The present invention relates to a liquid projection apparatus in the form of what is known as a ‘face-shooter’ array.
In our previous application WO 93/10910 we describe a device for projecting droplets from a nozzle that is excited to project liquid therefrom.
In our previous application WO 99/54140 we describe a device and method for projecting liquid as jets or droplets from multiple nozzles formed in a material layer. The nozzles are formed in a transducer that incorporates a finger with liquid being supplied to an inner end of the nozzles. By continuously stimulating excitation of the finger motion at a certain frequency, the nozzle will eject a continuous droplet stream from an outer end of the nozzle.
Such devices as described above can be operated in a so called ‘drop on demand’ mode. A problem arises when the frequency at which drop on demand ejection can be made from a device is limited by the time it takes for the motion of the material layer to decay to a level where it does not significantly affect the next ejection.
U.S. Pat. No. 5,903,286 discusses how in order to avoid the above problem by applying pulse signals to an electrode of an ink channel. In this way, pressure waves in a liquid filled chamber behind the material layer can be cancelled. However, in the type of device described in WO 93/10910 and WO 99/54140 there is no local chamber and hence no reflected pressure waves of the type found in U.S. Pat. No. 5,903,286.
EP 0752312 describes an inkjet printhead that ejects ink by changing the volume in an ink channel such that an ink droplet is expelled from a nozzle. However, it does not describe ejecting droplets by exciting the nozzles themselves.
It is an aim of the present invention to increase the frequency at which ejection can occur by cancelling the residual motion in the material layer itself.
According to the present invention, there is provided a method of projecting liquid as jets or droplets from a nozzle provided on a transducer formed by a region of a material layer, the method comprising the steps of:
supplying liquid to an inner end of the nozzle;
exciting the nozzle with a transducer, to cause movement of the nozzle in a direction substantially aligned with the nozzle axis in order to project liquid as a droplet from an outer face of the nozzle;
wherein the step of exciting the nozzle comprises sequentially driving the transducer with a first rising voltage change, a first falling voltage change, a second rising voltage change and a second falling voltage change;
and wherein the first rising voltage change and the first falling voltage change are timed so that they enhance the movement of the material layer, and the second rising voltage change and the second falling voltage change are timed so that they substantially cancel the movement of the material layer.
By timing the voltage changes which excite the material layer, the movement of the material layer can be substantially cancelled. This allows droplets to be ejected at a higher frequency because the device is not limited by the time it takes for the motion of the material layer arising from a first ejection to naturally decay to a level where it does not significantly affect the second ejection.
Preferably, the movement of the material layer following any edge is mono-modal.
Preferably, the duration between the first rising voltage change and the first falling voltage change is half a period of the movement of the material layer.
Preferably, the midpoint in time between the first rising voltage change and the first falling voltage change is 1.5 periods of the movement of the material layer before the midpoint in time between the second rising voltage change and the second falling voltage change such that the combination of the voltage changes and the damping of the device substantially cancel the motion of the material layer.
Multiple re-inforcing voltage changes may be applied to cause ejection of a number of droplets, followed by multiple cancelling voltage changes to substantially stop the motion of the material layer.
Examples of the invention will now be described with reference to the accompanying drawings, in which:
a, b, c, d illustrate plan views of four further examples;
a is a cross-section of the device, illustrating a patterned surface provided at the rear of the transducers;
b is a cross-section of the device, illustrating a surface with rigid and compliant surfaces provided at the rear of the transducers;
a is a cut-away isometric view of the device, illustrating rigid walls provided between adjacent transducers in combination with a rigid backplane;
b is a cut-away isometric view of the device, illustrating rigid walls provided between adjacent transducers;
c is a plan view of the device, illustrating rigid walls provided between adjacent transducers;
a-d illustrate examples in plan view, of variation in slot width between transducers;
a is a plan view of the device, illustrating a compliant surface provided at the rear of the transducers;
b is a cross-section view of
a-i illustrates the effect of different drive signals on the motion of the material layer;
One example embodiment, which has been reduced to practice, of a single transducer of the overall array device, is shown in plan view in
In this example as an operating liquid projection device, material layer 100 is electroformed Nickel of 60 microns thickness and bearing a nozzle of exit diameter 20 microns. The slots 10 were formed by electroforming and are of width 40 microns; the slot length is 6 mm, and the distance between the centres of adjacent slots 10 is 254 microns. The piezoelectric components 7 have width 214 microns, and are formed of piezoelectric ceramic 5H sourced from CTS providing high piezoelectric constants and mechanical strength. The electrode material applied to said piezoelectric components 7 was sputtered Nickel gold of thickness in the range 2-5 microns. In this example the piezoelectric material was mounted between the material layer 100 and the substrate 101. The material layer 100 was bonded to the piezoelectric material 7 and the piezoelectric material 7 was bonded to the substrate 101 using Epotek 353 supplied by Promatech. Electrical connections were made to the piezoelectric material 7 via the material layer 100 and the substrate 101.
By stimulating excitation with only one or a discrete number of such cycles the device ejects droplets ‘on demand’ i.e. responsive to that short droplet-projection pulse or pulse train, and ceasing after that pulse train ceases. The device described above was operated with a drive voltage of 100V peak to peak and with a base frequency of 46.6 kHz. This device yielded a maximum ‘on-demand’ ejection frequency of 10 kHz. With other devices of this general form, on-demand ejection has been observed with a drive voltage of 40V peak-to-peak. The electrical signals required to drive the device can be derived from a number of means such as an array of discrete device drivers or from an ASIC.
This liquid projection apparatus whose fabrication was described above was mounted onto a manifold to provide liquid supply means and in proximity to printing media to form a system suitable for ink-jet printing. Using water-based ink, at a supply bias pressure from 0 to 30 mbar below atmospheric pressure, the device was demonstrated operating in drop on demand mode. It was found experimentally that no sealant was needed in order to prevent egress of fluid from the slots.
The experimental measurement of the motion of the device of
In alternative constructions for the example of
Being substantially isolated by slots 10 and by the substrate 101, arrays of such transducers allow substantially independent control of drop ejection from an array liquid projection device such as an ink-jet printhead.
a, 6b, 6c and 6d illustrate optional constructions wherein multiple nozzle-bearing transducers 9 are formed within the material layer 100, their lateral extent being defined by the slots 10. Each such transducer bears a nozzle 13 through layer 100.
The “characteristic dimension of the material layer” is defined as the smallest dimension of a region of the material layer, which is normal to the direction of nozzle motion, which is moving substantially in phase.
In an example of the device type such as those illustrated in
A rigid surface 20 may be provided substantially parallel to the moving material layer 100 and at a distance D behind the inner face of the moving material layer as shown in
As noted above, pressure is generated in the fluid through the impulse of the moving material layer. By increasing the impulse applied to the fluid, for a given motion of the material layer, the rate of fluid flow through the nozzle 13 is increased. Therefore, increasing the impulse applied to the fluid by the material layer for a given motion of the material layer reduces the motion of the material layer that is required in order to eject liquid droplets.
In order to increase the impulse applied to the fluid by the material layer, the distance D should be comparable to or smaller than the characteristic dimension of the material layer, L.
Without the rigid surface 20, or with a rigid surface 20 at a distance D from the material layer where D>>L, for example D ten times greater than L, the pressure behind the material layer is proportional to the characteristic dimension L of the material layer. When a rigid surface 20 is placed at a distance D from the material layer where D is much less than L, for example D equal to half L or less, then the pressure generated by motion of the material layer is proportional to L2/D. At intermediate distances the pressure generated by the same motion of the material layer will vary with L in a manner between L and L2/D.
In a second example, the rigid surface 20 is patterned as shown in
Crosstalk can be defined as being the amount that an ejection event is changed (typically a change in the velocity or volume of an ejected drop) by the presence of an ejection event from a neighbouring nozzle. Consider two adjacent independently actuated regions of material layer each with a nozzle 13, material layer region A and material layer region B. If material layer region B is driven in isolation with fixed drive conditions, pressure is generated behind material layer region B to cause ejection. If both material layer regions A and B are simultaneously driven to cause ejection, then the pressure under both material layer regions A and B will be changed slightly by the motion of the adjacent material layer region compared to that when they are driven in isolation. This small pressure change behind each material layer region results in a change in the drop volume and/or drop velocity of the drop ejected by each material layer region compared to that when it is driven alone. This change is the crosstalk between material layer region A and material layer region B. The crosstalk will thus be reduced if the ratio of the pressure generated behind material layer region B due to the motion of material layer region B to the additional pressure generated behind material layer region B due to the motion of material layer region A is increased. Placing a rigid surface behind each material layer region A and B increases the pressure behind material layer region B due to the motion of material layer region B. The pressure behind region B is increased by a larger ratio than the increase in the additional pressure behind material layer region B that results from the motion of material layer region A. This is a result of the additional pressure generated being dissipated in the gaps between the rigid surfaces. Thus placing a rigid surface behind each material layer region reduces the fluidic crosstalk.
In a third example shown in
Rigid side walls 21 can also be placed, between the transducers, extending along the length of the transducer, as illustrated in
The rigid side walls 21 may also be placed without the rigid surface 20 as shown in
In order not to introduce mechanical crosstalk between adjacent transducers, the rigid walls are isolated from the material layer, i.e. they are not mechanically engaged with the material layer.
The rigid surface 20 and side walls 21 do not form a chamber that contains the ink, as the ink is still free to flow in the direction that is not bounded by any walls or surfaces. For example, in
The width of the slot 10 between adjacent transducers 9 can be varied along the length of the transducer as shown in
By increasing the slot width in some regions along the length of the slot 10, spatial crosstalk is reduced between the transducers. It is desirable to reduce crosstalk so that the motion of one nozzle-bearing transducer 9, when excited to eject liquid from its associated nozzle 13, does not cause substantial pressure fluctuations in liquid that is adjacent to nozzle-bearing regions of other transducers. The definition of crosstalk is discussed in relation to
The pressure that is transmitted, by a moving material layer region to the fluid behind a neighbouring material layer region, is reduced by the action of the air liquid interface in the slot, which acts as a pressure absorbing surface. By increasing the width of the slot 10 between two neighbouring material layer regions, the amount of pressure absorbed by the air liquid interface is increased. The pressure absorbing surface could also be a surface that has a low bending stiffness and low inertia and is therefore able to respond during the time scale with which the pressure in the fluid is created and removed, thus absorbing some of the pressure. For instance, the slot could be covered with a compliant membrane.
In the examples shown in
It is not so advantageous simply to increase the width of the slot along the whole length of the transducer as this will also narrow the finger width. A narrow finger means that the motion required for ejection is increased. Therefore, the slots are widened at a distance away from the nozzle as illustrated in
As illustrated in
The amount of pressure that is transmitted through the fluid behind the transducers 9 is reduced because the compliant surface 30 acts as a pressure absorbing surface.
A compliant surface is defined as a surface that will move in response to the pressure induced in the fluid on a timescale sufficiently short that it significantly reduces the pressure in the fluid next to the compliant surface compared to the pressure at that point when the compliant surface is replaced with a bulk region of fluid. The compliant surface 30 could be a compliant membrane, with air behind it, or it could be a soft foam, or it could be a liquid air interface.
One example of a compliant surface as part of an ejecting device is shown in
In this example the device is similar in construction to that shown in
In a further example shown in
The frequency at which drop on demand ejection can be made from a device is limited by the time it takes for the motion of the ejection system to decay to a level where it does not significantly affect the next ejection. If a device is made so that its motion is primarily mono-modal following a single voltage change, the motion can be built up and then cancelled by applying voltage changes at suitable times. Thus a lower voltage can be used to achieve a desired amplitude of motion and this motion can be stopped allowing the drop on demand frequency to be increased. If the device is not mono-modal and so energy is transferred into other modes then, in general, it is not possible to construct a signal that will successfully cancel the motion of the device in a small number of cycles of the dominant mode.
The device can be described as mono-modal when, following a single voltage change, the maximum velocity of the material layer due to the first order mode is significantly larger than the maximum velocity of the material layer due to higher order modes. Preferably the initial velocity of the device due to the first order mode is more than twice the velocity due to higher order modes. More preferably it is greater than four times the velocity due to higher order modes. This can be achieved by selecting a suitable ratio between the length of the piezoelectric actuator and the transducer length.
For example consider the device shown in
In order to drive such a device, rising and falling voltages are applied that reinforce the motion and thus reduce the voltage that is required to achieve a given amplitude. These voltage changes can be used to produce motion that cause one, two or many drops to be ejected. Following the ejection of the last drop that is required, the motion of the device can be stopped or significantly reduced by applying one, two or more voltage changes that are timed so as to cancel the motion of the device. This is desirable for two reasons. Firstly the frequency at which drop on demand ejection can be made from a device can be increased, as active motion cancellation can be achieved more rapidly than allowing the motion to decay to a level where it does not significantly affect the next ejection. Secondly if the motion of the device is not significantly reduced by applying a suitable signal then the ensuing motion may cause undesired drops to be ejected.
One example of such a drive scheme is shown in
Because the device is mono-modal, the further voltage changes 42 and 43 can be applied to cancel the motion of the device. Such active cancellation of the motion reduces or removes motion of the material layer in substantially less time than would be the case if the motion is simply allowed to decay. This significantly reduces the delay time before a further series of voltage changes can be applied to initiate the next ejection event. With this drive scheme the drop on demand ejection frequency can be increased to up to a half of the resonant frequency of the device for ejection where the motion of the transducer is cancelled prior to initiating the motion required to eject the next droplet.
a-e illustrate the effect of changing the timings between the four voltage changes. The material layer has a resonant frequency and associated period p and this is shown by line 400 in
In a preferred embodiment, a first falling voltage change 44b is timed to be a time p/2 after the first rising voltage change 44a so that the motion from these two voltage changes is reinforced. The motion of the material layer will be stopped if the following two conditions are met. The first condition is that the midpoint in time between the second rising voltage change 44c and the second falling voltage change 44d is 1.5 periods of the movement of the material layer after the midpoint in time between the first rising voltage change 44a and the first falling voltage change 44b. The second condition is that the second falling voltage change 44d is placed at a suitable time after the second rising voltage change 44c. In the theoretical case of a device with insignificant damping, the second falling voltage change 44d should be placed at a time p/2 after the second rising voltage change 44c in order to cancel the motion, as in the case of a device with insignificant damping, the motion of the material layer will continue with no decay of motion until the third and fourth voltage changes, This is illustrated in
In a device where damping is significant, the time between the second rising voltage change 44c and the second falling voltage change 44d needs to be altered in order to cancel the motion of the material layer. In particular, the gap between the second rising voltage change 44c and the second falling voltage change 44d must be increased or decreased to detune these edges to compensate for the amplitude already lost owing to the damping of the material layer.
The damping causes a reduction in amplitude with time, and whilst in order to induce the maximum motion to the material layer the first rising voltage change will occur at time t=0 and the first falling edge should still occur at t=p/2, in the same way as an undamped device, the second rising voltage change and second falling voltage change are at t >3p/2 and t<2p respectively or at t<3p/2 and t>2p respectively to compensate for the fact that the induced motion has been reduced by the damping. The case where the second rising voltage change and second falling voltage change are at t>3p/2 and t<2p respectively is illustrated in
It is also possible to reduce the amplitude of motion of the material layer by increasing or decreasing the time between the first two voltage changes 40 and 41.
In
The motion of the material layer represented by line 46e can be cancelled as described above, by applying a second rising voltage change 46c and a second falling voltage change 46d. The second rising voltage change occurs at one and a half resonant periods after the first voltage change 46a, and the second falling voltage change 46d occurs at the same time interval after the second rising voltage change 46c as the time period between the first rising 46a and falling 46b voltage changes.
a illustrated the how the timings of the voltage changes are arranged to cancel the motion of the material layer for a damped and an undamped device.
c shows the voltage changes and response of the material layer for an undamped device at maximum amplitude. It also shows voltage changes 47a, 47b, 47c and 47d that are required to achieve reduced motion 47e in a damped device.
First rising voltage change 47a and first falling voltage change 47b occur at the same time as voltage changes 46a and 46b. In other words, whether the device is damped or not has no bearing on when the first rising and falling voltage changes are applied to achieve a reduction in amplitude of the material layer.
To cancel the motion shown by line 47e, a second rising voltage change 47c occurs at a time t>3p/2 and a second falling voltage change 47d occurs at t<2p to compensate for the fact that the induced motion has been reduced by the damping, as described in relation to
Longer sequences of reinforcing and cancelling edges can be used to eject a number of droplets at resonant frequency prior to stopping the motion. An example of such a drive scheme is shown in
The residual motion of the material layer after the cancellation pulses is a combination of any other modes of the device, the error in how accurately the decay constant is known and the error in how accurately the resonant frequency of the device is known. The amount of residual motion is less sensitive to errors in how accurately the frequency is known when the damping coefficient is larger. Thus in order to reduce this sensitivity the damping coefficient could be raised. This could be achieved in a number of ways for example: (i) bonding a lossy material to one surface of the actuator or material layer; (ii) making the material layer out of a lossy material; and (iii) placing a rigid surface close to, but not in contact with, a portion of the ink side of the material layer or actuator, there by creating a small gap which is lossy as fluid is forced in and out of the gap by the motion of the material layer.
When a first finger is driven to cause ejection of its associated nozzle, the neighbouring fingers also induced to move slightly. If the neighbouring fingers are driven in order to cause ejection from their associated nozzles at some later time, then the ejection velocity will be altered if those neighbouring fingers still have some residual motion before they are driven. This means that the neighbouring finger cannot be used for a certain period after the first finger has been driven, while the induced motion is allowed to decay. This restricts the ejection speed that can be achieved.
f illustrates this effect. A drive voltage scheme as shown in
g, 16h and 16i show how a drive signal is applied to a neighbouring finger in order to cancel the motion that it is induced in it.
If the fluid to be ejected is treated as being incompressible, the cancelling pulse 50c, 50d must be centred around the time 3/4p, 7/4p or 11/4p after the centre of the first pulse 44a, 44b. In practice the compressibility of the fluid will mean that the cancelling pulse 50c, 50d will need to be fractionally later than this, by a duration whose magnitude is of the order of the time taken for a compressible pressure wave to propagate from the ejecting finger to the neighbouring finger through the liquid on the inner face of the material layer, where compressible pressure waves travel for example in aqueous fluids at around 1000 meters per second. The duration of the pulse will depend on the geometry of the system and the damping coefficient of the fingers.
The motion with which finger 13b moves, if nozzle 13b is ejecting liquid at the same time as nozzle 13a, will not need to be as great as the motion required if nozzle 13b is ejecting alone.
The increase in pressure under a region of material layer as a result of the pressure generated under a neighbouring material layer region is shown in
It is desirable to ensure that the properties of the drop ejected from a nozzle 13 such as drop volume and velocity are independent of whether or not drops are ejected by neighbouring nozzles. This is achieved by adjusting the motion of the material layer surrounding the ejecting nozzle in such a way so as to compensate for the motion of the material layer surrounding neighbouring nozzles.
In order to compensate for the pressure produced by the motion of neighbouring regions of material layer, the motion of a finger is reduced when neighbouring fingers are also ejecting. This can be achieved either by changing the voltage of the drive scheme or by changing the degree to which the driving voltage changes reinforce the material layer motion. In both cases, compensation can be applied either using pre-determined variations in the drive scheme, or using feedback from a sensor.
A nozzle may have more than two neighbouring nozzles, for instance the nozzles may be provided in a two-dimensional array. In this case, if say a first nozzle has three neighbouring nozzles which are simultaneously ejecting, the amplitude of motion of the finger associated with the first nozzle is reduced even further than when only one (or two) neighbouring nozzle(s) is(are) simultaneously ejecting.
Each of the examples described above could usefully confer benefit in all application fields including, but not restricted to: an inkjet printer, an office printer, to image a printing plate to function as an offset master, to print onto packaging, to directly mark food stuffs, to mark paper for example to generate receipts and coupons, to mark labels and decals, to mark glass, to mark ceramics, to mark metals and alloys, to mark plastics, to mark textiles, to mark or deposit material onto integrated circuits, to mark or deposit material onto printed circuit boards, to deposit pharmaceuticals or biologically active material either directly onto human or animal or onto a substrate, to deposit functional material to form part of an electric circuit, for example to alter or generate an RFID tag, an aerial or a display.
Number | Date | Country | Kind |
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0620218.8 | Oct 2006 | GB | national |
0620219.6 | Oct 2006 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2007/050625 | 10/12/2007 | WO | 00 | 8/9/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/044069 | 4/17/2008 | WO | A |
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