the flapper 55 through the flapper driving unit 112 to guide the sheet P1 to the reversing roller pair 50. Note that the CPU 104 may, for example, start reverse rotation of the reversing roller pair 50 by the motor M1 when the leading edge of the sheet P1 passes the reversing point 201 to prepare for the arrival of the leading edge of the sheet P1. Further, when the controller 102 instructs the sheet feeding of the sheet P2 from the controller 102, the CPU 104 instructs the sheet feeding device 12 to feed the sheet P2. When the trailing edge of the sheet P1 passes the reversal point 201, the CPU 104 starts normal rotation of the reversing roller pair 50 by the motor M1, and starts rotation of the conveying roller pairs 51, 52, 53 by the motor M2, and the sheet P1. To the standby position. When the sheet P2 reaches the registration roller pair 16, the CPU 104 stops the registration roller pair 16 by stopping the motor M3. The CPU 104 resumes the rotation of the motor M3 in synchronization with the image formation timing of the image forming unit 110, rotates the registration roller pair 16, conveys the sheet P2 to the secondary transfer unit 80, and the first surface of the sheet P2. The toner image is transferred to. The CPU 104 controls the flapper 55 through the flapper driving unit 112 to guide the sheet P <b> 2 to the reverse roller pair 50. Note that the CPU 104 starts the reverse rotation of the pair of reverse rollers 50 by the motor M1 when the rear end of the sheet P2 passes the joining point 200, and prepares for the arrival of the front end of the sheet P2. When the CPU 102 instructs the sheet feeding of the sheet P3 from the controller 102, the CPU 104 instructs the sheet feeding device 12 to feed the sheet P3.

  In step S <b> 602, the CPU 104 starts image formation on the first surface of the sheet fed from the sheet feeding device 12. For example, when N−1 sheets are waiting in the sub-conveying path r2, the CPU 104 controls the image forming unit 110, the motor driving unit 111, the flapper driving unit 112, and the like, and the first sheet of the Nth sheet is controlled. Start image formation on the surface.

In step S <b> 603, the CPU 104 determines whether the trailing edge of the sheet during image formation has passed the joining point 200 based on the detection result of the sheet sensor. When the trailing end of the sheet in the image formation passes through the confluence 200, CPU 104 proceeds to S60 4. The CPU 104 controls the flapper 55 and the reverse roller pair 50 to convey the sheet on which the image is formed on the first surface toward the reverse roller pair 50.

  In step S <b> 604, the CPU 104 resumes the conveyance of the sheet waiting on the sub conveyance path r <b> 2. The CPU 104 activates the motor M1 through the motor driving unit 111 to rotate the reverse roller pair 50 in the normal direction, activates the motor M2 to rotate the conveyance roller pairs 51, 52, and 53, and waits on the sub conveyance path r2. Resume transport. Thereby, the sheet positioned at the head in the sub-transport path r2 is transported to the main transport path r1. In addition, the trailing edge of the sheet that is held by the reversing roller pair 50 is moved downstream from the reversing point 201. Therefore, even if the succeeding sheet arrives at the turning point 201, it does not collide with the preceding sheet. Note that when the trailing edge of the sheet held between the pair of reversing rollers 50 and waiting has passed the reversal point 201, the CPU 104 switches the motor M1 from normal rotation to reverse rotation to prepare for the sheet fed from the main conveyance path r1. Further, when the trailing edge of the sheet fed from the main conveyance path r1 and drawn into the pair of reversing rollers 50 passes the reversal point 201, the CPU 104 switches the motor M1 from reverse rotation to normal rotation, and moves the sheet to the sub conveyance path. Send to r2. As shown in FIG. 5C, when the leading edge of the sheet that has been located second from the top in the sub-transport path r2 arrives at the standby position, the CPU 104 stops the motors M1 and M2.

  In step S <b> 605, the CPU 104 forms an image on the second surface of the sheet fed from the sub transport path r <b> 2 to the main transport path r <b> 1 and discharges it. For example, the CPU 104 sends the sheet to the secondary transfer unit 80 while synchronizing the sheet conveyance timing with the image formation timing by the registration roller pair 16. The CPU 104 switches the flapper 55, guides the sheet on which the image is formed on the second surface to the paper discharge path r <b> 3, and discharges it to the paper discharge tray 90.

  In step S <b> 606, the CPU 104 determines whether there is a sheet to be newly fed from the sheet feeding device 12 to the main conveyance path r <b> 1. For example, if M sheets have already been fed, the CPU 104 determines that there is no sheet to be fed (print job is completed). If the number of sheets fed from the paper feeder 12 has not reached M, the CPU 104 returns to S602 and repeats the processing from S602 to S606. In other words, when the number of sheets waiting in the sub-conveying path r2 reaches the upper limit of N−1 sheets, image formation on the first surface of the sheet fed from the sheet feeding device and the sub-conveying path r2 are performed. The image formation on the second surface of the sheet fed from is alternately executed. If the number of sheets fed from the paper feeder 12 has reached M, the CPU 104 advances to S607 because there is no sheet to be newly fed from the paper feeder 12 to the main transport path r1.

  In step S <b> 607, the CPU 104 forms an image on the second surface of the N−1 sheets waiting in the sub-transport path r <b> 2 and discharges the image. For example, the CPU 104 sends the sheet to the secondary transfer unit 80 while synchronizing the sheet conveyance timing with the image formation timing by the registration roller pair 16. The CPU 104 switches the flapper 55, guides the sheet on which the image is formed on the second surface to the paper discharge path r <b> 3, and discharges it to the paper discharge tray 90. The CPU 104 controls the motors M1 and M2 to convey N−1 sheets downstream in the sub-conveying path r2. As shown in FIG. 3A and the like, image formation on the second surface of the last N−1 sheets among the M sheets is continuously executed. This is because no new sheet is supplied from the sheet feeding device 12.

<Timing chart>
FIG. 7 shows a timing chart of preceding paper feeding in double-sided printing. Here, N = 3.

  T100: When the rear end of the third sheet P3 passes the joining point 200, the level of the detection signal output from the sheet sensor 62 is turned off (no sheet) (Yes in S603). The CPU 104 starts normal rotation of the reverse roller pair 50 by the motor M1. Further, the CPU 104 rotates the motor M <b> 2 and starts to rotate the conveyance roller pair 51, 52, 53. As a result, the sheets P1 and P2 travel downstream along the sub-transport path r2.

  T101: When the trailing edge of the sheet P2 passes the inversion point 201, the level of the detection signal output by the sheet sensor 61 is turned off (no sheet). In order to draw the sheet P3 into the reversing unit 70, the CPU 104 reverses the motor M1 to reverse the reverse roller pair 50.

  T102: When the leading edge of the sheet P1 reaches the joining point 200, the level of the detection signal output by the sheet sensor 62 is turned on (there is a sheet).

  T103: When the leading edge of the sheet P1 reaches the sheet sensor 63, sometimes called a registration sensor, the CPU 104 stops the motors M2 and M3. As a result, the registration roller pair 16 and the transport roller pairs 51, 52, 53 are also stopped.

  T104: When the leading edge of the sheet P3 reaches the inversion point 201, the level of the detection signal output by the sheet sensor 61 is turned on (there is a sheet). When the rear end of the sheet P3 passes the sheet sensor 61 and the level of the detection signal output from the sheet sensor 61 is turned off (no sheet), the CPU 104 switches the motor M1 from reverse rotation to normal rotation. The CPU 104 stops the motor M1 when the leading edge of the sheet P3 reaches a predetermined standby position in the sub transport path r2.

<Sub transport path length>
FIG. 8A shows a standby state of the sheet in the sub conveyance path r2. Here, a Letter sheet and a Ledger sheet are illustrated. The sheet length Ltr in the transport direction of the Letter sheet is 215.9 mm. The CPU 104 controls the motor M2 so that the leading edge of the first sheet P1 stops at a position separated by a distance La from the joining point 200 toward the upstream side. If the leading end of the sheet protrudes downstream from the junction 200, there is a possibility of colliding with the third sheet P3 newly fed from the sheet feeding device 12. Therefore, in consideration of conveyance variations and the like, the leading end of the sheet P1 stops and stands by at a position separated by a distance La upstream from the junction 200. La is determined from a measurement result of variation in sheet conveyance, a result of simulation, and the like. The distance between the trailing edge of the preceding sheet P1 and the succeeding sheet P2 is Lb. Lb is determined in consideration of the conveyance variation of the sheet P1, the conveyance variation of the sheet P2, and the margin value of the sheet length allowed by the image forming apparatus 100.

  The Ledger sheet is an example of a maximum size sheet that can be printed by the image forming apparatus 100. The sheet length Lldr of the Ledger sheet in the transport direction is 431.8 mm. Since the sheet length of the Ledger sheet is too long, the three-sheet circulation mode cannot be applied, and the two-sheet circulation mode is applied. In the two-sheet circulation mode, the Ledger sheet waits between the junction point 200 and the inversion point 201. The CPU 104 stops the leading edge of the Ledger sheet at a position away from the junction 200 by the distance La to the upstream side. This is the same concept as in the case of the Letter size. The distance from the trailing edge of the Ledger sheet to the reversal point 201 is set to Ls in consideration of conveyance variations.

As can be seen from FIG. 8A, the length of the sub-transport path r2 of the image forming apparatus 100 is restricted by the length of the Ledger sheet. A distance Ldup1 from the junction 200 to the inversion point 201 is determined so as to satisfy the following equation.
Ldup1 = La + Lldr + Ls (1)
FIG. 8B shows a standby state of the sheet in the sub conveyance path r2 of the comparative example. In the Letter sheet, the rear end of the second sheet P2 needs to be positioned downstream of the reversal point 201. This restriction determines the distance Ldup2 of the sub transport path r2.
Ldup2 = La + Lltr + Lb + Lltr + Ls
= La + Lldr + Lb + Ls (2)
As can be seen from a comparison between the expressions (1) and (2), the length of the sub-transport path r2 of the present embodiment is shortened by Lb than the length of the sub-transport path r2 of the comparative example.

  In the present embodiment, the example of the circulation number N = 3 is mainly taken up, but N may be 4 or more. According to this embodiment, the sub-transport path r2 is shortened so that the sheet on which the image is formed on the first surface has to stand by across the reverse roller pair 50 and the sub-transport path r2. Therefore, the waiting sheet must be moved to the downstream side of the sub conveying path r2 so that the waiting sheet and the sheet fed from the main conveying path r1 do not come into contact with each other. That is, after the sheet at which the image is being formed on the first surface passes through the merge point 200 and the leading edge of the sheet reaches the reversal point 201, the rear of the sheet existing at the reversal point 201 is reached. The CPU 104 executes the conveyance control so that the end finishes passing through the reversal point 201. That is, this embodiment can be applied to an image forming apparatus in which the last sheet waiting in the sub-transport path r2 can be positioned at least at the reversal point 201. A plurality of sheets may be waiting between the first sheet and the last sheet waiting in the sub-transport path r2. Note that the first sheet and the last sheet may be the same. In this case, the two-sheet circulation mode shown in FIG. Therefore, N may be an integer of 2 or more.

  In the first embodiment, the number of circulating sheets may be changed depending on the length of the sheet. For example, the CPU 104 may set the number of circulating sheets to three when the sheet length is shorter than a predetermined length, and may set the number of circulating sheets to two when the sheet length is longer than the predetermined length. Good. The predetermined length serving as the threshold may be set according to the length of the conveyance path.

  In the first exemplary embodiment, the conveyance roller pair 51 and 52 may be omitted, and the sheet may be conveyed directly from the reverse roller pair 50 to the conveyance roller pair 53.

[Example 2]
The second embodiment is an example in which the length of the sub transport path r2 is determined in consideration of factors other than the control. In the second embodiment, the same reference numerals are assigned to items common to the first embodiment, and the description thereof is omitted.

  There are various types of seats on the market. For example, not only thick paper and coated paper (gross paper) with a large basis weight but also plain paper and thin paper with a relatively small basis weight are in widespread use. It should be noted here that the basis weight of the sheet has an influence on the conveyance control. In general, the basis weight of a sheet and the sheet conveyance efficiency are inversely proportional. For example, the transport efficiency of thick paper and glossy paper is lower than that of plain paper and thin paper. For this reason, transport delay is likely to occur with thick paper and glossy paper. Such a sheet with low conveyance efficiency may stop upstream of the target position. As a result, the preceding sheet and the succeeding sheet may come into contact with each other at the inversion point 201. Therefore, in the second embodiment, conveyance control in consideration of the type of sheet (a parameter that affects conveyance efficiency such as basis weight) is proposed.

  FIG. 9 is a diagram illustrating the distance Ldup3 of the sub-transport path r2 according to the second embodiment. Here, the relationship of Ldup2> Ldup3> Ldup1 is established. The distance Ldup3 of the sub-transport path r2 of the second embodiment is shorter than the distance Ldup2 of the sub-transport path r2 of the comparative example, but is longer than the distance Ldup1 of the sub-transport path r2 of the first embodiment. As shown in FIG. 9, the distance Ldup3 is the distance from the merging point 200 to the reversal point 201, and the rear end of the last sheet waiting in the sub conveyance path r2 is located at the reversal point 201. Therefore, plain paper or thin paper does not completely block the inversion point 201. On the other hand, in the case of thick paper or the like, the trailing edge of the sheet can stop and wait on the downstream side of the pair of reversing rollers 50 and the upstream side of the reversing point 201, so that the reversing point 201 can be blocked. That is, if plain paper or thin paper is the last sheet, the succeeding sheet can be carried into the reversing unit 70 as in the comparative example, but if thick paper or the like is the last sheet, the succeeding sheet is placed in the reversing unit 70. Cannot be brought in. Therefore, for thick paper or the like, it is necessary to feed the standby sheet in advance as described in the first embodiment.

Flowchart FIG. 10 is a flowchart illustrating sheet conveyance control according to the second exemplary embodiment. In the second embodiment, the same reference numerals are assigned to items common to the first embodiment. In S601, image formation of the N-1st sheet is completed, and these sheets wait in the sub-transport path r2. In step S <b> 602, the CPU 104 feeds the next sheet (for example, the Nth sheet) from the sheet feeding device 12 and starts forming an image on the first surface of the next sheet.

In step S1001, the CPU 104 determines whether the sheet type is a specific type (such as cardboard or glossy paper). Here, the basis weight of the sheet may be determined as the threshold value, and the sheet conveyance efficiency may be determined as the threshold value. Information indicating the type of sheet is provided from the host computer 103, for example. If the type of the sheet is a particular type, CPU 104, to execute the preceding feeding in the beginning of the sheet waiting in sub-passage r2, the process proceeds to S60 4. Therefore, the CPU 104 prohibits sheet feeding from the sheet feeding device 12 while feeding the leading sheet that has been waiting in the sub-conveying path r2 to the main conveying path r1. Thereafter, the CPU 104 executes the processing after S603. That is, in the case of thick paper or the like, the same processing as in the first embodiment is applied. On the other hand, if the CPU 104 determines that the type of the next sheet is a specific type, the process advances to step S1002. Note that if the types of M sheets constituting one print job are all the same type, the type specified by the print job is determined. However, it is sufficient that only the type of the last sheet is determined at least in the sub-transport path r2. This is because the last sheet may block the reversal point 201.

  In step S <b> 1002, the CPU 104 determines whether the sheet (for example, the Nth sheet) on which the image is formed on the first surface is drawn into the reversing unit 70 by the reversing roller pair 50 and whether the trailing edge of the sheet has passed the reversing point 201. judge. When the trailing edge of the sheet passes the reversal point 201, the CPU 104 proceeds to S604. In step S604, the CPU 104 resumes the conveyance of the N−1 sheets that have been waiting on the sub conveyance path r2.

  As described above, the timing and trigger for resuming the conveyance of the sheet waiting in the sub-conveyance path r2 are different between the sheet having high conveyance efficiency and the sheet having low conveyance efficiency. For example, if plain paper, thin paper, or the like is the last sheet in the sub-transport path r2, the preceding paper feed in the first embodiment is not executed. Therefore, the feeding of the next sheet (N + 1th sheet) from the sheet feeding device 12 is not prohibited, and the image formation on that sheet is not prohibited. This is because an image can be formed on another sheet and discharged onto the discharge tray 90 while waiting N sheets on a standby path formed by the sub-transport path r2 and the reversing unit 70.

  As described above, if the type of the sheet having the closest rear end position to the reversal point among the sheets waiting in the sub conveyance path r <b> 2 is a specific type having low conveyance efficiency, the CPU 104 determines the sub conveyance path. The leading sheet in r2 is fed in advance. This makes it difficult for the succeeding sheet to contact the preceding sheet at the reversal point 201. On the other hand, if the type of the sheet having the closest rear end position with respect to the reversal point among the sheets waiting in the sub-conveying path r2 is a type that is not low in conveying efficiency, the CPU 104 executes the preceding sheet feeding. do not do. That is, the CPU 104 sends the succeeding sheet to the reversing unit 70 while waiting N−1 sheets in the sub-transport path r2. In this case, since the rear end of the sheet waiting near the inversion point is located downstream of the inversion point, contact between the sheets hardly occurs.

  FIG. 11 is a timing chart showing conveyance control for a sheet having a small conveyance efficiency (large basis weight) such as a thick sheet or glossy sheet. Here, it is assumed that N = 3.

  T200: When the rear end of the third sheet P3 passes the joining point 200, the motor M2 is activated to drive the conveying roller pairs 51, 52, and 53. In the embodiment, as shown in FIG. 9, the rear end of the second sheet P <b> 2 is located downstream of the reversing roller pair 50. Therefore, the CPU 104 does not need to rotate the motor M1 that drives the reverse roller pair 50.

  T201: The sheet P2 is conveyed downstream by the conveyance roller pairs 51, 52, and 53, so that the rear end of the sheet P2 passes the inversion point 201.

  T202: The leading end of the sheet P1 reaches the confluence 200 by the sheet P1 waiting at the head in the sub-conveying path r2 being conveyed downstream by the conveying roller pair 51, 52, 53.

T203: When the leading end of the sheet P1 in the sheet sensor 63 (registration sensor) reaches, CPU 104 stops the motor M2 for driving the motor M 3 and the conveying roller pair 51, 52 and 53 for driving the registration roller pair 16.

  T204: Before the leading edge of the sheet P3 reaches the reversal point 201, the CPU 104 starts the reverse rotation of the motor M1. Thereby, the acceptance posture of sheet P3 is prepared.

  T205: The leading edge of the sheet P3 reaches the reversal point 201.

  As described above, in the second exemplary embodiment, whether or not the preceding sheet feeding is appropriate is switched according to the type of sheet. As a result, the contact of the sheet is less likely to occur while the length of the sub-transport path r2 is shorter than that of the comparative example.

[Example 3]
The CPU 104 may variably control the rotation speed of the registration roller pair 16 in order to match the timing at which the toner image reaches the secondary transfer unit 80 and the timing at which the leading edge of the sheet reaches the secondary transfer unit 80. Good. For example, if the sheet fed from the sheet feeding device 12 is delayed from a predetermined timing, the sheet conveyance speed is temporarily increased. If the sheet fed from the sheet feeding device 12 is earlier than the predetermined timing, the sheet conveyance speed is temporarily reduced. However, the CPU 104 returns the sheet conveyance speed to the conveyance speed of the intermediate transfer belt 8 immediately before the leading edge of the sheet reaches the secondary transfer unit 80.

  By the way, in order to reduce the number of motors, it can be considered that the conveyance roller pair 53 and the registration roller pair 16 are driven by the same motor. In this case, when the rotation speed of the registration roller pair 16 changes, the rotation speed of the conveyance roller pair 53 also changes. If the vicinity of the leading edge of the sheet conveyed on the sub-conveying path r2 is nipped by the conveying roller pair 53, and the vicinity of the center or the rear end is nipped by a conveying roller pair driven by another motor, the sheet is pulled. Or break. In order to avoid this, it is conceivable that the leading edge of the sheet conveyed on the sub-conveying path r <b> 2 waits before the conveying roller pair 53 until the speed adjustment of the registration roller pair 16 is completed. That is, the sheet must wait at a standby position further upstream than the standby position of the first embodiment. If the trailing edge of the sheet waiting in the sub-transport path r <b> 2 blocks the reversal point 201, the sheet on which the image is formed on the first surface cannot be transported to the reversing roller pair 50. In order to solve this problem, a method of avoiding the contact of the sheet by lengthening the sub-conveying path r <b> 2 can be considered, but this hinders downsizing of the image forming apparatus 100.

  Therefore, in the third embodiment, an image forming apparatus 100 is provided that can reduce the length of the sub-transport path while reducing the number of motors. In particular, in the present embodiment, while the registration roller pair 16 is executing the speed adjustment, the sheet is put on standby in the sub-transport path r2 before the transport roller pair 53. This makes it difficult for the sheets to be pulled. When the speed adjustment of the registration roller pair 16 is completed, the conveyance of the sheet is resumed in the sub conveyance path r2, and when the leading edge of the sheet arrives at the standby position before the junction 200, the conveyance roller pair 53 is stopped by the clutch. Thereby, the rear end of the sheet conveyed on the sub conveyance path r <b> 2 can be positioned downstream of the reversal point 201. Further, the conveyance of the sheet by the registration roller pair 16 can be continued in the main conveyance path r1. As a result, the sub-transport path r2 can be shortened.

<Description of Configuration of Example 3>
FIG. 12 shows an image forming apparatus 100 according to the third embodiment. Since the third embodiment is an image forming apparatus 100 that performs double-sided printing in the two-sheet circulation mode, the sub-transport path length is shorter than that of the first embodiment. Therefore, the conveyance roller pair 51 and the conveyance roller pair 53 are provided in the sub conveyance path r2, and the conveyance roller pair 52 is omitted.

  FIG. 13 shows a control system. The motor M1 drives the reverse roller pair 50 and the conveyance roller pair 51 arranged on the most upstream side in the sub-conveyance path r2. The clutch CL1 is a one-way clutch. When the motor M1 is rotating forward, the clutch CL1 transmits the driving force of the motor M1 to the conveying roller pair 51, and the conveying roller pair 51 rotates. On the other hand, when the motor M1 is rotating in the reverse direction, the clutch CL1 does not transmit the driving force of the motor M1 to the conveying roller pair 51. The reversing roller pair 50 rotates forward and backward in conjunction with forward and reverse rotation of the motor M1. The motor M3 drives the registration roller pair 16 and the transport roller pair 53 arranged on the most downstream side in the sub transport path r2. The clutch CL2 is, for example, an electromagnetic clutch that the CPU 104 controls via the motor drive unit 111. That is, even when the registration roller pair 16 is rotating, the CPU 104 can stop the conveying roller pair 53 by controlling the clutch CL2.

<Sheet transport control for duplex printing>
FIG. 14A to FIG. 14F are diagrams for explaining a two-sheet circulation mode using Letter / A4 size sheets.
1. As illustrated in FIG. 14A, the CPU 104 conveys the first sheet P <b> 1 with the image formed on the first surface to the reversal point 201.
2. As illustrated in FIG. 14B, the CPU 104 conveys the sheet P <b> 1 toward the competition point 203 through the sub conveyance path r <b> 2. On the other hand, the CPU 104 starts adjusting the rotation speed of the registration roller pair 16 in order to adjust the timing at which the second sheet P2 fed from the paper feeding device 12 arrives at the secondary transfer unit 80. .
3. As illustrated in FIG. 14C, the CPU 104 controls the motor M <b> 1 so that the sheet P <b> 1 waits at the first standby position x <b> 0 that is in front of the competition point 203. The CPU 104 rotates the motor M <b> 2 and conveys the sheet P <b> 2 toward the secondary transfer unit 80 while executing speed adjustment by the registration roller pair 16. Since the sheet P1 stands by upstream from the competition point 203, the sheet P1 is not affected by the speed difference between the conveyance speed of the conveyance roller pair 53 and the conveyance speed of the conveyance roller pair 51 and the reverse roller pair 50.
4). As shown in FIG. 14D, when the sheet P2 reaches the speed stable point 202, the CPU 104 controls the motor M1 so that the conveyance speed of the registration roller pair 16 is substantially the same as the conveyance speed of the image forming unit. To do. Further, the CPU 104 resumes the conveyance of the sheet P1 by transmitting the driving force of the motor M3 to the conveyance roller pair 53 by switching on the clutch CL2. At this time, the CPU 104 may activate the motor M1 to rotate the conveyance roller pair 51.
5. As shown in FIG. 14E, the CPU 104 switches the clutch CL2 off so that the leading edge of the sheet P1 stops at the second standby position x1. Accordingly, the pair of conveyance rollers 53 can be stopped while the pair of registration rollers 16 conveys the sheet P2. At this time, the length of the sub conveyance path length is designed so that the rear end of the sheet P1 passes through the inversion point 201. Therefore, the CPU 104 may prepare for the carry-in of the sheet P2 by switching the motor M1 from the forward rotation to the reverse rotation in parallel with the leading edge of the sheet P1 stopping at the second standby position x1.
6). As illustrated in FIG. 14F, the CPU 104 controls the flapper 55 to convey the sheet P <b> 2 toward the reversal point 201. At this time, the rear end of the sheet P1 passes through the reversal point 201, so that the sheet P2 does not come into contact with the sheet P1.
By adopting such conveyance control, the distance from the reversal point 201 to the first standby position x0 can be made shorter than the length of the sheet.

  FIG. 15 shows the sub-transport path r2 of the comparative example. In this comparative example, since the clutch CL2 is not provided, the sheet P1 must always stop and wait at the first standby position x0. Furthermore, in order to avoid contact with the sheet P2, the distance from the first standby position x0 to the inversion point 201 must be longer than the sheet P1. On the other hand, in Example 3, the distance from the first standby position x0 to the reversal point 201 can be made shorter than the length of the sheet, which is superior to the comparative example.

  In particular, the CPU 104 starts moving the sheet P1 existing at the reversal point 201 within a period from when the leading end of the sheet P2 passes the speed stabilization point 202 until the leading end of the sheet P2 reaches the reversal point 201. Then, the rear end of the sheet P1 is moved downstream from the reversal point 201.

  FIG. 16 is a flowchart showing sheet conveyance control in duplex printing.

  In step S1601, the CPU 104 controls the image forming unit 110, the motor driving unit 111, the flapper driving unit 112, and the like, forms an image on the first surface of the preceding sheet (first sheet P1), and transfers the preceding sheet to the sub-conveying path. r2 is sent to wait at the first standby position x0. The time from when the leading edge of the preceding sheet is detected by the sheet sensor 61 until the leading edge of the preceding sheet arrives at the first standby position x0 is a substantially constant value (specified value). Therefore, the CPU 104 starts a timer when the leading edge of the preceding sheet is detected by the sheet sensor 61, and stops the motor M1 when the time counted by the timer reaches a specified value. Thereby, as shown in FIG. 14C, the leading edge of the preceding sheet stops at the first standby position x0.

  In step S1602, the CPU 104 feeds the succeeding sheet from the sheet feeding device 12, and conveys the succeeding sheet while performing speed adjustment. As shown in FIG. 14B, the feeding timing of the succeeding sheet may be before the timing when the preceding sheet arrives at the first standby position x0. For example, the CPU 104 adjusts the conveyance speed of the registration roller pair 16 according to whether or not the timing at which the leading edge of the succeeding sheet arrives at the sheet sensor 62 is delayed with respect to a specified timing (reference timing). This speed adjustment is executed by the CPU 104 adjusting the rotational speed of the motor M3.

  In step S <b> 1603, the CPU 104 determines whether the leading edge of the subsequent sheet has arrived at the speed stable point 202. For example, the CPU 104 calculates a distance based on the count value of the timer started when the sheet sensor 63 detects the leading edge of the succeeding sheet and the conveyance speed, and determines whether the calculated distance is a distance corresponding to the speed stable point 202. Determine. When the leading edge of the succeeding sheet arrives at the speed stable point 202, the CPU 104 proceeds to S1604. At this time, the CPU 104 completes the speed adjustment by the motor M3, and the conveying speed matches the image forming speed (the peripheral speed of the intermediate transfer belt).

  In step S1604, the CPU 104 resumes the conveyance of the preceding sheet that has been waiting at the first standby position x0. The CPU 104 starts normal rotation of the motor M1 and switches on the clutch CL2. As a result, the reverse roller pair 50 and the conveyance roller pairs 51 and 53 convey the preceding sheet to the downstream side of the sub conveyance path r2 at the same conveyance speed.

In step S <b> 1605, the CPU 104 determines whether the trailing edge of the preceding sheet has passed the reversal point 201. For example, when the sheet sensor 61 detects that the trailing edge of the preceding sheet has passed, the CPU 104 may determine that the trailing edge of the preceding sheet has passed the reversal point 201. The CPU 104 may determine that the trailing edge of the preceding sheet has passed the reversal point 201 when a predetermined time has elapsed since the sheet sensor 61 detected that the trailing edge of the preceding sheet has passed. The predetermined time is a time obtained by dividing the distance between the sheet sensor 61 and the reversal point 201 by the conveyance speed. When the trailing edge of the preceding sheet passes the reversal point 201, the CPU 104 proceeds to S1606.

  In S <b> 1606, the CPU 104 switches the motor M <b> 1 from normal rotation to reverse rotation to switch the reverse roller pair 50 from normal rotation to reverse rotation. Thus, preparation for receiving the succeeding sheet into the reversing unit 70 is completed.

  In step S1607, the CPU 104 determines whether the leading edge of the preceding sheet has arrived at the second standby position x1. The CPU 104 causes the timer to count the elapsed time from when the conveyance of the preceding sheet is resumed, and determines that the leading edge of the preceding sheet has arrived at the second standby position x1 when the elapsed time reaches a predetermined time. The predetermined time is obtained by dividing the distance between the first standby position x0 and the second standby position x1 by the conveyance speed. Even if the clutch CL2 is disengaged, the conveyance roller pair 53 may rotate due to inertia. Therefore, the predetermined time may be set shorter by subtracting the margin. When the leading edge of the preceding sheet arrives at the second standby position x1, the CPU 104 advances to S1608.

  In step S1608, the CPU 104 switches off the clutch CL2 and stops the conveyance of the preceding sheet. As a result, the leading edge of the preceding sheet stops at the second standby position x1. Since the motor M3 is continuously rotating at this time, the registration roller pair 16 also continuously conveys subsequent sheets. That is, each step from S1601 is applied to the succeeding sheet in the same manner as the preceding sheet.

  In step S1609, when the CPU 104 is ready for image formation on the second side of the preceding sheet, the process advances to step S1610. In step S1610, the CPU 104 sends the preceding sheet to the main conveyance path r1, forms an image on the second surface, and discharges the sheet via the discharge path r3. For example, when the leading edge of the second surface of the preceding sheet arrives at the speed stable point 202, the CPU 104 switches the flapper 55 and discharges the preceding sheet having an image formed on both sides to the discharge tray 90. Further, when the discharge of the preceding sheet is completed, the CPU 104 returns the flapper 55 for the third sheet fed from the sheet feeding device 12. In the following, the third sheet becomes the subsequent sheet, an image is formed on the first surface, and is sent to the sub-transport path r2. Thereafter, the second sheet fed from the sub-transport path r2 becomes a preceding sheet, an image is formed on the second surface, and the sheet is discharged.

  FIG. 17 is a timing chart showing the two-sheet circulation mode.

  T300: As shown in S1602, in order to synchronize the timing at which the subsequent sheet arrives at the secondary transfer unit 80 and the timing at which the toner image arrives at the secondary transfer unit 80, the conveyance speed of the registration roller pair 16 is adjusted. Be started.

  T301: As shown in S1601, when the preceding sheet reaches the first standby position x0, the motor M1 stops. In S1601, various transport controls are comprehensively described as one step, and therefore some steps may be executed after S1602.

  T302: As shown in S1603, when the leading edge of the succeeding sheet reaches the speed stable point 202, the speed adjustment ends. The CPU 104 returns the conveyance speed of the registration roller pair 16 to the conveyance speed of the image forming unit. Further, as shown in S1604, the CPU 104 causes the motor M1 to rotate forward and turns on the clutch CL2.

  T303: As shown in S1605, when the trailing edge of the preceding sheet passes the reversing point (reversing roller pair 50), the motor M1 is switched from normal rotation to reverse rotation in S1606. Thereby, the reverse roller pair 50 prepares for the arrival of the succeeding sheet.

  T304: As shown in S1607, when the leading edge of the preceding sheet reaches the second standby position x1, the clutch CL2 is disconnected, and the power of the motor M3 is not transmitted to the conveying roller pair 53 in S1608.

  T305: The subsequent sheet on which the image is formed on the first surface is conveyed toward the reversal point 201, and the leading edge of the subsequent sheet eventually reaches the reversal point 201.

  In the third exemplary embodiment, as illustrated in FIG. 17, the CPU 104 starts driving the motor M <b> 1 in synchronization with the timing (T <b> 302) when the speed adjustment of the subsequent sheet is completed. However, the present invention is not limited to this. For example, the CPU 104 may start driving the motor M1 before the speed adjustment of the subsequent sheet is completed. While the speed of the registration roller pair 16 is being returned to the process speed, the conveyance of the preceding sheet is started, and the speed adjustment is just completed at the timing when the leading edge of the preceding sheet reaches the conveyance roller pair 53. In this case, the timing at which the CPU 104 starts driving the motor M <b> 1 is obtained from the distance in the sub conveyance path r <b> 2 between the leading edge position of the preceding sheet waiting at the first standby position x <b> 0 and the conveyance roller pair 53.

  In the third embodiment, the conveyance speed (sheet feeding speed) of the sheet fed from the sheet feeding cassette 13 is accelerated or decelerated by the registration roller pair 16 and is again set to the conveyance speed (process speed) of the image forming unit. Return control was explained. Here, the sheet feeding speed, that is, the sheet conveying speed before being accelerated or decelerated by the registration roller pair 16 is not necessarily the same as the process speed. The paper feed speed and the process speed may be different.

  In the case of the control of the third embodiment, the sheet conveyance speed is changed twice. However, the present invention is not limited to this. As an example, it is assumed that the transport speed of the sheet fed from the paper feed cassette 13 and the process speed are different. The CPU 104 changes the timing at which the sheet conveyance speed is returned to the process speed based on the timing at which the sheet sensor 62 detects the leading edge of the sheet. As a result, the position of the sheet being conveyed is aligned with the image formed on the intermediate transfer belt 8. In the case of this control, the sheet conveyance speed may be changed only once.

Modification Example In comparison with the third embodiment, the sheet feeding timing for subsequent sheets may be set later by design. In this case, the preceding sheet reaches the first standby position x0 before the succeeding sheet reaches the registration roller pair 16. That is, the CPU 104 continues the conveyance of the preceding sheet without stopping the preceding sheet at the first standby position x0. This is because the speed adjustment of the registration roller pair is not started until the subsequent sheet reaches the registration roller pair 16. However, when the succeeding sheet reaches the registration roller pair 16, the transport of the preceding sheet must be interrupted. This can be realized by the above-described clutch CL2.

  FIG. 18 is a timing chart showing conveyance control when the sheet feeding timing of the succeeding sheet is set late.

  T400: The CPU 104 conveys the preceding sheet drawn into the reversing unit 70 toward the downstream side of the sub-conveying path r2 by rotating the motor M1 forward and turning on the clutch CL2. Note that the timing when the clutch CL2 is turned on may be when the leading edge of the preceding sheet reaches the first standby position x0. The leading edge of the preceding sheet passes through the first standby position x0 and the competition point 203, and further toward the second standby position x1. That is, in the modification, the sheet does not stop at the first standby position x0.

  T401: When the succeeding sheet arrives at the registration roller pair 16, the CPU 104 switches off the clutch CL2 and starts adjusting the conveyance speed by the registration roller pair 16. That is, when the leading edge of the preceding sheet reaches a position (interruption position) downstream of the conveyance roller pair 53 and upstream of the second standby position x1, the preceding sheet stops. This interruption position is also a standby position. Note that the CPU 104 also stops the motor M1 during the period in which the conveyance speed is being adjusted. As a result, it is possible to avoid the leading sheet from being bent due to the conveyance roller pair 52 pushing the trailing edge of the preceding sheet downstream.

  T402: When the leading edge of the succeeding sheet reaches the speed stable point 202, the CPU 104 ends the speed adjustment. The CPU 104 returns the conveyance speed of the registration roller pair 16 to the conveyance speed of the image forming unit. Further, the CPU 104 causes the motor M1 to rotate forward again and turns on the clutch CL2. Thereby, the conveyance of the preceding sheet in the sub conveyance path r2 is resumed.

  T403: When the trailing edge of the preceding sheet passes the reversal point (reversing roller pair 50), the CPU 104 switches the motor M1 from normal rotation to reverse rotation. Thereby, the reverse roller pair 50 prepares for the arrival of the succeeding sheet.

  T404: When the leading edge of the preceding sheet reaches the second standby position x1, the CPU 104 disconnects the clutch CL2. As a result, the power of the motor M3 is not transmitted to the conveying roller pair 53, the leading edge of the preceding sheet is positioned at the second standby position x1, and the preceding sheet stops in the sub-conveying path r2.

  T405: The subsequent sheet on which the image is formed on the first surface is conveyed toward the reversal point 201, and the leading edge of the subsequent sheet eventually reaches the reversal point 201.

  As described above, in the case where the feeding of the subsequent sheet is set late by design, the CPU 104 may convey the preceding sheet further downstream without stopping at the first standby position x0. However, when the leading edge of the succeeding sheet arrives at the registration roller pair 16, the CPU 104 turns off the clutch CL2, stops the motor M1, and interrupts the transport of the preceding sheet. As a result, the load on the preceding sheet due to the difference in the conveyance speed between the conveyance roller pairs 51 and 53 does not occur.

Sub-transport path length FIG. 19A shows the standby state of the preceding sheet in the sub-transport path r2 of the third embodiment. FIG. 19B shows the position of the succeeding sheet when the preceding sheet is conveyed to the merging point 200. In the case of a Letter sheet, the leading edge of the preceding sheet is stopped for the first time at the first standby position x0. The first standby position x0 is a position upstream from the competition point 203 by a distance La. When the leading edge of the succeeding sheet reaches the speed stable point 202, the transport of the preceding sheet is resumed, and the second stop is performed at the second standby position x1. Further, the second standby position x1 is a position upstream from the junction 200 by a distance La. Here, the distance La is obtained from experimental results and simulations of variations in sheet conveyance. As shown in FIG. 19A, the distance Ls from the rear end of the Letter sheet whose leading end is located at the second standby position x1 to the inversion point 201 is also determined in consideration of the conveyance variation. That is, Ls is determined so that the rear end is located downstream of the reversal point 201 even if the assumed conveyance variation occurs.

The distance Ldup4 from the competition point 203 to the inversion point 201 is expressed by the following equation.
Ldup4 = Lltr + Ls−Lc + La (3)
Here, Lc is a distance between the first standby position x0 and the second standby position x1. Lc is a distance shorter than the distance L2 from the speed stable point 202 to the inversion point 201 shown in FIG. 19B.

FIG. 19C shows the dimensions of the sub conveyance path r2 of the comparative example shown in FIG. In the comparative example, the rear end of the preceding sheet needs to be positioned downstream from the reversal point 201. This restriction determines the conveyance path length Ldup5.
Ldup5 = La + Lltr + Ls (4)
Therefore, the sub-transport path length of the third embodiment is shorter by the distance Lc than the sub-transport path length of the comparative example.

  In the third embodiment, the circulation number is two, but may be three or more. That is, the present invention can be applied to the case where the preceding sheet exists at the reversal point 201 when the leading edge of the succeeding sheet passes the speed stable point 202. In this case, it is sufficient that the trailing edge of the preceding sheet passes through the inversion point 201 until the leading edge of the subsequent sheet reaches the inversion point 201. That is, another sheet may exist in the sub transport path r2.

  In the third embodiment, the CPU 104 may change the number of circulating sheets depending on the length of the sheet. For example, the CPU 104 may set the number of circulating sheets to three when the sheet length is shorter than a predetermined length, and may set the number of circulating sheets to two when the sheet length is longer than the predetermined length. Good. The predetermined length serving as the threshold may be set according to the length of the conveyance path.

In the third exemplary embodiment, a configuration in which the conveyance roller pair 51 is omitted and the sheet is conveyed directly from the reverse roller pair 50 to the conveyance roller pair 53 may be employed.
Further, the image forming method is not limited to the electrophotographic method, and may be an ink jet method or the like.

<Summary>
According to the present exemplary embodiment, the paper feeding device 12 is an example of a paper feeding unit that feeds a sheet to the main transport path r1. The exposure device 7, the process cartridge, and the secondary transfer unit 80 are an example of an image forming unit that forms an image on a sheet conveyed through the main conveyance path r1. The reversing unit 70 including the reversing roller pair 50 is an example of a reversing unit that pulls in the sheet that has been transported through the main transport path r1 and feeds the sheet to the sub transport path r2 by reversing the transport direction of the sheet. The reversing unit 70 forms an image by the image forming unit, pulls in the sheet conveyed from the main conveyance path, and after the trailing edge of the sheet passes through the branch point between the main conveyance path and the sub conveyance path, the sheet conveyance direction Is an example of reversing means for reversing and feeding the sheet to the sub-conveying path. The conveyance roller pairs 51, 52, 53 and the like are an example of a conveyance unit that conveys a sheet sent to the sub conveyance path r2 to the main conveyance path r1. The conveyance roller pairs 51, 52, 53 and the like are an example of a conveyance unit that conveys the sheet fed to the sub conveyance path by the reversing unit from the junction of the sub conveyance path and the main conveyance path to the main conveyance path again. The CPU 104 and the motor drive unit 111 are examples of a control unit that controls the reversing unit and the conveying unit. The CPU 104 and the motor drive unit 111 are an example of a control unit that controls the reversing unit and the conveying unit so that the first sheet fed into the sub conveying path by the reversing unit is placed on standby in the sub conveying path so as to straddle the branch point.

  As shown in FIG. 5D and the like, the CPU 104 sets the reversing unit and the conveying unit so that the first sheet P1 waits on the downstream side of the sub conveying path r2 and the second sheet P2 waits so as to close the reversing point 201. To control. This brings about the effect of shortening the sub-transport path length and the downsizing of the image forming apparatus. The reversal point 201 is an example of a connection portion of the main transport path r1, the sub transport path r2, and the reversing unit on the upstream side of the sub transport path r2.

  The CPU 104 causes the leading end of the third sheet P3 to reach the connecting portion after the trailing end of the third sheet P3 fed from the sheet feeding means passes through the junction between the main transport path r1 and the sub transport path r2. By the time, the conveyance of the first sheet P1 and the second sheet P2 to the downstream side of the sub conveyance path r2 is resumed. With this control, even if the sub-transport path length is shortened, contact between sheets is less likely to occur. Note that when the two-sheet circulation mode is adopted, the first sheet and the second sheet are the same sheet. In the circulation mode in which four or more sheets are circulated in the circulation path, one or more sheets exist between the first sheet and the second sheet.

  According to the present embodiment, the maximum number of sheets that can be simultaneously accommodated in the circulation path formed by the reversing unit 70, the sub conveyance path r2, and the main conveyance path r1 is N sheets. N is an integer of 2 or more. While the rear end of the third sheet P3 passes through the merge point 200, the second sheet P2 stands by across the reversing unit 70 and the reversing point 201. That is, the reversing point 201 that is the exit of the main transport path r1 and the entrance of the reversing unit 70 is blocked by the second sheet P2. Of the N sheets, (N-1) sheets excluding the third sheet P3 are waiting in the sub-transport path r2.

  The length Ldup of the sub-transport path r2 is the length from the reversal point 201 to the junction point 200. In Example 1, the length Ldup1 of the sub-transport path r2 is the sum of the lengths of (N-1) sheets and the sum of the lengths between adjacent sheets in (N-1) sheets, It is shorter than the sum of the distance from the junction point 200 to the standby position where the leading edge of the first sheet P1 waits. This is illustrated in FIG. 8A. Therefore, according to FIG. 8A, the rear end region of the second sheet P2, which is the last sheet, is positioned upstream of the reversal point 201. Thereby, the sub-transport path length is shortened.

  The CPU 104 conveys the standby first sheet to the main conveyance path by the conveyance unit after the trailing end of the second sheet following the first sheet fed from the sheet feeding unit passes the merging point, Before the second sheet reaches the branch point, the rear end of the first sheet may be moved downstream from the branch point. In addition, the CPU 104 may control the reversing unit and the conveying unit so that the first sheet waiting on the upstream side of the image forming unit is made to wait again after the waiting first sheet is conveyed to the main conveying path by the conveying unit. .

  The CPU 104 may have first detection means for detecting a sheet that passes through the junction 200. The first detection means may be a sheet sensor provided at the junction 200. The first detection unit may be a counter that counts the number of drive pulses supplied to a motor involved in sheet conveyance. When the counter value reaches a predetermined value corresponding to the merging point 200, the CPU 104 detects that the leading edge of the sheet has arrived at the merging point 200 or detects that the trailing edge has passed. The registration roller pair 16 is an example of a registration roller that is provided in the main conveyance path r1 and feeds a sheet to the image forming unit.

  When the CPU 104 recognizes that the trailing edge of the third sheet P3 being conveyed by the registration roller pair 16 has passed through the joining point 200 based on the detection result of the first detecting means, the CPU 104 resumes driving of the conveying means. One sheet P1 is fed from the sub transport path r2 to the main transport path r1. As a result, the CPU 104 can further convey the second sheet P <b> 2 that has blocked the reversal point 201 to the downstream side, and can open the reversal point 201. Note that the CPU 104 may stop the conveyance of the first sheet P1 and the second sheet P2 by the conveying unit when the leading edge of the first sheet reaches the registration roller pair 16. This is because the arrival timing of the first sheet P1 with respect to the secondary transfer unit 80 is synchronized with the arrival timing of the toner image.

  The CPU 104 forwardly rotates the reverse roller pair 50 that is the roller of the reversing unit 70 based on the fact that the trailing edge of the third sheet P3 conveyed by the registration roller pair 16 has passed the joining point 200. The sheet P2 is moved to the downstream side of the sub conveyance path r2. Further, when the trailing edge of the second sheet P2 passes through the reversing unit 70 and the reversing point 201, the CPU 104 reverses the rollers of the reversing unit 70. Thereby, the acceptance posture of the 3rd sheet P3 to the inversion part 70 is prepared.

  The CPU 104 may further include a second detection unit that detects a sheet passing through the reversal point 201. The second detection unit may be a sheet sensor 61 that detects a sheet passing through the reversal point 201. The second detection unit may be a counter that counts the number of drive pulses supplied to a motor involved in sheet conveyance. When the counter value reaches a predetermined value corresponding to the merge point 200, the CPU 104 detects that the leading edge of the sheet has arrived at the reversal point 201 or detects that the trailing edge has passed. The CPU 104 may recognize that the trailing edge of the second sheet P2 that goes to the downstream side of the sub-transport path r2 has passed the reversal point 201 based on the detection result of the second detection unit.

  When the CPU 104 resumes driving of the conveyance roller pair 53 in order to send the first sheet P1 to the main conveyance path r1, the sheet feeding device 12 may prohibit the sheet feeding. As a result, it is possible to avoid contact between the sheet fed from the sheet feeding device 12 and the sheet fed again from the sub-transport path r2.

  When the sheet length in the sheet conveyance direction is shorter than the predetermined length, the CPU 104 sets the number of sheets waiting in the sub conveyance path to two, and the sheet length in the sheet conveyance direction is the predetermined length. If it is longer than this, the number of sheets waiting in the sub-transport path may be set to one. The distance from the junction point to the branch point in the main conveyance path may be longer than the sheet length in the sheet conveyance direction.

  As described with reference to FIG. 10, the CPU 104 waits at the end of the (N−1) sheets for the timing of resuming the conveyance of the (N−1) sheets waiting in the sub-transport path r2. It may be determined according to the type of the second sheet P2. For example, if the second sheet is a sheet having low conveyance efficiency, the CPU 104 stands by in the sub-conveyance path r2 when the trailing edge of the third sheet passes the junction point 200 (N−1) sheets. Resume sheet conveyance. If the second sheet is a sheet with high conveyance efficiency, the CPU 104 stands by in the sub conveyance path r2 when the trailing edge of the third sheet toward the reversing unit 70 passes the reversal point 201 (N-1). ) Restart conveyance of sheets. Therefore, since the preceding sheet feeding is executed for a type of sheet having a relatively low conveyance efficiency such as thick paper or glossy paper, contact between sheets at the reversal point 201 is less likely to occur. If the sheet is of a type having high conveyance efficiency such as plain paper or thin paper, the preceding paper feed may not be executed. This is because a sheet having a high conveyance efficiency is less likely to block the reversal point 201.

  As shown in FIG. 5A and the like, the distance between the junction point 200 and the reversal point 201 in the main conveyance path r1 is longer than the sheet length in the sheet conveyance direction. Accordingly, the Nth sheet can move on the main transport path r1 while N−1 sheets are waiting on the sub transport path r2.

  As described with reference to FIGS. 12 and 13, the conveyance roller pair 51 is an example of a first conveyance unit that conveys the sheet that has been sent to the sub conveyance path r <b> 2 by the reversing unit 70. The conveyance roller pair 53 is provided downstream of the first conveyance unit in the conveyance direction of the sheet in the sub conveyance path r2, and conveys the sheet to the junction 200 between the sub conveyance path r2 and the main conveyance path r1. It is an example. The registration roller pair 16 is provided between the junction 200 and the secondary transfer unit 80, which is an image forming unit, in the main conveyance path r1, and is an example of a third conveyance unit that conveys the sheet while adjusting the sheet conveyance speed variably. It is. The motor M3 is an example of a first drive unit that drives the second transport unit and the third transport unit. The CPU 104 is an example of a control unit that controls the reversing unit 70, the first transport unit, and the first drive unit. As shown in FIG. 14C, the CPU 104 moves the sheet fed to the sub conveyance path r <b> 2 by the reversing unit 70 in the second conveyance unit r <b> 2 until the variable adjustment of the conveyance speed of the third conveyance unit is completed. It is made to wait at the first standby position x0 on the upstream side. When the variable adjustment of the conveyance speed of the third conveyance unit is completed, the CPU 104 conveys the sheet to the downstream side of the second conveyance unit. As a result, the load on the sheet due to the transport roller pairs 51 and 53 having temporarily different transport speeds is reduced.

  When the variable adjustment of the conveyance speed of the third conveyance unit is completed, the CPU 104 conveys the sheet waiting at the first standby position x0 to the second standby position x1 positioned downstream from the second conveyance unit, and the sheet At the second standby position x1. As a result, as shown in FIG. 14F, the succeeding sheet can go to the reversing unit 70 without contacting the preceding sheet.

  The clutch CL2 is an example of a clutch that connects or disconnects the second transport unit to the first drive unit. The CPU 104 waits the sheet at the second standby position X1 by disconnecting the first driving unit from the second conveying unit by the clutch CL2. As a result, the registration roller pair 16 and the conveyance roller pair 53 can be driven by a single motor, and the number of motors can be reduced.

  As shown in FIG. 13, the motor M1 is an example of a second drive unit that drives the reversing unit 70 and the first transport unit. The clutch CL1 transmits the driving force of the second driving means to the first conveying means when the second driving means is rotating forward, and the driving force of the second driving means when the second driving means is rotating reversely. Is an example of a one-way clutch that does not transmit to the first conveying means. As a result, the reverse roller pair 50 and the transport roller pair 51 can be driven by a single motor, and the number of motors can be reduced. That is, even if the reverse roller pair 50 and the transport roller pair 51 are driven by a single motor, the reverse rotation of the reverse roller pair 50 can be started at an early stage by employing the one-way clutch. The clutches CL1 and CL2 may be electromagnetic clutches that can be disconnected / connected by a solenoid or the like.

  As shown in FIG. 16, the CPU 104 determines that the trailing edge of the last sheet in the sub-transport path r2 is the reversal point 201 that connects the main transport path r1, the sub-transport path r2, and the reversing unit 70 in the sub-transport path r2. If it is also conveyed downstream, the second drive means is reversed. Thereby, the acceptance posture of the succeeding sheet to the reversing unit 70 is adjusted. As shown in FIG. 19A, the length of the sheet in the sheet conveyance direction may be shorter than or equal to the distance from the entrance of the sub conveyance path r2 to the second standby position.

The registration roller pair 16 is also an example of a first transport unit that transports a sheet in the main transport path by changing the transport speed of the sheet fed from the paper feed unit from the first speed to the second speed. The exposure device 7, the process cartridge, and the secondary transfer unit 80 are an example of an image forming unit that forms an image on a sheet conveyed at a second speed from the first conveying unit. The reversing unit 70 forms an image by the image forming unit, pulls in the sheet conveyed from the main conveyance path, and changes the sheet conveyance direction after the trailing edge of the sheet passes through a branch point between the main conveyance path and the sub conveyance path. It is an example of a reversing unit that reverses and feeds a sheet to a sub-conveying path. The conveyance roller pair 53 is an example of a second conveyance unit that conveys the sheet fed to the sub conveyance path by the reversing unit from the sub conveyance path to the main conveyance path again. The motor M3 is an example of a drive source that drives the first transport unit and the second transport unit. The CPU 104 is an example of a control unit that controls the reversing unit and the second conveying unit so that the first sheet fed into the sub conveying path by the reversing unit is made to wait on the upstream side of the second conveying unit in the sub conveying path. The CPU 104 reverses the waiting first sheet according to the timing when the first conveying unit completes the change of the conveying speed of the second sheet following the first sheet from the first speed to the second speed. The second sheet may be conveyed to the second conveying means, and the rear end of the first sheet may be moved downstream of the branch point before the second sheet reaches the branch point. The CPU 104 conveys the waiting first sheet to the downstream of the second conveying means by the reversing means, and then reverses the first sheet again on the upstream side from the junction of the sub conveying path and the main conveying path. The second conveying means may be controlled. Clutch CL2 is an example of a clutch for transmitting or interrupting a driving force from a driving dynamic source for the second conveying means. The CPU 104 may control the clutch so that the first sheet is made to wait again on the upstream side from the merging point by blocking the driving force from the driving source with respect to the second conveying unit by the clutch.

  The conveyance roller pair 51 is an example of a third conveyance unit that conveys the sheet sent to the sub conveyance path by the reversing unit to the second conveyance unit. The motor M1 is an example of a second drive source that drives the reversing unit and the third transport unit. The clutch CL1 transmits the driving force of the second driving source to the third transport means when the second driving source is rotating forward, and the driving force of the second driving source when the second driving source is rotating backward. It is an example of the one-way clutch which is not transmitted to a 3rd conveyance means.

  The sheet sensor 62 is an example of a detection unit that is provided between the sheet feeding unit and the image forming unit and detects a sheet conveyed on the main conveyance path. The CPU 104 sets the first speed based on the timing at which the leading edge of the second sheet is detected by the detecting means, changes the sheet conveying speed by the first conveying means from the second speed to the first speed, and further The speed may be changed from the first speed to the second speed.

  As described with respect to the modified example, when the sheet fed to the sub-transport path r2 by the reversing unit 70 is transported by the transport roller pair 53, variable adjustment of the transport speed of the registration roller pair 16 is started. There may also be an image forming apparatus. In this case, the CPU 104 interrupts the sheet conveyance by cutting the conveyance roller pair 53 from the motor M3 by the clutch CL2. When the variable adjustment of the conveyance speed of the registration roller pair 16 is completed, the CPU 104 resumes the conveyance of the sheet by connecting the motor M3 and the conveyance roller pair 53 with the clutch CL2. Further, the CPU 104 again disconnects the conveyance roller pair 53 from the motor M3 by the clutch CL2 so that the leading end of the sheet stops at the standby position upstream of the junction 200. As a result, the load on the sheet due to the transport roller pairs 51 and 53 having temporarily different transport speeds is reduced.

  The CPU 104 stops the normal rotation of the reversing unit 70 and the conveyance roller pair 51 when the conveyance roller pair 53 is cut from the motor M3 by the clutch. When the conveying roller pair 53 is connected to the motor M3 by the clutch CL2, the CPU 104 resumes normal rotation of the reversing unit 70 and the conveying roller pair 51. As a result, the load on the sheet by the conveying roller pairs 51 and 53 is reduced.

  The CPU 104 temporarily increases or decreases the conveyance speed of the registration roller pair 16 so that the timing at which the sheet arrives at the toner image transfer position and the timing at which the toner image arrives at the transfer position are synchronized. When the conveyance speed of the registration roller pair 16 matches the conveyance speed of the image forming unit (intermediate transfer belt 8), the CPU 104 completes the variable adjustment of the conveyance speed of the registration roller pair 16. In the case where the registration roller pair 16 and the transport roller pair 53 are driven by the same motor, the transport speed of the transport roller pair 53 is temporarily increased or decreased. As a result, a mismatch occurs between the conveyance speed of the conveyance roller pair 53 and the conveyance speed of the conveyance roller pair 51, and a load may be applied to the sheet conveyed across the conveyance roller pair 53 and the conveyance roller pair 51. Therefore, it is worth applying this embodiment.

  The CPU 104 changes the sheet conveying speed from the second speed to the first speed while the second conveying means conveys the first sheet that has been sent to the sub conveying path by the reversing means. In this case, the clutch may be controlled such that the driving force from the driving source is interrupted by the clutch with respect to the second conveying unit, and the first sheet is made to wait in the sub conveying path. Here, the waiting first sheet straddles the branch point. The CPU 104 applies the driving force from the driving source by the clutch according to the timing when the first conveying unit completes the change of the conveying speed of the second sheet following the first sheet from the first speed to the second speed. The rear end of the first sheet may be moved downstream of the branch point before the second sheet reaches the branch point. The CPU 104 conveys the waiting first sheet by the second conveying unit, and then interrupts the driving force from the driving source with respect to the second conveying unit by the clutch, so that the auxiliary conveying path and the main conveying path are separated. You may make a 1st sheet | seat wait again upstream from a junction.

  It should be noted that the numbers such as first, second, and third given to the technical terms described above are only given to distinguish the same or similar technical terms. Each number can be replaced with another number. For example, the first transport unit may be referred to as a third transport unit. The number in the claims may be the same as or different from the number in the specification. For example, the first conveying means described in the claims may be described as a third conveying means in the specification. Thus, the number itself has no technical meaning.

  DESCRIPTION OF SYMBOLS 100 ... Image forming apparatus, 12 ... Paper feeding apparatus, 8 ... Intermediate transfer belt, 50 ... Reversing roller pair, 51-53 ... Conveying roller pair, 104 ... CPU, 201 ... Reversing point, 200 ... Confluence

Claims (13)

A feeding means for feeding the sheet to the main conveyance path;
Changing the conveyance speed of the sheet fed from the feeding means from a first speed to a second speed, and conveying the sheet in the main conveyance path;
Image forming means for forming an image on the sheet conveyed at the second speed from the first conveying means;
After the image is formed by the image forming unit, the sheet conveyed from the main conveyance path is pulled in, and after the trailing edge of the sheet passes through a branch point between the main conveyance path and the sub conveyance path, the conveyance direction of the sheet Reversing means for reversing and feeding the sheet to the sub-transport path,
Second conveying means for conveying the sheet sent to the sub conveying path by the reversing means from the sub conveying path to the main conveying path again;
A driving source for driving the first conveying means and the second conveying means;
Control means for controlling the reversing means so that the first sheet fed into the sub conveying path by the reversing means is made to wait on the upstream side of the second conveying means in the sub conveying path;
When the waiting first sheet spans the branch point,
The control unit waits according to a timing at which the first transport unit completes a change in the transport speed of the second sheet following the first sheet from the first speed to the second speed. The first sheet is conveyed to the second conveying means by the reversing means, and the rear end of the first sheet is located downstream of the branch point before the second sheet reaches the branch point. An image forming apparatus that is moved. The control means transports the waiting first sheet to the downstream of the second transport means by the reversing means, and then the first sheet is located upstream of the junction of the sub transport path and the main transport path. The image forming apparatus according to claim 1 , wherein the reversing unit and the second conveying unit are controlled so as to wait for one sheet again. A clutch for transmitting or interrupting the driving force from the driving source to the second conveying means;
The control means shuts off the driving force from the driving source with respect to the second conveying means by the clutch, so that the reversing means and the reversing means are made to wait again on the upstream side from the merging point. The image forming apparatus according to claim 2 , wherein the second conveying unit is controlled. Third conveying means for conveying the sheet fed to the sub-conveying path by the reversing means to the second conveying means;
A second drive source for driving the reversing means and the third conveying means;
When the second drive source is rotating forward, the driving force of the second drive source is transmitted to the third transport means, and when the second drive source is rotating reversely, the second drive source is driven. the image forming apparatus according to any one of claims 1 to 3, further comprising a one-way clutch which does not transmit force to said third transport means. A detecting unit that is provided between the feeding unit and the image forming unit and detects a sheet conveyed through the main conveying path;
The control means sets the first speed based on the timing at which the leading edge of the second sheet is detected by the detection means, and sets the conveyance speed of the sheet by the first conveyance means from the second speed to the first speed. change into single speed, further image forming apparatus according to any one of claims 1 to 4, characterized in that changing from the first speed to the second speed. When the length of the sheet in the sheet conveyance direction is shorter than a predetermined length, the control unit sets the number of sheets waiting in the sub conveyance path to two, and the sheet in the sheet conveyance direction If the length of longer than the predetermined length, the image forming apparatus according to any one of claims 1 to 5, characterized in that setting the number of sheets to be waiting in the sub-passage on one . The length of the sheet in the conveying direction of the sheet, according to claim 1 to 6, characterized in that shorter than the distance from the branch point in the sub-passage to the junction of the main transport path and the sub-passage The image forming apparatus according to any one of the above. A feeding means for feeding the sheet to the main conveyance path;
The conveyance speed of the sheet fed from the feeding means is changed from the second speed to the first speed, and further changed from the first speed to the second speed, and the sheet is moved in the main conveyance path. First conveying means for conveying;
Image forming means for forming an image on the sheet conveyed at the second speed from the first conveying means;
After the image is formed by the image forming unit, the sheet conveyed from the main conveyance path is pulled in, and after the trailing edge of the sheet passes through a branch point between the main conveyance path and the sub conveyance path, the conveyance direction of the sheet Reversing means for reversing and feeding the sheet to the sub-transport path,
Second conveying means for conveying the sheet sent to the sub conveying path by the reversing means from the sub conveying path to the main conveying path again;
A driving source for driving the first conveying means and the second conveying means;
The second conveying means conveys the clutch that transmits or interrupts the driving force from the driving source to the second conveying means, and the first sheet that has been sent to the sub conveying path by the reversing means. In the meantime, when the first conveying means changes the sheet conveying speed from the second speed to the first speed, the clutch cuts off the driving force from the driving source from the second conveying means. And a control means for controlling the clutch so as to make the first sheet stand by in the sub conveyance path,
When the waiting first sheet spans the branch point ,
The control means is configured such that the first conveying means changes the conveying speed of the second sheet following the first sheet from the first speed to the second speed by the clutch according to the timing. A driving force from a driving source is transmitted to the second conveying means, and the rear end of the first sheet is located downstream of the branch point before the second sheet reaches the branch point. An image forming apparatus that is moved. The control means, after the waiting first sheet is conveyed by the second conveying means, the driving force from the driving source is cut off from the second conveying means by the clutch, 9. The image forming apparatus according to claim 8 , wherein the second conveying unit and the clutch are controlled so that the first sheet is made to wait again on the upstream side of the confluence of the sub conveying path and the main conveying path. . Third conveying means for conveying the sheet fed to the sub-conveying path by the reversing means to the second conveying means;
A second drive source for driving the reversing means and the third conveying means;
When the second drive source is rotating forward, the driving force of the second drive source is transmitted to the third transport means, and when the second drive source is rotating reversely, the second drive source is driven. A one-way clutch that does not transmit force to the third conveying means;
The image forming apparatus according to claim 8 or 9, characterized in that it further comprises a. A detecting unit that is provided between the feeding unit and the image forming unit and detects a sheet conveyed through the main conveying path;
The control means sets the first speed based on the timing at which the leading edge of the second sheet is detected by the detection means, and sets the conveyance speed of the sheet by the first conveyance means from the second speed to the first speed. change into single speed, further image forming apparatus according to any one of claims 8 to 10, characterized in that changing from the first speed to the second speed. When the length of the sheet in the sheet conveyance direction is shorter than a predetermined length, the control unit sets the number of sheets waiting in the sub conveyance path to two, and the sheet in the sheet conveyance direction If the length of longer than the predetermined length, the image forming apparatus according to any one of claims 8 to 11, characterized in that setting the number of sheets to be waiting in the sub-passage on one . The length of the sheet in the conveying direction of the sheet, according to claim 8 to 12, wherein the shorter than the distance from the branch point in the sub-passage to the junction of the main transport path and the sub-passage The image forming apparatus according to any one of the above.

Images