The present disclosure relates to printable media transport and hold-down systems. More specifically, the present disclosure relates to movable guides used to overlap and hold down printable media such as paper, cardstock, or other substrates.
Direct-to-paper ink jet printing systems typically include a printable media hold-down system. As a printable medium passes on a transport surface under an ink jet print head, the hold-down system attempts to prevent contact between the printable medium and the print head. Contact between printable media and the print head may result in fibers from printable media becoming lodged in ink nozzles in the print head. Over time, a substantial number of fibers could become lodged in the nozzles causing the print head to clog. A clogged print head can damage printable media by printing incorrectly, wasting ink and causing significant downtime as the clogged head must be cleaned and/or replaced.
Some high speed printing systems, or systems for printing larger sizes of printable media, may require a large array of print heads. A clogged print head is especially troubling when using a print head array. Cleaning and/or replacing the print heads in a print head array can cause an even greater downtime depending on the size of the print head array.
Several hold-down systems are prevalent in modern direct-to-paper printing systems. One example is a vacuum/plenum system. In this system, a series of small holes are placed in the transport surface, and air is sucked through the holes, away from the print head (or print head array). As the printable medium passes under the print head (or print head array), a vacuum is created under the printable medium, thereby holding the printable medium against the transport surface.
Another exemplary hold-down system is an electrostatic tacking hold-down system. In this system, the transport surface is electrostatically charged, resulting in the printable medium tacking, or electrostatically sticking, to the transport surface as the printable medium moves under the print head (or print head array).
Both of these hold-down systems have inherent problems, however. Specifically, both of these approaches have limits to the amount of force that can be applied across printable media to protect printable media from coming into contact with the print head (or print head array). Both of these approaches are particularly susceptible to failure at the corners and edges of printable media. At the corners and edges, the downward force caused by the vacuum is less than at other portions of a printable medium due to air leakage around the edge of the printable medium, and the force exerted by an electrostatic system decreases if the sheet edge is not in intimate contact with the belt. Also, at the corners at edges, the bending moment imparted by the vacuum or the electrostatic tacking is lowest, which can result in the corners and edges bending away from the transport surface and contacting the print head (or print head array).
This disclosure is not limited to the particular systems, devices and methods described, as these may vary. The terminology used in the description is for the purpose of describing the particular versions or embodiments only, and is not intended to limit the scope.
As used in this document, the singular forms “a,” “an,” and “the” include plural references unless the context clearly dictates otherwise. Unless defined otherwise, all technical and scientific terms used herein have the same meanings as commonly understood by one of ordinary skill in the art. Nothing in this document is to be construed as an admission that the embodiments described in this document are not entitled to antedate such disclosure by virtue of prior invention. As used in this document, the term “comprising” means “including, but not limited to.”
In one general respect, the embodiments disclose a printable media hold-down system. The printable media hold-down system includes a print head array, a transport surface positioned adjacent to the print head array which transports a printable medium past the print head array in a location where the print head array may apply ink to the printable medium, and a vacuum system that creates vacuum pressure that holds the printable medium to the transport surface, the vacuum system having at least one adjustable baffle configured to move in a cross process direction and change a dimension of the vacuum system based on a dimension of the printable medium.
In another general respect, the embodiments disclose an alternative printable media hold-down system. The alternative printable media hold-down system includes a print head array, a transport surface positioned adjacent to the print head array which transports a printable medium past the print head array in a location where the print head array may apply ink to the printable medium, and a vacuum system that creates an area of vacuum pressure that holds the printable medium to the transport surface, wherein the vacuum pressure applied to an edge region of the printable medium parallel to a process direction of the printable medium is higher that the vacuum pressure applied to an interior region of the printable medium.
In another general respect, the embodiments disclose an additional alternative printable media hold-down system. The additional alternative printable media hold-down system includes a print head array, a transport surface positioned adjacent to the print head array which transports a printable medium past the print head array in a location where the print head array may apply ink to the printable medium, at least one sensor for detecting size and dimension information of the printable medium, and a vacuum system that creates vacuum pressure that holds the printable medium to the transport surface, the vacuum system having at least one adjustable baffle configured to change a dimension of the vacuum system based on a dimension of the printable medium.
For purposes of the discussion below, a “printable medium” refers to a physical sheet of paper, plastic and/or other suitable substrate for printing images thereon.
A “print head” refers to a device configured to disperse ink onto a printable medium.
A “print head array” refers to one or more print heads configured to disperse ink onto a printable medium.
A “transport surface” refers to a porous or non-porous surface on which a printable medium is transported past a print head or print head array.
A “vacuum chamber” refers to an enclosed space where a quantity of air may be removed to create a negative pressure in the enclose space.
The transport surface 104 may include a vacuum/plenum system or an electrostatic system of holding the printable medium 102 down flat. In this example, a vacuum system 114 may include one or more adjustable baffles 124. The adjustable baffles 124 may be configured such that they move in a cross process direction, e.g., a direction perpendicular to the direction a piece of printable media moves through the printing system, thus changing the cross process dimension of a vacuum chamber 120. The adjustable baffles 124 may be positioned such that they define the vacuum chamber 120 as well as one or more areas 130 having no vacuum pressure created by the vacuum system 114.
The adjustable baffles 124 may be connected to various baffle drives 126 and 128. The baffle drives 126 and 128 may be a metal rod having threads on each end such that as the drives turn, the adjustable baffles 124 move in either an inboard or outboard direction. The threads may be oriented such that as the drives 126 and 128 turn, the adjustable baffles 124 move in opposite directions of each other. Conversely, the threads may be oriented such that the adjustable baffles 124 move in the same direction.
By moving the adjustable baffles 124, the printable media hold-down system 100 may change the size of the vacuum chamber 120, thus changing the surface area on transport surface 104 where vacuum pressure is present. This arrangement may reduce the requirements of vacuum system 114 by eliminating wasted vacuum suction on areas of the transport surface 104 not transporting the printable media 102.
As the printable medium approaches the vacuum chamber 120, the size of the printable medium may be determined via a set of one or more sensors (e.g., the sensors 118, not shown in
Depending on the capabilities of the motor 132, a home sensor may be included such that the adjustable baffles 124 are returned to a standard position after a printable medium passes, or after a run of same sized printable media is completed. The motor 132 may be a stepper motor having a series of defined rotations wherein each rotation corresponds to a particular distance. For example, if the adjustable baffles 124 return to a home position such that the vacuum chamber 120 is at its largest size (i.e., the adjustable baffles are at the extreme outboard and inboard positions), and an approaching printable medium is measured to be 8 inches wide, the motor 132 may move the baffle drive 126 until the adjustable baffles are positioned such that the vacuum chamber is optimally sized for an 8 inch wide printable medium.
It should be noted that a stepper motor is include by way of example only. Additional motors such as electric servo motors, induction motors, or other similar devices may be incorporated.
Each high pressure vacuum chamber 136 may include a vacuum duct 138 to create a high pressure vacuum in the chamber. As the alternative adjustable baffles 134 may move, thereby moving the high pressure vacuum chambers 136, the vacuum ducts 138 may be constructed from a lightweight flexible material such that the ducts do not impede the movement of the alternative adjustable baffles.
As discussed above, as the printable medium 102 approaches the vacuum chamber 120, the size of the printable medium may be determined via a set of sensors (e.g., the sensors 118, not shown in
The larger holes 304 and the smaller holes 306 may be positioned such that the largest and smallest sizes of printable media that may be transported are accommodated. For example, if a printing device is configured to handle printable media ranging from 8 inches to 16 inches, the larger holes may be positioned such that the edges parallel to the process direction of all sizes of printable media between 8 inches and 16 inches are positioned in the larger holes 304.
It should be noted the sizes and patterns of the holes in transport surface 302 as shown in
The tabs 406 may be removably or permanently attached to the adjustable baffles such that the tabs move in concert with any movement of the adjustable baffles. Thus, as the adjustable baffles move to accommodate various sizes of printable media, the tabs 406 move as well.
The arrangement of the tabs 406 as shown in
As before, one or more tabs 406 may be positioned adjacent to the holes (e.g., holes 304 and 306) of transport surface 302 to reduce the amount of unnecessary or redundant air being pulled through the holes in the area of low vacuum pressure 404. The tabs 406 may be constructed from a material such as plastic, aluminum or steel. The tabs 406, however, may be made from a material that will not deflect as a result of the vacuum pressure created by blower 410.
As illustrated in the discussions of
Various of the above-disclosed and other features and functions, or alternatives thereof, may be combined into many other different systems or applications. Various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art, each of which is also intended to be encompassed by the disclosed embodiments.
This application is related to U.S. patent application Ser. No. 12/389,023, filed Feb. 19, 2009, the content of which is hereby incorporated by reference in its entirety.