• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    FLUID EJECTION DEVICE AND METHOD FOR CIRCULAR FLUID IN A FLUID EJECTION DEVICE. In one configuration, a method for circulating fluid in a fluid ejection device includes generating compressive and expansive displacements of fluid of different durations from a first actuator located asymmetrically within a fluid channel between a first fluid feed hole and a nozzle while not generating fluid displacements from a second actuator located asymmetrically within the channel between the nozzle and a second fluid supply hole.
    公开号:BR112014004800B1
    申请号:R112014004800-2
    申请日:2011-08-31
    公开日:2021-01-26
    发明作者:Alexander Govyadinov;Kianoush Naeli;Tony S. Cruz-Uribe
    申请人:Hewlett-Packard Development Company, L.P.;
    IPC主号:
    专利说明:

    [0001] [001] Fluid ejection devices in inkjet printers provide drop ejection on demand for fluid droplets. Inkjet printers produce images by ejecting drops of ink through a plurality of nozzles onto a media, such as a sheet of paper. The nozzles are typically arranged in one or more arrays, such that the correctly sequenced ejection of ink droplets from the nozzles causes characters or other images to be printed on the media as the print head and media become move in relation to each other. In a specific example, a thermal printhead ejects drops from a nozzle by passing electrical current through a heating element to generate heat and vaporize a small portion of the fluid inside a firing chamber. Part of the fluid displaced by the vapor bubble is ejected from the nozzle. In another example, a piezoelectric printhead uses a piezoelectric material actuator to generate pressure pulses that force drops of ink out of a nozzle.
    [0002] [002] While inkjet printers provide high print quality at a reasonable cost, their continued improvement depends in part on overcoming several operational challenges. For example, the release of air bubbles from ink during printing can cause problems such as blocking ink flow, insufficient pressure to eject drops, and misdirected drops. Ink-pigment vehicle separation (PIVS) is another problem that can occur when using pigment-based ink. PIVS is typically a result of water evaporation from the ink in the nozzle area and depletion of the pigment concentration in ink close to the nozzle area due to increased pigment affinity with water. During periods of storage or non-use, pigment particles can also settle or eject out of the ink vehicle which can prevent or block ink flow to the firing chambers and nozzles in the printhead. Other factors related to “unblocking”, such as evaporation of water or solvent can cause PIVS and the formation of a viscous plug of paint. Unblocking is the amount of time that inkjet nozzles can remain uncovered and exposed to environmental conditions without causing degradation in the ejected ink droplets. The effects of uncovering can alter the trajectories, speeds, shapes and colors of drops, all of which can negatively impact the print quality of an inkjet printer. Brief description of the drawings
    [0003] [003] The present configurations will now be described, by way of example, with reference to the attached drawings, in which:
    [0004] [004] Figure 1 illustrates an inkjet printing system suitable for incorporating a fluid ejection device and implementing methods for circulating fluid in a fluid ejection device as disclosed here, according to a configuration;
    [0005] [005] Figure 2 shows a partial cross-sectional side view of an exemplary fluid ejection device, according to a configuration;
    [0006] [006] Figure 3a shows a fluid ejection device in a normal drop ejection mode, according to a configuration;
    [0007] [007] Figure 3b shows a fluid ejection device in a normal fluid refill mode, according to a configuration;
    [0008] [008] Figure 3c shows a graph of an exemplary voltage waveform (V) applied to actuators to achieve actuator deflections (X) that generate drop ejections and corresponding fluid replenishments, according to a configuration;
    [0009] [009] Figure 4a shows a fluid ejection device in a normal drop ejection mode with actuators deflecting into a fluidic channel in forward pumping strokes that generate compressive fluid displacements within the channel, according to a configuration;
    [0010] [0010] Figure 4b shows a fluid ejection device in a normal fluid replenishment mode with actuators back to an initial or resting state, according to a configuration;
    [0011] [0011] Figure 4c shows a graph of an exemplary voltage waveform (V) applied to actuators to achieve actuator deflections (X) that generate drop ejections and corresponding fluid replenishments, according to a configuration;
    [0012] [0012] Figures 5a and 5b show a cross-sectional view of a fluid ejection device with fluid displacement actuators operating in a single actuator pumping mode and a graph of exemplary voltage waveforms (V) applied to actuators, according to configurations;
    [0013] [0013] Figure 6 shows a cross-sectional view of a fluid ejection device with fluid displacement actuators operating in an alternating multipulse actuation mode, according to a configuration;
    [0014] [0014] Figure 7 shows a cross-sectional view of a fluid ejection device with fluid displacement actuators operating in an alternate multipulse actuation mode, according to a configuration;
    [0015] [0015] Figure 8 shows a cross-sectional view of a fluid ejection device with fluid displacement actuators operating in a simultaneous multi-pulse actuation mode, according to a configuration;
    [0016] [0016] Figure 9 shows a cross-sectional view of a fluid ejection device with fluid displacement actuators operating in a simultaneous multi-pulse actuation mode according to a configuration; and
    [0017] [0017] Figure 10 shows a cross-sectional view of a fluid ejection device with fluid displacement actuators operating in a simultaneous phase actuation mode, according to a configuration. Detailed Description Overview of the problem and solution
    [0018] [0018] As noted above, several challenges have yet to be overcome in the development of inkjet printing systems. For example, inkjet printheads used in such systems sometimes have problems with blocking and / or clogging. A cause of ink blockage is an excess of air that accumulates as air bubbles in the printhead. When ink is exposed to air, such as when ink is stored in an ink reservoir, additional air dissolves in the ink. The subsequent action to eject ink droplets from the printhead firing chamber releases excess air from the ink, which then accumulates like air bubbles. Bubbles move from the firing chamber to other areas of the printhead where they can block the flow of ink to the printhead and inside the printhead. The bubbles in the chamber absorb pressure, reducing the force on the fluid pushed through the nozzle, which reduces the speed of the drop or prevents ejection.
    [0019] [0019] Pigment-based inks can also cause ink blocking or clogging in the printheads. Inkjet printing systems use pigment-based inks and dye-based inks, and although there are advantages and disadvantages with both types of ink, pigment-based inks are generally preferred. In dye-based inks, the dye particles are dissolved in a liquid such that the ink tends to soak more deeply in the paper. This makes dye-based ink less efficient and can reduce image quality as the ink drains at the edges of the image. Pigment-based inks, in contrast, consist of an ink carrier and high concentrations of insoluble pigment particles coated with a dispersant that allows the particles to remain suspended in the ink carrier. This helps pigment inks to stay more on the surface of the paper instead of getting soaked in the paper. Pigment ink is therefore more efficient than dye ink because less ink is needed to create the same color intensity in a printed image. Pigment inks also tend to be more durable and permanent than dye inks since they smear less than dye inks when they encounter water.
    [0020] [0020] A drawback with pigment-based inks, however, is that ink blocking can occur on the inkjet printhead due to factors such as prolonged storage and other environmental extremes that can result in poor performance outside the pen case. of inkjet. Inkjet pens have a printhead attached to one end that is internally attached to an ink supply. The ink supply can be self-contained inside the printhead assembly or it can reside in the printer outside the pen and be attached to the printhead through the printhead assembly. During prolonged periods of storage, gravitational effects on large pigment particles, random fluctuations, and / or dispersant degradation can cause pigment agglomeration, sedimentation or rupture. The accumulation of pigment particles in one location can prevent or completely block the firing chambers and nozzles in the printhead, resulting in poor out-of-box performance by the printhead and reduced image quality from the printer. Other factors such as water and solvent evaporation from the ink can also contribute to PIVS and / or increased ink viscosity and formation of a viscous plug, which can decrease uncapped performance and prevent immediate printing after periods of non-use.
    [0021] [0021] The previous solutions were primarily involved in maintaining the printheads before and after their use, as well as using various types of external pumps to circulate the ink through the printhead. For example, printheads are typically capped during non-use to prevent nozzles from becoming clogged with dry ink. Prior to use, the nozzles can also be primed by spraying ink through them or using the external pump to purge the printhead with a continuous flow of ink. The disadvantages to these solutions include the inability to print immediately (that is, on demand) due to maintenance time, and an increase in the total cost of ownership due to the consumption of ink during maintenance. The use of external pumps to circulate ink through the printhead is typically cumbersome and expensive, involving pressure regulators designed to maintain back pressure at the nozzle inlet. Consequently, uncapped performance, PIVS, the accumulation of air and particulates, and other causes of ink blocking and / or clogging in inkjet printing systems continue to be fundamental problems that can degrade the overall quality of printing and increase print quality. ownership costs, manufacturing costs, or both.
    [0022] [0022] The configurations of the present disclosure reduce ink blocking and / or clogging in inkjet printing systems generally through the use of piezoelectric fluid actuators and other types of mechanically controllable fluid actuators which provide fluid microcirculation within fluid channels and / or chambers of fluid ejection devices (eg, inkjet printheads). Fluid actuators located asymmetrically (ie, off-center, or eccentrically) within a fluidic channel, and a controller, allow directional flow of fluid through and within fluidic channels by controlling the lengths of forward and reverse actuation strokes (ie ie, pump strokes) that generate compressive fluid displacements (that is, in the forward pump strokes) and expansive or traction fluid displacements (that is, in reverse pump strokes).
    [0023] [0023] In one configuration, a fluid ejection device includes a fluidic channel having an inlet, an outlet and a nozzle. A first fluid displacement actuator is located asymmetrically within the channel between the inlet and the nozzle. A second fluid displacement actuator is located asymmetrically within the channel between the outlet and the nozzle. A controller controls fluid flow through the channel generating compressive and expansive fluid displacements of different durations from at least one actuator.
    [0024] [0024] In one configuration, a method for circulating fluid in a fluid ejection device includes generating compressive and expansive displacements of fluid of different durations from a first actuator located asymmetrically within a fluidic channel between an inlet and a nozzle, while not generating fluid displacements from a second actuator located asymmetrically within the channel between the nozzle and an outlet. In one implementation, the method includes generating compressive and expansive displacements of fluid of different durations from the second actuator while not generating displacements from the first actuator. In another implementation, the method includes alternating activation of the first and second actuators to generate compressive and expansive fluid displacements from both actuators.
    [0025] [0025] In one configuration, a method for circulating fluid in a fluid ejection device includes simultaneously activating a first and second actuators to generate compressive and expansive displacements of fluid, where the first and second actuators alternate between compressive and expansive displacements of fluid such that they do not generate compressive or expansive displacements of fluid at the same time. The first actuator is located asymmetrically within a fluidic channel between an inlet and an outlet, and the second actuator is located asymmetrically within the channel between the nozzle and an outlet. A nozzle and chamber are located between the actuators, and the simultaneous activation of the actuators creates a reciprocating fluid flow between the actuators. In one implementation, the simultaneous activation of the first and second actuators includes activating the first and second actuators to generate concurrent compressive fluid displacements having different magnitudes of compressive displacements to eject a drop of fluid from the nozzle and create a directional liquid flow of fluid through the channel. Illustrative configurations
    [0026] [0026] Figure 1 illustrates an inkjet printing system 100 suitable for incorporating a fluid ejection device and implementing methods for circulating fluid in a fluid ejection device as disclosed herein, according to a disclosure configuration. In this configuration, a fluid ejection device 114 is disclosed as a fluid drop blasting printhead 114. The inkjet printing system 100 includes an inkjet printhead assembly 102, a set of ink supply 104, a mounting assembly 106, a media transport assembly 108, an electronic controller 110, and at least one power supply 112 that supplies power to the various electrical components of the inkjet printing system 100. The inkjet printhead assembly 102 includes at least one printhead 114 that ejects ink droplets through a plurality of nozzles or nozzles 116 against a printing medium 118 in order to print on the printing medium 118. Print media 118 can be any type of suitable sheet or roll material, such as paper, cardboard, transparencies, Mylar, polyester, plywood, foam board, fabric, canvas and the like. The nozzles 116 are typically arranged in one or more columns or arrangements such that the correctly sequenced ejection of ink from the nozzles 116 causes characters, symbols, and / or other graphics or images to be printed on the print media 118 as the inkjet printhead assembly 102 and print media 118 are moved relative to each other.
    [0027] [0027] The ink supply set 104 provides fluid ink for the printhead assembly 102 from an ink storage reservoir 120 via an interface connection, such as a supply tube. Reservoir 120 can be removed, replaced and / or refilled. In one configuration, as shown in figure 1a, the ink supply set 104 and the inkjet printhead set 102 form a one-way ink supply system. In a one-way ink supply system, substantially all of the ink supplied to the inkjet printhead assembly 102 is consumed during printing. In another configuration, as shown in figure 1b, the ink supply assembly 104 and inkjet printhead assembly 102 form a recirculating ink supply system. In a recirculating ink supply system, only a portion of the ink supplied to the printhead assembly 102 is consumed during printing. Ink not consumed during printing is returned to ink supply set 104.
    [0028] [0028] In one configuration, the ink supply set 104 includes pressure pumps and regulators (not specifically illustrated), allowing the ink supply set 104 to supply ink to the printhead set 102 under pressure. In one configuration, ink is supplied to the printhead assembly 102 through an ink conditioning set 105. Conditioning in the ink conditioning set 105 can include filtering, preheating, pressure surge absorption, and degassing . During normal operation of the printing system 100, ink is drawn under negative pressure from the printhead assembly 102 to the ink supply assembly 104. The pressure difference between the inlet and outlet for the printhead assembly 102 provides an appropriate back pressure on nozzles 116, which is usually in the range of 1 ”negative to 10” negative H2O.
    [0029] [0029] Mounting set 106 positions inkjet printhead assembly 102 relative to media transport set 108, and media carrying set 108 positions print media 118 relative to head head assembly ink jet print 102. Thus, a print zone 122 is defined adjacent to the nozzles 116 in an area between the ink jet printhead assembly 102 and the print media. In one configuration, the inkjet printhead assembly 102 is a scan-type printhead assembly. As such, mounting assembly 106 includes a cart for moving inkjet printhead assembly 102 relative to media transport assembly 108 to scan print media 118. In another configuration, the mounting assembly 106 fixes the inkjet printhead assembly 102 in a prescribed position with respect to the media transport assembly 108 while the media transport assembly 108 positions the print media 118 in relation to the jet printhead assembly of ink 102.
    [0030] [0030] The electronic printer controller 110 typically includes a processor, firmware [resident boot software], software, one or more memory components including volatile and non-volatile memory components, and other printer electronics to communicate with and control the inkjet printhead assembly 102, the mounting assembly 106, and the media transport assembly 108. The electronic controller 110 receives data 124 from a host 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 file to be printed. As such, data 124 forms a print job for inkjet printing system 100 and includes one or more print job command parameters and / or parameters.
    [0031] [0031] In one configuration, the electronic printer controller 110 controls the inkjet printhead assembly 102 for ejecting ink droplets from nozzles 116. Therefore, electronic controller 110 defines an ink droplet pattern ejections that form characters, symbols, and / or other graphics or images on the print media 118. The pattern of ejected drops of ink is determined by the commands and / or parameters of print job commands. In one configuration, electronic controller 110 includes software instruction modules stored in memory and executable in controller 110 (i.e., processor 110 controller) to control the operation of one or more fluid displacement actuators integrated with a control device. fluid ejection 114. The software instruction modules include the single actuation module 126, multipulse actuation module 128, chamber circulation module 130 and drop ejection circulation module 132. In general, modules 126, 128, 130 and 132 are executable in the controller 110 to control the timing, duration and amplitude of the compressive and expansive fluid displacements (i.e., forward and reverse pumping strokes, respectively) generated by the fluid displacement actuators in a pressure ejection device. fluid 114. The execution of modules 126, 128, 130 and 132 in controller 110 controls the direction, rate and timing of fluid flow within the devices. fluid ejection devices 114.
    [0032] [0032] In the configurations described, the inkjet printing system 100 is a piezoelectric drop-on-demand inkjet printing system where a fluid ejection device 114 comprises a piezoelectric inkjet printhead (PIJ ) 114. The PIJ 114 printhead includes a stack of multilayer MEMS inserts that includes thin film piezoelectric fluid displacement actuators with control and drive circuitry. The actuators are controlled to generate displacements of fluid within fluid channels and / or chambers. Fluid displacements can force drops of fluid out of the chambers through nozzles 116, as well as generate directional liquid flow of fluid through the channels and / or reciprocating fluid movement within the chambers. In one implementation, the inkjet printhead assembly 102 includes a single PIJ 114 printhead. In another implementation, the inkjet printhead assembly 102 includes a wide array of PIJ 114 printheads.
    [0033] [0033] Although fluid ejection device 114 is described here as a PIJ 114 printhead having piezoelectric fluid displacement actuators, fluid ejection device 114 is not limited to this specific implementation. Other types of fluid ejection devices 114 implementing a variety of other types of fluid displacement actuators are contemplated. For example, fluid ejection devices 114 can implement electrostatic actuators (MEMS), mechanical / impact actuators, voice coil actuators, magnetostrictive actuators, and so on.
    [0034] [0034] Figure 2 shows a partial cross-sectional side view of an exemplary fluid ejection device 114, according to a configuration of the disclosure. An exploded and simplified portion of the fluid ejection device 114a, discussed below with reference to figures 3-10, is recorded in figure 2 with dotted lines. In general, fluid ejection device 114 includes a stack of pads 200 with multiple layers of pads each of which has different functionality. The layers in the stack of inserts 200 include a first (i.e., lower) substrate insert 202, a second circuit insert 204 (or ASIC insert), a third actuator / chamber layer 206, a fourth cover insert 208, and a fifth layer of nozzle 210 (or nozzle plate). In some configurations, the cap insert 208 and nozzle layer 210 are integrated as a single layer. There is also usually a non-wetting layer (not shown) on top of nozzle layer 210 that includes a hydrophobic coating to help prevent ink from pooling around nozzles 116. Each layer in the stack of pellets 200 is typically formed of silicon, except for the non-wetting layer and sometimes the nozzle layer 210. In some configurations, the nozzle layer 210 may be formed of stainless steel or a durable and chemically inert polymer such as polyimide or SU8. The layers are glued together with a chemically inert adhesive such as epoxy (not shown). In the illustrated configuration, the wafer layers have fluid passages such as slots, channels, or holes to conduct ink to and from pressure chambers 212. Each pressure chamber 212 includes a first fluid feed hole 214 and a second fluid feed hole 216 located on floor 218 of the chamber (i.e., opposite the nozzle side of the chamber) that is in fluid communication with an ink delivery manifold that includes a first fluid dispenser 220 and a second fluid dispenser 222. The floor 218 of the pressure chamber 212 is formed by the surface of the circuit layer 204. The first and second fluid supply holes 214 and 216 are on opposite sides of the floor 218 of the chamber 212 where they pierce the insert of the circuit 204 and allow ink to be circulated through chamber 212. Fluid displacement actuators 224 (ie piezoelectric actuators) are on a flexible membrane that serves as a ceiling for chamber 212 and is located opposite the chamber floor 218. Thus, the fluid displacement actuators 224 are located on the same side of the chamber 212 as the nozzles 116 are (i.e., on the ceiling or upper side of the chamber).
    [0035] [0035] The lower substrate tablet 202 includes fluid passages 226 through which fluid is able to flow to and from the pressure chambers 212 via first and second fluid dispensers 220 and 222. The substrate tablet 202 supports a film conformation thin 228 configured to relieve pressure surges from pulsating fluid flows through the fluid distribution manifold due to starting transients and fluid ejections at adjacent nozzles, for example. The conformation film 228 covers a gap in the substrate insert 202 that forms a cavity or air space 230 on the rear side of the conformation to allow it to expand freely in response to fluid pressure surges in the manifold.
    [0036] [0036] Circuit chip 204 is the second chip in the chip stack 200 and is located above the substrate chip 202. Circuit chip 204 includes the distribution manifold comprising the first and second fluid distributors 220 and 222. The first fluid collector 220 provides fluid flow to and from the chamber 212 via the first fluid supply hole 214, while the second fluid supply hole 216 allows fluid to exit the chamber 212 into the second fluid distributor 222 Circuit chip 204 also includes fluid bypass channels 232 that allow some fluid coming into the first fluid distributor 220 to bypass pressure chamber 212 and flow directly into the second fluid distributor 222 through bypass 232. A circuit insert 204 includes CMOS 234 electrical circuitry implemented in an ASIC 234 and manufactured on its upper surface adjacent to the actuator / chamber insert 206. OA SIC 234 includes ejection control circuitry that controls the pressure pulsation of fluid displacement actuators 224 (ie, piezoelectric actuators). The circuit chip 204 also includes piezoelectric actuator drive circuitry / transistors 236 (eg, FETs) manufactured on the edge of the chip 204 outside of the connecting wires 238. The drive transistors 236 are controlled (ie connected) and switched off) by control circuitry on ASIC 234.
    [0037] [0037] The next layer in the stack of pads 200 located above circuit insert 204 is the actuator / chamber insert 206 ("actuator insert 206", hereinafter). The actuator insert 206 is adhered to the circuit insert 204 and includes pressure chambers 212 having chamber floors 218 that comprise the adjacent circuit insert 204. As noted above, the chamber floor 218 additionally comprises control circuitry such as ASIC 234 manufactured on the circuit insert 204 forming the chamber floor 218. The actuator insert 206 additionally includes a flexible thin film membrane 240 such as silicon dioxide, located opposite the chamber floor 218 which serves as the chamber roof. Above and attached to the flexible membrane 240 are fluid displacement actuators 224. In the present configuration, fluid displacement actuators 224 include a thin film piezoelectric material such as a piezoceramic material that stresses mechanically in response to an applied electrical voltage . When activated, the piezoelectric actuator 224 expands or contracts physically which causes the piezoceramic laminate and membrane 240 to flex. This flexion displaces fluid in chamber 212 generating pressure waves in pressure chamber 212 that eject drops of fluid through nozzle 116 and / or circulate fluid within and through chamber 212 and first and second feed holes 214 and 216. The flexible membrane 240 and fluid displacement actuator 224 (piezoelectric actuator 224) are divided by depressor 242 that extends between pressure chamber 212 and nozzle 116. Thus, fluid displacement actuator 224 is a divided actuator 224 having a displacement actuator fluid 224, or fluid displacement actuator segment 224, on each side of chamber 212.
    [0038] [0038] The cap insert 208 is adhered to the actuator insert 206 and forms a sealed cap cavity 244 over the piezoelectric actuator 224 that encapsulates and protects the fluid displacement actuators 224. The cap insert 208 includes the depressor 242 noted above, which is a channel in the cap insert 208 that extends between the pressure chamber 212 and nozzle 116 that allows fluid to travel from the chamber 212 and out of the nozzle 116 during drop ejection events caused by pressure waves from the fluid displacement actuator 224. The nozzle layer 210, or nozzle plate, is adhered to the top of the cap insert 208 and has nozzles 116 formed therein.
    [0039] [0039] Figure 3a shows an exploded and simplified portion of a cross-sectional view of a fluid ejection device 114a as in Figure 2, in a normal drop ejection mode, according to a disclosure configuration. In this configuration, both fluid displacement actuators 224 operate simultaneously with sufficient deflection and outward displacement (i.e., convex) to eject drops of fluid of desired speed and volume from pressure chamber 212 and through nozzle 116. Both fluid displacement actuators 224 deflect outwardly in forward pumping strokes that temporarily reduce the volume in and around pressure chamber 212, generating compressive fluid displacements. Pressure waves from the simultaneous compressive fluid displacements of both actuators 224 cause fluid to eject from nozzle 116, as well as create fluid flow through the first and second fluid feed holes 214 and 216 in manifolds 220 and 222, respectively (as indicated by the fluid flow arrows).
    [0040] [0040] Figure 3b shows an exploded and simplified portion of a cross-sectional view of a fluid ejection device 114a in a normal fluid replenishment mode, according to a disclosure configuration. In this configuration, a simultaneous reverse or inward deflection of the actuators 224 back to their flat or natural state draws fluid back into the pressure chamber 212 to refill the chamber in preparation for the next drop ejection. In some implementations, reverse deflection into or into actuators 224 deflects actuators 224 beyond their flat or natural state and upward into cover cavity 244 in a concave deflection. As shown in figure 3b, both fluid displacement actuators 224 deflected back to their initial flat or neutral state (i.e., resting state). Deflection back to the initial state retracts actuators 224 back out of space in and around pressure chamber 212 in a reverse pumping stroke that increases volume in the chamber area and generates expansive fluid displacements. Expansive fluid displacements create fluid flow back into chamber 212 through first and second fluid feed holes 213 from dispensers 220 and 222, respectively (as indicated by the fluid flow arrows), refilling the chamber 212 with fluid in preparation for the next drop ejection event. During drop ejections and normal fluid refills as shown in Figures 3a and 3b, no fluid microcirculation occurs other than the fluid movement to refill the pressure chamber 212.
    [0041] [0041] Figure 3c shows a graph 302 of an exemplary voltage waveform (V) applied to actuators 224 to achieve the actuator deflections (X) shown in figures 3a and 3b that generate drops ejections and the corresponding replenishment of fluid, according to a disclosure configuration. When the applied voltage increases, the actuator 224 deflects in an outward deflection (ie, convex) that generates a compressive displacement of fluid (that is, the fluid is displaced as it is compressed within the area and around the chamber 212). When the applied voltage decreases, the actuator 224 deflects back to its flat or neutral state (ie, resting state) which generates an expansive fluid displacement (that is, the fluid is displaced as it is pulled out). back into the increasing volume in and around chamber 212). The dotted line voltage waveform in figure 3c represents an alternating voltage drive waveform whose negative voltage oscillation deflects the actuator 224 inward (ie, concave) beyond its normal resting state and into the cap cavity 244 of cap insert 208 (see figure 2), temporarily increasing the volume in and around chamber 212 additionally, and generating a greater expansive fluid displacement. Therefore, the dotted line voltage waveform drives actuator 224 to deflect outward into channel 500, generating a compressive displacement of fluid, and then back beyond its normal resting position in an opposite deflection that extends the actuator 224 upward into the cap cavity 244, generating a greater expansive fluid displacement. Although not illustrated by the voltage waveform in figure 3c, whenever a piezoelectric actuator is deflected above the flat or neutral position (ie, concave shape), the voltage is actually much lower than for deflections of the actuator into the chamber (either for pumping or recirculation). This is to avoid electric fields acting against the polarization of the piezoceramics to degrade the polarization (depolarization) which can decrease subsequent deflections, degrade the printing and pumping performance.
    [0042] [0042] Although fluid displacement actuators 224 are discussed everywhere as being located on the nozzle side of chamber 212 (i.e., in the cap insert layer 208 on the same side of chamber 212 as nozzle 116), in another configuration shown in figure 4, actuators 224 can be located in the circuit chip layer 204 (see figure 2) that is opposite the nozzle side. In yet another configuration (not shown), fluid displacement actuators 224 can be located on either the nozzle side of chamber 212 or opposite the nozzle 116. Figure 4 shows a simplified cross-sectional view of a device fluid ejection 114a with fluid displacement actuators 224 located in the circuit tablet layer 204, opposite the nozzle 116, according to a disclosure configuration.
    [0043] [0043] In figure 4a the fluid ejection device 114a is shown in a normal drop ejection mode similar to that discussed with respect to figure 3a, with actuators 224 deflecting in outward deflections (ie, convex) or strokes forward pumps that generate compressive fluid displacements, according to a disclosure configuration. In figure 4b the fluid ejection device 114a is shown in a normal fluid replenishment mode similar to that discussed with respect to figure 3b, with actuators 224 deflected back to an initial, flat or neutral state (ie, rest), according to a disclosure configuration. The actuators have retracted back in a reverse pumping stroke that generates expansive displacements of fluid, replenishing chamber 212 with fluid.
    [0044] [0044] Figure 4c shows a graph 400 of an exemplary voltage waveform (V) applied to actuators 224 to achieve the actuator deflections (X) shown in figures 4a and 4b that generate drops ejections and the corresponding refills. fluid, according to a disclosure configuration. When the applied voltage increases, it causes an outward (i.e., convex) deflection in the actuator 224 which generates a compressive fluid displacement, and when the applied voltage decreases, it causes an inward (i.e., concave) deflection in the actuator. 224 back to its initial, flat or neutral state, generating an expansive fluid displacement. The dotted line voltage waveform in figure 4c represents an alternating voltage drive waveform whose negative voltage oscillation deflects actuator 224 beyond its resting state and into a cavity (not shown) in the circuit 204, temporarily increasing the volume in and around chamber 212 and generating an expansive fluid displacement. Thus, the dotted line voltage waveform drives actuator 224 to deflect outward, generating a compressive displacement of fluid, and then back beyond its normal resting position in an opposite deflection that extends actuator 224 inward. of the circuit layer 204, generating an expansive fluid displacement. As noted above with respect to figures 3a and 3b, during normal drop ejections and fluid refills as shown in figures 4a and 4b, no fluid microcirculation occurs other than the fluid movement to refill the pressure chamber 212.
    [0045] [0045] Figures 5-10 illustrate the operating modes of fluid displacement actuators 224 that provide fluid microcirculation within fluid channels and / or chambers of fluid ejection devices 114 (e.g., printheads) inkjet). In general, fluid actuators 224 located asymmetrically (i.e., off-center, or eccentrically) within a fluidic channel, and which are controlled (eg, by a controller 110) to generate compressive and expansive fluid displacements whose durations are asymmetrical, function both as ejectors of fluid droplets to eject droplets of fluid through nozzles 116 and elements of fluid circulation (i.e., pumps) to circulate fluid through and within fluid channels. Consequently, to facilitate this description, a fluid channel 500 is defined and shown within the fluid ejection device 114a for each of the figures 5-10. Fluid channel 500 includes fluid volume within fluid ejection device 114a extending from the first fluid distributor 220 in the first fluid supply hole 214 around to the second fluid distributor 222 in the second fluid supply hole fluid 216. Chamber 212 is part of fluid channel 500, and fluid channel 500 flows through chamber 212. Thus, references here to fluid channel 500 also include chamber 212 as part and portion of channel 500. Each of the two fluid displacement actuators 224 are located in the fluid channel asymmetrically (i.e., off-center, or eccentrically) with respect to the length of channel 500. Chamber 212 is located between the two actuators 224.
    [0046] [0046] Figure 5 shows a simplified cross-sectional view of a fluid ejection device 114a with fluid displacement actuators 224 operating in a single actuator pumping mode, according to a disclosure configuration. In both figures 5a and 5b, the single actuator 224 on the right side of the figures is shown arbitrarily and discussed as the actuator operating as a fluid pump to achieve liquid flow of fluid through channel 500. The opposite flow effect is achieved when the single actuator 224 on the left side of the figures operates like the fluidic pump. Controller 110 controls the single actuator pumping operation mode of actuator 224 in figure 5 by executing software instructions on single actuation module 126. Consequently, controller 110 by executing module 126 determines which actuator 224 (on the left or on the right) operates at any given time to provide a single-actuator fluid pumping effect. Figures 5a and 5b also show a graph of an exemplary voltage waveform (V) applied to actuator 224 to achieve the illustrated actuator deflections (X) that generate the pumping effect and the resulting liquid fluid flow through the channel 500 shown by the fluid flow direction arrows. The large X at the top of the nozzle 116 is intended to indicate that there is no flow of fluid through the nozzle 116.
    [0047] [0047] In general, an inertial pumping mechanism allows a pumping effect from a fluid displacement actuator 224 in a fluidic channel 500 based on two factors. These factors are the asymmetric (ie, off-center, or eccentric) placement of actuator 224 on channel 500 with respect to the length of the channel, and the asymmetric operation of actuator 224. As shown in figure 5, each of the two actuators of fluid displacement 224 is located asymmetrically (i.e., off-center, or eccentrically) in channel 500 with respect to the length of the channel. This asymmetric actuator placement, together with the asymmetric operation of the actuator 224 (ie, control of the timing, duration and amplitude of fluid displacements), allows the inertial pumping mechanism of the actuator 224.
    [0048] [0048] Referring generally to figures 5a and 5b, the asymmetric location of the actuator 224 in the fluidic channel 500 creates a short side of the channel 500 that extends from the first fluid supply hole 214 to the actuator 224, and a long side of channel 500 extending from actuator 224 to the second fluid supply hole 216. The asymmetric location of actuator 224 within channel 500 creates an inertial mechanism that triggers fluidic diodicity (liquid fluid flow) within channel 500. A fluid displacement from actuator 224 generates a wave propagating within channel 500 which pushes fluid in two opposite directions. The most massive part of the fluid contained on the longest side of channel 500 has greater mechanical inertia at the end of a fluid actuator pump stroke forward (ie, deflection of actuator 224 within channel 500 causing a fluidic compressive displacement) . Therefore, the larger fluid body reverses direction more slowly than the fluid on the short side of channel 500. The fluid on the short side of channel 500 has more time to collect the mechanical moment during the reverse stroke of the fluid actuator pump ( i.e., deflection of the actuator 224 back to its initial resting state or additionally, causing an expansive fluidic displacement). Thus, at the end of the reverse stroke, the fluid on the shortest side of channel 500 has greater mechanical momentum than the fluid on the longest side of channel 500. As a result, the fluidic fluid flow moves towards the shorter side of channel 500 to the longest side of channel 500, as indicated by the black direction arrows in figures 5a and 5b. The liquid flow of fluid is a consequence of the unequal inertial properties of two fluid elements (i.e., the short and long sides of channel 500).
    [0049] [0049] The asymmetric operation of actuator 224 within channel 500 is the second factor that enables the inertial pumping mechanism of the fluid displacement actuator. The operation of the actuator 224 on the right side of the fluid ejection device 114a in figure 5a shows a shorter compressive displacement (i.e., the displacement is shorter with more deflection of the actuator 224 within the channel 500) and a longer expansive displacement (that is, the travel is longer in duration with less deflection of actuator 224 out of channel 500) of actuator 224. In one configuration, the asymmetric operation of actuator 224 is controlled by controller 110 via the voltage waveform of conjugate ramp in graph 502. Although similar conjugate ramp voltage waveforms are discussed everywhere as controlling the asymmetric operation of actuators 224, controlling the operation of actuators 224 in an asymmetric manner can be achieved using other types of trigger wave. The dotted line arrows in figure 5a between actuator 224 and the conjugate ramp voltage waveform in graph 502 show that the strongest compressive displacement is associated with a voltage change that is temporarily short and steeper more sharply, while the Minor expansive displacement is associated with a voltage change that is temporarily longer and gently tilted. The durations and amplitudes of the waveforms control the durations and magnitudes of the displacements from the actuator 224. Therefore, the voltage-triggering waveforms having asymmetric durations and amplitudes controlled by the controller 110 control the asymmetric operation of the actuator 224. With this Asymmetric operation of actuator 224, the direction of liquid fluid flow through channel 500 is from the short side in the first fluid supply hole 214 towards the long side in the second fluid supply hole 216. Note that if this same Asymmetric operation is implemented with respect to actuator 224 on the left side of figure 5a, the direction of liquid fluid flow through channel 500 will be inverted.
    [0050] [0050] The actuator 224 in figure 5b on the right side of the fluid ejection device 114a is shown operating in an opposite manner to that shown in figure 5a. That is, the operation of actuator 224 on the right side of figure 5b shows a longer compressive displacement (i.e., the displacement is longer in duration with less deflection of the actuator 224 within channel 500) and a shorter expansive displacement (ie that is, the displacement is shorter with more deflection of the actuator 224 out of channel 500) of the actuator 224. The ramp voltage waveform conjugated in graph 502 and the dotted line arrows show that the longer / weaker compressive displacement it is associated with a voltage change that is temporarily long and gently tilted, although the smaller expansive displacement is associated with a voltage change that is temporarily shorter and sharply inclined. With this asymmetric operation of actuator 224, the direction of liquid fluid flow through channel 500 is reversed from that shown in figure 5a. The direction of liquid fluid flow through channel 500 is from the long side at the second fluid feed hole 216 towards the short side at the first fluid feed hole 214. Note that if this same way of asymmetric operation is implemented with respect to to actuator 224 on the left side of figure 5a, the direction of liquid fluid flow through channel 500 will be reversed.
    [0051] [0051] Figure 6 shows a simplified cross-sectional view of a fluid ejection device 114a with fluid displacement actuators 224 operating in a multipulse actuation mode, according to a disclosure configuration. The multipulse actuation module 128 executed in the controller 110 controls the actuators 224 in a multipulse actuation to activate the actuators in different combinations of compressive and expansive displacements of fluid. The multipulse actuation provides a double pumping action that results in a stronger directional liquid flow through the 500 channel.
    [0052] [0052] As shown in figure 6, the multipulse actuation module 128 controls the left and right actuators 224 such that they are activated in an alternating manner. For example, the first left actuator generates a compressive fluid displacement and an expansive fluid displacement. The stronger compressive displacement and greater deflection of the left actuator are associated (by dotted lines of the arrow) with a voltage change in the conjugate ramp voltage waveform of graph 600 that is temporarily longer and gradually more inclined. As mentioned in the discussion of figure 5 above, the operation of the left actuator results in a liquid flow of fluid through channel 500 in a direction from the short side of channel 500 (with respect to the left actuator) in the second feed hole in the direction of the long side in the first fluid feed hole 214.
    [0053] [0053] After a time delay during which the left side actuator is activated, the multipulse actuation module 128 activates the right side actuator to generate a compressive fluid displacement and an expansive fluid displacement. The time delay is at least long enough to encompass activation of the left actuator, but in some configurations it may be longer such that activation of the right side actuator does not start directly after activation of the left side actuator. . Graph 600 shows that the strongest expansive displacement of the actuator on the right side is associated (by dotted arrow lines) with a voltage change that is temporarily shorter and more sharply inclined than the compressive displacement, which is associated with a change in voltage that is temporarily longer and more gradually inclined. As mentioned in the discussion of figure 5 above, this operation of the right side actuator results in a liquid flow of fluid through channel 500 in a direction from the long side of channel 500 (with respect to the right actuator) in the second feed hole. fluid 216 towards the short side at the first fluid feed hole 214. Pumping double action from the left and right side actuators in a phase defined by a graph 600 and the following equation results in a liquid flow of fluid through of channel 500 that is available when only one actuator operates as a pump: Time delay: t = d / v (v: circulation flow rate / speed; d: average distance between the left and right actuators) Phase delay: φ = 2πt / T (T: operating period = 1 / (operating frequency)
    [0054] [0054] The multipulse actuation module 128 controls the right and left actuators 224 and the actuation conditions (eg, duration, amplitude, frequency) to control fluid flow through channel 500, and first and second supply holes fluid 214 and 216, in any direction. Although only one example is discussed, a number of different operating combinations for this multipulse mode are available.
    [0055] [0055] Figure 7 shows a simplified cross-sectional view of a fluid ejection device 114a with fluid displacement actuators 224 operating in an alternate multipulse actuation mode, according to a disclosure configuration. In this configuration, the multipulse actuation module 128 executed on controller 110 controls actuators 224 in a multipulse actuation that activates the left and right actuators in an alternating way that has fluid displacements that are opposite to those discussed in relation to figure 6. Therefore, the multipulse actuation provides a double pumping action that results in a strong directional fluid flow through channel 500 in the opposite direction to that of the configuration in figure 6.
    [0056] [0056] As shown in graph 700 of figure 7, the multipulse actuation module 128 controls the right and left actuators 224 such that they are activated in an alternating way. However, in the configuration in figure 7, the expansive and compressive displacements of fluid are reversed. Figure 7 shows a stronger expansive displacement and a greater deflection of the associated left actuator (by dotted arrow lines) with a voltage change that is temporarily shorter and more sharply inclined. Figure 7 shows a weaker compressive displacement and lower deflection of the associated left actuator (by dotted arrow lines) with a voltage change that is temporarily longer and gradually inclined. This operation of the left side actuator results in a liquid flow of fluid through channel 500 in a direction from the long side of channel 500 (with respect to the left actuator) in the first fluid feed hole 214 towards the short side in the second fluid feed hole 216. The double pumping action from the left and right side actuators in a phase defined by graph 600 and the time and phase delay equations noted above result in a stronger liquid fluid flow through channel 500 than is available when only one actuator operates as a pump.
    [0057] [0057] Figure 8 shows a simplified cross-sectional view of a fluid ejection device 114a with fluid displacement actuators 224 operating in a simultaneous multi-pulse actuation mode, according to a disclosure configuration. In this configuration, the multipulse actuation module 128 controls the right and left actuators 224 such that they are activated simultaneously (that is, without time delay) but with displacements that are opposite each other. That is, while the right side actuator has an expansive short fluid displacement with a greater deflection, the left side actuator has a compressive fluid displacement with a greater deflection. Likewise, while the right side actuator has an expansive long fluid displacement with less deflection, the left side actuator has a long compressive fluid displacement with less deflection. As noted above, these fluid shifts create a directional liquid flow of fluid through channel 500 from the first fluid feed hole 214 to the second fluid feed hole 216.
    [0058] [0058] Figure 9 shows a simplified cross-sectional view of a fluid ejection device 114a with fluid displacement actuators 224 operating in a simultaneous multi-pulse actuation mode, according to a disclosure configuration. In this configuration, the chamber circulation module 130 controls the right and left actuators 224 such that they are activated simultaneously and in different displacement phases. Thus, as shown in figure 9, while the left-side actuator has an expansive fluid displacement of short duration followed by a compressive displacement of fluid of long duration, the right-side actuator has, respectively, a long-lasting compressive displacement by an expansive short-term displacement. After a time delay, the operation of the actuators continues with an inversion of the compressive and expansive fluid displacements as shown in graph 900. The operation of the actuators repeatedly alternates the compressive and expansive fluid displacements in this way, creating the movement of the fluid within the channel 500 (more specifically, the chamber portion 212 of channel 500) that splashes the fluid back and forth between the left actuator and the right actuator forming a local fluid circulation loop 902 within the chamber 212.
    [0059] [0059] Figure 10 shows a simplified cross-sectional view of a fluid ejection device 114a with fluid displacement actuators 224 operating in a simultaneous phase actuation mode, according to a disclosure configuration. In this configuration, the drop ejection circulation module 132 controls the right and left actuators 224 such that they are activated simultaneously and in the same phases of compressive travel. As discussed above with respect to figure 3a, this type of compressive displacement actuation of the same phase, simultaneous of both left and right 224 actuators typically results in a drop ejection. This is also the case in the present configuration in figure 10. However, in the configuration in figure 10, the amplitudes of the voltage waveforms driving the left and right side actuators 224 are different as shown in graph 1000. Consequently there is a greater fluidic displacement created by the right side actuator than by the left side actuator. The drop ejection circulation module 132 controls the right and left actuators 224 to generate simultaneous compressive fluid displacements with sufficient energy to eject a drop of fluid through the nozzle 116. In addition, the extra compressive displacement of fluid from the actuator right side generates a directional liquid flow of fluid in channel 500 of the first fluid feed hole 214 towards the second fluid feed hole 216. In another configuration (not shown), the left side actuator can be actuated with a higher voltage waveform than the right-side actuator, creating additional compressive fluid displacement from the left-side actuator that generates a directional liquid flow of fluid in channel 500 of the second fluid feed hole 216 towards the first hole fluid supply 214.
    [0060] [0060] In one implementation, generating compressive and expansive displacements of fluid includes generating compressive displacements of fluid of a first duration and generating expansive displacements of fluid of a second duration different from the first duration. In an implementation, the first duration is shorter than the second duration and fluid displacements cause fluid to flow through the channel in a first direction. In an implementation, the first duration is longer than the second duration and fluid displacements cause fluid to flow through the channel in a second direction. In one implementation, generating compressive and expansive displacements of fluid of different durations includes running a machine-readable software module that makes a controller control voltage waveforms by triggering the activation of the first actuator.
    [0061] [0061] In an implementation, generating compressive fluid displacements includes flexing the first actuator within the channel such that the area within the channel is reduced. In one implementation, generating expansive fluid displacements includes flexing the first actuator out of the channel such that the area within the channel is increased.
    [0062] [0062] In one implementation, the first actuator is located asymmetrically within a fluid channel 500 between a first fluid supply hole 214 and a nozzle 116, and the second actuator is located asymmetrically within the channel between nozzle 116 and a second fluid supply bore 216. In one implementation the nozzle 116 and a chamber 212 are located between the actuators, and simultaneous activation creates a reciprocating fluid flow between the actuators.
    权利要求:
    Claims (14)
    [0001]
    Fluid ejection device (114), comprising: - a fluidic channel (500) having a first fluid supply hole (214), a second fluid supply hole (216) and a nozzle (116); - a first fluid displacement actuator (224) located asymmetrically within the channel (500) between the first fluid supply hole (214) and the nozzle (116); - a second fluid displacement actuator (224) located asymmetrically within the channel (500) between the second fluid supply hole (216) and the nozzle (116); and the fluid ejection device, characterized by further comprising a controller (110) for controlling fluid flow through the channel (500) generating compressive and expansive displacements of fluid of different durations from at least one actuator (224), comprising the generation of compressive displacements of fluids of a first duration, and to generate expansive displacements of fluid of a second duration different from the first duration.
    [0002]
    Fluid ejection device (114) according to claim 1, characterized in that it additionally comprises a chamber corresponding to the nozzle (116) and located between the first and second actuators (224).
    [0003]
    Fluid ejection device (114) according to claim 1, characterized in that it additionally comprises at least one of: a single actuation module to activate one of the first actuator (224) or the second actuator (224) to induce directional flow of fluid through the channel (500); a multi-pulse actuation module executable in the controller (110) to alternately activate both actuators (224) to cause directional flow of fluid through the channel (500), the first fluid feed hole (214) and the second feed hole fluid (216), but not through the nozzle (116); and a drop ejection circulation module executable on the controller (110) to simultaneously activate the actuators (224) to generate actuator deflections in phase that eject a drop of fluid through the nozzle (116) and induce directional flow of fluid through the channel (500).
    [0004]
    Fluid ejection device (114), according to claim 2, characterized by the fact that it additionally comprises an interchangeable circulation module executable in the controller (110) to simultaneously activate the actuators (224) to generate deflections of the opposite phase actuator that fluid circulates within the chamber but not through the first fluid supply hole (214), the second fluid supply hole (216), or the nozzle (116).
    [0005]
    Fluid ejection device (114), according to claim 1, characterized in that the controller is to generate the compressive and expansive displacements of fluid of different durations from at least one actuator (224) while not generating displacements of fluid from the other actuator (224), where the controller (110) is to additionally generate compressive and expansive displacements of fluid of different durations from the second actuator (224) while not generating fluid displacements from the first actuator ( 224).
    [0006]
    Fluid ejection device (114), according to claim 5, characterized by the fact that the controller (110) alternates the activation of the first and second actuators (224) to generate compressive and expansive displacements of fluid from both actuators (224).
    [0007]
    Fluid ejection device (114), according to claim 6, characterized by the fact that it alternates the activation of the first and second actuators (224) the controller (110) is for: - activate the first actuator (224) while not activating the second actuator (224); - executing a time delay while activating the first actuator (224), the time delay lasting as long as activating the first actuator (224); and after the time delay expires, activate the second actuator (224).
    [0008]
    Fluid ejection device (114), according to claim 7, characterized by the fact that it alternates the activation of the first and second actuators (224) the controller (110) is for additionally: - during the activation of the second actuator (224), delay the activation of the first actuator (224) by the time delay; and after activating the second actuator (224), activate the first actuator (224).
    [0009]
    Fluid ejection device (114), according to claim 1, characterized in that the controller is to generate the compressive and expansive displacements of fluid of different durations from at least one actuator (224) while not generating displacements of fluid from another actuator (224), and in which the first duration is shorter than the second duration and the fluid displacements cause fluid to flow through the channel (500) in a first direction.
    [0010]
    Fluid ejection device (114) according to claim 1, characterized in that the controller is to generate compressive and expansive displacements of fluid of different durations from at least one actuator (224) while not generating fluid displacements from another actuator (224), and in which the first duration is longer than the second duration and the fluid displacements cause fluid to flow through the channel (500) in a second direction.
    [0011]
    Fluid ejection device (114) according to claim 1, characterized in that the controller is to generate compressive and expansive displacements of fluid of different durations from at least one actuator (224) while not generating fluid displacements of the other actuator (224), and in which to generate compressive fluid displacements, the controller (110) is to flex the first actuator (224) inside the channel (500) such that the volume inside the channel (500) is reduced, or in that to generate expansive displacements of fluid the controller (110) is to flex the first actuator (224) out of the channel (500) such that the volume inside the channel (500) is increased.
    [0012]
    Fluid ejection device (114) according to claim 1, characterized in that the controller (110) is for: - simultaneously activating a first and second actuators (224) to generate compressive and expansive fluid displacements, the first and second actuators (224) alternating between compressive and expansive fluid displacements such that they do not generate compressive or expansive fluid displacements at the same time time; wherein the nozzle (116) and a chamber (212) are located between the actuators (224), and the simultaneous activation creates a reciprocal fluidic flow within the chamber (212) between the actuators (224).
    [0013]
    Fluid ejection device (114) according to claim 12, characterized by the fact that simultaneously activating the first and second actuators (224) comprises activating the first and second actuators (224) to generate concurrent compressive fluid displacements having different magnitudes compressive displacement to eject a drop of fluid from the nozzle (116) and to create a directional liquid flow of fluid through the channel (500).
    [0014]
    Method of fluid circulation in a fluid ejection device (114) as defined in claim 1, characterized in that it comprises generating compressive and expansive displacements of fluid of different durations from a first actuator (224) located asymmetrically within a fluidic channel (500) between a first fluid supply hole (214) and a nozzle (116) while not generating fluid displacements from a second actuator (224) located asymmetrically within the channel (500) between the nozzle (116) and a second fluid supply hole (216), in which the generation of compressive and expansive fluid displacements of different durations comprises: generate displacement of compressive fluid of a first duration; and, generate expansive fluid shifts of a second duration different from the first duration.
    类似技术:
    公开号 | 公开日 | 专利标题
    BR112014004800B1|2021-01-26|fluid ejection device and method for circulating fluid in a fluid ejection device
    US10336090B2|2019-07-02|Circulation in a fluid ejection device
    EP2571696B1|2019-08-07|Fluid ejection device with circulation pump
    JP5777706B2|2015-09-09|Fluid ejecting apparatus having circulation pump
    US8721061B2|2014-05-13|Fluid ejection device with circulation pump
    US8651646B2|2014-02-18|Fluid ejection assembly with circulation pump
    BR112013010249B1|2021-06-22|FLUID EJECTION DEVICE AND METHOD FOR OPERATING A FLUID EJECTION DEVICE
    WO2013162606A1|2013-10-31|Fluid ejection device with two-layer tophat
    US10112407B2|2018-10-30|Fluid ejection device
    US10780705B2|2020-09-22|Fluid ejection device
    同族专利:
    公开号 | 公开日
    EP2750894A4|2015-04-01|
    US8991954B2|2015-03-31|
    CN103781630A|2014-05-07|
    WO2013032471A1|2013-03-07|
    EP2750894A1|2014-07-09|
    JP5731712B2|2015-06-10|
    US20140118431A1|2014-05-01|
    EP2750894B1|2016-04-27|
    KR101865989B1|2018-06-08|
    JP2014527490A|2014-10-16|
    KR20140074283A|2014-06-17|
    CN103781630B|2016-06-01|
    BR112014004800A2|2017-03-28|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    CA1319561C|1988-08-10|1993-06-29|Steven J. Bares|Ink flow control system and method for an ink jet printer|
    US5023625A|1988-08-10|1991-06-11|Hewlett-Packard Company|Ink flow control system and method for an ink jet printer|
    JPH07251504A|1994-03-16|1995-10-03|Nikon Corp|Ink jet printing head|
    JP2858958B2|1994-06-15|1999-02-17|シチズン時計株式会社|Driving method of inkjet head|
    US5818485A|1996-11-22|1998-10-06|Xerox Corporation|Thermal ink jet printing system with continuous ink circulation through a printhead|
    JPH10250110A|1997-03-14|1998-09-22|Toshiba Corp|Ink jet recording apparatus|
    US6244694B1|1999-08-03|2001-06-12|Hewlett-Packard Company|Method and apparatus for dampening vibration in the ink in computer controlled printers|
    JP3629405B2|2000-05-16|2005-03-16|コニカミノルタホールディングス株式会社|Micro pump|
    SG105459A1|2000-07-24|2004-08-27|Micron Technology Inc|Mems heat pumps for integrated circuit heat dissipation|
    JP4617799B2|2004-09-24|2011-01-26|富士ゼロックス株式会社|Inkjet recording head maintenance method and inkjet recording apparatus|
    US7604327B2|2004-09-24|2009-10-20|Brother Kogyo Kabushiki Kaisha|Liquid ejection apparatus and method for controlling liquid ejection apparatus|
    JP2006147937A|2004-11-22|2006-06-08|Tdk Corp|Piezoelectric element and liquid control piezoelectric device|
    JP2007118309A|2005-10-26|2007-05-17|Fujifilm Corp|Inkjet recording head and image forming device equipped with the same|
    JP2007203610A|2006-02-02|2007-08-16|Konica Minolta Holdings Inc|Liquid drop ejection head and liquid drop ejector|
    KR100798371B1|2006-09-27|2008-01-28|삼성전기주식회사|Ink-jet head|
    KR101306005B1|2006-09-29|2013-09-12|삼성전자주식회사|Ink circulation system and ink-jet recording apparatus and method for ink circulation|
    JP4875997B2|2007-02-16|2012-02-15|富士フイルム株式会社|Liquid discharge head and liquid discharge apparatus|
    JP2009279816A|2008-05-21|2009-12-03|Riso Kagaku Corp|Inkjet printer|
    US8388108B2|2009-01-12|2013-03-05|Enjet Co., Ltd.|Liquid droplet spraying apparatus and method|
    JP5335580B2|2009-06-30|2013-11-06|キヤノン株式会社|Liquid ejection device|
    KR20110086946A|2010-01-25|2011-08-02|삼성전기주식회사|Inkjet print head|GB2527804B|2014-07-02|2016-07-27|Xaar Technology Ltd|Droplet deposition apparatus|
    TW201625425A|2014-09-17|2016-07-16|滿捷特科技公司|Inkjet nozzle device with roof actuator connected to lateral drive circuitry|
    FR3027380A1|2014-10-17|2016-04-22|Commissariat Energie Atomique|COOLANT LIQUID COOLING DEVICE FOR ELECTRONIC COMPONENTS|
    US10632743B2|2014-10-31|2020-04-28|Hewlett-Packard Development Company, L.P.|Fluid ejection device|
    ITUB20156035A1|2015-11-30|2017-05-30|St Microelectronics Srl|FLUID EJECTION DEVICE WITH RESTRING CLOG, AND METHOD OF MANUFACTURE OF THE SAME|
    JP6929640B2|2016-01-08|2021-09-01|キヤノン株式会社|Recording element substrate and liquid discharge head|
    JP6851800B2|2016-01-08|2021-03-31|キヤノン株式会社|Liquid discharge device and liquid discharge head|
    CN109070077A|2016-04-28|2018-12-21|惠普发展公司,有限责任合伙企业|Microfluid filtering|
    JP6919267B2|2017-03-28|2021-08-18|セイコーエプソン株式会社|Liquid discharge device and liquid discharge method|
    US10343400B2|2017-03-28|2019-07-09|Seiko Epson Corporation|Liquid discharge apparatus and method for controlling the same|
    EP3381701B1|2017-03-28|2020-05-13|Seiko Epson Corporation|Liquid discharge apparatus and method for controlling the same|
    EP3634763A4|2017-06-09|2020-06-17|Fujifilm Dimatix, Inc.|Fluid ejection devices with reduced crosstalk|
    JP2019010762A|2017-06-29|2019-01-24|キヤノン株式会社|Liquid discharge module|
    US10486424B2|2017-07-07|2019-11-26|Canon Kabushiki Kaisha|Liquid ejection head and liquid ejection apparatus|
    TWI667189B|2017-08-31|2019-08-01|研能科技股份有限公司|Microelectromechanical fluid control device|
    JP2019064109A|2017-09-29|2019-04-25|キヤノン株式会社|Liquid discharge device, liquid discharge head, and recovery method|
    CN111372782B|2017-11-27|2021-10-29|惠普发展公司,有限责任合伙企业|Cross-die recirculation channel and chamber recirculation channel|
    JP6985513B2|2017-12-02|2021-12-22|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.Hewlett‐Packard Development Company, L.P.|Fluid circulation and discharge|
    GB201803177D0|2018-02-27|2018-04-11|3C Project Man Limited|Droplet ejector|
    US20210039391A1|2018-04-26|2021-02-11|Hewlett-Packard Development Company, L.P.|Fluid ejection unit with circulation loop and fluid bypass|
    US11097536B2|2018-12-28|2021-08-24|Canon Kabushiki Kaisha|Driving method of liquid feeding apparatus|
    US11090935B2|2018-12-28|2021-08-17|Canon Kabushiki Kaisha|Liquid ejection module|
    JP2020168744A|2019-04-01|2020-10-15|ブラザー工業株式会社|Liquid discharge head|
    WO2021183124A1|2020-03-11|2021-09-16|Hewlett-Packard Development Company, L.P.|Recirculation bypass|
    法律状态:
    2018-12-26| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2019-10-22| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2020-05-26| B06A| Notification to applicant to reply to the report for non-patentability or inadequacy of the application [chapter 6.1 patent gazette]|
    2020-09-24| B06A| Notification to applicant to reply to the report for non-patentability or inadequacy of the application [chapter 6.1 patent gazette]|
    2020-12-08| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2021-01-12| B25G| Requested change of headquarter approved|Owner name: HEWLETT-PACKARD DEVELOPMENT COMPANY, L.P. (US) |
    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 31/08/2011, OBSERVADAS AS CONDICOES LEGAIS. |
    优先权:
    申请号 | 申请日 | 专利标题
    PCT/US2011/050072|WO2013032471A1|2011-08-31|2011-08-31|Fluid ejection device with fluid displacement actuator and related methods|
    [返回顶部]