1. Field of the Invention
The present invention relates to a device for driving a recording head that conducts recordings on a record medium, and also to a recording apparatus.
2. Description of Related Art
Various types are known as a recording head that conducts recording on a record medium. A mentionable example thereof is an ink-jet head that performs printing by ejecting ink through a large number of nozzles. Some ink-jet heads change the amount of ink ejected through the respective nozzles during one printing cycle, to thereby achieve gradation printing.
For example, Japanese Patent Unexamined Publication No. 2000-158643 discloses that transmitted from a main circuit of an ink-jet recording apparatus to a head driver are a plurality of waveform signals that are to be used for performing gradation printing and select data sets that include a predetermined number of bits and correspond to respective nozzles and also to any one of the plurality of waveform signals. In the head driver, a predetermined one of the plurality of waveform signals is selected for every nozzle based on the select data set corresponding to that nozzle. Ink is ejected through the nozzle in accordance with the waveform signal thus selected. In a case where, for example, four waveform signals that correspond to respective four ink-ejection mode (e.g., four cases where the ink ejection amount is zero, small, middle, and large) are transmitted to the head driver, the select data set which is used for selecting, for each nozzle, any one of these four waveform signals is constituted of two-bit data in order to have one-to-one correspondence with the four waveform signals. Here, the ink ejection amount being zero means no ink ejection performed.
In many cases, the number of signal lines through which the select data sets are serially transmitted from the main circuit to the head driver is the same as the number of bits included in the select data set, because it simplifies circuitries. For example, two signal lines are adopted in order to transmit two-bit select data set to the head driver, and three signal lines are adopted in order to transmit three-bit select data set to the head driver.
The number of nozzles has seen a recent trend of considerable increase in order to meet a demand for high-quality and high-speed printings. In addition, there arises a need of increasing the number of waveform signals for the purpose of performing a multi-gradation printing to thereby improve print quality. An increase in the number of waveform signals inevitably involves an increase in the number of bits included in a select data set that is to be used for selecting, for each nozzle, any one of a plurality of waveform signals. Thus, not only nozzles but also bits included in a select data set for each nozzle are increased in number. As a result, the select data transmitted from a main body to a head driver of a recording apparatus include a considerably increased number of bits in total. When, like this, the total number of bits included in the transmitted select data is increased, a longer transmission time is required. This causes difficulty in high-speed printing which should have been an original object, However, when the select data are transmitted at a higher rate (i.e., when a clock signal applied for every transmission has a higher frequency) for the purpose of high-speed printing, signal lines emit more noise during transmission, to adversely affect peripheral devices of the recording apparatus.
An object of the present invention is to provide a device for driving a recording head and a recording apparatus, which are capable of suppressing emitted noise and at the same time shortening a transmission time.
According to a first aspect of the present invention, there is provided a device for driving a recording head comprising: a plurality of select data input elements; a waveform signal selector; and a drive signal supplier. To the plurality of select data input elements, a plurality of select data sets corresponding to a plurality of recording elements included in the recording head are inputted in a serial manner. Each one of the select data sets indicates which one among a plurality of waveform signals is to be employed for a corresponding recording element in a single printing cycle. The waveform signal selector selects, for each of the recording elements, one among the plurality of waveform signals on the basis of a corresponding one among the plurality of select data sets inputted to the select data input elements. The drive signal supplier supplies, based on a waveform signal selected by the waveform signal selector, a drive signal to each of the plurality of recording elements. The number of the select data input elements is greater than the number of bits included in each of the select data sets. The number of signal lines through which the plurality of select data sets are inputted to the select data input elements in a serial manner is the same as the number of the select data input elements.
Like this, the number of signal lines through which the select data sets are transmitted is greater than the number of bits included in each of the select data sets. In such a case, as compared with a case where the number of signal lines is the same as the number of bits included in each of the select data sets, the select data can be transmitted at a less rate (which means that a clock signal applied to the device for every transmission has a lower frequency), to thereby suppress noise emitted from the respective signal lines. This can shorten a transmission time and therefore allows higher-speed printings.
According to a second aspect of the present invention, there is provided a recording apparatus comprising a recording head including a plurality of recording elements; a device for driving the recording head; and a main circuit. The main circuit comprises: a waveform signal generator; a distributor; a plurality of select data generators; and a transmitter. The waveform signal generator generates a plurality of waveform signals to be used for driving the plurality of recording elements in different modes from one another. The distributor distributes a plurality of pixel data sets corresponding to the plurality of recording elements into a plurality of groups on a pixel-data-set basis. Each one of the pixel data sets indicates which gradation value is to be employed for a corresponding recording element in a single printing cycle. The plurality of select data generators correspond to the plurality of groups respectively and generate, on the basis of the plurality of pixel data sets, a plurality of select data sets each including such a number of bits as adequate to indicate the plurality of waveform signals respectively. Each one of the select data sets indicates which one among the plurality of waveform signals is to be employed for a corresponding recording element in a single printing cycle. The transmitter includes a plurality of signal lines through which the plurality of select data sets are transmitted to the device. The number of the signal lines is the same as the number of the groups so that the plurality of signal lines connects the plurality of select data generators with the device for driving the recording head for each of the groups. The device for driving the recording head comprises; a plurality of select data input elements; a waveform signal selector; and a drive signal supplier. To the plurality of select data input elements, the plurality of select data sets are inputted in a serial manner through the plurality of signal lines. The waveform signal selector selects, for each of the recording elements, one among the plurality of waveform signals on the basis of a corresponding one among the plurality of select data sets inputted to the select data input elements. The drive signal supplier supplies, based on a waveform signal selected by the waveform signal selector, a drive signal to each of the plurality of recording elements. The number of the signal lines is greater than the number of bits included in each of the select data sets.
The aforementioned recording apparatus provides the same effects as those obtained by the device according to the aforesaid first aspect.
Other and further objects, features and advantages of the invention will appear more fully from the following description taken in connection with the accompanying drawings in which:
In the following, some preferred embodiment of the present invention will be described with reference to the accompanying drawings.
First, referring to FIGS. 1 to 7, a description will be given to a construction of an ink-jet printer according to a first embodiment of the present invention.
As illustrated in
The carriage 64 is supported in a slidable manner by a guide shaft 71 and a guide plate 72 both disposed in parallel with the axis of the platen roller 66. Pulleys 73 and 74 are supported near both ends of the guide shaft 71, and are spanned with an endless belt 75. The carriage 64 is secured to the endless belt 75. In the drive mechanism 65 thus constructed, when one pulley 73 is driven in reversible rotation by a motor 76, the carriage 64 is accordingly reciprocated in linear direction along the guide shaft 71 and the guide plate 72, so that the ink-jet heads 6 are also reciprocated.
A paper 62 is fed from a paper feed cassette (not illustrated) provided at one side of the ink-jet printer 100, then guided into a space between the ink-jet heads 6 and the platen roller 66, then subjected to a predetermined printing with ink ejected through the ink-jet heads 6, and subsequently discharged from the ink-jet printer 100.
A purge system 67 is provided for forcibly sucking and removing defective ink which contains bubbles, dusts, or the like accumulated inside the ink-jet heads 6. The purge system 67 locates on one side of the platen roller 66. A position of the purge system 67 is determined such that, when the drive mechanism 65 brings the ink-jet heads 6 into a reset position, the purge system 67 may face the ink-jet heads 6. The purge system 67 includes a purge cap 81 that is to be attached to lower ends of the ink-jet heads 6 so as to cover many nozzles 35 (see FIGS. 2 to 6) formed on a lower face of the ink-jet heads 6.
As illustrated in
As illustrated in FIGS. 3 to 6, the passage unit 10 has a layered structure in which six thin plates made of metal are laminated and bonded to one another. The six thin plates are a nozzle plate 11, a damper plate 12, two manifold plates 13× and 13Y, a spacer plate 14, and a base plate 15.
Referring to
As illustrated in
Referring to
Referring to
The actuator unit 20 will next be described.
As illustrated in
A common electrode 25 common to a plurality of pressure chambers 36 is formed on an upper face of the other piezoelectric sheet 22. The common electrode 25 also has its one end 25a exposed on a side face of the actuator unit 20, which is similar to the one end 24a of the driving electrode 24. A portion of the piezoelectric sheet 22 sandwiched between each driving electrode 24 and the common electrode 25 acts as a pressure generation portion that corresponds to each pressure chamber. Surface electrodes 27 corresponding to the common electrode 25 and many surface electrodes 26 corresponding to the respective driving electrodes 24 are formed on an upper face of the insulating sheet 23 of the top layer. The surface electrodes 27 and 26 are arranged along both edges of the insulating sheet 23.
First recesses 30 and second recesses 31 are formed in side faces of the insulating sheet 23 and the piezoelectric sheets 21 and 22. A position of the first recess 30 corresponds to the one end 24a of the driving electrode 24. A position of the second recess 31 corresponds to the one end 25a of the common electrode 25. The first recesses 30 and the second recesses 31 extend in a lamination direction of the sheets. Formed in each first recess 30 is a side-face electrode that connects each driving electrode 24 with each surface electrode 26. Formed in each second recess 31 is a side-face electrode that connects each common electrode 25 with each surface electrode 27. Reference numbers 28 and 29 denote electrodes of dummy patterns.
The passage unit 10 and the actuator unit 20 are put in layers such that the pressure chambers 36 of the passage unit 10 may correspond to the respective driving electrodes 24 of the actuator unit 20. On the upper face of the actuator unit 20, the flexible flat cable 40 and the surface electrodes 26 and 27 are electrically bonded to each other. One actuator that ejects ink droplets from corresponding nozzles 35 is constituted by: the surface electrodes 26 and the individual electrodes 24 corresponding to the respective pressure chambers 36; the surface electrodes 27 and the common electrode 25; and the piezoelectric sheets 21, 22, and 23.
In the ink-jet printer 100 of this embodiment, the individual ink passage (Ch) including the nozzle 35 and the aforementioned actuator are equivalent to a recording element according to the present invention.
When pressure is selectively applied to between the common electrode 25 and the driving electrode 24 that is electrically connected to the surface electrode 26, a portion of the piezoelectric sheet 22 corresponding to the pressurized driving electrode 24 is distorted in the lamination direction due to piezoelectric. Thereby, the volume of the corresponding pressure chamber 36 is reduced. This raises pressure of ink contained in the pressure chamber 36, so that the ink is ejected through the nozzle 35.
Next, with reference to FIGS. 8 to 20, a detailed description will be given to an electrical construction for ink ejection of the ink-jet printer 100.
As shown in
Referring to
An external device such as a personal computer inputs the pixel data sets concerning a to-be-printed image to the controller 101 via an I/F (interface) controller 112. These pixel data sets are, via a DMA (Direct Memory Access) controller 114, stored in an SDRAM (Synchronous Direct Random Access Memory) 113. The DMA controller 114 is under control of a MAIN controller 116 that is connected to a CPU 115.
In the ink-jet printer 100, the waveform signal generator 110 generates the six waveform signals (FIRE1-FIRE6), based on which gradation printing can be performed.
As shown in
Then, the many pixel data sets stored in the SDRAM 113 are, on a set basis, distributed into four groups by the distributor 111. The distributor 111 includes two pixel RAMs 117, 118 (Bank1, Bank0) which are SRAMs (Static Random Access Memories), and a read address counter 119. As shown in
The pixel data sets are forwarded from the pixel RAM 117 (or 118) to the four select data generators 130 to 133 in the order indicated by the arrows of
The select data generators 130 to 133 comprise memories for storing eight-dot pixel data sets (each having 16 bits) that have been distributed into four groups by the distributor 111. Based on the pixel data sets, the select data generators 130 to 133 generate select data sets, each of which is used for selecting, in the later-described driver IC 103, any one of seven waveform signals FIRE1 to FIRE6 and VDD1 in correspondence with each nozzle 35 (i.e., each channel). Here, the signal VDD1 is always kept at the same potential as the high level of the remaining six waveform signals FIRE1 to FIRE6. As shown in
Each of the select data generators 130 to 133 calculates a hysteresis in consideration of the last (immediately preceding) ink ejection amount, and thereby determines which waveform signal is suitable for the current ink ejection amount, and then generates a select data set that corresponds to the suitable waveform signal. To be more specific, as shown in
Referring to a table of
Referring to, in the table of
When ink was ejected last time with smaller ejection amount than that of this time, the last ink ejection is considered to give little influence on the current ink ejection characteristics. Therefore, generated is a select data set d0 to d2 that corresponds to the waveform signal (FIRE1, FIRE2, or FIRE3) for normal ink ejection amount of small, middle, or large, which is the same as in the aforementioned case where the last ink amount was zero.
When the last ink ejection amount is larger than the current ink ejection amount or when the last ink ejection amount is large and current ink ejection amount is also large, the last ink ejection is considered to give much influence on the current ink ejection characteristics. Therefore, generated is a select data set d0 to d2 that corresponds to the waveform signal (FIRE4, FIRE5, or FIRE6) for hysteresis control, whose first pulse width is shorter than a pulse width A of FIRE1 to FIRE3 (see
The three-bit select data sets d0 to d2 thus generated in the four select data generators 130 to 133 are transmitted to the transfer buffers 140 to 143 corresponding to the select data generators 130 to 133. The three-bit select data sets d0 to d2 are, as shown in
Next will be described a construction of the driver IC 103 of the ink-jet heads 6.
As shown in
The three-bit select data sets are, through the four signal lines 120 to 123 (see
As shown in FIGS. 18 to 20, the three-bit select data sets are, sequentially for every channel, inputted serially to the shift registers 160 to 163. Referring to
The shift registers 160 to 163 convert three-bit select data sets inputted thereto from serial data to parallel data, and then output, into the D-flip-flop 170, parallel signals Sx-0, Sx-1, and Sx-2 corresponding to every channel. Here, “x” represents a channel number, that is, represents any integer between 0 to 303. More specifically, in the shift register 160 x represents any integer between 0 to 75, in the shift register 161 x represents any integer between 76 to 151, in the shift register 162 x represents any integer between 152 to 227, and in the shift register 163 x represents any integer between 228 to 303.
At a rise timing of a strobe control signal STB which is forwarded from the main circuit 102, the D-flip-flop 170 turns the parallel signals Sx-0, Sx-1, and Sx-2 into select signals SELx-0, SELx-1, and SELx-2, and outputs the select signals SELx-0, SELx-1, and SELx-2 into the waveform signal selector 171 that is formed of a multiplexer.
Inputted to the waveform signal selector 171 are select signals SELx-0, SELx-1, and SELx-2 and seven waveform signals FIRE1 to FIRE6 plus VDD1. Based on the select signals SELx-0, SELx-1, and SELx-2, the waveform signal selector 171 selects corresponding one of the seven waveform signals FIRE1 to FIRE6 plus VDD1. Then, a selected waveform signal Bx is outputted into the driver buffer 172. The driver buffer 172 turns the waveform signal Bx which has been output from the waveform signal selector 171 into an ejection pulse signal OUTx having a predetermined voltage, and supplies the ejection pulse signal OUTx to an actuator corresponding to the channel.
In the above-described ink-jet printer 100, the three-bit select data set is, through the four signal lines 120 to 123, serially inputted from the main circuit 102 to the four select data input elements 150 to 153 of the driver IC 103. In this case, since the select data set is serially input through the signal lines, the number of signal lines can be easily increased no matter how many bits are included in the select data set. In this embodiment, the number of signal lines 120 to 123 (four signal lines) is greater than the number of bits included in the select data set (three bits) Accordingly, as compared with a case where the number of bits included in the select data set is the same as the number of signal lines, the select data can be transmitted from the main circuit 102 to the driver IC 103 at a less rate, to thereby suppress noise emitted from the respective signal lines 120 to 123. This can shorten a transmission time and therefore allows higher-speed printings.
In addition, the number of select data input elements 150 to 153 is one greater than the number of bits included in the select data set (three bits). Thus, the number of signal lines is increased just by one as compared with a case where the number of bit included in the select data set is the same as the number of signal lines. This enables a transmission rate to be reduced with utmost suppression of increase in cost which may otherwise be caused by an increased number of signal lines.
Next, a second embodiment of the present invention will be described with reference to
As shown in
More specifically, as shown in
In the second embodiment thus far described, one bit included in a select data set is inputted to each shift register 210 to 217 at both rise and fall timings of a transfer clock CLK. This enables a frequency of the transfer clock CLK to be reduced by half so that a transmission rate from the main circuit 102 (see
Next, a third embodiment of the present invention will be described with reference to
As shown in
The driver IC 303 includes a temperature sensor 330, a check circuit 331, and a switch circuit 332. The temperature sensor 330 detects a temperature of the driver IC 303. The switch circuit 332 outputs either one of an output (A) from the temperature sensor 330 and an output (B) from the check circuit 331. The check circuit 331 detects whether the main circuit 102 and the driver IC 303 are connected with each other, by checking whether there are normal inputs of waveform signals FIREm (m; any integer between 1 to 6) outputted from the main circuit 102 (see
Referring to
After the connection is confirmed, the switch signal nV-C inputted from the main circuit 102 to the shift register 313 is always kept at a low level. When the low-level switch signal nV-C is inputted from the select data input 153 through the shift register 313 and the D-flip-flop 320 to the switch circuit 332, the switch circuit 332 outputs a signal sent from the temperature sensor 330 through VTEMP-CHEK into the main circuit 102. This means that, after the connection is confirmed, a signal sent from the temperature sensor 330 is always outputted into the main circuit 102. Thus, the main circuit 102 monitors a temperature of the driver IC 303 all the time during the use of the ink-jet printer. When the temperature of the driver IC 303 becomes too high (e.g., 100 degrees C. or higher), the main circuit 102 takes measures to prevent heat from causing failure of the driver IC 303 by, e.g., adjusting a downtime of printing operation.
In the third embodiment thus far described, the signal line 123 (see
Control data sets transmissible through the signal line used basically for select data sets include not only the aforementioned switch signal nV-C but also various data sets for controlling a driving operation performed by the driver IC on the ink-jet head as follows. There may be mentioned for example a control data set including a trigger signal that, in order to regularly monitor an output from the temperature sensor 330, outputs a signal sent from the temperature sensor 330 through the VTEMP-CHEK to the main circuit 102 when the trigger signal is inputted. Alternatively, when inputted data comprises not only a signal group including, without the signal VDD1 which indicates no ejection, the six waveform signals FIRE1 to FIRE6 but also another signal group including six waveform signals FIRE1′ to FIRE6′ which indicate different ejection modes from the signals FIRE1 to FIRE6, the aforesaid control data set may be one including a select signal for selecting either one of these two signal groups. In such a case, ejection modes indicated by two waveform signal groups can properly be selected. In addition, the control data set may be one including a strobe control signal STB which acts as a reference signal for output timing of a select signal,.
The number of waveform signals transmitted from the main circuit 102 is not limited to six (FIRE1 to FIRE6). For example, a waveform signal having four pulses may be applied in order to eject ink droplets four times. Also adoptable is a waveform signal including, after one or more pulses for ink ejection, an additional stop pulse for restraining vibration of ink that remains in the nozzles after ink ejections. The number of waveform signals can properly be changed depending on various conditions such as required print quality. Change of the number of waveform signals may sometimes involve change of the number of bits included in each select data set. For example, when nine waveform signals (one of which indicates no ink ejection) are employed, a select data is constituted of four-bit data in order to have one-to-one correspondence with the nine signals.
It is not always necessary that the number of signal lines (which equals the number of select data input elements) through which the select data are transmitted from the main circuit of the printer to the driver IC of the ink-jet head is one greater than the number of bits included in each select data set. The number of signal lines can properly be determined in consideration of costs, a transmission rate of the select data, or the like.
Although the ink-jet head 6 of the above-described embodiments includes a piezoelectric actuator, the present invention is applicable to ink-jet heads that include other actuators such as heaters, diaphragms, etc.
While this invention has been described in conjunction with the specific embodiments outlined above, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the preferred embodiments of the invention as set forth above are intended to be illustrative, not limiting. Various changes may be made without departing from the spirit and scope of the invention as defined in the following claims.
Number | Date | Country | Kind |
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2004-034333 | Feb 2004 | JP | national |