1. Field of the Invention
The present invention is directed to an image forming apparatus including a recording head that jets liquid droplets.
2. Description of the Related Art
Among image forming apparatuses such as printers, facsimile machines, copiers, plotters and multifunction peripherals having the aforementioned functions for performing image formation, there are liquid jet recording image forming apparatuses including a recording head for jetting, for example, ink droplets. An ink jet recording apparatus is known as an example of such liquid jet recording image forming apparatuses. The liquid jet recording image forming apparatuses jet ink droplets from the recording head onto a sheet being transferred to form an image on the sheet. It is to be noted that the term “sheet” in the present application is not limited only to paper, and refers to a medium onto which ink droplets or another type of liquid is allowed to adhere. Examples of such a medium include an OHP film. The term “sheet” may be referred to also as “recording target”, “recording medium”, and “recording sheet”. Furthermore, in this application, the terms “recording”, “printing” and “imaging” are used synonymously with the term “image forming”. There are different types of liquid jet recording image forming apparatuses, such as, a serial-type image forming apparatus which forms an image by causing a recording head to jet liquid droplets while moving in the main scanning direction; and a line-type image forming apparatus which forms an image by causing a line-type recording head in a stationary position to jet liquid droplets.
It is also to be noted that the term “image forming apparatus” in the present application refers to an apparatus for forming an image by jetting liquid onto a medium made of, for example, paper, textile threads, fibers, fabric, leather, metal, plastic, glass, wood or ceramic. In addition, the term “image forming” includes forming not only an image having meaning (e.g. characters, figures and symbols) but also an image having no particular meaning (e.g. patterns) on a medium. In this sense, simply depositing liquid droplets on a medium is also regarded as “image forming”. The term “ink” is not only directed to substances called ink, but is used as a generic term for all liquid substances allowing image formation, such as recording liquids and fixing liquids.
Such liquid jet recording image forming apparatuses, particularly ones that form an image by causing a carriage having a recording head for jetting liquid droplets to travel in a reciprocating motion (i.e. moving alternately backward and forward), have the following problem. That is, in the case of printing bidirectionally, positional misalignment tends to occur if the printed image is a ruled line. Also, in superposing different colors, a color registration error is likely to occur.
In the case of ink jet recording apparatuses, these problems are handled generally in such a manner that the user selects and inputs optimal values with reference to an output test chart for adjusting misalignment of landing positions of liquid droplets so that the jetting timing is adjusted based on the input results. However, the test chart is subject to individual interpretation, and data input errors may occur due to inexperienced users, thus possibly posing greater problems in the adjustment.
In order to address the problems associated with the test chart, conventionally, a test pattern is formed on a conveying belt or a media conveying member and then read by a sensor (see, for example, Patent Documents 1, 2 and 3).
Patent Document 4 discloses a technique for forming on recording paper a test pattern, which is then read by a sensor.
Patent Document 5 discloses a technique in which a positional misalignment correction pattern is formed on a conveying belt and then read by a sensor for detecting the presence or absence of the positional misalignment correction pattern. A filter process is subsequently performed on an output of the sensor using a filter for cutting off frequency components higher than a frequency of the positional misalignment correction pattern. Patent Document 5 discusses that positional misalignment can be corrected by removing high-frequency component noise in this manner.
However, in the case of forming a test pattern on a conveying belt or a medium and reading it by a sensor as described above, it is difficult to accurately read the test pattern if there is a small difference between, for example, the color of the conveying belt and the color of an ink used. In order to achieve accurate color detection, a structure is needed such that colors are detected using, for example, light sources having different wavelengths corresponding to respective colors, however, in practice, conventional techniques cannot accurately read the test pattern formed on the conveying belt.
For example, assume that the conveying belt is an electrostatic adsorption belt including an insulating layer on its surface and a medium resistance layer on its rear surface, and carbon is mixed in the medium resistance layer to provide conductivity. In this case, the color of the conveying belt is black, and therefore, pattern detection by measuring only color reflectance has little success since the conveying belt cannot be distinguished from black ink.
In order to resolve this problem, the following technique for accurately detecting the position and positional misalignment of the pattern may be considerable. First, a pattern is formed on a water-repellent pattern formation member so that the pattern is made up of isolated ink droplets. The ink droplets have the characteristic of being separately formed in a hemispherical shape. Using this characteristic, a single-wavelength light beam is projected onto the pattern on the pattern formation member. The specularly reflected light of the projected light beam attenuates over the pattern with the ink droplets, whereby the position and positional misalignment of the pattern can be accurately detected.
However, if a conveying belt, for example, is used as the water-repellent pattern formation member, the surface of the conveying belt changes over time. It is also subject to accidental scratches and dirt build-up caused by paper-dust and paper-jam removing operations. By simply eliminating high-frequency component noise as described in Patent Document 5, low-frequency noise cannot be removed that are caused due to such accidental scratches and dirt as well as the time degradation of the belt, thus interrupting accurate pattern detection.
In view of the above-described issues, the present invention aims at maintaining at a stable level pattern detection accuracy and accuracy of correcting the liquid droplet landing positions.
In order to resolve the above-mentioned problems, one embodiment of the present invention may be an image forming apparatus including a carriage having a recording head for jetting liquid droplets; a pattern forming unit configured to form, on a conveying belt, an adjustment pattern used for detecting displacement of landing positions of the liquid droplets; a reading unit mounted on the carriage, including a light emitting unit and a light receiving unit, and configured to scan and read the conveying belt before the adjustment pattern is formed so as to output a first reading result, and scan and read the adjustment pattern on the conveying belt so as to output a second reading result; a correcting unit configured to correct the displacement of the landing positions based on the second reading result; a frequency analyzing unit configured to calculate frequencies of the surface of the conveying belt and amplitudes of respective frequency components based on the first reading result; and a peak frequency calculating unit configured to calculate one or more peak frequencies of the surface of the conveying belt based on the frequencies of the surface of the conveying belt and the amplitudes of the frequency components, the peak frequencies being one or more of the frequency components whose amplitude exceeds a predetermined level. The pattern forming unit forms the adjustment pattern at a frequency different from the peak frequencies.
Embodiments that describe the best mode for carrying out the present invention are explained next with reference to the drawings. The following outlines one example of the image forming apparatus of the present invention which implements a method for correcting liquid droplet landing positions, with reference to
The image forming apparatus includes an image forming unit 2 and a sub scanning conveying unit 3 disposed inside an apparatus main body 1 (inside a casing). The image forming unit 2 is for forming images while sheets are being conveyed. The sub scanning conveying unit 3 is for conveying sheets. A sheet feeding unit 4 including a sheet feeding cassette disposed at the bottom of the apparatus main body 1 feeds sheets 5 one by one. The sub scanning conveying unit 3 conveys the sheet 5 to a position facing the image forming unit 2. While the sheet 5 is being conveyed, the image forming unit 2 jets liquid droplets onto the sheet 5 to form (record) a desired image. Subsequently, the sheet 5 is ejected, through a sheet eject conveying unit 7, onto a sheet eject tray 8 formed in the upper section of the apparatus main body 1.
Furthermore, the image forming apparatus includes, above the sheet eject tray 8 in the upper section of the apparatus main body 1, an image scanning unit (scanner unit) 11 for scanning images, which is an input system for image data (printing data) to be used by the image forming unit 2 to form an image. In the image scanning unit 11, a scanning optical system 15 including an illumination light source 13 and a mirror 14, and a scanning optical system 18 including mirrors 16 and 17 are moved along for scanning an image of an original placed on a contact glass 12. The scanned original image is read as image signals by an image reading element 20 disposed behind a lens 19. The image signals that have been read are converted into digital signals. An image processing operation is performed on these digital signals. The image-processed printing data can be printed out as an image.
As shown in
As shown in
A total of five liquid droplet jetting heads are provided in the carriage 23. Specifically, there are recording heads 24k1, 24k2, which are two liquid droplet jetting heads for jetting black (K) ink, and recording heads 24c, 24m, and 24y, each including one liquid droplet jetting head for jetting cyan (C) ink, magenta (M) ink, and yellow (Y) ink, respectively (hereinafter referred to as “recording head 24” when the colors need not be distinguished and when referred to collectively). This carriage 23 is a shuttle type carriage that moves in the main scanning direction to form images by jetting liquid droplets from the recording heads 24, while the sheet 5 is being conveyed in the sheet conveyance direction (sub scanning direction) by the sub scanning conveying unit 3.
Furthermore, sub tanks 25 are provided in the carriage 23 for supplying recording liquid of necessary colors to the recording heads 24. Meanwhile, as shown in
The recording head 24 can be a piezo type head, a thermal type head, or an electrostatic type head. In the piezo type head, a piezoelectric element is used as a pressure generating unit (actuator unit) for pressurizing the ink inside an ink flow path (pressure generating chamber). The walls of the ink flow path are formed with oscillating plates. These oscillating plates are caused to deform by the piezoelectric element, so that the volume inside the ink flow path changes and ink droplets are jetted outside. In the thermal type head, a heating element is used to heat the ink in the ink flow paths so that bubbles are generated. Due to pressure caused by these bubbles, the ink droplets are jetted outside. In the electrostatic type head, an oscillating plate forming a wall of the ink flow path is disposed in such a manner as to face an electrode. An electrostatic force is generated between the oscillating plate and the electrode. This electrostatic force causes the oscillating plate to deform, so that the volume inside the ink flow path changes and ink droplets are jetted outside.
Furthermore, a linear scale 128 having slits is stretched across from the front side plate 101F to the rear side plate 101R along the main scanning direction of the carriage 23. The carriage 23 is provided with an encoder sensor 129 that is a transmission photosensor for detecting the slits of the linear scale 128. The linear scale 128 and the encoder sensor 129 form a linear encoder for detecting movements of the carriage 23.
On one side of the carriage 23, a pattern reading sensor 401 is provided, which is a reading unit (detecting unit) configured with a reflection photosensor including a light emitting unit and a light receiving unit for reading a landing position detection adjustment pattern (hereinafter referred to as “adjustment pattern”) according to an embodiment of the present invention. This pattern reading sensor 401 reads an adjustment pattern formed on a conveying belt 31, as described below. On the other side of the carriage 23, a sheet member detecting unit (leading edge detecting sensor) 330 is provided, which is a reflection photosensor for detecting the leading edge of a material being conveyed.
In a non-printing region on one side of the carriage 23 in the scanning direction, there is provided a maintaining/recovering mechanism (device) 121 for maintaining and recovering the operability of the nozzles of the recording head 24. This maintaining/recovering mechanism 121 is a cap member for capping a nozzle face 24a (see
As shown in
The conveying belt 31 is configured to revolve in the sheet conveyance direction (sub scanning direction) as the conveying roller 32 is rotated by a sub scanning motor 131 using a DC brushless motor via a timing belt 132 and a timing roller 133. As shown in
Furthermore, a Mylar unit (paper dust removing unit) 191, a cleaning brush 192, and a discharging brush 193 are provided between the subordinate roller 33 and the charging roller 34, arranged in this order from the upstream side of the movement direction of the conveying belt 31. The Mylar unit 191 is a cleaning unit for removing paper dust, etc., adhering to the surface of the conveying belt 31. The Mylar unit 191 is an abutment member made of a PET film, which abuts the surface of the conveying belt 31. The cleaning brush 192 is a brush that also abuts the surface of the conveying belt 31. The discharging brush 193 is for removing electric charges from the surface of the conveying belt 31.
Moreover, a high-resolution code wheel 137 is attached to a shaft 32a of the conveying roller 32. An encoder sensor 138 is provided, which is a transmission photosensor for detecting slits 137a formed on this code wheel 137. The code wheel 137 and the encoder sensor 138 form a rotary encoder.
The sheet feeding unit 4 includes a sheet feeding cassette 41, a sheet feeding roller 42, a friction pad 43, and a pair of resist rollers 44. The sheet feeding cassette 41 is an accommodation unit for accommodating multiple stacked sheets 5, and further, the sheet feeding cassette 41 can be inserted in/removed from the apparatus main body 1. The sheet feeding roller 42 and the friction pad 43 are for separating the sheets 5 in the sheet feeding cassette 41 from each other and sending them out one by one. The resist rollers 44 are for resisting the sheet 5 being fed.
Furthermore, the sheet feeding unit 4 includes a manual feed tray 46, a manual feed roller 47, and a vertical conveying roller 48. The manual feed tray 46 is for accommodating multiple stacked sheets 5. The manual feed roller 47 is for feeding the sheets 5 one by one from the manual feed tray 46. The vertical conveying roller 48 is for conveying the sheet 5 that is fed from a sheet feeding cassette that is optionally installed at the bottom of the apparatus main body 1 or from a double-side unit. Members for feeding the sheet 5 to the sub scanning conveying unit 3, such as the sheet feeding roller 42, the resist rollers 44, the manual feed roller 47, and the vertical conveying roller 48, are rotated by a sheet feeding motor (driving unit) 49 that is an HB type stepping motor, via a not-shown electromagnetic clutch.
The sheet eject conveying unit 7 includes three conveying rollers 71a, 71b, and 71c (referred to as “conveying rollers 71” when not distinguished) and spurs 72a, 72b, and 72c (referred to as “spurs 72” when not distinguished) that face the conveying rollers 71, a pair of reverse rollers 77, and a pair of reverse sheet eject rollers 78. The conveying rollers 71 are for conveying the sheet 5 which has been separated from the conveying belt 31 by the separating claw 39 of the sub scanning conveying unit 3. The reverse rollers 77 and the reverse sheet eject rollers 78 are for reversing the sheet 5 and sending the sheet 5 face-down to the sheet eject tray 8.
Furthermore, in order to manually feed a single sheet, as shown in
Meanwhile, in order to eject the sheet 5 on which an image has been formed face-up and in a straight manner, a straight sheet eject tray 181 that can be opened and closed (unfolded) is provided on the other side of the apparatus main body 1. By opening (unfolding) this straight sheet eject tray 181, the sheet 5 that is sent out from the sheet eject conveying unit 7 can be linearly ejected to the straight sheet eject tray 181.
Next, an overview of a control unit of this image forming apparatus is described with reference to a block diagram shown in
A control unit 300 includes a main control unit 310 for controlling the entire apparatus as well as specific operations according to embodiments of the present invention such as pre-scanning, a frequency analysis, a peak frequency calculation, formation of adjustment patterns, detection of the adjustment patterns, and adjustment (correction) of landing positions. The main control unit 310 includes a CPU 301, a ROM 302 for storing a program to be executed by the CPU 301 and other fixed data, a RAM 303 for temporarily storing image data, etc., a nonvolatile memory (NVRAM) 304 for holding data even while the power of the apparatus is shut off, and an ASIC 305 for performing various signal processes on the image data, image processes such as sorting, and other processes on input/output signals to control the entire apparatus.
Furthermore, the control unit 300 includes an external I/F 311, a head driving control unit 312, a main scanning driving unit (motor driver) 313, a sub scanning driving unit (motor driver) 314, a sheet feed driving unit 315, a sheet eject driving unit 316, and an AC bias supplying unit 319. The external I/F 311 is provided between the host side and the main control unit 310 for transmitting/receiving data and signals. The head driving control unit 312 includes a head driver (actually provided in the recording head 24) configured with a head data generating rearranging ASIC for driving/controlling the recording head 24. The main scanning driving unit 313 is for driving the main scanning motor 27 to move the carriage 23. The sub scanning driving unit 314 is for driving the sub scanning motor 131. The sheet feed driving unit 315 is for driving the sheet feeding motor 49. The sheet eject driving unit 316 is for driving a sheet eject motor 79 which drives the rollers of the sheet eject conveying unit 7. The AC bias supplying unit 319 is for supplying an AC bias to the charging roller 34. Although not shown, the control unit 300 also includes a recovering system driving unit for driving a maintaining/recovering motor which drives the maintaining/recovering mechanism 121, a double side driving unit for driving a double side unit if the double side unit is installed, a solenoid driving unit (driver) for driving various solenoids (SOL), a clutch driving unit for driving electromagnetic clutches, and a scanner control unit 325 for controlling the image scanning unit 11.
Various detection signals of an environment sensor 234 for detecting, for example, the temperature and the humidity around the conveying belt 31 (environment conditions) are input to the main control unit 310. Detection signals of other not-shown sensors are also input to the main control unit 310. Furthermore, the main control unit 310 acquires necessary key input from various keys provided in the apparatus main body 1 such as a numeric keypad and a print start key, and outputs display information to an operations/display unit 327 including various display devices.
Moreover, output signals from the photosensor (encoder sensor) 129, which is a part of the linear encoder for detecting the above-described carriage position, are input to the main control unit 310. Based on these output signals, the main control unit 310 moves the carriage 23 back and forth in the main scanning direction by driving/controlling the main scanning motor 27 via the main scanning driving unit 313. Furthermore, output signals (pulses) from the photosensor (encoder sensor) 138, which is a part of the rotary encoder for detecting the movement amount of the above-described conveying belt 31, are input to the main control unit 310. Based on these output signals, the main control unit 310 moves the conveying belt 31 via the conveying roller 32 by driving/controlling the sub scanning motor 131 via the sub scanning driving unit 314.
The main control unit 310 pre-scans the conveying belt 31 using the reading sensor 401 and then carries out a frequency analysis for calculating frequencies of the surface of the conveying belt 31 and amplitudes of respective frequency components. Based on the obtained frequencies and amplitudes, the main control unit 310 calculates frequency components exceeding a predetermined level (referred to as “peak frequencies”) and forms an adjustment pattern on the conveying belt 31 at a frequency different from the calculated peak frequencies. The main control unit 310 performs a light emitting driving control operation for emitting light onto the formed adjustment pattern from the pattern reading sensor 401 installed in the carriage 23. Output signals from the light receiving unit are input to the main control unit 310 so as to read the adjustment pattern. From the reading results, the main control unit 310 detects the landing positional misalignment amount, and performs a control operation based on the landing positional misalignment amount to correct the timings at which liquid droplets are jetted from the recording heads 24 so as to eliminate the landing positional misalignment. This process is described in detail later.
When carrying out a maintenance/recovery operation of the recording heads 24, the main control unit 310 drives/controls a driving motor 239 of the maintaining/recovering mechanism 121 via a maintaining/recovering mechanism driving unit 238 so as to move up and down the caps 122, the wiper blade (wiper member) 124 and the like.
A brief description is given of an image forming operation of the image forming apparatus having the above configuration. The rotation amount of the conveying roller 32 for driving the conveying belt 31 is detected. According to the detected rotation amount, the sub scanning motor 131 is driven/controlled, and high voltage alternating current rectangular waves of positive and negative polarities are applied from the AC bias supplying unit 319 to the charging roller 34. Accordingly, positive and negative charges are alternately applied onto the conveying belt 31 in a striped manner with respect to the conveyance direction of the conveying belt 31. Thus, the conveying belt 31 is charged with predetermined charge widths so that a non-uniform electric field is generated.
The sheet 5 is fed from the sheet feeding unit 4, and is sent in between the conveying roller 32 and the first pressurizing roller 36. When the sheet 5 is sent onto the conveying belt 31, on which charges of positive and negative polarities are formed so that a non-uniform electric field is generated, the sheet 5 immediately becomes polarized according to the direction of the electric field. Then, the sheet 5 adheres onto the conveying belt 31 due to an electrostatic adhering force, so that it is conveyed along with the movement of the conveying belt 31.
The sheet 5 is intermittently conveyed by the conveying belt 31. The carriage 23 is moved in the main scanning direction to jet droplets of recording liquid from the recording heads 24 onto the stationary sheet 5 so as to record (print) an image. The leading edge of the sheet 5 which has undergone the printing operation is separated from the conveying belt 31 with the separating claw 39. The sheet 5 is then sent out to the sheet eject conveying unit 7 and is ejected onto the sheet eject tray 8.
Furthermore, during standby periods between printing (recording) operations, the carriage 23 is moved to the maintaining/recovering mechanism 121. The nozzle faces of the recording heads 24 are capped by the caps 122 so that the nozzles are maintained in a moist condition. This prevents jetting failures that may be caused when the ink becomes dry. Furthermore, a recovery operation is performed by suctioning the recording liquid through the nozzles and discharging viscous recording liquid and bubbles, where the recording heads 24 are capped by suction and moisture retention caps 122. By performing this recovery operation, ink adheres to the nozzle faces of the recording heads 24. In order to clean/remove this ink, the wiper blade 124 is used to wipe off the ink. Furthermore, before starting the recording operation or during the recording operation, the recording heads 24 perform idle jetting operations by jetting ink into the idle jetting reception section 125, which ink is unrelated to the recording operation. Accordingly, the jetting performance of the recording heads 24 can be maintained at a stable level.
Next, the units relevant to landing positional misalignment correction control in the image forming apparatus are described with reference to
As shown in
The pattern reading sensor 401 includes a light emitting element 402 and a light receiving element 403, which are arranged in a direction perpendicular to the main scanning direction, and are held and packaged in a holder 404. The light emitting element 402 is a light emitting unit for emitting light onto the adjustment pattern 400 on the conveying belt 31. The light receiving element 403 is a light receiving unit for receiving specularly reflected light from the adjustment pattern 400. A lens 405 is provided at the light beam outgoing part and the light beam incoming part of the holder 404.
Inside the pattern reading sensor 401, the light emitting element 402 and the light receiving element 403 are arranged in a direction perpendicular to the main scanning direction of the carriage 23, which main scanning direction is indicated in
When a landing positional misalignment correction operation is directed, an adjustment pattern forming/reading control unit 501 performs pre-scanning by causing the carriage 23 to scan in the main scanning direction so that the reading sensor 401 reads the surface of the conveying belt 31. Then, a sensor output from the reading sensor 401 is read and detected by a frequency analyzing unit 507.
Based on the sensor output of the reading sensor 401, the frequency analyzing unit 507 calculates frequencies of the surface of the conveying belt 31 and amplitudes of respective frequency components, and outputs them to a peak frequency calculating unit 508. Based on the calculations of the frequency analyzing unit 507, the peak frequency calculating unit 508 calculates only frequency components exceeding a predetermined level (peak frequencies), and gives the calculated frequency components to the adjustment pattern forming/reading control unit 501.
In response, the adjustment pattern forming/reading control unit 501 causes, via a liquid droplet jetting control unit 502, the recording heads 24 functioning as liquid droplet jetting units to jet liquid droplets while causing the carriage 23 to scan the conveying belt 31 in the main scanning direction. Accordingly, the line-shaped reference and measurement patterns 400a and 400b (collectively referred to as “adjustment pattern 400”) are formed with multiple isolated liquid droplets 500. At this point, the reference pattern 400a and the measurement pattern 400b are formed in such a manner that a frequency of the adjustment pattern 400 (hereinafter, “pattern frequency”) is different from the frequencies of the belt surface.
The adjustment pattern forming/reading control unit 501 reads, with the pattern reading sensor 401, the adjustment pattern 400 formed on the conveying belt 31. This adjustment pattern reading control operation is performed by emitting light from the light emitting element 402 of the pattern reading sensor 401 while moving the carriage 23 in the main scanning direction, so that light output from the light emitting element 402 is irradiated onto the adjustment pattern 400 on the conveying belt 31.
In the pattern reading sensor 401, as light output from the light emitting element 402 is irradiated onto the adjustment pattern 400 on the conveying belt 31, the specularly reflected light from the adjustment pattern 400 is irradiated into the light receiving element 403. The light receiving element 403 outputs detection signals according to the amount of the specularly reflected light received from the adjustment pattern 400. These detection signals are input to a landing positional misalignment amount computing unit 503 of a landing position correction unit 505.
The landing positional misalignment amount computing unit 503 of the landing position correction unit 505 detects the position of the adjustment pattern 400 based on output results from the light receiving element 403 of the pattern reading sensor 401, and calculates the shift amount with respect to a reference position (landing positional misalignment amount). The landing positional misalignment amount calculated by the landing positional misalignment amount computing unit 503 is output to a jetting timing correction amount computing unit 504. The jetting timing correction amount computing unit 504 calculates the correction amount of the jetting timing so that there are no misalignment in the landing positions when the liquid droplet jetting control unit 502 drives the recording heads 24. The jetting timing correction amount computing unit 504 sets the calculated jetting timing correction amount in the liquid droplet jetting control unit 502. Accordingly, the liquid droplet jetting control unit 502 can drive the recording heads 24 at jetting timings that have been corrected based on the correction amount. Thus, the misalignment in the liquid droplet landing positions can be reduced.
Principles of the formation and detection of the adjustment pattern 400 according to an embodiment of the present invention are described next with reference to
As shown in
In this case, the surface of the conveying belt 31 (belt surface) is made lustrous and therefore tends to readily yield specularly reflected light when light is received from the light emitting element 402 of the pattern reading sensor 401. When light output from the light emitting element 402 is irradiated onto the surface of the conveying belt 31 on which the adjustment pattern 400 is formed with multiple isolated liquid droplets 500, the amount of specularly reflected light 603 decreases in the region where the adjustment pattern 400 is formed since the light is diffused on the surfaces of the lustrous, hemispheric ink droplets 500. Therefore, the output (sensor output voltage So) from the light receiving element 403 for receiving the specularly reflected light 603 is relatively small.
Accordingly, the position of the adjustment pattern 400 formed on the conveying belt 31 can be detected based on the sensor output voltage So of the pattern reading sensor 401.
In a comparative example, as illustrated in
Note that, as shown in
Thus, using the output from the light receiving unit for receiving specularly reflected light from the ink droplets, the adjustment pattern is detected by identifying portions where specularly reflected light is attenuated. Accordingly, the adjustment pattern is detected with high precision. In this case, the adjustment pattern 400 is preferably formed, in the detection region of the pattern reading sensor 401, with multiple liquid droplets that are separated from each other. More preferably, the ink droplets are close to each other (in the detection region, the area between the ink droplets is smaller than the adhering area where the ink drops are adhering to the belt surface).
In view of the characteristics unique to the liquid droplets, the adjustment pattern is formed with multiple isolated liquid droplets on the conveying belt which is a water-repellent pattern formation member. Herewith, the adjustment pattern can be detected with high precision according to the difference in the amount of specularly reflected light in the region on the conveying belt without the ink droplets and the region with the ink droplets. As a result, gap deviation can be detected with high precision.
Next, different examples of a position detection process of the adjustment pattern 400 formed on the conveying belt 31 and a distance calculation process for calculating the distance between the patterns 400a and 400b are described with reference to
By comparing the sensor output voltage So with a predetermined threshold Vr, the positions at which the sensor output voltage So becomes lower than the threshold Vr can be detected as edges of the reference pattern 400a and the measurement pattern 400b. The area centroid of the region surrounded by the lines representing the threshold Vr and the sensor output voltage So (the hatched parts in the figure) is calculated. This area centroid can be set to be the center of the patterns 400a and 400b. By using a centroid, it is possible to reduce errors caused by microscopic variations of the sensor output voltage.
This portion where the sensor output voltage So falls is searched in a direction indicated by an arrow Q1 shown in
A process is performed to remove harmonic noise with an IIR filter, and then the quality of the detected signals is evaluated (whether there are missing signals, unstable signals, or excessive signals). Sloped portions near the threshold Vr are detected, and a regression curve is calculated. Furthermore, intersection points a1, a2, b1, and b2 of the regression curve and the threshold Vr are calculated (in a practical situation, the calculation is performed by a position counter). Moreover, an intermediate point A of the intersection points a1 and a2, and an intermediate point B of the intersection points b1 and b2 are calculated.
With reference to
In the landing positional misalignment correction method for this image forming apparatus, a line-shaped pattern is formed on the conveying belt using a recording head (color) that is to be a reference head in such a manner so as to extend in a direction perpendicular to the movement direction of the conveying belt. By other recording heads (of other colors), similar line-shaped patterns are formed with fixed intervals along the movement direction of the conveying belt. The distance between the reference head and another head is calculated (measured).
There are four types of block patterns (basic patterns) for each minimum unit, as follows. In the basic pattern shown in
Landing positional misalignment could be caused by a single recording head during bidirectional printing. However, in the case of the above-described image forming apparatus, since it includes two recording heads 24k1 and 24k2 for jetting black ink, landing positional misalignment may also be attributable to a discrepancy between the two recording heads 24k1 and 24k2. Therefore, the image forming apparatus includes the block pattern for detecting the landing positional misalignment of the pattern FK2 formed by the recording head 24k2 using the pattern FK1 formed by the recording head 24k1.
Next, with reference to
In a ruled line misalignment adjustment pattern 400B shown in
With reference to a flowchart shown in
If the conveying belt 31 remains clean, the sensor output voltage of the pattern reading sensor 401 is stable and takes on a profile similar to one shown in
Next, the main control unit 310 performs a frequency analysis in which frequencies of the belt surface and amplitudes of respective frequency components are calculated based on the sensor output voltage of the pattern reading sensor 401 obtained in the pre-scanning. In the frequency analysis, the obtained sensor output voltage (pre-scan data) along the time axis of the belt surface is converted into a signal along the frequency axis.
If the frequency analyzing unit 507 converts (fast Fourier transform), for example, the sensor output voltage shown in
Next, the main control unit 310 reads pre-stored belt surface frequency data (initial condition data, for example, frequency data obtained from the surface of the conveying belt in factory shipment), and performs a peak frequency calculating process in which, using the frequencies of the belt surface and the amplitudes of respective frequency components obtained by the frequency analysis, frequency components exceeding a predetermined level are calculated as peak frequencies. That is, the belt surface frequency data obtained in the pre-scanning are compared with the initial condition data to calculate their difference, and frequency components whose difference in amplitude exceeds a predetermined value (predetermined level) are searched. These frequency components are stored in a nonvolatile memory (storing unit) as peak frequencies.
For example, assume that the initial condition data are the belt surface frequency data of the new belt of
Next, the main control unit 310 compares an initial value of the frequency for the adjustment pattern 400 (pattern frequency) with the calculated peak frequencies to determine whether the peak frequencies are different from the pattern frequency. It should be noted that the pattern frequency is a frequency band within a predetermined range which includes the calculated peak frequencies, or includes the calculated peak frequencies as well as frequencies adjacent to the peak frequencies.
For example, the initial value of the pattern frequency of the adjustment pattern 400 is compared with the peak frequencies fb1, fb2 and the like in
At this point, if the pattern frequency is determined to be different from any of the peak frequencies, the main control unit 310 sets, for a filter, a filter coefficient such that the filter has a cut-off frequency f0 beyond the pattern frequency and frequencies adjacent to the pattern frequency.
If the pattern frequency is similar to one of the peak frequencies, the main control unit 310 changes the pattern frequency. Specifically, the main control unit 310 searches a frequency band that does not coincide with any of the peak frequencies, in ascending order starting from a frequency band of the lowest peak frequency. If there is a frequency band that does not coincide with any of the peak frequencies, the main control unit 310 changes the pattern frequency of the adjustment pattern 400 to the found frequency band. Subsequently, the main control unit 310 sets, for the filter, a filter coefficient such that the filter has a cut-off frequency beyond the changed pattern frequency and frequencies adjacent to the changed pattern frequency.
Next, the main control unit 310 forms the adjustment pattern 400 on the conveying belt 31 and reads the adjustment pattern 400 with the pattern reading sensor 401, and then performs filtering on the read data with the filter.
For example, as shown in
The pattern frequency is obtained by 1/{(X+Y)/Z}, where X is the pattern width of the reference pattern 400a and the measurement pattern 400b, Y is the gap between these two patterns, and Z is the carriage speed (reading speed), as shown in
Therefore, in order to change the pattern frequency of the adjustment pattern 400, either one of the pattern width X of the reference pattern 400a and the measurement pattern 400b or the pattern gap Y may be changed. A new frequency band of the pattern frequency is determined depending on the peak frequencies.
Next, the main control unit 310 detects the position of the adjustment pattern 400 based on the sensor output from the pattern reading sensor 401, and detects the landing positional misalignment amount. In this case, the landing positional misalignment amount is calculated by obtaining a discrepancy with a specified distance. The discrepancy may be obtained by identifying the position of the adjustment pattern 400 using addresses (position information) obtained by the linear encoder for detecting movements of the carriage 23, or, alternatively, by calculating the pattern-to-pattern distance based on the pattern-to-pattern time and the carriage speed. Subsequently, the main control unit 310 calculates the landing positional misalignment correction amount and adjusts the landing positional misalignment by changing the jetting timing.
Next, the main control unit 310 calculates a correction value of the printing jetting timing based on a discrepancy between the forward printing and the backward printing (bidirectional misalignment amount) of the carriage 23. Using the calculated correction value, the main control unit 310 corrects the printing jetting timing.
On the other hand, if the pattern frequency coincides with one of the peak frequencies over almost all frequency bands, and thus, there is no frequency band to which the pattern frequency can be changed, the main control unit 310 reports to the user and the service provider that the positional misalignment cannot be adjusted. By reporting the unadjustable condition, it is possible to reduce downtime when positional misalignment cannot be adjusted.
As has been described above, the belt surface is pre-scanned to obtain its condition, and the frequency analysis (FFT) is performed on the output of the belt surface. Then, peak frequencies are detected, and an adjustment pattern is formed at a frequency different from the frequencies of the belt surface. Herewith, the adjustment pattern is free from the influence of frequency components (scratches caused by paper powder, dirt due to ink mist and the like) on the belt surface which are not present in the initial condition. Accordingly, even if the condition of the belt surface changes, the position of the adjustment pattern can be detected with less possibility of misdetection and accordingly, the landing positional misalignment can be appropriately adjusted.
Next, with reference to a flowchart shown in
In this example, prior to the formation of the adjustment pattern 400, the carriage is moved in the main scanning direction to pre-scan only a predetermined pattern printing region with the reading sensor 401, thereby reading the condition of the surface of the conveying belt 31 (belt surface).
Subsequently, as explained in the first example above, the frequency analysis is performed on the pre-scanned pattern formation regions to calculate frequencies of the pattern formation regions and amplitudes of respective frequency components based on the sensor output voltage of the pattern reading sensor 401 obtained in the pre-scanning. In the frequency analysis, the obtained sensor output voltage (pre-scan data) along the time axis of the belt surface is converted into a signal along the frequency axis.
Next, a difference between the initial condition data (belt surface frequency data) for the pre-scanned regions and the belt surface frequency data obtained in the pre-scanning is calculated, and frequency components whose difference in amplitude exceeds a predetermined value are searched. These frequency components are stored in a nonvolatile memory (storing unit) as peak frequencies.
Next, an initial value of the pattern frequency is compared with the calculated peak frequencies. If none of the peak frequencies is within the initial value range of the pattern frequency, a filter coefficient such that the filter has a cut-off frequency f0 beyond the pattern frequency and frequencies adjacent to the pattern frequency is set for the filter. Subsequently, the adjustment pattern 400 is formed, and the positional misalignment adjustment is carried out.
If the pattern frequency is similar to one of the peak frequencies, the pattern frequency is changed. Specifically, a frequency band that does not coincide with any of the peak frequencies is searched in ascending order starting from a frequency band of the lowest peak frequency. If there is a frequency band that does not coincide with any of the peak frequencies, the pattern frequency is changed to the found frequency band. Subsequently, a filter coefficient such that the filter has a cut-off frequency f0 beyond the changed pattern frequency and frequencies adjacent to the changed pattern frequency is set for the filter. Then, the adjustment pattern 400 is formed, and the positional misalignment adjustment is carried out.
On the other hand, if, in the pre-scanned pattern formation regions, the pattern frequency coincides with one of the peak frequencies over almost all frequency bands, one or more regions different from the pre-scanned regions are pre-scanned. Then, a frequency band which does not coincide with the peak frequencies is searched, and subsequently, the same processes as described above in the first example are performed. If, in all the pattern formation regions (in this example, all regions A through H), the pattern frequency coincides with one of the peak frequencies over almost all frequency bands, the unadjustable condition is reported to the user and the service provider. By reporting the unadjustable condition, it is possible to reduce downtime when positional misalignment cannot be adjusted.
Thus, by pre-scanning only the pattern formation region (a region on which a pattern is to be formed), it is possible to improve the processing speed and also reduce a storage area of the storage medium used during the processing operations. Furthermore, the pattern detection sensitivity can be continuously maintained.
In conclusion, according to the image forming apparatus of the present invention, the adjustment pattern is formed at a frequency different from the frequencies of the surface of the conveying belt. Therefore, it is possible to maintain at a stable level pattern detection accuracy and accuracy of correcting the misalignment of the liquid droplet landing positions.
This application is based on Japanese Patent Application No. 2008-008849 filed on Jan. 18, 2008, the contents of which are hereby incorporated herein by reference.
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