This disclosure relates generally to phase change ink printers, and in particular to solid ink loaders for use in such printers.
Phase change ink imaging products encompass a wide variety of imaging devices, such as ink jet printers, facsimile machines, copiers, and the like, that are configured to utilize phase change ink to form images on recording media. Some of these devices use phase change ink in a solid form, referred to as solid ink sticks. Imaging devices that utilize solid ink sticks are typically provided with an ink loader having feed channels for receiving the solid ink sticks. The ink sticks are inserted into a feed channel through an insertion opening located near one end, or insertion end, of the channel and urged by a spring-loaded push block toward a melting device located at the other end, or melt end, of the channel that melts the ink to a liquid suitable for jetting onto print media. When multiple ink sticks are inserted into the channel, the ink sticks abut against each other in the channel to form a column of ink that extends from the ink melting device toward the insertion area.
In some devices, a manually operated access cover controls access to the insertion openings of the ink loader for ink stick insertion. The access cover is positioned over the insertion openings and linked to the push blocks in a manner that enables the manual operation of the access cover to be used to control the position of the push blocks in the feed channels. For example, when the access cover is opened, a link retracts the push blocks toward the insertion end to provide clearance for ink sticks to be inserted through the insertion openings into the corresponding feed channels in front of the push blocks. When the access cover is closed, the link returns the push blocks to operable positions in the feed channels for urging ink sticks toward the melting devices at the melt ends of the channels.
While effective, using a manually operated access cover and linkage assembly to enable ink stick insertion into the feed channels requires that the access cover be located at a position that provides sufficient clearance for the cover to be moved through its full range of required motion. Providing this clearance is an issue in some imaging device configurations. In addition, because the access cover is manually operated, manipulation of the access cover by an operator may occur at inappropriate times during printer operation, such as during an ink melt cycle when ink stick feed toward the melt device is required.
In accordance with the present disclosure, a solid ink loading system for a phase change ink imaging device is provided that includes an automated access control system for enabling ink stick insertion based on user initiated ink load requests with reference to the operating state of the imaging device. In one particular embodiment, a solid ink loading system for a phase change ink imaging device includes at least one feed channel having an insertion opening through which ink sticks are inserted into the feed channel, and an access structure that provides access to the insertion opening. A push block is movably supported in the feed channel for translational movement between the first end and the second end of the feed channel. The push block is driven by an actuator via a drive member. The actuator is configured to actuate the drive member to move the push block toward the first end of the feed channel to at least one retracted position in response to a first signal, and to actuate the drive member to move the push block to an urging position for applying an urging force to ink sticks in the feed channel in the feed direction in response to a second signal. The system includes a load request signal generator configured to generate a load request signal. A controller is operatively connected to the actuator and the load request signal generator that is configured to determine an operating state of the imaging device in response to the load request signal and to generate the first signal selectively with reference to the operating state.
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.
The printing system 26 includes at least one printhead 28 having inkjets arranged to eject drops of melted ink onto an intermediate surface 30. A single printhead is shown in
The imaging device 10 includes a media supply and handling system 48 that is configured to transport recording media along a media path 50 defined in the device 10 that guides media through the nip 44, where the ink is transferred from the intermediate surface 30 to the recording media 52. The media supply and handling system 48 includes at least one media source 58, such as supply tray 58 for storing and supplying recording media of different types and sizes for the device 10. The media supply and handling system includes suitable mechanisms, such as rollers 60, which may be driven or idle rollers, as well as baffles, deflectors, and the like, for transporting media along the media path 50.
Media conditioning devices may be positioned along the media path 50 for controlling and regulating the temperature of the recording media so that the media arrives at the nip 44 at a suitable temperature to receive the ink from the intermediate surface 30. For example, in the embodiment of
Operation and control of the various subsystems, components and functions of the imaging device 10 are performed with the aid of a control system 68. The control system 68 is operably coupled to receive and manage image data from one or more image sources 72, such as a scanner system or a work station connection, and to generate control signal that are delivered to the components and subsystems based on the image data which causes the components and systems to perform the various procedures and operations for the imaging device 10. The control system 68 includes a controller 70, electronic storage or memory 74, and a user interface (UI) 78. The controller 70 comprises a processing device, such as a central processing unit (CPU), an application specific integrated circuit (ASIC), a field programmable gate array (FPGA) device, or microcontroller, configured to execute instructions stored in the memory 74. Any suitable type of memory or electronic storage may be used. For example, the memory 74 may be a non-volatile memory, such as read only memory (ROM), or a programmable non-volatile memory, such as EEPROM or flash memory.
User interface (UI) 78 comprises a suitable input/output device located on the imaging device 10 that enables operator interaction with the control system 68. For example, UI 78 may include a keypad, buttons, or other similar types of manual actuators 82, and a display 86 (
The controller 70 is operably coupled to the various systems and components of the device 10, such as the ink handling system 12, printing system 26, media handing system 48, release agent application assembly 38, media conditioning devices 50, and other devices and mechanisms 80 of the imaging device 10, and is configured to generate control signals that are output to these systems and devices in accordance with the print data and instructions stored in memory 74. The control signals, for example, control the operating speeds, power levels, timing, actuation, and other parameters, of the system components to cause the imaging device 10 to operate in various states, modes, or levels of operation, referred to collectively herein as operating modes.
As depicted in
Ink sticks, such as ink stick 14 of
The ink stick 14 includes feed control and guidance features for interacting with various structures provided in the feed channel. In one embodiment, ink stick 14 includes a feed key groove 180 formed in the bottom surface 160 extending from the leading end surface 154 to the trailing end surface 158. The feed key groove 180 is configured to straddle a feed key (not shown) that extends from the feed channel. In alternative embodiments, the ink stick 14 may be provided with any suitable type of feed key feature for interacting in any manner with whatever type of keying, guidance or support members are provided in a feed channel. In addition, the ink stick 14 includes guide feature 184 near the ink stick side surface 170 for interacting with a complementary structure in the feed channel to facilitate alignment of ink sticks in the channel and to limit contact between ink sticks and the feed channel structural elements, such as ribs, supports and other potentially restrictive surfaces.
The ink stick 14 also includes nesting features 188 at the leading end 154 of the ink stick. Although not visible in
In addition to or as an alternative to the insertion, feed guidance, and nesting features, ink sticks may be provided with sensor features for conveying ink stick data to the print controller of the solid ink printer. The ink stick data encoded onto an ink stick may include identification information, such as color, formulation, and intended printer model, as well as printing information, such as printer settings or preferences for use with the ink stick. Sensor features comprise surface formations on the ink stick body that are configured to interact with sensors positioned at one or more locations in the insertion region and/or other portions of feed channels to convey ink stick data to the print controller of a solid ink printer.
Sensor features may have any suitable configuration that permits reliable sensor interaction, such as protrusions, recesses, reflective features, non-reflective features, and the like, depending on the type of sensor used. In the embodiment of
Ink stick data may be encoded into a sensor feature 190 of an ink stick by assigning data to the sensor feature 190. To extract the data from the sensor feature 148, the feed channel 18 is provided with a sensor system 194 (
To enable ink sticks to be inserted into the feed channels 18 of the ink loader 12, the housing 80 of the device 10 includes an access structure 84, such as a cover, that provides access to the insertion area of the ink loader 12. In the embodiment of
As seen in
The heated plate 104 heats the impinging portion of the ink stick 14a to a melting temperature for the ink which melts the solid ink to a liquid ink suitable for fluid ink transport or jetting by the ink jets of the printhead(s) 28. The melted ink is directed from the heated plate to the melted ink reservoir 24 (
In the embodiment of
When retracted, the push block is moved toward the insertion end 98 of the feed channel to a point past the insertion region 112 of the channel (i.e., the location in the feed channel where inserted ink sticks 14 come to rest in the feed channel) to enable ink sticks to be inserted into the feed channel in front of the push block (relative to the feed direction F). In embodiments, the surface 110 of the push block 208 that faces in the feed direction F may be contoured complementary to the trailing end of the ink sticks with which it is intended to be used to enable the push block to nest with the trailing ink stick of the column of ink in the feed channel. Nesting the push block with the trailing ink stick in this manner reduces the ability of the push block and the trailing ink stick to move laterally with respect to each other and promotes reliable feed of the column of ink toward the melt area 138. The push block nesting feature may also be used as an insertion key for the mating side of ink sticks.
In the embodiment of
When the yoke 118 is in the forward position J, the constant force spring 114 pulls the push block 108 toward the melt area 138 proximate the yoke 118. If ink sticks are loaded into the feed channel 18 in front of the push block 108, the pulling force of spring 114 on the push block 108 causes the push block 108 to move into contact with the trailing end of the ink sticks in the channel and urge the ink sticks toward the melt end 100 of the channel 18. The spring 114 is coupled to the hub of the push block 108 in a manner that enables the spring body to extend between the yoke 118 and the push block 108 without interfering with ink stick movement in the feed channel. For example, as depicted in
In embodiments, to the extent that the face 110 of the ink push block 108 protrudes into the insertion region 112 when in the retracted position, the push block face 112 may function as a part of the insertion keying to block insertion of incorrect ink sticks. For example, the face 110 of the push block 108 may prevent full insertion of an ink stick 14 unless the ink stick has a length from the leading end to the trailing end of the ink stick 14 that corresponds to the distance between the leading end of the insertion opening 88 (i.e. portion of the perimeter of the insertion opening 88 that extends toward the melt end of the channel) and the face 110 of the push block 108, which may extend into the insertion region sufficiently to act as a keying element. In addition, if the push block face 110 is contoured, as described above, the push block may prevent full insertion of an ink stick into the feed channel if the trailing end of the ink stick does not have a contour that complements the contour of the face of the ink stick push block. Push block insertion keying may be used in addition to, or in lieu of, providing a key shape in the section of the perimeter of the opening 88 that is farthest from the melt plate. In embodiments, the height of the ink stick may be greater than the height of the push block to allow for keying features in the lower portion of the ink stick that are not present in the upper portion of the ink stick.
As mentioned above, in previously known devices, the yoke was linked to the access cover in a manner that allowed manual operation of the access cover to cause the yoke to move between its forward position and rearward position. Thus, ink stick insertion was enabled by simply opening the access cover thereby causing the yoke to move the push block to its retracted position. However, moving the push block fully to the retracted position in this manner required the access cover to be moved through substantially its full range of motion, e.g., fully closed to fully open. Clearance for a full range of motion for such an access cover may not available for some device configurations, particularly an access cover that extends over substantially the full length of the feed channels which is long enough to provide leverage advantage for the user. In addition, because the access cover is manually operated, manipulation of the access cover by an operator may result in the urging force being removed from the column of ink in the feed channel at inappropriate times during printer operation, such as during an ink melt cycle when ink stick feed toward the melt device is required.
To address these issues, the imaging device 10 includes an ink loader access control system 200 (
In addition, because access cover movement is not required to position the yoke, a number of other access structure configurations and movement types are possible. For example, one such configuration is a multi-part drawer style loader that enables ink to be loaded into the withdrawn portion of the loader without having to perform some type of ink stick feed force relief. The yoke can be driven from a forward melt function location to a rearward retracted park position beyond the pull out drawer region. Other examples include a fixed in place ink loader that is located under an extended media path leading to a finisher, e.g., binder, stapler, hole puncher, and the like, or an ink loader of a device having an input feeder and/or scanner, affixed or integrated at the upper surface region of the housing. The use of a powered yoke positioning system enables a small region within the media exit path to be used for ink stick insertion access without requiring the exit path, input feeder, or scanner structure to be lifted to access the loader and cycle the yoke.
A schematic embodiment of an access control system with powered yoke positioning is shown in
The actuator 124 may be implemented in any suitable manner. For example, as depicted in
Referring again to
In one embodiment, the controller 70 is operatively connected to a load request signal generator 128 that is configured to output a load request signal to the controller 70 in response to user selection or designation of the load request option via the user interface 78. In response to receiving the load request signal, the controller 70 implements a load grant process for determining whether and/when to generate the retract signal for the actuator 124 which results in the push block being moved to the retracted position to enable ink stick insertion. Data and instructions for implementing the load grant process may be stored in the memory 74 for the controller 70 to access. In this case, the push block drive member being in an imaging device operation enabled position may be utilized to lock or constrain the access cover so as not to allow interruption of print operations that might occur due to full or partial opening of the cover.
A flowchart of an embodiment of a load grant process that may be implemented by the controller 70 in response to receiving a load request is depicted in
The controller then determines the current operating state of the imaging device (block 604). The current operating state may be determined in any suitable manner. As mentioned, the controller is operably coupled to the various systems and mechanisms of the device 10, such as the ink handling system 12, printing system 26, media handing system 48, release agent application assembly 38, media conditioning devices 50, and other devices and mechanisms 80 of the imaging device 10 and is configured to send operating instructions to and receive status information from these systems. Based on the status information received from the various systems, the controller 70 is configured to determine the current operating state of the device.
At block 608, a determination is made as to whether the current operating state is a non-active operating state, such as standby, sleep, ready, power-saving, or similar type of state or mode where ink loader access does not present a concern, or an active operating state, such as a print mode in which a print job is being executed, a maintenance mode in which the device is implementing a maintenance routine (e.g., purging and/or wiping the printheads), any state in which a melt cycle is currently being performed, and others. If the current operating state is a non-active state, the controller generates the retract signal for the actuator 124 without a substantial delay (block 610). If the current operating state is an active state, the load request is denied and the retract signal is not generated (block 614) and control returns to block 608. In embodiments, the controller 70 may be configured to output a suitable message, alert, alarm, or other form of communication to the user via the user interface 78 indicating, for example, that the load request cannot be granted at this time (block 618). The controller may be configured to determine, based on the current activities of the device 10, an estimated time remaining until the load request can be granted and to communicate the estimated time to the user as well.
In embodiments, the controller may be configured to delay the granting of a load request until the device 10 has completed its current activity or function before granting the load request. For example, if one or more print jobs are currently being executed by the device, the controller may be configured to wait until the currently executed print job(s) has been completed and the device 10 has returned to a non-active state before granting the load request by generating the retract signal. In some cases, if the device is in an active state when a load request is received, the controller may be configured to determine a suitable time to interrupt the device 10 to transition the device to a non-active state for ink loading and then to return the device 10 to the active state when ink loading has been completed. For example, if the device is printing a multi-page print job, the controller may be configured to wait until the current page of the print job has been completed and then temporarily suspend printing operations to place the device in an inactive state for ink loading. Once ink loading has been finished (explained below), the controller may return device 10 to the active state to resume executing the suspended print job. In some implementations, it may not be advisable to allow loading ink while one or more melt plates are capable of melting ink. Influence to load access timing may extend to whether or not one or more melt plate heaters are on or how long they have been off. There are other considerations that may provide opportunity to more optimally balance machine state and user needs, for example, the number of pages in a print job and page coverage. Another embodiment may provide an overriding interrupt to establish the ink load enable state as soon as is practical by user action, for example, a double press of the load access request.
As depicted in
Referring again to
In addition to access control, the use of a power driven yoke positioning system enables an intermediate state in which the push block applies reduced or no force against ink sticks. This intermediate state may be implemented by the controller 70 in any suitable manner. For example, the controller may be configured to output a force reduction signal to the actuator 124 which causes the actuator to move the yoke to a position relieving force of the push block against the ink. The movement of the yoke to a point nearer the push block's retracted position relieves the urging force imparted to the push block by the spring 114. This is possible because the force of the constant force spring does exhibit a reduced force nearer its wound up state, partially due to the force vector to its attachment to the drive member. Retraction movement of the drive member may cause loss of contact between the push block and the ink sticks but the point at which this occurs will most likely be different for each of the color feed channels since ink by color is not consumed at the same rate. With the yoke in the retracted or partially retracted position, the force exerted against the ink sticks by the push block through the spring is thus relieved, which can be a reduced force, elimination of force or a combination across the group of color feed channels. A partially retracted position may enable imaging device operation equivalent to the fully forward position. As mentioned, the reduction in force results in less heat and pressure induced ink deformation and irregular path melt and flow tendencies which can cause or contribute to ink jams. The force reduction state of the push block may be activated at any suitable time, such as in a non-active ready state in which no jobs are currently being executed but the likelihood of a print job being requested is high.
The yoke positioning system may also be used to adjust the insertion openings for use with different ink stick configurations. As mentioned above, the push block may implement an insertion keying function by positioning the push block so that it protrudes into the insertion region. Automating the position of the yoke enables the yoke to be moved to a plurality of different rearward positions thus moving the push block to a plurality of different retracted positions with respect to the insertion region of the feed channel. Each retracted position may result in the push block protruding into the insertion regions at different distances thereby altering the perimeter shape of the insertion opening for each retracted position. Thus, each retracted position of the push block may correspond to a different ink stick configuration.
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 of ordinary skill in the art, which are also intended to be encompassed by the following claims.
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7591550 | Buehler et al. | Sep 2009 | B2 |
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Number | Date | Country | |
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20120026218 A1 | Feb 2012 | US |