Printing apparatuses can include a tray to contain sheets of media used to produce prints. In such apparatuses, when stacks of the sheets are loaded into the tray, variable loading can cause the stacks' positions to vary in both position and straightness. Such variable loading can detrimentally affect the feeding of the sheets from the tray.
It would be desirable to provide apparatuses for feeding sheets and printing apparatuses constructed to assist positioning of as-loaded sheets in trays to improve feeding of the sheets.
Apparatuses for feeding sheets and printing apparatuses are provided. An exemplary embodiment of the apparatuses for feeding sheets comprises a first guide; a second guide opposite the first guide; a first side wall; a second side wall opposite the first side wall; a support surface configured to support a stack of sheets with a first edge of the sheets facing the first guide, a second edge of the sheets facing the second guide and a center line of the stack extending from the first edge to the second edge; and at least two tampers including: a first tamper secured to the first guide between the center line and the first side wall, the first tamper including a first lower pad and a first upper pad which applies a lower force to the first edge of the sheets than the first lower pad; and a second tamper secured to the first guide between the center line and the second side wall, the second tamper including a second lower pad and a second upper pad which applies a lower force to the first edge of the sheets than the second lower pad.
The disclosed embodiments include an apparatus for feeding sheets comprising a first guide; a second guide opposite the first guide; a first side wall; a second side wall opposite the first side wall; a support surface configured to support a stack of sheets with a first edge of the sheets facing the first guide, a second edge of the sheets facing the second guide and a center line of the stack extending from the first edge to the second edge; and at least two tampers including: a first tamper secured to the first guide between the center line and the first side wall, the first tamper including a first lower pad and a first upper pad which applies a lower force to the first edge of the sheets than the first lower pad; and a second tamper secured to the first guide between the center line and the second side wall, the second tamper including a second lower pad and a second upper pad which applies a lower force to the first edge of the sheets than the second lower pad.
The disclosed embodiments further include a printing apparatus comprising at least one media tray for feeding sheets. The media tray includes a first guide; a second guide opposite the first guide; a first side wall; a second side wall opposite the first side wall; and a support surface configured to support a stack of sheets with a first edge of the sheets facing the first guide, a second edge of the sheets facing the second guide and a center line of the stack extending from the first edge to the second edge. The media tray further includes at least two tampers including: a first tamper secured to the first guide between the center line and the first side wall, the first tamper including a first lower pad and a first upper pad which applies a lower force to the first edge of the sheets than the first lower pad; and a second tamper secured to the first guide between the center line and the second side wall, the second tamper including a second lower pad and a second upper pad which applies a lower force to the first edge of the sheets than the second lower pad.
As used herein, the term “printing apparatus” encompasses apparatuses including digital copiers, bookmaking machines, multifunction machines, and the like, or portions of such apparatuses, that perform a print outputting function for any purpose. The printing apparatuses can use various types of solid and liquid marking materials, and treat the marking materials using various process conditions to form images on media.
Embodiments of the media tray 104 can also be included in media feeder modules that can be connected to a printing apparatus. For example, embodiments of the media tray 104 can be used in the feeder modules of the printing apparatus disclosed in U.S. Patent Application No. 2008/0037069, which is incorporated herein by reference in its entirety.
As shown in
Embodiments of the media trays further include at least two tampers. When sheets are loaded into a media tray by a user, the stack may not be positioned properly for feeding sheets from the stack. The as-loaded stacks can vary in both inboard-to-outboard position and straightness, i.e., alignment with respect to a media loading surface. The as-loaded stack can be slanted, i.e., skewed, with respect to a reference surface. In embodiments, the tampers are constructed to reduce the effects of such variable loading of sheets into the media tray on media feeding. The tampers are constructed to position the sheets in the media tray prior to feeding the sheets from the media tray. The tampers can properly position the stack of sheets against a datum, de-skew the stack, and apply a balanced de-skew force against the sheets as they are fed from the media tray.
The embodiment of the media tray 104 shown in
As shown in
In embodiments, the pads of the tampers can be comprised of any suitable material that can transmit forces to stacks to position the stacks in the desired position in the media tray. The material can be a rigid material, such as a rigid polymer. In other embodiments, the material can be a softer, deformable polymeric material. In embodiments, the material has a sufficiently-low coefficient of friction to reduce drag forces on sheets during feeding, and sufficient wear resistance to resist cutting by the repeated movement of edges of sheets against the pads.
The tampers are shown in the fully-extended (non-depressed) position in
At least one force-producing element (not shown) is provided for each lower pad 126, 130 to move the lower pads 126, 130 outwardly away from the rear guide 110. In embodiments, the force-producing element can be, e.g., at least one spring, such as a compression spring, leaf spring, or the like, which exerts a spring force to resiliently bias the lower pads 126, 130 outwardly away from the rear guide 110. The force-producing elements can be inside of, or behind, the lower pads 126, 130. The lower pads 126, 130 exert a force against the edges 116 of the sheets 106 facing the rear guide 110. Typically, the lower pads 126, 130 can each exert a force of about 4 N to about 8 N, such as about 6 N, to the stack. In embodiments, the lower pads 126, 130 can each apply about the same force to the sheets 106. When the stack is improperly positioned in the media tray 104 during loading, as the stack is elevated, the forces exerted by the lower pads 126, 130 are sufficient to cause the stack to shift forward in the media tray 104 toward the front guide 108, as indicated by arrow A, and reposition the stack relative to the front guide 108.
The upper pads 124, 128 are in the outwardly fully-extended position when the stack of sheets 106 is below the upper pads 124, 128 as shown in
At least one force-producing member (not shown) is provided for each upper pad 124, 128 to move the upper pads 124, 128 outwardly away from the rear guide 110, as shown. In embodiments, the force-producing element can be, e.g., at least one spring, such as a compression spring, leaf spring, or the like, which resiliently biases the upper pads 124, 128 outwardly away from the rear guide 110. The force-producing elements can be inside of, or behind, the upper pads 124, 128. The upper pads 124, 128 exert a force against the edge 116 of the upper sheets 106 of the stack facing the rear guide 110. The tapered profile of the front surfaces 136, 138 creates an even shingling effect. Typically, the upper pads 124, 128 each exert a force of about 0.2 N to about 0.5 N, such as about 0.3 N, to the sheets 106. In embodiments, the upper pads 124, 128 can each apply about the same force to the sheets 106 of the stack.
The forces exerted by the lower pads 126, 130 and the upper pads 124, 128 of the respective tampers 120, 122 act separately and in unison against stacks of sheets. When the stack is loaded improperly in the media tray 104, the forces exerted by the upper pads 124, 128 are sufficient to reposition the upper sheets 106 of the stack relative to the front guide 108. The upper pads 124, 128 control the position of the upper sheets 106 in the media tray 104, and produce a balanced de-skew force during feeding of the sheets 106 from the media tray 104.
Accordingly, the two tampers 120, 122 provide control of the trailing edge of the sheets 106, resulting in less output skew and top edge registration variation. The balanced pair of force-applying tampers 120, 122 allows the sheets 106 to be both positioned and de-skewed at the same time as the stack interacts with the tampers 120, 122.
In embodiments, the tampers 120, 122 can be adjustably movable relative to each other along the rear guide 110 to position the tampers 120, 122 symmetrically with respect to the center line CL of stacks of sheets having significantly different width dimensions. For example, the tampers 120, 122 can be movable along a horizontal slot, or the like, provided at the rear guide 110.
Other embodiments of the media tray can include more than two tampers provided along the rear guide to position stacks of media in a desired manner. For example, embodiments of the media tray can include four tampers spaced from each along the rear guide. With reference to the media tray 104 shown in
The outer tampers can have the same construction as the inner tampers. The lower pads of the outer tampers can apply about the same force to stacks of sheets as the lower pads of the inner tampers, and the upper pads of the outer tampers can apply about the same force to stacks of sheets as the upper pads of the inner tampers. In embodiments, the four tampers can position the front edges of the sheets against the front guide, de-skew the stack, and apply a balanced de-skew force against the sheets as the sheets are fed from the media tray.
By incorporating additional tampers, such as four tampers, in the media tray, the force exerted by each lower pad and each upper pad of the tampers against sheets of stacks supported on the media tray can be further reduced as compared to embodiments of the media tray that include two tampers, such as the media tray 104 shown in
It will be appreciated that various ones of the above-disclosed, as well as 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.