CN211416643U

CN211416643U - Print head control circuit and liquid ejecting apparatus

Info

Publication number: CN211416643U
Application number: CN201921547873.9U
Authority: CN
Inventors: 山田智仁; 松山徹
Original assignee: Seiko Epson Corp
Current assignee: Seiko Epson Corp
Priority date: 2018-09-19
Filing date: 2019-09-18
Publication date: 2020-09-04
Anticipated expiration: 2029-09-18
Also published as: JP2020049931A; EP3693172A2; EP3693172B1; EP3693172A3; JP7272013B2

Abstract

The utility model provides a can reduce the self-diagnostic function that beats printer head and beat printer head control circuit of possibility of action unusually. In the print head control circuit, the first diagnostic signal wiring group includes: a first diagnostic signal transmission wiring that transmits a first diagnostic signal; a second diagnostic signal transmission wiring that transmits a second diagnostic signal; and a third diagnostic signal transmission wiring that transmits a third diagnostic signal, the second diagnostic signal wiring group including: a fourth diagnostic signal transmission wiring that transmits a fourth diagnostic signal; and a fifth diagnostic signal transmission wiring that transmits a fifth diagnostic signal, the first to fourth drive signal wiring groups transmitting a first drive signal and a second drive signal for ejecting liquid, the first diagnostic signal wiring group being provided between the first drive signal wiring group and the second drive signal wiring group in the first cable, and the second diagnostic signal wiring group being provided between the third drive signal wiring group and the fourth drive signal wiring group in the second cable.

Description

Print head control circuit and liquid ejecting apparatus

Technical Field

The utility model relates to a beat printer head control circuit and liquid jettison device.

Background

A liquid ejecting apparatus such as an ink jet printer drives a piezoelectric element provided in a print head by a drive signal to eject liquid such as ink filled in a chamber from a nozzle, thereby forming characters or images on a recording medium. In such a liquid ejecting apparatus, when the print head fails, an ejection abnormality may occur in which the liquid cannot be normally ejected from the nozzles. When such an ejection abnormality occurs, the accuracy of ejection of ink ejected from the nozzles may be reduced, and the quality of an image formed on a recording medium may be reduced.

Patent document 1 discloses a print head having a self-diagnostic function for determining whether or not dots satisfying normal print quality can be formed by the print head itself based on a plurality of signals input to the print head.

Patent document 2 discloses a technique for performing multi-tone printing by ejecting different amounts of liquid from nozzles by transmitting a plurality of drive signals to a print head and selectively supplying the drive signals to piezoelectric elements.

[ Prior art documents ]

[ patent document ]

[ patent document 1] Japanese patent laid-open publication No. 2017-114020

[ patent document 2] Japanese patent laid-open No. Hei 09-011457

However, in the technique described in patent document 1, a plurality of signal lines for self-diagnosis of the print head are arranged in a distributed manner in the cable and the connector. Therefore, when the print head described in patent document 1 is applied to the print head described in patent document 2, which performs multi-gradation expression by using a plurality of drive signals, there is a possibility that the plurality of drive signals transmitted as high-voltage signals interfere with a plurality of signals used for self-diagnosis of the print head, and the self-diagnosis function of the print head may not operate normally.

Disclosure of Invention

The utility model relates to a printing head control circuit, which is a printing head control circuit for controlling the action of a printing head,

the print head has a function of performing self-diagnosis based on signals input from a first connection point, a second connection point, a third connection point, a fourth connection point, and a fifth connection point, and the print head control circuit includes:

a first cable having a first drive signal wiring group, a second drive signal wiring group, and a first diagnostic signal wiring group;

a second cable having a third drive signal wiring group, a fourth drive signal wiring group, and a second diagnostic signal wiring group;

a diagnostic signal output circuit that outputs a first diagnostic signal, a second diagnostic signal, a third diagnostic signal, and a fourth diagnostic signal; and

a drive signal output circuit that outputs a first drive signal and a second drive signal for causing liquid to be ejected from the print head,

the first diagnostic signal wiring group includes: a first diagnostic signal transmission wiring that transmits the first diagnostic signal input to the first connection point; a second diagnostic signal transmission wiring line that transmits the second diagnostic signal input to the second connection point; and a third diagnostic signal transmission wiring that transmits the third diagnostic signal input to the third connection point,

the second diagnostic signal wiring group includes: a fourth diagnostic signal transmission wiring line that transmits the fourth diagnostic signal input to the fourth connection point; and a fifth diagnostic signal transmission wiring that transmits a fifth diagnostic signal input to the fifth connection point,

the first drive signal wiring group transfers at least one of the first drive signal and the second drive signal,

the second drive signal wiring group transfers at least one of the first drive signal and the second drive signal,

the third drive signal wiring group transfers at least one of the first drive signal and the second drive signal,

the fourth drive signal wiring group transfers at least one of the first drive signal and the second drive signal,

in the first cable, the first diagnostic signal wiring group is disposed between the first drive signal wiring group and the second drive signal wiring group,

in the second cable, the second diagnostic signal wiring group is disposed between the third drive signal wiring group and the fourth drive signal wiring group.

In one mode of the print head control circuit, the print head control circuit may further include a print head control circuit,

the first drive signal is a signal for causing a first amount of liquid to be ejected from the print head,

the second drive signal is a signal for causing a different amount of liquid from the first amount to be ejected from the print head,

the first drive signal wiring group includes first drive signal transfer wirings which transfer the first drive signal,

the second drive signal wiring group includes second drive signal transfer wirings that transfer the second drive signal.

the first diagnostic signal transmission wiring also serves as a wiring for transmitting a signal for specifying an ejection timing.

the second diagnostic signal transmission wiring also serves as a wiring for transmitting a signal that specifies a timing of switching a waveform of at least one of the first drive signal and the second drive signal.

the third diagnostic signal transmission wiring also serves as a wiring for transmitting a signal that specifies selection of waveforms of the first drive signal and the second drive signal.

the print head includes a nozzle that ejects black liquid,

the first drive signal and the second drive signal are signals for causing the black liquid to be ejected from the nozzles.

the fourth diagnostic signal transmission wiring also serves as a wiring for transmitting a clock signal.

the fifth diagnostic signal transmission wiring also serves as a wiring for transmitting a signal indicating the presence or absence of a temperature abnormality of the print head.

the first diagnostic signal wiring group includes a first ground signal transmission wiring and a second ground signal transmission wiring that transmit a signal of a ground potential,

the first ground signal transfer wiring is disposed between the first diagnostic signal transfer wiring, the second diagnostic signal transfer wiring, and the third diagnostic signal transfer wiring and the first driving signal wiring group,

the second ground signal transfer wiring is disposed between the first diagnostic signal transfer wiring, the second diagnostic signal transfer wiring, and the third diagnostic signal transfer wiring and the second driving signal wiring group.

the second diagnostic signal wiring group includes a third ground signal transmission wiring and a fourth ground signal transmission wiring that transmit a signal of a ground potential,

the third ground signal transfer wiring is disposed between the fourth and fifth diagnostic signal transfer wirings and the third driving signal wiring group,

the fourth ground signal transfer wiring is disposed between the fourth diagnostic signal transfer wiring and the fourth driving signal wiring group and between the fifth diagnostic signal transfer wiring and the fourth driving signal wiring group.

the first diagnostic signal wiring group includes a fifth ground signal transmission wiring and a sixth ground signal transmission wiring that transmit a signal of a ground potential,

the second diagnostic signal transmission wiring is provided between the first diagnostic signal transmission wiring and the third diagnostic signal transmission wiring,

the fifth ground signal transmission wiring is provided between the first diagnostic signal transmission wiring and the second diagnostic signal transmission wiring,

the sixth ground signal transmission wiring is provided between the second diagnostic signal transmission wiring and the third diagnostic signal transmission wiring.

the second diagnostic signal wiring group includes a seventh ground signal transmission wiring that transmits a signal of a ground potential,

the seventh ground signal transmission wiring is provided between the fourth diagnostic signal transmission wiring and the fifth diagnostic signal transmission wiring.

The utility model relates to a liquid ejecting device's mode possesses:

a print head having a function of self-diagnosing based on signals inputted from a first connection point, a second connection point, a third connection point, a fourth connection point, and a fifth connection point; and

a printhead control circuit that controls an action of the printhead,

the print head control circuit has:

in a first contact group in which the first cable is in electrical contact with the print head, a first contact portion in which the first connection point is in electrical contact with the first diagnostic signal transmission wiring, a second contact portion in which the second connection point is in electrical contact with the second diagnostic signal transmission wiring, and a third contact portion in which the third connection point is in electrical contact with the third diagnostic signal transmission wiring are located between the first drive signal contact group in electrical contact with the print head, the second drive signal contact group in electrical contact with the second drive signal wiring group, and the print head,

in the second contact group in which the second cable is in electrical contact with the print head, a fourth contact portion in which the fourth connection point is in electrical contact with the fourth diagnostic signal transmission wiring, and a fifth contact portion in which the fifth connection point is in electrical contact with the fifth diagnostic signal transmission wiring are located between the third drive signal wiring group and the third drive signal contact group in electrical contact with the print head, and the fourth drive signal contact group in electrical contact with the fourth drive signal wiring group and the print head.

In one aspect of the liquid ejecting apparatus, the liquid ejecting apparatus may further include a liquid ejecting head,

the first contact portion is electrically contacted to a wiring for transmitting a signal for specifying the ejection timing.

the second contact portion is electrically contacted to a wiring that transmits a signal that specifies a waveform switching timing of at least one of the first drive signal and the second drive signal.

the third contact portion is electrically contacted to a wiring that transmits a signal that specifies waveform selection of the first drive signal and the second drive signal.

the print head includes a nozzle that ejects black liquid,

the fourth contact portion is in electrical contact with a wiring that transmits a clock signal.

the fifth contact portion is electrically contacted to a wiring that transmits a signal indicating the presence or absence of a temperature abnormality of the print head.

in the first set of contacts, the first contact set,

a sixth contact of the first ground signal transmission wiring in electrical contact with the printhead is located between the first contact, the second contact, and the third contact and the first drive signal contact set,

a seventh contact portion of the second ground signal transmission wiring in electrical contact with the printhead is located between the first contact portion, the second contact portion, and the third contact portion and the second drive signal contact group.

in the second set of contacts, the first set of contacts,

an eighth contact of the third ground signal transmission wiring in electrical contact with the printhead is located between the fourth and fifth contacts and the third drive signal contact set,

a ninth contact of the fourth ground signal transmission wire in electrical contact with the printhead is between the fourth and fifth contacts and the fourth drive signal contact set.

in the first set of contacts, the first contact set,

the second contact portion is located between the first contact portion and the third contact portion,

a tenth contact portion of the fifth ground signal transmission wiring in electrical contact with the printhead is located between the first contact portion and the second contact portion,

an eleventh contact portion of the sixth ground signal transmission wiring in electrical contact with the printhead is located between the second contact portion and the third contact portion.

in the second set of contacts, the first set of contacts,

a twelfth contact portion of the seventh ground signal transmission wiring in electrical contact with the printhead is located between the fourth contact portion and the fifth contact portion.

Drawings

Fig. 1 is a diagram showing a schematic configuration of a liquid ejecting apparatus.

Fig. 2 is a block diagram showing an electrical configuration of the liquid ejecting apparatus.

Fig. 3 is a diagram showing an example of the drive signals COMA and COMB.

Fig. 4 is a diagram showing an example of the drive signal VOUT.

Fig. 5 is a diagram showing a configuration of the drive signal selection circuit.

Fig. 6 is a diagram showing the decoded content in the decoder.

Fig. 7 is a diagram showing a configuration of a selection circuit corresponding to one ejection unit.

Fig. 8 is a diagram for explaining an operation of the drive signal selection circuit.

Fig. 9 is a diagram showing a configuration of a temperature abnormality detection circuit.

Fig. 10 is a perspective view showing the structure of the print head.

Fig. 11 is a plan view showing an ink ejection surface of the head.

Fig. 12 is a diagram showing a schematic configuration of the ejection section.

Fig. 13 is a diagram showing a structure of the first connector.

Fig. 14 is a diagram showing the structure of the second connector.

Fig. 15 is a view schematically showing an internal configuration of the liquid discharge apparatus when viewed from the Y direction.

Fig. 16 is a diagram showing a structure of a cable.

Fig. 17 is a diagram for explaining the contact portion in the case where the cable is attached to the first connector.

Fig. 18 is a diagram for explaining details of a signal transmitted by the first cable.

Fig. 19 is a diagram for explaining details of a signal transmitted by the second cable.

[ description of reference numerals ]

1: a liquid ejecting device; 2: a liquid container; 10: a control mechanism; 11: a main substrate; 12 a: a third connector; 12 b: a fourth connector; 15: a print head control circuit; 19: a cable; 19 a: a first cable; 19 b: a second cable; 20: a bracket; 21: a print head; 30: a moving mechanism; 31: a bracket motor; 32: an endless belt; 40: a conveying mechanism; 41: a conveying motor; 42: a conveying roller; 50: a drive signal output circuit; 50a, 50 b: a drive circuit; 60: a piezoelectric element; 81: a first wiring group; 82: a second wiring group; 83: a third wiring group; 84: a fourth wiring group; 85: a fifth wiring group; 86: a sixth wiring group; 90: a linear encoder; 91: a first wiring contact group; 92: a second wiring contact group; 93: a third wiring contact group; 94: a fourth wiring contact group; 95: a fifth wiring contact group; 96: a sixth wiring contact group; 97. 98: a contact group; 100: a control circuit; 110: a power supply circuit; 180: a contact portion; 191. 192: a short side; 193. 194: a long side; 195. 196, and (2) preparing: a terminal; 197: wiring; 198: an insulator; 200: a drive signal selection circuit; 210: a temperature detection circuit; 220: a selection control circuit; 222: a shift register; 224: a latch circuit; 226: a decoder; 230: a selection circuit; 232a, 232 b: an inverter; 234a, 234 b: a transmission gate; 250: a temperature abnormality detection circuit; 251: a comparator; 252: a reference voltage output circuit; 253: a transistor; 254: a diode; 255. 256: a resistance; 310: a head; 311: ink-jet surfaces; 320: a head substrate; 321. 322: kneading; 323. 324, 325, 326: an edge; 331. 332, 333, 334, 335, 336: connecting a terminal group; 337. 338, 339: an FPC through hole; 340. 341, 342, 343, 344, 345: an ink supply path through hole; 350: a first connector; 351: a housing; 352: a cable mounting section; 353: a terminal; 353 a: a substrate mounting portion; 353 b: a housing penetration portion; 353 c: a cable holding section; 360: a second connector; 361: a housing; 362: a cable mounting section; 363: a terminal; 600: a discharge section; 601: a piezoelectric body; 611. 612: an electrode; 621: a vibrating plate; 631: a chamber; 632: a nozzle plate; 641: a liquid reservoir; 651: a nozzle; 661: an ink supply port; l1, L2, L3, L4, L5, L6: a nozzle row; p: a medium.

Detailed Description

Hereinafter, preferred embodiments of the present invention will be described with reference to the drawings. The drawings are utilized for ease of illustration. The embodiments described below are not intended to unduly limit the scope of the present invention set forth in the claims. The configurations described below are not necessarily all essential components of the present invention.

Hereinafter, a print head control circuit according to the present invention will be described by taking as an example a print head control circuit that is applied to a liquid ejecting apparatus and operates a print head having a self-diagnostic function.

1. Outline of liquid ejecting apparatus

Fig. 1 is a diagram showing a schematic configuration of a liquid ejecting apparatus 1 to which a print head control circuit according to the present embodiment is applied. The liquid discharge apparatus 1 according to the present embodiment is a serial printing type inkjet printer in which a carriage 20 on which a print head 21 that discharges ink as an example of liquid is mounted reciprocates and discharges ink to a medium P to be conveyed. In the following description, the direction in which the carriage 20 moves is referred to as the X direction, the direction in which the medium P is conveyed is referred to as the Y direction, and the direction in which ink is ejected is referred to as the Z direction. In the following description, the X direction, the Y direction, and the Z direction are orthogonal to each other. In addition, any printing object such as printing paper, resin film, fabric, or the like may be used as the medium P.

The liquid ejecting apparatus 1 includes a liquid container 2, a control mechanism 10, a carriage 20, a moving mechanism 30, and a conveying mechanism 40.

The liquid container 2 stores a plurality of kinds of ink discharged to the medium P. Specifically, six kinds of ink, black, cyan, magenta, yellow, red, and gray, are stored in the liquid container 2. The number and type of the inks stored in the liquid container 2 are examples, and five or less, or seven or more inks may be stored in the liquid container 2. Further, the liquid container 2 may store therein light cyan, light magenta, green, and other inks. As the liquid container 2 for storing such ink, an ink cartridge, a bag-shaped ink pack formed of a flexible film, an ink tank capable of replenishing ink, and the like can be used.

The control means 10 includes a Processing circuit such as a CPU (Central Processing Unit) or an FPGA (Field Programmable Gate Array) and a memory circuit such as a semiconductor memory, and controls each element of the liquid ejecting apparatus 1.

A print head 21 is mounted on the carriage 20. The carriage 20 is fixed to an endless belt 32 included in the moving mechanism 30 in a state where the print head 21 is mounted. The liquid container 2 may be mounted on the bracket 20.

A control signal Ctrl-H including a plurality of signals for controlling the print head 21 and a plurality of drive signals COM for driving the print head 21 are input from the control mechanism 10 to the print head 21. Then, the print head 21 ejects the ink supplied from the liquid tank 2 in the Z direction based on the control signal Ctrl-H and the plurality of drive signals COM.

The moving mechanism 30 includes a carriage motor 31 and an endless belt 32. The carriage motor 31 operates based on a control signal Ctrl-C input from the control mechanism 10. The endless belt 32 is rotated by the operation of the carriage motor 31. Thereby, the carriage 20 fixed to the endless belt 32 reciprocates in the X direction.

The conveying mechanism 40 includes a conveying motor 41 and a conveying roller 42. The conveyance motor 41 operates based on a control signal Ctrl-T input from the control mechanism 10. The conveying roller 42 rotates in accordance with the operation of the conveying motor 41. With the rotation of the conveying roller 42, the medium P is conveyed in the Y direction.

As described above, the liquid discharge apparatus 1 discharges ink from the print head 21 mounted on the carriage 20 in conjunction with the conveyance of the medium P by the conveyance mechanism 40 and the reciprocation of the carriage 20 by the movement mechanism 30, and thereby lands the ink at an arbitrary position on the surface of the medium P to form a desired image on the medium P.

2. Electrical structure of liquid ejecting apparatus

Fig. 2 is a block diagram showing an electrical configuration of the liquid ejection device 1. The liquid ejecting apparatus 1 includes a control mechanism 10, a print head 21, a carriage motor 31, a conveyance motor 41, and a linear encoder 90. As shown in fig. 2, the control mechanism 10 includes a drive signal output circuit 50, a control circuit 100, and a power supply circuit 110.

The control circuit 100 includes, for example, a processor such as a microcontroller. The control circuit 100 generates data or signals for controlling the liquid discharge apparatus 1 based on various signals such as image data supplied from a host computer.

Specifically, the control circuit 100 grasps the scanning position of the print head 21 based on the detection signal input from the linear encoder 90. The control circuit 100 outputs a control signal Ctrl-C corresponding to the scanning position of the print head 21 to the carriage motor 31. Thereby, the reciprocating motion of the print head 21 is controlled. Further, the control circuit 100 outputs a control signal Ctrl-T to the conveyance motor 41. Thereby, the conveyance of the medium P is controlled. The control signal Ctrl-C may be converted by a carriage motor driver not shown in the figure and supplied to the carriage motor 31. Similarly, the control signal Ctrl-T may be converted by a transport motor driver not shown in the figure and supplied to the transport motor 41.

The control circuit 100 outputs six print data signals SI1 to SI6, two conversion signals CH1 and CH2, a latch signal LAT, a clock signal SCK, and an N charge signal NCHG to the print head 21 as a control signal Ctrl-H for controlling the print head 21, based on various signals such as image data supplied from a host computer.

The control circuit 100 outputs the drive control signals dA and dB as digital signals to the drive signal output circuit 50.

The drive signal output circuit 50 includes a drive circuit 50a and a drive circuit 50 b. The drive signal output circuit 50 generates and outputs the drive signals COMA and COMB as a plurality of drive signals COM. The drive signal output circuit 50 generates and outputs a reference voltage signal CGND indicating a reference potential of the drive signals COMA and COMB, for example, a ground potential (0V). The reference voltage signal CGND is not limited to a voltage signal at ground potential, and may be a voltage signal of DC6V, for example.

Specifically, the drive control signal dA is input to the drive circuit 50 a. Then, the drive circuit 50a performs digital/analog conversion on the drive control signal dA, and then performs D-class amplification on the converted analog signal to generate the drive signal COMA. In addition, the drive control signal dB is input to the drive circuit 50 b. Then, the drive circuit 50b performs digital/analog conversion on the drive control signal dB, and performs D-class amplification on the converted analog signal to generate the drive signal COMB. That is, the drive control signals dA and dB are digital data signals that define the waveforms of the drive signals COMA and COMB, and the

drive circuits

50a and 50b generate the drive signals COMA and COMB by performing D-class amplification on the waveforms defined by the drive control signals dA and dB. Then, the generated drive signals COMA and COMB are output from the drive signal output circuit 50. The drive control signals dA and dB may be analog signals that define the waveforms of the drive signals COMA and COMB, and the drive circuits 50a and 50B may amplify the waveforms defined by the drive control signals dA and dB by class a amplification, class B amplification, class AB amplification, or the like.

The drive signals COMA are branched into drive signals COMA1 to COMA6 in the control means 10, and then output to the print head 21. The drive signals COMB are branched into drive signals COMB1 to COMB6 in the control unit 10, and then output to the print head 21. The reference voltage signal CGND is branched into reference voltage signals CGND1 to CGND6 in the control unit 10, and then output to the printhead 21. One of the driving signals COMA including the driving signals COMA1 to COMA6 or the driving signals COMB including the driving signals COMB1 to COMB6 is an example of a first driving signal, and the other one of the driving signals COMA including the driving signals COMA1 to COMA6 or the driving signals COMB including the driving signals COMB1 to COMB6 is an example of a second driving signal.

The power supply circuit 110 generates and outputs a high-voltage signal VHV, low-voltage signals VDD1, VDD2, and a ground signal GND. The high voltage signal VHV is, for example, a voltage signal of DC 42V. The low voltage signals VDD1 and VDD2 are, for example, 3.3V voltage signals. The ground signal GND is a voltage signal indicating the reference potential of the high-voltage signal VHV, the low-voltage signals VDD1, VDD2, and is, for example, a voltage signal of a ground potential (0V). The high-voltage signal VHV, the low-voltage signals VDD1, VDD2, and the ground signal GND are used as power supply voltages for various configurations in the control mechanism 10, and are output to the print head 21. The power supply circuit 110 may generate various voltage signals other than the high-voltage signal VHV, the low-voltage signals VDD1 and VDD2, and the ground signal GND.

The print head 21 includes six drive signal selection circuits 200a to 200f, a plurality of ejection portions 600, a temperature detection circuit 210, and a temperature abnormality detection circuit 250.

The drive signal selection circuits 200a to 200f generate drive signals VOUT1 to VOUT6 by selecting or deselecting the drive signals COMA1 to COMA6 and the drive signals COMB1 to COMB6 based on the input print data signals SI1 to SI6, the clock signal SCK, the latch signal LAT, and the conversion signals CH1 and CH2, and supply the drive signals VOUT1 to VOUT6 to the piezoelectric elements 60 included in the corresponding ejection sections 600. The piezoelectric element 60 is displaced by being supplied with the drive signal VOUT. Then, ink of an amount corresponding to the displacement is ejected from the ejection section 600.

The drive signal selection circuit 200a receives drive signals COMA1, COMB1, print data signal SI1, latch signal LAT, conversion signals CH1, CH2, and clock signal SCK. Then, the drive signal selection circuit 200a outputs the drive signal VOUT1 by selecting or deselecting the drive signals COMA1, COMB1 based on the print data signal SI1, the latch signal LAT, the conversion signals CH1, CH2, and the clock signal SCK. The driving signal VOUT1 is supplied to one end of the piezoelectric element 60 of the ejection section 600 provided correspondingly. The reference voltage signal CGND1 is supplied to the other end of the piezoelectric element 60. The piezoelectric element 60 is displaced by a potential difference between the drive signal VOUT1 and the reference voltage signal CGND 1.

Similarly, the drive signal selection circuit 200b receives the drive signals COMA2 and COMB2, the print data signal SI2, the latch signal LAT, the conversion signals CH1 and CH2, and the clock signal SCK. Then, the drive signal selection circuit 200b outputs the drive signal VOUT2 by selecting or deselecting the drive signals COMA2, COMB2 based on the print data signal SI2, the latch signal LAT, the conversion signals CH1, CH2, and the clock signal SCK. The driving signal VOUT2 is supplied to one end of the piezoelectric element 60 of the ejection section 600 provided correspondingly. The reference voltage signal CGND2 is supplied to the other end of the piezoelectric element 60. The piezoelectric element 60 is displaced by a potential difference between the drive signal VOUT2 and the reference voltage signal CGND 2.

Similarly, the drive signal selection circuit 200c receives the drive signals COMA3 and COMB3, the print data signal SI3, the latch signal LAT, the conversion signals CH1 and CH2, and the clock signal SCK. Then, the drive signal selection circuit 200c outputs the drive signal VOUT3 by selecting or deselecting the drive signals COMA3, COMB3 based on the print data signal SI3, the latch signal LAT, the conversion signals CH1, CH2, and the clock signal SCK. The driving signal VOUT3 is supplied to one end of the piezoelectric element 60 of the ejection section 600 provided correspondingly. The reference voltage signal CGND3 is supplied to the other end of the piezoelectric element 60. The piezoelectric element 60 is displaced by a potential difference between the drive signal VOUT3 and the reference voltage signal CGND 3.

Similarly, the drive signal selection circuit 200d receives the drive signals COMA4 and COMB4, the print data signal SI4, the latch signal LAT, the conversion signals CH1 and CH2, and the clock signal SCK. Then, the drive signal selection circuit 200d outputs the drive signal VOUT4 by selecting or deselecting the drive signals COMA4, COMB4 based on the print data signal SI4, the latch signal LAT, the conversion signals CH1, CH2, and the clock signal SCK. The driving signal VOUT4 is supplied to one end of the piezoelectric element 60 of the ejection section 600 provided correspondingly. The reference voltage signal CGND4 is supplied to the other end of the piezoelectric element 60. The piezoelectric element 60 is displaced by a potential difference between the drive signal VOUT4 and the reference voltage signal CGND 4.

Similarly, the drive signal selection circuit 200e receives the drive signals COMA5, COMB5, print data signal SI5, latch signal LAT, conversion signals CH1, CH2, and clock signal SCK. Then, the drive signal selection circuit 200e outputs the drive signal VOUT5 by selecting or deselecting the drive signals COMA5, COMB5 based on the print data signal SI5, the latch signal LAT, the conversion signals CH1, CH2, and the clock signal SCK. The driving signal VOUT5 is supplied to one end of the piezoelectric element 60 of the ejection section 600 provided correspondingly. The reference voltage signal CGND5 is supplied to the other end of the piezoelectric element 60. The piezoelectric element 60 is displaced by a potential difference between the drive signal VOUT5 and the reference voltage signal CGND 5.

Similarly, the drive signal selection circuit 200f receives the drive signals COMA6, COMB6, print data signal SI6, latch signal LAT, conversion signals CH1, CH2, and clock signal SCK. The drive signal selection circuit 200f outputs the drive signal VOUT6 by selecting or deselecting the drive signals COMA6 and COMB6 based on the print data signal SI6, the latch signal LAT, the conversion signals CH1 and CH2, and the clock signal SCK. The driving signal VOUT6 is supplied to one end of the piezoelectric element 60 of the ejection section 600 provided correspondingly. The reference voltage signal CGND6 is supplied to the other end of the piezoelectric element 60. The piezoelectric element 60 is displaced by a potential difference between the drive signal VOUT6 and the reference voltage signal CGND 6.

Here, the drive signal selection circuits 200a to 200f have the same circuit configuration. Therefore, in the following description, the drive signal selection circuits 200a to 200f may be referred to as drive signal selection circuits 200 when there is no need to particularly distinguish them. In this case, the drive signals COMA1 to COMA6 and COMB1 to COMB6 input to the drive signal selection circuit 200 are referred to as drive signals COMA and COMB, and the print data signals SI1 to SI6 are referred to as print data signals SI. The driving signals VOUT1 to VOUT6 outputted from the driving signal selection circuit 200 are referred to as driving signals VOUT.

The temperature detection circuit 210 includes a temperature sensor such as a thermistor not shown in the figure. The temperature sensor detects the temperature of the print head 21. Then, the temperature detection circuit 210 generates a temperature signal TH, which is an analog signal containing temperature information of the print head 21, and outputs the temperature signal TH to the control circuit 100.

The temperature abnormality detection circuit 250 generates an abnormality signal XHOT of a digital signal indicating whether a temperature abnormality occurs in the print head 21 and the drive signal selection circuit 200, and outputs the abnormality signal XHOT to the control circuit 100. Specifically, the temperature abnormality detection circuit 250 outputs the abnormality signal XHOT at the H level when determining that the temperature abnormality has not occurred in the printhead 21 or the drive signal selection circuit 200, and outputs the abnormality signal XHOT at the L level when determining that the temperature abnormality has occurred in the printhead 21 or the drive signal selection circuit 200. The logic level of the abnormal signal XHOT is an example, and for example, the abnormal temperature detection circuit 250 may output the abnormal signal XHOT at an L level when determining that the temperatures of the printhead 21 and the drive signal selection circuit 200 are normal, and may output the abnormal signal XHOT at an H level when determining that the temperatures of the printhead 21 and the drive signal selection circuit 200 are abnormal.

The control circuit 100 performs various processes corresponding to the temperature signal TH and the abnormality signal XHOT. In other words, the abnormality signal XHOT is a signal indicating the presence or absence of a temperature abnormality in the print head 21 and the drive signal selection circuit 200. This improves the accuracy of ink ejection from the ejection unit 600, and prevents operational abnormalities, malfunctions, and the like of the print head 21 and the drive signal selection circuit 200 in the printing state.

3. Example of waveform of drive signal

Here, an example of the waveforms of the drive signals COMA and COMB generated by the drive signal output circuit 50 and an example of the waveform of the drive signal VOUT supplied to the piezoelectric element 60 will be described with reference to fig. 3 and 4.

Fig. 3 is a diagram showing an example of the drive signals COMA and COMB. As shown in fig. 3, the drive signal COMA is a waveform in which the trapezoidal waveform Adp1 and the trapezoidal waveform Adp2 are continuous, the trapezoidal waveform Adp1 is arranged in a period T1 from the start of rising of the latch signal LAT to the rise of the transition signal CH1, and the trapezoidal waveform Adp2 is arranged in a period T2 from the start of rising of the transition signal CH1 to the rise of the next latch signal LAT. In the present embodiment, the trapezoidal waveform Adp1 and the trapezoidal waveform Adp2 are waveforms in which substantially the same amount of ink is ejected. When the trapezoidal waveforms Adp1 and Adp2 are supplied to one end of the piezoelectric element 60, an intermediate amount of ink is ejected from the ejection section 600 corresponding to the piezoelectric element 60.

The drive signal COMB is a waveform in which the trapezoidal waveform Bdp1 and the trapezoidal waveform Bdp2 are continuous, the trapezoidal waveform Bdp1 is arranged in a period T3 from the start of rising of the latch signal LAT to the rise of the transition signal CH2, and the trapezoidal waveform Bdp2 is arranged in a period T4 from the start of rising of the transition signal CH2 to the rise of the next latch signal LAT. In the present embodiment, the trapezoidal waveform Bdp1 and the trapezoidal waveform Bdp2 are different waveforms from each other. The trapezoidal waveform Bdp1 is a waveform for preventing an increase in ink viscosity by slightly vibrating ink in the vicinity of the nozzle opening portion of the ejection portion 600. When the trapezoidal waveform Bdp1 is supplied to one end of the piezoelectric element 60, ink is not ejected from the ejection section 600 corresponding to the piezoelectric element 60. The trapezoidal waveform Bdp2 is a waveform different from the trapezoidal waveforms Adp1, Adp2, and trapezoidal waveform Bdp 1. When the trapezoidal waveform Bdp2 is supplied to one end of the piezoelectric element 60, an amount of ink smaller than the medium amount is ejected from the ejection section 600 corresponding to the piezoelectric element 60.

As described above, the ejection section 600 ejects different amounts of ink when the drive signal COMA is supplied to the piezoelectric element 60 and when the drive signal COMB is supplied to the piezoelectric element 60. That is, one of the amount of ink discharged from the discharge portion 600 when the drive signal COMA is supplied to the piezoelectric element 60 and the amount of ink discharged from the discharge portion 600 when the drive signal COMB is supplied to the piezoelectric element 60 is an example of the first amount, and the other of the amounts of ink discharged from the discharge portion 600 is an example of an amount different from the first amount.

Here, a period Ta from the rise of the latch signal LAT to the rise of the next latch signal LAT corresponds to a print period for forming a new dot (dot) on the medium P. That is, the latch signal LAT is a signal for defining the ejection timing. The conversion signal CH1 is a signal for specifying waveform switching timings of the trapezoidal waveform Adp1 and the trapezoidal waveform Adp2 included in the drive signal COMA. The conversion signal CH2 is a signal for specifying the waveform switching timing of the trapezoidal waveform Bdp1 and the trapezoidal waveform Bdp2 included in the drive signal COMB.

The voltages at the start timings and the end timings of the trapezoidal waveforms Adp1, Adp2, Bdp1, and Bdp2 are all the voltages Vc. That is, the trapezoidal waveforms Adp1, Adp2, Bdp1, and Bdp2 are waveforms starting at the voltage Vc and ending at the voltage Vc, respectively. Further, the description has been given of the drive signals COMA and COMB as signals having two continuous trapezoidal waveforms in the period Ta, but three or more continuous trapezoidal waveforms may be used.

Fig. 4 is a diagram showing an example of the drive signal VOUT corresponding to each of "large dot", "middle dot", "small dot", and "non-recording".

As shown in fig. 4, the drive signal VOUT corresponding to the "large dot" is a waveform in which the trapezoidal waveform Adp1 and the trapezoidal waveform Adp2 continue in the period Ta. When the drive signal VOUT is supplied to one end of the piezoelectric element 60, an intermediate amount of ink is ejected twice from the ejection section 600 corresponding to the piezoelectric element 60 in the period Ta. Therefore, the inks land on the medium P and are combined to form a large dot.

The drive signal VOUT corresponding to the "midpoint" is a waveform in which the trapezoidal waveform Adp1 and the trapezoidal waveform Bdp2 continue in the period Ta. When the drive signal VOUT is supplied to one end of the piezoelectric element 60, a medium amount of ink and a small amount of ink are ejected from the ejection section 600 corresponding to the piezoelectric element 60 in the period Ta. Therefore, the inks land and join together on the medium P to form a midpoint.

The drive signal VOUT corresponding to the "small dot" has a trapezoidal waveform Bdp2 in the period Ta. When the drive signal VOUT is supplied to one end of the piezoelectric element 60, a small amount of ink is ejected from the ejection section 600 corresponding to the piezoelectric element 60 in the period Ta. Therefore, the ink lands on the medium P to form small dots.

The drive signal VOUT corresponding to "non-recording" has a trapezoidal waveform Bdp1 in the period Ta. When the drive signal VOUT is supplied to one end of the piezoelectric element 60, the ink in the vicinity of the nozzle opening portion of the ejection portion 600 corresponding to the piezoelectric element 60 vibrates slightly in the period Ta, and the ink is not ejected. Therefore, the ink does not land on the medium P, and dots are not formed.

Here, when neither of the drive signals COMA and COMB is selected as the drive signal VOUT, the previous voltage Vc is held at one end of the piezoelectric element 60 by the capacitance component of the piezoelectric element 60. That is, when either one of the drive signals COMA and COMB is not selected, the voltage Vc is supplied to the piezoelectric element 60 as the drive signal VOUT.

The drive signals COMA and COMB and the drive signal VOUT shown in fig. 3 and 4 are always examples, and various combinations of waveforms may be used depending on the moving speed of the carriage 20 on which the print head 21 is mounted, the physical properties of the ejected ink, the material of the medium P, and the like. The drive signal COMA and the drive signal COMB may be continuous signals having the same trapezoidal waveform.

4. Structure and operation of drive signal selection circuit

Next, the configuration and operation of the drive signal selection circuit 200 will be described with reference to fig. 5 to 8. Fig. 5 is a diagram showing the configuration of the drive signal selection circuit 200. As shown in fig. 5, the drive signal selection circuit 200 includes a selection control circuit 220 and a plurality of selection circuits 230.

The print data signal SI, the latch signal LAT, the conversion signals CH1, CH2, the clock signal SCK, and the N charge signal NCHG are input to the selection control circuit 220. In the selection control circuit 220, a set of a shift register (S/R)222, a latch circuit 224, and a decoder 226 is provided corresponding to each of the plurality of ejection sections 600. That is, the drive signal selection circuit 200 includes the same number of sets of the shift register 222, the latch circuit 224, and the decoder 226 as the total number m of the corresponding ejection sections 600.

The print data signal SI is a signal for specifying the selection of the waveforms of the drive signal COMA and the drive signal COMB. Specifically, the print data signal SI is a signal synchronized with the clock signal SCK, and is a signal including 2 bits (bit) of print data [ SIH, SIL ] for selecting any one of "large dot", "middle dot", "small dot", and "non-recording" for each of the m ejection units 600, and having a total of 2m bits. The print data signal SI corresponds to the discharge unit 600, and is held in the shift register 222 in accordance with the 2-bit print data [ SIH, SIL ] included in the print data signal SI. Specifically, the m-stage shift registers 222 corresponding to the ejection section 600 are vertically connected to each other, and sequentially transfer the print data signal SI supplied in series to the subsequent stage in accordance with the clock signal SCK. In fig. 5, the shift register 222 is labeled as 1 stage, 2 stages, … … stage, and m stages in order from the upstream side to which the print data signal SI is supplied.

The m latch circuits 224 latch the print data [ SIH, SIL ] of 2 bits held by the m shift registers 222, respectively, by the rise of the latch signal LAT, respectively.

The m decoders 226 respectively decode the print data [ SIH, SIL ] of 2 bits respectively latched by the m latch circuits 224. Then, the decoder 226 outputs the selection signal S1 for each of the periods T1 and T2 defined by the latch signal LAT and the transition signal CH1, and outputs the selection signal S2 for each of the periods T3 and T4 defined by the latch signal LAT and the transition signal CH 2.

Fig. 6 is a diagram showing the decoded content in the decoder 226. When the N charge signal NCHG is at the L level, the decoder 226 outputs the selection signals S1 and S2 in accordance with the latched 2-bit print data [ SIH, SIL ]. For example, when the N charge signal NCHG is at the L level and the latched 2-bit print data [ SIH, SIL ] is [1, 0], the decoder 226 outputs the selection signal S1 at the H, L level in the periods T1 and T2, respectively, and outputs the selection signal S2 at the L, H level in the periods T3 and T4, respectively. When the N charge signal NCHG is at the H level, the decoder 226 outputs the selection signal S1 at the H level and outputs the selection signal S2 at the L level, in accordance with the print data [ SIH, SIL ] and the period Ta. In addition, the selection signals S1, S2 are level-shifted to high amplitude logic based on the high voltage signal VHV by a level shifter not shown in the figure.

The selection circuit 230 is provided corresponding to each of the discharge units 600. That is, the number of the selection circuits 230 included in the drive signal selection circuit 200 is equal to the total number m of the corresponding ejection portions 600.

Fig. 7 is a diagram showing the configuration of the selection circuit 230 corresponding to one ejection unit 600. As shown in fig. 7, the selection circuit 230 has

inverters

232a, 232b as a NOT circuit, and

transmission gates

234a, 234 b.

The selection signal S1 is supplied to the positive control terminal with no circular mark in the transfer gate 234a, and on the other hand, the selection signal S1 is logically inverted by the inverter 232a and supplied to the negative control terminal with a circular mark in the transfer gate 234 a. In addition, the selection signal S2 is supplied to the positive control terminal of the transfer gate 234b, and on the other hand, the selection signal S2 is logically inverted by the inverter 232b and supplied to the negative control terminal of the transfer gate 234 b.

The drive signal COMA is supplied to the input terminal of the transfer gate 234a, and the drive signal COMB is supplied to the input terminal of the transfer gate 234 b. The output terminals of the

transmission gates

234a and 234b are commonly connected to each other, and the drive signal VOUT is output to the ejection section 600 through the common connection terminal.

The transmission gate 234a turns ON (ON) the input terminal and the output terminal when the selection signal S1 is at the H level, and turns OFF (OFF) the input terminal and the output terminal when the selection signal S1 is at the L level. The transmission gate 234b is turned on between the input terminal and the output terminal when the selection signal S2 is at the H level, and is turned off between the input terminal and the output terminal when the selection signal S2 is at the L level.

Here, as described above, the N charge signal NCHG does not cause the selection signal S1 of the H level and the selection signal S2 of the L level to be output from the decoder 226 depending on the print data [ SIH, SIL ] and the period Ta. That is, the N charge signal NCHG is a signal for forcibly turning on the transmission gate 234 a. The N charge signal NCHG is used for, for example, maintenance actions of the print head 21 and the like. In the present embodiment, the N charge signal NCHG is set to the L level when the liquid ejecting apparatus 1 performs a printing operation, and is set to the H level when a maintenance operation or the like is performed, but the present invention is not limited thereto.

Next, the operation of the drive signal selection circuit 200 will be described with reference to fig. 8. Fig. 8 is a diagram for explaining the operation of the drive signal selection circuit 200. The print data signal SI is supplied in series in synchronization with the clock signal SCK, and is sequentially transferred through the shift register 222 corresponding to the ejection unit 600. When the supply of the clock signal SCK is stopped, the 2-bit print data [ SIH, SIL ] corresponding to each discharge unit 600 is held in each shift register 222. The print data signal SI is supplied to the shift register 222 in the order of the final m stages, … …, 2 stages, and 1 stage corresponding to the ejection unit 600.

When the latch signal LAT rises, the latch circuits 224 latch the 2-bit print data [ SIH, SIL ] held in the shift register 222 at once. In fig. 8, LT1, LT2, … …, LTm denote 2-bit print data [ SIH, SIL ] latched by the latch circuits 224 corresponding to the shift registers 222 of 1 stage, 2 stages, … …, m stages.

The decoder 226 outputs the logic levels of the selection signals S1 and S2 in the respective periods T1, T2, T3 and T4 in accordance with the dot size defined by the latched 2-bit print data [ SIH, SIL ] as shown in fig. 6.

Specifically, when the print data [ SIH, SIL ] is [1, 1], the decoder 226 sets the selection signal S1 to the H, H level in the periods T1 and T2, and sets the selection signal S2 to the L, L level in the periods T3 and T4. In this case, the selection circuit 230 selects the trapezoidal waveform Adp1 included in the drive signal COMA in the period T1, selects the trapezoidal waveform Adp2 included in the drive signal COMA in the period T2, does not select the trapezoidal waveform Bdp1 included in the drive signal COMB in the period T3, and does not select the trapezoidal waveform Bdp2 included in the drive signal COMB in the period T4. As a result, the drive signal VOUT corresponding to the "large dot" shown in fig. 4 is generated.

When the print data [ SIH, SIL ] is [1, 0], the decoder 226 sets the selection signal S1 to the H, L level in the periods T1 and T2, and sets the selection signal S2 to the L, H level in the periods T3 and T4. In this case, the selection circuit 230 selects the trapezoidal waveform Adp1 included in the drive signal COMA in the period T1, does not select the trapezoidal waveform Adp2 included in the drive signal COMA in the period T2, does not select the trapezoidal waveform Bdp1 included in the drive signal COMB in the period T3, and selects the trapezoidal waveform Bdp2 included in the drive signal COMB in the period T4. As a result, the drive signal VOUT corresponding to the "midpoint" shown in fig. 4 is generated.

When the print data [ SIH, SIL ] is [0, 1], the decoder 226 sets the selection signal S1 to the L, L level in the periods T1 and T2, and sets the selection signal S2 to the L, H level in the periods T3 and T4. In this case, the selection circuit 230 does not select the trapezoidal waveform Adp1 included in the drive signal COMA during the period T1, does not select the trapezoidal waveform Adp2 included in the drive signal COMA during the period T2, does not select the trapezoidal waveform Bdp1 included in the drive signal COMB during the period T3, and selects the trapezoidal waveform Bdp2 included in the drive signal COMB during the period T4. As a result, the drive signal VOUT corresponding to the "small dot" shown in fig. 4 is generated.

When the print data [ SIH, SIL ] is [0, 0], the decoder 226 sets the selection signal S1 to the L, L level in the periods T1 and T2, and sets the selection signal S2 to the H, L level in the periods T3 and T4. In this case, the selection circuit 230 does not select the trapezoidal waveform Adp1 included in the drive signal COMA during the period T1, does not select the trapezoidal waveform Adp2 included in the drive signal COMA during the period T2, selects the trapezoidal waveform Bdp1 included in the drive signal COMB during the period T3, and does not select the trapezoidal waveform Bdp2 included in the drive signal COMB during the period T4. As a result, the drive signal VOUT corresponding to "non-recording" shown in fig. 4 is generated.

As described above, the drive signal selection circuit 200 selects the drive signals COMA and COMB based on the print data signal SI, the latch signal LAT, the conversion signals CH1 and CH2, and the clock signal SCK, and outputs the drive signal VOUT. The drive signal selection Circuit 200 may be formed as an IC (Integrated Circuit), for example.

5. Structure and operation of temperature abnormality detection circuit

Next, the configuration and operation of the temperature abnormality detection circuit 250 will be described with reference to fig. 9. Fig. 9 is a diagram showing the configuration of the temperature abnormality detection circuit 250. As shown in fig. 9, the temperature abnormality detection circuit 250 includes a comparator 251, a reference voltage output circuit 252, a transistor 253, a plurality of diodes 254, and

resistors

255, 256.

The reference voltage output circuit 252 is input with a low voltage signal VDD 2. The reference voltage output circuit 252 generates a voltage Vref by transforming the low voltage signal VDD2, and supplies the voltage Vref to the + side input terminal of the comparator 251. The reference voltage output circuit 252 is configured by, for example, a voltage regulator circuit.

The plurality of diodes 254 are connected in series with each other. Among the plurality of diodes 254 connected in series, the anode terminal of the diode 254 on the highest potential side is supplied with the low voltage signal VDD2 via the resistor 255, and the cathode terminal of the diode 254 on the lowest potential side is supplied with the ground signal GND. Specifically, the temperature abnormality detection circuit 250 includes diodes 254-1, 254-2, 254-3, and 254-4 as the plurality of diodes 254. The anode terminal of the diode 254-1 is supplied with the low-voltage signal VDD2 via the resistor 255, and the anode terminal of the diode 254-1 is connected to the minus-side input terminal of the comparator 251. The cathode terminal of the diode 254-1 is connected to the anode terminal of the diode 254-2. The cathode terminal of the diode 254-2 is connected to the anode terminal of the diode 254-3. The cathode terminal of the diode 254-3 is connected to the anode terminal of the diode 254-4. The ground signal GND is supplied to the cathode terminal of the diode 254-4. The resistor 255 and the diodes 254 configured as described above supply the voltage Vdet, which is the sum of the forward voltages of the diodes 254, to the negative input terminal of the comparator 251. The number of the plurality of diodes 254 included in the temperature abnormality detection circuit 250 is not limited to four.

The comparator 251 operates based on the potential difference between the low-voltage signal VDD2 and the ground signal GND. The comparator 251 compares the voltage Vref supplied to the + side input terminal with the voltage Vdet supplied to the-side input terminal, and outputs a signal based on the comparison result from the output terminal.

The low-voltage signal VDD2 is supplied to the drain terminal of the transistor 253 via the resistor 256. The gate terminal of the transistor 253 is connected to the output terminal of the comparator 251, and the ground signal GND is supplied to the source terminal. The voltage supplied to the drain terminal of the transistor 253 connected as described above is output from the temperature abnormality detection circuit 250 as an abnormality signal XHOT.

The voltage value of the voltage Vref generated by the reference voltage output circuit 252 is smaller than the voltage Vdet when the temperatures of the plurality of diodes 254 are within a predetermined range. In this case, the comparator 251 outputs a signal of L level. Therefore, the transistor 253 is controlled to be off, and as a result, the temperature abnormality detection circuit 250 outputs the abnormality signal XHOT of the H level.

The forward voltage of the diode 254 has a characteristic of decreasing as the temperature rises. Therefore, when a temperature abnormality occurs in the print head 21 or the drive signal selection circuit 200, the temperature of the diode 254 rises, and the voltage Vdet decreases accordingly. When the voltage Vdet is lower than the voltage Vref due to the temperature rise, the output signal of the comparator 251 changes from the L level to the H level. Accordingly, the transistor 253 is controlled to be on. As a result, the temperature abnormality detection circuit 250 outputs the L-level abnormality signal XHOT. That is, the temperature abnormality detection circuit 250 controls the transistor 253 to be on or off based on the temperature of the drive signal selection circuit 200, thereby outputting the low voltage signal VDD2 supplied as the pull-up voltage of the transistor 253 as the H-level abnormality signal XHOT, and outputting the ground signal GND as the L-level abnormality signal XHOT.

6. Structure of printing head

Here, an example of the structure of the print head 21 will be described with reference to fig. 10. Fig. 10 is a perspective view showing the structure of the print head 21. The print head 21 has a head 310 and a head substrate 320. The head 310 has an ink ejection surface 311 that ejects ink from the plurality of ejection portions 600.

Fig. 11 is a plan view showing the ink ejection surface 311 of the head 310. As shown in fig. 11, six nozzle plates 632 are arranged in parallel along the X direction on the ink ejection surface 311. Nozzle rows L1 to L6 in which the nozzles 651 are arranged in the Y direction are formed in the nozzle plates 632. In fig. 11, the nozzles 651 are arranged in a row in the nozzle rows L1 to L6 provided in the nozzle plates 632, but the nozzles 651 may be arranged in two or more rows. Then, inks of different colors are supplied to the nozzle rows L1 to L6 formed on the ink ejection surface 311. Further, ink of a common color may be supplied to several of the nozzle rows L1 to L6.

Here, the discharge units 600 provided corresponding to the drive signal selection circuits 200a to 200f described in fig. 2 correspond to the discharge units 600 provided in the nozzle rows L1 to L6 shown in fig. 11. Specifically, the drive signal VOUT1 output from the drive signal selection circuit 200a is supplied to one end of the piezoelectric element 60 included in the plurality of discharge units 600 provided in the nozzle row L1, and the reference voltage signal CGND1 is supplied to the other end of the piezoelectric element 60. Similarly, the drive signal VOUT2 output from the drive signal selection circuit 200b is supplied to one end of the piezoelectric element 60 included in the plurality of ejection sections 600 provided in the nozzle row L2, and the reference voltage signal CGND2 is supplied to the other end of the piezoelectric element 60. Similarly, the drive signal VOUT3 output from the drive signal selection circuit 200c is supplied to one end of the piezoelectric element 60 included in the plurality of ejection sections 600 provided in the nozzle row L3, and the reference voltage signal CGND3 is supplied to the other end of the piezoelectric element 60. Similarly, the drive signal VOUT4 output from the drive signal selection circuit 200d is supplied to one end of the piezoelectric element 60 included in the plurality of ejection sections 600 provided in the nozzle row L4, and the reference voltage signal CGND4 is supplied to the other end of the piezoelectric element 60. Similarly, the drive signal VOUT5 output from the drive signal selection circuit 200e is supplied to one end of the piezoelectric element 60 included in the plurality of ejection sections 600 provided in the nozzle row L5, and the reference voltage signal CGND5 is supplied to the other end of the piezoelectric element 60. Similarly, the drive signal VOUT6 output from the drive signal selection circuit 200f is supplied to one end of the piezoelectric element 60 included in the plurality of ejection sections 600 provided in the nozzle row L6, and the reference voltage signal CGND6 is supplied to the other end of the piezoelectric element 60.

Next, the structure of the discharge unit 600 will be described with reference to fig. 12. Fig. 12 is a diagram showing a schematic configuration of one of the plurality of ejection units 600 included in the print head 21. As shown in fig. 12, the print head 21 includes the ejection section 600 and the reservoir 641.

The reservoir 641 is disposed in the color of ink. That is, the reservoir 641 is provided in common in each of the nozzle rows L1 to L6. Ink is introduced from the ink supply port 661 into the reservoir 641.

The discharge unit 600 includes a piezoelectric element 60, a vibration plate 621, a chamber 631 functioning as a pressure chamber, and a nozzle 651. The vibrating plate 621 is displaced by the piezoelectric element 60 provided on the upper surface in fig. 12, and functions as a diaphragm that expands and contracts the internal volume of the ink-filled chamber 631. The nozzle 651 is provided on the nozzle plate 632, and is an aperture portion communicating with the chamber 631. The chamber 631 is filled with ink therein, and the internal volume is changed by the displacement of the piezoelectric element 60. The nozzle 651 communicates with the chamber 631, and ejects ink in the chamber 631 according to a change in the internal volume of the chamber 631.

The piezoelectric element 60 shown in fig. 12 has a structure in which a piezoelectric body 601 is sandwiched between a pair of

electrodes

611 and 612. In the piezoelectric body 601 having this structure, the center portions of the

electrodes

611 and 612 and the vibrating plate 621 are bent in the vertical direction in fig. 12 with respect to both end portions in accordance with the voltage supplied to the

electrodes

611 and 612. Specifically, when the voltage of the drive signal VOUT becomes high, the center portion of the piezoelectric element 60 bends upward. On the other hand, when the voltage of the drive signal VOUT decreases, the central portion of the piezoelectric element 60 is configured to bend downward. In this configuration, when the piezoelectric element 60 is bent upward, the internal volume of the chamber 631 is expanded. Accordingly, ink is introduced from the reservoir 641. On the other hand, when the piezoelectric element 60 is bent downward, the internal volume of the chamber 631 decreases. Therefore, ink is ejected from the nozzle 651 to the extent of the reduction.

The piezoelectric element 60 is not limited to the illustrated configuration, and may be of a type that can deform the piezoelectric element 60 and eject a liquid such as ink. The piezoelectric element 60 is not limited to bending vibration, and may be configured to vibrate in the longitudinal direction.

Returning to fig. 10, the head substrate 320, which is an example of a substrate, is a substantially rectangular circuit substrate having a surface 321 and a surface 322 different from the surface 321, and having a side 323, a side 324 facing the side 323 in the X direction, a side 325, and a side 326 facing the side 325 in the Y direction. Here, in the head board 320, the

surfaces

321 and 322 are surfaces that are positioned to face each other through the base material of the head board 320, in other words, the

surfaces

321 and 322 are front and back surfaces of the head board 320. The shape of the head substrate 320 is not limited to a rectangle, and may be a polygon such as a hexagon or an octagon, or a part thereof may be formed with a notch, an arc, or the like.

On a surface 321 of the head substrate 320 to which the head 310 is connected, a first connector 350 and a second connector 360 are mounted. The head board 320 has a surface 322 opposite to the surface 321, and connection terminal groups 331 to 336 are formed on the surface 322. Further, the head substrate 320 is formed with FPC through holes 337 to 339 and ink supply path through holes 340 to 345, which penetrate the surface 321 and the surface 322.

The first connector 350 is disposed along the edge 323 of the head substrate 320. In addition, the second connector 360 is disposed along the side 324 of the head substrate 320. The first connector 350 and the second connector 360 are input with a control signal Ctrl-H including a plurality of signals for controlling the print head 21 and a plurality of drive signals COM. The control signal Ctrl-H and the plurality of drive signals COM are transmitted to the respective connection terminal groups 331 to 336 via wiring patterns, not shown, formed on the head substrate 320.

Specifically, the connection terminal group 331 has a plurality of electrodes arranged side by side along the Y direction. Then, signals including the following signals are supplied to the connection terminal group 331: the print data signal SI1, the conversion signals CH1 and CH2, the latch signal LAT, the clock signal SCK, the drive signals COMA1 and COMB1, and the reference voltage signal CGND1 for controlling the ejection of ink from the ejection section 600 included in the nozzle row L1.

Similarly, the connection terminal group 332 has a plurality of electrodes arranged in parallel in the Y direction on the side 324 side of the connection terminal group 331. Then, signals including the following signals are supplied to the connection terminal group 332: the print data signal SI2, the conversion signals CH1 and CH2, the latch signal LAT, the clock signal SCK, the drive signals COMA2 and COMB2, and the reference voltage signal CGND2 for controlling the ejection of ink from the ejection section 600 included in the nozzle row L2.

Similarly, the connection terminal group 333 has a plurality of electrodes arranged in parallel in the Y direction on the side 324 side of the connection terminal group 332. Further, signals including the following signals are supplied to the connection terminal group 333: the print data signal SI3, the conversion signals CH1 and CH2, the latch signal LAT, the clock signal SCK, the drive signals COMA3 and COMB3, and the reference voltage signal CGND3 for controlling the ejection of ink from the ejection section 600 included in the nozzle row L3.

Similarly, the connection terminal group 334 includes a plurality of electrodes arranged side by side in the Y direction on the side 324 side of the connection terminal group 333. Then, signals including the following signals are supplied to the connection terminal group 334: the print data signal SI4, the conversion signals CH1 and CH2, the latch signal LAT, the clock signal SCK, the drive signals COMA4 and COMB4, and the reference voltage signal CGND4 for controlling the ejection of ink from the ejection section 600 included in the nozzle row L4.

Similarly, the connection terminal group 335 has a plurality of electrodes arranged side by side in the Y direction on the side 324 side of the connection terminal group 334. Then, signals including the following signals are supplied to the connection terminal group 335: the print data signal SI5, the conversion signals CH1 and CH2, the latch signal LAT, the clock signal SCK, the drive signals COMA5 and COMB5, and the reference voltage signal CGND5 for controlling the ejection of ink from the ejection section 600 included in the nozzle row L5.

Similarly, the connection terminal group 336 has a plurality of electrodes arranged in parallel in the Y direction on the side 324 side of the connection terminal group 335. Then, signals including the following signals are supplied to the connection terminal group 336: the print data signal SI6, the conversion signals CH1 and CH2, the latch signal LAT, the clock signal SCK, the drive signals COMA6 and COMB6, and the reference voltage signal CGND6 for controlling the ejection of ink to the ejection section 600 included in the nozzle row L6.

In addition, a Flexible Printed Circuit (FPC), not shown, is connected to each of the connection terminal groups 331 to 336. The signals supplied to the respective connection terminal groups 331 to 336 are examples, and signals corresponding to the arrangement of the nozzle rows L1 to L6 provided in the head 310, the structure of the FPC, and the like may be supplied.

The FPC through-hole 337 is formed between the connection terminal group 331 and the connection terminal group 332 in the X direction. The FPCs connected to the respective

connection terminal groups

331 and 332 are inserted into the FPC insertion holes 337 and electrically connected to the plurality of piezoelectric elements 60 included in the respective nozzle rows L1 and L2 provided in the head 310.

The FPC through-hole 338 is formed between the connection terminal group 333 and the connection terminal group 334 in the X direction. The FPCs connected to the respective

connection terminal groups

333 and 334 are inserted into the FPC insertion holes 338 and electrically connected to the plurality of piezoelectric elements 60 included in the respective nozzle rows L3 and L4 provided in the head 310.

The FPC insertion hole 339 is formed between the connection terminal group 335 and the connection terminal group 336 in the X direction. The FPCs connected to the respective

connection terminal groups

335 and 336 are inserted into the FPC insertion holes 339, and are electrically connected to the plurality of piezoelectric elements 60 included in the respective nozzle rows L5 and L6 provided in the head 310.

Although not shown, the drive signal selection circuits 200a to 200f of the print head 21 may be mounted On FPCs connected to the connection terminal groups 331 to 336 by COF (Chip On Film), or may be provided inside the head 310.

The ink supply path through-hole 340 is inserted into and passes through a part of an ink supply path, not shown, that supplies ink to the ink supply ports 661, which supplies ink ejected from the nozzle row L1. Similarly, the ink supply path through holes 341 to 345 are inserted into and pass through a part of an ink supply path, not shown, that supplies ink to the ink supply port 661, which supplies ink discharged from the nozzle rows L2, L3, L4, L5, and L6, respectively.

Next, the structure of the first connector 350 and the second connector 360 mounted on the head substrate 320 will be described with reference to fig. 13 and 14.

Fig. 13 is a diagram showing the structure of the first connector 350. The first connector 350 has a housing 351, a cable mounting portion 352, and a plurality of terminals 353. The plurality of terminals 353 are arranged side by side in the Y direction. When a cable electrically connected to the control mechanism 10 is attached to the cable attachment portion 352, a plurality of terminals included in the cable are electrically connected to the plurality of terminals 353, respectively. In the first connector 350 of the present embodiment, 29 terminals 353 are arranged in parallel in the Y direction. In the following description, 29 terminals 353 arranged side by side may be referred to as terminals 353-1, 353-2, … …, 353-29 in order in a direction from the side 326 toward the side 325.

Fig. 14 is a diagram showing the structure of the second connector 360. The second connector 360 has a housing 361, a cable mounting part 362, and a plurality of terminals 363. The plurality of terminals 363 are arranged side by side in the Y direction. When a cable electrically connected to the control mechanism 10 is attached to the cable attachment portion 362, a plurality of terminals included in the cable are electrically connected to the plurality of terminals 363, respectively. In the second connector 360 of the present embodiment, 29 terminals 363 are arranged side by side in the Y direction. In the following description, 29 terminals 363 arranged side by side may be referred to as terminals 363-1, 363-2, … …, 363-29 in order from the side 325 side toward the side 326 side.

The print head 21 configured as described above has a function of self-diagnosis based on an input diagnosis signal. The self-diagnosis function is a function of self-diagnosing whether or not the print head 21 is normal, and for example, a function of determining whether or not the formation of dots and the ejection of ink satisfying normal print quality can be performed by the print head 21 itself based on a diagnosis signal input to the print head 21 from the control circuit 100 of the control mechanism 10.

Such self-diagnosis is preferably performed in a non-printing state, for example, when power is turned on to the liquid ejecting apparatus 1, when shutdown processing of the liquid ejecting apparatus 1 is executed, or when a print start instruction or a print end instruction is generated. In addition, when the liquid ejecting apparatus 1 is continuously turned on, the self-diagnosis in the case where the non-printing state is continuous may be performed periodically or aperiodically. Such self-diagnosis is performed based on the diagnosis signals input from the first connector 350 and the second connector 360.

The connection between the print head 21 and the control mechanism 10 may be checked as a self-diagnosis based on whether or not the voltage level of the input diagnosis signal is normal, for example. The print head 21 may operate any configuration such as the drive signal selection circuit 200 and the piezoelectric element 60 included in the print head 21 based on a combination of logic levels of the input diagnosis signals, and detect a voltage signal caused by the operation to check the operation of various configurations included in the print head 21 as a self-diagnosis. The print head 21 may check the operation of any configuration, such as the drive signal selection circuit 200 and the piezoelectric element 60, included in the print head 21 as a self-diagnosis, based on a predetermined command included in the input diagnosis signal. In addition, the print head 21 may perform self-diagnosis other than the above.

7. Structure of printing head control circuit

Fig. 15 is a diagram schematically showing an internal configuration of the liquid discharge apparatus 1 when viewed from the Y direction. As shown in fig. 15, the liquid ejection device 1 includes a main substrate 11, a first cable 19a, a second cable 19b, and a print head 21.

Various circuits including a drive signal output circuit 50 included in the control mechanism 10 shown in fig. 1 and 2 and a control circuit 100 for outputting various signals such as a control signal Ctrl-H and a diagnostic signal are mounted on the main board 11. Further, a third connector 12a and a fourth connector 12b are mounted on the main board 11. In fig. 15, one circuit board is shown as the main board 11, but the main board 11 may be configured by two or more circuit boards. To the third connector 12a, one end of a first cable 19a is attached. Further, one end of the second cable 19b is attached to the fourth connector 12 b.

As described above, the print head 21 has the head 310, the head substrate 320, the first connector 350, and the second connector 360. The other end of the first cable 19a is attached to the first connector 350. Further, the other end of the second cable 19b is attached to the second connector 360.

The liquid ejecting apparatus 1 configured as described above controls the operation of the print head 21 having the self-diagnostic function based on various signals such as the plurality of drive signals COM, the control signal Ctrl-H, and the plurality of diagnostic signals, which are output from the control means 10 mounted on the main board 11. That is, in the liquid ejecting apparatus 1 shown in fig. 15, the configuration including the main board 11 on which the control means 10 for outputting various signals such as the plurality of drive signals COM, the control signal Ctrl-H, and the plurality of diagnostic signals for controlling the operation of the print head 21 is mounted, the first cable 19a and the second cable 19b for transmitting various signals such as the plurality of drive signals COM, the control signal Ctrl-H, and the plurality of diagnostic signals for controlling the operation of the print head 21 is an example of the print head control circuit 15 for controlling the operation of the print head 21 having the self-diagnostic function. In the print head control circuit 15, the control circuit 100 that generates a plurality of diagnostic signals is an example of a diagnostic signal output circuit.

Here, the structure of the first cable 19a and the second cable 19b will be described with reference to fig. 16. In the present embodiment, the first cable 19a and the second cable 19b have the same configuration. Therefore, in fig. 16, the first cable 19a and the second cable 19b will be referred to as cables 19. Fig. 16 is a diagram showing the structure of the cable 19. The cable 19 is substantially rectangular having

short sides

191, 192 opposed to each other and

long sides

193, 194 opposed to each other, and is, for example, a Flexible Flat Cable (FFC).

On the short side 191 side of the

cable

19, 29 terminals 195-1 to 195-29 are provided in parallel from the long side 193 side to the long side 194 side along the short side 191. In addition, 29 terminals 196-1 to 196-29 are provided along the short side 192 of the cable 19 from the long side 193 to the long side 194. In the

cable

19, 29 wires 197-1 to 197-29 are arranged side by side from the long side 193 side toward the long side 194 side, and the 29 wires 197-1 to 197-29 electrically connect the 29 terminals 195-1 to 195-29 to the 29 terminals 196-1 to 196-29, respectively. Specifically, wiring 197-i (i is any one of 1 to 29) electrically connects terminal 195-i and terminal 196-i.

The wires 197-1 to 197-29 are insulated from each other and from the outside of the cable 19 by insulators 198. In the cable 19, for example, various signals inputted from the terminal 195-i are transmitted by the wiring 197-i and outputted from the terminal 196-i to the head substrate 320. The structure of the cable 19 shown in fig. 16 is an example, but not limited to this, and for example, 29 terminals 195-1 to 195-29 and 29 terminals 196-1 to 196-29 may be provided on different surfaces of the cable 19. In addition, for example, 29 terminals 195-1 to 195-29 and 29 terminals 196-1 to 196-29 may be provided on both the front and back surfaces of the cable 19.

In fig. 16, a contact portion 180 is shown in which the terminal 196 contacts the terminal 353 of the first connector 350 or the terminal 363 of the second connector 360 provided on the head substrate 320. Fig. 17 is a diagram for explaining the contact portion 180 in a case where the cable 19 is mounted on the first connector 350. In addition, the first connector 350 and the second connector 360 have the same structure. Therefore, in fig. 17, a case where the cable 19 is attached to the first connector 350 will be described, and a description of a case where the cable 19 is attached to the second connector 360 will be omitted.

As shown in fig. 17, the terminal 353 of the first connector 350 includes a substrate mounting portion 353a, a housing penetrating portion 353b, and a cable holding portion 353 c. The substrate mounting portion 353a is located below the first connector 350 and is provided between the housing 351 and the head substrate 320. The substrate mounting portion 353a is electrically connected to an electrode, not shown, provided on the head substrate 320, for example, by solder or the like. The housing penetration portion 353b penetrates the inside of the housing 351. The housing insertion portion 353b electrically connects the substrate mounting portion 353a and the cable holding portion 353 c. The cable holding portion 353c has a curved shape protruding into the cable attachment portion 352. When the cable 19 is attached to the cable attachment portion 352, the cable holding portion 353c electrically contacts the terminal 196. Thereby, the cable 19 is electrically connected to the first connector 350 and the head substrate 320. In this case, by attaching the cable 19, stress is generated on the curved shape formed in the cable holding portion 353 c. And the cable 19 is held inside the cable fitting portion 352 by the stress. The contact portion 180 is a contact point at which the terminal 196 is electrically connected to the cable holding portion 353 c.

In addition, the shape of the first connector 350 is not limited to the above shape. The first connector 350 may have any shape as long as it holds the cable 19 and can transmit the signal transmitted from the cable 19 to the head substrate 320, and for example, the first connector 350 may have a lock mechanism, and hold the cable 19 by the lock mechanism, and electrically connect the cable 19 and the first connector 350 in accordance with the operation of the lock mechanism. That is, the contact portion 180 is a contact point at which the cable 19 included in the head control circuit 15 electrically contacts the print head 21, in other words, the contact portion 180 is an output point at which the head control circuit 15 outputs various control signals to the print head 21.

In the following description, the contact portions 180 of the terminals 196-1 to 196-24, which are in contact with the first connector 350 or the second connector 360, are sometimes referred to as contact portions 180-1 to 180-24, respectively.

Next, details of signals transmitted through the first cable 19a and the second cable 19b will be described with reference to fig. 18 and 19. In the explanation of fig. 18 and 19, the respective terminals 195-i, 196-i, wiring 197-i, and contact portion 180-i provided on the first cable 19a will be referred to as terminals 195a-i, 196a-i, wiring 197a-i, and contact portion 180 a-i. Similarly, the respective terminals 195-i, 196-i, wiring 197-i, and contact portion 180-i provided on the second cable 19b are referred to as terminals 195b-i, 196b-i, wiring 197b-i, and contact portion 180 b-i. In addition, the terminals 195a-i, 195b-i are mounted on the third connector 12a and the fourth connector 12b, respectively, and the terminals 196a-i, 196b-i are mounted so as to be electrically connected to the terminals 353-i, 363-i of the first connector 350 and the second connector 360 via the contact portions 180a-i, 180b-i, respectively.

First, details of a signal transmitted through the first cable 19a will be described with reference to fig. 18. Fig. 18 is a diagram for explaining details of a signal transmitted by the first cable 19 a. As shown in fig. 18, the first cable 19a includes a first wiring group 81 as an example of a first drive signal wiring group, a second wiring group 82 as an example of a first diagnostic signal wiring group, and a third wiring group 83 as an example of a second drive signal wiring group. The first wiring group 81 electrically contacts the print head 21 via the first wiring contact group 91. In addition, the second wiring group 82 is electrically contacted to the print head 21 via the second wiring contact group 92. In addition, the third wiring group 83 is electrically contacted to the print head 21 via the third wiring contact group 93. Here, the first wiring contact group 91 in which the first wiring group 81 electrically contacts the print head 21 is an example of the first drive signal contact group, and the third wiring contact group 93 in which the third wiring group 83 electrically contacts the print head 21 is an example of the second drive signal contact group.

The first wiring group 81 includes wirings 197a-24 to 197 a-29. In addition, the first wiring contact group 91 includes contacts 180a-24 to 180 a-29. The wirings 197a to 25 transmit a driving signal COMA1 supplied to one end of the piezoelectric element 60 included in the nozzle row L1. The drive signal COMA1 is then supplied to the printhead 21 via the contacts 180 a-25. The reference voltage signal CGND1 supplied to the other end of the piezoelectric element 60 included in the nozzle row L1 is transmitted through the wirings 197a to 24. The reference voltage signal CGND1 is then supplied to the printhead 21 via the contacts 180 a-24. The wirings 197a to 27 transmit a driving signal COMB2 supplied to one end of the piezoelectric element 60 included in the nozzle row L2. The drive signal COMB2 is then supplied to the printhead 21 via the contacts 180 a-27. The reference voltage signal CGND2 supplied to the other end of the piezoelectric element 60 included in the nozzle row L2 is transmitted to the wirings 197a to 26. The reference voltage signal CGND2 is then supplied to the printhead 21 via the contacts 180 a-26. The wirings 197a to 29 transmit a drive signal COMA3 supplied to one end of the piezoelectric element 60 included in the nozzle row L3. The drive signal COMA3 is then supplied to the printhead 21 via the contacts 180 a-29. The reference voltage signal CGND3 supplied to the other end of the piezoelectric element 60 included in the nozzle row L3 is transmitted through the wirings 197a to 28. The reference voltage signal CGND3 is then supplied to the printhead 21 via the contacts 180 a-28.

As described above, the first wiring group 81 transfers at least either one of the driving signals COMA and COMB for ejecting ink from the print head 21. Then, at least any one of the driving signals COMA and COMB transmitted by the first wiring group 81 is supplied to the print head 21 via the first wiring contact group 91.

Such a first wiring group 81 is constituted by wirings adjacent to each other in the first cable 19 a. That is, the first wiring group 81 is a set of a plurality of wirings including wirings which transfer at least any one of the driving signals COMA and COMB which are high voltage signals for driving the plurality of piezoelectric elements 60 included in the print head 21. Also, a plurality of wirings included in the first wiring group 81 are provided adjacent to each other in the first cable 19 a.

Similarly, the first wiring contact group 91 is a set of a plurality of contact portions for electrically contacting the first wiring group 81 to the print head 21 and supplying at least one of a drive signal COMA and a drive signal COMB, which are high-voltage signals for driving the plurality of piezoelectric elements 60 included in the print head 21, to the print head 21. Also, the plurality of contact portions included in the first wiring contact group 91 are disposed adjacent to each other among the plurality of contact portions where the first electrical cable 19a electrically contacts the first connector 350.

When the first cable 19a including the first wiring group 81 configured as described above is attached to the first connector 350 via the first wiring contact group 91, the terminals 196 a-24-196 a-29 of the first cable 19a are electrically connected to the terminals 353-24-353-29 of the first connector 350 via the contact portions 180 a-24-180 a-29. Thus, the drive signals COMA1, COMA2, COMA3, reference voltage signals CGND1, CGND2, and CGND3 transmitted through the wirings 197a to 24 to 197a to 29 are supplied to the print head 21.

The third wiring group 83 includes wirings 197a-1 to 197 a-6. In addition, the third wiring contact group 93 includes contact portions 180a-1 to 180 a-6. The wiring 197a to 6 transmits a drive signal COMB1 supplied to one end of the piezoelectric element 60 included in the nozzle row L1. The drive signal COMB1 is then supplied to the printhead 21 via contacts 180 a-6. The reference voltage signal CGND1 supplied to the other end of the piezoelectric element 60 included in the nozzle row L1 is transmitted through the wiring 197 a-5. Then, the reference voltage signal CGND1 is supplied to the print head 21 via the contacts 180 a-5. The wiring 197a-4 transmits a drive signal COMA2 supplied to one end of the piezoelectric element 60 included in the nozzle row L2. The drive signal COMA2 is then supplied to the printhead 21 via contacts 180 a-4. The reference voltage signal CGND2 supplied to the other end of the piezoelectric element 60 included in the nozzle row L2 is transmitted through the wiring 197 a-3. Then, the reference voltage signal CGND2 is supplied to the print head 21 via the contact portion 180 a-3. The wiring 197a-2 transmits a drive signal COMB3 supplied to one end of the piezoelectric element 60 included in the nozzle row L3. Then, the drive signal COMB3 is supplied to the print head 21 via the contact portion 180 a-2. The reference voltage signal CGND3 supplied to the other end of the piezoelectric element 60 included in the nozzle row L3 is transmitted through the wiring 197 a-1. Then, the reference voltage signal CGND3 is supplied to the print head 21 via the contact portion 180 a-1.

As described above, the third wiring group 83 transfers at least either one of the drive signal COMA and the drive signal COMB for ejecting ink from the print head 21. Then, at least any one of the driving signals COMA and COMB transmitted by the third wiring group 83 is supplied to the print head 21 via the third wiring contact group 93.

Such a third wiring group 83 is constituted by wirings adjacent to each other in the first cable 19 a. That is, the third wiring group 83 is a set of a plurality of wirings including wirings which transfer at least any one of the driving signals COMA and COMB which are high voltage signals for driving the plurality of piezoelectric elements 60 included in the print head 21. Also, a plurality of wirings included in the third wiring group 83 are provided adjacent to each other in the first cable 19 a.

Similarly, the third wiring contact group 93 is a set of a plurality of contact portions for electrically contacting the third wiring group 83 with the print head 21 and supplying at least either one of a drive signal COMA and a drive signal COMB, which are high voltage signals for driving the plurality of piezoelectric elements 60 included in the print head 21, to the print head 21. Also, the plurality of contact portions included in the third wiring contact group 93 are disposed adjacent to each other among the plurality of contact portions where the first electrical cable 19a electrically contacts the first connector 350.

When the first cable 19a including the third wiring group 83 configured as described above is attached to the first connector 350 via the third wiring contact group 93, the terminals 196a-1 to 196a-6 of the first cable 19a are electrically connected to the terminals 353-1 to 353-6 of the first connector 350 via the contact portions 180a-1 to 180 a-6. Thus, the drive signals COMA1, COMA2, COMA3, reference voltage signals CGND1, CGND2, CGND3 transmitted through the wirings 197a-1 to 197a-6 are supplied to the print head 21.

Here, the wirings 197a to 25 and 197a to 29 included in the first wiring group 81 and transmitting the drive signals COMA1 and COMA3 are examples of first drive signal transmission wirings, and the wirings 197a to 6 and 197a to 2 included in the third wiring group 83 and transmitting the drive signals COMB1 and COMB3 are examples of second drive signal transmission wirings. The wirings 197a to 27 included in the first wiring group 81 and transmitting the drive signal COMA2 are another example of the first drive signal transmission wirings, and the wirings 197a to 4 included in the third wiring group 83 and transmitting the drive signal COMA2 are another example of the second drive signal transmission wirings.

The second wiring group 82 includes wirings 197a-7 to 197 a-22. In addition, the second wiring contact group 92 includes contacts 180a-7 to 180 a-22. The latch signal LAT and the first diagnostic signal DIG1 may be transmitted by different wirings, but it is preferable that the latch signal LAT and the first diagnostic signal DIG1 for performing self-diagnosis of the print head 21 are transmitted by common wirings 197a to 21 as shown in fig. 18. In other words, the wirings 197a to 21 preferably serve as both a wiring for transmitting the first diagnostic signal DIG1 and a wiring for transmitting the latch signal LAT. In the non-printing state, the latch signal LAT is not transmitted through the wirings 197a to 21. On the other hand, since the self-diagnosis of the print head 21 is performed in the non-printing state, the first diagnostic signal DIG1 is transmitted by the wirings 197a to 21 in the non-printing state. Therefore, the latch signal LAT and the first diagnostic signal DIG1 can be transmitted through the common wirings 197a to 21, whereby the number of wirings included in the first cable 19a can be reduced.

Similarly, as shown in fig. 18, it is preferable that the wiring for transmitting the latch signal LAT and the wiring for transmitting the first diagnostic signal DIG1 for self-diagnosis of the print head 21 are electrically connected to the common contact portions 180a to 21. In other words, contacts 180a-21 preferably serve as both contacts that make electrical contact with the wiring that transmits the first diagnostic signal DIG1 and contacts that make electrical contact with the wiring that transmits the latch signal LAT. In the non-printing state, the latch signal LAT is not transmitted through the wirings 197a to 21. Therefore, the latch signal LAT is not supplied to the contacts 180a to 21. On the other hand, since the self-diagnosis of the print head 21 is performed in the non-printing state, the first diagnosis signal DIG1 is supplied to the contacts 180a-21 in the non-printing state. Therefore, the latch signal LAT and the first diagnostic signal DIG1 can be supplied to the print head 21 through the common contacts 180a-21, whereby the number of contacts at which the first cable 19a electrically contacts the print head 21 can be reduced. Therefore, the number of wires included in the first cable 19a and the number of terminals of the first connector 350 can be reduced.

Further, the latch signal LAT is an important signal for controlling the timing of ink ejection in the liquid ejection device 1, and when a connection failure occurs in a wiring and a contact portion through which the latch signal LAT is transmitted, there is a possibility that the accuracy of ink ejection deteriorates. By transmitting the first diagnostic signal DIG1 and the latch signal LAT through the common wirings 197a to 21 and supplying them to the print head 21 via the common contacts 180a to 21, the connection state of the wirings 197a to 21 transmitting the latch signal LAT and the contact state of the contacts 180a to 21 can be confirmed based on the result of self-diagnosis of the print head 21. That is, by performing self-diagnosis of the print head 21 based on the first diagnostic signal DIG1, it is possible to reduce the possibility of deterioration in the ink ejection accuracy of the liquid ejection device 1. The wires 197a to 21 transmitting the first diagnostic signal DIG1 exemplify a first diagnostic signal transmission wire, and the contacts 180a to 21 exemplify first contacts.

The converted signal CH1 and the second diagnostic signal DIG2 may be transmitted by different wirings, but preferably, as shown in fig. 18, the converted signal CH1 and the second diagnostic signal DIG2 for performing self-diagnosis of the print head 21 are transmitted by the common wirings 197a to 17. In other words, the wirings 197a to 17 preferably serve as both a wiring for transmitting the second diagnostic signal DIG2 and a wiring for transmitting the converted signal CH 1. In the non-printing state, the conversion signal CH1 is not transmitted through the wirings 197a to 17. On the other hand, since the self-diagnosis of the print head 21 is performed in the non-printing state, the second diagnosis signal DIG2 is transmitted by the wirings 197a to 17 in the non-printing state. Therefore, the converted signal CH1 and the second diagnostic signal DIG2 can be transmitted through the common wiring 197a to 17, whereby the number of wirings included in the first cable 19a can be reduced.

Similarly, as shown in fig. 18, it is preferable that the wiring for transmitting the converted signal CH1 and the wiring for transmitting the second diagnostic signal DIG2 for performing self-diagnosis of the print head 21 be electrically connected by the common contact portions 180a to 17. In other words, contacts 180a-17 preferably serve as both contacts that make electrical contact with the wiring that carries second diagnostic signal DIG2 and contacts that make electrical contact with the wiring that carries converted signal CH 1. In the non-printing state, the conversion signal CH1 is not transmitted through the wirings 197a to 17. Therefore, the conversion signal CH1 is not supplied to the contact portions 180 a-17. On the other hand, since the self-diagnosis of the print head 21 is performed in the non-printing state, the second diagnosis signal DIG2 is supplied to the contacts 180a-17 in the non-printing state. Thus, the converted signal CH1 and the second diagnostic signal DIG2 can be supplied to the printhead 21 through the common contacts 180 a-17. Thereby, the number of contact portions of the first cable 19a electrically contacting the print head 21 can be reduced. Therefore, the number of wires included in the first cable 19a and the number of terminals of the first connector 350 can be reduced.

Further, the conversion signal CH1 is an important signal for defining the timing of switching the waveform of the drive signal COMA in the liquid ejecting apparatus 1, and when a connection failure occurs in the wiring and the contact portion through which the conversion signal CH1 is transmitted, there is a possibility that the accuracy of ejecting ink may deteriorate. By transmitting the second diagnostic signal DIG2 and the conversion signal CH1 over the common wirings 197a to 17 and supplying them to the print head 21 via the common contacts 180a to 17, the connection state of the wirings 197a to 17 transmitting the conversion signal CH1 and the contact state of the contacts 180a to 17 can be confirmed based on the result of self-diagnosis of the print head 21. Therefore, the possibility of deterioration of the ink ejection accuracy of the liquid ejection device 1 can be reduced based on the result of self-diagnosis by the second diagnostic signal DIG2 of the print head 21. The wirings 197a to 17 transmitting the second diagnostic signal DIG2 are examples of second diagnostic signal transmission wirings, and the contacts 180a to 17 are examples of second contacts.

The wirings 197a to 19 transmit a conversion signal CH2 that defines waveform switching timings of the trapezoidal waveform Bdp1 and the trapezoidal waveform Bdp2 included in the drive signal COMB. The converted signal CH2 is then supplied to the print head 21 via the contacts 180 a-19. The second diagnostic signal DIG2 may be transmitted through the wirings 197a to 19 that transmit the converted signal CH2, and supplied to the printhead 21 through the contacts 180a to 19.

The print data signal SI1 and the third diagnostic signal DIG3 may be transmitted by different wirings, but preferably, as shown in fig. 18, the print data signal SI1 and the third diagnostic signal DIG3 for performing self-diagnosis of the print head 21 are transmitted by the common wirings 197a to 14. In other words, the wirings 197a to 14 preferably serve as both a wiring for transmitting the third diagnostic signal DIG3 and a wiring for transmitting the print data signal SI 1. In the non-printing state, the print data signal SI1 is not transmitted through the wirings 197a to 14. On the other hand, since the self-diagnosis of the print head 21 is performed in the non-printing state, the third diagnostic signal DIG3 is transmitted by the wirings 197a to 14 in the non-printing state. Therefore, the print data signal SI1 and the third diagnostic signal DIG3 can be transmitted through the common wiring 197a to 14, whereby the number of wirings included in the first cable 19a can be reduced.

Similarly, as shown in fig. 18, it is preferable that the wiring for transmitting the print data signal SI1 and the wiring for transmitting the third diagnostic signal DIG3 for performing self-diagnosis of the print head 21 be electrically connected to the common contact portions 180a to 14. In other words, contacts 180a-14 preferably serve as both contacts that are in electrical contact with the wiring that transmits third diagnostic signal DIG3 and contacts that are in electrical contact with the wiring that transmits print data signal SI 1. In the non-printing state, the print data signal SI1 is not transmitted through the wirings 197a to 14. Therefore, the print data signal SI1 is not supplied to the contacts 180 a-14. On the other hand, since the self-diagnosis of the print head 21 is performed in the non-printing state, the third diagnostic signal DIG3 is supplied to the contacts 180a-14 in the non-printing state. Accordingly, the print data signal SI1 and the third diagnostic signal DIG3 can be supplied to the printhead 21 through the common contacts 180a-14, whereby the number of contacts of the first cable 19a that electrically contact the printhead 21 can be reduced. Therefore, the number of wires included in the first cable 19a and the number of terminals of the first connector 350 can be reduced.

Further, the print data signal SI1 is an important signal for defining the waveform selection of the drive signals COMA1 and COMB1 in the liquid ejecting apparatus 1, and when a connection failure occurs in the wiring and the contact portion through which the print data signal SI1 is transmitted, there is a possibility that the ink ejection accuracy deteriorates. By transmitting the third diagnostic signal DIG3 and the print data signal SI1 over the common wiring 197a to 14 and supplying them to the print head 21 via the common contacts 180a to 14, the connection state of the wiring 197a to 14 transmitting the print data signal SI1 and the contact state of the contacts 180a to 14 can be confirmed based on the result of self-diagnosis of the print head 21. Therefore, the possibility of deterioration of the ink ejection accuracy of the liquid ejection device 1 can be reduced based on the result of self-diagnosis by the third diagnostic signal DIG3 of the print head 21. The wirings 197a to 14 transmitting the third diagnostic signal DIG3 exemplify the third diagnostic signal transmission wiring, and the contacts 180a to 14 exemplify the third contacts.

The wirings 197a to 8 transmit a print data signal SI2 which specifies the waveform selection of the drive signals COMA2 and COMB2 supplied to the nozzle row L2. The print data signal SI2 is then supplied to the printhead 21 via contacts 180 a-8. In addition, the wirings 197a to 10 transmit a print data signal SI3 which specifies the waveform selection of the drive signals COMA3 and COMB3 supplied to the nozzle row L3. The print data signal SI3 is then supplied to the printhead 21 via contacts 180 a-10.

Here, the third diagnostic signal DIG3 may also be transmitted through the wiring 197a-8 that transmits the print data signal SI2 or the wiring 197a-10 that transmits the print data signal SI3, and supplied to the print head 21 via the corresponding contacts 180a-8, 180 a-10. Specifically, the third diagnostic signal DIG3 is preferably supplied to a wiring that also serves as a transmission line for a print data signal corresponding to a nozzle row that ejects black ink, or to a contact portion that is common to the wiring. In other words, it is preferable that the wiring for transmitting the third diagnostic signal DIG3 and the contact portion for supplying the third diagnostic signal DIG3 are used as both the wiring for transmitting a signal for specifying the selection of the waveforms of the drive signal COMA and the drive signal COMB corresponding to the nozzle row including the nozzles 651 for ejecting the black liquid and the contact portion for supplying the signal. The black ink is one of the most commonly used inks in the liquid ejection device 1. Therefore, by using both the wiring for transmitting the third diagnostic signal DIG3 and the wiring for transmitting the print data signal corresponding to the nozzle row for ejecting the black ink and making the common contact portion electrically contact the print head 21, the self-diagnostic function of the print head 21 can be performed even when the number of the nozzle rows for ejecting the ink is different in the print head 21. Here, the black ink is not limited to black, and may be matte black or photo black.

In the wirings 197a to 16, a temperature signal TH as an analog signal containing temperature information of the print head 21 is transmitted. The temperature signal TH is supplied to the wirings 197a to 16 via the contacts 180a to 16.

The wirings 197a-7, 197a-9, 197a-11 to 197a-13, 197a-15, 197a-18, 197a-20, and 197a-22 transmit a ground signal GND. Then, the ground signal GND is supplied to the print head 21 via the contacts 180a-7, 180a-9, 180a-11 to 180a-13, 180a-15, 180a-18, 180a-20, and 180 a-22.

As shown in fig. 18, the wirings 197a to 22 among the wirings which transmit the ground signal GND are provided between the wirings 197a to 21, the wirings 197a to 17, and the wirings 197a to 14 and the first wiring group 81. In addition, the wirings 197a to 7 are provided between the wirings 197a to 21, the wirings 197a to 17, and the wirings 197a to 14 and the third wiring group 83. In other words, the wirings 197a to 22 among the wirings which transmit the ground signal GND are located on the first wiring group 81 side than the wirings 197a to 21, the wirings 197a to 17, and the wirings 197a to 14, and the wirings 197a to 7 are located on the third wiring group 83 side than the wirings 197a to 21, the wirings 197a to 17, and the wirings 197a to 14. Thereby, the possibility that the driving signals COMA and COMB interfere with the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 is reduced. Therefore, the first, second, and third diagnostic signals DIG1, DIG2, and DIG3 are supplied to the printhead 21 with high accuracy. Therefore, the possibility that the self-diagnostic function of the print head 21 does not operate normally can be reduced. Here, the wirings 197a to 22 for transmitting the ground signal GND are an example of a first ground signal transmission wiring, and the wirings 197a to 7 are an example of a second ground signal transmission wiring.

In addition, similarly, the contacts 180a-22 among the contacts that supply the ground signal GND to the print head 21 are disposed between the contacts 180a-21, the contacts 180a-17, and the contacts 180a-14 and the first wiring contact group 91. Additionally, contacts 180a-7 are disposed between contacts 180a-21, contacts 180a-17, and contacts 180a-14 and the third set of wiring contacts 93. In other words, the contacts 180a to 22 among the contacts that supply the ground signal GND to the printhead 21 are located closer to the first wiring contact group 91 than the contacts 180a to 21, the contacts 180a to 17, and the contacts 180a to 14, and the contacts 180a to 7 are located closer to the third wiring contact group 93 than the contacts 180a to 21, the contacts 180a to 17, and the contacts 180a to 14. Thereby, the possibility that the driving signals COMA and COMB interfere with the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 is reduced. Therefore, the first, second, and third diagnostic signals DIG1, DIG2, and DIG3 are supplied to the printhead 21 with high accuracy. Therefore, the possibility that the self-diagnostic function of the print head 21 does not operate normally can be reduced. Here, the contact portions 180a to 22 of the wiring for transmitting the ground signal GND and the print head 21 are an example of the sixth contact portion, and the contact portions 180a to 7 are an example of the seventh contact portion.

In addition, in the first cable 19a, the wirings 197a to 17 are provided between the wirings 197a to 21 and the wirings 197a to 14. In this case, wirings 197a to 18 and 197a to 20 which transmit ground signals are provided between the wirings 197a to 21 and the wirings 197a to 17, and wirings 197a to 15 which transmit ground signals are provided between the wirings 197a to 17 and the wirings 197a to 14. That is, the wirings 197a to 21, 197a to 17, 197a to 14 that transmit the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3, respectively, are located at positions that are not adjacent to each other, and a wiring that transmits the ground signal GND is provided between the wirings 197a to 21, 197a to 17, 197a to 14. Thereby, the possibility that the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 interfere with each other is reduced. Therefore, the first, second, and third diagnostic signals DIG1, DIG2, and DIG3 are supplied to the printhead 21 with high accuracy. Therefore, the possibility that the self-diagnostic function of the print head 21 does not operate normally can be reduced. Here, at least one of the wirings 197a to 18 and 197a to 20 is an example of a fifth ground signal transmission wiring, and the wirings 197a to 15 are an example of a sixth ground signal transmission wiring.

In addition, also in the contact portions that electrically contact the first cable 19a with the print head 21, the contact portions 180a to 17 are provided between the contact portions 180a to 21 and the contact portions 180a to 14. In this case, contacts 180a-18, 180a-20 are disposed between contacts 180a-21 and contacts 180a-17, and contacts 180a-15 are disposed between contacts 180a-17 and contacts 180 a-14. That is, the contacts 180a-21, 180a-17, 180a-14 that supply the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 to the printhead 21, respectively, are located at positions that are not adjacent to each other, and a contact that supplies the ground signal GND to the printhead 21 is provided between the contacts 180a-21, 180a-17, 180 a-14. Thereby, the possibility that the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 interfere with each other is reduced. Therefore, the first, second, and third diagnostic signals DIG1, DIG2, and DIG3 are supplied to the printhead 21 with high accuracy. Therefore, the possibility that the self-diagnostic function of the print head 21 does not operate normally can be reduced. Here, at least one of the contact portions 180a to 18 and 180a to 20 is an example of a tenth contact portion, and the contact portions 180a to 15 is an example of an eleventh contact portion.

As described above, the second wiring group 82 includes at least: wirings 197a to 21 that transmit a first diagnostic signal DIG1 for performing self-diagnosis of the print head 21; wiring 197a-17 that transmits the second diagnostic signal DIG 2; and wiring 197a-14 that carries a third diagnostic signal DIG 3. Such a second wiring group 82 is constituted by wirings adjacent to each other in the first cable 19 a. That is, the second wiring group 82 is a set of a plurality of wirings including wirings transmitting the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3, and the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 are low-voltage signals for performing self-diagnosis of the printhead 21. Also, a plurality of wirings included in the second wiring group 82 are provided adjacent to each other in the first cable 19 a. The second wiring group 82 may include a plurality of wirings for transmitting low-voltage signals for controlling the printhead 21, such as the print data signals SI1 to SI3, the conversion signals CH1 and CH2, the latch signal LAT, and the ground signal GND, or may include wirings for transmitting the ground signal GND.

Similarly, the second wiring contact group 92 includes at least: contacts 180a-21 that transmit first diagnostic signals DIG1 for self-diagnosis of the print head 21, wiring 197a-21 being in electrical contact with the print head 21; contacts 180a-17 where wires 197a-17 carrying second diagnostic signal DIG2 make electrical contact with printhead 21; and contacts 180a-14 where wires 197a-14 carrying third diagnostic signal DIG3 make electrical contact with printhead 21. Such a second wiring contact group 92 is constituted by contact portions adjacent to each other. That is, the second wire contact group 92 is a set of a plurality of contact portions for supplying the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 to the printhead 21, and the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 are low-voltage signals for performing self-diagnosis of the printhead 21. And, the plurality of contact portions are disposed adjacent to each other. The second wiring contact group 92 may include a plurality of contacts for transmitting low-voltage signals for controlling the print head 21, such as the print data signals SI1 to SI3, the conversion signals CH1 and CH2, the latch signal LAT, and the ground signal GND, or a contact group for supplying the ground signal GND to the print head 21.

When the first cable 19a including the second wiring group 82 configured as described above is attached to the first connector 350 via the second wiring contact group 92, the terminals 196a-7 to 196a-22 of the first cable 19a are electrically connected to the terminals 353-7 to 353-22 of the first connector 350 via the contact portions 180a-7 to 180 a-22. Thus, a plurality of signals including the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 transmitted through the wirings 197a-7 to 197a-22 are supplied to the print head 21. That is, in the print head 21, the terminals 353 to 21 to which the first diagnostic signal DIG1 is input are an example of a first connection point, the terminals 353 to 17 to which the second diagnostic signal DIG2 is input are an example of a second connection point, and the terminals 353 to 14 to which the third diagnostic signal DIG3 is input are an example of a third connection point. The contact group 97 including the first wiring contact group 91, the second wiring contact group 92, and the third wiring contact group 93 for electrically connecting the first cable 19a and the print head 21 is an example of the first contact group.

In addition, in the first cable 19a, the second wiring group 82 is disposed between the first wiring group 81 and the third wiring group 83. Thereby, noise generated outside the first cable 19a is shielded by the first wiring group 81 and the third wiring group 83, and the possibility of the noise being superimposed on the second wiring group 82 is reduced. Likewise, in the contact group 97, the second wiring contact group 92 is disposed between the first wiring contact group 91 and the third wiring contact group 93. Thus, noise generated in the vicinity of the contact group 97 is shielded by the first wiring contact group 91 and the third wiring contact group 93, and the possibility of the noise being superimposed on the second wiring contact group 92 is reduced. Thereby, the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3, which are transmitted through the second wiring group 82 and supplied to the print head 21 via the second wiring contact group 92, are supplied to the print head 21 with high accuracy. Therefore, the possibility that the self-diagnostic function of the print head 21 does not operate normally can be reduced.

In addition, the first cable 19a includes wirings 197a to 23 that transmit a high-voltage signal VHV. And, the high voltage signal VHV is supplied to the print head 21 via the contacts 180 a-23. The wirings 197a to 23 are positioned between the first wiring group 81 and the second wiring group 82, and the contacts 180a to 23 are positioned between the first wiring contact group 91 and the second wiring contact group 92. This can further reduce the possibility of noise being superimposed on the second wiring group 82 and the second wiring contact group 92. Further, the wiring for transmitting the high voltage signal VHV may be provided between the second wiring group 82 and the third wiring group 83, and the contact portion for supplying the high voltage signal VHV to the print head 21 may be provided between the second wiring contact group 92 and the third wiring contact group 93.

Next, details of the signal transmitted through the second cable 19b will be described with reference to fig. 19. Fig. 19 is a diagram for explaining details of a signal transmitted by the second cable 19 b. As shown in fig. 19, the second cable 19b includes a fourth wiring group 84 as an example of the third drive signal wiring group, a fifth wiring group 85 as an example of the second diagnostic signal wiring group, and a sixth wiring group 86 as an example of the fourth drive signal wiring group. And, the fourth wiring group 84 is electrically contacted to the print head 21 via the fourth wiring contact group 94. In addition, the fifth wiring group 85 electrically contacts the print head 21 via the fifth wiring contact group 95. In addition, the sixth wiring group 86 electrically contacts the print head 21 via the sixth wiring contact group 96. Here, the fourth wiring contact group 94 in which the fourth wiring group 84 electrically contacts the print head 21 is an example of the third drive signal contact group, and the sixth wiring contact group 96 in which the sixth wiring group 86 electrically contacts the print head 21 is an example of the fourth drive signal contact group.

The fourth wiring group 84 includes wirings 197b-24 to 197 b-29. In addition, the fourth wiring contact group 94 includes contacts 180b-24 to 180 b-29. The wirings 197b to 29 transmit a drive signal COMA4 supplied to one end of the piezoelectric element 60 included in the nozzle row L4. Then, the drive signal COMA4 is supplied to the print head 21 via the contacts 180 b-29. The reference voltage signal CGND4 supplied to the other end of the piezoelectric element 60 included in the nozzle row L4 is transmitted through the wiring 197 b-28. Then, the reference voltage signal CGND4 is supplied to the print head 21 via the contacts 180 b-28. The wirings 197b to 27 transmit a driving signal COMB5 supplied to one end of the piezoelectric element 60 included in the nozzle row L5. Then, the drive signal COMB5 is supplied to the print head 21 via the contacts 180 b-27. The reference voltage signal CGND5 supplied to the other end of the piezoelectric element 60 included in the nozzle row L5 is transmitted to the wirings 197b to 26. Then, the reference voltage signal CGND5 is supplied to the print head 21 via the contacts 180 b-26. The wirings 197b to 25 transmit a driving signal COMA6 supplied to one end of the piezoelectric element 60 included in the nozzle row L6. Then, the drive signal COMA6 is supplied to the print head 21 via the contacts 180 b-25. The reference voltage signal CGND6 supplied to the other end of the piezoelectric element 60 included in the nozzle row L6 is transmitted through the wirings 197b to 24. Then, the reference voltage signal CGND6 is supplied to the print head 21 via the contacts 180 b-24.

As described above, the fourth wiring group 84 transmits at least either one of the driving signals COMA and COMB for ejecting ink from the print head 21. Then, at least any one of the driving signals COMA and COMB transmitted by the fourth wiring group 84 is supplied to the print head 21 via the fourth wiring contact group 94.

Such a fourth wiring group 84 is constituted by wirings adjacent to each other in the second cable 19 b. That is, the fourth wiring group 84 is a set of a plurality of wirings including wirings which transfer at least any one of the driving signals COMA and COMB which are high voltage signals for driving the plurality of piezoelectric elements 60 included in the print head 21. Also, a plurality of wirings included in the fourth wiring group 84 are provided adjacent to each other in the second cable 19 b.

Similarly, the fourth wiring contact group 94 is a set of a plurality of contact portions for electrically contacting the fourth wiring group 84 to the print head 21 and supplying at least either one of a drive signal COMA and a drive signal COMB to the print head 21, the drive signal COMA and the drive signal COMB being high-voltage signals for driving the plurality of piezoelectric elements 60 included in the print head 21. Also, the plurality of contact portions included in the fourth wiring contact group 94 are provided adjacent to each other in the plurality of contact portions 180 where the second electrical cable 19b electrically contacts the second connector 360.

When the second cable 19b including the fourth wiring group 84 configured as described above is attached to the second connector 360 via the fourth wiring contact group 94, the terminals 196b-24 to 196b-29 of the second cable 19b are electrically connected to the terminals 363-24 to 363-29 of the second connector 360 via the contacts 180b-24 to 180 b-29. Thus, the drive signals COMA4, COMA5, COMA6, and the reference voltage signals CGND4, CGND5, and CGND6 transmitted through the wirings 197b-24 to 197b-29 are supplied to the print head 21.

The sixth wiring group 86 includes wirings 197b-1 to 197 b-6. The sixth wiring contact group 96 includes contact portions 180b-1 to 180 b-6. The wiring 197b-2 transmits a drive signal COMB4 supplied to one end of the piezoelectric element 60 included in the nozzle row L4. Then, the drive signal COMB4 is supplied to the print head 21 via the contact portion 180 b-2. The reference voltage signal CGND4 supplied to the other end of the piezoelectric element 60 included in the nozzle row L4 is transmitted through the wiring 197 b-1. Then, the reference voltage signal CGND4 is supplied to the print head 21 via the contact portion 180 b-1. The wiring 197b-4 transmits a drive signal COMA5 supplied to one end of the piezoelectric element 60 included in the nozzle row L5. Then, the drive signal COMA5 is supplied to the print head 21 via the contact portion 180 b-4. The reference voltage signal CGND5 supplied to the other end of the piezoelectric element 60 included in the nozzle row L5 is transmitted through the wiring 197 b-3. Then, the reference voltage signal CGND5 is supplied to the print head 21 via the contact portion 180 b-3. The wiring 197b-6 transmits a drive signal COMB6 supplied to one end of the piezoelectric element 60 included in the nozzle row L6. Then, the drive signal COMB6 is supplied to the print head 21 via the contact portion 180 b-6. The reference voltage signal CGND6 supplied to the other end of the piezoelectric element 60 included in the nozzle row L6 is transmitted through the wiring 197 b-5. Then, the reference voltage signal CGND6 is supplied to the print head 21 via the contact portion 180 b-5.

As described above, the sixth wiring group 86 transfers at least either one of the drive signal COMA and the drive signal COMB for ejecting ink from the print head 21. At least one of the drive signal COMA and the drive signal COMB transmitted by the sixth wiring group 86 is supplied to the print head 21 via the sixth wiring contact group 96.

Such a sixth wiring group 86 is constituted by wirings adjacent to each other in the second cable 19 b. That is, the sixth wiring group 86 is a set of a plurality of wirings including wirings for transferring at least any one of the driving signals COMA and COMB, which are high-voltage signals for driving the plurality of piezoelectric elements 60 included in the print head 21. Also, the plurality of wirings included in the sixth wiring group 86 are provided adjacent to each other in the second cable 19 b.

Similarly, the sixth wiring contact group 96 is a set of a plurality of contact portions for electrically contacting the sixth wiring group 86 to the print head 21 and supplying at least one of a drive signal COMA and a drive signal COMB, which are high-voltage signals for driving the plurality of piezoelectric elements 60 included in the print head 21, to the print head 21. Also, the plurality of contact portions included in the sixth wiring contact group 96 are provided adjacent to each other in the plurality of contact portions 180 where the second electrical cable 19b electrically contacts the second connector 360.

When the second cable 19b including the sixth wiring group 86 configured as described above is attached to the second connector 360 via the sixth wiring contact group 96, the terminals 196b-1 to 196b-6 of the second cable 19b are electrically connected to the terminals 363-1 to 363-6 of the second connector 360 via the contacts 180b-1 to 180 b-6. Thus, the drive signals COMA4, COMB5, COMA6, reference voltage signals CGND4, CGND5, and CGND6 transmitted through the wirings 197b-1 to 197b-6 are supplied to the print head 21.

The fifth wiring group 85 includes wirings 197b-7 to 197 b-23. In addition, the fifth wiring contact group 95 includes contacts 180b-7 to 180 b-23. The clock signal SCK and the fourth diagnostic signal DIG4 may be transmitted through different wirings, but as shown in fig. 19, it is preferable that the clock signal SCK for controlling the timing of various signals supplied to the print head 21 and the fourth diagnostic signal DIG4 for performing self-diagnosis of the print head 21 are transmitted through a common wiring 197 b-10. In other words, the wiring 197b to 10 preferably serves as both a wiring for transmitting the fourth diagnostic signal DIG4 and a wiring for transmitting the clock signal SCK. In the non-printing state, when the print data signal SI is not supplied, the clock signal SCK is not transmitted through the wiring 197 b-10. On the other hand, since the self-diagnosis of the print head 21 is performed in the non-printing state, the fourth diagnostic signal DIG4 is transmitted by the wiring 197b-10 in the non-printing state. Therefore, the clock signal SCK and the fourth diagnostic signal DIG4 can be transmitted through the common wiring 197b-10, whereby the number of wirings included in the second cable 19b can be reduced.

Similarly, as shown in fig. 19, it is preferable that the wiring for transmitting the clock signal SCK and the wiring for transmitting the fourth diagnostic signal DIG4 for performing self-diagnosis of the print head 21 be electrically connected to the common contact portion 180 b-10. In other words, the contact portion 180b-10 preferably functions as both a contact portion electrically contacting the wiring that transmits the fourth diagnostic signal DIG4 and a contact portion electrically contacting the wiring that transmits the clock signal SCK. In the non-printing state, the clock signal SCK is not transmitted through the wiring 197 b-10. Therefore, the clock signal SCK is not supplied to the contact portion 180 b-10. On the other hand, since the self-diagnosis of the print head 21 is performed in the non-printing state, the fourth diagnosis signal DIG4 is supplied to the contact portion 180b-10 in the non-printing state. Therefore, the clock signal SCK and the fourth diagnostic signal DIG4 can be supplied to the print head 21 through the common contact portion 180b-10, whereby the number of contact portions of the second cable 19b electrically contacting the print head 21 can be reduced. Therefore, the number of wires included in the second cable 19b and the number of terminals of the second connector 360 can be reduced.

The clock signal SCK is an important signal for controlling the timing of various signals for controlling the ejection of ink in the liquid ejection device 1, and when a connection failure occurs in the wiring and the contact portion through which the clock signal SCK is transmitted, the accuracy of ink ejection may deteriorate. By transmitting the fourth diagnostic signal DIG4 and the clock signal SCK through the common wiring 197b-10 and supplying the signals to the print head 21 through the common contact 180b-10, the connection state of the wiring 197b-10 transmitting the clock signal SCK and the contact state of the contact 180b-10 can be confirmed based on the self-diagnosis result of the print head 21. That is, by performing self-diagnosis of the print head 21 based on the fourth diagnostic signal DIG4, it is possible to reduce the possibility of deterioration in the ink ejection accuracy of the liquid ejection device 1. The wiring 197b-10 transmitting the fourth diagnostic signal DIG4 is an example of a fourth diagnostic signal transmission wiring, and the contact 180b-10 is an example of a fourth contact.

The abnormality signal XHOT and the fifth diagnostic signal DIG5 may be transmitted through different wirings, but it is preferable that the abnormality signal XHOT and the fifth diagnostic signal DIG5 for performing self-diagnosis of the printhead 21 be transmitted through common wirings 197b to 16 as shown in fig. 19. In other words, the wirings 197b to 16 preferably serve as both a wiring for transmitting the fifth diagnostic signal DIG5 and a wiring for transmitting the abnormality signal XHOT. The abnormality signal XHOT is output as an H-level or L-level signal according to whether or not the print head 21 has a temperature abnormality. In other words, the abnormality signal XHOT is a signal indicating whether or not the temperature of the print head 21 is abnormal in the printing state. Therefore, the abnormality signal XHOT for determining the state of the print head 21 in the printing state and the fifth diagnostic signal DIG5 for determining the state of the print head 21 by self-diagnosis in the non-printing state are transmitted through the common wiring 197b to 16, so that the processing in the control mechanism 10 can be shared. This can simplify the control of the liquid discharge apparatus 1. In addition, by transmitting the abnormality signal XHOT and the fifth diagnostic signal DIG5 through the common wiring 197b to 16, the number of wirings included in the second cable 19b can be reduced.

In addition, also, it is preferable that the wiring that transmits the abnormality signal XHOT and the wiring that transmits the fifth diagnostic signal DIG5 indicating the diagnostic result of the self-diagnosis of the print head 21 are electrically contacted through the common contact portions 180b to 16. In other words, the contacts 180b-16 preferably serve as both a contact electrically contacting the wiring that transmits the fifth diagnostic signal DIG5 and a contact electrically contacting the wiring that transmits the abnormality signal XHOT. The abnormality signal XHOT is output as an H-level or L-level signal according to whether or not the print head 21 has a temperature abnormality. In other words, the abnormality signal XHOT is a signal indicating whether or not the temperature of the print head 21 is abnormal in the printing state. Therefore, the abnormality signal XHOT for determining the state of the print head 21 in the printing state and the fifth diagnostic signal DIG5 for self-diagnosing the state of the print head 21 in the non-printing state are supplied to the common contact portions 180b to 16, whereby the processes in the control mechanism 10 can be shared. This can simplify the control of the liquid discharge apparatus 1. In addition, by supplying the abnormality signal XHOT and the fifth diagnostic signal DIG5 to the common contact portions 180b to 16, the number of wires included in the second cable 19b and the number of terminals included in the second connector 360 can be reduced.

The abnormality signal XHOT is an important signal indicating whether or not the print head 21 is abnormal in the liquid ejecting apparatus 1, and when a connection failure occurs in the wiring and the contact portion through which the abnormality signal XHOT is transmitted, the control unit 10 may erroneously detect that an abnormality has occurred in the print head 21. By transmitting the fifth diagnostic signal DIG5 and the abnormality signal XHOT through the common wiring 197b-16 and supplying the signals from the print heads 21 through the common contacts 180b-16, the connection state of the wiring 197b-16 through which the abnormality signal XHOT is transmitted and the contact state of the contacts 180b-16 can be confirmed based on the self-diagnosis result of the print heads 21. Therefore, the possibility of erroneous detection of the abnormal signal XHOT can be reduced based on the diagnostic result of the fifth diagnostic signal DIG 5. The wiring 197b-16 transmitting the fifth diagnostic signal DIG5 is an example of a fifth diagnostic signal transmission wiring, and the contact 180b-16 is an example of a fifth contact.

The wiring 197b-8 transmits a print data signal SI4 specifying the waveform selection of the drive signals COMA4 and COMB4 supplied to the nozzle row L4. Then, the print data signal SI4 is supplied to the print head 21 via the contact portion 180 b-8. The wirings 197b to 17 transmit a print data signal SI5 for defining waveform selection of the drive signals COMA5 and COMB5 supplied to the nozzle row L5. Then, the print data signal SI5 is supplied to the print head 21 via the contacts 180 b-17. The wirings 197b to 21 transmit a print data signal SI6 for specifying the waveform selection of the drive signals COMA6 and COMB6 supplied to the nozzle row L6. Then, the print data signal SI6 is supplied to the print head 21 via the contacts 180 b-21.

In the wirings 197b to 12, either one of the drive signal COMA or the drive signal COMB is forcibly selected in a non-printing state, and the N charge signal NCHG output as the drive signal VOUT is transmitted. Then, the N charge signal NCHG is supplied to the print head 21 via the contacts 180 b-12.

The wirings 197b-7, 197b-9, 197b-11, 197b-14, 197b-15, 197b-18 to 197b-20, and 197b-22 transmit a ground signal GND. The ground signal GND is supplied to the print head 21 via the contacts 180b-7, 180b-9, 180b-11, 180b-14, 180b-15, 180b-18 to 180b-20, and 180 b-22.

The wiring 197b to 22 of the wirings transmitting the ground signal GND is provided between the wiring 197b to 10 and the wiring 197b to 16 and the fourth wiring group 84. In addition, the wiring 197b-7 is provided between the wiring 197b-10 and the wiring 197b-16 and the sixth wiring group 86. In other words, the wiring 197b-22 is located closer to the fourth wiring group 84 than the wiring 197b-10 and the wiring 197b-16, and the wiring 197b-7 is located closer to the sixth wiring group 86 than the wiring 197b-10 and the wiring 197 b-16. This can reduce interference between the driving signals COMA and COMB and the fourth and fifth diagnostic signals DIG4 and DIG 5. Therefore, the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 are supplied with high accuracy. Therefore, the possibility that the self-diagnostic function of the print head 21 does not operate normally can be reduced. Here, the wiring 197b to 22 for transmitting the ground signal GND is an example of a third ground signal transmission wiring, and the wiring 197b to 7 is an example of a fourth ground signal transmission wiring.

In addition, similarly, the contact portions 180b-22 among the contact portions that supply the ground signal GND to the print head 21 are provided between the contact portions 180b-10 and the contact portions 180b-16 and the fourth wiring contact group 94. In addition, the contact portion 180b-7 is disposed between the contact portion 180b-10 and the contact portion 180b-16 and the sixth wiring contact group 96. In other words, the contact portion 180b-22 is located closer to the fourth wiring contact group 94 than the contact portion 180b-10 and the contact portion 180b-16, and the contact portion 180b-7 is located closer to the sixth wiring contact group 96 than the contact portion 180b-10 and the contact portion 180 b-16. This can reduce interference between the driving signals COMA and COMB and the fourth and fifth diagnostic signals DIG4 and DIG 5. Therefore, the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 are supplied with high accuracy. Therefore, the possibility that the self-diagnostic function of the print head 21 does not operate normally can be reduced. Here, the contact portion 180b-22 of the wiring for transmitting the ground signal GND and the print head 21 electrically contacts one example of the eighth contact portion, and the contact portion 180b-7 one example of the ninth contact portion.

In addition, in the second cable 19b, the wirings 197b-11, 197b-14, 197b-15 are provided between the wiring 197b-10 and the wiring 197 b-16. That is, the wirings 197b-10, 197b-16 that transmit the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5, respectively, are located at positions that are not adjacent to each other, and further, between the wirings 197b-10, 197b-16, a wiring that transmits the ground signal GND is provided. This reduces interference between the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG 5. Therefore, the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 are supplied with high accuracy. Therefore, the possibility that the self-diagnostic function of the print head 21 does not operate normally can be reduced. Here, at least one of the wirings 197b to 11, 197b to 14, and 197b to 15 is an example of the seventh ground signal transmission wiring.

In addition, in the second cable 19b, likewise, the contact portions 180b-11, 180b-14, 180b-15 are disposed between the contact portion 180b-10 and the contact portion 180 b-16. That is, the contacts 180b-10, 180b-16 to which the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 are supplied, respectively, are located at positions that are not adjacent to each other, and a contact that supplies the ground signal GND to the print head 21 is provided between the contacts 180b-10, 180 b-16. This reduces interference between the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG 5. Therefore, the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 are supplied with high accuracy. Therefore, the possibility that the self-diagnostic function of the print head 21 does not operate normally can be reduced. Here, at least one of the contact portions 180b-11, 180b-14, and 180b-15 is an example of the twelfth contact portion.

As described above, the fifth wiring group 85 includes at least the wirings 197b to 10 which transmit the fourth diagnostic signal DIG4 for performing self-diagnosis of the printhead 21, and the wirings 197b to 16 which transmit the fifth diagnostic signal DIG 5. Such a fifth wiring group 85 is constituted by wirings adjacent to each other in the second cable 19 b. That is, the fifth wiring group 85 is a set of a plurality of wirings including at least wirings transmitting the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 as low voltage signals for performing self-diagnosis of the print head 21. Also, a plurality of wirings included in the fifth wiring group 85 are provided adjacent to each other in the second cable 19 b. The fifth wiring group 85 may include a plurality of wirings for transmitting the print data signals SI4 to SI6, the abnormality signal XHOT, the ground signal GND, and the like.

In addition, similarly, the fifth wiring contact group 95 includes at least: a contact portion 180b-10 where a wiring 197b-10 transmitting a fourth diagnostic signal DIG4 for performing self-diagnosis of the print head 21 electrically contacts the print head 21; and contacts 180b-16 where wires 197b-16 carrying fifth diagnostic signal DIG5 make electrical contact with printhead 21. Such a fifth wiring contact group 95 is constituted by contact portions adjacent to each other. That is, the fifth wiring contact group 95 is a set of a plurality of contacts for supplying the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5, which are low voltage signals, for performing self-diagnosis of the printhead 21. And, the plurality of contact portions are disposed adjacent to each other. The fifth wiring contact group 95 may include a plurality of contacts for transmitting low voltage signals for controlling the printhead 21, such as the print data signals SI4 to SI6, the abnormality signal XHOT, and the ground signal GND, and a contact group for supplying the ground signal GND to the printhead 21.

When the second cable 19b including the fifth wiring group 85 configured as described above is attached to the second connector 360 via the fifth wiring contact group 95, the terminals 196b-7 to 196b-23 of the second cable 19b are electrically connected to the terminals 363-7 to 363-23 of the second connector 360 via the contacts 180b-7 to 180 b-23. Thus, a plurality of signals including the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 transmitted through the wirings 197b-7 to 197b-23 are supplied. That is, in the print head 21, the terminal 363-10 to which the fourth diagnostic signal DIG4 is supplied is an example of a fourth connection point, and the terminal 363-16 to which the fifth diagnostic signal DIG5 is supplied is an example of a fifth connection point. The contact group 98 including the fourth wiring contact group 94 and the fifth wiring contact group 95, which electrically connect the second cable 19b to the print head 21, exemplifies a second contact group.

In addition, in the second cable 19b, the fifth wiring group 85 is disposed between the fourth wiring group 84 and the sixth wiring group 86. Thereby, noise generated outside the second cable 19b is shielded by the fourth wiring group 84 and the sixth wiring group 86, and the possibility of the noise being superimposed on the fifth wiring group 85 is reduced. Likewise, in the contact group 98, the fifth wiring contact group 95 is disposed between the fourth wiring contact group 94 and the sixth wiring contact group 96. Thereby, noise generated in the vicinity of the contact group 98 is shielded by the fourth wiring contact group 94 and the sixth wiring contact group 96, and the possibility that the noise is superimposed on the fifth wiring contact group 95 is reduced. Therefore, the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5, which are transmitted through the fifth wiring group 85 and supplied via the fifth wiring contact group 95, are supplied with high accuracy. Therefore, the possibility that the self-diagnostic function of the print head 21 does not operate normally can be reduced.

Also, in the present embodiment, the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 output from the printhead control circuit 15 are transmitted through the first cable 19a and supplied to the printhead 21 via the contact group 97, and the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 are transmitted through the second cable 19b and supplied via the contact group 98. That is, a part of the plurality of diagnostic signals for performing self-diagnosis of the print head 21 is transmitted by the first cable 19a, and a different part is transmitted by the second cable 19 b. Therefore, even when a connection failure occurs in the first cable 19a or the second cable 19b, or when a contact failure occurs in the contact group 97 or the contact group 98, the connection failure can be detected.

8. action/Effect

As described above, in the head control circuit 15 provided in the liquid ejection device 1 of the present embodiment, the wirings through which the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 for controlling the self-diagnosis of the head 21 are transmitted are collectively provided as the second wiring group 82 in the first cable 19 a. That is, the wirings through which the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 are transmitted are not dispersedly provided in the first cable 19 a. In the liquid ejection device 1 according to the present embodiment, the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 for controlling the self-diagnosis of the print head 21 transmitted through the first cable 19a are collectively provided as the second wire contact group 92. That is, the contact portions that supply the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 to the print head 21 are not dispersedly provided in the contact group 97. Therefore, the possibility of noise being superimposed on the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 is reduced.

In addition, in the second cable 19b, wirings that transmit the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 for controlling self-diagnosis of the print head 21 are collectively provided as a fifth wiring group 85. That is, the wirings for transmitting the fourth and fifth diagnostic signals DIG4 and DIG5 are not provided in the second cable 19b in a dispersed manner. Likewise, the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 for controlling self-diagnosis of the print head 21 transmitted by the second cable 19b are collectively provided as the fifth wiring contact group 95. That is, the contact portions to which the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 are supplied are not provided in a dispersed manner in the contact group 98. Therefore, the possibility of noise being superimposed on the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 is reduced.

As described above, even in the case where there is a possibility that noise is superimposed on the first cable 19a and the second cable 19b, respectively, which transmit the diagnostic signals, the noise can be dealt with, and therefore the print head control circuit 15 can transmit the first diagnostic signal DIG1, the second diagnostic signal DIG2, the third diagnostic signal DIG3, the fourth diagnostic signal DIG4, and the fifth diagnostic signal DIG5 with high accuracy. Therefore, the possibility that the self-diagnostic function of the print head 21 does not operate normally can be reduced.

In the head control circuit 15 provided in the liquid discharge apparatus 1 according to the present embodiment, the second wiring group 82 including wirings for transmitting the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3 is provided between the first wiring group 81 and the third wiring group 83 including a plurality of wirings for transmitting the drive signals COMA and COMB. Similarly, in the liquid ejection device 1, the second wiring contact group 92, which electrically contacts the print head 21, includes the second wiring group 82 including the wirings for transmitting the first diagnostic signal DIG1, the second diagnostic signal DIG2, and the third diagnostic signal DIG3, and is provided between the first wiring group 81 including the wirings for transmitting the drive signals COMA and COMB and the first wiring contact group 91 which electrically contacts the print head 21, and the third wiring group 83 including the wirings for transmitting the drive signals COMA and COMB and the third wiring contact group 93 which electrically contacts the print head 21. This can reduce the possibility of superimposing interference noise on the second wiring group 82.

In addition, the fifth wiring group 85 including wirings which transmit the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 is provided between the fourth wiring group 84 including a plurality of wirings which transmit a plurality of driving signals COM and the sixth wiring group 86. Likewise, a fifth wiring contact group 95, in which the fifth wiring group 85 including wirings transmitting the fourth diagnostic signal DIG4 and the fifth diagnostic signal DIG5 is electrically contacted to the print head 21, is provided between the fourth wiring group 84 including a plurality of wirings transmitting the plurality of drive signals COM and the fourth wiring contact group 94 electrically contacted to the print head 21, and the sixth wiring group 86 including a plurality of wirings transmitting the plurality of drive signals COM and the sixth wiring contact group 96 electrically contacted to the print head 21. This can reduce the possibility of superimposing interference noise on the fifth wiring group 85.

As described above, since the possibility of the interference noise being superimposed on the second wiring group 82 transmitting the first, second, and third diagnostic signals DIG1, DIG2, and DIG3 and the fifth wiring group 85 transmitting the fourth and fifth diagnostic signals DIG4 and DIG5 can be reduced, and the possibility of the interference noise being superimposed on the second wiring contact group 92 supplying the first, second, and third diagnostic signals DIG1, DIG2, and DIG3 and the fifth wiring contact group 95 supplying the fourth and fifth diagnostic signals DIG4 and DIG5 to the printhead 21 can be reduced, the first, second, third, fourth, and fifth diagnostic signals DIG1, DIG2, DIG3, DIG4, and DIG5 can be transmitted with high accuracy. Therefore, the possibility that the self-diagnostic function of the print head 21 does not operate normally can be reduced.

Claims

1. A print head control circuit that controls an operation of a print head having a function of performing self-diagnosis based on a diagnosis signal input from a first connection point, a second connection point, a third connection point, a fourth connection point, and a fifth connection point, the print head control circuit comprising:

a third connector to which the first cable is mounted;

a fourth connector to which the second cable is mounted;

2. The printhead control circuit of claim 1,

3. The printhead control circuit according to claim 1 or 2,

4. The printhead control circuit according to claim 1 or 2,

5. The printhead control circuit according to claim 1 or 2,

6. The printhead control circuit of claim 5,

the print head includes a nozzle that ejects black liquid,

7. The printhead control circuit according to claim 1 or 2,

8. The printhead control circuit according to claim 1 or 2,

9. The printhead control circuit according to claim 1 or 2,

10. The printhead control circuit according to claim 1 or 2,

11. The printhead control circuit according to claim 1 or 2,

12. The printhead control circuit according to claim 1 or 2,

13. A liquid ejecting apparatus includes:

a print head having a function of self-diagnosing based on diagnostic signals input from a first connection point, a second connection point, a third connection point, a fourth connection point, and a fifth connection point; and

a printhead control circuit that controls an action of the printhead,

the print head control circuit has:

a third connector to which the first cable is mounted;

a fourth connector to which the second cable is mounted;

14. The liquid ejection device according to claim 13,

15. The liquid ejection device according to claim 13 or 14,

16. The liquid ejection device according to claim 13 or 14,

17. The liquid ejection device according to claim 13 or 14,

18. The liquid ejection device according to claim 17,

the print head includes a nozzle that ejects black liquid,

19. The liquid ejection device according to claim 13 or 14,

20. The liquid ejection device according to claim 13 or 14,

21. The liquid ejection device according to claim 13 or 14,

in the first set of contacts, the first contact set,

22. The liquid ejection device according to claim 13 or 14,

in the second set of contacts, the first set of contacts,

23. The liquid ejection device according to claim 13 or 14,

in the first set of contacts, the first contact set,

24. The liquid ejection device according to claim 13 or 14,

in the second set of contacts, the first set of contacts,