This disclosure relates to paper handling systems for xerographic marking and devices, and more specifically, relates to an improved drive roll/idler roll nip release mechanism used in media or sheet registration.
Heretofore, media path drive roller nips have been opened in order to disengage by using an electrical solenoid or dedicated motor in order to activate the nip release (idlers lifted) mechanism upstream of a registration nip. One actuator is required to drive the nip release mechanism. An improvement to this type of nip release mechanism is shown in U.S. Pat. No. 7,506,870 B2 where one or more cams are operatively connected to corresponding ones of idler rolls within nip drive assemblies. As the cams rotate, the cams move the idler rolls between a first position biased against the driver rolls and a second position out of contact with the drive rolls. A camshaft is operatively connected to the cams, and the camshaft is operatively connected to a clutch driven by the drive motor/axle of the nip drive assembly. The camshaft is rotated by the clutch only when the drive axle rotates in a reverse direction opposite the forward direction. Thus, the forward movement of the drive axle moves media through the drive nips and reverse movement of the drive axle rotates the cams, thereby controlling the position of the idler rolls. A limitation of this nip release mechanism is the fact that the drive nips must be driven in reverse in order to initiate the separation of idlers. If a sheet were present in the drive nip as the nip release is initiated, it would momentarily be stopped and then driven in reverse until the idlers were sufficiently lifted. This makes the described mechanism impractical for certain applications, such as the release of an upstream nip in order to allow a downstream nip to assume full control of a sheet.
Accordingly, disclosed herein is a drive roll/idler roll nip release mechanism that utilizes the motor used for the drive nip, coupled with one-way clutches, to power the nip release as a sheet is handed off to a downstream nip. A drive shaft is coupled to a one-way clutch in one direction, whereas the idler cam shaft is coupled to a one-way clutch in the opposite direction. This allows the idler cam shaft to be driven only when the motor is reversed, and the drive shaft to be driven only when the motor is moving forward. The one-way clutch on the drive shaft allows the drive wheels to freewheel when the motor is reversed in order to engage the nip release. This configuration allows the nip release mechanism to be activated while the sheet is still under the drive nip, as long as the lead edge of the sheet has been acquired by a downstream nip, and thus increases sheet throughput through the nip.
Various of the above-mentioned and further features and advantages will be apparent to those skilled in the art from the specific apparatus and its operation or methods described in the example(s) below, and the claims. Thus, they will be better understood from this description of these specific embodiment(s), including the drawing figures (which are approximately to scale) wherein:
In prior art
When the nip is in the engaged (loaded) state (
When the nip is in the released (unloaded) state (
The nip load cam 12 is rotated on the nip load camshaft 13, which is driven by gears 14-16. Gear 16 is fastened to the single direction device 17. By including clutch 17 within the gear 16 that is adjacent the drive axle 4, the gears 14-16 only rotate when the drive axle rotates in the reverse direction, which reduces wear of the gears 14-16. The roller clutch 17 is oriented such that forward rotation of the driver roll 1 does not act on gear 16, but rather acts as a roller bearing. Reverse rotation of the driver roll will lock the roll clutch such that the gear 16 is driven in order to select a different cam 12 position.
The clutch 17 is a one-way clutch that can, for example, include internal ratchets that engage in only one direction. The clutch 17 connects the gear 16 to the drive axle 4. Therefore, gear 16 only rotates when the drive axle 4 rotates in the reverse direction because when the drive axle 4 rotates in the forward direction, the clutch 17 spins freely and does not cause the gear 16 to rotate. Because of this, gear 16 will only rotate in the reverse direction and will only rotate when the drive axle 4 rotates in the reverse direction. Thus, one clutch is used to power the idler shaft while the drive shaft is driven in the opposite direction. In one application, this is used to change from wide to narrow stance and vice versa, that is, the cam settings determine which set of rolls are engaged for different sizes of media. This configuration enables the use of a one-way clutch to select the nip to be released for a given media size.
An improvement to the heretofore described nip release mechanism in accordance with the present disclosure is shown in
An alternative nip release mechanism 70 is shown in
In recapitulation, it should now be understood that an improved nip release mechanism in a paper handling device of a printer has been disclosed that utilizes the motor used for a drive nip, coupled with one-way-clutches, to power release of the nip as paper is handed off to a downstream registration nip. The drive shaft is coupled to a one-way clutch in one direction while an idler cam shaft is coupled to a one-way clutch in the opposite direction. This allows the idler cam shaft to be driven only when the motor is reversed, and the drive shaft to be driven only when the motor is moving forward. The one-way clutch on the drive shaft allows drive wheels to freewheel when the motor is reversed in order to engage the nip release. Thus, the nip release is activated while the sheet is still under the drive nip as long as the lead edge of the sheet has been acquired by the down stream nip. This nip release mechanism is useful in a printing apparatus, such as, electrostatographic and/or xerographic machines.
The claims, as originally presented and as they may be amended, encompass variations, alternatives, modifications, improvements, equivalents, and substantial equivalents of the embodiments and teachings disclosed herein, including those that are presently unforeseen or unappreciated, and that, for example, may arise from applicants/patentees and others. Unless specifically recited in a claim, steps or components of claims should not be implied or imported from the specification or any other claims as to any particular order, number, position, size, shape, angle, color, or material.