Patent Grant
11592780
This application is a U.S. National Stage Application which claims the benefit under 35 U.S.C. § 371 of International Patent Application No. PCT/US2018/048753 filed on Aug. 30, 2018, the contents of which are incorporated herein by reference.
Printing devices, such as printers, copiers, etc., may be used to form markings on a physical medium, such as text, images, etc. In some examples, imaging systems may form markings on the physical medium by performing a print job. A print job can include forming markings such as text and/or images by transferring print materials to the physical medium.
Printing devices can include a supply of print materials including print material particles located in a container (e.g., a hopper, a reservoir, etc.). As used herein, the term “print materials” refers to a substance which, when applied to a medium, can form representation(s) on the medium during a print job. For example, print materials can include a toner material, liquid-based print materials, or other powder and/or particulate. In some examples, the print material particles can be deposited in successive layers to create three-dimensional (3D) objects. For example, print material particles can include a toner material, a powdered semi-crystalline thermoplastic material, a powdered metal material, a powdered plastic material, a powdered composite material, a powdered ceramic material, a powdered glass material, a powdered resin material, and/or a powdered polymer material, among other types of powdered or particulate material. The print material particles can be particles with an average diameter of less than one hundred microns. For example, the print material particles can be particles with an average diameter of between 0-100 microns. However, examples of the disclosure are not so limited. For example, print material particles can be particles with an average diameter of between 20-50 microns, 5-10 microns, or any other range between 0-100 microns. The print material particles can be fused when deposited to create 3D objects.
The print materials can be deposited onto a physical medium. As used herein, the term “printing device” refers to any hardware device with functionalities to physically produce representation(s) on the medium. In some examples, the printing device can be a laser printer, a scanning device, or a laser printer/scanner combination device, among others.
The container including the print materials may be inside of the printing device and include a supply of the print materials such that the printing device may draw the print materials from the container as the printing device creates the images on the print medium. As used herein, the term “container” refers to a reservoir, a hopper, a tank, and/or a similar vessel to store a supply of the print materials for use by the printing device.
As the printing device draws the print materials from the container, the amount of print materials in the container may deplete. As a result, the amount of print materials in the container of the printing device may have to be replenished.
A replenishment device may be utilized to fill and/or refill the container of the printing device with print materials, During a fill and/or refill operation, the replenishment can transfer print materials from the print materials supply to the container of the printing device.
Some approaches to print materials container replenishment can include replacing a combination toner cartridge, replacing a developer and toner cartridge, replacing a toner-only cartridge, or replacing a toner bottle. In such approaches, a printing device is opened, a cartridge or bottle is removed from the printing device, and a new cartridge is installed. In some approaches, the printing device may have more than one cartridge meaning a user is required to know which cartridge to remove and replace.
In other approaches, the cartridge or bottle is removed, replenished outside of the printing device, and returned to the printing device. This can be a messy process that can result in spills and/or contamination of an environment. Over- or under-filling of a cartridge or bottle may also occur due to user error or inefficient fill methods.
In contrast, examples of the present disclosure include a combination cartridge device that allows for replenishment of a print materials container in-situ. For instance, the print materials container can be coupled to an access port of the combination cartridge device that can receive a replenishment device. The replenishment device can replenish the print materials container in-situ such that the combination cartridge device, including the print materials container, remain within a printing device during replenishment. For instance, some examples of the present disclosure allow for replenishment of print materials in a manner that may be more convenient, faster, and simpler for a user as compared to other approaches. A combination cartridge device can be replenished in some examples. As used herein, a combination cartridge device includes a cartridge device having a plurality of components or functions in a single unit. For instance, in contrast to stand-alone cartridges, a combination cartridge device can include a print materials container and/or a waste collection container, along with components such as an organic photo conductor drum (OPC) and a developer roller. In some examples, the combination cartridge device can include an additional print materials container and/or an additional waste collection container.
By replenishing the cartridge device in-situ using a replenishment device, printing and/or operating costs (e.g., costs-per-page) can be reduced because a replenishment device is sufficient for refilling a print materials container. Because the replenishment device may not include gears, motors, electronics, etc., the cost to make and distribute the replenishment device may be reduced. This reduction can result in cost savings for a user. A combination cartridge device may have a longer life expectancy as compared to other approaches because components may not be removed for a longer period of time. For instance, because print materials can be replenished while the combination cartridge remains in a printing device, the combination cartridge may last 25,000 pages or longer, as compared to other cartridges with smaller capacities.
Reserve print materials container 114 can receive print materials directly from a replenishment device via access port 106. This can happen in-situ in some instances such that cartridge device 100 remains inside of printing device 108 while reserve print materials container 114 is replenished. As used herein, replenishment refers to the filling or refilling of a container. For instance, the reserve print materials container can be partially or completely filled or refilled with print materials (e.g., toner or other print material particles) by the replenishment device.
In some examples cartridge device 100 can be a combination cartridge device such that it includes an OPC (not illustrated in
In the example illustrated in
In some examples, replenishment device 216 can be resiliently coupled to access port 206. The coupling can be resilient, such that the coupling is releasable, removable, detachable, etc. For instance, the coupling of replenishment device 216 to access port 206 may not be a permanent coupling. For example, replenishment device 216 can be locked and unlocked from access port 206. Replenishment device 216 can be resiliently coupled to access port 206 via an interlocking connection. For instance, replenishment device 216 can be coupled, or “locked” to access port 206 by connecting replenishment device 216 to access port 206 and turning and/or twisting replenishment device 216. In some examples, replenishment device 216 may be turned and/or twisted a particular amount, for instance, 180 degrees. Other degree amounts or directions may be used, for instance a range of degrees or different coupling approaches. The interlocking connection can include the opening of valve doors on replenishment device 216 and/or access port 206 to allow for transfer of print materials while avoiding spillage or spraying of print materials. Other interlocking connections and/or other coupling techniques may be used to couple replenishment device 216 to access port 206.
Replenishment device 216, in some examples, can house print materials for replenishing the main print materials container and can include a plunger mechanism 218 for deployment of print materials into the main print materials container. Deployment can include, for example, the plunger mechanism creating and/or applying pressure or force to the print materials causing the expulsion of the print materials out of replenishment device 216 and into the main print materials container. For instance, replenishment device 216 can be preloaded with print materials, and upon release of a stopper (e.g., a pull tab, etc.), the plunger mechanism 218 can deploy print materials into the main print materials container.
Upon completion of deployment (e.g., all print materials deployed into the main print materials container), plunger mechanism 218 can be locked or remains in a fixed position. By locking plunger mechanism 218 or leaving it in a fixed position, extra air may be prevented from entering the main print materials container. Upon release from access port 206, plunger mechanism 218 can be unlocked and/or replenishment device 216 may be refilled or discarded. In some examples, locking plunger mechanism 218 can render replenishment device 216 inoperable, such that replenishment device 216 is a single-use replenishment device. In some examples, plunger mechanism 218 can include a plunger arm, force leverage mechanism, or force receiving mechanism, among others.
In the example illustrated in
Cartridge device 300 can be a combination cartridge device including, for instance, access port 306, reserve print materials container 314, first waste collection container 312, second waste collection container 310, and OPC 320. In some examples, cartridge device 300 may include a developer roller (not illustrated in
In some examples OPC 320 can be resiliently coupled to cartridge device 300. The coupling can be resilient, such that the coupling is releasable, removable, detachable, etc. For instance, the coupling of OPC 320 cartridge device 300 may not be a permanent coupling. In such an example, OPC 320 may be separated from cartridge device 300 for replacement of OPC 320 or cartridge device 300. Such an approach can reduce replacement costs and/or shipping costs, among others. In an example in which OPC 320 is resiliently coupled to cartridge device 300, OPC 320 may be part of a combination cartridge device and no components of the combination cartridge device are removed during replenishment of a reserve print materials container 314 or a main print materials container of the combination cartridge device.
In some examples other components may be resiliently coupled to cartridge device 300. For instance, the developer roller and/or waste collection containers may be resiliently coupled. In some examples, the main print materials container may be resiliently coupled to the developer roller, OPC 320, and a waste collection container. In some instances, the main print materials container may be resiliently coupled to OPC 320, but permanently coupled to the developer roller. Other combinations of resilient and permanent coupling are possible.
In some examples, reserve print materials container 402 can supply main print materials container 404 with print materials in response to an indication of the print materials falling below a threshold in main print materials container 404. For instance, if main print materials container 404 has a print materials capacity of 25,000 sheets, and reserve print materials container 402 has a print materials capacity of 5; 000 sheets, an indication may occur when print materials falls below 20,000 sheets, 15,000 sheets, 10,000 sheets, and/or 5,000 sheets in main print materials container 404. Other thresholds may be set by a manufacture or a user, in some instances. Other capacities may be possible in some examples for main print materials container 404 and reserve print materials container 402. In some examples, reserve print materials container 402 can supply main print materials container 404 automatically or in response to user input. As used herein, “automatically” can include main print materials container being supplied by reserve print materials container 402 with limited or no user input and/or with limited or no prompting (other than the threshold indication).
The threshold indication can be prompted by sensors (e.g.; optical sensors) within cartridge device 400 and/or main print materials container 404 and/or reserve print materials container 402 that can detect print materials levels. In some examples, a combination cartridge may not include a reserve print materials container. In such an example, main print materials container 404 receives print materials directly from a replenishment device via access port 406.
In some instances, a user may be alerted that print materials in reserve print materials container 402 and/or main print materials container 404 has fallen below a threshold. In such an example, a user may use a replenishment device to replenish reserve print materials container 402 if present in the combination cartridge device or main print materials container 404 if no reserve print materials container is present in the combination cartridge device. No components of the combination cartridge device are removed for/during replenishment.
This collected waste can be moved, for instance using a belt or other waste transfer system 514, to second waste collection container 510 for storage. Having second waste collection container 510 to store waste can allow for storage of more waste as compared to other approaches, meaning removal of waste collection containers may not be necessary. Waste collection containers 510 and 512 can be part of the combination cartridge device, such that they may not be removable.
In some examples, during a print job, as OPC 520 rotates and developer roller 521 picks up print materials from main print materials container 504, most of the print materials may be dropped onto the print job medium (e.g., paper), What is left, which can be referred to as “waste”, can be caught by cleaning blade 523 and moved into first waste collection container 512. The waste can be moved (or free flow) into second waste collection container 510 for storage. Unprocessed toner print materials material, paper debris, dust, or other unwanted material can build up on the OPC and if not removed can cause printing defects when it inadvertently transfers to the print job medium. A cleaning blade, such as cleaning blade 523, can be implemented to gather up such material and collect it into a waste collection container such as first waste collection container 512, for instance.
In some examples, second waste collection container 510 can hold a larger amount of waste than first waste collection container 512 or waste collection containers in other print materials cartridges. For instance, in some examples, first waste collection container 512 and second waste collection container 510 can together hold 25,000 pages worth of waste, which can increase a lifetime of a combination cartridge device because the combination cartridge device does not have waste removed until 25,000 pages. For instance, if a replenishment device holds 2,500 pages worth of print materials, a combination cartridge device (e.g., its print materials containers) may be filled ten times before second waste collection container 510 is full. This can reduce spills and contamination issues as compared to other approaches that include frequent waste print materials container removals and/or disposals. While 25,000 pages and 2,500 pages are used herein as examples, other page amounts may be possible.
In some examples, cartridge device 500 includes a single waste collection container. In such an example, the waste collection container can be elongated and uses a conveyer mechanism to move waste from near OPC 520 to a larger storage waste collection container. For instance, in such an example, first waste collection container 510 and second waste collection container 512 may not be separate containers, but rather a single, elongated waste collection container. In other examples, the single waste collection container is not a same shape as a combination of first waste collection container 510 and second waste collection container 512, In some examples, no waste collection container is present in cartridge device 500.
At 634, method 630 can include receiving print materials deployed from the replenishment device at a print materials container of the cartridge device while the cartridge device is in the printing device. Print materials, for instance, can be received at a reserve print materials container and the print materials can be moved from the reserve print materials container to a main print materials container using a belt. The reserve print materials container, in some instances, can be used to store print materials until print materials in the main print materials container falls below a particular threshold. The cartridge device remains in the printing device during deployment of print materials. Put another way, print materials is deployed to an in-situ cartridge device.
Method 630, at 636, can include performing a print job using the print materials. During the print job or during other printing device operations, waste or other by-products may be produced. At 638, method 630 can include collecting waste to a first waste collection container of the cartridge device, and at 640, method 630 can include moving the waste to a second waste collection container of the cartridge device for storage of the waste. In some instances, the movement can be performed using a belt. The second waste collection container can store waste associated with more pages than the replenishment device can deploy. This can allow for a plurality of replenishments before removal of the second waste collection container is performed.
In the foregoing detailed description of the present disclosure, reference is made to the accompanying drawings that form a part hereof, and in which is shown by way of illustration how examples of the disclosure may be practiced. These examples are described in sufficient detail to enable those of ordinary skill in the art to practice the examples of this disclosure, and it is to be understood that other examples may be utilized and that process, electrical, and/or structural changes may be made without departing from the scope of the present disclosure.
The figures herein follow a numbering convention in which the first digit corresponds to the drawing figure number and the remaining digits identify an element or component in the drawing. Elements shown in the various figures herein can be added, exchanged, and/or eliminated so as to provide a number of additional examples of the present disclosure. In addition, the proportion and the relative scale of the elements provided in the figures are intended to illustrate the examples of the present disclosure and should not be taken in a limiting sense. Further, as used herein, “a” element and/or feature can refer to one or more of such elements and/or features.
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| WO2020/046317 | 3/5/2020 | WO | A |
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