Disclosed is an idler roller assembly for use with a printing apparatus.
In a typical printing apparatus, media such as paper will be stored in a tray or trays. When printing occurs, typically the paper or media will be pulled from the tray and fed through a printing feed path. Typically the paper will be driven through the printing feed path by rollers assemblies, each of which may include a drive roller assembly and an idler roller assembly. Where the printer is an electrophotographic printer, the roller assemblies will drive the paper along the printing feed path to printing elements such as a photoreceptor, fuser, and the like. Where the printer is an ink jet printer, the roller assemblies will drive the paper along the printing feed path to printing elements such as an inkjet printhead, a print assembly, a pressure roll, and the like, and eventually to an output tray.
The idler roller assemblies are often made of a lightweight and low cost material, such as plastic. The idler roller assembly typically includes a shaft with one or a pair of idler rolling elements. The idler rolling elements are aligned with drive roller elements to form nips for driving the paper or other media. To ensure control of the media and to minimize wear of the drive roller elements, the idler rolling elements must maintain substantial parallelism to the shaft of the idler assembly.
According to aspects of the embodiments, there is provided an idler roller assembly for a printing apparatus. The idler rolling assembly includes a shaft, at least one idler rolling element connected to the shaft, the at least one idler rolling element having an inner surface and an outer surface and being connected to the shaft at a substantially center portion of the idler rolling element, the at least one idler rolling element being cylindrically shaped and having an axis substantially parallel to an axis of the shaft, and at least one radial control movement element connected to the shaft, the at least one radial control movement element having a radius selected to leave a predetermined gap between an outer edge of the at least one radial control movement element and the inner surface of the idler rolling element.
While the present invention will be described in connection with preferred embodiments thereof, it will be understood that it is not intended to limit the invention to that embodiment. On the contrary, it is intended to cover all alternatives, modifications and equivalents as may be included within the spirit and scope of the invention as defined by the appended claims.
The embodiments include an idler roller assembly for a printing apparatus. The idler roller assembly includes a shaft, at least one idler rolling element connected to the shaft, the at least one idler rolling element having an inner surface and an outer surface and being connected to the shaft at a substantially center portion of the idler rolling element, the at least one idler rolling element being cylindrically shaped and having an axis substantially parallel to an axis of the shaft, and at least one radial control movement element connected to the shaft, the at least one radial control movement element having a radius selected to leave a predetermined gap between an outer edge of the at least one radial control movement element and the inner surface of the at least one idler rolling element.
The embodiments further include an idler roller assembly for a printing apparatus, which includes a shaft, a plurality of idler rolling elements connected to the shaft, the plurality of idler rolling elements each having an inner surface and an outer surface, the plurality of idler rolling elements having an axis substantially parallel to an axis of the shaft, and a plurality of radial control movement elements connected to the shaft, the plurality of radial control movement elements each having a radius selected to leave a predetermined gap between an outer edge of the radial control movement element and the inner surface of each of the plurality of idler rolling elements.
In as much as the art of electrophotographic printing is well known, the various elements employed in the
The printing apparatus 110 may also include a feed tray 132. The feed tray 132 can feed media to be scanned into the printing apparatus 110, where it may be scanned by scanning device 118, for example. Scanning device 118 may be a duplex scanning device, such as full-width array bars or the like. Media from feed tray 132 does not follow the entire printing feed path, but instead may exit from the printing feed path at scanner feed path 120, where it may be directed to the scanner output tray 122, which may be formed as an integral part of a cover of the printing apparatus 110. Thus, media to be scanned from the scanner feed tray 132 may not proceed to the photoreceptor 124 or to the fuser 126.
When pressure is applied to the idler rolling element 214 at either end away from the lengthwise central portion, the idler rolling element is movable towards the shaft 212, while the central portion is held a uniform distance from the shaft 212, by a connection such as a snap-fit connection inside the idler rolling element 214. For example, if pressure is put on the idler rolling element 214 in the location of and in the direction of arrow A, that portion of the idler rolling element 214 can move towards the shaft 212 in the direction of arrow A. Likewise, if pressure is put on the idler rolling element 214 in the location of and in the direction of arrow B, that portion of the idler rolling element 214 can move towards the shaft 212 in the direction of arrow B. This may result in the idler rolling element 214 becoming misaligned with the shaft 212. The shape of the shaft 212 shown is just one possible shape.
The drive roller assembly 116 includes drive rolling elements that align with the rolling elements 214 to form a nip, through which the media is drawn. If one or more of the idler rolling elements 214 becomes substantially misaligned with the shaft 212, it will cause undesirable wear on the drive rolling elements of the drive roller assembly 116.
Accordingly, the present invention includes at least one radial movement control element 316 for controlling the movement of each idler rolling element 314 in a radial direction in a perpendicular direction towards the shaft 312, as part of the idler rolling assembly 310. The radial movement control element 316 may be attached to the shaft 312, and may be formed from a same material as the shaft 312, such as plastic or the like. The idler rolling elements 314 have an axis that is substantially parallel to an axis of the shaft 312.
The radial movement control element 316 may be disposed adjacent to an inner end portion of each of the idler rolling elements 314 in a lengthwise direction towards a center of shaft 312. Further, the radial movement control element 316 may be disposed at one end only of each idler rolling element 314, or there may be a radial movement control element 316 disposed at each end of each idler rolling element 314.
When the radial movement control element 316 is disposed at one end of each idler rolling element 314, it may be advantageous to dispose the radial movement control element 316 adjacent to an inner end of each idler rolling element, towards a center of shaft 312, and not on an end 318 of idler rolling element 314. Such placement may be advantageous when assembling the idler roller assembly 310, such that the radial movement control element 316 could be attached to or preformed with shaft 312 before sliding the idler rolling element 314 on the shaft 312.
The radial movement control element 316 may have a predetermined diameter so as to leave a predetermined gap between an outer edge of the radial movement control element 316 and an inner edge of the idler rolling element 314. The gap may be selected to limit an amount of movement of the idler rolling element 314 towards the radial movement control element 316. This will keep the idler rolling element substantially parallel with the shaft 312.
The radial movement control element 316 may have a predetermined diameter of approximately 14 mm, and the gap between the inner surface of the idler rolling element and the radial movement control element 316 may be approximately 1 mm. Any predetermined gap size could be used.
The radial movement control element 316 may be circular in shape. Alternatively, the radial movement control element 316 may be any shape that limits movement of the idler rolling element 314 by a substantially equal amount in all radial directions. For example, the radial movement control element 316 could be shaped to have arms extending radially outward from the shaft 312, to leave a substantially equal gap between the end of each arm and an inner edge of the idler rolling element 314.
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 embodiments. 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.