A medium feeding apparatus includes an apparatus main body, and a medium cassette removably inserted into the apparatus main body. The medium cassette is configured to store a medium. The medium cassette includes a medium positioning unit for determining a position of the medium, and a locking unit that locks a movement of the medium positioning unit when the medium cassette is inserted into the apparatus main body and before the medium cassette reaches a predetermined position in the apparatus main body.
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1. A medium feeding apparatus comprising:
an apparatus main body; and
a medium cassette removably inserted into the apparatus main body, the medium cassette being configured to store a medium in a medium placing region;
wherein the medium cassette includes:
a medium positioning unit that determines a position of the medium; and
a locking unit that locks a movement of the medium positioning unit when the medium cassette is inserted into the apparatus main body and before the medium cassette reaches a predetermined position in the apparatus main body;
wherein the apparatus main body includes a contacting section that faces a bottom surface of the medium cassette in the medium placing region when the medium cassette reaches the predetermined position in the apparatus main body;
wherein the locking unit locks the medium positioning unit by contacting the contacting section; and
wherein the medium cassette has a hole through which the locking unit protrudes downward from the medium cassette.
13. A medium feeding apparatus comprising:
an apparatus main body; and
a medium cassette removably inserted into the apparatus main body, the medium cassette being configured to store a medium;
wherein the medium cassette includes:
a medium positioning unit that determines a position of the medium; and
a locking unit that locks a movement of the medium positioning unit when the medium cassette is inserted into the apparatus main body and before the medium cassette reaches a predetermined position in the apparatus main body;
wherein the apparatus main body includes a contacting section provided so that the contacting section faces the medium cassette when the medium cassette reaches the predetermined position in the apparatus main body;
wherein the locking unit locks the medium positioning unit by contacting the contacting section;
wherein the medium positioning unit includes a medium guide movably provided on the medium cassette;
wherein the locking unit locks a movement of the medium guide;
wherein the medium guide includes a rack portion;
wherein the medium cassette includes a rotatable pinion gear that engages the rack portion of the medium guide; and
wherein the locking unit includes a first engaging portion that engages the pinion gear to thereby lock the movement of the medium guide.
2. The medium feeding apparatus according to
3. The medium feeding apparatus according to
the medium positioning unit includes a medium guide movably provided on the medium cassette; and
the locking unit locks a movement of the medium guide.
4. The medium feeding apparatus according to
wherein the medium cassette includes a medium tray for storing the medium, and the medium guide is movably provided on the medium tray;
wherein the locking unit includes a third engaging portion movably provided on the medium guide so as to be contactable with the contacting section of the apparatus main body, and
wherein the third engaging portion is swung by contact with the contacting section of the apparatus main body, and engages a fourth engaging portion formed on the medium tray to lock the movement of the medium guide, to thereby lock the movement of the medium guide.
5. The medium feeding apparatus according to
wherein the fourth engaging portion is formed on a part of the medium tray facing the third engaging portion protruding through the opening.
6. The medium feeding apparatus according to
7. The medium feeding apparatus according to
8. The medium feeding apparatus according to
9. The medium feeding apparatus according to
10. The medium feeding apparatus according to
11. An image forming apparatus comprising:
the medium feeding apparatus according to
an image forming portion that forms an image on the medium fed by the medium feeding apparatus.
12. The medium feeding apparatus according to
14. The medium feeding apparatus according to
the pinion gear is movable in an axial direction of the pinion gear, and is contactable with the contacting section of the apparatus main body; and
the pinion gear moves toward the first engaging portion by contact with the contacting section.
15. The medium feeding apparatus according to
the medium cassette includes a biasing member that biases the pinion gear in a direction away from the first engaging portion; and
the pinion gear has a second engaging portion that engages the first engaging portion when the pinion gear moves toward the first engaging portion resisting a biasing force of the biasing member.
16. The medium feeding apparatus according to
17. The medium feeding apparatus according to
18. The medium feeding apparatus according to
19. The medium feeding apparatus according to
20. The medium feeding apparatus according to
21. The medium feeding apparatus according to
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The present invention relates to a medium feeding apparatus provided in an image forming apparatus or the like.
In an image forming apparatus such as a copier, a printer, a facsimile or the like, an exposure unit such as a laser scanning unit or an LED (light emitting diode) emits light to expose a surface of a photosensitive body (i.e., an image bearing body) based on a image data to form a latent image. The latent image is developed with toner. The resulting toner image is transferred directly or via an intermediate transfer body to a medium such as a printing sheet or a film. The medium is conveyed to a fixing unit, where the toner image is fixed to the medium by application of heat and pressure.
Such an image forming apparatus includes a medium feeding apparatus for storing and feeding the medium. The medium feeding apparatus has a medium cassette in which a stack of the media (i.e., printing sheets) is stored. The medium cassette is detachably mounted to a main body of the medium feeding apparatus. The medium cassette has a pair of medium guides that determine positions of both ends of the media in a widthwise direction. Both medium guides have guide racks that engage a common pinion gear (see, for example, Japanese Laid-open Patent Publication No. 2008-81259 (FIG. 1)).
In this regard, when the medium cassette is mounted to the main body of the medium feeding apparatus, there is a possibility that the medium guides may be unintentionally displaced. In such a case, the medium (guided by the medium guides) may also be displaced.
An aspect of the present invention is intended to provide a medium feeding apparatus and an image forming apparatus capable of enhancing positioning accuracy of a medium stored in a medium cassette.
According to an aspect of the present invention, there is provided a medium feeding apparatus including an apparatus main body, and a medium cassette removably inserted into the apparatus main body. The medium cassette is configured to store a medium. The medium cassette includes a medium positioning unit for determining a position of the medium, and a locking unit that locks a movement of the medium positioning unit when the medium cassette is inserted into the apparatus main body and before the medium cassette reaches a predetermined position in the apparatus main body.
Since the movement of the medium positioning unit is locked by the locking unit while the medium cassette is mounted to the apparatus main body, the medium positioning unit can be prevented from being displaced. Therefore, positioning accuracy of the medium can be enhanced.
According to another aspect of the present invention, there is provided an image forming apparatus including a fan having an impeller. The fan further has a first side and a second side opposite to each other. The image forming apparatus further includes a frame to which the fan is mounted in a predetermined orientation so that the first side of the fan faces the frame. The frame has a ventilation opening facing the impeller. A resilient member is provided on the frame so as to face the fan. The fan has a supporting member on the first side, and an opening on the second side. The supporting member faces the resilient member.
Further scope of applicability of the present invention will become apparent from the detailed description given hereinafter. However, it should be understood that the detailed description and specific embodiments, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the invention will become apparent to those skilled in the art from this detailed description.
In the attached drawings:
Hereinafter, embodiments of the present invention will be described with reference to drawings. In the embodiments described below, descriptions will be given to a case where a medium cassette is inserted in a direction perpendicular to a medium feeding direction. In other words, descriptions will be given to a case where a movable direction of a medium guide is parallel to a mounting/detaching direction (i.e., an insertion/removal direction) of the medium cassette.
First Embodiment.
The medium feeding apparatus 30 includes a medium cassette 100 storing a plurality of media (i.e., printing sheets) 101, and a pickup-and-feeding unit 200 that picks up the media 101 one by one and feeds each medium 101 into a medium feeding path. The pickup-and-feeding unit 200 and a main body of the printer 10 has a continuous medium feeding path, so that the medium 101 can be smoothly fed from the pickup-and-feeding unit 200 to the main body of the printer 10 without causing a paper jam.
The medium feeding apparatus 30 and the main body of the printer 10 are connected using connectors for transmitting and receiving electric signal or the like.
The medium cassette 100 is removably inserted (i.e., detachably mounted) into a main body (i.e., an apparatus main body) 31 of the medium feeding apparatus 30. The medium cassette 100 includes a medium tray 105 for storing the media 101. The medium tray 105 has a placing plate 102 swingably supported by a shaft 102a. A stack of the media 101 is placed on the placing plate 102.
A swingable lift-up lever 103 is provided on a feeding side (i.e., a right side in
A pickup roller 202 is disposed at a position where the pickup roller 202 contacts an upper surface of the stacked media 101 placed on the placing plate 102 pushed upward by the lift-up lever 103. Further, an upward movement detector 102 is provided for detecting that the stacked media 101 reach a height where the upper surface of the media 101 contacts the pickup roller 202.
When the upward movement detector 102 detects that the stacked media 101 reach the height where the upper surface of the stacked media 101 contacts the pickup roller 202, the control unit 600 (
A feed roller 203 and a retard roller 204 are provided on a feeding side (i.e., a right side in
The feed roller 203 and the retard roller 204 separate the media 101 (drawn by the pickup roller 202) into each single medium 101. The pickup roller 202, the feed roller 203 and the retard roller 204 constitute the pickup-and-feeding unit 200.
A pair of conveying rollers 303 and another pair of conveying rollers 310 are provided on a downstream side of the pickup-and-feeding unit 200 in a feeding direction of the medium 101. The conveying rollers 303 convey the medium 101 while correcting a skew of the medium 101. The conveying rollers 304 convey the medium 101 to the image forming portion 410. The conveying rollers 303 include a driving roller 304 and a driven roller 305. The conveying rollers 310 include a driving roller 311 and a driven roller 312.
A passage sensor 302 is provided on an upstream side of the conveying rollers 303. Another passage sensor 313 is provided on an upstream side of the conveying rollers 311. The passage sensors 302 and 313 detect passage of the medium 101. A writing sensor 314 is provided on a downstream side of the conveying rollers 303. The wiring sensor 314 detects passage of the medium 101 for determining timing to start exposure (i.e., writing) in the image forming portion 410.
A rotation of the feed motor 711 (
Further, an MPT (Multi-Purpose Tray) 320 is swingably provided on a side surface (i.e., a right surface in
The MPT 320 further includes a pickup roller 323 for picking up the medium P from the stack placed on the placing plate 321. The placing plate 321 is pushed upward by a not shown spring provided on a bottom of the placing plate 321. An upper surface of the stacked media P on the placing plate 321 contacts the pickup roller 323. The pickup roller 323 is driven by the feed motor 711 (
An MPT roller 324 and a retard roller 325 are provided on a feeding side (i.e., a left side in
The MPT roller 324 and the retard roller 325 separate the media P (drawn by the pickup roller 323) into each single medium P, and feed the medium P toward the conveying rollers 310 in the main body of the printer 10. The pickup roller 323, the MPT roller 324 and the retard roller 325 constitute a MPT pickup-and-feeding unit 322.
The image forming portion 410 of the printer 10 includes a process units (i.e., image forming units) 430K, 430Y, 430M and 430C that respectively form images of black, yellow, magenta and cyan. The process units 430K, 430Y, 430M and 430C are arranged in this order from an upstream side toward a downstream side along the feeding direction of the medium 101. Each of the process units 430K, 430Y, 430M and 430C is detachably mounted to the main body of the printer 10.
Here, a configuration of the process unit 430K will be described. The process unit 430K includes a photosensitive drum 431 as a latent image bearing body. The photosensitive drum 431 has a cylindrical shape and is rotatable in a direction shown by an arrow. The photosensitive drum 431 has a surface capable of holding an electric charge to bear a latent image.
Along a circumference of the photosensitive drum 431, a charging roller 432, an exposure device 433, a developing roller 434 and a cleaning blade 435 are provided in this order in a rotational direction of the photosensitive drum 431. The charging roller (i.e., a charging member) 432 is configured to uniformly charge the surface of the photosensitive drum 431. The exposure device 433 is configured to selectively emit light to the surface of the photosensitive drum 431 to thereby form a latent image. The developing roller (i.e., a developer bearing body) 434 is configured to develop the latent image on the surface of the photosensitive drum 431 using a black toner (i.e., a developer). The cleaning member 435 is configured to remove a residual toner that remains on the surface of the photosensitive drum 431.
The charging roller 432 is applied with a charging voltage for uniformly charging the surface of the photosensitive drum 431. The charging roller 432 rotates contacting the surface of the photosensitive drum 431. The exposure device 433 is provided above the photosensitive drum 431. The exposure device 433 emits light to the surface of the photosensitive drum 431 based on image data to thereby form a latent image. The developing roller 434 is applied with a developing voltage for causing the toner to adhere to the surface of the developing roller 434. The developing roller 434 rotates contacting the surface of the photosensitive drum 431.
A rotation of the ID motor 610 (
The process units 430Y, 430M and 430C have the same configurations as that of the process unit 430K except the toner.
A transfer unit 460 is provided below the process units 430K, 430Y, 430M and 430C. The transfer unit 460 includes four transfer rollers 464 (i.e., transfer members) respectively pressed against the photosensitive drums 431 of the process units 430K, 430Y, 430M and 430C. Each transfer roller 464 includes a roller portion made of conductive rubber or the like. Each transfer roller 464 is applied with a transfer voltage, so as to create a potential difference between a surface potential of the transfer roller 464 and a surface potential of the photosensitive drum 431. The potential difference is for transferring the toner image to the medium 101.
A transfer belt 461 is provided through between the respective photosensitive drums 431 and the transfer rollers 464. The transfer belt 461 is stretched around a driving roller 462 and a tension roller 463. The driving roller 462 is driven by a belt motor 609 (
A cleaning blade 465 and a toner box 466 are provided below the transfer belt 461. The cleaning blade 465 scrapes off (i.e., removes) the toner adhering to the surface of the transfer belt 461. The toner box 466 stores the scraped-off toner. A film 469 is provided on an upstream side of the cleaning blade 465 in a moving direction of the transfer belt 461. The film 469 is provided so as to contact the transfer belt 461 for preventing the toner from scattering outside the toner box 466.
A fixing unit 500 is provided on a downstream side of the image forming portion 410 in the feeding direction of the medium 101. The fixing unit 500 includes an upper roller 501 and a lower roller 502. The upper roller 501 has a halogen lamp 503a therein as a heat source. A surface layer of the upper roller 501 is made of a resilient body. The lower roller 502 has a halogen lamp 503b therein as a heat source. A surface layer of the lower roller 502 is made of a resilient body. The upper roller 501 and the lower roller 502 of the fixing unit 500 apply heat and pressure to the toner image on the medium 101 (fed from the image forming portion 410) to thereby cause the toner to be molten and fixed to the medium 101.
Ejection rollers 504a, 504b and 504c are provided on a downstream side of the fixing unit 500 in the feeding direction of the medium 101. The ejection rollers 504a, 504b and 504c are configured to eject the medium 101 to which the toner image is fixed by the fixing unit 500. A stacker portion 505 is provided on an upper cover of the printer 10. The ejected medium 101 is placed on the stacker portion 505. An ejection sensor 506 is provided on an upstream side of the ejection rollers 504a, 504b and 504c. The ejection sensor 506 detects passage of the medium 101 for determining timings to start rotating the ejection rollers 504a, 504b and 504c.
Electromagnetic clutches (i.e., electromagnetic clutches 706 show in
Next, a configuration of the medium cassette 100 according to the first embodiment will be described in detail.
In
To be more specific, a horizontal plane is defined as an XY-plane. In the XY-plane, a direction parallel to an insertion/removal direction is defined as the Y-direction, and a direction perpendicular to the Y-direction is defined as the X-direction. A direction perpendicular to both of the X-direction and the Y-direction is defined as a Z-direction. A feeding direction of the medium 101 (from the medium cassette 100) is substantially parallel to the X-direction.
A cassette cover 106 is provided at an end portion of the medium cassette 100 in the removal direction (shown by the arrow “e”). The cassette cover 105 has a handle portion 116 which is gripped by a user when the medium cassette 100 is inserted into or removed from (i.e., mounted to or detached from) the main body 31 of the medium feeding apparatus 30.
The medium cassette 100 includes a medium tray 105 for storing a stack of the media 101 therein. The medium tray 105 includes a pair of medium guides 107 and 108 (i.e., a medium positioning unit) for determining positions of both ends of the stacked media 101 in a widthwise direction (i.e., both ends in the Y-direction). The medium tray 105 further includes the above described placing plate 102 (
The medium guides 107 and 108 are made of plate members parallel to an XZ-plane. The medium guides 107 and 108 face each other in the Y-direction. Guide racks 110 and 111 (i.e., rack portions) extend respectively from lower ends of the medium guides 107 and 108. The guide rack 110 and 111 extend inwardly (i.e., toward each other) in the Y-direction. The guide racks 110 and 111 also face each other in the X-direction. A pinion gear 113 is provided between the guide racks 110 and 111 in the X-direction. The pinion gear 113 engages both guide racks 110 and 111. The pinion gear 113 is provided for coupling (i.e., interlocking) movements of the medium guides 107 and 108 so that the medium guides 107 and 108 move symmetrically with respect to a center in the Y-direction. Further, a first engaging portion 112 (i.e., a locking unit) is provided so as to cover the guide racks 110, 111 and the pinion gear 113.
Guide rails 119a and 119b are provided on both ends of the medium cassette 100 in the X-direction. The guide rails 119a and 119b extend in the Y-direction and protruding in the insertion direction (shown by the arrow “d”). The guide rails 119a and 119b engage predetermined parts of the main body 31 of the medium feeding apparatus 30, so as to guide insertion of the medium cassette 110.
As shown in
The first engaging portion 112 further includes posts 120 that protrude from lower surfaces of the base part 112b. The posts 120 engage positioning holes formed on the medium tray 105 to thereby determine a position of the first engaging portion 112. Claw portions 121 are formed on both ends of each base part 112b in the Y-direction. The claw portions 121 engage engaging holes formed on the medium tray 105. By engagement between the claw portions 121 and the engaging holes, the first engaging portion 112 is fixed to the medium tray 105.
The above described pinion gear 113 has a rotation axis extending in the Z-direction. The pinion gear 113 is movable in the Z-direction (i.e., a direction of the rotation axis). In other words, the pinion gear 113 is movable vertically. A gear portion 113G as a second engaging portion is formed on an upper part (i.e., one side in the direction of the rotation axis) of the pinion gear 113. A contact portion 113A is formed on a lower part (i.e., an opposite side in the direction of the rotation axis) of the pinion gear 113. The contact portion 113A protrudes downward via a hole formed on a bottom plate portion (i.e., a tray bottom portion) 105a of the medium tray 105.
Further, a biasing member 115 (for example, a coil spring) is provided on the first engaging portion 112. The biasing member 115 biases the pinion gear 113 downward along the direction of the rotation axis. A lower surface of the contact portion 113A of the pinion gear 113 faces a bottom plate portion (i.e., a main body bottom portion) 150 of the main body 31 of the medium feeding apparatus 30.
A rib 151 is formed on an upper surface of the main body bottom portion 150 of the medium feeding apparatus 30. The rib 151 has a predetermined height with respect to the upper surface of the main body bottom portion 150. The rib 151 is elongated in the Y-direction. The rib 151 includes a slope portion 152 as a contacting section. As shown in
The rib 151 has the predetermined height and extends in the Y-direction, and is kept in contact with the contact portion 113A even when the medium cassette 100 is fully inserted into the main body 31 of the medium feeding apparatus 30. In this example, the rib 151 is formed on the main body bottom portion 150 so as to extend in the Y-direction. However, it is also possible to partially increase a thickness of the main body bottom portion 150.
When the contact portion 113A of the pinion gear 113 contacts the rib 151 of the main body bottom portion 150, the pinion gear 113 is pushed upward resisting the biasing force of the biasing member 115 along the Z-direction (i.e., the direction of the rotation axis).
When the pinion gear 113 moves upward, the gear portion 113G of the pinion gear 113 engages the engaging racks 114a and 114b of the first engaging portion 112. Therefore, a rotation of the pinion gear 113 is locked by the first engaging portion 112 (i.e., the engaging racks 114a and 114b).
Further, the gear portion 113G consistently engages the above described guide racks 110 and 111 (
As shown in
Therefore, the pinion gear 113 moves downward along the Z-direction by the force of the biasing member 115, and the gear portion 113G of the pinion gear 113 disengages from the engaging racks 114a and 114b of the first engaging portion 112. In this state, the pinion 113 becomes rotatable, and the guide racks 110 and 111 become movable in the Y-direction.
Here, a lock lever 117 of the medium guide 107 will be described. The lock lever 117 is provided for locking the medium guides 107 and 108 at arbitrary positions in accordance with the width of the medium 101 stored in the medium tray 105.
As shown in
A rack portion 118 is formed on an inner surface of the groove 105b of the medium tray 105. The rack portion 118 of the groove 105b engages the rack portion 117a of the lock lever 117. A biasing member 123 (
In a state shown in
Further, when a user pushes an upper end of the lock lever 117 in a direction resisting the biasing force of the biasing member 123, the rack portion 117a of the lock lever 117 moves apart from the rack portion 118 of the medium tray 105. Therefore, the medium guide 107 becomes movable in the Y-direction. The medium guide 108 becomes movable symmetrically to the medium guide 107.
Next, a control system of the printer 10 will be described.
Detection signals are inputted into the main controller 601 via an input port. The detection signals are outputted by the passage sensors 302 and 313, the writing sensor 314 and the ejection sensor 506. Based on the received detection signals, the main controller 601 performs control (i.e., activation, stopping, or switching between operations) of components of the printer 10.
The main controller 601 is also connected to a feed motor controller 602, a clutch controller 603, a belt motor controller 604, an ID motor controller 605 and a fixing motor controller 606.
The feed motor controller 602 sends an actuation signal to the feed motor 711 to thereby control the rotation of the feed motor 711. The clutch controller 603 send an actuation signal to the electromagnetic clutch 706 to thereby control the operation of the electromagnetic clutch 706. With this process, rotations of the pickup roller 202, the feed roller 203, the conveying rollers 303 and 310 and the ejection rollers 504a, 504b and 504c are controlled. That is, the feeding and conveying of the medium 101 are controlled.
The belt motor controller 604 sends an actuation signal to the belt motor 609 to thereby control the rotation of the belt motor 609. With this process, the conveying of the medium 101 by the transfer belt 461 is controlled.
The ID motor controller 605 sends an actuation signal to the ID motor 610 to thereby control the rotation of the ID motor 610. With this process, rotations of the photosensitive drum 431 and the developing roller 434 of each of the process units 430K, 430Y, 430M and 430C are controlled. In this regard, the charging roller 432 rotates following the rotation of the photosensitive drum 431.
The fixing motor controller 606 sends an actuation signal to the fixing motor 611 to thereby control the rotation of the fixing motor 611. With this process, rotations of the upper roller 501 and the lower roller 502 of the fixing unit 500 are controlled.
These motors are, for example, two-phase excitation pulse motors, DC (Direct Current) motors or the like. The two-phase excitation pulse motor is driven by a constant current. Acceleration and deceleration of the rotation speed of the motor are controlled by switching a phase current direction based on rising of clock signal, or by varying a clock frequency. A rotation speed of the DC motor is controlled by controlling a voltage applied to motor terminals. A rotating direction of the DC motor is controlled by changing polarities of the motor terminals.
The main controller 601 is connected to an operation panel 612. The operation panel 612 includes an input unit 612a and a display unit 612b. The input unit 612a has switches and the like. The display unit 612b has an LED (Light Emitting Diode), LCD (Liquid Crystal Display) and the like. Setting of conditions (for example, choice of font or choice of medium) of the printer 10 can be performed using the input unit 612a of the operation panel 612. The display unit 612b displays the conditions set by means of the input unit 612a.
The main controller 601 is connected to an interface unit 613. The interface unit 613 includes an interface connector, an interface IC (Integrated Circuit) and the like. The interface unit 613 receives a print data (i.e., image data) sent from a host computer HC, and transfers the received data to the main controller 601.
The control unit 600 of the printer 10 is capable of sending a signal to the medium feeding apparatus 30 via a connector connecting the main body of the printer 10 and the medium feeding apparatus 30. The signal is for controlling an operation of the medium feeding apparatus 30 (for example, rotations of the hopping roller 202 and the feed roller 203).
The control unit 600 of the printer 10 further includes voltage controllers for controlling charging voltages, developing voltages and transfer voltages applied to the charging rollers 432, the developing rollers 434 and the transfer rollers 464, temperature controllers for controlling temperatures of the heat sources 503a and 503b of the fixing unit 500, and a lift-up controller for driving the motor 104 (
Next, an operation of the printer 10 and an operation of the medium feeding apparatus 30 will be described. In the case of feeding the medium 101 from the medium cassette 100, the media 101 stored in the medium cassette 100 are fed into the medium feeding path one by one (beginning at the top of a stack of the media 101) by the pickup-and-feeding unit 200 including the pickup roller 202, the feed roller 203 and the retard roller 204.
The medium 101 fed by the pickup-and-feeding unit 200 passes the passage sensor 302, and reaches the conveying rollers 303. The conveying rollers 303 start rotation at a predetermined timing after the passage sensor 302 detects the passage of the medium 101. That is, the conveying rollers 303 halt for a certain time period in a state where a leading edge of the medium 101 contacts a nip portion of the conveying rollers 303. Therefore, the skew of the medium 101 is corrected. As the conveying rollers 303 start rotation, the conveying rollers 303 convey the medium 101.
The medium 101 conveyed by the conveying rollers 303 passes the passage sensor 313 and reaches the conveying rollers 310. The conveying rollers 310 start rotation when the passage sensor 302 detects the passage of the medium 101, and conveys the medium 101 toward the image forming portion 410 without stopping the medium 101. The medium 101 conveyed by the conveying rollers 310 passes the writing sensor 314 and reaches the image forming portion 410.
In the image forming portion 410, the medium 101 is conveyed by the transfer belt 461 and reaches a nip portion between the photosensitive drum 431 of the process unit 430K and the transfer roller 464. In the process unit 430K, the surface of the photosensitive drum 431 is uniformly charged by the charging roller 432. The uniformly charged surface of the photosensitive drum 431 is exposed with light emitted by the exposure device 433, and a latent image is formed on the surface of the photosensitive drum 431. The latent image on the surface of the photosensitive drum 431 is developed by the developing roller 434 using a black toner (i.e., a developer), and a toner image (i.e., a develop image) is formed on the surface of the photosensitive drum 431. When the medium 101 passes the nip portion between the photosensitive drum 431 and the transfer roller 464, the toner image is transferred from the surface of the photosensitive drum 431 to the medium 101.
The medium 101 further passes the process units 430Y, 430M and 430C, and the toner images of respective colors are transferred to the surface of the medium 101 in an overlapping manner.
The medium 101 having passed the process units 430K, 430Y, 430M and 430C is further conveyed by the transfer belt 461, and reaches the fixing unit 500. In the fixing unit 500, the upper roller 501 and the lower roller 502 apply heat and pressure to the medium 101, so that the toner image is fixed to the medium 101.
The medium 101 to which the toner image (i.e., a color image) is fixed by the fixing unit 500 is ejected by the ejection rollers 504a, 504b and 504c, and is placed on the stacker portion 505 on the upper cover of the printer 10. As a result, a formation process of the color image is completed.
In the case of feeding the medium P from the MPT 320, the media P are fed one by one from the stack on the placing plate 321 into a medium feeding path by the MPT pickup-and-feeding unit 322 including the pickup roller 323, the MPT roller 324 and the retard roller 325. The medium P passes the passage sensor 313 and reaches the conveying rollers 310.
The conveying rollers 310 start rotation after the passage sensor 313 detects the passage of the medium P. That is, the conveying rollers 310 halt for a certain time period in a state where a leading edge of the medium P contacts the nip portion of the conveying rollers 310. Therefore, a skew of the medium P is corrected. As the conveying rollers 310 start rotation, the conveying rollers 310 convey the medium P.
The medium P conveyed by the conveying rollers 310 passes the writing sensor 314, and reaches the image forming portion 410. Thereafter, a toner image is formed on the medium P in a similar manner as described above.
Next, the insertion and removal (i.e., the mounting and detaching) of the medium cassette 100 into and from the medium feeding apparatus 30 of the printer will be described with reference to
Upon insertion of the medium cassette 100 into the main body 31 of the medium feeding apparatus 30, the user grips the handle portion 116 (
As the medium cassette 100 is inserted into the main body 31 of the medium feeding apparatus 30, the lower end (i.e., the contact portion 113A shown in
As the pinion gear 113 is pushed upward, the gear portion 113G of the pinion gear 113 engages the engaging racks 114a and 114b of the first engaging portion 112 (
In a state where the pinion gear 113 is pushed upward by the rib 151 of the main body bottom portion 150, the medium cassette 100 is further inserted into the main body 31 of the medium feeding apparatus 30. As a result, the medium cassette 100 is fully (completely) inserted into the main body 31 of the medium feeding apparatus 30 as shown in
During the insertion operation, the pinion gear 113 is kept being pushed upward by the rib 151 of the main body bottom portion 150. Therefore, the pinion gear 113 does not disengage from the engaging racks 114a and 114b. Therefore, the medium guides 107 and 108 do not move.
In this regard, when the medium cassette 100 is fully inserted into the main body 31, a connecting portion 162a of the lift-up gear 162 engages a driving gear 163 provided on the medium feeding apparatus 30 as shown in
The lift-up gear 162 is a sun gear. The lift-up gear 162 engages a planetary gear 161 mounted to a lift-up shaft 160. The lift-up shaft 160 is provided on the medium cassette 100 so as to be vertically movable. The rotation of the lift-up gear 162 causes the planetary gear 161 (
In this regard, the lift-up shaft 160 is schematically shown as the lift-up lever 103 in
Upon removal of the medium cassette 100 from the medium feeding apparatus 30, the user grips the handle 116 (
As shown in
As described above, according to the first embodiment of the present invention, the rotation of the pinion gear 113 is locked (
Further, in a state where the medium cassette 100 is fully inserted into the medium feeding apparatus 30, the rotation of the pinion gear 113 is locked. Therefore, it becomes possible to prevent displacement of initial positions of the medium guides 107 and 108 resulted from an impact during transportation of the printer 10.
First Modification of First Embodiment.
As shown in
With such a configuration, even when there is a phase shift between the gear portion 113G of the pinion gear 113 and the engaging racks 114a and 114b, the gear portion 113G of the pinion gear 113 is smoothly brought into engagement with the engaging racks 114a and 114b owing to the bevel portions 113c and 114c.In this regard, since there is a certain gap between the pinion gear 113 and the engaging racks 114a and 114b, the pinion gear 113 can rotate to eliminate the phase shift.
Second Modification of First Embodiment.
Further, the guides 170 are disposed so as to sandwich the rib 151 (including the slope portion 152) of the medium tray 105 in the X-direction. With such a configuration, the pinion gear 113 is prevented from being pushed by other components than the rib 151 (including the slope portion 152) of the main body bottom portion 150 of the medium feeding apparatus 30. Therefore, when the medium guides 107 and 108 are operated in a state where the medium tray 105 is removed from the main body 31 of the medium feeding apparatus 30, the pinion gear 113 is not pushed by a floor or the like on which the medium tray 105 is placed.
Second Embodiment.
Next, the second embodiment of the present invention will be described.
In the second embodiment, the pinion gear 130 shown in
The pinion gear 130 includes a gear portion 130G that engages the guide racks 110 and 111, and a contact portion 130A that contacts the main body bottom portion 150 of the medium feeding apparatus 30. The gear portion 130G has a structure substantially the same as the gear portion 113G (
Concave portions 132 are formed on a lower surface of the first engaging portion 131 facing the pinion gear 130. The concave portions 132 are engageable with the convex portions 130S of the second engaging portion 130B. The concave portions 132 are formed at the same arrangement pitch as the convex portions 130S. A large number of convex portions 130S of the pinion gear 130 extend radially about a rotation axis of the pinion gear 130. A large number of concave portions 132 of the first engaging portion 131 extend radially about the rotation axis of the pinion gear 130.
Further, the convex portions 130S of the pinion gear 130 and the concave portions 132 of the first engaging portion 131 are arranged at the same arrangement pitch as the rack portion 117a (
The pinion gear 130 is movable in the direction of the rotation axis (i.e., the Z-direction) as was described in the first embodiment. Further, the gear portion 130G is configured not to disengage from the guide racks 110 and 111 throughout a range of movement of the pinion gear 130 in the Z-direction.
A configuration of the printer as an image forming apparatus according to the second embodiment is the same as that of the printer 10 of the first embodiment except configurations of the pinion gear 130 and the first engaging portion 131. An operation of the printer according to the second embodiment is the same as that of the printer 10 of the first embodiment.
Next, the insertion and removal of the medium cassette 100 according to the second embodiment will be described.
Upon insertion of the medium cassette 100 into the medium feeding apparatus 30, the user grips the handle portion 116 provided on the cassette cover 106 (
As the pinion gear 130 is pushed upward, the convex portions 130S (i.e., the second engaging portion 130B) of the pinion gear 130 engages the concave portions 132 of the first engaging portion 131. The convex portions 130S and the concave portions 132 (formed at the same arrangement pitch) engage each other. Therefore, the rotation of the pinion gear 130 is locked. Then, the medium cassette 100 is further inserted into the main body 31 of the medium feeding apparatus 30. During the insertion, the pinion gear 130 is kept being pushed upward by the rib 151 of the main body bottom portion 150, and therefore the convex portions 130S do not separate from the concave portions 132.
The convex portions 130S of the pinion gear 130 and the concave portions 132 of the first engaging portion 131 are in the form of serrations, and can be formed into fine shapes. Further, the convex portions 130S of the pinion gear 130 and the concave portions 132 of the first engaging portion 131 are arranged at the same arrangement pitch as the rack portion 117a (
Upon removal of the medium cassette 100 from the medium feeding apparatus 30, the user grips the handle 116 (
The convex portions 130S of the pinion gear 130 move downward, and disengage from the concave portions 132 of the first engaging portion 131. The gear portion 131G consistently engages the guide racks 110 and 111. Therefore, the pinion gear 130 becomes rotatable according to the movement of the guide racks 110 and 111. Accordingly, the user can operate the medium guides 107 and 108 in accordance with the width of the medium 101.
As described above, according to the second embodiment of the present invention, the concave portions 132 of the first engaging portion 131 and the convex portions 130S (i.e., the second engaging portion 130B) of the pinion gear 130 are in the form of serrations, and therefore can be arranged at a finer pitch than the arrangement pitch of the gear portion 130G. Therefore, the positions of the medium guides 107 and 108 can be finely set in accordance with the width of the medium 101.
Further, a large number of concave portions 132 of the first engaging portion 131 engage a large number convex portions 130S (i.e., the second engaging portion 130B) of the pinion gear 130, and therefore it becomes possible to enhance a strength against an impact upon insertion of the medium cassette 100 into the medium feeding apparatus 30.
In this regard, it is also possible that the first engaging portion 131 have convex portions instead of the concave portions 132, and the second engaging portion 130B of the pinion gear 130 have concave portions instead of the convex portions 130S.
Modification of Second Embodiment.
As shown in
With such a configuration, even when there is a phase shift between the concave portions 132 of the first engaging portion 131 and the convex portions 130S of the pinion gear 130, the concave portions 132 and the convex portions 130S are smoothly brought into engagement with each other owing to the bevel portions 132C and the 130C.
In the above described first and second embodiments and their modifications, the engagement between the gear portion 113G of the pinion gear 113 and the engaging racks 114a and 114b, and the engagement between the convex portions 130S and the concave portions 132 are used. However, the present invention is not limited to such configurations. For example, it is also possible to use a detent mechanism.
Third Embodiment.
Next, the third embodiment of the present invention will be described.
The above described pinion gear 130 of the second embodiment has the convex portions 130S (i.e., the second engaging portion 130B) in the form of serrations at the upper surface thereof. In contrast, a pinion gear 146 of the third embodiment has a friction engaging portion 146B on an outer circumference of an end portion (i.e., an upper end portion in the direction of the rotation axis) facing a first engaging portion 147 (i.e., a locking unit). The friction engaging portion 146B (i.e., a friction contact portion) corresponds to a second engaging portion. The friction engaging portion 146B is inclined with respect to the Z-direction at a predetermined angle.
A contact portion 148 is provided on a surface of the first engaging portion 147 facing the friction engaging portion 146B. The contact portion 148 is a slope surface capable of contacting the friction engaging portion 146.
The pinion gear 146 includes a gear portion 146G that engages the guide racks 110 and 111, and a contact portion 146A pushed by a rib 153 of the main body bottom portion 150 of the medium feeding apparatus 30.
The pinion gear 146 is supported by a supporting portion 149 provided on the first engaging portion 147 so that the pinion gear 146 is movable in the direction of the rotation axis (i.e., the Z-direction). Further, the gear portion 146G is configured not to disengage from the guide racks 110 and 111 throughout a range of movement of the pinion gear 146 in the Z-direction.
The contact portion 146A of the pinion gear 146 does not protrude downward from the medium tray 105, unlike the pinion gear 113 (130) of the first and second embodiments. Instead, a pressing portion 141 is provided on the medium tray 105. The pressing portion 141 is provided so as to contact a lower surface of the contact portion 146A of the pinion gear 146.
When the medium cassette 100 is inserted into the main body 31, the pressing portion 141 contacts the slope portion 152 and reaches the rib 153 (having a predetermined height) of the main body bottom portion 150 of the medium feeding apparatus 30. When the pressing portion 141 contacts the slope portion 152 and then contacts the rib 153, the pressing portion 141 is deformed as shown in
Other configurations of the third embodiment are the same as those described in the first and second embodiments.
Next, the insertion and removal of the medium cassette 100 according to the third embodiment will be described with reference to
Upon insertion of the medium cassette 100 into the medium feeding apparatus 30, the user grips the handle portion 116 provided on the cassette cover 106 (
As the pinion gear 146 is pushed upward, the friction engaging portion 146B of the pinion gear 146 contacts the contact portion 148 of the first engaging portion 147. A rotation of the pinion gear 146 is locked by a friction force between the friction engaging portion 146B and the contact portion 148.
Then, the medium cassette 100 is fully inserted into the main body 31 of the medium feeding apparatus 30 in a state where the pinion gear 146 is pushed upward. During the insertion, the pinion gear 146 is kept being pushed upward by the rib 153 of the main body bottom portion 150, and therefore the friction engaging portion 146B and the contact portion 148 do not separate from each other.
Upon removal of the medium cassette 100 from the medium feeding apparatus 30, the user grips the handle 116 (
As the pinion gear 130 moves downward, the friction engaging portion 146B of the pinion gear 146 disengage from the contact portion 148 of the first engaging portion 147. The gear portion 146G of the pinion gear 146 consistently engages the guide racks 110 and 111. Therefore, the pinion gear 146 becomes rotatable according to the movement of the guide racks 110 and 111. Accordingly, the user can operate the medium guides 107 and 108 in accordance with the width of the medium 101.
As described above, according to the third embodiment of the present invention, the following advantages can be obtained in addition to the advantages described in the first and second embodiments. That is, since the pinion gear 146 is locked by the friction between the contact portion 148 of the first engaging portion 147 and the friction engaging portion 146B of the pinion gear 146, the pinion gear 146 can be locked regardless of the position of the guide racks 107 and 108. Therefore, the third embodiment is advantageous even in the case where the teeth of the guide racks 110 and 111 of the medium guides 107 and 108 are not arranged at constant pitch. This is a case where, for example, the teeth of the guide racks 110 and 111 are arranged at positions corresponding regular medium sizes (A4, A3 or the like), or when the teeth of the guide racks 110 and 111 are arranged at positions corresponding to regular medium sizes and intermediate positions therebetween (i.e., a complex type).
Fourth Embodiment.
Next, the fourth embodiment of the present invention will be described.
The medium cassette 100 includes a cassette cover 106 with a handle portion 116 which is gripped by a user upon insertion and removal of the medium cassette 100 into and from the medium feeding apparatus 30 as described in the first embodiment. The medium cassette 100 further includes a medium tray 205 for storing the medium 101 therein, a pair of medium guides 207 and 208 for determining positions of both ends of the medium 101 in the widthwise direction, and a placing plate 102 on which a stack of the media 101 is placed.
Guide racks 110 and 111 are formed on the lower end of the medium guides 207 and 208. The guide racks 110 and 111 extend inwardly in the Y-direction. As described in the first embodiment, the pinion gear 113 is provided between the guide racks 110 and 111. The pinion gear 113 engages both of the guide racks 110 and 111.
The lock piece 212 has a pair of claw portions 212a as locking portions. The claw portions 212a are provided on both ends of the lock piece 212 in the X-direction. Each claw portion 212a has a plurality of claws arranged in a radial direction (i.e., a direction of a rotation radius) about the swinging axis 208b.
As shown in
A swinging range of the lock piece 212 has a lower end position and an upper end position. In the lower end position, the claw portions 212a are apart from the claw portions 205a of the tray bottom portion 205e by a predetermined angle as shown in
The rib 151 has a predetermined height and extends in the Y-direction. As described below, when the medium cassette 100 is inserted into a predetermined position in the medium feeding apparatus 30, the rib 151 contacts the lock piece 212 from below. The rib 151 keeps contacting the lock piece 212. This state continues to a state where the medium cassette 100 is fully inserted into the main body 31 of the medium feeding apparatus 30.
As shown in
In this regard, the lock lever 117 (
Next, the insertion and removal of the medium cassette 100 according to the fourth embodiment will be described with reference to
Before the medium cassette 100 is inserted into the main body 31 of the medium feeding apparatus 30, the lock piece 212 is in the lower end position as shown in
Upon insertion of the medium cassette 100 into the medium feeding apparatus 30, the user grips the handle portion 116 provided on the cassette cover 106 (
As the medium cassette 100 is inserted into the main body 31, the lock piece 212 moves along the slope portion 152, and reaches onto the rib 151 (having the predetermined height) as shown in
In the state where the lock piece 212 is pushed upward and the claw portions 212a engage the claw portions 205a of the medium cassette 205, the medium guide 208 (to which the lock piece 212 is mounted) is locked with respect to the medium tray 205 so that the medium guide 208 does not move. In other words, the medium guide 208 is locked with respect to the medium tray 205 (i.e., the movement of the medium guide 208 is locked) in a state where medium cassette 100 is inserted halfway into the main body 31. Further, since the movement of the medium guide 207 is coupled with the movement of the medium guide 208 via the pinion gear 113 (
Then, the cassette 100 is further inserted into the main body 31 in a state where the lock piece 212 is pushed upward by the rib 151. As a result, the cassette 100 is fully inserted into the main body 31 of the medium feeding apparatus 30 (
During the insertion of the medium cassette 100, the lock piece 212 is kept being pushed upward by the rib 151 of the main body bottom portion 150, and therefore the claw portions 212a of the lock piece 212 do not separate from the claw portions 205a of the medium tray 205. Therefore, the medium guides 207 and 208 do not move.
As described in the first embodiment, in a state where the medium cassette 100 is fully inserted into the main body 31 of the medium feeding apparatus 30, the connection portion 162a of the lift-up gear 162 provided on the medium cassette 100 engage the driving gear 163 provided in the medium feeding apparatus 30 as shown in
As described above, the lock piece 212 is pushed upward by the rib 151 of the main body bottom portion 150, and the claw portions 212a of the lock piece 212 engage the claw portions 205a of the medium tray 205 to lock the movement of the medium guide 207 and 208 when the medium cassette 100 reaches the predetermined position in the main body 31 of the medium feeding apparatus 30 (
Therefore, it becomes possible to prevent displacement of the medium guides 207 and 208 resulted from an impact upon insertion of the medium cassette 100 or an inertia force of the medium 101. In this regard, the locking of the medium guides 207 and 208 is performed in a state where the medium cassette 100 is almost fully inserted into the main body 31, and therefore it is not necessary for a user to operate the medium guides 207 and 208.
As described above, according to the fourth embodiment, the movements of the medium guides 207 and 208 are locked by the lock piece 212 when the medium cassette 100 is inserted halfway into the main body 31 of the medium feeding apparatus 30. Therefore, it becomes possible to prevent displacement of the medium guides 207 and 208 resulted from an impact upon insertion of the medium cassette 100 or an inertia force of the medium 101. Accordingly, it becomes possible to prevent a skew and displacement of the medium 101.
Here, an operation when the claw portions 212a of the lock piece 212 do not engage the claw portions 205a of the medium tray 205 will be described.
However, the claw portions 212a of the lock piece 212 and the claw portions 205a of the medium tray 205 are arranged at a relatively fine pitch in a range from 0.5 mm to 1.0 mm. Therefore, an engaging manner of the claw portions 212a of the lock piece 212 and the claw portions 205a of the medium tray 205 does not impair the function of the medium guides 207 and 208 (i.e., the function to determine positions of both ends of the medium 101 in the widthwise direction).
Modification.
As shown in
In this regard, the resilient member 212B can be formed of a resilient body such as resin. However, if the resilient member 212B is kept being resiliently deformed for a long time period as shown in
Fifth Embodiment.
Next, the fifth embodiment of the present invention will be described.
As shown in
Each friction contact portion 214a is made of a resilient body having a certain thickness, and has a high friction surface. In other words, the friction contact portion 214a is made of a high friction member. The friction contact portion 214a can be formed of a rubber piece composed of, for example, NBR (Nitrile Butadiene Rubber). The friction contact portion 214a can also be formed of a plate spring to which a urethane film is bonded.
As shown in
As shown in
In contrast, as shown in
The friction contact portions 214a of the lock piece 214 are slightly compressed, and generate repulsion force (i.e., resilient force), so that friction force is generated between the friction contact portions 214a and the contact surfaces 205c. In this state, the movement of the medium guide 208 is locked. Further, since the movement of the medium guide 207 is coupled with the movement of the medium guide 208 via the pinion gear 113 (
As described above, according to the fifth embodiment of the present invention, the movements of the medium guides 207 and 208 are locked by the friction force between the friction contact portions 214a of the lock piece 214 and the contact surfaces 205c of the medium tray 205. Therefore, the medium guides 207 and 208 can be locked at arbitrary positions. Further, fine displacement (
In this embodiment, the lock piece 214 has the friction contact portions 214a (made of high friction material) that contact the contact surfaces 205c of the medium tray 205. However, it is also possible that the contact surfaces 205c of the medium tray 205 has a friction contact portion (made of high friction material) that contacts a surface of the lock piece 214 provided with no friction contact portion.
Sixth Embodiment.
Next, the sixth embodiment of the present invention will be described.
As shown in
In order not to interfere with the contact between the lock piece 215 and the rib 151 of the main body bottom portion 150 of the medium feeding apparatus 30, the guide ribs 205d are not provided on a position (i.e., a center position in the X-direction) facing the rib 151.
With such a configuration, the lock piece 214 is prevented from being unintentionally pushed when the medium cassette 100 is inserted into or removed from the main body 31 of the medium feeding apparatus 30, or when the medium guides 207 and 208 operated while the medium cassette 100 (removed from the main body 31) is placed on a table or the like.
As described above, according to the sixth embodiment of the present invention, the guide ribs 205d are provided for holding the lock piece 214, and therefore unintentional locking of the movement of the guide members 207 and 208 can be prevented. Therefore, operability can be enhanced.
It is also possible to provide the guide ribs 205d on both sides of the slit 205b (
The first through sixth embodiments and modifications thereof can be appropriately combined.
Further, in the first through sixth embodiments and modifications thereof, descriptions have been made of the medium feeding apparatus provided in the printer as the image forming apparatus. However, the present invention is not limited to such a configuration. For example, the present invention is also applicable to a configuration in which a medium cassette is directly inserted into (i.e., mounted to) and removed from (i.e., detached from) a main body of an image forming apparatus.
Furthermore, in the first through sixth embodiments and modifications thereof, the image forming portion 410 includes the process unit 430K, 430Y, 430M and 430C of black, yellow, magenta and cyan (i.e., four colors). However, the number of colors, the number and positions of process units and an image forming system are not limited to those described in the embodiments.
The first through sixth embodiments are particularly advantageous in a medium feeding apparatus where the insertion/removal direction of the medium cassette is parallel to a movable direction of the medium guides. In a general medium feeding apparatus of such type, a tooth jumping may occur between the pinion gear and the guide racks, and the medium guides may be unintentionally displaced, with the result that the medium (guided by the medium guides) may also be displaced. Further, if the medium guides are displaced, a gap may be formed between the medium and the medium guides, with the result that a skew of the medium may occur.
However, according to the first through sixth embodiments (and modifications thereof) described above, the medium guides can be prevented from being unintentionally displaced. Thus, positioning accuracy of the medium can be enhanced, and a skew of the medium can be prevented.
While the preferred embodiments of the present invention have been illustrated in detail, it should be apparent that modifications and improvements may be made to the invention without departing from the spirit and scope of the invention as described in the following claims.
Udagawa, Hiroshi, Kitamura, Makoto
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Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Jan 30 2013 | Oki Data Corporation | (assignment on the face of the patent) | / |
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