Printers, like page-wide-array printers and multi-pass printers, include a print bar having a print head or array of print heads. Usually, the print bar extends at least across the width of a print substrate (e.g. paper) in the case of 2D printers or a build material in the case of 3D printers. A print head comprises one or more nozzles for ejecting printing fluid (e.g. ink) to be printed onto the print substrate or, in the case of 3D printers, for emitting radiation (e.g. light) to interact with build material in order to generate a 3D print out. In the following, the term “print target” covers both a print substrate used in 2D printers and build material used in 3D printers. Likewise the term “print” applies to 2D printers and 3D printers, wherein in the latter case “print” covers a generation of 3D structures and the like being producible by a 3D printer.
In general, in a print process, the print bar and a print target are moved in relation to each other. For example, the print target may be moved relative to the print bar, which is not moved, like in the case of page-wide-array printers. It is also possible that the print target is not moved, while the print head is moved, like in the case of 3D printers.
Defects of single nozzles of a print head may result in printing artifacts. Movements of the print bar and the print target in relation to each other may result in different aging of the nozzles. Thus, some nozzles are more used than others and, hence, degrade faster. This may also lead to visible printing irregularities. To address these aspects, multi-pass printing may be used in page-wide array printers and 3D printers. In multi-pass printing overlapping portions of a print target are printed on multiple times, wherein the print target or the print head is moved forwards and backwards (i.e. in the opposite direction) in a “two step forward one step backward” style. Information on multi-pass printing used in page-wide array printers can be found in U.S. Pat. No. 8,057,010 B2.
Figures may show a print target for demonstration purposes. However, the print target is typically not a component of the printer.
An aspect provides a print bar for a multi-pass printer. The print bar comprises a static part and a movable part. The static part may be configured to extend across a print area of the print target and comprises an indexing profile having a longitudinal axis. The moveable part may comprise a print bar beam defining an elongated space through which the indexing profile extends. The print bar beam is supported on the indexing profile movably in an indexing direction extending parallel to the longitudinal axis of the indexing profile.
In some examples, the printer may be a page-wide-array printer for 2D print processes. In some examples, the printer may be a printer for 2D print processes, wherein the printer may be also a page-wide-array printer.
In some examples of the print bar, the print bar may further comprise an actuation device being operatively coupled with the print bar beam for moving the same in the indexing direction.
In some examples of the print bar, the print bar beam may be supported on the indexing profile by means of at least two sliders, which provide only one translational degree of freedom for the print bar beam for movement of the print bar beam in the indexing direction.
In some examples of the print bar, the at least two sliders may provide a rotational degree of freedom for the print bar beam for rotation of the print bar beam about a pivot axis extending in a direction parallel to the indexing direction.
In some examples of the print bar, the at least two sliders may comprise a rear slider providing a contact point, and at least one front slider, wherein each of the at least one front slider provides at least one contact point.
In some examples of the print bar, the at least two sliders may comprise a first front slider providing two contact points and a second front slider providing two contact points, wherein the two contact points of the first front slider and two contact points of the second front slider define a pivot axis for the print bar beam, wherein the pivot axis extending in a direction parallel to the indexing direction.
In some examples of the print bar, the rear slider or its contact point may be movable, and a movement of the rear slider or its contact point may pivot the print bar beam about the pivot axis.
In some examples of the print bar, the at least two sliders may provide five contact points so that the print bar beam is isostatically supported with five translational constraints and a single translational degree of freedom.
In some examples of the print bar the actuation device may comprise a motor, and a gear transmission, wherein the print bar beam may comprise a rack being operatively coupled with the gear transmission.
In some examples of the print bar, the print bar may further comprise at least one of a series of print heads and a series of latches, each of which being arranged on the print bar beam in a cantilever configuration.
In some examples of the print bar, the print bar may further comprise a first lift bracket being connected to a first end of the indexing profile and a second lift bracket connected to a second end of the indexing profile.
Another aspect provides a multi-pass printer and further comprising a print bar. The print bar comprises a static part and a movable part. The static part may be configured to extend across a Print area of the print target and comprises an indexing profile having a longitudinal axis.
The moveable part may comprise a print bar beam defining an elongated space through which the indexing profile extends. The print bar beam is supported on the indexing profile movably in an indexing direction extending parallel to the longitudinal axis of the indexing profile.
In some examples, the printer may be a page-wide-array printer for 2D print processes. In some examples, the printer may be a printer for 2D print processes, wherein the printer may be also a page-wide-array printer.
In some examples, the printer may further comprise an actuation device being operatively coupled with the print bar beam for moving the same in the indexing direction.
In some examples of the printer, the print bar beam may be supported on the indexing profile by means of at least two sliders, which provide only one translational degree of freedom for the print bar beam for movement of the print bar beam in the indexing direction.
In some examples of the printer, the at least two sliders may provide a rotational degree of freedom for the print bar beam for rotation of the print bar beam about a pivot axis extending in a direction parallel to the indexing direction.
In some examples of the printer, the at least two sliders may comprise a rear slider providing a contact point, and at least one front slider, wherein each of the at least one front slider provides at least one contact point.
In some examples of the printer, the at least two sliders may comprise a first front slider providing two contact points and a second front slider providing two contact points, wherein the two contact points of the first front slider and two contact points of the second front slider define a pivot axis for the print bar beam, wherein the pivot axis extending in a direction parallel to the indexing direction.
In some examples of the printer, the rear slider or its contact point may be movable, and a movement of the rear slider or its contact point may pivot the print bar beam about the pivot axis.
In some examples of the printer, the at least two sliders may provide five contact points so that the print bar beam is isostatically supported with five translation constraints and a single translational degree of freedom.
In some examples of the printer, the actuation device may comprise a motor, and a gear transmission, wherein the print bar beam comprises a rack being operatively coupled with the gear transmission.
In some examples, the printer may further comprise at least one of a series of print heads and a series of latches, each of which is arranged on the print bar beam in a cantilever configuration.
In some examples of the printer, the print bar may further comprise a first lift bracket being connected to a first end of the indexing profile, and a second lift bracket connected to a second end of the indexing profile; wherein the printer may further comprise a first lift device operatively coupled to the first lift bracket, the first lift device being adapted to move the first lift bracket in a direction perpendicular to the print area, and a second lift device operatively coupled to the second lift bracket, the second lift device being adapted to move the second lift bracket in a direction perpendicular to the print area.
Here, if not otherwise specified, the term “longitudinal direction” refers to the direction of net movement of the print target and the print head in relation to each other during a printing process, which is also called the feeding direction. As already note above, during a multi-pass printing process, the print target or the print head is moved in “two step forward one step backward” style, i.e. forward to some extent, then backward in an extent smaller than the previous forward movement and so on. The resulting net movement, i.e. movement in the feeding direction, moves the print target underneath the print bar through the printer (in the case the print target is moved) or moves the print head above the print target through the printer (in the case the print head is moved).
The term “vertical direction” refers to a direction perpendicular to the print target's plane, which plane is also referred to as print area.
The term “static part” particularly refers to a part of the print bar, which may be movable in a direction differing from a direction parallel to the longitudinal axis of the indexing profile and the indexing direction, respectively, for example, in a direction perpendicular to the print area. However, in some examples the “static part” cannot be moved in a direction parallel to the longitudinal axis of the indexing profile and the indexing direction, respectively.
The term “movable part” refers to that part of the print bar, which can be moved in a direction parallel to the longitudinal axis of the indexing profile and the indexing direction, respectively. However, the “static part” of the print bar may be movable also in a different direction, for example, may be pivoted around an axis parallel to the longitudinal axis of the indexing profile and the indexing direction, respectively.
The term “slider” relates to elements connected to the print bar beam or the indexing profile and supporting, one the one hand, the print bar beam (and, thus, the movable part) and, on the other hand, the indexing profile (and, thus, the static part) with respect to each other. A slider may be connected to the print bar beam so that the indexing profile is movably supported thereon. A slider may be connected to the indexing profile so that the print bar beam is movably supported thereon. A slider can comprise at least one contact pad providing a contact surface or contact point for the print bar beam or the indexing profile depending to which thereof the slider is connected. A slider or, if applicable, its contact pad may permit a low-friction movement thereon.
The term “lateral direction”, also referred to as “indexing direction”, refers to a direction perpendicular to both the longitudinal direction and the vertical direction, i.e. in a direction across the print area.
Typically, but not necessarily, the print bar extends primarily into the lateral direction and in parallel to the print target plane.
In some examples, the print bar beam is rotatable or pivotable around an axis extending in lateral direction and the indexing direction, respectively.
In some examples, the vertical position of the print bar with respect to the print area printer is adjustable. A vertical adjustment may serve to reach various positions, including those for print head replacement, capping, wiping, spitting, drop detection or printing.
In some examples, the vertical adjustment of the print bar is independently of a lateral movement of the print bar beam.
In some examples, the vertical adjustment is achieved by means of two lift brackets, one at each end of the print bar.
In some examples, the lift brackets can be positioned at same positions in the vertical direction. As a result, the print bar can be positioned closer or more far away from the print area and the print target, respectively.
In some examples, the lift brackets can be positioned at different positions in the vertical direction. As a result, the print bar can be rotated or pivoted about an axis extending in longitudinal direction. This allows to adjust the print bar position in relation to lateral extension/dimension of the print area and the print target, respectively.
In some examples, the motor of the actuation device is an electrical, piezoelectric, hydraulic, or similar motor generating a translational or rotational movement.
In some examples, the transmission may comprise at least one of gear(s), pinion(s), ratchet(s) and rack(s) to transmit the generated movement onto the print bar beam. The movement may be up- or down-shifted during transmission. In some further examples, the motor and/or transmission may be placed within the volume of the print bar and/or indexing mechanism, which may lead to a compact design.
In some examples, the printer further comprises a controller configured to control the print bar and, particularly, movements thereof. In some examples, the controller is configured to control the lateral movement of the print bar beam in at least one of the indexing direction and an opposite direction. In some examples, the controller is configured to control the activation of the actuation device and, particularly, its motor. In some examples, the controller is configured to control vertical movements of at least one of the first lift bracket and the second lift bracket.
In
Then, as shown in
According to
The movement of the print bar 4 from its position in
For printing onto the whole pint media 2, the above described phases of the printing process can be repeated for the parts 16 and 26 of the print target at least once more and will be carried out in similar manner for the remaining parts of the print target 2.
It is noted that the different positioning of
As described in detail further below, the indexing profile 34 is configured to be installed in a printer (particularly a page-wide-array printer), while the print bar beam 36 has no direction contact with the printer. Thus, the indexing profile 34 can act as support for the print bar beam 36. To this end, sliders 40 and 42 are provided.
According to
Further, it is also contemplated that at least one of the sliders does provide, in place of a contact point, a contact line extending in a direction parallel to the lateral or indexing direction. In such a case, a contact line may extend about the whole lateral extension of the print bar beam or the indexing profile or may have any length being shorter. Also this variation is again contemplated for all other sliders referred to in the following.
The indexing profile 34 serves as support for the print bar beam 36, which can moved and positioned along the indexing profile 34. The indexing profile 34 and the sliders 40 and 42 are arranged in a space 50 in the print bar beam 36. As a result, a volume-saving arrangement is achieved. Further, this arrangement allows to use a cantilever-style connection of the print head 38 to the print bar beam 36.
Moving the adjustment device 52 in the feed direction 20 (to the right in
Moving the adjustment device 52 in the direction opposite to the feed direction 20 (to the left in
In some examples, the sliders 44 and 46 have double curvature towards the indexing profile 34. The double curvature allows for a single point of contact between each of the sliders 44 and 36 and the indexing profile 34 in various degrees of inclination. The single point of contact supports low-friction sliding movements.
As can be seen from the arrangement of
The change of inclination may be used to restore the parallelism between the print bar beam 38 and its print head(s) 38 and the print target 11.
The motor 66 can be a rotary electrical motor connected to the transmission 68. In the illustrated example, the transmission 68 comprises a gear 70 and a ratchet or rack 72. The gear 70 is coupled with the motor 66 and can be rotated by the motor 66. The gear 70 is engagement with the ratchet 72, whereby a rotation of the gear 70 results in a movement of the ratchet 72 in lateral direction 8. The ratchet 72 is connected to the print bar beam 36. Thus, rotation of the motor is transmitted through the gear 70 and ratchet 72 is translated into a lateral movement of the print bar beam 36.
The example illustrated in
As shown in, for example,
Further, the indexing profile 34 has a first end 78 being connected with a first lift bracket 80 and a second end 82 being connected with a second lift bracket 84. Using the print bar 4 in a printer, the lift brackets 80 and 84 serve to adjust the vertical positioning of the print bar 4. In some examples, the lift brackets 80 and 84 can be actuated independently of each other so that the print bar 4 can be inclined with respect to the lateral direction. In other words, in such examples, the distances of the first end 78 and the second end 82 of the indexing profile 34 to the print target 2 can be different.
As shown, for example, in
The sliders 40, 42 and 74 may be rigidly attached to the print bar beam 36 and move with it. Each of the two front sliders 40 and 74 has two sliding pads, one in longitudinal/feed direction and one in vertical direction, proving contact points.
The rear slider 42 has the contact point 48 and may be also rigidly attached to the print bar beam 36. The rear slider 42 has the particularity that the vertical position of its contact point 48 can be adjusted, for example, before its final attachment to the print bar beam 36. This allows a control of a rotation of the print bar beam 36 and, particularly, its printing heads 38 around an axis being parallel to the lateral direction in order to maintain the print heads 38 parallel to the print target to be printed on.
The adjustment device 52 of the rear slider 42 comprise a sliding wedge 86, actuated with a screw 88, which is linked with the vertical movement of the rear slider 42, and therefore with a rotation or pivoting movement of the print bar beam 36 around the pivot axis 64.
The rear slider 42 and the two front sliders 40 and 74 may have the contact pads with double curvature, in order to ensure a single point of contact between them and the indexing profile 34 (see e.g.
This allows to adjust the Pen-to-Paper-Space (PPS) by means of the lift brackets 80 and 84 and the rotation of the print heads 38 around the pivot axis 64 by means of the adjustment of the rear slider 42.
In the illustrate example of
This translational degree of freedom can be actuated by the motor 66 and transmission 68, which e.g. comprises 2 stages of gears 70 and the rack 72 (see e.g.
Filing Document | Filing Date | Country | Kind |
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PCT/IB2015/001047 | 4/24/2015 | WO | 00 |