EP1219426B1 - Cmos/mems integrierter Tintenstrahldruckkopf und Verfahren zu seiner Herstellung - Google Patents

Cmos/mems integrierter Tintenstrahldruckkopf und Verfahren zu seiner Herstellung Download PDF

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Publication number
EP1219426B1
EP1219426B1 EP20010130224 EP01130224A EP1219426B1 EP 1219426 B1 EP1219426 B1 EP 1219426B1 EP 20010130224 EP20010130224 EP 20010130224 EP 01130224 A EP01130224 A EP 01130224A EP 1219426 B1 EP1219426 B1 EP 1219426B1
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EP
European Patent Office
Prior art keywords
ink
layers
nozzle
insulating layer
heater
Prior art date
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EP20010130224
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English (en)
French (fr)
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EP1219426A3 (de
EP1219426A2 (de
Inventor
Constantine N. Anagnostopoulos
John A. Lebens
David P. Trauernicht
James M. Chwalek
Christopher N. Delametter
Gilbert A. Hawkins
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Eastman Kodak Co
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Eastman Kodak Co
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Publication date
Priority claimed from US09/751,593 external-priority patent/US6382782B1/en
Priority claimed from US09/751,115 external-priority patent/US6412928B1/en
Priority claimed from US09/792,114 external-priority patent/US6502925B2/en
Application filed by Eastman Kodak Co filed Critical Eastman Kodak Co
Publication of EP1219426A2 publication Critical patent/EP1219426A2/de
Publication of EP1219426A3 publication Critical patent/EP1219426A3/de
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Publication of EP1219426B1 publication Critical patent/EP1219426B1/de
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J2/00Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
    • B41J2/005Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by bringing liquid or particles selectively into contact with a printing material
    • B41J2/01Ink jet
    • B41J2/07Ink jet characterised by jet control
    • B41J2/105Ink jet characterised by jet control for binary-valued deflection
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J2/00Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
    • B41J2/005Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by bringing liquid or particles selectively into contact with a printing material
    • B41J2/01Ink jet
    • B41J2/015Ink jet characterised by the jet generation process
    • B41J2/02Ink jet characterised by the jet generation process generating a continuous ink jet
    • B41J2/03Ink jet characterised by the jet generation process generating a continuous ink jet by pressure
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J2/00Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
    • B41J2/005Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by bringing liquid or particles selectively into contact with a printing material
    • B41J2/01Ink jet
    • B41J2/015Ink jet characterised by the jet generation process
    • B41J2/02Ink jet characterised by the jet generation process generating a continuous ink jet
    • B41J2/03Ink jet characterised by the jet generation process generating a continuous ink jet by pressure
    • B41J2002/032Deflection by heater around the nozzle
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J2202/00Embodiments of or processes related to ink-jet or thermal heads
    • B41J2202/01Embodiments of or processes related to ink-jet heads
    • B41J2202/13Heads having an integrated circuit
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J2202/00Embodiments of or processes related to ink-jet or thermal heads
    • B41J2202/01Embodiments of or processes related to ink-jet heads
    • B41J2202/16Nozzle heaters
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J2202/00Embodiments of or processes related to ink-jet or thermal heads
    • B41J2202/01Embodiments of or processes related to ink-jet heads
    • B41J2202/22Manufacturing print heads

Definitions

  • This invention generally relates to the field of digitally controlled printing devices, and in particular to liquid ink print heads which integrate multiple nozzles on a single substrate and in which a liquid drop is selected for printing by thermo-mechanical means.
  • Ink jet printing has become recognized as a prominent contender in the digitally controlled, electronic printing arena because, e.g., of its non-impact, low noise characteristics and system simplicity. For these reasons, ink jet printers have achieved commercial success for home and office use and other areas.
  • Ink jet printing mechanisms can be categorized as either continuous (CIJ) or Drop-on-Demand (DOD).
  • Piezoelectric DOD printers have achieved commercial success at image resolutions greater than 720 dpi for home and office printers.
  • piezoelectric printing mechanisms usually require complex high voltage drive circuitry and bulky piezoelectric crystal arrays, which are disadvantageous in regard to number of nozzles per unit length of print head, as well as the length of the print head.
  • piezoelectric print heads contain at most a few hundred nozzles.
  • Thermal ink jet printing typically requires that the heater generates an energy impulse enough to heat the ink to a temperature near 400 ° C which causes a rapid formation of a bubble.
  • the high temperatures needed with this device necessitate the use of special inks, complicates driver electronics, and precipitates deterioration of heater elements through cavitation and kogation.
  • Kogation is the accumulation of ink combustion by-products that encrust the heater with debris. Such encrusted debris interferes with the thermal efficiency of the heater and thus shorten the operational life of the print head.
  • the high active power consumption of each heater prevents the manufacture of low cost, high speed and page wide print heads.
  • a gutter (sometimes referred to as a "catcher") is normally used to intercept the charged drops and establish a non-print mode, while the uncharged drops are free to strike the recording medium in a print mode as the ink stream is thereby deflected, between the "non-print” mode and the "print” mode.
  • the charging tunnels and drop deflector plates in continuous ink jet printers operate at large voltages, for example 100 volts or more, compared to the voltages commonly considered damaging to conventional CMOS circuitry, typically 25 volts or less.
  • the inks in electrostatic continuous ink jet printers to be conductive and to carry current.
  • the manufacture of continuous ink jet print heads has not been generally integrated with the manufacture of CMOS circuitry.
  • the apparatus comprises an ink delivery channel, a source of pressurized ink in communication with the ink delivery channel, and a nozzle having a bore which opens into the ink delivery channel, from which a continuous stream of ink flows.
  • Periodic application of weak heat pulses to the stream by a heater causes the ink stream to break up into a plurality of droplets synchronously with the applied heat pulses and at a position spaced from the nozzle.
  • the droplets are deflected by increased heat pulses from the heater (in the nozzle bore) which heater has a selectively actuated section, i.e. the section associated with only a portion of the nozzle bore.
  • Asymmetrically applied heat results in stream deflection, the magnitude of which depends on several factors, e.g. the geometric and thermal properties of the nozzles, the quantity of applied heat, the pressure applied to, and the physical, chemical and thermal properties of the ink.
  • solvent-based (particularly alcohol-based) inks have quite good deflection patterns (see in this regard U.S. Patent No. 6,247,801 B1 filed in the names of Trauemicht et al)
  • water-based inks are more problematic.
  • a continuous ink jet print printer that includes a print head of the type wherein ink forms a meniscus above a nozzle bore and spreads along an upper surface of the print head.
  • the print head includes a substrate having an upper surface, an ink delivery channel below the substrate, and a nozzle bore through the substrate and opening below the substrate inot the ink delivery channel to establish an ink flow path.
  • a resistive heater lies about at least a portion of the heater bore.
  • the invention to be described herein builds upon the work of Chwalek et al. and Delametter et al. in terms of constructing continuous ink jet printheads that are suitable for low-cost manufacture and preferably for printheads that can be made page wide.
  • page wide refers to print heads of a minimum length of about four inches.
  • High-resolution implies nozzle density, for each ink color, of a minimum of about 300 nozzles per inch to a maximum of about 2400 nozzles per inch.
  • page wide print heads To take full advantage of page wide print heads with regard to increased printing speed, they must contain a large number of nozzles. For example, a conventional scanning type print head may have only a few hundred nozzles per ink color. A four inch page wide printhead, suitable for the printing of photographs, should have a few thousand nozzles. While a scanned printhead is slowed down by the need for mechanically moving it across the page, a page wide printhead is stationary and paper moves past it. The image can theoretically be printed in a single pass, thus substantially increasing the printing speed.
  • nozzles have to be spaced closely together, of the order of 10 to 80 micrometers, center to center spacing.
  • the drivers providing the power to the heaters and the electronics controlling each nozzle must be integrated with each nozzle, since attempting to make thousands of bonds or other types of connections to external circuits is presently impractical.
  • One way of meeting these challenges is to build the print heads on silicon wafers utilizing VLSI technology and to integrate the CMOS circuits on the same silicon substrate with the nozzles.
  • a continuous ink jet printer system is generally shown at 10.
  • the printhead 10a from which extends an array of nozzles 20, incorporating heater control circuits (not shown).
  • Heater control circuits read data from an image memory, and send time-sequenced electrical pulses to the heaters of the nozzles of nozzle array 20. These pulses are applied an appropriate length of time, and to the appropriate nozzle, so that drops formed from a continuous ink jet stream will form spots on a recording medium 13, in the appropriate position designated by the data sent from the image memory. Pressurized ink travels from an ink reservoir (not shown) to an ink delivery channel, built inside member 14 and through nozzle array 20 on to either the recording medium 13 or the gutter 19.
  • the ink gutter 19 is configured to catch undeflected ink droplets 11 while allowing deflected droplets 12 to reach a recording medium.
  • the general description of the continuous ink jet printer system of Fig. 20 is also suited for use as a general description in the printer system of the invention.
  • FIG. 1 there is shown a top view of an ink jet print head according to the teachings of the present invention.
  • the print head comprises an array of nozzles 1a-1d arranged in a line or a staggered configuration.
  • Each nozzle is addressed by a logic AND gate (2a-2d) each of which contains logic circuitry and a heater driver transistor (not shown).
  • the logic circuitry causes a respective driver transistor to turn on if a respective signal on a respective data input line (3a-3d) to the AND gate (2a-2d) and the respective enable clock lines (5a-5d), which is connected to the logic gate, are both logic ONE.
  • signals on the enable clock lines (5a-5d) determine durations of the lengths of time current flows through the heaters in the particular nozzles 1a-1d.
  • Data for driving the heater driver transistor may be provided from processed image data that is input to a data shift register 6.
  • the latch register 7a-7d in response to a latch clock, receives the data from a respective shift register stage and provides a signal on the lines 3a-3d representative of the respective latched signal (logical ONE or ZERO) representing either that a dot is to be printed or not on a receiver.
  • the lines A-A and B-B define the direction in which cross-sectional views are taken.
  • Figures 1A -1F show more detailed top views of the two types of heaters (the "notch type” and “split type” respectively) used in CIJ print heads. They produce asymmetric heating of the jet and thus cause ink jet deflection. Asymmetrical application of heat merely means supplying electrical current to one or the other section of the heater independently in the case of a split type heater. In the case of a notch type heater applied current to the notch type heater will inherently involve an asymmetrical heating of the ink.
  • FIG 1A there is illustrated a top view of an ink jet printhead nozzle with a notched type heater. The heater is formed adjacent the exit opening of the nozzle.
  • the heater element material substantially encircles the nozzle bore but for a very small notched out area, just enough to cause an electrical open.
  • These nozzle bores and associated heater configurations are illustrated as being circular, but can be non-circular as disclosed by Jeanmaire et al. in commonly assigned U.S. patent 6,203,145 B1.
  • one side of each heater is connected to a common bus line, which in turn is connected to the power supply typically +5 volts.
  • the other side of each heater is connected to a logic AND gate within which resides an MOS transistor driver capable of delivering up to 30 mA of current to that heater.
  • the AND gate has two logic inputs.
  • One is from the Latch 7a-d which has captured the information from the respective shift register stage indicating whether the particular heater will be activated or not during the present line time.
  • the other input is the enable clock that determines the length of time and sequence of pulses that are applied to the particular heater.
  • the enable clock typically there are two or more enable clocks in the printhead so that neighboring heaters can be turned on at slightly different times to avoid thermal and other cross talk effects.
  • FIG. 1B there is illustrated the nozzle with a split type heater wherein there are essentially two semicircular heater elements surrounding the nozzle bore adjacent the exit opening thereof. Separate conductors are provided to the upper and lower segments of each semi circle, it being understood that in this instance upper and lower refer to elements in the same plane. Vias are provided that electrically contact the conductors to metal layers associated with each of these conductors. These metal layers are in turn connected to driver circuitry formed on a silicon substrate as will be described below.
  • nozzles with multiple notch type heaters located at different heights along the ink flow path. Vias are provided that electrically contact the conductors to metal layers associated with each of the contact pads. These metal layers are in turn connected to driver circuitry formed on a silicon substrate as will be described below.
  • the top and bottom heaters can be connected in parallel and thus fired simultaneously or have their own lines so they can be activated at different times. If not fired simultaneously, it is preferred to fire the bottom heaters at a small advance ahead of the top heaters.
  • FIG 2 there is shown a simplified cross-sectional view of an operating nozzle across the B-B direction.
  • an ink channel formed under the nozzle bores to supply the ink.
  • This ink supply is under pressure typically between 15 to 25 psi for a typical bore diameter of about 8.8 micrometers and using a typical ink with a viscosity of 4 centipoise or less.
  • the ink in the delivery channel emanates from a pressurized reservoir (not shown), leaving the ink in the channel under pressure. This pressure is adjusted to yield the desired velocity for the streams of fluid emanating from the nozzles.
  • the constant pressure can be achieved by employing an ink pressure regulator (not shown).
  • a jet forms that is straight and flows directly into the gutter.
  • On the surface of the printhead a symmetric meniscus forms around each nozzle that is a few microns larger in diameter than the bore. If a current pulse is applied to the heater, the meniscus in the heated side pulls in and the jet deflects away from the heater. The droplets that form then bypass the gutter and land on the receiver. When the current through the heater is returned to zero, the meniscus becomes symmetric again and the jet direction is straight.
  • the device could just as easily operate in the opposite way, that is, the deflected droplets are directed into the gutter and the printing is done on the receiver with the non-deflected droplets. Also, having all the nozzles in a line is not absolutely necessary. It is just simpler to build a gutter that is essentially a straight edge rather than one that has a staggered edge that reflects the staggered nozzle arrangement.
  • the heater resistance is of the order of 400 ohms for a heater conform all to an 8.8 micrometers diameter bore, the current amplitude is between 10 to 20 mA , the pulse duration is about 2 microseconds and the resulting deflection angle for pure water is of the order of a few degrees, in this regard reference is made to U.S. patent 6,213,595 B1, entitled “Continuous Ink Jet Print Head Having Power-Adjustable Segmented Heaters" and to U.S. patent 6,217,163 B1, entitled “Continuous Ink Jet Print Head Having Multi-Segment Heaters", both filed December 28, 1998.
  • the application of periodic current pulses causes the jet to break up into synchronous droplets, to the applied pulses.
  • These droplets form about 100 to 200 micrometers away from the surface of the printhead and for an 8.8 micrometers diameter bore and about 2 microseconds wide, 200 kHz pulse rate, they are typically 3 to 4 pL in volume.
  • the drop volume generated is a function of the pulsing frequency, the bore diameter and the jet velocity.
  • the jet velocity is determined by the applied pressure for a given bore diameter and fluid viscosity as mentioned previously.
  • the bore diameter may range from I micrometer to 100 micrometers, with a preferred range being 6 micrometers to 16 micrometers.
  • the heater pulsing frequency is chosen to yield the desired drop volume.
  • the cross-sectional view taken along sectional line A-B and shown in Figure 3 represents an incomplete stage in the formation of a printhead in which nozzles are to be later formed in an array wherein CMOS circuitry is integrated on the same silicon substrate.
  • the CMOS circuitry is fabricated first on the silicon wafers as one or more integrated circuits.
  • the CMOS process may be a standard 0.5 micrometers mixed signal process incorporating two levels of polysilicon and three levels of metal on a six inch diameter wafer. Wafer thickness is typically 675 micrometers.
  • this process is represented by the three layers of metal, shown interconnected with vias.
  • polysilicon level 2 and an N+ diffusion and contact to metal layer 1 are drawn to indicate active circuitry in the silicon substrate.
  • the gate electrodes of the CMOS transistor devices are formed using one of the polysilicon layers.
  • dielectric layers are deposited between them making the total thickness of the film on top of the silicon wafer about 4.5 micrometers.
  • the structure illustrated in Figure 3 basically would provide the necessary interconnects, transistors and logic gates for providing the control components illustrated in Figure 1.
  • a silicon substrate of approximately 675 micrometers in thickness and about 6 inches in diameter is provided. Larger or smaller diameter silicon wafers can be used equally as well.
  • a plurality of transistor devices are formed in the silicon substrate through conventional steps of selectively depositing various materials to form these transistors as is well known.
  • Supported on the silicon substrate are a series of layers eventually forming an oxide/nitride insulating layer that has one or more layers of polysilicon and metal layers formed therein in accordance with desired pattern.
  • Vias are provided between various layers as needed and openings may be provided in the surface for allowing access to metal layers to provide for bond pads.
  • the various bond pads are provided to make respective connections of data, latch clock, enable clocks, and power provided from a circuit board mounted adjacent the printhead.
  • Figure 4 is a similar view to that of Figure 3 and also taken along line A-B, a mask has been applied to the front side of the wafer and a window of 22 micrometers in diameter is defined. The dielectric layers in the window are then etched down to the silicon surface, which provides a natural etch stop as shown in Figure 4.
  • the first step is to fill in the window opened in the previous step with a sacrificial layer such as amorphous silicon or polyimide.
  • the sacrificial layer is deposited sufficiently thick to fully cover the recesses formed between the front surface of the oxide/nitride insulating layer and the silicon substrate. These films are deposited at a temperature lower than 450 degrees centigrade to prevent melting of aluminum layers that are present.
  • the wafer is then planarized.
  • a thin, about 3500 angstroms, protection layer such as PECVD Si3N4, is deposited next and then the via3's to the metal 3 layer are opened.
  • the vias can be filled with Ti/TiN/W and planarized, or they can be etched with sloped sidewalls so that the heater layer, which is deposited next can directly contact the metal3 layer.
  • the heater layer consisting of about 50 angstroms of Ti and 600 angstroms of TiN is deposited and then patterned.
  • a final thin protection (typically referred to as passivation) layer is deposited next. This layer must have properties that, as the one below the heater, protects the heater from the corrosive action of the ink, it must not be easily fouled by the ink and can be cleaned easily when fouled. It also provides protection against mechanical abrasion.
  • FIG. 5 shows the cross-sectional view of the nozzle at this stage. It will be understood of course that along the silicon array many nozzle bores are simultaneously etched.
  • the silicon wafer is then thinned from its initial thickness of 675 micrometers to 300 micrometers, see Figure 6, a mask to open the ink channels is then applied to the backside of the wafer and the silicon is etched, in an STS etcher, all the way to the front surface of the silicon. Thereafter, the sacrificial layer is etched from the backside and the front side resulting in the finished device shown in Figure 6. It is seen from Figure 6 that the device now has a flat top surface for easier cleaning and the bore is shallow enough for increased jet deflection. Bore diameters, D, may be in the range of one micrometer to 100 micrometers, with the preferred range being 6 micrometers to 16 micrometers.
  • the thickness of the resulting membrane,t may be in the range of 0.5 micrometers to 6 micrometers, with the preferred range being 0.5 micrometers to 2.5 micrometers.
  • the temperature during post-processing was maintained below the 420 degrees centigrade annealing temperature of the heater, so its resistance remains constant for a long time.
  • the embedded heater element effectively surrounds the nozzle bore and is proximate to the nozzle bore which reduces the temperature requirement of the heater for heating the ink jet in the bore.
  • the printhead structure is illustrated with the bottom polysilicon layer extended to the ink channel formed in the oxide layer to provide a polysilicon bottom heater element.
  • the bottom heater element is used to provide an initial preheating of the ink as it enters the ink channel portion in the oxide layer. This structure is created during the CMOS process.
  • the supplementary heater elements formed in the polysilicon layer are not essential.
  • the ink channel formed in the silicon substrate is illustrated as being a rectangular cavity passing centrally beneath the nozzle array.
  • a long cavity in the center of the die tends to structurally weaken the printhead array so that if the array was subject to torsional stresses, such as during packaging, the membrane could crack.
  • pressure variations in the ink channels due to low frequency pressure waves can cause jet jitter.
  • the ink channel pattern defined in the back of the wafer therefore, is no longer a long rectangular recess running parallel to the direction of the row of nozzles but is instead a series of smaller rectangular cavities each feeding a single nozzle.
  • each individual ink channel is fabricated to be a rectangle of 20 micrometers along the direction of the row of nozzles and 120 micrometers in the direction orthogonal to the row of nozzles, see Figure 8.
  • jet deflection could be further increased by increasing the portion of ink entering the bore of the nozzle with lateral rather than axial momentum. Such can be accomplished by blocking some of the fluid having axial momentum by building a block in the center of each nozzle just below the nozzle bore.
  • FIG. 9A shows a cross-sectional view of the silicon wafer in the vicinity of the nozzle at the end of the CMOS fabrication sequence.
  • the first step in the post-processing sequence is to apply a mask to the front of the wafer at the region of each nozzle opening to be formed.
  • the mask is shaped so as to allow an etchant to open two 6 micrometer wide semicircular openings co-centric with the nozzle bore to be formed. The outside edges of these openings correspond to a 22 micrometers diameter circle.
  • the dielectric layers in the semicircular regions are then etched completely to the silicon surface as shown in Figure 9B.
  • a second mask is then applied and is of the shape to permit selective etching of the oxide block shown in Figure 10.
  • the oxide block is etched down to a final thickness or height,b, from the silicon substrate that may range from 0.5 micrometers to 3 micrometers, with a typical thickness of about 1.5 micrometers as shown in Figure 10 for a cross-section along sectional line B-B and in in Figure 11 for a cross-section along sectional line A-A.
  • a cross-sectional view of the nozzle area along A-B is shown in Figure 12.
  • openings in the dielectric layer are filled with a sacrificial film such as amorphous silicon or polyimide and the wafers are planarized.
  • a sacrificial film such as amorphous silicon or polyimide
  • a thin layer of Ti/TiN is deposited next over the whole wafer followed by a much thicker W layer. The surface is then planarized in a chemical mechanical polishing process sequence that removes the W (wolfram) and Ti/TiN films from everywhere except from inside the via3's.
  • the via3's can be etched with sloped sidewalls so that the heater layer, which is deposited next, can directly contact the metal3 layer.
  • the heater layer consisting of about 50 angstroms of Ti and 600 angstroms of TiN is deposited and then patterned.
  • a final thin protection (typically referred to as passivation) layer is deposited next.
  • This layer must have properties that, as the one below the heater, protects the heater from the corrosive action of the ink, it must not be easily fouled by the ink and it can be cleaned easily when fouled. It also provides protection against mechanical abrasion and has the desired contact angle to the ink.
  • the passivation layer may consist of a stack of films of different materials.
  • the final membrane thickness,t, encompassing the heater preferably is in the range from 0.5 micrometers to 2.5 micrometers with a typical thickness of about 1.5 micrometers.
  • the resulting gap,G, between the top of the oxide block and the bottom of the membrane encompassing the heater may be in the range of 0.5 micrometers to 5 micrometers, with the typical gap being 3 micrometers.
  • a bore mask is applied next to the front of the wafer and the passivation layers are etched to open the bore for each nozzle and the bond pads.
  • the bore diameters,D may be in the range of 1 micrometer to 100 micrometers, with the preferred range being 6 micrometers to 16 micrometers.
  • Figures 13 and 14 show respective cross-sectional views of each nozzle at this stage. Although only one of the bond pads is shown, it will be understood that multiple bond pads are formed in the nozzle array.
  • the various bond pads are provided to make respective connections of data, latch clock, enable clocks, and power provided from a circuit board mounted adjacent the printhead or from a remote location.
  • the silicon wafer is then thinned from its initial thickness of 675 micrometers to approximately 300 micrometers.
  • a mask to open the ink channels is then applied to the backside of the wafer and the silicon is then etched in an STS deep silicon etch system, all the way to the front surface of the silicon.
  • the sacrificial layer is etched from the backside and front side resulting in the finished device shown in Figures 15,18 and 19. Alignment of the ink channel openings in the back of the wafer to the nozzle array in the front of the wafer may be provided with an aligner system such as the Karl Suss 1X aligner system.
  • the polysilicon type heater is incorporated in the bottom of the dielectric stack of each nozzle adjacent an access opening between a primary ink channel formed in the silicon substrate and a secondary ink channel formed in the oxide insulating layers. These heaters also contribute to reducing the viscosity of the ink asymmetrically. Thus as illustrated in Figure 17, ink flow passing through the access opening at the right side of the blocking structure will be heated while ink flow passing through the access opening at the left side of the blocking structure will not be heated.
  • This asymmetric preheating of the ink flow tends to reduce the viscosity of ink having the lateral momentum components desired for deflection and because more ink will tend to flow where the viscosity is reduced there is a greater tendency for deflection of the ink in the desired direction; i.e. away from the heating elements adjacent the bore.
  • the polysilicon type heating elements can be of similar configuration to that of the primary heating elements adjacent the bore. Where heaters are used at both the top and the bottom of each nozzle bore, as illustrated in these figures, the temperature at which each individual heater operates can be reduced dramatically. The reliability of the TiN heaters is much improved when they are allowed to operate at temperatures well below their annealing temperature.
  • the lateral flow structure made using the oxide block allows the location of the oxide block to be aligned to within 0.02 micrometers relative to the nozzle bore.
  • the ink flowing into the bore is dominated by lateral momentum components, which is what is desired for increased droplet deflection.
  • etching of the silicon substrate be made to leave behind a silicon bridge or rib between each nozzle of the nozzle array during the etching of the ink channel.
  • These bridges extend all the way from the back of the silicon wafer to the front of the silicon wafer.
  • the ink channel pattern defined in the back of the wafer therefore, is a series of small rectangular cavities each feeding a single nozzle.
  • the ink cavities may be considered to each comprise a primary ink channel formed in the silicon substrate and a secondary ink channel formed in the oxide/nitride layers with the primary and secondary ink channels communicating through an access opening established in the oxide/nitride layer.
  • These access openings require ink to flow under pressure between the primary and secondary channels and develop lateral flow components because direct axial access to the secondary ink channel is effectively blocked by the oxide block.
  • the secondary ink channel communicates with the nozzle bore.
  • CMOS/MEMS print head 120 corresponding to any of the embodiments described herein is mounted on a supporting mount 110 having a pair of ink feed lines 130L, 130R connected adjacent end portions of the mount for feeding ink to ends of a longitudinally extending channel formed in the supporting mount.
  • the channel faces the rear of the print head 120 and is thus in communication with the array of ink channels formed in the silicon substrate of the print head 120.
  • the supporting mount which could be a ceramic substrate, includes mounting holes at the ends for attachment of this structure to a printer system.
  • the ink jet printheads are characterized by relative ease of manufacture and/or with relatively planar surfaces to facilitate cleaning and maintenance of the printhead and a relatively thin insulating layer or layers, such as a passivation layer or layers, through which is formed the nozzle bore. Adjacent each nozzle bore is an appropriate asymmetric heating element.
  • the printhead described herein are suited for preparation in a conventional CMOS facility and the heater elements and channels and nozzle bore may be formed in a conventional MEMS facility.

Landscapes

  • Particle Formation And Scattering Control In Inkjet Printers (AREA)

Claims (1)

  1. Verfahren zum Ausbilden eines kontinuierlich arbeitenden Tintenstrahldruckkopfs mit den Schritten:
    Bereitstellen eines Siliciumsubstrats mit einem integrierten Schaltkreis zum Steuern des Betriebs des Druckkopfs, wobei das Siliciumsubstrat eine darauf ausgebildete Isolierschicht oder darauf ausgebildete Isolierschichten aufweist, die darin ausgebildete elektrische Leiterbahnen umfasst bzw. umfassen, welche elektrisch mit im Siliciumsubstrat ausgebildeten Schaltungen verbunden sind, und ein erstes Heizelement aufweist bzw. aufweisen, welches mindestens einer darin ausgebildeten Tintenströmungsbahn benachbart ist;
    Ausbilden einer Reihe relativ großer Öffnungen in der Isolierschicht oder den Isolierschichten, von denen jede Öffnung einen ersten Teil aufweist, der sich von der Oberfläche der Isolierschicht oder Isolierschichten bis zum Silciumsubstrat erstreckt zum Ausbilden der mindestens einen Tintenströmungsbahn, und einen zweiten Teil, der sich von der Oberfläche der Isolierschicht oder Isolierschichten in eine Tiefe erstreckt, die geringer ist als die Dicke der Isolierschicht oder Isolierschichten zum Ausbilden eines zweiten Tintenkanals und einer Blockierstruktur in der Isolierschicht oder den Isolierschichten, welche einen ersten Tintenkanal im Siliciumsubstrat vom zweiten Tintenkanal trennt, wodurch mindestens eine erste Tintenströmungsbahn zwischen dem ersten und dem zweiten Tintenkanal entsteht, wobei sich der erste Tintenkanal von der Rückseite des Siliciumsubstrats zur Rückseite der Isolierschicht oder Isolierschichten erstreckt;
    Aufbringen einer Platzhalterschicht in jeder aus der Reihe von Öffnungen;
    Ausbilden einer Isolierschicht oder von Isolierschichten über der Platzhalterschicht in jeder Öffnung, wobei die Isolierschicht bzw. Isolierschichten benachbart zu jeder aus der Reihe von Öffnungen ein zweites Heizelement aufweist bzw. aufweisen;
    Ausbilden eines Düsenlochs in der Isolierschicht oder den Isolierschichten, welche das zweite Heizelement aufweist oder aufweisen, wobei jedes Düsenloch über einem entsprechenden, in den Isolierschichten ausgebildeten zweiten Kanal angeordnet ist und wobei die Tintenströmungsbahn nicht mit einem der Düsenlöcher vertikal ausgerichtet ist;
    Ausbilden des ersten Tintenkanals im Siliciumsubstrat; und
    Entfernen der Platzhalterschicht aus jedem Düsenloch, um einen Druckkopf auszubilden, der um den Bereich der Düsenöffnungen herum eine relativ planare Fläche aufweist, um die Wartung des Druckkopfes zu vereinfachen.
EP20010130224 2000-12-29 2001-12-19 Cmos/mems integrierter Tintenstrahldruckkopf und Verfahren zu seiner Herstellung Expired - Lifetime EP1219426B1 (de)

Applications Claiming Priority (6)

Application Number Priority Date Filing Date Title
US751115 1985-07-02
US09/751,593 US6382782B1 (en) 2000-12-29 2000-12-29 CMOS/MEMS integrated ink jet print head with oxide based lateral flow nozzle architecture and method of forming same
US09/751,115 US6412928B1 (en) 2000-12-29 2000-12-29 Incorporation of supplementary heaters in the ink channels of CMOS/MEMS integrated ink jet print head and method of forming same
US751593 2000-12-29
US792114 2001-02-22
US09/792,114 US6502925B2 (en) 2001-02-22 2001-02-22 CMOS/MEMS integrated ink jet print head and method of operating same

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EP1219426A2 EP1219426A2 (de) 2002-07-03
EP1219426A3 EP1219426A3 (de) 2003-03-19
EP1219426B1 true EP1219426B1 (de) 2006-03-01

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US7735981B2 (en) * 2007-07-31 2010-06-15 Eastman Kodak Company Continuous ink-jet printing with jet straightness correction
US7762647B2 (en) * 2007-09-25 2010-07-27 Eastman Kodak Company MEMS printhead based compressed fluid printing system
EP2865787A1 (de) 2013-10-22 2015-04-29 ATOTECH Deutschland GmbH Kupfergalvanisierungsverfahren
JPWO2018116561A1 (ja) * 2016-12-20 2019-10-24 コニカミノルタ株式会社 インクジェットヘッドおよび画像形成装置
ES2885775T3 (es) 2019-02-06 2021-12-15 Hewlett Packard Development Co Matriz para un cabezal de impresión
WO2020162912A1 (en) 2019-02-06 2020-08-13 Hewlett-Packard Development Company, L.P. Die for a printhead
JP7146094B2 (ja) 2019-02-06 2022-10-03 ヒューレット-パッカード デベロップメント カンパニー エル.ピー. プリントヘッド用のダイ
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EP1219426A3 (de) 2003-03-19
EP1219426A2 (de) 2002-07-03
DE60117456D1 (de) 2006-04-27
JP2002225278A (ja) 2002-08-14
DE60117456T2 (de) 2006-10-05

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