JP3600472B2 - Image forming device - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention is directed to, for example, a method in which a transfer material such as a sheet is supported and conveyed by a transfer conveyance belt abutting in a predetermined positional relationship with a transfer unit surface of a rotationally driven image carrier such as a photosensitive drum. The present invention relates to an image forming apparatus that transfers and reproduces a toner image formed thereon on a transfer material, and more specifically, controls a positional relationship when an image carrier stops to stop with a predetermined positional relationship. Further, the present invention relates to an image forming apparatus capable of performing subsequent image formation with high accuracy.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there is a color image forming apparatus in which a color image is transferred to a recording unit as YMCK image data, and the color image of each color is sequentially superimposed and reproduced as a color image by a transfer unit for each color.
In such a color image forming apparatus, there is a problem that a color image cannot be faithfully reproduced unless images of the respective colors are accurately superimposed at each transfer unit. This is a major development challenge.
[0003]
In an image forming apparatus having an infinite number of components, there is a small variation in the component accuracy of each component, and a variation occurs in each image forming device due to the assembling accuracy when assembling these components.
Therefore, conventionally, a pattern adjustment of each color is performed by forming a pattern image of each color on a trial basis, confirming the positional relationship between the pattern images of each color, and adjusting the image formation position for each image forming unit of each color ( Registered Patent No. 2642351).
[0004]
However, even if the above-described registration adjustment is performed, the "color shift" due to the "shift of the image writing start position" can be corrected, but the periodic drive of a drive system such as a drive gear for driving the photosensitive drum can be corrected. It was not possible to correct color misregistration caused by irregular speed fluctuations of the photosensitive drum caused by unevenness.
In other words, in such an image forming apparatus, there has conventionally been a problem of drive unevenness that periodically occurs in each recording unit of an image. When the images recorded with the color materials are sequentially superimposed and reproduced as a color image, there is a problem that a color shift occurs and a faithful color image cannot be reproduced.
[0005]
Therefore, in the conventional color image forming apparatus, when the image formed on the photosensitive drum in each recording unit is transferred in the transfer unit, the condition of the drive unevenness that periodically occurs is the same. It has been considered that the relationship between the distance (time) from the image writing position to the transfer position to the photosensitive drum and the drive fluctuation period of the drive mechanism is N times as large as the relationship (Japanese Patent Publication No. Hei 7-31446). Gazette, Japanese Patent Publication No. 8-14731, etc.).
[0006]
FIG. 8 shows a configuration around the image forming units of the conventional color image forming apparatus employing the above-described method and a transfer conveyance belt that conveys a transfer material for transferring an image formed by each image forming unit.
In FIG. 8, photosensitive drums 322a, 322b, 322c, and 322d constituting black, cyan, magenta, and yellow recording units in order from the right. The images of the respective colors formed by the photosensitive drums 322 a to 322 d are transferred to a transfer material (not shown) supported and transported by the transfer and transport belt 316 as the transfer and transport belt 316 moves. At the transfer portion A where the conveyance belt is close to the transfer belt, the transfer is performed in a superimposed order from black ink. Here, the photosensitive drums 322a to 322d are connected to each other so that their driving is connected and start rotating at the same time. Each photosensitive drum is mounted such that its rotational drive unevenness is in the same phase. I have.
[0007]
As a specific example, a drive gear (not shown) to which a drive shaft (not shown) of each of the photoconductor drums 322a to 322d is fitted is set to a certain reference (for example, a key type as shown in FIG. Holes) are all aligned in the same direction. Thus, at the same time, each photosensitive drum always rotates with the same driving unevenness.
Therefore, each distance L ′ between the transfer portions of each photoconductor drum is defined as the diameter of the photoconductor drum as d.
L ′ = Nπd (N is an integer)
In the image transfer process of each of the transfer units A of the four photosensitive drums 322a to 322d arranged in parallel as viewed in FIG. 8, the drive unevenness on the transfer material is always the same. The images formed of the color materials of the respective colors are sequentially superimposed in a cycle, and as a result, a color shift caused by driving unevenness is eliminated.
[0008]
[Problems to be solved by the invention]
However, in the above-described conventional configuration, the distance relationship between the recording units arranged in parallel must be arranged in accordance with the periodic drive fluctuation. When the distance between the recording units is determined in this way, even if the integer N is set to 1, a distance corresponding to the peripheral length of the photosensitive drum is necessarily required. As a result, the size of the image forming apparatus itself becomes large, so that not only can the size of the image forming apparatus desired by the user not be reduced, but also it takes a long time to assemble each part, or each part has a high precision. Is required and the production cost increases.
[0009]
On the other hand, in a device that detects a color shift of each component color image or a rotational position shift of each of the photosensitive drums 322a to 322d and constantly corrects the phase of each printing unit, the photosensitive unit of each printing unit always responds to the generated shift. The speed of the body drum is controlled and the phase is constantly adjusted. In this case, the phase adjustment control is performed even for a minute phase shift of each photosensitive drum that does not significantly affect the color shift of an image. In order to match the phase of the photosensitive drum, rubbing occurs between the photosensitive drum and the recording medium or the transfer carrier, causing damage to the photosensitive drum, greatly affecting the life of the photosensitive drum, and significantly shortening the life cycle. There was a problem.
[0010]
SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problem, and has been made in response to a periodic drive fluctuation in each of the recording units arranged in parallel (perpendicular to the flow direction of the transfer conveyance belt) as in the related art. Provided is an image forming apparatus which can be faithfully reproduced as one color image, and which can be reduced in size even if an image carrier having the same diameter is used and the installation area in an office environment is minimized. The purpose is to do.
[0011]
Furthermore, the timing shift between the start and stop of the driving of the image carrier such as the photosensitive drum and the contact portion of the transfer conveyance belt contacting the transfer portion of the image carrier is performed, and the phase matching control is performed. minimizing the deterioration of the front surface of the image carrier or the transfer carrier by abrasion of the image bearing member and a transfer carrier for, to provide an image forming apparatus capable of reproducing an image faithful along the entire circumference image carrier The purpose is to:
[0012]
[Means for Solving the Problems]
The present invention has the following configuration to achieve the above object.
According to the present invention, a first and a second image carrier having the same perimeter and provided in order from an upstream side to a downstream side of a recording medium conveyance path , and rotating and stopping the first and the second image carrier are provided. First and second driving means to be driven, a first reference mark indicating a reference position of rotational driving unevenness of the first image carrier due to periodic driving unevenness of a driving system of the first driving means, Detecting a second reference mark indicating a reference position of rotational drive unevenness of the second image carrier due to periodic drive unevenness of the drive system of the second drive unit, and detecting the first and second reference marks. first to the second detecting means, the first, on the basis of the detection result of the second detecting means, the first, and a phase control means for performing phase adjustment rotation stop control of the second image bearing member has the phase matching rotation stop control, the first reference for the transfer position of said first image bearing member A phase shift X between a first stop position of the second reference mark and a second stop position of the second reference mark with respect to the transfer position of the second image carrier. The image carrier is stopped, and the relationship between the distance L between the first and second transfer positions and the phase shift X is L = perimeter of the first or second image carrier × (360−X) degrees / 360 degrees, and when stopping the rotating first and second image carriers, the phase control means sets the second reference mark of the second image carrier located downstream. A second fiducial mark detecting step of detecting by the second detecting means, and after the second fiducial mark detecting step, the first fiducial mark of the first image carrier positioned upstream is A first fiducial mark detecting step of detecting by the first detecting means, and the first fiducial mark from the time of detecting the second fiducial mark. A step of obtaining a detection time until a reference mark is detected, a step of detecting a correction amount for making the detection time coincide with a time corresponding to the phase shift X, and setting the first driving means to the first reference mark. Stopping after a lapse of a first margin time from the detection, and after a second margin time obtained by adding the correction amount to the first margin time from the detection of the first reference mark, And a step of stopping the image forming apparatus.
Further, according to the present invention, the first and second image carriers having the same perimeter and provided in order from the upstream side to the downstream side of the recording medium transport path, and the first and second image carriers are rotated. A first reference mark indicating a reference position of rotation drive unevenness of the first image carrier due to periodic drive unevenness of a drive system of the first and second drive means to be stopped; A second reference mark indicating a reference position of rotational drive unevenness of the second image carrier due to a periodic drive unevenness of the drive system of the second drive unit; and the first and second reference marks. First and second detecting means for detecting the phase difference, and phase control means for performing phase stop rotation stop control of the first and second image carriers based on the detection results of the first and second detecting means. Wherein the phase-matching rotation stop control is performed with respect to the transfer position of the first image carrier. A phase shift X is provided between a first stop position of the second reference mark and a second stop position of the second reference mark with respect to the transfer position of the second image carrier. Is stopped, and the relationship between the distance L between the first and second transfer positions and the phase shift X is: L = the circumference of the first or second image carrier × (360−X) Degrees / 360 degrees, and the phase control means, when stopping the rotating first and second image carriers, the second reference mark of the second image carrier located downstream. A second reference mark detecting step of detecting the first reference mark of the first image bearing member located on the upstream side after the second reference mark detecting step. Detecting by the first detecting means; and detecting the first fiducial mark from the time of detecting the second fiducial mark. A step of obtaining a detection time up to the time of output, a step of detecting a correction amount for making the detection time coincide with a time corresponding to the phase shift X, and a step of detecting the first driving means when the first reference mark is detected. And stopping after a first margin angle rotation, and stopping the second drive means after a second margin angle rotation in which the correction amount is added to the first margin angle from the time of detecting the first reference mark. And an image forming apparatus.
According to a first aspect of the present invention, in the image forming apparatus, the first and second driving units maintain the first and second image carriers not used for image formation in a rotation stopped state, The phase control means stops the image carrier used for the image formation at a position where the rotation phase state with the image carrier in the rotation stopped state without performing the image formation is the phase shift X when the image formation is completed. is images forming apparatus Ru is.
[0013]
The second aspect of the present invention, the first, second drive means, the gist 1, wherein the maintaining the rotation stopped state of the image carrier is not used for image formation by exciting the motor An image forming apparatus.
[0014]
The third aspect of the present invention, the motor - data is an image forming apparatus of the subject matter 2, wherein it is a pulse motor.
[0015]
A fourth aspect of the present invention, an image carrier that is not used for the image formation is an image forming apparatus of the subject matter 1, wherein the conveying carrier for conveying a recording medium and a non-contact.
[0016]
According to the first aspect of the present invention, an image carrier not used for image formation is maintained in a rotation stopped state, and the rotation phase of only the image carrier used for image formation is not used for image formation. In order to match the phase of the body, it is not necessary to rotate the image carrier not used for image formation just to match the rotation phase, simplifying control and shortening the time required for positioning, as well as reducing unnecessary operations. This can be reduced as much as possible, and the life of the image carrier and the like can be extended.
In addition, when the image carriers are stopped (when the image forming apparatus is stopped), the rotation phases of all the image carriers are matched, so that a plurality of image carriers for the next full-color image formation or the like are simultaneously operated. Image formation can be started immediately without performing control to match the rotational phase state of the image carrier at the start of image formation to be used.
Further, in order to maintain and lock the image carrier which is not used for image formation by the driving means by, for example, a locking means or the like, the image forming apparatus does not perform image formation due to external force such as vibration of the apparatus while the image forming apparatus is operating. It is possible to prevent the image carrier from rotating.
Therefore, the phase relationship between the image carriers not used for image formation can be maintained in accordance with the predetermined state, so that only the image carrier on which the image is formed is rotated to lock the phase of the image carrier. By adjusting to the state, an accurate rotational phase state can be formed.
[0017]
According to the second aspect of the present invention, it is possible to generate a holding torque by energizing and exciting a motor of a driving unit that drives an image carrier that does not perform image formation, thereby preventing rotation movement due to external force, The rotation of the image carrier can be easily and inexpensively realized without the need for a mechanical member for mechanically locking the image carrier.
[0018]
According to the third aspect of the present invention, the pulse motor generates a holding torque by being energized and excited, and can be easily locked without rotating at a certain position, and can be easily locked by an external force of the image carrier that does not perform image formation. Rotational movement can be prevented.
In addition, the pulse motor can perform high-precision rotation in an open loop according to the set driving pulse signal, and can easily position the motor at the set rotation position. Therefore, the unused image carrier can be securely locked, and the image carrier used for image formation can be accurately and easily positioned so that the rotational phase of the unused image carrier becomes a predetermined phase state. Can be.
In addition, by using a pulse motor, a high-precision rotation operation can be realized in an open loop while the rotation phase of the image carriers is in a predetermined state when all the image carriers are operating.
[0019]
According to the fourth aspect of the present invention, the image carrier whose rotation has been stopped is partially rubbed with the carrier by separating the carrier and the image carrier not used for image formation. As a result, it is possible to prevent a part of the surface from being significantly worn to prevent image formation failure and to prolong the life thereof.
[0020]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
One embodiment of the present invention will be described below with reference to FIGS. FIG. 1 is a schematic front sectional view showing a configuration of a digital color copying machine 1 which is an image forming apparatus according to an embodiment of the present invention. A document table 111 and an operation panel (not shown) are provided on the upper surface of the copying machine main body 1, and an image reading unit 110 and an image forming unit 210 are provided inside the copying machine main body 1. A reversing automatic document feeder (RADF; Reversing Automatic Document Feeder) 112 is mounted on the upper surface of the platen 111 so as to be openable and closable with respect to the platen 111 and has a predetermined positional relationship with the surface of the platen 111. Have been.
[0021]
The automatic double-sided document feeder 112 first conveys the document such that one side of the document faces the image reading unit 110 at a predetermined position on the document table 111, and after the image reading on one side is completed, the other side. The document is inverted and transported toward the document table 111 such that the surface of the document faces the image reading unit 110 at a predetermined position on the document table 111. Then, after the two-sided image reading for one document has been completed, the double-sided automatic document feeder 112 discharges the document and performs a double-sided conveyance operation for the next document.
The above-described document transport and reverse operation are controlled in relation to the operation of the entire copying machine 1.
[0022]
The image reading section 110 is arranged below the document table 111 for reading an image of a document conveyed onto the document table 111 by the automatic duplex document feeder 112.
The image reading unit 110 has document scanning bodies 113 and 114 that reciprocate in parallel along the lower surface of the document table 111, an optical lens 115, and a CCD line sensor 116 that is a photoelectric conversion element.
[0023]
The document scanning bodies 113 and 114 include a first scanning unit 113 and a second scanning unit 114. The first scanning unit 114 has an exposure lamp for exposing the surface of the original image, and a first mirror for deflecting a reflected light image from the original in a predetermined direction. It reciprocates in parallel at a predetermined scanning speed while maintaining the distance. The second scanning unit 114 has second and third mirrors for further deflecting the reflected light image from the document deflected by the first mirror of the first scanning unit 113 in a predetermined direction. It reciprocates in parallel with one scanning unit 113 while maintaining a constant speed relationship.
[0024]
The optical lens 115 reduces the reflected light image from the document deflected by the third mirror of the second scanning unit, and forms the reduced light image at a predetermined position on the CCD line sensor 116.
[0025]
The CCD line sensor 116 photoelectrically converts the formed light image in order and outputs it as an electric signal. The CCD line sensor 116 is a three-line color CCD capable of reading a black-and-white image or a color image and outputting line data separated into R (red), G (green), and B (blue) color components. is there. The document image information converted into an electric signal by the CCD line sensor 116 is further transferred to an image processing unit (not shown) to perform predetermined image data processing.
[0026]
Next, the configuration of the image forming unit 210 and the configuration of each unit related to the image forming unit 210 will be described.
Below the image forming unit 210, paper (for example, a recording medium such as paper, OHP paper) P stacked and stored in the paper tray TR is separated one by one and supplied to the image forming unit 210. A paper mechanism 211 is provided. Then, the sheets P separated and supplied one by one are conveyed to the image forming unit 210 at a controlled timing by a pair of registration rollers 212 disposed in front of the image forming unit 210. Further, the sheet P on which an image is formed on one side is re-supplied and conveyed to the image forming unit 210 in synchronization with the image formation of the image forming unit 210.
[0027]
Below the image forming unit 210, a transfer and transport belt mechanism 213 is disposed. The transfer transport belt mechanism 213 transports the paper P by electrostatically attracting the paper P to a transfer transport belt 216 stretched so as to extend substantially parallel between the drive roller 214 and the driven roller 215. Further, a pattern image detection unit 300 that detects a test pattern formed on the transfer / transport belt 216 is provided near the lower side of the rotation orbit of the transfer / transport belt 216.
[0028]
Further, a fixing device 217 for fixing the toner image transferred and formed on the paper P on the paper P is disposed near the drive roller 214 on the downstream side of the transfer and transport belt mechanism 213 in the paper transport path. . The sheet P having passed through the nip between the pair of fixing rollers of the fixing device 217 passes through a conveyance direction switching gate 218, and is discharged by a discharge roller 219 onto a discharge tray 220 attached to the outer wall of the copying machine body 1. Is discharged.
[0029]
The switching gate 218 selectively switches the conveyance path of the sheet P after fixing between a path for discharging the sheet P to the copying machine main body 1 and a path for re-supplying the sheet P to the image forming unit 210. Things. The sheet P whose transport direction has been switched again toward the image forming unit 210 by the switching gate 218 is turned upside down via the switchback transport path 221, and is again supplied to the image forming unit 210.
[0030]
In addition, above the transfer conveyance belt 216 in the image forming section 210, the first image formation station Pa, the second image formation station Pb, the third image formation station Pc, and the proximity of the transfer conveyance belt 216. A fourth image forming station Pd is provided in order from the upstream side of the sheet transport path.
[0031]
The transfer conveyance belt 216 is frictionally driven by the drive roller 214 in the direction indicated by the arrow Z in FIG. 1 to grip the sheet P fed through the sheet feeding mechanism 211 as described above, and transfer the sheet P to the image forming station Pa. To Pd.
Each of the image stations Pa to Pd has substantially the same configuration. Each of the image stations Pa, Pb, Pc, and Pd includes a photosensitive drum 222a, 222b, 222c, and 222d that is driven to rotate in the direction of arrow F shown in FIG.
[0032]
Around the photosensitive drums 222a to 222d, chargers 223a, 223b, 223c, 223d for uniformly charging the photosensitive drums 222a to 222d, respectively, and electrostatic latents formed on the photosensitive drums 222a to 222d. Developing devices 224a, 224b, 224c, 224d for developing the respective images; transfer dischargers 225a, 225b, 225c, 225d for transferring the developed toner images on the photosensitive drums 222a to 222d to the paper P; Cleaning devices 226a, 226b, 226e, and 226d for removing toner remaining on the drums 222a to 222d are sequentially arranged along the rotation direction of the photosensitive drums 222a to 222d.
[0033]
Laser beam scanner units 227a, 227b, 227c, and 227d are provided above the photosensitive drums 222a to 222d, respectively. Each of the laser beam scanner units 227a to 227d includes a semiconductor laser device (not shown) for emitting dot light modulated according to image data, and a polygon mirror (not shown) for deflecting a laser beam from the semiconductor laser device in the main scanning direction. Deflecting device) 240, an fθ lens 241 and mirrors 242 and 243 for forming an image of the laser beam deflected by the polygon mirror 240 on the surfaces of the photosensitive drums 222a to 222d.
[0034]
A pixel signal corresponding to the black component image of the color original image is supplied to the laser beam scanner 227a, a pixel signal corresponding to the cyan component image of the color original image is provided to the laser beam scanner 227b, and the color original image is provided to the laser beam scanner 227c. , And a pixel signal corresponding to the yellow component image of the color document image is input to the laser beam scanner 227d.
[0035]
Thus, an electrostatic latent image corresponding to the color-converted document image information is formed on each of the photosensitive drums 222a to 222d. The developing device 227a contains black toner, the developing device 227b contains cyan toner, the developing device 227c contains magenta toner, and the developing device 227d contains yellow toner. The electrostatic latent images on the photoconductive drums 222a to 222d are developed with the toners of these colors. As a result, the document image information color-converted by the image forming unit 210 is reproduced as a toner image of each color.
[0036]
Further, a paper suction (brush) charger 228 is provided between the first image forming station Pa and the paper feed mechanism 211, and the suction charger 228 charges the surface of the transfer conveyance belt 216. The sheet P supplied from the sheet feeding mechanism 211 is conveyed without shifting between the first image forming station Pa and the fourth image forming station Pd in a state where the sheet P is securely attracted onto the transfer conveying belt 216.
[0037]
On the other hand, between the fourth image station Pd and the fixing device 217, a cathode (not shown) is provided almost directly above the drive roller 214. An AC current is applied to the static eliminator to separate the sheet P electrostatically attracted to the transport belt 216 from the transfer transport belt 216.
[0038]
In the digital color copier having the above configuration, cut sheet-shaped paper is used as the paper P. When the sheet P is sent out from the sheet cassette and supplied into the guide of the sheet feeding path of the sheet feeding mechanism 211, the leading end of the sheet P is detected by a sensor (not shown). Is temporarily stopped by the pair of registration rollers 212 based on the detection signal output from the printer.
Then, the paper P is sent onto the transfer / conveying belt 216 rotating in the direction of arrow Z in FIG. 1 at the timing of each of the image stations Pa to Pd. At this time, as described above, the transfer conveyance belt 216 is given a predetermined charge by the suction charger 228, so that the paper P is stably conveyed and supplied while passing through the image stations Pa to Pd. .
[0039]
In each of the image stations Pa to Pd, a toner image of each color is formed, and is superposed on the support surface of the paper P conveyed by being electrostatically attracted by the transfer / conveyance belt 216. When the transfer of the image by the fourth image station Pd is completed, the sheet P is sequentially separated from the transfer conveyance belt 216 by the negative discharger from the leading end thereof, and is guided to the fixing device 217. Finally, the paper P on which the toner image has been fixed is discharged onto a paper discharge tray 220 from a paper discharge port (not shown). In the above description, the laser beam is scanned and exposed by the laser beam scanner units 227a to 227d, thereby performing optical writing on the photosensitive member.
[0040]
Note that a writing optical system (LED head) including a light emitting diode array and an imaging lens array may be used instead of the laser beam scanner unit. The LED head is smaller in size than the laser beam scanner unit, and has no moving parts and is silent. Therefore, it can be suitably used in an image forming apparatus such as a tandem type digital color copying machine which requires a plurality of optical writing units.
[0041]
Next, the rotation phase control of each photosensitive drum, which is a characteristic part of the present embodiment, will be described.
In the digital color copying machine of the present embodiment, as shown in FIG. 2, unlike the image forming apparatus having the conventional configuration shown in FIG. 8, the four photosensitive drums 222a to 222d of the image forming stations Pa to Pd are provided. Rotation of the photoconductive drum (if the phases are the same, common to each photoconductive drum), the phase is shifted by a predetermined amount (in the image, the expansion / contraction phase of each color component image matches) Driven. More specifically, since each photosensitive drum starts rotating at the same time and stops rotating at the same time, the photosensitive drums are stopped at different stop positions (rotation start positions). In the future, each photoconductor drum will be rotated with its phase shifted so that the expansion and contraction of each color component image on the image will match, but the rotation phase state of each photoconductor drum will be changed. The description will be made with the description that the state is the predetermined state.
[0042]
In FIG. 2, similarly to FIG. 8, in order to correct a phase shift in each photoconductor drum, a predetermined positional relationship (a position where periodic driving unevenness is a constant condition) with respect to a shaft that is driven to rotate. (Relationship), taking into account that the photoconductor drums are attached in such a manner, the respective photoconductor drums are shifted by a predetermined angle (the difference between the circumference of the photoconductor drum and the distance between transfer portions of adjacent photoconductors) The state of stopping is shown with reference to a key-shaped hole (or projection) ha of the drive gear attached to the shaft.
[0043]
Now, with reference to the black photosensitive drum 222a, the phase of the adjacent cyan photosensitive drum 222b is advanced by about 60 degrees. Similarly, the phase of the magenta photosensitive drum 222c is advanced by 120 degrees, and the phase of the yellow photosensitive drum 222d is advanced by 180 degrees.
In this way, by shifting the phase of the drive unevenness in each photoconductor drum, the distance between the transfer units A-A corresponding to the respective image forming stations Pa to Pd is reduced by the amount corresponding to the phase shift. Even if the transfer material is reduced, the drive unevenness between the photosensitive drums can be the same for the transfer material passing through the transfer unit A. In addition, by shifting in the opposite direction, the distance between A and A can be made longer than the circumference of the photosensitive drum.
[0044]
As described above, if the diameter of the photosensitive drum is d by advancing the cycle of drive unevenness between adjacent photosensitive drums by 60 degrees, L corresponding to the distance between the transfer portions A-A is L = photosensitive Circumference of body drum πd x ((360-60) degrees / 360 degrees)
It becomes.
[0045]
Here, for convenience of explanation, the distance between the transfer units A-A is set based on the phase shift in each photosensitive drum, but actually, the distance L between the transfer units A-A is determined. Then, based on this, the phase shift of each photosensitive drum may be set. For example, when a photosensitive drum having a drum diameter of 40 mm is used and the distance L between the transfer units A-A is set to 105 mm, the stop position between the adjacent photosensitive drums is set as described above for each drive. The unevenness is set so that the phase is shifted by about 60 degrees.
[0046]
Here, the manner in which images of the respective photosensitive drums are superimposed without color shift due to driving unevenness will be described with reference to FIG.
Now, it is assumed that four photosensitive drums are rotating in a state as shown in FIG. The image written at the timing of (1) at the position of “G” of the black photosensitive drum 222a (the reference of drive unevenness is indicated by line a for clarity) is the timing of (4) (at the position of the photosensitive drum 222a). After the time required for 180 ° rotation has elapsed), the image is transferred onto the transfer / conveying belt 216, and is superimposed on the image on the cyan photosensitive drum 222b at the timing (9). Here, an image has already been formed on the cyan photosensitive drum 222b by the laser beam at the timing (6). FIG. 3A shows the position of the line a of the cyan photosensitive drum 222b at the timings (1) to (6). As is clear from the figure, the line a at the timing (9) is located at the same position as the black photosensitive drum 222a at the timing (4). Therefore, the driving unevenness of the superposed images is the same, and there is no color shift due to the influence of the driving unevenness.
[0047]
Similarly, the image formed on the magenta photosensitive drum 222c is superimposed at the timing (14). Here, an image has already been formed on the magenta photosensitive drum 222c at the timing (11). FIG. 3B shows the position of the line a of the magenta photosensitive drum 222c at the timings (1) to (11). As is clear from the figure, the line a at the timing (11) is located at the same position as the black and cyan photosensitive drums at the timings (1) and (6). Therefore, the superimposed images have the same driving unevenness, and there is no color shift due to the influence of the driving unevenness.
[0048]
Similarly, the image formed on the yellow photosensitive drum 222d is superimposed at the timing (19). Accordingly, an image has already been formed on the yellow photosensitive drum 222d at the timing of (16). FIG. 3C shows the position of the line a of the yellow photosensitive drum 222d at the timings (1) to (16). As is clear from the figure, the line a at the timing (16) is located at the same position as the black and cyan photosensitive drums at the timings (1), (6) and (11). Therefore, the superimposed images have the same driving unevenness, and there is no color shift due to the influence of the driving unevenness. The rotational driving of the four photosensitive drums 222a to 222d is controlled by the control unit CON shown in FIG. 4 based on the reference mark Q that can specify the driving unevenness of each photosensitive drum.
[0049]
Hereinafter, the rotation drive control of the photosensitive drum will be described with reference to FIGS. 4 and 5. As shown in FIG. 4, a key-shaped mark (convex portion) ha is provided in a hole of the drive gears G1 to G4 for transmitting a rotational drive force to the photosensitive drums 222a to 222d in the digital color copying machine of the present embodiment. The pins provided on the shafts engage with the protrusions ha, so that any of the shafts connected to the drive mechanism having the same configuration is rotationally driven with a constant periodic drive unevenness characteristic. .
Since the image carrier (photosensitive drum) is also supported in a predetermined positional relationship with respect to the shaft that is rotationally driven, the periodic drive unevenness in each photosensitive drum is reduced. , All become almost identical.
[0050]
Further, as shown in FIG. 4, the reference marks Q attached to the drive gears G1 to G4 are detected by detection sensors S1 to S4 including optical sensors and the like, respectively.
Each of the sensors S1 to S4 is attached at the same position from each transfer portion A. The sensor output is sent to the control unit CON, and based on this, the control unit CON controls the motors M that independently drive the respective photosensitive drums.
The sensors S1 to S4 are described to detect the reference marks Q attached to the drive gears G1 to G4 and to control the stop position of the photoconductor. However, in other sequences, It is also used as a reference for correcting the conditions for forming an image formed on each photosensitive drum by detecting the reference mark Q (for details, see Japanese Patent Application Laid-Open No. 6-51551). The position of the reference mark Q will be described with reference to a drive gear. However, any position may be used as long as the rotation of the photosensitive drum can be detected. For example, a portion that does not hinder image formation of the photosensitive drum may be used. Is also good.
[0051]
The control unit CON includes a first control unit that controls an image forming process on the photosensitive drum based on a detection result (signal) from each sensor based on a different sequence, and the stop position of each photosensitive drum is in a predetermined positional relationship. And a second control means for controlling so as to reliably stop at each stop position so that each control sequence is automatically performed when a predetermined condition and a predetermined timing (timing) are reached.
[0052]
FIG. 5 shows a timing chart of the outputs of the sensors S1 to S4 when the photosensitive drum is stopped. The reference mark Q is detected and turned on sequentially from the sensor S4 of the photosensitive drum 222d located on the downstream side, and the sensor Sl of the photosensitive drum 222a located on the most upstream side is turned on last.
After the last sensor S1 is turned ON, the time required for the reference mark Q shown in FIG. 4 to reach the transfer portion A (here, the time required to rotate about 90 degrees) is defined as a margin time and a margin angle. Then, the photosensitive drum 222a is stopped.
In the photosensitive drums 222b to 222d other than the reference photosensitive drum 222a, the correction amount is detected from the detection results of the sensors S2 to S4 and the detection result of the sensor S1, and the correction amount is added to the extra time. Later, when that time has elapsed, the operation is stopped.
[0053]
For example, when the photosensitive drum 222b for cyan is considered, there is a shift of 60 degrees between the photosensitive drum 222b and the reference photosensitive drum 222a. Therefore, the correction amount of the photosensitive drum 222b is calculated from the timing when the sensor S1 is turned on and the timing when the sensor S2 is turned on. In this case, if the interval is 61 degrees and is advanced by 1 degree, it is necessary to return it once. Therefore, the correction amount is set to −1, this is added to 90 degrees of the extra time, and the extra time is 89 After the sensor S1 is turned on and the margin time for 89 degrees has elapsed, the operation is stopped.
[0054]
If the above-mentioned margin time is not set, if the correction amount is positive, the photosensitive drum 222b may be further rotated and stopped by that much, but if it is negative, the photosensitive drum 222b has already passed the stop position. In order to stop at the correct position, it is necessary to make one more rotation. If this is done, the surface of the transfer conveyance belt 216 and the surface of the photosensitive drum will be damaged by contact. While suppressing, it is possible to stop in a state where an ideal image can be recorded in a short time, and the subsequent image recording can be smoothly performed.
[0055]
A stepping motor is most suitable as a motor for individually driving the photosensitive drums.
That is, the pulse motor generates a holding torque by energizing and energizing, and can easily be locked without rotating at a certain position, and can prevent the image carrier that does not perform image formation from rotating and moving due to external force. In addition, the pulse motor can perform high-precision rotation in an open loop in accordance with the set drive pulse signal, and can easily perform positioning at the set rotation position.
Therefore, the photosensitive drum that is not used can be securely locked, and the photosensitive drum used for image formation can be accurately and easily positioned so that the rotational phase with the unused photosensitive drum is in a predetermined phase state. Can be.
Further, by using the pulse motor, a high-precision rotation operation can be realized in an open loop while the rotation phase of the photosensitive drums is in a predetermined state when all the photosensitive drums are operating.
[0056]
Further, no matter how precisely the dimension between the transfer sections A-A is set, if the mounting position of the photosensitive drum is shifted and there is an error of only 100 μm in the dimension, 600 dpi (diameter of one dot: 43 μm) In the image forming apparatus for high-density recording such as (approximately), a large color shift appears. Therefore, it is desirable to additionally provide a means for adjusting the stop position of each photosensitive drum regardless of the drive unevenness of the photosensitive drum. Similarly, an error is likely to occur in the mounting position of the above-described sensors S1 to S4. Therefore, it is desirable that the configuration be such that such an error can be corrected.
[0057]
Specifically, any configuration may be used as long as the above-mentioned margin time (margin angle) can be adjusted for each photosensitive drum. That is, in the above description, the allowance time is set to 90 degrees for all four photosensitive drums. However, the allowance time is corrected in advance in accordance with the sensor mounting error and the dimensional error between the transfer units, and the corrected allowance is used. It is only necessary to newly add (subtract) the correction amount at the time of stop to the time.
[0058]
Further, since it is difficult to correct these errors in advance, a method of adjusting a stop position of each photoconductor automatically or manually by outputting a specific test image in an adjustment process after assembly is completed. Good.
[0059]
Next, a method of supporting the photosensitive drum on the shaft that is driven to rotate as described above will be described with reference to FIG.
First, the configuration of the photoconductors 222a to 222d and the peripheral devices and the procedure for attaching the photoconductors to the copying machine 1 shown in FIG. 1 will be described below with reference to FIG. Although FIG. 6 illustrates the photoconductor drum 222a as a representative because of the side sectional view, the photoconductors 222b to 222d have the same configuration. Further, since the constituent members of each image station are common, (a) to (d) described after the member numbers are omitted.
6, only the photosensitive drum 222a in the process unit 2 in which the image station Pa (FIG. 1) is unitized is illustrated, and illustration and description of other chargers, developing devices, cleaning devices, and the like are omitted. .
[0060]
The cylindrical photosensitive drum 222a has flanges 4a to 4b fixed to both ends, and a shaft 6 penetrates the center of the photosensitive drum 222a in the longitudinal direction through the drum flanges 4a to 4b. The positioning of the photoreceptor 222a in the main body of the copying machine 1 (FIG. 1) is performed by passing the shaft 6 therethrough.
[0061]
The process unit 2 is installed in the process unit support frame 3, and when replacing the unit due to the life of the photosensitive drum 222a or the like, the process unit 2 is pulled out from the copying machine 1 and then replaced. After replacing the process unit 2 with a new process unit, the process unit support frame 3 is mounted again on the copying machine 1 main body.
[0062]
Next, the configuration of the main unit on which the process unit support frame 3 is mounted will be described. The driving force of the motor 7 in the drive unit DU is transmitted to the shaft 6 via the motor gear 8 and the shaft gear 9.
The shaft 6 is provided inside the apparatus main body 1 by a bearing 10A (including a bearing) fixed to the rear frame 14 of the apparatus main body 1 via the holding block 5 and a bearing 10B held by the frame FL of the drive unit DU. It is installed to rotate.
[0063]
A flywheel 17 for stabilizing the rotation of the photoconductor 222a is supported by a support portion 13 at a right end 6R of the shaft 6 as viewed in FIG. Stable rotation is compensated to some extent.
In addition, the holding block 5 is configured so that the axis of the shaft 6 and the axis of the process unit 2 are the same by performing positioning by fitting with the process unit 2 as well as the shaft 6. ing.
[0064]
That is, in the present embodiment, the holding block 5 is formed into a cylindrical shape in accordance with the outer shape of the shaft 6, so that the axis of the shaft 6 and the axis of the process unit 2 and the axis of the holding block 5 are aligned. The concentricity is easily realized, and the blur caused by the displacement of the axis between the shaft 6 and the process unit 2 is eliminated.
[0065]
Next, a procedure for attaching the process unit 2 to the main device will be described.
The process unit 2 fits an opening-shaped connection portion 3R formed on the back side (the right side in FIG. 6) of the process unit support frame 3 to the projection 5A of the holding block 5 supported by the back frame 14, and Positioning is performed by fixing the connection portion 3F on the front side (left side in FIG. 6) of the process unit support frame 3 to the front frame 12 of the apparatus main body 1 using the fixing screw 11.
[0066]
The photosensitive member 222a is positioned such that the shaft 6 penetrates through the inside of the photosensitive member 222a in the rotation axis direction, and the distal end portion 6F of the shaft 6 is engaged with a bearing 10C provided on the front side of the process unit support frame 3. Is held.
[0067]
Next, a description will be given, with reference to FIG. 7, of a phase adjustment stop control operation of the photosensitive drum when only some of the image stations are used, for example, when black and white copying is performed. When black and white copying is performed by the image forming apparatus, only the image station Pa having the photosensitive drum 222a for forming a black image may be used. Therefore, since the image stations Pb to Pd having the remaining photosensitive drums 222b, 222c, and 222d do not need to be used, these photosensitive drums are not driven to rotate and are stopped.
[0068]
However, if the photoconductor drums 222b to 222d that are not rotationally driven are present, both of them are abnormally worn due to the rubbing with the rotating transfer / conveying belt 216. Therefore, as shown in FIG. The photosensitive drums 222b to 222d are stopped from rotating.
[0069]
The separation between the photosensitive drums 222b to 222d and the transfer conveyance belt 216 is realized by supporting the drive roller 214 of the transfer conveyance belt 216 downward and the driven roller 215 slightly upward. The separating unit is not limited to the above-described unit, and may be a unit that moves the photosensitive drums 222b to 222d upward without moving the transfer / conveying belt 216, for example.
[0070]
The photosensitive drums 222b to 222d whose rotation is stopped are locked by energizing the separately provided pulse motor 7 and exciting them to generate a holding torque. This prevents the drum from shifting and ensures the phase state when the rotation is stopped.
[0071]
As shown in FIG. 7, the photosensitive drums 222b to 222d in the above-mentioned stopped state include a position where the photosensitive member 222b is advanced by 60 degrees, a position where the photosensitive member 222c is advanced by 120 degrees, and a position where the photosensitive member 222d is advanced by 180 degrees. The rotation position is kept shifted by the set phase.
[0072]
The method of locking the photosensitive drum is not the lock by the excitation of the driving pulse motor 7, but an electromagnetic brake provided in the drive unit DU so as to cover the circumferential direction of the shaft 6 as shown in FIG. 20 or another mechanical lock mechanism (not shown) may be used.
[0073]
The photosensitive drum 222a to form areas of black and white images, the pulse by the motor 7 is driven rotated image is formed, the formed image is transferred onto the transfer medium P image forming process after the end, sensor Sl during rotation As a result, the reference mark Q of the photosensitive drum 222a is detected, and the photosensitive drum 222a is stopped in a preset phase state. At this time, since the photoconductor drums 222b to 222d that have stopped rotating maintain the predetermined phase state, all the photoconductors 222a to 222d match the preset phase state, and the next copy is performed. Even if a color image is formed, an operation for forming a good color image without color shift can be started immediately.
[0074]
Therefore, in an image forming apparatus capable of performing color copying and black-and-white copying, during frequent black-and-white copying, the rotational phase control of the photosensitive drums 222a to 222d can be performed without operating all the photosensitive drums. It is possible to prevent the life of the photosensitive drums 222b to 222d from being shortened due to useless rotation and wasteful energy consumption. Further, the rotation phase control can be simplified and the execution time can be shortened.
Although the present embodiment has been described for the case of forming a black-and-white image, the transfer / transport belt 216 for carrying / transferring the transfer medium P can be separated for each photoconductor, so that the transfer / transfer belt 216 can be separated only at the time of monochrome image formation. Similarly, in the formation of one-color images such as yellow, magenta, and cyan, and the formation of two-color images such as red, green, and blue, similarly, the photosensitive drums that are not used are stopped and the photosensitive drums that are used are stopped. Needless to say, stop control for stopping the rotation phase and the predetermined state can be performed.
[0076]
【The invention's effect】
As described above, according to the first aspect of the present invention, the image carrier not used for image formation is maintained in the rotation stopped state, and the rotation phase of only the image carrier used for image formation is used for the image formation. In order to match the phase state of the image carrier that has not been performed, it is not necessary to rotate the image carrier not used for image formation only to adjust the rotational phase, so that control can be simplified and the time required for positioning can be shortened. It is possible to reduce unnecessary operation as much as possible and extend the life of the image carrier and the like.
[0077]
In addition, when the image carriers are stopped (when the image forming apparatus is stopped), the rotation phases of all the image carriers are matched, so that a plurality of image carriers for the next full-color image formation or the like are simultaneously operated. Image formation can be started immediately without performing control to match the rotational phase state of the image carrier at the start of image formation to be used.
[0078]
Further, in order to maintain and lock the image carrier which is not used for image formation by the driving means by, for example, a locking means or the like, the image forming apparatus does not perform image formation due to external force such as vibration of the apparatus while the image forming apparatus is operating. It is possible to prevent the image carrier from rotating. Therefore, the phase relationship between the image carriers not used for image formation can be maintained in accordance with the predetermined state, so that only the image carrier on which the image is formed is rotated to lock the phase of the image carrier. By adjusting to the state, an accurate rotational phase state can be formed.
[0079]
According to the second aspect of the present invention, it is possible to generate a holding torque by energizing and exciting a motor of a driving unit that drives an image carrier that does not perform image formation, thereby preventing rotation movement due to external force, The rotation of the image carrier can be easily and inexpensively realized without the need for a mechanical member for mechanically locking the image carrier.
[0080]
According to the third aspect of the present invention, the pulse motor generates a holding torque by being energized and excited, and can be easily locked without rotating at a certain position, and can be easily locked by an external force of the image carrier that does not perform image formation. Rotational movement can be prevented.
In addition, the pulse motor can perform high-precision rotation in an open loop according to the set driving pulse signal, and can easily position the motor at the set rotation position. Therefore, the unused image carrier can be securely locked, and the image carrier used for image formation can be accurately and easily positioned so that the rotational phase of the unused image carrier becomes a predetermined phase state. Can be.
In addition, by using a pulse motor, a high-precision rotation operation can be realized in an open loop while the rotation phase of the image carriers is in a predetermined state when all the image carriers are operating.
[0081]
According to the fourth aspect of the present invention, the image carrier whose rotation has been stopped is partially rubbed with the carrier by separating the carrier and the image carrier not used for image formation. As a result, it is possible to prevent a part of the surface from being significantly worn to prevent image formation failure and to prolong the life thereof.
[Brief description of the drawings]
FIG. 1 is a side sectional view of an image forming apparatus according to an embodiment of the present invention.
FIG. 2 is an explanatory diagram showing a rotational phase relationship between photosensitive drums arranged in parallel according to the embodiment of the present invention.
FIG. 3 is an operational explanatory diagram showing an overlapping state of image formation according to the embodiment of the present invention.
FIG. 4 is an explanatory diagram for controlling rotation stop positions of a plurality of photosensitive drums according to the embodiment of the present invention.
FIG. 5 is a time chart showing rotation stop positions of a plurality of photosensitive drums according to the embodiment of the present invention.
FIG. 6 is a sectional view of a photosensitive drum supporting portion of the image forming apparatus according to the embodiment of the present invention.
FIG. 7 is a functional explanatory diagram showing a plurality of photosensitive drums and a transfer belt during black and white copying according to the embodiment of the present invention.
FIG. 8 is an explanatory diagram showing a rotation phase relationship of each photosensitive drum arranged in parallel according to the related art.
[Explanation of symbols]
1 Image Forming Apparatus 216 Transfer Conveying Belts 222a to 222d Photoconductor Drum M Motor Q Reference Mark CON Control Units G1 to G4 Drive Gears S1 to S4 Sensor

Claims (4)

First and second image carriers having the same peripheral length and sequentially provided from the upstream side to the downstream side of the recording medium transport path ;
First and second driving means for rotating and stopping the first and second image carriers;
A first reference mark indicating a reference position of rotational drive unevenness of the first image carrier due to periodic drive unevenness of a drive system of the first drive unit;
A second reference mark indicating a reference position of rotational drive unevenness of the second image carrier due to periodic drive unevenness of the drive system of the second drive unit;
First and second detecting means for detecting the first and second reference marks,
The first, based on a detection result of the second detecting means, and a first, phase control means for performing phase matching rotation stop control of the second image bearing member,
The phase matching rotation stop control includes a first stop position of the first reference mark with respect to a transfer position of the first image carrier, and a second reference mark with respect to a transfer position of the second image carrier. A phase shift X is provided between the first and second image carriers to stop the first and second image carriers;
The relationship between the distance L between the first and second transfer positions and the phase shift X is
L = perimeter of first or second image carrier × (360−X) degrees / 360 degrees
age,
When stopping the rotating first and second image carriers, the phase control unit may include:
A second fiducial mark detecting step of detecting the second fiducial mark of the second image carrier located on the downstream side by the second detecting means;
A first fiducial mark detecting step of detecting the first fiducial mark of the first image carrier located on the upstream side by the first detecting means after the second fiducial mark detecting step;
Obtaining a detection time from the detection of the second reference mark to the detection of the first reference mark;
Detecting a correction amount for matching the detection time with a time corresponding to the phase shift X;
Stopping the first driving means after a first margin time has passed since the detection of the first reference mark;
Stopping the second driving means after a second margin time obtained by adding the correction amount to the first margin time from the time of detecting the first reference mark;
The first and second driving units maintain the first and second image carriers not used for image formation in a rotation stopped state,
The phase control means, at the end of image formation, the image carrier used for the image formation at a position where the rotation phase state with the image carrier in a rotation stopped state without performing the image formation is the phase shift X. images forming device, characterized in that stopping. First and second image carriers having the same peripheral length and sequentially provided from the upstream side to the downstream side of the recording medium transport path;
First and second driving means for rotating and stopping the first and second image carriers;
A first reference mark indicating a reference position of rotational drive unevenness of the first image carrier due to periodic drive unevenness of a drive system of the first drive unit;
A second reference mark indicating a reference position of rotational drive unevenness of the second image carrier due to periodic drive unevenness of the drive system of the second drive unit;
First and second detecting means for detecting the first and second reference marks,
Phase control means for performing phase adjustment rotation stop control of the first and second image carriers based on the detection results of the first and second detection means,
The phase matching rotation stop control includes a first stop position of the first reference mark with respect to a transfer position of the first image carrier, and a second reference mark with respect to a transfer position of the second image carrier. A phase shift X is provided between the first and second image carriers to stop the first and second image carriers;
The relationship between the distance L between the first and second transfer positions and the phase shift X is
L = perimeter of first or second image carrier × (360−X) degrees / 360 degrees
age,
When stopping the rotating first and second image carriers, the phase control unit may include:
A second fiducial mark detecting step of detecting the second fiducial mark of the second image carrier located on the downstream side by the second detecting means;
Detecting the first reference mark of the first image carrier positioned upstream by the first detection unit after the second reference mark detection step;
Obtaining a detection time from the detection of the second reference mark to the detection of the first reference mark;
Detecting a correction amount for matching the detection time with a time corresponding to the phase shift X;
Stopping the first driving means after a first margin angle rotation from the time of detecting the first reference mark;
Stopping the second driving means after a second margin angle rotation in which the correction amount is added to the first margin angle from the time of detecting the first reference mark;
The first and second driving means maintain an image carrier not used for image formation in a rotation stopped state,
The phase control means, at the end of image formation, the image carrier used for the image formation at a position where the rotation phase state with the image carrier in a rotation stopped state without performing the image formation is the phase shift X. An image forming apparatus to be stopped . It said first, second drive means, an image forming apparatus according to claim 1 or 2, wherein the maintaining the rotation stopped state of the image carrier is not used for image formation by energizing the motor. Said image bearing member which is not used for image formation, the image forming apparatus according to claim 1, wherein that the conveyance carrier for conveying a recording medium and a non-contact.

Images