The present invention relates to a developer container for supplying developer to an image forming apparatus, such as an electrophotographic copying machine or a printer.
In an image forming apparatus such as an electrophotographic copying machine or a printer, developer in the form of fine powder has been conventionally used as developer therefor. When the developer for the image forming apparatus is consumed, developer is supplied to the image forming apparatus by using a developer supply container.
The developer supply container for supplying developer to the image forming apparatus is roughly classified into two types thereof including a so-called simultaneous supply type container which supplies the entire amount of developer contained therein to a developer-receiving portion of the image forming apparatus at the same time, and a mounting type container which is mounted in a main assembly of the image forming apparatus and gradually supplies developer until the developer is used up.
In recent years, the mounting type developer supply container tends to be generally used in order to realize a compact image forming apparatus. Further, as the developer supply container described above, such a developer supply container that it is provided with a discharge opening, disposed on a peripheral surface of a cylindrical bottle, for permitting discharge of developer therefrom and supplies the developer by intermittently feeding toner while rotating the developer supply container, has been known. This developer supply container is changed in amount of discharge depending on an amount of toner remaining in the developer supply container, so that it has a poor supply stability. For this reason, Japanese Patent (JP-B) No. 3,168,722 has proposed such a developer supply container 500, as shown in
However, the above described conventional developer supply container as described in JP-B No. 3,168,722 is accompanied with such a problem that when toner has a large bulk density in the neighborhood of the discharge opening, the toner causes a blockage or a decrease in discharge amount at the discharge opening during the supply thereof although the developer supply container is provided with the measuring portion at the discharge opening to ensure supply of the toner in a constant amount for each supply operation with respect to such a phenomenon that the discharge amount is larger with a larger amount of developer remaining in the developer supply container and smaller with a smaller amount thereof.
An object of the present invention is to provide a developer supply container (hereinafter, simply referred to as a “developer container”) capable of discharging developer smoothly by suppressing a blockage of developer even when the developer has a large bulk density in the vicinity of a discharge opening.
According to the present invention, there is provided a developer container for feeding and discharging developer by rotationally moving about a rotation axis, comprising:
This and other objects, features and advantages of the present invention will become more apparent upon a consideration of the following description of the preferred embodiments of the present invention taken in conjunction with the accompanying drawings.
Each of
FIGS. 15(a), 15(b) and 15(c) are views showing structural members of a developer container according to Comparative Embodiment 1.
FIGS. 18(a) and 18(b) are views for illustrating a developer container according to Embodiment 2.
FIGS. 20(a) and 20(b) are views for illustrating a developer container according to Embodiment 3.
Hereinbelow, the present invention will be described specifically with reference to the drawings.
In this embodiment, the developer container is used in an electrophotographic copying machine, as the image forming apparatus, capable of forming a monochromatic image and a full-color image but may also be applicable to other electrophotographic image forming apparatuses, for forming an image on a recording medium according to an electrophotographic image forming method, such as another electrophotographic copying machine, electrophotographic printers (e.g., a laser beam printer, an LED printer, etc.), a facsimile apparatus, and a word processor.
(General Structure)
First of all, a general structure and an operation of the image forming apparatus will be described.
An original 101 is placed on a document glass 102 by an operator. By a plurality of mirrors and lenses of an optical means 103, an optical image of the original is formed on a photosensitive drum 104. On the other hand, a size of a sheet P (such as paper or an OHP sheet), as a recording medium, stacked in paper supply cassettes 105 and 106 in choose on the basis of information inputted by the operator through an operation means (not shown). Then, a feeding roller 105a or 106a corresponding to the chosen paper supply cassette 105 or 106 is rotated, and a single sheet P fed from the paper supply cassette 105 or 106 is conveyed to registration rollers 110 through a conveying means 109.
The registration rollers 110 convey the sheet P to the photosensitive drum 104 rotated in synchronism with scanning timing of the optical means 103. Onto the sheet P, a toner image on the photosensitive drum 104 is transferred by a transfer means 111. Thereafter, the sheet P is separated from the photosensitive drum 104 by a separation means 112. The sheet P is conveyed to a fixing means 114 by a conveying means 113. The toner image is fixed on the sheet P by the fixing means 114 under application of heat and pressure. Then, the sheet P is discharged onto a tray 117 by discharge rollers 116.
Around the photosensitive drums 104, a rotary developing apparatus 201, a cleaning means 202 and a primary charging means 203 are disposed. The rotary developing apparatus 201 develops an electrostatic latent image formed on the photosensitive drum 104 with toner. The primary charging means 203 electrically charges the photosensitive drum 104. The cleaning means 202 removes the toner remaining on the surface of the photosensitive drum 104. The developer which is decreased in amount by the development is successively supplied from a developer container.
(Rotary Developing Apparatus)
As shown in
The rotary developing apparatus 201 of this type is rotated 90 degrees at a time counterclockwise about a rotation (revolution) axis RA (in a direction of an arrow R) so that the developing device 9 located opposite to the photosensitive drum 104 is changed. In this embodiment, the developing device 9 is located opposite to the photosensitive drum 104 at a position 7a, which is herein referred to as a developing station. A developer conveyance member 9a and a developing sleeve 9b of the developing device 9 and a developer conveyance member 8b of a developer receiving means 8 receives a driving force from a main assembly of the image forming apparatus only at the developing station 7a, thus being rotated about the rotation axis RA. At this time, other developing devices 9 and other developer receiving means 8 located at positions 7b, 7c and 7d other than the developing station 7a are not actuated.
The developing sleeve 9b of the developing device 9 is disposed to have a minute spacing (about 300 μm) with the photosensitive drum 104. During the development, a thin toner layer is formed on a peripheral surface of the developing sleeve 9b by a developing blade (not shown). By applying a developing bias voltage to the developing sleeve 9b, an electrostatic latent image formed on the photosensitive drum 104 is developed.
The rotary developing apparatus in this embodiment is rotated, 90 degrees at a time, when image formation on two A4-sized sheets or one A3-sized sheet is performed, whereby the developing device is rotationally moved and changed in position. A movement time for the position change is about 0.3 sec, a stopping time for image formation is about 1.2 sec, a peripheral speed during the movement is about 0.7 m/sec, and a diameter of the rotary developing apparatus is 190 mm.
The diameter of the rotary developing apparatus means a maximum diameter of the rotary developing apparatus 201 placed in such a state that the developer containers 1 are mounted to the rotary developing apparatus 201. Further, in the present invention, a maximum radius (length) from the rotation center of the rotary developing apparatus 201 in such a state that the developer containers 1 are mounted to the rotary developing apparatus 201 is defined as a revolution radius of the developer container 1 and a speed at the maximum radius position is defined as a peripheral speed.
The rotary developing apparatus 201 in this embodiment is equally divided into four sections provided with four developing devices 9 of Bk, Y, M and C and corresponding four developer containers 1, respectively, as described above.
However, the four sections may also be provided by, e.g., unequally dividing the rotary developing apparatus into a Bk developing device having a large volume for supplying a larger amount of black developer which is frequently used, and other three Y, M and C developing devices. By using such a rotary developing apparatus having four sections different in occupied volume, it is also possible to achieve the effect of the present invention.
The developer used in this embodiment may be a monocomponent developer, a two-component toner, a two-component carrier, or a mixture of the two-component toner and the two-component carrier.
(Structure of Developer Supply Container)
Next, the structure of the developer container according to this embodiment will be described.
<General Structure of Developer Container>
The developer container shown in these Figures includes a container body 1, a rotation member 2 (hereinafter, referred to as a “knob”), a shutter 3, a packing member 4, and a powder pressure suppression member (as shown in
The container body 1 has a hollow cylindrical shape as shown in
On the peripheral surface of the container body 1 at one end portion thereof in an axial direction, a discharge opening 1c is provided. The discharge opening 1c is hermetically closed in an openable and closable manner by the shutter 3 and the packing member 4. The container body 1 can be provided through a method wherein a plastic material is subjected to injection molding, blow molding, injection blow molding, etc. In this embodiment, the container body 1 is prepared by molding and producing separately an upper member 1a and a lower member 1b with a high-impact polystyrene material and subjecting the upper and lower members 1a and 1b to ultrasonic fusion, but may be prepared by using another material and/or another method.
The discharge opening 1c has a rectangular shape (8 mm×15 mm) and is disposed at a position of 40 mm distant from a container end at the container peripheral surface. The developer contained in the container body 1 is discharged from the discharge opening 1c to the developing device on the apparatus main assembly side. By providing the discharge opening 1c at the peripheral surface of the container body 1, compared with a developer container provided with a discharge opening at its end surface, it becomes possible to reduce an amount of developer remaining in the developer container after the discharge operation. Further, by shortening a length of the discharge opening 1c compared with the full length of the container body 1 in its longitudinal (lengthwise) direction, contamination due to deposition of developer can be alleviated.
The knob (rotation member) 2 comprises a handle portion and a bi-cylindrical portion and is provided with a knob gear at an outer peripheral surface of an outer cylindrical portion and a claw, at an inner peripheral surface of an inner cylindrical portion, for being engaged with a circular projection provided to a side end portion of the container body 1 at its front side end portion by the claw so that it can be reciprocated in a circumferential direction of the container body 1. In this embodiment, the knob 2 is also produced by injection molding of the high-impact polystyrene material but may also be produced by using another material and/or another method. A material having a rigidity which is not less than a certain level is suitably used for the shutter 3. In this embodiment, the shutter 3 is produced through injection molding of a high-slidable ABS resin.
The packing member 4 is disposed to surround the discharge opening 1c of the container body 1 and is compressed by the container body 1 and the shutter 3 to hermetically close the discharge opening 1c. As the packing member 4, known various foams and elastic members can be appropriately be used. In this embodiment, a polyurethane foam is used.
<Feeding Projection>
As shown in
Each of the feeding projections 1d and 1e is so inclined that it is away from the discharge opening 1c toward upstream with respect to the direction of the rotation movement thereof. More specifically, on the drawing (
Further, the feeding projections 1e provided to the upper member 1a and the feeding projections 1d provided to the lower member 1b have such a positional relationship therebetween that they are alternately disposed as shown in
An inclination angle (Y shown in
Further, as shown in
<Powder Pressure Suppression Member>
As shown in
The powder pressure suppression member 5 used in this embodiment is produced through injection molding with a high-impact polystyrene material in an integral molding manner with the container body 1 but may be produced by using another material and/or another method. By performing the integral molding, it is possible to prepare the powder pressure suppression member 5 inexpensively.
<Mounting of Developer Container in Image Forming Apparatus>
Next, such a state that the developer container is mounted in the image forming apparatus and used will be described.
First of all, the container body 1 of the developer container is inserted into the developing device 9 of the rotary developing apparatus 201 of the image forming apparatus main assembly with the knob 2 (on the developer discharge opening side) directed toward an operator. In conjunction with the mounting of the developer container, an engagement between a known gear 2a and a developing device-side gear 10 and an engagement between the developing device-side gear 10 and a shutter gear 3a are ensured and the shutter 3 is engaged in a developing device-side shutter 11 (as shown in
Then, when the knob 2 is rotated a predetermined angle in a direction of an indicated arrow, a rotational force is transmitted from the known gear 2a to the gear 3a of the shutter 3 through the developing device-side gear 10, thus rotating the shutter 3. Together with the shutter 3, the developing device-side shutter is also rotated, whereby a hole provided on the developing deice shutter side is communicated with the discharge opening 1c on the developer container side, thus ensuring a discharge opening portion. A mounting position or method of the developer container in the image forming apparatus is not restricted to that described above but may appropriately be selected depending on a structure of the main assembly of the image forming apparatus.
The developer container is mounted in the rotary developing apparatus in such a manner that it is not rotated on its own axis, and revolves and moves around the rotation axis of the rotary developing apparatus by utilizing the rotation of the rotary developing apparatus. Accordingly, it becomes possible to eliminate a rotational moving force-receiving means from the developer container. As a result, it is possible to realize cost reduction with respect to the developer container and the main assembly of the image forming apparatus.
Mounting and demounting of the developer container may be performed at any position of four stations 7a to 7d shown in
<Operation State>
A state during an operation of the developer container 1 in this embodiment in the rotary developing apparatus 201 will be described.
As shown in
The developer container 1 is disposed immediately above the developer-receiving portion 8. For this reason, when the developer in the 1.5 developer-receiving portion 8 is decreased, developer present at the end portion of the developer container 1 falls immediately under its own weight to be supplied in the developer-receiving portion 8.
As described above, the developer container 1 disposed in association with the developing device 9 located at a stopping position (developing station 7a) where development is performed by the developing device 9 effectively supplies developer in the developing device 9 located at the developing position where developer is consumed because the discharge opening 1c is substantially directed toward a gravity direction to permit discharge of developer therefrom by free fall.
In the case where a sufficient amount of developer is not present at the end portion of the developer container 1, the developer contained in the developer container 1 is fed to the end portion by the action of the feeding projections 1d and 1d during one rotation of the rotary developing apparatus 201. As a result, the developer is supplied in the developer-receiving portion 8 during a period in which the associated developing device 9 is returned again to the developing station 7a.
The position of the discharge opening 1c of the developer container 1 in the developing station 7a may be any position but may preferably be obliquely above the rotation axis of the rotary developing apparatus, particularly immediately above the developer-receiving portion 8. Even when the developing device 9 is so disposed that the developer cannot be supplied from the developer container 1 into the developer-receiving portion 8 by fee fall in the developing station 7a, the developer container 1 can be located above the developer-receiving portion 8a always during one rotation of the rotary developing apparatus 201. As a result, the developer can be supplied.
Such a state that the developer in the developer container is discharged by rotation will be described with reference to
When the developer is supplied in the developing device 9, the developer passes through the discharge opening 1c under its own weight. At that time, by the presence of the back wall 5b of the powder pressure suppression member 5, toner located downstream in the rotation direction R is passed through the discharge opening 1c to be discharged as it is, and toner located upstream in the rotation direction R is passed through the back opening 5c while being regulated by the back wall 5b and then is passed through the discharge opening 1c to be supplied in the developing device 9.
Here, in the case where there is no back wall 5b, powder pressure of toner is increased on an inner surface of the discharge opening 1c, so that a bulk density of the toner is increased. As a result, a possibility of an occurrence of toner blocking becomes high.
The developer in the developer container 1 is moved in the directions of indicated arrows by revolution of the developer container 1 (around the rotation axis of the rotary developing apparatus) to be fed to the discharge opening 1c. At that time, the pressure of developer in the lengthwise direction of the developer container 1 is suppressed by the side walls 5a of the powder pressure suppression member 5, so that it is possible to prevent an increase in powder pressure in the vicinity of the discharge opening 1c.
The developer in the developer container 1 is substituted with air during the discharge thereof from the discharge opening 1c. By taking in air from the outside of the developer container 1, a difference in atmospheric pressure is removed, thus permitting discharge of developer through the discharge opening 1c. Air is passed through a spacing between toner particles but is less liable to be passed therethrough when a powder pressure of the toner particles is increased to narrow the spacing. As shown in
The back opening 5c further has two functions including a function of permitting discharge of developer located close to the discharge opening 1c by inertial force during a stop of initial rotation and a function of causing the toner to pass through it during the latter stage of discharge of toner (i.e., when an amount of toner remaining in the developer container is decreased). With respect to the former function, when the container body 1 is revolved and stopped at a position (4) (at which the discharge opening 1c is directed downward) as shown in
(Experiment)
In this experiment, discharge performances of a developer container described in JP-B No. 3,168,722 and the developer container of this embodiment are compared. As described above the developer container of this embodiment has the structure shown in
A structure of a discharge opening of Comparative Embodiment 1 is shown in FIGS. 15(a), 15(b) and 15(c).
In Comparative Embodiment 1, a powder pressure suppression member provided at a discharge opening 1 corresponds to a measuring member 301 proposed in JP-B No. 3,168,722.
As shown in
A comparative experiment was conducted by using the above described three types of developer containers under such a condition that the same feeding performance for feeding the developer to the discharge opening is provided. More specifically, each of the developer containers has 5 mm-high feeding projections including 5 feeding projections provided on the upper member 1a side and 5 feeding projections provided on the lower member 1b side with an overlapping amount of 5 mm therebetween.
In each of these developer containers, 180 g of developer was filled and subjected to a discharging test by using a simple rotary developer discharging jig (capable of directly measuring an amount of developer discharged from the discharge opening of the developer container by removing the developing devices from the rotary developing apparatus) under conditions including a rotation angle, of the simple rotary developer discharging jig, of 90 degrees at a step (90 degrees×4 for one revolution), a movement time of about 0.3 sec., a stop time for image formation of about 1.2 sec., a peripheral speed during movement of about 0.7 m/sec., and a diameter of 190 mm.
<Results>
Experimental results are shown in
As shown in
Further, a remarkable difference in discharge state between the developer containers was observed. More specifically, with respect to the developer containers of Comparative Embodiment 1 (with measuring member 301) and Comparative Embodiment 2 (only with feeding projections), the discharge state of developer was such that toner having a high bulk density was not discharged successively but discharged intermittently at an initial discharge state. On the other hand, with respect to the developer container of Embodiment 1, the discharge state of developer was such that toner having a low bulk density was successively discharged.
A remaining amount (rest) of toner was about 1.5 g for the developer container of Embodiment 1, about 2.4 g for the developer container of Comparative Embodiment 1, and about 1.5 g for the developer container of Comparative Embodiment 2.
<Constitution>
From the above results, compared with the comparative developer containers of Comparative Embodiment 1 (with measuring member 301) and Comparative Embodiment 2 (only with feeding projections), the developer container of Embodiment 1 (with powder pressure suppression member 5) provided a higher discharge speed of developer.
The reason therefor will be considered based on the cross-sectional views of developer containers shown in
In Comparative Embodiment 1, as shown in
In the developer container (only with feeding projections) of Comparative Embodiment 2, as described with reference to
On the other hand, in Embodiment 1, as shown in
However, the back wall 5b of the powder pressure suppression member 5 is provided with a back opening 5c, which is a characteristic feature of the present invention, through which the toner is caused to pass while suppressing an increase in bulk density in the powder pressure suppression member 5 by restricting the power pressure of toner owing to the presence of the back wall 5b. As a result, the toner in the powder pressure suppression member 5 is replenished.
Accordingly, as shown in
FIGS. 18(a) and 18(b) are perspective views for illustrating a developer container of this embodiment, and
In this embodiment, the developer container has the same structure as that in Embodiment 1 except that the shape of the powder pressure suppression member 5 is changed to that shown in
More specifically, the powder pressure suppression member 5 is further provided with a top wall 5d disposed to cover the upper (top) surfaces of three walls 5a and 5b. Instead of the top wall 5d, it is also possible to so design the upper member 1a that a part thereof is disposed to cover the upper surfaces of three walls 5a and 5b.
As a result of experiment, as shown in
FIGS. 20(a) and 20(b) are perspective views for illustrating a developer container of this embodiment, and
In this embodiment, the developer container has the same structure as that in Embodiment 1 except that the shape of the powder pressure suppression member 5 is changed to that shown in
More specifically, the powder pressure suppression member 5 is further provided with not only a top wall 5d disposed similarly as in Embodiment 2 but also side openings 5e each provided to an associated side wall 5a of the powder pressure suppression member 5. In other words, different from the powder pressure suppression member 5 having only one opening (the back opening 5c of the back wall 5b) in Embodiment 1, the powder pressure suppression member 5 in this embodiment further has other two openings (side openings 5e of the side wall 5a).
As a result of experiment, as shown in
While the invention has been described with reference to the structures disclosed herein, it is not confined to the details set forth and this application is intended to cover such modifications or changes as may come within the purposes of the improvements or the scope of the following claims.
This application claims priority from Japanese Patent Application No. 307151/2003 filed August 29,2003 which is hereby incorporated by reference.
Number | Date | Country | Kind |
---|---|---|---|
307151/2003 (PAT) | Aug 2003 | JP | national |
Number | Date | Country | |
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Parent | 10924922 | Aug 2004 | US |
Child | 11201319 | Aug 2005 | US |