This application relates to commonly assigned, copending U.S. application Ser. No. 12/846,651, filed Jul. 29, 2010, entitled: “A METHOD FOR FORMING DURABLE COMBINATION PRINTS”; U.S. application Ser. No. 12/846,660, filed Jul. 29, 2010, entitled: “APPARATUS FOR FORMING DURABLE COMBINATION PRINTS”; U.S. application Ser. No. 12/846,634, filed Jul. 29, 2010, entitled: “A METHOD FOR MAKING COMBINATION PRINTS WITH PLEASING APPEARANCE”; U.S. application Ser. No. 12/846,643, filed Jul. 29, 2010, entitled: “APPARATUS FOR MAKING COMBINATION PRINTS WITH PLEASING APPEARANCE” and U.S. application Ser. No. 12/846,623, filed Jul. 29, 2010, entitled: “A METHOD FOR FORMING A COMBINATION PRINT WITH CONTINUOUS IMAGING” each hereby incorporated by reference.
This invention pertains to the field of printing.
Sheet fed digital printers are capable of storing only limited numbers of different types of receivers. However, with increased use of digital image capture, image editing and digital image and document creation, there is an increased demand for prints that have specific print lengths that are not typically stored in such sheet fed printers.
This demand can be met by manually feeding such printers with receivers that have the specific print length. This adds significant costs to the process of printing using the requested receiver in that less frequently used receiver must be acquired and manually loaded before printing and because the manual loading process includes expenses for the labor required to locate and to load such receiver into the printer. It will be appreciated that such manual processes can also lead to delays in printing.
Alternatively, this demand can be met by cutting receiver to the specific receiver length. Typically, this is accomplished by printing on a stored receiver that is larger than the required print length and cutting excess length from the receiver during one or more finishing operations. Such finishing requires manual processes or the provision of equipment that is capable of cutting longer prints to the determined length. The use of either form of finishing can add significant equipment or processing costs and/or can add significant processing time to the fulfillment of the print order.
In still another alternative, print orders for prints that have specific print lengths that are not typically stored in such sheet fed printers. However, such an approach requires a custom measuring and cutting operations for each receiver. Printing and cutting long sheets poses several limitations. First, rolls of paper are heavy and hard to handle. The use of such roles precludes rapidly changing from one type of paper to another. Moreover, an entire print would have to be made from a single type of paper. Having a print engine and process capable of printing on sheets of paper that can be bound allows using different papers for special effects at different portions of the print. For example, a cover can be printed using a heavy black paper around the spine portion and a different color paper where the title and author are to be printed, thereby creating a decorative effect. Textured papers can also be blended with non-textured papers for an artistic effect.
Accordingly, what is needed is a method for printing and a printer that enable readily available stored receivers in a printer to be used to create prints that have specific lengths without requiring precutting or finishing operations.
What is also needed in the art is a method for operating a printer and a printer that can generate long prints using combinations of sections of available stored receivers in a printer.
One attempt to meet this second need in an electrophotographic printing system is described in U.S. Pat. No. 6,577,845 entitled “End to End Binding Using Imaging Material and Continuous Sheet Printing” issued to Stevens on Jun. 10, 2003. This patent describes using imaging material binding techniques to simulate continuous sheet printing with single sheets of printed receiver. In accordance with the methods described therein, imaging material is applied to a binding region along the trailing edge of a first printed sheet. The trailing edge of the first printed sheet and the leading edge of a following second sheet are overlapped and the imaging material is activated to bind the sheets together. This process may be repeated for successive sheets to form one continuous sheet. The technique described therein is said to be capable of implementation, for example, in a stand alone appliance used in conjunction with a conventional single sheet printer, as in integrated printing device or through a computer readable medium used to control operations in one or both of these devices.
As will be observed from
A step of such height detracts from the overall appearance of the printed image by providing a vertical or horizontal line extending across an image in which a difference in relief is observable from all angles of viewing, and in which an unprinted edge of the overlapping sheet is viewable from many angles of viewing. Both of these conditions detract from the appearance of a combined print. Such artifacts are typically not acceptable to consumers who expect prints to be recorded on a continuous receiver.
A step of such height also creates a catch point that can cause damage to the bound sheets if mechanically engaged while the combination print is being moved.
What is needed therefore are improved printing methods and systems that can join receivers to form a combination print having a length that is greater than a length of any available receiver but with a more durable configuration and a better appearance.
Overlap positioning systems are provided positioning system for use with a printer having a receiver transport system that moves receiver from a pre-printing path to a post-printing path. In one aspect, the overlap positioning system has a receiver transport system that moves receiver from a post-printing path to a reentry point in the pre-printing path, a diverter positioned proximate the post printing path and having a diverter actuator that enables the diverter to selectively move between a first position where the diverter diverts the a first receiver from the post printing path into a recirculation system having a plurality of surfaces to guide a receiver from the post printing path to a reentry position in the pre-printing path; a receiver movement system having at least one actuator cooperating with the recirculation system to move the first receiver through the recirculation system; a position sensing system having a sensor to sense conditions from which amount of movement of the first receiver or second receiver through the reentry point can be determined and a sensor positioned to detect a when one of the first receiver or second receiver is staged at a position where the first receiver or second receiver can be moved to the reentry point within a predetermined time period. A controller that cooperates with the receiver transport system, position sensing system and receiver movement system to cause the diverter to of the first receiver or the second receiver to enter the reentry point, to monitor the amount of movement of the receiver moving through the reentry point and to cause the other of the first and second receiver to move from the staging area so that the first receiver is overlapped by the second receiver by a predetermined amount when the non-selected receiver reaches the staging area.
Toner 24 is a material or mixture that contains toner particles, and that can form an image, pattern, or coating when electrostatically deposited on an imaging member including a photoreceptor, photoconductor, electrostatically-charged, or magnetic surface. As used herein, “toner particles” are the marking particles electrostatically transferred by an electrophotographic print engine 22 to form a pattern of material on a receiver such as 26a or 26b to convert an electrostatic latent image into a visible image or other pattern of toner 24 on receiver. Toner particles can also include clear particles that have the appearance of being transparent or that while being generally transparent impart a coloration or opacity. Such clear toner particles can provide for example a protective layer on an image or can be used to create other effects and properties on the image. The toner particles are fused or fixed to bind toner 24 to a receiver such as 26a or 26b.
Toner particles can have a range of diameters, e.g. less than 8 μm, on the order of 10-15 μm, up to approximately 30 μm, or larger. When referring to particles of toner 24, the toner size or diameter is defined in terms of the median volume weighted diameter as measured by conventional diameter measuring devices such as a Coulter Multisizer, sold by Coulter, Inc. The volume weighted diameter is the sum of the mass of each toner particle multiplied by the diameter of a spherical particle of equal mass and density, divided by the total particle mass. Toner 24 is also referred to in the art as marking particles or dry ink. In certain embodiments, toner 24 can also comprise particles that are entrained in a wet carrier.
Typically, receiver 26a or 26b takes the form of paper, film, fabric, metallicized or metallic sheets or webs. However, receiver 26a or 26b can take any number of forms and can comprise, in general, any article or structure that can be moved relative to print engine 22 and processed as described herein.
Returning again to
A toner image 25a formed from more than one application of toner 24, (also known as a multi-part image) can be used for a variety of purposes, the most common of which is to provide toner images 25a with more than one color. For example, in a four color image, four toners having subtractive primary colors, cyan, magenta, yellow, and black, can be combined to form a representative spectrum of colors. Similarly, in a five color image various combinations of any of five differently colored toners can be combined to form other colors on receiver 26a or 26b at various locations on receiver 26a or 26b. That is, any of the five colors of toner 24 can be combined with toner 24 of one or more of the other colors at a particular location on receiver 26a or 26b to form a color different than the colors of the toners 24 applied at that location.
In addition to adding to the color gamut, the fifth color can also be a specialty color toner or spot color, such as for making proprietary logos or colors that cannot be produced with only CMYK colors (e.g. metallic, fluorescent, or pearlescent colors), or a clear toner or tinted toner. Tinted toners absorb less light than they transmit, but do contain pigments or dyes that move the hue of light passing through them towards the hue of the tint. For example, a blue-tinted toner coated on white paper will cause the white paper to appear light blue when viewed under white light, and will cause yellows printed under the blue-tinted toner to appear slightly greenish under white light.
In the embodiment that is illustrated, a primary imaging member (not shown) such as a photoreceptor is initially charged. An electrostatic latent image is formed by image-wise exposing the primary imaging member using known methods such as optical exposure, an LED array, or a laser scanner. The electrostatic latent image is developed into a visible image by bringing the primary imaging member into close proximity to a development station that contains toner 24. The toner image 25a on the primary imaging member is then transferred to receiver 26a or 26b, generally by pressing receiver 26a or 26b against the primary imaging member while subjecting the toner to an electrostatic field that urges the toner to receiver 26a or 26b. The toner image 25a is then fixed to receiver 26a or 26b by fusing to become a print 70.
In
Electrophotographic printer 20 is operated by a printer controller 82 that controls the operation of print engine 22 including but not limited to each of the respective printing modules 40, 42, 44, 46, and 48, receiver transport system 28, receiver supply 32, transfer subsystem 50, to form a toner image 25a on receiver 26a or 26b and to cause fuser 60 to fuse toner image 25a on receiver 26a or 26b to form prints 70 as described herein.
A printer controller 82 operates electrophotographic printer 20 based upon input signals from a user input system 84, sensors 86, a memory 88 and a communication system 90. User input system 84 can comprise any form of transducer or other device capable of receiving an input from a user and converting this input into a form that can be used by printer controller 82. For example, user input system 84 can comprise a touch screen input, a touch pad input, a 4-way switch, a 6-way switch, an 8-way switch, a stylus system, a trackball system, a joystick system, a voice recognition system, a gesture recognition system or other such systems. Sensors 86 can include contact, proximity, magnetic, or optical sensors and other sensors known in the art that can be used to detect conditions in electrophotographic printer 20 or in the environment-surrounding electrophotographic printer 20 and to convert this information into a form that can be used by printer controller 82 in governing printing, fusing, finishing or other functions. Memory 88 can comprise any form of conventionally known memory devices including but not limited to optical, magnetic or other movable media as well as semiconductor or other forms of electronic memory. Memory 88 can be fixed within electrophotographic printer 20 or removable from electrophotographic printer 20 at a port, memory card slot or other known means for temporarily connecting a memory 88 to an electronic device. Memory 88 can also be connected to electrophotographic printer 20 by way of a fixed data path or by way of communication system 90.
Communication system 90 can comprise any form of circuit, system or transducer that can be used to send signals to or receive signals from memory 88 or external devices 92 that are separate from or separable from direct connection with printer controller 82. Communication system 90 can connect to external devices 92 by way of a wired or wireless connection. In certain embodiments, communication system 90 can comprise any circuit that can communicate with one of external devices 92 using a wired connection such as a local area network, a point-to-point connection, or an Ethernet connection. In certain embodiments, communication system 90 can alternatively or in combination provide wireless communication circuits for communication with separate or separable devices using, for example, wireless telecommunication or wireless protocols such as those found in the Institute of Electronics and Electrical Engineers Standard 802.11 or any other known wireless communication systems. Such systems can be networked or point to point communication.
External devices 92 can comprise any type of electronic system that can generate signals bearing data that may be useful to printer controller 82 in operating electrophotographic printer 20. For example and without limitation, one example of such external devices 92 can comprise what is known in the art as a digital front end (DFE), which is a computing device that can be used to provide an external source of a print order that has image data and, optionally, production data including printing information from which the manner in which the images are to be printed can be determined. Optionally the production data can include finishing information that defines how the images that are provided are to be processed after printing. A print order that is generated by such external devices 92 is received at communication system 90 which in turn provides appropriate signals that are received by communication system 90.
Similarly, the print order or portions thereof including image and production data can be obtained from any other source that can provide such data to printer 20 in any other manner, including but not limited to memory 88. Further, in certain embodiments image data and/or production data or certain aspects thereof can be generated from a source at printer 20 such as by use of user input system 84 and an output system 94, such as a display, audio signal source or tactile signal generator or any other device that can be used by printer controller 82 to provide human perceptible signals for feedback, informational or other purposes.
As is shown in
Printer controller 82 uses the information in the print order to determine an image for printing and a length of receiver L to be used in printing the image (step 120). In this regard, the print order can generally comprise any type of data or instructions that printer controller 82 can use to determine an image for printing and a length L of the receiver onto which the determined image is to be printed. For example, and without limitation, the print order can comprise image data such as an image data file that defines the determined image and associated data providing printing instructions that define the length L of receiver 26a or 26b. In another example, the print order can comprise instructions or data that will allow printer controller 82 and communication system 90 to obtain an image data file from external devices 92. Further, in other embodiments the print order can contain data from which printer controller 82 can generate the determined image for example from an algorithm or other mathematical or other formula.
The determined image includes the entirety of what is to be printed on a single combination of receivers by printer 20. The determined image can include image information from separate data files and/or separate locations, and/or other types of image information. The determined image can comprise any pattern that can be recorded using one or more applications of toner.
Receiver length L can be determined based upon information from the print order as generally described in the examples above. In other embodiments, signals from user input system 84 can be used as the basis for determining the receiver length L. In still other embodiments, receiver length L can be determined by analysis of the designated image such as may occur by determining an aspect ratio for the determined image and determining a receiver length L based upon the aspect ratio and a required size of the receiver. The receiver length L can also be determined based upon analysis of other information in the print order. For example, the print order can include production data or other types of data or instructions from which the receiver length L can be calculated or otherwise automatically determined, or data indicating a location from which such data can be obtained by printer controller 82 such as by way of communication system 90. In certain embodiments the print order data can include information that identifies a mounting into which the image is to be placed. This can include for example a frame, pocket, pouch or other surface that is associated with a defined area for housing or mounting a receiver having a certain length. Printer controller 82 can be used to determine the receiver length L based upon this information for example, by reference to a look up tables or databases that can be stored in memory 88 or that are available by way of communication system 90, or can determine information from such sources allowing printer controller 82 to determine a receiver length L by way of calculation. Printer controller can also determine the receiver length from information in the print order from which a print size can be determined or a user input from which information indicating a receiver length can be determined (Step 121).
Printer controller 82 then determines whether printer 20 has a receiver 26a or 26b available for printing having a length that matches the determined receiver length L (step 122). Where printer controller 82 determines that there is such a receiver 26a or 26b available for printing, printer controller 82 can cause, for example, receiver supply 32 to supply such receiver 26a or 26b for use in printing or can activate manual loading processes that enable a user to load receiver 26a or 26b of the matching length onto receiver transport system 28 (step 124). The determined image is then printed on the matching receiver (step 126).
Forming Combination Print of Determined Length
Where printer controller 82 determines that receivers 26a or 26b available at printer 20 do not have lengths that correspond to the determined receiver length L (step 122) printer controller 82 identifies an arrangement of overlapping receivers 26a, 26b etc. that forms the determined receiver length L (step 128).
One example of this will now be explained with reference to
In this example, printer controller 82 determines a length L1 of a first receiver 26a and a length L2 of a second receiver 26b that are available for printing. In the example shown in
Printer controller 82 then identifies an overlapping arrangement of first receiver 26a and second receiver 26b that forms the determined receiver length L (step 128). In one embodiment, printer controller 82 identifies the type or types of receiver available at receiver supply 32 and determines from the type or types available any number of arrangements of available receivers 26a or 26b that can provide determined receiver length L. The selection of the receivers 26a or 26b for use in this fashion can be made in any of a variety of ways. In one, example printer controller 82 can select a combination of receivers 26a or 26b from a look up table identifying a preferred combination of the available receivers 26a or 26b to make a receiver having the determined receiver length L. By way of example, and not limitation, printer controller 82 can determine an arrangement of available receivers 26a or 26b by way of calculation, or fuzzy logic or iterative techniques known in the art.
After the arrangement of available receivers 26a or 26b is determined, a first toner pattern is established for recording on a first side of the first receiver and a second toner pattern for recording on a first side of the second receiver to form the image (step 130). This process involves portioning determined image 140 into portions that will be provided on a first print 160 to be formed on first receiver 26a and second print 180 formed on second receiver 26b. In the example of
Accordingly, in this example, printer controller assigns 70% of image 140 for printing on entire portion 184 on first side 182 of second receiver 26b and assigns 30% of image 140 for printing in the non-overlapped portion 164 of first print 160.
First and second toner patterns are then established for recording determined image 140 using the predetermined arrangement of first receiver 26a and second receiver 26b.
As can also be seen in
Accordingly, while it is possible to provide image content or other printed patterns in the toner 24 that is applied to overlap area 168, printer controller 82 will typically determine an extent to which any patterns of toner are to be formed in overlap area 168 based upon the extent of the bond required between first receiver 26a and second receiver 26b. This analysis can consider, for example, the extent of the overlap, the ability of the toner 24 in the overlap area 168 to form a bond between with first receiver 26a and second receiver 26b and other factors that may place stress on such a bond.
Optionally, the pattern of toner 24 in overlap area 168 of first print 160 can be printed to provide an additional portion of image 140 that matches a portion of image 140 printed near second edge 192 of second receiver 26b. This can be done to help ensure image continuity between first print 160 and second print 180 in the event of minor alignment errors during positioning, fusing or afterward.
Also shown in the first toner pattern 166 is an inter-print toner area 230 which will be described in greater detail below.
Referring again to
Printer controller 82 then causes first receiver 26a and second receiver 26b to be moved so that second receiver 26b overlaps first receiver 26a to an extent that is necessary to position second edge 172 according to the identified arrangement (Step 134). This requires two things, that the second edge 192 of second receiver 26b be moved past first edge 170 of first receiver without collision at the edges which can create paper jams and attendant maintenance problems and that second edge of second receiver 26b be moved to a position where the distance from the first edge 190 of second receiver 26b and the second edge of second receiver 26b provide the determined receiver length L.
Accordingly, printer 20 incorporates an overlap positioning system 110 proximate to the receiver transport system that is adapted to cooperate with receiver transport system 28 to enable a non-collision overlap to occur.
In the embodiment of printer 20 shown in
In this embodiment of overlap positioning system 110, a positioner 114 lifts a trailing edge of second receiver 26b allowing first receiver 26a to be advanced under and relative to second receiver 26b.
A position sensing system 116 cooperates with printer controller 82 to determine when second receiver 26b overlaps first receiver 26a to form the overlapping arrangement of first receiver 26a and second receiver 26b that provides determined receiver length L.
Position sensing system 116 can comprise, for example, one or more types of sensors including but not limited to contact, electro-mechanical, electrical, magnetic or optical sensors that can detect the presence or absence of a receiver, an edge of a receiver, proximity of a receiver or an extent of movement of a receiver. In certain embodiments, position sensing system 116 can include a video or still image sensor. It will be appreciated that other arrangements are possible.
In an alternative embodiment stop 112 holds first receiver 26a after printing while allowing second receiver 26b to be more toward first receiver 26a. Here, positioner 114 positions first edge 170 of first receiver 26a in a downward direction to allow a second edge 192 of second receiver 26b to move past first edge 170 of first receiver 26a without a collision. In other alternative embodiments, positioner 114 can depress second edge of second receiver 26b.
Positioner 114 can comprise, for example, mechanical, pneumatic, hydraulic, vacuum, or electrostatic systems of conventional design that can adjust the vertical position of either a first edge 170 of first receiver 26a or second edge 192 of second receiver 26b to allow receiver transport system 28 to move these receivers into an overlapping position without collision. Any system that can be used for such a purpose can be employed here.
In other embodiments, positioner 114 can be arranged along receiver transport system 28 to position first receiver 26a or second receiver 26b as necessary to allow overlapping of the first receiver 26a by the second receiver 26b avoid collision of the first edge 170 of first receiver 26a with second edge 192 of second receiver 26b, without stopping movement of first receiver 26a along receiver transport system 28. Where this is done, printer controller 82 causes receiver transport system 28 to create rate of movement differential between the rate of movement of first receiver 26a and the rate of movement of second receiver 26b that allows second edge 192 of second receiver 26b to advance past first edge 170 of first receiver 26a until a sufficient extent of overlap is reached to provide the determined receiver length L. In this regard, either the rate of movement of first receiver 26a can be slowed or the rate of movement of second receiver 26b can be increased as necessary. Once that first receiver 26a and second receiver 26b are positioned in the identified arrangement, the rate of movement of first receiver 26a and second receiver 26b are be equalized.
As is shown in
As is shown in
As is shown in
Overlap positioning system 110 also provides a receiver movement system 216 shown here as taking the form of a combination of motors that drive particular rollers 215. Printer controller 82 sends signals to receiver movement system 216 causing the motorized rollers to direct first receiver 26a back to receiver transport system 28 to the reentry position.
In this embodiment, position sensing system 116 provides at least one sensor that can sense conditions in recirculation system 208 from which the position of first receiver 26a from which it can be determined when first receiver 26a is positioned where first receiver 26a can be moved to a receiver staging position 194 from which first receiver 26a can be moved to the reentry position within a predetermined time and from which the extent to which a portion of second receiver 26b will have moved past the reentry point 198 after the predetermined period of time can be determined. In the embodiment of
Printer controller 82 use the signals from position sensing system 116 to measure, calculate or otherwise determine when second receiver 26b is located at staging position 194 along receiver transport system 28 where reentry of first receiver 26a into receiver transport system 28 at the reentry point 198 will cause first receiver 26a and second receiver 26b to be positioned with an amount of overlap required to form in the identified overlapping arrangement.
Printer controller 82 causes the receiver movement system 214 to drive first receiver 26a to reenter receiver transport system 28 at reentry point 198 and then causes receiver transport system 28 to move first receiver 26a and second receiver 26b in unison past print engine 22 and fuser 60 as is illustrated in
Such reintroduction can be done with second receiver 26b being stationary or moving as desired.
It will be appreciated that where a portion of the determined image is recorded on either of first receiver 26a or second receiver 26b at the time of overlapping, it can become important to the appearance of certain images that the overlapping be done accurately to ensure image continuity and to ensure that the rendered combination print 200 has the determined length L. However, that there are many variables that can influence the exact timing of the reintroduction of first receiver 26a into the receiver transport system 28 and that can cause variations in the amount of overlap. Such variables include among other things sheet-to-sheet receiver length variability, receiver thickness variability, variability in detection or variability in the location of the receiver.
Accordingly, in the embodiment that is illustrated in
In this embodiment, the movement of second receiver 26b past first motorized rollers 218a is sensed by position sensing system 116 and stopped when a portion of second receiver 26b extending from a nip between first motorized rollers 218a that corresponds to the portion of second receiver 26b that is to overlap first receiver 26a. Printer controller 82 then causes receiver movement system 214 to move first receiver 26a from the recirculation path staging position 194 toward the nip between first motorized rollers 218a such that first edge 170 of first receiver 26a is positioned against the nip between first motorized rollers 218a.
Optionally, as is shown in
The example shown in
Alternatively, in another embodiment printer 20 can be adapted to use overlap positioning system 110 to form combination print 200 with a second edge 172 of first receiver 26a is overlapped with a first edge 190 of second receiver 26b to form a combination print 200.
In this embodiment, position sensing system 116 provides at least one sensor that can sense conditions in receiver transport system 28 and from which it can be determined when second receiver 26b is positioned where second receiver 26b can be moved to a staging position 196 from which second receiver 26b can be moved to the reentry point 198 within a predetermined time and from which the extent to which a portion of first receiver 26a will have moved past the reentry point 198 after the predetermined period of time can be determined. In the embodiment of
In other embodiments position sensing system 116 can use other arrangements of sensors 117 to generate signals from which printer controller 82 can determine such information or equivalents of such information. Position sensing system 116 can include any type of sensor 117 that can sense a receiver, or measure conditions indicative of movement of a receiver, or sense conditions from which a position of a receiver or amount of movement of a receiver can be determined and can comprise without limitation an optical, mechanical, electrical, electro-magnetic sensors, for example and without limitation.
Printer controller 82 uses the signals from position sensing system 116 to, measure, calculate or otherwise determine when first receiver 26a is located at a position where second 26b can be moved from the staging position 196 to reentry point 198 to cause first receiver 26a and second receiver 26b to be positioned with an amount of overlap required to form in the identified overlapping arrangement.
As shown in
Printer controller 82 and position sensing system 116 can determine the amount of overlap in a variety of ways. For example, in one embodiment, the amount of overlap is established based upon receiver position sensing system that are positioned to sense movement of the first receiver 26a past a fixed point and movement of second edge 192 of second receiver 26b to the fixed point.
In another embodiment, the amount of overlap is determined by sensors 117 that can sense the position or movement of a first receiver 26a to a fixed point and that can further measure movement of the second receiver 26b to a position relative to the fixed point.
In still another embodiment, that can be used the amount of the overlap can be determined by use of a position sensing system 116 that captures electronic images of the overlapping first receiver 26a and second receiver 26b while printer controller 82 cooperates with overlap positioning system 110 to increase the extent of the overlap. In such an embodiment, printer controller 82 monitors the signals from the position sensing system 116 and increases the amount of the overlap until the amount of the overlap is sufficient to form determined image 140.
In still another embodiment, the amount of the overlap is established by positioning first receiver 26a and the second receiver 26b in a minimal overlap position, and using position sensing system 116 to sense a distance between a first edge 190 of second receiver 26b and second edge 172 of first receiver 26a. Where this is done, printer controller 82 cooperates with overlap positioning system 110 and receiver transport system 28 to adjust the relative positions of first receiver 26a and second receiver 26b to reduce a distance between first edge 190 and second edge 172 to the determined receiver length L. Other known techniques can be used to define the extent of the overlap.
In further embodiments, the amount of the overlap can be established by providing fiducial markings or other types of machine detectable fiducial features deposits or structures, on either first receiver 26a or on second receiver 26b that can be detected by a position sensing system 116 using sensors 117 that are adapted to detect the fiducial markings and can generate signals that can be used by printer controller 82 to help ensure alignment of first print receiver 26a and second receiver 26b during the overlap process.
It will be understood that overlap positioning system 110 can be incorporated in a printer 20 or supplied as an add-on modular feature or upgraded for use with a printer 20. In a modular or add on embodiment, generally any functions ascribed to printer controller 82 herein can be performed by an optional control circuit or control system 225 shown in
Overlap positioning system 110 can be used for other purposes that can be of benefit in the further processing of a combination print 200. As is shown in
In this regard, it will be appreciated that using overlap positioning system 110 and an appropriate arrangement of sensors 117 of a position sensing system 116, printer 20 can form combination prints 200 with a first receiver having lead edge overlapped or a trailing edge overlapped or both. First toner image 26a will be adjusted accordingly to provide toner in an overlap area that is properly positioned to be overlapped at either first edge 170 or second edge 172.
As is shown in
Returning to
Edge Protection Shield
As is illustrated in
As is noted above, inter-print differential 220 creates both an increased risk of providing a surface that can act as a mechanical catch for combination print 200 when a combination print 200 is moved through various passageways of a printer 20, finishing system 100 or elsewhere, and further provides visual artifact that can detract from the appearance of the combination print 200. It will be appreciated that such passageways are typically designed for the movement of a single thickness of receiver and therefore attempting to pass a combination print 200 which can be more than twice as thick as a thickness of a single sheet of receiver thickness can be exposed to a significant risk of damage.
Accordingly, as can be seen in
Toner edge shield 232 further has a deflection surface 238 that is sloped from first end 234 to second end 236. Deflection surface 238 is provided to reduce the likelihood that any structure might catch combination print 200 at second edge 192 by being positioned to confront such a structure before second edge 192 is moved past such a structure and is sloped to deflect combination print 200 away from such a structure by an extent sufficient to allow combination print 200 to pass such a structure without damage second edge 192. In certain embodiments deflection surface 238 can be monotonically declining from first end 234 to second end 236.
One effect of toner edge shield 232 is shown for example in
It will further be appreciated that in some embodiments, during fusing of first receiver 26a and second receiver 26b, first end 234 of toner edge shield 232 can fuse to a second edge 192 of second print 180 to provide additional binding between first print 160 and second print 180. In other embodiments, a separation can be provided between first end 234 of toner edge shield 232 and second edge 192.
In the embodiment of
In one optional embodiment, the thickness of toner 24 at first end 234 of toner edge shield 232 can be built up in part by including amount of toner from overlap area 168 that builds up against the second receiver 26b as second receiver 26b is moved from a first overlapping position shown in
As is further shown in
It will be appreciated that the steps described herein are not limiting as to the order of overlapping and fusing. For example, in accordance with one embodiment, first toner image 25a is recorded on first receiver 26a and pre-fused or sintered thereto before overlapping first print 160 with second receiver 26b and before fusing. This can be done to allow, for example the printing of first print 160 to occur in a batch that is prepared before second receiver 26b is printed. As is shown in
It will be appreciated that in multi-color printing it is often possible to form individual picture elements of a particular color using more than one combination of colored toners. It will also be appreciated that different combinations of colored toners will typically have different toner thicknesses. Using, for example and without limitation, a processes known to those of skill in the art as under color removal, the numbers of color used to represent a color in an image can be reduced, for example, by substituting black toner for a combination of other colors that will appear to be black. When such a process is used the average amount of toner used to form an image can be reduced as can the thicknesses of toner used to form an image. When such a process is not used toner thicknesses can be larger. Accordingly, in certain embodiments, under color removal or other techniques know to those of skill in the art for forming colors can be used to minimize toner thicknesses in portions of second toner image 25b formed at second edge 192 of second receiver 26b. Optionally, such techniques can be applied to any image forming toner at second edge 172 of first receiver 26a or at first edge 190 of second receiver so as to provide combination print 200 leading or trailing edges having a thickness that more closely approximates conventional required thicknesses
In certain embodiments, it may be necessary or advantageous to perform printing of only one of first receiver or second receiver during the process of forming a combination print 200. For example, either of first receiver 26a or second receiver 26b can be printed using a separate or separable printer, or can be printed on printer 20 and stored as discussed above.
It will be appreciated that in this example, as in the embodiments illustrated in
It will further be appreciated that where the determined image is printed on first receiver 26a when first receiver 26a is overlapped by second receiver 26b, the non-overlapped portion of the first receiver 26a can optionally have a base toner image applied in non-overlapped portion of first receiver 26a which will be overprinted during the printing of determined image 140. Accordingly, as is shown in the example of
Edge Concealment Toner Pattern
As discussed previously, the combined sheets of the prior art shown in
As is also shown in
Accordingly, what is needed is a method and a printer for forming a combination print 200 that has an appearance that is acceptable to viewers across a range of viewing positions.
Printer controller 82 then determines whether printer 20 has a receiver 26 available for printing having a length that matches the determined receiver length L (step 334). Where printer controller 82 determines that there is such a receiver 26 available for printing, printer controller 82 can cause, for example, receiver supply 32 to supply such receiver 26 for use in printing or can activate manual loading processes that enable a user to load receiver 26 of the matching length onto receiver transport system 28 (step 336). The determined image is then printed on the matching receiver (step 338). It will be appreciated that steps 334-338 are optional and that in this regard printer controller 82 can be instructed to form an image on two joined receivers and can do so without making such a determination. Such instruction can be provided in the print order, in signals received from external devices 92 or by way of user input system 84.
Printer controller 82 then identifies an overlapped arrangement of a first receiver and a second receiver that can be overlapped to form the determined receiver length (step 340). These steps can be performed in the manner and using the structures and mechanisms that are described above with respect to steps 126-138 respectively in
Printer controller 82 establishes a first toner pattern to form a first portion of the image on a first surface of the first receiver and a second toner pattern to form a second portion of the image on a second surface of the second receiver positioned so that when the first receiver is overlapped by the second receiver to form the determined combination, the overlapped combination forms the determined image (step 336). The first toner pattern toner provides toner in an overlap area and an image forming area to form a portion of the determined image as generally described above with reference to
Printer controller 82 then causes print engine 22 to apply first toner image 25a to first receiver 26a according to the first toner pattern and to apply a second toner image 25b to the second receiver according to second toner pattern (step 338) overlap positioning system 22 to cooperate with receiver transport system 28 to overlap a portion of first receiver 26a with a portion of the second receiver 26b to form the identified combination (step 340); and, causes fuser 60 to fuse the overlapped first receiver 26a and second receiver 26b (step 342). Printer controller 82 then causes the first toner pattern to be formed such that the first toner pattern further provides toner on an overlapped portion of the first receiver such that fusing the overlapped first receiver and second receiver causes the toner in the overlapped portion to bind the first receiver to the second receiver (step 344). Steps 338-344 can be performed in the manner and using the structures and mechanisms that are described above with respect to steps 126-138 respectively in
However, as is also shown in the embodiment of
Printer controller 82 further cooperates with receiver transport system 28, overlap positioning system 110 and fuser 60 to apply toner to the first receiver according to the first toner pattern, and to apply toner to according to the second toner pattern to the second receiver 26b (step 346), to overlap first edge 170 of first receiver 26a with a second edge 172 of second receiver 26b to form the identified arrangement (step 348) and to fuse the overlapped first receiver 26a and second receiver 26b to form a combination print 200 including a first print formed by the toner fused to the first receiver and a second print formed by the toner fused to the second receiver (step 350). Optionally, the combination print can be recirculated to allow an additional sheet to be added thereto or recirculated for duplex printing on a second side. Steps 344-352 can also be performed in the manner and using the structures and mechanisms that are described above with respect to steps 126-138 respectively in
In the embodiment that is illustrated, toner 24 from first toner image 25a is provided and extends from first receiver 26a to an extent that provides stack heights that are sufficient to cover a portion of second edge 192 sufficient to mask second edge 192. The coverage of second edge 192 by masking toner 362 can be complete or partial as desired to achieve a desired extent of concealment of second edge 192.
Various techniques for forming toner piles having a particular height can be employed toward this end. In certain embodiments, use of clear toner 24, including toner having particle sizes that are greater than at least 20 um can also be advantageously applied to form toner stack heights that are in excess of about 50 um to 100 um or more. Further, in some embodiments such toner stack heights can be provided by applying multiple layers of toner, the use of foaming toners that expand during fusion as is known in the art or by using large sized toner particles to form at least a part of toner edge shield 232 as is also known generally in the art.
In this regard, where print engine 22 is capable of recording image elements forming first toner image 25a or second toner image 25b using different combinations of toner 24 having different thicknesses, for example, where printer 20 can form the same image content using, for example, under color removal techniques, printer controller 82 can for example suspend the application of under color removal techniques proximate to second edge 192 to secure greater toner stack heights or printer controller 82 can cause print engine 22 to record a portion of first toner image 26a proximate second edge 192 using combinations of toner that have greater thickness than other combinations of toner that can be used.
Such techniques can also be used in combination as desired.
In a second embodiment, shown in
In other embodiments, a portion of the edge concealment toner pattern 360 can be provided on second edge 192 of second receiver 26b during printing. For example, in the embodiment that is illustrated in
Because second edge 192 is perpendicular to first side 182 of first receiver 26a, such a transfer system 50 can be made to apply first toner image 25a and second toner image 25b using a compliant surface 364. As is illustrated in
This can be achieved by forming first toner image 25a or second toner image 25b using a compliant surface 366 in transfer subsystem 50, as is known in the literature, and then transferring a portion of edge concealment toner pattern 360 from a portion of the compliant surface 366 that conforms to accommodate second edge 192. Compliant surface 366 will be able to conform to the shape of second edge 192 sufficiently so as to allow transfer of an edge toner image 26c to occur. Specifically, it will be observed from
It will be appreciated however that while in some cases the use of an edge concealment toner pattern 360 in the manner shown in
Accordingly, in certain embodiments, the extent of the pixilation or graininess may itself require mitigation, and in such embodiments of edge concealment toner pattern 360 can be defined by printer controller 82 to limit the extent to which any individual toner stack forming a part of edge concealment toner pattern 360 can deviate from an adjacent stack can be minimized such that there is a gradation of toner stack heights in the first toner image as is illustrated in
As is shown in
As is also shown in
In yet another embodiment of edge concealment masking toner 360 can use mask second edge 192 using a gradient of clear toner mixed with an amount of pigmented toner to create an image density that can obscure the second edge. Here, the clear toner would elevate at least some of the pigmented toner so as to allow the pigmented toner to gradually decrease in offset from the underlying receiver sheet, thereby reducing the edge appearance of second edge 192.
This approach would be particularly useful where the image content of the first toner image 26a has a high optical density proximate to second edge 192. Such mixing can occur as a product of planned mixing of toners, or it can occur during the development or fusing processes.
In still other embodiments, the edge concealment toner pattern 360 comprises clear toner patterns that are shaped to direct light in ways that minimize the extent to which light travels to second edge or the extent to which light that is reflected by second edge 192 is apparent to a viewer. In one example of this type of embodiment, the edge concealment toner pattern 360 includes light transmissive toner such as clear toner that is shaped to direct light that is incident on combination print 200 away from second edge 192 and onto first receiver 26a. Techniques for forming optical elements that can be used for such purposes are described in commonly assigned U.S. Pat. Pub. No. 2009/0016757 entitled Printing of Optical Elements by Electrophotography, filed by Priebe et al. on or about Jul. 13, 2008, which is incorporated herein by reference.
In another embodiment of this type, the edge concealment toner pattern 360 is shaped to reduce the visual impact of image artifacts created by the appearance of the second edge 192 by directing light that is reflected from the first print proximate to the second edge to a viewing surface having a height that is above the thickness of the second edge of the receiver. For example, in the embodiment shown in
In a similar embodiment illustrated in
As can also be observed in this embodiment optical element 390 is further used to help to address image discontinuities created by the overlap of second edge 192 relative to first edge 190 in that optical element 390 can be positioned to provide image content from different positions of first toner image 25a as a viewer moves between different viewing fields of view. Specifically, in this example, as a viewer moves between viewing areas 400, 402 and 404, the viewer will be able to observer image content from slightly different portions of first toner image 25a, shown here as areas 406, 408 and 410 respectively. In the event that a viewer shifts position from a first viewing position within a first field of view 400 relative to combination print 200 to a second viewing position within a second field 410 relative to combination print 200 the viewer will observe different content at optical element 390 that shifts from content presented in area 406 of first toner image 25a to image content presented in area 408.
In this regard, optical element 390 can, for example, comprise a lenticular lens with image content recorded relative to lens in first toner image 25a in a manner that is adapted to provide an angularly changing display that minimizes any discontinuities created by second edge 192. Techniques for forming such image content are well known in the art of making lenticular motion, depth enhanced and as well as other types of auto stereoscopic displays. In similar respect, edge concealment toner pattern 360 can incorporate barrier image techniques as are well known in the art to provide an angularly changing image.
In still another embodiment, edge concealment toner pattern 360 is shaped to scatter or diffuse light that has been reflected by the second edge with light that has been reflected by the first receiver. This can be done by shaping a clear or non-clear toner to form structures such as triangular prisms, lenses, mixtures of concave and convex lens patterns or shapes or surface patterns that will cause variations in the direction of a light passing through the surface pattern. Similarly, under fused or partially fused toner can form internal structures that diffuse or scatter light and can be selectively formed at second edge 192 by selection of toner 24, toner image 25a and fusing technique as known in the art.
In yet another embodiment edge concealment toner pattern 360 can reduce the visual impact of image discontinuities created at second edge 192 by forming a surface having a pattern of toner 24 fused to a low gloss level, i.e. fused to a gloss level of less than approximately 15 as measured using a G-20 gloss meter. This allows scattered light to be diffused rather than specular, thereby softening the appearance of second edge 192. This can be accomplished using known means such as casting the first toner image 25a against a textured ferrotyping member, using one or more toner having glass transition temperatures that exceed 60 degrees Celsius or using one or more toners 24 having high rheological properties.
In still another embodiment of this type, the edge concealment toner pattern 360 includes providing a clear toner 24 having light scattering material or diffusing material therein to scatter or diffuse light that has been reflected by the second edge 192. Examples of such light scattering or diffusing materials include, for example, high dielectric constant materials including but not limited to TiO2 and SrTiO3 and BaTiO3.
In other embodiments, the edge concealment toner pattern 360 is formed in part by modification of image 140 formed in part by first toner image 25a and in part by second toner image 25b.
As is further illustrated in
In yet another embodiment, edge concealment toner pattern 360 can include variations in the apparent thickness, texture, gloss, color, tone or hue, image density that are added to the image to appear to or to actually extend across the second edge include at least one of varied patterns of stripes, spots, shapes, or objects across the edge making the extent of the edge difficult detect. In one example of such an embodiment, edge concealment toner pattern 360 can be formed from a first toner image 25a and a second toner image 25b that have patterns of thickness, texture, gloss, color, tone or hue, image, contrast or color patterns density that extend across second edge that are mapped to detected edges, colors, shapes or other automatically detectable image content in the determined image. Preferably, such patterns are mapped to objects that are formed in part in first toner image 25a and in the second toner image 25b, as shown in the window glossing example discussed with reference to
Such content mapped patterns can help to focus the attention of the viewer away from artifacts created by second edge 192.
It will further be appreciated that the above described features of toner edge shield 232 can be incorporated into edge concealment toner pattern 360 and similarly that edge concealment toner pattern 360 can be incorporated in edge shield 323.
The invention has been described in detail with particular reference to certain preferred embodiments thereof, but it will be understood that variations and modifications can be effected within the scope of the invention.
Number | Name | Date | Kind |
---|---|---|---|
6577845 | Stevens | Jun 2003 | B2 |
6836640 | Isemura et al. | Dec 2004 | B2 |
6980767 | Cahill et al. | Dec 2005 | B1 |
7419151 | Kaneko | Sep 2008 | B2 |
7627271 | Ookushi et al. | Dec 2009 | B2 |
7641951 | Hodsdon et al. | Jan 2010 | B2 |
7720401 | Domoto et al. | May 2010 | B2 |
Number | Date | Country | |
---|---|---|---|
20120027482 A1 | Feb 2012 | US |