This application claims priority from Japanese Patent Application No. 2019-234143, filed on Dec. 25, 2019, the entire subject matter of which is incorporated herein by reference.
An aspect of the present disclosure is related to an image forming apparatus capable of moving a developing roller to separate from a photosensitive drum.
Image forming apparatus, having a developing roller and a photosensitive drum, capable of forming images electro-photographically, is known. In the image forming apparatus with the developing roller and the photosensitive drum, in order to restrain the developing cartridge from being exhausted in a shorter term, the developing roller may be separated from the photosensitive drum in a timely fashion.
For example, an image forming apparatus may have a rotatable disc-shaped cam to move the developing roller. In particular, the cam may rotate to move the developing roller to contact or separate from the developing roller. The cam may have a disc portion with a gear, and a cam portion arranged on the disc portion., The cam portion may move the developing roller between a position, at which the developing roller contacts the photosensitive drum, and a position, at which the developing roller is separated from the photosensitive drum. Moreover, the cam may have a flag having a form of a rib and a phase-detectable sensor to detect the flag, by which a phase of the cam at a home position may be detected. With this arrangement, when the phase-detectable sensor detects the flag, it may be determined that the developing roller is in a separated condition, in which the developing roller is separated from the photosensitive drum.
For another example, an image forming apparatus may have a rotatable cam, with a leaf cam portion on one side thereof and a cylindrical wall portion projecting on the other side thereof. The cylindrical wall portion may have, for example, three (3) slits. The slits may have different sizes, based on which a controller may detect different phases of the rotating cam. The controller may, during an initializing action after, for example, the image forming apparatus is powered on, identify one of the slits passing by a sensor based on the size and control the cam to stop when a next one of the slits comes in the position to be detected by the sensor.
The former one of the image forming apparatuses mentioned above may have solely one (1) flag in the cam, by which one of the plurality of phases of the cam, corresponding to the separated condition of the developing roller, may be detected. Depending on the single flag alone, when attempting to stop the rotating cam while the developing roller is in another condition, in which the developing roller contacts the photosensitive drum, the phase of the cam may not be accurately detected.
Meanwhile, the latter one of the image forming apparatuses mentioned above with three different-sized slits may detect both the separated condition, in which the developing roller is separated from the photosensitive drum, and a contacting condition, in which the developing roller is in contact with the photosensitive drum. However, in the image forming apparatus, an initializing action, in which the cam may be rotated reversely in a direction opposite to the normal rotating direction when an image is being formed, may not be taken into consideration.
The present disclosure is advantageous in that an image forming apparatus with a developing roller being movable to contact and separate from a photosensitive drum, which is capable of conducting an initializing action in a shorter period based on a movement of a cover, and in which a cam may be stopped accurately at a correct phase, is provided.
According to an aspect of the present disclosure, an image forming apparatus, including a casing, a cover, a photosensitive drum, a developing roller, a photo-interrupter, a moving mechanism, and a controller, is provided. The casing has an opening. The cover is movable between a closed position, at which the opening is closed by the cover, and an open position, at which the opening is exposed. The photo-interrupter includes a light-emitter and a light-receiver. The moving mechanism is configured to move the developing roller between a contacting position, at which the developing roller contacts the photosensitive drum, and a separated position, at which the developing roller is separated from the photosensitive drum. The moving mechanism includes a cam and a cam follower. The cam is configured to rotate about a rotation axis bidirectionally in a normal direction and a reverse direction. The cam includes a first cam portion and a phase-detector wall. The phase-detector wall extends in a circumferential direction centered at the rotation axis of the cam. The phase-detector wall has a first slit, through which light emitted from the light-emitter is allowed to pass the phase-detector wall when the developing roller is at the separated position, and a second slit, through which the light emitted from the light-emitter is allowed to pass the phase-detector wall when the developing roller is at the contacting position. The second slit has a different size in the circumferential direction from the first slit. The cam follower is slidably movable between a protrusive position and a standby position and being pivotable between an operable position and an inoperable position. The cam follower includes a contacting portion and an arm. The contacting portion is configured to contact the first cam portion. The arm extends in a direction different from the contacting portion. The controller is configured to, when the cover moves from the open position to the closed position, conduct a first initializing control, in which the controller causes the cam to rotate in the reverse direction and, after detecting the first slit based on a time period, in which the light emitted from the light-emitter passes through one of the first slit and the second slit, causes the cam to stop rotating.
According to another aspect of the present disclosure, an image forming apparatus, including a casing, a cover, a photosensitive drum, a developing roller, a photo-interrupter, a moving mechanism, and a controller, is provided. The casing has an opening. The cover is movable between a closed position, at which the opening is closed by the cover, and an open position, at which the opening is exposed. The photo-interrupter includes a light-emitter and a light-receiver. The moving mechanism is configured to move the developing roller between a contacting position, at which the developing roller contacts the photosensitive drum, and a separated position, at which the developing roller is separated from the photosensitive drum. The moving mechanism includes a cam and a cam follower. The cam is configured to rotate about a rotation axis bidirectionally in a normal direction and a reverse direction. The cam includes a first cam portion and a phase-detector wall. The phase-detector wall extends in a circumferential direction centered at the rotation axis of the cam. The phase-detector wall has a first slit, through which light emitted from the light-emitter is allowed to pass the phase-detector wall when the developing roller is at the separated position, and a second slit, through which the light emitted from the light-emitter is allowed to pass the phase-detector wall when the developing roller is at the contacting position. The second slit has a different size in the circumferential direction from the first slit. The cam follower is slidably movable between a protrusive position and a standby position and being pivotable between an operable position and an inoperable position. The cam follower includes a contacting portion and an arm. The contacting portion is configured to contact the first cam portion. The arm extends in a direction different from the contacting portion. The controller is configured to, when the cover moves from the open position to the closed position, conduct a first initializing control, in which the controller causes the cam to rotate in the reverse direction and, after detecting the first slit based on a time period, in which the light emitted from the light-emitter passes through one of the first slit and the second slit, causes the cam to stop rotating.
According to another aspect of the present disclosure, an image forming apparatus, including a casing, a cover, a photosensitive drum, a developing roller, a moving mechanism, a photo-interrupter, and a controller, is provided. The casing has an opening. The cover is movable between a closed position, where the cover covers the opening, and an open position, where the cover does not cover the opening. The moving mechanism is configured to move the developing roller between a contacting position, at which the developing roller contacts the photosensitive drum, and a separated position, at which the developing roller is separated from the photosensitive drum. The moving mechanism includes a cam configured to rotate about a rotation axis bidirectionally in a normal direction and a reverse direction. The cam includes a phase-detector wall extending in a circumferential direction centered at the rotation axis of the cam. The phase-detector wall has a first slit and a second slit having a different size in the circumferential direction from the first slit. The photo-interrupter includes a light-emitter and a light-receiver. The controller is configured to, when the cover moves from the open position to the closed position, start rotating the cam in the reverse direction; after starting rotating the cam in the reverse direction, detect the first slit based on a time period, in which light emitted from the light-emitter passes through one of the first slit and the second slit; and after detecting the first slit, stop rotating the cam.
Hereinafter, described with reference to the accompanying drawings will be an embodiment of the present disclosure.
As shown in
In the following description, directions related the image forming apparatus 1 and parts or items included in the image forming apparatus 1 will be referred to on basis of indications by arrows in
The casing 10 has a first opening 10A on the front side thereof. The cover 11 is movable between a closed position, in which the cover 11 closes the first opening 10A, as indicated by solid lines in
The sheet feeder 20 is arranged at a lower position in the casing 10 and includes a sheet tray 21 to store sheet(s) S and a feeder device 22 to feed the sheets S from the sheet tray 21 to the image forming device 30. The sheet tray 21 is movable to be pulled frontward, i.e., leftward in
In the sheet feeder 20, one of the sheets S in the sheet tray 21 may be picked up by the feeder roller 23 and separated from the other sheets S by the separator roller 24 and the separator pad 25. As the separated sheet S is conveyed further, a position of a leading edge of the sheet S may be regulated by the registration roller 27, which may be pausing. Thereafter, as the registration roller 27 starts rotating, the sheet S may be fed to the image forming device 30.
A feeder sensor 28A, a pre-registration sensor 28B, and a post-registration sensor 28C are arranged in the sheet-feeder 20. The feeder sensor 28A is located at a position downstream from the feeder roller 23 and the separator roller 24 in a conveying direction to convey the sheet S. The pre-registration sensor 28B is located at a position upstream from the registration roller 27 in the conveying direction. The post-registration sensor 28C is located at a position downstream from the registration roller 27 in the conveying direction.
The image forming device 30 includes an exposure device 40, a drawer 90 (see
The exposure device 40 includes laser diodes, deflectors, lenses, and mirrors, which are not shown. The exposure device 40 may emit laser beams at the photosensitive drums 50 to expose the photosensitive drums 50 to the light and to scan surfaces of the photosensitive drums 50.
The photosensitive drums 50 include a first photosensitive drum 50Y corresponding to a color of yellow, a second photosensitive drum 50M corresponding to a color of magenta, a third photosensitive drum 50C corresponding to a color of cyan, and a fourth photosensitive drum 50K corresponding to a color of black. In the following paragraphs and the accompanying drawings, a color to which an item corresponds may be identified by a suffix Y, M, C, or K, representing yellow, magenta, cyan, or black, respectively, appended to a reference sign of the item. On the other hand, when items are described generally without necessity of referring to the corresponding colors thereto, the items may be described representatively in a singular form with a single reference sign without the suffix Y, M, C, or K; and the ordinal terms (e.g., first, second, etc.) may be omitted.
The developing cartridge 60 is provided correspondingly to the photosensitive drum 50. In particular, the developing cartridge 60 includes a first developing cartridge 60Y, a second developing cartridge 60M, a third developing cartridge 60C, and a fourth developing cartridge 60K. The first developing cartridge 60Y includes a first developing roller 61Y, which may supply yellow toner to the first photosensitive drum 50Y. The second developing cartridge 60M includes a second developing roller 61M, which may supply magenta toner to the second photosensitive drum 50M. The third developing cartridge 60C includes a third developing roller 61C, which may supply cyan toner to the third photosensitive drum 50C. The fourth developing cartridge 60K includes a fourth developing roller 61K, which may supply black toner to the fourth photosensitive drum 50K.
The first developing roller 61Y, the second developing roller 61M, the third developing roller 61C, and the fourth developing roller 61K are arranged in line in this recited order from upstream to downstream along a sheet-moving direction. In other words, the first developing roller 61Y is at a most upstream position, and the fourth developing roller 61K is at a most downstream position, in the sheet-moving direction for the sheet S. The sheet-moving direction is a direction, in which the sheet S is conveyed in the conveyer 70 (e.g., rearward in
The developing cartridge 60 is movable between a position, in which the developing roller 61 being at a contacting position contacts the corresponding photosensitive drum 50, as indicated by solid lines in
As shown in
Although illustration of the detailed structure of the side frame 91 is omitted, the side frame 91, i.e., the pair of side frames 91R, 91L, may support ends of the photosensitive drum 50. One of the side frames 91R, 91L, e.g., the side frame 91L on the left, has second openings 91A. The second openings 91A may be cutouts formed to dent downward from an upper edge of the side frame 91L. Thus, the second openings 91A are formed through the side frame 91L in the widthwise direction, and cam followers 170, which will be described in detail below, may be accepted in the second openings 91A.
The image forming apparatus 1 has four (4) moving mechanisms, each of which may move one of the first, second, third, and fourth developing rollers 61Y, 61M, 61C, 61K between the contacting position, in which the developing roller 61 contacts the corresponding photosensitive drum 51, and the separated position, in which the developing roller 61 is separated from the corresponding photosensitive drum 51. Thus, four (4) moving mechanisms are provided for the first, second, third, and fourth colors on one-to-one basis.
Each moving mechanism includes a cam 150, a supporting shaft 179, a cam follower 170, a first spring 176, and a releasing member 180 (see
The supporting shaft 179 extends in the widthwise direction. The supporting shaft 179 is arranged on a side frame in the casing 10, which is not shown.
The cam follower 170 engages with the supporting shaft 179. The cam follower 170 is slidably movable along an axial direction of the supporting shaft 179 and is pivotable about the axis of the supporting shaft 179. The cam follower 170 includes a contact portion 172, which may contact the first cam portion 152 of the cam 150.
The cam follower 170 is movable between an operable position, in which the contact portion 172 contacts an end face of the first cam portion 152, as shown in
When the cam follower 170 is located at the protrusive position, the cam follower 170 is received in the second opening 91A in the side frame 91L and urges the developing cartridge 60 to locate the developing roller 61 at the separated position. When the cam follower 170 is located at the standby position, the cam follower 170 is outside the second opening 91A and causes the developing roller 61 to be located at the contacting position. Meanwhile, when the cam follower 170 is at the inoperable position, due to the releasing member 180 moving along with the cover 11 moving from the open position to the closed position, the contact portion 172 is not guided on the first cam portion 152; therefore, the cam follower 170 is maintained at the standby position irrespectively from the rotation of the cam 150.
Referring back to
At upper positions with respect to the side frames 91R, 91L in the drawer 90, arranged are contact portions 94. Each contact portion 94 may contact a slider member 64, which will be described further below. The contact portion 94 includes a roller, and while the axial direction of the photosensitive drum 50 extends in a first direction, and the first, second, third, and fourth photosensitive drums 50Y, 50M, 50C, 50K align along a second direction, the roller in the contact portion 94 may rotate about an axis extending along a third direction, e.g., vertical direction, which extends orthogonally to the first direction and to the second direction.
The drawer 90 includes pressing members 95 for the first, second, third, and fourth developing cartridges 60Y, 60M, 60C, 60K. In particular, two (2) pressing members 95 may be provided for each of the first, second, third, and fourth developing cartridges 60Y, 60M, 60C, 60K. The pressing members 95 are arranged at one and the other ends of the corresponding developing cartridge 60 in the axial direction of the photosensitive drum 50. The pressing members 95 are urged rearward by springs 95A (see
The developing cartridge 60 as shown in
The case 63 has a first protrusive portion 63A and a second protrusive portion 63B, which protrude in the rotation-axis direction, on one sideward face, e.g., a leftward face, thereof. The first protrusive portion 63A is arranged coaxially with the rotation axis 61X of the developing roller 61 and protrudes in the rotation-axis direction. The second protrusive portion 63B is arranged at a position apart from the first protrusive portion 63A for a predetermined distance. The second protrusive portion 63B is arranged at an upper position with respect to the first protrusive portion 63A. The first protrusive portion 63A and the second protrusive portion 63B are rollers, which are rotatable about axes extending in parallel with the rotation-axis direction. Although not shown in the drawings, on the other sideward face, e.g., a rightward face, of the case 63 in the widthwise direction, arranged are a first protrusive portion and a second protrusive portion, which are in the same forms as the first protrusive portion 63A and the second protrusive portion 63B, respectively, at widthwise symmetrical positions.
The case 63 includes a protrusion 63D to be pressed by the pressing member 95 at a frontward position on each sideward face thereof. Thus, the protrusions 63D are arranged at 38649 end faces of the case 63 in the rotation-axis direction.
The coupling 65 may engage with a coupling shaft 119, which will be described further below, so that a rotation-driving force may be input from the coupling shaft 119 to the coupling 65.
The slider member 64 is slidable to move in the rotation-axis direction with respect to the case 63. The slider member 64 may be pressed by the cam follower 170 to slidably move in the rotation-axis direction.
As shown in
The shaft 191 is arranged to extend through the case 63 via holes, which are formed in the rotation-axis direction in the case 63, to be slidably supported by the case 63.
The first contact member 192 includes a pressing face 192A, which is an end face of the first contact member 192 in the rotation-axis direction, and an oblique face 192B, which inclines with respect to the rotation-axis direction. The pressing face 192A is a face to be pressed by the cam follower 170. The oblique face 192B may, when the slider member 64 is pressed by the cam follower 170 in the rotation-axis direction, contact the contact portion 94 on the left in the drawer 90 and urge the developing cartridge 60 in a direction parallel to the sheet-moving direction to move the developing cartridge 60 (see
The second contact member 193 includes an oblique face 193B, which inclines similarly to the oblique face 192B of the first contact member 192. The oblique face 193B may, when the slider member 64 is pressed by the cam follower 170 in the rotation-axis direction, contact the contact portion 94 on the right in the drawer 90 and urge the developing cartridge 60 in the direction parallel to the sheet-moving direction to move the developing cartridge 60 (see
At a position between the first contact member 192 and the case 63, arranged is a spring 194, which urges the slider member 64 toward one side, e.g., leftward, in the 38649 rotation-axis direction. The spring 194 may be a compressed coil spring arranged to coil around an outer periphery of the shaft 191.
As shown in
When the developing roller 61 is located at the contacting position, in which the developing roller 61 contacts the corresponding photosensitive drum 50, as seen in the first developing cartridge 60Y, the second developing cartridge 60M, and the third developing cartridge 60C shown in
As shown in
The disc portion 151 has an approximate shape of a disc and is rotatably supported by a supporting plate 102 (see
The second cam portion 153 works in conjunction with a lever 160 to manipulate the clutch 120 to switch transmission and disconnection through the clutch 120. The second cam portion 153 is a leaf cam protruding sideward along the rotation-axis direction from a second face 151B, which is on the other side of the disc portion 151 opposite to the first face 151A. The second cam portion 153 protrudes sideward from a side face opposite to the side face, on which the first cam portion 152 is arranged. The second cam portion 153 extends in an arc in a view along the rotation-axis direction. The second cam portion 153 may be formed integrally with the disc portion 151. Therefore, the second cam portion 153 rotates synchronously with the first cam portion 152.
The phase-detector wall 154 is a wall, extending in a circumferential direction centered at the rotation axis of the cam 150, to block light emitted from light-emitters in separation sensor 4C or 4K (see
As shown in
The first spring 176 may be a contractive spring, and one end of the first spring 176 is hooked to the spring hook 174. The other end of the first spring 176 is hooked to the supporting plate 102 at a position lower than the spring hook 174. Thus, the first spring 176 may urge the cam follower 170 toward the supporting plate 102, in other words, in a direction from the protrusive position toward the standby position. The first spring 176 may, moreover, urge the cam follower 170 counterclockwise in
As shown in
The separation sensors 4C, 4K are phase sensors detectable of phases of the cams 150C, 150 K, respectively. The separation sensors 4C, 4K each include a photo-interrupter having a light-emitter and a light-receiver. When the first slit 154A or the second slit 154 of the separation sensor 4C/4K is located at a position between the light-emitter and the light-receiver, and when the light emitted from the light-emitter is received by the light-receiver, the separation sensor 4C/4K may output an ON signal to the controller 2. While the phase-detector wall 154 is between the light-emitter and the light-receiver to block the light from the light-emitter, the separation sensor 4C/4K may output an OFF signal to the controller 2.
The first slit 154A and the second slit 154B described earlier may allow the light emitted from the light emitter in the separation sensor 4C/4K to pass there-through when the developing roller 61 is at the separated position and the contacting position, respectively. Therefore, the separation sensor 4C may output the ON signal to the controller 2 when the third developing roller 61C is at the separated position and the light from the light-emitter passing through the first slit 154A is received by the light-receiver. The separation sensor 4K may output the ON signal to the controller 2 when the fourth developing roller 61K is at the separated position and the light from the light-emitter passing through the first slit 154A is received by the light-receiver. Moreover, the separation sensor 4C may out put the ON signal to the controller 2 when the third developing roller 61C is at the contacting position and the light from the light-emitter passing through the second slit 154B is received by the light-receiver. The separation sensor 4K may out put the ON signal to the controller 2 when the fourth developing roller 61K is at the contacting position and the light from the light-emitter passing through the second slit 154B is received by the light-receiver. In other words, each separation sensor 4C/4K is located at a position, in which the separation sensor 4C/4K may detect the first slit 154A when the third/fourth developing roller 61C/61K is at the separated position and may detect the second slit 154B when the third/fourth developing roller 61C/61K is at the contacting position.
In the present embodiment, for a reason of convenience, a condition, in which the light-receiver(s) in the separation sensor(s) 4C, 4K is/are receiving the light, may be expressed as “the separation sensor(s) 4C, 4K is/are ON.” On the other hand, a condition, in which the light-receiver(s) in the separation sensor(s) 4C, 4K are not receiving the light, may be expressed as “the separation sensor(s) 4C, 4K is/are OFF. A voltage required in the phase sensors 4C, 4K to output the ON signal may either be higher or lower than a voltage in the phase sensors 4C, 4K not outputting the ON signal. It may be noted that the cams 150Y, 150M as well has the same formation as the phase-detector wall 154; however, neither the cam 150Y nor the cam 150M is provided with a separation sensor.
Referring back to
The fuser 80 is arranged at a rearward position with respect to the photosensitive drum 50 and the conveyer 70. The fuser 80 includes a heat roller 81 and a pressurizer roller 82 arranged to face the heat roller 81. At an upper position with respect to the fuser 80, arranged is a conveyer roller 15, and at an upper position with respect to the conveyer roller 15, arranged is an ejection roller 16.
In the image forming device 30 configured as above, the surface of the photosensitive drum 50 may be charged evenly by the charger and selectively exposed to the light emitted from the exposure device 40. Thereby, electrostatic latent images based on image data may be formed on the surface of the photosensitive drum 50.
Meanwhile, the toner in the case 63 may be supplied to the surface of the developing roller 61, and when the developing roller 61 contacts the corresponding photosensitive drum 50, the toner may be supplied to the electrostatic latent image formed on the surface of the photosensitive drum 50. Thus, the toner image may be formed on the photosensitive drum 50.
When the sheet S on the conveyer belt 73 passes through the position between the photosensitive drum 50 and the transfer roller 74, the toner image formed on the photosensitive drum 50 may be transferred onto the sheet S. Further, as the sheet S is conveyed to pass through the position between the heat roller 81 and the pressurizer roller 82, the toner images transferred to the sheet S may be fused to the sheet S.
The sheet S ejected from the fuser 80 may be conveyed by the conveyer roller 15 and the ejection roller 16 to rest on an ejection tray 13 formed on an upper face of the casing 10.
Next, described in the following paragraphs will be a configuration to drive or stop rotation of the developing roller 61 and a configuration to move the developing roller 61 to contact or separate from the photosensitive drum 50.
As shown in
The motor 3 is a driving source to drive the developing roller 61 and the cam 150. The motor 3 may rotate in either a normal direction or a reverse direction. The controller 2 may control rotation of the motor 3.
The driving-force transmitter 100 includes, as shown in
The driving-force transmitter gear train 100D includes first idle gears 110, three (3) second idle gears 113A, 113B, 113C, third idle gears 115, clutches 120, and coupling gears 117. The first idle gears 100 include two (2) first idle gears 110A, 110B; the third idle gears 115 include four (4) third idle gears 115Y, 115M, 115C, 115K; the clutches 120 includes four (4) clutches 120; and the coupling gears 117 include four (4) coupling gears 117Y, 117M, 117C, 117K. The gears forming the driving-force transmitter gear train 100D are supported by either the supporting plate 102 or a frame, which is not shown, and may rotate about rotation axes parallel to the rotation axis of the photosensitive drum 50.
The motor 3 includes an output shaft 3A, which may rotate when the motor 3 is active. To the output shaft 3A, attached is a gear, which is not shown.
The third idle gears 115Y, 115M, 115C, 115K are provided to correspond to the colors of yellow, magenta, cyan, and black, respectively, and arranged in this recited order from front to rear. In other words, the third idle gear 115Y for yellow is at a most frontward position among the third idle gears 115Y, 115M, 115C, 115K, and the third idle gear 115K for black is at a most rearward position among the third idle gears 115Y, 115M, 115C, 115K.
The clutches 120 are in a same configuration. The clutches 120 each meshes with one of the third idle gears 115Y, 115M, 115C, 115K to receive the driving force from the third idle gears 115Y, 115M, 115C, 115K. The clutches 120 will be described further below.
The coupling gears 117 each meshes with one of the clutches 120. Each coupling gear 117 includes a coupling shaft 119 (see
With the driving-force transmitter gear train 100D, the coupling gear 117Y for yellow may receive the driving force from the motor 3 through the first idle gear 110A, the second idle gear 113A, the third idle gear 115Y, and the clutch 120. The coupling gear 117M for magenta may receive the driving force from the motor 3 through the first idle gear 110A, the second idle gear 113A, the third idle gear 115M, and the clutch 120. The coupling gear 117C for cyan may receive the driving force from the motor 3 through the first idle gear 110B, the second idle gear 113B, the third idle gear 115C, and the clutch 120. The coupling gear 117K for black may receive the driving force from the motor 3 through the first idle gear 110B, the second idle gear 113B, the third idle gear 115C, the second idle gear 113C, the third idle gear 115K, and the clutch 120.
As shown in
The fifth idle gear 132A is arranged at a frontward position with respect to the fourth idle gear 131A, and the fifth idle gear 132B is arranged at a rearward position with respect to the fourth idle gear 131B. The fifth idle gears 132A, 132B mesh with the fourth idle gears 131A, 131B, respectively.
The YMC clutch 140A may switch transmission and disconnection of the driving-force controller gear train 100C, which forms the transmission flow to transmit the driving force from the motor 3 to the cams 150Y, 150M, 150C. In other words, the YMC clutch 140A may switch state of the cams 150Y, 150M, 150C between rotating and stationary. The YMC clutch 140A includes a larger-diameter gear 140L and a smaller-diameter gear 140S. A quantity of teeth in the smaller-diameter gear 140S is smaller than a quantity of teeth in the larger-diameter gear 140L. The YMC clutch 140A is arranged at a frontward position with respect to the fifth idle gear 132A, with the larger-diameter gear 140L meshing with the fifth idle gear 132A. The YMC clutch 140A may be, for example, an electromagnetic clutch, in which the larger-diameter gear 140L and the smaller-diameter gear 140S may rotate integrally when the YMC clutch 140A is powered on, or activated; and when the YMC clutch 140A is powered off, or deactivated, the larger-diameter gear 140L may idle so that the smaller-diameter gear 140S may stay stationary.
The K clutch 140K is in the configuration similar to the YMC clutch 140A. Therefore, the K clutch 140K may switch transmission and disconnection of the driving-force controller gear train 100C, which forms the transmission flow to transmit the driving force from the motor 3 to the cam 150K. In other words, the K clutch 140K may switch state of the cam 150K between rotating and stationary. The K clutch 140K includes a larger-diameter gear 140L and a smaller-diameter gear 140S. A quantity of teeth in the smaller-diameter gear 140S is smaller than a quantity of teeth in the larger-diameter gear 140L. The K clutch 140A is arranged at a rearward position with respect to the fifth idle gear 132B, with the larger-diameter gear 140L meshing with the fifth idle gear 132B.
The sixth idle gear 133A is arranged at a frontward position with respect to the YMC clutch 140A, and the sixth idle gear 133B is arranged at a rearward position with respect to the K clutch 140K. The sixth idle gears 133A, 133B mesh with the smaller-diameter gears 140S in the YMC clutch 140A and the K clutch 140K, respectively.
The seventh idle gear 134 is arranged between the sixth idle gear 133A and the cam 150Y. The seventh idle gear 134 meshes with the sixth idle gear 133A and the gear portion 150G in the cam 150Y.
The eighth idle gear 135 is arranged between the cam 150Y and the cam 150M. The eighth idle gear 135 meshes with the gear portion 150G in the cam 150Y and the gear portion 150G in the cam 150M.
The ninth idle gear 136 is arranged between the cam 150M and the cam 150C. The ninth idle gear 136 meshes with the gear portion 150G in the cam 150M and the gear portion 150G in the cam 150C.
The tenth idle gear 137 is arranged between the sixth idle gear 133B and the cam 150K. The tenth idle gear 137 meshes with the sixth idle gear 133B and the gear portion 150G in the cam 150K.
With the driving-force controlling gear train 100C, the cam 150Y for yellow may receive the driving force from the motor 3 through the first idle gear 110A, the fourth idle gear 131A, the fifth idle gear 132A, the YMC clutch 140A, the sixth idle gear 133A, and the seventh idle gear 134. The cam 150M for magenta may receive the driving force from the cam 150Y for yellow through the eighth idle gear 135. The cam 150C for cyan may receive the driving force from the cam 150M for magenta through the ninth idle gear 136. The cams 150Y, 150M, 150C may synchronously rotate when the YMC clutch 140A is activated and stop rotating by when the YMC clutch 140A is deactivated.
The cam 150K for black, on the other hand, may receive the driving force from the motor 3 through the first idle gear 110B, the fourth idle gear 131B, the fifth idle gear 132B, the K clutch 140K, the sixth idle gear 133B, and the tenth idle gear 137. The cam 150K may rotate when the K clutch 150K is activated and stop rotating when the K clutch 140K is deactivated.
Next, the releasing member 180 will be described in detail below. The releasing member 180 as shown in
As shown in
Referring back to
The coupling-movable member 181 has a through-hole 181A and a coupling-withdrawable cam 181B, which correspond to one of the coupling shafts 119. The through hole 181A allows an end of the coupling shaft 119 to penetrate there-through to be engaged with the coupling 65. The coupling-withdrawable cam 181B has a face inclining with respect to the front-rear direction, which may cause the coupling shaft 119 to move in the rotation-axis direction so that the coupling shaft 119 may be detached from the coupling 65 when the releasing member 180 moves frontward.
The cam follower-movable member 182 includes four (4) cam follower-movable members 182, each of which corresponds to one of the cam followers 170. The cam follower-movable member 182 is fixed to the coupling-movable member 180 and may move linearly in the front-rear direction along with the coupling-movable member 181.
As shown in
The cam-follower retainer 182B extends rearward from an upper end of the release-engagement portion 182A. The cam-follower retainer 182B has an upward face, which may contact the arm 173 of the cam follower 170 to retain a posture of the cam follower 170 when the cover 11 moved from the closed position is located to the open position and the cam follower 170 is located at the inoperable position.
The stopper 183 is pivotably supported at a frontward portion thereof by the cam follower-movable member 182. In particular, the stopper 183 may pivot about an axis that extends in the rotation-axis direction and is pivotable upward and downward between a pivot-restrictive position, as shown in
The stopper-urging spring 184 is arranged to urge the stopper 183 at all time in a direction from the pivot-restrictive position toward the pivot-allowable position. In
The stopper 183 is arranged such that the arm 173 is located between the release-engagement portion 182A and the stopper 183 when the cover 11 moved from the open position is located at the closed position, and the cam follower 170 is located at the operable position (see
On the other hand, when the cover 11 moved from the open position is located at the closed position, if the cam follower 170 is located at the inoperable position, the cam follower 170 may be moved by the contractive force of the first spring 176 toward the operable position, and the arm 173 may push the stopper 183 downward. Thereby, the stopper 183 may be moved to swing downward to allow the cam follower 170 to pivot to the operable position.
Next, in the following paragraphs, described will be the detailed configuration and movements of the clutch 120. As shown in
The sun gear 121 includes a disc portion 121B, which is rotatable integrally with the gear portion 121A, and claw portions 121C, which are arranged on an outer circumference of the disc portion 121. The claw portions 121C each has a pointed end, which leans to one side in a rotating direction of the sun gear 121. The ring gear 122 includes an inner gear 122A arranged on an inner circumferential surface and an input gear 122B arranged on an outer circumferential surface.
The carrier 123 includes four (4) shaft portions 123A, which support the planetary gears 124 rotatably. The carrier 123 includes an output gear 123B arranged on an outer circumferential surface thereof.
The planetary gears 124 include four (4) planetary gears 124, each of which is supported by one of the shaft portions 123A in the carrier 123. The planetary gears 124 mesh with gear portion 121A of the sun gear 121 and with the inner gear 122A in the ring gear 122.
In the clutch 120, the input gear 122B meshes with the third idle gear 115, and the output gear 123B meshes with the coupling gear 117 (see
As shown in
As shown in
The second lever 162 is swingable about the swing axis X2. The second lever 162 is engageable with the sun gear 121 being one of elements in the clutch 120. The second lever 162 is coupled with the first lever 161 and is swingable with respect to the first lever 161 about the swing axis X2. In other words, the first lever 161 is coupled to the second lever 162 in an arrangement such that the first lever 161 may swing with respect to the second lever 162 about the swing axis X2. In the present embodiment, a position of the first lever 161 as shown in
The second lever 162 includes a rotation-supporting portion 162A having a hole 162B, in which the supporting shaft 102A fits, a second arm 162C extending from the rotation-supporting portion 162A, a rotation-restrictive portion 162D, and a spring hook 162E. The rotation-restrictive portion 162D protrudes from the second arm 162C in a direction parallel to the swing axis X2. The rotation-restrictive portion 162D may restrict the second lever 162 from rotating with respect to the first lever 161 in one direction by contacting the protrusion 161D. In particular, as the first lever 161 swings, the protrusion 161D may collide with the rotation-restrictive portion 162D of the second lever 162, as shown in
The second spring 163 may be a torsion spring and may urge the first lever 161 with respect to the second lever 162 in a direction, in which the protrusion 161D may be urged against the rotation-restrictive portion 162D. In other words, the second spring 163 may urge the first lever 161 to cause the rotation-restrictive portion 162D in the second lever 162 to contact the protrusion 161D in the first lever 161 so that the first lever 161 may not rotate with respect to the second lever 162.
In the lever 160, with the first lever 161 and the second lever 162 being coupled with each other, the second arm 162C extends in an arrangement such that a tip end thereof points at an outer circumferential surface of the disc portion 121B of the sun gear 121. Meanwhile, to the spring hook 162E, as shown in
The lever 160 may contact the outer circumferential surface of the second cam portion 153 of the cam 150 at the tip end of the first arm 161C. The lever 160 is movable between a transmittable position, in which the tip end of the first lever 161 is separated from the second cam portion 153 and the second lever 162 engages with the claw portion 121C in the clutch 120 to place the clutch 120 in the engaging state, as shown in
Moreover, when the lever 160 is at the transmittable position, in which the second lever 162 engages with the claw portion 121C in the sun gear 121 being one of the elements forming the planetary gear assembly, and when the motor 3 rotates in the reverse direction, the first lever 161 may be pushed by the second cam portion 153, and the first lever 161 may swing relatively to the second lever 162 against the urging force of the second spring 163 to move to the swung position, as shown in
Next, described in the following paragraphs will be actions in the image forming apparatus 1 under control of the controller 2. The controller 2 may control overall actions in the image forming apparatus 1. The controller 2 includes a CPU, a ROM, a RAM, and input/output device, which are not shown. The controller 2 may execute predetermined programs to process operations.
For example, the controller 2 may control the YMC clutch 140A and the clutch 140K based on signals from the separation sensors 4C, 4K to control the contacting and separating motions of the developing roller 61 with respect to the photosensitive drum 50.
Moreover, when the cover 11 moves from the open position to the closed position, the controller 2 may conduct a first initializing control (see S101-S153 in
As shown in
After the image forming apparatus 1 is powered on, in S2, the controller 2 determines, based on signals from the cover sensor, whether the cover 11 is closed or not. If the controller 2 determines that the cover 11 is not closed (S2: NO), the controller 2 waits until the cover 11 is closed. If the controller 2 determines that the cover 11 is closed (S2: YES), in S100, the controller 2 conducts a cam reverse-separation process, in which the controller 2 manipulates the cam 150 to rotate in the reverse direction to separate the developing roller 61 from the photosensitive drum 50. Thereafter, in S4, the controller 2 determines, based on signals from the cove sensor, whether the cover 11 is open. If the controller 2 determines that the cover 11 is not open (S4: NO), the controller 2 waits until the cover 11 opens. If the controller 2 determines that the cover is open (S4: YES), the flow returns to S2 and waits until the cover 11 is closed.
When the controller 2 determines that the cover 11 is closed (S2: YES), the controller 2 conducts a process to place the cam 150, the lever 160 and the cam follower 170 which may interact with the cam 150, at respective initial positions through the cam reverse-separation process (S100) as shown in
In the cam reverse-separation process, in S101, the controller 2 rotates the motor 3 in the reverse direction, and in S102, activates the YMC clutch 140A. Thereby, the cam 150, in particular, the cams 150Y, 150M, 150C, rotates in the reverse direction.
In S111, the controller 2 determines whether the separation sensor 4C is switched OFF. If the separation sensor 4C is not OFF (S111: NO), the controller 2 waits until the separation sensor 4C is switched OFF. If the controller 2 determines that the separation sensor 4C is OFF (S111: YES), in S120, the controller 2 determines whether the separation sensor 4C is thereafter switched ON. If the separation sensor 4C is not switched ON (S120: NO), the controller 2 waits until the separation sensor 4C is switched ON. If the controller 2 determines that the separation sensor 4C is switched ON (S120: YES), in S121, the controller 2 starts counting for a counter 1. The counter 1 indicates a value, which corresponds to a size of a slit detected firstly by the separation sensor 4C after the cam 150 started the reverse rotation. in other words, the controller 2 starts measuring a size of the slit which is detected firstly after the cam 150 started the reverse rotation. In S122, the controller 2 determines whether the separation sensor 4C is switched OFF. If the separation sensor 4C is not OFF, the controller 2 waits until the separation sensor 4C is switched OFF. If the separation sensor 4C is switched OFF (S122: YES), in S123, the controller 2 ends counting for the counter 1.
In S130, the controller 2 determines whether the separation sensor 4C is switched ON, and if the separation sensor 4C is not ON (S130: NO), the controller 2 waits until the separation sensor 4C is switched ON. If the separation sensor 4C is switched ON (S130: YES), in S131, the controller 2 starts counting for a counter 2. The counter 2 indicates a value, which corresponds to a size of a slit detected secondly by the separation sensor 4C after the cam 150 started the reverse rotation. In S132, the controller 2 determines whether the separation sensor 4C is switched OFF. If the separation sensor 4C is not OFF, the controller 2 waits until the separation sensor 4C is switched OFF. If the separation sensor 4C is switched OFF (S132: YES), in S134, the controller 2 ends counting for the counter 2.
In S140, the controller 2 determines whether the counter 2 indicates a value greater than a predetermined threshold value. The predetermined threshold value is a value representing a time length between a time length, which is required for the first slit 154A to pass by the separation sensor 4C, and a time length, which is required for the second slit 154B to pass by the separation sensor 4C. In S140, if the controller 2 determines that the counter 2 indicates a value greater than the predetermined threshold value (S140: YES), it may be determined that the slit that passed through the separation sensor 4C to cause the separation sensor 4C to output the signal is the second slit 154B. Therefore, the controller 2 waits until the separation sensor 4C is switched ON (S141: YES) and thereafter switched OFF (S142: YES). After the separation sensor 4C is switched OFF (S142: YES), or in S140, if the controller 2 determines that the counter 2 indicates a value not greater than the predetermined threshold value (S140: NO), the flow proceeds to S150. In S150, the controller 2 waits until a predetermined time period T1 elapses. The predetermined time period T1 is a period required for the cam 150 to rotate for a predetermined angle after the first slit 150A passed through the separation sensor 4C. If the controller 2 determines that the predetermined time period T1 elapses (S150: YES), in S151, the controller 2 deactivates the YMC clutch 140A and, in S152, stores a state “D” of the cam 150 in a memory, e.g., the RAM. The cam 150 may stop when the YMC clutch 140A is deactivated.
In this paragraph, distinguishable states of the cam 150 will be described. As shown in
Referring back to
It may be noted that the above paragraphs described the process to locate any of the cams 150Y, 150M, 150C for yellow, magenta, and cyan at the initial position. Meanwhile, the cam 150K for black may be similarly located at the initial position thereof through the same process by controlling the K clutch 140K instead of the YMC clutch 140A based on the signal from the separation sensor 4K instead of the separation sensor 4C. Therefore, detailed description of the process to locate the cam 150K at the initial position is herein omitted.
In the following paragraphs, with reference to a timing chart in
When the cover 11 is at the closed position, and while the image forming apparatus 1 is operating normally, as shown in
In the arrangement as shown in
As the cam follower 170 pivots from the operable position to the inoperable position, the first sprig 176 keeps urging the cam follower 170 toward the standby position. Therefore, at the moment when the contacting portion 172 is separated from the first cam portion 152, the cam follower 170 may move from the protrusive position to the standby position, causing the developing roller 61 to move from the separated position to the contacting position. With the cam follower 170 being located at the standby position, the slidable shaft 171 may retract from the second opening 91A; therefore, if the drawer 90 is pulled outward from the casing 10, or if the drawer 90 drawn outside the casing 10 is pushed back in the casing 10, the slidable shaft 171 may not interfere with the side frame 91L of the drawer 90.
Thereafter, when the cover 11 is moved from the open position to the closed position, the cover sensor may be switched ON (t1 in
Meanwhile, in an arrangement, in which the cover 11 is at the closed, position, the contacting portion 172 is located on the first retainer face F1, and the developing roller 61 is located at the contacting position, the cover 11 may be moved from the closed position to the open position and moved back to the closed position. Thereby, the cam follower 170 may be moved by the urging force of the first spring 176 to pivot and return to the position, at which the contacting portion 172 may contact the first cam portion 152 (see
After the cover 11 is placed at the closed position, the controller 2 may rotate the motor 3 in the reverse direction (t2) and activate the YMC clutch 140A (t3). Thereby, the cam 150 may rotate in the reverse direction. In particular, the cam 150 may rotate in the reverse direction from the position shown in
As the cam 150 rotates further in the reverse direction, the contacting portion 172 may contact the second guiding face F4 of the first cam portion 152, as shown in
As the cam 150 rotates further in the reverse direction from the position shown in
Thereafter, the controller 2 may rotate the motor 3 in the normal direction (t13) and activate the YMC clutch 140A (t14) to cause the cam 150 to rotate in the normal direction for the predetermined angle. After the predetermined time period T2 since the first slit 154A reached the separation sensor 4C and the separation sensor 4C was switched ON, the controller 2 may deactivate the YMC clutch 140A (t15). Thereafter, the controller 2 may stop the motor 3 (t16). Thus, with the contacting portion 172 being located on the second retainer face F2, as shown in
Described above with reference to
Next, with reference to
For multicolored image printing, prior to an image forming operation, the initializing action is completed; therefore, the first, second, third, and fourth developing rollers 61Y, 61M, 61C, 61K are all located at the respective separated positions. In order to locate the first, second, third, and fourth developing rollers 61Y, 61M, 61C, 61K at the respective contacting positions, the controller 2 activates the YMC clutch 140A and the K clutch 140K to cause the cams 150Y, 150M, 150C, 150K to rotate in the normal direction (t0). In the following paragraphs, the cam 150K rotating in the normal direction may be simply expressed as “the cam 150K rotates.” Shortly after the cams 150Y, 150M, 150C, 150K start rotating (t31), the separation sensors 4C, 4K are switched OFF. Thereafter, the controller 2 drives the feeder roller 23 (t51) for a predetermined period so that the sheet S may be picked up and conveyed.
After a time period T11 elapsed (t32), since the separation sensor 4C for cyan output the OFF signal, the controller 2 deactivates the YMC clutch 140A to cause the cams 150Y, 150M, 150C to pause. The time period T11 is set to have a length, in which the contact portion 172 of the cam follower 170 for yellow reaches the position on the second retainer face F2 of the cam 150Y most adjacent to the second guide face F4 at the time when the cams 150Y, 150M, 150C pause.
After a time period T12 elapsed, since t53 when the pre-registration sensor 28B output the ON signal, i.e., when the leading edge of the sheet S passes by the pre-registration sensor 28B, the controller 2 activates the YMC clutch 140A to resume the rotation of the cams 150Y, 150M, 150C (t33). The time period T12 is set to have a length, in which the development of the toner image on the first photosensitive drum 50Y by the first developing roller 61Y may be rendered in time without being late for the transfer of the developed toner image onto the sheet S.
After a time period T21 elapsed, since the separation sensor 4K for black output the OFF signal, the controller 2 deactivates the K clutch 140K to stop the rotation of the cam 150K (t42). The time period T21 is set to have a length, in which the contact portion 172 of the cam follower 170 for black may be located at the position on the second retainer face F2 of the cam 150K most adjacent to the second guide face F4 at the time when the cam 150K pauses.
After a time period T22 elapsed, since t54 when the post-registration sensor 28C output the ON signal, i.e., since the leading edge of the sheet S passed by the post-registration sensor 28C, the controller 2 activates the K clutch 140K to rotate the cam 150K (t43). The time period T22 is set to have a length, in which the development of the toner image in black on the fourth photosensitive drum 50K by the fourth developing roller 61K may be rendered in time to be transferred onto the sheet S.
Next, after a time period T13 elapsed, since t34 when the separation sensor 4C for cyan output the ON signal, the controller 2 deactivates the YMC clutch 140A (t35) to stop the cams 150Y, 150M, 150C. The time period T13 is set to have a length, in which the first developing roller 61Y, the second developing roller 61M, and the third developing roller 61C may all be located at the respective contacting positions, and in which the cams 150Y, 150M, 150C may be stopped at positions corresponding to a position of the cam 150C where the light from the light emitter in the separation sensor 4C passes through a center of the second slit 154B in the cam 150C in the circumferential direction.
After a time period T23 since t43 elapsed, since t36 when the separation sensor 4K for black output the ON signal, the controller 2 deactivates the K clutch 140K to stop the rotation of the cam 150K (t44). The time period T23 is set to have a length, in which the fourth developing roller 61K is moved and located at the contacting position, and in which the cam 150K may be stopped at a position where the light from the light emitter in the separation sensor 4K passes through the center of the second slit 154B in the cam 150K in the circumferential direction.
After a time period T14 elapsed, since t57 when the post-registration sensor 28C output the OFF signal, i.e., since the trailing end of the sheet S passed by the post-registration sensor 28C, the controller 2 activates the YMC clutch 140A (t37) to rotate the cams 150Y, 150M, 150C to cause the first developing roller 61Y, the second developing roller 61M, the third developing roller 61C to be sequentially separated from the first photosensitive drum 50Y, the second photosensitive drum 50M, and the third photosensitive drum 50C, respectively. The time period T14 is set to have a length, in which, after the toner image in yellow is completely developed on the first photosensitive drum 50Y by the first developing roller 61Y, and shortly after completion of transferring the toner image from the first photosensitive drum 50Y to the sheet S, the first developing roller 61Y becomes ready to be moved to the separated position.
After a time period T24 elapsed, since t57 when the post-registration sensor 28C output the OFF signal, the controller 2 activates the K clutch 140K to rotate the cam 150K (t45). The time period T24 is set to have a length, in which, after the toner image in black is completely developed on the fourth photosensitive drum 50K by the fourth developing roller 61K, and shortly after completion of transferring the toner image from the fourth photosensitive drum 50K to the sheet S, the fourth developing roller 61K becomes ready to be moved to the separated position.
After a time period T15 elapsed, since t38 when the separation sensor 4C for cyan output the OFF signal, the controller 2 deactivates the YMC clutch 140A to stop the cams 150Y, 150M, 150C (t40). The time period T15 is set to have a length, in which the cams 150Y, 150M, 150C may be stopped at positions corresponding to a position of the cam 150C where the light from the light emitter in the separation sensor 4C passes through the center of the first slit 154A in the cam 150C in the circumferential direction.
After a time period T25 elapsed, since t39 when the separation sensor 4C for cyan output the OFF signal, the controller 2 deactivates the K clutch 140K to stop the cams 150K (t46). The time period T25 is set to have a length, in which the cam 150K may be stopped at a position where the light from the light emitter in the separation sensor 4K passes through the center of the first slit 154A in the cam 150K in the circumferential direction.
By the actions describe above, the cams 150Y, 150M, 150C, 150K may be maintained at the positions, in which the light emitted from the light emitters in the separation sensors 4C, 4K may pass through the centers of the second slits 154B in the circumferential direction. Therefore, the condition, in which the developing roller 61 is located at the contacting position may be reliably maintained.
According to the embodiment described above, when the cover 11 is moved from the closed position to the open position, the release-engagement portion 182A may contact the arm 173 of the cam follower 170 to move the cam follower 170 to the inoperable position. Meanwhile, the contacting portion 172 of the cam portion 170 is not guided by the first cam portion 152 when the cam follower 170 is located at the inoperable position. Therefore, the cam follower 170 may be maintained at the standby position irrelevantly from the rotation of the cam 150. In this arrangement, when the cover 11 is open, the cam 150 may be located at the standby position, and the cam follower 170 may be restrained from interfering with the side frame 91L of the drawer 90.
The cam 150 has the first cam portion 152, which may move the developing roller 61, and the phase-detector wall 154. The first cam portion 152 protrudes from the first face 151A on one side of the disc portion 151, and the phase-detector wall 154 protrudes from the same first face 151A as the first cam portion 152. Therefore, a size of the cam 150 may be restrained from increasing in the axial direction compared to an arrangement, in which the first cam portion 152 and the phase-detector wall 152 may be arranged on different sides. In this regard, the cam 150, which enables detection of the conditions of the developing roller contacting and separating from the photosensitive drum 50, may be formed compactly so that the image forming apparatus 1 may be downsized.
In particular, the phase-detector wall 154 is arranged in the space inside the inner circumferential face 152S of the first cam portion 152; therefore, the cam 150 may be formed in the compact shape effectively.
Meanwhile, the controller 2 may cause the cam 150 to rotate in the reverse direction to conduct the initializing action and stop the reverse rotation of the cam 150 after the first slit 154A in the phase-detector wall 154 is detected based on the time when the light emitted from the light-emitter transmits through either the first slit 154A or the second slit 154B. Therefore, the initializing action may be performed in a shorter time while the cam 150 may be stopped at the correct phase accurately.
Moreover, the controller 2 may cause the cam 150 to stop at the position, in which the light from the light-emitter transmits through the first slit 154A. Therefore, the initializing action may be completed while the developing roller 61 is reliably located at the separated position.
Moreover, when an image is being formed on the sheet S, the controller 2 may stop the cam 150 at the position, in which the light from the light-emitter passes through the second slit 154B. Therefore, compared to an example that the cam 150 may be stopped in a phase, in which the light from the light-emitter does not pass through the second slit 154B, the image forming operation may be conducted with the developing roller 61 being reliably placed to contact the photosensitive drum 50.
Moreover, according to the present embodiment, the cam follower 170 may be urged to move from the protrusive position to the standby position and from the inoperable position to the operable position by the same first spring 176. In this regard, a quantity of parts in the image forming apparatus 1 may be reduced or restrained from increasing.
Moreover, according to the present embodiment, when the cover 11 moves from the open position to the closed position, and if the cam follower 170 is located at the inoperable position, the stopper 183 may be pushed by the arm 173 to swing and allow the cam follower 170 to pivot from the inoperable position to the operable position. Therefore, the cam follower 170 may return to the operable position easily.
Moreover, according to the present embodiment, the lever 160 includes the first lever 161 and the second lever 162, and the first lever 161 is swingable with respect to the second lever 162. Therefore, when the motor 3 rotates in the reverse direction, the lever 160 may be restrained from bearing an excessive load from the motor 3.
Although an example of carrying out the invention has been described, those skilled in the art will appreciate that there are numerous variations and permutations of the image forming apparatus that fall within the spirit and scope of the invention as set forth in the appended claims. It is to be understood that the subject matter defined in the appended claims is not necessarily limited to the specific features or act described above. Rather, the specific features and acts described above are disclosed as example forms of implementing the claims.
For example, the size of the second slit 154B in the circumferential direction may not necessarily be greater than the size of the first slit 154A in the circumferential direction but may be smaller than the size of the first slit 154A.
For another example, a quantity of the slits formed in different sizes in the circumferential direction in the phase-detector wall 154 may not necessarily be limited to two (2), but the phase-detector wall 154 may have three (3) or more slits in different sizes in the circumferential direction.
For another example, the controller 2 may not necessarily store the state of the cam 150 in the memory after S151 in
For another example, the second opening 91A formed on the side frame 91L may not necessarily be in the cutout form which is open upward but may be, for example, a through hole formed through the side wall.
For another example, the image forming apparatus 1 may not necessarily be limited to an image forming apparatus for forming multicolored images in toners of four colors but may be an image forming apparatus for forming monochrome images or for forming multicolored images in toners of three colors, five colors, or a different number of colors.
For another example, the image forming apparatus may be a multifunction peripheral machine or a copier.
Number | Date | Country | Kind |
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2019-234143 | Dec 2019 | JP | national |