Patent Grant
11491797
Printing devices such as printers, copiers, large format, plotters, 3D-printers, etc. deposit various materials onto a medium, substrate, or platform to form objects or markings human visible, or machine detectable, in various wavelengths across the light spectrum otherwise referred to as text, graphics, images, reproductions, shadings, highlights, constructs, objects, print jobs, etc.). In some examples, printing devices may form markings on a physical medium by performing a process such as a print job. A print job can include forming markings such as text and/or images by, in part, by transferring and or depositing print materials to the physical medium as part of an overall print process.
Printing devices may include a supply of a print materials located in a reservoir. 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. In some examples, the print materials can be deposited in successive layers to create three-dimensional (3D) objects. For example, print materials can include print material particles, 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 materials can be particles with an average diameter of less than one hundred microns. For example, the print materials can be particles with an average diameter of between 0-100 microns. However, examples of the disclosure are not so limited. For example, print materials 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 materials 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 3D printer. For example, the 3D printer can create a representation (e.g., a 3D object) by depositing print materials in successive layers to create the 3D object.
The reservoir 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 reservoir as the printing device creates the images on the print medium. As used herein, the term “reservoir” refers to a container, 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 reservoir, the amount of print materials in the reservoir may deplete. As a result, the amount of print materials in the reservoir of the printing device may have to be replenished.
A print materials container may be utilized to replenish a the reservoir of the printing device with print materials. For instance, the print materials container can be a print materials replenishment device. During an initial fill or replenishment operation, the print materials container can transfer print materials from the print materials container to the reservoir of the printing device.
Some approaches to initially filling or replenishing a reservoir of printing device include replacing a print materials reservoir. In such approaches, a printing device is opened, a print materials reservoir is removed from the printing device, and a new print materials reservoir is installed. In some approaches, the printing device may have more than one print materials reservoir, meaning a user is required to know which print materials reservoir to remove and replace.
In other approaches, the print materials reservoir 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 environment contamination. Over- or under-filling of a print materials reservoir may also occur due to user error or inefficient fill methods.
In contrast, examples of the present disclosure include a print materials container that allows for replenishment of a print materials reservoir in-situ. For instance, the print materials reservoir can be coupled to a fill port of the print materials reservoir that can receive the print materials reservoir container. The print materials container can fill and/or replenish the print materials reservoir in-situ such that the print materials reservoir remains within a printing device during filling/replenishing. For instance, some examples of the present disclosure allow for filling/replenishing of print materials in a manner that may be more convenient, faster, and simpler for a user as compared to other approaches. For instance, a plurality of mechanisms can be used in the print materials container to make a filling/replenishing process easier and cleaner.
In some instances, by filling/replenishing the print materials reservoir in-situ using the print materials container, printing and/or operating costs (e.g., costs-per-page) can be reduced because a print materials container is sufficient for refilling a print materials reservoir. Because the print materials container may include limited or no gears, motors, electronics, etc., the cost to make and distribute the print materials container may be reduced. This reduction can result in cost savings for a user.
Dispense mechanism 102 can include plurality of mechanisms, as will be discussed further herein, including a compression mechanism, a squeeze bottle mechanism, a print materials bag mechanism, a bulb pump mechanism, and/or an accordion-shaped collapsible container, among others. In some instances, dispense mechanism 102 can include a print material reservoir to store a supply of print materials. The print material reservoir can supply/resupply a printing device (e.g., a host print system) with print materials, as is further described herein.
In some examples, print materials container 100 can be prepared for dispensing print materials by agitating print materials container 100 and inserting print materials container 100 into fill port 106. Docking of print materials container 100 can include locking print materials container 100 to fill port 106, allowing print materials container 100 to open along with an opening in the reservoir. This can allow transfer of print materials to the reservoir. Responsive to an indication that transfer is complete, print materials container 100 can be unlocked and undocked, which closes openings in print materials container 100 and the reservoir. Print materials container 100 can be removed from fill port 106, completing the print materials transfer.
Printing device 208 can house a reservoir for receiving print materials from print materials container 202. The reservoir may remain in printing device 208 during filling/replenishing of the reservoir. Upon completion of the fill/refill, print materials container 202 can be removed from printing device 208 (e.g., valve 206 removed from fill port 206) and a print job can resume/commence.
As used herein, the term “plunger” refers to a piston to take in and/or expel liquid, gas, or other material through an orifice at the end of print materials container 300. For example, print materials container 300 can include an inner compress body (not illustrated in
Plunger 310 can have a base 312, which can be a rubber material or other material for moving print materials. Base 312, in some examples, can include a seal 314 coupled to plunger 310 via base 312 to protect plunger 310 from print materials and sweep the print materials within the compression mechanism. Seal 314 can be a felt material wipe seal or a synthetic material wipe seal, among other seals that prevent air from escaping around base 312. Seal 314 can allow for a more constant pressure on print materials as compared to a plunger 310 and base 312 without a seal, in some instances. In some examples, plunger 310 and/or base 312 may be removed from the compression mechanism (e.g., for cleaning, replacement of components, etc.).
Print materials container 300 can include a valve 304, in some examples. The valve can be an opening through which material can be moved. For example, valve 304 can be an opening through which print materials can be moved in response to plunger 310 decreasing the volume of the print materials reservoir based on movement of plunger 310 from position 307 to position 309.
While in position 307, print materials container 300 is not depressed. In such an example, a print materials reservoir within print materials container 300 can contain print materials. While in position 309, print materials container 300 and it's print materials reservoir are void of print materials (e.g., having filled/refilled a printing device).
Although not illustrated in
In some examples, print materials container 300 can be a toner materials container, and can include a dispense mechanism (e.g., a compression mechanism) to dispense toner materials to an in-situ reservoir of a printing device. In such an example, the dispense mechanism can include compress storing the toner materials and having plunger 310 to dispense the toner materials responsive to a force applied at an end of the plunger. For instance, a force can be applied at the end of the plunger which creates pressure to drive air and print materials out of the compression mechanism. The compress can include a tip (not illustrated here), as will be discussed further herein with respect to
For instance,
Valve 406 can prevent exposure of a compress tip 405 or fill port entrance 421 to a user. For instance, during docking and undocking, compress tip 405 swaps places with a cover 419 of fill port 406. This can result in compress tip 405 and an entrance 421 to fill port 406 in direct contact with each other. This can prevent residual print materials from falling out of the compress during removal by allowing fill port 406 to cleanly shear (e.g., at shear plane 413) a print materials column 411 between wipe seals 423.
In some examples, valve 406 can include an output opening, for instance at an end of print materials column 411, that is offset from a center axis of tip 450. During locking, a lock feature can engage fill port 406 during connection of tip 405 to fill port 406. Valve 404 can open responsive to rotation of an opening of valve 404 with respect to the lock feature such that opposite openings align. The open valve 404, in some instances can facilitate a plunger to push toner materials through aligned openings into the reservoir.
In the example illustrated in
Valve 506 can prevent exposure of a compress tip 505 or fill port 506 entrance to a user. For instance, during docking and undocking, compress tip 505 swaps places with a cover of fill port 506. This can result in compress tip 505 and an entrance to fill port 506 in direct contact with each other. This can prevent residual print materials from falling out of the compress during removal by allowing fill port 506 to cleanly shear (e.g., at shear plane 513) a print materials column 511 between seal wipes.
In the example illustrated in
Valve 606 can prevent exposure of a compress tip 605 or fill port 606 entrance to a user. For instance, during docking and undocking, compress tip 605 swaps places with a cover of fill port 606. This can result in compress tip 605 and an entrance to fill port 606 in direct contact with each other. This can prevent residual print materials from falling out of the compress during removal by allowing fill port 606 to cleanly shear (e.g., at shear plane 613) a print materials column 611 between seal wipes.
In the example illustrated in
Valve 706 can prevent exposure of a compress tip 705 or fill port 706 entrance to a user. For instance, during docking and undocking, compress tip 705 swaps places with a cover of fill port 706. This can result in compress tip 705 and an entrance to fill port 706 in direct contact with each other. An axis of valve 704, print materials column 711, and compress 700 can be in line such that compress time 705 uncovers fill port 706 while docking, creating a seal and allowing print materials to pass through print materials column 711.
In the example illustrated in
Squeeze bottle mechanism 818 can be squeezed a plurality of times using a pumping action to dispense the print materials. This pumping action can aerate the print materials during dispensing in some instances. The pumping action can be repeated until the desired amount of print materials (e.g., all the print materials) have been dispensed through valve 804 into the reservoir of the printing device. Valve 804 can be received by a fill port of the printing device to facilitate the transfer of print materials, in some examples.
For example, bag mechanism 920 can be squeezed a plurality of times using a pumping action to dispense the print materials. This pumping action can aerate the print materials during dispensing in some instances. The pumping action can be repeated until the desired amount of print materials (e.g., all the print materials) have been dispensed through valve 904 into the reservoir of the printing device. Valve 904 can be received by a fill port of the printing device to facilitate the transfer of print materials, in some examples. In some instances, compressed air can be used to dispense the print materials alternatively or in addition to the pumping action.
Bulb pump 1024 can be squeezed a plurality of times using a pumping action to dispense the print materials. This pumping action can aerate the print materials during dispensing in some instances. The pumping action can be repeated until the desired amount of print materials (e.g., all the print materials) have been dispensed from cannister 1022 through valve 1004 into the reservoir of the printing device. Valve 1004 can be received by a fill port of the printing device to facilitate the transfer of print materials, in some examples.
Smooth container 1128 can be removable from compression mechanism 1130, in some instances. For instance, smooth container 1128 can be a container that can be placed in compression mechanism 1130 for filling/replenishing of a printing device reservoir. Smooth container 1128 can be removed from compression mechanism 1130 upon completion of filling/replenishing of the printing device reservoir.
Accordion-shaped collapsible container 1234 can be removable from mechanism 1230, in some instances. For instance, accordion-shaped collapsible container 1234 can be a container that can be placed in mechanism 1230 for filling/replenishing of a printing device reservoir. Accordion-shaped collapsible container 1234 can be removed from mechanism 1230 upon completion of filling/replenishing of the printing device reservoir. In some instances, accordion-shaped collapsible container 1234 can collapse on itself and remain collapsed upon completion of filling/replenishing of the printing device reservoir. Accordion-shaped collapsible container 1234, in some examples, can have a valve as described in
In some examples, the dispense mechanism can be mechanically locked to the fill port responsive to a turn of the dispense mechanism. The turn can include sufficient rotation to enable connection of the fill port. For instance, the dispense mechanism can be coupled, or “locked” to a fill port by connecting the dispense mechanism to the fill port and turning and/or twisting the dispense mechanism. In some examples, the dispense mechanism may be turned and/or twisted a particular amount, for instance, 15 degrees, 30 degrees, 45 degrees, 90 degrees, or 180 degrees, among others. 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 the dispense mechanism and/or the fill port 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 the dispense mechanism to the fill port, for instance as described with respect to
Locking and sealing of the dispense mechanism can include the lock feature engaging the fill port during connection of a tip of the dispense mechanism to the fill port at 1343 and the valve opening responsive to rotation of an opening of the valve with respect to the lock feature such that opposite openings align at 1345. For instance, an opening created by the aligned openings can appear such that dispensing of print materials occurs when the dispense mechanism is locked to the fill port, but not when unlocked.
At 1344, method 1340 includes dispensing print materials directly to the in-situ reservoir, via the dispense mechanism, the fill port, and the aligned openings, responsive to an outside force applied to the dispense mechanism. For example, a plunger of the dispense mechanism can release a seal, which in turn can seal the print materials and dispense the print materials in response.
In the foregoing detailed description of the 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 disclosure. Further, as used herein, “a” can refer to one such thing or more than one such thing.
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. For example, reference numeral 102 may refer to element 102 in
It can be understood that when an element is referred to as being “on,” “connected to”, “coupled to”, or “coupled with” another element, it can be directly on, connected, or coupled with the other element or intervening elements may be present, In contrast, when an object is “directly coupled to” or “directly coupled with” another element it is understood that are no intervening elements (adhesives, screws, other elements) etc.
The above specification, examples, and data provide a description of the method and applications and the use of the system and method of the disclosure, Since many examples can be made without departing from the spirit and scope of the system and method of the disclosure, this specification merely sets forth some of the many possible example configurations and implementations.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/US2018/048769 | 8/30/2018 | WO |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2020/046321 | 3/5/2020 | WO | A |
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