The present invention relates to a developing apparatus which has first and second chambers and is shipped from a manufacturer in such a condition that developer is kept sealed in the second chamber by keeping the openings of the partitioning wall between the first and second chambers remain sealed with sealing sheets. More specifically, it relates to a developing apparatus structure which can reduces a developing apparatus in the amount of load to which a developing apparatus driving motor is subjected when a brand-new developing apparatus is started up for the very first time.
Image forming apparatuses in which a developing apparatus or a process cartridge is removably mountable, and which forms an electrostatic latent image on its image forming member, develop the electrostatic latent image by the developing apparatus, into a toner image, that is, an image formed of toner, and transfer the toner image onto recording medium, have been widely in use (Japanese Laid-open Patent Application 2001-75346). It is customary that an image forming apparatus and a replacement developing apparatus are shipped from a manufacturer in such a condition that the startup developer, which is the first body of developer to be used by the developing apparatus, is kept sealed along with nitrogen gas or the like, in the developing apparatus to prevent the body of developer from coming into contact with ambient air, for the following reason. That is, if developer is left unattended while being left in contact with such ambient air that is high in temperature and humidity, the developer deteriorates by absorbing the humidity. With the developer deteriorated by the humidity, it is possible that right after a brand-new developing apparatus is started up, the startup developer in the developing apparatus will fail to perform at a preset level.
Japanese Laid-open Patent Application 2001-75346 discloses a developing apparatus, to which the output of the motor with which the image forming apparatus is provided is transmitted to the developing apparatus through a coupling, and in which the inputted output (rotational force) is transmitted to its developer conveying screw and development sleeve by way of its gear train.
Japanese Laid-open Patent Application 2002-236413 discloses a developing apparatus which contains a developer container in which the startup developer, that is, the developer which is to be used when the developing apparatus is used for the very first time, is kept sealed by a sealing sheet. In the case of this developing apparatus, the developer container is to be unsealed by manually peeling the sealing sheet from outside of the apparatus, right after the mounting of the developing apparatus into the main assembly of an image forming apparatus. As the sealing sheet is peeled away, the startup developer in the developer container is allowed to fall into the developing apparatus to fill the developing apparatus.
However, in a case where a developing apparatus is shipped from a manufacturer with its first and second chambers left empty, and then, the developing apparatus is filled with the startup developer left sealed in the developer container, when the developing apparatus is used for the very first time, a large space for the developer container is necessary in the developing apparatus. Thus, if a developing apparatus is small, it cannot contain a developer container which is satisfactory in developer capacity. On the other hand, in order for a developing apparatus to be afforded a space for a developer container which is satisfactory in developer capacity, the developing apparatus has to be large in size, which interferes with the effort to reduce an image forming apparatus in size.
Thus, Japanese Laid-open Patent Application 2004-252174 proposes a developing apparatus structured as follows: It has first and second chambers, and until the developing apparatus is used for the very first time, the startup developer is kept hermetically sealed by a necessary amount, in the second chamber. More specifically, the partitioning wall of the developing apparatus, with which the first and second chambers are partitioned from each other, is provided with two openings, which are in the end portions, one for one, in terms of the lengthwise direction of the developing apparatus, and the second chamber is kept hermetically sealed by sealing the two openings of the partitioning wall with a sealing sheet. In the case of this developing apparatus, the second chamber functions as the developer container for containing the startup developer, that is, the developer to be used when the developing apparatus is used for the very first time. Therefore, storing the startup developer in the developing apparatus in the developing apparatus disclosed in Japanese Laid-open Patent Application 2004-252174 by a satisfactory amount does not require the developing apparatus to be significantly larger than an ordinary developing apparatus.
In the case of the developing apparatus proposed in Japanese Laid-open Patent Application 2004-252174, when an image forming apparatus is operated for the very first time, or right after the developing apparatus in the image forming apparatus was replaced with a brand-new developing apparatus, the sealing sheet has to be manually pulled out from outside the image forming apparatus to fill the development chamber of the developing apparatus with the startup developer, that is, the developer kept hermetically sealed in the developing apparatus, before an image forming operation is started. Thus, it was proposed to automatically peel the sealing sheet away from the openings of the partitioning wall between the first and second chambers, with the use of a part of the rotational force transmitted to the developing apparatus from the main assembly of the image forming apparatus through the coupling and a gear train, as disclosed in Japanese Laid-open Patent Application 2001-75346.
The development apparatus structured as disclosed in Japanese Laid-open Patent Application 2004-252174 is smaller in the area of the sealing sheet, by which the sealing sheet is pasted to the edges of the openings, being therefore smaller in the amount of torque necessary to peel way the sealing sheet, than that in Japanese Laid-open Patent Application 2002-236413. However, when an experiment was carried out in which the sealing sheet of a developing apparatus structured like the developing apparatus disclosed in Japanese Laid-open Patent Application 2004-252174 is automatically peeled, the torque required of the motor for peeling the sheet increased when the sealing sheet was being peeled by being rolled up. Thus, the motor was overloaded while the sealing sheet was peeled.
Thus, the operation of the mechanism for automatically peeling the sheet was observed by making transparent a part of the external wall of the developing apparatus. The observation revealed that as the second developer conveyance screw continued to rotate in the second chamber while the openings (outlets) of the second chamber remained sealed with the sealing sheet, the body of developer in the second chamber reached the ceiling of the chamber, on the downstream side of the chamber. Then, as the second developer conveyance screw was rotated more, the portion of the body of developer, which was in the downstream end portion of the second chamber, was compacted because the sealing sheet has not been removed from the openings, and therefore, the downstream end portion of the second chamber did not have an outlet for developer. Consequently, the body of developer, which was in the downstream end portion of the second chamber increased in internal pressure, overloading thereby the developer conveyance screw.
Thus, the primary object of the present invention is to provide a developing apparatus which is structured so that the openings of the wall between the two chambers of the apparatus are kept sealed with sealing sheets when it is shipped from a manufacturer, and yet, does not overload the motor of the main assembly of the image forming apparatus when the sealing sheets are automatically peeled away by being rolled up.
According to an aspect of the present invention, there is provided a developing apparatus comprising a first chamber for accommodating a developer, said first chamber being provided with a developer carrying member for carrying the developer; a second chamber communicated with said first chamber through communication openings provided at opposite end portions to establish a circulation path; a feeding member, provided in said second chamber, for feeding the developer in a feeding direction which is from one of the communication openings toward the other communication opening; a sealing portion for openably sealing said communication openings; a moving mechanism for opening said communication openings by moving said sealing portion; and a reverse feeding member for feeding the developer in a direction which is opposite the feeding direction.
These and other objects, features, and advantages of the present invention will become more apparent upon consideration of the following description of the preferred embodiments of the present invention, taken in conjunction with the accompanying drawings.
Hereinafter, the preferred embodiments of the present invention are described in detail with reference to the appended drawings. The present invention is also applicable to developing apparatuses other than the one in the preferred embodiment of the present invention, as long as the second chamber of the developing apparatuses is provided with an additional developer conveyance screw, and the additional developer screw is opposite in developer conveyance direction from the second developer conveyance screw. That is, as long as the above-described requirement is met, the present invention is applicable to any developing apparatus even if the developing apparatus is partially or entirely different in structure from the developing apparatuses in the preferred embodiments.
The developing apparatus in accordance with the present invention is employable by an image forming apparatus regardless of the apparatus type. For example, it is employable by an image forming apparatus regardless of whether the apparatus is of the tandem-type or single drum type, and whether or not the apparatus is of the intermediary transfer type or direct transfer type. Further, the present invention is also applicable to image forming apparatuses other than the one in the preferred embodiment, for example, a printer, a copying machine, a facsimile machine, a multifunction image forming apparatus, etc., which are made up of one of the image forming apparatuses in the preferred embodiments, and additional devices, equipment, and frames.
Incidentally, the ordinary items of the developing apparatuses disclosed in Japanese Laid-open Patent Applications 2001-75346, 2002-236413, and 2004-252174 are not illustrated, and are not described.
<Image Forming Apparatus>
In the image forming portion Sa, a yellow toner image is formed on a photosensitive drum 1a, and transferred onto the intermediary transfer belt 7. In the image forming portion Sb, a magenta toner image is formed on a photosensitive drum 1b, and is transferred onto the intermediary transfer belt 7. In the image forming portions Sc and Sb, a cyan toner image and a black toner image are formed on photosensitive drums 1c and 1d, respectively, and are transferred onto the intermediary transfer belt 7.
The intermediary transfer belt 7 is stretched and supported by first transfer rollers 5a, 5b, 5c, and 5d, a backup roller 8, a tension roller 17, and a tension roller 18, and is circularly driven in the direction indicated by an arrow mark R7 by the backup roller 8 which doubles as a belt driving roller. After the transfer of the four monochromatic toner images, different in color, onto the intermediary transfer belt 7, the four toner images are conveyed by the intermediary transfer belt 7 to the second transfer portion T2, in which they are transferred (second transfer) onto a sheet P of recording medium which was taken out of a recording sheet cassette 10 and conveyed to the second transfer portion T2. The sheet P of recording medium is supplied to the second transfer portion T2 by a sheet feeding-and-conveying apparatus which comprises a sheet feeding roller, sheet conveying roller, registration rollers, etc. (which are not shown in
After the transfer of the toner images onto the sheet P of recording medium in the second transfer portion T2, the sheet P is conveyed to a fixing apparatus 13 which has a fixation roller 14 and a pressure roller 15, and is conveyed through the fixing apparatus 13. While the sheet P is conveyed through the fixing apparatus 13, the sheet P and the toner images thereon are subjected to heat and pressure by the fixation roller 14 and pressure roller 15 which are kept pressed upon each other. Thus, the toner images are fixed to the sheet P. Then, the sheet P is discharged from the image forming apparatus 200.
The image forming portions Sa, Sb, Sc, and Sd are roughly the same in structure, although they are different in the color of the toner they use. The developing apparatuses 100a, 100b, 100c, and 100d also are roughly the same in structure although they also are different in the color of the toner they use. Hereafter, therefore, only the image forming portion Sa is described. The description of the image forming portions Sb, Sc, and Sd are the same as that of the image forming portion Sa, except for the suffixes of the referential codes of the structural components.
The image forming portion Sa comprises: a photosensitive drum 1a; and a charge roller 2a, an exposing apparatus 3a, a developing apparatus 100a, first transfer roller 5a, and an auxiliary charge roller 6a, which are in the adjacencies of the peripheral surface of the photosensitive drum 1a.
The photosensitive drum 1a comprises: an aluminum cylinder; and a negatively chargeable photosensitive layer which covers virtually the entirety of the peripheral surface of the photosensitive drum 1a. The photosensitive drum 1a is rotated in the direction indicated by an arrow mark R1 at a preset peripheral velocity. The charge roller 2a uniformly charges the peripheral surface of the photosensitive drum 1a to the negative polarity. The exposing apparatus 3a writes an electrostatic image of the original to be formed, on the peripheral surface of the photosensitive drum 1a by scanning the uniformly charged portion of the peripheral surface of the photosensitive drum 1a with the beam of laser light it projects while reflecting the beam with a rotating mirror. The developing apparatus 100a forms a visible image formed of toner (which hereafter will be referred to simply as toner image) on the peripheral surface of the photosensitive drum 1a, by developing the electrostatic image on the peripheral surface of the photosensitive drum 1, with the use of two-component developer made up of toner and carrier.
The first transfer roller 5a is within the loop which the intermediary transfer belt 7 forms. It is kept against the peripheral surface of the photosensitive drum 1 with the presence of the intermediary transfer belt 7 between the first transfer roller 5a and photosensitive drum 1a, forming thereby the first transfer portion T1, between the peripheral surface of the photosensitive drum 1a and intermediary transfer belt 7. As positive DC voltage is applied to the first transfer roller 5a, the toner image on the peripheral surface of the photosensitive drum 1a, which is made of negatively charged toner particles, is transferred (first transfer) onto the intermediary transfer belt 7. The auxiliary charge roller 6a negatively charges the transfer residual toner particles in order to make the transfer residual toner contribute to the following development process to be carried out by the developing apparatus 100a. The transfer residual toner particles are the toner particles on the peripheral surface of the photosensitive drum 1a, which failed to be transferred onto the intermediary transfer belt 7, and therefore, remained on the peripheral surface of the photosensitive drum 1.
The image forming apparatus 200 is provided with a belt cleaner 11 for removing the transfer residual toner remaining adhered to the intermediary transfer belt 7. The belt cleaner 11 is positioned so that it opposes the tension roller 17 with the presence of the intermediary transfer belt 7 between the cleaner 11 and roller 17.
<Developing Apparatus>
Referring to
The developing apparatus shell 101 has a development chamber 101a and a developer stirring chamber 101b, which are partitioned from each other by a vertical partition wall 103. Both the development chamber 101a and developer stirring chamber 101b contain two-component developer, that is, mixture of nonmagnetic toner, magnetic carrier, and a small amount of external additives.
The developing apparatus 100 has a stationary magnet 102m which has multiple magnetic poles. The magnet 102m is within the hollow of the development sleeve 102. The developer in the development chamber 101a is borne on the peripheral surface of the development sleeve 102 by being confined by the magnetic flux formed between the adjacent two magnetic poles of the magnet 102m, forming thereby a magnetic brush made up of positive charged carrier particles, and the negative charge toner particles which are electrostatically held to the surface of the carrier particles. An electric power source 52 is for transferring the negative charged toner particles in the magnetic brush, onto the electrostatic image on the photosensitive drum 1, by applying oscillatory voltage, that is, a combination of negative DC voltage, and AC voltage.
Referring to
The partitioning wall 103 has openings 107a and 107b, which are at the lengthwise ends of the partitioning wall 103 in terms of the lengthwise direction of the developing apparatus 200. Thus, the development chamber 101a, opening 107b, stirring chamber 101b, and opening 107a form a passage through which developer can be circulated. That is, the developer in the stirring chamber 101b is moved into the development chamber 101a through the opening 107a, whereas the developer in the development chamber 101a is moved into the stirring chamber 101b through the opening 107b.
While the developer is circulated through the developer circulation path structured as described above, the developer becomes frictionally charged by being stirred. More specifically, the toner particles become negatively charged, whereas the carrier particles become positive charged. The developer in the stirring chamber 101b is conveyed toward the opening 107a while being stirred by the stirring screw 104b, and flows into the development chamber 101a through the opening 107a of the partitioning wall 103. Then, the developer in the development chamber 101a is borne on the peripheral surface of the development sleeve 102 as it is conveyed toward the opening 107b while being stirred by the development screw 104a.
The development screw 104a, which is an example of the first developer conveyance screw, is rotatably position in the development chamber 101a, which is an example of the first chamber. As the first stirring screw 104a is rotated, the two-component developer in the development chamber 101a is conveyed toward the opening 107b as indicated by an arrow mark B.
The stirring screw 104b, which is an example of the second developer conveyance screw, is rotatably positioned in the stirring chamber 101b, which is an example of the second chamber. As the second developer conveyance screw 104b is rotated, the two-component developer in the stirring chamber 101b is conveyed toward the opening 107a as indicated by an arrow mark A.
There is a toner supplying mechanism 105, which is above the upstream end of the stirring chamber 101b in terms of the developer conveyance direction (
The amount Q/M of the toner charge of the two-component developer is one of the primary parameters which determine the image density level to which an electrostatic image is developed. Further, there is a correlation between the weight ratio (density T/D of toner) of the toner in the two-component developer, and the amount Q/M of the toner charge.
Toner particles are charged by the friction between them and carrier particles. Therefore, the greater the frequency with which they come into contact with carrier particles, the greater the amount Q/M of the toner charge. Thus, the smaller the developer in the toner density T/D, the greater the amount Q/M of the toner charge, and therefore, the lower the developer in the image density level to which it develops an electrostatic image. Therefore, the toner density T/D of the developer is continuously monitored with an unshown magnetic permeability sensor as the developer is circulated through the development chamber 101a and stirring chamber 101b. Further, the amount by which the developing apparatus 100 is supplied with replenishment toner from the toner supplying mechanism 105 is adjusted so that the developer in the developing apparatus 100 remains roughly stable in the toner density T/D.
The two-component developer is a mixture of toner and carrier, which is preset in the toner density T/D as disclosed in Japanese Laid-open Patent Application 2001-249544. It remains sealed in the developer container. If the two-component developer is left unattended for a substantial length time in an ambience which is high is temperature and humidity, after the toner and carrier are mixed with each other, the average toner particle charge Q/M of the two-component developer remaining sealed in the developer container is lower than the preset value, when the developing apparatus 100 is started up.
As one of the means for dealing with the above described situation, it is possible to circulate the developer in the developing apparatus 100 through the development chamber 101a and stirring chamber 101b by the development screw 104a and stirring screw 104b until the toner charge amount Q/M of the developer reaches a proper value. However, continuous stirring of the developer sometimes causes the developer to deteriorate. For example, it sometimes reduces the developer in fluidity and/or rechargeability.
Thus, the length of time the developer is circulated in the developing apparatus 100 during the startup period of the developing apparatus is desired to be as short as possible. In this embodiment, therefore, such a method that the startup developer, that is, the developer which is used by the developing apparatus when the developing apparatus is used for the very first time, is kept sealed in a container independent from the developing apparatus, or the startup developer is kept sealed within the developing apparatus, is employed.
The method which supplies the developing apparatus with the startup developer from the container different from the developing apparatus shell is problematic in that when the developing apparatus is supplied with the startup developer, the developer is likely to scatter and contaminate the adjacencies of the developing apparatus. It is also problematic in that the length of time spent to supply the developing apparatus with the startup developer from the container other than the developing apparatus shell is wasted time; it reduces the developing apparatus in operability; it requires a certain amount of skill to supply the developing apparatus with the startup developer; and the like. Further, it is problematic in that when the developing apparatus is transported after it was supplied with the startup developer, the developer in the apparatus is liable to overflow or leak.
Therefore, having the startup developer hermetically sealed in the developing apparatus has been becoming mainstream (Japanese Laid-open Patent Applications 2001-75346, and 2002-236413). Further, Japanese Laid-open Patent Application 2004-252174 discloses a developing apparatus structured so that the startup developer remains sealed in the stirring chamber of the developing apparatus by sealing the openings of the partitioning wall with a sealing member.
<Structural Arrangement for Keeping Startup Developer Sealed>
Referring to
Referring to
The sealing sheet 51a is pasted to the edge portions of the opening 107a in such a manner that it extends from the top edge portion of the opening 107a to the bottom edge portion of the opening 107a, and is doubled back to the downstream end, at which it is solidly attached to a rotational take-up shaft 600. Similarly, the sealing sheet 51b is pasted to the edge portions of the opening 107b in such a manner that it extends from the downstream edge portion of the opening 107b to the upstream end portion of the opening 107b, and is doubled back to the downstream end, at which it is solidly attached to the rotational take-up shaft 600.
As the stirring screw 104b is rotated, the rotational take-up shaft 600, which is a part of a sealing member pealing mechanism, is rotated by the rotation of the stirring screw 104b, exposing the openings 107a and 107b by peeling the sealing sheets 51a and 51b. The image forming apparatus 200 and developing apparatus 100 are structured so that when a brand-new developing apparatus is used for the very first time, the rotational take-up shaft 600 automatically (that is, without being operated by user) peels away the sealing sheets 51a and 51b from the edge portions of the openings 107a and 107b to start up the developing apparatus for image formation.
Further, the developing apparatus 100 is structured so that the timing with which the sealing member 51a begins to be peeled away by the rotational take-up shaft 600, is different from that with which the sealing member 51b begins to be peeled away by the rotational take-up shaft 600, and also, the timing with which the peeling of the sealing member 51a by the rotational take-up shaft 600 ends is different from that with which the peeling of the sealing member 51b by the rotational take-up shaft 600 ends. More specifically, the timing with which the peeling of the sealing member 51a by the rotational take-up shaft 600 from the edge portions of the opening 107a begins is earlier than the timing with which the peeling of the sealing member 51b by the rotational take-up shaft 600 from the edge portion of the opening 107b begins. In other words, the portion of the sealing sheet 51b, one of the end portions of which is pasted to the bottom edge portion of the opening 107b, and the other end portion of which is attached to the rotational take-up shaft 600 is made to be longer than the portion of the sealing sheet 51a, which extends from the point of double-back to the rotational take-up shaft 600.
<Mechanism for Driving Take-Up Shaft>
The mechanical force transmitted to the development sleeve 102 from the motor 53 rotates the stirring screw 104b, development screw 104a, rotational take-up shaft 600, and reverse conveyance screw 104c together, by being transmitted to them through a gear train 160, which is on the opposite side of the developing apparatus 100 from the side on which the motor 53 is connected to the development sleeve 102. The stirring screw 104b, development screw 104a, rotational take-up shaft 600, and reverse conveyance screw 104c are in connection to each other through the gear train 160. Thus, as the development sleeve 102 rotates, a center gear 151 rotates. A gear 150 which is in mesh with the gear 151 rotates the development screw 104a. A gear 152 which is in mesh with the gear 151 rotates the stirring screw 104b.
The reverse conveyance screw 104c is rotated by the driving force transmitted thereto through the gears 151, 153, and 156; the gear 153 is in mesh with the gear 151, and the gear 153 is in mesh with the gear 153. The rotational take-up shaft 600 is rotated by the driving force transmitted thereto through the gears 151, 153, 157, 154, and 155; the gear 153 is in mesh with the gears 151 and 157, and the gear 154 is in mesh with the gears 157 and 155. In order to ensure that the torque transmitted to the rotational take-up shaft 600 is large enough to efficiently peel away the sealing sheets 51a and 51b, a worm gear is employed as the gear 154 to cause the gear 154 to rotate substantially slower than the gear 154.
With the employment of the above described structural arrangement, the development sleeve 102, development screw 104a, and stirring screw 104b rotate at 250 rpm, 300 rpm, and 400 rpm, respectively. In order to make the stirring screw 104b higher in the developer charging performance than the development screw 104a, the stirring screw 104b is made higher in rotational speed than the development screw 104a. The reverse conveyance screw 104c and rotational take-up shaft 600 rotate at 300 rpm and 20 rpm, respectively.
Further, the developing apparatus 100 is structured so that the joint between the rotational take-up shaft 600 and gear 155 is in the adjacencies of the sealing sheet 51a. Thus, the sealing member which is farther from the lengthwise end portion of the rotational take-up shaft 600, by which the rotational take-up shaft 600 is driven, begins to be peeled later than the other sealing member.
Incidentally, in a case where the startup developer is kept hermetically sealed in the stirring chamber 101b by sealing the openings between the development chamber 101a and stirring chamber 101b, there is a problem that the amount of the load to which the motor 53 is subjected when the developing apparatus is started up is substantial. That is, if the rotation of the stirring screw 104b is continued without removing the sealing sheets 51a and 51b, the developer in the stirring chamber 101b cannot move into the development chamber 101a, and therefore, the amount of the force (torque) necessary to drive the developing apparatus 100 becomes very large.
In the case of the developing apparatus in this embodiment, as the developer in the stirring chamber 101b is moved by the rotation of the stirring screw 104b, into the downstream end portion of the chamber 101b when the opening 107a of the partitioning wall 103 is not exposed, the reverse conveyance screw 104c, which is an example of a means for conveying developer in the reverse direction, conveys the developer in the downstream end portion of the chamber 101b, (which was moved (packed) into the downstream end portion of the chamber 101b by the second conveyance screw (104b)), in the opposite direction from the direction in which the stirring screw 104b conveys the developer. The reverse conveyance screw 104c is positioned at such a height (relative to bottom of stirring chamber 101b) that after the formation of the developer recirculation path by exposing of the openings 107a and 107b, it will be above the developer recirculation path. The above described effect was confirmed by the experiments carried out by the inventors of the present invention, in which the reverse conveyance screw 104c was 15 mm in diameter, and no less than 9 mm in length.
<Control of Very First Startup>
Unlike the sealing member(s) described in Japanese Laid-open Patent Application 2004-252174, the sealing members 51a and 51b of the developing apparatus 100 in this embodiment do not need to be manually removed by a user or service person. Instead, the sealing members 51a and 51b are automatically removed with the use of the motor 53 of the main assembly of the image forming apparatus 200. Thus, the developing apparatus 100 is significantly higher in usability than any of the developing apparatuses in accordance with the prior art.
Referring to
Then, the user is to input a command for starting up the developing apparatus for the very first time, through a control panel 56. As the command is inputted, the control portion 50 begins to rotate the development sleeve 102 by activating the motor 53 with which the main assembly of the image forming apparatus 200 is provided. Thus, the stirring screw 104b, development screw 104a, reverse conveyance screw 104c, and rotational take-up shaft 600 begin to be rotated by the development sleeve 102, simultaneously with the development sleeve 102, by the rotation of the development sleeve 102 through the above described gear train 160 (S802).
Referring to
Referring to
Referring to
As the sealing sheet 51a continues to be peeled, the amount by which the developer in the stirring chamber 101b is pushed into the development chamber 101a by the stirring screw 104b through the portion of the opening 107a, which is exposed by the peeling of the sealing sheet 51a, gradually increases. Thus, the developer pushed into the development chamber 101a by the stirring screw 104b from the stirring chamber 101b begins to be conveyed toward the opening 107b in the development chamber 101a.
Next, referring to
By the time the developer pushed into the development chamber 101a from the stirring chamber 101b is conveyed to the opening 107b by the development screw 104a, a substantial length of time will have elapsed since the sealing sheet 51b began to be peeled. Thus, as the developer in the development chamber 101a is conveyed by the development screw 104a to the portion of the development chamber 101a, which has the opening 107b, the developer flows into the stirring chamber 101b through the opening 107b without interference from the sealing sheet 51b. Then, the developer is picked up by the stirring screw 104b. This is when the developer begins to circulate throughout the developing apparatus 100 (S805).
As the sealing sheet 51a is peeled all the way, and the entirety of the sheet 51a is rolled up on the rotational take-up shaft 600, the opening 107a becomes fully exposed (S806). Slightly later, the sealing sheet 51b is completely rolled up on the rotational take-up shaft 600, and therefore, the opening 107b becomes fully exposed (S807).
After the full exposure of the openings 107a and 107b, the control portion 50 continues to rotate the development sleeve 102, development screw 104a, stirring screw 104b, and reverse conveyance screw 104c for 120 seconds, and then, stops them. Thus, the two-component developer in the developing apparatus shell becomes fully mixed by being stirred as shown in
While the developing apparatus 100 is engaged in an operation, the reverse conveyance screw 104c and rotational take-up shaft 6000 continue to be rotated with the development sleeve 102, etc. However, after the very first startup of the developing apparatus 100, the reverse conveyance screw 104c rotates in an area which is spaced from the top surface of the powder of developer in the stirring chamber 101b, that is, the reverse conveyance screw 104c is disposed above and spaced from the normal level (top), during the image forming operation, of the developer powder in the stirring chamber 101b during the image forming operation, and the rotational take-up shaft 600 idly rotates bearing the sealing sheets 51a and 51b. Therefore, the amount of the torque required of the motor 53 to rotate the reverse conveyance screw 104c and rotational take-up shaft 600 is relatively small, and therefore, does not have adverse affect upon the rotation of the development sleeve 102 and the stirring of the developer.
<Comparative Developing Apparatus>
In the first preferred embodiment of the present invention described above, the reverse conveyance screw 104c is utilized during the very first startup of the brand-new developing apparatus. If a developing apparatus is not provided with the reverse conveyance screw 104c, the amount of torque required of the motor 53 when its sealing sheet 51a begins to be peeled becomes greater by Δtmax than that when the sealing sheet 51a of the developing apparatus in the first embodiment of the present invention begins to be peeled, as indicated by a broken line in
Incidentally, as the method for keeping the startup developer hermetically sealed in the developing apparatus, it is possible to use a method, shown in
As long as the openings 107a and 107b are kept open to keep intact the developer circulation path in the developing apparatus, the continuous rotation of the developer conveyance screw 104a does not cause the phenomenon that the amount of the load to which the motor 50 is subjected to rotate the stirring screw 104b is increased by the pressure increase in a part of the body of developer in the stirring chamber 101b. Therefore, there is no need for the provision of the reverse conveyance screw 104c.
In this case, however, a space through which the sealing sheet can be passed has to be provided between the development sleeve 102 and development screw 104a. In other words, the space between the development sleeve 102 and development screw 104a has to be made larger than in the case of the first embodiment of the present invention, which is a problem. In the case of the developing apparatus in the first embodiment, the distance between the development sleeve 102 and development screw 104a was reduced to enable an image forming apparatus to output high quality images, and also, to prevent the developer therein from deteriorating. Thus, this comparative developing apparatus invites opposite effects from those of the developing apparatus in the first embodiment of the present invention.
Also in the case of the developing apparatus 100 in the first embodiment, the magnetic force of the magnet 102m in the development sleeve 102 is used to attract the developer to the peripheral surface of the development sleeve 102 and keep the developer borne thereon. Thus, unless the distance between the development sleeve 102 and development screw 104a is very small, the magnet 102m has to be replaced with a magnet which is substantially stronger in magnetism than the magnet 102m. This creates a problem in that the stronger the magnetic force to which the developer is subjected, the faster the developer deteriorates; the developer is reduced in durability.
Further, in order to improve the developing apparatus 100 (image forming apparatus 200) in image quality, it is desired to reduce the distance T1 between the development sleeve 102 and development screw 104a as much as possible. That is, in order to prevent the problem that the amount by which developer is supplied from the development screw 104a to the development sleeve 102 becomes insufficient, it is desired that the distance T1 is made as small as possible.
Regarding this matter, if it is necessary to place a sealing sheet between the development sleeve 102 and development screw 104a, the distance T1 cannot be reduced as much as it can be if it is unnecessary to place a sealing sheet between the development sleeve 102 and development screw 104a. Further, it is possible that the development sleeve 102 may be damaged when the sealing sheet is peeled away.
<Effects of First Preferred Embodiment>
Referring to
Also in the first embodiment, in order to make it easier to roll up the sealing sheets 51a and 51b on the rotational take-up shaft 600, thin sheets (0.1 mm in thickness) of resin (which includes polyester) was used as the material for the sealing sheets 51a and 51b. This material is basically the same as that used as the material for the sealing sheet, disclosed in Japanese Laid-open Patent Application 2002-236413, which is to be manually peeled. Incidentally, the material and shape of the sealing sheet, and the timing with which the sealing sheet is to be peeled, do not need to be limited to those described above.
The amount of load to which the motor 53 is subjected to peel the sealing sheets 51a and 51b is likely to be higher at the beginning and end of the peeling. In this embodiment, therefore, even though the two sealing sheets are peeled together, the two sealing sheets 51a and 51b are made different in the peeling starting timing as well as the peeling ending timing. Thus, the point in time at which the amount of load to which the motor 53 is subjected peaks while the sealing sheet 51a is peeled does not coincide with the timing with which the sealing sheet 51b is peeled. Therefore, the developing apparatus 100 in this embodiment is significantly smaller than any of the developing apparatuses in accordance with the prior art, in terms of the maximum amount of load to which the motor 53 is subjected when the sealing sheets are peeled.
Further, in this embodiment, the points in time at which the amount of load to which the motor 53 is subjected peaks while the sealing sheets 51a and 51b are peeled are adjusted by making the doubled-back portion of the sealing sheet 51b longer than that of the sealing sheet 51a. However, the timing with which the peeling of the sealing sheet 51a begins or ends may be made different from the timing with which the peeling of the sealing sheet 51b begins or ends, by making the portion of the rotational take-up shaft 600, on which the sealing sheet 51a is rolled, different in diameter from the portion of the rotational take-up shaft 600, on which the sealing sheet 51b is rolled.
Further, if the amount of load to which the rotational take-up shaft 600 is subjected while the sealing sheets 51a and 51b are peeled exceeds a certain value, the rotational take-up shaft 600 is likely to be twisted in its rotational direction, in such a manner that the farther a given point of the rotational take-up shaft 600 is from the point of the driving force input, the later it is in the timing with which it begins to take up the sealing sheets.
In the first embodiment, therefore, the developing apparatus 100 is structured so that the point of connection between the gear 155 and rotational take-up shaft 600 is positioned in the adjacencies of the sealing sheet 51a, which is the first of the sealing sheets 51a and 51b that begins to be peeled. Therefore, it is ensured that even if the rotational take-up shaft 600 becomes twisted, the sealing sheet 51b always begins to be peeled after the sealing sheet 51a begins. Thus, it is ensured that even if the rotational take-up shaft 600 is low in rigidity, the sealing sheet 51b always begins to be peeled before the sealing sheet 51a begins. In other words, not only is the first embodiment applicable to a developing apparatus, the rotational take-up roller 600 of which is formed of a highly rigid material such as metal, but also, a developing apparatus, the rotational take-up roller 600 of which is made of a material, such as resin, which is relatively low in rigidity.
Also in the first embodiment, no sealing sheet is necessary between the development sleeve 102 and development screw 104a as mentioned in the description of the comparative developing apparatus. Thus, the distance T1 is only 2 mm, as shown in
Further, in this embodiment, the developer in the development chamber 101a is attracted to the development sleeve 102 by the magnetic force of the magnet 102m in the development sleeve 102. Thus, the magnet 102m may be reduced in magnetic force by reducing the distance T1.
Conventionally, when the distance T1 was 2.5 mm, the magnetic force of the pole of the magnet which attracts the developer in the development chamber 101a to the development sleeve 102 was 600 G. However, in this embodiment, the distance 51 is only 2 mm. Therefore, the toner attracting pole of the magnet 102m may be no more than 500 G. In other words, this embodiment makes it possible to minimize the amount of developer deterioration by reducing the effect of the magnetism upon the developer by reducing the magnet 102m in magnetic force.
As the developer in the developing apparatus in an image forming apparatus deteriorates, the image forming apparatus begins to output foggy images. In the first embodiment, therefore, the deterioration of developer is minimized by the employment of the magnet 102m, which is significantly weaker in magnetic force than any of the conventional magnets for developer attraction. Therefore, not only is the developing apparatus in this embodiment unlikely to allow toner to scatter, but also, it prevents an image forming apparatus from outputting foggy images, the fogginess of which is attributable to the developer deterioration. Therefore, it enables an image forming apparatus to output high quality images for a long period of time.
<Embodiment 2>
Referring to
Next, referring to
Therefore, in the case of the developing apparatus 100 in this embodiment, when it is started up for the very first time, the startup developer in the developing apparatus 100 is stirred, while being kept confined in the stirring chamber 101b, in order to charge the developer to a certain potential level. Then, after the developer has been charged to a desired potential level, the developer is supplied to the development chamber 101a. More specifically, the startup developer is increased in the amount Q/M of toner charge by circulating the developer in the stirring chamber 101b while stirring the developer by the stirring screw 104b and reverse conveyance screw 104c, with the openings 107a and 107b kept sealed by the sealing sheets 51a and 51b.
That is, in the development chamber 101a, which is an example of the first chamber, the developer can be conveyed by the development screw 104a, which is an example of the first developer conveyance screw, along the development sleeve 102, which is an example of a developer bearing member, whereas in the stirring chamber 101b which is an example of the second chamber and is in connection to the development chamber 101a, the developer can be conveyed by the stirring screw 104b, which is an example of the second developer conveyance screw, in the opposite direction from the direction in which the developer is conveyed in the development chamber 101a.
Further, the sealing sheet 51a which is an example of a sealing member, keeps sealed in an unsealable manner, the opening 107a, which is on the downstream end of the developing apparatus in terms of the developer conveyance direction of the second developer conveyance screw. The rotational take-up shaft 600, which is an example of a sealing member removing mechanism, exposes the opening 107a by removing the sealing sheet 51a.
Further, in the stirring chamber 101b, the reverse conveyance screw 104c, which is an example of a means for conveying the developer in the reverse direction, conveys the developer in the opposite direction from the direction in which the developer is conveyed by the second developer conveyance screw, while the opening 107a is kept sealed. Thus, the reverse conveyance screw 104c can circulate the developer in the stirring chamber 101b, while stirring the developer, in coordination with the stirring screw 104b.
As for the control portion 50 which is an example of a controlling means, it executes such a control that, first, the startup developer which has been kept confined in the stirring chamber 101b by keeping the opening 107a sealed with the sealing sheet 51a is circulated, while being stirred, by the stirring screw 104b and reverse conveyance screw 104c, and then, the opening 107a is exposed by the control of the rotational take-up roller 600 to circulate the developer through the development chamber 101a and stirring chamber 101b.
In other words, right after the developing apparatus 100 is started up for the very first time, the development chamber 101a remains empty, and therefore, no developer is borne on the development sleeve 102 no matter how many times the development sleeve 102 rotates. That is, until the sealing sheet 51a is peeled, the startup developer is continuously charged by being circulated in the stirring chamber 101b by the stirring screw 104b and reverse conveyance screw 104c along the stirring screw 104b and reverse conveyance screw 104c. Then, as soon as the opening 107a is unsealed, the fully charged developer in the stirring chamber 101b flows into the development chamber 101a. Then, as the body of the developer in the development chamber 101a becomes large enough for its top surface to reach the development sleeve 102, the developer is borne on the development sleeve 102. Therefore, even right after the completion of the startup operation of a brand-new developing apparatus, the amount Q/M of toner charge is at a proper level. Therefore, the problem that an image forming apparatus outputs low quality images, the low quality of which is attributable to the scattering of toner which occurs during the initial startup of a brand-new developing apparatus, contamination of the charge roller(s), and the like, is prevented.
<Embodiment 3>
Even though the present invention was described with reference to the developing apparatus which is removably mountable in an image forming apparatus, it is also applicable to a developing apparatus which is in the form of a process cartridge. With the application of the present invention to a developing apparatus in the form of a process cartridge, it is possible to realize a development cartridge which does not scatter toner, is maintenance-free, and is high in usability.
In the case of a developing apparatus in accordance with the present invention, the second chamber is provided with a developer conveying means which conveys the developer in the second chamber in the opposite direction from the direction in which the developer is conveyed by the second developer conveyance screw. Therefore, the developer in the second chamber is prevented from accumulating in the downstream end of the second chamber in terms of the developer conveyance direction of the second developer conveyance screw. Therefore, even if the second developer conveyance screw continues to rotate, the increase in the amount of the developer pressure in the downstream end portion of the second chamber in terms of the developer conveyance direction of the second developer conveyance screw remains relatively low. Therefore, the amount of torque necessary to drive the second developer conveyance screw does not excessively increase.
Therefore, the developing apparatus driving motor of an image forming apparatus is not overloaded while the sealing sheets of a developing apparatus shipped from a manufacturer, with the openings of its partitioning wall kept sealed with sealing sheets, are automatically removed by a rotational means for taking up the sealing sheets.
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. 115327/2010 filed May 19, 2010 which is hereby incorporated by reference.
Number | Date | Country | Kind |
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2010-115327 | May 2010 | JP | national |
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Entry |
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Notification of the First Office Action dated Jul. 20, 2012, in Chinese Application No. 201110130116.3. |
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Number | Date | Country | |
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20110286768 A1 | Nov 2011 | US |