Patent Application
20060170717
This application claims benefit of and priority to Japanese Patent Application No. 2005-026170, filed on Feb. 2, 2005, which is incorporated herein by reference in its entirety for all purposes.
1. Field of the Invention
The present invention relates to a driving device for a recording head at which droplet ejection portions, which are equipped with actuating elements such that droplets are ejected in accordance with driving signals, are plurally arranged, and to a printing apparatus which includes this recording head.
2. Description of the Related Art
As a recording head which is employed in an inkjet-system printing apparatus, a recording head is known with a form in which droplet ejectors (ink ejection portions) at which respective actuating elements are provided are plurally arranged, and driving signals with predetermined waveforms are applied to the actuating elements, thus altering volumes of pressure generation chambers of the droplet ejectors and ejecting drops of ink from inside the pressure generation chambers.
All the actuating elements are electrically connected in parallel between a common power supply line and an earth line, and predetermined switching elements are electrically connected in series with the respective actuating elements. When, in accordance with printing data, a predetermined switching element is selected and turned on, a driving signal is inputted to the actuating element, and an ink drop is ejected from a nozzle opening of the droplet ejector at which the actuating element to which the driving signal has been inputted is provided. The driving signal has been generated by a standard driving waveform generation circuit, then current-amplified by a current amplification circuit (for example, an A class amplification circuit), and is supplied to the actuating element.
In a printing apparatus which is structured in this manner, because the actuating elements feature capacitance, a head-driving circuit of the printing apparatus has the characteristics of a capacitive load-driving circuit. Consequently, in a conventional printing apparatus, because a capacitance value of the load varies with the number of the droplet ejectors that are ejecting ink drops (i.e., printing density), waveforms of driving signals are disturbed, and problems arise in that sizes of ink drops vary and so forth.
Accordingly, as has been disclosed in Japanese Patent Application Laid-Open (JP-A) No. 11-320872, a capacitive load-driving circuit has been proposed which is provided with capacitive dummy loads in addition to the actuating elements, and which keeps a sum of load capacitances of the actuating elements and the dummy load capacitances constant in order to provide driving signals having consistent waveforms.
However, with this kind of capacitive load driving circuit, it is necessary to supply energy to the dummy loads even when the number of actuating elements to be driven (i.e. the loading capacitance of the actuating elements) is small. As a result, power is consumed excessively. Particularly in recent years, there has been a trend in which the number of droplet ejectors that are provided at heads are increased, in order to realize high-speed printing, and overall power consumption of heads has been increasing. Accordingly, devices which suppress power consumption are in great demand.
Consequently, as devices for responding to loading variations without providing dummy loads, devices which vary the current value of a power supply side have been proposed. For example, a driving device which utilizes a variable constant-current power supply to regulate a waveform, as has been disclosed in JP-A No. 8-112894, a driving device which utilizes a current-limiting element to regulate a waveform, as has been disclosed in JP-A No. 9-187949, and the like are known.
However, even with a device which varies a current value at the current supply side in such a manner, it is necessary to implement fine adjustments of the waveform with an A class amplification circuit or the like. In such a case, because power efficiency of the amplification circuit is low, power consumption amounts are greatly increased. In addition, there is a problem in that heat generation amounts are accordingly increased, so larger radiator plates are necessary, and the device is increased in size. Further still, in such a case, a circuit with a wide frequency range is necessary. However, there are range limitations with simple circuits, and it is difficult to adapt to this requirement.
In order to solve these problems, driving devices in which the current amplification circuit is subdivided have been proposed. For example, a driving device which is provided with a current amplification circuit portion for each of a plurality of rows of nozzles, as has been disclosed in JP-A No. 2003-072063, an inkjet recording device which is provided with a plurality of current amplification sections covering a plurality of heads, as has been disclosed in JP-A Nos. 2000-325882 and 2004-195792, and the like are known.
However, in a driving device which is provided with a current amplification section for each of nozzle row, because the current amplification sections and the nozzle rows are in one-to-one correspondence, output terminals are required for outputting driving signals to the individual nozzles from the individual current amplification circuits. Consequently, a problem arises in that the driving device is increased in size. Further, with an inkjet driving device which is provided with current amplification sections covering a plurality of heads, problems also arise in that distribution of wiring is more complicated and terminals connecting the respective current amplification sections to the respective heads are required, which increases the size of the driving device.
The present invention has been devised in consideration of the problems described above, and will provide a recording head driving device and printing apparatus with small size and good energy efficiency, in which waveforms of driving signals are preserved.
A first aspect of the present invention is a recording head driving device for driving a recording head at which droplet ejection portions are plurally arranged, the droplet ejection portions including actuating elements which are driven such that droplets are ejected in accordance with driving signals, the recording head driving device being structured to include: a generation section, which generates a signal with a standard waveform; a voltage amplification section, which amplifies a voltage component of the signal generated by the generation section; a plurality of current amplification sections with output terminals thereby being commonly connected, the plurality of current amplification sections outputting a signal, in which a current component of a signal inputted through an input terminal has been amplified, through the output terminals to serve as a driving signal; and a selection section which, in accordance with the number of the actuating elements to be driven concurrently or a printing density of an image to be printed by the recording head, selects at least one of the plurality of current amplification sections and inputs a signal outputted from the voltage amplification section to the input terminal of selected current amplification section.
A second aspect of the present invention is a recording head driving device for driving a recording head at which droplet ejection portions are plurally arranged, the droplet ejection portions including actuating elements which are driven such that droplets are ejected in accordance with driving signals, the recording head driving device being structured to include: a generation section, which generates a signal with a standard waveform; a plurality of series circuits with output terminals thereof being commonly connected, the plurality of series circuits being structured such that a voltage amplification section and a current amplification section are connected in series in each circuit, the voltage amplification section amplifying a voltage component of the signal generated by the generation section, and the current amplification section amplifying a current component of the signal whose voltage component has been amplified by the voltage amplification section and outputting through the output terminal to serve as a driving signal; and a selection section which, in accordance with the number of the actuating elements to be driven concurrently or a printing density of an image to be printed by the recording head, selects at least one from the plurality of series circuits and inputs the signal generated by the generation section to an input terminal of selected series circuit.
A third aspect of the present invention is a recording head driving device for driving a recording head at which droplet ejection portions are plurally arranged, the droplet ejection portions including actuating elements which are driven such that droplets are ejected in accordance with driving signals, the recording head driving device being structured to include: a plurality of series circuits with output terminals thereof being commonly connected, the plurality of series circuits being structured such that a generation section, a voltage amplification section and a current amplification section are connected in series in each circuit, the generation section generating a signal with a standard waveform in accordance with an input of a generation signal, the voltage amplification section amplifying a voltage component of the signal generated by the generation section, and the current amplification section amplifying a current component of the signal whose voltage component has been amplified by the voltage amplification section and outputting through the output terminal to serve as a driving signal; and a selection section which, in accordance with the number of the actuating elements to be driven concurrently or a printing density of an image to be printed by the recording head, selects at least one from the plurality of series circuits and inputs the generation signal to an input terminal of selected series circuit.
A fourth aspect of the present invention is a recording head driving device for driving a recording head at which droplet ejection portions are plurally arranged, the droplet ejection portions including actuating elements which are driven such that droplets are ejected in accordance with driving signals, the recording head driving device being structured to include: a digital waveform generation section, which generates a signal with a standard digital waveform; a plurality of series circuits with output terminals thereof being commonly connected, the plurality of series circuits being structured such that an analog waveform generation section, a voltage amplification section and a current amplification section are connected in series in each circuit, the analog waveform generation section generating a signal with an analog waveform from the signal generated by the digital waveform generation section, the voltage amplification section amplifying a voltage component of the signal generated by the analog waveform generation section, and the current amplification section amplifying a current component of the signal whose voltage component has been amplified by the voltage amplification section and outputting through the output terminal to serve as a driving signal; and a selection section which, in accordance with the number of the actuating elements to be driven concurrently or a printing density of an image to be printed by the recording head, selects at least one from the plurality of series circuits and inputs the signal generated by the digital waveform generation section to an input terminal of selected series circuit.
Further, a fifth aspect of the present invention is a printing apparatus structured to include: a recording head at which droplet ejection portions are plurally arranged, the droplet ejection portions including actuating elements which are driven such that droplets are ejected in accordance with driving signals; and a recording head driving device for driving the recording head which includes a generation section, which generates a signal with a standard waveform, a voltage amplification section, which amplifies a voltage component of the signal generated by the generation section, a plurality of current amplification sections with output terminals thereby being commonly connected, the plurality of current amplification sections outputting a signal, in which a current component of a signal inputted through an input terminal has been amplified, through the output terminals to serve as a driving signal, and a selection section which, in accordance with the number of the actuating elements to be driven concurrently or a printing density of an image to be printed by the recording head, selects at least one of the plurality of current amplification sections and inputs a signal outputted from the voltage amplification section to each input terminal of selected current amplification section.
Preferred embodiments of the present invention will be described in detail based on the following figures, wherein:
Herebelow, an embodiment of the present invention will be described in detail with reference to the drawings. A printing apparatus of the present embodiment is equipped with a recording head and a driving device.
The recording head driving device thereof drives the recording head, at which droplet ejection portions including actuating elements are plurally arranged, the actuating elements being driven such that droplets are ejected in accordance with driving signals.
As shown in
The waveform preparation section 33 includes three waveform preparation circuits 35a, 35b and 35c, for preparing the plurality of types of waveform. Here, the three waveform preparation circuits 35a, 35b and 35c have similar structures. Accordingly, a case will be described in which these are not particularly distinguished from one another, but are referred to as a waveform preparation circuit 35, with the suffixes of the reference numeral being omitted.
At the recording head 11, when waveform data corresponding to ink droplets of different diameters (large drops, medium drops and small drops) is supplied to the waveform preparation circuits 35a, 35b and 35c, the driving signals of the three types of waveform are simultaneously generated and ink drops of the three different diameters can be simultaneously printed (tone printing). This waveform data has been memorized at the memory section 32, and is provided to the waveform preparation circuits 35a, 35b and 35c via the control section 31.
Herein, waveform data for non-ejection of an ink drop is also memorized at the memory section 32. This waveform data is data for generating a driving signal for agitating the ink in the pressure generation chamber 4 with pressure in an amount which will not eject an ink drop, in order to prevent variations in ejection characteristics due to contact between the ink and air at a vicinity of the nozzle 2 and thickening of the ink. This driving signal for non-ejection of an ink drop is employed with being combined in a time series with the driving signals for any of large drops, medium drops and small drops.
Each of the waveform preparation circuits 35a, 35b and 35c is connected by signal lines with the actuators 7 provided at the respective droplet ejectors 24. In order to supply one of the driving signals with mutually differing waveforms which are prepared by the waveform preparation circuits 35a, 35b and 35c to the actuators 7, switches 37 are provided between the signal lines and the actuators 7. By on/off switching of these switches 37, for each actuator 7, one driving signal from the driving signals prepared by the waveform preparation circuits 35a, 35b and 35c can be selected and supplied to the actuator 7. The on/off switching of the switches 37 is implemented by a waveform selection circuit 36 of the switching section 34, on the basis of instruction signals DSWN from the control section 31. Thus, driving of the actuators 7 is controlled.
The control section 31, in addition to controlling each section described above and the sending/receiving of the various signals, outputs driving instruction signals SC for a driving motor (not shown), which is for turning a paper conveyance roller which conveys paper for printing.
The standard waveform generation section 56 generates a driving signal with a standard waveform on the basis of waveform data which is inputted from the control section 31.
The voltage amplification section 54 amplifies a voltage component of the driving signal that is generated by the standard waveform generation section 56.
The plurality of current amplification sections 50a, 50b and 50c, when the driving signal whose the voltage component has been amplified is inputted thereto, amplify the current component of the driving signal. In the present embodiment, each of the current amplification sections 50a, 50b and 50c has the same structure, and amplification ratios thereof are equal. Herebelow, a case will be described in which these are not particularly distinguished from one another, but are referred to as a current amplification section 50, with the suffixes of the reference numeral being omitted.
Output terminals of the respective current amplification sections 50 are commonly connected, and are connected to all of the actuators 7 via the switching section 34. Thus, it is possible to unify the driving signals which have been current-amplified by the current amplification sections 50 and output the unified driving signal to the actuators 7.
The selection section 40 is a single-input, multiple-output switching circuit. When a driving signal which has been voltage-amplified by the voltage amplification section 54 is inputted, at least one current amplification section 50 is selected from the plurality of current amplification sections 50, and the voltage-amplified driving signal is outputted to the input terminal(s) of the selected current amplification section(s) 50. Of the plurality of current amplification sections 50, each current amplification section 50 to which the driving signal has been inputted amplifies the current component of the driving signal and outputs the same through the output terminal thereof. Here, because the current amplification sections 50 all have the same amplification ratio, it is possible to regulate the current component of the driving signal that is supplied to the actuators 7 by regulating the number of the current amplification sections 50 to be selected.
Here, because the current amplification sections 50 that have not been selected are in a driving-paused state, power consumption can be correspondingly suppressed. Note that the selection of the current amplification sections 50 is controlled by control signals from the control section 31.
As shown in
As shown in
The selection signal is a signal for selecting the current amplification section(s) 50 to be driven, and is a serial signal composed of an a-selection signal, a b-selection signal and a c-selection signal. Each selection signal is one bit of data, which is a ‘0’ or a ‘1’. The current amplification section 50a is not selected when the a-selection signal is ‘0’, and is selected when the a-selection signal is ‘1’. The current amplification section 50b is not selected when the b-selection signal is ‘0’, and is selected when the b-selection signal is ‘1’. The current amplification section 50c is not selected when the c-selection signal is ‘0’, and is selected when the c-selection signal is ‘1’.
The shift register 42 converts the inputted selection signal, which is three bits of serial data, to three bits of parallel data and outputs the same to the latch circuit 44.
The latch circuit 44 latches (self-maintains) the parallel data outputted from the shift register 42, in accordance with input of the latch signal.
The level shifter 46 level-converts the respective selection signals from the latch circuit 44, and outputs the level-converted selection signals to the respective switches 52a, 52b and 52c. In accordance with these selection signals, the switches 52a, 52b and 52c are respectively turned on or off, and the driving signal that has been voltage-amplified by the voltage amplification section 54 is fed to the current amplification sections 50 that are connected to the switches 52 that are switched on. Thus, it is possible to selectively drive the current amplification sections 50. Here, because the driving signal is not inputted to the current amplification sections 50 that are connected to the switches 52 that are turned off, those current amplification sections 50 are in the driving-paused state, and power consumption can be suppressed.
Next, operations of the driving device 10 relating to the present embodiment will be described.
The control section 31, in accordance with printing data which includes tone information, which is supplied from outside, determines whether to supply one of the driving signals of the three types of waveform which have been prepared by the three waveform preparation circuits 35a, 35b and 35c, or not to supply any of the driving signals, to the actuators 7, and sends waveform selection signals to the waveform selection circuit 36 in order to switch the switches 37 on and off.
Then, when a printing commencement instruction is supplied from outside, the control section 31 reads the waveform data corresponding to each waveform preparation circuit 35 from the memory section 32 and outputs the same to the standard waveform generation section 56 of each waveform preparation circuit 35, and outputs the control signal for selectively driving the current amplification sections 50 to the selection section 40 of the waveform preparation circuit 35.
As described above, the control signal is structured to include the selection signal, the clock and the latch signal. Of these, the selection signal is generated as described below and outputted.
A loading capacitance value varies in accordance with the number of the actuators 7 that are being driven at one time (a concurrent driving count). Accordingly, herein, in order to suppress disturbance of a driving signal waveform due to variations in loading capacitance values, a driving count of the current amplification sections 50 (a number of the current amplification sections 50 to which the driving signal which has been amplified by the voltage amplification section 54 is inputted) is varied in correspondence with the concurrent driving count of the actuators 7. Thus, the current component of the driving signal which is outputted at the commonly connected output terminals of the current amplification sections 50 is adjusted, and disturbance of the waveform is prevented.
Now, when a printing density represented by the printing data is low, the concurrent driving count of the actuators 7 is small, and when the printing density is high, the concurrent driving count of the actuators 7 is large. Therefore, it is also possible to determine the number of current amplification sections 50 to be selected in accordance with printing densities.
Specifically, when the printing density is low (i.e., the concurrent driving count of the actuators 7 is to be small), the selection signal is generated and outputted such that the number of the current amplification sections 50 selected by the selection section 40 is small (i.e., such that the current component of the driving signal supplied to the actuators 7 is small). Further, when the printing density is high (i.e., the concurrent driving count of the actuators 7 is to be large), the selection signal is generated and outputted such that the number of the current amplification sections 50 selected by the selection section 40 is large (i.e., such that the current component of the driving signal supplied to the actuators 7 is large).
Herein, a table in which printing densities are corresponded with selection numbers of the current amplification sections 50 may be memorized beforehand at the memory section 32. On the basis of this table, selection numbers corresponding to printing densities derived from printing data may be read out and selection signals are generated. It is also possible to generate selection signals by deriving selection numbers of the current amplification sections 50 with a function in which printing density is a parameter.
When the standard waveform generation section 56 of the waveform preparation circuit 35 inputs waveform data from the control section 31, a driving signal is generated with a waveform in accordance with the waveform data, and is outputted to the voltage amplification section 54. The voltage amplification section 54 amplifies the voltage component of the driving signal that has been generated by the standard waveform generation section 56, by a predetermined amplification ratio, and outputs the waveform whose voltage component has been amplified to the selection section 40.
The selection section 40 selects at least one, or more, of the current amplification sections 50 in accordance with the selection signal from the control section 31, and inputs the driving signal whose voltage component has been amplified by the voltage amplification section 54 to the selected current amplification section(s) 50.
The current amplification section 50 to which the driving signal is inputted amplifies the current component of the inputted driving signal, and outputs the driving signal through the output terminal. Because the output terminals of the current amplification sections 50 are commonly connected as mentioned above, the current-amplified driving signals are unified for output to the switching section 34. The switching section 34 supplies the driving signal that has been current-amplified by the current amplification section(s) 50 selected by the selection section 40 to the actuators 7 in which the switches 37 corresponding to each respective waveform preparation circuit 35 are turned on.
Thus, it is possible to vary the selection numbers of the pluralities of current amplification sections 50 in accordance with printing densities (concurrent driving numbers of the actuators 7). Therefore, it is possible to appropriately adjust the current components of the driving signals in accordance with load variations, without providing dummy loads, and waveform regulation over a broad frequency range is facilitated. Further, with such a structure, because there is no need for large radiator plates for suppressing heating amounts, it is possible to prevent an increase in size of the device. Further still, because the output terminals of the current amplification sections 50 for the respective actuating elements are commonly connected, wiring distribution is not made more complicated and it is possible to restrain size of the device.
Further again, because the current amplification sections 50 which are not selected by the selection section 40 are in a driving-paused state, power consumption can be correspondingly suppressed.
Now, in the embodiment described above, a case in which three of the current amplification sections 50 are provided at the waveform preparation circuit 35 has been described as an example. However, the number of current amplification sections 50 is not particularly limited to three, and may be four or more. For example, it is possible to provide small-scale current amplification portions, at which large radiator plates are not required, in a number that is sufficient for providing a required range.
Furthermore, for the embodiment described above, a case in which the current amplification sections 50 whose current amplification ratios are the same are plurally provided has been described as an example. However, this is not limiting. For example, the amplification ratios of the current amplification sections 50 may be different. For example, the current amplification sections 50 could be designed with a smallest amplification ratio of 1, with the other amplification ratios being second powers (that is, ×1, ×2, ×4, . . . ). When the current amplification sections 50 are plurally provided with amplification ratios which differ in such a manner, the current components of driving signals can be altered (amplified) to desired values by combinations of the current amplification sections 50. Note that in such a case too, it is possible, for example, to memorize a table in which the image printing densities are associated with types of the current amplification sections 50 to be selected, at the memory section 32 beforehand, and to select the current amplification sections 50 of types corresponding to printing densities which are derived from printing data on the basis of this table.
Further yet, for the embodiment described above, an example has been described in which the selection section 40 is structured by the shift register 42, the latch circuit 44, the level shifter 46 and the switches 52. However, in a case in which the number of current amplification sections 50 is small, the selection section 40 may be structured by the level shifter 46 and the switches 52 for example, as shown in
Next, variant examples of the embodiment described above will be described with reference to FIGS. 7 to 9.
For the embodiment described above, an example has been described of a waveform preparation circuit at which only one of the voltage amplification section 54 is provided. However, as shown in
With such a waveform preparation circuit 135, the selection section 40 selects at least one among the plurality of series circuits in accordance with a concurrent driving count of the actuators 7 or a printing density, and inputs the driving signal generated by the standard waveform generation section 56 to the input terminal(s) of the selected series circuit(s). The voltage amplification section 54 to which the driving signal is inputted amplifies the voltage component of the driving signal and outputs the same. When the driving signal outputted from the voltage amplification section 54 is inputted to the current amplification section 50 to which the voltage amplification section 54 is connected in series, the current amplification section 50 amplifies the current component of the driving signal. With this structure too, it is possible to adjust the current component of the driving signal in accordance with loading variations, and it is possible to regulate the waveform of the driving signal. Further, because the series circuits which are not selected are in a driving-paused state, it is possible to suppress power consumption accordingly. Further, with this structure too, wiring is not made particularly complicated. Therefore, size of the apparatus will not be increased.
Further again, as shown in
With such a waveform preparation circuit 235, the selection section 40 selects at least one among the plurality of series circuits in accordance with a concurrent driving count of the actuators 7 or a printing density, and inputs waveform data from the control section 31 to the input terminal(s) of the selected series circuit(s). The standard waveform generation sections 56 at which the waveform data is inputted generates and outputs the driving signal. When the driving signal from the standard waveform generation section 56 is inputted to the voltage amplification section 54 to which the standard waveform generation section 56 is connected in series, the voltage amplification section 54 amplifies the voltage component of the driving signal and outputs the signal whose voltage component has been amplified. When the driving signal from the voltage amplification section 54 is inputted to the current amplification section 50 to which the voltage amplification section 54 is connected in series, the current amplification section 50 amplifies the current component of the driving signal.
With this structure too, it is possible to adjust the current component of the driving signal in accordance with loading variations, and it is possible to regulate the waveform of the driving signal. Further, because the series circuits which are not selected are in the driving-paused state, it is possible to suppress power consumption accordingly. Further, with this structure too, wiring is not made particularly complicated. Therefore, size of the apparatus will not be increased.
In a recording head driving device of the structures described above, each generation section may be structured by: a digital waveform generation section, which generates a signal with a standard digital waveform; and an analog waveform generation section, which generates a signal with an analog waveform from the signal generated by the digital waveform generation section.
Further, as shown in
With such a waveform preparation circuit 335, the selection section 40 selects at least one among the plurality of series circuits in accordance with a concurrent driving count of the actuators 7 or a printing density, and inputs the driving signal generated by the digital standard waveform generation section 156 to the input terminal(s) of the selected series circuit(s).
The analog standard waveform generation section 256 at which the digital waveform driving signal is inputted generates and outputs the analog waveform driving signal. When the driving signal from the analog standard waveform generation section 256 is inputted to the voltage amplification section 54 to which the analog standard waveform generation section 256 is connected in series, the voltage amplification section 54 amplifies the voltage component of the driving signal and outputs the signal whose voltage component has been amplified. When the driving signal from the voltage amplification section 54 is inputted to the current amplification section 50 to which the voltage amplification section 54 is connected in series, the current amplification section 50 amplifies the current component of the driving signal.
With this structure too, it is possible to adjust the current component of the driving signal in accordance with loading variations, and it is possible to regulate the waveform of the driving signal. Further, because the series circuits which are not selected are in the driving-paused state, it is possible to suppress power consumption accordingly. Further, with this structure too, wiring is not made particularly complicated. Therefore, size of the apparatus will not be increased.
Anyway, for the embodiment including the variant examples described above, examples have been described of printing apparatuses (recording heads) at which waveform preparation circuits are plurally provided and which are capable of performing tone printing. However, the waveform preparation circuit may be provided singly at a recording head (which will not perform tone printing), and is not particularly limited.
Note that structures of the recording head driving device are not particularly limited as long as the structures realize the functions of the present invention. For example, structures are possible in which the functions are separated, being divided between a circuit which features a voltage amplification function and a circuit which features a current amplification function, structures are possible in which the voltage amplification function and the current amplification function are integrated as a power amplification circuit, and structures are not particularly limited.
For the embodiment described earlier, a case in which ink is employed as droplets has been described as an example. However, the present invention is not limited thus. Instead of ink, for example, a reaction fluid could be employed. A reaction fluid is a fluid which is employed for, for example, promoting solidification of ink droplets which have been ejected or the like. More specifically, a mixing of ink droplets with the reaction fluid droplets on a recording medium improves image quality. Therefore, when reaction fluid droplets are to be ejected by droplet ejectors, the present invention can be employed in the same manner as described above. Further, with the inkjet process, the present invention can be applied in the same manner as described above to application of an orientation film formation material for liquid crystal displaying elements, application of flux, application of adhesive, and so forth.
Further, the recording head which is driven by each of the inventions described above may be a recording head for an FWA (full width array) system printing apparatus, in which recording is performed while only a recording medium is being conveyed, with the recording head staying fixed, and may be a recording head for a PWA (partial width array) system printing apparatus, which prints by moving the recording head in a main scanning direction while moving recording paper in a sub-scanning direction.
According to the invention as explained hereabove, excellent effects are achieved in that it is possible to prevent distortions of a driving signal waveform due to loading variations, without providing dummy loads, and it is possible to suppress power consumption and an increase in size of an apparatus.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2005-026170 | Feb 2005 | JP | national |
