EP1164014A1 - Liquid jet device and liquid jet driving method - Google Patents
Liquid jet device and liquid jet driving method Download PDFInfo
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- EP1164014A1 EP1164014A1 EP00112694A EP00112694A EP1164014A1 EP 1164014 A1 EP1164014 A1 EP 1164014A1 EP 00112694 A EP00112694 A EP 00112694A EP 00112694 A EP00112694 A EP 00112694A EP 1164014 A1 EP1164014 A1 EP 1164014A1
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- European Patent Office
- Prior art keywords
- jet
- liquid
- burst signal
- signal
- vibration exciter
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- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B41—PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
- B41J—TYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
- B41J2/00—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
- B41J2/005—Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by bringing liquid or particles selectively into contact with a printing material
- B41J2/01—Ink jet
- B41J2/135—Nozzles
- B41J2/14—Structure thereof only for on-demand ink jet heads
- B41J2/14008—Structure of acoustic ink jet print heads
Definitions
- the vibration exciter has a first vibration exciter supplied with the jet burst signal and a second vibration exciter supplied with the suppressing signal.
- the jet burst signal and the suppressing signal are supplied for the vibration exciter repeatedly with a second frequency.
- the second frequency is a frequency with which the liquid makes free vibration in a mode specific to the shape of the opening.
- the jet burst signal is supplied for the vibration exciter repeatedly during a period required for a to-and-fro movement of a surface wave in the opening, which is excited on the basis of a radiation pressure to push the liquid out from the opening in a period while the vibration exciter is driven.
- the suppressing signal is a pulse to be supplied in order for the vibration exciter to provide the liquid with a pressure.
- the suppressing signal is supplied at the same cycle as the jet burst signal, the motion of liquid becomes stationary and stable droplets are jetted.
- the second frequency set to be larger than the period while the jet burst signal is supplied, the meniscus of liquid in the opening is retreated towards the side of the vibration exciter, to narrow the width of jetting liquid.
- the hydrostatic pressure applying mechanism by applying the hydrostatic pressure to the liquid so that the meniscus of the liquid reaches the rim of the opening in a waiting state where the liquid is in a stationary state as the jet burst signal is not supplied and reducing the hydrostatic pressure or applying the negative pressure when the jet burst signal is supplied, it is possible to prevent the meniscus from spilling over from the opening. That makes the meniscus stable, and avoids jet failure of the liquid and jetting of large droplets.
- the vibration provided for the liquid on the basis of the jet burst signal also works as the radiation pressure to push the liquid out from the opening in the period. Since the pressure opposite to the radiation pressure is provided for the liquid in the period while the radiation pressure works, the method of the eighteenth aspect can produce the same effect as the method of the thirteenth aspect.
- the vibration exciter 9a has an ultrasonic vibration exciter, for example, a piezoelectric vibrator 92, and further a protection sheet 91 between the body 94 and the piezoelectric vibrator 92, for protecting the piezoelectric vibrator 92 so that it should not be wetted by the ink 30.
- an ultrasonic vibration exciter for example, a piezoelectric vibrator 92
- a protection sheet 91 between the body 94 and the piezoelectric vibrator 92, for protecting the piezoelectric vibrator 92 so that it should not be wetted by the ink 30.
- burst cycle T2 At a value slightly shifted from the time required for the to-and-fro movement of the second surface wave in the opening 95. It falls within correction of burst cycle of this description, however, to adjust the cycle of variation in level of ink 30 due to the second surface wave and the burst cycle T2 for keeping equally the shape of meniscus at the point of time when the jet burst signal 26 is supplied.
- Figs. 21A to 21C are waveform views showing a liquid jet driving technique in accordance with the fifth preferred embodiment of the present invention.
- Fig. 21A shows a timing for supplying the jet burst signal 26
- Fig. 21B shows a timing for supplying the pressure pulse signal
- Fig. 21C shows the center position in the surface of the ink 30 which is exposed in the opening 95.
- the base lines of Figs. 21A to 21C show the same as those of Figs. 19A to 19C. For convenience, it is shown that the negative pressure pulse signal is supplied at the point of time when the pressure pulse signal becomes "L".
- the third to fifth preferred embodiments can be also achieved with the ink head 9 having the structure of Fig. 2 by driving the piezoelectric vibrator 92 with the pressure pulse signal, instead of using the ink head 9 having the structure of Fig. 18.
- providing the pressure pulse generator 96 additionally to the piezoelectric vibrator 92 driven with the jet burst signal 26 is better for easy designing.
- Fig. 23 is a cross section schematically showing the state of meniscus of the ink 30 in a waiting state of the ink head.
- the "waiting state of the ink head” refers to a stationary state where only atmospheric pressure is applied to the ink 30 for a long time.
- the ink 30 is retreated towards the piezoelectric vibrator 92 while keeping wetting against the inner wall of the nozzle plate 93 with surface tension, and the meniscus is out of contact with the rim of the opening 95.
- the jet burst signal 26 when the jet burst signal 26 is supplied from the waiting state of the ink head, it is desirable to provide the ink 30 with the hydrostatic pressure, to push the liquid level of the ink 30 up to the rim of the opening 95, and to reduce the hydrostatic pressure or provide a negative hydrostatic pressure after the jet burst signal 26 is supplied for the piezoelectric vibrator 92.
- the seventh preferred embodiment proposes a control to avoid the state where the meniscus of the ink 30 is out of contact with the rim of the opening 95 while preventing the ink 30 from spilling over from the opening 95. It is possible, however, to control the hydrostatic pressure while keeping the liquid surface of the ink 30 in contact with the rim of the opening 95 also in the state where the ink head is driven at the dot cycle T3, instead of the waiting state of the ink head.
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- Particle Formation And Scattering Control In Inkjet Printers (AREA)
Abstract
Description
- The present invention relates to a technique to drive a liquid jet unit for jetting droplets from a liquid surface, and more particularly to a technique to jet droplets by providing vibration to a liquid having a surface limitedly exposed by an opening.
- There has been a technique of depositing ink onto printing paper in a form of droplet to draw images and characters, i.e., ink jet printing. In this description, for distinction, a term "jet" is used when a plurality of ink droplets are simultaneously generated and a term "discharge" is used when droplets are sequentially generated one by one.
- To faithfully reproduce tone of an image proposed is a technique of ultrasonically providing ink with vibration to obtain droplets from an ink surface. For example, Japanese Patent Application Laid Open Gazette No. 2-303849 discloses a technique of controlling the length of period for continuously providing ink with ultrasound to control the amount of ink to be discharged. Japanese Patent Application Laid Open Gazette No. 10-128968 discloses a technique of providing ink with ultrasonic burst including a certain number of pulses repeatedly a plurality of times to control the amount of ink to be jetted with the repeat number.
- In the technique of controlling the length of period for continuously providing ink with ultrasound to control the amount of ink to be discharged, however, in order to discharge a large amount of ink, it is necessary to provide ink with continuous ultrasonic supply for a long time. That causes a marked rise of the level of ink surface from the opening with a radiation pressure as discussed later, resulting in an unstable discharge of droplets.
- The technique of providing ink with ultrasonic burst repeatedly a plurality of times is superior in not providing continuous radiation pressure. Since the ink jet printing, however, requires depositing of ink on printing paper with different tones for dots, it is necessary to adjust the timing of sending the printing paper and that of disposing ink for every dot. The length of period while no continuous ultrasonic is supplied varies from dot to dot in the technique of providing ink with ultrasonic burst repeatedly a plurality of times as well as in the technique of controlling the length of period for continuously providing ink with ultrasound. Since the length of period while a radiation pressure is provided therefore varies from dot to dot, the rise of ink level from the opening varies from dot to dot. This variation causes an unstable jetting of droplets, and further causes deterioration in graininess in terms of printing quality and difficulty in controlling gradation.
- The present invention is directed to a liquid jet driving device. According to a first aspect of the present invention, the liquid jet driving device comprises: a liquid jet unit having a jet surface provided with an opening to limitedly expose a surface of liquid to be jetted out and a vibration exciter provided on an opposite side to the jet surface with the liquid interposed therebetween for providing the liquid with vibration; and a driving unit for providing the vibration exciter with a suppressing signal and a jet burst signal consisting of a pulse train of a first frequency to drive the vibration exciter. In the device of the first aspect, vibration provided for the liquid by the vibration exciter which is driven with the jet burst signal is sufficient for the liquid to jet out from the jet surface and vibration provided for the liquid by the vibration exciter which is driven with the suppressing signal is not sufficient for the liquid to jet out from the jet surface.
- According to a second aspect of the present invention, in the liquid jet driving device according to the first aspect, the suppressing signal is a suppressing burst signal. consisting of a pulse train of the first frequency and has less pulses in number than the jet burst signal.
- According to a third aspect of the present invention, in the liquid jet driving device according to the first aspect, the suppressing signal is a suppressing burst signal consisting of a pulse train of the first frequency which has a smaller amplitude than those of the jet burst signal.
- According to a fourth aspect of the present invention, in the liquid jet driving device according to the first aspect, the vibration exciter is driven with the jet burst signal to provide the liquid with a first radiation pressure, the liquid makes free vibration caused by the first radiation pressure in a mode specific to the shape of the opening, the suppressing signal is supplied for the vibration exciter near at least one timing when the free vibration takes an amplitude of extreme value, and the vibration exciter is driven with the suppressing signal to provide the liquid with a second radiation pressure which works in a direction to suppress the free vibration.
- According to a fifth aspect of the present invention, in the liquid jet driving device according to the first aspect, the vibration exciter has a first vibration exciter supplied with the jet burst signal and a second vibration exciter supplied with the suppressing signal.
- According to a sixth aspect of the present invention, in the liquid jet driving device according to the fifth aspect, the first vibration exciter is driven with the jet burst signal to provide the liquid with a radiation pressure, the liquid makes free vibration caused by the radiation pressure in a mode specific to the shape and size of the opening, the suppressing signal is supplied for the second vibration exciter near at least one timing when the free vibration takes an amplitude of extreme value, and the second vibration exciter is driven with the suppressing signal to provide the liquid with a pressure which works in a direction to suppress the free vibration.
- According to a seventh aspect of the present invention, in the liquid jet driving device according to the sixth aspect, the suppressing signal is supplied for the vibration exciter at the point of time when a liquid level of the liquid in the opening takes an extreme value near the side of the vibration exciter in the free vibration.
- According to an eighth aspect of the present invention, in the liquid jet driving device according to the fifth aspect, the second vibration exciter is driven with the suppressing signal in a period while the jet burst signal is supplied for the first vibration exciter, to provide the liquid with a pressure having a direction opposite to that of a radiation pressure provided for the liquid by the first vibration exciter driven with the jet burst signal.
- According to a ninth aspect of the present invention, in the liquid jet driving device according to the first aspect, the jet burst signal and the suppressing signal are supplied for the vibration exciter repeatedly with a second frequency.
- According to a tenth aspect of the present invention, in the liquid jet driving device according to the ninth aspect, the second frequency is a frequency with which the liquid makes free vibration in a mode specific to the shape of the opening.
- According to an eleventh aspect of the present invention, in the liquid jet driving device according to the first aspect, the jet burst signal is supplied for the vibration exciter repeatedly during a period required for a to-and-fro movement of a surface wave in the opening, which is excited on the basis of a radiation pressure to push the liquid out from the opening in a period while the vibration exciter is driven.
- According to a twelfth aspect of the present invention, the liquid jet driving device comprises: a liquid jet unit having a jet surface provided with an opening to limitedly expose a surface of liquid to be jetted out and a vibration exciter provided on an opposite side to the jet surface with the liquid interposed therebetween for providing the liquid with vibration; a. driving unit for providing the vibration exciter with a jet burst signal consisting of a pulse train of a predetermined frequency to drive the vibration exciter; and a hydrostatic pressure applying mechanism for applying a controllable hydrostatic pressure to the liquid.
- The present invention is also directed to a method of driving liquid jet. According to a thirteenth aspect of the present invention, the method of driving liquid jet, for driving a liquid jet unit having a jet surface provided with an opening to limitedly expose a surface of liquid to be jetted out and a vibration exciter provided on an opposite side to the jet surface with the liquid interposed therebetween for providing the liquid with vibration, the method comprises the steps of: supplying the vibration exciter with a jet burst signal consisting of a pulse train of a first frequency so that the vibration exciter provides the liquid with vibration sufficient to jet out from the jet surface, to drive the vibration exciter, and supplying the vibration exciter with a suppressing signal which makes the vibration exciter provide the liquid with vibration not sufficient to jet out from the jet surface.
- According to a fourteenth aspect of the present invention, in the method of driving liquid jet according to the thirteenth aspect, the suppressing signal is a suppressing burst signal consisting of a pulse train of the first frequency.
- According to a fifteenth aspect of the present invention, in the method of driving liquid jet according to the thirteenth aspect, the suppressing signal is a pulse to be supplied in order for the vibration exciter to provide the liquid with a pressure.
- According to a sixteenth aspect of the present invention, in the method of driving liquid jet according to the thirteenth aspect, the suppressing signal is supplied for the vibration exciter repeatedly with a second frequency together with the jet burst signal.
- According to a seventeenth aspect of the present invention, in the method of driving liquid jet according to the thirteenth aspect, against free vibration in a mode specific to the shape of the opening, which is made by the liquid on the basis of a radiation pressure to push the liquid out from the opening in a period while the jet.burst signal is supplied, the suppressing signal drives the vibration exciter in a direction to suppress the free vibration near at least one timing when the free vibration takes an amplitude of extreme value.
- According to an eighteenth aspect of the present inveativn, in the method of driving liquid jet according to the thirteenth aspect, the suppressing signal is supplied for the vibration exciter in a period while the jet burst signal is supplied and provides the liquid with a pressure having a direction opposite to that of a radiation pressure to push the liquid out from the opening in a period while the jet burst signal is supplied.
- According to a nineteenth aspect of the present invention, the method of driving liquid jet, for driving a liquid jet unit having a jet surface provided with an opening to limitedly expose a surface of liquid to be jetted out and a vibration exciter provided on an opposite side to the jet surface with the liquid interposed therebetween for providing the liquid with vibration, the method comprises the steps of: supplying the vibration exciter with a jet burst signal consisting of a pulse train of a predetermined frequency which makes the vibration exciter provide the liquid with vibration sufficient to jet out from the jet surface, to drive the vibration exciter; and applying a positive hydrostatic pressure to said liquid in a waiting state where said liquid is in a stationary state as said jet burst signal is not supplied and reducing said positive hydrostatic pressure or applying a negative hydrostatic pressure after said jet burst signal is supplied.
- In the liquid jet driving device of the first aspect and the methods of driving liquid jet of the thirteenth and fifteenth aspects, the jet burst signal is supplied for the vibration exciter to create the fine first surface wave at an end portion of the opening and the liquid is jetted out as droplets from near the top of the first surface wave. At this time, the vibration provided for the liquid by the vibration exciter on the basis of the jet burst signal also works as the radiation pressure to push the liquid out from the opening in the period while the vibration exciter is driven. The second surface wave excited depending on whether there is the radiation pressure or not moves in the opening also after the first surface wave is attenuated. Since the radiation pressure on the basis of the suppressing signal is provided for the liquid, however, by supplying the vibration exciter with the suppressing signal, the free vibration of the liquid in a mode specific to the shape and size of the opening is suppressed. That suppresses variation in shape of the liquid surface in the opening, to ensure easy control of liquid jet after that.
- In the devices of the second and third aspects and the method of the fourteenth aspect, since the suppressing burst signal having the first frequency can be generated by controlling the number of pulses and the amplitude of the pulse train, the vibration exciter has only to create great resonance near the first frequency. That allows a simple structure of the vibration exciter.
- In the devices of the fourth, sixth and seventh aspects and the method of the seventeenth aspect, since a pressure is provided for the liquid so as to suppress the free vibration whose wavelength is longer than the vibration of the liquid on the basis of the jet burst signal near at its extreme value of amplitude, a smaller number of suppressing signals are supplied.
- In the device of the fifth aspect, since the second vibration exciter is driven with the suppressing signal, the first vibration exciter can be designed most suitably to the first frequency, to effectively create the first surface wave.
- In the device of the eighth aspect, the vibration provided for the liquid by the first vibration exciter on the basis of the jet burst signal also works as the radiation pressure to push the liquid out from the opening in a period while the first vibration exciter is driven. Since the second vibration exciter, however, provides the liquid with a pressure opposite to the radiation pressure in the period the radiation pressure works, the device of the eighth aspect can produce the same effect as the device of the first aspect.
- In the device of the ninth aspect and the method of the sixteenth aspect, since the suppressing signal is supplied at the same cycle as the jet burst signal, the motion of liquid becomes stationary and stable droplets are jetted. By using the second frequency set to be larger than the period while the jet burst signal is supplied, the meniscus of liquid in the opening is retreated towards the side of the vibration exciter, to narrow the width of jetting liquid.
- In the device of the tenth aspect, since the shape of meniscus can be largely displaced by utilizing the second surface wave, it is possible to jet large droplets suitable for an image having a small number of tones.
- In the device of the eleventh aspect, by adjusting the cycle of the state of meniscus of the second surface wave to supply of the jet burst signal, the state of meniscus in supplying the jet burst signal can be kept equally.
- In the device of the twelfth aspect, with the hydrostatic pressure applying mechanism, by applying the hydrostatic pressure to the liquid so that the meniscus of the liquid reaches the rim of the opening in a waiting state where the liquid is in a stationary state as the jet burst signal is not supplied and reducing the hydrostatic pressure or applying the negative pressure when the jet burst signal is supplied, it is possible to prevent the meniscus from spilling over from the opening. That makes the meniscus stable, and avoids jet failure of the liquid and jetting of large droplets.
- In the method of the eighteenth aspect, the vibration provided for the liquid on the basis of the jet burst signal also works as the radiation pressure to push the liquid out from the opening in the period. Since the pressure opposite to the radiation pressure is provided for the liquid in the period while the radiation pressure works, the method of the eighteenth aspect can produce the same effect as the method of the thirteenth aspect.
- In the method of the nineteenth aspect since the pressure to raise the liquid level is provided in the waiting period and the pressure is reduced after the jet burst signal is supplied, the meniscus becomes stable and it is possible to avoid the jet failure and jetting of large droplets.
- An object of the present invention is to provide a technique for stable jetting of droplets by improving the shape of ink surface from which the droplets are generated. A particular object, noticing a radiation pressure, is to provide a technique of controlling variation of liquid level due to the radiation pressure from dot to dot.
- These and other objects, features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.
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- Fig. 1 is a block diagram showing a configuration of a liquid jet driving device which is also applied to the present invention;
- Fig. 2 is a cross section schematically showing a structure of an ink head;
- Figs. 3A to 3C are waveform views for description of a jet burst signal;
- Fig. 4 is a cross section schematically showing a concept of a sound pressure;
- Fig. 5 is a cross section schematically showing a concept of a radiation pressure;
- Figs. 6A to 6D are waveform views showing a relation among the jet burst signal, the sound pressure and the radiation pressure;
- Figs. 7 to 14 are cross sections schematically showing states of meniscus of ink in an opening;
- Figs. 15A and 15B are waveform views showing a relation between the jet burst signal and meniscus motion of ink;
- Figs. 16A and 16B are waveform views showing a liquid jet driving technique in accordance with a first preferred embodiment of the present invention;
- Figs. 17A and 17B are waveform views showing a liquid jet driving technique in accordance with a second preferred embodiment of the present invention;
- Fig. 18 is a cross section schematically showing a structure in accordance with third to sixth preferred embodiments of the present invention;
- Figs. 19A to 19C are waveform views showing a liquid jet driving technique in accordance with the third preferred embodiment of the present invention;
- Figs. 20A to 20C are waveform views showing a liquid jet driving technique in accordance with the fourth preferred embodiment of the present invention;
- Figs. 21A to 21C are waveform views showing a liquid jet driving technique in accordance with the fifth preferred embodiment of the present invention;
- Figs. 22A and 22B are waveform views showing a liquid jet driving technique in accordance with the sixth preferred embodiment of the present invention;
- Figs. 23 to 31 are cross sections showing a liquid jet driving technique in accordance with a seventh preferred embodiment of the present invention;
- Fig. 32 is a cross section schematically showing an exemplary structure in accordance with the seventh preferred embodiment of the present invention;
- Figs. 33 to 35 are cross sections showing a liquid jet driving technique in accordance with an eighth preferred embodiment of the present invention; and
- Fig. 36 is a cross section showing a liquid jet driving technique in accordance with a ninth preferred embodiment of the present invention.
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- Before detailed discussion on preferred embodiments of the present invention, findings on a radiation pressure as the background of the present invention will be discussed. Fig. 1 is a block diagram showing a configuration of a liquid jet driving device which is also applied to the present invention. The liquid jet driving device comprises an input-
amount conversion circuit 1 for converting animage signal 20 having information on, for example, a tone value of an image to be drawn, into ajet signal 21, a basic-signal generation circuit 2 for generating abasic signal 28 consisting of continuous pulses of frequency f0, a drivingcircuit 3 adopting thebasic signal 28 for a predetermined period based on thejet signal 21 to generate a jet burst signal 26 consisting of continuous pulses of frequency f0 in number k and anink head 9 including avibration exciter 9a driven with the jet burst signal 26. Theink head 9 hasink 30 therein. Thevibration exciter 9a is driven with the jet burst signal 26 to jet theink 30 as adroplet 31 from theink head 9. - The input-
amount conversion circuit 1 performs conversion in consideration of conversion of dynamic range (e.g., converting tone values of 256 levels into 32 bits) and a non-linear relation between the amount of ink to be jetted from theink head 9 and the repeat number of jet burst signal 26. - Further, in the preferred embodiments discussed later, the driving
circuit 3 generates a suppressing signal 27 and thevibration exciter 9a is also driven with the suppressing signal 27. - Fig. 2 is a cross section schematically showing a structure of the
ink head 9. Theink head 9 comprises abody 94 having, for example, rotary paraboloid as an inner wall to store theink 30, anozzle plate 93 having anopening 95 to limitedly expose a surface of theink 30 and being communicated with thebody 94 through theopening 95 and thevibration exciter 9a for providingink 30 with vibration. Without thenozzle plate 93, theopening 95 may be disposed in thebody 94. - The
vibration exciter 9a has an ultrasonic vibration exciter, for example, apiezoelectric vibrator 92, and further aprotection sheet 91 between thebody 94 and thepiezoelectric vibrator 92, for protecting thepiezoelectric vibrator 92 so that it should not be wetted by theink 30. - Figs. 3A to 3C are waveform views of the
basic signal 28, the jet burst signal 26 and a dot recording signal, respectively, which show a relation among the three signals. Thebasic signal 28 has a cycle T0 = 1/f0, assuming herein that, for example, f0 = 10 MHz (T0 = 100 ns). Each jet burst signal 26 is generated by collecting k pulses of the basic signals 28. It this case, k = 6. - The jet burst signal 26 is repeated a predetermined number of times every predetermined burst cycle T2. The jet burst signal 26 is repeated burst number dj of times at the j-th dot #j, depending on a value of the
jet signal 21 corresponding to a tone value required of one dot. A period corresponding to one dot is defined as a dot cycle T3, and for example, it is shown that burst numbers d1 = 25, d2 = 5 and d3 = 17 at thefirst dot # 1, thesecond dot # 2 and thethird dot # 3, respectively. Since T3-dj·T2 varies from dot to dot, an unstable level of ink surface is caused as above discussed. - Figs. 4 and 5 are cross sections schematically showing concepts of a sound pressure Ps a radiation pressure Pi. Though a discussion will be made taking a case where the
piezoelectric vibrator 92 makes thickness longitudinal vibration as an example, these two pressures may be applied to theink 30 even by other-mode vibration. - When the
piezoelectric vibrator 92 provides theink 30 with vibration with a frequency of f0, the sound pressure Ps having a frequency f0 drives the surface of theink 30 exposed in theopening 95 almost vertically in two direction, as shown in Fig. 4. Since a rim of theopening 95 serves as a fixed end of the surface of theink 30, a first surface wave is created from the rim of theopening 95. The first surface wave jets thefine droplet 31 from its loop. The first surface wave goes towards the center of theopening 95 at a velocity Vc, and is attenuated to vanish immediately after vibration excitement of thepiezoelectric vibrator 92 is completed. - On the other hand, since the
ink 30 has an interface with air near theopening 95 and the vibration of theink 30 is entirely reflected on the interface, the radiation pressure Pi drives the surface of theink 30 almost vertically as shown in Fig. 5 in one direction from thepiezoelectric vibrator 92 to theopening 93. Since the radiation pressure Pi vanishes after vibration excitement of thepiezoelectric vibrator 92 is completed, a second surface wave is created from the rim of theopening 95. The second surface wave goes towards the center of theopening 95 at a velocity Vr. - Figs. 6A to 6D are waveform views showing a relation among the jet burst signal 26, the sound pressure Ps and the radiation pressure Pi. The pulse train included in the jet burst signal 26 has a cycle T0 = 1/f0 and each jet burst signal 26 consists of pulses in a burst in number k. The burst cycle T2 is set at not less than k·T0, and therefore there is a relation of T2-k·T0≧0 between adjacent jet bust signals 26.
- The
piezoelectric vibrator 92 has a shape of thin plate perpendicular to a direction from thevibration exciter 9a to theopening 95 as shown in Fig. 3, and receives the jet burst signal 26 to excite thickness longitudinal vibration almost in a form of sine wave. If it is now considered that theink 30 has viscosity low enough to ideally follow the vibration applied by thepiezoelectric vibrator 92, assuming that the velocity of sound propagated in the ink 30 (sound velocity), the maximum value of the velocity of the ink moving by vibration excitement (maximum velocity) and the density of theink 30 are c, u and ρ, respectively, the sound pressure Ps has a cycle T0 and shows a sine wave with an amplitude ρ cu. When a pressure in a case of no vibration excitement for theink 30 is 0, the sound pressure Ps varies within a range of ± ρ cu and drives theink 30 in the two directions as shown in Fig. 4. It is assumed herein that a positive sign is taken in a direction from thepiezoelectric vibrator 92 to theopening 95. - On the other hand, the vibration of the
ink 30 is entirely reflected on the interface with air near theopening 95, and that causes a base radiation pressure Bi showing a sine wave with a cycle T0/2 and an amplitude ρ u2/2. The base radiation pressure Bi varies from 0 to ρ u2. The maximum velocity u of theink 30 is lower than the sound velocity c, and therefore the amplitude of the base radiation pressure Bi produces little effect on the motion of the ink when the sound pressure Ps is applied to theink 30. The base radiation pressure Bi, however, has an average value ρ u2/2 in a period T1 while the jet burst signal 26 exists. Since the radiation pressure Pi, as a pulse having the average value, is applied in one direction, when the vibration excitement continues to perform on theink 30 for a long time, the meniscus of theink 30 in theopening 95 greatly rises. - Further, when the sound pressure Ps is not applied between the adjacent jet burst signals 26, the base radiation pressure Bi also vanishes. Therefore, the radiation pressure Pi produces a considerable effect, i.e., the second surface wave on the
ink 30 entirely at the dot cycle T3. - Further, Japanese Patent Application Laid Open Gazette No. 9-57963 discloses an aspect where the piezoelectric vibrator is driven with triangular waveform and surface waves going from the rim to the center of the opening interfere with one another to discharge a droplet and another aspect where a plurality of fine droplets are jetted from an end of the surface wave. In both aspects, however, the triangular wave has to make a great drive on the liquid and is not a technique in consideration of radiation pressure accompanying the jet burst signal like the present invention.
- In a state where the jet burst signal 26 is repeatedly supplied, i.e., the period dj· T2 in the dot cycle T3 of the j-th dot #j referring to Fig. 3C, the burst cycle T2 is corrected on the basis of the velocity Vr of the second surface wave, to keep the state of the meniscus of the
ink 30 in a common shape at the point of time when the jet burst signal 26 is supplied. This correction of the burst cycle is adopted in the preferred embodiments discussed later as the present invention. - Figs. 7 to 14 are cross sections schematically showing states of meniscus of the
ink 30 in theopening 95 at time t = 0 µs, 0.6 µs, 1 µs, 2 µs, 4 µs, 8 µs, 10 µs and 15.6 µs, respectively, assuming that the sound pressure Ps of f0 = 10 MHz and k = 6 begins to be supplied at the time t = 0 µs. - At the point of time when the sound pressure Ps begins to be supplied, as shown in Fig. 7, the meniscus of the
ink 30 has a small rise from theopening 95 due to surface tension. By applying the sound pressure Ps, thedroplets 31 are jetted from near the rim of theopening 95 until k/f0 = 0.6 µs. Since the meniscus has a small rise from theopening 95 as shown in Fig. 7, thedroplets 31 are jetted radiantly from theopening 95. - With the sound pressure Ps applied, the radiation pressure Pi is applied in a period from t = 0 to t = 0.6 µs. Considering that the radiation pressure Pi has one-half wavelength of fi = f0/2k, the velocity Vr of the second surface wave is obtained as fi·(2π σ/ρ fi2)1/3. Assuming that the
opening 95 is a circle with a diameter D, a time required for a to-and-fro movement of the second surface wave in theopening 95 is obtained as 2D/Vr. For example, assuming that the surface tension σ of theink 30 is 5 × 10-2 N/m, the density ρ is 1×103 kg/m3 and D = 50 µm, the required time can be obtained as 2D/Vr = 15.6 µs. - Therefore, as shown in Figs. 9 to 13, the state of meniscus has a complicate shape until t = 15.6 µs due to propagation of the second surface wave, and returns to a state almost like that of t = 0, as shown in Fig. 14, when t = 15.6 µS. Setting the burst cycle T2 at 2D/Vr, the state of meniscus at the point of time when the jet burst signal 26 is supplied can be kept equally.
- There may be a case, naturally, where it is found from an actual measurement that an optimum result can be obtained by setting the burst cycle T2 at a value slightly shifted from the time required for the to-and-fro movement of the second surface wave in the
opening 95. It falls within correction of burst cycle of this description, however, to adjust the cycle of variation in level ofink 30 due to the second surface wave and the burst cycle T2 for keeping equally the shape of meniscus at the point of time when the jet burst signal 26 is supplied. - Figs. 15A and 15B are waveform views showing a relation between the jet burst signal 26 and meniscus motion of the
ink 30 at the dot cycle T3. Fig. 15A shows a timing for supplying the jet burst signal 26 while Fig. 15B shows the center position in the surface of theink 30 which is exposed in theopening 95. In Figs. 15A and 15B, horizontally-extended lines are base lines, indicating that the pressure is 0 in the figure on the jet burst signal 26 and the center position of the liquid surface in the state of Fig. 7 in the figure on the position of the liquid surface. - In a period while the jet burst signal 26 is stopped (T3-dj·T2 in Fig. 3), since no radiation pressure Pi is applied, the surface of the
ink 30 which is driven with the radiation pressure Pi applied in a period while the jet burst signal 26 is supplied (dj·T2 in Fig. 3) makes free vibration in a mode specific to theopening 95. The free vibration has a wavelength about several times as long as the burst period T2. As discussed in (A-1), when the tone level required of dot is different, dj becomes different and T3-dj·T2 also becomes different, and hence the first jet burst signal 26 in the next dot cycle T3 is not necessarily given to the state of meniscus shown in Fig. 7 or 14. - Therefore, with control over the free vibration specific to the
opening 95 which may occur in the period while the jet burst signal 26 is stopped, the surface of theink 30 is controlled so that the jet burst signal 26 may be given in an appropriate state of meniscus. - Figs. 16A and 16B are waveform views showing a liquid jet driving technique in accordance with the first preferred embodiment of the present invention. Fig. 16A shows a timing for supplying the jet burst signal 26 and a dummy burst signal which is adopted as the suppressing signal 27 while Fig. 16B shows the center position in the surface of the
ink 30. The base lines of Figs. 16A and 16B show the same as those of Fig. 15A and 15B. - In the present invention, the dummy burst signal refers to a burst signal with which the
vibration exciter 9a is driven to provide theink 30 with vibration not sufficient to jet out from theopening 95. The dummy burst signal is generated as a burst signal consisting of a pulse train of a frequency f0, of which pulse number k is smaller than that of the jet burst signal 26. For example, when the jet burst signal 26 has pulses in number k = 6, the dummy burst signal has pulses in number k = 4. Alternatively, the dummy burst signal is generated as a burst signal having pulses in the same number k and the same frequency f0 as the jet burst signal 26 and a smaller amplitude than the jet burst signal 26. - This dummy burst signal drives the
vibration exciter 9a in the period while the jet burst signal 26 is not applied in the dot cycle T3, i.e., at a period T3-dj·T2. Therefore, over almost entire dot cycle T3, the jet burst signal 26 or the dummy burst signal is applied to thevibration exciter 9a almost at the burst cycle T2. - Since the dummy burst signal does not jet the
ink 30 unlike the jet burst signal 26 as discussed above, the tone level of the dot is not deteriorated. Since the dummy burst signal also provide theink 30 with the radiation pressure, however, it is possible to control the free vibration as shown in Fig. 15B that theink 30 can make in the period T3-dj·T2 to be almost the same as that in the period dj·T2 while the jet burst signal 26 is applied. Since the dummy burst signal is applied repeatedly at the same cycle as the jet burst signal 26 is applied, especially, the motion of theink 30 can be kept in an almost stationary state. - The dummy burst signal can be generated easily in the
driving circuit 3 shown in Fig. 1. The drivingcircuit 3 continuously generates dj jet burst signals 26 with respect to the j-th dot on the basis of the information from thejet signal 21. After that, the drivingcircuit 3 continuously generates the dummy burst signals until the end of the dot cycle T3 to give the signals to thevibration exciter 9a as the suppressing signal 27. As discussed earlier, since the dummy burst signal has a frequency f0, the dummy burst signal can be easily generated from thebasic signal 28 by using different number k of pulses or different amplitude, like the jet burst signal 26. - In the dot cycle T3, the dummy burst signal does not necessarily have to be supplied after the jet burst signal 26. For example, earlier in the dot cycle T3, some dummy burst signals are supplied to the
vibration exciter 9a, then the jet burst signals 26 are supplied and thereafter the dummy burst signals are supplied until the end of the dot cycle T3. - Figs. 17A and 17B are waveform views showing a liquid jet driving technique in accordance with the second preferred embodiment of the present invention. Fig. 17A shows a timing for supplying the jet burst signal 26 and the dummy burst signal while Fig. 17B shows the center position in the surface of the
ink 30 which is exposed in theopening 95. The base lines of Figs. 17A and 17B show the same as those of Fig. 15A and 15B. - In this preferred embodiment, the dummy burst signal is supplied at a cycle different from the burst cycle T2. Since the wavelength of the free vibration of the
ink 30 in a mode specific to theopening 95 can be obtained to be several times as long as the burst cycle T2 through calculation or actual measurement, the dummy burst signal, being adjusted to the wavelength, is supplied for thevibration exciter 9a. - In this case, it is desirable to supply the dummy burst signal when the meniscus is displaced closest to the
piezoelectric vibrator 92. Supplying the dummy burst signal at this point of time, thepiezoelectric vibrator 92 provides theink 30 with the radiation pressure in a direction from thepiezoelectric vibrator 92 to theopening 95, ensuring an easy control of the free vibration. Though there may be a case, naturally, where it is found from an actual measurement that an optimum result can be obtained by supplying the dummy burst signal at a timing slightly shifted from the time when the meniscus is displaced closest to thepiezoelectric vibrator 92, it falls within this preferred embodiment to supply the dummy burst signals intermittently in the direction to suppress the free vibration as discussed above. - In the preferred embodiments of Section B, the dummy burst signal is used to generate the radiation pressure Pi. Instead of using the radiation pressure Pi accompanying the sound pressure Ps, however, a pressure independent of the sound pressure Ps can be used and by applying the pressure to the
ink 30, the free vibration in the surface of theink 30 in theopening 95 can be suppressed. - Fig. 18 is a cross section schematically showing a structure of the
ink head 9 additionally provided with a structure to apply that pressure. Thebody 94 and thevibration exciter 9a of Fig. 2 are replaced by abody 97 and avibration exciter 9b, respectively. - The
vibration exciter 9b comprises apressure pulse generator 96 as well as theprotection sheet 91 and thepiezoelectric vibrator 92. Thebody 97 is opened on a side of thevibration exciter 9b more widely than thebody 94. Theink 30 is given pressure by thepressure pulse generator 96 as well as thepiezoelectric vibrator 92 with theprotection sheet 91 interposed. - Since the
pressure pulse generator 96 has no need of generating a sound pressure having a frequency f0, theink 30 may be given a pressure by generating bubbles with a heating device, instead of being given vibration by a piezoelectric device. This pressure may be applied, for example, for the same period as the radiation pressure, i.e., the period T1 while the jet burst signal 26 exists, or may be applied for a shorter period. Further, the pressure does not necessarily have the same magnitude as that of the radiation pressure Pi by the jet burst signal 26. In other words, this is advantageous in designing flexibility which is greater than a case of using the dummy burst signal as the suppressing signal 27. - In the following discussion, a pressure pulse signal is adopted as the suppressing signal 27, and a positive pressure is applied to the
ink 30 in a period while the pressure pulse signal is "H". This pressure pulse signal can be generated easily by using a well-known technique in thedriving circuit 3 of Fig. 1. - Figs. 19A to 19C are waveform views showing a liquid jet driving technique in accordance with the third preferred embodiment of the present invention. Fig. 19A shows a timing for supplying the jet burst signal 26, Fig. 19B shows a timing for supplying the pressure pulse signal and Fig. 19C shows the center position in the surface of the
ink 30 which is exposed in theopening 95. The base lines of Figs. 19A and 19B indicate that the pressure is 0 and that of Fig. 19C indicates the center position of the liquid surface in the state of Fig. 7. This pressure pulse signal can be generated easily by using a well-known technique in thedriving circuit 3. - This preferred embodiment is regarded as the same as the first preferred embodiment except that the dummy burst signal is replaced by the pressure pulse signal, and therefore this preferred embodiment can produce the same effect as the first preferred embodiment.
- Figs. 20A to 20C are waveform views showing a liquid jet driving technique in accordance with the fourth preferred embodiment of the present invention. Fig. 20A shows a timing for supplying the jet burst signal 26, Fig. 20B shows a tuning for supplying the pressure pulse signal and Fig. 20C shows the center position in the surface of the
ink 30 which is exposed in theopening 95. The base lines of Figs. 20A to 20C show the same as those of Figs. 19A to 19C. This pressure pulse signal can be generated easily by using a well-known technique in thedriving circuit 3. - This preferred embodiment is regarded as the same as the second preferred embodiment except that the dummy burst signal is replaced by the pressure pulse signal, and therefore this preferred embodiment can produce the same effect as the second preferred embodiment.
- By additionally providing the
pressure pulse generator 96 as shown in Fig.18, a negative pressure pulse can be also applied to theink 30. Only at a desired timing, the pressure pulse signal is made "L". This can be achieved in a case of using a heating device as thepressure pulse generator 96, by stopping heating only at a desired timing, as well as the case of using the piezoelectric device. The pressure pulse signal can be generated easily by using a well-known technique in thedriving circuit 3. - Figs. 21A to 21C are waveform views showing a liquid jet driving technique in accordance with the fifth preferred embodiment of the present invention. Fig. 21A shows a timing for supplying the jet burst signal 26, Fig. 21B shows a timing for supplying the pressure pulse signal and Fig. 21C shows the center position in the surface of the
ink 30 which is exposed in theopening 95. The base lines of Figs. 21A to 21C show the same as those of Figs. 19A to 19C. For convenience, it is shown that the negative pressure pulse signal is supplied at the point of time when the pressure pulse signal becomes "L". - In this preferred embodiment, it is desirable to supply the negative pressure pulse signal when the meniscus is displaced farthest from the
piezoelectric vibrator 92. Supplying the negative pressure pulse signal at this point of time, thepiezoelectric vibrator 92 provides theink 30 with a pressure in a direction from theopening 95 to thepiezoelectric vibrator 92, ensuring an easy control of the free vibration. Though there may be a case, naturally, where it is found from an actual measurement that an optimum result can be obtained by supplying the negative pressure pulse signal at a timing slightly shifted from the time when the meniscus is displaced farthest from thepiezoelectric vibrator 92, it falls within this preferred embodiment to supply the negative pressure pulse signals intermittently in the direction to suppress the free vibration. - Thus, this preferred embodiment can produce the same effect as the fourth preferred embodiment Since the
pressure pulse generator 96 applies a pressure to theink 30 also when thedroplets 31 are jetted on the basis of the jet burst signal 26, the meniscus at that time is likely to have a shape protruding outside from theopening 95 as compared with the state of Fig. 7. Since the meniscus has the same shape when the jet burst signal 26 is supplied in the dot cycles T3, however, it is advantageously possible to avoid different controls of jetting for dots. - Further, the third to fifth preferred embodiments can be also achieved with the
ink head 9 having the structure of Fig. 2 by driving thepiezoelectric vibrator 92 with the pressure pulse signal, instead of using theink head 9 having the structure of Fig. 18. Since thepiezoelectric vibrator 92, however, is designed to provide theink 30 with larger vibration with near the frequency f0 in order to effectively generate the sound pressure Ps, there may be a case where thepiezoelectric vibrator 92 does not effectively work, for example, when the pressure pulse is applied in the period T1 = k/f0. In other words, in the case of applying the pressure pulse, providing thepressure pulse generator 96 additionally to thepiezoelectric vibrator 92 driven with the jet burst signal 26 is better for easy designing. - The
ink head 9 having the structure of Fig. 18 can apply the negative pressure pulse at the same timing as supply of the jet bust signal 26. The pressure pulse signal can be generated easily by using a well-known technique in thedriving circuit 3. - Figs. 22A and 22B are waveform views showing a liquid jet driving technique in accordance with the sixth preferred embodiment of the present invention. Fig. 22A shows a timing for supplying the jet burst signal 26 and Fig. 22B shows a timing for supplying the pressure pulse signal. The base lines of Figs. 22A and 22B show the same as those of Figs. 19A and 19B. For convenience, it is shown that the negative pressure pulse signal is applied at the point of time when the pressure pulse signal becomes "L".
- This preferred embodiment can dilute the radiation pressure Pi based on supply of the jet bust signal 26 by applying the negative pressure pulse at the same timing and can thereby suppress generation of the second surface wave. Therefore, even without correction of the burst cycle T2 which can be applied to the present invention in (A-3), a considerable effect can be achieved in preventing variation of meniscus.
- Fig. 23 is a cross section schematically showing the state of meniscus of the
ink 30 in a waiting state of the ink head. The "waiting state of the ink head" refers to a stationary state where only atmospheric pressure is applied to theink 30 for a long time. In the waiting state of the ink head, theink 30 is retreated towards thepiezoelectric vibrator 92 while keeping wetting against the inner wall of thenozzle plate 93 with surface tension, and the meniscus is out of contact with the rim of theopening 95. - Fig. 24 is a cross section schematically showing the state of meniscus of the
ink 30 when the jet burst signal 26 is applied to thepiezoelectric vibrator 92 immediately after the waiting state of theink 30. Since the liquid surface is out of contact with the rim of theopening 95 serving as a fixed end in the state immediately before the ink is vibrated, the first surface wave becomes hard to create and it becomes difficult to jet thedroplets 31. When the jet burst signal 26 is supplied for thepiezoelectric vibrator 92 several times, the surface level of theink 30 gradually rises and theink 30 reaches the rim of theopening 95 to appropriately jet thedroplets 31. - In consideration of this phenomenon, at least when the jet burst signal 26 is applied from the waiting state of the ink head, it is desirable to provide the
ink 30 with hydrostatic pressure, which overwhelms the surface tension to push the liquid level up. On the other hand, once the liquid level of theink 30 rises, it takes considerable time to reach a stationary state because at least one jet burst signal 26, dummy burst signal or pressure pulse signal is applied to thevibration exciters - Fig. 26 is a cross section schematically showing the state of meniscus of the
ink 30 after the jet burst signal 26 is supplied for thepiezoelectric vibrator 92 several times, where the hydrostatic pressure continues to be applied. As shown in this figure, when the hydrostatic pressure continues to be applied to the liquid surface which once reaches the rim of theopening 95, the shape of the liquid surface is deformed. Fig. 27 is a cross section schematically showing the state of meniscus of theink 30 when the jet burst signal 26 is supplied for thepiezoelectric vibrator 92 in the state of Fig. 26. In a state immediately before theink 30 is vibrated, since the liquid level greatly rises from theopening 95 or the liquid spills over, it becomes difficult in some cases to control jetting of thedroplets 31. Further, in some cases, a large droplet is discharged from the liquid surface of theink 30, to deteriorate the tone of dot. - Therefore, when the jet burst signal 26 is supplied from the waiting state of the ink head, it is desirable to provide the
ink 30 with the hydrostatic pressure, to push the liquid level of theink 30 up to the rim of theopening 95, and to reduce the hydrostatic pressure or provide a negative hydrostatic pressure after the jet burst signal 26 is supplied for thepiezoelectric vibrator 92. - Fig. 29 is a cross section schematically showing the state where a positive hydrostatic pressure Pp is applied in the waiting state of the ink head. Thus, by applying the positive hydrostatic pressure Pp, the liquid surface of the
ink 30 reaches the rim of theopening 95. Fig. 30 is a cross section schematically showing the state where the jet burst signal 26 is supplied for thepiezoelectric vibrator 92 and a negative hydrostatic pressure Pn is applied. As discussed above, instead of applying the negative hydrostatic pressure, there may be a case where the positive hydrostatic pressure Pp is reduced to the degree smaller than that in the waiting state of the ink head. That makes the meniscus stable and avoids jet failure of thedroplet 31 and discharge of large droplet. - Fig. 32 is a cross section schematically showing an exemplary structure to achieve this preferred embodiment. The
ink 30 is supplied from anink tank 34 through anink supply tube 33 to the inside of theink head 9. Applying the positive hydrostatic pressure Pp as shown in Fig. 29 is achieved by moving theink tank 34 in the upward direction P and applying the negative hydrostatic pressure Pn or reducing the positive hydrostatic pressure Pp as shown in Fig. 30 is achieved by moving theink tank 34 in a downward direction N. The moving operation of theink tank 34 is achieved by using a well-known technique. - The seventh preferred embodiment proposes a control to avoid the state where the meniscus of the
ink 30 is out of contact with the rim of theopening 95 while preventing theink 30 from spilling over from theopening 95. It is possible, however, to control the hydrostatic pressure while keeping the liquid surface of theink 30 in contact with the rim of theopening 95 also in the state where the ink head is driven at the dot cycle T3, instead of the waiting state of the ink head. - Figs. 33 to 35 are cross sections schematically showing the state of meniscus of the
ink 30 in the period while the jet burst signal 26 is supplied for thepiezoelectric vibrator 92. The negative hydrostatic pressure Pn is higher in Fig. 34 than in Fig. 33, and higher in Fig. 35 than in Fig. 34. As the negative hydrostatic pressure Pn becomes higher, the liquid surface of theink 30 moves in a direction from theopening 95 towards thepiezoelectric vibrator 92. Since the first surface wave is created when the liquid surface of theink 30 is in contact with the rim of theopening 95, the more convergeddroplets 31 can be jetted as the negative hydrostatic pressure becomes higher, and narrowing the width of jetting, thedroplets 31 responding to more delicate image can be jetted. - The control of the shape of the meniscus shown in Figs. 33 to 35 is achieved by controlling the ratio of the burst cycle T2 to the period k·T0 for supplying the jet burst signal 26 to change the length of period to apply the radiation pressure Pi to the
ink 30. Specifically, if the period k·T0 for supplying the jet burst signal 26 is fixed, the burst cycle T2 is made longer to retreat the shape of meniscus towards thepiezoelectric vibrator 92 and that makes the width of jetting narrower. Further, in order to keep the shape of meniscus stable, it is desirable to supply thepiezoelectric vibrator 92 with the dummy burst signal and the pressure pulse signal as discussed in the first and third preferred embodiments. - As discussed earlier, the
piezoelectric vibrator 92 supplied with the jet burst signal 26 provides theink 30 with the radiation pressure Pi as well as the sound pressure Ps. Therefore, adjusting the timing of applying the radiation pressure Pi, i.e., the burst cycle T2 to the cycle of free vibration specific to theopening 95 allows great displacement of the meniscus. - Fig. 36 is a cross section schematically showing the motion of the meniscus in accordance with this preferred embodiment Although the second surface wave is created from the rim of the
opening 95 by the radiation pressure Pi, since the jet burst signal 26 is supplied at the cycle of the free vibration specific to theopening 95, the meniscus is greatly displaced to jet thelarge droplets 31. - Thus, in this preferred embodiment, by controlling the burst cycle T2, the
small droplets 31 are jetted from the first surface wave, as shown in the first preferred embodiment, to obtain an excellent graininess when the image data has a great number of tone levels, and thelarge droplets 31 are jetted from the second surface wave to obtain a sharp image when the image data has a small number of tone levels (e.g., binary image such as character information). Depending on whether the number of tone levels is large or small, thesuitable droplets 31 can be deposited on printed paper. - In this preferred embodiment, like the eighth preferred embodiment, in order to keep the shape of meniscus stable, it is desirable to supply the
piezoelectric vibrator 92 with the dummy burst signal as discussed in the first preferred embodiment and the pressure pulse signal as discussed in the third preferred embodiment. - Though there may be a case, naturally, where it is found from an actual measurement that an optimum result can be obtained when there is a slight difference between the burst cycle T2 and the cycle of free vibration specific to the
opening 95, it falls within this preferred embodiment to control the burst cycle T2 to excite the above free vibration by utilizing resonance. - While the invention has been shown and described in detail, the foregoing description is in all aspects illustrative and not restrictive. It is therefore understood that numerous modifications and variations can be devised without departing from the scope of the invention.
Claims (10)
- A liquid jet driving device, comprising:a liquid jet unit (9) having a jet surface (93) provided with an opening (95) to limitedly expose a surface of liquid (30) to be jetted out, and a vibration exciter (9a, 9b) provided on the opposite side to the jet surface (93) with the liquid (30) interposed therebetween for providing the liquid (30) with vibration; anda driving unit (3) for providing the vibration exciter (9a, 9b) with a suppressing signal (27) and a jet burst signal (26) consisting of a pulse train of a first frequency to drive the vibration exciter (9a, 9b);wherein vibration provided for the liquid (30) by the vibration exciter (9a, 9b) which is driven with the jet burst signal (26) is sufficient for the liquid (30) to jet out from the jet surface (93), and vibration provided for the liquid (30) by the vibration exciter (9a, 9b) which is driven with the suppressing signal (27) is not sufficient for the liquid (30) to jet out from the jet surface (93).
- The device according to claim 1,
wherein the suppressing signal (27) is a suppressing burst signal consisting of a pulse train of the first frequency. - The device according to claim 1 or 2,
wherein the suppressing signal (27) has less pulses in number than the jet burst signal (26). - The device according to any of claims 1 to 3,
wherein the suppressing signal (27) is a suppressing burst signal consisting of a pulse train of the first frequency which has a smaller amplitude than that of the jet burst signal (26). - The device according to any of claims 1 to 4,wherein the vibration exciter (9a, 9b) is driven with the jet burst signal (26) to provide the liquid (30) with a first radiation pressure,wherein the liquid (30) makes free vibrations caused by the first radiation pressure in a mode specific to the shape of the opening (95),wherein the suppressing signal (27) is supplied for the vibration exciter (9a, 9b) near at least one timing when the free vibration takes an amplitude of extreme value, andwherein the vibration exciter (9a, 9b) is driven with the suppressing signal (27) to provide the liquid (30) with a second radiation pressure which works in a direction to suppress the free vibration.
- The device according to any of claims 1 to 5,
wherein the vibration exciter (9b) has a first vibration exciter (92) supplied with the jet burst signal and a second vibration exciter (96) supplied with the suppressing signal. - The device according to claim 6,wherein the first vibration exciter (92) is driven with the jet burst signal to provide the liquid (30) with a radiation pressure,wherein the liquid (30) makes free vibrations caused by the radiation pressure in a mode specific to the shape and size of the opening (95),wherein the suppressing signal is supplied for the second vibration exciter (96) near at least one timing when the free vibration takes an amplitude of extreme value, and wherein the second vibration exciter (96) is driven with the suppressing signal to provide the liquid (30) with a pressure which works in a direction to suppress the free vibration.
- The device according to any of claims 1 to 7,
wherein the jet burst signal (26) and the suppressing signal (27) are supplied for the vibration exciter (9a, 9b) repeatedly with a second frequency. - The device according to claim 8,
wherein the second frequency is a frequency with which the liquid (30) makes free vibrations in a mode specific to the shape of the opening (95). - The device according to any of claims 1 to 9,
wherein the jet burst signal (26) is supplied for the vibration exciter (9a, 9b) repeatedly during a period required for a to-and-fro movement of a surface wave in the opening (95), which is excited on the basis of a radiation pressure to push the liquid (30) out from the opening (95) in a period while the vibration exciter (9a, 9b) is driven.
Priority Applications (2)
Application Number | Priority Date | Filing Date | Title |
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EP20000112694 EP1164014B1 (en) | 2000-06-15 | 2000-06-15 | Liquid jet device and liquid jet driving method |
DE2000606366 DE60006366T2 (en) | 2000-06-15 | 2000-06-15 | Liquid jet device and liquid jet control method |
Applications Claiming Priority (1)
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EP20000112694 EP1164014B1 (en) | 2000-06-15 | 2000-06-15 | Liquid jet device and liquid jet driving method |
Publications (2)
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EP1164014A1 true EP1164014A1 (en) | 2001-12-19 |
EP1164014B1 EP1164014B1 (en) | 2003-11-05 |
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EP20000112694 Expired - Lifetime EP1164014B1 (en) | 2000-06-15 | 2000-06-15 | Liquid jet device and liquid jet driving method |
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DE (1) | DE60006366T2 (en) |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US7097280B2 (en) | 2004-02-12 | 2006-08-29 | Lexmark International, Inc. | Printheads having improved heater chip construction |
CN109720106A (en) * | 2017-10-30 | 2019-05-07 | 惠普赛天使公司 | It is dry to print reagent |
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US5122818A (en) * | 1988-12-21 | 1992-06-16 | Xerox Corporation | Acoustic ink printers having reduced focusing sensitivity |
EP0557048A2 (en) * | 1992-02-19 | 1993-08-25 | Xerox Corporation | Method and apparatus for suppressing capillary waves in an ink jet printer |
EP0845357A2 (en) * | 1996-10-30 | 1998-06-03 | Mitsubishi Denki Kabushiki Kaisha | Liquid ejector and printing apparatus using same |
US5798779A (en) * | 1995-03-16 | 1998-08-25 | Fujitsu Limited | Ultrasonic printing apparatus and method in which the phases of the ultrasonic oscillators are controlled to prevent unwanted phase cancellations |
US5877789A (en) * | 1995-06-12 | 1999-03-02 | Oce-Nederland B.V. | Acoustic pressure wave propagating ink-system |
-
2000
- 2000-06-15 DE DE2000606366 patent/DE60006366T2/en not_active Expired - Lifetime
- 2000-06-15 EP EP20000112694 patent/EP1164014B1/en not_active Expired - Lifetime
Patent Citations (5)
Publication number | Priority date | Publication date | Assignee | Title |
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US5122818A (en) * | 1988-12-21 | 1992-06-16 | Xerox Corporation | Acoustic ink printers having reduced focusing sensitivity |
EP0557048A2 (en) * | 1992-02-19 | 1993-08-25 | Xerox Corporation | Method and apparatus for suppressing capillary waves in an ink jet printer |
US5798779A (en) * | 1995-03-16 | 1998-08-25 | Fujitsu Limited | Ultrasonic printing apparatus and method in which the phases of the ultrasonic oscillators are controlled to prevent unwanted phase cancellations |
US5877789A (en) * | 1995-06-12 | 1999-03-02 | Oce-Nederland B.V. | Acoustic pressure wave propagating ink-system |
EP0845357A2 (en) * | 1996-10-30 | 1998-06-03 | Mitsubishi Denki Kabushiki Kaisha | Liquid ejector and printing apparatus using same |
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
US7097280B2 (en) | 2004-02-12 | 2006-08-29 | Lexmark International, Inc. | Printheads having improved heater chip construction |
CN109720106A (en) * | 2017-10-30 | 2019-05-07 | 惠普赛天使公司 | It is dry to print reagent |
CN109720106B (en) * | 2017-10-30 | 2020-12-18 | 惠普赛天使公司 | Printing agent drying unit and method |
Also Published As
Publication number | Publication date |
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DE60006366D1 (en) | 2003-12-11 |
DE60006366T2 (en) | 2004-08-26 |
EP1164014B1 (en) | 2003-11-05 |
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