The present disclosure broadly relates to the art of packaging and, more particularly, to packaged sheet media and a method of loading the same on or into a printing system.
The terms “print”, “printing” and “marking” as used herein are to be broadly interpreted to encompass any action or process involving the production or output of sheet media having text, images, graphics and/or other indicia formed thereon by any process, such as ink jet or electrophotographic processes, for example. The terms “printer” and “printing system” as used herein are to be broadly interpreted to encompass any device, apparatus or system that is loaded or otherwise utilizes one or more stacks of sheet media and is capable a “printing” action. Examples of such equipment and/or systems include, without limitation, desktop printers, network printers, standalone copiers, multi-function printer/copier/facsimile devices, and high-speed printing/publishing systems. Additionally, such sheet media can be of any type or kind, such as paper or polymeric film, for example. Furthermore, such exemplary embodiments of equipment and/or systems can output indicia on the sheet media using any printing or marking substance, such as ink, toner or colorant, for example, in monochrome (e.g., black) or one or more colors, or any combination thereof.
Printing systems are well known and commonly available in a wide variety of types, kinds and configurations. Volumes of paper and other media are processed each day using such printing systems, generally with minimal problems and/or difficulties. However, discontinuities in performance and operation do occur in these printing systems and such occurrences are sometimes attributed to jams caused by misfeeds or multi-feeds of the sheet media being used, such as paper, polymeric transparencies or other media.
Significant efforts have been directed to improving media transport pathways and components, and considerable improvements have been achieved. It seems, however, that less attention has been paid heretofore to improving the condition of the media itself, and particularly the state of the media at the time of loading into a component of the printing system, such as a media supply tray.
As an example, adhesion between adjacent sheets of media can often occur as a result of manufacturing and/or packaging processes. This condition is sometimes referred to as “edge weld”, and it can cause multiple sheets of media to be simultaneously drawn into and/or fed along the media pathway. This is undesirable and occasionally results in the printing system undergoing an operational discontinuity. To minimize the difficulties encountered due to edge weld and/or other undesirable conditions, instructions and training are often provided that include techniques for preparing and loading sheet media into a printing system. Such techniques, however, may not be performed correctly or, in some cases, may not be performed at all. As such, the undesirable conditions of the sheet media discussed above often remain present and result in performance discontinuities which are desirable to avoid.
Another issue associated with the loading of sheet media into a component of a printing system, such as a media supply tray, is the physical challenge of fitting the stack of sheet media into the tray. For sheets of media to be correctly and consistently drawn into and fed along the media pathways of the printing system, it is desirable for the supply of sheet media to be captured within the tray or other supply component. This assists in maintaining a consistent orientation of the media within the tray for uniform presentation of the sheets of media to the feeding mechanism. As such, the tray and/or component parts thereof are normally adjusted to closely fit around the sheet media stored therein. Unfortunately, this arrangement often makes the proper loading a stack of sheet media into the tray a challenging task.
Due to the difficulties of loading an entire stack of media into the supply tray at one time, others techniques are attempted by users and/or operators of printing systems. For example, in one such technique a stack of sheet media is divided into smaller portions, which are then individually loaded into the supply tray. While these portions are usually somewhat more manageable to physically handle, the resulting load of sheet media will normally consist of multiple small portions that are often not uniformly stacked and may have considerable variability in orientation and/or presentation to the feeding mechanism. As a result, misfeeds, multi-feeds and other conditions can occur and result in performance discontinuities.
The embodiments of packaged sheet media and method of using the same of the present disclosure have been developed to overcome these and other problems and disadvantages.
A package of sheet media in accordance with the present disclosure is provided and includes a stack of sheet media and a wrapping layer. The stack having a stack length, a stack width and a stack height. The wrapping layer extending around the stack along the stack height and one of the stack length and the stack width such that the other of the stack length and stack width remains exposed by the wrapping layer.
A ream of paper packaged for use on an associated paper tray of an associated printing system is provided and includes a stack of from about 475 to about 525 sheets of paper, a first wrap formed from paper, and a second wrap formed from paper. The stack includes a top, a bottom, a first end, an opposing second end, a first side and an opposing second side. The first wrap has a central portion extending between opposing end portions and is disposed around the stack with the opposing end portions secured together along one of the top and the bottom of the stack. The second wrap covers substantially all of the top, the bottom, the first end, the second end, the first side and the second side of the stack.
A method of loading a stack of sheet media into a media supply tray of a printing system is provided and includes providing a packaged stack of sheet media including a stack of individual sheets of media and an inner wrapping layer extending around a portion of the stack of sheets. The method also includes loading the stack of sheets into the associated paper tray using the inner wrapping layer. The method further includes removing the inner wrapping layer.
Turning now to the drawings wherein the showings are for the purpose of illustrating exemplary embodiments and not for limiting the same,
Packaging wrap or wrapping layer 104 includes a central portion 118 extending between opposing end portions 120 and 122. As shown in
An alternate embodiment of wrapping layer 104 is shown in
Turning again to
Wrapping layers 104 and 104′ are preferably of a sufficient length to extend around stack 102, such as across top 106, bottom 108 and opposing sides 114 and 116, for example, or across top 106, bottom 108 and opposing ends 110 and 112, for example. Thus, it will be appreciated that wrapping layer 104 (or wrapping layer 104′) will have a minimum length of twice the height H of the stack plus either twice the width W1 of the stack or twice the length L of the stack. Additionally, one exemplary embodiment of the wrapping layer includes enough additional material to form an overlap portion suitable for securing the ends of the wrapping layer together, as indicated by dimension OL1 in
Wrapping layers 104 and 104′ can be formed from any suitable material or combination of materials. For example, the wrapping layer could be formed from either a paper, such as a recycled paper stock, for example, or a polymeric material. What's more, wrapping layers 104 and 104′ are shown as being formed from a unitary length of material. It will be appreciated, however, that in other exemplary embodiments wrapping layers 104 and 104′ can be formed from two or more lengths of material that are joined together to form a wrapping layer having an overall length sufficient to extend around the stack of sheet media. As such, a packaged stack of sheet media could include two or more joints, such as is the overlap portion identified by dimension OL1, for example, joining the two or more lengths of material. In such an arrangement, it would be possible to dispose an overlap portion along each of the top and bottom of the stack for convenient separation of the joint. However, any other suitable positioning or orientation could alternately be used.
In the exemplary embodiment shown in
Wrapping layer 104 (or 104′) is shown in
Additionally, the buckling or flexing of the stack reduces an overall dimension of the stack such that increased clearance between the side walls of the media supply tray and the stack is formed, as indicated by dimensions GP2. Thus, the stack of sheet media can be more easily loaded into the cavity of the supply tray. Upon releasing the wrapping layer and stack of sheet media into the cavity of the supply tray, the stack reverts to its substantially rectangular shape having the minimal clearance with the walls of the supply tray, as indicated by dimensions GP1. Thereafter, the wrapping layer can be torn or otherwise separated and removed from around the stack of sheet material.
Another embodiment of a package of sheet material 200 is shown in
Providing a packaged stack of sheet media in item number 302 can optionally include providing an unpackaged stack of individual sheets of media, as indicated by item number 310, and securing a first wrap or inner wrapping layer, such as wrapping layer 104, 104′ or 204, around the stack of sheet media as indicated by item number 312. Providing a packaged stack of sheet media in item number 302 can also optionally include securing a second wrap or outer wrapping layer, such as wrapping layer 206, for example, around the stack of sheet material and the first wrap or inner wrapping layer, as indicated by item number 314.
If item number 304 is included and the outer wrapping layer is provided, transporting the packaged stack in item number 304 can include transporting the stack while the same is covered by both the inner and outer wrapping layers. Furthermore, if the optional outer wrapping layer is provided, method 300 can include removing the outer wrapping layer exposing the inner wrapping layer, as indicated by item number 316.
Loading the packaged stack of sheet media in item number 306 can optionally include transporting the stack of sheet media to the media supply tray using the first wrapping layer, as indicated by item number 318. Furthermore, loading the packaged stack of sheet media in item number 306 can optionally include orienting the stack of sheet media relative to the media supply tray and placing the stack in or on the media supply tray, as indicated by item number 320. Thereafter, item number 308 can be performed.
It will be appreciated that various of the above-disclosed and other features and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Also that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.
Number | Name | Date | Kind |
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2199676 | Salsman | May 1940 | A |
4830186 | George et al. | May 1989 | A |
4998620 | Taylor | Mar 1991 | A |
6044975 | Dirx et al. | Apr 2000 | A |
Number | Date | Country | |
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20070119725 A1 | May 2007 | US |