阅读说明：本技术 打印子组件 (Printing subassembly ) 是由 肯尼思·威廉姆斯 维恩·迈尔斯 于 2017-04-12 设计创作，主要内容包括：公开一种打印子组件。所述打印子组件包括框架、联接到所述框架的打印棒以及联接到所述打印棒的提升机构。所述提升机构使所述打印棒相对于所述框架选择性地移动。流体接收系统联接到所述打印棒。(A printing subassembly is disclosed. The print subassembly includes a frame, a print bar coupled to the frame, and a lift mechanism coupled to the print bar. The lift mechanism selectively moves the print bar relative to the frame. A fluid receiving system is coupled to the print bar.)

1. A printing subassembly, comprising:

a print bar;

a lifting mechanism;

a frame coupled to the print bar and the lifting mechanism such that the lifting mechanism selectively moves the print bar relative to the frame; and

a fluid receiving system coupled to the print bar.

2. The printing subassembly of claim 1, wherein the fluid receiving system is in fluid communication with the print bar.

3. The printing subassembly of claim 2, wherein the fluid receiving system comprises a pump coupled to the frame.

4. The print sub-assembly of claim 2, wherein the print bar comprises a print bar element coupled to a plurality of printheads.

5. A print sub-assembly according to claim 1, comprising circuitry to connect power and data to the print bar.

6. A printing apparatus comprising:

a chassis;

a media support operably coupled to the chassis;

a fluid supply operably coupled to the chassis; and

a replaceable printing subassembly, the replaceable printing subassembly comprising:

the number of the printing rods is increased,

a lift mechanism operably coupled to the print bar to selectively position the print bar relative to the media support, an

A fluid receiving system coupled to the print bar and removably coupled to the fluid supply.

7. A printing apparatus according to claim 6, comprising an inkjet printer.

8. The printing device of claim 6, wherein the chassis includes a housing having an opening, and wherein the subassembly is accessible from the opening.

9. The printing apparatus of claim 6, wherein the fluid receiving system comprises a pump and a tube having a coupler that is removably coupled to the fluid supply.

10. The printing apparatus of claim 9, wherein the fluid receiving system comprises a return tube in fluid communication with the print bar and the fluid supply source.

11. The printing apparatus of claim 9, wherein the coupler comprises a needle.

12. The printing apparatus of claim 6, comprising a controller having a detachable signal pathway operably coupled to the subassembly to connect power and data to the printing subassembly.

13. The printing apparatus of claim 12, wherein the removable signal pathway comprises a flat flexible circuit.

14. A replaceable printing sub-assembly comprising

A frame;

a print bar;

an ink receiving system in fluid communication with the print bar, the ink receiving system having a pump operably coupled to the frame;

a frame coupled to the ink delivery system such that the ink delivery system and the print bar do not move relative to the frame; and

a lift mechanism operably coupled to the print bar to selectively move the print bar relative to the frame.

15. The replaceable printing subassembly of claim 14, comprising a service station operably coupled to the frame and movable relative to the frame.

Background

Printing devices-including printers, copiers, facsimile machines, multi-function devices including additional scanning, copying, and finishing functions, all-in-one devices, or other devices, such as pad printers and three-dimensional printers (additive manufacturing) for printing images on three-dimensional objects-receive digital images or digital models and produce objects or images on media such as plain paper, photographic paper, transparency, and on other media such as metallic and polymeric media in addition to or in place of wide and thin media. The image may be obtained directly from the printing device or communicated to the printing device from a remote location (e.g., from a computing device or computing network). The ink or other printed material may be stored in a refillable or removable container. In an example of a sheet-fed apparatus, sheets are selected from a stack of media, typically one at a time, and fed along a feed path through a media support to an output tray. In a roller-fed apparatus, a cartridge (web) of media is fed to an output portion through a media support portion along a feed path. The media interacts with the printhead at the media support to produce an image on the media. The three-dimensional printer receives a digital model or other data source of the object and may form successive layers of material to produce the three-dimensional object, such as via a print head, extrusion process, sintering-based process, or other process.

Drawings

FIG. 1 is a schematic diagram illustrating an example printing subassembly.

Fig. 2 is a schematic diagram illustrating an example of a printing device including a replaceable printing subassembly, such as the printing subassembly of fig. 1.

Fig. 3 is a schematic diagram illustrating example features included on an example print subassembly, such as the example print subassembly of fig. 1.

FIG. 4 is a schematic diagram illustrating another example of a printing subassembly of the example printing subassembly of FIG. 1.

Detailed Description

Many commercially used printing devices, such as inkjet printers, copiers, or multifunction devices in offices, schools, and laboratories, are repaired on site rather than being returned to the factory. Technicians are often quickly dispatched to the printer where maintenance is performed based on service contracts. If repairs are too frequent and costly, the business suffers a loss or the user becomes frustrated due to the inability to use the printing device or because of the cost of the service contract.

In many examples, commercially used printing devices are robustly constructed, but are difficult to repair. In one example, a printing device may have a hard-to-repair print bar that may include a set of printheads spanning the width of the media. Repair of the print bar may include first removing the scanner or document feeder and disassembling a portion of the components of the feed path and data cable. If the print bar has failed or is under way, it is possible that the associated parts (such as drive motors, gears, bearings) and other features are also near the end of the useful life. These parts can also be difficult to repair and are often replaced one by one in different top services. Repairing small parts that are difficult to access at various service intervals can result in costly door repairs, repeated door service, and long repair times for relatively inexpensive components.

Fig. 1 illustrates an example printing subassembly 100, which example printing subassembly 100 may include a replaceable printing subassembly for use in a printing device. The print subassembly 100 includes a print bar 102 and a lift mechanism 104, each of the print bar 102 and the lift mechanism 104 being coupled to a frame 106. The lift mechanism 104 selectively moves the print bar 102 relative to the frame 106. A fluid receiving system 108 is coupled to the print bar 102. For example, fluid receiving system 108 is in fluid communication with print bar 102.

In one example, the printing subassembly 100 may also include other components coupled to the frame 106 that are not intended to be repaired or are repaired in the field, such as service stations and other components. Instead, the replaceable printing subassembly 100 can be removed from the printing device and replaced with a new subassembly. In one example, fluid receiving system 108 may include a pump, but printing subassembly 100 does not include a user-refillable ink container or ink supply. Instead, a user-refillable ink container or supply of ink is located within the printing device and is removably coupled to the fluid receiving system 108.

Fig. 2 illustrates an example printing device 200 having a chassis 202, the chassis 202 being operably coupled to an installed replaceable printing subassembly 204. The replaceable printing subassembly 204 may be an example of the printing subassembly 100.

Examples of printing devices 200 suitable for adopting replaceable printing subassemblies 204 may include one or more combinations of two or more of a printer, scanner, copier, facsimile machine, plotter, or other device (such as a pad printer or three-dimensional printer). The printing device may operate as one or more combinations of two or more of a standalone device, a device coupled to a computer network, or a peripheral or auxiliary device operated by a computer or other processing device. In one example, the printing device is an inkjet printer. Print media may include various sizes and types of paper, plastic, fabric, such as paper, roll-fed media, and other media. The present disclosure includes examples of inkjet printing on media for illustration, and the examples are not intended to be limited to ink or printing on media, and may include dispensing, jetting, or otherwise depositing fluids other than ink for uses other than printing on media.

The printing device 200 may include a media transport system 210 having a media support 212, the media support 212 being adapted to provide media for marking by the print subassembly 204. For example, the media transport system 210 may include mechanisms for transporting and providing media in the form of sheets or rollers to the sub-assembly 204 for printing. A controller 214 is operably coupled to the media transport system 210 to control the media transport system 210, the controller 214 may include a processor, a storage device, and communication circuitry. The controller 214 may include power circuitry 216 and image processing circuitry 218 coupled to the print subassembly 204 to provide power and data (e.g., image data) to operate the subassembly 204. Printing device 200 also includes a refillable fluid supply 220 to provide ink or other material for printing. For example, refillable fluid supply 220 may include multiple reservoirs for respectively receiving multiple color inks for color printing, or a single reservoir for monochrome printing. In one example, a fluid supply is operably coupled to the chassis 202.

The print subassembly 204 in the example includes a frame 222, a print bar 224, a fluid receiving system 226, and a lifting mechanism 228. The frame 222 may be removably coupled to the chassis 202 and may include coupling and positioning features that selectively position the frame relative to components of the printing device 200, such as the media support 212. Controller 214 may be operably coupled with the signal connection to selectively operate print bar 224.

The frame 222 may include a set of upstanding walls stamped or cut from a substantially rigid material such as sheet metal. In one example, four upstanding walls of the frame 222 surround the print bar 224 and the fluid receiving system 226. The frame 222 may include an alignment system having one or more protrusions (such as flanges or tabs), or openings (such as slots or holes) extending from the frame. The alignment system may be used to properly position and fully constrain the rigid print subassembly 204 within the printing device 200 in all six degrees of freedom of motion. The alignment system is configured to mate or attach with corresponding features in the printing device (such as on the chassis 202) to constrain the printing subassembly 204. The frame 222 may include other features (such as holes) for receiving fasteners (e.g., screws) to attach the subassembly 204 to the chassis 202 of the printing device 200.

Fluid receiving system 226 is in fluid communication with print bar 224. Further, the fluid receiving system 226 may be coupled by one or more removable connections to be in fluid communication with the fluid supply 220. In one example, a fluid receiving system 226 on frame 222 includes a pump for drawing ink or other material from fluid supply 220, and the fluid receiving system 226 provides ink or other material to print bar 224 for printing on media. In some examples, the fluid receiving system 226 may include several pumps, each pump corresponding to multiple fluid reservoirs of the fluid supply 220. The fluid receiving system 226 includes a coupler that may be operatively connected, such as removably coupled, to the fluid supply 220. In examples where the fluid receiving system 226 comprises a pump, the pump may comprise a fluid conduit, such as a tube, having a coupler that may be removably connected to a fluid supply. The coupler may include a needle, septum, or other fluid coupling mechanism to attach to a fluid supply and transfer fluid to the pump. In examples where frame 222 does not include a pump, fluid receiving system 226 may include a tube (tubing) that is removably coupled to the pump. However, the fluid receiving system does not include a refillable or replaceable fluid supply 220 that is not located within the subassembly 204.

Print bar 224 includes an elongated member having one or more printheads for dispensing ink. In one example, print bar 224 spans the width of the print media on media support 212 such that print bar 224 does not move back and forth across the width of the print media to dispense ink.

Print bar 224 includes one or more pens for printing. In one example, print bar 224 includes a plurality of pens arranged end-to-end in an array on print bar 224, a portion of each pen overlapping a portion of an adjacent pen along the span of the print bar. Print bar 224 may include, for example, two or more rows of pens in a staggered configuration, with one pen in each row extending into the overlap between pens for seamless printing across the entire span or a majority of the span of the print bar. In one example, the configuration of the pen may provide seamless printing across the full span of the print medium.

The pen includes a mechanism configured to eject a fluid, such as ink, onto a medium (e.g., a cartridge or a sheet of paper). Each pen may include one or more printheads and a self-contained reservoir or reservoir of fluid applied to the printheads. A self-contained reservoir or reservoir of fluid is in fluid communication with the fluid receiving system 226 and receives fluid from the fluid supply 220. Each printhead may include one or more print dies. For example, a printhead may include a die configured to print cyan and magenta inks, while another die may be configured to print black and yellow inks. In one example, the printhead includes a thermal resistance drop on demand inkjet printhead. In another example, the printhead may comprise a piezo resistive inkjet printhead. In yet another example, the printhead may include other mechanisms configured to eject fluid in a controlled manner.

In the example of a thermal resistance inkjet printhead, the heating elements are located within individual nozzles that eject ink. An electrical current is applied to heat the heating element and cause a small amount of ink to heat up quickly and become vaporized. The vaporized ink forms a pressurized bubble that ejects fluid ink through a nozzle as the ink expands. Printhead driver circuitry is coupled to the various heating elements to provide energy pulses and control the ejection of liquid ink, and thus the deposition of ink drops from the nozzles. The printhead driver is responsive to the character generator and other image forming circuitry (which may be included as part of the controller), for example, to energize selected nozzles of the printhead to form an image on the print medium.

Print subassembly 204 can also include a service station 240 for cleaning print bar 224 and a cover for covering print bar 224 when not in use. Service station 240 may also include a service driver 242, or be operatively coupled to service driver 242 and actuated by controller 214 through a signal connection to move service station 240 relative to print bar 224. In one example, service station 240 is coupled to frame 224 and is included within replaceable printing subassembly 204 and attached to frame 222. In another example, service station 240 is not included within replaceable printing subassembly 204 and is operably coupled to chassis 202.

Lift mechanism 228 may be used to accurately position print bar 224 within a particular selected distance from media support 212, such as a "pen-to-paper spacing," in response to signals provided from controller 214 based on the type of print media and other considerations. In addition, a lift mechanism 228 may be used to separate the print bar 224 from the media support 212 for application of the service station 240 to the printhead. Lift mechanism 228 may selectively move print bar 224 relative to media support 212 from a print position where the print head is proximate to the print media to one or more service positions where service station 240 may clean or cover print bar 224 when the print head is not printing.

The lift mechanism 228 may include a motor and drive that operate in response to signals from the controller 214. The drive may include gears or other mechanisms to move print bar 224 relative to frame 222 along the lift guides. In one example, the lift guide may include a rack coupled to the frame 222, and the motor is operably coupled to a pinion that meshes with the rack. In this example, a motor and pinion may be operably coupled to print bar 224 to move with print bar 224 and relative to frame 222. The motor may selectively position the pinion relative to the rack to position print bar 224 relative to frame 222.

Subassembly 204 may include circuitry for connecting appropriate power and actuation signals to print bar 424, fluid receiving system 226, lifting mechanism 228, and service station 240 (if included on subassembly 400). In one example, the circuitry is included on one or more printed circuit assemblies including one or more flat flexible circuits having signal connectors that may be operably coupled to receive power and data signals from the controller 214. In one example, the flat flexible circuits are configured to not overlap in order to reduce cross-talk or electromagnetic interference. The fixed position of the signal wires in the flat flex circuit avoids overlap if the components of the subassembly are individually installed or repaired and the corresponding wiring attached to the controller is not noticed.

In the illustrated example, the chassis 202 is coupled to the housing 260 and is enclosed by the housing 260. The housing 206 may include an opening 262 and the cover 264 is selectively placed over the opening 262. In one example, the cover 264 may be detachable, i.e., removably attached, from the housing 260 to expose the subassembly 204 within the housing 260 via the opening 262. In another example, the lid 264 remains attached to the housing 260, such as via a hinge or other mechanism, and is selectively removed from the opening 262 to provide access to the subassembly 204. In one example, the opening 262 is large enough to allow a technician to detach the subassembly 204 from the chassis 202, the controller 214, and from the fluid supply 220, and remove the subassembly 204 through the opening 262. The mechanical fasteners used to fasten the subassembly 204 to the chassis 202, the signal connectors used to couple the subassembly 204 to the controller 214, the fluid connectors used to couple the subassembly to the fluid supply 220 are easily accessible via the openings 262 to remove the subassembly 204. Further, the replacement subassembly may be reattached to the controller 214 and the fluid supply 220 via the opening 262 and connected to the chassis 202. Another example housing includes a plurality of openings including openings for passing fasteners and electrical and fluid connections to the subassembly 204. The housing may include another opening for refilling the fluid supply 220. .

Fig. 3 illustrates an example service station 300 that generally corresponds to service station 240. During printing, ink tends to accumulate at the nozzles of the printhead. Ink build-up or residual ink may be caused by incompletely ejected ink drops, excess ink around the nozzles, and ink splattering reflected from the print medium. Nozzles are also susceptible to clogging by dust, quick drying inks, ink solids, and media particles.

The service station 300 includes a wiping mechanism 302 for cleaning the printhead and maintaining the functionality of the printhead, and a cap 304 for covering the printhead when not in use to reduce the likelihood of ink drying or contaminants collecting in and on the nozzles. In one example where the service station is carried on the frame 222, the service station 300 is operably coupled to the frame 222 via a service guide (not shown). In examples where the service station 300 is carried on the chassis 204 instead of on the replaceable printing subassembly 204, the service guide is coupled to the chassis 204. Service station 300 may also include a service driver 306 or be operably coupled to service driver 306 to move service station 300 along a service guide relative to frame 222 and print bar 224 in response to signals from controller 214.

The wiping mechanism 302 may include a barrel roller and a feed mechanism. The feed mechanism may include two spools, such as a feed supply and a take-up reel, between which the exposed area of the drum roll 310 is wound (wound). In one example, the spool is operatively coupled to a gear or cogwheel 312, which gear or cogwheel 312 can be selectively engaged with a pawl to push the barrel roller. The barrel roller may be urged in response to a signal from the controller 214, and the controller 214 may determine whether to urge the barrel roller based on factors including health of the print bar, frequency of use, and time of last wipe.

The cover 304 may be configured to fit over and substantially encapsulate the die of the print bar 224. In one example, the cover 304 is formed of a flexible material, such as ethylene propylene diene monomer (M-grade) (EPDM) rubber or other elastomer, that is suitable for sealing the printhead and preventing the printhead from drying and accumulating contaminants when not in use. In one example, the shroud 304 may include a micro vent to allow the air pressure within the shroud to slowly adjust to ambient pressure. The printhead may be capped in response to a signal from the controller 214, and the controller 214 may determine whether to cap based on factors such as the time between print jobs, or whether the printing device has stopped printing, has been powered down, or whether the sub-assembly 204 is removed from the printing device 200.

Service drive 306 may selectively position service station 300 relative to frame 222 and print bar 224 along a service path of travel between a wiping position for wiping the print bar with exposed portions of barrel roll 310, a covering position for covering print bar 224 with hood 304, and one or more other positions for allowing lift mechanism 226 to position media support 212 relative to print bar 224 in a printing position.

Fig. 4 illustrates an example subassembly 400 having a frame 422, a print bar 424, a fluid receiving system 426, and a lifting mechanism 428 constructed in accordance with the subassemblies 100, 204. The subassembly 400 is removably coupled to a fluid supply vessel 420, which fluid supply vessel 420 may be configured according to the supply 220 and is not included as part of the subassembly 400. In an example, the fluid receiving system 426 includes a pump 430, the pump 430 in fluid communication with the printbar 424 via a conduit 432. For example, conduit 432 may be in fluid communication with a self-contained reservoir or reservoir of fluid on printbar 424. Conduit 432 may be configured to be non-removable from print bar 424. In another example, if pump 430 is included as part of subassembly 400, conduit 432 is also not removable from pump 430.

In examples where pump 430 is included as part of subassembly 400, fluid receiving system 426 may also include additional tubing 434 in fluid communication with pump 430, which pump 430 is configured to be coupled to fluid supply container 420. Conduit 434 may include a distal end 436 having a coupler 438 that is removably coupled to container 420. Fluid delivery system 426 may include additional conduits 434, where there are multiple fluid supply containers (such as containers of ink or adhesive for each color), the additional conduits 434 are removably coupled to fluid container 420. In one example, conduit 434 from fluid container 420 is removably coupled with pump 430.

In another example, the fluid receiving system 426 includes a return conduit 440, the return conduit 440 forming a return path for fluid to flow from the print bar 424 to the fluid container 420. Excess fluid or ink from print bar 424 is returned to fluid reservoir 420 on a return path through return conduit 440. In one example, returning excess fluid from printbar 424 to fluid reservoir 420 may reduce degradation or slow aging of ink in printbar 424. The return conduit 440 may include a coupler 442 on a distal end 444, and the coupler 442 may be removably coupled to the fluid container 420. The fluid receiving system 426 may include an additional return conduit 440, where there are multiple fluid supply containers (such as containers of ink or adhesive for each color), the additional return conduit 440 being removably coupled to the fluid container 420.

The fluid receiving system 426 may include additional components and elements for providing fluid from the fluid supply container(s) 420 to the print bar 424. For example, the fluid receiving system 426 may include circuitry and sensors for detecting fluid supply levels or fluid flow, as well as other fluid-related parameters or information on the sub-assembly 400, and for providing electrical signals to a controller (such as controller 214) on the printing device via electrical interconnects.

Although specific examples have been illustrated and described herein, various alternative and/or equivalent implementations may be substituted for the specific examples shown and described without departing from the scope of the present disclosure. This application is intended to cover any adaptations or variations of the specific examples discussed herein. Therefore, it is intended that this disclosure be limited only by the claims and the equivalents thereof.