Patent Description:
More particularly, the invention relates to detecting the presence of dirt particles leading to abnormal ejection of ink.

During the execution of print processes several faults can disturb the jetting of a nozzle. For example, blocking of an ink nozzle due to the presence of a dirt particle is one of the most common causes of malfunction in ink jetting.

However, it remains an unsolved problem being able to determine whether the malfunctioning is caused by the presence of a dirt particle originated outside the nozzle (e.g. paper dust, an outside particle causing malfunctioning due to bad wiping, etc.), or by the presence of a dirt particle originated inside the ink channel (e.g. caused by a poor print head assembly, large ink pigment accumulation, etc.). This is important because when a dirt particle is located inside the ink channel it is difficult to remove said particle by purging the ink out and wiping the nozzle. Therefore, an accurate differentiation allows skipping this step, thereby reducing ink waste.

Also, the invention allows detecting dirt/debris entering through the ink path of the printer, which may be caused by other elements of the printer in said ink path (as for example plastic debris from an improperly placed combination of ink stirrer - plastic ink jar).

As a consequence, it is desired to have a method for detecting the presence of dirt particles in an inkjet print head that is further capable of distinguishing the location of the dirt particle such that appropriate countermeasures can be applied.

<CIT> discloses a method of detecting a malfunctioning state of a piezoelectric printhead by measuring the residual pressures.

In an aspect of the present invention, a method of operating a droplet ejection device according to claim <NUM> is provided. In another aspect of the present invention, a droplet ejection device is provided.

In an embodiment, the present invention relates to a method for detecting an operating state of an ejection unit during the printing of an object of a print job comprising one or more objects, wherein the ejection unit is arranged to eject droplets of a liquid and comprises a plurality of nozzles, a liquid duct connected to the nozzle, and an electro-mechanical transducer arranged to create an acoustic pressure wave in the liquid in the duct. Said method comprises a step of actuating the electro-mechanical transducer, and subsequently sensing the residual pressure wave that was generated in the liquid.

Then, the resonance frequency of the sensed residual pressure wave is measured, and it is determined whether the ejection unit is in an operative state or in a malfunctioning state based upon whether the difference between the measured resonance frequency of the residual pressure wave and the resonance frequency of a reference residual pressure wave of a correctly functioning ejection unit exceeds a resonance frequency threshold amount.

if it is determined in previous step that the ejection unit is in a malfunctioning state, measuring the energy of the sensed residual pressure wave and determining that the ejection unit is in a malfunctioning state due to first cause if the measured energy of the residual pressure wave is lower than the energy of a reference residual pressure wave of a correctly functioning ejection unit at least an energy threshold amount, and is in a malfunctioning state due to a second cause if the measured energy of the residual pressure wave is higher than the energy of a reference residual pressure wave of a correctly functioning ejection unit at least an energy threshold amount.

Further, the method of the present invention comprises additional steps if it is determined in the previous steps that the ejection unit is in a malfunctioning state. In said case, the energy of the sensed residual pressure wave is measured. Said measurement can be performed before, subsequently or simultaneous to the above mentioned measurement of the resonance frequency of the sensed residual pressure wave. Once this determination has been performed, the method of the present invention determines, that the ejection unit is in a malfunctioning state due to first cause if the measured energy of the residual pressure wave is lower than the energy of a reference residual pressure wave of a correctly functioning ejection unit at least an energy threshold amount, and is in a malfunctioning state due to a second cause if the measured energy of the residual pressure wave is higher than the energy of a reference residual pressure wave of a correctly functioning ejection unit at least an energy threshold amount.

In the same embodiment, the method of the present invention determines that the first cause of malfunctioning is the presence of a dirt particle inside the duct, and that the second cause of malfunctioning is the presence of a dirt particle at/inside the nozzle. In this way, the present invention is capable of distinguishing between different causes if malfunctioning, and is therefore capable of implementing adequate countermeasures: stopping the printing processes when the cause of malfunctioning is the presence of a dirt particle inside the duct, and purging and wiping when the cause of malfunctioning is the presence of a dirt particle at/inside the nozzle. A person skilled in the art would readily understand that the latter countermeasure would be ineffective when the cause of malfunctioning is the presence of a dirt particle inside the duct, and purging and wiping in said case would only lead to in waste. As a consequence, the method of the present invention allows determining the most adequate measure to counteract a detected malfunctioning.

In an embodiment, the present invention further comprises a step of determining the location of a dirt particle within the length of the duct.

In an embodiment, the present invention further comprises a step of determining the percentage of the duct blocked by the dirt particle.

In an embodiment, the present invention performs the step of determining the percentage of the channel area of the duct blocked by the dirt particle when it is determined that the ejection unit is in a malfunctioning state due to a first cause based upon the amount that the measured energy of the residual pressure wave is higher than the energy of a reference residual pressure wave of a correctly functioning ejection unit.

In an embodiment, the present invention comprises a software product comprising program code on a machine-readable non-transitory medium, the program code, when loaded into a processor of the droplet ejection device of the present invention, causes the processor to perform a method of the present invention.

In an embodiment, the present invention also comprises a droplet ejection device comprising a number of ejection units arranged to eject droplets of a liquid and each comprising a nozzle formed in a nozzle face, a liquid duct connected to the nozzle, and an electro-mechanical transducer arranged to create an acoustic pressure wave in the liquid in the duct, characterized in that at least one of the number of ejection units is associated with a processor configured to perform any of the methods of the present invention.

Lastly, in an embodiment the present invention comprises a printing system comprising the droplet ejection device of the present invention, and a software product comprising program code on a machine-readable non-transitory medium, the program code, when loaded into a control unit of the printing system according the present invention, causes the control unit to perform the method according to any of the embodiments of the present invention.

The present invention will become more fully understood from the detailed description given below, and the accompanying drawings which are given by way of illustration only, and are thus not limitative of the present invention, and wherein:.

The present invention will now be described with reference to the accompanying drawings, wherein the same or similar elements are identified with the same reference numeral.

A single ejection unit of an ink jet print head is shown in <FIG>. The print head constitutes an example of a droplet ejection device according to the invention. The device comprises a wafer <NUM> and a support member <NUM> that are bonded to opposite sides of a thin flexible membrane <NUM>.

A recess that forms an ink duct <NUM> is formed in the face of the wafer <NUM> that engages the membrane <NUM>, e.g. the bottom face in <FIG>. The ink duct <NUM> has an essentially rectangular shape. An end portion on the left side in <FIG> is connected to an ink supply line <NUM> that passes through the wafer <NUM> in thickness direction of the wafer and serves for supplying liquid ink to the ink duct <NUM>.

An opposite end of the ink duct <NUM>, on the right side in <FIG>, is connected, through an opening in the membrane <NUM>, to a chamber <NUM> that is formed in the support member <NUM> and opens out into a nozzle <NUM> that is formed in a nozzle face <NUM> constituting the bottom face of the support member.

Adjacent to the membrane <NUM> and separated from the chamber <NUM>, the support member <NUM> forms another cavity <NUM> accommodating a piezoelectric actuator <NUM> that is bonded to the membrane <NUM>.

An ink supply system which has not been shown here keeps the pressure of the liquid ink in the ink duct <NUM> slightly below the atmospheric pressure, so as to prevent the ink from leaking out through the nozzle <NUM>.

The nozzle face <NUM> is made of or coated with a material which is wetted by the ink, so that adhesion forces cause a pool <NUM> of ink to be formed on the nozzle face <NUM> around the nozzle <NUM>. The pool <NUM> is delimited on the outward (bottom) side by a meniscus 32a.

The piezoelectric transducer <NUM> has electrodes <NUM> that are connected to an electronic circuit that has been shown in the lower part of <FIG>. In the example shown, one electrode of the transducer is grounded via a line <NUM> and a resistor <NUM>. Another electrode of the transducer is connected to an output of an amplifier <NUM> that is feedback-controlled via a feedback network <NUM>, so that a voltage V applied to the transducer will be proportional to a signal on an input line <NUM> of the amplifier. The signal on the input line <NUM> is generated by a D/A-converter <NUM> that receives a digital input from a local digital controller <NUM>. The controller <NUM> is connected to a processor <NUM>.

When an ink droplet is to be expelled from the nozzle <NUM>, the processor <NUM> sends a command to the controller <NUM> which outputs a digital signal that causes the D/A-converter <NUM> and the amplifier <NUM> to apply an actuation pulse to the transducer <NUM>. This voltage pulse causes the transducer to deform in a bending mode. More specifically, the transducer <NUM> is caused to flex downward, so that the membrane <NUM> which is bonded to the transducer <NUM> will also flex downward, thereby to increase the volume of the ink duct <NUM>. As a consequence, additional ink will be sucked-in via the supply line <NUM>. Then, when the voltage pulse falls off again, the membrane <NUM> will flex back into the original state, so that a positive acoustic pressure wave is generated in the liquid ink in the duct <NUM>. This pressure wave propagates to the nozzle <NUM> and causes an ink droplet to be expelled. The pressure wave will then be reflected at the meniscus 32a and will oscillate in the cavity formed between the meniscus and the left end of the duct <NUM> in <FIG>. The oscillation will be damped due to the viscosity of the ink. Further, the transducer <NUM> is energized with a quench pulse which has a polarity opposite to that of the actuation pulse and is timed such that the decaying oscillation will be suppressed further by destructive interference.

The electrodes <NUM> of the transducer <NUM> are also connected to an A/D converter <NUM> which measures a voltage drop across the transducer and also a voltage drop across the resistor <NUM> and thereby implicitly the current flowing through the transducer. Corresponding digital signals S are forwarded to the controller <NUM> which can derive the impedance of the transducer <NUM> from these signals. The measured electric response (current, voltage, impedance, etc.) is signaled to the processor <NUM> where the electric response is processed further.

As explained above, the presence of dirt particles may be a recurrent cause of malfunctioning in print heads as the one shown in <FIG>.

For example, said malfunctioning can be caused by the presence of a dirt particle whose origin is outside the nozzle <NUM>. A person skilled in the art would readily understand that there are several different causes for the presence of this type of particle, as for example debris from the printed media, a particle originated in the wiper, etc..

Alternatively, said malfunctioning can be caused by the presence of a dirt particle whose origin is inside ink duct <NUM> or ink supply line <NUM>, namely dirt or debris which entered through the ink path of the printer. Typical examples are blockages caused by dirt from the print head assembly, large impurities created by pigment accumulation, the presence of residual glue, etc..

In <FIG>, the <NUM>-D geometry of a wave model for an ink channel in shown. One of the sides <NUM> of the ink channel is connected to the ink reservoir, while the nozzle <NUM> is located in the opposite side of the ink channel. A piezoelectric actuator <NUM>, also known as piezoelectric transducer, is present on the ink channel.

As explained above, when an actuation pulse is generated and applied to the piezoelectric actuator an acoustic pressure wave is generated in the liquid ink in the ink channel. This pressure wave propagates to the nozzle <NUM> and causes an ink droplet to be expelled. <FIG> shows the state of the ink channel when there is no disturbance in the ink channel that could lead to an abnormal ejection of ink, in contrast with <FIG> below. A person of skill in the art would readily understand that it is possible to design different actuation pulses.

In <FIG>, the <NUM>-D geometry of a wave model for an ink channel in shown, in the case in which a blockage is present in the ink channel, caused by the presence of a particle therein. Merely as an example, said blockage occupies <NUM>% of the area. One of the sides 60a of the ink channel is connected to the ink reservoir, while the nozzle 80a is located in the opposite side of the ink channel. A piezoelectric actuator 70a is present on the ink channel.

The presence of a blockage in the ink channel is likely to cause abnormal functioning behavior when ink is jetted though the nozzle. More specifically, when the blockage occupies a significant part of the ink channel, it is inevitable that the jetting behavior is adversely affected. It has been observed that when a blockage occupies between a <NUM> - <NUM>% of the ink channel droplet quality is affected, as the blockage causes variation in droplet quality: ejection velocity, ejection angle, etc. Said adverse affection may consist in the nozzle being unable to jet ink in the proper direction (e.g. side shooting nozzles), spurting ink partially contaminated with debris which would inevitably lead to undesired artifacts in the printed image, or the nozzle not being able to jet ink at all leading to a blank in the printed image.

Next, <FIG> shows the main variables than have been measured in the residual acoustic pressure wave in the liquid in the duct <NUM> generated when ink is jetted from a nozzle. The four graphs from top to bottom relate respectively to the behavior of the resonance frequency (defined as the resonance frequency of the dominant channel, i.e. the strongest resonance frequency found in the channel), the energy of the residual pressure wave, the dampening factor of the residual pressure wave, and the phase of the residual pressure wave, depending upon the position within the ink channel where a blockage is present, as indicated by the lowermost fifth graph.

<FIG> includes a first region <NUM> that spans across the aforementioned graphs. Said region <NUM> corresponds in each graph to the residual pressure wave measured when a blockage is present in the position within the ink channel shown in the lowermost fifth graph, which in the case of first region <NUM> corresponds to a blockage in position five within the ink channel, representing a blockage at the ink inlet side. In said first region <NUM> two different positions within the waveform have been highlighted, namely 430a and 430b. 430a represents the resonance frequency with a blockage occupying a small area of the ink channel, e.g. <NUM>% thereof, while 430a represents the resonance frequency with a blockage occupying a large area of the ink channel, e.g. <NUM>% thereof.

It can be observed that region <NUM>, represents the waveforms measured when there is presence of a dirt particle close to the ink inlet. From left to right the waveforms represent a presence in the same location but with a growing size, with 430c representing a blockage occupying a small area of the ink channel, e.g. <NUM>% thereof, while 430d representing a blockage occupying a large area of the ink channel, e.g. <NUM>% thereof, as can be readily observed in the lowermost graph.

In an embodiment, it is possible determine, at least approximately, the location of a dirt particle within the length of the duct based upon the observations above in regions <NUM> and <NUM> regarding the relative amount in which the resonance frequency and the energy of the residual pressure wave vary. More particularly, it possible to detect the presence of dirt or debris in the nozzle side, due to the significantly high amount of energy than can be detected in the measured residual pressure wave (upwards > <NUM>%).

The resonance frequency of the residual pressure wave measured can be observed in the uppermost graph when a blockage is present in the aforementioned position within the ink channel. It can be observed in region <NUM> that the resonance frequency of the measured residual pressure wave is significantly lower than the resonance frequency 401f of a reference healthy nozzle, which is also shown in the uppermost graph. This deviation in resonance frequency determines that the related ejection unit is in malfunctioning state, more particularly when it is determined that an ejection unit is in a malfunctioning state when the observed deviation exceeds a predetermined threshold. Accordingly, reference waveforms 401e, 401d, and 401p represent respectively the energy, dampening factor, and phase of the measured residual pressure wave.

<FIG> includes a second region <NUM> that spans across the aforementioned graphs. Said region <NUM> corresponds in each graph to the residual pressure wave measured when a blockage is present in the position within the ink channel shown in the lowermost fifth graph, which in the case of first region <NUM> corresponds to a blockage in position eighty five within the ink channel, representing a blockage at the nozzle side.

The resonance frequency of the residual pressure wave measured can be observed in the uppermost graph when a blockage is present in the aforementioned position within the ink channel. It can be observed in region <NUM> that the resonance frequency of the measured residual pressure wave is also significantly lower than the resonance frequency 401f of a reference healthy nozzle, which is also shown in the uppermost graph. This deviation in resonance frequency also determines that the related ejection unit is in malfunctioning state, more particularly when it is determined that an ejection unit is in a malfunctioning state when the observed deviation exceeds a predetermined threshold.

As explained above in relation with <FIG>, a significant deviation in the measured resonance frequency is used in the present invention to determine if an ejection unit is in a malfunctioning state.

It can also be observed in the second graph from the top of <FIG> the behavior of the energy of a residual pressure wave. In region <NUM> it can be observed that the energy of the measured residual pressure wave is significantly lower than the energy 401e of a reference healthy nozzle, which is also shown in the same graph.

Further, it can also be observed in <FIG> the behavior of the energy of a residual pressure wave when the location of a blockage is closer to the nozzles of the ejection unit, which indicates that the particle causing the blockage has its origin outside the nozzle (e.g. paper dust, an outside particle causing malfunctioning due to bad wiping, etc.). This is caused by the typical size of the ink channel, which does not easily allow particles travelling through, causing most of them to deposit close to the nozzle. It can be observed in region <NUM> that in this case, the energy of the measured residual pressure wave is significantly higher than the energy 401e of a reference healthy nozzle, which is also shown in the same graph.

In this way, it is possible to use the characteristics observed in <FIG> to discern whether the malfunctioning is caused by the presence of a dirt particle originated outside the nozzle, or by the presence of a dirt particle originated inside the ink channel (e.g. caused by a poor print head assembly, large ink pigment accumulation, etc.), as is also explained in detail below with reference to the workflow of <FIG>. As mentioned above, it is important being able to make this differentiation because when a dirt particle is located inside the ink channel, it is difficult to remove said particle by purging the ink out and wiping the nozzle. Therefore, an accurate differentiation between both events allows skipping this step, thereby reducing ink waste.

<FIG> shows in its uppermost graph the measured residual pressure wave 501b for a particular blockage together with the residual pressure wave 501a measured from a correctly functioning print head. Namely, the residual pressure wave has been measured, as a mere example, when a blockage of a <NUM>% exists in position <NUM>. In <FIG>, it is to be interpreted that a blockage of a <NUM>% implies that <NUM>% of the channel is blocked. In this way, a blockage of a <NUM>% represented by 502a implies that <NUM>% of the channel is blocked, and therefore, the ejection unit is a functioning properly. In said uppermost graph of <FIG> it can observed that there is a severe reduction in resonance frequency of the residual pressure wave, which indicates that a blockage is present.

<FIG> shows in its lowermost graph a plurality of measured residual pressure waves 502a, 502b, and 502c for different blockages. Residual pressure wave 502a represents the response of a properly functioning ejection unit. On the other hand, residual pressure waves 502b and 502c represent the response when there is a blockage in position <NUM> of respectively <NUM>% (meaning <NUM>% of the ink channel is blocked) and <NUM>% (meaning <NUM>% of the ink channel is blocked). In said lowermost graph of <FIG> it can observed that the observed reduction in resonance frequency of the residual pressure wave is higher when the blockage leaves a smaller effective area for the ink to flow, i.e. there is a bigger blockage in the ink flow.

In the present invention, step S1 comprises actuating the electro-mechanical transducer <NUM> to generate a pressure wave in the liquid.

Subsequently, the residual pressure wave generated in the liquid is sensed in step S2.

Step S3 of the present invention relates to measuring the resonance frequency of the sensed residual pressure wave.

Next, in step S4 the present invention determines whether the ejection unit is in an operative state or in a malfunctioning state based upon the difference between the resonance frequency of the sensed residual pressure wave and the resonance frequency of a reference residual pressure wave of a correctly functioning ejection unit, wherein the ejection unit is determined to be in a malfunctioning state when the measured resonance frequency of the residual pressure wave is lower than the resonance frequency of a reference residual pressure wave of a correctly functioning ejection unit at least a resonance frequency threshold amount.

If FγREF is the reference resonance frequency and Fγ(i) is the measured resonance frequency for a properly functioning ejection unit, the relative deviation in the resonance frequency with respect to the reference can be defined based upon the following equation: <MAT>.

It has been observed that when based on the above equation -<NUM>% < ΔFγ (i) < <NUM> the jetting capacity of the ejection unit is not affected. In turn, when - <NUM>% < ΔFγ (i) < - <NUM>% it has been determined that the blocked area of the ink channel lies between a <NUM> - <NUM>% which can be regarded as a soft blockage in the ink channel leading to jetting inaccuracies. Further, when ΔFγ (i) < - <NUM>% it has been determined that the blocked area of the ink channel lies between a <NUM> - <NUM>% which can be considered a blocked ink channel leading to incorrect jetting behavior, which will inevitably have detrimental effects in the printing quality.

Step S5 of the present invention relates to steps taken if it is determined in step S4 that the ejection unit is in a malfunctioning state. A first step comprises measuring the energy of the sensed residual pressure wave, and subsequently determining that the ejection unit is in a malfunctioning state due to a first cause if the measured energy of the residual pressure wave is lower than the energy of a reference residual pressure wave of a correctly functioning ejection unit at least an energy threshold amount, and is in a malfunctioning state due to a second cause if the measured energy of the residual pressure wave is higher than the energy of a reference residual pressure wave of a correctly functioning ejection unit at least an energy threshold amount.

It can be observed with reference to <FIG> that malfunctioning state due to a second cause can be detected by observing deviations in the measured energy of the residual pressure wave. When the deviations in measured energy are smaller than <NUM>% with respect to the reference energy measured in a properly functioning print head, it can be assumed that the energy threshold amount condition is not met. A person of skill in the art would readily understand that depending upon print head design said threshold may vary, such as <NUM>% or <NUM>%.

In a particular embodiment, said first cause of malfunctioning is the presence of a dirt particle inside the duct <NUM>, while the second cause of malfunctioning is the presence of a dirt particle at/inside the nozzle <NUM>.

A person of skill in the art would readily understand that the group of steps S3 and S4 and the group of steps S5 and S6 can be performed in different order. It is possible to perform the determinations of steps S5 and S6 related to determining whether there have been significant changes in the energy of a residual pressure wave generated before the determinations in steps S3 and S4. Also, a person of skill in the art would readily recognize that both groups of steps can be performed concurrently.

Claim 1:
A method for detecting an operating state of an ejection unit during the printing of an object of a print job comprising one or more objects, wherein the ejection unit is arranged to eject droplets of a liquid and comprises a plurality of nozzles (<NUM>), a liquid duct (<NUM>) connected to a nozzle (<NUM>), and an electro-mechanical transducer (<NUM>) arranged to create an acoustic pressure wave in the liquid in the duct (<NUM>), the method comprising the steps of:
a) actuating the electro-mechanical transducer (<NUM>) to generate a pressure wave in the liquid;
b) sensing a residual pressure wave in the liquid;
c) measuring a resonance frequency of the sensed residual pressure wave;
d) determining whether the ejection unit is in an operative state or in a malfunctioning state, wherein the ejection unit is determined to be in a malfunctioning state when the difference between the measured resonance frequency of the residual pressure wave and the resonance frequency of a reference residual pressure wave of a correctly functioning ejection unit exceeds a resonance frequency threshold amount; and
e) if it is determined in step d) that the ejection unit is in a malfunctioning state, measuring the energy of the sensed residual pressure wave and determining that the ejection unit is in a malfunctioning state due to the presence of a dirt particle inside the duct (<NUM>) if the measured energy of the residual pressure wave is lower than the energy of a reference residual pressure wave of a correctly functioning ejection unit by at least an energy threshold amount, and is in a malfunctioning state due to the presence of a dirt particle at/inside the nozzle (<NUM>) if the measured energy of the residual pressure wave is higher than the energy of a reference residual pressure wave of a correctly functioning ejection unit by at least an energy threshold amount.