Patent Application
20120008969
Embodiments described herein relate generally to an image forming apparatus and a toner charge amount adjustment method of the image forming apparatus.
In an electrophotographic process, to keep a developer charge amount constant is very importance in order to keep high print quality. However, when images having a high printing ratio are continuously printed, a toner corresponding to the amount of toner consumed by development is supplied from a cartridge in order to keep toner density in the developer constant. At this time, since a large amount of toner is supplied, a chance of contact with carrier is reduced. Consequently, a sufficient toner charge amount is not obtained, and there arises a problem such as white background fogging or deterioration in gradation reproducibility due to excessive development.
On the other hand, there is an idea to increase the chance of contact between toner and carrier by raising the rotation speed of a developer mixer. However, when the rotation speed of the developer mixer is excessively increased, the deterioration of the toner progresses. Thus, the agitation of the developer is required to be performed at a minimum necessary mixer rotation intensity and in a short time.
In general, according to one embodiment, an image forming apparatus includes a developer containing part, a developer mixer, a mixer drive motor, a magnetic sleeve, a sleeve drive motor, a mixer rotation speed determination part and a motor drive controller.
The developer containing part contains a two-component developer including a toner and a carrier. The developer mixer is provided in the developer containing part, agitates the two-component developer, and charges the toner and the carrier. The mixer drive motor drives the developer mixer.
The magnetic sleeve is provided in the developer containing part, and supplies the charged toner to an oppositely arranged photoreceptor. The sleeve drive motor drives the magnetic sleeve. The mixer rotation speed determination part determines the mixer rotation speed of the mixer drive motor according to a supply amount of the toner supplied to the developer containing part from a toner cartridge by driving of a toner supply motor. The motor drive controller independently performs rotation control of the sleeve drive motor and the mixer drive motor, and rotates and controls the mixer drive motor at the mixer rotation speed determined by the mixer rotation speed determination part.
An auto document feeder (ADF) 7 is provided at an upper side of the image forming apparatus 100. When the document is sheet-like, after the reading of the image information in the image reading part 5 is ended, the auto document feeder 7 discharges the document subjected to the reading to a discharge position from a read position, and guides a next document to the read position. Besides, the image forming apparatus 100 is provided with an instruction input part for instructing start of image formation in the image forming part 1 and start of reading the image information of the document by the image reading part 5, that is, a display part 8, as a control panel.
Next, a structure of the image forming part 1 will be described. Toner cartridges 10a to 10d are provided at the upper side of the image forming part 1. The toner cartridges 10a to 10d are detachable from and attachable to a toner cartridge holding mechanism 10 provided at the front side of the image forming part 1. The toner cartridges 10a to 10d respectively contain toners of yellow (Y), magenta (M), cyan (C) and black (K), and sequentially supply the toners to after-mentioned developing devices 14a to 14d.
The image forming part 1 includes photoconductive drums 11a to 11d as image carriers to carry latent images, an exposure device 12 that includes LEDs 12a to 12d and forms the latent images by irradiating laser beams modulated according to writing image data to the photoconductive drums 11a to 11d, charging devices 13a to 13d to uniformly charge the photoconductive drums 11a to 11d, the developing devices 14a to 14d to develop the latent images formed on the photoconductive drums 11a to 11d, an intermediate transfer belt 15 to hold developer images developed on the photoconductive drums 11a to 11d in a stacked state, and cleaners 16a to 16d to remove adhered substances such as residual toner on the photoconductive drums 11a to 11d.
Further, the image forming part 1 includes a transfer device 17 to transfer the developer images stacked on the intermediate transfer belt 15 to a sheet-like output medium such as standard paper which is not subjected to special processing or an OHP sheet as a transparent resin sheet, and a fixing device 18 to fix the developer images transferred on the intermediate transfer belt 15 to the output medium.
The intermediate transfer belt 15 is stretched by a drive roller 15a to rotate the intermediate transfer belt 15, a backup roller 15b for secondary transfer, and a tension roller 15c to cause tensile force applied to the intermediate transfer belt 15 to be constant. Besides, a belt cleaner 15d is arranged to contact the intermediate transfer belt 15 at a position opposite to the drive roller 15a across the intermediate transfer belt 15.
Primary transfer rollers 17a to 17d are arranged to come in press contact with the photoconductive drums 11a to 11d through the intermediate transfer belt 15 on the rear side of the intermediate transfer belt 15a and at places (hereinafter referred to as “primary transfer parts”) where the intermediate transfer belt 15 contacts the photoconductive drums 11a to 11d.
The transfer device 17 (hereinafter referred to as a “secondary transfer part”) is opposite to the backup roller 15b arranged on the rear side (inner side) of the intermediate transfer belt 15, and is arranged to contact the intermediate transfer belt 15 at the toner carrying surface side (outer side) of the intermediate transfer belt 15.
The respective photoconductive drums 11a to 11d hold electrostatic latent images (toner images) of colors to be visualized (developed) by the developing devices 14a to 14d containing toners of arbitrary colors of yellow (Y), magenta (M), cyan (C) and black (K). The order of arrangement thereof is regulated in a specified order according to an image forming process and toner characteristics. The intermediate transfer belt 15 holds the toner images of the respective colors formed by the photoconductive drums 11a to 11d and the corresponding developing devices 14a to 14d in the order of formation.
Besides, in order to detect the reflected light amount of a toner pattern formed on the intermediate transfer belt 15, an LED light source 20a and an optical sensor 20b are arranged between the fourth station of the primary transfer part and the secondary transfer part.
When the transfer device 17 transfers the developer image, the sheet supply part 3 supplies an output medium at a specified timing to the transfer device 17. Cassettes set in plural cassette slots 31 contain output media of arbitrary sizes. A pickup roller 32 takes out an output medium according to the operation of image formation. The size of the output medium corresponds to the size of the developer image formed by the image forming part 1. A separation mechanism 33 prevents two or more output media from being taken out from the cassette by the pickup roller 32. Plural conveyance rollers 34 convey the one output medium separated by the separation mechanism 33 to an aligning roller 35. The aligning roller 35 sends the output medium to the transfer position where the transfer device 17 contacts the intermediate transfer belt 15 in synchronization with the timing when the transfer device 17 transfers the developer image from the intermediate transfer belt 15. Incidentally, plural cassette slots 31, plural pickup rollers 32 and plural separation mechanisms 33 may be prepared when necessary, and the cassette can be arbitrarily mounted to a different slot.
The output medium on which the image information is fixed through the fixing device 18 is discharged to a discharge tray 51 provided at a lateral side of the image reading part 5 and above the image forming part 1. Here, the fixing device 18 includes a fixing roller 18a and a pressure roller 18b at the downstream side in the paper discharge direction. The output medium on which the developer image (toner image) is transferred is heated and pressed by the fixing roller 18a heated up to, for example, 180° C. and the pressure roller 18b, so that the toner image is melted and the image information is fixed.
Besides, the image forming apparatus 100 includes a side paper discharge tray 9 on a lateral side of the image forming part 1. The output medium discharged from the fixing device 18 is guided to the side paper discharge tray 9 through a relay conveyance part 21.
The control part 101 is a control device to control the operations of the respective parts constituting the image forming apparatus 100. As the control part 101, a CPU (Central Processing Unit), an MPU (Micro Processing Unit) capable of executing an arithmetic operation comparable to the CPU, or the like can be used.
The memory part 102 is a storage device to store programs for executing the respective processes in the image forming apparatus 100, definition data, detection values of various sensors, and the like. The memory part 102 includes, for example, a RAM (Random Access Memory), a ROM (Read Only Memory), a DRAM (Dynamic Random Access Memory), an SRAM (Static Random Access Memory), a VRAM (Video RAM), a flash memory or the like.
The external I/F part 103 mediates information transmission between an equipment, such as a personal computer, connected to a network (not shown) and the image forming apparatus 100.
The image processing part 104 converts the output signal from the reflected light received by a CCD in the image reading part 5 into image data of yellow (Y), magenta (M), cyan (C) and black (K), performs data processing such as density correction, and outputs the writing image data to the control part 101. Besides, the image processing part 104 performs data processing on data inputted from the PC through the external I/F 103, and outputs the writing image data to the control part 101.
The motor drive controller 105 controls driving of various motors in the image forming apparatus 100 based on control information from the control part 101. For example, supply voltage to the motor is changed to control the rotation speed of the motor. The sensor part 106 includes various sensors installed in the image forming apparatus 100, such as a temperature sensor and a humidity sensor.
Besides, each of the developing devices 14a to 14d includes a developer containing part 140 to contain a two-component developer including a toner and a carrier, a magnetic sleeve 141 arranged to be opposite to the photoconductive drum 11a to 11d, and a developer mixer 142 to agitate and convey the developer to the magnetic sleeve 141 side.
The magnetic sleeve 141 is made of a magnetic substance, attracts both the carrier and the toner in the developer, and supplies the toner to the photoconductive drum 11a to 11d side. The developer mixer 142 includes a helical fin in the inside, and the fin rotates to agitate the developer.
When it is detected based on the output of the toner density sensor 144 that the toner in the developer containing part 140 of the developing device 14a to 14d becomes low, the toner is supplied from the corresponding toner cartridge 10a to 10d to the developing device 14a to 14d for a specified time. Specifically, the toner is supplied from the toner cartridge 10a to 10d to the toner hopper 143, and a toner supply motor 145 drives a supply roller 146, so that the toner is supplied from the toner hopper 143 into the developer containing part 140.
After the supply, the rotation of the magnetic sleeve 141 is stopped, and only the developer mixer 142 is rotated. When it is detected that the output of the toner density sensor 144 exceeds a specific threshold, the toner supply is completed.
The motor drive controller 105 is the controller to independently control the toner supply motor 145, the sleeve drive motor 147 and the mixer drive motor 148 based on control information from the control part 101. For example, at the time of initial adjustment, the mixer drive motor 148 is driven while the sleeve drive motor 147 is stopped. Here, the initial adjustment is the adjustment in which toner supply is performed from the toner cartridge 10a to 10d to the developer containing part 140 of the developing device 14a to 14d until the toner density sensor 144 detects that the toner density again reaches the specific toner density.
After the initial adjustment is ended, the motor drive controller 105 drives the sleeve drive motor 147 and the mixer drive motor 148 at the time of image formation and the time of toner supply. For example, the rotation speed of the sleeve drive motor 147 and the mixer drive motor 148 at the time of image formation is such that when the rotation speed of the sleeve drive motor 147 is 450 rpm, the rotation speed of the mixer drive motor 148 is about 600 rpm. When the mixer drive motor 148 is driven, the developer mixer 142 rotates at a specified rotation speed (hereinafter referred to as a “mixer rotation speed”) in the developer containing part 140, and agitates the developer. By this agitation, the toner and the carrier contact each other and are charged.
The toner charge amount is changed according to the mixer rotation speed and the toner supply amount.
Besides, in
The image formation processing part 101a controls an equipment constituting the image forming part 1, and performs image forming process on the writing image data acquired from an equipment on the network or the image reading part 5.
The printing ratio calculation part 101b counts the number of pixels per unit number of printed sheet, calculates the printing ratio, and outputs the printing ratio to the mixer rotation speed determination part 101c. The printing ratio is an occupied ratio of a print area in a main scanning direction corresponding to a perpendicular direction to the movement direction of the intermediate transfer belt 15 in an area where an image can be formed. For example, the printing ratio can be calculated by analyzing the writing image data outputted by a computer to output image information or the image reading part. Specifically, the number of all pixels of the writing image data and the number of pixels to be printed (hereinafter referred to as “the number of print pixels”) in the number of pixels within a previously determined range are counted, and the printing ratio is calculated by an expression: (printing ratio)=(the number of print pixels)/(the number of all pixels).
Besides, the printing ratio can be calculated by a method other than the method of previously analyzing the writing image data. For example, since the exposure time of the exposure device has a proportional relation with the number of print pixels, that is, the number of exposed dots, the printing ratio can be calculated by obtaining from the number of exposed dots corresponding to the actual exposure time of the exposure device based on the writing image data. Specifically, with respect to the number of exposed dots necessary for performing full-surface solid printing in the area of an A4 (297 mm×210 mm) sheet, when the ratio of the number of exposed dots on one A4 sheet at the time of measurement is obtained, the printing ratio can be calculated as follows:
the number of exposed dots at the time of A4 solid printing=(297/25.4×600)×(210/25.4×600)=3.48×107
the actual number of exposed dots=7.5×105
printing ratio=(7.5×105/3.48×107)×100≈2.16 (%).
The mixer rotation speed determination part 101c determines the mixer rotation speed of the mixer drive motor to be a high value according to the increasing tendency of the toner supply amount from the toner cartridge 10a to 10d to the developer containing part 140. Specifically, reference is made to the printing ratio-mixer rotation speed correspondence information stored in the printing ratio-mixer rotation speed storage part 102a while using the printing ratio calculated by the printing ratio calculation part 101b as a key, and the mixer rotation speed of the mixer drive motor 148 is determined. The mixer rotation speed determination part 101c outputs the determined mixer rotation speed to the motor drive controller 105.
The toner consumption amount calculation part 101d calculates the toner consumption amount based on the density data outputted by the toner density sensor 144, determines the toner supply amount corresponding to the toner consumption amount, and outputs to the motor drive controller 105. The motor drive controller 105 controls the driving of the toner supply motor 145 according to the toner supply amount, and supplies the toner.
At Act 801, the image formation processing part 101a determines the presence or absence of input of a print job. Here, when determination is made that the print job is inputted (Act 801: Yes), advance is made to Act 802. When determination is made that the print job is not inputted (Act 801: No), a standby state occurs.
At Act 802, the image formation processing part 101a outputs an image forming condition, which is set in the finally executed image stabilization control and is stored in the memory part 102, to the image forming part 1 and causes the image forming process to be executed.
At Act 803, the printing ratio calculation part 101b analyzes the writing image data acquired from the image formation processing part 101a, and counts the number of print pixels and the number of all pixels of the data. Besides, the printing ratio calculation part 101b counts the number of printed sheets during the execution of the print job, and stores in the memory part 102.
At Act 804, the printing ratio calculation part 101b determines whether the number of printed sheets stored in the memory part 102 reaches the unit number of sheets. Here, when determination is made that printing of the unit number of sheets is ended (Act 804: Yes), advance is made to Act 805. When determination is made that printing of the unit number of sheets is not ended (Act 804: No), return is made to Act 803.
At Act 805, the printing ratio calculation part 101b calculates the printing ratio per unit number of sheets from the number of print pixels, and outputs to the mixer rotation speed determination part 101c.
At Act 806, the mixer rotation speed determination part 101c refers to the printing ratio-mixer rotation speed correspondence information stored in the printing ratio-mixer rotation speed storage part 102a while using the printing ratio calculated by the printing ratio calculation part 101b as a key. When determining the mixer rotation speed of the mixer drive motor 148, the mixer rotation speed determination part outputs a motor drive signal corresponding to the mixer rotation speed to the motor drive controller 105.
At Act 807, the motor drive controller 105 controls the supply voltage and the like to the mixer drive motor 148 based on the motor drive signal outputted from the mixer rotation speed determination part 101c, and the motor rotates at the determined mixer rotation speed.
At Act 808, the image formation processing part 101a determines whether the print job is ended. Here, when determination is made that the print job is ended (Act 808, Yes), the process is ended. When determination is made that the print job is not ended (Act 808: No), return is made to Act 803, and the process of Act 803 to Act 808 is repeated until the print job is ended.
As described above, according to the image forming apparatus 100 of the embodiment, even when the toner supply amount becomes large, for example, even when a continuous print job having a high printing ratio is executed, since the agitation can be performed at suitable mixer rotation intensity, a sufficient toner charge amount can be obtained. Thus, the occurrence of a problem such as white background fogging or deterioration in gradation reproducibility due to excessive development can be suppressed. Besides, since the agitation of the developer can be performed at the necessary minimum mixer rotation intensity, the deterioration of the toner can be suppressed.
Hereinafter, a second embodiment will be described with reference to
In this embodiment, a relation between a motor drive time and a mixer rotation speed (hereinafter referred to as “motor drive time-mixer rotation speed correspondence information”) is previously defined in the motor drive time-mixer rotation speed storage part 102b (memory part 102).
In this embodiment, a mixer rotation speed determination part 101c refers to the motor drive time-mixer rotation speed correspondence information stored in the motor drive time-mixer rotation speed storage part 102b while using the motor drive time of the toner supply motor 145 counted by the motor drive time counting part 101e as a key, and determines the mixer rotation speed of a mixer drive motor 148.
At Act 1101, an image formation processing part 101a determines the presence or absence of input of a print job. Here, when determination is made that the print job is inputted (Act 1101: Yes), advance is made to Act 1102. When determination is made that the print job is not inputted (Act 1101: No), a standby state occurs.
Act 1102, the image formation processing part 101a outputs an image forming condition, which is set in the finally executed image stabilization control and is stored in the memory part 102, to an image forming part 1, and causes the image forming process to be executed.
At Act 1103, the motor drive time counting part 101e counts a drive time of the toner supply motor 145 elapsed from the start point of printing of a unit number of sheets, and stores in the memory part 102. Besides, the motor drive time counting part 101e counts also the number of printed sheets during execution of the print job, and stores in the memory part 102.
At Act 1104, the motor drive time counting part 101e determines whether the number of printed sheets stored in the memory part 102 reaches the unit number of sheets. Here, when determination is made that the printing of the unit number of sheets is ended (Act 1104: Yes), advance is made to Act 1105. When determination is made that printing of the unit number of sheets is not ended (Act 1104: No), return is made to Act 1103.
At Act 1105, the motor drive time counting part 101e outputs the counted drive time of the toner supply motor 145 to the mixer rotation speed determination part 101c.
At Act 1106, the mixer rotation speed determination part 101c refers to the motor drive time-mixer rotation speed correspondence information stored in the motor drive time-mixer rotation speed storage part 102b while using the motor drive time counted by the motor drive time counting part 101e as a key. When determining the mixer rotation speed of the mixer drive motor 148, the mixer rotation speed determination part outputs a motor drive signal corresponding to the mixer rotation speed to a motor drive controller 105.
At Act 1107, the motor drive controller 105 controls the supply voltage and the like to the mixer drive motor 148 based on the motor drive signal outputted from the mixer rotation speed determination part 101c, and the motor rotates at the determined mixer rotation speed.
At Act 1108, the image formation processing part 101a determines whether the print job is ended. Here, when determination is made that the print job is ended (Act 1108: yes), the process is ended. When determination is made that the print job is not ended (Act 1108: No), return is made to Act 1103, and the process of Act 1103 to Act 1108 is repeated until the job is ended.
As described above, according to the image forming apparatus 100 of this embodiment, even under the state where the toner adhesion amount per unit pixel increases, the amount of actually supplied toner can be derived from the drive time of the toner supply motor 145. Thus, the mixer rotation speed is changed to a high value according to the increasing tendency of the motor drive time, and the mixer rotation speed is determined based on the actual supply, so that a more stable toner charge amount can be obtained.
Incidentally, in the embodiment, reference is made to the definition information while using the printing ratio or the drive time of the toner supply motor 145 as a key, and the mixer rotation speed is determined. However, a modification can be made such that reference is made to definition information of the combination of these, and the mixer rotation speed is determined. In this case, since a more accurate toner supply amount can be calculated by knowing the printing ratio and the toner supply time, the mixer rotation speed necessary to stabilize the toner charge amount can be more accurately determined. Besides, since a position where development is performed by the developer conveyed by the magnetic sleeve 141 is often separated from a position where toner supply is performed, the toner supply timing is controlled, so that the toner consumed by the development can be accurately supplied to a necessary portion.
Further, the printing ratio-mixer rotation speed correspondence information in the first embodiment and the motor drive time-mixer rotation speed correspondence information in the second embodiment are respectively previously stored in the storage device. However, a structure may be made such that the mixer rotation speed determination part 101c calculates the toner supply amount by substituting the printing ratio calculated by the printing ratio calculation part 101b or the motor drive time counted by the motor drive time counting part 101e into a specified computation expression, and determines the mixer rotation speed. This computation expression is preferably defined such that as the toner supply amount calculated based on the printing ratio or the motor drive time increases, the mixer rotation speed of the mixer drive motor is determined to be a high value.
While certain embodiments have been described these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel apparatus and methods described herein may be embodied in a variety of other forms: furthermore various omissions, substitutions and changes in the form of the apparatus and methods described herein may be made without departing from the spirit of the inventions. The accompanying claims and there equivalents are intended to cover such forms of modifications as would fall within the scope and spirit of the invention.
This application is based upon and claims the benefit of priority from Provisional U.S. Application No. 61/362435, filed on 8 Jul. 2010, the entire contents of which are incorporated herein by reference.
| Number | Date | Country | |
|---|---|---|---|
| 61362435 | Jul 2010 | US |
