The present application claims priority from Japanese patent application number 2010-170720, filed on Jul. 29, 2010, the entire contents of which are incorporated by reference herein.
1. Field of the Invention
The present invention relates to an image forming apparatus such as a copier, printer, facsimile machine, or the like, and in particular relates to an image forming apparatus using a developer and capable of optimally controlling toner concentration of the developer.
2. Description of the Related Art
In image forming apparatuses such as printers, copiers, or facsimile machines, a developing device as disclosed in JP-2008-299315-A is known.
Recently, for the purpose of saving energy, the apparatus is frequently turned off in a relatively short time after the image formation has been completed. In addition, developer should not be performed after the completion of image formation in order to prevent degradation of the developer inside a developing device. Therefore, the drive of the developing device is frequently stopped immediately after image formation. In such a case, however, if the time until the drive of the developing device is stopped is too short, there may be a case in which all toner replenishment operation by a toner replenishing device is not completed while the developing device is still being driven, thereby causing toner concentration fluctuation to occur. To prevent such a toner concentration fluctuation, it is preferred that the unreplenished portion of the toner replenishment amount excluding the already replenished amount be replenished at a time when the drive of the developing device is resumed.
When the power to the image forming apparatus is turned off until the drive of the developing device is resumed after it has been stopped, there is a disadvantage in that the information relating to the unreplenished portion of the toner replenishment amount is lost when the above information is not stored in a nonvolatile memory or the like. If the above information is lost, the unreplenished toner is not replenished after the drive of the developing device has been resumed, and the necessary amount of toner is not supplied to the developing device, thereby causing the toner concentration of the developer inside the developing device to be decreased.
Accordingly, the present invention provides a novel image forming apparatus capable of preventing the toner concentration inside the developing device from decreasing.
As an aspect of the present invention, an image forming apparatus includes a latent image carrier to carry a latent image thereon, an image data obtaining unit to obtain image information, a latent image forming unit to form a latent image on the latent image carrier based on the image information, a developing device to carry a developer including toner and a carrier on a developer carrier moving surface to convey it toward a developing area in which the developer carrier and the latent image carrier faces, and deposit the toner of the developer onto the latent image carried on the latent image carrier in the developing area to thereby develop the latent image, a toner replenishing device to replenish toner to the developing device, and a control unit to control a toner replenishment amount by controlling a drive of the toner replenishing device based on the image information. In such an image forming apparatus, when the drive of the developing device is stopped, information relating to the unreplenished toner replenishment amount subtracting the already-replenished toner amount among the image information-based toner replenishment amount is stored in a nonvolatile memory, and the toner replenishing device is so controlled as to be driven based on the information relating to the unreplenished toner replenishment amount when the drive of the developing unit is resumed.
These and other objects, features, and advantages of the present invention will become apparent upon consideration of the following description of the preferred embodiments of the present invention when taken in conjunction with the accompanying drawings.
Preferred embodiments of the present invention applied to an electrophotographic printer as an image forming apparatus will now be described with reference to drawings.
A description will now be given of a basic structure of the printer according to a first embodiment, with initial reference to
As illustrated in
The first conveyance screw 8Y rotates driven by a drive means, not shown, and conveys Y-developer inside the first developer container 9Y toward a front side in
The second conveyance screw 11Y inside the second developer container 14Y is driven to rotate by the drive means, not shown, thereby conveying the Y-developer to a depth side in
The developing roller 12Y includes a developing sleeve 15Y, formed of non-magnetic materials and rotating in the counterclockwise direction in
The Y-developer from which Y-toner is consumed by the developing operation returns on the second conveyance screw 11Y by a rotation of the developing sleeve 15Y, is conveyed to the edge portion of the second developer container 14Y by the second conveyance screw 11Y, and returns to the first developer container 9Y via the through opening 19Y. The Y-developer is thus circulated inside the developing device.
As illustrated in
As illustrated in
While a polygon mirror 21 rotatably driven by a motor is deflecting the laser light L emitted from the light source, the optical writing unit 20 radiates the laser light L onto the photoreceptors 3Y, 3C, 3M, and 3K, via a plurality of optical lenses and mirrors . The optical writing unit 20 may also employ an LED array instead of the above structure.
A first sheet feed cassette 31 and a second sheet feed cassette 32 are disposed vertically in a stacked manner. Each sheet feed cassette includes a plurality of stacked recording sheets P in a state of sheet bundle. Both a first sheet feed roller 31a and a second sheet feed roller 32a contact an uppermost recording sheet P.
When a first sheet feed roller 31a rotates counterclockwise driven by a drive means, not shown, the uppermost recording sheet P in the first sheet feed cassette 31 is conveyed toward a sheet feed pathway 33 extending vertically from the first cassette 31 as illustrated on the right in
The sheet feed pathway 33 includes a plurality of pairs of conveyance rollers 34. The recording sheet P inserted into this sheet feed pathway 33 is sandwiched by these plurality of pairs of conveyance rollers 34 and is conveyed from a bottom side to upper as illustrated in
A transfer unit 40 is disposed above the process units 1Y, 1C, 1M, and 1K and moves the intermediate transfer belt 41 while stretching it endlessly. The transfer unit 40 includes, in addition to the intermediate transfer belt 41, a belt cleaning unit, a first bracket, a second bracket, four primary transfer rollers 45Y, 45C, 45M, and 45K, a secondary transfer backup roller 46, a drive roller 47, an auxiliary roller, a tension roller 49, and the like. The intermediate transfer belt 41 is stretched over these rollers and moves endlessly by the rotational driving of the drive roller 47.
Each of the four primary transfer rollers 45Y, 45C, 45M, and 45K sandwiches the thus endlessly moving intermediate transfer belt 41, together with the photoreceptors 3Y, 3C, 3M, and 3K, thereby forming a primary transfer nip respectively. A transfer bias (of positive polarity in the present embodiment) having a polarity opposite that of the toner is applied to the inner surface of the intermediate transfer belt 41. While the intermediate transfer belt 41 sequentially passing through the primary transfer nips for Y-color, C-color, M-color, and K-color according to the endless movement, color toner images on the photoreceptors 3Y, 3C, 3M, and 3K are primarily transferred in a superimposed manner onto the outer surface of the intermediate transfer belt 41 to form a 4-color toner image.
The secondary transfer backup roller 46 sandwiches the intermediate transfer belt 41 together with a secondary transfer roller 50 disposed outside the loop of the intermediate transfer belt 41, thereby forming a secondary transfer nip. The previously explained pair of registration rollers 35 sends the recording sheet P sandwiched between rollers to the secondary transfer nip at timing synchronous with the 4-color toner image on the intermediate transfer belt 41.
The 4-color toner image on the intermediate transfer belt 41 is secondarily transferred to the recording sheet P en bloc at the secondary transfer nip by effects of secondary transfer electric field and nip pressure generated between the secondary transfer roller 50 to which secondary transfer bias is applied and the secondary transfer backup roller 46. With the effect of background white color of the recording sheet P, a full-color toner image is formed.
The intermediate transfer belt 41 upon passing through the secondary transfer nip is attached with residual toner after transfer that has not used for the transfer to the recording sheet P. The belt cleaning unit comes into contact with the upper surface of the intermediate transfer belt 41 and scrapes off the residual toner remaining on the intermediate transfer belt 41, thereby removing the residual toner.
The first bracket of the transfer unit 40 is configured to swing about a rotation shaft of the auxiliary roller at a predetermined angle according to the drive of a solenoid, not shown.
In the printer according to the present embodiment, the first bracket is slightly rotated counterclockwise by the drive of the solenoid when forming a monochrome image. Due to this slight rotation, the primary transfer rollers 45Y, 45C, and 45M for Y-color, C-color, and M-color are rotated counterclockwise about a rotation shaft of the auxiliary roller, thereby separating the intermediate transfer belt 41 from the photoreceptors 3Y, 3C, and 3M for Y-color, C-color, and M-color. Then, only the process unit 1K for K-color is rotated among the four process units 1Y, 1C, 1M, and 1K, thereby forming a monochrome image. With this construction, depletion of those process units caused by driving other process units 1Y, 1C, and 1M in the monochrome image formation can be prevented.
A fixing unit 60 serving as a fixing means is disposed above the secondary transfer nip in
A temperature sensor, not shown, is disposed at an outer side of the loop of the fixing belt 64 and facing the outer surface of the fixing belt 64 over a predetermined gap. The temperature sensor detects a surface temperature of the fixing belt 64 immediately before the belt 64 enters the fixing nip, and the temperature reading thus obtained is sent to a fixing power supply circuit, not shown. The fixing power supply circuit controls the built-in heat source included in the heat roller 63 and of the built-in heat source included in the press-heat roller 61. With this configuration, the surface temperature of the fixing belt 64 is maintained at approximately 140° C. The recording sheet P, which has passed through the secondary transfer nip, is separated from the intermediate transfer belt 41 and sent into the fixing unit 60. While being conveyed from the lower side to upper being sandwiched between rollers at the fixing nip inside the fixing unit 60, the recoding sheet is heated and pressed by the fixing belt 64 and the full-color toner image is fixed onto the recording sheet P.
The recording sheet P to which the fixing process is applied is discharged outside the printer after passing between rollers of a pair of sheet discharge rollers 67. A stack section 68 is disposed on an upper surface of the printer body. The recording sheet P discharged outside the printer body by the pair of sheet discharge rollers 67 is sequentially stacked on this stack section 68.
Toner bottles 72Y, 72C, 72M, and 72K each are a toner container to include therein each toner of Y-toner, C-toner, M-toner, and K-toner, and disposed above the transfer unit 40. Each color toner inside the toner bottles 72Y, 72C, 72M, and 72K is supplied appropriately to the corresponding developing devices 7Y, 7C, 7M, and 7K of the process units 1Y, 1C, 1M, and 1K. These toner bottles 72Y, 72C, 72M, and 72K are detachably attached to the printer body independently from the process units 1Y, 10, 1M, and 1K.
Each holder portion of the toner bottles 72Y, 72C, 72M, and 72K set on the bottle placement rack 95 engages with the bottle drive section 96. When the toner bottle 72K being engaged with the bottle drive section 96 is moved slidably on the bottle placement rack 95 toward a direction separating from the bottle drive section 96 as illustrated by arrow X1 in
In addition, in a state in which the toner bottle 72K of the toner replenishing device 70 is not attached, when the toner bottle 72K is moved slidably on the bottle placement rack 95 in a direction approaching the bottle drive section 96 as illustrated by arrow X2 in
The other toner bottles 72Y, 72C, and 72M for other toner colors maybe attached to and detached from the toner replenishing device by a similar operation as above.
A gear, not shown, is formed to an outer periphery of each of the bottle portions 73Y, 73C, 73M, and 73K of the toner bottles 72Y, 72C, 72M, and 72K. Each of the gears is covered by the holder portions 74Y, 74C, 74M, and 74K, but is partly exposed from a notch formed on the outer periphery of the holder portions 74Y, 74C, 74M, and 74K.
The bottle drive section 96 includes bottle drive gears, not shown, for Y- , C- , M- , and K-toner bottles . When the holder portions 74Y, 74C, 74M, and 74K of the toner bottles 72Y, 72C, 72M, and 72K are engaged with the bottle drive section 96, the bottle drive gears for Y, C, M, and K respectively engage with the gears of the bottle portions 73Y, 73C, 73M, and 73K, via the notch. Due to the rotation of the bottle drive gears for Y, C, M, and K of the bottle drive section 96, driven by a drive system, not shown, the bottle portions 73Y, 73C, 73M, and 73K are driven to rotate on the holder portions 74Y, 74C, 74M, and 74K.
As illustrated in
The holder portion 74Y of the toner bottle engages with a hopper 76Y of the toner replenishing device 70. This hopper 76Y has a flat shape in the direction perpendicular to the cross section in
The Y-toner sent from the bottle portion of the toner bottle to the holder portion 74Y falls into the hopper 76Y due to its weight. In the hopper 76Y, a flexible pressing film 78Y fixed to a rotational axis member 77Y rotates together with the rotational axis member 77T. A toner detection sensor 82, formed of piezoelectric elements, to detect toner amount inside the hopper 76Y is fixed on an inner surface of the hopper 76Y.
The pressing film 78Y formed of polyethylene terephthalate (PET) film and the like presses the Y-toner toward a detection surface of the toner detection sensor 82. Accordingly, the toner detection sensor 82 can detect a state of toner inside the hopper 76Y appropriately. The rotation of the bottle portion of the toner bottle is controlled so that the toner detection sensor 82 can appropriately detect the Y-toner. As far as a sufficient amount of toner exists in the bottle, a sufficient amount of Y-toner falls into the hopper 76Y via the holder portion 74Y from the bottle portion, and the hopper 76Y is filled with a plenty of toner. When the state changes from this state to another state in which the toner detection sensor 82 cannot detect the Y-toner even though the bottle portion is rotated frequently, a controller, not shown, determines that the Y-toner in the bottle is short and sends a user a warning of “toner near end.”
A lateral conveyance tube 79Y is disposed below the hopper 76Y and connected with the hopper 76Y. The Y-toner inside the hopper 76Y slides down along the tapered surface under its own weight and falls into the lateral conveyance tube 79Y. A toner replenishing screw 80Y is disposed in the interior of the lateral conveyance tube 79Y and conveys the Y-toner along a longitudinal direction of the lateral conveyance tube 79Y.
A drop guide tube 81Y connected to an edge portion of the lateral conveyance tube 79Y in the longitudinal direction, extends in the vertical direction. A bottom end of the drop guide tube 81Y connects a toner replenishing port 17Y of a first developer container 9Y of a developing device 7Y. When the toner replenishing screw 80Y in the lateral conveyance tube 79Y rotates, the Y-toner which has been conveyed up to the edge portion of the lateral conveyance tube 79Y in the longitudinal direction falls in the first developer container 9Y of the developing device 7Y via the drop guide tube 81Y and the toner replenishing port 17Y. Accordingly, the Y-toner is replenished in the first developer container 9Y. Other colors of toner (C, M, and K) are also replenished in the similar manner.
In the structure to replenish toner by the rotation driving of the toner replenishing screw 80Y, the replenishing resolution is not so high.
In the printer according to the present embodiment, a lower limit B is set to the driving period of the toner replenishing device 70, and driving of the toner replenishing device 70 is controlled to secure the driving period of the lower limit B or more. With such replenishment, the fluctuation in the replenished amount in each replenishing operation can be suppressed.
Further, in the printer according to the present embodiment, the driving speed of the toner replenishing device 70 is constant regardless of the necessary replenishing amount per unit time. The replenishing amount per unit time is adjusted by the frequency of driving. During the period when the necessary replenishing amount per unit time is comparably large, the frequency of the driving is high. By contrast, during the period when the necessary replenishing amount per unit time is comparably small, the frequency of the driving is low.
When images with high image coverage ratio are continuously output under the above control, as illustrated in an upper column in
To solve the above problem, the printer according to the present embodiment provides an upper limit E to the driving time of the replenishing operation as illustrated in a lower column in
Herein, a toner replenishing control in the conventional image forming apparatus will now be described.
Here, the toner replenishment amount fluctuation pattern is a pattern capable of implementing replenishment according to a correct opposite phase waveform if the toner replenishing device 70 operates as indicated by the pattern. However, considering the mechanical limitations of the toner replenishing device 70, a final driving control pattern is generated.
As one example of the mechanical restrictions,
Alternatively, the pseudo-impulse signal indicates a toner replenishment amount corresponding to the toner consumption as a result of printing operation obtained from the image information. By passing the pseudo-impulse signal through the ANC filter 110 to generate a toner replenishment amount fluctuation pattern, the toner replenishment is performed in a distributed manner. Accordingly, as illustrated in
A case in which image information is contained in one sheet only to be printed-out was described above. In a case in which a plurality of prints are consecutively performed, the pseudo-impulse signals each depending on the image information are sequentially inserted into the ANC filter 110 as illustrated in
A case in which power on/off signal is received when the printing is interrupted will now be described. As illustrated in
In this case, when all information of the ANC filter 110 (that is, all information relating to the toner replenishment amount fluctuation pattern) is stored in the memory, a number of memories are required.
[ANC Filter Internal Operation]
Va(k)=−[Aa1*Va(k−1)+Aa2*Va(k−2)+Aa3*Va(k−3)+Aa4*Va(k−4)<−Output
+[Ba1*Xa(k−1)+Ba2*Xa(k−2)+Ba3*Xa(k−3)+Ba4*Xa(k−4)<−Input
Aa1 to Aa4: Output Factor
Ba1 to Ba4: Input Factor
In addition, in a case in which the driving control pattern is previously generated from the toner replenishment amount fluctuation pattern, as indicated by pattern C in
By contrast, according to the present embodiment, a toner replenishment amount is obtained by arithmetic operation in accordance with the non-converted component/portion of the toner replenishment amount fluctuation pattern, which is a difference between the pseudo-impulse signal input to the ANC filter 110 and the output from the ANC filter 110, and is stored in the nonvolatile memory 103. It is to be noted that although eight memories are required in the conventional operation as illustrated in
When resuming the printing operation, the toner replenishment amount corresponding to the non-converted component/portion stored in the nonvolatile memory 103 is again input to the ANC filter 110 as a pseudo-impulse signal as illustrated in
It is to be noted that the ANC filter 110 used herein is not limited to any particular type of filter, such as IIR filters or FIR filters, nor to any particular difference in order or filter length. Moreover, any other method using a table may also be used to obtain the same effect as that of the ANC filter 110 described above.
In the second example, when stopping the drive of the developing device 7, the unused portion of the drive control pattern is calculated and stored in the nonvolatile memory 103. The stored value is used and input for the toner replenishment amount fluctuation pattern when the driving of the development device 7 is resumed. Specifically, when the printing is interrupted, as illustrated in
As illustrated in
The toner replenishment amount is calculated upon receiving image information and the calculated toner replenishment amount is stored in the nonvolatile memory 103. Thus, even when the power to the printer is turned of f at any arbitrary timing, the toner replenishment amount corresponding to the image information is stored in the memory. However, when calculating the toner replenishment amount fluctuation pattern using the ANC filter 110, normally, the calculation is performed at a sampling cycle shorter than the time to print a single sheet. If the data is stored in the nonvolatile memory 103 at such a short cycle, the writing number exceeds the maximum rewritable number of the nonvolatile memory 103, to thus shorten its lifetime.
In addition, even though storing the data into the memory is performed each time when a sheet is printed out, as shown by B1 to B4 in
By contrast, because the user does not normally turn off the power during the printing operation, it is enough to store the data in the nonvolatile memory 103 twice at A1 and A2 as illustrated in
Then, in the third example, the data relating to the toner replenishment amount and the like is stored in the nonvolatile memory 103 when the power is turned off at a time of completion of printing. With this structure, the frequency to write data into the nonvolatile memory 103 is reduced, a plurality of nonvolatile memories need not provided to secure the total number of writing operation, thereby suppressing the cost increase.
As illustrated in
However, certain users keen about the energy saving, may manually turns off the apparatus immediately after the print end without waiting for the normal power off between the period from the print end (at point C) to the power off (at point A). In this case, because there is a time lag between the print end (at point C) and the power off (at point A) as described above, if storing data into the nonvolatile memory 103 is performed at an automatic power-of f timing, the toner replenishment amount data temporarily stored in the volatile memory 102 is lost when the power is manually turned off by the user in the period B. Then, when the power is turned on again, the unused toner replenishment amount data is not obtained and the replenishment of toner corresponding to the image area cannot be performed continuously.
Then, in the present embodiment, by storing the data of the unimplemented toner replenishment amount in the nonvolatile memory 103 immediately after the print end or job end, the data of the unimplemented toner replenishment amount may be stored before the abrupt manual turnoff by the user.
In the aforementioned embodiments, when the toner replenishment amount corresponding to the non-converted portion stored in the nonvolatile memory 103 is input again in the ANC filter 110 as a pseudo-impulse signal when resuming the print operation, the toner replenishment amount fluctuation pattern from the initial stage is created. Thus, even though the total sum of the toner replenishment amount is maintained, the continuity from the previous replenishment result is lost.
For example, a desired toner replenishment amount fluctuation pattern when the replenishment is resumed in the continued manner is as in pattern B of the toner replenishment amount fluctuation pattern <A> as illustrated in
Then, in the fifth embodiment, to maintain the continuity of the toner replenishment amount fluctuation pattern before and after the replenishment drive operation, the toner replenishment amount corresponding to the non-converted portion stored in the nonvolatile memory 103 is input , as a pseudo- impulse signal, to an ANC filer 110B configured to have a filter shape as illustrated in
In the image forming apparatus such as a printer or a copier according to the sixth example of the present invention, printing speed or linear speed may be changed depending on the sheet type or sheet thickness, and the like. In this case, the number of rotations of the screws inside the developing device 7 is also changed to thus change the developer conveyance speed. For example, assume that the linear speed for a standard thickness of sheet is a standard speed as indicated by (a) in
Then, in the present example, a plurality of filters is provided to cope with a plurality of linear speeds. When the linear speed has changed, a portion of the replenishment amount not converted into the toner replenishment amount fluctuation pattern from the previous print information is input to the ANC filer 110 corresponding to the linear speed upon the linear speed change. With this structure, toner replenishment using an appropriate toner replenishment amount fluctuation pattern relative to the linear speed may be performed.
As illustrated in
Hereinafter, a description will now be given of an electrophotographic printer as one of image forming apparatuses according to a second embodiment. The basic structure of the image forming apparatus is identical to that of the image forming apparatus according to the first embodiment, and the description thereof will be omitted.
In the image forming apparatus according to the first embodiment, to cope with the problem that the toner concentration inside the developing device 7 decreases due to the lack of memory information occurring at the time of power of f when the necessary toner amount is not replenished to the developing device 7, the necessary toner amount is stored in a reduced number of memories as unimplemented toner replenishment amount being a difference between before and after the generation of the toner replenishment amount fluctuation pattern or between before and after the generation of the drive pattern, so that the necessary toner replenishment amount may be replenished in accordance with the image information.
However, because the section to calculate the unimplemented toner replenishment amount or the section to additionally input the unimplemented toner replenishment amount stored in the nonvolatile memory is limited and is not suitable for the general purposes. There arises a problem when the unimplemented toner replenishment amount cannot be input due to the system configuration and needs to be input in the distributed manner.
To cope with the above problem, the image forming apparatus according to the second embodiment in which toner replenishment of an inverse phase to offset the toner concentration fluctuation is performed using the image information, is configured such that: unimplemented toner amount is obtained both in a section to generate a necessary toner replenishment amount and its timing and in a section to actually perform toner replenishment; the obtained unimplemented toner replenishment amount is stored in the nonvolatile memory 103 when the power is off; and the stored unimplemented toner replenishment amount is additionally input either or both of the section to generate a necessary toner replenishment amount and its timing and the section to actually perform toner replenishment, thereby satisfying the target toner concentration with high precision and low cost.
A case in which the power is turned on or off while the printing operation is being interrupted will now be described with reference to
However, there is a possibility that the power is turned on or off at the same time when the drive control pattern C2 obtained by the toner replenishment amount fluctuation pattern B2 has been calculated. In such a case, the calculation result of the drive control pattern C2 may be stored in the nonvolatile memory 103. However, how the content stored in the nonvolatile memory 103 is reflected to the operation may affect the final image quality.
To cope with the above problem, in the present example, the difference value between the pseudo-impulse signal being an input to the ANC filter 110 and an output from the ANC filter 110, that is, a non-converted value from the image information to the toner replenishment amount fluctuation pattern is stored in the nonvolatile memory 103 when the power is turned off, and the stored difference value between the input to and output from the ANC filter 110 is caused to be reflected to the drive control pattern when the power is turned on.
It is noted that any content maybe stored in the nonvolatile memory 103 as far as it can be read out when the power is turned on or off, and the content can be read out in various ways and timings such that the nonvolatile memory 103 constantly continues calculation operation, even when the image output has been completed, or after the power-off command has been received.
As illustrated in
Accordingly, the information relating to the short portion of the toner replenishment amount not reflected in the toner replenishment, among the toner replenishment amount required from the image information, is stored in the nonvolatile memory 103, thereby suppressing the memory area and finally enabling high quality image formation with low cost.
In the present example, a toner replenishment amount corresponding to an unused portion of the drive control pattern is stored in the nonvolatile memory when the power is turned off, and the stored toner replenishment amount corresponding to the unused portion of the drive control pattern is reflected to the drive control pattern when the power is turned on.
It is noted that the content stored in the nonvolatile memory 103 may only be read out when the power is turned on or off and can be read out in various ways and timings such as, even when the data is constantly calculated in the nonvolatile memory 113, when the image output has been completed, after the power off command has been received.
In the eighth example, the drive control pattern generated in the replenishment drive pattern generation circuit 111 and the difference value between the input to and the output from the replenishment drive pattern generation circuit ill stored in the nonvolatile memory 103 are subjected to addition and subtraction operation to perform the replenishment drive operation. In this case, the addition and subtraction operation of the drive control pattern generated in the replenishment drive pattern generation circuit 111 and the difference value between the input to and the output from the replenishment drive pattern generation circuit 111 (that is, the unused portion of the drive control pattern) may preferably be performed during the power-on period by reading out the data from the nonvolatile memory 103. For simplifying purposes, the series of operations are described in one block as illustrated in
In the ninth example according to the present embodiment, a toner replenishment amount corresponding to the non-converted portion of the toner replenishment amount fluctuation pattern from the image information and a toner replenishment amount corresponding to the unused portion of the drive control pattern are stored in the nonvolatile memory 103 during the power-off period. Then, a toner replenishment amount corresponding to the stored non-converted portion of the tonner replenishment amount fluctuation pattern and a toner replenishment amount corresponding to the unused portion of the drive control pattern are reflected to the drive control pattern during the power-on period.
It is noted that the content stored in the nonvolatile memory 103 may only be read out when the power is turned on or off and can be read out in various ways and timings such as, even when the data is constantly calculated in the nonvolatile memory 113, when the image output has been completed, after the power off command has been received.
The output from the ANC filter 110 is input to the replenishment drive pattern generation circuit 111 to form a drive control pattern. Then, a difference value between the replenishment drive pattern generated based on the input from the ANC filer 110 to the replenishment drive pattern generation circuit 111, and the drive control pattern divided and output from the replenishment drive pattern generation circuit 111, that is, the difference value between the input to and the output from the replenishment drive pattern generation circuit 111 or the unused portion of the drive control pattern is calculated and is stored in the nonvolatile memory 103.
It is noted that the content stored in the nonvolatile memory 103 may only be read out when the power is turned on or off and can be read out in various ways and timings such as, even when the data is constantly calculated in the nonvolatile memory 113, when the image output has been completed, after the power off command has been received.
Successively, the difference value between the input to and the output from the ANC filter or the non-converted portion of the toner replenishment amount fluctuation pattern, and the difference value between the input to and the output from the replenishment drive pattern generation circuit or the unused portion of the drive control pattern are added together. As a result of addition operation, the non-driven toner replenishment amount is stored in the nonvolatile memory 103. Here, because the type of the signal of the ANC filer input and output difference value and that of the replenishment drive pattern generation circuit input and output difference value is different from each other, the conversion or signal conversion is preformed in the addition operation and storing operation. Specifically, when the difference value between the input to and the output from the ANC filter or the non-converted portion of the toner replenishment amount fluctuation pattern, and the difference value between the input to and the output from the replenishment drive pattern generation circuit or the unused portion of the drive control pattern are subjected to addition operation or stored in the nonvolatile memory 103, signal conversion is performed to unify the both types of signals.
It is noted that the content stored in the nonvolatile memory 103 may only be read out when the power is turned on or off and can be read out in various ways and timings such as, even when the data is constantly calculated in the nonvolatile memory 113, when the image output has been completed, after the power off command has been received.
In the present example 9, the toner replenishment amount of the drive control pattern generated in the replenishment drive pattern generation circuit 111 and the toner replenishment amount of the non-driven portion stored in the nonvolatile memory 103 are subjected to addition and subtraction operation to perform replenishment drive operation of the toner replenishing device. In this case, the addition/subtraction operation between the toner replenishment amount of the drive control pattern generated in the replenishment drive pattern generation circuit 111 and the toner replenishment amount of the non-driven portion may only be performed during the power-on period by retrieving the stored data from the nonvolatile memory 103. For simplifying purposes, the series of operations are described in one block as illustrated in
In the present tenth example, the toner replenishment amount corresponding to the non-converted portion from the image information to the toner replenishment amount fluctuation pattern and the toner replenishment amount corresponding to the unused portion of the drive control pattern are stored in the nonvolatile memory 103 during the power-off period, and the toner replenishment amount corresponding to the stored non-converted portion and the toner replenishment amount corresponding to the unused portion are respectively reflected to the toner replenishment amount fluctuation pattern and the drive control pattern during the power-on period.
It is noted that the content stored in the nonvolatile memory 103 may only be read out when the power is turned on or off and can be read out in various ways and timings such as, even when the data is constantly calculated in the nonvolatile memory 113, when the image output has been completed, after the power off command has been received.
The output from the ANC filter 110 is input to the replenishment drive pattern generation circuit 111, thereby forming a drive control pattern. Then, a difference value between the replenishment drive pattern generated based on the input from the ANC filter 110 to the replenishment drive pattern generation circuit 111 and the drive control pattern divided and output from the replenishment drive pattern generation circuit 111, that is, an used portion of the drive control pattern, is calculated and is stored in the nonvolatile memory 103.
It is noted that the content stored in the nonvolatile memory 103 may only be read out when the power is turned on or off and can be read out in various ways and timings such as, even when the data is constantly calculated in the nonvolatile memory 113, when the image output has been completed, after the power off command has been received.
The difference value between the input to and the output from the ANC filter 110 or the non-converted portion of the toner replenishment amount fluctuation pattern, and the difference value between the input to and the output from the replenishment drive pattern generation circuit 111 or the unused portion of the drive control pattern are added. After the addition, data to be reflected to the toner replenishment fluctuation pattern, data to be reflected to the drive control pattern, and data to be reflected to both the toner replenishment fluctuation pattern and the drive control pattern are separately stored in the nonvolatile memory 103. (Specifically, data are separately stored as a non-converted portion or an unused portion, or as a non-converted portion plus an unused portion.)
When calculating variables to store in the nonvolatile memory 103, the ANC filter input and output difference value (that is, the non-converted portion of the toner replenishment amount fluctuation pattern) may be applied directly to data to be reflected to the toner replenishment amount fluctuation pattern, and the replenishment drive pattern generation circuit input and output difference value (that is, the unused portion of the drive control pattern) may be applied directly to data to be reflected to the drive control pattern. Alternatively, after having added the ANC filter input and output difference value (that is, the non-converted portion of the toner replenishment amount fluctuation pattern) and the replenishment drive pattern generation circuit input and output difference value (that is, the unused portion of the drive control pattern), the added data may be applied to the data to be reflected to the toner replenishment amount fluctuation pattern and to the data to be reflected to the drive control pattern. In addition, because the type of the signal of the ANC filer input and output difference value and that of the replenishment drive pattern input and output difference value may be signal-converted at timings of performing addition operation or storing operation to the nonvolatile memory 103, to thus match with the type of signals of the ANC filter input and output difference value (that is, the non-converted portion of the toner replenishment amount fluctuation pattern) and the replenishment drive pattern generation circuit input and output difference value (that is, the unused portion of the drive control pattern).
It is noted that any content maybe stored in the nonvolatile memory 103 as far as it can be read out when the power is turned on or off, and the content can be read out in various ways and timings such that the nonvolatile memory 103 constantly continues calculation operation, even when the image output has been completed, or after the power-off command has been received.
Thereafter, the drive control pattern generated in the drive control pattern generation circuit 111 and the unused portion stored in the nonvolatile memory 103 are subjected to the addition and subtraction operation, thereby driving the replenishment operation. In this case, it is preferred that the addition and subtraction of the drive control pattern generated in the replenishment drive pattern generation circuit 111 and the unused portion be performed by being read out from the nonvolatile memory 103 when the power is turned on. In addition, to simplify, the series of operations are illustrated in
In the examples 7 to 10 according to the second embodiment, the contents or values to be stored in the nonvolatile memory 103 are not limited to the type of signals to be used in the post-processing such as the non-converted portion of the toner replenishment amount fluctuation pattern or the unused portion of the drive control pattern.
Additional modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that, within the scope of the appended claims, the invention may be practiced other than as specifically described herein.
Number | Date | Country | Kind |
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2010-170720 | Jul 2010 | JP | national |