In some inkjet printers, a stationary media wide printhead assembly, commonly called a print bar, is used to print on paper or other print media moving past the print bar.
The same part numbers are used to designate the same or similar parts throughout the figures.
Media wide print bars for inkjet printers must meet precise dimensional requirements to maintain the appropriate position and spacing during printing. Scaling print bars to print on wider media, for example to span B, C, D or even E size media sheets, presents special challenges for cost-effective manufacturing and high performance. For example, dimensional tolerances such as size, position and flatness for the cast or molded parts in chassis and flow structure increase with length while the dimensional requirements for the assembled parts are the same regardless of length. For another example, the reliability requirements for a wider print bar will usually be more stringent than for a narrower print bar due to the greater number of printheads and other parts that can fail, as well as the greater cost to reject a defective print bar at the factory or to replace a defective print bar in a printer.
A new modular print bar has been developed to help meet the challenges of scaling print bars up to print on wider media. In one example, the new print bar includes multiple interchangeable printhead assembly modules stacked end to end with a part of each module overlapping a part of an adjacent module. Each module may include, for example, two rows of printheads in a staggered configuration where one printhead in each row extends into the overlap between modules for seamless printing across the full span of the print bar. A modular print bar allows narrower individual printhead assemblies, half the width of an A-size page for example, reducing the length and corresponding dimensional tolerances of the chassis and flow distribution parts. Also, the use of narrower printhead assemblies helps moderate reliability requirements for a wider print bar by limiting reliability primarily to the narrower individual assemblies.
Unfortunately, the external shape of a stackable module with the desired overlap presents spatial problems for the flow distribution parts supported in or on the chassis. For example, notching the ends of the chassis to enable stacking reduces the space available at each end for routing printing fluid to the printheads, eliminating the repeating geometric flow blocks used in earlier monolithic bars as a viable option for the new modular print bar. Accordingly, a new fluid flow structure has been developed to help effectively implement the notched modules. In one example, the new flow structure includes slots to carry printing fluid to the printheads and corresponding channels to distribute printing fluid to the slots. The slots and channels are arranged on one or more plates so that the arrangement is the same when rotated 180° about an axis of symmetry located at the geometric center of the arrangement. The symmetrical arrangement of the channels and slots allows the same fluid flow “solution” on both ends of the notched, stackable module. Also, the channels may be formed in different levels in multiple plates to further shrink the footprint of the fluid flow structure.
These and other examples shown in the figures and described herein are non-limiting examples. Other examples are possible and nothing in this Description should be construed to limit the scope of the invention which is defined in the Claims that follow the Description.
As used in this document, “printhead” and “print bar” are not limited to printing with ink but also include inkjet type dispensing of other fluids and/or for uses other than printing; “stack” means things arranged one next to another or one upon another; and “upstream”, “downstream”, “top”, “bottom” and other terms of orientation or direction are determined with reference to the usual orientation of a print bar when installed in printer for printing in which the printheads face vertically downward.
Printheads 14A-14F are arranged in two rows—printheads 14A-14C are aligned across the upstream part 22 of chassis 18 in the X direction and printheads 14D-14F are aligned across the downstream part 24 of chassis 18 in the X direction. As noted above, “upstream” and “downstream” and other such references to orientation and direction are taken with respect to the usual position of a module 12 when it is installed in a printer and the printer is ready for printing—the printer will be oriented so the print media moves horizontally past the print bar and ink or other printing fluid is dispensed vertically downward from the print bar on to the media. X, Y, Z axes are noted on each of the figures to help clearly and consistently depict orientation among the different views. The Y axis, or the Y “direction” as it is sometimes called, shows the direction print media usually would move past the printhead assembly module. The X axis, or X “direction” as it is sometimes called, is perpendicular to the media direction and is usually aligned with the print bar. That is to say, the print bar is usually aligned perpendicular to the media direction, although skewing the print bar to the media direction may be possible in some implementations. The Z axis, or Z direction as it is sometimes called, is perpendicular to the X and Y directions and is aligned with the direction printing fluid is usually dispensed from the print bar.
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Middle plate passages 62 also include two groups of ports 68Y, 68K in top 58 through which third and fourth printing fluids, respectively, may flow to channels 70Y, 70K in bottom 60. Each group of ports 68Y, 68K includes a single first port 68Y1, 68K1 connected to a first one of the channels 70Y, 70K which is aligned with first channel 56Y1, 56Y2 in bottom plate top 50, a single second port 68Y2, 68K2 connected to a second one of the channels 70Y, 70K which is aligned with second channel 56Y2, 56K2 in bottom plate top 50, and a single third port 68Y3, 68K3 connected to a third one of the channels 70Y, 70K which is aligned with third channel 56Y3, 56K3 bottom plate top 50.
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Plates 40, 42, and 44 are assembled together to form an integrated network of ports, channels and slots in which the ports carry fluid to channels that distribute the fluid to slots that carry the fluid to the printheads. The fluid distribution channels 64C/80C, 64M/80M for the first and second printing fluids, cyan and magenta inks in this example, are formed in the bottom 74 of top plate 44 and in the top 58 of middle plate 42. Thus, the first and second printing fluids flow through one level of ports 78C, 78M to channels 64C/80C, 64M/80M where they are distributed to the printheads through three levels of slots 66C/46C, 66M/46M. By contrast, the fluid distribution channels 70Y/56Y, 70Y/56K for the third and fourth printing fluids, yellow and black in this example, are formed in the bottom 60 of middle plate 42 and in the top 50 of bottom plate 40. Thus, the third and fourth printing fluids flow through three levels of ports 82Y/68Y, 82K/68K to channels 70Y/56Y, 70Y/56K where they are distributed to the printheads through one level of slots 48Y, 48K. Accordingly, the flow path for the first and second printing fluids may be represented by the sequence P-C-C-S-S-S (port to channel to channel to slot to slot to slot) compared to P-P-P-C-C-S (port to port to port to channel to channel to slot) for the third and fourth printing fluids
As used in this document, a “level” for each port, channel and slot means the top of a plate or the bottom of a plate.
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A flow structure to distribute printing fluids to multiple printheads, the flow structure comprising a plate, slots in the plate to carry printing fluid to the printheads, and corresponding channels in the plate to distribute printing fluid to the slots, the slots and channels arranged on the plate such that the arrangement is the same when rotated 180° about an axis of symmetry located at the geometric center of the arrangement.
The flow structure of paragraph [0029], wherein the channels are formed in a top part of the plate and the slots are formed in a bottom part of the plate.
The flow structure of paragraph [0029], wherein the plate includes multiple plates attached to one another with the channels and slots formed at least partially in different plates.
The flow structure of paragraph [0029], wherein single first ones of the channels are each connected to exactly one of the slots, single second ones of the channels are each connected to exactly two of the slots, and single third ones of the channels are each connected to exactly three of the slots.
The flow structure of paragraph [0032], wherein:
the channels are arranged across the plate in a 1-2-3 sequence in which each of the second ones of the channels are located between the corresponding first and third ones of the channels; or
the channels are arranged across the plate in a 1-3-2 sequence in which each of the third ones of the channels are located between the corresponding first and second ones of the channels.
A flow structure to distribute printing fluids to multiple printheads, the flow structure comprising:
a plate;
slots in the plate to carry printing fluid to the printheads; and
corresponding channels in the plate to distribute printing fluid to the slots;
the plate having a first notched end where an upstream part of the plate extends past a downstream part of the plate and a second notched end opposite the first end where the downstream part of the plate extends past the upstream part of the plate; and
single first ones of the channels are each connected to exactly one of the slots, single second ones of the channels are each connected to exactly two of the slots, and single third ones of the channels are each connected to exactly three of the slots.
The flow structure of paragraph [0034], wherein:
the channels are arranged across the plate in a 1-2-3 sequence in which each of the second ones of the channels are located between the corresponding first and third ones of the channels; or
the channels are arranged across the plate in a 1-3-2 sequence in which each of the third ones of the channels are located between the corresponding first and second ones of the channels.
A flow structure to distribute printing fluids to multiple printheads, the flow structure comprising:
a first plate having a top, a bottom and first and second notched ends where one part of the plate extends past another part;
a second plate having a top, a bottom and first and second notched ends where one part of the plate extends past another part, the top of the second plate attached to the bottom of the first plate such that the notched ends are aligned on both plates; and
a first group of channels in the top of the first plate: a first one of the channels in the first group to distribute a first printing fluid to exactly one opening in the bottom of the first plate aligned with a corresponding opening in the second plate and extending into a protruding part at the first notched end the first plate; a second one of the channels in the first group to distribute the first printing fluid to exactly two openings in the bottom of the first plate aligned with corresponding openings in the second plate; and a third one of the channels in the first group to distribute the first printing fluid to exactly three openings in the bottom of the first plate aligned with corresponding openings in the second plate.
The flow structure of paragraph [0036], comprising a second group of channels in the top of the first plate: a first one of the channels in the second group to distribute a second printing fluid to exactly one opening in the bottom of the first plate aligned with a corresponding opening in the second plate and extending into the protruding part at the second notched end of the plate; a second one of the channels in the second group to distribute the second printing fluid to exactly two openings in the bottom of the first plate aligned with corresponding openings in the second plate; and a third one of the channels in the second group to distribute the second printing fluid to exactly three openings in the bottom of the first plate aligned with corresponding openings in the second plate.
The flow structure of paragraph [0037], comprising a third group of channels in the top of the second plate: a first one of the channels in the third group to distribute a third printing fluid to exactly one opening in the bottom of the second plate and extending into the protruding part at the first notched end of the second plate; a second one of the channels in the third group to distribute the third printing fluid to exactly two openings in the bottom of the second plate; and a third one of the channels in the third group to distribute the third printing fluid to exactly three openings in the bottom of the second plate.
The flow structure of paragraph [0038], comprising a fourth group of channels in the top of the second plate: a first one of the channels in the fourth group to distribute a fourth printing fluid to exactly one opening in the bottom of the second plate and extending into the protruding part at the second notched end of the second plate; a second one of the channels in the fourth group to distribute the fourth printing fluid to exactly two openings in the bottom of the second plate; and a third one of the channels in the fourth group to distribute the fourth printing fluid to exactly three openings in the bottom of the second plate.
The flow structure of paragraph [0039], wherein each of the openings is a slot.
A print bar, comprising multiple interchangeable printhead assembly modules stacked end to end with a part of each module overlapping a part of an adjacent module.
The print bar of paragraph [0041], wherein:
an upstream row of printheads on each module is aligned with an upstream row of printheads on each of the other modules;
a downstream row of printheads on each module is aligned with a downstream row of printheads on each of the other modules; and
a printhead in the upstream row of each module overlaps a printhead in the downstream row of an adjacent module.
The print bar of paragraph [0042], wherein:
each module includes multiple printheads supported by a chassis having an upstream part supporting the upstream row of printheads and a downstream part supporting the downstream row of printheads parallel to the upstream row; and
the upstream and downstream rows of printheads are offset from one another such that a printhead in the upstream row extends past the downstream part of the chassis at one end of the module and a printhead in the downstream row extends past the upstream part of the chassis at the other end of the module.
The print bar of paragraph [0043], wherein each module includes a flow structure to distribute printing fluid to the printheads, the flow structure supported by the chassis over the printheads.
The print bar of paragraph [0044], wherein the flow structure includes a plate, slots in the plate to carry printing fluid to the printheads, and corresponding channels in the plate to distribute printing fluid to the slots, the slots and channels arranged on the plate such that the arrangement is the same when rotated 180° about an axis of symmetry located at the geometric center of the arrangement.
The print bar of paragraph [0045], wherein the channels are formed in a top part of the plate and the slots are formed in a bottom part of the plate.
The print bar of paragraph [0046], wherein the plate includes multiple plates attached to one another with the channels and slots formed at least partially in different plates.
The print bar of paragraph [0047], wherein single first ones of the channels are each connected to exactly one of the slots, single second ones of the channels are each connected to exactly two of the slots, and single third ones of the channels are each connected to exactly three of the slots.
“A” and “an” as used in the claims means one or more.
The examples shown in the Figures and described above illustrate but do not limit the invention. Other forms, details and examples may be made without departing from the spirit and scope of the invention which is defined in the following claims.
This is a continuation of U.S. patent application Ser. No. 15/311,772 filed Nov. 16, 2016 which is itself a Section 371 national entry of international patent application no. PCT/US2014/040264 filed May 30, 2014, each incorporated herein by reference in its entirety.
Number | Date | Country | |
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Parent | 15311772 | Nov 2016 | US |
Child | 15966226 | US |