JP2017035836A - Recording device and control method for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently utilize a nonvolatile memory of an ink cartridge for management of a printer.SOLUTION: An ink jet printer 10 comprises: a printer side communication control section 44 writing data into a nonvolatile memory 14 of an ink cartridge 11; and a printer side input section 41 receiving operation instructing to turn off the power supply. A printer side control section 40 of the ink jet printer 10 executes writing processing for writing operation information including information related to operation of the ink jet printer 10 into the nonvolatile memory 14 when the operation instructing to turn off the power supply is received. The printer side control section 40 executes a stop sequence after executing the writing processing.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a recording apparatus and a control method for the recording apparatus.

  2. Description of the Related Art Conventionally, printers have a configuration in which data such as ink consumption is written in a non-volatile memory mounted on an ink cartridge (see, for example, Patent Document 1). Since the printer described in Patent Document 1 writes ink consumption data for the purpose of billing, the data to be written to the nonvolatile memory is incremented each time ink is consumed.

JP 2012-206426 A

In general, the upper limit of the number of rewrites that can guarantee the operation is determined for the nonvolatile memory. For this reason, in the configuration described in Patent Document 1, when data rewriting frequently occurs, the number of times of rewriting of the nonvolatile memory may exceed the upper limit. For example, if data that is frequently updated with regard to operations, such as the number of ink shots, the number of print lines, and the number of occurrences of errors, is written in the nonvolatile memory of the ink cartridge, the upper limit of the number of rewrites may be reached immediately .
SUMMARY An advantage of some aspects of the invention is that a nonvolatile memory of an ink cartridge is efficiently used for printer management.

In order to achieve the above object, a recording apparatus of the present invention is a recording apparatus configured to be able to mount an ink cartridge having a nonvolatile memory, and a writing unit for writing data into the nonvolatile memory of the ink cartridge; An operation unit that accepts (detects) an operation to turn off the power, and operation information including information about the operation of the recording device when the operation to turn off the power is accepted by the operation unit. And a control unit that executes a writing process for writing to the nonvolatile memory and then executes a stop sequence.
According to the present invention, the nonvolatile memory of the ink cartridge can be used for the purpose of recording the operation information of the recording apparatus and managing the recording apparatus. In addition, since writing to the nonvolatile memory is performed when an operation to turn off the power is accepted instead of incrementing the number of times, frequent writing to the nonvolatile memory can be prevented. Thereby, the non-volatile memory of the ink cartridge can be efficiently used for managing the printer.

In the recording apparatus, the operation information may be any of an error that occurs during the operation of the recording apparatus, a log of the operation of the recording apparatus, and a set value that is set for the operation of the recording apparatus. It is characterized by including.
According to the present invention, the operation of the recording apparatus can be managed in detail using the nonvolatile memory of the ink cartridge.

According to the present invention, in the recording apparatus, an operation unit including a recording head that performs recording on a recording medium with at least ink supplied from the ink cartridge, a counter that performs a count related to an operation of the operation unit, A volatile memory for storing a count value, and the control unit writes data including the count value stored in the volatile memory in the nonvolatile memory in the writing unit in the writing process. It is characterized by.
According to the present invention, the count value related to the operation of the operation unit is once written in the work memory, which is a volatile memory that can be rewritten more times than the nonvolatile memory. Can be written to non-volatile memory.

The recording apparatus may further include a storage unit that stores the set value and a detection unit that detects the mounting of the ink cartridge, and the control unit detects the mounting of the ink cartridge. In this case, the data including the set value recorded in the nonvolatile memory of the ink cartridge is read out and written into the storage unit.
According to the present invention, data recorded in the nonvolatile memory of the ink cartridge can be taken into the recording device.

According to the present invention, in the recording apparatus, a power supply circuit that supplies power to the recording apparatus, a transistor that connects the power supply circuit and the operation unit of the recording apparatus and switches on and off under the control of the control unit The control unit switches off the transistor after executing the writing process and the stop sequence when an operation to turn off the power is received by the operation unit.
According to the present invention, when an operation to turn off the power is accepted, a series of operations for turning off the power of the recording apparatus after writing to the nonvolatile memory can be easily performed.

In order to achieve the above object, the present invention provides a control method of a recording apparatus configured to be able to mount an ink cartridge having a non-volatile memory, wherein the recording is performed when an operation to turn off the power is received. A write process for writing operation information including information related to the operation of the apparatus to the nonvolatile memory is executed, and then a stop sequence is executed.
According to the present invention, the nonvolatile memory of the ink cartridge can be used for the purpose of recording the operation information of the recording apparatus and managing the recording apparatus. Further, since writing to the nonvolatile memory is performed when an operation to turn off the power is accepted, frequent writing to the nonvolatile memory can be prevented. Thereby, the non-volatile memory of the ink cartridge can be efficiently used for managing the printer.

  When the above-described recording apparatus is controlled by a computer, the above-described recording apparatus may be configured in the form of a program for realizing the function or a recording medium on which the program is recorded so as to be readable by the computer. Is possible. Further, the above-described recording apparatus control method can be configured as a program to be executed by the recording apparatus, and can also be configured in the form of a recording medium or the like in which the program is recorded so as to be readable by the computer. . Recording media include flexible disk, HDD (Hard Disk Drive), CD ROM (Compact Disk Read Only Memory), DVD (Digital Versatile Disk), Bluray (registered trademark) Disc, magneto-optical disk, nonvolatile memory card In addition, the computer can read the internal storage device (RAM (Random Access Memory), ROM (Read Only Memory), etc.) and external storage device (USB (Universal Serial Bus) memory, etc.) of the image display device. Various media can be used.

The figure which shows the structure of the information processing system which concerns on embodiment. The figure which shows schematic structure of an inkjet printer. FIG. 2 is a block diagram illustrating a functional configuration of the inkjet printer. The block diagram which shows the functional structure of information processing apparatus. The flowchart which shows operation | movement of an inkjet printer. The flowchart which shows operation | movement of an inkjet printer. The figure which shows the specific structural example of an inkjet printer.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram schematically illustrating a configuration of an information processing system 1 according to the embodiment.
When an error or the like occurs in the inkjet printer 10 (recording apparatus) used by the user U, the information processing system 1 determines the cause of the error or a recovery method at an analysis base provided by the manufacturer of the inkjet printer 10 or the like. It is a system to analyze.
The user U is a subject who purchases and uses the inkjet printer 10. The user U may be an individual or a corporation. Further, the ink jet printer 10 may be used personally in a private house or the like, or may be shared and used in a company or the like. The inkjet printer 10 may be configured to be able to perform communication via a communication network such as the Internet, but does not execute a communication function in the operation of the information processing system 1 described in the present embodiment. Accordingly, the inkjet printer 10 does not execute communication for a range exceeding the range managed by the user U within the range described in the present embodiment.

The outline of the information processing system 1 will be described along the cycle of the ink cartridge 11 in the information processing system 1.
The ink jet printer 10 is configured so that an ink cartridge 11 can be attached and detached, and performs printing by consuming ink stored in the ink cartridge 11. When the ink in the ink cartridge 11 is used up, the user U replaces the ink cartridge 11. The ink cartridge 11 is recycled by the manufacturer of the ink jet printer 10, but can be said to be a consumable if limited to the environment in which the ink jet printer 10 is used.
The ink cartridge 11 has an IC chip 12 mounted thereon. The IC chip 12 has a nonvolatile memory 14 (FIG. 3) capable of recording data as will be described later. The ink jet printer 10 can write and read information with respect to the IC chip 12.

  When an error occurs during a printing operation or the like, the inkjet printer 10 writes error-related information including information on the error content and operation parameters in the inkjet printer 10 when the error occurs in the IC chip 12 (step S1). ).

The ink cartridge 11 on which writing has been performed is removable from the ink jet printer 10. For example, a business operator who performs maintenance of the inkjet printer 10 dispatches a service person to the user U side. This service person removes the ink cartridge 11 from the ink jet printer 10 (step S2), collects it, sends it to the analysis base, or brings it in (step S3).
Further, when an error occurs, the user U may remove the ink cartridge 11 from the ink jet printer 10 by himself / herself and send it to the analysis base in accordance with instructions from the maintenance company or the person in charge of the analysis base (step S3).

  At the analysis base, the information processing device 16 reads information on the error from the IC chip 12 (step S4). Thereby, the person in charge at the analysis base can obtain error-related information regarding the error that has occurred in the inkjet printer 10. The person in charge at the analysis base can investigate the cause of the error that has occurred in the inkjet printer 10 and the countermeasures by analyzing the error-related information.

  After obtaining the error related information at the analysis base, the ink cartridge 11 may be discarded or recycled. Further, there is a method of using the ink cartridge 11 again in the ink jet printer 10 after the information processing device 16 reads the error related information from the IC chip 12. For example, it may be possible to deal with errors and prevent recurrence by changing the settings of the inkjet printer 10. In this case, the information processing device 16 writes various setting values (parameters) relating to the settings of the ink jet printer 10 to the IC chip 12, and the ink cartridge 11 after writing is removed from the information processing device 16 (step S5). The ink cartridge 11 is sent to the user U side or brought in by a service person (step S6) and mounted on the ink jet printer 10. Then, in the inkjet printer 10, the setting value is read from the IC chip 12 and the inkjet printer 10 is set (step S7).

Further, the IC chip 12 may be used not only for storing error-related information but also as a storage medium for storing setting values of the inkjet printer 10.
In the ink jet printer 10, adjustment of ink density and specification of a recording medium such as paper to be used can be set in many cases, but these settings may be initialized to cope with an error. In this case, it is necessary to reset by operating the inkjet printer 10. Before the inkjet printer 10 is initialized, the set value can be backed up by writing the set value of the inkjet printer 10 into the IC chip 12. After the initialization of the ink jet printer 10, the ink cartridge 11 is attached to the ink jet printer 10, the setting value is read from the IC chip 12 and set in the ink jet printer 10, and the setting value can be restored by the ink jet printer 10.

  The movement of the ink cartridge 11 between the user U and the analysis base may be carried by a service person or entrusted to a delivery company for transportation. Of course, it is also possible for a service person to perform maintenance of the ink jet printer 10 to check the set value, the content of the error, and the like. However, by storing error-related information in the IC chip 12, the information content and the number of pieces of information to be collected are more accurate than when error-related information is transmitted verbally or manually input or recorded. Can be secured.

Next, the ink jet printer 10 and the information processing apparatus 16 will be described.
FIG. 2 is a diagram illustrating a schematic configuration of the inkjet printer 10.
The ink jet printer 10 includes a carriage 20 on which an ink jet head 26 (recording head) is mounted. The carriage 20 performs reciprocating scanning in the main scanning direction indicated by reference numeral Y1 in FIG. The carriage 20 carries the ink cartridge 11. In the present embodiment, the inkjet printer 10 is a printer that uses four-color ink, and the four-color integrated ink cartridge 11 is used. In this case, the ink cartridge 11 constitutes a cyan cartridge 21, a black cartridge 22, a yellow cartridge 23, and a magenta cartridge 24. The cyan cartridge 21 stores cyan (C) ink. The black cartridge 22 stores black (K) ink, and the yellow cartridge 23 stores yellow (Y) ink. The magenta cartridge 24 stores magenta (M) ink.

  An inkjet head 26 (recording head) that ejects ink toward a recording medium has a nozzle hole that ejects ink as fine ink particles on the tip surface. The inkjet head 26 pushes out ink supplied from the ink cartridge 11 toward the recording medium by an actuator (not shown) configured using a piezoelectric element, and selectively ejects fine ink particles from the nozzle holes.

  The nozzle holes form four nozzle rows on the nozzle forming surface 27 that forms the lower surface of the inkjet head 26. In the example of FIG. 2, there are a cyan nozzle row 21a, a black nozzle row 22a, a yellow nozzle row 23a, and a magenta nozzle row 24a. The cyan nozzle row 21 a ejects ink from the cyan cartridge 21, and the black nozzle row 22 a ejects ink from the black cartridge 22. The yellow nozzle row 23 a ejects ink from the yellow cartridge 23, and the magenta nozzle row 24 a ejects ink from the magenta cartridge 24.

  A target on which the inkjet printer 10 performs printing by discharging ink is a sheet-like print medium. Examples of the printing medium include cut sheets, continuous sheets, and roll sheets, and are made of paper or synthetic resin. Moreover, you may have a coating in the printing surface to which an ink adheres. The ink jet printer 10 performs a transport operation for transporting the print medium in the sub-scanning direction orthogonal to the main scanning direction Y1. Further, the inkjet printer 10 performs a printing operation for forming an image by ejecting ink with the inkjet head 26 on the transported print medium.

One end of the scanning range of the carriage 20 is a home position HP. A capping device 29 is arranged at the home position HP so as to be located immediately below the inkjet head 26.
The capping device 29 includes a box-shaped cap body 30 whose upper surface is open. The cap body 30 includes a frame body 31 made of an elastic member such as rubber, and a recording head storage portion 32 is formed in a space surrounded by the frame body 31. The cap body 30 is configured to be able to be raised and lowered according to the operation of a motor driven by the control of the printer-side control unit 40. When the cap body 30 is raised, the nozzle forming surface 27 of the inkjet head 26 located at the home position HP is stored in the recording head storage portion 32.

A discharge hole 34 penetrating the lower surface 33 is formed on the lower surface 33 of the cap body 30, and the discharge hole 34 is connected to the waste ink tank 36 by a tube 35. The tube 35 is provided with a pump 37 that sends waste ink from the cap body 30 to the waste ink tank 36.
The capping device 29 described above, the tube 35, the pump 37, and the waste ink tank 36 cooperate to function as a waste ink collection unit. The waste ink collection unit may be included in the operation unit.
The inkjet printer 10 according to the present embodiment can execute a cleaning operation and a flushing operation using the capping device 29.

  The cleaning operation is an operation for forcibly sucking ink remaining in the nozzles of the inkjet head 26. In the cleaning operation, the inkjet head 26 is positioned at the home position HP, and the nozzle forming surface 27 is stored in the recording head storage portion 32. Here, a negative pressure is applied to the nozzle forming surface 27 by the suction force of the pump 37, and the ink remaining on the nozzles is discharged by this negative pressure. The flushing operation is an operation of ejecting ink from the nozzle holes by an actuator (not shown) provided in the inkjet head 26 at the home position HP.

FIG. 3 is a block diagram illustrating a functional configuration of the inkjet printer 10.
The inkjet printer 10 includes a printer side control unit 40, a printer side input unit 41, a printer side display unit 42, a printer side storage unit 43, and a printer side communication control unit 44.

The printer-side control unit 40 (control unit) includes a CPU, a ROM that stores a basic control program in a nonvolatile manner in a computer-readable manner, a RAM that temporarily stores programs and data, and other peripheral circuits. Is provided. Printer-side controller 40 executes a control program by CPU, and controls the ink jet printer 10.
The printer-side control unit 40 controls the carriage drive motor 38 that scans the carriage 20 and the inkjet head 26 to print characters and images on a print medium. Further, the printer-side control unit 40 controls the pump drive motor 39 to perform the above-described cleaning operation and the removal of the waste ink accumulated in the capping device 29.

The printer-side input unit 41 (operation unit) is an operation unit having various switches that receive operations of the user U and other users. The printer side input unit 41 detects an operation on the switch, and outputs an operation signal corresponding to the detected operation to the printer side control unit 40.
The printer-side display unit 42 includes a printer-side display panel 42 a made up of a liquid crystal display panel, an organic EL panel, or the like, and displays various information according to the control of the printer-side control unit 40.
The printer-side storage unit 43 (storage unit) includes a nonvolatile storage device such as an EEPROM or a hard disk, and stores various data in a rewritable manner.

The printer-side control unit 40 includes an ink consumption amount detection unit 50, an error detection unit 53, and an information writing unit 58.
The ink consumption detection unit 50 (counter) counts the number of shots in which ink is ejected by the inkjet head 26. The count value of the ink consumption amount detection unit 50 is stored in the memory 45 as cumulative shot number data 45b.
The error detection unit 53 detects an error that occurs in the inkjet printer 10 and generates an error log including information such as the content of the error and the number of occurrences. The information writing unit 58 controls the printer-side communication control unit 44 to be described later, and executes writing and / or reading of data with respect to the nonvolatile memory 14 included in the ink cartridge 11.

  The printer-side control unit 40 has a memory 45 (volatile memory). The memory 45 is a work memory in which the printer-side control unit 40 can temporarily store programs and data, and includes a volatile storage device such as a RAM. The memory 45 stores, for example, a first error log 45a described later. Since the memory 45 is a volatile storage area, the stored data and programs are lost when the power of the inkjet printer 10 is turned off. In addition, the memory 45 can be rewritten more times than a non-volatile semiconductor memory element.

The ink cartridge 11 includes an IC chip 12 including a chip-side communication control unit 46, a chip-side control unit 47, a memory interface unit 48 (memory I / F), and a nonvolatile memory 14.
The IC chip 12 may be a contact type or a non-contact type, and the ink cartridge 11 of the present embodiment has the non-contact type IC chip 12 mounted thereon.

The printer-side communication control unit 44 (writing unit) transmits a radio signal to the IC chip 12 in a state where the ink cartridge 11 is mounted on the inkjet printer 10 and is positioned at the home position HP. In the IC chip 12, induced power is generated by a radio signal transmitted from the printer-side communication control unit 44, and the IC chip 12 is operated by this induced power.
The printer-side communication control unit 44 (writing unit) can detect the mounting of the ink cartridge 11 when communication with the IC chip 12 of the ink cartridge 11 is enabled. Moreover, you may detect by providing the sensor which detects mounting | wearing. In this case, the printer-side communication control unit 44 functions as a detection unit. Further, a sensor that mechanically or optically detects the presence or absence of the ink cartridge 11 may be provided on the carriage 20 or the like. In this case, the detection state of this sensor may be acquired by the printer-side communication control unit 44, the printer-side control unit 40, or the ink consumption detection unit 50, and the mounting of the ink cartridge 11 may be detected. In this case, the printer-side communication control unit 44, the printer-side control unit 40, or the ink consumption amount detection unit 50 functions as a detection unit.
The IC chip 12 includes a chip side communication control unit 46, a chip side control unit 47, a memory interface unit 48, and the nonvolatile memory 14.

The printer-side communication control unit 44 performs wireless communication with the IC chip 12.
The carrier wave of the wireless signal transmitted by the printer-side communication control unit 44 generates induced power in the IC chip 12. In addition, the printer-side communication control unit 44 transmits data to be written to the nonvolatile memory 14 by the information writing unit 58 to the IC chip 12 and causes the writing to the nonvolatile memory 14 to be executed. Specifically, the printer-side communication control unit 44 encodes data output from the information writing unit 58, modulates the encoded transmission data, and outputs the encoded transmission data to the chip-side communication control unit 46 via the antenna. . Further, the printer-side communication control unit 44 receives the radio wave transmitted by the IC chip 12 by the antenna, demodulates and decodes the received radio signal, and outputs it to the information writing unit 58.

In the IC chip 12, the chip-side control unit 47 controls each part of the IC chip 12. The chip side communication control unit 46 transmits and receives wireless signals to and from the printer side communication control unit 44 provided in the inkjet printer 10. Chip communication control unit 46 outputs a radio signal received in the chip-side control unit 47. Further, the chip side communication control unit 46 wirelessly transmits the data output from the chip side control unit 47 to the printer side communication control unit 44.
Further, the power induced in the antenna of the chip-side communication control unit 46 is supplied to each part of the IC chip 12 by the carrier wave of the radio signal transmitted by the printer-side communication control unit 44.

The chip-side control unit 47 performs a process of writing the data received by the chip-side communication control unit 46 to the nonvolatile memory 14 using the memory interface unit 48. This data may include a command instructing writing to the nonvolatile memory 14 in addition to the data body to be written to the nonvolatile memory 14.
The chip-side control unit 47 reads data from the nonvolatile memory 14 by the memory interface unit 48 in accordance with a read request command included in the data received by the chip-side communication control unit 46. The chip side control unit 47 outputs the data read from the nonvolatile memory 14 to the chip side communication control unit 46 and causes the printer side communication control unit 44 to transmit the data.

The memory interface unit 48 is an interface connected to the non-volatile memory 14, and drives the non-volatile memory 14 under the control of the chip side control unit 47 to write and read data.
The nonvolatile memory 14 is composed of a semiconductor memory element such as a flash memory, and stores data in a nonvolatile manner.

Various data stored in the inkjet printer 10 will be described.
The printer-side storage unit 43 included in the inkjet printer 10 stores an adjustment value 43a, a first error log 43b, and a second error log 43c.
The adjustment value 43a is a parameter set with respect to the operation of the ink jet printer 10, and includes, for example, an adjustment value for adjusting the amount of ink ejected by the ink jet head 26, a setting value for the specification of the print medium, and the like.
The first error log 43b and the second error log 43c are data relating to errors detected by the error detection unit 53.

The error detection unit 53 detects an error that occurs while the inkjet printer 10 is powered on. The error detection unit 53 detects the error by dividing it into a first error and a second error in accordance with a prior setting.
Errors that occur relatively frequently in the inkjet printer 10 are classified as first errors. In the present embodiment, the first error mainly includes an error that occurs with respect to software processing. Specifically, it includes a buffer overflow of a print buffer memory (not shown) for developing an image to be printed by the printer-side control unit 40, and a memory overflow that occurs when the printer-side control unit 40 executes a program. The first error may include a variable error during program execution, a detection value error of a sensor (not shown), and the like.

  The second error is classified as an error having a lower occurrence frequency than the first error in the inkjet printer 10. In the present embodiment, the second error mainly includes an error related to hardware. Specifically, it includes an abnormality in the position of the carriage 20, an operation error of the inkjet head 26, the carriage drive motor 38, and the pump drive motor 39. Further, the ink jet printer 10 may include an error relating to a cover open error in which the cover of the ink cartridge 11 or the storage unit that stores the print medium is opened during printing, or an error related to a conveyance error (jam or the like) of the print medium.

  When the error set as the first error occurs, the error detection unit 53 stores data indicating the content of the error in the memory 45 as the first error log 45a. The printer-side control unit 40 may have an RTC (Real Time Clock) and include the date and time when the error occurred in the data of the first error log 45a. The first error log 45a is added and updated by the error detection unit 53 every time a first error occurs. The first error log 45a can be cleared under the control of the printer-side control unit 40, and data is accumulated every time an error occurs while the first error log 45a is not cleared.

  When the error set as the second error occurs, the error detection unit 53 causes the printer-side storage unit 43 to store data indicating the content of the error as the second error log 43c. The printer-side control unit 40 may have an RTC (Real Time Clock) and include the date and time when the error occurred in the data of the second error log 43c. The second error log 43c is added and updated by the error detection unit 53 every time a second error occurs. The second error log 43c can be cleared under the control of the printer-side control unit 40, and accumulates data every time an error occurs while the second error log 43c is not cleared.

Further, the printer-side control unit 40 copies the first error log 45 a stored in the memory 45 to the printer-side storage unit 43 when the power of the inkjet printer 10 is turned off according to the operation on the printer-side input unit 41. . This data is stored in the printer-side storage unit 43 as the first error log 43b. Thereby, the number of accesses and the number of rewrites to the printer-side storage unit 43 can be suppressed. Since the occurrence frequency of the first error is high, if the rewriting of the printer-side storage unit 43 is suppressed every time the first error occurs, the life of the printer-side storage unit 43 can be expected to be extended.
Further, since the occurrence frequency of the second error is lower than that of the first error, it is reasonable to record the second error log 43c directly in the printer-side storage unit 43.

The first error log 45a and the second error log 43c may include count values related to the operation status and operation history of the inkjet printer 10 when an error occurs. This count value is called a so-called maintenance counter. For example, the cumulative shot number data 45b (count value) counted by the ink consumption amount detection unit 50 is one of the maintenance counters. Further, for example, it may include a count value of operation pulses of a motor (not shown) that conveys the print medium, and a count value of the number of times of cutter driving when the inkjet printer 10 includes an auto cutter that cuts the print medium. These count values are stored in the memory 45, and are written in the printer-side storage unit 43 or the nonvolatile memory 14 prior to the stop sequence when the inkjet printer 10 is turned off.
At least one of the adjustment value 43a, the first error log 43b, the second error log 43c, the first error log 45a, and the cumulative shot number data 45b corresponds to operation information. At least the first error log 45a of the present embodiment corresponds to operation information.

  The printer-side control unit 40 executes a stop sequence when the power of the inkjet printer 10 is switched off by operating the printer-side input unit 41. The stop sequence includes an operation of moving various motors included in the ink jet printer 10 to return the drive units such as the carriage 20 and the cap body 30 to the initial positions. The stop sequence includes software processing that writes data to be processed by the program executed by the printer-side control unit 40 to the printer-side storage unit 43 and other storage units and enables the next program operation. The stop sequence includes a process for stopping the program executed by the printer-side control unit 40.

  Before executing the stop sequence, the printer-side control unit 40 copies and stores the first error log 45a stored in the memory 45 and the count value of the maintenance counter in the printer-side storage unit 43. In this processing, the printer-side control unit 40 causes the first error log 45 a and the cumulative shot number data 45 b stored in the memory 45 to be written in the nonvolatile memory 14. As a result, the first error log 56 and the cumulative shot number data 57 are written in the nonvolatile memory 14. In addition, the printer-side control unit 40 may write the adjustment value 43 a stored in the printer-side storage unit 43 in the nonvolatile memory 14. As described above, when the adjustment value 43 a is erased or initialized in the printer-side storage unit 43, the adjustment value 59 is stored in the nonvolatile memory 14 and can be used as a backup of the adjustment value.

FIG. 4 is a block diagram illustrating a functional configuration of the information processing apparatus 16.
The information processing apparatus 16 includes a control unit 60, an input unit 61, a display unit 62, a communication control unit 63, and a storage unit 64.
Similar to the printer-side control unit 40, the control unit 60 includes a CPU, a ROM, a RAM, other peripheral circuits, and the like, and controls each unit of the information processing device 16 when the CPU executes a program. The control unit 60 includes an information reading unit 70.
The input unit 61 is connected to various input interfaces, detects an operation on the input interface, and outputs the operation to the control unit 60.
The display unit 62 includes a display panel 62 a such as a liquid crystal display panel or an organic EL panel, and displays various types of information on the display panel 62 a under the control of the control unit 60.
The communication control unit 63 communicates with the chip-side communication control unit 46 of the ink cartridge 11 under the control of the control unit 60. The communication method is the same as that of the printer-side communication control unit 44 described above.
The storage unit 64 is a nonvolatile storage device such as an EEPROM or a hard disk, and stores various data in a rewritable manner.

  The information processing apparatus 16 includes a holding unit (not shown) that holds the ink cartridge 11, and the communication control unit 63 performs non-contact communication with the IC chip 12 of the ink cartridge 11 held in the holding unit.

The control unit 60 controls the communication control unit 63 by the function of the information reading unit 70 to execute communication with the IC chip 12, and the first error log 56 stored in the nonvolatile memory 14, the cumulative shot number data 57, etc. The maintenance counter value and the adjustment value 59 are read.
An operator at the analysis base that operates the information processing device 16 can analyze the first error log 56, the count value of the maintenance counter, the adjustment value 59, and the like read by the information processing device 16 from the nonvolatile memory 14. As a result, it is possible to investigate the cause of the error and develop a method for dealing with and preventing the error.

  FIG. 5 is a flowchart showing the operation of the inkjet printer 10. In the flowchart of FIG. 5, the printer-side control unit 40 writes the data in the memory 45 and the printer-side storage unit 43 to the nonvolatile memory 14 according to the power-off operation, and the data in the nonvolatile memory 14 when the power is turned on. Indicates the reading operation.

  When the power of the inkjet printer 10 is turned on by operating the power switch (FIG. 7) provided in the printer side input unit 41 (step S11), the printer side control unit 40 detects the mounting of the ink cartridge 11 on the carriage 20 (step S11). S12).

After detecting that the ink cartridge 11 is mounted, the printer-side control unit 40 determines whether or not the mounted ink cartridge 11 has been replaced (step S13). For example, the printer-side control unit 40 makes a difference between the ink cartridge 11 mounted before the power is turned off and the ink cartridge 11 detected in step S12 based on the unique identification ID and the like that the IC chip 12 has. Determine.
If it is determined that the ink cartridge 11 has been replaced (step S13; Yes), the printer-side control unit 40 refers to the data recorded in the nonvolatile memory 14, and whether or not the nonvolatile memory 14 stores the adjustment value 59. Is determined (step S14). When the adjustment value 59 is stored (step S14; Yes), the printer-side control unit 40 reads the adjustment value 59 in the nonvolatile memory 14 and copies it to the printer-side storage unit 43 (step S15). Here, when the printer-side storage unit 43 stores the adjustment value 43a, the adjustment value 43a is overwritten and updated.
The operations in steps S12 to S15 correspond to the operations in step S7 shown in FIG.

  Thereafter, the printer-side control unit 40 proceeds to step S16. When it is determined that the ink cartridge 11 has not been replaced (step S13; No) and when it is determined that the nonvolatile memory 14 does not store the adjustment value 59 (step S14; No), the process proceeds to step S16.

In step S16, the printer-side control unit 40 executes a startup sequence (step S16). The startup sequence includes initialization of a program executed by the printer-side control unit 40 and the memory 45, execution of a basic control program by the printer-side control unit 40, initialization of driving units and sensors such as various motors.
The printer-side control unit 40 reads the first error log 43b stored in the printer-side storage unit 43, and stores it in the memory 45 as the first error log 45a (step S17). In step S17, the cumulative shot number data 57 may be read from the nonvolatile memory 14 and stored in the memory 45 as the cumulative shot number data 45b.

  The printer-side control unit 40 shifts to a state in which printing can be performed (step S18), receives a print command instructing printing and data to be printed from a host computer (not shown) or the like (step S19), and starts printing (step S19). Step S20).

  When the error detection unit 53 detects the occurrence of an error (step S21), the printer-side control unit 40 stops the operation of each motor of the inkjet printer 10 and the inkjet head 26 (step S22).

  The error detection unit 53 determines whether the generated error is the first error or the second error (step S23). When the second error occurs, the error detection unit 53 updates the second error log 43c in the printer-side storage unit 43 (Step S24). When the first error occurs, the error detection unit 53 updates the first error log 45a in the memory 45 (step S25).

After that, for example, the print medium causing the jam is removed by the user U, the print command is received again from the host computer, or the command for initializing the print data is received (step S26). ).
After the error recovery, the printer-side control unit 40 executes the printing operation again (step S27), and monitors whether the power is turned off by operating the printer-side input unit 41 (step S28). If there is no operation to turn off the power (step S28; No), the process returns to step S18 and shifts to a printable state.

  When an operation for instructing to turn off the power is performed (step S28; Yes), the printer-side control unit 40 controls the printer-side communication control unit 44 to store the first error log 45a of the memory 45 in the nonvolatile memory 14. (Step S29). Further, the printer-side control unit 40 writes the adjustment value 43a stored in the printer-side storage unit 43 in the nonvolatile memory 14 (step S30). Further, the printer-side control unit 40 performs a process of writing the first error log 45a of the memory 45 as the first error log 43b in the printer-side storage unit 43 (step S31). The operations in steps S29 to S31 correspond to the writing process shown in step S1 of FIG. The printer-side control unit 40 executes a stop sequence (step S32) and stops.

  The ink jet printer 10 is not limited to the case where the power-off operation is detected in step S28, and performs the writing process to the nonvolatile memory 14 without turning off the power corresponding to the operation of the printer-side input unit 41. Can do. Thereby, the ink cartridge 11 can be used for backup of the adjustment value when the inkjet printer 10 is repaired, for example. The operation in this case is shown in FIG.

FIG. 6 is a flowchart showing the operation of the inkjet printer 10.
When the power of the inkjet printer 10 is turned on (step S41) and a predetermined operation is performed in advance, the inkjet printer 10 shifts to a maintenance mode (step S42). For example, the maintenance mode is an operation mode that is executed when a service person performs maintenance, repair, or the like of the inkjet printer 10. For example, the operation mode can be switched from the normal operation mode having the print standby state to the maintenance mode by performing a special operation not known to the user U. The special operation is, for example, an operation such as simultaneously pressing the power switch of the ink jet printer 10 and some other keys while the power is off.

  In the maintenance mode, when the printer-side control unit 40 is instructed to write data by operating the printer-side input unit 41, the printer-side control unit 40 writes the adjustment value 43a stored in the printer-side storage unit 43 to the nonvolatile memory 14 (step S43). .

  Thereafter, the power of the inkjet printer 10 is turned off by an operation on the printer-side input unit 41 by a service person (step S44). The service person removes the ink cartridge 11 and repairs the inkjet printer 10. During this time, initialization of data in the printer-side storage unit 43 of the inkjet printer 10 is performed.

  After the repair is performed, when the power is turned on by operating the printer-side input unit 41 (step S45), the printer-side control unit 40 stores the adjustment value 59 stored in the nonvolatile memory 14 in the printer-side storage unit 43. Copy as the adjustment value 43a (step S46). The operation in step S46 is the same as that in step S15 in FIG.

  As described with reference to FIG. 5, in the inkjet printer 10, the printer-side control unit 40 executes the writing to the nonvolatile memory 14 and the stop sequence after the power-off instruction is issued by operating the printer-side input unit 41. To do. An example of a configuration capable of this operation is shown in FIG.

FIG. 7 is a diagram illustrating a specific configuration example of the inkjet printer 10.
As shown in FIG. 7, the inkjet printer 10 includes a main substrate 101, a printing unit 110, and a power supply unit 120.
The main board 101 is mounted with a CPU 102, a RAM 103, and a ROM 104 that constitute the printer-side control unit 40 shown in FIG. The RAM 103 constitutes a memory 45. Further, a flash memory 105 constituting the printer-side storage unit 43 (FIG. 3) may be mounted on the main board 101.

  The printing unit 110 includes various sensors, motors, and mechanical mechanisms that execute operations related to printing, and includes the inkjet head 26, the carriage drive motor 38, the pump drive motor 39, and the like illustrated in FIG. The printing unit 110 corresponds to an operation unit.

The power supply unit 120 supplies power to each unit of the inkjet printer 10 including the main substrate 101 and the printing unit 110. The power supply unit 120 includes an AC / DC converter 121 (power supply circuit) connected to an AC commercial power supply 125. The direct current output from the AC / DC converter 121 is supplied by the power supply unit 122 to each part of the inkjet printer 10 including the main substrate 101 and the printing unit 110.
A transistor 123 is provided on the output line of the AC / DC converter 121. The transistor 123 can be switched on / off under the control of the CPU 102. When the transistor 123 is on, power is supplied from the power supply unit 120 to each unit of the inkjet printer 10.

The CPU 102 is connected to a power switch 106 provided in the printer-side input unit 41 (FIG. 3).
In the configuration of FIG. 7, when the power switch 106 is operated and switched off, the CPU 102 detects this operation. The CPU 102 executes, for example, the writing process and the stop sequence in steps S29 to S31 in FIG. At the final stage of the stop sequence, the CPU 102 switches the transistor 123 off. Thereby, the power supply of the inkjet printer 10 is turned off. In this configuration, the writing process and the stop sequence can be reliably executed in response to the operation of the power switch 106.

As described above, the ink jet printer 10 according to this embodiment is configured so that the ink cartridge 11 having the nonvolatile memory 14 can be mounted. The inkjet printer 10 includes a printer-side communication control unit 44 that writes data to the nonvolatile memory 14 of the ink cartridge 11 and a printer-side input unit 41 that accepts (detects) an operation for instructing power-off. When the printer-side input unit 41 receives an operation to turn off the power, the printer-side control unit 40 writes the first error log 45a as operation information to the nonvolatile memory 14 by the printer-side communication control unit 44. To execute the stop sequence.
According to the configuration of the ink jet printer 10 and the control method of the ink jet printer 10, the ink cartridge 11 can be used for recording the operation information of the ink jet printer 10 and managing the ink jet printer 10. In addition, since writing to the nonvolatile memory 14 is performed when an operation to turn off the power is accepted instead of incrementing the number of times, frequent writing to the nonvolatile memory 14 can be prevented. Thereby, the non-volatile memory 14 of the ink cartridge 11 can be efficiently used for printer management.

  The operation information written to the nonvolatile memory 14 includes a first error log 45a related to an error that occurs during operation of the inkjet printer 10. Further, the cumulative shot number data 45b corresponding to the operation log of the inkjet printer 10 may be included. Moreover, the adjustment value 43a which is a setting value set regarding the operation of the inkjet printer 10 may be included. In this case, the operation of the inkjet printer 10 can be managed in detail using the nonvolatile memory 14 of the ink cartridge 11.

  The inkjet printer 10 includes a printing unit 110 including an inkjet head 26 that performs recording on a recording medium with ink supplied from the ink cartridge 11. In addition, an ink consumption amount detection unit 50 serving as a counter that performs counting related to the operation of the printing unit 110 and a memory 45 that stores a count value are provided. The printer-side control unit 40 may write data including the cumulative shot number data 45 b stored in the memory 45 in the nonvolatile memory 14 by the printer-side communication control unit 44 in the writing process. In this case, since the count value related to the operation of the printing unit 110 is once written in the memory 45, which is a volatile memory that can be rewritten more than the non-volatile memory, the ink cartridge 11 can be rewritten with a reduced number of rewriting times. The nonvolatile memory 14 can be written.

  The inkjet printer 10 includes a printer-side storage unit 43 that stores the adjustment value 43a, and the printer-side communication control unit 44 detects the mounting of the ink cartridge 11. The printer-side control unit 40 may read the data recorded in the nonvolatile memory 14 of the ink cartridge 11 and write it in the printer-side storage unit 43 when detecting the mounting of the ink cartridge 11. In this case, data recorded in the nonvolatile memory 14 of the ink cartridge 11 can be taken into the ink jet printer 10.

  The inkjet printer 10 includes an AC / DC converter 121 that supplies power to the inkjet printer 10 and a transistor 123. The transistor 123 connects the AC / DC converter 121 and the printing unit 110 of the inkjet printer 10, and switches on and off under the control of the printer-side control unit 40. When the printer-side input unit 41 receives an operation to turn off the power, the printer-side control unit 40 switches the transistor 123 off after executing the writing process and the stop sequence. According to this configuration, when an operation to turn off the power is accepted, a series of operations for turning off the power of the inkjet printer 10 after writing to the nonvolatile memory 14 can be easily performed.

The above-described embodiment is merely an aspect of the present invention, and can be arbitrarily modified and applied within the scope of the present invention.
For example, in the above embodiment, the inkjet printer 10 that uses four-color ink is illustrated, but the present invention may be applied to a printer that uses single-color or two-color ink. In the above-described embodiment, the configuration in which writing to and reading from the nonvolatile memory 14 is performed according to the operation on the printer-side input unit 41 is illustrated, but the present invention is not limited to this. For example, the inkjet printer 10 may be connected to the host computer by wire or wirelessly. In this configuration, the ink jet printer 10 may write data stored in the printer-side storage unit 43 and / or the memory 45 into the nonvolatile memory 14 in accordance with a command transmitted from the host computer.

  In addition, the functional blocks of the inkjet printer 10 and the information processing apparatus 16 illustrated in FIGS. 3 and 4 indicate functional configurations realized by cooperation of hardware and software. Specific implementation forms of these devices are not limited to the above block diagrams. Therefore, it is not necessary to individually implement hardware corresponding to each functional unit in the functional block diagram, and it is possible to realize a configuration in which a single processor executes a program to realize the functions of a plurality of functional units. It is. In addition, in the above embodiment, a part of the function realized by software may be realized by hardware, or a part of the function realized by hardware may be realized by software. In addition, specific detailed configurations of other parts of the information processing system 1 can be arbitrarily changed without departing from the spirit of the present invention.

  DESCRIPTION OF SYMBOLS 1 ... Information processing system, 10 ... Inkjet printer (recording device), 11 ... Ink cartridge, 12 ... IC chip, 14 ... Nonvolatile memory, 16 ... Information processing device, 20 ... Carriage, 26 ... Inkjet head (recording head), DESCRIPTION OF SYMBOLS 29 ... Capping apparatus, 32 ... Recording head accommodating part, 37 ... Pump, 38 ... Carriage drive motor, 39 ... Pump drive motor, 40 ... Printer side control part (control part), 41 ... Printer side input part (operation part), 42 ... printer side display unit, 43 ... printer side storage unit (storage unit), 43a ... adjustment value, 43b ... first error log, 43c ... second error log, 44 ... printer side communication control unit, 45 ... memory (volatile) Memory), 45a ... first error log, 45b ... cumulative shot number data (count value), 46 Chip side communication control unit (writing unit) 47 ... Chip side control unit 48 ... Memory interface unit 50 ... Ink consumption detection unit (counter) 53 ... Error detection unit 56 ... First error log 57 ... Cumulative shot number data, 58 ... Information writing section, 59 ... Adjustment value, 101 ... Main board, 102 ... CPU, 103 ... RAM, 104 ... ROM, 105 ... Flash memory, 106 ... Power switch (operating section), 110 ... Printing unit (operation unit), 120... Power supply unit, 121... AC / DC converter (power supply circuit), 122.

Claims (6)

A mountable configured recording apparatus an ink cartridge having a non-volatile memory,
A writing unit for writing data to the nonvolatile memory of the ink cartridge;
An operation unit that accepts an operation for instructing to turn off the power;
When an operation to turn off the power is accepted by the operation unit, the writing process of writing operation information including information related to the operation of the recording device to the nonvolatile memory is performed by the writing unit, and then a stop sequence is performed. A control unit to execute;
A recording apparatus comprising:   The recording apparatus according to claim 1, wherein the operation information includes any of an error that occurs during operation of the recording apparatus, a log of the operation of the recording apparatus, and a setting value that is set for the operation of the recording apparatus. An operation unit including a recording head for recording on a recording medium with at least ink supplied from the ink cartridge;
A counter that performs a count on the operation of the operation unit;
A volatile memory for storing the count value of the counter,
The recording apparatus according to claim 1, wherein the control unit writes data including the count value stored in the volatile memory in the nonvolatile memory by the writing unit in the writing process. A storage unit that stores the set value; and a detection unit that detects the mounting of the ink cartridge;
The control unit reads out data including a set value recorded in the nonvolatile memory of the ink cartridge and writes the data in the storage unit when the detection unit detects the mounting of the ink cartridge. The recording device described. A power supply circuit for supplying power to the recording apparatus;
A transistor that connects the power supply circuit and the operation unit of the recording apparatus, and that is turned on and off by the control of the control unit;
5. The control unit according to claim 1, wherein the control unit switches the transistor off after executing the writing process and the stop sequence when an operation to turn off the power is received by the operation unit. 6. Recording device. A control method of a recording apparatus configured to be able to mount an ink cartridge having a nonvolatile memory,
When an operation to turn off the power is accepted, a writing process for writing operation information including information related to the operation of the recording device to the nonvolatile memory is performed, and then a stop sequence is performed.
A control method for a recording apparatus.

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