1. Field of the Invention
The present invention relates to a solution for mounting and positioning a print head onto a print head carriage framework. More specifically, the present invention is related to a mounting assembly for accurately mounting an inkjet print head onto a less accurate print head carriage framework.
2. Description of the Related Art
In industrial printing applications, print throughput is an important characteristic of a printing device. One of the parameters determining print throughput in digital printers using a reciprocating print head configuration, e.g., wide format ink jet printers, is the size of the print head shuttle. The wider the print head shuttle is, the wider the area on the printing medium is that may be printed with a single print stroke or pass of the print head shuttle across the printing medium. Several problems arise when using larger print head shuttles in digital printer configurations. As print head shuttles get larger, they get heavier which complicates fast and accurate movement of the shuttle. As print head shuttles get larger, the left and right abutments of the shuttle on the printer frame diverge and the shuttle structure becomes more susceptible to bending and torsion. As print head shuttles get larger, the print width of a single print stroke increases and the throw-distance, defined as the distance between the print head's printing elements (e.g., the ink jet nozzles) and the print surface of the printing medium across the entire print stroke become more difficult to control within acceptable tolerances. Additionally, as print head shuttles get larger, they carry more print heads and accurate positioning of the print heads over the full width of the shuttle becomes more difficult.
These are just some of the problems that arise when scaling up existing print head shuttle concepts for industrial type printing equipment.
In view of the problems mentioned above, the inventors of the present application have discovered that it would be advantageous to have a method of mounting a print head onto a shuttle that relaxes the manufacturing tolerances of the shuttle without compromising mounting accuracy of the print heads relative to each other and to a printing surface.
In order to overcome the problems described above, preferred embodiments of the present invention provide a print head mounting assembly having specific features and a method of mounting a print head as described below. With the print head mounting assembly according to preferred embodiments of the present invention, the manufacturing tolerances of the print head carriage framework can be narrowed down to a range suitable for accurately position print heads using known print head positioning devices.
Other features, elements, processes, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the present invention with reference to the attached drawing.
While the present invention will hereinafter be described in connection with preferred embodiments thereof, it will be understood that it is not intended to limit the invention to those preferred embodiments.
One Preferred Embodiment of a Digital Printer
A digital printer according to a preferred embodiment of the present invention is shown in
As an alternative to using a sheet-based medium transport system, e.g., a gripper bar transport system 6 known from automated flat bed screen printing presses as indicated in
Preferred embodiments of the present invention may also be used in single pass printing systems where the print heads are fixed and the printing medium moves along the print heads. In this alternative printer configuration, a shuttle as depicted in
Shuttle Structure
As shown in
The width along the x-direction of the print head carriage of the shuttle shown in
Shuttle Construction
The entire print head shuttle may be designed as a framework or skeleton of sheet metal parts. The sheet metal parts may be positioned in the framework by paired pen and slot portions and welded together. Sheet metal parts have the advantage that they often are lighter than machined parts. Furthermore, sheet metal technology is easy to create framework structures with and it allows inserts to be designed that increase the overall stiffness of the framework against bending, torsion, vibrations, etc.
Between the supporting end of the print head shuttle and the side wall of the print head carriage, additional diagonal sheet portions 52 are used to stiffen the corner of the framework. The stiffness of the corner plays an important roll in passing on a torque moment of the print head framework around the x-axis to the abutments of the shuttle onto the printer frame, without introducing horizontal shear components at the abutments. The stiffness of the corner is therefore an important prerequisite.
The vertical partitions 53 oriented substantially perpendicular to the x-axis and positioned at regular distances along the x-axis provide additional resistance against bending of the print head carriage. These partitions extend from the front 45 of the carriage to the back 46 of the carriage in a yz-plane and are attached to multiple substantially vertical oriented sheet portions of the print head carriage in an xz-plane. They create additional substantially perpendicular substructures to increase overall stiffness of the print head shuttle.
At a halfway point of the print head carriage height, substantially horizontally oriented strips 54 are attached to the substantially vertically oriented carriage walls 55 over the full width of the print head shuttle. The strips provide additional stiffness to the relatively high vertical walls of the carriage and increase the eigenfrequency of these walls by dividing the free wall surface in two.
In between the rows of print head locations at the bottom of the print head carriage, rectangular beams 56 are mounted along the full width of the print head carriage in the x-direction to provide additional bending and torsion resistance to the bottom area of the carriage. The rectangular beams are linked together via plate 50, as shown in
The present preferred embodiment of the print head shuttle framework, of which some aspects have just been discussed in detail, and with dimensions as given before yields a sheet metal framework weighing about 200 kg, for example. A fully loaded print head shuttle, including 64 print heads and all necessary supplies that need to shuttle along with the print heads, weighs at least 300 kg, for example. It is clear that this size and weight of print head shuttles creates special concerns regarding bending, torsion, vibrations, etc. The design features discussed above provide answers to these concerns.
In the preferred embodiment shown in
In the present preferred embodiment, the entire print head shuttle is made of a framework of sheet metal parts providing a light and stiff construction. Other print head shuttle constructions or the use of other materials may also provide similar properties. An alternative may, for example, be a framework of machined aluminum parts with sheet metal parts. The machined aluminum parts may provide features that are difficult to provide in sheet metal. The framework may also include synthetic materials that are light-weight, possibly reinforced to add stiffness. One common aspect of these preferred embodiments is that a substantial portion of the print head shuttle construction is a framework.
Print Head Positioning
The flatness accuracy of a sheet metal framework of a size of the print head shuttle as described above is typically only a few millimeters. The 3D positioning of print heads in the print head shuttle however needs to be within micrometers and milliradians in order to achieve an acceptable droplet landing position accuracy, and linked therewith print quality. The droplet landing is critical in ink jet printing because digital images are printed as individual pixels on a predefined raster. Any deviation of a pixel from that raster is a printing error and may be visible to the human eye.
Digital printers generally use multiple print heads, all of them mounted on a single shuttle or carriage. They may be mounted on a common base plate of the shuttle or carriage by print head positioning devices. The base plate may, for example, be the sheet metal portion of the print head shuttle described above, having a cutout at each print head location. Examples of print head positioning devices have been described in U.S. Pat. No. 6,796,630 to R. Ison et al. and European Patent Application No. 04106837.0, which is incorporated herein by reference. Print head positioning devices may include features to adjust the position of the print heads relative to some reference data on the base plate itself or on a portion of the printer frame. These position adjustment features are designed to be very accurate, but are limited in their adjustment range. This range often is insufficient to compensate for manufacturing tolerances, e.g., flatness of the base plate, which may be in the range of millimeters for large constructions.
The problem of specification incompatibility between the flatness of a mounting plate, e.g., the sheet metal base plate of the print head shuttle framework, and the print head position accuracy in 3D space, is solved by providing a mounting assembly as illustrated in the
The tile 58 may be manufactured from a stainless steel plate or any other suitable material. The tile has a cutout 60, inline with the cutout in the base plate 57, through which a print head may be positioned. The tile 58 may be moveably fixed to the base plate 57 by spring loaded adjustment screws 63 and using mechanical reference data on the tile 58 and base plate 57. In a particular preferred embodiment, the tile's xy-position is determined by two bushings 61, one cooperating with a V-groove type datum on the tile and the other cooperating with a straight datum on the tile. The tiles are secured against these bushings by a spring 62. In the preferred embodiment shown in
A print head positioning device 59 is moveably mounted on each tile 58. The position of the print head positioning device 59 relative to the tile 58 can be adjusted by two spring loaded adjustment screws 65. The adjustments take place in a coplanar manner relative to the mounting surface of tile 58 onto which the print head positioning device 59 is mounted. In
The particular preferred embodiment of a mounting assembly as described above may be used as follows. In a first step, the print head mounting tile 58 is mounted onto the base plate 57 of the print head carriage framework 44. Its position is adjusted such that the mounting surface of tile 58, onto which the print head positioning device will be mounted, is level with a reference printing surface. This reference printing surface may be the surface of the printing table 2 of the digital printer 1. A reference printing surface may also be established offline, i.e., when the print head carriage framework 44 is not mounted in the printing system 1, by referring to the mechanical references 47 used to mount the print head carriage framework 44 onto the support frame 5 of digital printer 1. The print head carriage framework 44 may also be mounted on a calibration table, in which case the surface of the calibration table may serve as the reference printing surface. In the drawings, a reference printing surface is parallel with the xy-plane of the coordinate system. The position of the tile 58 coplanar with the reference printing surface is controlled by the bushings 61, the mechanical data on the tile, and the spring 62. In a particular preferred embodiment, the position accuracy of the tile's xy-position coplanar with the reference printing surface may be within 0.2 mm and it's levelness with the reference printing surface within 20 μm, for example.
The print head positioning device 59 is then mounted onto the print head mounting tile 58. Its position, relative and coplanar with the mounting surface of the tile and therefore substantially parallel with the reference printing surface, is adjusted with a resolution of the positioning device (e.g., the lever system mentioned above) associated with adjustment screws 65. In a particular preferred embodiment, the print head positioning device may be positioned with a resolution of about 3 μm and an accuracy of about ±5 μm relative to a fixed reference on the print head carriage 44 or relative to a neighboring print head positioning device, for example. In the specific embodiment of the print head positioning device disclosed in European Patent Application No. 04106837.0, the print head's printing surface (e.g., the ink jet nozzle plate) inherits the levelness of the tile 58 and the position of the print head positioning device 59. A levelness of the print head's printing surface of less than 20 μm and an xy-position accuracy of the print head better than about ±3 to ±5 μm is sufficient for high quality ink jet printing, for example.
If the adjustment range of screws 65 of print head positioning device 59 is insufficient to compensate for the inaccuracy of the position of the print head mounting tile 58 onto the base plate 57 or print head carriage 44, the print head's printing surface cannot be positioned to provide acceptable print quality. Then, additional positioning devices are required that bridge the tolerance gap between the base plate 57 or print head carriage frame 44 and the print head's printing surface. In inkjet printing, additional positioning devices may be provided by changing the range of operational inkjet printing nozzles within the range of an available inkjet printing nozzle in the inkjet print head. If, for example, an inkjet print head has 764 nozzles arranged in an array with an inter-nozzle distance (nozzle pitch) of 1/360 inch, a print width of 2 inches may be achieved with a contiguous set of 720 operational nozzles of the 764 nozzles. The contiguous set may be selected via software or firmware in the print head control circuitry. A shift of the selection with one nozzle yields another contiguous set of 720 operational nozzles of which the x-position is shifted 1/360 inch without adjusting the print head positioning device 59 or the mounting tile 58. Therefore, if not all the nozzles in an inkjet print head are operational during printing, a proper selection of the operational set of nozzles provides additional position adjustment of the final pixels on the printing medium, i.e., a position adjustment of a multiple of the nozzle pitch for the printed pixels on the printing medium. A proper selection of the operational set of nozzles in a print head may reduce the required range for adjustability of the position of the print head positioning device in the x-direction to one nozzle pitch distance, i.e. from −½ the nozzle pitch to +½ the nozzle pitch. This approach is especially advantageous in situations where high position accuracy and a wide adjustability range are required.
Other preferred embodiments of print head mounting and positioning methods and assemblies may be thought of that close the gap between inaccurate sheet metal frameworks and very accurate print head position specifications. The multitude of position adjustment devices used in the preferred embodiments, such as screws, bushings and springs, acting in multiple directions and controlling multiple relative positions between individual parts of the assembly may be replaced by other position adjustment devices known in the art or operate between other parts of the assembly without departing from the concept of using intermediate tiles and/or print head positioning devices to increase the print head position accuracy and finally the printed pixel position on the printing medium.
Thermal Stability
In the prior art it is known that the ink temperature of hot melt inks or UV-curable inks in ink jet printing processes is an important print quality and print reliability determining parameter. Multiple approaches have been described to control the ink temperature in these ink jet processes, both in the ink supply and in the ink jet print head. It has also been known in the prior art that local heat generation by activating individual ink jet chambers of the ink jet print head may disturb the heat management and influence the printing process, e.g., the droplet size may change. Already a number of solutions have been provided to control the temperature of the ink that is to be jetted by the ink jet print head, at the level of the ink supply as well as at the print head level.
A problem of thermal stability in ink jet printers, not often addressed in the prior art, is the thermal stability of the mounting frame or print head shuttle, especially the thermal stability of the references on the frame or shuttle that are used for precisely positioning of the print head. Temperature variations in mechanical structures introduce stresses that cause dimensional instability of the structure. In a mounting or print head shuttle framework, temperature variations in the mechanical structure may be introduced through parts of an ink supply system that are operated at an elevated temperature, e.g., UV-curable ink supplied at 45° C. or hot melt inks supplied at temperatures of about 100° C. and more. Temperature variations may also be introduced by the operation of radiation-curing or drying units that reciprocate back and forth together or synchronous with the print heads in the head shuttle for curing or drying the ink right after jetting. It is known that, for example, UV-curing systems not only radiate UV light but also radiate a substantial amount of IR light. The IR light scatters around and heats up the surrounding structures, including the print head shuttle framework. Heating of the print head shuttle framework may lead to positional drift of the print head positioning references of the framework. A solution to positional drift is provided by actively cooling the shuttle framework at locations contributing to the dimensional stability of the print head positioning references.
In this preferred embodiment of print head shuttle cooling channels, copper pipes are preferably used with an internal diameter of 8 mm. However, cooling channels may also be implemented using alternative concepts. These alternatives may include machined rectangular channels or extruded parts that are fixed to the sheet metal parts of the print head framework to form a sandwich of sheet metal parts with cooling channels. The bridge cooling channels may be located at the inside of the bridge or may be mounted at the outside. The cooling channels may also be manufactured from other materials than copper.
Any type of cooling fluid known in the art may be used, including water. The cooling channels, in order to drain heat energy from locations on the print head shuttle that are critical for the dimensional stability of the structure, are preferably linked to a supply of cooling fluid. The supply system preferably is a closed loop circulation system including a heat exchanger to withdraw heat from the cooling fluid. The flow rate of the cooling fluid in the circulation system may be adjustable. Given the mechanical implementation of the cooling circuits in the print head shuttle, the heat exchanger settings and the cooling fluid flow rate may be used to control the cooling efficiency and therefore control the temperature of the print head shuttle framework.
In the majority of applications, the print head shuttle will need active cooling to control its temperature at a number of locations. However, the cooling circuits may also be used to heat the print head shuttle at locations along the cooling circuits. It is important that a number of locations of the print head shuttle can be temperature controlled to preserve the dimensional stability of the framework and of the print head shuttle.
Print Head Shuttle Mounting
Referring to
The linear slides in turn may be mounted on a fast scan drive system to move the entire print head shuttle including the slow scan linear slides in the fast scan direction. This connection preferably uses ball joints to allow limited rocking or skew of the print head shuttle during movement, without introducing stress in the fast scan drive system or introducing distortions in the print head shuttle framework.
Other preferred embodiments may be used to provide both a fast scan movement and a slow scan movement of the print head shuttle relative to a printing table.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
Number | Date | Country | Kind |
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05104627 | May 2005 | EP | regional |
This application is a 371 of PCT/EP2006/062706, filed May 30, 2006. This application claims the benefit of U.S. Provisional Application No. 60/692,199, filed Jun. 20, 2005, which is incorporated by reference. In addition, this application claims the benefit of European Application No. 05104627.4, filed May 30, 2005, which is also incorporated by reference.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2006/062706 | 5/30/2006 | WO | 00 | 9/11/2009 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/128859 | 12/7/2006 | WO | A |
Number | Name | Date | Kind |
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5880757 | Ta et al. | Mar 1999 | A |
6796630 | Ison et al. | Sep 2004 | B2 |
7018027 | Harada et al. | Mar 2006 | B2 |
20030128254 | Ison et al. | Jul 2003 | A1 |
Number | Date | Country |
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1 674 279 | Jun 2006 | EP |
Number | Date | Country | |
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20100002050 A1 | Jan 2010 | US |
Number | Date | Country | |
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60692199 | Jun 2005 | US |