Vapor handling in printing

Information

  • Patent Grant
  • 6643220
  • Patent Number
    6,643,220
  • Date Filed
    Thursday, March 21, 2002
    22 years ago
  • Date Issued
    Tuesday, November 4, 2003
    21 years ago
Abstract
Apparatus and methods are disclosed for enabling vapor handling in printing. In certain implementations, for example, one or more volatiles emitted during an ink-based printing process may be condensed into one or more liquids. The one or more liquids may be directed into absorbent materials such that the combined liquids and absorbent materials form a substance that qualifies as a solid, as determined by a given solid definition or regulatory standard. In certain (alternative but non-exhaustive) implementations, the volatiles emitted during printing may include water and oil, with the oil vapor being condensed into a liquid and added to the absorbent materials while the water vapor is being forwarded under the force of, e.g., negative air pressure.
Description




BACKGROUND




The present invention relates generally to waste management, and more specifically to vapor handling in ink-based printing devices.




Ink-based printing devices are used in many different types of printing environments. For example, ink-jet printers are used in stand-alone environments attached to individual computers. Ink-jet printers are also used in networked environments as printing devices that are utilized by a number of network clients and attached thereto via network connections. As another example of an ink-based printing device, ink-using web printers are capable of printing many “pages” of text and graphics from a single roll of paper, which may then be cut into separate or groups of pages for subsequent formation into a newspaper, a newsletter, etc. As yet another example of ink-based printing devices, ink-using copiers, facsimile machines, multi-function devices, etc. may each rely on an ink-based print engine to create printed hard copies. These various ink-printing devices may print using black, color, or black and color inks.




With these many attractive options, ink-based printing devices have become ubiquitous in society. Furthermore, these printers provide many other desirable characteristics at an affordable price. However, the desire of customers for ever more features or conveniences (usually at ever-lower prices) continues to encourage manufacturers to improve efficiencies and other attributes of ink-based printing devices. One area of continual improvement is in printer throughput, in increased pages per minute.




As throughput increases, however, problems related to throughput become more significant, such as the generation of waste products, including vapors generated during the printing process. These vapors may include substances which must be disposed of in compliance with to hazardous waste procedures, such as described in the United States Environmental Protection Agency (EPA) regulations. Currently, addressing ink waste issues can be an expensive and time consuming aggravation for consumers of ink-based printing devices. There is thus a need for methods and apparatus that simplify the waste recovery and disposal process.




SUMMARY




One or more of the deficiencies and problems described above are ameliorated or eliminated by embodiments of the present invention. Embodiment of the present invention simplify or reduce the cost of addressing ink waste issues by enabling an operator to relatively easily and inexpensively handle vapor that is produced as a waste byproduct of printing with ink-based printing devices.




To that end, apparatuses, methods, systems, and arrangements as described herein facilitate vapor handling in printing. In certain implementations, for example, one or more volatiles emitted during an ink-based printing process may be condensed into one or more liquids. The one or more liquids may be directed into absorbent materials such that the combined liquids and absorbent materials form a substance that qualifies as a solid, as determined by a given solid definition or regulatory standard. In certain (alternative but non-exhaustive) implementations, the volatiles emitted during printing may include water and oil vapors, with the oil vapor being condensed into a liquid and added to the absorbent materials while the water vapor is being forwarded under the force of, e.g., negative air pressure.











The above-described and other features and aspects are explained in detail hereinafter in the Detailed Description with reference to the illustrative examples shown in the accompanying Drawings. Those skilled in the art will appreciate that the described or illustrated implementations are provided for purposes of explanation and understanding and that numerous alternative or equivalent implementations are suggested herein or contemplated hereby.




BRIEF DESCRIPTION OF THE DRAWINGS




A more complete understanding of the apparatuses, methods, systems, and arrangements may be had by reference to the following Detailed Description when taken in conjunction with the accompanying drawings wherein:





FIG. 1

illustrates an exemplary printing system implementation.





FIG. 2

is a block diagram that illustrates various exemplary components of an exemplary multifunction printing device implementation.





FIG. 3

illustrates an exemplary print unit implementation having an exemplary vapor handler.





FIG. 4A

illustrates a first exemplary vapor handler implementation.





FIG. 4B

illustrates a second exemplary vapor handler implementation.





FIG. 5

illustrates an exemplary method in flowchart form for manufacturing an exemplary printing device implementation.





FIG. 6

illustrates an exemplary method in flowchart form for operating an exemplary printing device implementation.











DETAILED DESCRIPTION




In the following Detailed Description, for purposes of explanation and not limitation, specific details are set forth, such as particular physical shapes, structural features, numbers of parts, modular components, operative or formative techniques, methodological steps, etc. in order to provide a thorough understanding. However, it will be apparent to one of ordinary skill in the art that the present invention may be practiced in other implementations that depart from these specific details. In other instances, detailed descriptions of well-known techniques, components, materials, manufacturing approaches, etc. are omitted so as not to obscure the description with unnecessary detail.




Exemplary implementations are best understood by referring to

FIGS. 1-6

of the Drawings, like numerals being used for like or corresponding features, aspects, and components of the various drawings.





FIG. 1

illustrates an exemplary printing system implementation at


100


. The exemplary printing system implementation


100


may include a printing device


105


and a computing system


110


, which may be in communication with each other via a connector


115


. The printing device


105


may represent any one of many different types and sizes (e.g., physical dimensions and operative capacity) of multifunction printing devices. In other words, the printing device


105


may be, for example, a handheld printer; a multifunction desktop machine having printing, faxing, copying, and scanning features; a high capacity “industrial strength” printer (e.g., capable of approximately 50,000 copies monthly), a web printer, some blend or combination thereof, etc. The computing system


110


may be, for example, a palm-sized computer, a lap-top computer, a desktop computer, a mainframe computer, a network of any given size, some blend or combination thereof, etc.




The connector


115


provides a communication link between the computing system


110


and the printing device


105


. The manner in which the connector


115


creates such a communication link depends, for example, on the constituents of which the computing system


110


is composed or the capabilities of the printing device


105


. For instance, the connector


115


may be a network connector operating under, e.g., an Ethernet protocol, an internet protocol (IP), etc. Alternatively, the connector


115


may be a local connector operating under, e.g., a parallel cable protocol, a Universal Serial Bus (USB) protocol, an IEEE 1394 (“FireWire”) protocol, etc. Other protocols and connection mechanisms may instead be used to realize the connector


115


, such as a wireless protocol (e.g., Bluetooth®, IEEE 802.11b, wireless Local Area Network (LAN), etc.). Additionally, it should be understood that the above-described examples for the printing device


105


and the computing system


110


are only exemplary and are non-exhaustive and that numerous other implementations will be apparent to those of ordinary skill in the art after reading and understanding the principles and techniques described herein.





FIG. 2

is a block diagram at


105


illustrating various exemplary components of an exemplary multifunction printing device implementation. An exemplary multifunction printing device, as the name implies, is a device capable of multiple functions which are related, but not necessarily limited, to one or more of the following: printing; copying; scanning, including image acquisition and text recognition; sending and receiving faxes; print media handling; or data communication, either by print media or e-media, such as via email or electronic fax. It should be noted that a multifunction printing device need not include other functions beyond that of printing. Furthermore, the term “printing device” is used herein, including in the Drawings and in the Claims, to represent and include a multifunction printing device. In other words, a “printing device” may (but need not necessarily) have other features in addition to printing, such as copying, scanning, faxing, etc.




The exemplary printing device


105


may include one or more processors


205


, an electrically erasable programmable read-only memory (EEPROM) or read-only (non-erasable) memory (ROM)


210


and a random access memory (RAM)


215


. It should be understood that the printing device


105


may have one of, both of, or neither an EEPROM nor a ROM


210


. Also, if there are two such memory components, they may be integrated on a single chip, separate, etc. Additionally, although not explicitly shown, a system bus may connect and interconnect the various illustrated components within the printing device


105


.




The printing device


105


may also include a firmware component (not explicitly shown) that may be implemented as a, e.g., permanent memory module portion of the EEPROM or ROM


210


. The firmware may be programmed and tested like software, and it may be distributed with the printing device


105


. The firmware may be implemented to coordinate operations of the hardware within the printing device


105


when, for example, it stores programming constructs used to perform such operations. It should be understood that the EEPROM or ROM


210


, including any firmware portion, may instead be realized using some other type of memory such as flash memory.




The processors


205


process various instructions to control the operation of the printing device


105


and optionally to communicate with other electronic or computing devices. The memory components (e.g., EEPROM or ROM


210


, RAM


215


, etc.) store various information or data such as configuration information, fonts, templates, print data, scanned image data, and menu structure information, depending on the functions provided by and being used with the printing device


105


. It should also be understood that a particular printing device


105


may include a flash memory component in addition to the EEPROM or ROM


210


(e.g., for firmware updating).




The printing device


105


may also include a disk drive


220


, a network interface


225


, and a serial or parallel interface


230


. The disk drive


220


provides additional storage for data being printed, copied, scanned, or faxed, or other information maintained by or for the printing device


105


. Although the printing device


105


is illustrated as having both the RAM


215


and the disk drive


220


, a particular printing device


105


may alternatively include either a RAM


215


or a disk drive


220


, depending on the storage needs of the printing device. It should be understood that the disk drive


220


(as well as the RAM


215


) may alternatively be substituted with or complemented by another removable and rewritable storage medium, such as a flash memory card, a removable hard drive, or a proprietary format device.




The network interface


225


may provide a connection between the printing device


105


and a data communication network (or a specific device connected over a network-type medium). The network interface


225


allows devices coupled to a common data communication network to send print jobs, faxes, menu data, and other information to printing device


105


via the network. Similarly, the serial or parallel interface


230


may provide a data communication path directly between the printing device


105


and another electronic or computing device. Although the printing device


105


is illustrated as having the network interface


225


and the serial or parallel interface


230


, a particular printing device


105


may only include one such interface component. It should be understood that the printing device


105


may alternatively substitute or add another interface connection type, such as a Universal Serial Bus (USB) interface, an IEEE 1394 (“Firewire”) interface, a wireless interface (e.g., Bluetooth®, IEEE 802.11b, wireless Local Area Network (LAN), etc.), etc.




The printing device


105


may also include a print unit


235


that includes mechanisms arranged to selectively apply ink (e.g., liquid ink, toner ink, etc.) to a print media such as paper, plastic, fabric, and the like in accordance with print data corresponding to a print job. For example, the print unit


235


may include a laser printing mechanism that selectively causes toner to be applied from ink containers to an intermediate surface of a drum or belt. The intermediate surface can then be brought in the proximity of a print media in a manner that causes the toner to be transferred to the print media in a controlled fashion. The toner on the print media can then be more permanently fixed to the print media, for example, by selectively applying thermal energy to the toner. Alternatively, the print unit


235


may include an ink jet printing mechanism that selectively causes liquid to be ejected from ink containers through nozzles and onto print media to form an intended pattern (e.g., text, pictures, etc.).




The print unit


235


may also be designed or configured to support duplex printing, for example, by selectively flipping or turning the print media as required to print on both sides. Those of ordinary skill in the art will recognize that there are many different types of print units available and that the print unit


235


may be composed of any one or more of these different types.




The printing device


105


may also optionally include a user interface (UI) or menu browser


240


and a display or control panel


245


. The UI or menu browser


240


allows a user of the printing device


105


to navigate the device's menu structure (if any). A control aspect of the display or control panel


245


may be composed of indicators or a series of buttons, switches, or other selectable controls that are manipulated by a user of the printing device


105


. A display aspect of the display or control panel


245


may be a graphical display that provides information regarding the status of the printing device


105


and the current options available to a user through, e.g., a menu structure.




The printing device


105


may, and typically does, include application components


250


that provide a runtime environment in which software applications or components can run or execute. Those of ordinary skill in the art will recognize that there are many different types of available runtime environments, which facilitate the extensibility of the printing device


105


by allowing various interfaces to be defined that, in turn, allow the application components


250


to further interact with the printing device


105


.





FIG. 3

illustrates an exemplary print unit implementation at


235


having an exemplary vapor handler


325


according to the present invention. The exemplary print unit implementation


235


may include a print carriage


310


that prints onto a print media (not explicitly shown) that may be guided through the printing device


105


(of

FIGS. 1 and 2

) through a media routing assembly as represented by the platen


305


. The print carriage


310


, which may be fixed or mobile, may include a printhead


320


and an ink source


315


. The ink source


315


may hold color or black inks. The printhead may include print nozzles or pins (not explicitly shown) that cause the inks of the ink source to be applied to print media in accordance with instructions from a print job. The inks of the ink source


315


may be composed, for example, of ink toners (or, more generally, pigments), oils, and water. When heat is applied to the inks of the ink source


315


during the printing process by the printhead


320


, small quantities of the oils and water are typically heated to such a degree that they become vapor as the ink toner is transferred onto the print media. Other mechanisms, such as evaporation, also account for small quantities of volatile oils and water becoming vapor.




These oil and water vapors, individually or collectively referred to herein as waste products, are therefore created during the printing process. If the oil and water vapors are merely released into the environment surrounding the printing device


105


, the surroundings thereof can gradually become coated with an unpleasantly sticky oil. If the oil and water vapors are merely combined into a container and allowed to jointly condense into liquids, the combined liquid must be disposed of with adherence to particular hazardous waste procedures as dictated by current Environmental Protection Agency (EPA) regulations. This may require that an operator of a printer become a party to an expensive or inconvenient agreement with an outside contractor who can properly dispose of the combined oil and water liquid. On the other hand, if the oil vapors are condensed and directed into a substances of predetermined characteristics such that the combined oil liquids and substances meet the EPA regulatory definition of a solid, then the combined oil liquids and substances (now qualifying as one or more solids) may be disposed of with ordinary refuse, for example, in regular trash destined for a city landfill.




To successfully transform oil vapors into a solid, print units


235


may incorporate a vapor handler


325


, which is described in further detail below, for example, with reference to

FIGS. 4A and 4B

. It should be noted that a vapor handler


325


need not be located fully or even partially within the print unit


235


. An air passageway


330


provides a path between the print carriage


310


and the vapor handler


325


. The passageway


330


may be formed of a separate piece or pieces of material or materials (e.g., from a plastic or similar material, a metal, another material suited to containing water and oil vapors, etc.), or integrated into the print unit


235


(or another part of the printing device


105


). Water and oil vapors


335


flow through the passageway


330


(at least primarily) in the direction of the arrows


340


. The flow of the water and oil vapors


335


may be encouraged by a partial vacuum (or, more generally, a negative air pressure that pulls or a positive air pressure that blows/pushes). It should be understood that actual water and oil vapors need not “clump” together as illustrated in the present application for purposes of clarity. It should also be understood that the passageway


330


may have, instead of the two bends illustrated, a different number of bends or no bends along its path. Once the water and oil vapors


335


reach the vapor handler


325


, the vapor handler


325


may transform the oil vapor content of the water and oil vapors


335


into a solid, e.g., that meets the EPA regulatory definition thereof to facilitate easier and cheaper disposal of the waste products.





FIG. 4A

illustrates generally at


325


A a first exemplary vapor handler implementation. The first exemplary vapor handler implementation


325


A illustrates the passageway


330


(none, all, or a portion of which may be part of the vapor handler implementation


325


A) that guides the water and oil vapors


335


along to a condenser


405


. The condenser


405


may be realized as, for example, a so-called “cold finger” (typically a hollow tube carrying a cooling fluid) that may reduce the average temperature of the incoming water and oil vapors


335


. The temperature of the condenser


405


may be set such that the, e.g., average temperature of the water and oil vapors


335


is reduced to a temperature that condenses the oil vapors to oil liquids but still above a temperature that would ordinarily condense much if any of the water vapor to water liquid. To that end, the oils used in the inks of the ink source


315


(of

FIG. 3

) may be selected such that their volatility is lower than that of water. In other words, the oil solvents may be selected based on their having a boiling point that is greater than that of water.




With continuing reference to

FIG. 4A

, the condenser


405


cools the water and oil vapors


335


so that the oil vapors become oil liquids


410


and the water vapor is separated out as water vapor


415


. The oil liquids


410


may fall as oil drops (or streams or similar)


420


. Some of the water vapor, however, may be condensed into water liquid that may commingle with the oil liquids


410


at the condenser


405


and fall as water drops (or streams or similar)


455


. The oil drops


420


and the water drops


455


, if any, fall (e.g., under the influence of gravity or they may be propelled by another force, etc.) through, e.g., a chamber, pipe, or the like towards and thru a boundary


425


and into an absorbent


430


. The boundary


425


may be a physical dividing lines (or planes) between the absorbent


430


and the surrounding atmosphere (e.g., air and the water vapor


415


), may be a membrane holding the absorbent


430


in a desired position or retarding the entry of water vapor


415


, etc. The absorbent


430


may be realized as, for example, a powder, a spongy-type material, a gel-like material, or a combination thereof. Exemplary absorbent materials include silica gel (tradenames such as Aerosil, Cab-O-Sil, Syloid, Sylojet, etc.); cellulose fibers; water-swellable polymers such as polyvinyl alcohol, cellulose, polyvinylpyrrolidone, polyethylene oxide, polyethylene glycol and polyacrylamide; calcium carbonate, and clay. Other suitable absorbent materials are known in the art.




It may be advantageous from a disposal perspective to ensure that the selected absorbent


430


, even after addition of the oil drops


420


(and any water drops


455


), remains or becomes a solid under any or all applicable regulatory guidelines, standards, or laws. One standard/regulation that provides a guideline/method for determining whether a substance qualifies as a “solid” is, by way of example but not limitation, the


9095


A “Paint Filter Liquids Test” promulgated by the United States Environmental Protection Agency (EPA). In the Paint Filter Liquids Test, a predetermined amount of material is placed in a paint filter. If any portion of the material passes through and drops from the filter within a five minute test period, the material is deemed to contain free liquids. If no material passes through the filter, the material is deemed a “solid” for disposal purposes.




Again with reference to

FIG. 4A

, the water vapor


415


may propagate past, away from, or over the absorbent


430


under the force of a partial vacuum


435


and optionally ejected or otherwise introduced into the surrounding environment of the printing device


105


. The partial vacuum


435


may be created using, for example, a pump or a fan.





FIG. 4B

illustrates generally at


325


B a second exemplary vapor handler implementation. The second exemplary vapor handler implementation


325


B illustrates the passageway


330


that guides the water and oil vapors


335


therealong to the condenser


405


. After the water and oil vapors


335


pass thru the condenser


405


, the water and oil vapors


335


may be changed so that the oil vapors become oil drops (or streams or similar)


420


and the water vapor is separated out as water vapor


415


. Some of the water vapor, however, may be condensed into water drops (or streams or similar)


455


. The oil drops


420


and the water drops


455


, if any, fall (e.g., under the influence of gravity or they may be propelled by another force) toward and into a smaller cylindrical tube


440


that is surrounded and partly defined by the membrane


425


. The membrane


425


, which may be realized with plastic, metal, vinyl, a derivate thereof, etc., may be permeable to the oil drops


420


, any water drops


455


, and the water vapor


415


. The smaller cylindrical tube


440


may be surrounded (optionally in a concentric fashion) by a larger cylindrical tube


445


. The vapor handler


325


B also includes a quantity of the absorbent


430


. The absorbent


430


may fill a particular amount, to a particular level, of the larger cylindrical tube


445


(and optionally the smaller cylindrical tube


440


, also).




A height of this absorbent fill quantity is denoted by


430


′ (and the associated dashed curvilinear indicator). This absorbent fill height


430


′ may be determined based on any one or more of a number of factors such as: how many oil drops


420


and any water drops


455


are (e.g., total oil (and water) liquid volume is) expected between changes of the vapor handler


325


B (or changes of the absorbent


430


/larger cylindrical tube


445


/smaller cylindrical tube


440


while the condenser is not changed), how much (if any) does the absorbent


430


swell as it absorbs the oil drops


420


and any water drops


455


, how much space is desired between the top of the absorbent fill height


430


′ and the top of the larger cylindrical tube


445


for flow of the water vapor


415


, etc. As the oil drops


420


and any water drops


455


propagate toward the absorbent


430


, the water vapor


415


may enter the smaller cylindrical tube


440


and may flow thru the membrane


425


, into the larger cylindrical tube


445


, and then toward multiple apertures


450


. It should be noted that the apertures


450


may also extend in “front” of and “behind” the path between the condenser


405


and the smaller cylindrical tube


440


(even though such apertures


450


are not explicitly shown to avoid unduly obfuscating the drawing). The water vapor


415


may continue toward and then thru the apertures


450


, for example, under the influence of, e.g., a partial vacuum


435


or similar force.




As indicated above and in

FIGS. 4A and 4B

, with respect to both vapor handler implementations


325


A and


325


B as well as other implementations generally, the condenser may create water drops


455


as well as oil drops


420


from the water and oil vapors


335


. The water drops


455


may be separate from or intermingled with the oil drops


420


as they both propagate towards and into the absorbent


430


. While at least much of the water may remain as water vapor


415


after the condenser


405


, some water likely cools sufficiently to become the water drops


455


, which subsequently travel to the absorbent


430


. In fact, in some implementations, the condenser


405


may intentionally be set to a temperature that almost certainly creates some water drops


455


to increase the likelihood that little or no oil vapor of the water and oil vapors


335


passes the condenser


405


without becoming oil drops


420


. It should be noted that the relative sizes of the oil drops


420


and the water drops


455


, as well as the ratio of the respective number of drops, as illustrated in

FIGS. 4A and 4B

, are not necessarily reflective of any particular implementation. It should also be noted that, due to real-world tolerances, some small amounts or traces of the oil vapors of the water and oil vapors


335


may pass the condenser


405


without being condensed into oil drops


420


. Thus, some oil vapors may “escape” along with the water vapor


415


.




Many other alternative implementations will be apparent to those of ordinary skill in the art after reading and understanding the principles described herein. For example, the vapor handler


325


B may be reversed in the sense that the condenser


405


may forward oil drops


420


and water vapor


415


toward the larger cylindrical tube


445


so that the escaping water vapor


415


is thereafter withdrawn through the smaller cylindrical tube


440


(and any pipe or piping extending therefrom) under the force of a vacuum


435


or similar. As another example, the vapor handler implementation


325


B illustrated in

FIG. 4B

may be modified by removing the (cylindrical) membrane


425


and substituting therefore either (i) nothing or (ii) a membrane parallel to the top and bottom of the larger cylindrical tube


445


at a height corresponding to the absorbent fill height


430


′ (e.g., at the associated dashed curvilinear indicator), or the expected level thereof after any increase of volume of the absorbent


430


.





FIG. 5

illustrates generally at


500


an exemplary method in flowchart form for manufacturing an exemplary printing device implementation. The flowchart


500


relates to certain manufacturing schemes of many possible approaches to manufacturing printing devices. For example, a print carriage may be installed (block


505


) into a printing device. One side of a passageway (e.g., that is capable of collecting vapors from or directing vapors away from the print carriage) may be connected to the print carriage (block


510


). Another side of the passageway may be connected to a vapor handler (block


515


) (e.g., directly if the vapor handler has been previously assembled). It should be noted that there may be more than two sides of the passageway that may be connected. Additionally, one or more implementations of connecting another side of the passageway to the vapor handler (of block


515


) may entail linking another side of the passageway to a condenser (block


515


′) or linking the condenser to an absorbent material (block


515


″) (e.g., if the vapor handler has not been previously assembled).




It should be understood that many alternative manufacturing schemes may be employed. For example, a passageway may be connected to a vapor handler prior to, simultaneously with, or after connection of the passageway to a print carriage. Also, a passageway may be connected to one or both of a vapor handler and a print carriage prior to installation of either (or any) into a printing device. Furthermore, a passageway may be installed into a printing device prior to a vapor handler or a print carriage being installed into the printing device or being connected to the passageway (e.g., if the passageway is integral with/formed by a housing or other part of the printing device). As another alternative printing device manufacturing implementation, a printhead may be installed into a printing device, a vapor handler may be installed into the printing device (e.g., directly if pre-assembled or in parts (e.g., by linking one or more condensers to one or more absorbent materials) if not pre-assembled), and a passageway may be added and connected to each of the printhead and vapor handler.





FIG. 6

illustrates generally at


600


an exemplary method in flowchart form for operating an exemplary printing device implementation. The flowchart


600


relates to a printing operation in which (one or more) printheads and (one or more) ink sources may be used for printing (block


605


). The printing operation may emit volatiles (block


610


). These volatiles may include water vapor and one or more different types of oil vapor, for example. The volatiles may be directed along a passageway (which may be formed of a physically solid material, a flow of air within the printing device, some combination thereof, etc.) toward and to one or more condensers (block


615


). The condenser may condense the volatiles into liquids (block


620


). For example, the condenser may be set to a temperature such that oil vapors are condensed into oil liquids while at least most of the water vapor is not condensed into water liquid so that at least most of the water may be ejected while still in a gaseous phase. The amount of water vapor that is or may be condensed into water liquid may be set such that no or practically no oil remains in a gaseous phase after the condensing. The oil liquids and any water liquids may be directed to an absorbent material (block


625


), while the water vapor is funneled beyond the condensers under, e.g., negative air pressure. Because at least most of the water is ejected as water vapor, very little or no relatively clean or pure (e.g., non-messy) water liquid is collected with or by the absorbent material, which might unnecessarily occupy space volume in, around, or through the absorbent material.




The absorbent material may be selected or designed so that the addition of oil liquids and any water liquids creates a solid or does not cause the material to cease being a solid. The waste having the absorbent material, oil liquids, and any water liquids (or a new substance derived from a combination thereof) may be disposed of as a solid at regular intervals or as needed, with the operator replacing the solid waste with new absorbent material. Thus, the absorbent material may be replaced, for example, individually (e.g., by pouring a powder, by inserting a gel pack, by placing a spongy or other porous solid in the vapor handler, etc.), along with a cartridge (e.g., by substituting a new cartridge formed of plastic or something similar with new absorbent material therein or thereon, etc.), along with a partially or entirely new vapor handler (e.g., by installing the partially or entirely new vapor handler, etc.), and so forth. The absorbent material replacement (whether individually, along with a cartridge, etc.) may be accomplished according to certain guidelines as specified by the manufacturer. The guideline may be based, for example, on the volume of ink used, the weight gain of the absorbent material (alone or with any cartridge), an elapsed time since a previous replacement, and so forth. Additionally, a printing device employing a vapor handler may be adapted to follow any such guidelines and alert a user/operator as to when it is appropriate, advisable, or necessary to replace the absorbent material or the absorbent material cartridge.




Although implementations of apparatuses, methods, systems, and arrangements have been illustrated in the accompanying Drawings and described in the foregoing Detailed Description, it will be understood that the present invention is not limited to the implementations explicitly disclosed, but is capable of numerous rearrangements, modifications, substitutions, etc. without departing from the spirit and scope set forth and defined by the following claims.



Claims
  • 1. A printing device that collects at least one waste product of a printing operation, comprising:a print carriage, said print carriage including an ink source; a vapor handler, said vapor handler including a condenser and an absorbent material; and an air passageway, said passageway connecting said print carriage to said vapor handler.
  • 2. The printing device of claim 1, wherein said condenser is interposed between the passageway and the absorbent material.
  • 3. The printing device of claim 1, wherein the condenser comprises a cold finger.
  • 4. The printing device of claim 1, wherein the condenser is configured to selectively condense the at least one waste product of the printing operation from a gas phase into a liquid phase.
  • 5. The printing device of claim 4, wherein the at least one waste product of the printing operation comprises oil vapor and water vapor, the condenser being configured by setting the condenser to a temperature that selectively condenses the oil vapor to oil liquid while the temperature remains above that which would condense all of the water vapor.
  • 6. The printing device of claim 1, wherein the absorbent material is a material selected from the group consisting of silica gel, cellulose fibers, polyvinyl alcohol, polyvinylpyrrolidone, polyethylene oxide, polyethylene glycol, polyacrylamide, calcium carbonate, or clay.
  • 7. The printing device of claim 1, wherein said passageway includes a first opening and a second opening; the first opening connecting said passageway to said print carriage, and the second opening connecting said passageway to said vapor handler.
  • 8. The printing device of claim 1, wherein said passageway directs the at least one waste product of the printing operation to the absorbent material using air pressure.
  • 9. A printing device for disposing of oil vapor byproduct, comprising:a print carriage, said print carriage including a printhead and an ink source, said print carriage configured to cause the printhead to eject ink from the ink source during a printing operation that creates oil vapor; a vapor handler, said vapor handler including a condenser and an absorber; and a passageway, said passageway connecting said print carriage to said vapor handler, said passageway adapted to direct the oil vapor from said print carriage to said vapor handler; wherein the condenser is configured to condense the oil vapor into oil liquid, and the absorber is configured to absorb the oil liquid.
  • 10. The printing device of claim 9, wherein the condenser and the absorber are positioned such that gravity may propel the oil liquid from the condenser to the absorber.
  • 11. The printing device of claim 9, wherein the absorbent material is a material selected from the group consisting of silica gel, cellulose fibers, polyvinyl alcohol, polyvinylpyrrolidone, polyethylene oxide, polyethylene glycol, polyacrylamide, calcium carbonate, or clay.
  • 12. The printing device of claim 9, wherein the absorber is separated from ambient air by an oil-permeable membrane.
  • 13. The printing device of claim 9, wherein said passageway comprises a manifold having a first orifice and a second orifice; the first orifice forming at least part of a juncture between the manifold and said print carriage, and the second orifice forming at least part of a juncture between the manifold and said vapor handler.
  • 14. The printing device of claim 9, wherein the printing operation further creates water vapor along with the oil vapor, said passageway is further adapted to direct the water vapor along with the oil vapor from said print carriage to said vapor handler, the condenser is further configured selectively condense most of the oil vapor while not condensing most of the water vapor, and the absorber is further configured to absorb any condensed water vapor.
  • 15. The printing device of claim 14, wherein said vapor handler further includes a source of air pressure, the air pressure capable of extracting the water vapor present between the condenser and the absorber.
  • 16. A printing system for handling waste vapor created during printing, comprising:a computing system; and a printing device, said printing device operably connectable to said computing system for receiving printing instructions therefrom, said printing device including: an interface unit, the interface unit capable of interpreting printing instructions received from said computing system; and a print unit, the print unit including: a printing mechanism, the printing mechanism creating oil vapor during printing; a passageway, the passageway having a first point and a second point, the first point of the passageway connected to the printing mechanism; and a vapor handler, the vapor handler connected to the second point of the passageway, the vapor handler including a condenser that is capable of condensing the oil vapor into oil liquid and absorbent material that is capable of absorbing the oil liquid.
  • 17. The system of claim 16, wherein the condenser is located closer to the second point of the passageway than is the absorbent material.
  • 18. An apparatus for handling vapor in a printing process, comprising:an ink source, said ink source including at least one pigment and oil; a printing mechanism, said printing mechanism capable of applying the at least one pigment to a surface and producing oil vapor from the oil; a condenser, said condenser capable of converting the oil vapor to oil liquid; a passageway, said passageway including a first opening and a second opening; the first opening of said passageway at least proximate to said printing mechanism, and the second opening of said passageway at least proximate to said condenser; said passageway adapted to direct the oil vapor away from said printing mechanism and toward said condenser; and an absorbent material, said absorbent material capable of collecting and absorbing the oil liquid.
  • 19. The apparatus of claim 18, further comprising:an air pressure source, said air pressure source capable of creating air pressure to propel the oil vapor from said printing mechanism and to said condenser.
  • 20. The apparatus of claim 19, wherein said ink source further includes water, said printing mechanism is further capable of producing water vapor from the water, said condenser is configured to not convert at least most of the water vapor to water liquid, said passageway is further adapted to direct the water vapor away from said printing mechanism and toward said condenser, said air pressure source is further capable of creating the air pressure to propel the water vapor from said printing mechanism and past said condenser, and said absorbent material is further capable of collecting and absorbing the water liquid.
  • 21. The arrangement of claim 18, wherein the absorbent material is a material selected from the group consisting of silica gel, cellulose fibers, polyvinyl alcohol, polyvinylpyrrolidone, polyethylene oxide, polyethylene glycol, polyacrylamide, calcium carbonate, or clay.
  • 22. A system for handling vapor produced in a printing operation, comprising:means for producing oil vapor and water vapor from an ink supply; means for condensing the oil vapor into oil liquid; means for guiding the oil vapor and the water vapor from the means for producing oil vapor and water vapor from an ink supply to the means for condensing the oil vapor into oil liquid; and means for collecting the oil liquid into a solid.
  • 23. The system for handling vapor of claim 22, wherein said means for producing oil vapor and water vapor from an ink supply comprises means for printing.
  • 24. The system for handling vapor of claim 22, wherein said means for collecting the oil liquid into a solid comprises an absorbent material.
  • 25. The system for handling vapor of claim 22, further comprising:means for extracting the water vapor beyond the means for condensing the oil vapor into oil liquid.
  • 26. A method for handling vapor produced during printing, comprising the steps of:printing using an ink source; emitting water vapor and oil vapor as byproducts of printing; directing the water vapor and the oil vapor toward a condenser; condensing the oil vapor into oil liquid by cooling the oil vapor; and absorbing the oil liquid by an absorbent material.
  • 27. The method of claim 26, wherein said step of directing the water vapor and oil vapor comprises the step of:forcing the water vapor and the oil vapor along a passageway under air pressure established therein.
  • 28. The method of claim 27, wherein the air pressure is established via a partial vacuum.
  • 29. A method for handling and constraining waste produced during printing, comprising the steps of:printing using an ink that includes a first solvent and a second solvent, a first volatility of the first solvent being lower than a second volatility of the second solvent; emitting, during said step of printing, a first vapor that is related to the first solvent and a second vapor that is related to the second solvent; funneling the first vapor and the second vapor toward a condensing unit; condensing, at the condensing unit, the first vapor into a first liquid, a temperature of the condensing unit set responsive to a first temperature corresponding to the first volatility and a second temperature corresponding to the second volatility; directing the first liquid into an absorbent material; and funneling the second vapor beyond the condensing unit.
  • 30. The method of claim 29, wherein the first solvent comprises oil and the second solvent comprises water.
  • 31. The method of claim 29, wherein said steps of funneling are effectuated using, at least partly, negative air pressure.
  • 32. The method of claim 29, wherein the temperature of the condensing unit is set (i) approximately at or above the second temperature and (ii) aproximately at or below the first temperature.
  • 33. The method of claim 29, wherein said step of condensing comprises the step of:condensing, at the condensing unit, part of the second vapor into a second liquid; and wherein said step of directing comprises the step of: directing the second liquid into the absorbent material.
US Referenced Citations (4)
Number Name Date Kind
4901094 Iwagami et al. Feb 1990 A
5329306 Carlotta Jul 1994 A
6176563 Anderson et al. Jan 2001 B1
6397488 Brinkly Jun 2002 B1