This invention relates generally to a printing system for printing on a web of print media, and in particular to an apparatus for moving the web of print media through the printing system.
Some digital printing systems and processes, for example, inkjet printing systems and processes introduce significant moisture content during operation, particularly when the system is used to print multiple colors on a print media. Due to its moisture content, the print media expands and contracts in a non-isotropic manner often with significant hysteresis. The continual change of dimensional characteristics of the print media often adversely affects image quality. Although drying is used to remove moisture from the print media, drying too frequently, for example, after printing each color, also causes changes in the dimensional characteristics of the print media that often adversely affects image quality.
During an inkjet printing process, as the print media absorbs the water-based inks applied to it, the print media desires to expand. When the direction of expansion is in a direction that is perpendicular to the direction of media travel, it is often referred to as expansion in the cross-track direction. For example, when the print media wraps around a roller of an inkjet printing system, the outer, typically unprinted, edges of the print media remain attached to the roller although the remaining typically printed portions of the print media expand outwardly. The outward expansion, commonly referred to as buckling, of the print media in the cross-track direction between the firmly attached outer edges of the print media creates lengthwise ripples or wrinkles in the print media. Wrinkling of the print media during the printing process often leads to permanent creases forming in the print media which ultimately affects image quality.
As such, there is an ongoing need to provide digital printing systems and processes with the ability to effectively handle print media expansion associated with the absorption of water by the print media.
According to an aspect of the invention, a digital printing system for printing on a continuous web of print media includes a printhead configured to selectively moisten at least a portion of the web of print media as the web of print media is guided through the printing system. A roller, positioned downstream from the printhead, contacts the print media and causes the print media to wrap around a portion of the roller as the print media moves past the roller. The roller, having an axis of rotation, includes a pattern of recesses and ridges positioned along the axis of rotation of the roller. A second section of the roller is located between a first section of the roller and a third section of the roller as viewed along the axis of rotation. The roller includes a profile as viewed along the axis of rotation in which the diameter of the ridges located in the first section of the roller and the diameter of ridges located in the third section of the roller are greater than the diameter of the ridges located in the second section of the roller.
In the detailed description of the example embodiments of the invention presented below, reference is made to the accompanying drawings, in which:
The present description will be directed in particular to elements forming part of, or cooperating more directly with, apparatus in accordance with the present invention. It is to be understood that elements not specifically shown or described take various forms well known to those skilled in the art. In the following description and drawings, identical reference numerals have been used, where possible, to designate identical elements.
The example embodiments of the present invention are illustrated schematically and not to scale for the sake of clarity. One of the ordinary skills in the art will be able to readily determine the specific size and interconnections of the elements of the example embodiments of the present invention.
In the context of the present disclosure, the term “continuous web of print media” relates to a print media that is in the form of a continuous strip of media as it passes through the printing system from an entrance to an exit thereof. The continuous web of print media itself serves as the receiving print medium to which one or more printing ink or inks or other coating liquids are applied in non-contact fashion. This is distinguished from various types of “continuous webs” or “belts” that are actually transport system components rather than receiving print media and that are typically used to transport a cut sheet medium in an electrophotographic or other printing system. The terms “upstream” and “downstream” are terms of art referring to relative positions along the transport path of a moving web; points on the web move from upstream to downstream.
Generally described, an apparatus and method of moving a web of print media includes a roller that rotates about an axis of rotation as the print media makes contact with and wraps around a portion of the roller as the print media moves past the roller. The roller includes a pattern of recesses and ridges positioned along the axis of rotation that help compensate for cross track expansion of the print media caused by the absorption of water-based ink that is applied to the print media in the print zone. The recesses and ridges also help to reduce the likelihood of the print media wrinkling as the print media wraps around roller and moves through printing system.
The printing system and method including the web moving apparatus are particularly well suited for printing devices that provide non-contact application of ink, typically water based ink, or other colorant onto a continuously moving web of print media. The printhead of the printing system selectively moistens at least some portion of the media as it courses through the printing system, but without the need to make contact with the print media.
Example embodiments of the print media web moving apparatus are described below with reference to
The digital printing system can also include components for drying or curing of the printing fluid on the media; for inspection of the media, for example, to monitor and control print quality; and various other functions. The digital printing system receives the print media from a media source, and after acting on the print media conveys it to a media receiving unit. The print media is maintained under tension as it passes through the digital printing system, but it is not under tension as it is received from the media source.
The printing systems described with reference to
Referring to the schematic side view of
Downstream from first module 20 along the path of the continuous web media, second module 40 also has a support structure, similar to the support structure for first module 20. Affixed to the support structure of either or both the first or second module 20 or 40 is a kinematic connection mechanism that maintains the kinematic dynamics of the continuous web of print media in traveling from the first module 20 into the second module 40. Also affixed to the support structure of either the first or second module 20 or 40 are one or more angular constraint structures 26 for setting an angular trajectory of the web media.
Still referring to
A support structure 28 provides a supporting frame for mounting components within module 20. Similarly, a support structure 48 provides a supporting frame for mounting components within module 40. A continuous web of print media 60 moves through printing system 10 beginning at the source roller 12 and ending at the take-up roll 18.
The schematic side view diagram of
Table 1 that follows identifies the lettered components used for web media transport and shown in
The first angular constraint is provided by in-feed drive roller B. This is a fixed roller that cooperates with a drive roller in the turnover section and with an out-feed drive roller N in second module 40 in order to move the web through the printing system with suitable tension in the movement direction (from left to right as shown in
There is a single lateral constraint mechanism used at A. Here, at the beginning of the media path, a single edge guide provides lateral constraint that is sufficient for registering the continuous web of print media along the media path. It is significant that only one lateral constraint is actively applied throughout the media path, here, as an edge guide. However, given this lateral constraint and the following angular constraint, the lateral constraint for each subsequent web span is fixed. In one embodiment, a gentle additional force is applied along the cross-track direction as an aid for urging the media edge against the edge guide at A. This force is often referred to as a nesting force as the force helps cause the edge of the media to nest alongside the edge guide.
Angular constraints, rollers B, D, E, F, H, J, K, L, N, P, are Included in printing system 10. Each angular constraint sets the angular trajectory of the web as it moves along. However, the web is not otherwise steered in the embodiment shown.
Fixed rollers at F and L precede the printheads for each module, providing the desired angular constraint to the web in the print zone. These rollers provide a suitable location of mounting an encoder for monitoring the motion of the media through the printing system. Under the printheads, the print media is supported by fixed non-rotating supports. These supports provide'zero constraint to the web.
Roller G is a castered and gimbaled roller providing zero constraint. Castered and gimbaled rollers provide zero constraint along the web path. These mechanisms are used, for example, near the input to each module, making each module independent of angular constraints from earlier mechanisms. Other types of mechanisms that provide zero constraint include stationary curved surfaces or castered rollers.
If the span between roller F and G is sufficiently long, the continuous web can lack sufficient stiffness to cause castered roller G to align properly with the web. In such cases, roller G need not be castered. Because of the relative length to width ratio of the media in the segment between F and G, the continuous web in that segment is considered to be non-stiff, showing some degree of compliance in the cross-track direction. As a result, an additional constraint is included to exactly constrain that web segment. This is accomplished by eliminating the caster from roller G. Axially compliant rollers can alternately be used where cross-track constraint is undesirable.
A digital printing system 50 shown schematically in
Turnover mechanism (TB) 30 is shown as part of second module 40. Turnover mechanism TB can optionally be configured as a separate module, with its web media handling compatible with that of second module 40. The position of turnover mechanism TB is appropriately between print zones 54 for opposite sides of the media.
Load cells are provided in order to sense web tension at one or more points in the system. In the embodiments of
The tension in a module preceding the turn bar and a module following the turnover module TB can be independently controlled relative to each other further enhancing the flexibility of the printing system. To accomplish this, a drive motor is included in the turnover module TB. Alternatively, a drive motor is appropriately located along the web path so that tension within one module is independently controlled relative to tension in another module.
The configurations of
An entrance module 70 is the first module in sequence, following the media supply roll, as was shown earlier with reference to
A first printhead module 72 accepts the web media from entrance module 70, with the given edge constraint, and applies an angular constraint with fixed roller F. A series of stationary brush bars or, optionally, minimum-wrap rollers then transport the web along past a first series of printheads 16 with their supporting dryers and other components. Here, because of the considerable web length in the web segment beyond the angular constraint provided by roller F (that is, the distance between rollers F and G), that segment can exhibit flexibility in the cross track direction which is an additional degree of freedom that needs to be constrained. Eliminating the expected caster of roller G provides the additional constraint needed in that span.
An end feed module 74 provides an angular constraint to the incoming media from printhead module 72 by gimbaled roller H. Turnover module TB accepts the incoming media from end feed module 74 and provides an angular constraint with its drive roller, as described previously.
A forward feed module 76 provides a web span corresponding to each of its gimbaled rollers J and K. These rollers again provide angular constraint only; the lateral constraint for web spans in module 76 is obtained from the edge of the incoming media itself.
A second printhead module 78 accepts the web media from forward feed module 76, with the given edge constraint, and applies an angular constraint with fixed roller L. A series of stationary brush bars or, optionally, minimum-wrap rollers then feed the web along past a second series of printheads 16 with their supporting dryers and other components. Here again, because of considerable web length in the web segment (that is, extending the distance between rollers L and M), that segment will exhibit flexibility in the cross track direction which is an additional degree of freedom that needs to be constrained, eliminating the expected caster of roller M provides the additional constraint needed in that span. When overhang is present in the web span (that is, extending the distance between rollers L and M), exact constraint principles are sometimes difficult to apply successfully. Gimbaled roller M provides additional constraint over this long web span.
An out feed module 80 provides an out-feed drive roller N that serves as angular constraint for the incoming web and cooperates with other drive rollers and sensors along the web media path that maintain the desired web peed and tension. Optional rollers O and P (not shown in
Each module in this sequence provides a support structure and an input and an output interface for kinematic connection with upstream or downstream modules. With the exception of the first module in sequence, which provides the edge guide at A, each module uses one edge of the incoming web media as its “given” lateral constraint. The module then provides the needed angular constraint for the incoming media in order to provide the needed exact constraint or kinematic connection of the web media transport. It can be seen from this example that a number of modules can be linked together. For example, an additional module can alternately be added between any other of these modules in order to provide a useful function for the printing process.
Module function is adaptable to the configuration of the complete printing system. In many cases, rollers and components are interchangeable, including rollers at the interface between modules, moved from one module to another depending on the printer configuration. Frames and other support structures for the different modules either use a standard design and dimensions or are designed differently according to the contemplated application. This also helps to simplify upgrade situations.
There are a number of ways to track web position in order to locate and position inkjet dots or other marking that is made on the media. A variety of encoding and sensing devices are used for this purpose along with the associated timing and synchronization logic, provided by control logic processor 90 or by some other dedicated internal or external processor or computer workstation. Such encoders or sensing devices are typically placed just upstream of the print zone containing the one or more printheads, and are preferably placed on a fixed roller so as to avoid interfering with self aligning characteristic of castered or gimbaled rollers.
Sometimes an active steering mechanism is used within a web span, for example, when the web span length of an overhang exceeds its width, so that the web no longer has sufficient mechanical stiffness for exact constraint techniques. This happens, for example, where there is considerable overhang along the web span, that is, length of the web extending beyond the angular constraint for the span. This is the case for modules 72 and 78 in the embodiment described with respect to
Kinematic connection between modules 20 and 40 follows the same basic principles that are used for exact constraint within each web span. That is, cross-track or edge alignment is taken from the preceding module. Any attempt to re-register the media edge as it enters the next module would cause an overconstraint condition. Rather than attempting to steer the continuously moving media through a rigid and possibly over-constrained transport system, the media transport components self-align to the media, thereby providing acceptable registration at high transport speeds and reducing the likelihood of damage to the media or misregistration of applied ink or other colorant to the media.
Where multiple modules are used, as was described with reference to the embodiment shown in
Referring to
This embodiment also has an edge guide A and a non-pivoting drive roller B that establish an initial path for the media in the first span of the media entering the printing system. The combination of the castered and gimbaled rollers C and E and the gimbaled roller D removes an overconstraint condition that would have existed between the first media span and the span across the print zone. Edge guide A helps to ensure that the only minor shifting of the lateral position of the web is needed at edge guide F. This allows the bias force needed to shift the media to the edge stop to be kept to a minimum. With the media under tension as it passes edge guide F, the required bias force to shift the media is greater than it would be if the media were not under tension. The constraints provided by each roller are listed in table 3.
In the embodiment of
As described above, continuous web media transport within and between one, two, three, or more modules is accomplished by applying exact constraint techniques. This flexibility allows a web transport arrangement that provides acceptable registration and repeatable performance at high speeds commensurate with the requirements of high-speed color inkjet printing. As has been shown, multiple modules can be integrated to form a printing system, without the requirement for painstaking alignment of rollers or other media handling components at the interface between two modules.
It has been found that web transports systems as described above maintain effective control of the print media in the context of a digital print system where the selected portions of the print media are moistened in the printing process. This is true even when the print media is prone to expanding in length and width and to becoming less stiff when it is moistened, such as for cellulose based print media moistened by a water based ink. This enables the individual color planes of a multi-colored document to be printed with acceptable registration to each other.
The digital printing systems having one or more printheads that selectively moisten at least a portion of the print media as described above include a media transport system that serves as a support structure to guide the continuous web of print media. The support structure includes an edge guide or other mechanism that positions the print media in the cross track direction. This first mechanism is located upstream of the printheads of the digital printing system. The print media is pulled through the digital printing system by a driven roller that is located downstream of the printheads. The systems also include a mechanism located upstream of printheads of the printing system for establishing and setting the tension of the print media. Typically it is also located downstream of the first mechanism used for positioning the print media in the cross track direction. The transport system also includes a third mechanism to set an angular trajectory of the print media. This can be a fixed roller (for example, a non-pivoting roller) or a second edge guide. The printing system also includes a roller affixed to the support structure configured to align to the print media being guided through the printing system without necessarily being aligned to another roller located upstream or downstream relative to the roller. The castered, gimbaled or castered and gimbaled rollers serve in this manner.
As noted earlier, slack loops are not required between or within modules. Slack loops can be appropriate where the continuous web is initially fed from a supply roll or as it is re-wound onto a take-up roll, as was described with reference to the printing apparatus of
This system is adaptable for a printing system of variable size and facilitates straightforward reconfiguration of a system without requiring precise adjustment and alignment of rollers and related hardware when modules are combined. By using exact constraint mechanisms, rollers can be mounted within the equipment frame or structure using a reasonable amount of care in mechanical placement and seating within the frame, but without the need to individually align and adjust each roller along the path, as would be necessary when using conventional paper guidance mechanisms. That is, roller alignment with respect to either the media path or another roller located upstream or downstream is not needed.
Referring to
The concave profile of roller 100, created by ridges 106, causes the print media 60 to contact different locations of roller 100 as the web of print media 60 wraps around a portion of roller 100. This allows causes roller 100 to provide lateral forces on the web of print media 60 that spread (or stretch) the print media 60 in the cross track direction of the printing system 10 (to left and to the right as shown in
In contrast to a pattern of ridges and recesses that spiral around and along a roller in a non-perpendicular fashion relative to the axis of rotation of the roller, the edges 120, 122 of ridges 106 and the edges 124, 126 of recesses 104 wrap directly around roller 100 in a perpendicular fashion relative to the axis of rotation 102 of roller 100. This creates ridges 106 and recesses 104 of roller 100 that also extend (or wrap around) the circumference of roller 100 in a perpendicular fashion relative to the axis of rotation 102 roller 100. Ridges 106 and recesses 104 extend in periodic manner along the length 128 of roller 100. Recesses 104 provide area for the expanded print media 60 to fit into as the print media 60 wraps around roller 100. This reduces the likelihood of the print media 60 wrinkling as the print media 60 wraps around roller 100 and moves through printing system 10. Preferably, the combination of in-track web tension and the wrap angle is sufficient to cause print media 60 to pull slightly into the recesses 104 of roller 100. In some applications, the depth of recesses 104 is sized so that the portions of the print media 60 pulled into the recesses 104 of roller 100 contact a lower surface 130 of roller 100 which helps minimize print media 60 distortion as the print media is pulled into the recesses 104.
In
In
In
In
Although certain aspects of the example embodiments of the web moving apparatus have been discussed with reference to individual figures of
As shown in
As shown in
Referring back to
When roller 100 is a driven roller, the web of print media 60 is also caused to contact and wrap around a portion of roller 100 as the web of print media 60 moves past roller 100. After first nip roller 154 is positioned to engage first ridge 156 of ridges 106 of roller 100 and second nip roller 158 is positioned to engage second ridge 160 of ridges 106 of roller 100, the web of print media 60 is caused to pass between first nip roller 154 and first ridge 156 and to pass between second nip roller 158 and second ridge 160. Typically, this is accomplished by appropriately positioning roller 100, first nip roller 154, second nip roller 158, and print media web 60 relative to each other, for example, by locating roller 100, first nip roller 154, and second nip roller 158, in one or both of roller locations G or M as described above. Movement of the web of print media 60 is accomplished by driving roller 100 using, for example, a motor or another conventional roller driving mechanism.
One or more of printheads 16 ejects ink selectively moisten at least a portion of the web of print media 60 as the web of print media 60 is guided through printing system 10. Roller 100 is positioned downstream from the printhead 16. An optionally included dryer 14, positioned downstream from the printhead and upstream from the roller, removes moisture from the print media 60 as the print media 60 moves past dryer 14.
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 spirit and scope of the invention.
Reference is made to commonly-assigned, U.S. patent application Ser. No. ______ (Docket K000157), entitled “WEB MEDIA MOVING APPARATUS”, Ser. No. ______ (Docket K000158), entitled “WEB MEDIA MOVING METHOD”, and Ser. No. ______ (Docket K000160), entitled PRINTING METHOD INCLUDING WEB MEDIA MOVING APPARATUS”, all filed concurrently herewith.