The present disclosure generally relates to a cartridge for use in an image forming apparatus, a supply container for supplying an image forming apparatus with toner, and an image forming apparatus.
Generally, an electrophotographic image forming apparatus develops an electrostatic latent image formed on the surface of a photosensitive member as a toner image by using toner and then forms an image on a recording medium by transferring the toner image from the photosensitive member to the recording medium. A process cartridge system and a sequential supply system are known as methods for supplying an image forming apparatus with toner that is consumed as a result of repetition of image formation. The process cartridge system is a system in which a photosensitive member and a developer container containing toner are combined as a process cartridge and, when a toner residual amount in the developer container is empty, the process cartridge is replaced with a new one.
On the other hand, Japanese Patent Laid-Open No. 8-030084 describes a sequential supply developing apparatus. The sequential supply developing apparatus includes a toner conveyance path for supplying toner to a developing roller and a developer supply case connected to the toner conveyance path. The sequential supply developing apparatus supplies toner from the developer supply case to the toner conveyance path in accordance with a detection result of a toner residual amount.
In recent years, image forming apparatuses are not limited to adopting the above-described process cartridge system, sequential supply system, and the like, and are desired by users for various ways of usage.
An aspect of the present disclosure provides a cartridge configured to be attachable to a main body of an image forming apparatus and configured to receive toner supplied from a supply container. The cartridge includes: a supply port configured to receive the toner supplied from the supply container; a shutter member configured to be movable between a first position and a second position, the supply port being covered with the shutter member when the shutter member is located at the first position, the supply port being exposed when the shutter member is located at the second position; and a locking member configured to be movable between a lock position and an unlock position. Movement of the shutter member from the first position to the second position is restricted when the locking member is located at the lock position and movement of the shutter member from the first position to the second position is allowed when the locking member is located at the unlock position. The locking member is moved from the lock position to the unlock position by using electric power supplied from the main body.
Another aspect of the present disclosure provides an image forming apparatus including the cartridge of the above-described aspect, the main body including a power supply and a control unit configured to control the power supply. The control unit is configured to control the power supply such that, when an amount of toner contained in the cartridge is less than a first amount, electric power is supplied from the main body to the cartridge.
Further another aspect of the present disclosure provides a supply container attachable to a cartridge. The supply container includes: a frame configured to contain toner, the frame having an ejection port for ejecting toner contained in the frame; a pushing member attached to the frame, the pushing member being configured to be movable in a first direction, relative to the frame, from a first position to a second position, such that toner contained in the frame is ejected through the ejection port when the pushing member is moved in the first direction; and a movement restriction portion including a first part provided in one of the pushing member and the frame and a second part provided in an other one of the pushing member and the frame, the first part and the second part are brought in contact with each other to restrict movement of the pushing member in the first direction when the pushing member is located at an intermediate position between the first position and the second position. In a state where the pushing member is located at the intermediate position, the pushing member is configured to be movable relative to the frame such that the first part and the second part separate from each other.
Another aspect of the present disclosure provides a cartridge configured to be mounted on an image forming apparatus. The cartridge includes: a frame having a toner containing portion used to contain toner, a supply port for detachably mounting a supply container containing toner, a first opening, and a second opening, the supply port communicating with the toner containing portion, the first opening communicating the toner containing portion with an outside of the frame, the second opening communicating the toner containing portion with the outside of the frame; a first filter attached to the frame so as to cover the first opening, the first filter restricting passage of toner and allowing passage of air; and a second filter attached to the frame so as to cover the second opening, the second filter restricting passage of toner and allowing passage of air.
Further another aspect of the present disclosure provides a supply container used to supply toner to a cartridge mounted on an image forming apparatus. The supply container includes: a frame having a toner containing portion used to contain toner, the frame having a bottom portion and an opening portion, the bottom portion having an ejection port used to eject toner contained in the toner containing portion to the outside of the frame; a first movable member in the toner containing portion; a second movable member in the toner containing portion; and a pushing member fitted to the toner containing portion via the opening portion. When the pushing member is pushed toward the ejection port, toner in the toner containing portion is ejected through the ejection port. Each of the first movable member and the second movable member is restricted to exit through the ejection port to the outside of the frame and is freely movable relative to the frame inside the toner containing portion in a first direction, a second direction perpendicular to the first direction, and a third direction perpendicular to the first direction and the second direction.
Further features of the present disclosure will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Hereinafter, exemplary embodiments of the present disclosure will be described with reference to the attached drawings.
As shown in
The image forming unit 10 is an electrophotographic image forming device including a scanner unit 11, the process cartridge 20, and a transfer roller 12. The process cartridge 20 includes a photosensitive drum 21, a charge roller 22 disposed around the photosensitive drum 21, a developing roller 31, and a cleaning blade 24.
The photosensitive drum 21 as an image carrier in the present embodiment is a photosensitive member formed in a cylindrical shape. The photosensitive drum 21 of the present embodiment has a photosensitive layer made of a negatively-charged organic photosensitive member on a drum-shaped substrate molded by using aluminum. The photosensitive drum 21 is driven to rotate at a predetermined process speed in a predetermined direction (clockwise direction in the drawing) by a motor.
The charge roller 22 contacts with the photosensitive drum 21 at a predetermined pressure contact force and forms a charging portion. The surface of the photosensitive drum 21 is uniformly charged at a predetermined potential by being applied with a desired charging voltage from a charging high voltage power supply. In the present embodiment, the photosensitive drum 21 is charged with negative polarity by the charge roller 22.
The scanner unit 11 performs scanning exposure of the surface of the photosensitive drum 21 by irradiating laser light L corresponding to image information input from the external device or the reading apparatus 200 to the photosensitive drum 21 with a polygon mirror. Through the exposure, an electrostatic latent image based on the image information is formed on the surface of the photosensitive drum 21. The scanner unit 11 is not limited to a laser scanner apparatus. For example, an LED exposure apparatus including an LED array in which a plurality of LEDs is arranged along a longitudinal direction of the photosensitive drum 21 may be adopted as the scanner unit 11.
A developing unit 802 includes the developing roller 31 as a developer carrier that carries a developer, a developer container 32 that is a frame of the developing unit 802, and a supply roller 33 capable of supplying a developer to the developing roller 31. The developing roller 31 and the supply roller 33 are rotatably supported by the developer container 32. The developing roller 31 is disposed at an opening portion of the developer container 32 so as to face the photosensitive drum 21. The supply roller 33 is in contact with the developing roller 31 so as to be rotatable, and toner as a developer contained in the developer container 32 is applied to the surface of the developing roller 31 by the supply roller 33.
The developing unit 802 of the present embodiment uses a contact developing system as a developing system. In other words, a toner layer on the developing roller 31 as a developing device contacts with the photosensitive drum 21 in a developing unit (developing region) in which the photosensitive drum 21 and the developing roller 31 face each other. A developing voltage is applied to the developing roller 31 by a developing high-voltage power supply. Under the developing voltage, toner on the developing roller 31 is transferred from the developing roller 31 to the drum surface in accordance with a potential distribution on the surface of the photosensitive drum 21. Thus, an electrostatic latent image is developed into a toner image. In the present embodiment, a reversal developing system is adopted. In other words, within the surface of the photosensitive drum 21 charged in a charging process, toner adheres to a region in which the amount of electric charge is attenuated as a result of exposure in an exposure process, with the result that a toner image is formed.
In the present embodiment, toner having a particle size of 6 μm and having a negative polarity as a normal charge polarity is used. Polymerized toner produced by polymerization is adopted as an example of the toner of the present embodiment. The toner of the present embodiment is a so-called non-magnetic single-component developer that does not contain a magnetic component and, therefore, the toner is carried on the developing roller 31 mainly by intermolecular force or electrostatic force (image force). Alternatively, a single-component developer that contains a magnetic component may be used. A single-component developer may contain an additive (for example, wax or silica microparticles) for adjusting the flowability and chargeability of toner in addition to toner particles. A two-component developer composed of non-magnetic toner and a magnetic carrier may be used as a developer. When a magnetic developer is used, for example, a cylindrical developing sleeve in which a magnet is disposed is used as a developer carrier. In other words, a developer contained in the developer container 32 is not limited to a single-component developer composed of a toner component and may be a two-component developer composed of toner and a carrier.
An agitating member 34 as an agitator may be provided inside the developer container 32. When the agitating member 34 is driven to rotate, the agitating member 34 agitates toner in the developer container 32 and feeds toner toward the developing roller 31 and the supply roller 33. The agitating member 34 plays a role in equalizing toner in the developer container 32 by circulating toner, not used for developing and stripped from the developing roller 31, in the developer container 32.
A developing blade 35 is disposed at the opening portion of the developer container 32 in which the developing roller 31 is disposed. The developing blade 35 restricts the amount of toner on the developing roller 31. Toner supplied to the surface of the developing roller 31 is made uniform into a thin layer by passing a portion facing the developing blade 35 with rotation of the developing roller 31, and is negatively charged through triboelectric charging.
The feed unit 60 includes a front door 61 openably supported by the printer main body 100, a stack tray 62, an intermediate plate 63, a tray spring 64, and a pick-up roller 65. The stack tray 62 makes up a bottom surface of a recording medium accommodation space that appears when the front door 61 is open. The intermediate plate 63 is supported by the stack tray 62 so as to be movable up and down. The tray spring 64 urges the intermediate plate 63 upward to press recording media P stacked on the intermediate plate 63 against the pick-up roller 65. The front door 61 closes the recording medium accommodation space in a state where the front door 61 is closed with respect to the printer main body 100, and supports the recording media P in cooperation with the stack tray 62 and the intermediate plate 63 in a state where the front door 61 is open with respect to the printer main body 100.
The transfer roller 12 as a transfer device transfers a toner image formed on the photosensitive drum 21 of the process cartridge 20 onto a recording medium. The present embodiment describes a direct transfer system in which a toner image formed on an image carrier is directly transferred from the image carrier onto a recording medium. Alternatively, an intermediate transfer system in which a toner image is transferred from an image carrier onto a recording medium via an intermediate transfer member, such as an intermediate transfer belt, may be adopted. In this case, for example, a transfer unit made up of an intermediate transfer belt, a primary transfer roller that primarily transfers a toner image from a photosensitive drum onto the intermediate transfer belt, and a secondary transfer roller that transfers the toner image from the intermediate transfer belt onto a recording medium functions as a transfer device.
The fusing unit 70 is of a heat fusing type and performs image fusing process by heating toner on a recording medium to melt. The fusing unit 70 includes a fusing film 71, a fusing heater, such as a ceramic heater, that heats the fusing film 71, a thermistor that measures the temperature of the fusing heater, and a pressure roller 72 that is in pressure contact with the fusing film 71.
Next, the image forming operation of the image forming apparatus 1 will be described. When an image formation command is input to the image forming apparatus 1, an image forming process is started by the image forming unit 10 in accordance with image information input from the reading apparatus 200 or an external computer connected to the image forming apparatus 1. The scanner unit 11 irradiates laser light L toward the photosensitive drum 21 in accordance with the input image information. At this time, the photosensitive drum 21 is preliminary charged by the charge roller 22, and an electrostatic latent image is formed on the photosensitive drum 21 when laser light L is irradiated to the photosensitive drum 21. After that, the electrostatic latent image is developed by the developing roller 31, and a toner image is formed on the photosensitive drum 21.
In parallel with the above-described image forming process, the pick-up roller 65 of the feed unit 60 feeds a recording medium P supported on the front door 61, the stack tray 62, and the intermediate plate 63. The recording medium P is fed to a registration roller pair 15 by the pick-up roller 65, and a skew of the recording medium P is corrected when the recording medium P abuts against a nip of the registration roller pair 15. The registration roller pair 15 is driven in synchronization with transfer timing of the toner image, obtained from exposure starting time of the scanner unit 11, and conveys the recording medium P toward a transfer portion that is a nip portion formed by the transfer roller 12 and the photosensitive drum 21.
A transfer voltage is applied from a transfer voltage power supply to the transfer roller 12, and the toner image on the photosensitive drum 21 is transferred onto the recording medium P conveyed by the registration roller pair 15. Residual toner on the surface of the photosensitive drum 21 after transfer is removed by a cleaning blade 24 that is an elastic blade in contact with the photosensitive drum 21. The recording medium P onto which the toner image has been transferred is conveyed to the fusing unit 70, and the toner image is heated and pressurized at the time of passage of a nip portion between the fusing film 71 and pressure roller 72 of the fusing unit 70. Thus, toner particles melt and then fix, with the result that the toner image is fused onto the recording medium P. The recording medium P having passed through the fusing unit 70 is discharged to the outside of the image forming apparatus 1 by the discharge roller pair 80, and is stacked on a discharge tray 81 formed at the top part of the printer main body 100.
The discharge tray 81 is inclined upward toward a downstream side in a discharge direction of a recording medium. A recording medium discharged onto the discharge tray 81 slides down on the discharge tray 81, and a trailing edge is aligned by a restriction surface 84.
As shown in
When, for example, a recording medium is jammed (paper jam) in a conveyance path CP through which the recording medium fed by the pick-up roller 65 passes, a user opens the top cover 82 together with the reading apparatus 200. Then, the user accesses the process cartridge 20 through the first opening portion 101 exposed by opening the top cover 82 and pulls out the process cartridge 20 along a cartridge guide 102. A protruded portion 21a is provided at an end portion of the process cartridge 20 in an axial direction of the photosensitive drum 21 (
When the process cartridge 20 is pulled out to the outside through the first opening portion 101, space allowing hands to enter the conveyance path CP is provided. When the user puts his or her hands into the printer main body 100 through the first opening portion 101 and accesses the recording medium jammed in the conveyance path CP, the user is able to remove the jammed recording medium.
In the present embodiment, as shown in
The opening portion 82a is open such that the supply container mounting portion 701 for supplying toner, provided at the top part of the process cartridge 20, is exposed. When the opening/closing member 83 is open, a user is able to access the supply container mounting portion 701 without opening the top cover 82. The user is able to supply toner to the process cartridge 20 by mounting the toner pack 40 on the supply container mounting portion 701.
In the present embodiment, a system (direct supply system) in which a user supplies toner from the toner pack 40 (
In the present embodiment, the reading apparatus 200 is provided at the top part of the image forming apparatus 1, and, when the opening/closing member 83 is opened, the reading apparatus 200 is initially opened to expose the top cover 82. However, the reading apparatus 200 may be omitted, and the opening/closing member 83 may be configured to be exposed at the top part of the image forming apparatus 1 from the beginning.
As shown in
In the case of reading an image of a document by the reading apparatus 200, the user places the document on the platen glass 203 in a state where the pressure plate 202 is open. Then, the pressure plate 202 is closed to prevent a position deviation of the document on the platen glass 203 and a reading command is output to the image forming apparatus 1 by, for example, operating the operating unit 300. When a reading operation is started, the reading portion in the reading unit 201 reciprocates in a sub-scanning direction, that is, the right-and-left direction in a state of facing the operation portion 300 of the image forming apparatus 1 on the front side. The reading portion reads an image of a document by receiving light reflected from the document with a light receiving portion while emitting light from a light emitting portion toward the document and performing photoelectric conversion.
Hereinafter, the front-and-rear direction, the right-and-left direction, and an up-and-down direction (gravitational direction) in the image forming apparatus 1 are defined on the basis of a state of facing the operation portion 300 on the front side as a standard. Starting with the process cartridge 20, a positional relationship among members detachable from the printer main body 100 will be described with reference to a state of being mounted on the printer main body 100. A longitudinal direction of the process cartridge 20 indicates the axial direction of the photosensitive drum 21.
Next, the configuration of the process cartridge 20 will be described.
As shown in
The toner receiving unit 801 is disposed at the top part of the process cartridge 20. A toner containing portion 8011 made up of a frame for containing toner is provided inside the toner receiving unit 801, and the supply container mounting portion 701 to be coupled to the toner pack 40 is provided at an end portion in the longitudinal direction. The frame that makes up the toner containing portion 8011 may be made up of a single member or may be made up of a combination of a plurality of members. The supply container mounting portion 701 has a supply port 8012 used to receive toner ejected from the toner pack 40. The detailed configuration of the supply container mounting portion 701 and mounting of the toner pack 40 on the supply container mounting portion 701 will be described later.
A first conveyance member 8013, a second conveyance member 8014, and a third conveyance member 8015 are further provided inside the toner receiving unit 801. The first conveyance member 8013 conveys toner having fallen to the end portion of the toner containing portion 8011 in the longitudinal direction via the supply port 8012 in the direction of the arrow H (
When toner from the toner pack 40 as a supply container flows into the toner receiving unit 801, air also flows in at the same time. The toner receiving unit 801 has an air filter 8017 (see
The ejection ports 8016 (
The developing unit 802 located at the bottom part of the process cartridge 20 has an opening 8021 (
Toner having fallen from the toner pack 40 to the toner receiving unit 801 via the supply port 8012 is conveyed inside the toner receiving unit 801 by the first conveyance member 8013, the second conveyance member 8014, and the third conveyance member 8015. Then, the toner is transferred from the toner receiving unit 801 to the developing unit 802 via the ejection ports 8016 and the openings 8021 at both end portions in the longitudinal direction. In this way, toner supplied via the supply port 8012 located at the end portion of the process cartridge 20 in the longitudinal direction and located away from the developer container 32 in a horizontal direction when viewed in the longitudinal direction is transferred inside the cartridge to reach the developer container 32.
In this way, the toner containing portion 8011 of the toner receiving unit 801 and the developer container 32 of the developing unit 802 communicate with each other to make up a container that defines a space for containing toner in the process cartridge 20. Therefore, in the present embodiment, the supply port 8012 for supplying toner from an outside is provided as part of the container of the process cartridge 20. A supply port to be directly coupled to the supply container may be provided in the printer main body 100, and the process cartridge 20 may be configured to receive toner via the supply port. In this case, part of the process cartridge 20, other than the supply port, is detachable from the image forming apparatus 1 as shown in
Toner supplied to the developing unit 802 via the openings 8021 is contained in a conveyance chamber 36 formed inside the developer container 32 made up of the frame of the developing unit 802 (see
The cleaning unit 803 includes a fourth conveyance member 8031, a fifth conveyance member 8032, and a waste toner chamber 8033 defined by the frame (
Here, a laser passage space SP (
The configuration of the toner pack 40 will be described.
As shown in
As shown in
As shown in
As will be described later, when toner is supplied from the toner pack 40 to the image forming apparatus 1, the ejection portion 42 is aligned to a predetermined position, and the toner pack 40 is inserted and coupled to the supply container mounting portion 701. When the ejection portion 42 is rotated by 180 degrees, the ejection portion 42 rotates relative to the shutter member 41, and the ejection port 42a opens. As a result, toner in the bag member 43 flows down to the toner receiving unit 801 by gravity. At this time, the shutter member 41 does not move relative to the supply container mounting portion 701.
As shown in
Here, the rotary shutter member 41 is illustrated. Alternatively, the shutter member may be omitted or a slide shutter member may be applied instead of the rotary shutter member 41. The shutter member 41 may be configured to be broken by mounting the toner pack 40 at the supply port 8012 or rotating the toner pack 40 in a mounted state or may have a removable lid structure like a seal.
A protection cap may be attached to the ejection portion 42 of an unused toner pack 40 to prevent leakage of toner during transport or the like. The protection cap is, for example, configured to restrict relative rotation between the shutter member 41 and the ejection portion 42 by engaging with the cutaway portions of the shutter member 41 and the ejection portion 42 in a state of being connected to the ejection portion 42. By removing the protection cap, a user is able to mount the toner pack 40 on the supply container mounting portion 701.
A shutter opening/closing mechanism of the toner pack 40 and the toner receiving unit 801 and a locking mechanism of the shutter member 41 will be described.
The supply port 8012 is an opening portion that communicates with the toner containing portion 8011 (see
The rotation detection portion 7015 as a rotation detection sensor is a mechanism that detects rotation of the supply port shutter 7013. The rotation detection portion 7015 of the present embodiment is made up of two conductive leaf springs 70151, 70152. The leaf spring 70152 is urged in a clockwise direction and, when pressed by a protruded portion 70135a provided on the outer periphery of the supply port shutter 7013, contacts with the other leaf spring 70151 at a distal end portion 701521. In other words, the rotation detection portion 7015 is an electrical circuit configured to switch between a conductive state and an interrupted state in accordance with a rotational angle (rotational position) of the supply port shutter 7013. As will be described later, the control unit 90 (
As shown in
Before rotation of the supply port shutter 7013 in the R1 direction, the protruded portion 70125a contacts with the protruded portion 70135a (the left-side one in
The locking member 7014 is a member that restricts rotation of the supply port shutter 7013.
The advancing/retracting pin 604 is supported by a holding member so as to be linearly movable in the gravitational direction and its opposite direction (vertical direction). When the motor 601 rotates, the cam gear 603 rotates via the input gear 602, and the advancing/retracting pin 604 is pushed by the cam portion 6031 to reciprocate up and down. With this motion, the locking member 7014 also moves up and down between the lock position and the unlock position.
A drive transmission configuration in the push mechanism 600 of the present embodiment is a combination of the helical gear and the worm gear; however, the drive transmission configuration is not limited thereto as long as a configuration is capable of converting rotation of the motor to linear motion. For example, a configuration may use a bevel gear or a configuration in which the cam gear 603 is directly driven by the motor 601 without the input gear 602 may be adopted. Instead of the motor 601, an actuator that outputs linear motion like a solenoid may be used as a driving source.
The members that make up the push mechanism 600 shown in
A series of operations when the toner pack 40 is mounted on the supply container mounting portion 701, toner is supplied, and then the toner pack 40 is detached will be described on the assumption of the above-described configuration made up of the toner pack 40, the supply container mounting portion 701, and the push mechanism 600.
As shown in
When the toner pack 40 is inserted in the supply container mounting portion 701, a user inserts the toner pack 40 by aligning the cutaway portions (
Through insertion of the toner pack 40, the contact portion 45a (see
In a state where the locking member 7014 has moved to the unlock position, the locking member 7014 is spaced apart from the protruded portions 70135a of the supply port shutter 7013, so the supply port shutter 7013 is rotatable in the R1 direction in
When a user holds the toner pack 40 and rotates the ejection portion 42 or the bag member 43 near the ejection portion 42 by 180 degrees in the R1 direction, the state shown in
Toner having fallen to the toner containing portion 8011 is, as described above, conveyed inside the toner receiving unit 801 to reach the developer container 32 and is placed in a state usable in developing process. Even before newly supplied toner reaches the developer container 32, as long as toner in an amount to maintain image quality remains in the developer container 32, the developing unit 802 may be configured to be able to execute developing process. In other words, regardless of whether image forming operation is being executed in the image forming unit 10 (
The protruded portion 70125b is disposed so as to contact with the protruded portion 70135a of the supply port shutter 7013 when the supply port shutter 7013 is rotated by 180 degrees from the state shown in
In a state of
After ejection of toner from the toner pack 40 is started, when a condition for determining completion of ejection of toner is satisfied, the control unit 90 causes the push mechanism 600 to operate to move the locking member 7014 to the unlock position. In the present embodiment, completion of ejection of toner is determined in accordance with an elapsed time from the time when the rotation detection portion 7015 becomes a conductive state.
After the locking member 7014 moves to the unlock position, a user is able to detach the toner pack 40 in accordance with a procedure reverse to that when the toner pack 40 is attached. In other words, a user holds the ejection portion 42 of the toner pack 40 or the bag member 43 near the ejection portion 42 and rotates the ejection portion 42 or the bag member 43 near the ejection portion 42 by 180 degrees in the R2 direction opposite to that when the toner pack 40 is attached. Then, the supply port shutter 7013 rotates 180 degrees together with the ejection portion 42, and the supply port 8012 is covered with the lid portion 70131 of the supply port shutter 7013 as shown in
In a state where the ejection portion 42 of the toner pack 40 is rotated by 180 degrees in the R2 direction, the position of the cutaway portion of the ejection portion 42 and the position of the cutaway portion of the shutter member 41 match (
In the process of rotation of the supply port shutter 7013 by 180 degrees in the R2 direction, the protruded portion 70135a separates from the leaf spring 70152, and the rotation detection portion 7015 returns to an interrupted state. Then, the control unit 90 recognizes that the supply port shutter 7013 is closed, and causes the push mechanism 600 to operate to move the locking member 7014 to the lock position. Thus, the supply container mounting portion 701 returns to an initial state before toner supply operation is performed. For example, the control unit 90 may determine that a predetermined condition for moving the locking member 7014 to the unlock position is satisfied when a predetermined time has elapsed from when the rotation detection portion 7015 becomes a conductive state. A trigger to move the locking member 7014 to the lock position may be a loss of electrical continuity between the contact portion 70133 (see
In the present embodiment, a positional relationship in which the ejection port 42a of the toner pack 40 and the supply port 8012 communicate by 180-degree rotation is adopted; however, a rotational angle used for the communication may be changed as long as it is possible to attach and detach the toner pack 40 with a similar operation to that of the present embodiment.
Next, a panel 400 will be described. As shown in
In the configuration example of the illustrated panel 400, when all the three indicators 4001, 4002, 4003 are turned off, it indicates that toner in the developer container 32 is at the Out level (fourth state).
As shown in
As shown in
As shown in
The panel 400 shown in
The number of the indicators and its indication method in the panel 400 may be changed as needed. A user may be prompted to supply toner by, for example, blinking the bottom indicator when a toner residual amount in the developer container 32 is at the Low level.
Next, as another example of the supply container, a mode of a first modification example using a bottle-shaped toner bottle unit instead of a bag-shaped toner pack will be described with reference to
As shown in
The inner cylinder 901 includes a cylindrical toner containing portion 9014 used to contain toner, a bottom portion 9013 provided at one end side in the axial direction, and an ejection port 9011 provided at the bottom portion 9013. The inner cylinder 901 has such a cylinder shape that one end portion of the toner containing portion 9014 in the axial direction is closed by the bottom portion 9013. The other end side of the toner containing portion 9014 is an opening portion 9012. The piston 902 is inserted in the toner containing portion 9014 via the opening portion 9012. A spherical weight member 905 freely movable in the toner containing portion 9014 is accommodated in the inner cylinder 901.
The outer cylinder 903 includes a cylindrical inner cylinder accommodation portion 9034 that accommodates inside the toner containing portion 9014 of the inner cylinder 901, a bottom portion 9033 provided at one end side in the axial direction, and an ejection port 9031 provided at the bottom portion 9033. The outer cylinder 903, as well as the inner cylinder 901, has such a cylinder shape that one end portion of the inner cylinder accommodation portion 9034 in the axial direction is closed by the bottom portion 9033. The outer cylinder 903 holds the inner cylinder 901 such that the inner cylinder 901 is not movable relative to the outer cylinder 903. The other end side of the inner cylinder accommodation portion 9034 is an opening portion 9032 through which the piston 902 is inserted.
The ejection port 9011 of the inner cylinder 901 has a narrow cylindrical shape extending from the bottom portion 9013 to one end side in the axial direction. The ejection port 9031 of the outer cylinder 903 is provided at a position corresponding to the ejection port 9011 of the inner cylinder 901 in the bottom portion 9033. The ejection port 9031 of the outer cylinder 903 is an ejection port for ejecting toner contained in the toner containing portion 9014 to the outside of the toner bottle unit 900. A retract space 9013a into which the weight member 905 retracts so as not to close the ejection port 9011 at the time of pushing the piston is provided adjacent to the ejection port 9011 of the inner cylinder 901.
The bottom portion 9013 of the inner cylinder 901 has such a tapered shape that the cross-sectional area reduces toward the ejection port side in the axial direction (particularly, a conical shape that the inside diameter reduces toward the ejection port side in the axial direction). The bottom portion 9033 of the outer cylinder 903, facing the bottom portion 9013 of the inner cylinder 901, also has a similar tapered shape. The ejection port 9011 and the retract space 9013a of the inner cylinder 901 are provided at a vertex part of the tapered shape of the bottom portion 9033. The weight member 905 has a spherical shape. The weight member 905 is guided to the bottom portion 9013 and moves to the retract space 9013a by gravity.
The piston 902 includes an elastic member 906 attached to an end portion 9023 at one end side (ejection port side) in the axial direction, and a push rib 9021 provided around an end portion 9022 at the other end side (portion where a user pushes at the time of pushing the piston). The elastic member 906 is configured to be in contact with the inner peripheral surface of the toner containing portion 9014 without any gap and has a function to prevent passage of toner at the time of pushing the piston. The push rib 9021 has a protruded shape protruding radially outward from the outer peripheral surface of the piston 902.
The configuration of the shutter member 904 is similar to the shutter member 41 provided in the above-described toner pack 40. In other words, as shown in
The memory unit 911 as a storage unit that stores information on the toner bottle unit 900 is attached around the ejection port 9031 in the outer cylinder 903. The memory unit 911 has a plurality of metal plates 9111, 9112, 9113 (
As shown in
The push detection rod 907 is fitted in, for example, a groove in the axial direction, formed on the outer peripheral surface of the inner cylinder 901 or the inner peripheral surface of the outer cylinder 903. With this configuration, movement of the push detection rod 907 in a direction perpendicular to the axial direction is restricted, and the push detection rod 907 is held so as to be movable in the axial direction relative to the inner cylinder 901 and the outer cylinder 903. The piston contact portion 9071 has such a shape that the piston contact portion 9071 is bent perpendicularly to the axial direction, that is, in an L-shape. The piston contact portion 9071 is configured such that the push rib 9021 further reliably contacts. In
The first contact plate 908 and the second contact plate 909 each are a metal plate that switches between a conductive state and an interrupted state depending on the position of the push detection rod 907 made of an electrically insulating resin. A method of detecting a new toner bottle unit 900 by using the first contact plate 908 and the second contact plate 909 will be described later.
A cylinder cover 910 (
Next, a configuration to detect whether a toner bottle unit 900 is unused (new) or used when the toner bottle unit 900 is mounted on the supply container mounting portion 701 will be described. As shown in
The first contact plate 908 and the second contact plate 909 are respectively connected to different metal plates among a plurality of metal plates 9111 to 9113 at end portions opposite from the end portions that contact with the contact release portion 9072 of the push detection rod 907. Here, it is assumed that the first contact plate 908 is connected to the metal plate 9111, and the second contact plate 909 is connected to the metal plate 9113. In this case, by detecting whether there is a flow of current at the time of application of a small voltage between the metal plates 9111, 9113, it is possible to determine whether the toner bottle unit 900 is in a state before pushing the piston (unused) or a state after pushing the piston (used). In other words, in a state where the toner bottle unit 900 is mounted on the supply container mounting portion 701, the control unit 90 of the image forming apparatus 1 is capable of determining whether the toner bottle unit 900 is unused or used in accordance with whether there is electrical continuity between the metal plates 9111, 9113. The control unit 90 is able to determine that user's supply operation has completed on condition that the first contact plate 908 and the second contact plate 909 are not electrically continuous. In accordance with this determination, the control unit 90 executes display control over the panel 400, described above. The control unit 90 also writes a new one flag (new: 1, used: 0) in the memory unit 45 in accordance with a change in electrical continuity between the metal plates 9111, 9113. The new one flag indicates whether the toner bottle unit 900 is used.
In the case of the above configuration, the memory unit 911 may be disposed in a circuit connecting the metal plates 9111, 9112. Thus, the control unit 90 of the image forming apparatus 1 is able to monitor operation to push the toner bottle unit 900 via the metal plates 9111, 9113 while accessing the memory unit 911 via the metal plates 9111, 9112 in parallel.
Next, a method of detecting rotation of the toner bottle unit 900 will be described with reference to
As shown in
As shown in
A series of operations when the toner bottle unit 900 is mounted on the supply container mounting portion 701, toner is supplied, and then the toner bottle unit 900 is detached will be described. The description of similar portions to those of the above-described embodiment using the toner pack 40 is omitted.
First, a user mounts an unused toner bottle unit 900 on the supply container mounting portion 701. Specifically, the positions of the cutaway engagement surfaces 903s, 904s (
When the unused toner bottle unit 900 is inserted in the supply container mounting portion 701, the control unit 90 recognizes that the toner bottle unit 900 is new by using the above-described new one detection configuration. As described above, the control unit 90 may recognize electrical continuity between the metal plates 9111, 9113 or may perform determination by reading the new one flag (new: 1, used: 0) in the memory unit 45. Then, the control unit 90 moves the locking member 7014 to the unlock position by operating the push mechanism 600, with the result that the toner bottle unit 900 is placed in a rotatable state.
After that, when a user holds the toner bottle unit 900 and rotates the toner bottle unit 900 by 180 degrees, the shutter member 904 and the supply port shutter 7013 are opened, and the ejection port 9031 of the toner bottle unit 900 and the supply port 8012 of the supply container mounting portion 701 communicate with each other. The operation of the shutter member 904 and the supply port shutter 7013 to open with rotation of the toner bottle unit 900 is similar to that in the case of the toner pack 40 described with reference to
As shown in
Subsequently, the user starts ejecting toner by pushing the piston 902 of the toner bottle unit 900. Toner fallen to the toner containing portion 8011 is conveyed inside the toner receiving unit 801 to reach the developer container 32. In the present modification example as well, when the piston 902 is pushed to the end, completion of operation to push the piston 902 is detected by the above-described push detection mechanism. In other words, as shown in
The control unit 90 that has detected completion of ejection of toner from the toner bottle unit 900 operates the push mechanism 600 again to move the locking member 7014 to the unlock position and places the toner bottle unit 900 in a rotatable state. The user holds the toner bottle unit 900 and rotates the toner bottle unit 900 by 180 degrees. Then, the ejection port 9031 of the toner bottle unit 900 is covered with the shutter member 904, and the supply port 8012 of the supply container mounting portion 701 is covered with the lid portion 70131 of the supply port shutter 7013. As shown in
Next, a mode of a second modification example in which the configuration of the process cartridge is different will be described. The present modification example includes components common to those of the first embodiment in portions other than the configuration related to the process cartridge, so the description of the common portions is omitted.
As shown in
In the illustrated example, the developing unit 802 is located below the process cartridge 20A, and the toner receiving unit 801 and the drum unit 803A are located above the developing unit 802 in the gravitational direction. As shown in
A laser passage space SP as an air gap through which laser light L emitted from the scanner unit 11 (
The behavior of toner in the cleanerless configuration will be described. Residual toner remaining on the photosensitive drum 21 in the transfer portion is removed in the following process. Residual toner mixedly includes toner charged with positive polarity and toner charged with negative polarity but not carrying sufficient amount of charge. When charge on the photosensitive drum 21 after transfer is eliminated by the pre-exposure apparatus and then uniform discharge is generated by the charge roller 22, residual toner is charged with negative polarity again. Residual toner charged with negative polarity again in a charging portion reaches the developing unit again with rotation of the photosensitive drum 21. Then, a surface region of the photosensitive drum 21, having passed through the charging portion, is exposed to light by the scanner unit 11 while residual toner adheres to the surface, with the result that an electrostatic latent image is written.
Here, the behavior of residual toner that has reached the developing unit will be described separately for an exposed area and a non-exposed area of the photosensitive drum 21. Residual toner adhering to the non-exposed area of the photosensitive drum 21 transfers to the developing roller 31 by a potential difference between a developing voltage and a potential of the non-exposed area (dark area potential) of the photosensitive drum 21 in the developing unit, and is collected into the developer container 32. This is because, on the assumption that the normal charge polarity of toner is negative polarity, a developing voltage to be applied to the developing roller 31 is positive relative to the potential of the non-exposed area. Toner collected into the developer container 32 is agitated together with toner in the developer container 32 by the agitating member 34 to be dispersed and is used again in the developing process when carried on the developing roller 31.
On the other hand, residual toner adhering to the exposed area of the photosensitive drum 21 does not transfer from the photosensitive drum 21 to the developing roller 31 in the developing unit and remains on the drum surface. This is because, on the assumption that the normal charge polarity of toner is negative polarity, a developing voltage to be applied to the developing roller 31 is a potential further more negative than the potential of the exposed area (light area potential). Residual toner remaining on the drum surface is carried on the photosensitive drum 21 together with other toner that transfers from the developing roller 31 to the exposed area, moves to the transfer portion, and is then transferred to a recording medium in the transfer portion.
With the cleanerless configuration, no installation space for a collecting container for collecting residual toner or the like is used, so further reduction in the size of the image forming apparatus 1 is possible, and, in addition, reduction in printing cost is achieved by reusing residual toner.
Next, a third modification example in which the configuration of the process cartridge is different from any one of the above-described modes will be described. The present modification example includes components common to those of the first embodiment in portions other than the configuration related to the process cartridge, so the description of the common portions is omitted.
As shown in
A laser passage space SP as an air gap through which laser light L emitted from the scanner unit 11 (
T memory 57 and P memory 58 are connected to the control unit 90. The T memory 57 is a non-volatile memory mounted on the supply container, such as the toner pack 40 and the toner bottle unit 900. The P memory 58 is a non-volatile memory mounted on the process cartridge 20. Examples of the T memory 57 as a storage unit provided in the supply container include the memory unit 45 mounted on the above-described toner pack 40 and the memory unit 911 mounted on the above-described toner bottle unit 900. The T memory 57 also stores toner information indicating that toner contained in the supply container, such as the toner pack 40 and the toner bottle unit 900, can be supplied to the developer container 32. Toner information is information indicating, for example, whether the toner pack 40 is in an unused state, an initial amount of toner, an expiration date, and the like. The P memory 58 stores a residual amount of toner contained in the developer container 32, a total amount of toner ever supplied from the supply container, information on a photosensitive member lifetime, information on replacement timing of the process cartridge 20, and the like.
In addition, a rotation locking mechanism 59 and the image forming unit 10 are connected to the control unit 90. Examples of the rotation locking mechanism 59 include the locking member 7014 (
A toner residual amount detector 51, a waste toner full detector 52, a mount detector 53, an open/close detector 54, a rotation detector 55, and a push detector 56 are connected to the input side of the control unit 90.
The toner residual amount detector 51 detects the residual amount of toner contained in the developer container 32. An example of the toner residual amount detector 51 is the optical sensor (51a, 51b) shown in
The mount detector 53 detects a situation in which the supply container, such as the toner pack 40, is mounted on the supply container mounting portion 701. The mount detector 53 is provided in, for example, the supply container mounting portion 701 and is made up of a pressure-sensitive switch that outputs a detection signal when pressed by the bottom surface of the toner pack 40. The mount detector 53 may be a detection circuit that detects a situation in which the T memory 57 is electrically connected to the control unit 90 via the contact portion 70133 (
The rotation detector 55 detects rotation of the supply container mounted on the supply container mounting portion 701. An example of the rotation detector 55 is the rotation detection portion 7015 made up of the leaf springs 70151, 70152 (
The push detector 56 is an element that is added when the toner bottle unit 900 of the first modification example is used, and detects completion of pushing the piston 902 of the toner bottle unit 900. An example of the push detector 56 is a detection circuit provided in the image forming apparatus 1, and detects a change in the state of the push detection mechanism (
The operating unit 300 that is a user interface of the image forming apparatus 1 and the panel 400 as a notification device (information device) that notifies a user of information on a toner residual amount in the developer container 32 are connected to the control unit 90. Information on a toner residual amount is not limited to indicating a toner residual amount itself. Other than that, information on a toner residual amount also includes information indicating how much toner has been supplied by using the toner pack 40 or the toner bottle unit 900. Information on a toner residual amount also includes information indicating an available capacity of the developer container 32, which means how many toner packs 40 or toner bottle units 900 can be used to supply toner.
The operating unit 300 includes a display 301 that is capable of displaying various setting screens. The display 301 is made up of, for example, a liquid crystal panel. The operating unit 300 includes an input portion 302 for accepting input operation from a user. The input portion 302 is made up of, for example, a physical button or a touch panel functional portion of a liquid crystal panel. The control unit 90 is further connected to external devices, such as a desktop computer and a smartphone, via the I/O interface 94.
As described above, the supply port shutter 7013 rotatably attached to the supply port 8012 and the locking member 7014 used to restrict rotation of the supply port shutter 7013 are provided around the supply port 8012.
The locking member 7014 is movable between the lock position (restricted position) as a first position and the unlock position (allowed position) as a second position. When the locking member 7014 is at the lock position, rotation of the supply port shutter 7013 is restricted. When the locking member 7014 is at the unlock position, rotation of the supply port shutter 7013 is allowed. Supply of toner to the process cartridge 20 is allowed via the supply port 8012.
Unlock operation of the locking member 7014 is performed by the control unit 90 operating the push mechanism 600 to push the pivot shaft 7014a of the locking member 7014 with the advancing/retracting pin 604 of the push mechanism 600 (see
The amount of toner that can be contained in the process cartridge 20 is limited. Therefore, when toner is supplied from the supply container (the toner pack 40 or the toner bottle unit 900) in a state where, for example, the toner amount in the developer container 32 is a Full level (first state), toner may clog in the supply port 8012. For this reason, supplying toner from the supply container over the amount of toner that can be contained in the process cartridge 20 is restricted. Hereinafter, a configuration for restricting rotation of the supply port shutter 7013 by using the toner pack 40 will be described. The content of the following description is similar even when the toner bottle unit 900 is used instead of the toner pack 40.
In the image forming apparatus 1 according to the present embodiment, when the toner pack 40 is mounted, whether to unlock the locking member 7014 is determined in accordance with whether the process cartridge 20 allows supply of toner. More specifically, when a toner amount detected by the optical sensor (51a, 51b) as an example of the toner residual amount detector (residual amount detection portion) 51 is less than a predetermined amount, the control unit 90 performs unlock operation of the locking member 7014. On the other hand, when a toner amount detected by the optical sensor (51a, 51b) is greater than or equal to the predetermined amount, the control unit 90 does not perform unlock operation of the locking member 7014. As a result, when a toner amount detected by the optical sensor (51a, 51b) is greater than or equal to the predetermined amount, the supply port shutter 7013 remains locked by the locking member 7014.
Information on the amount of toner contained in the process cartridge 20 may be stored in the P memory 58, and the control unit 90 may be configured to, when the toner pack 40 is mounted, read the information. In this case as well, the control unit 90 is able to determine whether to unlock the locking member 7014 in accordance with the information stored in the P memory 58. Information on the amount of toner contained in the process cartridge 20 includes a detection result of the amount of toner detected by the toner residual amount detector 51, a predicted value of toner consumed in printing or the like, and other information.
In any case, the control unit 90 performs unlock operation of the locking member 7014 only when the control unit 90 determines that the amount of toner contained in the process cartridge 20 is less than an amount by which supply from the toner pack 40 is allowed (first amount).
As described above, the process cartridge 20 includes the supply container mounting portion 701. Therefore, the toner pack 40 is able to be mounted on the supply container mounting portion 701 in a state where the process cartridge 20 is detached from the printer main body 100.
In a state where the process cartridge 20 is mounted on the printer main body 100, the control unit 90 determines whether to unlock the locking member 7014 in accordance with the amount of toner contained in the process cartridge 20. Therefore, in a state where the process cartridge 20 does not allow supply of toner from the toner pack 40, the locking member 7014 is not unlocked. However, in a state where the process cartridge 20 is detached from the printer main body 100, the control unit 90 is not able to determine whether to unlock the locking member 7014.
On the other hand, when a user is able to touch the locking member 7014 in a state where the process cartridge 20 is detached from the printer main body 100, the locking member 7014 can be unlocked by the user.
In other words, even in a state where supply of toner from the toner pack 40 should be restricted, toner can be supplied from the toner pack 40 to the process cartridge 20. As a result, the supply port 8012 of the process cartridge 20 may be clogged with toner.
For this reason, unlocking the locking member 7014 in a state where the process cartridge 20 is detached from the printer main body 100 of the image forming apparatus 1 (hereinafter, referred to as detached state) is prevented. Hereinafter, the configuration of the process cartridge (cartridge) 20 for preventing the locking member 7014 from being unlocked in the detached state will be described.
A fourth modification example in which a configuration for locking the supply port shutter 7013 is different will be described with reference to
As shown in
The locking plate 512 is covered with the frame 8010 and cannot be accessed from the outside of the process cartridge 20. Here, the frame 8010 may be regarded as part of the process cartridge 20 or part of the frame of the developing unit 802. Therefore, in a state where the process cartridge 20 is detached from the printer main body 100, a user is not able to access the locking plate 512. On the other hand, the electrode 513 is exposed from the frame 8010 and is configured to be in contact with a supply portion 517 (described later).
As shown in
As described above, the process cartridge 20 includes the supply container mounting portion (mounting portion) 701 on which the supply container (the toner pack 40 or the toner bottle unit 900) is mounted, and the supply port 8012 for receiving toner supplied from the supply container. The process cartridge 20 further includes the movable supply port shutter (shutter member) 7013 that covers the supply port 8012.
The supply port shutter 7013 is configured to be movable between a position where the supply port shutter 7013 covers the supply port 8012 (first position, and the closed position) and a position where the supply port shutter 7013 retracts from the supply port 8012 (the second position, and the open position). When the supply port shutter 7013 is located at the position where the supply port shutter 7013 retracts from the supply port 8012 (second position), the supply port 8012 is exposed, and supply of toner from the supply container to the process cartridge 20 via the supply port 8012 is allowed. A state where the supply port shutter 7013 is located at the first position is the closed state of the supply port shutter 7013. A state where the supply port shutter 7013 is located at the second position is the open state of the supply port shutter 7013.
The locking plate 512 has a hook portion 512b. The supply port shutter 7013 has engaged portions 7013a. The engaged portions 7013a are provided at two portions. As will be described later, one of the engaged portions 7013a is configured to engage with the hook portion 512b when the supply port shutter 7013 is closed. The other one of the engaged portions 7013a is configured to engage with the hook portion 512b when the supply port shutter 7013 is open.
As shown in
On the other hand, the printer main body 100 of the image forming apparatus 1 includes the supply portion 517. When the process cartridge 20 is mounted on the printer main body 100, the supply portion 517 is configured to be in contact with the electrode 513. The electrode 513 is configured to receive electric power from the supply portion 517 of the printer main body 100. As will be described later, the locking plate 512 moves from the lock position to the unlock position by using electric power supplied from the supply portion 517 of the printer main body 100 to the electrode 513.
Current from the printer main body 100 flows to the electrode 513 via the supply portion 517. The electrode 513 is electrically connected to the coil portion 511. Therefore, current having flowed through the electrode 513 is transmitted to the coil portion 511. When current flows through the coil portion 511, a magnetic field is generated in the coil portion 511. Then, a force attracting the locking plate 512 (magnetic force F1) is generated, and the locking plate 512 is attracted toward the coil portion 511 against the urging force (F2) of the spring 514. Then, the locking plate 512 moves from the lock position to the unlock position (
When the locking plate 512 is at the unlock position, engagement between the hook portion 512b and the engaged portion 7013a is released. At this time, the supply port shutter 7013 is allowed to rotate (move) in the direction of the arrow R1 from the first position toward the second position. As shown in
As described above, the printer main body 100 includes the control unit 90 and the power supply (power supply) 211. The control unit 90 is configured to control the power supply 211.
In the present modification example as well, the control unit 90 determines whether to perform operation to unlock the locking apparatus 510 in accordance with the amount of toner contained in the process cartridge 20. In other words, when the toner pack 40 is mounted on the supply container mounting portion 701, the control unit 90 performs operation to unlock the locking apparatus 510 only when the amount of toner contained in the process cartridge 20 is small to such an extent that supply from the toner pack 40 is allowed.
More specifically, the control unit 90 controls the power supply 211 such that electric power is supplied to the electrode 513 when the amount of toner contained in the process cartridge 20 is less than an amount by which supply from the toner pack 40 is allowed (first amount). As in the case of the above-described example, the control unit 90 determines whether to perform operation to unlock the locking apparatus 510 in accordance with a detection result of the toner residual amount detector 51 and information on the amount of toner contained in the process cartridge 20, stored in the P memory 58. Electric power may be supplied to the electrode 513 when, for example, a toner amount in the process cartridge 20, detected by the toner residual amount detector 51, is less than the first amount. Alternatively, electric power may be supplied to the electrode 513 when it is determined that the toner amount in the process cartridge 20 is less than the first amount in accordance with the information stored in the P memory 58.
Alternatively, the control unit 90 may control the power supply 211 such that electric power is supplied to the electrode 513 when the toner pack 40 is able to supply toner (the toner amount contained in the toner pack 40 is greater than the second amount). For example, information on the toner amount contained in the toner pack 40 may be stored in the T memory (storage member) 57 mounted on the toner pack 40, and the control unit 90 may control the power supply 211 in accordance with the information. In other words, when it is determined from the information stored in the T memory 57 that the toner pack 40 is able to supply toner (the toner amount contained in the toner pack 40 is greater than the second amount), electric power may be supplied to the electrode 513.
When it is detected that the toner pack 40 is mounted on the supply container mounting portion 701, the control unit 90 determines whether to perform operation to unlock the locking apparatus 510. When it is determined to perform operation to unlock the locking apparatus 510, the control unit 90 performs operation to unlock the locking apparatus 510.
As described above, the supply port shutter 7013 moves from the closed position to the open position by displacing (rotating) the toner pack 40 attached to the supply container mounting portion 710.
As described with reference to
When the open state of the supply port shutter 7013 is recognized, supply of electric power from the supply portion 517 to the electrode 513 is stopped. Then, the locking plate 512 moves to the lock position by the urging force (F2) of the spring 514. After that, as shown in
As described above, after ejection of toner from the toner pack 40 begins, when a predetermined condition is satisfied, the control unit 90 determines that ejection of toner is complete. In the present modification example, the control unit 90 determines that ejection of toner is complete in accordance with an elapsed time from when conduction of the rotation detection portion 7015 turns on. When the toner bottle unit 900 is used instead of the toner pack 40, the control unit 90 may determine that ejection is complete by detecting completion of pushing the piston 902.
When the control unit 90 determines that ejection of toner is complete, the control unit 90 controls the power supply 211 such that current flows from the supply portion 517 to the electrode 513. Then, the locking plate 512 moves from the lock position to the unlock position, and engagement between the hook portion 512b and the engaged portion 7013a is released (see
When the user rotates the toner pack 40 and the supply port shutter 7013 in the direction of the arrow R2, the protruded portion 70125a and the protruded portion 70135a contact with each other. As a result, rotation of the toner pack 40 and the supply port shutter 7013 is stopped (
In the present modification example, in the process in which the supply port shutter 7013 rotates in the direction of the arrow R2, the control unit 90 stops supply of electric power to the electrode 513 when the rotation detection portion 7015 is interrupted. By pulling out the toner pack 40 from the supply container mounting portion 701, the control unit 90 may stop supply of electric power to the electrode 513 when electrical continuity between the contact portion 70133 (see
When supply of electric power to the electrode 513 is interrupted, the locking plate 512 moves to the lock position by the spring 514. When the supply port shutter 713 is closed, the hook portion 512b engages with the engaged portion 7013a.
As described above, when no electric power (current) is supplied to the electrode 513, the locking plate 512 is located at the lock position. Therefore, in a state where the process cartridge 20 is detached from the printer main body 100, the locking plate 512 is located at the lock position. Therefore, even when the toner pack 40 is mounted on the process cartridge 20, a user is not able to rotate the toner pack 40. Hence, when the process cartridge 20 is in a state where supply of toner from the toner pack 40 should be restricted, supply of toner from the toner pack 40 is prevented. Therefore, it is possible to prevent the supply port 8012 of the process cartridge 20 from being clogged with toner.
Here, the locking apparatus 510 may be disposed in the printer main body 100. Part of the locking apparatus 510 may be disposed in the printer main body 100. For example, the electrode 513 and the coil portion 511 as a magnetic force generator may be disposed in the printer main body 100, and the control unit 90 may be configured to control supply of electric power to the magnetic force generator. Then, the locking plate 512 is configured so as to be covered with the frame 8010 and not exposed to the outside of the frame 8010. With this configuration as well, magnetic force acts from the outside of the frame 8010 on the locking plate 512 accommodated inside the frame 8010, so it is possible to move the locking plate 512. With this configuration as well, the locking plate 512 may be configured to be urged by the spring 514 from the unlock position to the lock position. Electric power may be directly supplied from the supply portion 517 to the coil portion 511.
When the locking plate 512 can be located at the lock position while no electric power is supplied to the coil portion 511, the spring 514 may be omitted. For example, the locking plate 512 may be located at the lock position by the own weight of the locking plate 512.
A second embodiment of the present disclosure will be described with reference to
As shown in
On the other hand, as shown in
In consideration of a touch by a user, the opening formed by the wall 520 when the opening has a circular shape preferably has a diameter less than or equal to 8 mm and more preferably has a diameter less than or equal to 6 mm. When the opening has a rectangular shape, the opening preferably has a short side length of less than or equal to 8 mm and more preferably has a short side length of less than or equal to 6 mm. The distance between the pivot shaft 7014a and the opening at the time when the locking member 7014 switches from the lock state to the unlock state is preferably greater than or equal to 5 mm. When the locking member 7014 is at the lock position, the distance between the pivot shaft 7014a and the opening is preferably greater than or equal to 5 mm.
As described above, by providing the wall 520, it is possible to reduce a touch of a user with the locking member 7014.
As shown in
In the present embodiment, the cover member 522 is made of a resin. The cover member 522 is urged from the retracted position to the cover position by an urging member (not shown). When the process cartridge 20 is mounted on the printer main body 100, the cover member 522 contacts with part of the printer main body 100 and moves from the cover position (
As described above, by covering the opening of the wall 520 with the cover member 522, it is possible to reduce a touch of a user with the pivot shaft 7014a.
When the process cartridge 20 includes the cover member 522, the above-described wall 520 may be omitted. When the wall 520 is omitted, the frame 8010 may be regarded as having an opening in which the pivot shaft 7014a is inserted (see
With this configuration as well, by covering the opening of the frame 8010 with the cover member 522, it is possible to reduce a touch of a user with the pivot shaft 7014a.
A third embodiment of the present disclosure will be described. When the configurations of the toner bottle unit 900, image forming apparatus 1, and process cartridge 20 are the same as those of the first embodiment, like reference signs are assigned, and the description thereof is omitted.
A push configuration of the toner bottle unit 900 according to the present embodiment will be described with reference to
As described above, the toner bottle unit 900 as a supply unit (supply container) attachable to the process cartridge (cartridge) 20 includes the outer cylinder 903, the inner cylinder 901, the piston (pushing member) 902, the shutter member 904, and the memory unit 911. The outer cylinder 903 has the ejection port 9031. The inner cylinder 901 has the ejection port 9011. The inner cylinder 901 and the outer cylinder 903 each may be regarded as a container configured to contain toner or a frame having the toner containing portion 9014. The ejection port 9011 and the ejection port 9031 each may be regarded as an ejection port used to eject toner from the container (the inner cylinder 901 and the outer cylinder 903) of the toner bottle unit 900. The piston 902 is fitted to the inner cylinder 901 (see
When the piston 902 is pushed in toward the inner cylinder 901, toner contained in the toner containing portion 9014 is ejected through the ejection port 9011 and the ejection port 9031. A movement direction of the piston 902 at this time is referred to as push direction (first direction). The piston 902, the inner cylinder 901, and the outer cylinder 903 extend in the first direction. In other words, the longitudinal directions of the piston 902, inner cylinder 901, and outer cylinder 903 are the first direction.
As shown in
Here, when toner greater than a receivable amount (containable amount) of the process cartridge 20 is ejected from the toner bottle unit 900, the process cartridge 20 is not able to receive toner. As a result, toner may leak through a coupling portion between the toner bottle unit 900 and the toner receiving unit 801.
Therefore, toner greater in amount than the receivable amount of the process cartridge 20 may be prevented from being ejected from the toner bottle unit 900.
Particularly, a large-capacity toner bottle unit 900 containing toner in an amount exceeding the containable amount of the toner receiving unit 801 may be configured not to eject the entire toner at a time. In other words, when a user pushes in the piston 902, the toner bottle unit 900 may have a configuration to restrict the piston (a movement restriction mechanism, and a path restriction portion) so that the piston 902 can be pushed in a stepwise manner.
The toner bottle unit 900 in the present embodiment is capable of preventing ejection of toner in an amount greater than the receivable amount of the process cartridge 20 from the toner bottle unit 900.
As shown in
Next, the channel portion 9035 of the outer cylinder 903 and the arm 9024 and distal end portion 9025 of the piston 902 will be described with reference to
As shown in
As shown in
In addition, a second direction restriction portion (second direction stop portion) is provided in the channel portion 9035 of the outer cylinder 903. The second direction restriction portion restricts movement of the piston 902 in the R1 direction (a second direction that intersects with the first direction) by contacting with the rotation restricted surface 9025b of the distal end portion 9025 of the piston 902. The second direction restriction portion includes first rotation stop surfaces 9035b1, second rotation stop surfaces 9035b2, and third rotation stop surfaces 9035b3. In the present embodiment, the R1 direction is the second direction perpendicular to the first direction. In the R1 direction, the second rotation stop surfaces 9035b2 are located between the first rotation stop surfaces 9035b1 and the third rotation stop surfaces 9035b3.
Next, a specific pushing operation of the piston 902 will be described with reference to
When a user rotates (moves) the piston 902 in the R1 direction, the rotation restricted surface 9025b and the second rotation stop surface 9035b2 contact with each other. At this time, the contact between the distal end restricted surface 9025a and the first stop surface 9035a1 is released, and the piston 902 is able to be pushed in the P1 direction.
From this state, when the piston 902 is further pushed in the P1 direction, toner begins to be ejected through the ejection port 9011. At this time, the rotation restricted surface 9025b of the distal end portion 9025 is guided by the second rotation stop surfaces 9035b2. Then, the distal end restricted surface 9025a contacts with the second stop surface 9035a2. Thus, movement of the piston 902 in the P1 direction stops, and ejection of toner also stops (see
At this time, the rotation restricted surface 9025b is in contact with the second rotation stop surface 9035b2, and the piston 902 is not able to rotate in the direction opposite to the R1 direction.
Here, in the present embodiment, the control unit 90 detects the toner amount in the developing unit 802 with the toner residual amount detector 51 of the image forming apparatus 1. In addition, the printer main body 100 has a rotation locking member (locking member) 199 for locking rotation of the piston 902 (see
When there is no margin in the developing unit 802 for receiving toner any more, the control unit 90 causes the piston 902 not to be able to rotate in the R1 direction by restricting the arm 9024 or the distal end portion 9025 with the rotation locking member 199. The piston 902 is caused not to be pushed any more, and then the locking member 7014 (see
On the other hand, the control unit 90 unlocks the rotation locking member 199 when the toner amount contained in the developing unit 802 of the process cartridge 20 is less than the amount by which the developing unit 802 can further receive supply of toner (first amount). Thus, rotation of the piston 902 is allowed.
The rotation locking member 199 will be simply described with reference to a schematic drawing.
When the available capacity of the developing unit 802 is sufficient in accordance with the detection result of the residual amount, the locking member 7014 (see
When further supply of toner is allowed, a user further rotates the piston 902 in the R1 direction by a predetermined angle from the state shown in
When the piston 902 is further pushed in the P1 direction, toner begins to be ejected through the ejection port 9011 (see
In other words, the piston 902 and the distal end portion 9025 are configured to be movable in the P1 direction relative to the outer cylinder 903. A position where the distal end restricted surface 9025a contacts with the first stop surface 9035a1 is a first position of the piston 902 and the distal end portion 9025. A position where the distal end restricted surface 9025a contacts with the third stop surface 9035a3 is a second position of the piston 902 and the distal end portion 9025. A position where the distal end restricted surface 9025a of the distal end portion 9025 contacts with the second stop surface 9035a2 is an intermediate position of the piston 902 and the distal end portion 9025 (a first intermediate position, and a third position).
In other words, the intermediate position is located between the first position and the second position in the P1 direction. A position where the piston 902 and the distal end portion 9025 are rotated from the intermediate position in the R1 direction and the rotation restricted surface 9025b and the third rotation stop surface 9035b3 contact with each other is a fourth position of the piston 902 and the distal end portion 9025 (second intermediate position).
As described above, the toner bottle unit 900 has a movement restriction portion that restricts movement of the piston 902 in the P1 direction when the piston 902 is located at the intermediate position. The movement restriction portion includes the distal end portion 9025 and the second stop surface 9035a. When the piston 902 and the distal end portion 9025 are at the intermediate position, pushing the piston 902 in the P1 direction is restricted. When the piston 902 and the distal end portion 9025 are moved from the intermediate position to the fourth position, pushing the piston 902 in the P1 direction is allowed again.
In the present embodiment, the piston 902 has the distal end portion 9025, and the outer cylinder 903 has the second stop surface 9035a2. However, a portion corresponding to the distal end portion 9025 may be provided on any one of the piston 902 and the outer cylinder 903, and a portion corresponding to the second stop surface 9035a2 may be provided on the other one of the piston 902 and the outer cylinder 903.
Here, a method for allowing a user to check the push status of the toner bottle unit 900 will be described with reference to
As shown in
The number of times of pushing is inscribed, that is, “0” is inscribed at the first indicating portion 90271, “1” is inscribed at the second indicating portion 90272, and “2” is inscribed at the third indicating portion 90273.
As shown in
As shown in
As shown in
In this way, the user is able to instantaneously grasp the push status of the piston 902 of the toner bottle unit 900 by reading the numerals of the push indicating portions 9027.
In the present embodiment, the number of times of pushing is inscribed at the push indicating portions 9027. Alternatively, the toner residual amount in the toner bottle unit 900 may be indicated as “100%”, “50%”, and “0%”. In addition, the number of the push indicating portions 9037 may be freely changed in accordance with the number of the channel portion 9035 of the outer cylinder 903.
As described above, according to the present embodiment, it is possible to supply toner in the toner bottle unit 900 in a stepwise manner in accordance with the available capacity of the process cartridge 20. Therefore, toner leakage due to supply of toner greater than or equal to the available capacity of the process cartridge 20 is prevented.
A distance in the P1 direction between the distal end restriction surfaces of the outer cylinder 903 may be freely set, with the result that it is possible to adjust a toner ejection amount for a single pushing operation. The number of the distal end restriction surfaces of the outer cylinder 903 may also be freely set, with the result that it is possible to adjust the number of steps of ejection.
A fourth embodiment of the present disclosure will be described. In the present embodiment, another mode of the push indicating portions of the toner bottle unit 900, described in the third embodiment, will be described. The configurations of the toner bottle unit 900, image forming apparatus 1, and process cartridge 20, other than the push indicating portions, are the same as those described in the third embodiment, so like reference signs are assigned, and the description thereof is omitted.
As shown in
The number of times of pushing is inscribed, that is, “0” is inscribed at the first indicating portion 90371, “1” is inscribed at the second indicating portion 90372, and “2” is inscribed at the third indicating portion 90373.
As shown in
As shown in
As shown in
In this way, the user is able to instantaneously grasp the push status of the piston 902 of the toner bottle unit 900 by reading the push indicating portions 9037. In the present embodiment as well, the number of times of pushing is inscribed at the push indicating portions 9037. Alternatively, the toner residual amount in the toner bottle unit 900 may be indicated as “100%”, “50%”, and “0%”. In addition, the number of the push indicating portions 9037 may be freely changed in accordance with the number of the channel portion 9035 of the outer cylinder 903.
As described above, according to the present embodiment, it is possible to supply toner in the toner bottle unit 900 in a stepwise manner in accordance with the available capacity of the process cartridge 20. Therefore, toner leakage due to supply of toner greater than or equal to the available capacity of the process cartridge 20 is prevented.
In the present embodiment, by providing the push indicating portions 9037 on the outer cylinder 903, it is possible to constantly check the push indicating portions 9037 at a viewpoint in one direction even when the piston 902 is rotated, so the present embodiment is higher in visibility than the third embodiment.
Alternatively, both the push indicating portions 9027 described in the third embodiment and the push indicating portions 9037 described in the present embodiment may be provided on the toner bottle unit 900.
A fifth embodiment of the present disclosure will be described. In the present embodiment, another mode of the channel portion 9035 of the outer cylinder 903, described in the third embodiment or the fourth embodiment, will be described. The configurations of the toner bottle unit 900, image forming apparatus 1, and process cartridge 20, other than the outer cylinder 903, are the same as those described in the third embodiment, so like reference signs are assigned, and the description thereof is omitted.
As shown in
Here, a contact relation between the distal end portion 9025 and each of the resistance portions 9039 will be described by using an example of a state where the piston 902 is pushed in.
As shown in
When the distal end portion 9025 moves in the P1 direction, the distal end portion 9025 is deformed to be lifted by the inclined surface 90392e. When the distal end portion 9025 directly moves in the P1 direction, the distal end portion 9025 slips off from the inclined surface 90392e, and then the distal end restricted surface 9025a contacts with the second stop surface 9035a2 and is not able to move in the P1 direction any more.
Here, when a user attempts to pull out the piston 902 in the P2 direction (in the direction opposite to the P1 direction), the reverse movement stopped surface 9025c contacts with the reverse movement stop surface 90392c, and movement is restricted. In this way, movement of the piston 902 in the P2 direction is restricted by the resistance portions 9039. Therefore, it is possible to avoid inconsistency between the push-in status of the piston 902 and the toner amount in the toner bottle unit 900.
The contact relation between the second resistance portion 90392 and the distal end portion 9025 is described as an example here; however, there is a similar contact relation at the first resistance portion 90391 and at the third resistance portion 90393, so the description thereof is omitted.
As described above, according to the present embodiment, it is possible to supply toner in the toner bottle unit 900 in a stepwise manner in accordance with the available capacity of the process cartridge 20. Therefore, toner leakage due to supply of toner greater than or equal to the available capacity of the process cartridge 20 is prevented.
Furthermore, in the present embodiment, by providing the resistance portions 9039 on the outer cylinder 903, it is possible to restrict movement of the piston 902 in a direction reverse to the pushing direction, so a user is able to correctly recognize the push-in status of the piston 902 and the toner amount in the toner bottle unit 900.
A sixth embodiment of the present disclosure will be described. In the third to fifth embodiments, the piston 902 includes the arm 9024 and the distal end portion 9025, and the outer cylinder 903 includes the channel portion 9035. In the present embodiment, a configuration in which the above relation is switched will be described.
The configurations of the toner bottle unit 900, image forming apparatus 1, and process cartridge 20, other than the outer cylinder 903 and the piston 902, are the same as those described in the third to fifth embodiments, so like reference signs are assigned, and the description thereof is omitted.
The resistance portions 9029, as well as the resistance portions 9039 in the fifth embodiment, are resistance portions that restrict movement of the piston 902 in the P2 direction.
Next, the arm 9034 and distal end portion 9036 of the outer cylinder 903 and the channel portion 9026 of the piston 902 will be described. The outer cylinder 903 has the arm 9034 and the distal end portion 9036. The distal end portion 9036 has a distal end restriction surface 9036a as a first restriction portion that restricts movement of the piston 902 in the P1 direction and rotation restriction surfaces 9036b as a second restriction portion that restricts movement in the R1 direction.
The channel portion 9026 of the piston 902 has a fourth stop surface 9026a4, a fifth stop surface 9026a5, and a sixth stop surface 9026a6 as a first restricted portion that contacts with the distal end restriction surface 9036a of the distal end portion 9036 of the outer cylinder 903. The channel portion 9026 of the piston 902 has fourth rotation stop surfaces 9026b4, fifth rotation stop surfaces 9026b5, and sixth rotation stop surfaces 9026b6 as a second restricted portion that contacts with the rotation restriction surface 9036b of the distal end portion 9036 of the outer cylinder 903.
A specific pushing operation of the piston 902 is the same as those of the third to fifth embodiments, so the description thereof is omitted.
In other words, a position where the distal end restriction surface 9036a contacts with the fourth stop surface 9026a4 is a first position of the piston 902 and the fourth stop surface 9026a4. A position where the distal end restriction surface 9036a contacts with the sixth stop surface 9026a6 is a second position of the piston 902 and the sixth stop surface 9026a6. A position where the distal end restriction surface 9036a contacts with the fifth stop surface 9026a5 is an intermediate position of the piston 902 and the fifth stop surface 9026a5 (a third position, and a first intermediate position).
In other words, the intermediate position is located between the first position and the second position in the P1 direction. A position where the piston 902 is rotated from the intermediate position in the R1 direction and the rotation restriction surface 9036b and the sixth rotation stop surface 9026b6 contact with each other is a fourth position of the piston 902 and the distal end portion 9025 (second intermediate position).
As described above, the toner bottle unit 900 has a movement restriction portion that restricts movement of the piston 902 in the P1 direction when the piston 902 is located at the intermediate position. The movement restriction portion includes the distal end portion 9036 and the fifth stop surface 9026a5. When the piston 902 and the distal end portion 9025 are at the intermediate position, pushing the piston 902 in the P1 direction is restricted. When the piston 902 and the distal end portion 9025 are moved from the intermediate position to the fourth position, pushing the piston 902 in the P1 direction is allowed again.
As described above, according to the present embodiment, it is possible to supply toner in the toner bottle unit 900 in a stepwise manner in accordance with the available capacity of the process cartridge 20. Therefore, toner leakage due to supply of toner greater than or equal to the available capacity of the process cartridge 20 is prevented.
A distance in the P1 direction between the distal end restriction surfaces of the piston 902 may be freely set, with the result that it is possible to adjust a toner ejection amount for a single pushing operation. The number of the distal end restriction surfaces of the piston 902 may also be freely set, with the result that it is possible to adjust the number of steps of ejection.
A seventh embodiment of the present disclosure will be described. In the present embodiment, another mode of the outer cylinder 903, described in the third to sixth embodiments, will be described. The configurations of the toner bottle unit 900, image forming apparatus 1, and process cartridge 20, other than the outer cylinder 903, are the same as those described in the third to sixth embodiments, so like reference signs are assigned, and the description thereof is omitted.
As shown in
The channel portion 9035 has rotation stop surfaces 9035b as a second restricted portion that contacts with the rotation restricted surfaces 9025b of the distal end portion 9025 of the piston 902 and restricts rotation of the piston 902 in the R1 direction.
The first resistance portion 90391, the second resistance portion 90392, and the third resistance portion 90393 are provided in a region surrounded by the channel portion 9035. The first resistance portion 90391, the second resistance portion 90392, and the third resistance portion 90393 are similar to the resistance portions 9039 in the fifth embodiment, so the description thereof is omitted.
Here, a contact relation between the channel portion 9035 and the distal end portion 9025 will be described by using an example of a state where the piston 902 is pushed in.
As shown in
With the R-shaped portion 9025r and the R-shaped portion 9035r, the arm 9024 elastically deforms outward of the outer peripheral surface of the outer cylinder 903 by user's pushing force and is able to climb over the second stop surface 9035a2. The similar R-shaped portion is also formed at the first stop surface 9035a1, and the arm 9024 is able to climb over the first stop surface 9035a1 by user's pressing force.
More specifically, the arm 9024 deforms such that the distal end portion 9025 moves in a direction away from the outer cylinder 903. In other words, the R-shaped portion 9025r and the R-shaped portion 9035r each may be regarded as a control surface (guide surface) that controls (guides) the direction of the above-described deformation. Alternatively, only any one of the R-shaped portion 9025r and the R-shaped portion 9035r may be provided. One or both of the R-shaped portion 9025r and the R-shaped portion 9035r may be modified as an inclined surface.
As shown in
When the user pushes the piston 902 in the P1 direction, the arm 9024 elastically deforms, and the distal end restricted surface 9025a of the distal end portion 9025 climbs over the first stop surface 9035a1 and passes through the second resistance portion 90392. Then, when the distal end restricted surface 9025a contacts with the second stop surface 9035a2, the piston 902 once stops (the intermediate position of the piston 902). In other words, since the distal end portion 9025 contacts with the second stop surface 9035a2, resistance at the time of pushing the piston 902 increases. At the same time, movement of the piston 902 in the direction reverse to the P1 direction is restricted by the second resistance portion 90392. At this point in time, a half of toner contained in the toner bottle unit 900 is ejected.
In addition, when the user pushes the piston 902 in the P1 direction, the arm 9024 elastically deforms, and the distal end restricted surface 9025a of the distal end portion 9025 climbs over the second stop surface 9035a2. At this time, the distal end portion 9025 moves in the direction away from the outer cylinder 903. Then, the second stop surface 9035a passes through the third resistance portion 90393. Then, when the distal end restricted surface 9025a contacts with the third stop surface 9035a3, the piston 902 stops (the second position of the piston 902). At the same time, movement of the piston 902 in the direction reverse to the P1 direction is restricted by the third resistance portion 90393. At this point in time, the entire toner contained in the toner bottle unit 900 is ejected.
As described above, the toner bottle unit 900 has a movement restriction portion that restricts movement of the piston 902 in the P1 direction when the piston 902 is located at the intermediate position. The movement restriction portion includes the distal end portion 9025 and the second stop surface 9035a2. When the piston 902 and the distal end portion 9025 are at the intermediate position, the arm 9024 elastically deforms when the piston 902 is pushed in the P1 direction. Thus, pushing the piston 902 in the P1 direction is allowed again. As described in the sixth embodiment, the outer cylinder 903 has a portion corresponding to the distal end portion 9025 in the present embodiment, and the piston 902 has a portion corresponding to the second stop surface 9035a2.
In this way, it is possible to push the piston 902 in a stepwise manner by the distal end portion 9025 of the piston 902 and the channel portion 9035 of the outer cylinder 903.
A distance in the P1 direction between the distal end restriction surfaces of the outer cylinder 903 may be freely set, with the result that it is possible to adjust a toner ejection amount for a single pushing operation. The number of the distal end restriction surfaces of the outer cylinder 903 may also be freely set, with the result that it is possible to adjust the number of steps of ejection.
As described above, according to the present embodiment, it is possible to supply toner in the toner bottle unit 900 in a stepwise manner in accordance with the available capacity of the process cartridge 20. The present embodiment does not use the operation to rotate the piston 902 as compared to the third embodiment, so it is possible to further simply supply toner from the toner bottle unit 900.
According to the embodiments of the present disclosure, it is possible to provide an image forming apparatus and a supply container (supply unit) used to supply toner to the image forming apparatus.
An eighth embodiment of the present disclosure will be described. When the configurations of the image forming apparatus 1 and process cartridge 20 are the same as those of the first embodiment, like reference signs are assigned, and the description thereof is omitted.
Hereinafter, a configuration that controls air flow in the toner receiving unit 801 resulting from supply of toner will be described.
A partition wall 813 is provided between the first conveyance member 8013 and the second conveyance member 8014 inside the toner containing portion 8011. The partition wall 813 is a wall-shaped member that leaves a connection part for passing toner from the first conveyance member 8013 to the second conveyance member 8014 and that extends in the longitudinal direction of the process cartridge 20. The partition wall 813 forms a buffer region B0 with inner walls 8011x, 8011y of the toner containing portion 8011. The inner walls 8011x, 8011y similarly extend in the longitudinal direction. The buffer region B0 buffers toner flowing from the supply container into the process cartridge 20.
When the piston 902 (
When the piston 902 of the toner bottle unit 900 shown in
When the capacity of the toner bottle unit 900 is increased, larger amounts of air and toner flow into the process cartridge 20 in a short period of time. Therefore, the following configuration is also suitably applicable to a case where the capacity of the toner bottle unit 900 is increased.
In a supply container of a type in which the piston 902 is pushed in as in the case of the toner bottle unit 900, the internal pressure of the process cartridge 20 tends to increase as compared to a type in which toner is squeezed out from a bag member as in the case of the toner pack 40. Therefore, the present embodiment is particularly suitably applied to an image forming system that uses the toner bottle unit 900 as the supply container, and the toner pack 40 or other supply containers may be used.
The top views of the toner receiving unit 801 in the following description of
As shown in
The first ventilation portion 811 may be disposed as far as possible from the supply port 8012 in the axial direction of the rotational axis L0 (that is, in the longitudinal direction of the toner containing portion 8011), and the second ventilation portion 812 is disposed between the first ventilation portion 811 and the supply port 8012. For example, the first ventilation portion 811 may be disposed across a center position H1 of the toner containing portion 8011 in the axial direction from the supply port 8012, and the second ventilation portion 812 may be disposed between the center position H1 of the toner containing portion 8011 and the supply port 8012. Alternatively, the first ventilation portion 811 may be disposed across a center position hl of the developing roller 31 in the axial direction from the supply port 8012, and the second ventilation portion 812 may be disposed between the center position hl of the developing roller 31 and the supply port 8012. Here, the developer container 32 has an opening, and part of the developing roller 31 faces the photosensitive drum 21. The center position hl of the developing roller 31 also coincides with a center position, in the axial direction, of the opening provided in the developer container 32.
The second ventilation portion 812 is disposed so as to overlap a straight line L1 passing through the supply port 8012 and the first ventilation portion 811 when viewed in the vertical direction and forms linear air flow with a small loss. In the present embodiment, a straight line connecting the supply port 8012 and the first ventilation portion 811 by a shortest distance when viewed in the vertical direction is defined as the straight line L1.
In the relation with the partition wall 813, the first ventilation portion 811 and the second ventilation portion 812 are disposed upstream of the partition wall 813 in the movement direction of toner (see
As shown in
When a user pushes in the piston 902 of the toner bottle unit 900 to eject toner, air flowing in together with toner passes through a path indicated by the arrow AF and goes out through the first ventilation portion 811 and the second ventilation portion 812. In this way, it is possible to form air flow resulting from supply of toner in the axial direction (X1) of the first conveyance member 8013. In other words, toner flowing in through the supply port 8012 located at the end portion of the toner containing portion 8011 is moved in the axial direction and supplied to the first conveyance member 8013. Thus, it is possible to smoothly proceed with conveyance of toner by the first conveyance member 8013 while avoiding deformation of the container and leakage of toner.
In the present embodiment, the opening area of the first ventilation port 8111 and the opening area of the second ventilation port 8121 are equal to each other. Alternatively, the opening areas may be different from each other. When the first ventilation port 8111 and the second ventilation port 8121 overlap the rotational axis L0 of the first conveyance member 8013 when viewed in the vertical direction, the first ventilation port 8111 and the second ventilation port 8121 may be offset from each other in the X2 direction.
The shape and number of the holes that make up each of the first ventilation port 8111 and the second ventilation port 8121 may be changed. In this case, within a range in which the air outlet filters do not break due to atmospheric pressure, the number of holes may be freely set, and each ventilation port may be made up of a single hole.
As described above, in the present embodiment, the frame of the process cartridge has the first opening and the second opening, and the openings are respectively covered with the first filter and the second filter. With this configuration, the air outlet performance of the process cartridge 20 improves, so it is possible to further reliably prevent deformation of the container and leakage of toner. With the configuration of the present embodiment, even when the amount of air flowing into the process cartridge 20 increases with an increase in the capacity of a toner bottle, it is possible to form air flow that efficiently sends toner to a first agitating member while ensuring sufficient air outlet performance.
As a modification example, a single slit (rectangular shape having an axial direction as a long-side direction) opening portion extending in the axial direction (X1) of the first conveyance member 8013 may be disposed and may be covered with a single air pass filter. In this case, it is conceivable that the opening portion is formed from the position of the first ventilation port 8111 to the position of the second ventilation port 8121 of the present embodiment in the axial direction (X1) and provided at a position that overlaps the first conveyance member 8013 when viewed in the vertical direction with respect to the perpendicular direction (X2).
A ninth embodiment will be described with reference to
Here, as shown in
For the air permeability of each of the first air outlet filter 8112 and the second air outlet filter 8122, the amount of air flowing out from the first ventilation portion 811 may be greater than that from the second ventilation portion 812, and, for example, the air permeability of the first air outlet filter 8112 may be higher than that of the second air outlet filter 8122. The shape and number of the holes that make up each of the first ventilation port 8111 and the second ventilation port 8121 may be changed as in the case of the eighth embodiment.
As described above, according to the ninth embodiment as well, it is possible to further reliably prevent deformation of the container and leakage of toner by enhancing the air outlet performance of the process cartridge 20. Even when the amount of air flowing into the process cartridge 20 increases with an increase in the capacity of a toner bottle, it is possible to form air flow that sends toner to a position apart from the supply port while ensuring sufficient air outlet performance.
A tenth embodiment will be described. The present embodiment differs from the eighth embodiment in the configuration regarding the air permeability of each of the first ventilation portion 811 and the second ventilation portion 812. Like reference signs to those of the eighth embodiment are assigned to the other components having configurations and operations common to those of the eighth embodiment, and the description thereof is omitted.
Here, the first air outlet filter 8112 and the second air outlet filter 8122, shown in
Thus, air flowing in through the supply port 8012 is preferentially discharged from the first ventilation portion 811. In other words, the flow rate of air flowing from the position of the second ventilation portion 812 toward the first ventilation portion 811 along the axial direction (X1) of the first conveyance member 8013 increases as compared to the eighth embodiment. Therefore, it is possible to suppress, for example, a situation in which most of inflow air goes out through the second ventilation portion 812 and air flow that sends toner does not reach the end portion of the first conveyance member 8013 in the axial direction.
As long as the amount of air flowing out from the first ventilation portion 811 is greater than that from the second ventilation portion 812, for example, the opening area of the second ventilation port 8121 may be greater than that of the first ventilation port 8111 instead of the configuration in which the opening areas of the first ventilation port 8111 and the second ventilation port 8121 are equal to each other. In contrast, with a combination of the ninth embodiment and the tenth embodiment, discharge of air from the first ventilation portion 811 may be further facilitated by reducing the opening area of the first ventilation port 8111 as compared to the second ventilation port 8121. The shape and number of the holes that make up each of the first ventilation port 8111 and the second ventilation port 8121 may be changed as in the case of the eighth embodiment.
As described above, according to the tenth embodiment as well, it is possible to further reliably prevent deformation of the container and leakage of toner by enhancing the air outlet performance of the process cartridge 20. Even when the amount of air flowing into the process cartridge 20 increases with an increase in the capacity of a toner bottle, it is possible to form air flow that sends toner to a position apart from the supply port while ensuring sufficient air outlet performance.
An eleventh embodiment will be described. The present embodiment differs from the eighth embodiment in the disposition of the first ventilation portion 811 and the second ventilation portion 812. Like reference signs to those of the eighth embodiment are assigned to the other components having configurations and operations common to those of the eighth embodiment, and the description thereof is omitted.
Here, the second ventilation portion 812 of the present embodiment is disposed between the ejection port 8016 and supply port 8012 of the toner receiving unit 801 in the X2 direction when viewed in the vertical direction. The ejection port 8016 is a communication portion (see
Thus, it is possible to form air flow that sends toner to the first conveyance member 8013 with the first ventilation portion 811 and to form air flow in a direction to approach the ejection port 8016 in the X2 direction with the second ventilation portion 812. At this time, since the second ventilation portion 812 is disposed at the above-described position, it is possible to discharge air before the ejection port 8016, so it is possible to suppress clogging of the ejection port 8016 with toner pouring into the ejection port 8016.
The shape and number of the holes that make up each of the first ventilation port 8111 and the second ventilation port 8121 may be changed as in the case of the eighth embodiment. For the opening areas of the first ventilation port 8111 and second ventilation port 8121 and the first air outlet filter 8112 and the second air outlet filter 8122, the ninth and tenth embodiments may be applied in combination.
As described above, according to the eleventh embodiment as well, it is possible to further reliably prevent deformation of the container and leakage of toner by enhancing the air outlet performance of the process cartridge 20. Even when the amount of air flowing into the process cartridge 20 increases with an increase in the capacity of a toner bottle, it is possible to prevent clogging of the ventilation ports with toner while ensuring sufficient air outlet performance.
An ventilation portion similar to the second ventilation portion in the present embodiment may be added to the eighth embodiment as an intermediate ventilation portion 815 as shown in
Not limited to the example of the disposition of
A twelfth embodiment will be described. The present embodiment differs from the eighth embodiment in the configuration of the filters provided at the ventilation portions. Like reference signs to those of the eighth embodiment are assigned to the other components having configurations and operations common to those of the eighth embodiment, and the description thereof is omitted.
According to the present embodiment, by adding the protection sheet outside the air outlet filter (downstream of the air outlet filter), it is possible to further reliably prevent toner from scattering to the outside of the process cartridge 20. In addition, by trapping foreign substances, such as dust, that attempts to enter from the outside of the toner receiving unit 801 with the protection sheet, it is possible to suppress a decrease in air outlet performance due to foreign substances deposited in the air outlet filter.
The filter configuration of the present embodiment is applicable to part or all of the air outlet filters in the eighth to eleventh embodiments and their modification examples.
A thirteenth embodiment will be described. The present embodiment differs from the eighth embodiment in that a plurality of weight members that prevent agglomeration of toner inside the supply container is contained. Like reference signs to those of the eighth embodiment are assigned to the other components having configurations and operations common to those of the eighth embodiment, and the description thereof is omitted.
Hereinafter, the toner bottle unit 900 will be described as an example of the supply container. When the toner bottle unit 900 is stored in the same position or when the toner bottle unit 900 receives vibrations or the like of transport in the same position, toner filled in the toner bottle unit 900 gradually agglomerates by its own weight and decreases in flowability.
As described with reference to
However, it is conceivable that toner strongly agglomerates during storage or during transport. In this case, when the number of times or speed by which a user shakes the toner bottle unit 900 is insufficient, ejection of toner may begin without eliminating agglomeration of toner, and poor ejection may occur. When the amount of toner filled is increased by increasing the capacity of the toner bottle unit 900 as well, poor ejection due to agglomeration of toner may occur.
Then, in the present embodiment, a plurality of weight members is disposed inside the toner bottle unit 900.
As described above, the inner cylinder 901 of the toner bottle unit 900 includes the toner containing portion 9014, the bottom portion 9013, the opening portion 9012, and the ejection port 9011 and is fitted to the outer cylinder 903 (
Here, the toner bottle unit 900 of the present embodiment contains a first weight member 991 as a first movable member and a second weight member 992 as a second movable member. The first weight member 991 and the second weight member 992 are spheres made of metal. The first weight member 991 and the second weight member 992 have the same size and specific gravity.
The first weight member 991 and the second weight member 992 are encapsulated in the toner containing portion 9014 together with toner T1 and are configured not to slip off to the outside of the toner bottle unit 900 through the ejection port 9011. Inside the toner containing portion 9014, the first weight member 991 and the second weight member 992 are freely movable without restraint from the inner cylinder 901. In other words, the first weight member 991 and the second weight member 992 each are able to freely (independently) move in the first direction (D1 direction), the second direction (D2 direction), and the third direction (D3 direction) relative to the frame of the toner bottle unit 900. In other words, the degree of freedom of each of the first weight member 991 and the second weight member 992 is six. In other words, the first weight member 991 and the second weight member 992 each are able to move in any of the D1 direction, the D2 direction, and the D3 direction relative to the frame of the toner bottle unit 900. For example, the first weight member 991 and the second weight member 992 each are able to move in the D1 direction even when the first weight member 991 and the second weight member 992 each do not move in the D2 direction or the D3 direction relative to the frame of the toner bottle unit 900. The first weight member 991 and the second weight member 992 each are able to move in the D1 direction and the D2 direction even when the first weight member 991 and the second weight member 992 each do not move in the D2 direction relative to the frame of the toner bottle unit 900. The first weight member 991 and the second weight member 992 each are able to move in the D1 direction, the D2 direction, and the D3 direction relative to the frame of the toner bottle unit 900. In addition, the first weight member 991 and the second weight member 992 each are able to rotate around any of an axis extending in the D1 direction, an axis extending in the D2 direction, and an axis extending in the D3 direction.
As shown in
As shown in
The third accommodation portion 9011h3 also has a linear movement restriction surface 9011a3 that restricts movement of the weight member in the D1 direction, and a rolling restriction surface 9011b3 that restricts movement of the weight member in the D2 direction and the D3 direction. The rolling restriction surface 9011b3 has a circular arc shape having substantially the same diameter as the spherical diameter of the weight member and has an inner peripheral surface having a central angle greater than or equal to 180° when viewed in the direction of the arrow Cl. The linear movement restriction surface 9011a2 and the linear movement restriction surface 9011a3 are provided in the same plane in the D1 direction.
The first accommodation portion 9011h1 has protruded portions 9011w having a linear movement restriction surface 9011a1 that restricts movement of the weight member in the D1 direction, and a rolling restriction surface 9011b1 that restricts movement of the weight member in the D2 direction and the D3 direction. The rolling restriction surface 9011b1 has a circular arc shape having substantially the same diameter as the spherical diameter of the weight member and has an inner peripheral surface having a central angle greater than or equal to 180° when viewed in the direction of the arrow Cl. Each protruded portion 9011w protrudes in the D2 and D3 directions so as not to close the opening portion 9011n when viewed in the direction of the arrow C1 (
Each of the first weight member 991 and the second weight member 992 can be accommodated in any one of the first accommodation portion 9011h1, the second accommodation portion 9011h2, and the third accommodation portion 9011h3 (see
With the above-described linear movement restriction surfaces (9011a1 to 9011a3) and the rolling restriction surfaces (9011b1 to 9011b3), leaving of the weight member (991, 992) once accommodated in the accommodation portion (9011h1 to 9011h3) from the accommodation portion is restricted. Therefore, even when the pressure of toner around the ejection port 9011 increases as a result of pushing the piston 902, a situation in which the weight member slips off from the accommodation portion to impede ejection of toner is prevented.
In the present embodiment, the three accommodation portions (9011h1, 9011h2, 9011h3) that each can accommodate at least one movable member are provided for the two movable members (991, 992). In addition, each accommodation portion is configured to communicate with the opening portion 9011n of the ejection port 9011. In this way, by providing the accommodation portions greater in number than the weight members, even when the weight members are accommodated in two of the three accommodation portions, the flow path of toner from the toner containing portion 9014 to the opening portion 9011n of the ejection port 9011 is ensured.
A flow path (movement path) of toner at the time when toner is ejected from the toner bottle unit 900 will be described by way of an example of a combination of accommodation positions of the weight members 991, 992. Of
In this way, by disposing the three accommodation portions for the two weight members, a toner ejection path is reliably ensured. In any case, at least one toner ejection path is ensured.
In any one of the above-described cases, the weight members (991, 992) are accommodated in the accommodation portions (9011h1, 9011h2, 9011h3) so as not to contact with the piston 902.
Next, toner supply operation at the time of supplying toner from the toner bottle unit 900 to the toner receiving unit 801 shown in
As shown in
After sufficiently shaking the toner bottle unit 900, the user determines the position of the toner bottle unit 900 such that the shutter member 904 is faced downward in the vertical direction as shown in
Subsequently, as shown in
When the user mounts the toner bottle unit 900 on the supply container mounting portion 701 of the toner receiving unit 801, the weight members (991, 992) may be in a state of being floated in toner. In this case as well, after the start of pushing the piston 902, the weight members move together with toner and are accommodated in the accommodation portions. Therefore, regardless of the timing at which the weight members are accommodated in the accommodation portions, toner is smoothly ejected.
As shown in
As described above, according to the present embodiment, it is possible to effectively loosen toner in the toner bottle unit 900 with the plurality of movable members.
In the present embodiment, the first weight member 991 and the second weight member 992 that are examples of the movable members are metal spheres having the same shape; however, the configuration is not limited thereto. Alternatively, the first weight member 991 and the second weight member 992 may be, for example, a combination of different sizes, different shapes, different specific gravities, different materials, or the like. At least part of the movable members may be made of a resin material, or the movable members may be, for example, formed by coating the surfaces of metal spheres with a resin. To penetrate in between particles of toner T to agitate the toner T, the density of each of the first weight member 991 and the second weight member 992 may be higher than the density of toner. Therefore, the material of each of the first weight member 991 and the second weight member 992 may be a metal. The first weight member 991 and the second weight member 992 contact with toner T1, so the material of each of the first weight member 991 and the second weight member 992 may be a rustproof material. For example, stainless steel, brass, lead, or the like may be used. Rustproofing (for example, resin coating or rustproof plating) may be applied to the first weight member 991 and the second weight member 992.
In the present embodiment, the first weight member 991 and the second weight member 992 each are freely movable in the first direction (D1), the second direction (D2), and the third direction (D3) inside the inner cylinder 901; however, as long as the first weight member 991 and the second weight member 992 are able to contact with toner to loosen the toner, movement of each of the first weight member 991 and the second weight member 992 may be limited in a specific direction.
The supply container including the configuration described in the present embodiment may be combined with the image forming apparatus including the configuration described in any one of the eighth to twelfth embodiments. In other words, in the eighth to twelfth embodiments, air outlet performance is improved by providing the plurality of ventilation portions in the frame of the process cartridge, so it is possible to stably discharge air even with an increase in the capacity of the supply container. According to the thirteenth embodiment, the plurality of movable members is disposed inside the supply container, so it is possible to further reliably prevent agglomeration of toner even with an increase in the amount of toner contained in the supply container. By combining these configurations, it is possible to provide a highly-convenient image forming system that eliminates inconvenience due to an increase in capacity while reducing the frequency of toner supply by increasing the capacity of the supply container.
According to the embodiments of the present disclosure, a cartridge, a supply container, and an image forming apparatus are provided.
The configurations described in the embodiments may be combined where appropriate.
While the present disclosure has been described with reference to exemplary embodiments, it is to be understood that the disclosure is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
Number | Date | Country | Kind |
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2019-188139 | Oct 2019 | JP | national |
2019-193591 | Oct 2019 | JP | national |
2019-193592 | Oct 2019 | JP | national |
The present application is a continuation of U.S. patent application Ser. No. 17/871,762, filed Jul. 22, 2022 which is a continuation of U.S. patent application Ser. No. 17/065,150, filed on Oct. 7, 2020 and issued as U.S. Pat. No. 11,422,484 on Aug. 23, 2022, which claims priority from Japanese Patent Application No. 2019-188139 filed Oct. 11, 2019, Japanese Patent Application No. 2019-193591, filed Oct. 24, 2019, and Japanese Patent Application No. 2019-193592, filed Oct. 24, 2019, which are hereby incorporated by reference herein in their entirety.
Number | Date | Country | |
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Parent | 17871762 | Jul 2022 | US |
Child | 18512899 | US | |
Parent | 17065150 | Oct 2020 | US |
Child | 17871762 | US |