INK DELIVERY SYSTEM ADAPTER

Description

TECHNICAL FIELD

[0001] This invention relates in general to ink-jet printing systems and, more particularly, to ink-jet printing systems which makes use of an ink supply cartridge that includes a memory device for exchanging information with the ink-jet printing system.

BACKGROUND OF THE DISCLOSURE

[0002] One type of prior art ink-jet printing system or printing system has a printhead mounted to a carriage which is moved back and forth over print media, such as paper. As the printhead passes over appropriate locations on the print media, a control system activates the printhead to eject ink drop onto the print media and form desired images and characters. To work properly, such printing systems must have a reliable supply of ink for the printhead.

[0003] One category of ink-jet printing system uses an ink supply that is mounted to and moves with the carriage. In some types, the ink supply is replaceable separately from the printhead. In others, the printhead and ink supply together form an integral unit that is replaced as a unit once the ink in the ink supply is depleted. One such ink supply replaceable separately from the printhead is disclosed in European Patent Application 0 440 261 A2. European Patent Application 0 440 261 A2, which is considered to be the closest priov art, discloses an ink jet recording apparatus having a replaceable ink cartridge. The replaceable ink cartridge includes an ink cassette insertable into an adapter. The ink cartridge defined by the adapter and ink cassette is insertable into a cartridge guide of the recording apparatus. Sidewalls of the adapter of the ink cartridge include rails that engage guides of the cartridge guide to accurately position the ink cartridge within the cartridge guide. The ink cartridge includes a capping member and information medium contacts for engaging a hollow needle and corresponding connecting pins of the recording apparatus, respectively. The claimed adaptive ink supply differs from the above disclosure in that it comprises at least the guide member on the leading edge of the base of the adapter connectar.

[0004] Another category of printing system, referred to as an "off-axis" printing system, uses ink supplies which are not located on the carriage. One type replenishes the printhead intermittently. The printhead will travel to a stationary reservoir periodically for replenishment. Parent application serial number 09/034,874 to this application, entitled "Ink Delivery System Adapter" describes another printing system wherein the printhead is fluidically coupled to a replaceable ink supply or container via a conduit such as a flexible tube. This allows the printhead to be continuously replenished during a printing operation.

[0005] In a parent application to this application, a replaceable off-axis supply is described which has a memory device mounted to the housing. When installed into the printing system, an electrical connection between the printing system and the memory device is established. This electrical connection allows for the exchange of information between the printing system electronics and the memory. The memory device stores information which is utilized by the printing system electronics to ensure high print quality. This information is provided to the printing system electronics automatically when the cartridge is mounted to the printing system. The exchange of information assures compatibility of the cartridge with the printing system.

[0006] The stored information further prevents the use of the ink supply after it is depleted of ink. Operating a printing system when the reservoir has been depleted of ink can destroy the printhead. The memory devices concerned with this application are updated with data concerning the amount of ink left in the reservoir as it is being used. When a new cartridge is installed, the printing system will read information from the memory device indicative of the reservoir volume. During usage, the printing system estimates ink usage and updates the memory device to indicate how much ink is left in the cartridge. When the ink is substantially depleted, this type of memory device can store data indicative of an out-of-ink condition. When substantially depleted of ink, these cartridges are typically discarded and a new cartridge along with a new memory device is installed.

[0007] Previously used ink containers have fixed volumes of deliverable ink that have been provided for printing systems based generally on ink usage rate requirements of a particular user. However, printing systems users have a wide variety of ink usage rates which may change over time. For ink-jet printing system users who require relatively high ink usage rates, ink containers having these volumes require a relatively high ink container replacement rate. This can be especially disruptive for print jobs which are left to run overnight. Extended continuous use of printing systems causes ink containers to run out of ink during a print job. If the printing system does not shut down during an "ink out" condition, the printhead or the printing system itself may be permanently damaged.

[0008] For printing system users who require lower volumes of ink, a different set of problems is encountered if the ink volume is too large. The ink may surpass its shelf life prior to being utilized. Larger ink containers are more expensive and bulkier than smaller cartridges and may be cost prohibitive to small volume users. Thus, a need exists for providing adaptive ink supplies for the ink cartridge described in the parent application, so that ink containers having a variety of ink volumes may be utilized. The adaptive ink supplies should be still able to provide to the printing system the benefits of the memory device of the original equipment ink cartridge.

SUMMARY OF THE INVENTION

[0009] According to one broad aspect of the invention, there is provided an adaptive ink supply for a printing system for use in lieu of a first ink cartridge, the printing system having a receptacle for receiving the first ink cartridge, the receptacle containing an interconnect platform, a printing system electrical connector which protrudes from the platform, has at least two sides, and has and end containing a plurality of resilient electrical contacts protruding from the end, a controller which exchanges information with a first memory device mounted to the first ink cartridge containing information concerning ink in the first ink cartridge, an ink supply sleeve protruding from the platform and surrounding a hollow needle fluidically connected to a printhead, the adaptive ink supply comprising:

an ink reservoir containing a replacement ink;

a fluid outlet in fluid communication with the ink reservoir which is sized to be received by the ink supply sleeve and to receive the hollow needle to allow ink to flow from the ink reservoir to the printhead;

an adapter connector including a base having a leading end relative to a direction of engagement of the adapter connector with the printing system connector, a plurality of electrical contact pads mounted to the leading end of the base and spaced side-by-side for engaging the electrical contacts of the printing system electrical connector, the adapter connector having at least one guide member on the leading end of the base which engages at least one of the sides of the printing system electrical connector for moving the interconnect platform from which the printing system electrical connector protrudes so as to align the contact pads into engagement with the electrical contacts; and

a source of signals electrically connected to the contact pads of the adapter connector for exchanging information with the controller.

[0010] According to another broad aspect of the invention, there is provided a method for adapting an ink supply to a printing system which is configured to utilize a first ink cartridge which has a first memory device containing data concerning ink in the first ink cartridge, the printing system having an interconnect platform containing a fluid inlet with a hollow needle surrounded by a sliding biased sealing collar, a printing system electrical connector which protrudes from the platform, has at least two sides, and has an end containing a plurality of protruding resilient electrical contacts protruding from the end, the electrical contacts including two pairs of volume sensing contacts, a controller which exchanges information with the first memory device concerning ink in the first ink cartridge, the first ink cartridge having a pair of inductive coils for sensing ink quantity therein, each of the inductive coils adapted to be electrically connected to one of the pairs of the volume sensing contacts when the first ink cartridge is installed in the receptacle, the method comprising:

(a) providing an adaptive ink supply having an ink reservoir with a fluid outlet, an adapter connector including a base having a leading end relative to a direction of engagement of the adapter connector with the printing system electrical connector, a plurality of contact pads for engaging the electrical contacts mounted to the leading end of the base and spaced side-by-side for engaging the electrical contacts of the printing system electrical connector, the adapter connector having at least one guide member on the leading end of the base for engaging at least one of the sides of the printing system electrical connector, and a source of signals which contains electronic information which is readable by the controller to enable the printing system to operate;

(b) coupling the fluid outlet of the ink reservoir to the fluid inlet, depressing the sliding collar with an end of the fluid outlet and inserting the hollow needle of the fluid inlet into the fluid outlet to supply ink from the reservoir;

(c) engaging the adapter connector to the electrical connector of the printing system by moving the interconnect platform from which the printing system electrical connector protrudes so that the contact pads engage the electrical contacts of the printing system electrical connector,

(d) electrically connecting the volume sensing contacts of at least one of the pairs to each other;

(e) performing an electrical continuity check by supplying voltage from the controller to said at least one of the pairs; and

(f) exchanging information between the controller and the source of signals to enable the printing system to operate.

[0011] Multiple embodiments of an adaptive ink delivery system for an existing ink-jet printing system are provided. The adaptive ink delivery systems include ink reservoirs of varying configuration and size that are capable of accommodating a variety of ink use rates. Each adaptive ink delivery system also has an electrical connector and an information storage device which are suitable for the various ink use rates. The information storage device may be an emulation circuit that provides enabling information to the printing system regardless of the actual condition of the ink reservoir.

[0012] The adaptive ink delivery systems allow one to locate the ink reservoir and/or the information storage device remotely from the printing system.

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] Figure 1 is a schematic drawing of a printing system having an original equipment ink delivery system.

[0014] Figure 2 is an isometric view of a printing system utilizing the printing system of Figure 1.

[0015] Figure 3 is an end isometric view of an ink container of the printing system of Figure 1.

[0016] Figure 4 is a side view of the ink container of Figure 3.

[0017] Figure 5 is a partial enlarged proximal end view of the ink container of Figure 3.

[0018] Figure 6 is a sectional side view of the ink container of Figure 3 taken along the line 6-6 of Figure 5.

[0019] Figure 7 is a partial enlarged isometric view of a portion of the printing system of Figure 2, showing the ink container receptacles.

[0020] Figure 8 is an enlarged partial isometric and cut away view of the printing system of Figure 2 taken along the line 8-8 of Figure 7.

[0021] Figure 9 is an enlarged isometric view of an interface portion of the printing system of Figure 2.

[0022] Figure 10A is a partial sectional view of the interface portion of the printing system which is shown in Figure 9 taken along the line 10A-10A of Figure 9 and showing also a partial sectional view of the ink container installed.

[0023] Figure 10B is an enlarged view of the printing system of Figure 10A, taken along the line 10B-10B of Figure 10A.

[0024] Figure 11A is a partially exploded isometric view of the ink container of Figures 10A, 10B, as shown from the distal end.

[0025] Figure 11B is a partially exploded isometric view of the ink container of Figures 10A, 10B, as shown from the proximal end.

[0026] Figure 12 is a further exploded isometric view of the ink container of Figures 10A, 10B.

[0027] Figure 13 is an enlarged side view showing the inductive fluid level sensors for the ink container of Figures 10A, 10B, shown detached from the ink container.

[0028] Figure 14 is a sectional view of the ink container of Figures 10A, 10B, with the proximal cap removed.

[0029] Figure 15 is a side view of a first embodiment of an adaptive ink delivery system not felling under the scope of protection of Claim 1.

[0030] Figure 16 is a side view of another embodiment of an adaptive ink delivery system not felling under the scope of protection of Claim 1.

[0031] Figure 17 is a side view of another embodiment of an adaptive ink delivery system not felling under the scope of protection of Claim 1.

[0032] Figure 18 is a side view of another embodiment of an adaptive ink delivery system not felling under the scope of protection of Claim 1.

[0033] Figure 19 is a side view of another embodiment of an adaptive ink delivery system not felling under the scope of protection of Claim 1.

[0034] Figure 20 is a side view of another embodiment of an adaptive ink delivery system not felling under the scope of protection of Claim 1.

[0035] Figure 21 is an enlarged proximal end view of an ink container not falling under the scope of protection of claim 1, showing another embodiment of the electrical contacts.

[0036] Figure 22 is an enlarged sectional view of the ink container of Figure 21 shown in alignment with the electrical interconnect portion.

BEST MODE FOR CARRYING OUT THE INVENTION

[0037] Although the present invention comprises adapters and methods for altering the volume of ink and the corresponding informational requirements supplied to a printing system, the invention may be more clearly understood with a thorough discussion of the printing system and original equipment ink container.

[0038] Referring to Figure 1, a printing system 10 having an ink container 12, a printhead 14 and a source of pressurized gas, such as a compressor 16, is shown. Compressor 16 is connected to ink container 12 with a conduit 18. A marking fluid 19 such as ink is provided by ink container 12 to printhead 14 by a conduit 20. Ink container 12 includes a fluid reservoir 22 for containing ink 19, an outer shell 24, and a chassis 26. In the preferred embodiment, chassis 26 includes air inlet 28 configured for connection to conduit 18 for pressurizing the outer shell 24 with air. A fluid outlet 30 is also included in the chassis 26. The fluid outlet 30 is configured for connection to the conduit 20 for providing a connection between the fluid reservoir 22 and fluid conduit 20.

[0039] In the preferred embodiment, the fluid reservoir 22 is formed from a flexible material such that pressurization of outer shell 24 produces a pressurized flow of ink from the fluid reservoir 22 through the conduit 20 to the printhead 14. The use of a pressurized source of ink in the fluid reservoir 22 allows for a relatively high fluid flow rate from the fluid reservoir 22 to the printhead 14. The use of high flow rates or high rates of ink delivery to the printhead make it possible for high throughput printing by the printing system 10.

[0040] The ink container 12 also includes a plurality of electrical contacts, as will be discussed in more detail subsequently. The electrical contacts provide electrical connection between the ink container 12 and printing system control electronics or controller 32. The printing system control electronics 32 control various printing system 10 functions such as, but not limited to, printhead 14 activation to dispense ink and activate pump 16 to pressurize the ink container 12. Ink container 12 includes an information storage device 34 and ink volume sensing circuitry 36. In a preferred embodiment, ink volume sensing circuitry 36 includes two circuits 36 as will be described in more detail with respect to Figs. 12 and 13. The information storage device 34 provides information to the printing system control electronics 32 such as ink container 12 volume and ink characteristics. The ink volume sensing circuitry 36 provides signals relating to current ink volume in ink container 12 to the printing system control electronics 32.

[0041] Figure 2 depicts one embodiment of printing system 10 shown in perspective. Printing system 10 includes a printing frame 38 constructed for containing several ink containers 12 simultaneously. The embodiment shown in Figure 2 has four similar ink containers 12. In this embodiment, each ink container contains a different ink color so that four color printing is available including: cyan, yellow, magenta and black ink. Printing system frame 38 has a control panel 40 for controlling operation of printing system 10 and a media slot 42 from which paper is ejected.

[0042] Referring also to Figure 1, as ink 19 in each ink container 12 is exhausted, container 12 is replaced with a new ink container 12 containing a new supply of ink. In addition, ink containers 12 may be removed from the printing system frame 38 for reasons other than an out of ink condition such as changing inks for an application requiring different ink properties or for use on different media. It is important that the replacement ink container 12 form reliable fluidic and electronic connections with the printing system frame 38 so that printing system 10 performs reliably.

[0043] Figures 3 and 4 depict an original equipment ink container 12 having an outer shell 24 which contains the fluid reservoir 22 (Fig. 1) for containing ink 19. Outer shell 24 has a leading cap 50 secured on a leading end and a trailing cap 52 on secured on a trailing end, relative to a direction of insertion for the ink container 12 into the printing system frame 38. Leading cap 50 has an aperture 44 on its leading end through which air inlet 28 and fluid outlet 30 from reservoir 22 (Fig. 1) protrude. Reservoir chassis 26 has an end or base which abuts leading cap 50 so that air inlet 28 and fluid outlet 30 protrude through aperture 44. Aperture 44 is surrounded by a wall 45, placing aperture 44 within a recess. Air inlet 28 and fluid outlet 30 are configured for connection to compressor 16 and printhead 14, respectively, (Fig. 1) once ink container 12 is properly inserted into the printing system frame 38. Air inlet 28 and fluid outlet 30 will be discussed in more detail subsequently.

[0044] Leading cap 50 also has another aperture 46 which is located within the recess defined by a wall 45. The base or end of chassis 26 is also exposed to aperture 46. A plurality of flat electrical contact pads 54 are disposed on reservoir chassis 26 and positioned within aperture 46 for providing electrical connection between circuitry associated with the ink container 12 and printing system control electronics 32. Contact pads 54 are rectangular and located in a straight row. Four of the contact pads 54 are electrically connected to information storage device 34 and four are electrically interconnected to ink volume sensing circuitry 36 as discussed with respect to Figure 1. In a preferred embodiment, information storage device 34 is a semiconductor memory device and the ink volume sensing circuitry 36 comprises an inductive sensing device. Wall 45 helps protect information storage device 34 and contact pads 54 from mechanical damage. In addition, wall 45 helps minimize inadvertent finger contact with contact pads 54. Contact pads 54 will be discussed in more detail with respect to Figure 5.

[0045] In a preferred embodiment, ink container 12 includes one or more keying and guiding features 58 and 60 disposed on opposite sides of leading cap 50 of container 12. Keying and guiding features 58 and 60 protrude outward from sides of container 12 to work in conjunction with corresponding keying and guiding features on the printing system frame 38 (Fig. 2) to assist in aligning and guiding the ink container 12 during insertion of the ink container 12 into the printing system frame 38. Keying and guiding features 58 and 60 also provide a keying function to insure that ink containers 12 having proper ink parameters, such as proper color and ink type, are inserted into a given slot printing system frame 38.

[0046] A latch feature 62 is provided on one side of trailing cap 52. Latch feature 62 works in conjunction with corresponding latching portions on the printing system portion to secure the ink container 12 within the printing system frame 38 so that interconnects such as pressurized air, fluidic and electrical are accomplished in a reliable manner. Latch feature 62 is a molded tang which extends downwardly relative to a gravitational frame of reference. Ink container 12 as shown in Figure 4 is positioned for insertion into a printing system frame 38 (Fig. 2) along the Z-axis of coordinate system 64. In this orientation gravitational forces on the ink container 12 are along the Y-axis.

[0047] Figure 5 depicts an enlarged view of electrical contact pads 54. An upstanding guide member 72 is mounted to chassis 26 adjacent contact pads 54. Electrical contact pads 54 include two pairs of contact pads 78, each pair being electrically connected to one of the volume sensing circuits 36, discussed with respect to Figure 1. The four contact pads 80 spaced between each pair of pads 78 are electrically connected to the information storage device 34. Each pair of volume sensing contact pads 78 is located on an outer side of the row of contact pads 54. Contact pads 78 are part of a flexible circuit 82 (Fig. 13) which is mounted to the chassis 26 by fasteners 84. The four intermediate contacts 80 located between the pairs of volume sensing contacts 78 are metal conductive layers disposed on a nonconductive substrate 86 such as epoxy and fiberglass. Memory device 34 is also mounted on substrate 86 and is connected by conductive traces (not shown) formed in substrate 86. Memory device 34 is shown encapsulated by a protective coating such as epoxy. A backside of substrate 86, opposite contacts 80, is bonded by adhesive or attached to the chassis 26 by fasteners 84.

[0048] It can be seen from Figure 6 that the guide member 72 extends along a Z-axis in coordinate system 64. Guide member 72 has a pointed, tapered distal end. Guide member 72 provides an important guiding function to insure proper electrical connection is accomplished during the insertion of ink container 12 into the printing system frame 38.

[0049] Figure 7 depicts one ink container 12 shown secured within an ink container receptacle or receiving slot 88 of receiving station 89 within the printing system frame 38. Ink container indicia 90 may be positioned proximate each ink container receptacle 88. The ink container indicia 90 may be a color swatch or text indicating ink color to assist the user in color matching for inserting the ink container 12 in the proper slot 88 within the ink container receiving station 89. As discussed previously, the keying and guiding features 58 and 60 shown in Figures 3 and 4 prevent ink containers 12 from being installed in the wrong slot 88. Installation of an ink container 12 in the wrong receptacle 88 can result in improper color mixing or the mixing of inks of different ink types each of which can result in poor print quality.

[0050] Each receiving slot 88 within the ink container receiving station 89 includes keying and guiding slots 92 and latching portions 94. Keying and guiding slots 92 cooperate with the keying and guiding feature 60 (Fig. 3) to guide ink container 12 into the ink container receiving station 88. The keying and guiding slot associated with the keying and guiding feature 58 (Fig. 3) on ink container 12 is not shown. Each latching portion 94 is configured for engaging the corresponding latch feature 62 on the ink container 12. The geometries of keying and guiding slots 92 vary from one receptacle 88 to the other to assure that ink containers containing proper colors and ink compositions are only installed in the proper receiving receptacles.

[0051] Figure 8 shows a single ink container receiving slot 88 within the ink container receiving station 89. Slot 88 includes interconnect portions for interconnecting with the ink container 12. In the preferred embodiment these interconnect portions include a fluid inlet 98, and air outlet 96 and an electrical interconnect portion 100. Each of the interconnects 96, 98, and 100 are positioned on a floating platform 102 which is biased by coil springs 101 (Fig. 10A) along the Z-axis toward the installed ink container 12. Fluid inlet 98 and air outlet 96 are configured for connection with the corresponding fluid outlet 30 and air inlet 28 (Fig. 3), respectively on the ink container 12. The electrical interconnect 100 is configured for engaging electrical contacts 54 on the ink container 12.

[0052] It is the interaction between the keying and guiding features 58 and 60 associated with the ink container 12 and the corresponding keying and guiding slots 92 associated with the ink container receiving station 89 which guide the ink container 12 during the insertion such that proper interconnection is accomplished between the ink container 12 and the printing system frame 38. In addition, sidewalls associated with each slot 88 in the ink container receiving station 89 engage outer surfaces of ink container 12 to assist in guiding and aligning ink container 12 during insertion into slot 88.

[0053] Figures 9 and 10A illustrates further details of the floating platform 102. Platform 102 is spring biased by coil springs 101 in a direction opposite the direction of insertion of the ink container 12 into the ink container receiving slot 88 (Fig. 10A). Platform 102 is biased towards mechanical restraints (not shown) which limit the motion of platform 102 in each of the X, Y, and Z-axes. Therefore, platform 102 has a limited degree of motion in each of the X, Y, and Z-axes of coordinate system 64.

[0054] Electrical connector 100 is supported by and protrudes from platform 102. Electrical connector 100 is generally rectangular, having two lateral sides 107, upper and lower sides, and a distal end 105. A plurality of resilient, spring-biased electrical contacts 104 protrude from end 105. Electrical contacts 104 are thin wire-like members which engage corresponding electrical contacts 54 (Fig. 3) associated with ink container 12 to electrically connect an electronic portion of ink container 12 with the printing system control electronics 32 (Fig. 1). Electrical connector 100 has a guide slot 106 on its upper side. Guide slot 106 has opposed converging walls which cooperate to engage guide member 72 (Figs. 5 and 10B). Guide member 72 engages guide slot 106 to properly align contacts 104 with contact pads 54. Figure 10B shows contact pads 54 properly aligned with electrical contacts 104.

[0055] Referring to Figures 9 and 10A, fluid inlet 98 and air outlet 96 protrude from floating platform 102. Fluid inlet 98 includes an ink supply sleeve 110 surrounding a hollow needle 108. Needle 108 has a port near its distal end. A collar 111 sealingly and slidingly engages needle 108. A spring 113 urges collar 111 toward the distal end, blocking the port. Air outlet 96 includes an air supply sleeve 114 that surrounds a hollow needle 112.

[0056] Referring still to Figure 10A, fluid outlet 30 is an outwardly extending cylindrical member having a septum 122 on its distal end. Septum 122 has a slit for receiving needle 108. In a preferred embodiment, a check valve comprising a ball 124 and spring 126 are located in fluid outlet 30 to prevent outflow of ink needle 108 is inserted. Ball 124 seats against septum 122 and is pushed away from septum 122 by needle 108. Air inlet 28 is also a cylindrical member having a septum 128 with a slit.

[0057] When ink container 12 is releasably inserted into receiving slot 88, keying and guiding features 58 and 60 provide coarse alignment between the ink container and the receiving slot 88, such that the distal end of fluid outlet 30 can properly engage the distal end of ink supply sleeve 110 and such that the distal end of air inlet 28 can properly engage the distal end of air supply sleeve 114. Engagement forces between the distal end of fluid outlet 30 and the ink supply sleeve 110 and between the distal end of air inlet 28 and the air supply sleeve 114 generate a force that causes the floating platform 102 to move into alignment with respect to ink container 12 such that needle 108 can be received by and hence form a fluid connection with fluid outlet 30. This alignment of floating platform 102 also allows needle 112 to be received by and form an air connection with air inlet 28.

[0058] When fluid outlet 30 properly engages fluid inlet 98, the distal end of fluid outlet 30 slides collar 111 from a position wherein it seals the port on hollow needle 108 to a position wherein the port on hollow needle 108 is opened. At the same time, the distal end of fluid outlet 30 receives the hollow needle 108 providing fluid communication between the hollow needle 108 and fluid outlet 30. It is important that fluid outlet 30 is sized properly with the distal end having a proper diameter such that it can be received in ink supply sleeve 110 and the fluid outlet having sufficient length such that it will properly depress collar 111 and receive the port on the hollow needle to allow fluid flow from fluid outlet 30 to hollow needle 108.

[0059] The fluidic and air connections described above provide an intermediate accuracy of alignment between connector 100 and the plurality of contacts 54 associated with ink container 12. This intermediate accuracy is adequate for electrical connection along the y-axis depicted by axes 64 in Fig. 9. However, this coarse alignment is not accurate enough along the x-axis. Electrical connector 100 is mounted to floating platform 102 such that it has a degree of movement along the x-direction. A fine alignment along the x-direction is then provided by at least one guiding member associated with ink container 12 that engages the connector 100. In a preferred embodiment, the at least one guiding member is upstanding member 72 that engages opposed converging walls of electrical connector 100.

[0060] As shown in Figures 11A, 11B and 14, shell 24 is a generally rectangular member with a cylindrical neck 130 on its leading end. Chassis 26 is a circular disk or plug that inserts and seals in neck 130 with the leading side of chassis 26 flush with the rim of neck 130. Reservoir 22 is a collapsible reservoir such as a collapsible bag that fits within shell 24. An opening in reservoir 22 is sealingly joined to chassis 26. Shell 24 is airtight, creating a pressure chamber 132 in the space surrounding reservoir 22. Air inlet 30 leads to pressure chamber 132.

[0061] Referring to Figure 12, rigid stiffener plates 134 are attached to opposite outer sides of reservoir 22. The two inductive ink volume sensor coils 36 are formed on opposite legs of flexible circuit 82. Each of the coils 36 has two leads 138 (Fig. 13) connected to one of the pairs of sensor contacts 78 (Fig. 3). One of the coils 36 is located on one side of reservoir 22 while the other is on the opposite side. When connected to printing system 10, printing system electronics provide a time varying signal to one of the coils 36. This induces a voltage in the other coil 36 whose magnitude varies as the separation distance between coils 36 varies. As ink is used, the opposing side wall portions of reservoir 22 collapse together, changing the electromagnetic coupling or mutual inductance of the coil pair. This change in coupling is sensed by controller 32, which infers an ink level as a result. Additionally, controller 32 also makes a continuity check when ink container 12 is installed by determining if electrical continuity exists between the two contact pads 78 leading to one of the coils 36.

[0062] Each ink container 12 has unique ink container-related aspects that are represented in the form of data provided by information storage device 34. This data is provided from ink container 12 to printing system 10 via memory device 34 automatically without requiring the user to reconfigure printing system 10 for the particular ink container 12 installed. Memory device 34 has a protected section, a write-once section, and a multiple write/erase section. When the cartridge 12 is first installed in printing system 10, controller 32 reads ink container information such as the manufacturer identity, part identification, date code of ink supply, system coefficients, service mode and ink supply size. Printing system 10 energizes one of coils 36 and reads an initial receiving coil voltage from the other (receiving) coil 36. This initial receiving coil voltage from receiving coil 36 is indicative of the full state of ink container 12. The printing system control electronics then record a parameter onto the protected portion of memory device 34 that is indicative of the initial receiving coil voltage. The printing system control electronics then initiate a write protect feature to assure that the information in the protected portion of memory stays the same.

[0063] The write once section is a portion of memory which can be written to by controller 32 only one time. The multiple write/erase section can be written to and erased repeatedly. Both of these sections store information concerning current ink quantity. As will be explained below, the coarse bit information is stored in the write once section and the fine bit data is stored in the multiple write/erase section.

[0064] Upon insertion of ink container 12 into printing system 10, controller 32 reads information from memory device 34 for controlling various printing functions. For example, controller 32 utilizes information from memory device 34 to compute an estimate of remaining ink. If the ink remaining is less than a low ink threshold volume, a message is provided to the user indicating such. Further, when a substantial portion of the ink below the threshold volume is consumed, controller 32 can disable printing system 10 to prevent operation of printhead 14 without a supply of ink. Operating printhead 14 without ink can result in reduction of printhead reliability or catastrophic failure of printhead 14

[0065] In operation, controller 32 reads initial volume information from memory device 34 associated with ink container 12. As ink is used during printing, the ink level is monitored by controller 32, and memory device 34 is updated to contain information relating to remaining ink in ink container 12. Controller 32 thereafter monitors the level of deliverable ink in ink container 12 via memory device 34. In a preferred embodiment, data is transferred between printing system 10 and memory device 34 in serial fashion using a single data line relative to ground.

[0066] In a preferred embodiment, the volume information includes the following: (1) initial supply size data in a write protected portion of memory, (2) coarse ink level data stored in write once portion of memory and (3) fine ink level data stored in a write/erase portion of memory. The initial supply size data is indicative of the amount of deliverable ink initially present in ink container 12.

[0067] The coarse ink level data includes a number of write once bits that each correspond to some fraction of the deliverable ink initially present in ink container 12. In a first preferred embodiment, eight coarse ink level bits each correspond to one-eighth of the deliverable ink initially in ink container 12. In a second preferred embodiment, to be used in the discussion that follows, seven coarse ink level bits each correspond to one-eighth of the deliverable ink initially present in ink container 12 and one coarse ink level bit corresponds to an out-of-ink condition. However, more or less coarse bits can be used, depending on the accuracy desired for a coarse ink level counter.

[0068] The fine ink level data is indicative of a fine bit binary number that is proportional to a fraction of one-eighth of the volume of the deliverable ink initially present in ink container 12. Thus, the entire range of the fine bit binary number is equivalent to one coarse ink level bit as will be explained in more detail below.

[0069] Printing system 10 reads the initial supply size data and calculates the amount or volume of deliverable ink initially present in ink container 12. The drop volume ejected by the printhead 14 is determined by printing system 10 by reading parameters and/or performing calculations. Using the initial volume of deliverable ink in ink container 12 and the estimated drop volume of printhead 14, the printing system 10 calculates the fraction of the initial deliverable ink volume that each drop represents. This enables the printing system 10 to monitor the fraction of the initial volume of deliverable ink remaining in ink container 12.

[0070] While printing, printing system 10 maintains a drop count equal to the number of ink drops that have been ejected by printhead 14. After printing system 10 has printed a small amount, typically one page, it converts the drop count to a number of increments or decrements of the fine bit binary number. This conversion utilizes the fact that the entire range of the fine bit binary number corresponds to one eighth of the initial volume of deliverable ink in ink container 12. Each time the fine bit binary number is fully decremented or incremented, the printing system 10 writes to one of the coarse ink level bits to "latch down" the bit.

[0071] Printing system 10 periodically queries the coarse and fine ink level bits to determine the fraction of the initial deliverable ink that is remaining in ink container 12. Printing system 10 can then provide a "gas gauge" or other indication to a user of printing system 10 that is indicative of the ink level in ink container 12. In a preferred embodiment, the printing system provides a "low ink warning" when the sixth coarse ink level bit is set. Also in a preferred embodiment, the printing system sets the eight (last) coarse ink level bit when the ink container 12 is substantially depleted of ink. This last coarse ink level bit is referred to as an "ink out" bit. Upon querying the coarse ink level bits, the printing system interprets a "latched down" ink out bit as an "ink out" condition for ink container 12.

[0072] The volume is sensed by the inductive sensor coils 36 (Fig. 12) only during a second phase of ink usage. During the first phase, both fine and coarse counters of are used. Ink drops are counted and recorded in the fine counter portion of memory device 34. Each time the fine counter fully increments or decrements, another coarse counter bit will be set. During the second phase, only the ink level sensor coils 36 are used. The voltage output from the receiving coil 36 and is compared with the voltage level indicated by the parameter recorded on memory device 34. A parameter indicative voltage output is recorded on the write/erase portion of memory. Each successive reading is compared with the previous reading as an error checking technique to allow detection of coil malfunction.

[0073] At the start of the third phase, the fine counter is reset and used in the same manner as during the first phase. When the final coarse counter bit is set, an "ink out" warning will be indicated to the printing system. The three-phase arrangement is provided because inductive sensor coils 36 are sufficiently accurate only in the second phase.

[0074] In printing system 10, the transfer of data between printing system 10 and memory device 34 is in serial fashion on the single data line relative to ground. As explained above, while the ink in ink container 12 is being depleted, memory device 34 stores data that is indicative of its initial and current states. Printing system 10 updates memory device 34 to indicate the volume of ink remaining. When most or substantially all of the deliverable ink has been depleted, printing system 10 alters memory device 34 to allow ink container 12 to provide an "ink out" signal. Printing system 10 may respond by stopping printing with ink container 12. At that point, the user will insert a new ink container 12.

[0075] Referring to Figure 15, a first embodiment of an adaptive large volume ink supply 141 ; not falling within the scope of protection of claim 1, for replacing ink container 12 is shown. Ink supply 141 comprises a fluid conduit 143 such as a flexible tube that fluidically connects a fluid outlet 145 on one end of conduit 143 to an ink reservoir 146 on the other end of conduit 143. Conduit 143 allows reservoir 146 to be remotely located from receptacle 88 while fluid outlet 145 is connected to printing system 10. Locating reservoir 146 remotely from receptacle 88 allows reservoir 146 to be sized larger than the space constraints of receptacle 88 would allow. Fluid outlet 145 functions similarly to fluid outlet 30 discussed with respect to Fig. 12. In a preferred embodiment, fluid outlet 145 contains a septum 144 and is sized to connect to fluid inlet 98 (Fig. 10B). Hollow needle 108 pierces septum 144. The opposite end of conduit 143 is secured to ink reservoir 146. In the embodiment shown, air pressure from air outlet 96 is not utilized to force ink from reservoir 146.

[0076] Ink supply 141 also comprises an electrical ink supply circuit 147. Ink supply circuit 147 comprises a flexible electrical cable 149 with an adapter connector 151 on one end. Adapter connector 151 is provided for electrically connecting a signal source 155 to electrical connector 100 of printing system 10. Adapter connector 151 is configured to closely receive at least two opposite sides of electrical interconnect 100 (see also Fig. 9) to retain adapter connector 151. Adapter connector 151 may have a guide member similar to guide member 72 (Figs. 5 and 6) which engages guide slot 106 (Fig. 9).

[0077] Adapter connector 151 has a plurality of flat contact pads 153 arrayed in a row for engaging electrical contacts 104 of connector 100. In a preferred embodiment, number and spacing of contact pads 153 are substantially the same as those described with respect to Figure 5. Even if inductive volume sensing is not employed, preferably at least one pair of contacts would be positioned similar to contacts 78 in Figure 5 and electrically connected together to enable controller 32 (Fig. 1) to perform a continuity check.

[0078] Ink supply circuit 147 is connected to the source of electrical signals 155 for supplying enabling information to printing system 10. A cable 149 enables electrical signal source 155 to be remote from receptacle 88 while adapter connector 151 is in engagement with contacts 104 of printing system 10. Alternatively, signal source 155 may be connected to cable 149 with a pluggable connector (not shown).

[0079] Electrical signal source 155 may be a memory circuit substantially the same as memory circuit 34 (Fig. 3) of the first embodiment. Alternately, signal source 155 may be an emulation device, which is an electronic circuit that functions similar to memory device 34 but may have a substantially different structure. As an emulation device, signal source 155 may exchange substantially the same type of information with printing system 10 (Fig. 1) as memory device 34. For example, as an emulation device, signal source 155 may provide information to controller 32 (Fig. 1) regarding the volume of ink, the type of ink and color when connector 151 is connected to electrical connector 100. These signals may be interpreted by controller 32 to be indicative of the initial ink supply size, the coarse ink level and the fine ink level. Each time the signal indicative of the fine ink level reaches an extreme, the coarse ink level signal may be incremented in signal source 155 in response. Thus an emulation device as signal source 155 may function as a duplicate or near duplicate of memory device 34. Alternatively, signal source 155 may be a signal-providing circuit that merely enables printing system 10 to operate whenever a new ink supply is provided but does not provide information concerning the volume of ink in reservoir 146 during usage.

[0080] In operation, ink supply 141 delivers ink similarly to ink container 12. The large volume ink reservoir 146 is connected to fluid inlet 98 through conduit 143 and fluid outlet 145. The seal of fluid outlet 145 is pierced by needle 108 of fluid inlet 98. Signal source 155 is connected to system connector 100 through ink supply connector 151 and cable 149. Ink is delivered from the ink reservoir while the remaining volume or other ink parameters are communicated to printing system 10 through ink supply circuit 147. Conduit 143 and cable 149 allow reservoir 146 and signal source 155, respectively, to be located remotely from printing system 10.

[0081] Referring to Fig. 16, a second embodiment of an adaptive ink supply 161 for replacing ink container 12 is depicted which is not falling under the scope of protection of claim 1. Ink supply 161 comprises a housing 163 with a leading end and a trailing end relative to a direction of installation of ink supply 161 into receptacle 88 (Fig 8). Housing 163 is sized to be inserted at least partially into receptacle 88 (Fig. 7). Housing 163 includes an opening 165 at the leading end for allowing the establishment of fluidic and air connections between ink supply 161 and the printing system 10. In a preferred embodiment, housing 163 includes keying and aligning features 184 that function similarly to keying and aligning features 58 and 60 discussed with respect to ink container 12.

[0082] A flexible ink reservoir 167 located within a rigid shell 169 is located inside housing 163. An fluid outlet 171 extending from reservoir 167 engages fluid inlet 98 and receives hollow needle 108 therein in a manner similar to that of fluid outlet 30 discussed with respect to ink container 12. In a preferred embodiment, a check valve 172 is located between reservoir 167 and fluid outlet 171 and is opened by needle 108 when the needle pierces a seal or septum 172 in fluid outlet 171. Shell 169 has an air inlet 173 with a septum 174 which connects to air outlet 96 and is pierced by the hollow needle 112 therein for delivering pressurized air from air outlet 96 to the pressure chamber in shell 169 for pressurizing reservoir 167. Fluid outlet 171 and air inlet 173 protrude through opening 165 in housing 163. Preferably, a volume sensing circuit comprising inductive coils is also used similar to that shown in Figure 13.

[0083] In a preferred embodiment, ink supply 161 includes a latching feature 182 that allows ink supply 161 to be secured in receptacle 88 to assure a reliable fluidic, air, and electrical connections between ink supply 161 and printing system 10. In a preferred embodiment, the latching feature is an ink container latch feature 182 that is attached near the trailing end of shell 169 (as illustrated with respect to Fig. 16) or housing 163. Latch feature 182 is positioned on a lower side of ink supply 161 relative to a gravitational frame of reference. Latch feature 182 is positioned to engage latching portion 94 (discussed with respect to Figs. 7 and 8) associated with receptacle 88. Latch feature 182 forms an opening for receiving latching portion 94.

[0084] Ink supply 161 also comprises an electrical ink supply circuit 175. In an exemplary embodiment, ink supply circuit 175 comprises a flexible electrical cable 177 extending from electrical contact pads 179 mounted to a leading end of housing 163. Although not shown, an alignment device similar to guide member 72 (Figs. 5 and 6) may protrude from the leading end of housing 163 to assure proper alignment between contacts pads 179 and contacts 104 that protrude from connector 100. The alignment device generates movement of connector 100 in a direction perpendicular to the direction of insertion of ink supply 161 into printing system 10 in a manner similar to alignment feature 72 discussed with respect to ink container 12. The trailing end of housing 163 is open for allowing shell 169 to slide in and out of housing 163. Ink supply circuit 175 is provided for electrically coupling a source of signals 181 to electrical connector 100 of printing system 10.

[0085] Ink supply circuitry 175 also has the signal source 181 which may be an electrical memory device or an emulator for supplying enabling information to printing system 10. In an exemplary embodiment, signal source 181 is mounted to one side of housing 163. Housing 163 preferably has keying and guiding features 184 for functioning in a similar manner to items 58 and 60 (Fig. 3).

[0086] An alternative embodiment of the system described with respect to Fig. 16 would include a memory device 34 mounted to housing 163 in a manner similar to that discussed with respect to Fig. 5.

[0087] In operation, ink supply 161 operates similarly to ink container 12. The ink reservoir 167 is connected to fluid inlet 98 through fluid outlet 171. Pressure vessel 169 is connected to air outlet 96 through air inlet 173. Signal source 181 is coupled to system connector 100 through ink supply connector contacts 179 and cable 177. A continuity check will be made by controller 32 once housing 169 is installed. Preferably this is made through one pair of volume sensing contacts similar to contacts 78 (Fig. 5) and at least one inductive coil similar to coil 36 shown in Figure 13. Ink is delivered to printing system 10 as pressurized air flows to shell 169 to apply pressure to reservoir 167. The operating parameters of ink supply 161 may be communicated to printing system 10 as described above for ink supply 141.

[0088] When ink supply 161 is releasably installed into receptacle 88 such that fluid, air, and electrical connections are established between ink supply 161 and printing system 10, springs 101 are compressed. Springs 101 exert a force on ink supply 161 that is directed opposite to the direction of installation. If necessary, ink supply 161 includes at least one latching feature 184 to that exerts an opposing force directed along the direction of installation.

[0089] When ink is depleted from reservoir 167, there are several options. Reservoir 167 and shell 169 may be removed from housing 163 and replaced by another reservoir and shell. Alternately, reservoir 167 may be refilled. In both cases, if signal source 181 provides volume information, it will need to be updated in some manner so as to not supply erroneous information to printing system controller 32 (Fig. 1).

[0090] A third embodiment of a disclosed adaptive ink supply is depicted in Figure 17. Ink supply 191 comprises a housing 193 having leading and trailing ends relative to a direction of installation of housing 193 into receptacle 88. Housing 193 includes a fluid outlet 195 secured to and protruding from the leading end. Housing 193 contains an ink conduit 197 that extends from outlet 195 to an ink reservoir (not shown). In an exemplary embodiment, the reservoir (not shown) is remote from housing 193 similar to reservoir 146 in Figure 15. This remote configuration allows the use of ink supplies that would not fit in receptacle 88. Fluid outlet 195 extends laterally from housing 193 and engages fluid inlet 98 in a manner similar to the function of fluid outlet 30 discussed with respect to ink container 12. Ink supply 191 has an electrical ink supply circuit 199 which may be similar to circuit 175 discussed with respect to Fig. 16, having a plurality of contacts such as flat contact pads 200 on a leading end of housing 193 and connected to a signal source 202 by a plurality of conductive leads.

[0091] In a preferred embodiment, ink supply 191 includes a latching feature 196 that allows ink supply 191 to be secured in receptacle 88 to assure a reliable fluidic and electrical connections between ink supply 191 and printing system 10. Latch feature 196 is positioned to engage latching portion 94 associated with receptacle 88. Latch feature extends downwardly from a trailing end of housing 193 relative to a gravitational frame of reference. Other means of providing a latch feature are possible, including surfaces on housing 193 that provide a friction between housing 193 and the sides of receptacle 88.

[0092] In a preferred embodiment, housing 193 also includes keying and aligning features 198 that are preferably similar to the keying and aligning features 58 and 60 discussed with respect to Fig. 3. When housing 193 is releasably inserted into receptacle 88, the keying and aligning features 198 provide coarse alignment between housing 193 and receptacle 88. This allows fluid outlet 195 to properly engage sleeve 110 associated with fluid inlet 98 to allow needle 108 to properly align to and be received by fluid outlet 195. The fluidic connection between needle 108 and fluid outlet 195 provides an intermediate level of alignment accuracy between connector 100 and pads 200. An alignment member such as upstanding member 72 is then used to provide fine alignment between pads 200 and contacts 104. This coarse, intermediate, and fine alignment scheme is similar to that discussed for ink container 12 with respect to Figs. 10A and 10B.

[0093] In operation, when housing 193 is inserted into a receptacle 88 (Fig. 7), fluid outlet 195 connects to fluid inlet 98. Signal source 202 in ink supply connector 199 is coupled to system connector 100 through contact pads 200. In a preferred embodiment, an electrical continuity check is performed as described with respect to Fig. 15. Ink is delivered to printing system 10 through fluid outlet 195. Signal source 202 exchanges information with controller 32 (Fig. 1) as described above.

[0094] When ink supply 191 is releasably installed into receptacle 88 such that fluid and electrical connections are established between ink supply 191 and printing system 10, springs 101 are compressed. Springs 101 exert a force on ink supply 191 that is directed opposite to the direction of installation. If necessary, ink supply 191 includes at least one latching feature 198 to overcome this force, as discussed earlier.

[0095] Figure 18 depicts a fourth embodiment of a disclosed ink delivery system. Ink supply 201 has an ink reservoir 203 with a fluid outlet 205 protruding from one end. Volume sensing circuitry such as coils 36 (Fig. 13) can also be employed on reservoir 203. An electrical ink supply circuit 207 is employed which may be the similar to ink supply circuit 147 of ink supply 141 as described with respect to Figure 15. Ink supply circuit 207 has an electrical connector 209 which connects to a signal source 211. In operation, ink is metered from reservoir 203 as signal source 211 electronically exchanges information with controller 32 of printing system 10 (Fig. 1). Electrical continuity may be checked as described in connection with Figure 15. Electrical signal source 211 may be similar to memory device 34 or it may be an emulator that is functionally equivalent to the memory device 34.

[0096] A fifth embodiment of a disclosed adaptive ink delivery system is shown in Figure 19. Ink supply 211 has an external housing 213 that contains an ink reservoir 215 that has an fluid outlet 216. Housing 213 has an open trailing end for slidingly receiving reservoir 215. An electrical ink supply circuit 217 is mounted to housing 213 and may be the same as ink supply circuit 199, described above in connection with Figure 17. Ink supply circuit 217 has contact pads 218 mounted to a leading end of housing 213 and a signal source 219 mounted to the side of housing 213. Ink supply 211 operates similarly to ink supply 201 as described with respect to Fig. 18.

[0097] An alternative embodiment of the system described with respect to Fig. 19 would include a memory device 34 mounted to housing 213 in a manner similar to that discussed with respect to Fig. 5.

[0098] When ink supply 211 is releasably installed into receptacle 88 such that fluid and electrical connections are established between ink supply 211 and printing system 10, springs 101 are compressed. Springs 101 exert a force on ink supply 191 that is directed opposite to the direction of installation. If necessary, ink supply 211 includes at least one latching feature 220 to overcome this force, such as a latch feature located on the trailing end of housing 213. In a preferred embodiment, ink supply 211 includes keying and aligning features 222 that function similarly to the keying and aligning features 58 and 60 discussed with respect to ink container 12.

[0099] Figure 20 depicts an ink supply 224 that uses a rigid ink reservoir 226. Reservoir 226 has a fluid outlet 228 that is configured similar to the fluid outlets previously described for fluidic connection to fluid inlet 98 (Fig. 19). An ink conduit 230 extends into reservoir 226 and terminates at the bottom with a filter 232. Filter 232 is preferably of a type that will allow the passage of ink into ink tube 230, but block air flow into tube 230. An air inlet 234 is located next to fluid outlet 228 for reception into air outlet 96 (Fig. 19). Air inlet 234 is connected to an air tube 238 that extends into an upper side of reservoir 226. A memory or emulator unit and electrical contact pads 242 are located on a leading edge of reservoir 226. Contact pads 242 are positioned to engage printer electrical connector 100 (Fig. 19). A guide member (not shown) such as guide member 72 (Fig. 5) will be employed.

[0100] In a preferred embodiment, ink supply 224 includes latch feature 244 for engaging latch portion 94 associated with printing system 10. This latch feature would be similar to and function similarly to the latch feature 62 described with respect to Figs. 3-10.

[0101] In a preferred embodiment, ink supply 224 includes keying and aligning features 246 that would be similar to and function similarly to the keying and aligning features 58 and 60 discussed with respect to Figs. 3-10.

[0102] In use, reservoir 226 inserts into receiving slot 88 (Fig. 8), with fluid outlet 228 engaging fluid inlet 98, air inlet 234 engaging air outlet 96, and contact pads 242 engaging electrical connector 100. Air pressure is delivered from the printer compressor 16 (Fig. 1). The air pressure is applied to the interior of reservoir 226 above ink 240. This pressurizes ink 240 that then flows through filter 232 and conduit 230 to the printhead 14 (Fig. 1).

[0103] Each of the foregoing electrical circuits 147, 161, 199, 207 and 217 are preferably provided with an alignment or upstanding guide member similar to guide member 72 (Figures 5 and 6). Guide member 72 is located adjacent to the contact pads of the respective electrical connectors for engaging one of the sides of support member 100 to align the contact pads with those of printing system 10.

[0104] An alternate embodiment for guide member 72 of ink supply connectors 147, 161, 199, 207 and 217 is shown in Figures 21 and 22. A connector 221 having a row of contact pads 223 for engaging contacts 104 of connector 100 is provided with a pair of spaced-apart alignment members 225. One alignment member 225 is located adjacent each of the outermost contact pads 223. Alignment members 225 have inclined surfaces 227 for engaging opposite lateral sides 107 of support member 100 for facilitating the joining of connectors 100 and 221, and the proper alignment of contacts 223 and 104.

[0105] Some ink delivery systems described, such as those described with respect to Figs. 15 and 17 allow for large ink reservoirs that cannot be accommodated in receiving slot 88. This allows users who require high usage to replace the ink containers less frequently. On the other hand, systems such as those described with respect to Figs. 15, 16, 18, and 19, allow the ink reservoir portion of the ink supply to be replaced separately from the electronic portion. If desired for lower use rates, a plurality of relatively small reservoir portions can be utilized for each electronic portion.

[0106] While the invention has been shown or described in only some of its forms, it should be apparent to those skilled in the art that it is not so limited, but is susceptible to various changes without departing from the scope of the invention as defined by the following claims:

Claims

1. An adaptive ink supply for a printing system (10) for use in lieu of a first ink cartridge (12), the printing system (10) having a receptacle (88) for receiving the first ink cartridge (12), the receptacle (88) containing an interconnect platform (102), a printing system electrical connector (100) which protrudes from the platform (102), has at least two sides (107), and has and end (105) containing a plurality of resilient electrical contacts (104) protruding from the end (105), a controller (32) which exchanges information with a first memory device (34) mounted to the first ink cartridge containing information concerning ink in the first ink cartridge (12), an ink supply sleeve (110) protruding from the platform (102) and surrounding a hollow needle (108) fluidically connected to a printhead (14), the adaptive ink supply comprising:

an ink reservoir (22,146,167,203,215,226) containing a replacement ink (19);

a fluid outlet (30,145,171,195,205,216,228) in fluid communication with the ink reservoir which is sized to be received by the ink supply sleeve and to receive the hollow needle to allow ink to flow from the ink reservoir to the printhead;

an adapter connector (147,151,161,199,207,217) including a base having a leading end (50) relative to a direction of engagement of the adapter connector with the printing system connector, a plurality of electrical contact pads (54,153,179,200,218,242,223) mounted to the leading end of the base and spaced side-by-side for engaging the electrical contacts of the printing system electrical connector, the adapter connector having at least one guide member (72) on the leading end of the base which engages at least one of the sides of the printing system electrical connector for moving the interconnect platform from which the printing system electrical connector protrudes so as to align the contact pads into engagement with the electrical contacts (104); and

a source of signals (155,181,202,219) electrically connected to the contact pads (54) of the adapter connector for exchanging information with the controller (32).

2. The ink supply of claim 1, wherein the adapter connector comprises a housing (163,193,213) which is sized to be inserted at least partially into the receptacle, and wherein the contact pads are mounted to the housing.

3. The ink supply of claim 2, wherein the housing has an opening (44) adjacent to the contact pads; and wherein
   the ink reservoir along with the fluid outlet are slidably inserted into the housing, with the fluid outlet protruding through the opening.

4. The ink supply of claim 2, wherein the fluid outlet is secured to the housing; and wherein
   the ink reservoir is located exterior of the housing and connected to the fluid outlet by a conduit (20).

5. The ink supply as claimed in any one of claims 1 to 4, wherein the printing system has an air supply sleeve (96) protruding from the platform and a hollow needle (112) surrounded by the air supply sleeve (96) and leading to an air pressure source (16), and
wherein the ink supply further comprises:

an air inlet (28,173,234) which is sized to connect to the air supply sleeve, the air inlet having a distal end which is adapted to be received by the air supply sleeve and to receive the hollow needle.

6. The ink supply of claim 1 wherein the printing system has an air supply sleeve (96) protruding from the platform and a hollow needle (112) surrounded by the air supply sleeve and leading to an air pressure source (16), and wherein the adapter connector further comprises:

a housing (163,193,213) which is sized to be inserted at least partially into the receptacle, the contact pads being mounted to the housing, the housing having an opening adjacent to the contact pads;

a shell (24,169) surrounding at least a portion of the reservoir, defining an air pressure chamber (132) between the shell and the reservoir;

an air inlet (28,173,234) extending from the shell which is sized to be received by the air supply sleeve and is adapted to receive the hollow needle delivering pressurized air from the hollow needle to the pressure chamber for pressurizing the ink reservoir; and wherein

the shell, the reservoir, the fluid outlet and the air inlet are removably inserted into the housing, with the fluid outlet and air inlet protruding through the opening.

7. The ink supply as claimed in any one of the preceding claims, further comprising a flexible conduit (143) connected between the ink reservoir and the fluid outlet to allow the ink reservoir to be remotely located from the receptacle while the fluid outlet is connected to the ink supply sleeve.

8. The ink supply as claimed in any one of the preceding claims, wherein one of the sides of the printing system electrical connector has a guide slot (106); wherein
   the contact pads arranged along a line to define an x-axis direction;
   the guide member of the adapter connector is positioned to engage the guide slot to provide alignment between the contact pads and the resilient electrical contacts along the x-axis.

9. The ink supply as claimed in any one of claims 1 to 7, wherein the printer electrical connector has opposite lateral sides; wherein
   the contact pads are located in a row defining two outer contacts on opposite ends of the row;
   said at least one guide member includes at least one alignment member (225) for engaging one of the opposite lateral sides.

10. The ink supply as claimed in any one of the preceding claims, wherein the source of signals includes information regarding a volume of replacement ink in the reservoir.

11. The ink supply as claimed in any one of the preceding claims, wherein the source of signals contains a memory device which has a write portion which is adapted to be updated by the controller to provide an estimate during usage of the quantity of replacement ink in the ink reservoir.

12. The ink supply as claimed in any one of the preceding claims, wherein the source of signals is connected to the contact pads on the adapter connector by a flexible cable (149,177) to enable the source of signals to be remotely located from the receptacle while the adapter connector is in engagement with the electrical contacts of the printing system.

13. The ink supply as claimed in claim 1, further comprising:

a flexible conduit (143) connected between the ink reservoir and the fluid outlet to enable the ink reservoir to be remotely located from the receptacle while the fluid outlet is connected to the ink supply sleeve; and

a flexible cable (149,177) between the contact pads on the adapter connector and the sources of signals to enable the source of signals to be remotely located from the receptacle while the adapter connector is in engagement with the printing system electrical connector.

14. The ink supply as claimed in any one of claims 1 to 5, wherein the adapter connector comprises:

a housing (163,193,213) which is sized to be inserted at least partially into the receptacle, the contact pads being mounted to the housing; wherein

the fluid outlet is carried by the housing adjacent to the contact pads; and

a flexible cable (149,177) connects the source of signals to the contact pads to enable the source of signals to be remote from the receptacle while the adapter connector is in engagement with the electrical connector of the printing system.

15. The ink supply as claimed in any one of the preceding claims, wherein the electrical contacts include two pairs of volume sensing contacts (36).

16. The ink supply as claimed in claim 15, wherein the first ink cartridge has a pair of inductive coils (36) for sensing ink quantity therein, each of the inductive coils adapted to be electrically connected to one of the pairs of the volume sensing contacts when the first ink cartridge is installed in the receptacle.

17. The ink supply as claimed in claim 16, wherein a circuit connects at least one of the pairs of the volume sensing contacts (36) to each other for enabling a continuity check to be made by the controller once the adapter connector is connected to the printing system electrical contacts.

18. The ink supply as claimed in claim 17 when dependent on any one of claims 1 to 5, wherein the printing system has an air supply (96) sleeve protruding from the platform and a hollow needle (112) surrounded by the air supply sleeve and leading to an air pressure source (16), and wherein the adapter connector further comprises:

a housing (163,193,213) which is sized to be inserted at least partially into the receptacle, the contact pads being mounted to the housing, the housing having an opening adjacent to the contact pads;

a shell (24,169) surrounding at least a portion of the reservoir, defining an air pressure chamber (132) between the shell and the reservoir;

an air inlet (28,173,234) extending from the shell which is sized to connect to the air supply sleeve, the air inlet having an end which is adapted to be pierced by the needle in the air supply sleeve for delivering pressurized air from the air supply sleeve to the pressure chamber for pressurizing the ink reservoir; and wherein

the shell, the reservoir, the fluid outlet and the air inlet are removably inserted into the housing, with the fluid outlet and air inlet protruding through the opening.

19. The ink supply as claimed in claim 1, wherein the receptacle includes a fluid inlet (98) that includes the hollow needle surrounded by a sliding sealing collar (111), the ink supply sleeve surrounds the sliding collar and the hollow needle, the printing system includes printing system control electronics for controlling printing operations, the ink supply further comprising:

a housing (163,193,213) which is adapted to be at least partially inserted into the receptacle in a first direction, the housing having a leading end;

and wherein the fluid outlet includes a distal end member which is sized to be received by the ink supply sleeve, the distal member is adapted to depress the sliding collar and receive the hollow needle of the fluid inlet for supplying the replacement ink to the printing system; and the ink supply further comprises:

an information storage device (34) coupled to the contact pads for exchanging information with the printing system control electronics; and

a flexible cable (149) which connects the information storage device to the contact pads to enable the information storage device to be located remotely from the receptacle while the contact pads are in engagement with the electrical connector of the printing system.

20. A method for adapting an ink supply to a printing system which is configured to utilize a first ink cartridge (12) which has a first memory device (34) containing data concerning ink in the first ink cartridge, the printing system having an interconnect platform (102) containing a fluid inlet (110) with a hollow needle (108) surrounded by a sliding biased sealing collar (111), a printing system electrical connector (100) which protrudes from the platform, has at least two sides (107), and has an end containing a plurality of protruding resilient electrical contacts protruding from the end, the electrical contacts including two pairs of volume sensing contacts, a controller (32) which exchanges information with the first memory device concerning ink in the first ink cartridge, the first ink cartridge having a pair of inductive coils (36) for sensing ink quantity therein, each of the inductive coils adapted to be electrically connected to one of the pairs of the volume sensing contacts when the first ink cartridge is installed in the receptacle, the method comprising:

(a) providing an adaptive ink supply having an ink reservoir (22,146,167,203,215,226) with a fluid outlet (30,145,171,195,205,216,228), an adapter connector (147,151,161,199,207,217) including a base having a leading end relative to a direction of engagement of the adapter connector with the printing system electrical connector, a plurality of contact pads (54,153,179,200,218,242,223) for engaging the electrical contacts mounted to the leading end of the base and spaced side-by-side for engaging the electrical contacts of the printing system electrical connector, the adapter connector having at least one guide member (58,60) on the leading end of the base for engaging at least one of the sides of the printing system electrical connector, and a source of signals (36,155,181,202,219) which contains electronic information which is readable by the controller to enable the printing system to operate;

(b) coupling the fluid outlet of the ink reservoir to the fluid inlet, depressing the sliding collar with an end of the fluid outlet and inserting the hollow needle of the fluid inlet into the fluid outlet to supply ink from the reservoir;

(c) engaging the adapter connector to the electrical connector of the printing system by moving the interconnect platform from which the printing system electrical connector protrudes so that the contact pads engage the electrical contacts of the printing system electrical connector;

(d) electrically connecting the volume sensing contacts of at least one of the pairs to each other;

(e) performing an electrical continuity check by supplying voltage from the controller to said at least one of the pairs; and

(f) exchanging information between the controller and the source of signals to enable the printing system to operate.

21. The method of claim 20 wherein:

step (a) includes providing the source of signals with a memory which contains information concerning the volume of the ink reservoir and which may be written to; and

step (b) includes by using the controller, reading the volume information and writing to the memory with a new estimate of volume during usage.

22. The method of claim 20, further comprising the step of locating the source of signals remotely from the printing system.

23. The method of claim 20, further comprising the step of locating the ink reservoir remotely from the printing system.

24. The method of claim 20, further comprising the steps of locating the source of signals and the ink reservoir remotely from the printing system.

Revendications

1. Alimentation adaptative en encre pour un système d'impression (10) pour une utilisation à la place d'une première cartouche d'encre (12), le système d'impression (10) possédant un logement (88) pour recevoir la première cartouche d'encre (12), le logement (88) contenant une plate-forme d'interconnexion (102), un connecteur électrique de système d'impression (100) dépassant de la plate-forme (102), possède au moins deux côtés (100) et une extrémité (105) contenant une pluralité de contacts électriques élastiques (104) dépassant de l'extrémité (105), un microprocesseur (32) échangeant une information avec un premier dispositif de mémoire (34) monté sur la première cartouche d'encre, contenant une information concernant l'encre dans la première cartouche d'encre (12), une douille d'alimentation en encre (110) dépassant de la plate-forme (102) et entourant un pointeau creux (108) en connexion par fluide avec une tête d'impression (14), l'alimentation adaptative en encre comprenant :

- un réservoir d'encre (22, 146, 167, 203, 215, 226) contenant une encre de remplacement (19) ;

- une sortie de fluide (30, 145, 171, 195, 205, 216, 228) en communication par fluide avec le réservoir d'encre qui est dimensionné pour être reçu par la douille d'alimentation en encre et pour recevoir le pointeau creux afin de permettre un écoulement de l'encre du réservoir d'encre vers la tête d'impression ;

- un connecteur d'adaptation (147, 151, 161, 199, 207, 217) comprenant une base possédant une extrémité avant (50) par rapport à une direction d'engagement du connecteur d'adaptation avec le connecteur du système d'impression, une pluralité de plots de contact électrique (54, 153, 179, 200, 218, 242, 223) montés sur l'extrémité avant de la base et espacés côte à côte par engagement des contacts électriques du connecteur électrique du système d'impression, le connecteur d'adaptation possédant au moins une pièce de guidage (72) sur l'extrémité avant de la base, engageant au moins un des côtés du connecteur électrique du système d'impression afin de déplacer la plate-forme d'interconnexion de laquelle dépasse le connecteur électrique du système d'impression de façon à aligner les plots de contact en engagement avec les contacts électriques (104) ; et

- une source de signal (155, 181, 202, 219) connectée, de façon électrique, aux plots de contact (54) du connecteur d'adaptation pour échanger une information avec le microprocesseur (32).

2. Alimentation en encre selon la revendication 1, dans laquelle le connecteur d'adaptation comprend une enveloppe (163, 193, 213) qui est dimensionnée pour être insérée au moins partiellement dans le logement et dans laquelle les plots de contact sont montés sur l'enveloppe.

3. Alimentation en encre selon la revendication 2, dans laquelle l'enveloppe possède une ouverture (44) adjacente aux plots de contact, et dans laquelle le réservoir d'encre en conjonction avec la sortie de fluide sont insérés de façon coulissante dans l'enveloppe, la sortie de fluide dépassant par l'ouverture.

4. Alimentation en encre selon la revendication 2, dans laquelle la sortie de fluide est fixée à l'enveloppe, et dans laquelle le réservoir d'encre est situé à l'extérieur de l'enveloppe et est connecté à la sortie de fluide par un conduit (20).

5. Alimentation en encre selon l'une quelconque des revendications 1 à 4, dans laquelle le système d'impression possède une douille d'alimentation en air (96) dépassant de la plate-forme et un pointeau creux (112) entouré par la douille d'alimentation en air (96) et conduisant à une source d'air sous pression (16), et dans laquelle l'alimentation en encre comprend, de plus :

- une admission d'air (28, 173, 234) qui est dimensionnée pour se connecter à la douille d'alimentation en air, l'admission d'air possédant une extrémité distale qui est prévue pour être reçue par la douille d'alimentation en air et pour recevoir le pointeau creux.

6. Alimentation en encre selon la revendication 1, dans laquelle le système d'impression possède une douille d'alimentation en air (96) dépassant de la plate-forme et un pointeau creux (112) entouré par la douille d'alimentation en air et conduisant à une source d'air sous pression (16), et dans laquelle le connecteur d'adaptation comprend, de plus :

- une enveloppe (163, 193, 213) qui est dimensionnée pour être insérée au moins partiellement dans le logement, les plots de contact étant montés sur l'enveloppe, l'enveloppe possédant une ouverture adjacente aux plots de contact ;

- une coque (24, 169) entourant au moins une partie du réservoir, définissant une chambre d'air sous pression (132) entre la coque et le réservoir ;

- une admission d'air (28, 173, 234) s'étendant de la coque qui est dimensionnée pour être reçue par la douille d'alimentation en air et pour recevoir le pointeau creux délivrant l'air sous pression à partir du pointeau creux vers la chambre de pression pour mettre sous pression le réservoir d'encre ; et

   dans laquelle la coque, le réservoir, la sortie de fluide et l'admission d'air sont insérés, de façon amovible, dans l'enveloppe, la sortie de fluide et l'admission d'air dépassant de l'ouverture.

7. Alimentation en encre selon l'une quelconque des revendications précédentes, comprenant, de plus, un conduit flexible (143) connecté entre le réservoir d'encre et la sortie de fluide pour permettre au réservoir d'encre d'être placé à distance du logement tandis que la sortie de fluide est connectée à la douille d'alimentation en encre.

8. Alimentation en encre selon l'une quelconque des revendications précédentes, dans laquelle un des côtés du connecteur électrique du système d'impression possède une fente de guidage (106), dans laquelle :

- les plots de contact sont agencés selon une ligne pour définir une direction d'axe x ;

- la pièce de guidage du connecteur d'adaptation est positionnée pour engager la fente de guidage afin d'assurer l'alignement entres les plots de contact et les contacts électriques élastiques le long de l'axe x.

9. Alimentation en encre selon l'une quelconque des revendications 1 à 7, dans laquelle le connecteur électrique d'imprimante possède des côtés latéraux opposés, dans laquelle :

- les plots de contact sont situés sur une rangée définissant deux contacts externes aux extrémités opposées de la rangée ;

- ladite au moins une pièce de guidage comprend au moins une pièce d'alignement (225) pour engager un des côtés latéraux opposés.

10. Alimentation en encre selon l'une quelconque des revendications précédentes, dans laquelle la source des signaux comprend une information concernant un volume d'encre de recharge dans le réservoir.

11. Alimentation en encre selon l'une quelconque des revendications précédentes, dans laquelle la source des signaux comprend un dispositif de mémoire possédant une partie d'écriture qui est prévue pour être mise à jour par le microprocesseur pour fournir une estimation lors de l'utilisation de la quantité d'encre de recharge dans le réservoir d'encre.

12. Alimentation en encre selon l'une quelconque des revendications précédentes, dans laquelle la source des signaux est connectée aux plots de contact sur le connecteur d'adaptation par un câble flexible (149, 177) pour permettre à la source des signaux d'être placée à distance du logement tandis que le connecteur d'adaptation est en engagement avec les contacts électriques du système d'impression.

13. Alimentation en encre selon la revendication 1, comprenant, de plus :

- un conduit flexible (143) connecté entre le réservoir d'encre et la sortie de fluide pour permettre au réservoir d'encre d'être placé à distance du logement tandis que la sortie de fluide est connectée à la douille d'alimentation en encre ; et

- un câble flexible (149, 177) entre les plots de contact sur le connecteur d'adaptation et la source des signaux pour permettre à la source des signaux d'être placée à distance du logement tandis que le connecteur d'adaptation est en engagement avec le connecteur électrique du système d'impression.

14. Alimentation en encre selon l'une quelconque des revendications 1 à 5, dans laquelle le connecteur d'adaptation comprend :

- une enveloppe (163, 193, 213) qui est dimensionnée pour être insérée au moins partiellement dans le logement, les plots de contact étant montés sur l'enveloppe ;

   dans laquelle :

- la sortie de fluide est porté par l'enveloppe adjacente aux plots de contact ; et

- un câble flexible (149, 177) connecte la source des signaux aux plots de contact pour permettre à la source des signaux d'être éloignée du logement tandis que le connecteur d'adaptation est en engagement avec le connecteur électrique du système d'impression.

15. Alimentation en encre selon l'une quelconque des revendications précédentes, dans laquelle les contacts électriques comprennent deux paires de contacts de détection de volume (36).

16. Alimentation en encre selon la revendication 15, dans laquelle la première cartouche d'encre possède une paire de bobines d'induction (36) pour y détecter la quantité d'encre, chacune des bobines d'induction étant prévue pour être connectée, de façon électrique, à un des paires de contacts de détection de volume lorsque la première cartouche d'encre est installée dans le logement.

17. Alimentation en encre selon la revendication 16, dans laquelle un circuit connecte au moins un des paires de contacts de détection de volume (36) l'un à l'autre pour permettre qu'un contrôle en continu soit effectué par le microprocesseur une fois que le connecteur d'adaptation est connecté aux contacts électriques du système d'impression.

18. Alimentation en encre selon la revendication 17, lorsque dépendante de l'une quelconque des revendications 1 à 5, dans laquelle le système d'impression possède une douille d'alimentation en air (96) dépassant de la plate-forme et un pointeau creux (112) entouré par la douille d'alimentation en air et conduisant à une source d'air sous pression (16), et dans laquelle le connecteur d'adaptation comprend, de plus :

- une enveloppe (163, 193, 213) qui est dimensionnée pour être insérée au moins partiellement dans le logement, les plots de contact étant montés sur l'enveloppe, l'enveloppe possédant une ouverture adjacente aux plots de contact ;

- une coque (24, 169) entourant au moins une partie du réservoir, définissant une chambre d'air sous pression (132) entre la coque et le réservoir ;

- une admission d'air (28, 173, 234) s'étendant de la coque qui est dimensionnée pour être connectée à la douille d'alimentation en air, l'admission d'air possédant une extrémité qui est prévue pour être perforée par le pointeau dans la douille d'alimentation en air afin de délivrer de l'air sous pression à partir de la douille d'alimentation en air vers la chambre de pression pour mettre sous pression le réservoir d'encre ; et

   dans laquelle la coque, le réservoir, la sortie de fluide et l'admission d'air sont insérés, de façon amovible, dans l'enveloppe, la sortie de fluide et l'admission d'air dépassant de l'ouverture.

19. Alimentation en encre selon la revendication 1, dans laquelle le logement comprend une entrée de fluide (98) comprenant le pointeau creux entouré par un collier coulissant d'étanchéité (111), la douille d'alimentation en encre entoure le collier coulissant et le pointeau creux, le système d'impression comprend un circuit électronique de commande de système d'impression pour commander les opérations d'impression, l'alimentation en encre comprenant, de plus :

- une enveloppe (163, 193, 213) qui est prévue pour être au moins partiellement insérée dans le logement selon une première direction, le logement possédant une extrémité avant ; et

   dans laquelle la sortie de fluide comprend une pièce d'extrémité distale qui est dimensionnée pour être reçue par la douille d'alimentation en encre, la pièce distale est prévue pour enfoncer le collier coulissant et pour recevoir le pointeau creux de l'entrée de fluide afin de fournir l'encre de recharge au système d'impression ; et
   l'alimentation en encre comprend, de plus :

- un dispositif de stockage d'information (34) couplé aux plots de contact pour échanger une information avec le circuit électronique de commande du système d'impression ; et

- un câble flexible (149) connectant le dispositif de stockage d'information aux plots de contact pour permettre au dispositif de stockage d'information d'être placé à distance du logement tandis que les plots de contact sont en engagement avec le connecteur électrique du système d'impression.

20. Procédé d'adaptation d'une alimentation en encre à un système d'impression qui est configuré pour utiliser une première cartouche d'encre (12) possédant un premier dispositif de mémoire (34) contenant des données concernant l'encre dans la première cartouche d'encre, le système d'impression possédant une plate-forme d'interconnexion (102) contenant une entrée de fluide (110) avec un pointeau creux (108) entouré d'un collier coulissant d'étanchéité à ressort (111), un connecteur électrique de système d'impression (100) dépassant de la plate-forme possède au moins deux côtés (107) et une extrémité contenant une pluralité de contacts électriques élastiques en relief dépassant de l'extrémité, les contacts électriques comprenant deux paires de contacts de détection de volume, un microprocesseur (32) échangeant une information avec le premier dispositif de mémoire concernant l'encre dans la première cartouche d'encre, la première cartouche d'encre possédant une paire de bobines d'induction (36) pour y détecter la quantité d'encre, chacune des bobines d'induction étant prévue pour être connectée, de façon électrique, à un des paires de contacts de détection de volume lorsque la première cartouche d'encre est installée dans le logement, procédé comprenant :

a) la constitution d'une alimentation en encre adaptative possédant un réservoir d'encre (22, 146, 167, 203, 215, 226) avec une sortie de fluide (30, 145, 171, 195, 205, 216, 228), un connecteur d'adaptation (147, 151, 161, 199, 207, 217) comprenant une base possédant une extrémité avant par rapport à une direction d'engagement du connecteur d'adaptation avec le connecteur électrique du système d'impression, une pluralité de plots de contact (54, 153, 179, 200, 218, 242, 223) pour engager les contacts électriques montés sur l'extrémité avant de la base et espacés côte à côte pour engager les contacts électriques du connecteur électrique du système d'impression, le connecteur d'adaptation possédant au moins une pièce de guidage (58, 60) sur l'extrémité avant de la base pour engager au moins un des côtés du connecteur électrique du système d'impression, et une source de signaux (36, 155, 181, 202, 219) contenant une information électronique pouvant être lue par le microprocesseur pour permettre au système d'impression de fonctionner ;

b) le couplage de la sortie de fluide du réservoir d'encre à l'entrée de fluide, l'enfoncement du collier coulissant avec une extrémité de la sortie de fluide et l'insertion du pointeau creux de l'entrée de fluide dans la sortie de fluide pour fournir de l'encre du réservoir ;

c) l'engagement du connecteur d'adaptation avec le connecteur électrique du système d'impression par déplacement de la plate-forme d'interconnexion à partir de laquelle dépasse le connecteur électrique du système d'impression de telle façon que les plots de contact engagent les contacts électriques du connecteur électrique du système d'impression ;

d) la connexion électrique des contacts de détection de volume d'au moins une des paires l'un avec l'autre ;

e) l'application d'un contrôle électrique en continu en fournissant une tension à partir du microprocesseur à ladite au moins une des paires ; et

f) l'échange d'une information entre le microprocesseur et la source de signaux pour permettre au système d'impression de fonctionner.

21. Procédé selon la revendication 20, selon lequel :

- l'étape a) comprend la fourniture à la source de signaux d'une mémoire contenant une information concernant le volume du réservoir d'encre et pouvant être inscriptible ; et

- l'étape b) comprend la lecture, à l'aide du microprocesseur, de l'information de volume et l'écriture en mémoire avec une nouvelle estimation du volume en utilisation.

22. Procédé selon la revendication 20, comprenant, de plus, une étape de placement de la source de signaux à distance du système d'impression.

23. Procédé selon la revendication 20, comprenant, de plus, une étape de placement du réservoir d'encre à distance du système d'impression.

24. Procédé selon la revendication 20, comprenant, de plus, des étapes de placement de la source de signaux et du réservoir d'encre à distance du système d'impression.

Ansprüche

1. Ein adaptiver Tintenvorrat für ein Drucksystem (10) zur Verwendung anstelle einer ersten Tintenkassette (12), wobei das Drucksystem (10) eine Aufnahmevorrichtung (88) zum Aufnehmen der ersten Tintenkassette (12), wobei die Aufnahmevorrichtung (88) eine Verbindungsplattform (102) enthält, einen elektrischen Drucksystemverbinder (100), der von der Plattform (102) vorsteht, zumindest zwei Seiten (107) aufweist und ein Ende (105) aufweist, das eine Mehrzahl von elastischen elektrischen Kontakten (104) aufweist, die von dem Ende (105) vorstehen, eine Steuerung (32), die Informationen mit einer ersten Speichervorrichtung (34) austauscht, die an der ersten Tintenkassette befestigt ist und Informationen enthält, die die Tinte in der ersten Tintenkassette (12) betreffen und eine Tintenvorratshülse (110), die von der Plattform (102) vorsteht und eine hohle Nadel (108) umgibt, die mit einem Druckkopf (14) fluidmäßig verbunden ist, aufweist, wobei der adaptive Tintenvorrat folgende Merkmale aufweist:

ein Tintenreservoir (22, 146, 167, 203, 215, 226), das eine Ersatztinte (19) enthält;

einen Fluidauslaß (30, 145, 171, 195, 205, 216, 228) in Fluidkommunikation mit dem Tintenreservoir, der dimensioniert ist, um durch die Tintenvorratshülse aufgenommen zu werden und um die hohle Nadel aufzunehmen, um zu ermöglichen, daß Tinte von dem Tintenreservoir zu dem Druckkopf fließt;

einen Adapterverbinder (147, 151, 161, 199, 207, 217), der eine Basis umfaßt, die ein vorderes Ende (50) relativ zu einer Richtung der Ineingriffnahme des Adapterverbinders mit dem Drucksystemverbinder und eine Mehrzahl von elektrischen Kontaktanschlußflächen (54, 153, 179, 200, 218, 242, 223) aufweist, die an dem vorderen Ende der Basis befestigt und Seite an Seite beabstandet sind zum Ineingriffnehmen der elektrischen Kontakte des elektrischen Drucksystemverbinders, wobei der Adapterverbinder zumindest ein Führungsbauglied (72) an dem vorderen Ende der Basis aufweist, das zumindest eine der Seiten des elektrischen Drucksystemverbinders zum Bewegen der Verbindungsplattform in Eingriff nimmt, von der der elektrische Drucksystemverbinder vorsteht, um die Kontaktanschlußflächen in Eingriff mit den elektrischen Kontakten (104) auszurichten; und

eine Signalquelle (155, 181, 202, 219), die elektrisch mit den Kontaktanschlußflächen (54) des Adapterverbinders verbunden ist, zum Austauschen von Informationen mit der Steuerung (32).

2. Der Tintenvorrat gemäß Anspruch 1, bei dem der Adapterverbinder ein Gehäuse (163, 193, 213) aufweist, das dimensioniert ist, um zumindest teilweise in die Aufnahmevorrichtung eingeführt zu werden, und bei dem die Kontaktanschlußflächen an dem Gehäuse befestigt sind.

3. Der Tintenvorrat gemäß Anspruch 2, bei dem das Gehäuse eine Öffnung (44) benachbart zu den Kontaktanschlußflächen aufweist; und
bei dem das Tintenreservoir zusammen mit dem Fluidauslaß gleitbar in das Gehäuse einfügbar ist, wobei der Fluidauslaß durch die Öffnung vorsteht.

4. Der Tintenvorrat gemäß Anspruch 2, bei dem der Fluidauslaß an dem Gehäuse befestigt ist; und bei dem das Tintenreservoir außerhalb des Gehäuses positioniert und mit dem Fluidauslaß durch eine Leitung (20) verbunden ist.

5. Der Tintenvorrat gemäß einem der Ansprüche 1 bis 4, bei dem das Drucksystem eine Luftvorratshülse (96), die von der Plattform vorsteht, und eine hohle Nadel (112) aufweist, die von der Luftvorratshülse (96) umgeben ist und zu einer Luftdruckquelle (16) führt, und wobei der Tintenvorrat ferner folgendes Merkmal aufweist:

einen Lufteinlaß (28, 173, 234), der dimensioniert ist, um mit der Luftvorratshülse verbunden zu sein,

wobei der Lufteinlaß ein distales Ende aufweist, das angepaßt ist, um durch die Luftvorratshülse aufgenommen zu werden und um die hohle Nadel aufzunehmen.

6. Der Tintenvorrat gemäß Anspruch 1, bei dem das Drucksystem eine Luftvorratshülse (96), die von der Plattform vorsteht, und eine hohle Nadel (112) aufweist, die durch die Luftvorratshülse umgeben ist und zu einer Luftdruckquelle (16) führt, und wobei der Adapterverbinder ferner folgende Merkmale aufweist:

ein Gehäuse (163, 193, 213), das dimensioniert ist, um zumindest teilweise in die Aufnahmevorrichtung eingeführt zu werden, wobei die Kontaktanschlußflächen an dem Gehäuse befestigt sind, wobei das Gehäuse eine Öffnung benachbart zu den Kontaktanschlußflächen aufweist;

eine Hülle (24, 169), die zumindest einen Abschnitt des Reservoirs umgibt, was eine Luftdruckkammer (132) zwischen der Hülle und dem Reservoir definiert;

einen Lufteinlaß (28, 173, 234), der sich von der Hülle erstreckt dimensioniert ist, um durch die Luftvorratshülse aufgenommen zu werden, und angepaßt ist, um die hohle Nadel aufzunehmen, die zum Unterdrucksetzen des Tintenreservoirs unter Druck gesetzte Luft von der hohlen Nadel zu der Druckkammer liefert; und

wobei die Hülle, das Reservoir, der Fluidauslaß und der Lufteinlaß entnehmbar in das Gehäuse eingefügt sind, wobei der Fluidauslaß und der Lufteinlaß durch die Öffnung vorstehen.

7. Der Tintenvorrat gemäß einem der vorangehenden Ansprüche, der ferner eine flexible Leitung (143) aufweist, die zwischen das Tintenreservoir und den Fluidauslaß geschaltet ist, um zu ermöglichen, daß das Tintenreservoir entfernt von der Aufnahmevorrichtung positioniert ist, während der Fluidauslaß mit der Tintenvorratshülse verbunden ist.

8. Der Tintenvorrat gemäß einem der vorangehenden Ansprüche, bei dem eine der Seiten des elektrischen Drucksystemverbinders einen Führungsschlitz (106) aufweist; wobei
die Kontaktanschlußflächen entlang einer Linie angeordnet sind, um eine x-Achsen-Richtung zu definieren;
das Führungsbauglied des Adapterverbinders positioniert ist, um den Führungsschlitz in Eingriff zu nehmen, um eine Ausrichtung zwischen den Kontaktanschlußflächen und den elastischen elektrischen Kontakten entlang der x-Achse bereitzustellen.

9. Der Tintenvorrat gemäß einem der Ansprüche 1 bis 7, bei dem der elektrische Druckerverbinder gegenüberliegende seitliche Seiten aufweist; wobei
die Kontaktanschlußflächen in einer Reihe positioniert sind, die zwei äußere Kontakte an gegenüberliegenden Enden der Reihe definiert;
wobei das zumindest eine Führungsbauglied zumindest ein Ausrichtungsbauglied (225) zum Ineingriffnehmen von einer der gegenüberliegenden seitlichen Seiten umfaßt.

10. Der Tintenvorrat gemäß einem der vorangehenden Ansprüche, bei dem die Signalquelle Informationen betreffend ein Ersatztintenvolumen in dem Reservoir umfaßt.

11. Der Tintenvorrat gemäß einem der vorangehenden Ansprüche, bei dem die Signalquelle eine Speichervorrichtung enthält, die einen Schreibabschnitt aufweist, der angepaßt ist, um durch die Steuerung aktualisiert zu werden, um während der Verwendung eine Schätzung der Ersatztintenmenge in dem Tintenreservoir zu liefern.

12. Der Tintenvorrat gemäß einem der vorangehenden Ansprüche, bei dem die Signalquelle mit den Kontaktanschlußflächen an dem Adapterverbinder durch ein flexibles Kabel (149, 177) verbunden ist, um zu ermöglichen, daß die Signalquelle entfernt von der Aufnahmevorrichtung positioniert ist, während der Adapterverbinder in Eingriff mit den elektrischen Kontakten des Drucksystems steht.

13. Der Tintenvorrat wie beansprucht in Anspruch 1, der ferner folgende Merkmale aufweist:

eine flexible Leitung (143), die zwischen das Tintenreservoir und den Fluidauslaß geschaltet ist, um es dem Tintenreservoir zu ermöglichen, entfernt von der Aufnahmevorrichtung positioniert zu sein, während der Fluidauslaß mit der Tintenvorratshülse verbunden ist; und

ein flexibles Kabel (149, 177) zwischen den Kontaktanschlußflächen an dem Adapterverbinder und der Signalquelle, um zu ermöglichen, daß die Signalquelle entfernt von der Aufnahmevorrichtung positioniert ist, während der Adapterverbinder in Eingriff mit dem elektrischen Drucksystemverbinder steht.

14. Der Tintenvorrat gemäß einem der Ansprüche 1 bis 5, bei dem der Adapterverbinder folgende Merkmale aufweist:

ein Gehäuse (163, 192, 213), das dimensioniert ist, um zumindest teilweise in die Aufnahmevorrichtung eingefügt zu werden, wobei die Kontaktanschlußflächen an dem Gehäuse befestigt sind; wobei der Fluidauslaß durch das Gehäuse benachbart zu den Kontaktanschlußflächen getragen wird; und

ein flexibles Kabel (149, 177) die Signalquelle mit den Kontaktanschlußflächen verbindet, um es der Signalquelle zu ermöglichen, entfernt von der Aufnahmevorrichtung zu sein, während der Adapterverbinder mit dem elektrischen Verbinder des Drucksystems in Eingriff steht.

15. Der Tintenvorrat gemäß einem der vorangehenden Ansprüche, bei dem die elektrischen Kontakte zwei Paare von Volumenerfassungskontakten (36) umfassen.

16. Der Tintenvorrat gemäß Anspruch 15, bei dem die erste Tintenkassette ein Paar von induktiven Spulen (36) zum Erfassen einer Tintenmenge in derselben aufweist, wobei jede der induktiven Spulen angepaßt ist, um elektrisch mit einem der Paare der Volumenerfassungskontakte verbunden zu sein, wenn die erste Tintenkassette in der Aufnahmevorrichtung installiert ist.

17. Der Tintenvorrat gemäß Anspruch 16, bei dem eine Schaltung zumindest eines der Paare der Volumenerfassungskontakte (36) miteinander verbindet, um zu ermöglichen, daß eine die Steuerung Kontinuitätsprüfung durchführt, sobald der Adapterverbinder mit den elektrischen Drucksystemkontakten verbunden ist.

18. Der Tintenvorrat gemäß Anspruch 17, falls derselbe von einem der Ansprüche 1 bis 5 abhängig ist, bei dem das Drucksystem eine Luftvorratshülse (96) aufweist, die von der Plattform vorsteht, und eine hohle Nadel (112), die von der Luftvorratshülse umgeben ist und zu einer Luftdruckquelle (16) führt, und wobei der Adapterverbinder ferner folgende Merkmale aufweist:

ein Gehäuse (163, 193, 213), das dimensioniert ist, um zumindest teilweise in die Aufnahmevorrichtung eingefügt zu werden, wobei die Kontaktanschlußflächen an dem Gehäuse befestigt sind, wobei das Gehäuse eine Öffnung benachbart zu den Kontaktanschlußflächen aufweist;

eine Hülle (24, 169), die zumindest einen Abschnitt des Reservoirs umgibt, was eine Luftdruckkammer (132) zwischen der Hülle und dem Reservoir definiert;

einen Lufteinlaß (28, 173, 234), der sich von der Hülle erstreckt, die dimensioniert ist, um mit der Luftvorratshülse verbunden zu sein, wobei der Lufteinlaß ein Ende aufweist, das angepaßt ist, um durch die Nadel in der Luftvorratshülse durchstochen zu werden, zum Liefern von Druckluft von der Luftvorratshülse zu der Druckkammer zum Unterdrucksetzen des Tintenreservoirs; und

wobei die Hülle, das Reservoir, der Fluidauslaß und der Lufteinlaß entnehmbar in das Gehäuse eingefügt sind, wobei der Fluidauslaß und der Lufteinlaß durch die Öffnung hervorstehen.

19. Der Tintenvorrat beansprucht in Anspruch 1, bei dem die Aufnahmevorrichtung einen Fluideinlaß (98) umfaßt, der die hohle Nadel umfaßt, die durch eine Gleitabdichtungsmanschette (111) umgeben ist, wobei die Tintenvorratshülse die Gleitmanschette und die hohle Nadel umgibt, wobei das Drucksystem eine Drucksystemsteuerungselektronik zum Steuern von Druckoperationen umfaßt, wobei der Tintenvorrat ferner folgende Merkmale aufweist:

ein Gehäuse (163, 193, 213), das angepaßt ist, um zumindest teilweise in die Aufnahmevorrichtung in einer ersten Richtung eingeführt zu werden, wobei das Gehäuse ein vorderes Ende aufweist;

und wobei der Fluidauslaß ein Distalendenbauglied umfaßt, das dimensioniert ist, um durch die Tintenvorratshülse aufgenommen zu werden, wobei das distale Bauglied angepaßt ist, um die Gleitmanschette niederzudrücken und die hohle Nadel des Fluideinlasses zum Liefern der Ersatztinte zu dem Drucksystem aufzunehmen; und wobei der Tintenvorrat ferner folgende Merkmale aufweist:

eine Informationsspeicherungsvorrichtung (34), die mit den Kontaktanschlußflächen zum Austauschen von Informationen mit der Drucksystemsteuerungselektronik gekoppelt ist; und

ein flexibles Kabel (149), das die Informationsspeicherungsvorrichtung mit den Kontaktanschlußflächen verbindet, um zu ermöglichen, daß die Informationsspeicherungsvorrichtung entfernt von der Aufnahmevorrichtung positioniert ist, wobei die Kontaktanschlußflächen in Eingriff mit dem elektrischen Verbinder des Drucksystems stehen.

20. Ein Verfahren zum Anpassen eines Tintenvorrats an ein Drucksystem, das konfiguriert ist, um eine erste Tintenkassette (12) zu verwenden, die eine erste Speichervorrichtung (34), die Daten enthält, die die Tinte in der ersten Tintenkassette betreffen, wobei das Drucksystem eine Verbindungsplattform (102), die einen Fluideinlaß (110) mit einer hohlen Nadel (108) enthält, die von einer vorgespannten Gleitabdichtmanschette (111) umgeben ist, einen elektrischen Drucksystemverbinder (100), der von der Plattform vorsteht, zumindest zwei Seiten (107) aufweist und ein Ende aufweist, das eine Mehrzahl von vorstehenden, elastischen elektrischen Kontakten enthält, die von dem Ende vorstehen, wobei die elektrischen Kontakte zwei Paare von Volumenerfassungskontakten umfassen, und eine Steuerung (32) aufweist, die Informationen mit der ersten Speichervorrichtung austauscht, die die Tinte in der ersten Tintenkassette betreffen, wobei die erste Tintenkassette ein Paar von induktiven Spulen (36) zum Erfassen der Tintenmenge in derselben aufweist, wobei jede der induktiven Spulen angepaßt ist, um elektrisch mit einem der Paare der Volumenerfassungskontakte verbunden zu sein, wenn die erste Tintenkassette in der Aufnahmevorrichtung installiert ist, wobei das Verfahren folgende Schritte aufweist:

(a) Bereitstellen eines adaptiven Tintenvorrats, der ein Tintenreservoir (22, 146, 167, 203, 215, 226) mit einem Fluidauslaß (30, 145, 171, 195, 205, 216, 228), einen Adapterverbinder (147, 151, 161, 199, 207, 217), der eine Basis umfaßt, die ein vorderes Ende relativ zu einer Richtung der Ineingriffnahme des Adapterverbinders mit dem elektrischen Drucksystemverbinder, eine Mehrzahl von Kontaktanschlußflächen (54, 153, 179, 200, 218, 242, 223) zum Ineingriffnehmen der elektrischen Kontakte, die an dem vorderen Ende der Basis befestigt und Seite an Seite zum Ineingriffnehmen der elektrischen Kontakte des elektrischen Drucksystemverbinders beabstandet sind, wobei der Adapterverbinder zumindest ein Führungsbauglied (58, 60) an dem vorderen Ende der Basis zum Ineingriffnehmen von zumindest einer der Seiten des elektrischen Drucksystemverbinders aufweist, und eine Signalquelle (36, 155, 181, 202, 219) aufweist, die elektrische Informationen enthält, die durch die Steuerung lesbar sind, um es dem Drucksystem zu ermöglichen, zu arbeiten;

(b) Koppeln des Fluidauslasses des Tintenreservoirs mit dem Fluideinlaß, Niederdrücken der Gleitmanschette mit einem Ende des Fluidauslasses und Einfügen der hohlen Nadel des Fluideinlasses in den Fluidauslaß, um Tinte von dem Reservoir zu liefern;

(c) Ineingriffnehmen des Adapterverbinders mit dem elektrischen Verbinder des Drucksystems durch Bewegen der Verbindungsplattform, von der der elektrische Drucksystemverbinder hervorsteht, so daß die Kontaktanschlußflächen die elektrischen Kontakte des elektrischen Drucksystemverbinders in Eingriff nehmen;

(d) elektrisches Verbinden der Volumenerfassungskontakte von zumindest einem der Paare miteinander;

(e) Durchführen einer elektrischen Kontinuitätsprüfung durch Liefern einer Spannung von der Steuerung zu zumindest einem der Paare; und

(f) Austauschen von Informationen zwischen der Steuerung und der Signalquelle, um es dem Drucksystem zu ermöglichen, zu arbeiten.

21. Das Verfahren gemäß Anspruch 20, bei dem:

der Schritt (a) das Bereitstellen der Signalquelle mit einem Speicher umfaßt, der Informationen betreffend das Volumen des Tintenreservoirs enthält und wobei in denselben geschrieben werden kann; und

der Schritt (b) das Lesen der Volumeninformationen und das Schreiben in den Speicher durch Verwenden der Steuerung aufweist, mit einer neuen Volumenschätzung während der Verwendung.

22. Das Verfahren gemäß Anspruch 20, das ferner den Schritt des Lokalisierens der Signalquelle entfernt von dem Drucksystem aufweist.

23. Das Verfahren gemäß Anspruch 20, das ferner den Schritt des Lokalisierens des Tintenreservoirs entfernt von dem Drucksystem aufweist.

24. Das Verfahren gemäß Anspruch 20, das ferner die Schritte des Lokalisierens der Signalquelle und des Tintenreservoirs entfernt von dem Drucksystem aufweist.

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