The present invention pertains to printing apparatus having replaceable modules, and the replacement of replaceable modules of a printing apparatus. In particular, the present invention pertains to avoiding contamination of or damage to the printing apparatus by verifying the correct identity of a replaceable module before the printing apparatus fully engages the replaceable module.
Many types of printing apparatus, such as office printers and photocopiers, have replaceable modules, such as ink or toner containers, imaging elements, fusers, etc. Some of these modules are designed to be replaced easily by the user, and are sometimes called customer replaceable units (CRU's ). Such customer replaceable units are convenient for machine users. However, inserting an incorrect replaceable module may damage parts of the printing apparatus. For example, inserting into a printing apparatus a toner container having an incorrect toner may cause the printing apparatus to produce poor quality prints, or may even damage components of the printing apparatus.
Physical barriers, such as “keys,” are used to block insertion of an incorrect replaceable module. However, depending on the physical structure of the printing apparatus and associated replaceable module, the number of physical “key” combinations may be limited, which limits the number of incorrect replaceable modules that can be reliably excluded.
In accordance with an aspect of the present invention, a coupler on a printing apparatus communicates with a tag on a replaceable module for a printing apparatus. The tag on the replaceable module stores information concerning the identity of the replaceable module. The printing apparatus coupler reads the information from the replaceable module tag, and determines if the replaceable module is acceptable for use in the printing apparatus. The coupler causes the printing apparatus to automatically take action based on that determination, such that if the replaceable module in not acceptable for use in the printing apparatus, an operating element of the printing apparatus does not fully engage the replaceable module, whereby an unacceptable replaceable module does not contaminate or otherwise damage the operating element of the printing apparatus.
The printing subsystem 22 includes printing modules, such as a photoreceptor 26 upon which the image to be printed is formed. The photoreceptor can be a photoreceptor belt as shown, or a photoreceptor drum. The photoreceptor rotates so that a section of the photoreceptor on which images are formed sequentially comes into proximity with other printing modules of the printing subsystem. The other printing modules include a charging corotron 28 for charging the surface of the photoreceptor 26, and a raster output scanner (ROS) imaging element 30 for forming an image in the electrically charged photoreceptor surface. Other apparatus for imagewise discharging of the photoreceptor 26, such as an LED bar or ionographic head, are also known. The image data operative of the ROS 30 or other apparatus typically generated by what is here called an “electronic subsystem” or ESS 32. (For clarity, the necessary connection between the electronic subsystem ESS 32 and the ROS 30 is not shown, but will be apparent to persons skilled in the art.).
A developer unit 34 develops the image on the photoreceptor 26, and a transfer station 35 includes a transfer corotron 36 for transferring the developed image from the photoreceptor 26 to print media substrate as the print media substrate moves along the media path 38. A cleaning device 40 cleans the photoreceptor after the image has been transferred from the photoreceptor to the print media substrate. The cleaning device 40 deposits excess toner into a toner reclaim container 42. Persons skilled in the art will recognize that in any particular embodiment of an electrophotographic printer, there may be variations on this general outline, such as additional corotrons, or cleaning devices, or, in the case of a color printer, multiple developer units.
Persons familiar with the art will recognize that the developer unit 34 generally comprises a housing in which a supply of developer material (which typically contains marking material such as toner particles plus carrier particles) which can be supplied to an electrostatic latent image created on the surface of the photoreceptor or other charge receptor by the ROS. The developer unit 34 may be made integral with, or separable from, other modules of the printing subsystem 22. A printing apparatus capable of printing in multiple colors may have multiple developer units, each developing the photoreceptor with a different primary-color toner. The developer unit 34 receives toner from a toner container 44, which could contain either pure toner or an admixture of carrier particles. Excess developer material is deposited in a developer receptacle 46. In this particular embodiment, the developer receptacle 46 connected to the developer unit and the toner reclaim container 42 connected to the cleaning unit are different receptacles.
The fusing subsystem 24 may include fuser rolls, such as a pressure roll 52, a heat roll 54 including, at the core thereof, a heat element 56, and a web supply 58. The web supply provides a release agent to the outer surface of the heat roll 54 so that media passing between the heat roll 54 and the pressure roll 52 does not stick to the heat roll. Also typically included in a fusing subsystem is a temperature monitor 60, such as a thermistor, for monitoring the temperature of a relevant portion of the fusing subsystem.
Paper or other print media is supplied from media supply trays 62. Paper is drawn from the supply trays, typically one sheet at a time, by feed rollers 64, and transported along the paper path 38, past the image transfer station 35, and through the fusing subsystem 24.
A document handler 66 and a photosensor 68 provide the printing apparatus with copying capability. The document handler 66 presents one or both sides of hard-copy original pages to the photosensor 68. The photosensor creates an electronic image of each hard-copy original page presented to it. An exemplary photosensor is a photosensor bar. One or more lenses (not shown) may focus the image of the original page onto the photosensor. The document handler typically includes rollers 70, nudgers, and other well-understood elements for properly presenting the original page to the photosensor 68.
An information distribution component 72 can send or receive messages, as will be described below, through the same network channels as the electronic subsystem (ESS) 32, or alternatively through a telephone or facsimile line (not shown). Alternatively, the information distribution component 72 can cause messages to be displayed through a display 74, typically in the form of a touch screen disposed on the exterior of the apparatus. In other embodiments, the ESS 32 and the information distribution component 72 may be merged into a single module.
Certain modules in the printing apparatus are typically designed to be replaceable during the lifetime of the printing apparatus. For example, during use, the printing apparatus consumes the marking material contained in the toner container 44. Therefore, the toner container is generally designed to be replaceable by the user of the printing apparatus. Other modules may also be replaceable, either by a user or by a skilled technician. Examples of printing apparatus modules that may be designed to be replaceable include the cleaning unit 40, the transfer corotron 36, and the fusing subsystem 24 (or individual components of the fusing subsystem). In certain printing apparatus, the entire printing subsystem 22, including the photoreceptor 26, the developer unit 34, the toner container 44, the transfer corotron 36, and the cleaning unit 40, is replaceable as a single module.
The information distribution component 72 interacts with specially-adapted “customer replaceable unit monitors” or “CRUMs” 76, 78 that are associated with one or more of the replaceable modules within the printing apparatus. As described more fully in U.S. Pat. No. 6,016,409, the CRUMs contain memory that stores information pertaining to the replaceable module. Each CRUM is capable of communicating with the information distribution component 72 of the printing apparatus at certain times during use of the printing apparatus so that the information distribution component can read information from, and in some cases, write information to, the CRUM for the replaceable module.
In the exemplary embodiments described here, the toner container 44 is a representative replaceable module. However, after reading this description, persons skilled in the art will recognize that the principles can be applied with respect to many replaceable modules of the printing apparatus. In addition to the applicability to different replaceable modules of an electrophotographic printing apparatus, the principles are also applicable to replaceable modules of other types of printing apparatus. For example, in an ink jet printer, the replaceable module may be a container holding ink, either solid ink for a phase change ink jet printing apparatus or liquid ink for a liquid ink printing apparatus. Replaceable modules for an ink jet printer may also include the printhead, a transfer drum, and maintenance elements for the printhead and/or drum.
After studying this disclosure, persons skilled in the art will recognize that the principles represented can be applied to replaceable modules having other shapes and other mechanisms of engagement with the printing apparatus. For other types of replaceable modules, other arrangements may constitute engagement between the printing apparatus and the replaceable module. For example, some types of modules, full engagement is established by applying an electrical voltage or signal to the replaceable module. Such modules may be in physical contact, but not fully engaged until such voltage or signal is applied.
When the replaceable module toner container is fully inserted into the printing apparatus, the CRUM 76 on the replaceable module engages a CRUM reader 88 on the printing apparatus. The CRUM reader 88 communicates with the CRUM 76 to read certain information from the CRUM concerning the status of the toner container, and to write to the CRUM certain information concerning use of the toner container in the printing apparatus. Communication between the CRUM 76 and the CRUM reader 88 may be a wired communication contact, or a wireless communication link. The CRUM reader 88 forms part of the distribution component 72 of the printing apparatus (FIG. 1). Persons skilled in the art are familiar with such CRUMs, their construction, and their use.
The replaceable module 44 contains a tag 90 for communicating with a coupler 92 in the printing apparatus as the replaceable module moves along the insertion path, before the replaceable module fully engages the printing apparatus. In the exemplary embodiment, the tag 90 communicates with the coupler 92 before the operating element (the auger 82) engages the toner inside in the toner container 44. Although an exemplary embodiment is shown in which the tag 90 and the CRUM 76 are separate, the tag may be part of the customer replaceable unit monitor (CRUM) 76 that contains information pertaining to various monitoring functions such as tracking usage of the replaceable module. An exemplary CRUM into which the tag can be incorporated is described in U.S. Pat. No. 6,532,351, entitled Wireless Interaction With Memory Associated With a Replaceable Module for Office Equipment, by inventors Austin Richards and Michael Thomson.
The tag 90 on the replaceable module includes a tag memory element 94 for storing information relevant to identifying the replaceable module, such as model information, regional usage information, or a serial number. The tag memory element 94 may be a separate EEPROM or other conventional memory device attached to the replaceable module. In an embodiment in which the tag 90 is a portion of the CRUM 76, the tag memory element may be a portion of the memory of the CRUM. The tag also contains a tag communication element 96 for communicating with the printing apparatus coupler 92.
The printing apparatus coupler 92 includes a coupler processor element 98 and a coupler communication element 99 connected to one another. The coupler processor 98 may be either a dedicated processor for the coupler (as shown), or it may be a programmed function within the general processor for the printing apparatus. In certain implementations, the coupler processor 98 could be a simple “compare” circuit for comparing one set of data with another set of data, whether stored in the coupler or received from an external source. The coupler 92 draws operating electrical power from the printing apparatus.
The coupler communication element 99 and tag communication element 96 are capable of forming a communication link between the coupler 92 and the tag 90. The coupler communication element 99 is capable of transferring queries from the coupler processor 98 to the tag communication element 96. The tag communication element 96 receives the queries from the coupler communication element, transfers the query to the tag memory element 94, and transmits a response from the tag memory element to the coupler communication element 99. The coupler communication element 99 also receives the responses from the tag communication element 96, and transfers those received responses to the coupler processor 98.
The communication link formed between the coupler communication element 99 and the tag communication element 96 may be either a wireless communication link or a wired communication link. For a wireless communication link, the coupler communication element and the tag communication element are matched wireless transceivers that enable the coupler communication element to transmit queries to the tag communication element. In exemplary embodiments, the tag communication element 96 is a passive transceiver, so that the tag 92 does not require its own power source.
A wireless communication link can be, for example, a radio frequency (RF) link, an infrared link, or a magnetic link. For an exemplary radio frequency communication link such as shown schematically in
The coupler 92 can then issue a query through the coupler RF antenna 99. When the tag RF antenna 96 is within range of the coupler RF antenna, a communication link is formed between the coupler and the tag so that the coupler and the tag can communicate with one another. Once the communication link is established, the tag can receive the query. The RF communication element of the tag 99 retransmits from the tag specified information from the tag memory element 94 in response to the query received from the coupler.
The coupler 92 is positioned on the printing apparatus, and the tag 90 is positioned on the replaceable module, so that the coupler and tag establish such a communication link before the replaceable module to which the tag is attached fully engages the printing apparatus. The replaceable module fully engages the printing apparatus when the replaceable module is inserted into the printing apparatus to such a position that, if the replaceable module were improper, the replaceable module (or the contents of the replaceable module) could contaminate or otherwise damage the printing apparatus. Positioning of the coupler and the tag so they communicate with one another before the replaceable module is in a position to contaminate or otherwise damage the printing apparatus allows corrective action to occur to prevent such contamination or other damage if the user attempts to insert an incorrect replaceable module. In particular, if the replaceable module is a toner container, the coupler and the tag are positioned so that communication between them before an operating element of the printing apparatus (such as the auger 82 or other content removal tool) contacts the toner in the container. In an exemplary implementation in which the replaceable module 44 is inserted into the printing apparatus along the insertion path 79, the coupler and the tag are positioned so that the communication link is established as the replaceable module moves along the insertion path.
Once the communication link between the printing apparatus coupler and the replaceable module tag is established, the coupler communicates a query to the tag seeking, for example, identifying information. The tag responds with responding information, such as its identifying information stored in the tag memory. The coupler processor analyzes the information received from the tag. The coupler processor determines if the received tag identifying information indicates that the replaceable module is acceptable for the printing apparatus, or unacceptable.
An acceptable toner container, for example, would have the proper type of toner for that particular printing apparatus. A color printing apparatus that uses multiple toner containers, each having a different color, may have a separate coupler positioned along each insertion path for the toner containers of the different color toners to guard against inserting an incorrect color toner.
After receiving and analyzing the response information from the tag, the coupler processor 98 causes the printing apparatus to take action based on whether the replaceable module is acceptable or unacceptable. In one example, the printing apparatus can take acceptance action if the coupler processor determines that the tag information indicates the replaceable module is acceptable.
Printing apparatus acceptance action may include removing a barrier that would otherwise block full insertion of the replaceable module into the printing apparatus, or displaying on a user interface (such as a control panel screen) an instruction for the user to continue inserting the replaceable module into the printing apparatus. Such acceptance action may include causing the printing apparatus to fully engage the replaceable module, such as by inserting an auger into the toner container, or causing electrical operating contacts to engage the replaceable module, or applying particular operating voltages or electrical signals to the replaceable module.
In other examples, the printing apparatus can take exception action if the coupler processor determines that the tag information indicates the replacement module is unacceptable. Such exception action may include displaying a warning on a user interface (such as the display 74), or inserting a barrier that blocks engagement of the replaceable module and the printing apparatus. For example, the normal position of the moveable barrier 102 of the embodiment shown in
In some instances, the coupler processor 98 may not be able to determine conclusively whether the replaceable module is acceptable or unacceptable. The coupler processor may determine from the tag identifying information that the replaceable module may be acceptable in certain applications, and not in others, which would require that the user determine which application is pertinent. Or, the coupler processor may determine that the replaceable module is acceptable with a caveat (such as use of that particular replaceable module may void the warranty on the printing apparatus, or that print quality may change). In such instances, the printing apparatus may take exception action that includes displaying a comment for the user to acknowledge prior to completing insertion of the replaceable module.
In certain embodiments, the communication link between the coupler 92 and the tag 90 may be infrared radiation. In such an embodiment, the coupler communication element 99 may comprise an infrared emitter and an infrared detector. The tag communication element 96 may similarly comprise an infrared detector and an infrared emitter. Or, in an alternative, the tag memory 94 and the tag communication element may be formed of a single infrared reflector that reflects a pattern comprising the module identifying information.
In other embodiments the coupler communication element and the tag communication element may physically contact one another to establish the communication link between the printing apparatus coupler and the replaceable module tag. Such physical contact communication elements are also positioned so that the communication link is established before the replaceable module fully engages the printing apparatus. Persons skilled in the art will recognize that many different types of connectors are available for such physical contact. Different types of connectors are appropriate depending on whether the communication link is to be established while the replaceable module moves along the insertion path, or while the replaceable module is stationary with respect to the printing apparatus. One example of physical connectors includes incorporating an electrically conductive pad for one communication element, and an electrically conductive brush for the other communication element. Another example incorporates an electrically conductive pad for one communication element, and an electrically conductive roller for the other communication element. Yet another example incorporates an electrically conductive slot and an electrically conductive pin that fits into the slot.
The replaceable module tag and the printing apparatus coupler can be placed in other positions that allow for the coupler to read identifying information from the replaceable module before an operating element of the printing apparatus fully engages the replaceable module.
While particular embodiments exemplary of the invention have been described in detail, after reading the above descriptions, persons skilled in the art will be able to develop readily various modifications to the specific embodiments described, without departing from the spirit of the invention. For example, the principles of the invention can be applied to toner containers or other replaceable modules that are not cylindrical. The details of the positioning of the coupler, the tag, and the communication link between the coupler and the tag depend on the physical configuration of the replaceable module. Furthermore, the principles can be applied to various other types of replaceable modules, such as fusers, imaging elements (photoreceptor drum), cleaner elements, integrated print cartridges that incorporate multiple elements in a single module. In addition, the principles described can also be applied to replaceable modules of printing apparatus that use printing techniques other than electrostatic imaging, such as ink containers for solid or liquid ink printers, ink jet printhead maintenance stations, etc. Therefore, the invention should not be construed as limited to the particular embodiments described.
Number | Name | Date | Kind |
---|---|---|---|
4963939 | Kurando et al. | Oct 1990 | A |
5678121 | Meetze, Jr. et al. | Oct 1997 | A |
5999759 | Palumbo et al. | Dec 1999 | A |
6351621 | Richards et al. | Feb 2002 | B1 |
6385407 | Inose | May 2002 | B1 |
6473571 | Wegman et al. | Oct 2002 | B1 |
6532351 | Richards et al. | Mar 2003 | B2 |
6711362 | Asakura | Mar 2004 | B2 |
Number | Date | Country | |
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20040228641 A1 | Nov 2004 | US |