Stacker carts, printing apparatuses, and methods of stacking media on stacker carts are disclosed.
Stacker carts are used for stacking media in printing apparatuses. Such stacker carts can be loaded while positioned in spaces within such apparatuses. It would be desirable to provide stacker carts that can be used in a small space in a printing apparatus to stack longer printed media.
According to aspects of the embodiments, stacker carts, printing apparatuses and methods of stacking media on stacker carts are disclosed. An exemplary embodiment of the stacker carts for stacking media comprises a stacking surface including a first end and an opposite second end, the stacking surface sloping downwardly from the first end toward the second end; and a resiliently-biased, movable stop disposed at the second end of the stacking surface, the stop including at least one contact surface defining a height of the stop above the second end. When the contact surface is in contact with a first surface, the height of the stop (i) decreases as the stacker cart is moved toward the first surface, and (ii) increases as the stacker cart is moved away from the first surface.
The disclosed embodiments include a stacker cart for stacking media, which comprises a stacking surface having a first end and an opposite second end, with the stacking surface sloping downwardly from the first end toward the second end; and a resiliently-biased, movable stop at the second end of the stacking surface. The stop includes at least one contact surface defining a height of the stop above the second end. When the contact surface is in contact with a first surface, the height of the stop (i) decreases as the stacker cart is moved toward the first surface, and (ii) increases as the stacker cart is moved away from the first surface.
The disclosed embodiments further include a stacker cart for stacking media, which comprises a base including a top surface; a stacking surface on the top surface, the stacking surface curving downwardly from a rear end to an opposed front end; and a stop disposed at the front end of the stacking surface. The stop includes a first portion having a first contact surface, a second portion having a second contact surface, and at least one spring connected to the first and second portions. At least one of the first and second contact surfaces defines a height of the stop above the front end. When the first and second contact surfaces are in contact with a first surface, (i) the height of the stop decreases as the stacker cart is moved toward the first surface, and (ii) the spring resiliently-biases the first and second portions to move and increase the height of the stop when the stacker cart is moved away from the first surface.
The disclosed embodiments further include a method of stacking media on a stacker cart comprising a stacking surface which slopes downwardly from a first end toward an opposite second end, and a resiliently-biased stop at the second end. The stop has at least one contact surface defining a height of the stop above the second end. The method comprises raising the stacking cart above a support surface to bring the contact surface into contact with a first surface and decrease the height of the stop; loading at least one medium onto the stacking surface; and lowering the stacking cart relative to the first surface such that the height of the stop increases.
In the apparatus 10, the paper feeder modules 20 can feed media having various sizes (widths and lengths) and weights to the printer module 30. In the printer module 30, latent images are formed on a photoreceptor, such as a photoreceptor belt, using a light source, and dry developer material is used to form toner images on the photoreceptor. The toner images are transferred to a side of respective media fed through the paper path. The inverter module 40 manipulates media exiting the printer module 30 and either passes the media through to the inserter module 50, or inverts and returns the media to the printer module 20, where toner images are formed on the opposite side of these media to produce duplex prints. The inserter module 50 provides an additional media source for the printing process. Media that are inserted into the printing process at the inserter module 50 typically are not passed through the printer modules 20, but are inserted in the process stream to build a finished stack. The finisher module 60 receives media fed through the printer module 30, inverter module 40 and inserter module 50. In the finisher module 60, these media are loaded onto a removable stacker cart to form a stack.
A stacker cart 160 according to an exemplary embodiment is shown in
The stacker cart 160 further includes a stacking surface 178. Media 162 are stacked on the stacking surface 178 when the stacker cart 160 is positioned inside of the finisher station 55. The stacking surface 178 extends from a rear end 180 to a front end 182. When the stacker cart 160 is positioned on a horizontal surface, the rear end 180 is located above the front end 182. In the embodiment, the stacking surface 178 is the top surface of a curved plate 184. The plate 184 can be made, e.g., of metals including steel, aluminum, and the like, or a sufficiently-rigid polymeric material. The distance, d1, from top surface 186 of the base 164 to the rear end 180 of the stacking surface 178 can be, e.g., about 100 mm to about 105 mm. The front end 182 of the stacking surface 178 is positioned above the top surface 186 by a distance equal to the thickness of the plate 184.
The plate 184 is supported on the top surface 186 by an upstanding wall 188. As shown, the wall 188 can be a bracket attached to the tip surface 186 and the plate 184. In other embodiments, the plate 184 and wall 188 can be a single piece of material.
In embodiments, the stacking surface 178 is configured to allow media that are longer than the length, d2, of the base 164 from the front edge 166 to the rear edge 168, to be stacked on the stacking surface 178 without extending outwardly beyond the rear edge 168. In some embodiments, the stacking surface 178 is curved and convex shaped, as shown, such that the stacking surface 178 slopes downwardly from the rear end 180 to the front end 182. In an exemplary embodiment, the stacking cart 160 has a length of about 21 in. (about 533 mm). In such embodiment, media 162 having a length of up to about 22.5 in. (about 572 mm) can be stacked on the stacking surface 178 without extending beyond the rear edge 168 of the stacker cart 164. Accordingly, the stacker cart 160 can be used to stack media that are longer than the length of a space in which the stacker cart 160 is used. The stacking surface 178 typically has a width of about 11 in. (about 279 mm) to about 15 in. (about 381 mm), allowing media widths within this range to be stacked on the stacking surface 178.
In other embodiments, the stacking surface 178 can be planar (not shown) along its entire length between the rear end 180 and the front end 182. In such embodiments, the angle formed between the plane of the stacking surface 178 and the plane of the top surface 186 can be selected to provide the desired length of the stacking surface between the rear end and the front end. In an exemplary embodiment, when the stacker cart 160 has a dimension, d2, of about 21 in., media having a length greater than 21 in., but less than 22.5 in., can be stacked on the planar stacking surface without extending forwardly beyond the rear edge 168 of the stacker cart 160.
The stacker cart 160 further includes a stop 190 located at the front end 182 of the stacking surface 178 and the front edge 166 of the base 164. The stop 190 is movable to change its height with respect to the front end 182 of the stacking surface 178. The stop 190 is configured to prevent media 162 stacked on the stacking surface 178 from sliding off of the front edge 166 of the stacker cart 160. By incorporating the stop 190 on the stacker cart 160, media stacking capacity on the stacker cart 160 reduced by elevating the rear end 180 of the stacking surface 178 above the front end 182 to allow media that are longer than the base 164 to be stacked on the stacker cart 160, can be reclaimed.
In embodiments, the stop 190 is resiliently-biased. The height of the stop 190 relative to the front end 182 of the stacking surface 178 is variable from a minimum height, when the stop 190 is in a fully-lowered position, to a maximum height, when the stop 190 is in a fully-raised position. In the minimum-height position of the stop 190, a portion of the stop 190 can be located below the top surface 186 of the base 184, with the remainder of the stop 190 located above the top surface 186. When the stop 190 is brought into contact with a surface, the stacker cart 164 can then be raised toward the surface in order to push the stop 190 downwardly and decrease its height. Then, when the stacker cart 164 is lowered relative to the surface, the height of the stop 190 increases up to a maximum height when the stop 190 no longer contacts the surface.
As shown in
As shown in
The height of the stop 190 is measured from the front end 182 of the stacking surface 178 to the highest point of the top surface 202, or the top surface 204 above the front end 182. That is, the height of the stop 190 is the maximum distance of the top surface 202 or top surface 204 above the front end 182 above the stacking surface 178. The maximum height of the stop 190 in its fully raised position can be, e.g., about 185 mm to about 190 mm. As the height of the stop 190 decreases, the spring 196 is extended and the spring force increases. When the stacker cart 160 is at the fully-raised position, the stop 190 is at a minimum height, and the spring 196 is fully extended.
As media continue to be stacked on the stacker cart 160, the stacker cart 160 is lowered with respect to the surface 214. As the stacker cart 160 is lowered, the spring 196 continues to contract and apply a tensile force to the first portion 192 and second portion 194, causing these portions to rotate toward each other (i.e., from the phantom line position to the solid line position in
In other embodiments, the stop can be a single-piece of material, e.g., a metal or plastic material. In such embodiments, the stop is lowered by bringing the top surface of the stop into contact with a surface, as the stacker cart is raised toward the surface. The stop can be resiliently biased by a compression spring, for example. The compression spring is compressed as the stop is pushed downwardly as the stacker cart is raised. When the stacker cart is in the raised position, media can be loaded onto the stacking surface. The stacker cart can be lowered with respect to the surface and continue to be loaded with the media. As the stacker cart is lowered, the compression spring expands, thereby raising the stop relative to the top surface of the base. This movement of the stop increases its height relative to the top surface, allowing additional media to be stacked on the stacking surface efficiently.
In embodiments of the stacker cart including a multi-piece stop or embodiments including a single-piece stop, movement of the variable-height stop allows the stacker cart to be raised relative to a surface to bring the stacking surface close to the surface so that media can be stacked on the stacking surface.
As shown in
It will be appreciated that various ones of the above-disclosed and other features and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Also, 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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815008 | Davidson | Mar 1906 | A |
2838185 | Horstkotte | Jun 1958 | A |
2991075 | Wheeler et al. | Jul 1961 | A |
3178172 | Lettan | Apr 1965 | A |
5322496 | Ernst et al. | Jun 1994 | A |
Number | Date | Country | |
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20100014951 A1 | Jan 2010 | US |