The present application is based on Japanese Patent Application No. 2005-128109, filed on Apr. 26, 2005, the content of which is incorporated herein by reference.
1. Field of the Invention
The invention relates to an ink-droplet ejecting apparatus of inkjet type.
2. Description of Related Art
An inkjet printer as a kind of ink-droplet ejecting apparatus includes an inkjet head having an ink passage including a pressure chamber and ending at a nozzle, and an actuator which may be of piezoelectric type. The actuator is applied with a drive signal in the form of pulses to be displaced or deformed thereby, in order to apply a pressure to ink in the pressure chamber to eject a droplet of the ink from the nozzle.
It is known to damp a pulsation remaining in the ink after the ejection of an ink droplet, or to reduce the size or volume of an ink droplet to be ejected, by adding a pulse Ps that is not for ejecting an ink droplet, to the drive pulse. More specifically, the drive pulse includes a main pulse Pm that is for ejecting an ink droplet, and the pulse Ps is applied after the main pulse Pm.
For instance, JP-A-2001-301161 (see especially
The present inventor studied a comparative waveform of the drive signal as shown in
The inventor made an experiment on ink-droplet ejection using the waveform shown in
From the tables of
The mist is ink droplets further smaller in size than an ink droplet that is produced upon separation of an intentionally ejected ink droplet from the ink inside the nozzle, The ink droplets or the mist do not land on the recording medium but waft to eventually adhere to a member or part inside the inkjet printer, which may lead to various kinds of faulty behaviors of the printer, or contamination of the printer with the ink. This in turn leads to problems such as degradation in the quality of an image recorded by the printer, or increase in the cost due to disposing in the printer a member for preventing the mist from intruding into the printer.
This invention has been developed in view of the above-described situations, and it is an object of the invention to provide an ink-droplet ejecting apparatus which can eject a droplet of ink in a predetermined size, with stability and without producing a mist of the ink.
To attain the above object, the invention provides an ink-droplet ejecting apparatus including a pressure chamber filled with an ink, an actuator which varies an inner volume of the pressure chamber, and a control unit which has a drive-signal generator. The drive-signal generator generates a drive signal and applies the drive signal to the actuator when a droplet of the ink is to be ejected onto a recording medium. The drive signal is generated to be in one of at least one waveform including a waveform including a main pulse Pm in order to eject the ink droplet, and a stabilizing pulse Ps applied after the main pulse Pm in order not to eject an ink droplet, A pulse width Ts of the stabilizing pulse Ps is smaller than a rising time of the stabilizing pulse Ps.
According to this apparatus where the pulse width Ts of the stabilizing pulse Ps included in the drive pulse is set to be smaller than the rising time of the pulses, the stabilizing pulse Ps has such a form that before a value of a voltage applied to the actuator as the drive signal reaches a predetermined drive voltage value, the application of the voltage is terminated. Thus, energy of the stabilizing pulse Ps is made relatively low. Hence, it can be considered that the ink droplet about to be ejected is gently separated from the ink inside the apparatus by the relatively low energy of the stabilizing pulse Ps, thereby preventing occurrence of a mist of the ink. In this way, degradation in the quality of a result of recording by the apparatus, and faulty behaviors of the apparatus due to contamination of the apparatus with the ink mist.
Preferably, the pressure chamber is included in an ink passage, and a pulse width Tm of the main pulse Pm, a pulse width Ts of the stabilizing pulse Ps, and an interval Wm between a terminal end of the main pulse Pm and an initial end of the stabilizing pulse Ps are set to be within the following ranges, where AL represents a one-way propagation time which is a time taken by a pressure wave to propagate one way along the ink passage: 0.8AL≦Tm≦1.2AL, 0.1AL≦Ts≦0.3AL, and 0.6AL≦Wm≦1.0AL.
It was confirmed in an experiment that occurrence of the ink mist was well prevented and the ejection of the ink droplet was highly stably performed, when the values of Tm, Ts, and Wm were set to fall within the above ranges.
The above and other objects, features, advantages and technical and industrial significance of the present invention will be better understood by reading the following detailed description of preferred embodiments of the invention, when considered in connection with the accompanying drawings, in which:
Hereinafter, there will be described presently preferred embodiments of the invention, by referring to the accompanying drawings.
The inkjet printer includes an inkjet head 100 that is mounted in a carriage (not shown) reciprocated in a main scanning direction that will be hereinafter referred to as “the Y-axis direction”. The main scanning direction is perpendicular to a feeding direction that is a direction in which a recording medium is fed, i.e., a sub scanning direction that will be hereinafter referred to as “the X-axis direction”. Inks of respective colors, e.g., cyan, magenta, yellow, and black, are supplied into the inkjet head 100. Ink cartridges containing the respective color inks are detachably mounted on the carriage, or alternatively the ink cartridges are fixed in position in a mainbody of the inkjet printer, and the inks are supplied to the inkjet head 100 through respective supply pipes or the like.
As shown in
There will be described a structure of the cavity unit 1. As shown in
In this specific example, each of the plates 11-17 has a thickness of about 50-150 μm, and the nozzle plate 11 is made of synthetic resin such as polyimide, and the other plates 12-17 are formed of a nickel alloy steel sheet containing 42% of nickel. A plurality of the nozzles 4 for ejecting ink droplets therefrom are formed through the nozzle plate 11, and arranged at very small intervals. Each of the nozzles 4 has a diameter as small as about 25 μm. The nozzles 4 are arranged in five rows each extending along a longitudinal direction of the nozzle plate 11 that is parallel to the X-axis direction.
As shown in
The longitudinal end 36a of the pressure chamber 36 is communicated with the nozzle 4 formed through the nozzle plate 11, via a communication hole 37 of small diameter extending through the supply plate 15, the base plate 16, the two manifold plates 14a, 14b, the damper plate 13, and the spacer plate 12.
A plurality of through-holes are formed in the base plate 16 that is immediately under the cavity plate 17, and communicated with the respective ends 36b of the pressure chambers 36.
A plurality of through-holes to serve as connecting passages for supplying the inks from the common ink chambers 7 (described later) to the pressure chambers 36 are formed through the supply plate 15 that is immediately under the base plate 16 Each of the connecting passages includes an inlet, an outlet, and a restricting portion therebetween. The ink in the common ink chamber 7 is introduced into the connecting passage through the inlet, then passes through the restricting portion having a smaller cross-sectional area than the inlet and outlet in order to have the highest resistance to the ink flow in the connecting passage, and then goes out of the connecting passage through the outlet that opens into the through-hole 38 that is connected to the pressure chamber 36.
Five elongate through-holes to serve as common ink chambers 7 are formed through the two manifold plates 14a, 14b and extend along a longitudinal direction of the two manifold plates 14a, 14b, that is parallel to the X-axis direction. Positions of the common ink chambers 7 correspond to the rows of the nozzles 4. As shown in
As shown in
As shown in
Thus, a plurality of ink passages each beginning from one of the ink supply ports 47 and one of the nozzles 4 are formed. An ink introduced from one of the ink supply ports 47 into the corresponding common ink chamber 7 as an ink supply channel is distributed to the pressure chambers 36 via the connecting passages formed through the supply plate 15 and the through-holes 38 formed through the base plate 16, as shown in
In the present embodiment, as shown in
There will be described a structure of the piezoelectric actuator unit 2, which is similar to that disclosed in JP-A-4-341853, for instance. That is, as shown in
As well known in the art, a high voltage is applied between the individual electrodes 44 and the common electrodes 46 to polarize a portion 49 of the piezoelectric sheets between the individual electrodes 44 and the common electrodes 46, to make the portion function as an active portion 49 or an actuator.
The cavity unit 1 and the piezoelectric actuator unit 2 prepared as described above are bonded to each other as follows. An adhesive sheet (not shown) made of ink-impervious synthetic resin is attached to a lower surface of the planar piezoelectric actuator unit 2, which surface is a major surface to be opposed to the pressure chambers 36, to cover an entirety of the lower surface. Then, the piezoelectric actuator unit 2 is positioned relative to the cavity unit 1 such that the individual electrodes 44 in the actuator unit 2 are opposed to the pressure chambers 36 in the cavity unit 1, and bonded or fixed thereto. The above-mentioned flexible flat cable 3 is superposed on and pressed against an upper surface of the piezoelectric actuator unit 2, and various wiring patterns (not shown) on the flexible flat cable 3 are electrically connected to the surface electrodes.
There will be described a structure of a control unit for controlling a voltage to be applied as drive voltage value to the electrodes, by referring to
Upon the driver outputting the drive signal to the individual electrodes 44 of one of the active portions 49, that active portion 49 is deformed or displaced, thereby pressurizing the ink in the pressure chamber 36 corresponding to the active portion 49, and causing a pressure wave. A component of the pressure wave which advances from the pressure chamber 36 to the nozzle 4 ejects an ink droplet from the nozzle 4.
In the inkjet printer including the thus constructed inkjet head 100, the present inventor studied a waveform of the drive signal including a non-ejection pulse of high energy or pressure, as described above in the part of “SUMMARY OF THE INVENTION”. When such a waveform is employed, a mist occurs upon ejection of an ink droplet. This phenomenon can be explained as follows. That is, application of the non-ejection pulse of high energy or pressure contributes to stabilize the ejection of the ink droplet but produces smaller ink droplets, i.e., the mist, when the ink droplet separates from the ink in the nozzle 4.
Thus, according to the present embodiment, a waveform including a non-ejection or stabilizing pulse Ps of extremely low energy is employed, as shown in
In this embodiment, the driver controls the voltage applied to the individual electrodes 44 such that the application of the voltage to the individual electrodes 44 is stopped upon rising of the voltage of the drive signal, and applies the voltage to the individual electrodes 44 upon falling of the voltage of the drive signal. That is, the voltage is applied to the individual electrodes 44 in a waveform inverse to that of
Hence, during a waiting period before the ink-droplet ejection is implemented, a positive voltage is applied to all the individual electrodes 44 while the common electrodes 46 are grounded, so that all the active portions 49 disposed therebetween are expanded to decrease the inner volume of all the pressure chambers 36. Upon stopping application of the voltage in a direction of stacking of the piezoelectric sheets 41-43, to individual electrodes 44 corresponding to one of the pressure chambers 36 from which the ink is to be ejected in the form of a droplet, the corresponding active portion 49 restores to its contracted state to increase the inner volume of the pressure chamber 36. Thus, the ink pressure in the pressure chamber 36 becomes negative. At a timing when the pressure of the pressure wave inverts to be positive, the voltage is again applied to the individual electrodes 44, so that a pressure produced by expansion of the active portion 49 is added to the pressure of the pressure wave inverted to be positive, thereby ejecting an ink droplet from the nozzle 4.
The way of ejecting an ink droplet may be inversely modified such that a voltage is applied to a drive electrode to increase the inner volume of the pressure chamber to generate a pressure wave, and application of the voltage is stopped at the timing when the pressure of the pressure wave inverts from negative to positive, to decrease the inner volume of the pressure chamber to eject the ink droplet, as disclosed in JP-A-2001-301161.
The time the pressure wave takes from its generation to turn positive is determined by a one-way propagation time AL that is a time the pressure wave takes to propagate one way through each ink passage extending to one of the nozzles 4 and including the pressure chamber 36, the communication hole 37, and the through-hole 38. The one-way propagation time AL is determined by various factors including not only the natural vibration frequency of the ink and the length of the ink passage, but also a resistance of the ink passage to the ink flow and a rigidity of each of the plates defining the ink passages.
There will be described the shape of the stabilizing pulse Ps that is generally rectangular. The pulses of the drive signal such as the stabilizing pulse Ps and the main pulse Pm are applied between the individual electrodes 44 and the common electrodes 46 opposed to each other via the piezoelectric sheets or layers, so that the piezoelectric sheets or layers serve as a condenser. Further, the path or circuit from the driver outputting the pulses of the drive signal to the individual electrodes 44 has a resistance Hence, when the driver outputs a drive signal having a square waveform, an integrating circuit is formed by the condenser and the resistance, thereby causing a rounding or a lag at each rising edge and falling edge in the waveform, at the individual electrode 44. That is, the drive voltage value rises and falls with a slope, or the rising edge and falling edge of the waveform is not straight.
Hence, strictly, the waveform of the drive signal applied in a manner as indicated by broken line in
In this invention, the pulse width Ts of the stabilizing pulse Ps is set to be smaller than the rising time Tu, thereby making the shape of the stabilizing pulse Ps generally rectangular, that is, the application of the voltage to the individual electrode 44 is terminated before the voltage reaches the predetermined drive voltage value. However, by definition, the term “pulse width” refers to a time from a first time point when the applied voltage reaches 50% of the drive voltage value at a rising edge of a pulse, to a second time point when the applied voltage lowers down to 50% of the drive voltage value at a falling edge of the pulse, and the term “rising time Tu” refers to a time from a third time point when the applied voltage reaches 10% of the drive voltage value at a rising edge of a pulse, to a fourth time point when the applied voltage reaches 90% of the applied voltage, at a rising edge of a pulse. However, the time periods Tm and Tu are roughly and not strictly presented.
In this way, the stabilizing pulse Ps applied after the main pulse Pm is set to have a generally rectangular shape, in other words, to apply relatively low energy or pressure to the ink in the pressure chamber 36. The relatively low energy desirably damps the pressure wave produced by the main pulse Pm and remaining in the ink, but does not cause occurrence of the mist. In view of this, an experiment was conducted to optimize the pulse width Ts and the interval Wm, namely, to make the pulse width Ts and the interval Wm satisfy this condition.
A result of the experiment is shown in
As shown in
0.13AL≦Ts≦0.31AL, and 0.60AL≦Wm≦1.07AL.
In these cases, since the rising time Tu is about 1.8 μsec, and the one-way propagation time AL is about 5.0 μsec, the value to which the voltage can rise at the stabilizing pulse Ps having the pulse width Ts is about 20-90% of the predetermined drive voltage value.
On the other hand, as shown in
0.11AL≦Ts≦0.33AL, and 0.60AL≦Wm≦1.11AL.
In some cases where Ts was 0.33AL, and in some cases where Wm was 0.94AL, 1.03AL, and 1.11AL, the result was bad.
From the above results, it is found that when the values of Ts and Wm are respectively within the following ranges, occurrence of the mist is well prevented while the stability of the ink-droplet ejection is excellent: 0.1AL≦Ts≦0.3AL, and 0.6AL≦Wm≦1.0AL. Although it is not shown in
By forming the waveform of the drive signal such that the values of Tm, Ts, Wm satisfy the above-described conditions, ejection of an ink droplet is stably performed, while occurrence of an ink mist can be excellently prevented.
Number | Date | Country | Kind |
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2005128109 | Apr 2005 | JP | national |