JP2007237422A - Inkjet head - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a compact inkjet head with a nonvolatile memory capable of suppressing the cost. <P>SOLUTION: This inkjet head comprises an inkjet head chip having a nozzle for ejecting ink and an actuator, an actuator drive board connected to the actuator, a flexible circuit board for connecting the actuator drive board to an external device, and the nonvolatile memory mounted on the flexible circuit board. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an inkjet head.

  2. Description of the Related Art Conventionally, ink jet printers that record predetermined images by ejecting ink onto recording media such as paper and plastic thin plates have been proposed and put into practical use. The ink jet printer includes an ink jet head (hereinafter sometimes referred to as a head) having nozzles (ink discharge ports), and ink is directed from the nozzles toward the recording medium while moving the ink jet head in a predetermined direction. By discharging, a predetermined image is recorded on the recording medium.

  A technique for mounting a non-volatile memory in an ink jet printer is well known. For example, it is mounted in an ink pack to manage the remaining amount of ink (see, for example, Patent Document 6), or mounted on a head to store individual characteristics of the head. (For example, refer to Patent Documents 1 to 5 and 7) or a technique for storing the number of times the head has been operated (for example, refer to Patent Document 5).

However, none of the documents describes how to arrange the nonvolatile memory on the head, and these are mounted on a rigid substrate (see, for example, Patent Documents 3 and 7).
JP-A-5-169675 JP-A-8-174865 JP 2001-47630 A JP 2002-79666 A JP 2004-50428 A JP 2004-106221 A JP 2005-205886 A

  However, in the above prior art, when the nonvolatile memory is arranged in the inkjet head, the rigid substrate of the inkjet head chip (hereinafter sometimes referred to as the head chip) is provided with the nonvolatile memory. It was inefficient.

  In addition, there are inkjet heads that have a configuration with a non-volatile memory and those that do not have a non-volatile memory, but a configuration that does not have a non-volatile memory when the rigid substrate of the head chip has a non-volatile memory. Therefore, it is possible to manufacture a head chip having a nonvolatile memory on the rigid substrate of the head chip and a head chip having no nonvolatile memory in a common manufacturing process. Difficult to separate manufacturing processes. As a result, the cost increases.

  Accordingly, an object of the present invention is to provide an inkjet head with a non-volatile memory that is compact and can be reduced in cost.

The above object of the present invention is achieved by the following configurations.
1.
An inkjet head chip having a nozzle for discharging ink and an actuator;
An actuator drive board connected to the actuator;
A flexible wiring board for connecting the actuator drive board and the outside;
A non-volatile memory mounted on the flexible wiring board;
An ink jet head comprising:
2.
2. The flexible wiring board according to claim 1, wherein at least one of a signal wiring connecting the actuator driving substrate and the outside and a signal wiring connecting the nonvolatile memory and the outside overlap. Inkjet head.
3.
Two sets of the actuator drive boards are provided, and the flexible wiring board has one input terminal and two output terminals, and one output terminal is connected to each of the two sets of actuator drive boards. The inkjet head according to 1 or 2, wherein
4).
The inkjet head according to any one of 1 to 3, wherein an individual number of the inkjet head is stored in the nonvolatile memory.
5).
The inkjet head according to any one of claims 1 to 4, wherein the nonvolatile memory stores shipping inspection data including injection inspection data of the inkjet head.

  ADVANTAGE OF THE INVENTION According to this invention, the inkjet head with a non-volatile memory which can be compact and can suppress cost can be provided.

  That is, since the non-volatile memory is mounted on a flexible wiring board that connects the actuator drive substrate and the outside, the flexible wiring board can be folded and stored in a space, so that the inkjet head can be made compact.

  In addition, since the non-volatile memory is not provided in the head chip, there is a difference between the head chip of the ink jet head having the non-volatile memory and the head chip of the ink jet head having the non-volatile memory. Therefore, both head chips can be manufactured with almost the same members and manufacturing steps, and the cost can be reduced.

The present embodiment will be described below with reference to the drawings. The following is one embodiment of the present invention and does not limit the present invention.
<Inkjet printer configuration>
First, the overall configuration of the ink jet printer according to the present embodiment will be described with reference to FIG. FIG. 1 is an overall configuration diagram of an inkjet printer.

  The ink jet printer 1 ejects ink onto a recording medium P and records an image on the recording medium P. The ink jet printer 1 includes a transport unit (not shown), and the transport unit transports the recording medium P in the sub-scanning direction orthogonal to the main scanning direction A while passing through the recording area C in FIG. ing.

  Above the recording area C, a carriage rail 2 extending along the main scanning direction A is arranged. A carriage 3 guided by the carriage rail 2 is movably provided on the carriage rail 2. Yes.

  The carriage 3 is mounted with an inkjet head 4 that ejects ink onto the recording medium P, and moves in the direction of arrow A from the home position area B to the maintenance area D along the carriage rail 2.

  In the ink jet printer 1 according to the present embodiment, a total of four ink jet heads 4 are arranged in the carriage 3 so that four colors of ink of black (K), yellow (Y), magenta (M), and cyan (C) can be ejected. Is installed. In the present embodiment, two inkjet heads 4, 4 are arranged in a line in the front-rear direction, and the other two inkjet heads 4 are arranged on both sides of the center of the inkjet heads 4, 4 aligned in the front-rear direction. , 4 are arranged.

  Each of these inkjet heads 4 is connected to an ink tank 5 for storing black, yellow, magenta, and cyan inks via an ink supply pipe 6. That is, the ink in the ink tank 5 is supplied to each inkjet head 4 by the ink supply pipe 6.

  In the maintenance area D, a maintenance unit 7 that performs maintenance on the inkjet head 4 is provided. The maintenance unit 7 includes a plurality of suction caps 8 for covering the discharge surface of the inkjet head 4 and sucking ink in the nozzles, a cleaning blade 9 for wiping off ink adhering to the discharge surface, and the inkjet head 4. An ink receiver 10 for receiving the ink ejected idle, a suction pump 11 and a waste ink tank 12 are provided.

  The suction cap 8 communicates with the waste ink tank 12 via the suction pump 11 and is raised during the maintenance operation so as to cover the ejection surface of the inkjet head 4. Four suction caps 8, 8,... Are arranged so as to correspond to the respective ink-jet heads 4 so as to cover the ejection surfaces of all the ink-jet heads 4 when raised as described above.

  The suction pump 11 includes a cylinder pump and a tube pump. The suction pump 8 operates in a state where the suction cap 8 covers the discharge surface, thereby sucking ink in the inkjet head 4 from the nozzle together with foreign matter. It is designed to generate power.

  In the home position area B, a moisturizing unit 13 for moisturizing the inkjet head 4 is provided. The moisture retention unit 13 is provided with four moisture retention caps 14 that retain the ink of the inkjet head 4 by covering the ejection surface when the inkjet head 4 is in a standby state. These four moisturizing caps 14, 14,... Are arranged corresponding to the arrangement of the inkjet heads 4 so as to simultaneously cover the ejection surfaces of the four inkjet heads 4.

  The control unit is configured to include a CPU (Central Processing Unit) and a memory, and controls each component of the inkjet printer 1. The memory stores image data to be formed on the recording medium P and a program for controlling each component of the inkjet printer 1, and controls each component based on the image data and program in the memory. A signal is transmitted.

In addition, the control unit is connected to an input terminal 61 of the head described later by a flexible wiring board (not shown).
<Configuration of inkjet head>
Next, the inkjet head 4 will be described with reference to FIGS.

  FIG. 2 is an exploded perspective view of the inkjet head 4 of the present embodiment, and FIG. 3 is a side sectional view showing a schematic configuration of the inkjet head 4. In FIG. 2, the flexible wiring board 60 and the EEPROM 100 are omitted.

  The inkjet head 4 of the present embodiment is provided with an inkjet head chip (hereinafter referred to as “head chip”) 41 that ejects ink. The head chip 41 has a long outer shape, and a large number of nozzles 42 are arranged in two rows on one end surface (discharge surface) thereof. As shown in FIG. 3, ink supply ports 43 are provided on both side surfaces of the head chip 41, and the ink supply ports 43, the nozzles 42, Has become continuous. A part of the ink flow path 44 forms a pressure chamber, and the pressure is changed by the action of a piezoelectric element which is an example of an actuator constituting the partition wall of the ink flow path 44 so that ink droplets are ejected from the nozzle 42. It has become.

  Two sets of manifolds 48 that are connected to the ink supply port 43 and supply ink from the outside to the head chip 41 are attached to both sides of the head chip 41. An inlet 481 through which ink flows is provided at one end of the manifold 48. An ink heater 49 that heats the ink inside the manifold 48 is provided on the side of the manifold 48 so as to contact the manifold 48. In this embodiment, the case where the ink heater 49 is in contact with the manifold 48 is illustrated. However, if the ink in the manifold 48 is heated via the manifold 48, the ink heater 49 contacts the manifold 48. You don't have to.

  In this embodiment, an example of a head chip having two rows of nozzles and actuators is shown. However, the present invention is not limited to the head chip having such a configuration. For example, a single row of nozzles and actuators may be used. The present invention can also be applied to a head chip having the same.

  In the head chip 41, each of the two sets of actuator drive substrates 46 that transmits a control signal from the control unit to the drive electrode of each piezoelectric element is connected to the drive electrode of each piezoelectric element via the flexible wiring board 47. It is connected to the. Each actuator drive substrate 46 corresponds to each row of nozzles. A heater circuit for supplying power to the ink heater 49 is formed on the actuator drive board 46, and a heating wire (not shown) of the ink heater 49 is connected to the heater circuit via the electric wire 50. Electrically connected. Similarly, the temperature sensor 45 for detecting the temperature is electrically connected to the heater circuit by an electric wire (not shown). The temperature sensor 45 is disposed closer to the head chip 41 than the ink heater 49. Although not shown, the two sets of ink heaters 49 and 49 are connected in series to the heater circuit.

  The two sets of actuator drive boards 46 are each provided with a connector 461, and each of these connectors 461 has an output terminal 62 of a flexible wiring board 60 having one input terminal 61 and two output terminals 62. It is connected. An external power source and a control unit (not shown) are electrically connected to the input terminal 61 of the flexible wiring board 60, and control signals and electric power are supplied to the actuator drive board 46 via the flexible wiring board 60. It has come to be. In this embodiment, a 50-pin connector is used as the input terminal 61.

  An EEPROM 100, which is an example of a nonvolatile memory, is mounted on the flexible wiring board 60 and in the middle of wiring to the actuator drive board 46.

  In this way, the actuator drive board 46 is arranged corresponding to each of the two nozzle rows, and the flexible wiring board 60 having one input terminal 61 and two output terminals 62 is used as one connector to interface with the outside. Have taken. An EEPROM 100 which is an example of a nonvolatile memory is mounted on the flexible wiring board 60, and signals are exchanged between the EEPROM 100 and the outside using the flexible wiring board 60. As the mounting method of the nonvolatile memory, the package IC is connected by lead-free solder, but a bare chip may be flip-chip mounted (COF: Chip On Flexible cable) on the flexible wiring board 60.

  As described above, since the non-volatile memory is not provided in the head chip, the head chip of the ink-jet head having the structure having the non-volatile memory, and the head chip of the ink-jet head having the structure not having the non-volatile memory, Therefore, both head chips can be manufactured with almost the same members and manufacturing processes, and the cost can be reduced.

  Further, since the output terminals 62 of the flexible wiring board 60 are connected to each of the two sets of actuator drive boards 46, power supply and control of the two sets of actuator drive boards 46 and the ink heater 49, and the EEPROM 100, Signal exchange with the outside can be combined into one. The two sets of actuator drive substrates 46 can be the same.

  A manifold 48 and a holding plate 51 for holding the head chip 41 are attached to the lower part of the head chip 41 so that the ejection surface is exposed. At one end of the holding plate 51, an ink receiving portion 52 that holds the inlet 481 of the manifold 48 and allows ink to flow into the inlet 481 is formed.

  As shown in FIG. 2, the inkjet head 4 includes a housing frame 53 to which the components of the inkjet head 4 such as the head chip 41, the manifold 48, the actuator drive substrate 46, and the holding plate 51 are attached and fixed. A cover 54 is provided to cover the housing frame 53. The casing frame 53 is provided with a frame ink flow path 55 that supplies ink by being connected to the ink receiving portion 52 of the holding plate 51, and the ink supply pipe 6 is connected to the frame ink flow path 55. It has come to be. In addition, support beams 56 that support the two sets of actuator drive substrates 46 are provided inside the housing frame 53.

  An opening 57 is provided in the upper part of the cover 54, and the input terminal 61 of the flexible wiring board 60 is exposed to the outside from the opening 57 after the ink jet head 4 is assembled.

  FIG. 4 is a schematic view of another embodiment of a flexible wiring board in which a nonvolatile memory is arranged.

In this embodiment, as shown in FIG. 4A, the EEPROM 100 is mounted on the lateral extension of the flexible wiring board 60. When assembled as an ink jet head, as shown in FIG. 4B, the extension portion of the flexible wiring board 60 can be folded and stored in the internal space, so that the ink jet head can be made compact.
<Configuration of flexible wiring board 60>
FIG. 5 is a conceptual diagram showing a preferred configuration of signal wiring for signal connection between the flexible wiring board 60 and the outside of the control unit, the EEPROM 100, and the two actuator driving boards 46.

  The input terminal 61 of the flexible wiring board 60 is provided with pins 61-1... 61-50 for inputting actuator / heater driving / control signals from outside such as a control unit via a flexible wiring board (not shown). A total of 50 pins) are provided, and each of the signal wirings S-1... S-50 is provided with two sets of pins 62-1. Book). These two sets of output terminals 62 are connected to the connectors 461 of the two sets of actuator boards 46.

  A total of seven of the signal wirings S-1... S-50, S-44 to S-50, are used to branch SS-1 to SS-7 and pin 63- of the EEPROM 100 terminal 63- 1 to 63-7. The pins 63-1 to 63-7 are connected to the terminal 101 of the EEPROM 100.

  As described above, the signal wirings for the two sets of actuator drive boards 46 are composed of 50 signal lines, and 7 of the 50 lines are common signal wirings for the EEPROM 100.

  The common signal wiring for the EEPROM 100 includes a power supply signal line “VDD” and a ground signal line “GND” for supplying power, and a signal line “DATA” for transmitting / receiving a control signal (control data) and the like as will be described later. And a signal line such as a clock signal line “CLK”.

  In writing to the EEPROM 100, the data signals “start code + EEPROM designation information”, “control code”, “address code”, and “data code” are transmitted from the control unit on the main body side to the EEPROM 100 via the signal line DATA. The signals are sent in this order in synchronization with the clock signal CLK. “Start code + designation information” means the start of a series of data signals by the “start code” signal, and the output destination that is the target of this series of data signals by the “EEPROM designation information” signal, That is, the EEPROM 100 is specified. Each of the EEPROM 100 and the head drive board 46 includes an input / output control circuit.

  The “designation information” has a code corresponding to the EEPROM 100 or the head drive board 46, and each input / output control circuit compares the information indicated by this code with its own designation information and matches the information. Only after that, the process of fetching the subsequent data signal is performed, and when they do not match, the process of ignoring the capture of the subsequent data signal is performed.

  In reading, the configuration of the data signal is the same as in the case of the above writing, and the code of “start code + EEPROM designation information” is taken in by the input / output control circuit as in the case of the above writing, and thereafter The data signal is fetched only by the input / output control circuit of the EEPROM 100 whose “EEPROM designation information” matches.

  Even if a data signal is sent in common from the main body side via the common signal line “DATA”, the other party can be specified in the EEPROM 100 by including the above-mentioned EEPROM designation information in the data signal. Processing based on the data signal can be performed only for the specified EEPROM 100.

  In the drive and control of the actuator and heater, as in the above, first, a data signal of “start code + actuator drive board designation information” is sent from the main body side to the input / output control circuit via the signal line DATA. As described above, the actuator drive board 46 is specified by the “actuator drive board designation information”, and the drive signal and the control signal sent thereafter are taken into only the actuator drive board.

  As a result, it is possible to control the actuator and heater drive to the actuator drive board in addition to writing and reading data to and from the EEPROM 100 by the data transmitted via the common data signal line. It is possible to reduce the number of signal lines.

  The “control code” in the present embodiment includes “READ” and “WRITE” codes indicating access to the EEPROM 100, that is, read and write, respectively. In this writing operation, the “WRITE” code follows the “EEPROM designation information” code for specifying the EEPROM 100. The next “address code” indicates the address of the write destination EEPROM 100, and the last “data code” indicates the content to be written.

  In the flexible wiring board 60, it is preferable that at least one of the signal wiring that connects the actuator drive substrate 46 and the outside and the signal wiring that connects the EEPROM 100 and the outside overlap (common). In this example, the input terminal 61 requires 57 pins if they are not overlapped. However, if one is overlapped, the number of pins can be reduced to 56.

As described above, in the flexible wiring board, at least one of the signal wiring that connects the actuator driving substrate and the outside and the signal wiring that connects the nonvolatile memory and the outside is shared and overlapped, so that the nonvolatile memory is used. Even in this case, the number of signal lines to be connected to the outside such as the printer main body can be reduced, and the number of connector pins can be reduced. As a result, it is possible to provide a head and a printer that are inexpensive and simple in configuration without complicating the connection process in order to ensure the reliability of electrical connection.
<Memory map of EEPROM 100>
Next, the EEPROM 100 used in the present embodiment will be described in detail with reference to FIG. FIG. 6 is an explanatory diagram showing an example of the internal data structure (memory map) of the EEPROM 100. The memory uses a total of 8 Kbytes of 8 bit data × 8192.

Information on the head ID number of the inkjet head is stored at addresses 0000h to 000Fh of the EEPROM 100. The head ID number is an individual number of the head in the present invention, and means an identification number such as a head manufacturing number. Here, a head manufacturing serial number or the like is stored as the head ID number. Information on nozzle position accuracy data of the head is stored in addresses 0010h to 001Fh, and information on the pass / fail of shipping inspection including injection inspection and information on the designated drive voltage of the head are stored in addresses 0020h to 002Fh, respectively. Further, information on inspection conditions (temperature, ink used, apparatus, inspection date, etc.) of the shipping inspection including the injection inspection is provided at addresses 0030h to 0FFFh, and information on the injection speed data of the nozzles NO and 1 in the injection inspection is provided at address 1000h. However, information on the injection speed data of the nozzles NO and 2 is stored in the address 1001h, and information on the injection speed data of the nozzles NO and 3 to NO and 512 are stored in the addresses 1002h to 11FFh, respectively. Further, the address 1200h includes information on the injection angle data of the nozzles No. 1 and No. 1 in the injection inspection, the address 1201h includes information on the nozzles No. 2 and the injection angle data of 2, and the addresses 1202h to 13FFh include the nozzles No. 3 and No. 3 , 512 are stored and stored, respectively. The above information is written in a shipping inspection described later. Addresses 1400h to 1FFFh are user use areas after shipment.
<Flow of shipping inspection>
Next, a specific operation flow of the shipment inspection of the inkjet head will be described with reference to the flowchart shown in FIG. In the present embodiment, nozzle position accuracy inspection and injection inspection are performed as a shipping inspection.

First, as a completion inspection, the position of the nozzle relative to the ink jet head mounting reference is measured (S1). As an attachment reference, for example, a positioning portion on the side of the carriage when the head is attached to the carriage can be used as a reference. Further, the positions of the nozzles do not need to be measured for all the nozzles. For example, the nozzle positions may be measured for nozzles that eject ink and are located at both ends of the head in the nozzle row direction. The measured nozzle position accuracy data is written to the EEPROM (S2). An injection inspection is performed (S3). In this example, the injection speed and the injection angle (both in the main scanning direction and the sub-scanning direction) are measured for a total of 512 nozzles in two rows of one row and 256 nozzles. Next, the result of the injection inspection is written in the EEPROM (S4). A determination result is calculated by determining whether or not a predetermined standard is satisfied with respect to the inspection of the nozzle position accuracy and the injection inspection (S5). Determination results and the like (head ID number, pass / fail of inspection, designated drive voltage of head, inspection conditions such as inspection date) are written in the EEPROM (S6). A label printed with the head ID number, inspection pass / fail, designated drive voltage for the head, and inspection date is output (S7). A label is affixed to the head (S8).
<Operation of inkjet printer>
Next, the operation of the ink jet printer 1 of this embodiment will be described.

  When the power of the ink jet printer 1 is turned on, power is supplied to each part of the ink jet printer 1. If power is supplied to the ink heater 49 along with this, the heating wire of the ink heater 49 generates heat, and the ink in the manifold 48 is heated via the manifold 48 to reduce the viscosity.

  Thereafter, when an instruction to start image recording is input, the control unit transmits a control signal based on the image data to the actuator driving substrate 46 and other driving units, and starts image recording. Ink is ejected from the inkjet head 4 onto the recording medium P that is transported to the transporting means. When this ink is ejected, the ink is preheated to reduce the viscosity, so that stable ejection and high image quality are achieved. An image is formed.

  Further, the control unit contacts the EEPROM 100, which is an example of the nonvolatile memory according to the present invention, via the flexible wiring board 60 and the like, and reads and writes predetermined information as necessary. The control unit controls the exchange of signals between the EEPROM 100 and the printer main body.

  Specifically, the control unit makes contact with the EEPROM 100, specifies an address, and reads desired information. For example, by reading the designated drive voltage of the head and driving the head with this voltage, good printing can be performed. Further, since the information on the ejection speed of each nozzle corresponds to the ink ejection amount of each nozzle, it can be used as data called common head shading data for eliminating the density unevenness specific to the head. Further, when a head failure occurs, the manufacturing date and the manufacturing lot can be determined from the individual number.

  Further, desired information is written in the user use area. For example, the control unit counts the total number of driving pulses of the head related to the ejection of ink droplets, writes the data while updating it, and notifies the user of head replacement when a predetermined value is reached.

It is explanatory drawing showing schematic structure of the inkjet printer provided with the inkjet head of this embodiment. It is a disassembled perspective view of the inkjet head of FIG. FIG. 3 is a side sectional view showing a schematic configuration of the ink jet head of FIG. It is the schematic of other embodiment of the flexible wiring board which has arrange | positioned the non-volatile memory. It is a conceptual diagram which shows the preferable structure of the signal wiring in a flexible wiring board. It is explanatory drawing which shows an example of the internal data structure (memory map) of EEPROM. It is a chart of an inkjet head shipment inspection.

Explanation of symbols

4 Inkjet head 41 Inkjet head chip 42 Nozzle 46 Actuator drive substrate 48 Manifold 49 Ink heater

Claims (5)

An inkjet head chip having a nozzle for discharging ink and an actuator;
An actuator drive board connected to the actuator;
A flexible wiring board for connecting the actuator drive board and the outside;
A non-volatile memory mounted on the flexible wiring board;
An ink jet head comprising: 2. The flexible wiring board according to claim 1, wherein at least one of a signal wiring connecting the actuator driving substrate and the outside and a signal wiring connecting the nonvolatile memory and the outside overlap. The inkjet head described in 1. Two sets of the actuator drive boards are provided, and the flexible wiring board has one input terminal and two output terminals, and one output terminal is connected to each of the two sets of actuator drive boards. The ink jet head according to claim 1, wherein the ink jet head is provided. The inkjet head according to claim 1, wherein an individual number of the inkjet head is stored in the nonvolatile memory. 5. The inkjet head according to claim 1, wherein shipping inspection data including injection inspection data of the inkjet head is stored in the nonvolatile memory.

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