EP0334548A2

EP0334548A2 - Device to assure paper flatness and pen-to-paper spacing during printing

Info

Publication number: EP0334548A2
Application number: EP89302573A
Authority: EP
Inventors: Kent D. Vincent; John P. Ertel
Original assignee: Hewlett Packard Co
Current assignee: HP Inc
Priority date: 1988-03-21
Filing date: 1989-03-15
Publication date: 1989-09-27
Anticipated expiration: 2009-03-15
Also published as: DE68911564D1; EP0334548B1; DE68911564T2; HK128194A; JPH026170A; EP0334548A3

Abstract

A printer includes an inkjet pen (11) to eject ink drops for printing on the surface of a sheet (15), a carriage (13) mounted to carry the pen (11) back and forth on the sheet (15), and a skid-like spacer (21,31) to ride upon the printed surface. The spacer (21,31) maintains a preselected spacing between the pen (11) and the printed surface and, also, maintains paper flatness at the localized area of printing.

Description

The present invention generally relates to printers and, more particularly, to improved paper holddown devices for printers.
In printers such as inkjet printers having traveling inking means (e.g., inkjet pens), ink drops follow trajectories determined by the vector sum of the ink ejection velocity (Ve) and the velocity of the inking means (Vp). For example, in an inkjet printer providing resolution of about 300 dots per inch, a typical pen velocity would be about 0.34 m/sec and a typical inkjet ejection velocity would be about 5 m/s. If distance Dp is defined as the distance measured laterally along the surface of a printed sheet between the inking means and the intended location of ink dot placement on a sheet at the time of inkdrop ejection, and if distance Ds is defined as the pen-to-sheet spacing as measured perpendicular to the sheet surface, then the ratio of Dp to Ds is proportional to the ratio of the velocity Vp to the velocity Ve. Thus, assuming that the controllable variables Vp and Ve are fixed for a particular inkjet printer, the lateral distance Dp can be calculated to equal the quantity
Ds.
Ideally, distance Dp remains constant whenever a sheet is being printed to avoid misalignment of printed characters; however, because pen-to-sheet distance Dp is a function of distance Ds, the latter distance must also remain constant to maintain accurate ink drop placement during printing.
The maintenance of constant pen-to-sheet spacing distance, Ds, is especially critical in inkjet printers of the bidirectional type. In such devices, an inkjet pen prints a swath of ink drops while moving both from right-to-left and from left-to-right across the surface of a sheet. Normally, between each change in printing direction in bidirectional inkjet printers, the printed sheet is indexed a swath width (e.g., about 3/8 inch). Because such printers provide ink dots in columns in each swath, print defects will appear unless dot columns on adjacent swaths are closely aligned. In fact, it has been calculated that print defects will be perceived unless dot columns on adjacent swaths are aligned to within 1/10 of a dot diameter, or about 7 µm at a resolution of about 134 dots per cm. At the velocities described in this example, such alignment of dot columns in successive swaths requires that the pen-to-sheet spacing distance Ds be held to tolerances of about 756 µm.
Because of the precise tolerances required, conventional inkjet printers are often unable to provide consistently acceptable print quality. In fact, in conventional inkjet printers, the additive effect of manufacturing tolerances often cause pen-to-sheet spacing distance Ds to vary substantially more than desired. Also, the spacing distance Ds in conventional inkjet printers can be affected by lack of flatness in carriage guides and paper support plates.
Further, ink dot placement during printing can vary because of variations in sheet thickness and because of curls and cockles in sheets. For example, sheet thicknesses commonly used in printers vary from 45 µm to 157 µm. Also, cockles can be present because of paper defects and because of moisture present during printing.
To reduce the effects of paper curl and cockle on dot placement during printing, conventional practice is to employ sheet holddown devices such as electrostatic or suction devices. In an electrostatic holddown device, for example, paper flatness is maintained by establishing electrostatic attraction between a flat support plate on the printer and the back surface of a sheet to be printed. Likewise, in vacuum holddown devices, sheet flatness is maintained by providing suction between a support plate and the back surface of a sheet to be printed. It should be noted that, in either type of holddown device, direct contact of the holddown device with the printed surface is avoided to minimize ink smearing and other adverse affects on print appearance.
Although conventional holddown devices are fairly effective in maintaining sheet flatness during printing, they have drawbacks. One drawback is that such devices do not compensate for variations in sheet thickness. Another drawback is that the maximum holddown force on a sheet is limited because of the necessity to maintain low frictional loads on transport devices which index the sheets. In conventional inkjet printers, such limitations can cause pen-to-sheet spacing distances to vary from swath to swath. Also, the holddown pressure at a localized area being printed may be insufficient to flatten cockles and other paper irregularities; that is, the pressure required to flatten cockles in a sheet may be too great to allow precise paper indexing, especially in vacuum devices which exert pressure over the entire surface area of a sheet. Finally, conventional holddown devices are complicated and relatively expensive.
An object of the present invention is to provide improved paper holddown devices for use with printers.
More particularly, an object of the present invention is to improve printers, especially inkjet printers of the bidirectional printing type, by providing a device to accurately maintain pen-to-sheet spacing and sheet flatness during printing and, thereby, to minimize spacing deviations that cause misalignment in printed characters.
In accordance with the foregoing objects, the present invention generally provides a printer comprising an inking device that ejects ink drops for printing the surface of a sheet, and a spacer interposed between the inking means and the sheet surface to ride upon the surface being printed so as to maintain preselected spacing. In one particular embodiment, the spacer is a generally L-shaped member whose leg is connected to the inking device and whose foot is positioned to extend parallel to the sheet surface to ride as a skid on the printed surface of the sheet. In general, however, the spacer can be a skid, a wheel, a roller, or any other bearing-like device suited for supporting an inking device directly on a sheet with a preselected pen-to-sheet spacing.
The device of the present invention provides substantial advantages over conventional holddown mechanisms in printers because it directly acts on the printed surface to assure paper flatness and spacing accuracy. In contrast to conventional electrostatic and suction-type holddown mechanisms, devices according to the present invention maintain constant pen-to-sheet spacing even when paper thickness varies or when there are printer mechanism problems such as lack of flatness or straightness in carriage guide rods and paper support plates. Still further, the present invention simplifies printer design while increasing allowable manufacturing tolerances, thereby substantially reducing costs.
Additional objects and advantages can be ascertained by reference to the following description and attached drawings which illustrate various embodiments of the invention. Identical components are identified by the same reference numerals in the various figures.
In the drawings:

FIGURE 1 is a side view of a device according to the present invention;
FIGURE 1A is a side view of one component of the device of FIGURE 1, enlarged for purposes of clarity;
FIGURE 2 is a sideview of an alternative embodiment of the present invention;
FIGURE 3 is a cross-sectional detail, drawn to an enlarged scale for purposes of clarity, of a portion of the assembly in FIGURE 2 in an inverted position;
FIGURE 4 is a perspective view of the assembly of FIGURE 2;
FIGURE 5 is a sideview of yet another alternative embodiment of the present invention; and
FIGURE 6 is a fragmentary endview of the device of FIGURE 5.

In the preferred embodiment, a paper holddown device according to the present invention is used in conjunction with a printer of the inkjet type. Accordingly, FIGURE 1 shows a bidirectional inkjet printer includes an inkjet pen 11 that is held rigidly in a movable carriage 13 so that the pen nozzle 14 is above the surface of a sheet 15 which lays substantially flat on a stationary support plate 16. Further, the illustrated inkjet printer includes a drive roller 18 and a pinch roller 19 which are controlled to periodically index the sheet across the surface of plate 16. It should be understood that various systems for controlling sheet indexing are well known.
As also shown in FIGURE 1, carriage 13 is slidably journaled to a linear guide rod 20 by bearings 20A. Guide rod 20 is fixed to the printer chassis, not shown, to extend in the cross-direction parallel to the surface of sheet 15. (As used herein, the term "cross direction" refers to a direction perpendicular to the paper indexing direction.) Guide rod 20 and bearings 20A are designed to allow carriage 13 to move from side-to-side across the surface of a printed sheet but, in contrast to conventional inkjet printers, rotation of carriage 13 about rod 20 is not substantially restricted by the design of the rod or its bearings.
As further shown in FIGURE 1 and to an enlarged scale in FIGURE 1A, an L-shaped spacer member, generally designated by the number 21, is attached to carriage 13 with its foot 22 interposed between carriage 13 and sheet 15. Preferably, the upper surface 23 of spacer 21 abuts the lower end of inkjet pen 11 adjacent nozzle 14 and, thus, provides a physical stop. Also in the preferred embodiment, spacer 21 extends substantially across the width of inkjet pen 11 and its lower surface 24 is generally planar to provide a broad face to ride upon sheet 15. Thus, it can be understood that the distance between stop surface 23 and riding surface 24 defines the desired spacing of inkjet nozzle 14 from the surface of sheet 15.
In practice, it is necessary that spacer 21 have low contact friction with the surface of sheet 15 in both the cross-direction and in the indexing direction. Low contact friction in the cross-direction is required to facilitate back and forth travel of the inkjet pen, while low contact friction in the indexing direction is required to facilitate operation of the sheet transport device. To reduce contact friction, the peripheral edges of riding surface 24 are arcuate. Also, contact friction is reduced by the selection of the materials and the surface finish of riding surface 24. For example, riding surface 24 can be polished chromeplate to minimize friction as well as to increase wear life. To further reduce contact friction, a device (not shown) can be provided to lift spacer 21 off the sheet during indexing; normally, such a lifting device is operative at the margins of the sheet.
Another measure which can be taken to reduce contact friction is to provide an air bearing at the riding 24 surface of spacer 21. Such an air bearing is readily implemented by providing a source of pressurized gas and by forming appropriate holes or channels within riding surface 24 to allow the pressurized gas to escape between the riding surface and the face of sheet 15. In this embodiment, the spacer can still be said to ride on the sheet surface, albeit via a cushion of pressurized gas.
FIGURES 2 through 4 show an alternative embodiment of the present invention in which a spacer 31 is attached to the body of inkjet pen 11 rather than to carriage 13. More particularly, spacer 31 is an elongated rail-like member that is mounted to extend parallel to the longitudinal axis of guide shaft 20 across the body of inkjet pen 11. As shown in cross-section in FIGURE 3, spacer 31 has a generally planar riding surface 33 with arcuate peripheral edges to accommodate movement in the indexing direction. Also, as shown in perspective in FIGURE 4, the spacer ends 37a and 37b are arcuate to accommodate movement in the cross-direction.
FIGURES 5 and 6 show yet another alternative embodiment of the present invention. In this embodiment, a roller-like spacer 51 is connected to carriage 13 by flanges 55a and 55b. The flanges accept an axle 57 which extends coaxially of the roller-like spacer to allow it to roll freely in the indexing direction. As shown in FIGURE 6, the ends of roller-like spacer 51 are arcuately curved so that it easily skids back and forth over the surface sheet 15 in the cross-direction.
In operation of the inkjet printer of FIGURE 1, sheet 15 is held stationary by drive roller 18 while carriage 13 carries inkjet pen 11 back and forth across the sheet to print swaths of ink dots. After each swath is printed, roller 18 is driven so that sheet 15 is advanced in the direction indicated by the arrow over a distance equal to the swath width, and then carriage 13 again carries inkjet pen 11 across the sheet to print a second swath. This back-and-forth movement of carriage 13 is continued until the sheet is printed as desired.
As a sheet 15 is being printed, spacer 21 of FIGURE 1 slides across the printed surface of the sheet. Because of its proximity to the printed area, spacer 21 flattens the sheet at the localized area of printing. The force exerted by spacer 21 to flatten sheet 15 can be referred to as the contact force. The contact force is primarily determined by the weight distribution of inkjet pen 11 and carriage 13 relative to guide rod 20. That is, guide rod 20 acts as a fulcrum about which carriage 13 is pivoted. The net force, or torque, acting about rod 20 in the counterclockwise direction in FIGURE 1 depends upon the counterbalancing weight of the carriage on the opposite side of the rod. In practice, carriage 13 is mounted and balanced such that the contact force in the counterclockwise direction is sufficient to maintain the riding surface of spacer 21 in contact with the surface of sheet 15 and to assure substantial paper flatness under inkjet nozzle 14 without causing undue frictional drag.
At this juncture, it can be noted that the localized contact force exerted by spacer 21 can exceed the localized force exerted by a conventional holddown device which operates upon the entire paper surface. Accordingly, spacer 21 can provide a flatter surface at the point of printing than conventional holddown devices. In practice, spacer 21 holds pen-to-sheet spacing constant within one to two thousands of an inch.
Operation of the spacers in FIGURES 2 through 6 is substantially the same as the operation of spacer 21 in FIGURE 1. That is, those spacers either slide or roll over the printed surface while concentrating the contact force over localized areas near the point of ink impact with sheet 15. Thus, it can be appreciated that the spacers can take various forms, including notatable ball-like shapes (not shown), as long as they are capable of supporting an inking device directly on the surface of sheet 15 at the desired spacing.
In addition to the variations already mentioned, it should be noted that spacers can be formed integral with carriage 13 or pen body 11. In still another variation, a spacer is not physically attached to either carriage 13 or pen 11 but, instead, is mounted to float between the carriage and the surface of sheet 15. Also, although the preceding discussion has emphasized inkjet pens that move back-and-forth in the cross-direction, the afore-described spacing devices could be used with printers having stationary inkjet pens or with so-called wire-matrix print heads as well as other inking means, such as so-called daisy wheel printers. Still further, although the spacing devices have been discussed in the context of operating upon a flat surface, they could operate upon a generatrix of a cylindrical surface.

Claims

1. A printer comprising: inking means (11,13) for printing on the surface of a sheet (15); and characterised by that it further comprises a spacer (21) interposed between the inking means (11,13) and the sheet (15) so that the spacer (21) rides upon the surface of the sheet (15) to be printed so as to maintain a preselected spacing between the inking means (11,13) and the sheet (15) during printing and to exert a force to flatten the sheet (15) at the localised area of printing.

2. A printer according to Claim 1 wherein the spacer (21) is a generally L-shaped member(21) whose leg is connected to the inking means (11,13) and whose foot (22) is positioned to extend parallel to the sheets (15) surface.

3. A printer according to Claim 2 wherein the foot (22) is located such that the inking means (11,13) abuts the upper surface (23) of the foot (22) and the lower surface of the foot (24) rides as a skid on the printed surface of the sheet (15).

4. A printer according to Claim 1 wherein the spacer (31) is an elongated rail-like member which is substantially U-shaped in transverse cross-section and which is connected to the inking means (11,13) so as to ride as a skid on the surface of the sheet (15) to be printed.

5. A printer according to any of Claims 2 to 4 wherein the portion of the spacer (21,31) which rides upon the sheet (15) presents a substantially planar surface with radiused edges.

6. A printer according to any preceding claim wherein a gas bearing is formed between the spacer (21,31) and the surface of the sheet (15) to be printed.

7. A printer according to Claim 1 wherein the spacer comprises an elongated roller-like member (51) which is rotatably connected to the inking means (11,13)

8. A printer according to any preceding claim further comprising indexing means to index the sheet (15) on a surface (24) adjacent to the inking means (11,13).

9. A printer according to claim 8 wherein the elongated axis of the spacer (21,31) is at right angles to the direction of indexing.

10. A printer according to any preceding claim wherein the inking means (11,13) comprises an ink jet pen (11) mounted on carriage means (13).

11. A printer according to any preceding claim wherein the spacer (21,31) extends substantially across the width of the inking means (11).

12. A printer according to claim 10 wherein the spacer (21,31) extends substantially across the width of the ink jet pen (11).

13. A printer according to any preceding claim wherein the spacer (21,31) is attached to the ink jet pen (11).

14. A printer according to any of claims 8 to 13 wherein the spacer (21,31) is mounted so as to travel across an area of a sheet (15) to be printed immediately before the area is printed.