Some existing liquid toner systems utilize an intermediate transfer member to transfer a liquid toner image from a photosensitive member on which the image is developed to a final substrate. In order to reduce problems that may be caused when printing media is misfed, an impression media (generally of paper) is placed between the printing media and an impression roller which holds the printing media during transfer of the liquid toner image thereto from the intermediate transfer member.
The present application is directed to novel impression media and mechanisms utilizing it.
An exemplary configuration of existing laser printers is illustrated in a very simplified form in
The printing media is held to the impression member by printing media grippers 12.
If there is a paper jam, or some other malfunction, and the grippers do not pick up the printing media, then toner will be transferred from the intermediate transfer member directly to the surface of the impression member. Because the impression member, which has a metal surface, does not absorb toner as well as the printing media, some toner will remain on the intermediate transfer member. If the intermediate transfer member is not immediately cleaned off, then the toner may dry if it is liquid, or possibly melt if it is solid, which may cause permanent damage to the intermediate transfer member. To prevent this from happening, a piece of media, described herein as impression media or impression paper (since it is generally of paper) 9, is sometimes permanently glued to the surface of the impression member at a point designated as 11. The forward edge of the impression media is positioned underneath the printing media, i.e., the forward edge does not extend past the edge 13 of the printing media that is held by the grippers.
Even if the impression member picks up no printing media, the impression paper surface will absorb all the toner from the intermediate transfer member, and the intermediate transfer member will not be damaged by dried toner.
However, the impression paper can create its own problems. First there are the problems connected with gluing. Inter alia, since there may be a slight difference in velocity between the impression roller and the intermediate transfer member (in order to avoid buckling of the paper), there is significant stress on the glue. Therefore, the glue has to be strong. Unfortunately, since paper misfeeds do occur, the impression paper must be removable. This mandates a weaker bond for the glue. Furthermore, the area available for gluing is limited, in order not to interfere with the printable area of the print media and may sometimes intrude on this area slightly. Additionally with time, the impression paper may slide along the impression roller in a direction opposite the direction of motion of the impression roller surface.
The differences of height caused by the presence of glue under the impression paper cause poor or sometimes even an absence of transfer from the intermediate transfer member to the print media. If the impression media needs to be replaced, for example because it is worn or torn or because it has been printed on due to a paper misfeed, it can be difficult to remove the old impression paper completely. Finally, the smooth surface of the impression paper creates a partial vacuum between the impression paper and the printing media, when the latter is picked up by suction elements to remove it from the impression member. This may cause the printing media to be picked up in an uncontrolled manner, especially if it is thin paper.
Many of the features of the impression paper clamp shown in
Impression paper clamp 400 comprises an upper portion 402, in the form of a straight bar, and a lower portion. Optionally, upper portion 402 clamps the impression paper directly against in integral part of the impression member, instead of against the lower portion, and in that case there is no need for a lower portion. The lower portion optionally includes a back section 406, which fits into a slot in the impression member, and a number of teeth 408, which press against upper portion 402 to hold the impression paper. The spaces between the teeth optionally allow the grippers to open through corresponding apertures in the impression paper, as shown in
Two captive nut and bolt assemblies 414 can be tightened, through openings 416 (not visible in
In
When impression paper 600 is inserted into impression paper clamp 400, the bolts in the two assemblies 414 each go through its associated slot 802. Optionally, impression paper 600 lacks slots 802, and is inserted into impression paper clamp 400 only far enough so that its leading edge touches the bolts. However, allowing the bolts to go through slots 802 makes it possible to push impression paper 600 further into impression paper clamp 400, so that it can be held more firmly.
Optionally, slots 802 are replaced by bolt holes for the bolts to go through, and the bolts are disengaged from the nuts and raised above the impression paper until the impression paper is fully inserted, at which time the bolts are lowered through the bolt holes and engaged in the nuts. By using slots 802 instead of holes, the bolts can be kept engaged in the nuts while impression paper 600 is being inserted into impression paper clamp 400. Optionally, in embodiments of the invention where a mechanism other than the nut and bolt assemblies is used to tighten the impression paper clamp, or where there is no mechanism to tighten the impression paper clamp, impression paper 600 does not have slots 802, or bolt holes.
Although
Impression paper 600 is formed with apertures, such as narrow slits 900 or a pattern of small holes, beneath suction cup 14. When suction cup 14 pulls printing media 8 away from impression paper 600, a partial vacuum would be created between the smooth surfaces of printing media 8 and impression paper 600. Slits 900 allow air from the space between impression paper 600 and impression member 10 to flow into the space between impression paper 600 and printing media 8, preventing a significant vacuum from forming, and allowing suction cup 14 to pull printing media 8 away from impression paper 600 and impression member 10 in a controlled, predictable manner. It should be noted that because grippers 12 are no longer holding printing media 8 and impression paper 600 down against impression member 10, and because the other end of impression paper 600 opposite the end held by impression paper clamp 400) is free, and because impression paper 600 is somewhat stiff, impression paper 600 may not lie flat against impression member 10, so there may be a space filled with air between impression member 600 and impression member 10, which can flow through slits 900. In other embodiments of the invention, not all these conditions are met, however, even if only some of the conditions are met, there may still be enough air flowing through slits 900 so that suction cups 14 pull media 8 off impression member 10 in a controlled manner. However, as indicated above, while single slits or single or multiple apertures can be used for releasing the vacuum formed, they have a tendency to become clogged with debris, such as paper fibers. Thus, for this embodiment, the size of the apertures must be increased, for example greater than 0.1 mm and preferably larger, up to a size which interferes with the printing quality, which may be some larger fraction of a mm.
In a preferred embodiment of this aspect of the invention, the apertures are slits that are formed in pairs. Under these circumstances, the effect of lifting of the printing media is to lift the region between the slits. This allows air to enter the region between the printing media and the impression paper, releasing the vacuum. For this embodiment, the width of the slits is not a factor in the operational life of the impression paper and the slits are preferably made as thin as possible, for example 0.1 mm or less (e.g., 0.05 or 0.02 mm). However, the invention is not limited to such thin slits, which may be difficult to manufacture.
In general, it is desirable that the distance between slits be smaller than the size of suction cup 14. At present a distance of about 7 mm is used. However, smaller distances can be used and more than two slits may be provided beneath each suction cup. Furthermore, the length of the slits should be at least as long as the diameter of the suction cups, to aid in the lifting of the portion between the slits. However, this is not absolutely necessary.
The one suction cup 14 shown in
Slits 900 need not be used in conjunction with impression paper clamp 400, but optionally could be used in impression paper that is attached to the impression member in a different way, for example by gluing.
Impression paper preferably has a number of desired characteristics. First, the impression paper should be strong enough so that it can stand the sliding forces induced on it, considering that it contains a series of cut-outs. Second, it is desirable that the impression paper be smooth and of uniform thickness. This avoids texturing of the images printed on the printing media. Third, it should absorb the ink from the intermediate transfer member, in case of a paper miss-feed. However, since the same impression roller may also be used for printing a second side of duplex, it should not offset ink from the first side, when an image is transferred to the second side from the (hot) intermediate transfer member. Fourth, while it is desirable that the impression paper be stiff, it is also desirable that the paper conform to the curvature of the impression member. Of course, in order to work, impression paper need not be optimized for all or even any of these parameters.
It has been found that Gardamatt Art paper (Garda Cartiere, Italy) provides a suitable impression paper, for various thicknesses from nominally 101 micrometers thickness (Gardamatt 115) to nominally 313 micrometers thickness (Gardamatt 300), although thicker paper (>200 micrometers) are sturdier. The smoothness of this paper veries between 20.+−0.5 to 30 or 40.+−0.10 or 20 for the thinner papers. However, the smoothness is not critical, so long as there is no texturing of the image. This paper is short fiber paper and is cut so that the stiffer direction is parallel to the axis of the impression roller. This allows the impression paper to conform to the impression roller.
The invention has been described in the context of the best mode for carrying it out. It should be understood that not all features shown in the drawings or described in the associated text may be present in an actual device, in accordance with some embodiments of the invention. Furthermore, variations on the method and apparatus shown are included within the scope of the invention, which is limited only by the claims. Also, features of one embodiment may be provided in conjunction with features of a different embodiment of the invention. Furthermore, it should be understood that not all of the embodiments of the invention solve all of the problems that are associated with the prior. It is contemplated that some problems of the prior art will be solved by other means or will not be solved at all. As used herein, the terms “have”, “include” and “comprise” or their conjugates mean “including but not limited to.”
The present application is a continuation application claiming priority from co-pending U.S. patent application Ser. No. 11/190,378 filed on Jul. 26, 2005 by Alex Feygelman and Ofer Fredi and entitled IMAGE TRANSFER MECHANISM, which is a continuation application claiming priority to application PCT/IL03/00083, filed on Feb. 2, 2003, now International Publication WO 2004/067277 A1, titled IMAGE TRANSFER MECHANISM, the full disclosures of which is hereby incorporated by reference.
Number | Date | Country | |
---|---|---|---|
Parent | 11190378 | Jul 2005 | US |
Child | 12582331 | US | |
Parent | PCT/IL03/00083 | Feb 2003 | US |
Child | 11190378 | US |