阅读说明：本技术 具有压光辊的调节器模块 (Regulator module with calender roll ) 是由 凯文·洛 杰弗里·G·宾厄姆 布拉德利·B·布兰哈姆 于 2017-05-01 设计创作，主要内容包括：在示例中,调节器模块可以包括桥接部,用于从成像设备的介质路径接收介质并用于将介质传送到修整器模块的介质输入端。调节器模块可以包括设置在桥接部的输出端的压光夹口。压光夹口可以压缩介质,并且可以将介质馈送到修整器模块的介质输入端。(In an example, the conditioner module may include a bridge for receiving media from a media path of the imaging device and for conveying the media to a media input of the finisher module. The conditioner module may include a calendering nip disposed at an output end of the bridge. The calendering nip can compress the media and can feed the media to the media input end of the finisher module.)

1. a regulator module comprising:

A bridge portion to receive media from a media path of an image forming device and to convey the media to a media input of a finisher module; and

A calendering nip disposed at an output end of the bridge for compressing the media and for feeding the media to the media input end of the finisher module.

2. The conditioner module of claim 1, wherein the calendering nip is to burnish the media as the media moves through the calendering nip.

3. The conditioner module of claim 1 wherein the calendering nip comprises a calendering roll.

4. a regulator module according to claim 3, wherein the calender roll comprises a one-way clutch for enabling the calender roll to rotate only in a forward direction.

5. A governor module as defined in claim 4, wherein the one-way clutch is for enabling the calender roll to be overdriven in the forward direction.

6. The conditioner module as set forth in claim 1, wherein the calendering nip includes a first calender roll and a second calender roll, the first calender roll including a one-way clutch.

7. The conditioner module of claim 4, wherein the trimmer module is to pull media into the media input such that the media overdrive the calender roll.

8. The conditioner module of claim 1 wherein the bridge portion includes a plurality of media moving nips for conveying the media along the bridge portion to the output end.

9. A regulator module comprising:

A conditioner media path for receiving media from the copier media path; and

A calendering nip disposed at the media output of the conditioner module, the calendering nip comprising a calendering roll having a one-way clutch,

the calendering nip is for compressing and flattening the media as it moves through the calendering nip, thereby reducing stack friction of the media, and for feeding the media to a finisher module after the media has been compressed and flattened.

10. the conditioner module of claim 9, wherein the calendering nip is to burnish the media as the media moves through the calendering nip.

11. a regulator module according to claim 9, wherein the one-way clutch is adapted to enable the calender roll to rotate in the forward direction at a higher angular velocity than if the calender roll were driven by the regulator module.

12. an image forming apparatus comprising:

A copier;

A media path within the copier;

A finisher module; and

A regulator module comprising:

A bridge disposed along the media path for connecting the media path to a media input of the finisher module; and

A first and a second calender roll disposed at an output end of the bridge, the first and second calender rolls arranged to define a calendering nip for compressing and smoothing the media and for feeding the media into the media input end of the finisher module after the media has been compressed and smoothed.

13. An image forming apparatus as defined in claim 12, wherein the first and second calender rolls are radially pressed against each other to define the calendering nip.

14. An image forming apparatus as recited in claim 13, wherein said calendering nip is for buffing said media as it is conveyed through said calendering nip.

15. An image forming apparatus according to claim 14, wherein one of said first and second calender rolls includes a one-way clutch for enabling the respective first or second calender roll to rotate in a forward direction and for preventing the respective first or second calender roll from rotating in a reverse direction.

Background

The imaging device may perform actions on or on the media. An imaging device may print, scan, copy, or perform other actions on or on media. The imaging device may deposit printing fluid on the media. Further, the imaging devices may transport media through, into, or out of the imaging devices, or from a first imaging device to a second imaging device or other device.

Drawings

FIG. 1 is a schematic diagram of an example regulator module.

FIG. 2 is a schematic diagram of an example imaging device having an example regulator module.

FIG. 3A is a side view of an example regulator module.

Fig. 3B is a detailed view of an example regulator module.

FIG. 4 is a side view of an example imaging device with an example regulator module.

Detailed Description

an imaging device may perform actions on or with its media or media. An imaging device may print, scan, copy, or perform other actions or imaging operations on or on media. The imaging device may deposit a printing substance, such as ink, on the media while performing these imaging operations. These printing substances may be deposited on the top surface of the media to create or define a printed image, text, or other pattern. The printing substance may increase the friction of the media or its coefficient of friction by creating peaks and valleys of the printing substance on the top surface of the media. This increase in friction may thereby increase the friction present between sheets or portions of media in the media stack.

in some cases, the imaging device may perform an imaging operation in one portion of the imaging device and then transport the media to another portion of the imaging device where the imaging device may perform another operation on or on the media, such as a finishing operation. These finishing operations may include stacking, collating, organizing, repositioning, or another finishing operation performed on or to the media. The performance of these finishing operations may be inhibited or rendered inefficient by imaging operations performed on the media (e.g., operations that increase friction between sheets or portions of media in a media stack). In some cases, one or more of the finishing operations may be performed by a finisher module, which may be a stand-alone module attached to the imaging device or may be an integrated part or module of the imaging device. The medium may be conveyed from the image forming apparatus to the finisher module by the intermediate member.

In some instances, it may be desirable to perform an adjustment operation on the media between the imaging operation and the finishing operation, which may reduce friction of the media, or between sheets or portions of media in the media stack, and may include compression, flattening, burnishing, or other adjustment operations.

In some cases, certain imaging devices, such as high-speed, high-capacity, or other high-performance and/or high-output imaging devices, may incorporate laser printing technology to achieve the output and performance required of such imaging devices. Laser printing techniques may include depositing toner onto media during an imaging operation. The toner may reduce the friction of the medium or its coefficient of friction. Therefore, it may not be necessary for such a high-performance image forming apparatus to perform an adjustment operation on the medium before the trimming operation is performed on the medium. In other instances, it may be desirable to utilize inkjet printing technology, such as sheet wide array (PWA) inkjet printing technology, in such high performance image forming devices without using laser printing technology. Therefore, in some cases, due to the incorporation of inkjet printing technology in such image forming apparatuses rather than laser printing technology, the finishing operations performed by such image forming apparatuses or their attached finisher modules may be affected or inhibited by increased media friction.

Embodiments of the present disclosure provide an adjustment module that performs an adjustment operation on or on a medium after the medium has performed an imaging operation thereon or thereon. Such an adjustment operation may reduce the coefficient of friction of the media, or friction between sheets or portions of stacked media, thereby preparing the media so that it may be easier and/or more efficient to perform a trimming operation on or to the media after such an adjustment operation. In certain embodiments, embodiments of the conditioning module disclosed herein may be used in high performance imaging devices, such that inkjet technology may be used in such imaging devices without degradation of the performance of the finisher module due to increased media friction resulting from inkjet operations.

referring now to fig. 1, a schematic diagram of an example regulator module 100 is illustrated. The regulator module 100 can include a bridge 102 for receiving 103 media from a media path of the image forming device or a media output thereof and for transporting 105 media to a media input of the finisher module. The conditioner module 100 can further include a calendering nip 104 disposed at the output end of the bridge 102. The calendering nip 104 can compress and/or smooth the media and can feed or convey 105 the media to a media input of the finisher module. In certain embodiments, the calendering nip 104 can apply a compressive or compressive force in the direction 107, and in some embodiments, the direction 107 can be orthogonal, perpendicular, and/or transverse to the feed direction of the media path extending along the bridge 102.

The bridge portion 102 may include a bridge media path, sometimes referred to as a conditioner media path, for operatively engaging the media path of the image forming device and the media input of the finisher module. Thus, media may be conveyed along the media path of the image forming device, then through the bridge media path, and into the media input of the finisher module. In further embodiments, the bridge can include sufficient structure, such as a frame, roller, housing, or other structure, to support such a bridge media path. It is noted that although illustrated as extending in a generally downward direction across the regulator module 100, in some embodiments, the bridge 102, and thus the bridge media path thereof, may also extend in a variety of directions or orientations other than downward.

The calendering nip 104 may be a location, structure, or feature of the conditioner module 100 that can compress or apply pressure to the media as it is conveyed through or past the calendering nip 104. The calendering nip 104 may be different from the conditioner module 100, or other nips or rollers of the imaging apparatus in which the conditioner module 100 may be disposed or attached, in that: the calendering nip 104 can elastically or plastically deform the media, making the media better suited for manipulation by a finisher module. In some embodiments, the calendering nip 104 can compress the media. Compression may refer to the act of reducing the thickness of the media as it passes through the calendering nip 104. Further, the calendering nip 104 may level the media, which may refer to an action that reduces waviness or other planar deformations across the length and/or width of the media, or in other words, an action for increasing the smoothness or planarity of the media. Compressing and/or planarizing the media may eliminate or reduce peaks and valleys formed by printing substances deposited on the media by imaging operations performed on the media. In other words, the peaks and valleys of the media produced by the imaging operation may be reduced so that the media may be moved across the surface and other sheets of media in an easier, smoother, faster, or more efficient manner. Thus, compressing and/or flattening the media may have the effect of reducing the friction aspect of the media (e.g., the coefficient of friction of the media, or friction that may exist between sheets of stacked media). In further embodiments, the calendering nip 104 may polish the media, or in other words, may make the surface of the media more uniform, smoother, and/or improve the gloss, smoothness, or appearance of the media as the media moves through the calendering nip 104. Thus, media that has been compressed, buffed, and/or flattened may be better suited for stacking, collating, binding, repositioning, or other finishing operations. For example, the finisher module may be able to stack and bind more sheets of media after the sheets of media have been conveyed through the calendering nip 104 than if the media were not conveyed through the calendering nip 104.

Referring now to fig. 2, a schematic diagram of an example imaging device 201 having an example regulator module 200 is illustrated. The example regulator module 200 may be similar to the example regulator module 100. Further, like-named elements of the example regulator module 200 may be similar in function and/or structure to the various elements of the example regulator module 100 described above. In some embodiments, the imaging device 201 may further include an imaging portion 208 and a conditioner module 210, both of which may be operably engaged with the example regulator module 200. Although illustrated as separate components, in some embodiments, the regulator module 200, the finisher module 210, and the image forming portion 208 can be partially or wholly part of a single image forming device (e.g., a printer, copier, or multifunction device). In other embodiments, the finisher module 210 may be a device separate from the image forming apparatus 201, and may be attached to or assembled to the image forming apparatus when a finishing operation is required.

in the example shown, media, such as print media, may be conveyed along a media path of imaging portion 208. An imaging operation may be performed on or to the media as the media moves along the media path of the imaging portion. Media may be received by the regulator media path of the regulator module 200 from the media outlet 212 of the media path of the imaging portion 208. The regulator media path may be a path disposed on the bridge 202 that is sized and configured to move media through the regulator module 200. Upon receipt from the media outlet 212, the media may be conveyed or otherwise moved along the bridge 202 of the regulator module 200 to the output end 215 of the regulator module 200. The output 215 may refer to the portion of the regulator module 200 having the media output, or in other words, the location where the media may exit the regulator module 200. It is noted that in other embodiments, the position or orientation of the output 215 may be different than that shown in fig. 2.

The conditioner module 200 can include a calendering nip 204 disposed along the conditioner media path at the media output end of the conditioner module 200. In some embodiments, the calendering nip 204 can include a calendering roll 206, which in further embodiments can include a one-way clutch. Calender roll 206 may be a roll, wheel, bearing, or other member that may be driven along a longitudinal and/or rotational axis to rotate along a conditioner media path in a media movement direction. The calendering nip 204, or its calender rolls 206, may compress and/or flatten the media as the media is conveyed or otherwise moved through the calendering nip 204, thereby reducing the stack friction of the media. In further embodiments, the calendering nip 204 may also be a media moving nip and the media may be fed into the finisher module 210 after the media has been compressed and/or flattened. In other embodiments, the calendering nip 204 can also burnish the media as it moves through the calendering nip 204. After the media has passed through the calendering nip 204, the media can be fed or conveyed out of the output end 215 of the conditioner module 200 and into the media input end 214 of the finisher module 210.

Referring now to FIG. 3A, a side view of an example regulator module 300 is illustrated. The example regulator module 300 may be similar to other example regulator modules described above. Further, like-named elements of the example regulator module 300 may be similar in function and/or structure to the various elements of the other example regulator modules described above. In some embodiments, a regulator module 300 can receive 303 media at a media input of the regulator module 300 or its bridge 302 and transport 309 the media along a regulator media path to an output of the regulator module 300. In some embodiments, the regulator module 300 or its bridge 302 can include a plurality of media moving nips and/or rollers (e.g., nips and/or rollers 318a, 318b, and 318c) for moving media along the regulator media path on or in the bridge 302 to the output. In some embodiments, the conditioner module 300 or its bridge 302 may include more or fewer media moving nips and/or rollers than illustrated. The conditioner module 300 may include a calendering nip disposed at the output end. In some embodiments, the calendering nip may include a calendering roll 306 for applying pressure on the media as it passes through the calendering nip, for example, in direction 307, in order to compress, flatten, and/or burnish the media. In the embodiment shown, the calendering nip can comprise a second calender roll 316 and calender roll 306 can be referred to as a first calender roll 306.

Referring additionally to fig. 3B, a detailed view of an example regulator module 300 is illustrated. In particular, a detailed view of the output of the regulator module 300 is illustrated. The first calender roll 306 and the second calender roll 316 can be arranged at the output of the governor module 300 or its bridge. The first calender roll 306 and the second calender roll 316 may be similar in function and/or structure to the calender roll 206 described above. In some embodiments, the first calender roll 306 and the second calender roll 316 may rotate toward each other so that both rotate along the conditioner media path in the direction of media movement. In a further embodiment, the first calender roll 306 may be rotated or driven in the example direction 311, while the second calender roll 316 may be rotated or driven in the example direction 313. In some embodiments, direction 311 may be referred to as the forward direction of the first calender roll 306, and direction 313 may be referred to as the forward direction of the second calender roll 316. In some embodiments, one or both of the first calender roll 306 and the second calender roll 316 may be media moving rolls, or in other words, may be rotated to advance the media along the conditioner media path.

The first calender roll 306 and the second calender roll 316 may be arranged, oriented and/or configured to define a calendering nip 304, which may be disposed between the first calender roll 306 and the second calender roll 316. In a further embodiment, the first calender roll 306 and the second calender roll 316 may be pressed radially against each other along their longitudinal length to define the calendering nip 304 at the point of contact between the two rolls. In other words, the first calender roll 306 may be pressed against the second calender roll 316, for example, in the direction 307a, to define the calendering nip 304. Alternatively, the second calender roll 316 may be pressed against the first calender roll 306, for example, in the direction 307b, to define the calendering nip 304. In a further embodiment, both the first calender roll 306 and the second calender roll 316 may be pressed against the other calender roll to define the calendering nip 304.

The media may be transported or moved through the calendering nip 304 as it is transported to the output end by the conditioner module 300. The calendering nip 304 can compress and/or flatten the media as the media is fed through the calendering nip 304, and, in further embodiments, the calendering nip 304 can also polish the media. The calendering nip 304 may also feed 305 media to the media input of the conditioner module (downstream of the conditioner module 300) after the media has been compressed, flattened, and/or polished.

In some embodiments, one of the first calender roll 306 and the second calender roll 316 may include a one-way clutch to enable the respective first calender roll 306 or second calender roll 316 to rotate in a forward direction and to prevent the respective first calender roll 306 or second calender roll 316 from rotating in a reverse direction opposite the forward direction. In other words, the first calender roll 306 or the second calender roll 316 may include a one-way clutch so that this roll can only rotate in a corresponding forward direction in the medium moving direction and can be prevented from rotating in a direction opposite to the medium moving direction. In embodiments where the governor module includes only a single calender roll defining the calender nip, the single calender roll may include a one-way clutch. The one-way clutch may be any mechanism capable of unidirectional rotation of the roller. In further embodiments, the one-way clutch may enable the rollers to be overdriven in the forward direction of the respective roller. In other words, the one-way clutch may cause the calender roll to which it is operatively engaged to rotate in the forward direction of the roll at a higher angular or rotational speed than the calender roll is driven by the governor module. In further embodiments, the finisher module can pull the media from the output end of the conditioner module 300 into the media input end of the conditioner module so that the media itself overdrives the calender rolls.

Referring now to fig. 4, a side view of an example imaging device 401 including an example regulator module 400 is illustrated. The example regulator module 400 may be similar to the other example regulator modules described above. Further, like-named elements of the example regulator module 400 may be similar in function and/or structure to the various elements of the other example regulator modules as described above. In some embodiments, the imaging device 401 may further include an imaging portion 408 and a finisher module 410. Imaging portion 408 may perform imaging operations on or on media. These imaging operations may include printing, scanning, copying, or other imaging operations. In some implementations, imaging portion 408 can deposit printing fluid, such as ink, onto the media using inkjet technology or PWA inkjet technology. Media may be loaded into and disposed in the media storage portion 420, such as a media tray or drawer. In some implementations, the media may be provided in a media stack 422 or an order of media within the media storage portion 420. The media may be paper, cardboard, cardstock, vinyl, latex, or other types of materials suitable for use in the imaging device 401.

Imaging device 401 may include an imaging device media path 412 along which media may be conveyed through the imaging device. As the media is conveyed along imaging device media path 412, imaging operations may be performed on or to the media. Imaging device media path 412 may then convey the media after undergoing one (or more) imaging operations to the media input of regulator module 400. It is noted that other embodiments of the example imaging device 401 may have media paths with layouts different than the layout shown. The regulator module 400 can receive 403 media from the imaging device media path 412 and transport the media along the bridge 402 or a regulator media path thereon to perform a regulating operation on or to the media. Such conditioning operations may include compressing, planarizing, and/or polishing the media to reduce friction that may have previously increased in imaging operations with the media. In some implementations, the regulator media path may be integrated with the imaging device media path 412 such that they may be collectively referred to as a media path. The conditioner module 400 may then transport 405 the media after conditioning has been completed to the finisher module 410 or its media input. In other words, the bridge 402, which is disposed along the media path, can connect the media path to the media input of the finisher module 410 and convey the media to the finisher module 410. The finisher module 400 can include a finisher media path 414 (shown in abbreviated form) along which media can be conveyed to perform finishing operations on or on the media. Such finishing operations may include stacking, collating, stapling, reorienting or other finishing operations. In some embodiments, media may be delivered to an output tray and disposed in an output stack 424.

In some embodiments, the imaging device may be a copier for scanning and generating copies of documents, and the imaging device media path may be referred to as a copier media path. In some cases, the image forming portion 408 of the image forming apparatus 401 may be a copier. In other embodiments, the imaging device may use inkjet printing techniques to generate copies of the scanned document. In some embodiments, the conditioner module 400 may condition the copied documents so that they can perform trimming operations in an easier, more efficient, or more efficient manner.