JP2022189272A - Image forming apparatus - Google Patents

Abstract

To provide an image forming apparatus adapted to suppress the sheet transport speed from varying due to an urging force of an urge member in a configuration to drive cam and transport members by a common motor.SOLUTION: An image forming apparatus comprises a first drive transmission unit that transmits a drive force of a motor to a first transport member, a second drive transmission unit that is connected to the motor through at least a part of the first drive transmission unit and transmits the drive force transmitted from the first drive transmission unit to a cam member, and a third drive transmission unit that is connected to the motor through at least a part of the first drive transmission unit and transmits the drive force transmitted from the first drive transmission unit to the second transport member. The third drive transmission unit has a clutch allowed to switch over between a coupling state to transmit a drive force to the second transport member and a cancellation state to cancel the drive transmission to the second transport member. Control means places the clutch in a coupling state if rotating the cam member during transport of a preceding sheet by the first transport member and executing feeding of a succeeding sheet by the feed member.SELECTED DRAWING: Figure 5

Description

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

An image forming apparatus such as a printer, a copier, a printer, a multifunction machine, or the like includes a sheet feeding device for feeding sheets used as recording materials one by one, a conveying member such as a pair of conveying rollers for conveying the fed sheet, and a sheet conveying mechanism. The sheet feeding device includes a sheet stacking portion on which sheets are stacked, a feeding member (pickup roller, feeding roller) for feeding the sheet from the sheet stacking portion, and a feeding member for the sheet on the sheet stacking portion. and an urging member such as a spring for contacting with a sufficient pressure. Further, some sheet feeding devices are provided with a cam mechanism for bringing the feeding member into contact with and separating from the sheets on the sheet stacking portion. As for the cam mechanism, there is a system in which an up-and-down arm member that holds the feeding member moves up and down as the cam member rotates, and a system in which the up-and-down sheet stacking section (intermediate plate) moves up and down as the cam member rotates. and are known.

By the way, in recent years, in order to reduce costs, a configuration in which a single motor drives a plurality of driving targets in a sheet conveying mechanism is often adopted. In this case, the driving force output from the motor is transmitted to a driving object such as a feeding member, a conveying member, or a cam member via a drive transmission device such as a gear train. Here, when the feeding member or the sheet stacking portion is moved up and down by the cam member, the biasing force of the biasing member may act on the drive transmission device via the cam member. When the driving speed of the driven object other than the cam member connected to the drive transmission device changes due to the biasing force of the biasing member acting through the cam member, the sheet conveying speed fluctuates, resulting in image transfer. Inconvenience such as image blurring may occur.

In Patent Document 1, in an image forming apparatus in which a feed cam and a photosensitive drum are driven by a single motor, a helical gear is used as a gear that rotates together with the feed cam, and a brake pad is attached to the side surface of the gear. configuration is described. According to this document, when the feeding cam, which receives the bias force of the spring for raising and lowering the intermediate plate, tries to rotate faster than the driving speed of the motor, the thrust force generated on the meshing surface of the helical gear causes the brake pad to move. Abutting against the abutment wall, the feeding cam receives a braking force. As a result, the biasing force of the spring is suppressed from being transmitted to the drive transmission device via the feed cam, and speed fluctuations of the photosensitive drum and the like are suppressed.

JP 2015-197181 A

However, the configuration of the above-mentioned document, for the purpose of suppressing the transmission of the urging force of the spring to the drive transmission device, has accepted the increase in cost and the size of the device due to the additional arrangement of brake pads and the like. .

Accordingly, the present invention provides an image forming apparatus having a new configuration capable of suppressing fluctuations in the sheet conveying speed due to the biasing force of the biasing member in a configuration in which the cam member and the conveying member are driven by a common motor. intended to

According to one aspect of the present invention, a sheet stacking portion on which sheets are stacked and a feeding member that feeds the sheets stacked on the sheet stacking portion are rotated so that the feeding member is rotated by the sheet stacking portion. a cam member configured to switch between a state in which the feeding member is in contact with the upper sheet and a state in which the feeding member is separated from the sheet on the sheet stacking portion; an urging member for generating an urging force for pressing the feeding member against the sheet in a contacting state; a first conveying member for conveying the sheet fed by the feeding member; A second conveying member arranged on a conveying path different from a conveying path to the first conveying member for conveying the sheet, a motor, and a first drive transmission section for transmitting the driving force of the motor to the first conveying member. a second drive transmission section connected to the motor through at least a portion of the first drive transmission section for transmitting the driving force transmitted from the first drive transmission section to the cam member; A third drive transmission section connected to the motor through at least a part of the first drive transmission section and transmitting the driving force transmitted from the first drive transmission section to the second conveying member, a third drive transmission unit having a clutch capable of switching between a connected state of transmitting the driving force to the second conveying member and a released state of canceling the drive transmission to the second conveying member; and controlling the motor and the clutch. and a control means, wherein the control means rotates the cam member while the preceding sheet is being conveyed by the first conveying member to cause the feeding member to feed the succeeding sheet, the control means controlling the clutch. in the connected state.

According to the present invention, there is provided an image forming apparatus having a new configuration capable of suppressing variations in the sheet conveying speed due to the biasing force of the biasing member in the configuration in which the cam member and the conveying member are driven by a common motor. can do.

1 is a cross-sectional view showing an image forming apparatus according to a first embodiment; FIG. 4 is a perspective view of the sheet conveying mechanism according to the first embodiment; FIG. FIG. 2 is a perspective view showing the sheet conveying mechanism according to the first embodiment in a state separated for each drive train; FIG. 4 is a top view of the driving section of the sheet conveying mechanism according to the first embodiment; FIG. 4 is a schematic diagram showing the driving configuration of the sheet conveying mechanism according to the first embodiment; FIG. 4A is a side view showing a registration drive train of the sheet conveying mechanism according to the first embodiment, and FIG. 4B is a side view showing a feeding drive train; 4A to 4D are side views (a to d) for explaining the operation of the feeding cam according to the first embodiment; FIG. 4A and 4B are enlarged views showing the meshing portion of the gear according to the first embodiment; FIG. 4 is a flowchart showing an example of control of the sheet conveying mechanism according to the first embodiment; FIG. 4 is a schematic diagram showing a driving configuration of a sheet conveying mechanism of a reference example; FIG. 8 is a schematic diagram showing the driving configuration of a sheet conveying mechanism according to the second embodiment; FIG. 11 is a schematic diagram showing the driving configuration of a sheet conveying mechanism according to the third embodiment; FIG. 8A is a perspective view of a sheet feeding device according to a fourth embodiment, and FIG. 10A and 10B are side views for explaining the operation of the feed cam according to the fourth embodiment; FIG.

Hereinafter, embodiments according to the present disclosure will be described with reference to the drawings.

<First Embodiment>
An image forming apparatus 1 according to the first embodiment will be described with reference to FIGS. 1 to 9. FIG. Here, a color laser beam printer is exemplified as the image forming apparatus 1 . Further, the image forming apparatus 1 primarily transfers toner images formed on a plurality of image carriers (electrophotographic photosensitive members) to an intermediate transfer member, and then secondarily transfers the toner images collectively from the intermediate transfer member onto a sheet S. An intermediate transfer electrophotographic image forming unit 102 is provided as an image forming unit.

Note that the "image forming apparatus" may be a copying machine, a multifunction machine, or a facsimile machine. The image forming method does not need to be an electrophotographic method, and may be another image forming method such as an electrostatic recording method or an inkjet method. The sheet S, which is the recording material, includes paper such as plain paper and thick paper, surface-treated sheet materials such as plastic films, cloth, and coated paper, and sheet materials with special shapes such as envelopes and index paper. And various sheet materials of different materials can be used.

(Overall Configuration of Image Forming Apparatus)
The overall configuration of the image forming apparatus 1 will be described with reference to FIG. FIG. 1 is a cross-sectional view showing a schematic configuration of an image forming apparatus. An apparatus main body 101 of the image forming apparatus 1 is equipped with an image forming section 102 including four process units P1, P2, P3, and P4 each having a photosensitive drum 2 as an image carrier, and an intermediate transfer belt 130. ing. An intermediate transfer belt 130 is arranged below the process units P1 to P4, and a laser scanner 120 as an exposure device is arranged above the process units P1 to P4.

Each of the process units P1 to P4 has a charging device, a developing device, and a cleaning device in addition to the photosensitive drum 2. FIG. The intermediate transfer belt 130 is stretched around a plurality of rollers including the inner secondary transfer roller 105 . A primary transfer roller is arranged on the inner peripheral side of the intermediate transfer belt 130 at a position facing the photosensitive drum 2 with the intermediate transfer belt 130 interposed therebetween. A secondary transfer roller 122 is arranged on the outer peripheral side of the intermediate transfer belt 130 at a position facing the inner secondary transfer roller 105 with the intermediate transfer belt 130 interposed therebetween. A transfer portion (secondary transfer portion T2) for transferring an image onto a recording material is formed as a nip portion between the secondary transfer roller 122 and the intermediate transfer belt 130 .

The image forming apparatus 1 also has a cassette type sheet feeding section 40 and a manual sheet feeding section 400 . The cassette-type sheet feeding section 40 includes a feeding cassette 115 as a sheet stacking section (first sheet stacking section), a pickup roller 116 , a feed roller 117 , and a separation roller 118 . Similarly, the manual sheet feeding unit 400 includes a sheet feeding tray 401 (manual feed tray) as a sheet stacking unit (second sheet stacking unit), a pickup roller 402, a feed roller 403, and a separation roller 421. ,including. Each of the sheet feeding units 40 and 400 feeds out the sheet S set in the feeding cassette 115 or the feeding tray 401 by the pickup rollers 116 and 402, and separates the sheets one by one by the feed rollers 117 and 402 and the separating rollers 118 and 421. while feeding.
feed one sheet at a time

A registration roller (hereinafter referred to as a registration roller 250) is arranged between the cassette-type sheet feeding portion 40 and the secondary transfer portion T2. The manual sheet feeding unit 40 and the registration roller 250 are connected by a conveying path passing through the manual feeding rollers 310, 320, and 330 and the feed rollers 117 and separation rollers 118 of the cassette type sheet feeding unit 40. .

A thermal fixing device including a fixing film 107 and a pressure roller 108 is arranged downstream of the secondary transfer portion T2 in the sheet S conveying direction. A nip forming unit including a heater such as a ceramic heater and a holder for holding the heater is arranged on the inner peripheral side of the fixing film 107 . The pressure roller 108 is pressed against the nip forming unit with the fixing film 107 therebetween to form a fixing nip.

Further downstream of the fixing device, a switching guide 121 and an ejection roller unit including an ejection roller 109, an ejection roller 110 and a reversing roller 119 are arranged. The discharge rollers 109 and the discharge rollers 110 discharge the sheet S conveyed to the outside of the image forming apparatus 1 via a registration roller 250 as a first conveying member or a double-sided conveying roller 124 as a second conveying member, which will be described later. It functions as means (discharge section, discharge roller pair). The discharge roller 109 and the discharge roller 110 of this embodiment discharge the sheet S to the space outside the apparatus main body 101 and stack it on the discharge tray 101a. Note that the discharging means (discharging section, discharging roller pair) for discharging the sheet S to the outside of the image forming apparatus 1 may discharge the sheet toward another apparatus connected to the image forming apparatus 1. . Examples of other apparatuses include a sheet processing apparatus that receives sheets on which images have been formed by the image forming apparatus 1 and performs processing such as binding, and a relay conveying unit that conveys sheets toward other apparatuses. The discharge roller 109 and the reversing roller 119 function as reversing means (a pair of reversing rollers) for reversing and conveying the sheet S when double-sided printing is performed. The switching guide 121 is a flap-shaped guide that switches the conveying path of the sheet S between the discharge side and the reverse side. The nip portion of the discharge roller 109 and the reversing roller 119 and the registration roller 250 are connected via a double-sided transport path 125 . Double-sided conveying rollers 123 and 124 serving as conveying members for conveying the reversely conveyed sheet S toward the image forming portion 102 again are arranged in the double-sided conveying path 125 .

(Image forming operation)
An outline of an image forming operation by the image forming apparatus 1 will be described. When the control unit 100 (FIG. 5) of the image forming apparatus 1 receives image information and an instruction to execute image formation from an external device, the control unit 100 controls each unit of the image forming apparatus 1 according to a predetermined program. The described image forming operation is performed.

When the image forming operation is started, the photosensitive drums 2 and intermediate transfer belt 130 of each of the process units P1 to P4 are driven to rotate. The surface of the photosensitive drum 2 is uniformly charged to a predetermined polarity and potential by a charging device. The laser scanner 120 irradiates the charged surface of the photosensitive drum 2 with laser light modulated based on image information to write an electrostatic latent image on the surface of the photosensitive drum 2 . These electrostatic latent images are developed as toner images by a developer supplied by a developing device. Here, each of the process units P1 to P4 uses different colors of toner contained in the developer, and toner images of four colors of yellow, magenta, cyan, and black are formed on the four photosensitive drums 2 . The toner images are formed in parallel in the process units P1 to P4, and the toner images formed on the photosensitive drums 2 are primarily transferred on the intermediate transfer belt 130 so as to overlap each other. As a result, a full-color toner image is formed on the intermediate transfer belt 130 . The image carried on the intermediate transfer belt 130 is conveyed toward the secondary transfer portion T2 as the intermediate transfer belt 130 rotates.

The pick-up roller 116 and the feed roller 117 are rotationally driven clockwise in FIG. S is delivered. The fed sheet S is sent to the secondary transfer portion T2 by the registration rollers 250 . When the sheet S is fed from the manual sheet feeding unit 400 , the sheet S placed on the feeding tray 401 is fed by the pickup roller 402 and the feed roller 403 . The fed sheet S is transferred to the registration roller 250 via the manual feeding rollers 310, 320, 330 and the feed roller 117, and is sent to the secondary transfer portion T2 by the registration roller 250. FIG.

An image is transferred from the intermediate transfer belt 130 to the sheet S at the secondary transfer portion T2. The sheet S that has passed through the secondary transfer portion T2 is sent to the fixing device, and heat and pressure are applied to the image on the sheet S while being nipped and conveyed between the fixing film 107 and the pressure roller 108 . As a result, an image fixed on the sheet S is obtained by fixing the toner after being melted and color-mixed.

After passing through the fixing device, the sheet S is transported to the transport path guided by the switching guide 121 . In the case of single-sided printing, the sheet S is guided to the nip portion (discharge nip) between the discharge roller 109 and the discharge roller 110 and stacked on the discharge tray 101 a provided on the upper portion of the apparatus main body 101 . In the case of double-sided printing, the sheet S on which an image is formed on the first side is guided to the nip portion (reversal nip) between the ejection roller 109 and the reversing roller 119, and is reversed and conveyed (switchback) by the ejection roller 109 and the reversing roller 119. It is conveyed to the double-sided conveying path 125 . The sheet S conveyed again to the registration rollers 250 in a state in which the first side and the opposite second side are exchanged via the double-sided conveying rollers 123 and 124, while passing through the secondary transfer portion T2 and the fixing device. An image is formed on the second side. The sheet S with the image formed on the second side is guided to the discharge nip by the switching guide 121 and stacked on the discharge tray 101a.

(Sheet feeding section)
The configuration of the sheet feeding unit 40 and the feeding operation of the sheet feeding unit 40 for feeding the sheet S will be described in detail. As shown in FIG. 1, the feed cassette 115 is detachably attached to the lower portion of the apparatus main body 101 . Inside the feed cassette 115 , an intermediate plate 50 that is lifted and lowered by a lift plate 51 is provided, and the sheets S are stored in the feed cassette while being stacked on the intermediate plate 50 . A gear (not shown) is provided at one end of the lift plate 51, and the lift plate 51 is driven by a drive force transmitted to the gear from a middle plate drive train provided in the drive mechanism of the apparatus main body 101. . The intermediate plate drive train is controlled by rotating the intermediate plate drive train based on a detection signal from a sheet surface sensor (not shown) so that the top surface of the sheet S stacked on the intermediate plate 50 is positioned at a predetermined position (pickup roller 116). until it reaches a position where it can be fed by

A pickup roller 116 is a feeding member that feeds the sheet S from the feeding cassette 115 . The pickup roller 116 and feed roller 117 are rotatably supported by a pickup arm 68, which will be described later. The pickup arm 68 is swingable around the roller shaft of the feed roller 117 , and is driven by a feed cam 67 (to be described later) to swing, thereby raising and lowering the pickup roller 116 . As a result, the pickup roller 116 is positioned in a position (contact state) in contact with the sheets S stacked on the intermediate plate 50 (feeding position), and in a position separated upward from the sheet S (standby position). ) (separated state). The pickup arm 68 will be described later with reference to FIGS. 2 and 7. FIG.

The feed roller 117 and the separation roller 118 contact each other to form a separation nip, and constitute a conveying unit (separation roller pair) that separates and conveys the sheets S fed by the feeding member one by one. As the separation roller 118, a roller connected to a shaft fixed to the apparatus main body 101 through a torque limiter can be used. Further, the separating roller 118 may be configured to receive a driving force in a direction opposite to the conveying direction of the sheet S (clockwise direction in the figure) via a torque limiter. may be used as the separation member.

As shown in FIG. 1, before starting the feeding operation, the pickup arm 68 is positioned at the position (upper position) rotated in the R2 direction, whereby the pickup roller 116 is retracted (separated) above the sheet S. doing. When the feeding operation is started, the pickup arm 68 rotates in the R1 direction and moves to a position (lower position) where the pickup roller 116 contacts the sheet S stacked on the intermediate plate 50 . At this time, the pick-up roller 116 abuts (presses) the sheet S with a predetermined pressure suitable for feeding the sheet S due to the biasing force of the pressure spring 69 to be described later. Then, the pick-up roller 116 is rotated clockwise in FIG.

The sheet S fed by the pickup roller 116 is fed into the separation nip between the feed roller 117 and the separation roller 118 and separated one by one by the action of the frictional force received from the separation roller 118 . That is, when one sheet S enters the separation nip, the separation roller 118 rotates following the feed roller 117 while causing the torque limiter to slip. When a plurality of sheets S enter the separation nip, the separation roller 118 stops rotating and restricts the sheets S other than the uppermost sheet S in contact with the feed roller 117 from passing through the separation nip. The sheet S that has passed through the separation nip is further conveyed to the secondary transfer portion via the registration roller 250 as described above, and an image is formed on the sheet surface.

By the way, after the leading edge of the sheet S that has passed through the separation nip reaches the conveying member (here, the registration roller 250) on the downstream side, the pickup arm 68 rotates again in the R2 direction. Then, the pickup roller 116 waits in a state of being retracted (separated) above the sheet S until the next sheet S is to be fed. By repeating the above feeding operation, the sheets S are fed from the sheet feeding portion 40 one by one. Note that the manual sheet feeding unit 400 also has the same configuration as the cassette type sheet feeding unit 40 except that the sheet feeding tray 401 is provided so as to be openable and closable with respect to the apparatus main body 101 .

(Driving Configuration of Sheet Conveying Mechanism)
Next, the driving configuration of the sheet conveying mechanism will be described. FIG. 2 is a perspective view showing the driving configuration of the sheet conveying mechanism 103 according to this embodiment. FIG. 3 is a perspective view showing the sheet conveying mechanism 103 according to the present embodiment in a state separated for each drive train. However, in FIG. 3, illustration of the pickup arm 68 and the pressure spring 69 is omitted.

The sheet conveying mechanism 103 includes a pickup roller 116 as a feeding member, a feeding cam 67 as a cam member, a pressure spring 69 as a biasing member, a registration roller 250 as a first conveying member, and a second conveying member. and double-sided conveying rollers 124 as members. Further, the sheet conveying mechanism 103 includes a pickup arm 68 as an arm member that vertically holds the pickup roller 116 , feed rollers 117 , and double-sided conveying rollers 123 . The pickup roller 116, the feed roller 117, and the pickup arm 68 constitute a feeding unit 104 that feeds the sheet S while raising and lowering the pickup roller 116, as will be described later.

2 and 3 show only the driving rollers to which the driving force from the motor 60 is transmitted, out of the registration roller 250 and the double-sided conveying rollers 123 and 124, which are roller pairs. In this embodiment, one roller of each roller pair is a driving roller, and the other roller is a driven roller that rotates following the driving roller. It may be a roller.

The sheet conveying mechanism 103 also includes a motor 60 as a common drive source for driving the rollers, and a registration drive train (hereinafter referred to as a registration drive train) as a first drive transmission unit for transmitting the driving force of the motor 60 to the registration rollers 250 . register drive row 54). Further, the sheet conveying mechanism 103 includes a double-sided driving train 56 as a third drive transmission unit for transmitting the driving force of the motor 60 to the double-sided conveying rollers 123 and 124, and a third drive train 56 for transmitting the driving force of the motor 60 to the feeding cam 67. 2, a feeding drive train 55 as a drive transmission unit. The feeding drive train 55 transmits driving force not only to the feeding cam 67 but also to the feed roller 117 and the pickup roller 116 . In the present embodiment, the term “drive train” or “drive transmission unit” refers to a drive source that supplies driving force or a drive transmission element on the upstream side, which is mechanically connected to a roller to be driven. refers to a drive transmission mechanism consisting of one or more drive transmission elements that transmit drive force to

The pickup roller 116, the feed roller 117, the registration roller 250, and the double-sided conveying rollers 123 and 124 are rollers that rotate around axes extending substantially parallel to each other. The registration drive train 54, the double-sided drive train 56, and the feed drive train 55 are all provided at one end in the axial direction with respect to the pickup roller 116, the feed roller 117, the registration roller 250, and the double-sided conveying rollers 123 and 124. ing. Hereinafter, the axial direction of these rollers will be referred to as the "axial direction" of the sheet conveying mechanism 103, and the side on which the registration drive train 54, the double-sided drive train 56, and the feeding drive train 55 are provided in the axial direction will be referred to as the "drive side." , and the opposite side is the "non-driving side".

Hereinafter, the configuration of each drive train will be described with reference to FIGS. 4 and 6(a,b). FIG. 4 is a plan view of the drive-side end of the sheet conveying mechanism 103 viewed from a direction perpendicular to the axial direction (from the upper side in FIG. 2). FIG. 6A is a side view of part of the registration drive train 54 and the feed drive train 55 (feed control gear 65 and solenoid 66) viewed from the drive side in the axial direction. FIG. 6B is a side view of the feeding drive train 55 viewed from the drive side in the axial direction.

As shown in FIGS. 3 and 6A, the registration drive train 54 is a drive transmission mechanism that connects a pinion gear 60a provided on the output shaft of the motor 60 and a registration roller gear 64 that is an input gear to the registration roller 250. (gear train). The registration roller gear 64 is attached to the roller shaft of the registration roller 250 and rotates together with the registration roller 250 . The registration drive train 54 includes a first registration gear 61 that meshes with the pinion gear 60 a , a second registration gear 62 that meshes with the first registration gear 61 , and a third registration gear 63 that meshes with the second registration gear 62 and the registration roller gear 64 . By forming at least a part of the first to third register gears 61 to 63 as step gears in which two gears having different pitch circle diameters are combined, the rotation of the pinion gear 60 a can be reduced and transmitted to the registration roller gear 64 . . In the illustrated configuration example, the first register gear 61 and the second register gear 62 are configured as step gears.

As shown in FIGS. 3 and 4, the double-sided drive train 56 includes a double-sided input gear 74, an electromagnetic clutch 57, and a gear train 56G including double-sided roller gears 123a, 124a. The double-sided input gear 74 is provided coaxially with the third register gear 63 and rotates together with the third register gear 63 . The electromagnetic clutch 57 includes an input gear portion 57a that meshes with the double-sided input gear 74, and an output gear portion 57b that meshes with one of the gears forming the gear train 56G. The double-sided roller gears 123a and 124a are connected to the output gear portion 57b of the electromagnetic clutch 57 via a gear train 56G. The double-sided roller gears 123a and 124a are attached to the roller shafts of the double-sided conveying rollers 123 and 124 and rotate integrally with the double-sided conveying rollers 123 and 124, respectively.

The double-sided drive train 56 is a drive train branched from the third registration gear 63 constituting the registration drive train 54 and connected to the double-sided conveying rollers 123 and 124 . In other words, the double-sided drive train 56 transmits the driving force of the motor 60 transmitted via a part of the registration drive train 54 (the portion from the pinion gear 60a to the third registration gear 63) to the double-sided conveying rollers 123 and 124. It is a drive transmission mechanism.

The electromagnetic clutch 57 is a clutch according to this embodiment. The electromagnetic clutch 57 has a first rotating body that rotates integrally with the input gear portion 57a, a second rotating body that rotates integrally with the output gear portion 57b, and a coil that generates a magnetic field when energized. The first rotating body (input gear portion 57a) and the second rotating body (output gear portion 57b) are relatively rotatable when not energized, and rotate integrally with the relative rotation restricted by the magnetic field generated by the coil when energized. state. In other words, the electromagnetic clutch 57 enables selective drive transmission from the motor 60 to the double-sided conveying rollers 123 and 124 . Hereinafter, the state (excited state) in which the input gear portion 57a and the output gear portion 57b rotate integrally is referred to as the “connected state” of the electromagnetic clutch 57, and the state in which relative rotation between the input gear portion 57a and the output gear portion 57b is allowed (non-excited state). excitation state) is referred to as the “disengaged state” of the electromagnetic clutch 57 .

As the electromagnetic clutch 57, for example, a single-plate or multi-plate electromagnetic friction clutch can be used. In this case, the first rotating body is either the rotor or the armature, and the second rotating body is the other of the rotor and the armature. When the armature is brought into close contact with the rotor by the magnetic field generated by the energization of the coil, the armature and the rotor are frictionally engaged, and when the energization of the coil is cut off, the armature and the rotor are allowed to rotate relative to each other. As the electromagnetic clutch 57, a clutch having a known operation principle other than an electromagnetic friction clutch (for example, a tooth clutch or a powder clutch) may be used. A mechanical clutch operated by a solenoid or the like may be used instead of the electromagnetic clutch 57, but the electromagnetic clutch 57 is preferable from the viewpoint of response speed.

As shown in FIGS. 3 and 6B, the feed drive train 55 includes a feed control gear 65, a feed cam 67, a first feed gear 80, a second feed gear 81, and a feed drive train. A feed shaft 91 , a feed gear 82 , an idler gear 83 , a pickup gear 84 and a solenoid 66 are included. The feeding control gear 65 meshes with the third registration gear 63 of the registration drive train 54 . (FIGS. 4 and 6(a)). The feed cam 67 is provided coaxially with the feed control gear 65 and rotates together with the feed control gear 65 .

The first feed gear 80 meshes with the feed control gear 65 . The second feed gear 81 is attached to the drive-side end of the feed shaft 91 to which the feed roller 117 is attached, and meshes with the first feed gear 80 . The feed gear 82 is attached to the end of the feed shaft 91 on the non-drive side. The idler gear 83 is rotatably held by the pickup arm 68 (FIG. 2) and meshes with the feed gear 82 . The pickup gear 84 is rotatably held by the pickup arm 68 (FIG. 2) and meshes with the idler gear 83 . The feed gear 82 and the pickup gear 84 are provided coaxially with the feed roller 117 and the pickup roller 116, respectively, and rotate together.

(Schematic diagram of drive configuration)
FIG. 5 is a schematic diagram showing a drive transmission path in the sheet conveying mechanism 103. As shown in FIG. As described above, the motor 60 and the registration rollers 250 are connected via the registration drive train 54 so as to be able to transmit driving force. The motor 60 and the double-sided conveying rollers 123 and 124 are connected via a part of the registration drive train 54 and a double-sided drive train 56 branched from the registration drive train 54 so as to be able to transmit driving force. Further, an electromagnetic clutch 57 provided in the double-sided drive train 56 can selectively connect and release the drive transmission to the double-sided conveying rollers 123 and 124 . The motor 60 , the feed cam 67 , the pickup roller 116 and the feed roller 117 are connected in a drive-transmissible manner via a registration drive train 54 and a feed drive train 55 connected downstream of the registration drive train 54 . ing. That is, in the present embodiment, the feeding drive train 55 as the second drive transmission section is a drive transmission path connected downstream of the registration drive train 54 as the first drive transmission section. A double-sided drive train 56 as a third drive transmission unit is a drive transmission path branched from the middle of the registration drive train 54 .

Note that the control unit 100 (FIG. 1) of the image forming apparatus 1 controls the operation of the sheet conveying mechanism 103 by sending commands to the motor 60, the electromagnetic clutch 57, and the solenoid 66, which are actuators. A control unit 200, which is the control means of the present embodiment, has a central processing unit (CPU) and a ROM and a RAM as storage devices. The CPU reads and executes a program stored in the ROM, and controls the operation of the image forming apparatus 1 by sending commands to the motor 60 and the like. RAM provides a work space for the CPU to execute programs. A ROM is an example of a non-transitory storage medium that stores a program for controlling the image forming apparatus.

(One-rotation control of feeding control gear)
Details of the feed drive train 55 will be described. In this embodiment, the feeding unit 104 consisting of the pickup roller 116, the feed roller 117, and the pickup arm 68 performs a feeding operation with one rotation of the feeding control gear 65 as an operation unit, as described below. is configured to

As shown in FIG. 6B, the feeding control gear 65 is provided with an engaging portion 65a that is engaged with an engaging claw 66a of a solenoid 66. As shown in FIG. The locking claw 66a is provided at the tip of the flap that is attracted when the solenoid 66 is energized (excited). is biased to the locking position. Further, the feeding control gear 65 is provided with a toothless portion 65b (FIG. 3), and when the engaging portion 65a is engaged with the engaging pawl 66a, the toothless portion 65b is attached to the registration roller gear 64 (see FIG. 6). a)) so as to be disengaged from the registration roller gear 64. As shown in FIG. In other words, apart from the electromagnetic clutch 57 (first clutch), the feeding control gear 65 and the solenoid 66 function as a clutch (second clutch) capable of connecting and disconnecting drive transmission to the feeding unit 104 . Hereinafter, the rotation angle at which the toothless portion 65b faces the registration roller gear 64 is defined as the initial position of the feeding control gear 65. FIG. When the feeding operation is not performed, the solenoid 66 is not energized, and the feeding control gear 65 waits at the initial position with the engaging portion 65a engaged with the engaging claw 66a.

When the controller 100 (FIG. 5) determines that the timing of feeding the sheet S has arrived when the image forming operation is executed, the controller 100 energizes the solenoid 66 for a short period of time to move the locking claw 66a to the locking portion. Detach from 65a. Then, the feeding control gear 65 starts rotating in a predetermined rotational direction (direction R5) from the initial position, and the toothed portion 65c meshes with the registration roller gear 64 as shown in FIG. 6(a). As a result, the feeding control gear 65 receives the driving force of the motor 60 from the registration roller gear 64 and continues to rotate in the R5 direction. Then, when the feeding control gear 65 makes one rotation from the rotation angle of the standby state, the locking portion 65a is locked by the locking claw 66a of the solenoid 66 in the non-energized state, so that the feeding control gear 65 is again in the standby state. It stops at the rotation angle of the state and waits until the next feeding timing.

A specific configuration example that enables one-rotation control of the feeding control gear 65 will be described. The feeding control gear 65 is a gear unit in which a first gear 651 and a second gear 652 (FIG. 3), each having a toothed portion 65c and a toothless portion 65b, are coaxially overlapped. The first gear 651 meshes only with the registration roller gear 64 , and the second gear 652 meshes with both the registration roller gear 64 and the first feeding gear 80 . The first gear 651 and the second gear 652 are provided with a stopper shape so that they can rotate relative to each other within a predetermined range and are restricted from rotating relative to each other beyond the predetermined range. A spring is arranged between the first gear 651 and the second gear 652 to bias the first gear 651 in the R5 direction with the second gear 652 as a reference. Further, the first gear 651 is provided with the locking portion 65a, and the second gear 652 is formed integrally with the feeding cam 67. As shown in FIG.

According to the above configuration, when the solenoid 66 is energized with the first gear 651 and the second gear 652 positioned at the initial positions, the first gear 651 released from the locking claw 66a is moved in the R5 direction by the biasing force of the spring. to start. Then, the toothed portion 65 c of the first gear 651 meshes with the registration roller gear 64 . As a result, the first gear 651 first receives the driving force from the registration roller gear 64 and rotates in the R5 direction. After that, when the first gear 651 rotates by a predetermined angle, the stopper shape abuts, and the first gear 651 and the second gear 652 start rotating together in the R5 direction. When the second gear 652 starts to rotate, the feed cam 67 starts to rotate, the first feed gear 80 also starts to rotate, and the feed roller 117 and the pickup roller 116 start to rotate. After that, when the first gear 651 reaches the initial position again, the first gear 651 is held at the initial position by engaging the engaging portion 65a with the engaging claw 66a. Further, when the second gear 652 reaches the initial position after the first gear 651, the second gear 652 is also held at the initial position by a holding mechanism (not shown). The holding mechanism includes, for example, a half-moon cam portion provided on the second gear 652 and a plate spring that contacts the flat surface of the cam portion. 652 in its initial position.

As described above, the feeding control gear 65 is configured to rotate once each time the solenoid 66 is energized while the motor 60 is rotating. The rotation of the feed control gear 65 rotates the feed roller 117 and the pickup roller 116 via the gear train, and rotates the feed cam 67 coaxial with the feed control gear 65 . As a result, as described below, the pickup roller 116 is raised and lowered, and the sheet S is fed by the pickup roller 116 and the feed roller 117 .

(Operation of feeding cam and pickup arm)
Next, operations of the feeding cam 67 and the pickup arm 68 in the feeding operation will be described. As described above, since the feeding operation is performed in units of one rotation of the feeding control gear 65, the feeding cam 67 connected to the feeding control gear 65 rotates once per one feeding operation. 7A to 7D show how the feeding cam 67 rotates once from the initial position and returns to the initial position.

As shown in FIGS. 7A to 7D, the pickup arm 68 has a convex portion 68a as a portion to be contacted by the cam surface 67a of the feeding cam 67. As shown in FIG. The pickup arm 68 is rotatable (swingable) about the rotation center 68c in the R1 direction for lowering the pickup roller 116 and the R2 direction for raising the pickup roller 116 . A pressure spring 69 is connected to the pickup arm 68, and the pickup arm 68 is always urged in the R1 direction by the pressure spring 69. As shown in FIG. Therefore, the pickup arm 68 is positioned when the convex portion 68 a contacts the cam surface 67 a or when the pickup roller 116 contacts the sheet in the feed cassette 115 .

Also, the cam surface 67a includes the following three areas. The first area a1 is a curved surface extending substantially in an arc shape (cylindrical surface shape) around the center of rotation of the feeding cam 67 . The second area a2 is a curved surface extending radially inward from the rotation center of the feed cam 67 from the upstream end of the first area a1 in the forward rotation direction (R5 direction) of the feed cam 67. As shown in FIG. The third area a3 is a curved surface extending radially inward with respect to the rotation center of the feed cam 67 from the downstream end of the first area a1 in the forward rotation direction (R5 direction) of the feed cam 67 .

During one rotation of the feeding cam 67 in the feeding operation, the feeding cam 67 and the pickup arm 68 operate as follows. First, in a standby state in which no feeding operation is performed, the feeding cam 67 is positioned at the initial position (the position corresponding to the initial position of the feeding control gear 65) shown in FIG. 7(a). At this time, the pickup arm 68 is held at the upper position by the contact of the convex portion 68a with the first area a1 of the cam surface 67a, and the pickup roller 116 is at the standby position spaced upward from the sheets in the feed cassette 115. retained.

When the solenoid 66 is energized to start the feeding operation, the feeding cam 67 and the feeding control gear 65 start rotating from the initial position in the R5 direction, as shown in FIG. 7(b). Then, the pick-up arm 68 rotates in the R1 direction due to the biasing force of the pressure spring 69 while bringing the convex portion 68a into sliding contact with the second region a2 of the cam surface 67a. When the feeding cam 67 further rotates in the R5 direction, the convex portion 68a is separated from the second area a2 of the cam surface 67a, as shown in FIG. 7(c). Then, the pickup arm 68 rotates to the lower position according to the biasing force of the pressure spring 69 , and the pickup roller 116 moves to the feeding position and lands on the sheet on the feeding cassette 115 . The driving force transmitted from the feeding control gear 65 via the first feeding gear 80 rotates the pickup roller 116 and the feed roller 117 to feed the sheet.

When the feeding cam 67 further rotates in the R5 direction from the state shown in FIG. 7(c), the third region a2 of the cam surface 67a comes into contact with the convex portion 68a, and the pressure spring 69 is pressed as shown in FIG. 7(d). The pick-up arm 68 is rotated in the R2 direction against the urging force of . Then, when the feed cam 67 rotates to the initial position, the pickup arm 68 is moved from the lower position to the upper position again as shown in FIG. 7(a).

While the feeding cam 67 rotates once to perform the feeding operation as described above, the feeding cam 67 transitions between the following four states.

The first state is a balanced state (FIG. 7(a)). In the first state, the feeding control gear 65 is locked by the solenoid 66, the feeding operation is not performed, and the feeding cam 67 is stopped. The first state also includes the time immediately after the locking claw 66a of the solenoid 66 is disengaged and the feeding cam 67 starts rotating. In the first state, the convex portion 68a of the pickup arm 68 is in contact with the first area a1 of the cam surface 67a of the feed cam 67 due to the biasing force of the pressure spring 69 . The biasing force F that the feeding cam 67 receives from the convex portion 68a is directed toward the center of rotation of the feeding cam 67 . That is, when viewed in the rotation axis direction of the feeding cam 67, the line of action of the biasing force F acting from the convex portion 68a to the cam surface 67a due to the biasing force of the pressure spring 69 is the center of rotation of the feeding cam 67. pass through or pass near the center of rotation. Therefore, in the first state, the feed cam 67 is not urged in the forward rotation direction (R5 direction) by the biasing force F applied to the feed cam 67 via the pickup arm 68 by the pressure spring 69 . Here, the “forward rotation direction” refers to the rotation direction in which the feeding cam 67 is rotationally driven by the driving force of the motor 60 via the registration drive train 54 and the feeding drive train 55 .

The second state is the assist state (FIG. 7(b)). The second state is the state after the feeding control gear 65 is released from the locking of the solenoid 66 and the feeding operation is started, and the feeding cam 67 is rotating in the R5 direction. At this time, the convex portion 68 a of the pickup arm 68 is in contact with the second area a 2 of the cam surface 67 a of the feed cam 67 due to the biasing force of the pressure spring 69 . The direction of the biasing force F with which the convex portion 68a presses the cam surface 67a (the direction of the line of action of the biasing force F, the normal direction of the second area a2 of the cam surface 67a at the contact position of the convex portion 68a) It does not move toward the center of rotation of the cam 67, but passes below the center of rotation in the drawing. Therefore, in the second state, the biasing force F applied to the feed cam 67 by the pressure spring 69 via the pickup arm 68 acts on the feed cam 67 in the forward rotation direction (R5 direction). In other words, the second state is a state in which the driving force of the motor 60 assists the rotation of the feed cam 67 rotated in the forward rotation direction (R5 direction). In other words, the feeding cam 67 as a cam member is configured to be biased in the forward rotation direction (R5 direction) by the biasing force of the pressure spring 69 when positioned within a predetermined angle range. The “predetermined angular range” in this embodiment refers to the angular range of the feeding cam 67 in which the second area a2 of the cam surface 67a contacts the convex portion 68a of the pickup arm 68. As shown in FIG. A phenomenon occurring in the registration drive train 54 in this second state will be described later.

The third state is the non-contact state (FIG. 7(c)). The third state is a state in which the pickup arm 68 stops rotating in the direction R1 when the pickup roller 116 comes into contact with the sheet S in the feed cassette 115 and is positioned at the lower position. The third state is a non-contact state in which the convex portion 68a of the pickup arm 68 is separated from the cam surface 67a of the feeding cam 67 by rotating the feeding cam 67 while the pickup arm 68 is positioned. Therefore, in the third state, the urging force of the pressure spring 69 does not act on the feed cam 67 .

The fourth state is the push-up state (FIG. 7(d)). In the fourth state, the cam surface 67a of the feed cam 67 rotating in the forward rotation direction (R5 direction) is pressed against the convex portion 68a of the pickup arm 68 stopped at the lower position, and the biasing force of the pressure spring 69 is applied. In this state, the pickup arm 68 is being pushed up in the R2 direction. The convex portion 68a is in contact with the third region a3 of the feed cam 67 in the cam surface 67a of the feed cam 67. As shown in FIG. The cam surface 67a presses the convex portion 68a with a pressing force F′ in a direction along the forward rotation direction (R5 direction). is added. In the fourth state, unlike the second state, the urging force F applied to the feed cam 67 by the pickup arm 68 acts on the feed cam 67 with a moment M2 in the reverse rotation direction (counterclockwise direction in the drawing). When the pickup arm 68 moves to the upper position, the feeding cam 67 returns to the first state shown in FIG. 7(a).

(Explanation of assist state)
A phenomenon that occurs in the registration drive train 54 in the second state (assisted state) of the feed cam 67 described with reference to FIG. 7B will be described. 8A and 8B are enlarged views of the meshing portion between the registration roller gear 64 and the feeding control gear 65. FIG.

FIG. 8A shows the state during normal driving (when the feeding cam 67 is rotating in the forward rotation direction in a state other than the second state). The registration roller gear 64 rotates in a predetermined rotational direction (R4 direction, counterclockwise direction in the figure) by receiving driving force from the upstream third registration gear 63 . The feed control gear 65 is rotated in the forward rotation direction (R5 direction, clockwise in the figure) by transmission of driving force through meshing with the registration roller gear 64 .

Backlashes 71 and 72 are provided between the teeth of the registration roller gear 64 and the teeth of the feeding control gear 65 and between the teeth of the third registration gear 63 and the teeth of the registration roller gear 64, respectively. Similarly, meshing portions of other gears forming the registration drive train 54 are also provided with backlash. Backlash is a gap (play) between the tooth flanks provided so that rotation can be smoothly transmitted between the gears without interference between the teeth, and is required for each gear that constitutes the register drive train 54. It is set in advance according to the gear accuracy.

FIG. 8(b) shows when the feed cam 67 is in the second state (assisted state), that is, when the biasing force of the pressure spring 69 is received via the pickup arm 68, the moment M1 in the forward rotation direction (R5 direction) is generated. is in action. Since the feed control gear 65 rotates integrally with the feed cam 67, the forward rotation direction (R5 direction) moment M1 acts on the feed control gear 65 as well.

At this time, the feed control gear 65 is accelerated in the forward rotation direction (R5 direction) by the moment M1 so that the backlash 71 is clogged (disappeared) at the meshing portion between the feed control gear 65 and the registration roller gear 64 . That is, the rotational speed (peripheral speed on the pitch circle) of the feed control gear 65 is accelerated by the moment M1, and the rotational speed (peripheral speed on the pitch circle) of the registration roller gear 64 is temporarily increased. . 8A, the backlash 71 that exists downstream of the teeth of the feed control gear 65 in the forward rotation direction (R5 direction) disappears in the state of FIG. 8B. At this time, a gap corresponding to the backlash 71 is formed on the upstream side of the teeth of the feed control gear 65 in the tangential direction V5.

Further, the registration roller gear 64 is pressed by the feeding control gear 65 accelerated in the forward rotation direction (R5 direction) by the assist of the moment M1, and the rotation of the registration roller gear 64 in the forward rotation direction (R4 direction) is assisted. As a result, the registration roller gear 64 is accelerated in the forward rotation direction (R4 direction) so that the backlash 72 is blocked at the meshing portion with the third registration gear 63 . Similarly, at the meshing portion of each gear constituting the registration drive train 54, a phenomenon in which the downstream gear temporarily accelerates relative to the upstream gear propagates so that the backlash between the gears is reduced. go. In other words, while the driving force in the forward rotation direction is normally transmitted from the motor 60 to the registration roller gear 64 , in the second state of the feed cam 67 , the biasing force of the pressure spring 69 causes the motor to rotate from the registration roller gear 64 . The biasing force in the forward rotational direction toward 60 is temporarily reversed. In this way, a phenomenon occurs in which the rotational speed of the registration roller gear 64 in the forward rotation direction (R5 direction) is temporarily accelerated until the backlash is clogged at the meshing portions of all the gears of the registration drive train 54 .

The above phenomenon ends when the backlash at the meshing portion between the pinion gear 60a and the first registration gear 61, which is the meshing portion on the most upstream side, is clogged. However, depending on the magnitude of the moment M1, etc., the above phenomenon may end before reaching the meshing portion between the pinion gear 60a and the first registration gear 61. FIG. Here, since the motor 60 is controlled at a constant rotational speed corresponding to the set value of the sheet conveying speed of each roller of the sheet conveying mechanism 103, the driving force resulting from the biasing force of the pressure spring 69 is Even if it is input, fluctuations in the rotation speed of the motor 60 are suppressed. Therefore, after the backlash is blocked in the meshing portions of all the gears of the registration drive train 54, each gear of the registration drive train 54 rotates at the same rotational speed as normal.

When the second state of the feed cam 67 ends, the feed cam 67 is separated from the pickup arm 68 and is in a state where it is not subjected to the biasing force of the pressure spring 69 (third state, FIG. 7(c)). Then, the assist of the moment M1 caused by the biasing force of the pressure spring 69 disappears, so that the rotation speed of the feed control gear 65 becomes temporarily slower than the rotation speed of the registration roller gear 64. FIG. As a result, the feeding control gear 65 and the registration roller gear 64 return to the normal engagement state shown in FIG. 8A, and the feeding control gear 65 is driven by the registration roller gear 64 to rotate in the forward rotation direction (direction R5). becomes. Similarly, at the meshing portion between the gears forming the registration drive train 54, the rotational speed of the gear on the downstream side is temporarily slower than the rotational speed of the gear on the upstream side, and the normal meshing state is reached. Then, the gear on the downstream side is driven by the gear on the upstream side to rotate in the forward rotation direction.

In this way, the state (second state) in which the moment caused by the biasing force F of the pressure spring 69 acts on the feeding cam 67 during the feeding operation causes the registration roller gear 64 to rotate in the forward rotation direction (R4 direction). ) may temporarily fluctuate. When such a phenomenon occurs, the rotational speed of the registration rollers 250 temporarily fluctuates, resulting in fluctuations in the sheet conveying speed at which the sheets are fed by the registration rollers 250 . In particular, in an image forming operation in which images are continuously formed on one side of a plurality of sheets (hereinafter referred to as single-sided continuous printing), the image is transferred to the preceding sheet being conveyed by the registration rollers 250 . There is concern about the effect of starting the sheet feeding operation. In this case, if the sheet conveying speed of the registration rollers 250 accelerates during image transfer to the preceding sheet, image blurring may occur in the image transferred to the preceding sheet. Note that when single-sided continuous printing (single-sided continuous printing operation) is performed, a plurality of sheets (for example, a preceding sheet and a following sheet) are conveyed from the feed cassette 115 or the feed tray 401 to the discharge tray 101a by the double-sided conveying rollers 123 and 124. transported without At this time, the plurality of sheets are fed from the feed cassette 115 or the feed tray 401, conveyed via the registration rollers 250, and discharged to the outside of the image forming apparatus 1 by the discharge rollers 109 and the discharge rollers 110. , the two-sided conveying rollers 123 and 124.

(clutch control)
Therefore, in the present embodiment, the electromagnetic clutch 57 of the double-sided drive train 56 is operated during the feeding operation in continuous single-sided printing so as to suppress fluctuations in the sheet conveying speed of the registration rollers 250 due to the biasing force of the pressure spring 69 . are connected. That is, even when the sheet is not conveyed by the double-sided conveying rollers 123 and 124, the electromagnetic clutch 57 is controlled to be connected. By connecting the electromagnetic clutch 57, the double-sided drive train 56 is configured for the third registration gear 63 (FIGS. 3 and 5) that distributes the driving force from the registration drive train 54 to the double-sided drive train 56. The load of gears and double-sided transport rollers 123, 124 is applied. Since the double-sided conveying rollers 123 and 124 do not convey the sheet in continuous single-sided printing, the electromagnetic clutch 57 is connected during the feeding operation. It does not affect the sheet conveyance inside.

As shown in FIG. 4, the third register gear 63 forming the register drive train 54 and the double-sided input gear 74 forming the double-sided drive train 56 are arranged coaxially and rotate together. Therefore, when the electromagnetic clutch 57 is in the connected state, the load of the element on the downstream side of the electromagnetic clutch 57 in the drive transmission path is applied to the third register gear 63 . The loads on the elements downstream of the electromagnetic clutch 57 include the rotational resistance of the double-sided conveying rollers 123 and 124 and the rotational resistance of each gear constituting the gear train 56G that connects the electromagnetic clutch 57 and the double-sided conveying rollers 123 and 124. included. This load is load torque in a direction opposite to the forward rotation direction (R3 direction in FIG. 6A) in which the third register gear 63 is rotationally driven by the driving force from the motor 60 . Therefore, even if the feeding cam 67 is in the second state (assisted state) during the feeding operation, the registration roller gear 64 is accelerated, and a moment in the forward rotation direction (R3 direction) acts on the third registration gear 63 from the registration roller gear 64. , the acceleration of the third register gear 63 is suppressed by the load.

In the case of the configuration in which the electromagnetic clutch 57 is always released during the feeding operation, as described above, the rotational speed of the registration roller gear 64 is accelerated until the backlash is clogged at the meshing portions of all the gears from the registration roller gear 64 to the pinion gear 60a. there's a possibility that. In contrast, in the present embodiment, the acceleration of the third register gear 63 is suppressed by connecting the electromagnetic clutch 57 during the feeding operation. Therefore, the amount by which the rotational speed of the registration roller gear 64 is accelerated (the amount by which the registration roller gear 64 rotates excessively compared to when the normal rotational speed is maintained) is reduced at least compared to the above configuration, and fluctuations in the sheet conveying speed by the registration roller 250 are reduced. can do. As a result, it is possible to reduce the possibility of image blur occurring in the image transferred onto the sheet in the secondary transfer portion.

By the way, in order to effectively suppress fluctuations in the sheet conveying speed of the registration roller 250 by connecting the electromagnetic clutch 57, it is preferable that the load on the element downstream of the electromagnetic clutch 57 is large. In this embodiment, not only the double-sided conveying roller 124 as the second conveying member but also the double-sided conveying roller 123 as the third conveying member are connected to the downstream side of the electromagnetic clutch 57 . Therefore, fluctuations in the sheet conveying speed of the registration rollers 250 when the electromagnetic clutch 57 is connected can be suppressed more effectively than when only one conveying member is connected downstream of the electromagnetic clutch 57. can.

Further, in order to effectively suppress fluctuations in the sheet conveying speed of the registration rollers 250 by connecting the electromagnetic clutch 57 , the double-sided drive train 56 including the electromagnetic clutch 57 is connected to the registration roller gear 64 in the registration drive train 54 . It is preferably connected to the closest gear. That is, rather than connecting the double-sided drive train 56 to a gear (for example, the first registration gear 61) connected to the registration roller gear 64 via a plurality of gears, the double-sided drive train is connected to the registration roller gear 64 or the third registration gear 63 that directly meshes with the registration roller gear 64. 56 is preferred. That is, when the first drive transmission section has a first gear that rotates integrally with the first conveying member, and a second gear that meshes with the first gear and transmits the driving force to the first gear, the clutch is It is preferable that the third drive transmission part including the third drive transmission part is connected to the first gear or the second gear.

With such a connection relationship, the number of meshing portions between the gears existing in the section from the load receiving gear on the downstream side of the electromagnetic clutch 57 to the registration roller gear 64 in the connected state of the electromagnetic clutch 57 is reduced. As a result, when the feeding cam 67 is in the second state (assisted state) and the registration roller gear 64 is accelerated, the extra rotation amount of the registration roller gear 64 (total backlash of the meshing portions existing in the above section) becomes smaller. . In this embodiment, the double-sided drive train 56 is connected to the third registration gear 63 that directly meshes with the registration roller gear 64 . Therefore, even when the feeding cam 67 is in the second state (assisted state), when the backlash 72 (FIG. 8(a)) at the meshing portion between the registration roller gear 64 and the third registration gear 63 is jammed, the registration roller gear Acceleration in the forward rotation direction (R4 direction) of 64 is regulated.

FIG. 9 shows a flowchart illustrating a control method of the image forming apparatus 1. As shown in FIG. Each step of this control method is implemented by the CPU of the control unit 100 shown in FIG. 5 reading and executing the control program. When a single-sided continuous printing execution command (job) is input to the image forming apparatus 1, the control unit 100 starts executing this control method. When the execution of the job is started, the driving of the motor 60 is started (S1), and it is determined whether the timing (feeding timing) to start feeding the sheet S has arrived (S2). The feed timing in this embodiment is created by the image forming unit 102 based on the time when the writing of the electrostatic latent image by the laser scanner 120 in the most upstream process unit P1 in the conveying direction of the intermediate transfer belt 130 is started. It refers to the time at which a waiting time preset so that the sheet S enters the secondary transfer portion at the same time that the toner image reaches the secondary transfer portion has elapsed.

When the feeding timing arrives, the control unit 100 energizes the solenoid 66 to start rotating the feeding control gear 65 and start the feeding operation by the feeding unit 104 (S3). At the same time that the solenoid 66 is energized, the control unit 100 energizes the electromagnetic clutch 57 of the double-sided drive train 56 to bring the electromagnetic clutch 57 into the connected state (S3). When enough time elapses for the locking claw 66a to disengage from the locking portion 65a (FIG. 6(b)) of the feed control gear 65, the solenoid 66 is de-energized (S4). Thereafter, the control unit 100 waits while maintaining the electromagnetic clutch 57 in the connected state until a predetermined time elapses (S5). During this period, the feeding cam 67 transitions from the first state (FIG. 7(a)) to the third state (FIG. 7(c)) through the second state (FIG. 7(b)). After a predetermined time has elapsed from S3, the control unit 100 cuts off the energization of the electromagnetic clutch 57 (S6). If there is a succeeding sheet on which image formation has not yet been performed (S7: Yes), the process returns to S2 and the same processing is repeated, and if all the sheets specified by the job have been fed (S7: No) ends the process.

In the above control method, the period (predetermined time) in which the electromagnetic clutch 57 is connected is the time when the feeding cam 67 transitions from the first state (FIG. 7(a)) to the second state (FIG. 7(b)). is started before The period (predetermined time) is set to end after the feeding cam 67 transitions from the second state (FIG. 7(b)) to the third state (FIG. 7(c)). The point of transition of the feeding cam 67 from the first state to the second state is the point of time when the contact position of the convex portion 68a of the pickup arm 68 with respect to the cam surface 67a moves from the first area a1 to the second area a2. (Fig. 7 (a, b)). The transition point of the feeding cam 67 from the second state to the third state is the point of time when the convex portion 68a of the pickup arm 68 is separated from the second region a2 of the cam surface 67a (FIGS. 7B and 7C).

In the configuration example of the present embodiment, the electromagnetic clutch 57 is brought into the connected state at the same time when the solenoid 66 is energized, and the electromagnetic clutch 57 is brought into the released state after the feeding cam 67 makes one rotation from the initial position. is set. Alternatively, the electromagnetic clutch 57 may be connected before the solenoid 66 is energized, for example. Further, for example, after the electromagnetic clutch 57 is brought into the connected state, the electromagnetic clutch 57 is released after the feed cam 67 transitions from the second state to the third state and before the feed cam 67 makes one rotation. state.

(Drive configuration of reference example)
Advantages of the present embodiment will be described in comparison with the reference example. FIG. 10 is a schematic diagram showing the driving configuration of the sheet conveying mechanism according to the reference example. In this reference example, the pinion gear of the motor 60 meshes with the gears forming the registration drive train 54 and the gears forming the feeding drive train 155 . In other words, the registration drive train 54, which is the drive transmission path from the motor 60 to the registration roller 250, and the feed drive train 155, which is the drive transmission path from the motor 60 to the feed cam 67, branch from the root without overlapping each other. . Other configurations of the sheet conveying mechanism are the same as those of the present embodiment.

In the configuration of the reference example, even if a moment in the forward rotation direction acts on the feeding cam 67 due to the biasing force of the pressure spring 69 during the feeding operation, the load is received by the motor 60 and is not transmitted to the registration drive train 54. . Therefore, as in the present embodiment, the biasing force of the pressure spring 69 prevents the sheet conveying speed of the registration rollers 250 from fluctuating and causing image blurring.

However, in the configuration of the reference example, the drive transmission path from the motor 60 to the registration rollers 250 and the drive transmission path are branched from the root without overlapping each other, so more gears are required than in the present embodiment. Specifically, a reduction mechanism, such as the first registration gear 61 and the second registration gear 62, for reducing the speed of rotation output by the motor 60 to a speed suitable for driving the registration roller 250 and the feeding cam 67 is provided as a registration gear. Required for each of drive train 54 and feed drive train 155 . An increase in the number of necessary gears increases the manufacturing cost of the sheet conveying mechanism and requires space for arranging the gears, leading to an increase in the size of the image forming apparatus.

On the other hand, in this embodiment, the feeding drive train 55 is arranged downstream of the registration drive train 54 . In other words, the feeding cam 67 is configured to be rotationally driven by the driving force transmitted from the motor 60 via the registration drive train 54 . As a result, the number of gears in the entire sheet conveying mechanism can be reduced as much as possible to achieve a low-cost and space-saving configuration.

(summary)
As described above, according to the present embodiment, in single-sided continuous printing, the electromagnetic clutch 57 is connected when the feeding operation of the succeeding sheet is started while the preceding sheet is being conveyed by the registration rollers 250 . In other words, the control means of the present embodiment connects the clutch when the cam member is rotated to feed the succeeding sheet by the feeding member while the preceding sheet is being conveyed by the first conveying member. As a result, fluctuations in the sheet conveying speed of the registration rollers 250 due to the biasing force of the pressure spring 69 (biasing member) can be suppressed, and image blurring of the image transferred to the sheet can be suppressed.

In particular, in this embodiment, the electromagnetic clutch 57 is configured to be in the connected state at least during the period in which the feeding cam 67 is in the second state (assisted state) during the feeding operation. That is, when the cam member is positioned within a predetermined angle range, the biasing force of the biasing member causes the cam member to rotate in a rotational direction (direction R5) and a driving force transmitted from the motor via the third drive transmission section. configured to be biased in the same rotational direction. Then, when the control means rotates the cam member to start feeding the succeeding sheet by the feeding member while the preceding sheet is being conveyed by the first conveying member, the control means rotates the cam member before the cam member enters the predetermined angle range. To switch the clutch from the disengaged state to the engaged state. Further, the control means switches the clutch from the connected state to the released state after the cam member leaves the predetermined angular range.

Further, the registration drive train 54 serves as a drive transmission path from the motor 60 to the registration rollers 250 and also serves as a drive transmission path from the motor 60 to the feeding cam 67 . That is, the feeding drive train 55 as a second drive transmission section for transmitting the driving force of the motor to the cam member is connected to the motor via the registration drive train 54 as a first drive transmission section. As a result, the number of gears constituting the registration drive train 54 and the feed drive train 55 can be reduced as much as possible, and the cost and size of the apparatus can be reduced.

<Second embodiment>
A second embodiment will be described with reference to FIG. Hereinafter, elements with the same reference numerals as in the first embodiment will be described as having substantially the same configuration and action as those described in the first embodiment. This embodiment differs from the first embodiment in a part of the driving structure of the sheet conveying mechanism 103, and the overall structure of the image forming apparatus 1 is the same as that of the first embodiment.

In the first embodiment, as shown in FIG. 5, the double-sided drive train 56 is branched from the middle of the registration drive train 54 and connected to the double-sided conveying rollers 123 and 124 . In this embodiment, as shown in FIG. 11, the duplex drive train 256 is connected to the gear 280 forming the feed drive train 255 , and the duplex drive train 256 is branched from the feed drive train 255 . The gear 280 is, for example, a gear corresponding to the first feeding gear 80 of the first embodiment shown in FIG. 6(a). That is, in the present embodiment, the feeding drive train 255 as the second drive transmission section is a drive transmission path connected downstream of the registration drive train 54 as the first drive transmission section. Further, the double-sided drive train 256 as the third drive transmission section is connected to the downstream side of the registration drive train 54 as the first drive transmission section via a gear 280 which is part of the feeding drive train 255 . transmission route.

The feed cam 267 rotates in the forward rotation direction with the driving force transmitted from the motor 60 via the registration drive train 54 and the feed drive train 255, thereby raising and lowering the pickup arm 68 holding the pickup roller 116. . Also in the present embodiment, while the feed cam 267 is rotating, the pick-up arm 68 presses the feed cam 67 by the biasing force of the pressure spring 69, and the feed cam 267 is biased in the forward rotation direction. state.

The controller 100 of the image forming apparatus 1 connects the electromagnetic clutch 57 at the same timing as in the first embodiment when feeding the succeeding sheet while the registration roller 250 is conveying the preceding sheet. As a result, the gear 280 is loaded by the double-sided conveying rollers 123 and 124 arranged downstream of the electromagnetic clutch 57 . This load is load torque in a direction opposite to the direction of driving force transmitted from the motor 60 to the gear 280 (forward rotation direction). Therefore, even if the feeding cam 267 is in the second state (assisted state) during the feeding operation and a moment in the forward rotation direction acts on the gear 280 from the feeding cam 267, the gear 280 is accelerated by the load. Suppressed. As a result, the acceleration of the registration roller gear 64 connected to the gear 280 is also suppressed, and fluctuations in the sheet conveying speed of the registration roller 250 are suppressed.

As described above, according to the configuration of the present embodiment as well, fluctuation of the sheet conveying speed of the registration roller 250 due to the biasing force of the pressure spring 69 (biasing member) is suppressed, and image blurring of the image transferred to the sheet is suppressed. can do.

By the way, in the first embodiment, the load torque is applied to the third registration gear 63 provided on the upstream side of the registration roller gear 64 . Therefore, although the acceleration of the third registration gear 63 is suppressed, the registration roller gear 64 is allowed to accelerate in the forward rotation direction until the backlash at the meshing portion between the registration roller gear 64 and the third registration gear 63 is clogged.

On the other hand, in the present embodiment, a load torque is applied to the gear 280 provided on the downstream side of the registration roller gear 64 to suppress acceleration of the gear 280 in the forward rotation direction. Therefore, even if the feeding cam 267 is in the second state (assisted state) during the feeding operation, the moment in the forward rotation direction caused by the biasing force of the pressure spring 69 is restricted from acting on the registration roller gear 64 . be able to. At this time, unlike the first embodiment, the registration roller gear 64 is not accelerated so as to clog the backlash of the meshing portion between the registration roller gear 64 and the gear 280 receiving the load torque. Therefore, it is possible to further reduce fluctuations in the sheet conveying speed of the registration rollers 250 compared to the first embodiment.

<Third Embodiment>
A third embodiment will be described with reference to FIG. Hereinafter, elements with the same reference numerals as in the first embodiment will be described as having substantially the same configuration and action as those described in the first embodiment. This embodiment differs from the first embodiment in a part of the driving structure of the sheet conveying mechanism 103, and the overall structure of the image forming apparatus 1 is the same as that of the first embodiment.

In this embodiment, a manual feeding drive train 356 is provided which branches from the middle of the registration driving train 54 and transmits driving force to the manual feeding rollers 310 , 320 and 330 . The manual feeding drive train 356 is connected to a gear 363 that constitutes the registration drive train 54 . The gear 363 is, for example, a gear corresponding to the third registration gear 63 of the first embodiment shown in FIG. 6(a).

Furthermore, a manual feeding drive train 357 that transmits driving force to the pickup roller 402 and the feed roller 403 of the manual sheet feeding unit 400 is provided downstream of the manual feeding drive train 356 . The pickup roller 402 feeds the sheet from the feed tray 401 (FIG. 1) by driving a solenoid (not shown). In this embodiment, the feeding drive train 55 as the second drive transmission section is a drive transmission path connected downstream of the registration drive train 54 as the first drive transmission section. Also, the manual feeding drive train 356 as the third drive transmission section is a drive transmission path branched from the middle of the registration drive train 54 as the first drive transmission section.

An electromagnetic clutch 157 is arranged in the middle of the manual feeding drive train 356 so as to selectively drive the manual feeding rollers 310, 320 and 330 and the pickup roller 402 and the feed roller 403 on the downstream side thereof. . The manual feed roller 310 is arranged on a different transport path from the transport path from the pickup roller 116 as the feeding member to the registration roller 250 as the first transport member, and transmits driving force via a clutch (electromagnetic clutch 157). It is an example of a second conveying member. A manual feeding roller 310 conveys a sheet fed from a feeding tray 401 (FIG. 1) as a second sheet stacking section provided separately from the feeding cassette 115 as the first sheet stacking section. Further, each of the other manual feeding rollers 320 and 330, the pickup roller 402 and the feed roller 403 is a third feeding member to which driving force is transmitted via a clutch (electromagnetic clutch 157) provided in the manual feeding drive train 356. is an example of

The control unit 100 of the image forming apparatus 1 connects the electromagnetic clutch 157 at the same timing as in the first embodiment when feeding the succeeding sheet while the registration roller 250 is conveying the preceding sheet. As a result, the gear 363 of the registration drive train 54 is loaded by the manual feeding rollers 310 , 320 , 330 and the like arranged downstream of the electromagnetic clutch 157 . This load is load torque in a direction opposite to the direction of driving force transmitted from the motor 60 to the gear 363 (forward rotation direction). Therefore, even if the feeding cam 67 is in the second state (assisted state) during the feeding operation and a moment in the forward rotation direction acts on the gear 363 from the feeding cam 67, the gear 363 is accelerated by the load. Suppressed. As a result, the acceleration of the registration roller gear 64 connected to the gear 363 is also suppressed, and fluctuations in the sheet conveying speed of the registration roller 250 are suppressed.

As described above, according to the configuration of the present embodiment as well, fluctuation of the sheet conveying speed of the registration roller 250 due to the biasing force of the pressure spring 69 (biasing member) is suppressed, and image blurring of the image transferred to the sheet is suppressed. can do.

By the way, since the electromagnetic clutch 57 of the first embodiment is provided in the drive transmission path to the double-sided conveying rollers 123 and 124, the electromagnetic clutch 57 is disengaged when a sheet for double-sided printing is waiting in the double-sided conveying path 125. was not connected. On the other hand, in the present embodiment, the electromagnetic clutch 157 is provided in the drive transmission path to the manual feeding rollers 310 , 320 , 330 for feeding the sheet from the manual feeding tray 401 . For this reason, regardless of whether double-sided printing or single-sided printing is performed, when the sheet S is fed from the feed cassette 115 while the preceding sheet is being conveyed by the registration rollers 250, the electromagnetic clutch 157 is connected so that the sheets of the registration rollers 250 are fed. Fluctuations in the transport speed can be suppressed.

In this embodiment, the conveying roller 310 as the second conveying member conveys the sheet fed from the manual feeding tray 401 as the second sheet stacking unit. The second conveying member is not limited to this, and may be, for example, a conveying roller that conveys a sheet fed to the image forming apparatus 1 from a sheet feeding device (optional feeder) connected to the image forming apparatus 1. . That is, the third drive transmission section including the clutch can selectively transmit the driving force to the second conveying member provided on the conveying path different from the conveying path from the feeding member to the first conveying member. If so, the present technology can be applied.

<Fourth Embodiment>
A fourth embodiment will be described with reference to FIGS. 13(a, b) and 14(a, b). Hereinafter, elements with the same reference numerals as in the first embodiment will be described as having substantially the same configuration and action as those described in the first embodiment. This embodiment differs from the first embodiment in the pressurizing mechanism between the sheet feeding member and the sheet in the sheet feeding section, and the overall configuration of the image forming apparatus 1 is the same as in the first embodiment.

FIG. 13A is a perspective view of the sheet feeding section according to this embodiment, and FIG. 13B is a schematic diagram showing the driving configuration of the sheet conveying mechanism according to this embodiment. 14A and 14B are cross-sectional views showing the cross-sectional configuration of the sheet feeding portion when viewed in the rotation axis direction of the feeding roller 216. FIG. FIG. 14(b) shows a state in which the intermediate plate 246 is positioned at the upper position.

As shown in FIGS. 13(a, b) and 14(a, b), the sheet feeding portion of this embodiment includes a middle plate 268 as a sheet stacking portion and a feeding roller 216 as a feeding member. , and a registration roller 350 as a first conveying member. Further, the sheet feeding section has an intermediate plate spring 282 as an urging member and a feeding cam 467 as a cam member.

The sheet feeding section of this embodiment employs a so-called middle plate pressurization method in which the middle plate 268 is urged upward by the biasing force of the middle plate spring 282 to press the feeding roller 216 and the sheet. there is Sheets are stacked on the upper surface of the intermediate plate 268 . Feed roller 216 is positioned above intermediate plate 268 . The position of the rotation axis of the feed roller 216 is substantially fixed. A separation pad 269 for separating the sheets fed by the feeding roller 216 one by one is in contact with the lower surface of the feeding roller 216 .

The intermediate plate 268 has a position where the upper surface of the stacked sheets contacts the feeding roller 216 (upper position, feeding position, FIG. 13B), and a position where the upper surface of the stacked sheets is downward from the feeding roller 216 . It is possible to move up and down to a separated position (lower position, standby position, FIG. 13(a)). A middle leaf spring 282 is arranged below the middle plate 268 and biases the middle plate 268 toward the upper position.

The feed cam 467 is attached to the roller shaft 216 a of the feed roller 216 and rotates together with the feed roller 216 . A feed control gear 65 is further attached to the roller shaft 2216 a that supports the feed roller 216 and the feed cam 467 . The feeding control gear 265 meshes with a registration roller gear 264 attached to the roller shaft of the registration roller 350 . The feed control gear 265 is configured to make one rotation each time the solenoid 266 (FIG. 14(a)) is energized for a short period of time while the motor 60 is rotating by the same mechanism as in the first embodiment. there is

As shown in FIG. 13(b), in this embodiment, as in the first embodiment, a double-sided drive train 56 branches off from the middle of the registration drive train 54, and an electromagnetic clutch is in the middle of the double-sided drive train 56. 57 is provided. The feeding control gear 265 and the roller shaft 216a (FIG. 13A) transmit the driving force received from the registration roller gear 264, which is a part of the registration drive train 54, to the feeding roller 216 and the feeding cam 467. It constitutes a feed drive train 455 . That is, in the present embodiment, the feeding drive train 455 as the second drive transmission section is a drive transmission path connected downstream of the registration drive train 54 as the first drive transmission section. A double-sided drive train 56 as a third drive transmission unit is a drive transmission path branched from the middle of the registration drive train 54 .

Operations of the feeding cam 467 and the intermediate plate 268 will be described with reference to FIGS. Since the intermediate plate 268 is always urged upward in the drawing by the intermediate plate spring 282 , the cam surface 467 a of the feed cam 467 contacts the cam surface 268 a of the intermediate plate 268 .

FIG. 14(a) shows the first state (balanced state) of the feed cam 467. FIG. The first state is a state in which the feeding cam 467 is stopped or immediately after the solenoid 266 is driven and the feeding cam 467 starts rotating. In the first state, the biasing force of the intermediate plate spring 282 causes the cam surface 268a of the intermediate plate 268 to contact the first region a1 of the cam surface 467a of the feeding cam 467. As shown in FIG. At this time, the biasing force F applied to the feeding cam 467 is directed toward the center of rotation of the feeding cam 467 . In this state, the intermediate plate 268 does not apply a moment to the feed cam 467. That is, in the first state, the feed cam 467 is not urged in the forward rotation direction (clockwise direction in the figure) by the urging force F of the intermediate plate spring 282 .

FIG. 14B shows the second state (assist state) of the feeding cam 467. FIG. The second state is the state after the feeding control gear 265 is released from the locking of the solenoid 66 and the feeding operation is started, and the feeding cam 467 rotates forward (clockwise in the drawing). ing. At this time, the biasing force of the intermediate plate spring 282 causes the cam surface 268a of the intermediate plate 268 to contact the second region a2 of the cam surface 467a of the feeding cam 467. As shown in FIG. The direction of the biasing force F with which the intermediate plate 268 presses the feeding cam 467 (the direction of the line of action of the biasing force F) does not move toward the center of rotation of the feeding cam 467, but passes below the center of rotation in the drawing. . Therefore, in the second state, a moment in the forward rotation direction (clockwise direction in the figure) acts on the feeding cam 467 due to the biasing force F from the intermediate plate spring 282 . In other words, the second state is a state in which the rotation of the feeding cam 467 rotated in the forward rotation direction by the driving force of the motor 60 is assisted. Therefore, even in the configuration of the intermediate plate pressurizing method as in the present embodiment, the biasing force of the intermediate plate spring 282 acts on the feed cam 467 to generate a moment in the forward rotation direction, thereby causing the registration rollers connected to the feed cam 467 to rotate. 350 sheet transport speed may vary.

The control unit 100 of the image forming apparatus 1 connects the electromagnetic clutch 57 at the same timing as in the first embodiment when feeding the succeeding sheet while the registration roller 350 is conveying the preceding sheet. As a result, a load such as the double-sided conveying rollers 123 and 124 arranged downstream of the electromagnetic clutch 57 is applied to the third registration gear 63 of the registration drive train 54 . This load is load torque in a direction opposite to the direction of driving force transmitted from the motor 60 to the third register gear 63 (forward rotation direction). Therefore, even if the feeding cam 467 is in the second state (assisted state) during the feeding operation and a moment in the forward rotation direction acts on the third register gear 63 from the feeding cam 467, the third register gear 63 is Acceleration of 63 is suppressed. As a result, the acceleration of the registration roller gear 264 connected to the third registration gear 63 is also suppressed, and fluctuations in the sheet conveying speed of the registration rollers 350 are suppressed.

As described above, according to the configuration of the present embodiment as well, fluctuation of the sheet conveying speed of the registration roller 250 due to the biasing force of the pressure spring 69 (biasing member) is suppressed, and image blurring of the image transferred to the sheet is suppressed. can do.

<Other embodiments>
In the above embodiment, the second drive transmission section that transmits the driving force to the cam member is arranged downstream of the first drive transmission section that transmits the driving force to the first conveying member. With this configuration, when the cam member is urged in the forward rotation direction by the urging force of the urging member, the first conveying member is rotated until the backlash at the meshing portions of all the gears included in the first drive transmission portion is clogged. may accelerate. Therefore, it is particularly effective to suppress variations in the sheet conveying speed of the first conveying member by controlling the clutch as described in each embodiment.

However, the control of the clutch described in each embodiment is applied to the configuration in which the second drive transmission section for transmitting the driving force to the cam member branches from the middle of the first drive transmission section for transmitting the driving force to the first conveying member. may apply. For example, the feeding control gear 65 may mesh with the second registration gear 62 or the third registration gear 63 of the registration drive train 54 in the first embodiment (FIG. 6A). Even in this case, when the feeding cam 67 is in the second state (assisted state), the pressure spring 10 is applied until the backlash of the meshing portion of the gears from the second register gear 62 or the third register gear 63 to the pinion gear 60a is clogged. This is because the biasing force of 69 may accelerate the rotation of the registration roller gear 64 . That is, the second drive transmission section is connected to the downstream side of the first drive transmission section, or is arranged to branch from the middle of the first drive transmission section, and communicates with the motor via at least a part of the first drive transmission section. Connected configuration. Similarly, as exemplified in each of the above embodiments, the third drive transmission section is connected to the downstream side of the first drive transmission section or branched from the middle of the first drive transmission section. It is configured to be connected to the motor through at least a part of the part.

Further, in each of the above embodiments, the case where each drive train (driving transmission section) is composed of a gear train has been described. good. For example, in the case of a belt transmission mechanism using a toothed belt, backlash is provided between the teeth on the belt side and the teeth on the pulley side. Therefore, when the cam member is in the second state (assisted state), the sheet conveying speed of the first conveying member may fluctuate due to the biasing force of the biasing member until the backlash is blocked.

REFERENCE SIGNS LIST 1 image forming apparatus/54 first drive transmission section (registration drive train)/55, 155, 255 second drive transmission section (feed drive train)/56, 256 third drive transmission section (duplex drive train) )/60 Motor/67, 467 Cam member (feeding cam)/69, 282 Biasing member (pressure spring, middle leaf spring)/200 Control means (control unit)/115, 268 Sheet stacking Parts (feeding cassette, middle plate) / 116, 216 ... feeding members (pickup rollers, feeding rollers) / 124, 310 ... second conveying members (double-sided conveying rollers, manual feed conveying rollers) / 250, 350 ... first Conveying member (registration roller)

Claims (17)

a sheet stacking unit on which sheets are stacked;
a feeding member that feeds the sheets stacked on the sheet stacking portion;
A cam member configured to switch between a state in which the feeding member abuts against the sheets on the sheet stacking portion and a state in which the feeding member is separated from the sheets on the sheet stacking portion by being rotated. When,
an urging member for generating an urging force for pressing the feeding member against the sheet in a state where the feeding member abuts against the sheet on the sheet stacking portion;
a first conveying member that conveys the sheet fed by the feeding member;
a second conveying member arranged on a conveying path different from the conveying path from the feeding member to the first conveying member and conveying the sheet;
a motor;
a first drive transmission unit that transmits the driving force of the motor to the first conveying member;
a second drive transmission section connected to the motor through at least a portion of the first drive transmission section and transmitting the driving force transmitted from the first drive transmission section to the cam member;
a third drive transmission unit connected to the motor through at least a part of the first drive transmission unit and configured to transmit the driving force transmitted from the first drive transmission unit to the second conveying member, a third drive transmission unit having a clutch capable of switching between a connected state in which the driving force is transmitted to the second conveying member and a released state in which the drive transmission to the second conveying member is released;
control means for controlling the motor and the clutch;
has
The control means brings the clutch into the connected state when rotating the cam member to feed the succeeding sheet by the feeding member while the preceding sheet is being conveyed by the first conveying member. An image forming apparatus characterized by: The image forming apparatus according to claim 1,
When the cam member is positioned within a predetermined angle range, the biasing force of the biasing member causes the cam member to rotate in the same direction as the driving force transmitted from the motor via the third drive transmission section. configured to be rotationally biased;
The control means rotates the cam member to cause the feeding member to feed the subsequent sheet while the preceding sheet is being conveyed by the first conveying member, and the control means causes the cam member to move within the predetermined angle range. An image forming apparatus, wherein the clutch is switched from the disengaged state to the connected state before entering, and the clutch is switched from the connected state to the disengaged state after the cam member leaves the predetermined angle range. . The image forming apparatus according to claim 1 or 2,
Using the clutch as a first clutch,
The image forming apparatus, wherein the second drive transmission section has a second clutch capable of switching between a state of transmitting the driving force to the cam member and a state of releasing the drive transmission to the cam member. . The image forming apparatus according to claim 3,
The second clutch has a gear having a locking portion and a solenoid having a locking pawl that engages with the locking portion to lock the gear. The gear is configured to rotate once each time the detent pawl is disengaged from the locking portion,
The control means switches the first clutch from the released state to the connected state at the same time when the solenoid is energized, and switches the first clutch from the connected state to the released state after the gear makes one rotation. An image forming apparatus characterized by: The image forming apparatus according to any one of claims 1 to 4,
further comprising a third conveying member that conveys the sheet;
The image forming apparatus, wherein the third drive transmission section transmits the driving force to the second conveying member and the third conveying member through the clutch. The image forming apparatus according to any one of claims 1 to 5,
The first drive transmission section has a first gear that rotates together with the first conveying member, and a second gear that meshes with the first gear and transmits the driving force to the first gear. ,
The image forming apparatus, wherein the third drive transmission section is connected to the first gear or the second gear. The image forming apparatus according to any one of claims 1 to 6,
an image carrier;
a transfer unit that transfers the image formed on the image carrier onto a sheet;
further comprising
The image forming apparatus, wherein the first conveying member is a registration roller that feeds the sheet to the transfer section. The image forming apparatus according to any one of claims 1 to 7,
further comprising reversing means for reversing and conveying the sheet having the image formed on the first surface;
The image forming apparatus, wherein the second conveying member conveys the sheet reversed by the reversing means so as to form an image on a second surface opposite to the first surface. The image forming apparatus according to any one of claims 1 to 7,
Using the sheet stacking portion as a first sheet stacking portion,
The image forming apparatus, wherein the second conveying member conveys a sheet fed from a second sheet stacking section different from the first sheet stacking section. The image forming apparatus according to any one of claims 1 to 9,
The image forming apparatus, wherein the clutch is an electromagnetic clutch. The image forming apparatus according to any one of claims 1 to 10,
Between a lower position where the feeding member is held and the feeding member abuts against the sheets on the sheet stacking portion, and an upper position where the feeding member is separated upward from the sheets on the sheet stacking portion. further comprising an arm member that can be raised and lowered with
the biasing member is a spring that biases the arm member toward the lower position;
The image forming apparatus according to claim 1, wherein the cam member is arranged to abut against the arm member, and is rotated to raise and lower the arm member between the upper position and the lower position. The image forming apparatus according to any one of claims 1 to 10,
The sheet stacking portion moves up and down between an upper position where the sheets on the sheet stacking portion come into contact with the feeding member and a lower position where the sheets on the sheet stacking portion are separated downward from the feeding member. is possible and
the biasing member is a spring that biases the sheet stacking unit toward the upper position;
bias the middle plate,
The image forming apparatus according to claim 1, wherein the cam member is arranged so as to abut on the sheet stacking section, and is rotated to raise and lower the sheet stacking section between the upper position and the lower position. The image forming apparatus according to any one of claims 1 to 12,
The image forming apparatus, wherein the second drive transmission section is a drive transmission path connected downstream of the first drive transmission section. The image forming apparatus according to any one of claims 1 to 12,
The image forming apparatus, wherein the second drive transmission section is a drive transmission path branched from the middle of the first drive transmission section. The image forming apparatus according to any one of claims 1 to 14,
The image forming apparatus, wherein the third drive transmission section is a drive transmission path branched from the middle of the first drive transmission section. The image forming apparatus according to any one of claims 1 to 14,
The image forming apparatus, wherein the third drive transmission section is a drive transmission path connected downstream of the first drive transmission section. The image forming apparatus according to any one of claims 1 to 16,
a discharge unit for discharging the sheet conveyed from the first conveying member or the second conveying member to the outside of the image forming apparatus;
The control means causes the preceding sheet and the succeeding sheet to be fed from the sheet stacking section without using the second conveying member, conveyed via the first conveying member, and discharged by the discharging section. When the cam member is rotated to feed the succeeding sheet by the feeding member while the preceding sheet is being conveyed by the first conveying member during operation, the clutch is operated as described above. An image forming apparatus characterized by being in a connected state.

Images