巴西专利BR112015012291B1 fluid ejection device with integrated ink level sensor

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专利摘要:
FLUID EJECTION DEVICE WITH INTEGRATED INK LEVEL SENSOR. In one embodiment, a fluid ejection device includes a slit of ink formed in a printhead array. The fluid ejection device also includes an ink level sensor integrated in the printhead (PILS) for detecting an ink level from a chamber in fluid communication with the slit, and a cleaning resistor circuit arranged in the chamber for cleaning the ink chamber.
公开号:BR112015012291B1
申请号:R112015012291-4
申请日:2012-11-30
公开日:2021-01-26
发明作者:Ning Ge；Joseph M. Torgerson；Patrick Leonard
申请人:Hewlett-Packard Development Company, L.P.；
IPC主号:

专利说明:

BACKGROUND
[0001] Accurate ink level detection in ink supply reservoirs for many types of inkjet printers is desirable for a number of reasons. For example, detecting the correct ink level and providing a corresponding indication of the amount of ink left in an ink cartridge allows printer users to prepare for replacing finished ink cartridges. Accurate ink level indications also help prevent ink waste, as inaccurate ink level indications often result in premature replacement of ink cartridges that still contain ink. In addition, printer systems can use ink level detection to trigger certain actions that help prevent low quality prints that could result from inadequate supply levels.
[0002] Although there are several techniques available for determining the level of ink in a reservoir, or fluid chamber, several challenges may remain related to its accuracy and cost. BRIEF DESCRIPTION OF THE DRAWINGS
[0003] The present modalities will now be described by way of example with reference to the associated drawings, in which:
[0004] figure 1a shows a belt jet printing system suitable for incorporating a fluid ejection device comprising an ink level sensor integrated in the printhead (PILS) and a cleaning resistor circuit, as shown here, according to a modality;
[0005] Figure 1b shows a perspective view of an example inkjet cartridge that includes an inkjet printhead assembly, an ink supply assembly and a reservoir, according to an embodiment;
[0006] figures 2a, 2b and 2c show a bottom view of a TIJ printhead that has a single fluid gap formed in a matrix / silicon substrate, according to modalities;
[0007] figure 3 shows a cross-sectional view of an example fluid drop generator, according to an embodiment;
[0008] figure 4 shows a cross-sectional view of an example detection structure, according to an embodiment;
[0009] figure 5 shows a diagram of synchronism of non-overlapping clock signals used to drive a printhead, according to a modality;
[0010] figure 6 shows an example ink level sensor circuit according to an embodiment;
[0011] figure 7 shows a cross-sectional view of an example detection structure with a detection capacitor and an intrinsic parasitic capacitance, according to a modality;
[0012] figure 8 shows a cross-sectional view of an example detection structure that includes a parasitic elimination element, according to one embodiment;
[0013] figure 9 shows an example ink level sensor circuit with a parasitic elimination circuit, according to an embodiment;
[0014] Figure 10 shows an example PILS ink level sensor circuit with a parasitic elimination circuit, a cleaning resistor circuit and an offset register, according to one modality;
[0015] figure 11 shows an example of a shift register that addresses multiple PILS signals, according to one modality;
[0016] figures 12 and 13 show flowcharts of example methods related to the detection of an ink level with an ink level sensor integrated in the printhead (PILS) of a fluid ejection device, according to modalities. DETAILED DESCRIPTION Overview
[0017] As mentioned above, there are a number of techniques available for determining the level of a fluid, such as paint, in a reservoir or other fluidic chamber. For example, prisms have been used to reflect or refract laser beams in ink cartridges to generate electrical and / or visible ink level indications per user. Back pressure indicators are another way of determining ink levels in a reservoir. Some printing systems count the number of ink drops ejected from inkjet print cartridges as a way of determining ink levels. Still other techniques use the electrical conductivity of the ink as an ink level indicator in printing systems. The challenges remain, however, with regard to improving the accuracy and cost of ink level detection systems and techniques.
[0018] The modalities of the present exhibition improve previous ink level sensors and detection techniques, generally through a fluid ejection device (ie a printhead), which includes an integrated ink level sensor printhead (PILS). PILS employs a capacitive load sharing detection circuit together with a cleaning resistor circuit for purging ink residue from the sensor chamber. One or more PILS and cleaning resistor circuits are integrated embedded in a thermal inkjet printhead (TIJ) array. The detection circuit implements a sampling and maintenance technique that captures the state of the ink level through a capacitive sensor. The capacitance of the capacitive sensor changes with the ink level. A load placed on the capacitive sensor is shared between the capacitive sensor and a reference capacitor, causing a reference voltage at the port of an evaluation transistor. A current source in a printer application specific integrated circuit (ASIC) supplies current in the transistor drain. The ASIC measures the resulting voltage at the current source, and calculates the drain resistance to the corresponding source of the evaluation transistor. The ASIC then determines the status of the ink level based on the resistance determined from the evaluation transistor. In an implementation, accuracy is improved through the use of multiple PILS integrated into a printhead matrix. A shift register serves as a selective circuit to address multiple PILS, and allows the ASIC to measure multiple voltages and determine ink level status based on measurements taken at various locations in the printhead matrix.
[0019] In an example embodiment, a fluid ejection device includes a slit of ink formed in a printhead matrix, and a printhead-integrated ink level sensor (PILS) for level detection of ink from a chamber in fluid communication with the slit. The fluid ejection device includes a cleaning resistor circuit arranged in the chamber for cleaning the ink chamber. In one implementation, the fluid ejection device includes multiple PILS for detecting ink levels in multiple chambers in fluid communication with the slit, and a displacement recorder for selecting between multiple PILS for extraction to a common ID line.
[0020] In another modality, a medium that can be read in a processor stores a code representing instructions that, when executed by a processor, cause the processor to activate a cleaning resistor circuit to purge ink from an ink chamber. detection, apply a pre-charge voltage Vp to a detection capacitor in the chamber to charge the detection capacitor with a charge Q1. The charge Q1 is shared between the detection capacitor and a reference capacitor, causing a reference voltage Vg at the port of an evaluation transistor. A resistance is determined from the drain to the source of the evaluation transistor, which results from Vg. In an implementation, a delay can be provided after an activation of the cleaning resistor circuit to allow the ink from a fluid slit to flow back into the detection chamber, before applying the preload voltage Vp.
[0021] In another mode, a medium that can be read in a processor stores a code representing instructions that, when executed by a processor, cause the processor to start the operation of multiple PILS (ink level sensors integrated in the print head). for the detection of an ink level in multiple areas of a fluid ejection device. A displacement recorder in the fluid ejection device is controlled for multiplexing outputs from multiple PILS on a common ID line. Illustrative Modalities
[0022] Figure 1a illustrates an inkjet printing system 100 suitable for incorporating a fluid ejection device comprising an ink level sensor integrated in the printhead (PILS) and a cleaning resistor circuit as exposed here, according to an exhibition mode. In this embodiment, a fluid ejection device is implemented as a fluid drop blasting printhead 114. The inkjet printing system 100 includes an inkjet printhead assembly 102, a supply set ink assembly 104, a mounting assembly 106, a media transport assembly 108, an electronic controller 110, and at least one power supply 112 that provides power for the various electrical components of the inkjet printing system 100. The inkjet printhead assembly 102 includes at least one fluid ejection assembly 114 (printhead 114) that ejects drops of ink through a plurality of nozzles or nozzles 116 towards the print media 118. The media The printing press 118 can be any type of suitable sheet or roll material, such as paper, cardboard, transparencies, polyester, plywood, foam board, fabric, canvas, and the like. Nozzles 116 are typically arranged in one or more columns or arrangements, so that an appropriately sequenced ejection of ink from nozzles 116 causes characters, symbols and / or other graphic items or images to be printed on print media 118, as the inkjet printhead assembly 102 and print media 118 are moved relative to each other.
[0023] The ink supply set 104 supplies fluid ink to the inkjet printhead assembly 102 and includes a reservoir 120 for ink storage. In one implementation, 102, ink supply set 104 and reservoir 120 are housed together in a replaceable device, such as an integrated inkjet printhead cartridge 103, as shown in figure 1b. Figure 1b shows a perspective view of an example inkjet cartridge 103 that includes inkjet printhead assembly 102, ink supply assembly 104 and reservoir 120, according to an embodiment of exhibition. In addition to one or more printheads 114, the inkjet cartridge 103 includes electrical contacts 105 and an ink supply chamber (or other fluid) 107. In some implementations, cartridge 103 may have a supply chamber 107 that it stores an ink color, and in other implementations it can have several chambers 107 that each store a different ink color. Electrical contacts 105 carry electrical signals to and from controller 110, for example, to cause ink droplets to eject through nozzles 116 and make ink level measurements.
[0024] In general, ink flows from reservoir 120 to inkjet printhead assembly 102, ink supply assembly 104 and 102 can form a one-way ink delivery system or an ink delivery system with recirculation. In a one-way ink delivery system, substantially all of the ink supplied to the inkjet printhead assembly 102 is consumed during printing. In a recirculating ink delivery system, however, only a portion of the ink supplied to the inkjet printhead assembly 102 is consumed during printing. Ink not consumed during printing is returned to ink supply set 104. Ink supply set reservoir 120 can be removed, replaced and / or replenished.
[0025] In one implementation, the ink supply set 104 supplies ink under positive pressure through an ink conditioning set 111 to the inkjet printhead set 102 via an interface connection, such as a supply tube. The ink supply set 104 includes, for example, a reservoir, pumps and pressure regulators. Conditioning in ink conditioning set 111 may include filtration, preheating, pressure surge absorption and degassing. The ink is sucked under negative pressure from the inkjet printhead assembly 102 to the ink supply assembly 104. The pressure difference between the input and output of the inkjet printhead assembly 102 is selected to obtain the correct back pressure at nozzles 116, and it is usually a negative pressure between 1 ”negative and 10” negative H2O (-0.24884 and -2.4884).
[0026] Mounting set 106 positions inkjet printhead assembly 102 with respect to media transport set 108, and media carrying set 108 positions print media 118 relative to head assembly ink jet print 102. Thus, a print zone 122 is defined adjacent to nozzles 116 in an area between the ink jet printhead assembly 102 and the print media 118. In one implementation, the print set inkjet printhead 102 is a scan-type printhead set. As such, mounting assembly 106 includes a cart for moving inkjet printhead assembly 102 relative to media transport assembly 108 for scanning media 118. In another implementation, the printhead assembly Inkjet print cartridge 102 is a non-scan type printhead assembly. As such, the mounting set 106 secures the inkjet printhead assembly 102 in a prescribed position with respect to the media transport set 108. Thus, the media transport set 108 positions the print media 118 in with respect to the inkjet printhead assembly 102.
[0027] Electronic controller 110 typically includes a processor (CPU) 138, memory 140, firmware, software and other electronics for communicating with and controlling inkjet printhead assembly 102, assembly assembly 106 and media transport set 108. Memory 140 may include volatile (i.e., RAM) and non-volatile (for example, a ROM, a hard disk, a floppy disk, a CD-ROM, etc.) memory components. ) comprising means that can be read on a computer / processor that provide the storage of instructions coded on a computer / executable on a processor, data structures, program modules and other data for the inkjet printing system 100. The electronic controller 110 receives data 124 from a central system, such as a computer, and temporarily stores data 124 in a memory. Typically, data 124 is sent to the inkjet printing system 100 along an electronic, infrared, optical or other information transfer path. The data 124 represents, for example, a document and / or a file to be printed. As such, data 124 forms a print service for inkjet printing system 100 and includes one or more print service commands and / or command parameters.
[0028] In one embodiment, electronic controller 110 controls inkjet printhead assembly 102 for ejecting ink droplets from nozzles 116. Thus, electronic controller 110 defines a pattern of ejected ink droplets that form characters , symbols and / or other graphic items or images on print media 118. The pattern of ejected ink drops is determined by the print service commands and / or command parameters from data 124. In another implementation, the controller Electronic 110 includes an application specific lower head assembly (ASIC) of printer 126 for determining the ink level in the fluid ejection device / printhead 114, based on the resistance values of one or more pressure level sensors. ink integrated into the printhead, PILS 206 (figure 2), integrated into the printhead / substrate matrix 202 (figure 2). Printer ASIC 126 includes a current source 130 and an analog to digital converter (ADC) 132. ASIC 126 can convert the voltage present at current source 130 to determine a resistance, and then determine a resistance value corresponding digital via ADC 132. A programmable algorithm implemented through executable instructions on a resistance detection module 128 in memory 140 allows the determination of resistance and the subsequent digital conversion through ADC 132. In another implementation, memory 140 of Electronic controller 110 includes an ink cleaning module 134 that comprises instructions executable by a controller processor 138 for activating a cleaning resistor circuit in the printhead 114 to purge ink and / or ink residue out of a printing chamber. PILS. In another implementation, where the printhead 114 comprises multiple PILS, the electronic controller memory 140 includes a PILS selection module 136 executable by a controller processor 138 for controlling an offset register for selecting PILS to be used for detecting ink levels.
[0029] In the described modalities, the electronic controller 110 is a thermal drop inkjet printing system on demand with a thermal inkjet printhead (TIJ) 114 (fluid ejection device) suitable for the implementation of an ink level sensor integrated in the printhead (PILS), as exposed here. In one implementation, the inkjet printhead assembly 102 includes a single TIJ printhead 114. In another implementation, the inkjet printhead assembly 102 includes a wide array of inkjet printheads. TIJ 114. While the manufacturing processes associated with TIJ printheads are well suited for PILS integration, other types of printheads such as a piezoelectric printhead can also be implemented, such as an ink level sensor. Thus, the exposed PILS is not limited to implementation on a TIJ 114 printhead.
[0030] Figure 2 (figures 2a, 2b, 2c) shows a bottom view of a printhead 114 having a single fluid gap 200 formed in a silicon / substrate matrix 202, according to the modalities of the exposure. Various components integrated in the silicon matrix / substrate 202 include fluid drop generators 300, one or more ink level sensors integrated in the printhead (PILS) 206 and related circuits, and a shift register 218 to allow for a multiplexed selection of individual PILS, as discussed in greater detail below. Although the printhead 114 is shown with a single fluid slot 200, the principles discussed here are not limited in its application to a printhead with only a 200 slot. Instead, other printhead configurations are also possible , such as printheads with two or more ink slits. In the TIJ 114 printhead, the matrix / substrate 202 underlies a chamber layer having layers of fluid 204 and a nozzle layer having nozzles 116 formed there, as discussed below with respect to figure 3. However for purposes In the illustration, the chamber layer and the nozzle layer in figure 2 are assumed to be transparent, so as to show the underlying substrate 202. Therefore, the chambers 204 in figure 2 are illustrated using dashed lines.
[0031] Fluid slit 200 is an elongated slit formed on substrate 202 that is in fluid communication with a fluid supply (not shown), such as a fluid reservoir 120. Fluid slit 200 has multiple drop generators of fluid 300 arranged along both sides of the slot, as well as one or more PILS 206 located towards the slot ends along either side of the slot. For example, in one implementation, there are four PILS 206 per slot 200, each PILS 206 usually located near one of the four corners of slot 200, towards the ends of slot 200, as shown in figure 2a. In other implementations, there may be other numbers of PILS 206 per slot, such as two PILS 206 per slot, or one PILS 206 per slot 200, as shown in figures 2b and 2c, respectively. Although each PILS 206 is typically located near an end corner of a slot 200, as shown in figure 2, this is not intended as a limitation on the other possible locations of a PILS 206. Thus, PILS 206 can be located around of a slot 200 in other areas, such as midway between the ends of the slot. In some embodiments, a PILS 206 may even be located at one end of the slot 200, so that it extends outwardly from the end of the slot, rather than from the side edge of the slot. However, as shown in figure 2, for PILS 206 generally located near the end corners of a slot 200, it may be advantageous to maintain a certain safe distance “d” 203 between the plate detection capacitor (Csense) 212 and the end from the slot 200. Maintaining a safe distance “d” 203 helps to ensure that there is no signal degradation from the detection capacitor (Csense) 212 due to the reduced fluid flow potential that can be found at the ends of the slots 200. In one implementation, a safe distance "d" 203 to maintain between the plate detection capacitor (Csense) 212 and the end of the slot 200 is from 40 microns to around 50 microns.
[0032] Figure 3 shows a cross-sectional view of a fluid drop generator 300, according to an exposure mode. Each drop generator 300 includes a nozzle 116, a fluid chamber 204 and a firing element 302 disposed in fluid chamber 204. Nozzles 116 are formed in the nozzle layer 310 and are generally arranged to form nozzle columns around along the sides of the fluid gap 200. The firing element 302 is a thermal resistor formed by a metal plate (eg, tantalum-aluminum, TaAl) in a 304 insulation layer (eg, polysilicon glass, PSG ) on a top surface of the silicon substrate 202. A passivation layer 306 over the trigger element 302 protects the ink trigger element in chamber 204 and acts as a mechanical passivation barrier or cavitation protection structure to absorb the shock of steam bubbles collapsing. A chamber layer 308 has walls and chambers 204 that separate substrate 202 from nozzle layer 310.
[0033] During an operation, a drop of fluid is ejected from a chamber 204 through a corresponding nozzle 116, and the chamber 204 is then replenished with a fluid circulating from the fluid slot 200. More specifically, a stream electrical current is passed through a resistor firing element 302 resulting in rapid heating of the element. A thin layer of fluid adjacent to the passivation layer 306 on the firing element 302 is overheated and vaporizes, creating a vapor bubble in the corresponding firing chamber 204. The rapidly expanding vapor bubble forces a drop of fluid out of the corresponding nozzle 116.
[0034] Figure 4 shows a cross-sectional view of a portion of an example PILS 206, according to an exhibition mode. Referring now to both Figures 2 and 4, a PILS 206 generally includes a detection structure 208, a sensor circuit 210 and a cleaning resistor circuit 214, integrated in the matrix / substrate 202 of the printhead 114 The detection structure 208 of PILS 206 is generally configured in the same way as a drop generator 300, but includes a cleaning resistor circuit 214 and a ground 216 for the ground provision for the detection capacitor (Csense) 212 through of the substance (eg ink, ink-air, air) in the PILS 204 chamber. Therefore, as a typical drop generator 300, the detection structure 208 includes a nozzle 116, a fluid chamber 204, a conductive element, such as a metal plate element 302 disposed in the fluid / ink chamber 204, a passivation layer 306 over the plate element 302, and an insulation layer 304 (for example, polysilicon glass, PSG) on a surface of top of silicon substrate 202. Co However, as discussed above, a PILS 206 generally employs a current source 130 and an analog to digital converter (ADC) 132 from a printer ASIC 126 that is not integrated into the printhead 114. Instead, the Printer ASIC 126 is located, for example, on the printer cart or electronic controller 110 of the printer system 100.
[0035] In the detection structure 208, a detection capacitor (Csense) 212 is formed by the metal plate element 302, the passivation layer 306 and the substance or contents of the camera 204. The sensor circuit 210 incorporates the capacitor detection (Csense) 212 from within the detection structure 208. The value of the detection capacitor 212 changes as the substance in chamber 204 changes. The substance in chamber 204 can be all paint, paint and air or just air. Thus, the value of detection capacitor 212 changes with the ink level in chamber 204. When ink is present in chamber 204, detection capacitor 212 has good conductance to ground 216, so that the capacitance value is the highest (that is, 100%). However, when there is no ink in chamber 204 (i.e., air only), the capacitance of the detection capacitor 212 drops to a very small value, which ideally is close to zero. When the chamber contains ink and air, the capacitance value of the detection capacitor 212 is sometimes between zero and 100%. Using the change value of detection capacitor 212, the ink level sensor circuit 210 allows a determination of the ink level. In general, the ink level in chamber 204 is indicative of the ink level in reservoir 120 of printer system 100.
[0036] In some implementations, a cleaning resistor circuit 214 is used for purging ink and / or ink residue from chamber 204 of the PILS 208 detection structure, for measuring the ink level with the sensor 210. Thereafter, to the extent that an ink is present in reservoir 120, it flows back into the chamber to allow an accurate ink level measurement. As shown in figure 2, in one implementation, a cleaning resistor circuit 214 includes four cleaning resistors surrounding the metal plate element 302 of detection capacitor (Csense) 212. Each cleaning resistor is adjacent to one of the four sides of the metal plate element 302 of the detection capacitor (Csense) 212. The cleaning resistors comprise thermal resistors formed, for example, from tantalum aluminum or TaAl, as discussed above, which provides rapid heating of the paint for creation of steam bubbles that force the ink out of the PILS 204 chamber. The cleaning resistor circuit 214 purges ink from the 204 chamber, and removes residual ink from the metal plate element 302 of the detection capacitor (Csense) 212 The ink flowing back into the PILS 204 chamber from slot 200 then allows for more accurate detection of the ink level through the detection capacitor (Csense) 212. In some implementations, a delay can occur r provided by controller 110, after activating the cleaning resistor circuit 214 for the provision of time for ink from slot 200 to flow back into the PILS chamber, before detecting the ink level in the PILS chamber . While the cleaning resistor circuit 214 having four resistors surrounding the detection capacitor (Csense) 212 has an advantage of providing significant ink cleaning of the detection capacitor 212 and the PILS 204 chamber, other cleaning resistor configurations also are contemplated, which can provide cleaning up to a lesser or greater degree. For example, a cleaning resistor circuit 214 with a line resistor configuration is shown in PILS 206 on the bottom left of figure 2. In this resistor circuit 214, the cleaning resistors are in line with each other, adjacent to the edge back of the metal plate element 302 of the detection capacitor (Csense) 212 on the rear side of the PILS 204 chamber away from the slot 200.
[0037] Figure 5 shows an example of a partial timing diagram 500 that has non-overlapping clock signals (S1 to S4) with synchronized data and trigger signals that can be used to drive a printhead 114, from according to an exhibition mode. The clock signals in the timing diagram 500 are also used to trigger the operation of the PILS 210 ink level sensor circuit and shift register 218, as discussed below.
[0038] Figure 6 is an ink level sensor circuit of example 210 of a PILS 206, according to an exhibition mode. In general, sensor circuit 210 employs a load sharing mechanism for determining different levels of ink in a PILS 204 chamber. Sensor circuit 210 includes two first transistors, T1 (T1a, T1b), configured as switches. With reference to figures 5 and 6, during an operation of the sensor circuit 210, in a first stage, a clock pulse S1 is used to close the transistor switches T1a and T1b, coupling the memory nodes M1 and M2 to the ground, and discharging detection capacitor 212 and reference capacitor 600. A reference capacitor 600 is the capacitance between node M2 and ground. In this modality, the reference capacitor 600 is implemented as the inherent gate capacitance of the T4 evaluation transistor, and is illustrated, therefore, using dashed lines. The reference capacitor 600 additionally includes an associated parasitic capacitance, such as a source port overlapping capacitance, but the T4 port capacitance is the dominant capacitance in the 600 reference capacitor. Using the T4 transistor port capacitance as a capacitor reference 600 reduces the number of components in sensor circuit 210 by avoiding a specific reference capacitor manufacturing between node M2 and ground. However, in other modalities, it may be beneficial to adjust the value of the reference capacitor 600 by including a specific capacitor made from M2 for grounding (that is, in addition to the inherent port capacitance of T4).
[0039] In a second step, the clock pulse S1 ends, opening the switches T1a and T1b. Directly after switches T1 open, a clock pulse S2 is used to close transistor switch T2. Closing T2 couples the M1 node to a pre-charge voltage Vp (for example, on the order of +15 Volts), and a charge Q1 is placed through the detection capacitor 212 according to the equation, Q1 = (Csense) ( Vp). At this point, node M2 remains at a zero voltage potential, since the clock pulse S3 is switched off. In a third step, the clock pulse S2 ends, opening the transistor switch T2. Directly after switch T2 opens, clock pulse S3 closes transistor switch T3, coupling nodes M1 and M2 to each other, and sharing the load Q1 between detection capacitor 212 and reference capacitor 600. The load shared Q1 between detection capacitor 212 and reference capacitor 600 results in a reference voltage Vg at node M2, which is also at the port of the evaluation transistor T4, according to the following equation:
[0040] Vg remains in M2, until another cycle begins with a clock pulse S1 grounding the memory nodes M1 and M2. Vg in M2 connects the evaluation transistor T4, which allows a measurement in ID 602 (the transistor drain T4). In this modality, it is assumed that the transistor T4 is polarized in a linear mode of operation, where T4 acts as a resistor, whose value is proportional to the gate voltage Vg (that is, a reference voltage). The T4 resistance from drain to source (coupled to ground) is determined by forcing a small current in ID 602 (ie, a current of the order of 1 milliamp). ID 602 is coupled to a current source, such as current source 130, in printer ASIC 126. By applying the current source to ID, the voltage (VID) is measured in ID 602 by ASIC 126. One firmware, such as the Rsense 128 module running on controller 110 or ASIC 126 can convert VID into a drain Rds resistor to the source of transistor T4, using the current in ID 602 and VID. ADC 132 in printer ASIC 126 subsequently determines a corresponding digital value for the Rds resistance. The resistance Rds allows an inference as to the value of Vg, based on the characteristics of the transistor T4. Based on a value for Vg, a Csense value can be found from the equation for Vg shown above. An ink level can then be determined based on the Csense value.
[0041] Once the Rds resistance is determined, there are several ways in which the ink level can be found. For example, the measured Rds value can be compared with a reference value for Rds, or a table of experimentally determined Rds values to be associated with specific ink levels. Without ink (that is, a “dry” signal), or a very low ink level, the detection capacitor 212 value is very low. This results in a very low Vg (on the order of 1.7 Volts), and the evaluation transistor T4 is switched off or almost off (ie, T4 is in the cut or sub-limit operation region). Therefore, the Rds resistance of ID to ground via T4 would be very high (for example, with an ID current of 1.2 mA, Rds is typically above 12 kOhm). Conversely, with a high ink level (ie, a “wet” signal), the detection capacitor 212 value is close to 100% of its value, resulting in a high value for Vg (on the order of 3.5 Volts). Therefore, the Rds resistance is low. For example, with a high ink level, Rds is below 1 kOhm, and is typically a few hundred Ohms.
[0042] Figure 7 shows a cross-sectional view of an example 208 PILS detection structure that illustrates detection capacitor 212 and an intrinsic parasitic capacitance CPp (700) below metal plate 302 that forms part of the capacitor of detection 212, according to an exposure mode. The intrinsic parasitic capacitance CPp 700 is formed by the metal flap 302, the layer and insulation 304 and the substrate 302. As described above, a PILS 206 determines an ink level based on the capacitance value of detection capacitor 212. However, when a voltage (i.e., Vp) is applied to the metal plate 302, carrying the detection capacitor 212, the Cp1 700 capacitor also charges. Because of this, the parasitic capacitance Cp1 700 can contribute in the order of 20% of the capacitance determined for the detection capacitor 212. This percentage can vary, depending on the thickness of the insulation layer 304 and the dielectric constant of the insulation material. However, the remaining charge at the Cp1 700 parasitic capacitance in a “dry” state (that is, when no ink is present) is sufficient to activate the T4 evaluation transistor. The parasitic capacitance Cp1 700, therefore, dilutes the dry / wet signal.
[0043] Figure 8 shows a cross-sectional view of an example detection structure 208, which includes a parasitic elimination element 800, according to an embodiment of the exposure. The parasitic elimination element is a conductive layer 800, such as a polysilicon layer designed to eliminate the impact of the parasitic capacitance Cp1 700. In this design, when a voltage (ie, Vp) is applied to the metal plate 302, it it is also applied to the conductive layer 800. This prevents a charge from developing on the Cp1 700, so that the Cp1 is effectively removed / isolated from the determination of the capacitance of the detection capacitor 212. Cp2, element 802, is the intrinsic capacitance from of the parasitic elimination element 800 (conductive multi-layer 800). The Cp2 802 slows down the loading speed of the parasitic elimination element 800, but has no impact on the removal / isolation of the Cp1 700, as there is sufficient charging time provided for the element 800.
[0044] Figure 9 shows a PILS ink level sensor circuit of example 210 with a parasitic elimination circuit 900, according to an exposure mode. In figure 9, the parasitic capacitance Cp1 700 is shown coupled between the metal plate 302 (node M1) and the conductive layer 800 (node Mp). With reference to figures 8 and 9, the ink level sensor circuit 210 with the parasitic elimination circuit 900 are triggered by non-overlapping clock signals, such as those shown in the timing diagram 500 in figure 5. In a first step, a clock pulse S1 is used to close the transistor switches T1a, T1b and Tp1. Closing the switches T1a, T1b and Tp1 connects memory nodes M1, M2 and Mp to ground, unloading the detection capacitor (Csense) 212, the reference capacitor (Cref) 600 and the parasitic capacitor (Cp1) 700. In in a second step, the clock pulse S1 ends, opening the switches T1a, T1b and Tp1. Directly, after switches T1a, T1b and Tp1 open, a clock pulse S2 is used to close transistor switches T2 and Tp2. Closing T2 and Tp2 couples nodes M1 and Mp, respectively, to a preload voltage Vp. This puts a charge Q1 through the detection capacitor (Csense) 212. However, with nodes M1 and Mp at the same potential voltage Vp, no charge develops through the parasitic capacitor (Cp1) 700.
[0045] The ink level sensor circuit 210 then continues to function, as described above with respect to figure 6. Thus, in a third step, the clock pulse S2 ends, opening the transistor switches T2 and Tp2. Directly after the switches T2 and Tp2 open, the clock pulse S3 closes the transistor switches T3 and Tp3. Closing switch T3 connects nodes M1 and M2 to each other, and shares the load Q1 between the detection capacitor 212 and the reference capacitor 600. The load Q1 shared between the detection capacitor 212 and the reference capacitor 600 results at a reference voltage Vg, at node M2, which is also at the gate of the evaluation transistor T4. Closing the Tp3 switch couples the parasitic capacitor (Cp1) 700 to the ground. During the clock pulse S3, the parasitic charge at Cp1 700 is discharged, leaving only the detection capacitor 212 to be evaluated with the evaluation transistor T4. Once the effect of the parasitic capacitor (Cp1) 700 is removed, for a dry signal, there is a very small parasitic contribution to activate T4.
[0046] Figure 10 shows an example 210 PILS ink level sensor circuit with a parasitic elimination circuit 900, the cleaning resistor circuit 214 and the displacement register 218, according to an exposure mode. As mentioned above, the cleaning resistor circuit 214 can be activated to purge ink and / or an ink residue from a PILS 204 chamber, before measuring the sensor circuit 210 in ID 602. The cleaning resistors R1, R2 , R3 and R4 operate like typical TIJ trip resistors. Thus, they are addressed by a dynamic memory multiplexing (DMUX) 100 and driven by a power FET 1002 connected to a trigger line 1004. Controller 110 can control the activation of a cleaning resistor circuit 214 via the trip 1004 and DMUX 1000, by executing trip instructions in particular from cleaning module 134, for example.
[0047] Typically, multiple sensor circuits 210 from multiple PILS 206 will be connected to a common ID line 602. For example, a colored printhead matrix / substrate 202 with multiple slots 200 can have twelve or more PILS 206 (that is, four PILS 206 per slot 200, as in figure 2). The displacement register 218 allows the multiplexing of the outputs of multiple PILS sensor circuits 210 on the common ID line 602. A PILS 136 selection module running on controller 110 can control the displacement register 218, for the provision of a sequenced output, or the ordered output of the multiple PILS sensor circuits 210 on the common ID line 602. Figure 11 shows another example of a shift register 218 that addresses multiple PILS 206 signals, according to one embodiment. In Figure 11, a shift register 218 comprises a selective PILS block circuit to address multiple PILS signals from six PILS 206. There are three slots 200 (200a, 200b, 200c) in a colored matrix 202, with two PILS 206 for each slot 200. Addressing multiple PILS signals via shift register 218 increases the accuracy of ink level measurements by checking various locations in the matrix. In general, by using the shift register 218, measurement results from multiple PILS 206 can be compared, averaged or otherwise mathematically manipulated by ASIC 126, for example, to provide greater accuracy in determining of ink levels.
[0048] Figures 12 and 13 show flowcharts of example methods 1200 and 1300 that are related to the detection of an ink level with an ink level sensor integrated in the printhead (PILS) of a fluid ejection device, according to the modalities of the exhibition. Methods 1200 and 1300 are associated with the modalities discussed above with respect to figures 1 to 11, and the details of the steps shown in methods 1200 and 1300 can be found in the related discussion of these modalities. Method steps 1200 and 1300 can be implemented as programming instructions stored on a medium that can be read on a computer / processor, such as memory 140 in figure 1. In one embodiment, the implementation of method steps 1200 and 1300 is obtained by reading and executing these programming instructions by a processor, such as processor 138 in figure 1. Methods 1200 and 1300 may include more than one implementation, and different implementations of methods 1200 and 1300 may not employ every step presented in the respective flowcharts. Therefore, although method steps 1200 and 1300 are presented in a particular order, the order of their presentation is not intended to be a limitation as to the order in which the steps can actually be implemented, or as to whether all steps can be implemented. be implemented. For example, a method 1200 implementation could be obtained by executing several initial steps, without performing one or more of the subsequent steps, while another method 1200 implementation could be obtained by executing all steps.
[0049] Method 1200 of figure 12 begins at block 1202, in which the first step is shown for activating a cleaning resistor circuit to purge ink from a detection chamber. In block 1204, method 1200 continues to provide a delay, after activating the cleaning resistor circuit, to allow an ink from a fluid slit to flow back into the detection chamber. Method 1200 continues in block 1206 with the application of a pre-charge voltage Vp to a detection capacitor in the chamber, for charging the detection capacitor with a charge Q1. The charge Q1 is then shared between the detection capacitor and a reference capacitor, causing a reference voltage Vg at the port of an evaluation transistor, as shown in block 1208. In block 1210, method 1200 ends, with the determination of a drain resistance to the source of the evaluation transistor, which results from Vg.
[0050] The method 1300 in figure 13 starts at block 1302, where the first step shown is to start the operation of multiple PILS (ink level sensors integrated in the printhead) for the detection of an ink level in multiple areas of a fluid ejection device. The multiple PILS can be located around one or multiple slits of fluid. The operation of a PILS comprises several steps, including placing a charge on a detection capacitor in an M1 memory node, as shown in block 1304. As shown in block 1306, the operation of a PILS still includes the coupling of M1 to a second M2 memory node, for sharing the load between the detection capacitor and a reference capacitor. The shared load causes a reference voltage, Vg, on M1, M2, and on a transistor port. A resistance is then determined via the transistor drain to source, as shown in block 1308, and in block 1310, the resistance is compared with a reference value for determining an ink level. The operation of a PILS can also include the removal or elimination of the presence of an intrinsic parasitic capacitance in the PILS. This can be achieved, as shown in blocks 1312 and 1314, by applying a voltage Vp to M1 to place the charge on the detection capacitor and then to simultaneously apply Vp to an Mp node, to prevent a parasitic capacitance load develop between M1 and Mp.
[0051] Method 1300 continues in block 1316 with a displacement register control in the fluid ejection device for multiplexing outputs from 5 of multiple PILS on a common ID line. In block 1318, the ink level can be determined by using the outputs of the multiple PILS. This is achieved, for example, by averaging multiple outputs from multiple PILS in an algorithm performed by ASIC 126 or 10 by controller 110.

权利要求:
Claims (7)
[0001]
1. Fluid ejection device, characterized by the fact that it comprises: a printhead matrix (202) with an ink slit (200) formed in the printhead matrix; multiple fluid drop generators (300) arranged along both sides of the slot and multiple ink level sensors integrated in the printhead (PILS) (206); each PILS located in a respective detection chamber (204) in fluid communication with the slit for the detection of an ink level of the respective detection chamber, and comprising a cleaning resistor circuit (214) arranged in the detection chamber for purge the ink detection chamber; the device further comprises: a common ID line; shift register (218) to select between multiple PILS for extraction to the common ID line.
[0002]
2. Fluid ejection device according to claim 1, characterized in that the cleaning resistor circuit (214) comprises four resistors surrounding a PILS detection capacitor plate (206), each resistor adjacent to and aligned in parallel with a different side of the detection capacitor plate.
[0003]
3. Fluid ejection device according to claim 1, characterized in that the multiple PILS (206) comprise four PILS around a single slot, each of the four PILS located near a different end corner of the slot .
[0004]
4. Fluid ejection device, according to claim 3, characterized by the fact that it still comprises a detection capacitor plate in each PILS (206), in which each detection capacitor plate is at a minimum safety distance from around 40 to 50 microns from one end of the slit.
[0005]
5. Fluid ejection device, according to claim 1, characterized by the fact that it also comprises a controller (110) for controlling the activation of the cleaning resistor circuit (214) and for controlling the displacement recorder (218) for selection between multiple PILS (206) for extraction to the common ID line.
[0006]
6. Fluid ejection device, according to claim 1, characterized by the fact that the PILS (206) comprises: a detection capacitor (212), whose capacitance changes with the ink level in the chamber; a switch T2 for applying a voltage Vp to the detection capacitor, placing a load on the detection capacitor; a switch T3 for sharing the load between the detection capacitor and a reference capacitor, resulting in a reference voltage Vg; and an evaluation transistor configured to provide drain resistance to source in proportion to the reference voltage.
[0007]
7. Fluid ejection device, according to claim 1, characterized by the fact that it also comprises a parasitic elimination circuit (900) for eliminating the intrinsic parasitic capacitance of the PILS (206).

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同族专利:

公开号 | 公开日

ZA201504403B|2016-07-27|

US9487017B2|2016-11-08|

RU2015125746A|2017-01-10|

WO2014084843A1|2014-06-05|

TWI564166B|2017-01-01|

JP6012880B2|2016-10-25|

BR112015012291A2|2017-07-11|

KR20150091060A|2015-08-07|

US20170021626A1|2017-01-26|

US20150273848A1|2015-10-01|

EP2925528A4|2017-03-01|

EP2925528A1|2015-10-07|

RU2635080C2|2017-11-08|

KR101964494B1|2019-04-01|

JP2016501138A|2016-01-18|

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法律状态:
2018-12-04| B06F| Objections, documents and/or translations needed after an examination request according art. 34 industrial property law|

2019-10-08| B06U| Preliminary requirement: requests with searches performed by other patent offices: suspension of the patent application procedure|

2020-03-24| B25G| Requested change of headquarter approved|Owner name: HEWLETT-PACKARD DEVELOPMENT COMPANY, L.P. (US) |

2020-12-29| B09A| Decision: intention to grant|

2021-01-26| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 30/11/2012, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

申请号 | 申请日 | 专利标题

PCT/US2012/067225|WO2014084843A1|2012-11-30|2012-11-30|Fluid ejection device with integrated ink level sensor|

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