JPH1081013A - Ink jet printing head and ink jet printer using this printing head - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce the amount of transferred data to a printing head from a printer controlling while realizing high grade gradation printing without lowering the printing efficiency in relation to time for printing by controlling the diameter of a recording dot variably on a recording paper. SOLUTION: A drive signal generating circuit 8 generates a single drive signal based on a first pulse, a second pulse, a third pulse and a fourth pulse totaling four drive pulses. Various types of ink droplet are jetted from a single nozzle by selecting either one of the drive pulses or a plural number of the drive pulses within a single printing cycle. Gradation data from a printer controller 1 is compressed into two bits. The gradation data is translated into 4-bit print data by a decoder 17 and a control logic 18 in a printing head 10. Consequently, it is possible to reduce the amount of transferred data to the printing head 10.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an ink jet print head capable of ejecting ink droplets of different sizes from the same nozzle, and an ink jet printer using the print head. The present invention relates to an ink jet print head capable of discharging a plurality of ink droplets and an ink jet printer using the print head.

[0002]

2. Description of the Related Art An ink jet printer has a print head provided with a large number of nozzles in a sub-scanning direction (vertical direction). The print head is moved in a main scanning direction (horizontal direction) by a carriage mechanism. A desired print result is obtained by performing a predetermined paper feed. Based on dot pattern data obtained by developing print data input from a host computer, ink droplets are ejected from nozzles of the print head at predetermined timings, and these ink droplets are printed on a recording medium such as recording paper. Printing is performed by landing on and adhering to. As described above, since the ink jet printer is for controlling whether or not to eject ink droplets, that is, performs dot on / off control, it is not possible to print out an intermediate gray level such as gray as it is.

In view of the above, for example, a method of realizing an intermediate gradation by expressing one pixel by a plurality of dots such as 4 × 4, 8 × 8, etc. has been adopted. If one pixel is represented by a 4 × 4 dot matrix, the gradation can be represented by 16 gradations (17 gradations including all white). If the resolution of the pixel is increased, the gradation can be expressed more finely. However, if the gradation is increased without changing the recording dot diameter, the actual resolution will decrease. In addition, when the recording dot diameter on the recording paper is large, the granularity of the low density region becomes conspicuous. Therefore, it is necessary to reduce the weight of the ink droplet to reduce the recording dot diameter.

For example, as described in Japanese Patent Application Laid-Open No. 55-17589, so-called "pulling", in which a pressure chamber containing ink is expanded and then contracted.
By performing the above, it is possible to reduce the weight of the ejected ink droplets and to reduce the recording dot diameter.

[0005] When the recording dot diameter is small, the printing quality can be improved without noticeable graininess in a low density area, but the printing speed is greatly reduced. For example, when using a small diameter dot which is half the normal recording dot diameter, it takes four times as long as when using a normal recording dot diameter. In order to prevent the printing speed from lowering, the driving frequency for ejecting ink droplets may be increased four times or the number of nozzles may be increased four times, but neither is easy.

In view of the above, there has been proposed a technique for ejecting ink droplets of different weights from the same nozzle to enable gradation storage (for example, Japanese Patent Publication No. Hei 4-15735, US Pat. No. 5,285,215). Specification). With such technology,
By applying a plurality of pulse signals, a plurality of minute ink droplets are generated, and before landing on the recording paper, the plurality of minute ink droplets are combined to generate a large ink droplet.

[0007]

According to the prior art described in the above-mentioned publication, it is possible to eject a small ink droplet and a large ink droplet, but it is difficult to combine the ink droplets before the recording paper lands. Further, since it is necessary to combine minute ink droplets before landing on the recording paper, there is a problem that the variable range of the recording dot diameter is narrow.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described various problems, and an object of the present invention is to make it possible to eject a plurality of ink droplets having different ink weights from the same nozzle without lowering the printing speed. An object of the present invention is to provide an ink jet print head and an ink jet printer using the print head. A more specific object of the present invention is to reduce the transfer amount of gradation data input to the print head and the number of signal lines between the print head and the printer main body while reducing a plurality of ink droplets during one printing cycle. An object of the present invention is to provide an ink jet print head capable of discharging a plurality of inks and an ink jet printer using the print head.

[0009]

In order to achieve the above object, an ink jet print head according to the present invention comprises a plurality of drive pulses for a drive signal output for each printing cycle, and corresponds to each drive pulse. According to the print data including the pulse selection signal, any one or a plurality of drive pulses are selected from the respective drive pulses, and gradation data is translated into the print data inside the print head.

That is, according to the first aspect of the present invention, a switch for supplying a drive signal including a plurality of input drive pulses to the pressure generating element, a storage for storing the input gradation data, Translation means for translating the gradation data into print data comprising a pulse selection signal provided in correspondence with each of the drive pulses, wherein any one of the drive pulses is provided based on the print data. One or more drive pulses are selectively input to the pressure generating element within one printing cycle.

When a certain drive pulse is selected by the pulse selection signal, this drive pulse is input to the pressure generating element via the switch. Then, since the pressure generating element causes a pressure change according to the drive pulse, an ink droplet having an ink amount corresponding to the pressure change is ejected. Therefore, if one drive pulse is selected, one ink droplet is ejected in one printing cycle, and if a plurality of drive pulses are selected, a plurality of ink drops are ejected in one printing cycle. Thereby, the amount of ink that lands on a print storage medium such as recording paper is adjusted,
The recording dot diameter can be variably controlled. Further, since the translation means translates the gradation data into print data inside the print head, the transfer amount of the gradation data to the print head can be reduced. Therefore, the frequency of the transfer clock of the gradation data can be reduced.

The invention according to claim 2 is characterized in that the translation means translates the gradation data into the print data based on a timing detection signal for detecting the generation timing of each of the drive pulses.

If the gradation data is translated into print data based on the timing detection signal, the pressure generating element can be driven according to the generation of a desired drive pulse.

The invention according to claim 4 is characterized in that the data of each digit of the gradation data is input independently to each storage circuit constituting the storage means.

Thus, since the gradation data can be transferred to the storage means in parallel, the transfer speed of the gradation data to the storage means can be increased.

In the invention according to claim 6, which is a preferred embodiment of the present invention, the drive signal includes a first drive pulse for discharging the first ink droplet and a first drive pulse for discharging the first ink droplet. A second driving pulse for discharging the second ink droplet and a third driving pulse for discharging the same amount of the third ink droplet as the first ink droplet. It is characterized by.

According to this, the driving signals output in each printing cycle include a first driving pulse and a third driving pulse for discharging the same amount of ink droplets and a second driving pulse for discharging a small amount of ink droplets. And three driving pulses in total. Therefore, the recording dot diameter can be variably controlled by a combination of the first, second, and third ink droplets.

[0018]

Embodiments of the present invention will be described below in detail with reference to the drawings.

1. First Embodiment First, FIG. 1 is a functional block diagram of an ink jet printer to which a first embodiment of the present invention is applied.

1-1 Overall Configuration The ink-jet printer comprises a printer controller 1 as "printer control means" and a print engine 2. The printer controller 1 includes an interface (hereinafter referred to as “I / F”) 3 for receiving print data and the like from a host computer (not shown), a RAM 4 for storing various data, a routine for processing various data, and the like. , A control unit 6 including a CPU, an oscillation circuit 7, and a print head 1 described later.
A drive signal generating circuit 8 as “drive signal generating means” for generating a drive signal to “0”, and print data and drive signals developed into dot pattern data (bitmap data) to the print engine 2. An I / F 9 is provided.

The I / F 3 receives, for example, any one of character code, graphic function, and image data or print data including a plurality of data from a host computer or the like. Further, the I / F 3 can output a busy signal (BUSY), an acknowledge signal (ACK), and the like to the host computer.

The RAM 4 is used as a receiving buffer 4A, an intermediate buffer 4B, an output buffer 4C, a work memory (not shown), and the like. Receive buffer 4A
, The print data received from the host computer by the I / F 3 is temporarily stored. The intermediate buffer 4B stores the intermediate code data converted into the intermediate code by the control unit 6. The dot pattern data is developed in the output buffer 4C. The ROM 5 stores various control routines executed by the control unit 6, font data, graphic functions, various procedures, and the like.

The control section 6 reads out the print data in the reception buffer 4A, converts it into an intermediate code, and stores the intermediate code data in the intermediate buffer 4B. Next, the control unit 6
Analyzes the intermediate code data read from the intermediate buffer 4B, and develops the intermediate code data into dot pattern data with reference to font data and graphic functions in the ROM 5. The expanded dot pattern data is subjected to necessary decoration processing and then output to the output buffer 4C.
Is stored.

When dot pattern data corresponding to one line of the print head 10 is obtained, the dot pattern data for one line is transferred to the print head 1 via the I / F 9.
0 is serially transmitted. When one line of dot pattern data is output from the output buffer 4C, the contents of the intermediate buffer 4B are deleted, and the next intermediate code conversion is performed. Here, the data in the output buffer 4C developed into the dot pattern data is composed of, for example, 2 bits as gradation data for each nozzle, as described later.

The drive signal generating circuit 8 generates a single drive signal composed of a plurality of drive pulses, as shown in FIG.

The print engine 2 includes a print head 1
0, a paper feed mechanism (abbreviated as “paper feed” in the figure) 11, and a carriage mechanism (abbreviated as “carriage” in the figure) 12. The paper feed mechanism 11 includes a paper feed motor, a paper feed roller, and the like, and sequentially feeds a print storage medium such as a recording paper to perform sub-scanning. Carriage mechanism 12
Is composed of a carriage on which the print head 10 is mounted, a carriage motor for moving the carriage via a timing belt or the like, and the main scanning of the print head 10.

The print head 10 has a large number of nozzles such as 64 in the sub-scanning direction, and discharges ink droplets from each nozzle at a predetermined timing. The grayscale data (SI) from the print controller 1 is synchronized with the clock signal (CK) from the oscillation circuit 7 by the I / F 9.
Is serially transmitted to a first shift register (indicated as “SR” in the figure) 13 and a second shift register 14 as “serial / parallel conversion means”. As described later, the data of the most significant bit (MSB) of the grayscale data is input to the second shift register 14, and the least significant bit (LSB)
The data B) is input to the first shift register 13.

A first latch circuit 15 and a second latch circuit 16 as "latch means" are connected to the shift registers 13 and 14, respectively. Then, when a latch signal (LAT) from the printer controller 1 is input to each of the latch circuits 15 and 16, the respective latch circuits 15, 16
Latches the grayscale data converted in parallel by the shift registers 13 and 14, respectively. Therefore, the first
The latch circuit 15 latches the data of the least significant bit of the grayscale data, and the second latch circuit 16 latches the most significant bit of the grayscale data. Here, the first shift register 13, the first latch circuit 15, and the second shift register 14
And the second latch circuit 16 constitute a “storage circuit”, respectively, and these two storage circuits constitute a “storage unit”.

The gradation data latched by each of the latch circuits 15 and 16 is input to a decoder 17. The decoder 17 translates 2-bit gradation data into 4-bit print data according to a signal from the control logic 18. Therefore, the "translating means" is constituted by the decoder 17 and the control logic 18. Some specific preferred embodiments of the decoder 17 and the control logic 18 will be described later.

The print data translated by the decoder 17 and the like is boosted by the level shifter 19 as a voltage amplifier to a voltage that can drive the switch circuit 20, for example, a predetermined voltage value of about several tens of volts. The print data boosted to a predetermined voltage value is given to a switch circuit 20 as "switch means". A drive signal (COM) from the drive signal generation circuit 8 is applied to an input side of the switch circuit 20, and a piezoelectric vibrator 21 as a “pressure generation element” is connected to an output side of the switch circuit 20. ing.

The print data controls the operation of the switch circuit 20. For example, while the print data applied to the switch circuit 20 is “1”, the drive signal is
And the piezoelectric vibrator expands and contracts according to the drive signal. On the other hand, while the print data applied to the switch circuit 20 is “0”, the supply of the drive signal to the piezoelectric vibrator 21 is cut off.

1-2 Specific Configuration of Printhead FIG. 2 is a circuit diagram specifically showing the configuration of the printhead 10. As shown in FIG. In FIG. 2, the control logic 18 and the level shifter 19 are omitted. Each of the shift registers 13 and 14 and each of the latch circuits 15 and 16 in FIG.
Decoder 17, switch circuit 20, and piezoelectric vibrator 21
Are elements 13A to 13N, 14A to 14N, and 15A to 15N corresponding to each nozzle of the print head 10, respectively.
N, 16A-16N, 17A-17N, 20A-20
N, 21A to 21N. The gradation data from the printer controller 1 is, for example, (10), (0
As described in 1) and the like, each nozzle is composed of a total of 2 bit data from the most significant bit 1 to the least significant bit 0. Then, data of bit 0 for all nozzles is input to the first shift registers 13A to 13N, and data of bit 1 for all nozzles is input to the second shift registers 14A to 14N.

Each shift register 13A to 13N, 14A
The grayscale data for each nozzle input to １４14N is latched by each of the latch circuits 15AＮ15N and 16A〜16N and input to the decoders 17A〜17N. Decoder 1
7A to 17N translate 2-bit gradation data into 4-bit print data based on a signal from the control logic 18.

When the bit data applied to each of the switch elements 20A to 20N configured as analog switches is "1", for example, a drive signal (COM) is directly applied to the piezoelectric vibrators 21A to 21N, and Child 21
A to 21N are displaced in accordance with the signal waveform of the drive signal. Conversely, when the bit data applied to each of the switch elements 20A to 20N is "0", the drive signal to each of the piezoelectric vibrators 21A to 21N is cut off, and each of the piezoelectric vibrators 21A to 21N holds the previous charge. .

FIG. 3 shows an example of a mechanical structure of the print head 10. The substrate unit 31 is configured by sandwiching a flow path forming plate 34 between a nozzle plate 32 having a nozzle hole 32A formed therein and a vibration plate 33 having an island portion 33A formed therein. An ink chamber 35, an ink supply port 36, and a pressure generating chamber 37 are formed in the flow path forming plate 34.

A housing chamber 39 is formed in the base 38, and the piezoelectric vibrator 21 (more precisely, any of the piezoelectric vibrators 21A to 21N) is mounted in the housing chamber 39. The piezoelectric vibrator 21 is fixed via a fixed substrate 40 such that the tip thereof comes into contact with the island portion 33A of the diaphragm 33. Here, for example, PZT having a longitudinal vibration lateral effect is used for the piezoelectric vibrator 21, and contracts when charged and expands when discharged. The charging and discharging of the piezoelectric vibrator 21 is performed via the lead wire 41.

The piezoelectric vibrator 21 is not limited to the PZT of the longitudinal vibration / lateral effect, but may be a flexural vibration type PZT. Further, the pressure generating element is not limited to the piezoelectric vibrator, and another element such as a magnetostrictive element may be used. Alternatively, the ink may be heated by a heat source such as a heater, and the pressure may be changed by bubbles generated by the heating. In short, the pressure generating chamber 37 depends on a signal given from outside.
Any element can be used as long as it causes a pressure fluctuation inside.

When the piezoelectric vibrator 21 is charged, the piezoelectric vibrator 21 contracts, the pressure generating chamber 37 expands, and the pressure generating chamber 3 expands.
7, the pressure in the ink chamber 35 drops from the pressure chamber 37.
The ink flows into the inside. When the piezoelectric vibrator 21 is discharged, the piezoelectric vibrator 21 expands, the pressure generating chamber 37 contracts, and the pressure in the pressure generating chamber 37 increases to increase the pressure in the pressure generating chamber 37.
The ink inside is ejected to the outside through the nozzle hole 32A.

1-4 Relationship between Each Drive Pulse and Gradation Expression Next, a driving signal, an ejected ink droplet, and a gradation expression method will be described with reference to FIG. FIG. 4 shows the waveform of the drive signal and the magnitude relationship of the ejected ink droplets, and also shows a method of gradation expression using the drive signal. The drive signal generated by the drive signal generation circuit 8 is
A first pulse as a “first drive pulse”, a second pulse as a “second drive pulse”, a third pulse as a “third drive pulse”, and a “fourth drive pulse” And four drive pulses in total.

Here, the first pulse and the third pulse have the same pulse shape, for example, for ejecting a medium ink droplet of about 10 ng. This first pulse,
Since the dot diameter obtained by the third pulse is a medium size, the first pulse and the third pulse can be expressed as “medium dot pulse”. The second pulse is located between the first pulse and the third pulse,
For example, this is for discharging a small ink droplet of about 2 ng. Since a small dot diameter is obtained by the second pulse, the second pulse can be expressed as a “small dot pulse”. The fourth pulse positioned between the third pulse and the first pulse is for slightly vibrating the ink near the nozzle hole 32A to prevent an increase in the viscosity of the ink. Is not ejected. The fourth pulse can be expressed as a “micro vibration pulse”.

1-5 Details of Each Drive Pulse Next, each pulse constituting the drive signal will be described with reference to the reference numerals P11, P21 and the like attached to each portion of each pulse as shown in FIG. . Since the first pulse and the third pulse for forming the medium dot have the same shape,
Only the first pulse will be described, and description of the third pulse will be omitted.

First, as shown in FIG. 4, the voltage value of the first pulse starts from the intermediate potential Vm (P1).
1) With the predetermined voltage gradient θCM from the intermediate potential Vm, the “first
To the maximum potential VP as the “maximum potential of
2), the maximum potential VP is maintained for a predetermined time (P1
3). Next, the voltage value of the first pulse falls from the maximum potential VP to the minimum potential VL with a predetermined voltage gradient θDM (P14).

Here, the voltage gradient θDM during discharging is set to be larger than the voltage gradient θCM during charging. The time required for the voltage value of the first pulse to decrease from the maximum potential VP to the minimum potential VL is set to be substantially the same as the natural oscillation period TA of the piezoelectric vibrator 21.
Note that the lowest potential VL is preferably the same as the ground level (0 V) or a positive potential in order to prevent the polarization reversal of the piezoelectric vibrator 21.

Then, the voltage value of the first pulse rises to the intermediate potential Vm again (P16) after holding the minimum potential VL for a predetermined time (P15). Here, the maximum potential VP
The time from the start of the voltage drop to the end of the maintenance of the minimum potential VL is the natural period (Helmholtz frequency) T
C is set substantially the same.

As in the case of the first pulse, the voltage value of the second pulse starts from the intermediate potential Vm (P21) and rises to the maximum potential VP at a predetermined voltage gradient θCS (P22). Then, after maintaining the maximum potential VP for a predetermined time (P2
3) The voltage drops to the intermediate potential Vm with a predetermined voltage gradient θDS (P24). In the second pulse, the voltage gradient θCS during charging is set to be larger than the voltage gradient θDS during discharging.

Since the third pulse is the same as the first pulse, the description is omitted, but the time period between the first pulse and the third pulse is half the printing period. That is, the first pulse and the third pulse are used to form a large dot on the recording paper as described later.
When a pulse is selected, ink droplets corresponding to medium dots are ejected at equal time intervals. Specifically, for example, assuming that the printing cycle is 14.4 kHz, the ejection cycle of ink droplets corresponding to medium dots is set to 28.8 kHz. Also, the time between the first pulse and the third pulse is
The maximum drive cycle of the print head 10 is set.

Similarly to the first to third pulses, the voltage of the fourth pulse also starts from the intermediate potential Vm (P41) and, for example, the maximum potential VP that can be expressed as the "second maximum potential"
It rises to N (P42). Then, this maximum potential VP
After maintaining N for a predetermined time (P43), the voltage drops to the intermediate potential Vm. Here, since the fourth pulse gives a minute vibration that does not eject ink droplets, the maximum potential VPN of the fourth pulse is smaller than the maximum potential VPS of the second pulse. Further, the voltage gradient at the time of charging of the fourth pulse is substantially equal to the voltage gradient at the time of discharging.

1-6 Transfer Timing of Gradation Data and Translation into Print Data Next, the first pulse (medium dot), the second pulse (small dot), the third pulse (medium dot), and the fourth pulse (fine dot) vibration)
Is considered with reference to FIG.

As described above, while the bit of the print data applied from the decoder 17 to the switch circuit 20 is “1”, the drive signal is applied to the piezoelectric vibrator 21, and the piezoelectric vibrator 21 generates the waveform of the drive signal. It expands and contracts according to. On the other hand, while the bit of the print data is “0”, the piezoelectric vibrator 2
The supply of the drive signal to 1 is cut off, and the piezoelectric vibrator 21 maintains the state immediately before. Therefore, if the bits of the print data are synchronized with the generation timings of the first to fourth pulses, the first
Any one or more of the fourth to fourth pulses can be selected.

For example, in the case of no dot where no dot is formed (gradation value 1), in the case of forming only small dots (gradation value 2), in the case of forming only one medium dot (gradation value 3), If recording dots are formed on recording paper in four patterns when a large dot is formed by two medium dots (gradation value 4), four levels of dot gradation can be performed.

In the case of four gradations, the gradation value 1 is changed to (0
Each gradation value can be represented by 2-bit data such as 0), gradation value 2 (01), gradation value 3 (10), and gradation value 4 (11). Therefore, the printer controller 1
Is transmitted to the print head 10 in the form of data compressed to these two bits.

Non-dot gradation value 1 without ejection of ink droplets
In the case of (1), it is sufficient to supply the fourth pulse for generating the micro-vibration to the piezoelectric vibrator 21. Therefore, in the case of the gradation value 1, “0” is applied to the switch circuit 20 during the generation period of the first to third pulses, and “1” is applied in synchronization with the generation of the fourth pulse. Then, only the fourth pulse can be applied to the piezoelectric vibrator 21. That is, the decoder 17 translates (decodes) the 2-bit data (00) indicating the gradation value 1 into the 4-bit data (0001), so that only the fourth pulse that does not eject ink droplets is applied to the piezoelectric vibrator 21. Can have a dot value of 1
Can be realized.

Similarly, for the switch circuit 20, the first
When "0" is given during the pulse, the third pulse and the fourth pulse, and "1" is applied in synchronization with the second pulse, that is, the switch circuit 20 outputs 4-bit data (0100) at a predetermined timing. , Only the second pulse is supplied to the piezoelectric vibrator 21, whereby the ink droplet corresponding to the small dot lands on the recording paper, and the gradation value 2 can be realized.

Similarly, when the 4-bit data (1000) is given to the switch circuit 20, only the first pulse is applied to the piezoelectric vibrator 21.
Thus, a gradation value of 3 is realized.

Similarly, when the 4-bit data (1010) is given to the switch circuit 20, only the first and third pulses for forming the medium dot are supplied to the piezoelectric vibrator 21. As a result, two ink droplets equivalent to medium dots successively land on the recording paper, and the ink droplets are mixed to form substantially one large dot.

As described above, if print data is constituted by allocating one-bit data to each drive pulse, only a desired drive pulse can be selected according to the value of each bit. 1 assigned to each drive pulse
The bit data corresponds to the “pulse selection signal”. In the case where the fourth pulse is omitted, the gradation value of dotless 1
Is (000), the gradation value 2 of only the small dots is (010),
It is sufficient to translate the tone value 3 of the medium dot only into (100) and the tone value 4 of the large dot by two medium dots into (101) as 3-bit print data.

Next, a specific configuration for providing 4-bit print data to the switch circuit 20 and the like will be described with reference to the waveform diagram of FIG.

First, the 2-bit tone value (b1, b0) for each nozzle stored in the output buffer 4C is converted by the decoder 17 in the print head 10 into the 4-bit print data (D1, D2, D3, D4). Here, D1 is the selection signal of the first pulse, and D2 is the second pulse.
A pulse selection signal, D3 is a third pulse selection signal, D4
Is a selection signal of the fourth pulse. The 4-bit print data is supplied to a switch circuit 20 corresponding to each nozzle of the print head 10 within one printing cycle.

As shown in FIG. 5, 2
The bit gradation data (SI) is transferred to each of the shift registers 13 and 14 within one printing cycle, and is latched by each of the latch circuits 15 and 16 by the next latch signal. That is,
The gradation data to be executed in a certain printing cycle is transferred to the print head 10 in the immediately preceding printing cycle.

Then, the transferred gradation data is translated into 4-bit print data according to the generation timing of each drive pulse. The generation timing of each drive pulse is shown in FIG.
It is detected by the middle channel signal (CH) and the latch signal (LAT). That is, the generation timing of the first pulse is determined by the latch signal, the generation timing of the second pulse is determined by the channel signal (CH1), and the generation timing of the third pulse is determined by the channel signal (CH2).
The pulse generation timing is detected by the channel signal (CH3).

Therefore, in this embodiment, the "timing detection signal" is constituted by the latch signal and the channel signal. The channel signal (CH0) may be generated at the same timing as the latch signal, but in this case, the system becomes redundant. In other words, in the present embodiment,
The latch signal is also used as a first pulse generation timing detection signal.

When the generation of each drive pulse is detected, the decoder 17 outputs print data corresponding to the pulse to the switch circuit 20. That is, for example, when the generation of the first pulse is detected by the latch signal, the data of D1 is output for each nozzle, and when the second pulse is detected, the data of D2 is output for each nozzle. Accordingly, when the value of D1 given to the nozzle is “1”, the piezoelectric vibrator 21 expands and contracts according to the first pulse, so that an ink droplet equivalent to a medium dot is ejected from the nozzle, and this ink droplet is recorded. Landing on the paper forms medium dot recording dots.
On the other hand, the nozzle with the given value of D1 being “0” does not eject ink droplets because the first pulse is not applied to the piezoelectric vibrator 21.

FIG. 6 shows a pattern obtained by combining each drive pulse. As described above, if 4-bit print data (0100) is given, a small dot becomes
When (1000) is given, a medium dot is obtained, when (1010) is given, a large dot due to two medium dots is obtained, and when (0000) is given, a non-dot with only slight vibration is obtained.

According to this embodiment, the 2-bit gradation data transferred from the printer controller 1 is translated into 4-bit print data by the decoder 17 and the control logic 18 in the print head 10. 1 and the print head 10 can reduce the amount of data transfer. For example, when the data is translated into print data in the printer controller 1, if the number of nozzles is 64, 64 × 4 bits, that is, 256 bits of data must be transferred to the print head 10 within one printing cycle. On the other hand, according to the present invention, the printer controller 1 outputs gradation data compressed to 2 bits and expands the data to 4 bits in the print head 10 (translation).
With this configuration, the data transfer amount can be halved.

As a result, the frequency of the transfer clock for transferring the gradation data can be reduced. Therefore, the logic section can be manufactured by a slow semiconductor process. In other words, if the logic unit is formed into an IC by a semiconductor process that can handle a voltage of several tens of volts, the operation speed is reduced. However, in the present invention, the frequency of the transfer clock can be reduced, and the logic unit can be easily integrated into an IC. Further, since the clock frequency is small, it is advantageous for measures against unnecessary radiation noise.

In the present embodiment, a single drive waveform as a basic waveform is formed by a plurality of drive pulses, and print data corresponding to each drive pulse is supplied to the switch circuit 20. Thus, one or a plurality of ink droplets can be respectively discharged from each nozzle. Therefore, multi-tone expression can be performed for each recording dot on the recording paper, and high-quality printing can be realized without lowering the printing speed.

Further, since a single drive signal composed of a plurality of drive pulses is used, there is no need to provide a plurality of pulse generator circuits as in the second prior art, and the signal between the printer controller and the print head is eliminated. The number of lines can be reduced.

2. Second Embodiment Next, a second embodiment of the present invention will be described with reference to the functional block diagram of FIG. In the following embodiments, the same components as those in the above-described first embodiment are denoted by the same reference numerals, and description thereof will be omitted.

Print head 50 according to the present embodiment
Also, like the print head 10 described in the first embodiment, each shift register 13 and 14 and each latch circuit 1
5 and 16, a decoder 17, a control logic 18, a level shifter 19, a switch circuit 20, and a piezoelectric element 21.

However, in this embodiment, the gradation data is divided into the least significant bit data (SI1) and the most significant bit data (SI2) and transferred to the shift registers 13 and 14, respectively. This is different from the above embodiment.

In the present embodiment, the same effect as that of the first embodiment can be obtained. In addition, the least significant bit data is directly input to the first shift register 13 and the most significant bit data is stored in the second shift register 13. Since data is directly input to the shift register 14, even at the same clock frequency, data can be transferred at a higher speed than in the first embodiment.

3. Third Embodiment Next, a third embodiment of the present invention will be described with reference to the functional block diagram of FIG.

A feature of the print head 60 according to the present embodiment is that one of the two shift registers is replaced with a latch circuit. That is, in the present embodiment, a single shift register 61 and three of the first latch circuit 62, the second latch circuit 63, and the third latch circuit 64
The "storage means" is constituted by the latch circuits.

As shown in FIG. 9, first, the data of the most significant bit (MSB) of the gradation data is stored in the shift register 61.
Is forwarded to Next, when the first latch signal (LAT1) is input to the first latch circuit 62, the shift register 61
Is latched by the first latch circuit 62. As a result, the data of the least significant bit (LSB) is subsequently input to the shift register 61.

When the second latch signal (LAT2) is input to the second latch circuit 63 and the third latch circuit 64, the second latch circuit 63 latches the data in the shift register 61, and 3 latch circuit 64
The data in the latch circuit 62 is latched. Therefore, the first
The data of the most significant bit of the grayscale data held by the latch circuit 62 is transferred to the third latch circuit 64, and the data of the least significant bit of the grayscale data input to the shift register 61 is stored in the second latch circuit 63. Moved. The data of the most significant bit and the data of the least significant bit are
7 and converted into 4-bit print data.

According to the present embodiment, the same effects as those of the first embodiment can be obtained. In addition, only one shift register 61 is used, and the other shift registers of the first embodiment are used. Since the function is performed by the first latch circuit 62, the manufacturing cost can be reduced. That is,
In general, a latch circuit has a simpler configuration and a substrate area can be reduced to about half that of a shift register, so that the same effect as that of the first embodiment can be realized at lower cost.

4. Preferred Embodiments of Decoder and Control Logic Next, FIGS. 10 to 13 show some preferred embodiments of the decoder 17 and the control logic 18.

4-1 First Specific Example The decoder 17 has four AND gates for one nozzle.
Gates 71, 72, 73, 74 and the respective AND gates 71
And an OR gate 75 to which the outputs of .about.74 are input. Therefore, when the number of nozzles is 64, AND
The logic circuit between the gates 71 to 74 and the OR gate 75 is 64
A set is prepared. Further, as described above, the first latch circuit 15
And the second latch circuit 16 latches the data of the most significant bit of the grayscale data.

Each AND corresponding to each drive pulse
Signals from the first latch circuit 15 and the second latch circuit 16 are input to the gates 71 to 74, respectively.

The control logic 18 comprises four D flip-flops 76, 77, 78, 79. The input D of the first flip-flop 76 is grounded and set to L level ("0"). The output Q of the first flip-flop 76 is input to the first AND gate 71 and also serves as the input D of the second flip-flop 77. The output Q of the second flip-flop 77 is
The signal is input to the ND gate 72 and also to the input D of the third flip-flop 78. The output Q of the third flip-flop 78 is input to the third AND gate 73 and is also the input D of the fourth flip-flop 79. The output Q of the fourth flip-flop 79 is
The signal is input to the AND gate 74.

The latch signal (LAT) is connected to the set input of the first flip-flop 76 and to the reset inputs of the other flip-flops 77 to 79, respectively. Each of the flip-flops 76 to 79
, A channel signal (CH) is input as a clock pulse.

The specific operation will be described with reference to the waveform diagram shown in FIG. First, when a latch signal is input, the first flip-flop 76 is thereby set, and the output Q becomes "1". Accordingly, “1” is input to the first AND gate 71 and the input D of the second AND gate 77 is also “1”. Other flip-flops 77-7
Since 9 has a latch signal as a reset input, the output Q of each of the flip-flops 77 to 79 is "0". Therefore, the inputs to the AND gates 72 to 74 also become "0". That is, when the latch signal also serving as the first pulse generation timing signal is input, the first pulse is generated.
Since only the flip-flop 76 outputs “1”, only the first AND gate 71 among the AND gates 71 to 74 may have an output of “1”.

Next, a channel signal (CH1) as a second pulse detection signal is input. At this time, since the set input of the first flip-flop 76 has been released, the output Q of the first flip-flop 76 becomes “0” which is the same value as the input D. The reset input of the second flip-flop 77 is released, and the second flip-flop 7 holds the output Q immediately before the first flip-flop 76 which is input to its own input D by the input of the channel signal.
The output Q of 7 is "1". The third flip-flop 78 and the fourth flip-flop 79 hold “0” until the next channel signal (CH2) is input, because the output Q of the preceding flip-flop is “0”. . Therefore, when the channel signal (CH1) for detecting the generation timing of the second pulse is input, the second
Since only the flip-flop 77 outputs “1”, only the second AND gate 72 among the AND gates 71 to 74 whose output may be “1” is provided.

Similarly, when the channel signal (CH2), which is the third pulse generation timing detection signal, is input, only the third flip-flop 78 becomes "1".
, There is a possibility that only the third AND gate 73 will output “1”. When the channel signal (CH4), which is the detection timing signal of the fourth pulse, is input, only the fourth flip-flop 79 outputs “1”.
, There is a possibility that only the fourth AND gate 74 will output “1”.

Accordingly, each of the AND gates 71 to 74 outputs “1” when each input to each of the AND gates satisfies the AND condition. If the output of any one of the AND gates 71 to 74 becomes “1”, The OR gate 75 outputs “1”. The output of the OR gate 75 is input to the switch circuit 20 via the level shifter 19.

For example, consider the case where the gradation data is (01). The gradation data (01) requests ejection of ink droplets corresponding to small dots by the second pulse, and the decode value corresponding to each drive pulse is (0100). The most significant bit (0) of the gradation data (01) is latched by the second latch circuit 16, and the least significant bit "1" of the gradation data (01) is latched by the first latch circuit 15. Have been. The signal from the second latch circuit 16 is
Since it is inverted and input to the AND gate 72, it becomes "1". The signal from the first latch circuit 15 is not
Since it is input to the ND gate 72, it is "1".

Therefore, if the remaining input to the second AND gate 72, that is, the output Q of the second flip-flop 77 becomes "1", the AND condition is satisfied and the output of the second AND gate 72 becomes "1". Become. Here, the output Q of the second flip-flop 77 takes "1" only when a channel signal (CH1), which is a generation timing detection signal of the second pulse, is input. Therefore, the second AND gate 72 outputs “1” by the generation of the second pulse. As a result, the switch circuit 20 operates, and the piezoelectric vibrator 21 expands and contracts according to the second pulse, and an ink droplet equivalent to a small dot is ejected. As described above, when the second pulse is generated, only the output Q of the second flip-flop 77 outputs “1” and only the second AND gate 72 outputs “1”. AND gates 71, 73, 7
The output of 4 is "0".

As described above, when the gradation data given to a certain nozzle is (01), the output of the OR gate is "0" during the first pulse generation period and "1" during the second pulse generation period. , During the third pulse generation period, and becomes “0” during the fourth pulse generation period. Therefore, the 2-bit gradation data (01) is translated into 4-bit print data (0100). Similarly, other gradation data is also quickly translated by the logic circuit shown in FIG.

4-2 Second Specific Example In the second specific example shown in FIG.
1 to 84 and an OR gate 85 to which the output of each of the AND gates 81 to 84 is input, constitute a decoder 17 per nozzle. And each AND gate 81
84, the first latch circuit 15, the second latch circuit 16
Is input.

The control logic 18 comprises one quaternary counter 86. The latch signal (LAT) is input to the reset terminal of the counter 86, and the channel signal (CH) is input to the data input terminal. Then, the upper digit output C1 and the lower digit output C0 of the counter 86 are output.
Is input to the AND gates 81 to 84, respectively.

The counter 86 is cleared when the latch signal also serving as the first pulse generation timing detection signal is input, so that the upper digit output C1 and the lower digit output C0 both become "0". Then, when the channel signal (CH1), which is the generation timing detection signal of the second pulse, is input, the counter 86 advances, and the upper digit output C1 becomes “0” and the lower digit output C0 becomes “1”. . In addition, the third
When a channel signal (CH2), which is a pulse generation timing detection signal, is input, the upper digit output C1 becomes "1" and the lower digit output C0 becomes "0". Further, when the channel signal (CH3), which is the generation timing detection signal of the fourth pulse, is input, both the upper digit output C1 and the lower digit output C0 become "1".

Accordingly, as in the first embodiment, the output (C1, C0) of the counter 86 which advances in step with the generation of each drive pulse causes any one of the AND gates 81 to 84 to be ANDed. Only the gate can be selected.

4-3 Third Specific Example In the third specific example shown in FIG. 12, similarly to the above specific examples, four AND gates 91 to 94 and outputs of the respective AND gates 91 to 94 are output. The input OR gate 95 constitutes a decoder 17 per nozzle. The signals from the first latch circuit 15 and the second latch circuit 16 are input to each of the AND gates 91 to 94.

The control logic 18 includes a quaternary counter 96
And a combinational circuit 97 that changes the logical output according to the output from the counter 96. The counter 96 performs the same operation as the counter 86 described in the second specific example. That is, the counter output during the first pulse generation period becomes (00), the counter output during the second pulse generation period becomes (01), the counter output during the third pulse generation period becomes (10), and the fourth pulse The counter output during the occurrence period is (11).

Then, the combinational circuit 97 outputs the output (C1, C0) of the counter 96 as shown in the truth table in FIG.
The values of the outputs q1 to q4 are changed in accordance with the value of. Therefore, by appropriately setting the input state (inverted input or non-inverted input) from the combination circuit 97 to each of the AND gates 91 to 94, the gradation data is translated into print data and a desired drive pulse is transmitted to the piezoelectric vibrator 21. Can be applied.

For example, as an example, when the output of the counter 96 becomes (00) or (10), the combinational circuit 9
7, the value of the output q4 is “1”. As mentioned above, the first
When a pulse is generated, the counter output becomes (00), and the third
The counter output at the time of pulse generation is (10). Therefore, the fourth AND gate 94 to which the output q4 is input
When the input value from each of the latch circuits 15 and 16 is “1”, that is, when the grayscale data is (11), during the generation period of the first pulse and the generation period of the third pulse, "1" is output. Note that the combinational circuit 97 of this specific example is
May be a ROM in which C1 and C0 are addresses and q1, q2, q3, and q4 are data.

4-4 Fourth Specific Example In a fourth specific example shown in FIG. 13, the combinational circuit 97 in the third specific example is replaced with a plurality of flip-flops 100 and a plurality of multiplexers 101. .
The set of four flip-flops 100 connected in one stage is 4
Each flip-flop 100 of each stage
Are connected to the four multiplexers 101, respectively. The outputs (C1, C0) of the counter 96 are input to the multiplexer 101. Therefore, each multiplexer 101 has a counter 96
, One of the four outputs Q inputted thereto is selected and output.

Outputs q1 to q4 of each multiplexer 101
However, the program data is input to the flip-flop 100 of each stage so as to correspond to each output q1 to q4 of the combination circuit 97. That is, the data sequence corresponding to the truth table in FIG. 12 is a data transfer clock signal (CK).
Flows from the flip-flop 100 at the left end of the upper stage in accordance with. This data string is stored by each flip-flop 100 in each stage. The data stored in each flip-flop 100 is stored in each flip-flop 1
It is shown in 00. Therefore, for example, when the first input of each of the multiplexers 101 is selected by the counter output, each of the multiplexers 101 outputs the value of the first input, whereby the first-stage flip-flop 100 stores the value. Data is output. The input of the program data is performed once after the power of the printer is turned on and before printing.

According to this specific example, the combination of the gradation value and the driving pulse can be freely set by changing the program data. Therefore, when the logic section is formed into an IC, a plurality of models having various pulse patterns are provided. Can be handled. Further, since program data can be rewritten during operation (data is re-input to the flip-flop 100), the present invention can also be applied to a gradation printer of a specification in which a pattern of a driving pulse is changed during operation.

This specific example can be expressed, for example, as follows. "The translation means includes correspondence storage means (flip-flop 100, multiplexer 101) in which the correspondence between the gradation data and each of the drive pulses is stored so as to be changeable. 2. The ink jet print head according to claim 1, wherein the gradation data is translated into the print data based on a timing detection signal for detecting an occurrence timing.

It should be noted that those skilled in the art can make various additions and changes within the scope of the present invention described in each embodiment. For example, in the present invention, the case where four gradations are expressed using the first to fourth four drive pulses has been exemplified, but the present invention is not limited to this. For example, the present invention can be applied to a case where another gradation expression such as three gradations or six gradations is performed. In this case, the configuration of each specific example may be changed in accordance with the number of gradation expressions.

[0102]

As described above, according to the ink-jet print head and the ink-jet printer using the print head according to the present invention, the gradation data is translated in the print head. The amount of data transferred to the printer can be reduced, and necessary gradation data can be reliably transferred within one printing cycle. In particular, data transfer can be performed with high reliability even when the transfer time is limited because gradation is expressed by a single drive signal including a plurality of drive pulses.

[Brief description of the drawings]

FIG. 1 is a configuration explanatory diagram showing an overall configuration of an ink jet printer to which a first embodiment of the present invention is applied;

FIG. 2 is a circuit diagram showing a main part of a print head drive circuit.

FIG. 3 is a configuration explanatory view showing a mechanical structure of a print head.

FIG. 4 is an explanatory diagram showing a relationship between a drive signal and a gradation value in the embodiment of the present invention.

FIG. 5 is a time chart showing a relationship between each drive pulse of a drive signal and a transfer timing of gradation data.

FIG. 6 is a time chart showing a selection pattern of a driving pulse.

FIG. 7 is a configuration explanatory view of a print head according to a second embodiment of the present invention.

FIG. 8 is a configuration explanatory view of a print head according to a third embodiment of the present invention.

FIG. 9 is a time chart showing the transfer timing of gradation data and the like in the third embodiment.

FIG. 10 is a circuit diagram of a decoder and control logic according to a first embodiment of the present invention.

FIG. 11 is a circuit diagram of a decoder and control logic according to a second embodiment of the present invention.

FIG. 12 is a circuit diagram of a decoder and control logic according to a third embodiment of the present invention.

FIG. 13 is a circuit diagram of control logic according to a fourth embodiment of the present invention.

[Explanation of symbols]

 Reference Signs List 1 printer controller 2 print engine 8 drive signal generation circuit 10 print head 13 first shift register 14 second shift register 15 first latch circuit 16 second latch circuit 17 decoder 18 control logic 20 switch circuit 21 piezoelectric vibrator 61 shift register 62 First latch circuit 63 Second latch circuit 64 Third latch circuit

Claims (8)

[Claims] An ink jet print head that ejects ink droplets from each nozzle by activating pressure generating elements provided corresponding to each of a plurality of nozzles based on input gradation data. Switch means for supplying a drive signal including a plurality of inputted drive pulses to the pressure generating element; storage means for storing the inputted gradation data; Translation means for translating into print data comprising a pulse selection signal provided corresponding to each of the pulses, based on the print data, any one or a plurality of drive pulses among the respective drive pulses, the pressure An ink-jet printhead, wherein a generator element is selectively input within one printing cycle. 2. The ink jet printer according to claim 1, wherein the translation unit translates the gradation data into the print data based on a timing detection signal that detects a timing of generating each of the drive pulses. Type print head. 3. The storage means has a storage circuit corresponding to the number of digits of the gradation data, and stores data for each digit of the gradation data in each of the storage circuits. The ink jet print head according to claim 1 or 2, wherein 4. The ink-jet printhead according to claim 3, wherein data of each digit of said gradation data is independently inputted to each of said storage circuits. 5. The storage circuit according to claim 1, wherein the storage circuit converts serially-input data of each digit of the gradation data into a parallel signal, and a latch that latches the parallel signal according to an input latch signal. 5. The method as claimed in claim 3, wherein said means comprises:
4. The ink jet print head according to claim 1. 6. The driving signal includes a first driving pulse for discharging a first ink droplet and a second driving pulse for discharging a second ink droplet smaller than the first ink droplet. 6. The method according to claim 1, further comprising a driving pulse and a third driving pulse for discharging a third ink droplet having the same amount as the first ink droplet. The ink jet print head according to any one of the above. 7. The ink jet print head according to claim 1, wherein the pressure generating element is a piezoelectric vibrator. 8. An ink jet print head for ejecting ink droplets from each nozzle by operating a piezoelectric vibrator provided corresponding to each of a plurality of nozzles, and providing a necessary signal to the print head. A printer control means for controlling the operation of the printer head, wherein the printer control means comprises a drive signal generation means for generating a drive signal consisting of a plurality of drive pulses, the print head comprises: Storage means for dividing the divided gradation data into data for each digit of the gradation data, and storing the divided gradation data based on a timing detection signal for detecting the generation timing of each drive pulse. Translation for translating into print data consisting of pulse selection signals provided corresponding to each drive pulse And a switch means for selectively inputting any one or a plurality of drive pulses of the respective drive pulses to the piezoelectric vibrator within one printing cycle based on the print data. An ink jet printer characterized by the following.