This disclosure relates generally to imaging devices having intermediate transfer surfaces, and, in particular, to maintenance systems for such intermediate transfer surfaces.
In solid ink imaging systems having intermediate members, ink is loaded into the system in a solid form, either as pellets or as ink sticks, and transported through a feed chute by a feed mechanism for delivery to a heater assembly. A heater plate in the heater assembly melts the solid ink impinging on the plate into a liquid that is delivered to a print head for jetting onto an intermediate transfer member which may be in the form of a rotating drum, for example. In the print head, the liquid ink is typically maintained at a temperature that enables the ink to be ejected by the printing elements in the print head, but that preserves sufficient tackiness for the ink to adhere to the intermediate transfer drum. In some cases, however, the tackiness of the liquid ink may cause a portion of the ink to remain on the drum after the image is transferred onto the media sheet which may later degrade other images formed on the drum.
To address the accumulation of ink on a transfer drum, solid ink imaging systems may be provided with a drum maintenance unit (DMU). In solid ink imaging systems, the DMU is configured to 1) lubricate the image receiving surface of the drum with a very thin, uniform layer of release agent (e.g., Silicone oil) before each print cycle, and 2) remove and store any excess oil, ink and debris from the surface of the drum after each print cycle. Previously known DMU's typically included a reservoir for holding a suitable release agent and capillary forces delivered the release agent to an applicator as needed for applying the release agent to the surface of the drum.
One difficulty faced in drum maintenance systems that utilize an applicator for applying release agent to a transfer surface is uneven saturation of the applicator which may result in potential print quality variation and problems. Problems with uneven saturation are exacerbated by difficulties faced in oil saturation sensing of the applicator. For example, oil saturation sensing of an applicator, however, is prohibitive due to ink and debris buildup in the drum maintenance system over time. That buildup is a byproduct of the print process and results in changes to the characteristics of the applicator and system which potentially may vary from printer-to-printer.
As an alternative to using an on demand oil delivery system for delivery release agent to a release agent applicator of a drum maintenance system, the present disclosure proposes the use of an open loop oil delivery (OLOD) system. In particular, in one embodiment of an OLOD system, a drum maintenance system for use in an imaging device includes an applicator configured to apply a release agent to a surface of an intermediate transfer drum of an imaging device at a first flow rate, and a reservoir spaced from the applicator including a supply of the release agent for the applicator. A first fluid path fluidly couples the reservoir to the applicator for delivering release agent to the applicator; and a second fluid path fluidly couples the applicator to the reservoir for recirculating release agent back to the reservoir. A delivery pump is configured to pump release agent from the reservoir to the applicator via the first fluid path at a second flow rate; and a recirculation pump is configured to pump release agent from the applicator to the reservoir at a third flow rate. The second flow rate is greater than the first flow rate, and the third flow rate is greater than the second flow rate.
In another embodiment, a method of sensing or detecting the remaining life of an OLOD drum maintenance system is provided. The life sensing method includes detecting a media area and an inked area of the media for each print made by an imaging device, and incrementing a total media area value and total inked area value for each print made. A drum maintenance unit (DMU) reservoir level sensor is monitored to detect when the reservoir has reached a predetermined “low level.” In response to the DMU level sensor indicating that the “low level” has not been reached, a mass is decremented from a current mass for the DMU reservoir using a default oil coverage rate for each print made by the imaging device. In response to the DMU level sensor indicating that the “low level” has been reached, a mass is decremented from the current mass for the DMU reservoir using a refined oil coverage rate for each print made by the imaging device. The refined oil coverage rate is calculated based on the total media area value and the total inked area value.
In yet another embodiment, a reservoir for holding a supply of release agent for delivery to an applicator of a drum maintenance unit of an imaging device is provided. The reservoir includes a bottle configured to hold a predetermined quantity of a release agent, the bottle including an opening at one end thereof. An end cap is sealed over the opening in the bottle. The end cap includes a delivery pass through opening; a recirculation pass through opening; and a vent pass through opening. A float level sensor is attached to the end cap that includes a proboscis extending from an interior of the end cap toward the interior of the bottle, a pivot arm pivotably attached to the proboscis and a float attached to the pivot arm. The proboscis includes a reed switch and the float includes a magnet. The float is configured to pivot between an up position when a level of release agent in the bottle is greater than a trip oil mass and a down position when the level of release agent is at or below the trip oil mass. The reed switch and the magnet are in a closed circuit position when the float is in the up position and in an open circuit position when the float is in the down position.
The foregoing aspects and other features of the present disclosure are explained in the following description, taken in connection with the accompanying drawings, wherein:
For a general understanding of the present embodiments, reference is made to the drawings. In the drawings, like reference numerals have been used throughout to designate like elements.
As used herein, the terms “printer” or “imaging device” generally refer to a device for applying an image to print media and may encompass any apparatus, such as a digital copier, bookmaking machine, facsimile machine, multi-function machine, etc. which performs a print outputting function for any purpose. “Print media” can be a usually flimsy physical sheet of paper, plastic, or other suitable physical print media substrate for images. A “print job” or “document” is normally a set of related sheets, usually one or more collated copy sets copied from a set of original print job sheets or electronic document page images, from a particular user, or otherwise related. As used herein, the term “consumable” refers to anything that is used or consumed by an imaging device during operations, such as print media, marking material, cleaning fluid, and the like. An image generally may include information in electronic form which is to be rendered on the print media by the image forming device and may include text, graphics, pictures, and the like. The operation of applying images to print media, for example, graphics, text, photographs, etc., is generally referred to herein as printing or marking.
Referring now to
The imaging device 10 also includes an ink delivery subsystem 20 that has at least one source 22 of one color of ink. Since the imaging device 10 is a multicolor image producing machine, the ink delivery system 20 includes four (4) sources 22, 24, 26, 28, representing four (4) different colors CYMK (cyan, yellow, magenta, black) of ink. The ink delivery system is configured to supply ink in liquid form to a printhead system 30 including at least one printhead assembly 32. Since the imaging device 10 is a high-speed, or high throughput, multicolor device, the printhead system 30 includes multicolor ink printhead assemblies and a plural number (e.g. four (4)) of separate printhead assemblies (32, 34 shown in
In one embodiment, the ink utilized in the imaging device 10 is a “phase-change ink,” by which is meant that the ink is substantially solid at room temperature and substantially liquid when heated to a phase change ink melting temperature for jetting onto an imaging receiving surface. Accordingly, the ink delivery system includes a phase change ink melting and control apparatus (not shown) for melting or phase changing the solid form of the phase change ink into a liquid form. The phase change ink melting temperature may be any temperature that is capable of melting solid phase change ink into liquid or molten form. In one embodiment, the phase change ink melting temperate is approximately 100° C. to 140° C. In alternative embodiments, however, any suitable marking material or ink may be used including, for example, aqueous ink, oil-based ink, UV curable ink, or the like.
As further shown, the imaging device 10 includes a media supply and handling system 40. The media supply and handling system 40, for example, may include sheet or substrate supply sources 42, 44, 48, of which supply source 48, for example, is a high capacity paper supply or feeder for storing and supplying image receiving substrates in the form of cut sheets 49, for example. The substrate supply and handling system 40 also includes a substrate or sheet heater or pre-heater assembly 52. The imaging device 10 as shown may also include an original document feeder 70 that has a document holding tray 72, document sheet feeding and retrieval devices 74, and a document exposure and scanning system 76.
Operation and control of the various subsystems, components and functions of the machine or printer 10 are performed with the aid of a controller or electronic subsystem (ESS) 80. The ESS or controller 80 for example is a self-contained, dedicated mini-computer having a central processor unit (CPU) 82, electronic storage 84, and a display or user interface (UI) 86. The ESS or controller 80 for example includes a sensor input and control system 88 as well as a pixel placement and control system 89. In addition the CPU 82 reads, captures, prepares and manages the image data flow between image input sources such as the scanning system 76, or an online or a work station connection 90, and the printhead assemblies 32, 34. As such, the ESS or controller 80 is the main multi-tasking processor for operating and controlling all of the other machine subsystems and functions, including the printhead cleaning apparatus and method discussed below.
In operation, image data for an image to be produced are sent to the controller 80 from either the scanning system 76 or via the online or work station connection 90 for processing and output to the printhead assemblies 32, 34. Additionally, the controller determines and/or accepts related subsystem and component controls, for example, from operator inputs via the user interface 86, and accordingly executes such controls. As a result, appropriate color solid forms of phase change ink are melted and delivered to the printhead assemblies. Additionally, pixel placement control is exercised relative to the imaging surface 14 thus forming desired images per such image data, and receiving substrates are supplied by any one of the sources 42, 44, 48 along supply path 50 in timed registration with image formation on the surface 14. Finally, the image is transferred from the surface 14 and fixedly fused to the copy sheet within the transfix nip 18.
To facilitate transfer of an ink image from the drum to a recording medium, a drum maintenance system, also referred to as a drum maintenance unit (DMU), is provided to apply release agent to the surface of the print drum before ink is ejected onto the print drum. The release agent provides a thin layer on which an image is formed so the image does not adhere to the print drum. The release agent is typically silicone oil although any suitable release agent may be used. As depicted in
As mentioned, one difficulty faced in drum maintenance systems that utilize an applicator for applying release agent to a transfer surface is uneven saturation of the applicator which may result in potential print quality variation and problems. Previously known drum maintenance systems utilized a closed loop system in an effort to maintain consistent oil saturation of the applicator. For example, some previously known drum maintenance systems supplied release agent to the applicator based on input received from saturation sensors associated with the applicator. Oil saturation sensing of an applicator, however, is prohibitive due to ink and debris buildup in the drum maintenance system over time. That buildup is a byproduct of the print process and results in changes to the characteristics of the applicator and system which potentially may vary from printer-to-printer.
As an alternative to using a closed loop oil delivery process as in the prior art, the present disclosure proposes the use of an open loop oil delivery process (OLOD) for the DMU. Referring now to
Using an OLOD process, there is very little variation in oil saturation of the applicator over time. In addition, oil saturation sensing of the applicator is not necessary because the applicator is kept fully saturated. Another benefit of using an OLOD process is that loose oil does not buildup in the DMU because excess oil is actively pumped back into the reservoir. A large storage capacity in the DMU for oil, ink, and debris buildup in the DMU over life is not necessary because excess oil and ink removed from the drum is pumped into the reservoir.
Referring again to
The reclaim trough 118 is configured to receive release agent from a release agent reservoir 108. In the embodiment of
The reservoir 108 includes a low level sensor that is configured to generate a low level signal when the oil level in the reservoir reaches a predetermined low oil level. In one embodiment, the low level sensor comprises a float low level sensor that is incorporated into the end cap of the reservoir. Referring to
The float low level sensor 148 of the end cap sensor assembly 150 utilizes a reed switch (not shown) potted inside a proboscis 154 which extends from the inside of the end cap into the reservoir. Alternatively, a hall effect switch may be used. A float 148 made from a buoyant material less dense than the release agent fluid is attached to a pivot shaft 158 on the proboscis 154. A magnet (not shown) is molded into the float 148 and covered with epoxy. Alternatively, the magnet could be pressed in or adhered to the float. When the reservoir is full, the float 148 is in the up position. The proximity of the magnet to the reed switch causes the reed switch to be closed and the circuit complete. Once the level of the fluid passes below the float low level sensor, the float 148 drops away from the reed switch, and the switch and the circuit open to indicate that the low level has been reached.
Referring again to
Referring again to
In one embodiment, the delivery system 170 includes a peristaltic delivery pump. The peristaltic delivery pump 170 includes a pair of rotors through which the two tubes 110 that connect the reservoir to each end of the applicator are extended. The rotation of the rotors under the driving force of a motor (not shown) squeezes the delivery conduits in a delivery direction toward the reclaim trough. As the release agent is pushed through the tubes 110 in the delivery direction, release agent is being pulled into the tubes from the reservoir. Driving two tubes driven through one peristaltic pump insures equal oil delivery to both end of the applicator roller regardless of the effects of gravity on a tilted system.
In operation, as the transfer drum 12 rotates in the direction 16, the roller 104, is driven to rotate in the direction 17 by frictional contact with the transfer drum surface 14 and applies the release agent to the drum surface 14. As the roller 104 rotates, the point of contact on the roller 104 is continuously moving such that a fresh portion of the roller 104 is continuously contacting the drum surface 14 to apply the release agent. A metering blade 174 may be positioned to meter release agent applied to the drum surface 14 by the roller 104. The metering blade 174 may be formed of an elastomeric material such as urethane supported on an elongated metal support bracket (not shown). The metering blade 174 helps insure that a uniform thickness of the release agent is present across the width of the drum surface 14. In addition, the metering blade 174 is positioned above the reclaim trough 118 so that excess oil metered from the drum surface 14 by blade 174 is diverted down the metering blade 174 back to the reclaim trough 118.
The DMU 100 may also include a cleaning blade 178 that is positioned with respect to the drum surface 14 to scrape oil and debris, such as paper fibers, untransfixed ink pixels and the like, from the surface 14 of the drum prior to the drum being contacted by the roller 104 and metering blade 174. In particular, after an image is fixed onto a print media, the portion of the drum upon which the image was formed is contacted by the cleaning blade 178. The cleaning blade 178 may be formed of an elastomeric material and is positioned above the reclaim trough 118 so that that oil and debris scraped off of the drum surface by the cleaning blade is directed to the reclaim trough as well.
The reclaim trough 118 is capable of holding a limited amount of release agent. The volume of oil held in the reclaim trough is set to be the smallest amount that keeps the roller fully saturated. The reclaim trough volume is minimized to limit the potential for oil spills when the DMU is tilted. The volume of the reclaim trough is set by the height of the overflow wall that allows oil to flow into the sump area. Once the reclaim trough 118 has been filled with release agent received from the reservoir as well as release agent and debris diverted into the reclaim trough by the metering blade, excess release agent flows over the edge 180 of the reclaim trough 118 and is captured in sump 134 prior to recirculation to the reservoir 108. Sump 134 is fluidly coupled to the reservoir 108 by at least one flexible conduit or tube 114. A sump pump 184 is configured to pump release agent from the sump 134 through the sump tube 114 to the reservoir 108 at a predetermined rate of flow FAR. In one embodiment, the sump pump comprises a peristaltic pump although any suitable pumping system or method may be used that enables the release agent to be pumped to the reservoir at a desired flow rate.
Referring again to
During operation of the DMU, a pump cycle is performed at predetermined intervals to both deliver silicone oil to the application roller and to remove used oil from the sump and return it to the reservoir to be held until it is recycled and used again. In one embodiment, a pump cycle is performed every 20 pages printed although a pump cycle may be performed at any suitable interval. Referring to
As seen in
The DMU 100 described above (with reference to
As a CRU, the DMU 100 has an expected lifetime, or useful life, that corresponds to the amount of oil loaded in the DMU reservoir 108. In the exemplary embodiment, the useful life may be between approximately 10,000 and 30,000 depending on factors such as oil usage and the amount of oil in the reservoir. When the DMU has reached the end of its useful life, i.e. is out of oil, the DMU may be removed from its location or slot in the imaging device and replaced with a new DMU. To alert an operator that the DMU should be replaced, the DMU includes a “customer replaceable unit monitor,” or CRUM. As described more fully in U.S. Pat. No. 6,016,409, which is hereby incorporated by reference herein in its entirety, the CRUM of the DMU contains memory that stores information pertaining to the DMU.
In one embodiment, the DMU CRUM comprises a non-volatile memory device, such as an EEPROM, that is incorporated into the housing of the DMU. The EEPROM may be implemented in a circuit board (not shown), for example, that is electrically connected to the imaging device controller when the DMU is fully inserted into the imaging device. The EEPROM of the DMU includes a plurality of dedicated memory locations for storing information pertaining to the DMU such as, for example, the mass of silicone oil initially filled into the tank at the time of manufacture (born mass), the estimated current mass of silicone oil in the reservoir (current mass), the total amount of media area that has been printed while that DMU has been installed, the total amount of media area that has been covered by ink, the serial number of the DMU, the date of manufacture, the date of first use, the calculated oil consumption rates for blank media and ink covered media, the float low level sensor calibrated trip mass (explained below), and the current state of the float level sensor (explained below). In addition, the EEPROM includes a memory location for an end of life (EOL) page countdown (“EOL counter”) that is decremented as prints are made (explained below).
According to one aspect of the present disclosure, mass is decremented in three different stages throughout the DMU's life:. Stage 1—Open loop decrement based on media size and ink coverage; Stage 2—the low level sensor trips when the fluid level drops low enough and the mass decrement rates are refined; and Stage 3—a last drop detector determines that the reservoir is empty and a hard countdown begins. As explained below, the last drop detector utilizes the pressure transducer to determine when the reservoir is empty by measuring the pressure drop from ambient due to pumping. This drop is greater when pumping liquid than when pumping air.
When the float is tripped, the current mass is changed to the float low level sensor calibrated trip mass (block 622). If the current calculated mass is 400 grams greater than the low level sensor calibrated trip mass, a “level sensor early” fault is raised and the machine is disabled (not shown). The intent of this feature is to detect catastrophic leaks and alert service. Also when the float trips, the refined oil consumption rates are calculated by the print engine (block 618) and written to the EEPROM. For example, since it is known how much oil has been used at this point and how much paper and ink has been used at this point (block 610), the rate of oil consumption can be calculated given the assumption that the relative value of oil consumption between inked areas and blank areas is the same between all units. For example, oil is consumed on inked areas 1.7 times faster than oil is consumed on blank areas. Once the refined decrement rates have been calculated, oil mass may be decremented using the refined rates (block 622).
Oil continues to decrement at the refined rates until one of two things happens: either the mass decrements to zero (block 634) or last drop detector conditions are met. Normally last drop detect happens first. In one embodiment, a pressure transducer may be used as a last drop detector. For example, a pressure transducer may be used to detect when the reservoir is empty and the pumps are no longer moving liquid but instead are moving air (could be any gas). The way this is accomplished is by exploiting the physics explained by Pouiseuille's Law for flow in a pipe:
Simply stated, given constant tube radius and length and assuming constant flow rate and incompressible fluid, the higher the viscosity of a fluid, the higher the pressure that will develop during movement of the fluid in a tube. Referring again to
The debounce algorithm to determine if the reservoir is empty is as follows: If the average of the voltage deltas of the last 10 pump cycles is 15 mV or less (block 756), the reservoir is considered empty (block 758). The last drop detection algorithm is not enabled until either the float of the low level sensor has dropped or the current calculated mass is 300 grams or less (block 754). This is to prevent spurious last drop detections. Once the empty conditions of the algorithm are met, the “Oil Very Low” fault is raised and the end of life page countdown begins. Otherwise, after a pump cycle has completed, the pages printed value (n) is reset to zero.
In an alternative embodiment, the pressure sensor may be used for last drop detection by monitoring the amplitude of the cyclic pressure variation during a pump cycle.
Referring to the flowchart of
An alternative method for estimating current mass in the DMU involves inflating the reservoir using the sump pump and measuring the pressure difference. This could be done one of two ways—1) Run the pump for a given duration and measure the resulting change in voltage or 2) Run the pump until a given pressure difference is seen and measure how long it took. This concept can be explained analytically using the ideal gas law, a form of which is as follows: P=mRT/V. Where P=pressure, m=mass, R=constant, T=Temperature, V=Volume. In the case of running the pump for a set duration, m, R, and T are all constant. Mass can be considered constant because a peristaltic pump is a positive displacement pump. To be effective, the sump pump is essentially pumping only air. In that case, P=K/V, where K is a combined constant. It is shown that the more volume of compressible fluid (air) is in the essentially fixed volume of the reservoir, the less the pressure drop will be from running a pump a given duration (adding a given mass of air to the reservoir).
In addition to the life sensing algorithm described above, the DMU may be configured to periodically run a diagnostic cycle to check the operation of the pumps 170, 174 and the solenoid valve 144. For example, in one embodiment, a diagnostic cycle may be run every 1000 pages printed. The diagnostic cycle includes a sequence of sub-tests for testing the functionality of the delivery pump 170, sump pump 184, and solenoid valve 144 of the DMU. The sequence of each of the individual sub-tests (e.g., sump pump sub-test, valve sub-test 1, delivery pump sub-test, and valve sub-test 2) are shown in the flow chart depicted in
Failing one of these sub-tests just once does not raise a fault. In order to prevent false failures, a sub-test must fail multiple times for a fault to be raised.
In addition to the diagnostic routines described above, reservoir pressure is constantly monitored via the pressure sensor for pressure “too high” or “too low” conditions when the reservoir should be at or near ambient pressure. Acceptable ranges of pressure are predetermined. If the pressure is between −1.5 and −3 psig for 1.6 seconds (4 ADC clock cycles), a reservoir pressure low fault is declared. If the pressure is less than −3, a fault is not declared. This implementation is intended to ignore spurious reservoir pressure low readings which may be caused by an intermittent circuit. If the pressure transducer circuit is open, the voltage drops to zero which corresponds to a pressure of about −6 or −7 psi which will not raise a reservoir pressure low fault. If the circuit remains continuously open, a diagnostics fault or a reservoir empty fault will eventually be raised. If the reservoir pressure is over +2 psig, for 1.6 seconds, a reservoir pressure high fault is raised.
It will be appreciated that variations of the above-disclosed and other features, and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Various presently unforeseen or unanticipated alternatives, modifications, variations, or improvements therein may be subsequently made by those skilled in the art, which are also intended to be encompassed by the following claims.
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