Ink jet printing can be performed using an ink jet print head that includes multiple nozzles. Ink is introduced into the ink jet print head and, when activated, the nozzles eject droplets of ink to form an image on a substrate. Ink jet printing at an elevated height above the substrate can be used to print onto substrates with large variations in height.
In a general aspect, a system includes a print head including multiple nozzles formed in a bottom surface of the print head. The nozzles are configured to eject a liquid onto a substrate. The system includes a gas flow module configured to provide a flow of gas through a gap between the bottom surface of the print head and the substrate in a direction corresponding to a motion of the substrate relative to the print head.
Embodiments can include one or more of the following features.
The gas flow module includes one or more gas nozzles configured to inject gas into the gap. In some cases, the one or more gas flow nozzles are interleaved with the nozzles. In some cases, the one or more gas flow nozzles include an elongated nozzle. In some cases, the elongated nozzle is disposed at an angle of about 0-45° to the nozzle plate or about 45-90° to a direction that is perpendicular to a direction of motion of the substrate. In some cases, a width of the elongated nozzle is between about 1-8 mm. In some cases, each elongated nozzle is disposed substantially parallel to a row of the nozzles formed in the bottom surface of the print head. In some cases, at least one of the gas flow nozzles includes multiple holes.
The gas flow module is a first gas flow module. The system includes a second gas flow module. The first gas flow module is configured to provide a flow of gas through the gap in a first direction and the second gas flow module is configured to provide a flow of gas through the gap in a second direction opposite the first direction. The system includes a first valve configured to enable the first gas flow module to provide a flow of gas through the gap; and a second valve configured to enable the second gas flow module to provide a flow of gas through the gap. The first gas flow module includes a first suction module positioned on a first side of the print head and configured to apply suction to the gap. The second gas flow module includes a second suction module positioned on a second side of the print head opposite the first side and configured to apply suction to the gap.
The gas flow module is positioned to provide the flow of gas in a direction substantially corresponding to a direction in which the nozzles eject the liquid onto the substrate.
The gas flow module is configured to provide a flow of gas for each of multiple print heads.
The gas flow module includes a connector configured to receive the gas from a gas source.
The gas flow module is configured to provide a flow of low density gas through the gap. In some cases, the low density gas includes helium.
The gas flow module is positioned upstream of the nozzles.
The gas flow module is configured to apply a suction to the gap.
The gas flow module is positioned downstream of the nozzles. In some cases, the gas flow module is positioned such that a gas flow path through the gas flow module is lower than a gas flow path through the gap. In some cases, the gas flow module is wider than a bottom surface of the print head. In some cases, a lateral edge of the gap is sealed along at least a portion of the print head.
The gas flow module is a first gas flow module positioned upstream of the nozzles. The system includes a second gas flow module positioned downstream of the nozzles.
The gas flow module is a first gas flow module configured to inject a gas into the gap. The system includes a second gas flow module configured to apply a suction to the gap.
The gap between the bottom surface of the print head and the substrate is at least about 3 mm, such as at least about 5 mm.
The system includes one or more of an inlet baffle disposed at an entrance to the gap or an outlet baffle disposed at an exit from the gap. In some cases, a length of the inlet baffle, the outlet baffle, or both is at least five times greater than a height of the gap between the bottom surface of the print head and the substrate.
The system includes a suction generator configured to apply a suction to a back side of the substrate.
The gas flow module is configured to provide a flow of gas at a velocity of between about 0.25 m/s and about 1.5 m/s in a region of the gap substantially at a midpoint between the bottom surface of the print head and the substrate.
The gas flow module is configured to provide a flow of gas at a velocity having a uniformity within 20% along a length of the print head.
The gas flow module comprises a diffuser through which the gas flows prior to entering the gap. In some cases, the diffuser comprises a serpentine channel or a porous material.
In a general aspect, a system includes a print bar configured to receive multiple print heads. The print heads are configured to print a liquid onto a substrate. The system includes a gas flow module configured to provide a flow of gas through a gap between a bottom surface of each print head and the substrate in a direction corresponding to a motion of the substrate relative to the print head.
Embodiments can include one or more of the following features.
The system includes the multiple print heads attached to the print bar.
The print bar includes a non-printing region between an edge of the print bar and a location on the print bar configured to receive an outermost print head.
The gas flow module includes an elongated nozzle.
The gas flow module is formed in the print bar.
The gas flow module is configured to inject a gas into the gap.
The gas flow module is configured to apply a suction to the gap.
The gas flow module is a first gas flow module positioned upstream of the print heads. The system includes a second gas flow module positioned downstream of the print heads.
The gas flow module is a first gas flow module configured to inject a gas into the gap. The system includes a second gas flow module configured to apply a suction to the gap.
The gas flow module is configured to provide a flow of gas at a velocity having a uniformity within 20% along a length of the print bar.
The gas flow module is positioned such that a gas flow path through the gas flow module is lower than a gas flow path through the gap.
The gas flow module is wider than a bottom surface of the print bar.
A lateral edge of the gap is sealed along at least a portion of the print bar.
The system includes multiple print bars and multiple gas flow modules, wherein each gas flow module corresponding to one of the multiple print bars.
In a general aspect, a method includes providing a flow of low density gas through a gap between a bottom surface of a print head and a substrate; and ejecting a liquid through the gap and onto the substrate from multiple nozzles formed in the bottom surface of the print head.
Embodiments can include one or more of the following features.
The low density gas includes helium.
Providing the low density gas includes flowing the low density gas through the gap. In some cases, the method includes flowing the low density gas in a direction corresponding to a motion of the substrate relative to the print head. In some cases, the method includes flowing the low density gas through one or more of an inlet baffle disposed at an entrance to the gap or an outlet baffle disposed at an exit from the gap.
Providing the low density gas includes injecting the low density gas from one or more gas nozzles into the gap.
Providing the low density gas includes disposing the bottom surface of the print head in an environment containing the low density gas.
The method includes applying a suction to the gap.
The method includes applying a suction to a back side of the substrate.
Providing a flow of gas includes providing a flow of gas at a velocity of between about 0.25 m/s and about 1.5 m/s in a region of the gap substantially at a midpoint between the bottom surface of the print head and the substrate.
Providing a flow of gas includes providing a flow of gas at a velocity having a uniformity within 20% along a length of the print head.
Providing a flow of gas through the gap includes providing a flow of gas in a first direction through the gap when the print head moves in the first direction relative to the substrate; and providing a flow of gas in a second direction through the gap when the print head moves in the second direction relative to the substrate, the second direction opposite the first direction.
The approaches described here can have one or more of the following advantages. The occurrence of imaging defects caused by unsteady air flows under the print head (e.g., wood-grain defects) can be reduced. The occurrence of sustainability defects resulting from accumulation of ink on the nozzle plate can be reduced. The time to reach a steady state printing condition can be reduced.
Other features and advantages are apparent from the following description and from the claims.
We describe here an approach to ink jet printing that can mitigate various printing defects that occur when printing with a large separation between an ink jet print head and a substrate (referred to as high height ink jet printing). For instance, the occurrence of various types of defects can be reduced by providing a downstream suction or an upstream flow of gas, such as air or a low density gas such as helium, in the gap between the print head and the substrate. This suction or flow of forced gas can help to stabilize the pattern of gas flow in the gap, thus helping to control the displacement of drops ejected from the print head.
The resolution of the ink jet printing system 10 in the process direction, which is the direction in which the substrate 110 or the print head 100 moves during printing can be affected by factors such as one or more of the jetting frequency, velocity of substrate relative to the print head and the number of nozzles per unit of distance in the process direction, or other factors. In the cross-process direction, which is orthogonal to the process direction, the resolution is the number of nozzles per unit of distance in the cross process direction. For instance,
Ink jet printing can be performed with the print head 100 positioned at a high height above the substrate 110. For instance, a height h of the gap 112 can be greater than about 2 mm, greater than about 3 mm, greater than about 5 mm, or at another height. The height h of the gap 112 is the vertical distance between the bottom surface of the nozzle plate 104 and a top surface of the substrate 110. We sometimes refer to this approach as “high height ink jet printing” and the height h is sometimes referred to as the “standoff” High height ink jet printing can have various technological applications. In some examples, high height ink jet printing can be used to print onto a substrate that has significant height variations on its surface. In some examples, high height ink jet printing can be used to protect the print head from objects striking the print head, such strikes from loose fibers during printing on textiles.
In high height ink jet printing, the quality of the image printed onto the substrate can be affected by the pattern of gas flow in the gap 112 between the nozzle plate 104 and the substrate 110. For instance, gas flow patterns can give rise to defects in the image printed on the substrate 110. The pattern of gas flow can be influenced by couette flow of gas in the gap 112, by the effects of high frequency jetting of streams of ink drops from the nozzles 102, or by interactions between these two factors. Couette flow is the laminar flow of gas in the gap 112 caused by the velocity difference between the print head 100 and the substrate 110. For instance, when the substrate moves along the direction of the arrow 109 during the printing process, a laminar flow of gas is established, as indicated by the set of arrows 114. The gas at the interface with the substrate 110 moves with a velocity that is substantially equal to the velocity of the substrate, the gas at the interface with the stationary print head 100 has zero velocity, and a substantially linear velocity gradient exists between the print head 100 and the substrate 110. The pattern of gas flow can also be influenced by the drag on successive drops 108 of ink ejected from the print head 100 as the drops travel through the gap 112 and onto the substrate 110.
One or more satellite drops can be formed when the tail of an ejected ink drop 108 breaks off during flight. Satellite drops have low mass, and thus low momentum, which causes them to rapidly decrease in velocity as they are subjected to drag forces during flight. As the velocity of the satellite drops decreases, the momentum of the satellite drops continues to decrease, causing the satellite drops to become susceptible to displacement by the gas flow in the gap 112. In some cases, displacement of satellite drops can lead to defects in printed images. The large ink drop that remains after the satellite drops have broken off is referred to as the native drop (sometimes also called the main drop). The native drop has a larger mass and a higher velocity than the satellite drops, and as such can be less susceptible to displacement by the gas flows in the gap 112. In some cases, displacement of native drops can lead to defects in printed images.
In high height ink jet printing, gas flow patterns in the gap 112 can sometimes induce wood grain defects in images printed onto the substrate 110. Without being bound by theory, wood grain defects are believed to be caused by unsteady laminar gas flows that develop in the gap 112 due to interactions between the couette flow entrained by the motion of the substrate 110 or the print head 100 and the air flow entrained by the drag on successive drops of ink 108. The interaction between these two flows has been observed to lead to eddies upstream of the drops 108. The rotational motion of the eddies enables the eddies to easily move along the stream of drops in the gap 110 and develop into localized larger eddies. These unsteady flows and localized eddies can cause small, concentrated drop placement errors, e.g., errors typically ranging from about 10 microns to about 2 mm, in which ink drops group together in certain areas of the printed image to form a pattern that looks like a wood grain. An example of a satellite drop wood grain defect in an array of printed lines is shown in
As cross-process resolution increases or as the size of the ejected ink drops 108 increases, the non-printed area between adjacent droplets on the substrate decreases. This decrease in non-printed area enables placement errors to more easily be observed, which can cause native drop wood grain defects to become more visually dominant over satellite wood grain defects at lower heights (e.g., h less than about 6 mm). An example native drop wood grain defect is shown in
The height h at which wood grain defects and other types of high height printing defects occur can vary based on one or more parameters, such as the native drop size, satellite drop size, the drop velocity, the printing frequency, the nozzle spacing, or other parameters. For instance, the onset of high height printing defects can occur at a lower height when printing with small drops (e.g., less than about 10 ng) than when printing with larger drops (e.g., larger than 10 ng). The onset of high height printing defects can occur at a lower height when printing with a small nozzle spacing within each row (e.g., about 100 nozzles per inch) than when printing with a larger nozzle spacing (e.g., about 50 nozzles per inch).
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The forced gas module 500 includes a gas supply port 502 that is connected to a gas source. In some cases, the gas source can be the environment. For instance, if the printing system 10 is operated in normal atmosphere, the gas source can be the air. If the printing system 10 is operated in an environment of a gas, such as helium, the gas source can be the helium in the environment (discussed in more detail below). In some cases, the gas source can be a gas supply 504, such as a canister of compressed air, a canister of a low density gas such as helium, or another type of gas supply. The gas supply port 502 supplies the gas to a manifold 506 that distributes the gas to one or more gas nozzles 508, which inject the gas into the gap 112.
In some cases, each gas nozzle 508 can be implemented as a single hole. In some cases, each gas nozzle 508 can be implemented as a mesh of small holes. There can be one gas nozzle 508 (e.g., implemented as a single hole or as a mesh of small holes) for at least every 5 ink jet nozzles 102, e.g., at least every 20 nozzles, at least every 100 nozzles, or a greater number of nozzles. In some examples, there can be one gas nozzle 508 that supplies gas for thousands of ink jet nozzles 102. In some cases, the forced gas module 500 can also include other components, such as filters, screens, or other components for regulating gas flow.
In some cases, the gas nozzles 508 can be positioned upstream of the ink jet nozzles 102 such that the gas injected by the gas nozzles 508 will be entrained under the print head 100 by the motion of the substrate 110 or the print head 100. In some cases, the gas nozzles 508 can be angled towards the ink jet nozzles 102 (e.g., angled downstream) to assist with constraining the eddies which develop under the print head 100. In some cases, the gas nozzles 508 can be substantially parallel to the ink jet nozzles 102 or can angled away from the ink jet nozzles 102.
Without being bound by theory, it is believed that injecting a low density gas, such as helium, can help reduce the unsteady flows in the gap 112. By low density gas, we mean a gas that has a lower density than air at standard ambient temperature and pressure (SATP) (e.g., about 25° C. and about 1 atm). For instance, helium at SATP has a lower density than air. A low pressure environment filled with air (e.g., an environment at 0.8 atm, 0.5 atm, 0.3 atm, or another pressure) has a lower density than air at SATP. The flow of forced helium can stabilize unsteady flows in the gap and thus constrain eddies from becoming unsteady in much the same way as forced air can stabilize flows. In addition, a low density environment can reduce the air that is entrained by droplet drag, thus resulting in smaller and lower velocity eddies. A low density environment can reduce vertical drag during the drop flight from nozzle plate to substrate, thus reducing the reduction of drop velocity and enabling the drops to maintain a higher momentum. A low density environment can cause cross flows under the print head to exert lower horizontal drag forces on the ink which in turn reduces placement errors on the drops.
The breakdown of laminar couette flow and the onset of turbulent flow can be predicted by the Reynolds number Re, which is a dimensionless number given as:
where ρ is the density of the gas, V is the velocity of the gas, L is the characteristic length, and μ is the dynamic viscosity of the gas. In the case of flows under print heads, the characteristic length L is typically defined as the height h of the gap 112.
Reynolds numbers below about 2300 typically indicate laminar flow, while Reynolds numbers above about 4000 indicate turbulent flow. While not generally common in ink jet printing applications, it is possible for turbulence to occur under certain conditions (e.g., high height or high velocity flows). The Reynolds number can be decreased by decreasing the ratio of the density of the gas in the gap to the dynamic viscosity of the gas. The inverse of this ratio is defined as the kinematic viscosity:
The Reynolds number in the gap can thus be decreased by injecting a gas that has a high kinematic viscosity into the gap. For instance, helium has a kinematic viscosity that is 7 times higher than that of air, and thus injecting helium into the gap can reduce the Reynolds number in the gap by a factor of about 7. With a reduced Reynolds number in the gap, printing can be carried out at higher heights while still reducing the possibility of turbulence in the printing gap.
In some cases, when printing at high heights, the motion of small drops and satellite drops can be affected by drag on the drops by the gas in the gap. Small ink drops are ejected from the print head 100 with low initial momentum due to their low mass, and thus can rapidly decrease in velocity during flight. Similarly, satellite drops have low mass and low velocity when they are created, and thus also have low initial momentum. As the drop velocity decreases, the drops lose additional momentum, making the drops susceptible to displacement by gas flow patterns in the gap 112.
Assuming laminar flow through the gap, the drag force on a drop during flight can be calculated from:
where A is the cross-sectional area of the droplet approximated as a sphere and CD is the Schiller-Naumann drag coefficient:
The force of gravity can be considered negligible and from Newton's second law the deceleration rate can be simplified as:
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These calculations demonstrate that printing in a low density environment results in a lower Reynolds number which lowers the coefficient of drag for the drops of ink. A lower coefficient of drag in turn lowers the drag force (e.g., vertical drag force, horizontal drag force, or both) experienced by the drops. The effects of drag on small drops and satellite drops can contribute to drop displacements that contribute wood grain and sustainability defects. Forcing a low density gas, such as helium, through the gap can mitigate these defects, as shown in
In some examples, the gas nozzles 508 can be sufficient in size, number, or both to provide sufficient velocity of gas to stabilize unsteady flows in the gap 112 without generating disturbances, such as turbulent flow or large variations in air flow velocity, in the gap. The size or number of gas nozzles 508 can also be sufficient to provide a low density printing environment that reduces drag on ink drops, thus preventing the drops from losing velocity and reducing lateral drag forces exerted on the drops during flight. In some examples, the size, number, or both of the gas nozzles 508 is such that less than about 0.5 m/s of gas can stabilize the unsteady flows. In some examples, the velocity of the gas measured during a non-jetting condition at or around the midpoint of the gap 112 (e.g., halfway between the print head 100 and the substrate 110) is between about 0.25 m/s and about 1.5 m/s, e.g., between about 0.25 m/s and about 1.0 m/s, e.g., about 0.5 m/s.
The effect of forcing gas into the gap on the occurrence of wood grain defects was tested by injecting air or helium into the gap 112 between the print head 100 and the moving substrate 110. The gas flow was controlled by a mass flow controller (Aalborg® GFC Mass Flow Controller, Orangeburg, N.Y.). An image pattern of 256 lines spaced at 100 dots per inch (dpi) in the cross process direction and 400 dpi in the process direction and 2400 pixels long (6 inches) was printed using various flow rates of air and helium at various standoff heights (h). The images were printed using a black ceramic ink using a QE-30 print head (Fujifilm Dimatix, Lebanon, N.H.). Primary test parameters for these forced gas experiments were as follows:
The gas flow rates used in these forced gas experiments are significantly higher than gas flow rates that may be used in industrial applications, e.g., because of excess helium wasted to the ambient environment.
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In some examples, the substrate velocity can affect the occurrence of wood grain defects. For instance, moving the substrate at high velocity can induce a stronger couette flow in the gap, thus reducing unsteady flows in the gap and resulting in fewer wood grain defects.
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In some cases, when printing at high heights, the nozzle plate can be wetted by ejected ink, causing ink drops to be ejected from partially blocked nozzles with large trajectory errors or preventing one or more nozzles from ejecting ink drops altogether. Printing defects resulting from this partial or complete blockage of one or more nozzles on the nozzle plate by ejected ink are referred to as sustainability defects. Referring to
Without being bound by theory, nozzle plate wetting is believed to occur when small satellite drops rapidly lose velocity in the first portion of their flight path (e.g., in the first few millimeters), thus losing momentum. The low-momentum drops can be captured by eddies in the gap 112, which carry the drops back to the nozzle plate 104, where the drops are deposited. Referring to
Gas flow through the gap 112, e.g., upstream forced gas provided by the forced gas module 500 (
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In some cases, drag on ink drops when printing at high height can affect the transient response of the ink jet printing system when jetting ink drops into a still flow field, e.g., when printing is starting up. A slipstream is a gas flow pattern in the gap that is established by constant, steady jetting of streams of drops by the nozzles in the print head. Before the slipstream is developed, an initial drag force is exerted on the first few ink drops when printing is initiated (e.g., the first 10-20 ink drops) that leads to a reduction in velocity of those initial drops, making the initial drops subject to displacement errors. After the slipstream is fully developed, the drag force on the ejected drops is reduced and stabilized, and subsequent drops travel at a substantially consistent velocity. We sometimes refer to the initial printing period before the slipstream develops as the startup period.
The drag experienced by the initial drops, before the slipstream is established, can be reduced by printing in a low density environment, e.g., in a helium environment. For instance, by injecting helium into the gap, e.g., using the forced gas module 500 (
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In some examples, the forced gas module 152 can be formed integrally with the print bar assembly 150, for instance, by a stamping process, a three dimensional printing process, an injection molding process, or another fabrication process. In some examples, the forced gas module 152 can be a separate unit that can be positioned adjacent to the print bar assembly 150 or connected to the print bar assembly 150 during printing.
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In some examples, the suction module 360 can be configured such that the flow resistance of air flowing under the vacuum manifold 362 is greater than the flow resistance through the gap between each print head 100 and the substrate. This configuration helps to ensure that a large percentage of the air flow into the vacuum manifold 362 is pulled from the upstream direct (e.g., from under the print heads 100). In some instances, a high flow resistance under the vacuum manifold 362 can be achieved by positioning the suction module such that the air flow path under the vacuum manifold 362 is at a lower height than the gap under the print heads 100. For instance, the air flow path under the vacuum manifold 362 can be between about 1 mm and about 5 mm lower than the position of the gap under the print heads 100, e.g., about 2 mm lower. In some instances, a high flow resistance under the vacuum manifold 362 can be achieved by increasing the width of the vacuum manifold 362, e.g., such that the vacuum manifold 362 is wider than the width of the print heads 100. For instance, the vacuum manifold 362 can be between about 10 mm wide and about 100 mm wide, e.g., about 60 mm wide (for a print head having a width of between about 6 mm and about 60 mm). In some instances, a high flow resistance under the vacuum manifold 362 can be achieved by including one or more components in the air flow path that can reduce the downstream air flow, e.g., a brush, an air knife, or another component.
In some examples, the printing assembly 350 can include both the suction module 360 and an upstream forced gas module. The presence of upstream forced gas in the gap can reduce fluid resistance in the gap, thus allowing the printing system 350 to be implemented with a narrower vacuum manifold 362.
Referring to Table 1, results of computational fluid dynamics (CFD) simulations of the printing assembly 350 demonstrate the role of recessing the air flow path under the vacuum manifold 362 relative to the gap below the print heads 100 and the role of the width of the vacuum manifold 362. By “flush,” we mean that the vacuum manifold and print heads are approximately at the same distance from the substrate. These CFD results show that recessing the air flow path under the vacuum manifold 362 and increasing the width of the vacuum manifold 362 can affect the percentage of air flow that is pulled from under the print heads into the suction module 360.
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In order to allow steady state air flow to be achieved quickly when the printing direction is changed, a set of valves, such as solenoid valves, are coupled to the gas and suction modules. When the scanning print assembly 700 switches from scanning to the right to scanning to the left, the first forced gas module 704 is disabled by closing a valve 714 and the first suction module 706 is disabled by closing a valve 716; and the second forced gas module 708 is enabled by opening a valve 718 and the second suction module 710 is enabled by opening a valve 720. To switch direction from scanning to the right to scanning to the left, the opposite occurs. This valve-controlled switching helps the air flow pattern in the gap 112 to quickly reach steady state, thus allowing the scanning direction of the print assembly 700 to be changed quickly.
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The laminar flow slots 90, 96 can be disposed close enough to the rows 106 of nozzles 102 to establish a flow field along the flight path of the ink drops, e.g., within about 1 mm of the nozzles 102. Air or low density gas can be provided through the laminar flow slots 90, 96 at a sufficient velocity to increase the velocity in the area where jetting occurs without inducing the development of unsteady flows. For instance, air or gas can be provided at a velocity of about 0.5 m/s to about 5 m/s.
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Computational fluid dynamics (CFD) simulations of high height ink jet printing were performed to investigate how jetting conditions affect the gas flow under the print head. Simulations were performed using ANSYS® CFX (ANSYS, Canonsburg, Pa.), a fluid dynamics simulation program. The simulations were modeled as a half symmetry model of a 256 jet stationary print head with the nozzles positioned in a single row. The jets of ink drops developed by the drop streams were simulated using a particle tracking model to simulate ejection of 40 ng ink drops at 7 m/s and 8 kHz across a 5 mm gap. To perform the simulations, a mesh was generated by sub-dividing the fluid region into multiple rectangular bodies and meshed with a combination of ANSYS® multi-zone and hex dominant meshing methods. The mesh was refined to a size of 50 μm in the region surrounding the drop paths and gradually increased to a size of 2 mm. The resulting mesh yielded 2.6M modes and 3.0M elements.
The model was first solved as a steady state analysis to develop the couette flow under the print head. The substrate was simulated as a wall moving at 0.5 m/s, stationary walls were applied to the print head surfaces, and non-wall surfaces were modeled as openings at 1 atm. The Reynolds number computed with these simulated conditions and with a gap height of 5 mm was 167, which is significantly below the onset of turbulence. Therefore, a laminar flow model was applied.
After convergence of the couette flow solution, particle injections were added at each nozzle location and set to eject 42 μm and 40 ng drops at 7 m/s and 8 kHz. The substrate was configured to absorb all particles to prevent the particles from bouncing off the wall and causing additional disturbances to the flow. Since the flow was determined to be in the laminar flow regime, both experimentally and computationally, the Schiller-Naumann drag model was applied to the particles. The transient simulation was solved for a total time duration of 100 ms using time steps of 1E-5 seconds.
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In some cases, flow restrictors 76a, 76b, such as brushes or flexible wipers, can be located where the substrate 110 enters into and exits from the chamber 70 to mitigate leakage while still allowing substrates to continuously enter and exit the printing area under the print head 100.
In some examples, the gas flow module 500 can inject a flow of low density gas into the gap 112 between the print head 100 and the substrate 110 to augment the couette flow within the gap 112. The flow control device 500 can include components such as fans, ducts, filters, or screens to provide a controlled flow of gas into the gap. The gas flow module 500 can use recycled gas from the low density gas environment within the chamber 70 to reduce waste. In some examples, no flow of low density gas is provided in the gap.
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To evaluate the effect of nozzle spacing and row spacing on the occurrence of wood grain defects, test images were printed using a linear motor sled printer. An image pattern of 256 lines spaced at 100 dots per inch (dpi) in the cross process direction and 400 dpi in the process direction and 2400 pixels long (6 inches) was printed using various nozzle spacings, printing speeds, and printing frequencies. The images were printed using a black ceramic ink on a 10 mil photo base substrate. Experiments generally used Fujifilm Dimatix (Lebanon, N.H.) QE-30, PQ-M, or QS-40 print heads; certain experiments used SG-1024-MC or SAMBA 3pl print heads. Primary test parameters for the nozzle spacing experiments were as follows:
The drive voltage to jet at 7 m/s was determined for each print head and the drop mass was recorded. The normalized drop mass was used throughout the tests to ensure that each print head was jetting at 7 m/s. In multi-pulse jetting, an actuator in the print head that controls drop ejection from a nozzle is subjected to a rapid succession of electric pulses that results in the ejection of a larger droplet of ink. Multi-pulse jetting enables jetting of different drop sizes from a single nozzle diameter.
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For instance, in some examples, wood grain defects can be reduced or eliminated by having a nozzle spacing of about 0.5 mm between adjacent nozzles within a row and about 1 mm between adjacent rows of nozzles. Wood grain defects can also be reduced by positioning the rows of nozzles orthogonal to the flow direction, e.g., within about 10 degrees of the flow direction.
Embodiment 1 is directed to a system comprising a print head including multiple nozzles formed in a bottom surface of the print head, the nozzles configured to eject a liquid onto a substrate; and a gas flow module configured to provide a flow of gas through a gap between the bottom surface of the print head and the substrate in a direction corresponding to a motion of the substrate relative to the print head.
Embodiment 2 is directed to embodiment 1, in which the gas flow module comprises one or more gas nozzles configured to inject gas into the gap.
Embodiment 3 is directed to embodiment 2, in which the one or more gas flow nozzles are interleaved with the nozzles.
Embodiment 4 is directed to embodiment 2 or 3, in which the one or more gas flow nozzles comprises an elongated nozzle.
Embodiment 5 is directed to embodiment 4, in which the elongated gas nozzle is disposed at an angle of about 0-45° to the bottom surface of the print head.
Embodiment 6 is directed to embodiment 4 or 5, in which the elongated nozzle is disposed at an angle of about 45-90° to a direction that is perpendicular to a direction of motion of the substrate.
Embodiment 7 is directed to any of embodiments 4 to 6, in which a width of the elongated nozzle is between about 1-8 mm.
Embodiment 8 is directed to any of embodiments 4 to 7, in which each elongated nozzle is disposed substantially parallel to a row of the nozzles formed in the bottom surface of the print head.
Embodiment 9 is directed to any of embodiments 2 to 8, in which at least one of the gas flow nozzles comprises multiple holes.
Embodiment 10 is directed to any of embodiments 2 to 9, in which each gas nozzle is disposed at an angle of about 0-45° to the bottom surface of the print head.
Embodiment 11 is directed to any of embodiments 2 to 10, in which a width of each gas nozzle is between about 1-8 mm.
Embodiment 12 is directed to any of the preceding embodiments, in which the gas flow module is a first gas flow module and further comprising a second gas flow module, and in which the first gas flow module is configured to provide a flow of gas through the gap in a first direction and the second gas flow module is configured to provide a flow of gas through the gap in a second direction opposite the first direction.
Embodiment 13 is directed to embodiment 12, comprising a first valve configured to enable the first gas flow module to provide a flow of gas through the gap; and a second valve configured to enable the second gas flow module to provide a flow of gas through the gap.
Embodiment 14 is directed to embodiment 12 or 13, in which the first gas flow module comprises a first suction module positioned on a first side of the print head and configured to apply suction to the gap; and in which the second gas flow module comprises a second suction module positioned on a second side of the print head opposite the first side and configured to apply suction to the gap.
Embodiment 15 is directed to embodiment 14, in which the first gas flow module comprises one or more first gas flow nozzles positioned on the second side of the print head and configured to inject gas into the gap; and in which the second gas flow module comprises one or more second gas flow nozzles positioned on the first side of the print head and configured to inject gas into the gap.
Embodiment 16 is directed to any of the preceding embodiments, in which the gas flow module is positioned to provide the flow of gas in a direction substantially corresponding to a direction in which the nozzles eject the liquid onto the substrate.
Embodiment 17 is directed to any of the preceding embodiments, in which the gas flow module is configured to provide a flow of gas for each of multiple print heads.
Embodiment 18 is directed to any of the preceding embodiments, in which the gas flow module comprises a connector configured to receive the gas from a gas source.
Embodiment 19 is directed to any of the preceding embodiments, in which the gas flow module is configured to provide a flow of low density gas through the gap.
Embodiment 20 is directed to embodiment 19, in which the low density gas comprises helium.
Embodiment 21 is directed to any of the preceding embodiments, in which the gas flow module is positioned upstream of the nozzles.
Embodiment 22 is directed to any of the preceding embodiments, in which the gas flow module is configured to apply a suction to the gap.
Embodiment 23 is directed to any of the preceding embodiments, in which the gas flow module is positioned downstream of the nozzles.
Embodiment 24 is directed to embodiment 23, in which the gas flow module is positioned such that a gas flow path through the gas flow module is lower than a gas flow path through the gap.
Embodiment 25 is directed to embodiment 23 or 24, in which the gas flow module is wider than a bottom surface the print head.
Embodiment 26 is directed to any of embodiments 23 to 25, in which a lateral edge of the gap is sealed along at least a portion of the print head.
Embodiment 27 is directed to any of the preceding embodiments, in which the gas flow module is a first gas flow module positioned upstream of the nozzles, and in which the system includes a second gas flow module positioned downstream of the nozzles.
Embodiment 28 is directed to any of the preceding embodiments, in which the gas flow module is a first gas flow module configured to inject a gas into the gap, and in which the system includes a second gas flow module configured to apply a suction to the gap.
Embodiment 29 is directed to any of the preceding embodiments, in which the gap between the bottom surface of the print head and the substrate is at least about 3 mm.
Embodiment 30 is directed to any of the preceding embodiments, in which the gap between the bottom surface of the print head and the substrate is at least about 5 mm.
Embodiment 31 is directed to any of the preceding embodiments, comprising one or more of an inlet baffle disposed at an entrance to the gap or an outlet baffle disposed at an exit from the gap.
Embodiment 32 is directed to embodiment 31, in which a length of the inlet baffle, the outlet baffle, or both is at least five times greater than a height of the gap between the bottom surface of the print head and the substrate.
Embodiment 33 is directed to any of the preceding embodiments, comprising a suction generator configured to apply a suction to a back side of the substrate.
Embodiment 3444 is directed to any of the preceding embodiments, in which the gas flow module is configured to provide a flow of gas at a velocity of between about 0.25 m/s and about 1.5 m/s in a region of the gap substantially at a midpoint between the bottom surface of the print head and the substrate.
Embodiment 35 is directed to any of the preceding embodiments, in which the gas flow module is configured to provide a flow of gas at a velocity having a uniformity within 20% along a length of the print head.
Embodiment 36 is directed to any of the preceding embodiments, in which the gas flow module comprises a diffuser through which the gas flows prior to entering the gap.
Embodiment 37 is directed to embodiment 36, in which the diffuser comprises a serpentine channel.
Embodiment 38 is directed to embodiment 36 or 37, in which the diffuser comprises a porous material.
Embodiment 39 is directed to a system comprising a print bar configured to receive multiple print heads, the print heads configured to print a liquid onto a substrate; and a gas flow module configured to provide a flow of gas through a gap between the a bottom surface of each print head and the substrate in a direction corresponding to a motion of the substrate relative to the print head.
Embodiment 40 is directed to embodiment 39, comprising the multiple print heads attached to the print bar.
Embodiment 41 is directed to embodiment 40, in which the print bar includes a non-printing region between an edge of the print bar and a location on the print bar configured to receive an outermost print head.
Embodiment 42 is directed to any of embodiments 39 to 41, in which the gas flow module comprises an elongated nozzle.
Embodiment 43 is directed to any of embodiments 39 to 42, in which the gas flow module is formed in the print bar.
Embodiment 44 is directed to any of embodiments 39 to 43, in which the gas flow module is configured to inject a gas into the gap.
Embodiment 45 is directed to any of embodiments 39 to 44, in which the gas flow module is configured to apply a suction to the gap.
Embodiment 46 is directed to any of embodiments 39 to 45, in which the gas flow module is a first gas flow module positioned upstream of the print heads, and in which the system includes a second gas flow module positioned downstream of the print heads.
Embodiment 47 is directed to any of embodiments 39 to 46, in which the gas flow module is a first gas flow module configured to inject a gas into the gap, and in which the system includes a second gas flow module configured to apply a suction to the gap.
Embodiment 48 is directed to any of embodiments 39 to 47, in which the gas flow module is configured to provide a flow of gas at a velocity having a uniformity within 20% along a length of the print bar.
Embodiment 49 is directed to any of embodiments 39 to 48, in which the gas flow module is positioned such that a gas flow path through the gas flow module is lower than a gas flow path through the gap.
Embodiment 50 is directed to any of embodiments 39 to 49, in which the gas flow module is wider than a bottom surface of the print bar.
Embodiment 51 is directed to any of embodiments 39 to 50, in which a lateral edge of the gap is sealed along at least a portion of the print bar.
Embodiment 52 is directed to any of embodiments 39 to 51, in which the system comprises multiple print bars; and multiple gas flow modules, wherein each gas flow module corresponds to one of the multiple print bars.
Embodiment 53 is directed to a method comprising providing a flow of a low density gas through a gap between a bottom surface of a print head and a substrate; and ejecting a liquid through the gap and onto the substrate from multiple nozzles formed in the bottom surface of the print head.
Embodiment 54 is directed to embodiment 53, in which the low density gas comprises helium.
Embodiment 55 is directed to embodiment 53 or 54, in which providing the low density gas comprises flowing the low density gas through the gap.
Embodiment 56 is directed to embodiment 55, comprising flowing the low density gas in a direction corresponding to a motion of the substrate relative to the print head.
Embodiment 57 is directed to embodiment 55 or 56, comprising flowing the low density gas through one or more of an inlet baffle disposed at an entrance to the gap or an outlet baffle disposed at an exit from the gap.
Embodiment 58 is directed to any of embodiments 53 to 57, in which providing the low density gas comprises ejecting the low density gas from one or more gas nozzles into the gap.
Embodiment 59 is directed to any of embodiments 53 to 58, in which providing the low density gas comprises disposing the bottom surface of the print head in an environment containing the low density gas.
Embodiment 60 is directed to any of embodiments 53 to 59, comprising applying a suction to the gap.
Embodiment 61 is directed to any of embodiments 53 to 60, comprising applying a suction to a back side of the substrate.
Embodiment 62 is directed to any of embodiments 53 to 61, in which providing a flow of gas comprises providing a flow of gas at a velocity of between about 0.25 m/s and about 1.5 m/s in a region of the gap substantially at a midpoint between the bottom surface of the print head and the substrate.
Embodiment 63 is directed to any of embodiments 53 to 62, in which providing a flow of gas comprises providing a flow of gas at a velocity having a uniformity within 20% along a length of the print head.
Embodiment 64 is directed to any of embodiments 53 to 63, in which providing a flow of gas through the gap comprises providing a flow of gas in a first direction through the gap when the print head moves in the first direction relative to the substrate; and providing a flow of gas in a second direction through the gap when the print head moves in the second direction relative to the substrate, the second direction opposite the first direction.
It is to be understood that the foregoing description is intended to illustrate and not limit the scope of the invention, which is defined by the scope of the appended claims. Other implementations are also within the scope of the following claims.
This application is a continuation of and claims the benefit of priority to U.S. patent application Ser. No. 14/748,934, filed on Jun. 24, 2015, which claims priority to U.S. Provisional Application Ser. No. 62/105,413, filed on Jan. 20, 2015; U.S. Provisional Application Ser. No. 62/075,470, filed on Nov. 5, 2014; and U.S. Provisional Application Ser. No. 62/018,244, filed on Jun. 27, 2014, the contents of all of which are incorporated herein by reference in their entirety.
Number | Date | Country | |
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62018244 | Jun 2014 | US | |
62075470 | Nov 2014 | US | |
62105413 | Jan 2015 | US |
Number | Date | Country | |
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Parent | 14748934 | Jun 2015 | US |
Child | 15366500 | US |