This application is related to U.S. patent application Ser. No. 12/338,254, filed Dec. 18, 2008, entitled “Flexible Diagnostic Sensor Sheet;” filed by the same inventors and filed on the same day; the content of this related U.S. patent application is hereby incorporated by reference in its entirety.
Laser printers and Xerographic printers utilize charged toner to render an image on paper. Typically, the toner is charged and deposited on a charged drum in an image pattern. Toner that is to form part of the image is transferred to a charged sheet of paper or other material to be imaged. Toner that does not form part of the image is captured to be reused.
As toner is repeatedly charged, exposed to heat, and reused, the toner uniformity declines. In particular, the charge carrying capacity of the toner particles begins to change such that different toner particles have different physical characteristics resulting in different charge carrying capacities. Toner non-uniformity results in lower quality printer output.
Unfortunately, determining the optimum time to replace the toner is difficult. Counting the number of pages output is an inaccurate measure, because toner intensive printed pages will result in a quick consumption of toner and prevent substantial amounts of reused toner from being generated. Replacing the toner too early is wasteful and also increases printer operating costs. However, waiting too long to replace the toner can result in printer output degradation. Printing unusable output also results in waste.
Thus an improved method of measuring the decline in toner uniformity, or in general, determining when toner should be replaced, is needed.
An improved sensor for determining the uniformity of printer toner particles is described. The system utilizes a sensor that includes a semiconductor channel. A region for receiving toner particles is formed above the channel. When a printer deposits a toner particle on the channel, a charge on the toner particle generates as an electric field that affects the channel conductivity. The change in channel conductivity changes a current flowing in the channel. The toner particle charge can be determined from the change in current.
Using the improved sensor in an array, the charge on numerous toner particles can be detected and compared. If the toner particle charges are not reasonably uniform, particularly, if the toner charges vary from a median by a significant deviation, an indication can be provided to change the toner.
A system for diagnosing printing systems that does not require integration of costly sensor systems in the printer is described. In one embodiment of the system, a flexible diagnostic sheet feeds into a printing system, much like paper. Electronics in the diagnostic sheet sense the state of printing components along the printer paper path. The information communicated by the diagnostic sheet is analyzed thereby enabling detection of problems in the printing system prior to visible manifestation of those problems in the printer output.
In order to create an image, a corona wire or charge roller charges a photoconductive material coating a charging drum 124. A bright lamp, a LED or a laser 128 outputs light which is directed in a light pattern on the photoconductive material, the light pattern corresponding to an image to be printed. The light photons discharge to ground areas of the photoconductive material exposed to the light. Areas unexposed to light remain charged, typically negatively charged. Thus, an electrical charge pattern approximately matching a desired image is formed on the photoconductor surface of the charging drum 124.
A toner dispenser 132 deposits charged toner 136 on the charging drum. Toner 136 is attracted to the charged portions of the photoconductor surface. Because the charge distribution approximates a desired image, the toner distribution also approximately matches the same desired image.
In order to transfer the image from the charging drum 124 to a paper or diagnostic sheet, a charging mechanism 140 charges the paper or the flexible diagnostic sheet 104. When the sheet is brought into contact with the photoconductor surface of the drum, the toner transfers from the drum to the flexible diagnostic sheet 104.
After the image is transferred to the paper or diagnostic sheet, the image needs to be set.
To enable such thin diagnostic sheets, thin-film electronics are favored over conventional integrated circuits. The typical thickness of flexible electronics, such as polyimide and polyethylene naphthalate is on the order of 100 micro-meters. Example, amorphous-silicon thin film transistors can be less than 0.5 microns thick while ferroelectric polymer transducers can be less than 100 microns thick. Such organic or inorganic polymer transducers can be used to fabricate control electronics. The diagnostic sheet length and width may vary, but in order to pass easily through the paper handling system, the dimensions typically approximate a standard 8.5 inch width by 11 inch sheet of paper. This standard 8.5″ by 11″ sheet size is sufficient for the fabrication of large numbers of micro or millimeter scale electronic devices and sensors. Because typical printers can accept both plastic and paper sheets without any modification, typical printers should be able to handle such a thin and flexible diagnostic sheet without modification.
A power source 408 powers the sensors and other electronics on the diagnostic sheet. In one embodiment, the power source is an integrated thin film flexible battery such as that described in Thin-film solid-state lithium battery for body worn electronics by McDermott, J. (Infinite Power Solutions, Golden, Colo., USA); Brantner, P. C. Source: Electronics on Unconventional Substrates—Electrotextiles and Giant-Area Flexible Circuits. Symposium (Mater. Res. Soc. Symposium Proceedings Vol. 736), 2003, p 253-61. Other flexible and thin power sources that may be used include a super capacitor that is charged prior to sending the sheet through the printer, or a rf receiver that receives power transmitted wirelessly to the diagnostic sheet as it travels through the printer. An example of such a RF power source is provided in Tsuyoshi Sekitani, Makoto Takamiya, Yoshiaki Noguchi, Shintaro, Nakano, Yusaku Kato, Kazuki Hizu, Hiroshi Kawaguchi, Takayasu Sakurai, and Takao Someya in “A Large-Area Flexible Wireless Power Transmission Sheet using printed plastic MEMS switches and organic field-effect transistors” which is hereby incorporated by reference. Typical power source voltage requirements are low, typically only a few volts, and the current draw is usually very small; only that which is necessary to power the sensors in the sensor arrays such as illustrated arrays 412, 416, 420, and 424.
The sensors in the sensor array may be designed to detect a variety of parameters, including but not limited to temperature, pressure, charge, chemicals, humidity, acoustic energy (sounds) and the like. The sensor arrays typically include arrays of pixilated sensors distributed across an entire width of the flexible diagnostic sheet.
When printer components, such as an elastomeric roller, deposits oil on the top electrode, capillary action draws the oil into the porous dielectric 612 thereby changing the dielectric constant of the dielectric material 612. The change in dielectric constant changes the capacitor 620 capacitance.
To measure the capacitance, a thin film transistor (TFT) 624 biases the capacitor 620 to a specific voltage and measures the total charge needed to reach the specific voltage. Knowing the voltage and the charge on the capacitor enables determination of the capacitance using the relationship charge=Capacitance×voltage. The measured capacitance can be compared to the expected capacitance to determine whether excess oil has been deposited on the diagnostic sheet. In particular, the amount of oil absorbed can be determined by comparing the calibration capacitance curve with that of similar sensors.
The thin film oil sensor 604 shown in
A second important parameter that often needs to be measured is the consistency of toner. As used herein toner consistency or toner uniformity is defined as the uniformity of toner particles. When manufactured, toner particles are of fairly consistent size and have very similar charge carrying capacities. However, in use, toner is charged, distributed across a drum and heated. Toner that is to form part of an image is transferred to the paper. Unused toner, meaning, toner that is not fixed to paper as part of an image, is captured and reused. As toner is reused, over time, toner uniformity declines. Nonuniformities in the toner, particularly in the amount of charge each toner particle carries, degrades print quality. Determining the extent of such degradation enables toner replacement at optimum intervals.
One method of determining toner uniformity is to measure and compare charge on the toner particles.
A gap 740 between source 743 and drain 736 is designed to receive a charged toner particle 712. In one embodiment, a high-k dielectric, such as an insulating oxide 738 may be formed over semiconductor layer 728 to prevent discharge of the toner into semiconductor layer 728. The charge on the toner particle together with the charge on the gate generates a combined electric field that controls the conductivity of the FET channel in semiconductor layer 728. The IV characteristics of the transistor 704 at a given gate voltage is typically known. Measuring the IV characteristic of the FET with a toner particle in the gap and comparing the measured IV characteristic with the known IV characteristics at a given gate voltage enables determination of the toner charge. Another method to measure the change in the TFT characteristics is by measuring the charging and leakage of the pixel transistor during operation. The charging characteristics will change according to the additional field imparted by the charged particle and shown as a change in the stored charge in the TFT. The apparatus and method for this testing process is described in U.S. patent application Ser. No. 12/040,807 by Raj Apte entitled “Method and System for Improved Testing of Transistor Arrays” which is hereby incorporated by reference.
One difficulty of using the described FET structure is that a traditional FET may not offer sufficient mechanical flexibility to survive the flexing that occurs as the transistor is transported along the paper path. Silicon nanowires may be used to produce a more durable FET.
A gate electrode 824 along with electrical charge 828 on toner particle 832 generates an electric field across the nanowire. The electric field determines the current flow through the nanowire. As previously described for a traditional FET, by knowing the change in current thorough the nanowires due to the electric field from the toner particle, the charge on the toner particle can be determined. This may be done by comparing the measured IV characteristic curves with the known characteristic curves. Or similarly, measuring the change in stored charge storage within the pixel TFT.
One method of further increasing the probability of capturing a toner particle in close proximity to the nanowire is to coat the areas between adjacent nanowires 804 and nanowire 806 with a coating or alternatively providing a coating 808 over an encapsulating thin-film layer such as dielectric layer 807. The coating increases the adhesion of the charged toner particle to the substrate. For example, when the coating is formed between adjacent nanowires, a positively charged polyelectrolyte can be used to attract negatively charged toner particles. Because toner particle 832 is substantially wider than the nanowire, the polyelectrolyte may be patterned to maintain sufficient distance from the nanowire such that the charge on the polyelectrolyte does not affect the nanowire conductance while still being in close enough proximity to the toner particle to exert an attractive force.
In an alternative embodiment, a coating such as coating 808 may cover dielectric layer 807 that covers or otherwise encapsulate the nanowires. In such cases, the effect of the coating should be taken into account. One method of doing so is to take into account the charge of the coating when measuring the current flow changes due to a toner particle charge. Another method is to use an ultra thin (typically less than 10 μm thick organic coating) functionalized surface coating. For example, atomic layer deposition may be used to form a trimethylaluminum surface. Exposure to organic alcohols (cyano- or vinyl-terminated alcohols) results in an organic layer with a dipolar or reactive functional group at the surface. Such a functional group such as functional group 809 illustrated in
Charged toner particle 1036 is captured in a gap 1040 or “sensor window” between the two encapsulation regions 1024, 1032. A cross sectional length of gap 1040 is typically between 10 to 20 microns, large enough to create a high probability of one toner particle being captured in the gap region but small enough to avoid capture of multiple toner particles at once in the gap region. The encapsulation layers of encapsulation regions 1024, 1032 are typically thick enough to create a well in the gap 1040 such that charged toner particles deposited on the encapsulation layers are kept at a distance such that the electric fields from these charged toner particles do not appreciably affect the conductance of the nanowire 1016.
As previous described, one method of further increasing the probability of single toner particle capture is to coat the areas between adjacent nanowires with a coating. The coating increases the adhesion of the charged toner particle to the substrate. For example, a positively charged polyelectrolyte can be used to attract negatively charged toner particles.
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In order to save costs, a smaller number of sensors may be used. In such case, the charge on the detected toner particles can be compared with an expected toner charge rather than with each other. The number of deviations from an expected charge can be used to determine whether the toner needs to be replaced. Although there are cost savings associated with using a smaller number of sensors and comparing the sensor output with the expected output from new toner particles, those savings must be weighed against the benefit of using a large number of sensors to compare toner particles with each other. Comparing toner particles each enables continued use of toner when the toner particles uniformly degrade. Comparing toner particles with each other also enables changes in toner particle formulation without having to recalibrate the diagnostic system to account for any changes in the expected charge of new toner particles. Another embodiment would have the sensor directly mounted in the developer housing for constant monitoring of the toner charge. The sensor in this case may be fabricated on a flexible sheet that is then laminated onto the developer drum 132 of
In addition to monitoring toner charge and fuser oil deposition, another useful parameter for printer diagnosis is measuring the sound produced by moving parts during operation. A printing system typically has a sound characteristic associated with each subsystem during normal operations. This normal “characteristic sound signature” can be a very useful diagnostic tool to verify that printer operation is being carried out within the normal desired operating parameters or under desired operating conditions.
In order to detect the sounds, some of the sensors on the diagnostic sheet may be acoustic sensors. Thin acoustic sensors may be fabricated using thin films of piezoelectric materials such as poly(vinylidene fluoride (PVDF). Acoustic pressure acting on the film surface gives rise to a piezoelectric effect to convert the acoustic pressure into an electrical signal, typically a voltage across the film. The voltage can be detected by electrodes coupled to the piezo surface. Such a sensor is described in “Zinc Oxide thin film-based MEMS acoustic sensor with tunnel for pressure compensation” by Aarti Arora et al., in Sensors and Actuators, A 141 (2008) pp 256-261 which is hereby incorporated by reference in its entirety.
Mounting the acoustic sensors on the diagnostic sheet passing through the printer or even inside the printer itself allows more “noise” free (due to the closer proximity to the subsystem being detected) detection of sounds. By monitoring sound from each subsystem during operation ad comparing the result to pre-defined “characteristic sound signatures” or optimal sound characteristic typically produced during normal operation, potential problems can be detected and/or diagnosed.
Mathematical analysis including Fourier Transforms or Spectral analysis of the detected sound can be used to facilitate comparison to the expected sound. Fourier analysis enables quick comparison of given waveforms, especially frequency components, to determine similarity. Large deviations from an expected sound waveform, and the type of deviation can be used to detect and diagnose printer problems. Example typical problems include improper toner loading into the toner drum, improper operation of the paper feeding mechanisms, paper jams, misalignment of drums in the printer assembly, etc.
Although acoustic, oil and toner charge sensors have been described in detail, the diagnostic sheet should not be limited to detecting the sound signature, amount of fuser oil and/or the uniformity of toner charge. Other printer parameters may be determined using corresponding sensors typically fabricated using thin film technology. For example, pressure distribution of a roller on the printed page may be detected using a pixilated thin elastomeric layer with embedded conducting particles. As pressure from the rollers is applied, a change in resistance of the elastomeric layer is detected. The change in resistance determines the amount of applied pressure.
Although the various sensors herein have been primarily described as being mounted on a diagnostic sheet traveling through a printer paper path, the sensors may also be mounted directly within the printer for more continuous monitoring. For example, the fuser oil detecting capacitor sensor could be mounted on a supplemental roller or other surface within the fuser assembly. The toner charge sensor may be mounted on various components within the printer that come into contact with toner, such as the developer housing. The acoustic sensors and pressure sensors may be mounted on printer components in close proximity to the source of acoustic sound or pressure.
Eventually, information detected by the sensor should be communicated to printer service personnel or the end user. Various methods may be utilized to communicate the information. In one embodiment, the information is transferred from the sensor to a memory device located on the diagnostic sheet. The printer itself may read out information from the memory device. Alternately, a device or computer to read out the information may be coupled to the diagnostic sheet after it exits the printer.
In an alternative method of transmitting the information, a RF transmitter may be included on the diagnostic sheet. The RF transmitter can transmit the data in real time to printer diagnostic circuitry or to a service person either while the diagnostic sheet travels along the paper path or soon after the diagnostic sheet is output from the printer.
Although details have been provided describing how to create a diagnostic sheet and how the diagnostic sheet can be used, such details have been provided to facilitate understanding and are not intended to serve as limitations for the claims provided herein. Instead, the claims, as originally presented and as they may be amended should be interpreted to encompass variations, alternatives, modifications, improvements, equivalents, and substantial equivalents of the embodiments and teachings disclosed herein, including those that are presently unforeseen or unappreciated, and that, for example, may arise from applicants/patentees and others.
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