JP6574666B2 - Recording device - Google Patents

Description

  The present invention relates to a recording apparatus, and more particularly to detection of an abnormality in a recording head of a recording apparatus having a recording head.

  In the recording apparatus, if printing is continued even though printing is defective, useless cost and time are generated.

  Here, there are several factors that cause printing to be defective. In particular, factors that are caused by the recording head include aging of the recording head. When the recording head deteriorates over time and an internal circuit breaks down, a current leak occurs from the voltage supply line of the recording head, resulting in a printing failure.

  Conventionally, in order to detect an abnormality of the recording head, a method of detecting a current leak in the recording head has been proposed (Patent Document 1).

Patent No. 2930918

  In Patent Document 1, leak detection is performed with one detection line for one recording head. Therefore, when printing is performed from at least one nozzle, leak detection cannot be performed. Also, in Patent Document 1, leak detection cannot be performed when the print head is kept warm even between scans. For this reason, it is necessary to perform leak detection between pages, and it may take a long time to detect leak after a failure occurs in the head.

  In view of the above problems, an object of the present invention is to provide a recording apparatus capable of specifying a leak for each heater board.

  In order to solve the above problems, the present invention has the following configuration. That is, a recording apparatus having a recording head in which a nozzle array for ejecting ink is divided into a plurality of heater boards, and supplies a first voltage used for recording by the recording head to the recording head. A first power line; a second power line for supplying a current limited to a second voltage lower than the first voltage to each of the plurality of heater boards; and the first power line by the first power line. A first switch for switching on / off of the voltage supply, a plurality of second switches for switching on / off of the supply of the first voltage to each of the plurality of heater boards, and when the second voltage is applied A voltage monitor signal line for monitoring a voltage generated in the heater board, control means for controlling on / off of the first switch and the second switch, Determination means for determining whether there is a current leak in the heater board based on the voltage value of the pressure monitor signal line, and the voltage monitor signal line is provided for each heater board and wired adjacently, The determination by the determination means is performed in a state where the first switch is turned on and the second switch corresponding to the determination target heater board is turned off among the plurality of second switches. .

  According to the present invention, when a leak occurs, it can be identified at an earlier timing than before.

1 is a diagram illustrating a configuration example of an entire printer according to the present invention. FIG. 3 is a diagram illustrating a configuration example of a recording head according to the invention. The figure which shows the structural example of the carriage board | substrate and main board | substrate which concerns on this invention. The figure which shows the leak detection flow which concerns on 1st embodiment of this invention. The figure which shows the wiring required for FFC which concerns on 1st embodiment of this invention. The figure which shows the leak detection flow which concerns on 1st embodiment of this invention. The figure which shows the leak detection flow which concerns on 2nd embodiment of this invention. FIG. 10 is a diagram illustrating a configuration example of a recording head according to a third embodiment of the invention. The figure which shows the operation | movement flow which concerns on 3rd embodiment of this invention.

  The configuration and operation according to the present invention will be described below with reference to the drawings. Prior to this, terms and the like used in the description will be described.

  “Printing” is to be interpreted widely, and forms not only significant information such as characters and graphics (recording), but also forms an image, pattern, pattern, etc. on a recording material, or medium The case where the above processing is performed is also shown.

  “Recording material” is to be interpreted widely, not only paper used in general recording devices, but also vinyl, cloth, plastic film, metal plate, glass, ceramics, wood, leather, etc. It shall also represent that which can accept ink.

  “Ink” is to be interpreted widely, and is a liquid that can be applied to a recording material to form an image, a pattern, a pattern, or the like, process the recording material, or process ink. .

<First embodiment>
FIG. 1 shows a configuration example of an ink jet printer (hereinafter simply referred to as “printer”) which is a recording apparatus according to the present invention. The carriage unit 101 includes a recording head 102 and a carriage substrate 103. A signal is transmitted to the main board 104 as a main unit disposed on the back of the printer main body and the carriage board 103 by an FFC (Flexible Flat Cable) 105. The caterpillar 106 that supports the movable part of the FFC 105 is fixed by a support member 112.

  Although the carriage unit 101 includes the carriage substrate 103 here, the carriage substrate 103 may be divided in the carriage unit 101 depending on the circuit scale. Further, although the FFC 105 is supported by the caterpillar 106, a configuration without the caterpillar 106 may be used as long as the FFC 105 does not flutter.

  The position of the carriage unit 101 is controlled by a linear scale 107 and an encoder (not shown) mounted on the rear central portion of the carriage unit 101. The carriage unit 101 ejects ink from the recording head 102 while reciprocating on the main shaft 108 in the main scanning direction (X direction in FIG. 1) on the main shaft 108 by a motor (not shown) and transports it onto the platen 109. Printing is performed on the recorded material 110 that has been recorded. The recording material 110 is sequentially conveyed in accordance with printing by the carriage unit 101 in the sub-scanning direction (direction perpendicular to the X direction in FIG. 1).

  The carriage substrate 103 and the recording head 102 are connected by contact terminals (not shown), and power necessary for driving the recording head 102 is also supplied from the contact terminals (not shown). The operation panel 111 accepts selection of various printer operations by the user and displays information such as errors. That is, the operation panel 111 functions as a UI (User Interface) for the user.

  Next, an example of the internal configuration of the recording head 102 is shown in FIG. The nozzle rows 201 to 212 indicate nozzle rows for each color, and configure one heater board 213 to 215 for every four colors. That is, in FIG. 2, a total of three heater boards having two nozzle rows (4 colors × 2 rows) for each color are arranged in the print head. Here, independent power supply lines 216 to 218 are provided for each of the three heater boards. Further, signal lines 219 to 221 are connected to the heater boards 213 to 215, respectively, and when printing, ejection data and timing data are sent from the main board 104 to the head signal for each color in the heater boards 213 to 215. Received via lines 219-221. Thereby, printing and heat retention control are performed for each color.

  The diode sensor 225 is an element (detection unit) for grasping the temperature of the heater boards 213 to 215, is mounted on each of the heater boards 213 to 215, and outputs a voltage value corresponding to the temperature. Specifically, the output value of the diode sensor 225 varies as the internal resistance value changes according to the temperature. The nine output values of the diode sensor 225 are input to multiplexers 226 to 228 provided in the heater boards 213 to 215, respectively. Then, the main ASIC 309 selects one of the inputted nine output values and outputs it to the carriage substrate 103 via the diode sensor output lines 222 to 224. Further, the output value is input from the carriage substrate 103 to the main substrate 104 via the FFC 105. The multiplexers 226 to 228 are controlled via the head signal lines 219 to 221 for the heater boards 213 to 215, respectively.

  In the above configuration, an example in which one heater board corresponds to four colors of ink has been described. However, the present invention is not limited to this, and may be configured to support more colors.

  FIG. 3 shows a configuration example of the carriage substrate 103 and the main substrate 104 in the present embodiment. The carriage substrate 103 and the main substrate 104 are connected by an FFC 105. In the FFC 105, an I2C bus 310, voltage monitor signal lines 314 to 316, and power supply lines 216 to 218 are arranged. The first power supply line 301 is a line for supplying power to the heater boards 213 to 215 during printing, and is connected to the V1 power supply in the main board 104. The first switch 302 is an element for controlling connection of the first power supply line 301. That is, the switch 302 is a switch that switches on / off of the supply of V1.

  The second power supply line 303 is a power supply line for supplying power to the heater boards 213 to 215 when a leak is detected. The second power supply line 303 is connected to the V2 power supply in the carriage substrate 103, and the current is limited by the limiting resistor 304. The second switches 305 to 307 are control elements for applying a voltage from only the second power supply line 303 to the heater boards 213 to 215 when a leak is detected. That is, the second switches 305 to 307 are turned off when the corresponding heater board is a current leak detection target (determination target), and are turned on when they are not current leak detection targets. That is, the second switches 305 to 307 are switches for switching on / off the supply of V1 to each heater board. The first power line 301 and the second power line 303 are connected to the power lines 216 to 218 in the recording head 102 by the first switch 302 and the second switches 305 to 307, respectively. Further, V2 may be a voltage equal to or lower than V1, and a power supply in the main board 104 may be used. In the present embodiment, the second power supply line 303 is separated by diodes 327 to 329 in order to make the leak detection of the heater boards 213 to 215 independent. Further, the first switch 302 and the second switches 305 to 307 are configured by P-ch FETs.

  The first switch 302 and the second switches 305 to 307 are controlled by control signals on the control signal lines 317 to 320 from the control IC 308. The control timing to the control IC 308 is transmitted from the main ASIC 309 on the main board 104 via the FFC 105 via the I2C bus 310. The main ASIC 309 determines whether or not to detect a leak of each heater board described later.

  Further, in each of the power supply lines 216 to 218, large-capacity electrolytic capacitors 311 to 313 are arranged between the first switch 302 and the second switches 305 to 307 for voltage stabilization. In addition, voltage monitor signal lines 314 to 316 are respectively wired to the power supply lines 216 to 218, and the voltage monitor signal lines 314 to 316 are input to the main ASIC 309 via the FFC 105. The voltage monitor signal lines 314 to 316 may be configured to be divided into some voltages and then input to the main ASIC 309.

  The main ASIC 309 includes an AD converter 321, a comparison circuit 322, a memory 323, and an interpolation determination circuit 324. Thereafter, the output signal of the selected diode sensor is input to the temperature AD converter 325 in the main ASIC 309 and sent to the temperature determination circuit 326, and the temperature of each of the heater boards 213 to 215 is determined.

[Operation flow]
The operation at the time of leak detection in the configuration of FIG. 3 will be described with reference to FIG. The leak detection shown in FIG. 3 is executed when printing is not being executed. For example, it is executed before printing is started or after cleaning is executed.

  When the leak detection is started, the main ASIC 309 sends a signal to the I2C bus 310 and causes the control IC 308 on the carriage substrate 103 to turn on the first switch 302 in S401. In step S <b> 402, the main ASIC 309 sends a signal to the I2C bus 310 to cause the control IC 308 on the carriage substrate 103 to turn off the second switches 305 to 307. In S403, a voltage with a limited current from the second power supply line 303 is applied to the heater boards 213 to 215.

  Here, by turning on the first switch 302, a current flows from the drain side to the source side by a parasitic diode between the source and drain of the P-ch FET used in the second switches 305 to 307, It is possible to prevent leak detection from being performed correctly. Further, in this state, since the voltage stabilizing electrolytic capacitors 311 to 313 and the heater boards 213 to 215 are disconnected, it is possible to immediately detect a leak without considering the charge charged in the electrolytic capacitors. .

  In S <b> 404, the AD converter 321 in the main ASIC 309 takes in the value of the voltage monitor signal line 314 connected to the power supply line 216 of the heater board 213 and compares it with a threshold value designated in advance by the comparison circuit 322. Then, the comparison circuit 322 determines whether or not the value of the voltage monitor signal line 314 is equal to or higher than a predetermined voltage, that is, equal to or higher than a threshold value. If it is not equal to or greater than the threshold (NO in S404), the main ASIC 309 determines that there is an error (error) in the heater board 213, and executes error processing. This is because when the voltage is not higher than the predetermined voltage, the power supply line 216 is short-circuited to GND, other signal lines, or other power supply in the heater board 213, and it can be considered that current leakage has occurred. . As error processing, the fact that the heater board 213 is in error is output, the subsequent processing is stopped, and this processing flow ends. For example, if it is before printing execution, the subsequent printing is stopped, and if it is after cleaning, the subsequent preliminary ejection is stopped. Here, the predetermined voltage (threshold value) is set in advance based on the voltage value of V2, the value of the limiting resistor 304, and the like, and is stored in a memory or the like of the recording apparatus.

  If the value of voltage monitor signal line 314 is equal to or greater than the threshold value (YES in S404), main ASIC 309 performs leak detection equivalent to heater board 213 in heater board 214 in S406. If the value of voltage monitor signal line 314 is not equal to or greater than the threshold value (NO in S406), a message indicating that heater board 214 is in error is output in S407. Then, this processing flow ends. If heater board 214 is also equal to or greater than the threshold (YES in S406), main ASIC 309 performs leak detection equivalent to heater board 213 in heater board 215 in S408. If the value of voltage monitor signal line 316 is not equal to or greater than the threshold value (NO in S408), the fact that heater board 215 is in error is output in S409. Then, this processing flow ends. If the value of voltage monitor signal line 316 is equal to or greater than the threshold (YES in S408), the process flow ends.

  If a leak error is detected in steps S405, S407, and S409, the main ASIC 309 notifies the operation panel 111 that an error has occurred in the recording head 102 and prompts the user to replace the recording head 102.

  Next, the wiring of the voltage monitor signal lines 314 to 316 and the control signal lines 317 to 320 of the first switch 302 and the second switches 305 to 307 will be described with reference to FIG. In the present embodiment, leak detection is performed for each of the heater boards 213 to 215. Therefore, simply increasing the number of control lines and monitor lines causes an increase in the wiring of the FFC 105.

  Therefore, in the present embodiment, the voltage monitor signal lines 314 to 316 are configured to run three in parallel without sandwiching the GND line (line 501 in FIG. 5). In addition, there is a concern about the influence of crosstalk due to the mutual signals of the voltage monitor signal lines arranged adjacently in parallel. However, since the voltage monitor signal lines 314 to 316 are slow in rising speed and falling speed, the crosstalk is at a level with no problem.

  In this embodiment, the control IC 308 is mounted in the carriage unit 101, and the control signal lines 317 to 320 are controlled from the main ASIC 309 by the two-line I2C bus 310 (line 502 in FIG. 5). Thereby, the increase of the wiring of FFC105 can be suppressed. The I2C bus 310 is a line necessary for reading and writing EEPROM information in the recording head 102, and has been conventionally arranged in the FFC 105, and the I2C bus 310 is not a newly added wiring.

  As described above, it is possible to detect leaks of a plurality of heater boards with the same number as that wired to the FFC 105 when leak detection is performed on one conventional recording head 102. Specifically, the number of wires that are wired to the FFC 105 when leak detection is performed on one conventional recording head 102 is three (voltage monitor × 1 + switch control line × 2). On the other hand, in the present embodiment, the same configuration for performing leak detection of a plurality of heater boards is three (voltage monitor × 3). That is, according to this embodiment, leak detection (abnormality detection) can be executed for each heater board without increasing the wiring of the FFC 105.

  Next, leak detection during printing (during recording operation) will be described with reference to the flowchart of FIG. Here, “in recording operation” refers to the timing at which the carriage moves in any one of the bidirectional movements for printing based on the print data. 6 shows all leak detection processing depending on the presence or absence of print data in each of the heater boards 213 to 215, but here, as an example, printing when there is print data only in the heater board 214 is shown. The medium leak detection will be described.

  When the printing operation is started, in step S601, the main ASIC 309 receives print data from an external interface, an internal HDD, or the like.

  In step S <b> 602, the main ASIC 309 determines whether there is print data on the heater board 213. In this determination, it is determined whether there is print data of 1 dot or more in each nozzle row corresponding to the heater boards 213 to 215. Specifically, when the dot count value of each nozzle row corresponding to the heater boards 213 to 215 recorded in the memory 323 is acquired and there is a dot count value, that is, when the dot count value is 1 or more, It is determined that there is print data. If the dot count value is 0, it is determined that there is no print data. If there is print data on the heater board 213 (YES in S602), the process proceeds to S603, and if there is no print data on the heater board 213 (NO in S602), the process proceeds to S625.

  In this example, since there is no print data in the heater board 213 (NO in S602), the process proceeds to S625. In step S625, the main ASIC 309 determines whether there is print data in the nozzle row corresponding to the heater board (whether print data is assigned). That is, it is determined whether the dot count value of the nozzle row corresponding to the heater board 214 is 1 dot or more. If there is no print data in the nozzle row corresponding to the heater board 214 (NO in S625), the process proceeds to S638. In this example, since there is print data on the heater board 214 (YES in S625), the process proceeds to S626.

  In S626, the main ASIC 309 determines the presence / absence of print data of the heater board 215. If there is print data on the heater board 215 (YES in S626), the process proceeds to S627. If there is no print data (NO in S626), the process proceeds to S631. In this example, since there is no print data in the heater board 215 (NO in S625), the process proceeds to S631. In S631, the main ASIC 309 starts printing. First, the main ASIC 309 connects the first power supply line 301 and the second power supply line 303 to the heater boards 213 to 215 by turning on the first switch 302 and the second switches 305 to 307. . This is a state where power necessary for printing can be supplied, but leak detection cannot be performed.

  Subsequently, in S632, the main ASIC 309 performs leak detection of the heater board 213 without print data. The main ASIC 309 instructs the control IC 308 to turn off the second switch 305. As a result, the first power supply line 301 is disconnected from the heater board, and only the limited current is supplied from the second power supply line 303 to the heater board 213 that is a current leak detection target.

  Thereafter, in S633, the main ASIC 309 determines whether or not the voltage value of the voltage monitor signal line 314 is equal to or greater than a threshold value. If the voltage value of voltage monitor signal line 314 is equal to or greater than the threshold value (YES in S633), there is no problem with heater board 213, so the process proceeds to S635, and main ASIC 309 detects the leakage of heater board 215. As in the case of the heater board 213 described above, the main ASIC 309 turns off the second switch 307. In step S636, the main ASIC 309 determines whether the voltage value of the voltage monitor signal line 316 is greater than or equal to a threshold value. If it is determined that the voltage value of voltage monitor signal line 316 is equal to or greater than the threshold (YES in S636), the process proceeds to S606, and main ASIC 309 continues the printing operation. Here, the main ASIC 309 turns on all the second switches 305 to 307. As a result, it is possible to supply the power required for the heat retention control during printing to the heater boards 213 and 215 having no print data. As described above, the main ASIC 309 determines whether to perform leak detection for each heater board based on whether print data exists in the nozzle row corresponding to the heater board.

  Here, the heat insulation control will be briefly described. In a thermal ink jet printer, a heater mounted on each nozzle is heated in order to eject ink, and printing is performed by pushing the ink out of the nozzle by using foaming around the heater. In order to perform this heating more rapidly, there is a case in which minute energy that does not reach ink ejection is applied to the heater, and control is performed to keep the heater periphery at a constant temperature. This energy is very small for each nozzle, but when all the nozzles (for example, 1536 nozzles for each color) are used, the energy becomes large and power is supplied from the first power supply line 301.

  Further, whether or not to perform the heat retention control is determined based on the voltage value of the diode sensor 225 mounted around the heater boards 213 to 215. Specifically, the output value of the diode sensor 225 selectively output by the head control signal is input to the temperature AD converter 325 of the main ASIC 309 via the diode sensor output lines 222 to 224. Then, the temperature determination circuit 326 determines whether or not a predetermined temperature is reached. When the temperature is lower than the predetermined temperature, the minute energy described above is applied to the heater of each nozzle to generate thermal energy, and the heat retention control is performed to a desired temperature.

  After the printing operation is continued in S606, in S607, the main ASIC 309 determines whether there is data for the next scan. Specifically, it is determined whether or not there is data in the memory 323. If there is data (YES in S607), the flow returns to S602 to continue the series of flows. On the other hand, if there is no data (NO in S607), the printing operation is terminated in S608. Then, this processing flow ends.

  On the other hand, when the voltage value of voltage monitor signal line 314 is smaller than the threshold value (NO in S633), main ASIC 309 determines that a current leak has occurred, and proceeds to S634. In step S634, the main ASIC 309 immediately stops the printing operation and notifies the operation panel 111 that the recording head 102 has an error. This prompts the user to replace the recording head 102. Then, this processing flow ends.

  If the value of voltage monitor signal line 316 is less than the threshold value (NO in S636), main ASIC 309 determines that a current leak has occurred, and proceeds to S637. In step S637, the main ASIC 309 immediately stops the printing operation and notifies the operation panel 111 that the recording head 102 has an error. This prompts the user to replace the recording head 102. Then, this processing flow ends.

  In the above description, the flow in which the heater board 214 has print data and the heater boards 213 and 215 perform leak detection during printing has been described. Even in the case of other combinations, the flow of processing for performing leak detection on a heater board having no print data is the same as shown in FIG.

  As shown in FIG. 6, when leak detection is performed, the value of the voltage monitor signal line is detected by turning off the second switch corresponding to the heater board that is the target of leak detection.

  In S612, S617, S621, S630, S641, and S644, error processing similar to S634 and S637 is performed. Specifically, while stopping printing, the main ASIC 309 notifies the operation panel 111 that an error has occurred in the recording head 102 and prompts the user to replace the recording head 102.

  Note that the threshold values for leak detection of the voltage monitor signal line 314, the voltage monitor signal line 315, and the voltage monitor signal line 316 may be the same value or different values.

  In the present embodiment, as described above, even when printing is in progress, a failure due to current leakage can be quickly detected by frequently detecting leakage of the heater boards 213 to 215 depending on the presence or absence of print data. As a result, wasted ink, recording material, and waste of time can be prevented. For example, since a large-format printer has a large size in the width direction of a recording material, it may have a large amount of recording material, ink, and time in one printing operation, but this case is more effective.

  Further, as described above, it is possible to quickly detect a failure due to current leakage without increasing the number of signal lines between the main board and the carriage unit.

<Second Embodiment>
In the first embodiment, the leak detection during printing has been described. In the present embodiment, leak detection is further performed between scans. Here, “between scans” refers to a timing during which printing is not performed on the recording material because the carriage is off the recording material during the printing operation. Specifically, scanning is performed from the time when the carriage moves in the first direction and moves off the recording material to the time when the carriage moves in the second direction and moves again in the second direction and reaches the recording material again. It falls between. Similarly, from the time when the carriage moves in the second direction and moves off the recording material to the time when the movement direction of the carriage is switched and the carriage moves in the first direction and reaches the recording material again between scans. Applicable.

  Leak detection between scans will be described with reference to FIG. Since leak detection during printing has time allowance, both leak detection and heat retention control can be performed. However, scanning is performed for a short time, and throughput may be affected if both leak detection and heat insulation control are performed. Therefore, in the second embodiment, a method will be described in which the presence / absence of heat insulation control of the heater boards 213 to 215 is determined during scanning, and leak detection is selectively performed based on the result.

  In FIG. 7, all the leak detection processing according to the presence or absence of the heat retention control in each of the heater boards 213 to 215 is shown. However, here, as an example, a case will be described in which the heater board 215 performs heat insulation control and leak detection is performed on the heater boards 213 and 214.

  In S701, when the main ASIC 309 detects that it is between scans, it starts processing related to leak detection.

  In S702, the main ASIC 309 determines whether the heater board 213 needs to be kept warm. This determination is made based on the output value of the diode sensor 225 as described above. In the example given here, since only the heater board 215 performs the heat retention control, the process proceeds from S702 (NO) → S726 (NO) → S739 (YES) → S740. After S740, the heater board 215 is subjected to heat retention control, while leak detection is performed for the heater boards 213 and 214 which are not subjected to heat retention control.

  In S740, the main ASIC 309 turns on the first switch 302 and turns on the second switches 305-307.

  In S741, the main ASIC 309 turns off the second switch 305 and applies only the second power supply line 303 to the heater board 213. Thereby, first, the leak detection with respect to the heater board 213 is performed.

  In S742, the main ASIC 309 determines whether or not the value of the voltage monitor signal line 314 is equal to or greater than a predetermined threshold value. That is, the main ASIC 309 determines whether or not there is a current leak in the heater board 213 based on the value of the voltage monitor signal line 314. If there is no current leak (YES in S742), the process proceeds to S744, and leak detection for the heater board 214 is performed in the same manner. If there is no current leak in heater board 214 (YES in S745), the process proceeds to S706.

  In S706, the main ASIC 309 determines whether or not the heater board (here, the heater board 215) that is performing the heat insulation control reaches a predetermined temperature and the heat insulation control is finished. If the temperature has not been reached (NO in S706), in S707, the main ASIC 309 continues the heat retention control, and then determines the temperature again in S706. If the temperature has reached the predetermined temperature (YES in S706), printing is possible, and in S709, the main ASIC 309 proceeds to a leak detection process during printing (FIG. 6). Thereafter, this processing flow ends.

  If it is determined that there is a current leak in heater board 213 (NO in S742), the process proceeds to S743. In S743, the main ASIC 309 stops the subsequent printing operation and notifies the operation panel 111 that the recording head 102 has an error. This prompts the user to replace the recording head 102. Then, this processing flow ends.

  On the other hand, if there is no current leak in heater board 213 (YES in S742) and it is determined that there is a current leak in heater board 214 (NO in S745), the process proceeds to S746. In step S746, the main ASIC 309 stops the subsequent printing operation and notifies the operation panel 111 that the recording head 102 has an error. This prompts the user to replace the recording head 102. Then, this processing flow ends.

  In the above description, the flow for performing the heat retention control only on the heater board 215 and executing the inter-scan leak detection on the heater boards 213 and 214 has been described. Even in the case of other combinations, the flow of processing for performing leak detection on a heater board without heat retention control is the same as shown in FIG.

  In the present invention, as described above, the leak detection of the heater boards 213 to 215 is frequently performed according to the presence or absence of the heat insulation control without affecting the throughput even between scans, so that the failure due to the current leak can be quickly detected. Can be detected. As a result, wasted ink, recording material, and wasted time can be prevented.

<Third embodiment>
In the first to third embodiments, a case has been described in which, when an error occurs in leak detection, the user is immediately notified of the error and prompted to replace the recording head 102. However, depending on the configuration of the nozzle rows 201 to 212 in the recording head 102, it is possible to interpolate (substitute) a heater board having a current leak with another normal heater board to extend the life of the recording head 102. In the present embodiment, the configuration and operation in such a case will be described with reference to FIGS.

FIG. 8 shows the configuration of the recording head 102 in the third embodiment. The nozzle rows 801 to 812 correspond to colors (inks) as follows.
801: Cyan 802: Magenta 803: Yellow 804: Photo Cyan 805: Photo Black 806: Matt Black 807: Matt Black 808: Photo Black 809: Photo Cyan 810: Yellow 811: Magenta 812: Cyan A so-called mirror arrangement is provided from the center A to the R side and the L side. That is, the color arrangement in the recording head 102 is symmetric with respect to the center A as an axis. Such a recording head is mounted on, for example, a printer mainly focusing on speed. In the case of this arrangement, the same color is arranged on the heater board 213 and the heater board 215. Therefore, even if an abnormality occurs in either heater board, it is possible to interpolate with the heater board in which no abnormality has occurred.

[Operation flow]
The operation of the printer equipped with the recording heads 102 having such an arrangement will be described with reference to FIG. In the present embodiment, as an example, a case where current leakage occurs in the heater board 213 and interpolation is performed by the heater board 215 will be described.

  Since S901 to 904 are equivalent to S401 to S404 described with reference to FIG. 4 of the first embodiment, detailed description thereof is omitted. When the voltage value of voltage monitor signal line 314 of heater board 213 is less than the threshold value (NO in S904), the process proceeds to S905. In the first embodiment, if any leak is detected, an error is immediately displayed. On the other hand, in the present embodiment, the main ASIC 309 acquires a leak flag and records it in the memory 323. At this time, the leak flag is set so as to identify which heater board has a current leak. Thereafter, the process proceeds to S906.

  In S906, the main ASIC 309 detects the leak of the heater board 214. If there is no current leak in heater board 214 (YES in S906), the process proceeds to S908. On the other hand, when the voltage value of voltage monitor signal line 315 of heater board 214 is less than the threshold value (NO in S906), the process proceeds to S907, and the leak flag of heater board 214 is acquired and stored in memory 323. Then, the process proceeds to S908.

  In S908, the main ASIC 309 detects the leak of the heater board 215. If there is no current leak in heater board 215 (YES in S908), the process proceeds to S910. On the other hand, when the voltage value of voltage monitor signal line 316 of heater board 215 is less than the threshold value (NO in S908), the process proceeds to S909, where the leak flag of heater board 215 is acquired and stored in memory 323. Then, the process proceeds to S908.

  In S910, the main ASIC 309 ends the leak detection operation. Thereafter, the process proceeds to S911.

  In S911, the main ASIC 309 determines whether the error flag is recorded in the memory 323 by the interpolation determination circuit 324. Further, in S912, the main ASIC 309 determines whether or not the heater board having a current leak can be interpolated by another heater board. For example, if the heater board in which current leakage occurs is the heater board 213 and the heater board 215 in which the same color is arranged is normal, it is determined that interpolation is possible.

  If interpolation is possible (YES in S912), the main ASIC 309 records the interpolation processing execution flag in the memory 323 in S913. In the subsequent printing, control is performed so that the data that is scheduled to be printed on the heater board 213 is interpolated on the heater board 215 and printed. At this time, the main ASIC 309 displays on the operation panel 111 that a part of the heater board is abnormal and that interpolation processing is being performed, and that it is desirable to replace the recording head 102. Thereby, the user is made aware of the abnormality of the heater board. Thereafter, this processing flow ends.

  If interpolation is not possible (NO in S912), in S914, the main ASIC 309 stops the subsequent printing and notifies the operation panel 111 that there is an error in the recording head 102. This prompts the user to replace the recording head 102. Note that the case where interpolation is not possible means that, in the case of the configuration shown in FIG. 8, a current leak occurs in the heater board 214, a current leak occurs in both the heater boards 213 and 215, etc. Is mentioned.

  In this embodiment, as described above, even if one heater board becomes abnormal, if another heater board capable of interpolation processing is normal, the printing operation is performed with the normal heater board. Perform interpolation. As a result, until the user prepares the recording head 102, the throughput is lowered, but the printing can be continued. As a result, the life of the recording head can be extended.

<Other embodiments>
The present invention is not limited to the embodiment described above. For example, in the above-described embodiment, the description has been given by taking as an example an inkjet that performs printing by reciprocating a carriage unit on which a recording head is mounted. However, the present invention is not limited to this. For example, a so-called full multi-head in which nozzles are arranged in a range that covers the width of the print area of the maximum size sheet that can be used by the recording apparatus may be used. In the full multi-head, each color line head may be seamlessly formed by a single nozzle chip, or the divided nozzle chips (heater boards) are regularly arranged in a single row or a staggered arrangement. It may be arranged. In such a configuration as well, as in the above-described embodiment, a configuration is adopted in which leak detection can be performed for each heater board, and leakage detection may be performed for each heater board. In the above-described embodiment, each heater board has a plurality of colors. However, the present invention is not limited to this, and each heater board may have only one color. In this case as well, it is possible to determine whether there is print data for each heater board and determine the leak accordingly.

101: carriage unit, 102: recording head, 103: carriage substrate, 104: main substrate, 105: FFC, 106: caterpillar, 107: linear scale, 108: main shaft, 109: platen, 110: recording material, 111: Operation panel, 112: Support member

Claims (13)

A recording apparatus having a recording head in which a nozzle row for ejecting ink is divided into a plurality of heater boards,
A first power supply line for supplying the recording head with a first voltage used for recording by the recording head;
A second power supply line for supplying a current limited by a second voltage equal to or lower than the first voltage to each of the plurality of heater boards;
A first switch for switching on and off the supply of the first voltage by the first power line;
A plurality of second switches for switching on and off the supply of the first voltage to each of the plurality of heater boards;
A voltage monitor signal line for monitoring a voltage generated in the heater board when the second voltage is applied;
Control means for controlling on / off of the first switch and the second switch;
Based on the voltage value of the voltage monitor signal line, determination means for determining whether there is a current leak in the heater board;
Have
The voltage monitor signal line is provided for each heater board and wired adjacently,
The determination by the determination means is performed in a state in which the first switch is turned on and a second switch corresponding to the determination target heater board is turned off among the plurality of second switches. Recording device. A determination unit that determines whether or not to perform the determination by the determination unit;
The recording apparatus according to claim 1, wherein the control unit performs control based on the determination by the determination unit.   The recording apparatus according to claim 2, wherein the determination unit determines whether or not to perform the determination according to whether print data is assigned to a nozzle row corresponding to a heater board.   The recording apparatus according to claim 2, wherein the determination unit determines that the determination is performed on a heater board that has no print data to be recorded among the plurality of heater boards.   The determining means determines and controls whether or not to make a determination by the determining means during a scan for each of the plurality of heater boards, based on whether or not heat retention control is necessary. Item 5. The recording apparatus according to any one of Items 2 to 4.   The recording apparatus according to claim 5, wherein the determination unit determines to perform a determination during scanning for a heater board that does not require heat retention control among the plurality of heater boards.   7. The printing apparatus according to claim 1, wherein printing by the recording apparatus is stopped when the determination unit determines that there is a current leak in any of the plurality of heater boards. The recording device according to one item. Of the plurality of heater boards, when it is determined that there is a current leak in the first heater board, the recording operation by the first heater board using a second heater board different from the first heater board A second determination means for determining whether or not interpolation is possible,
The recording operation is continued using the second heater board when the second determination means determines that the second heater board can be interpolated. The recording apparatus as described in any one of thru | or 6.   The printing by the recording device is stopped at that time when the second determination unit determines that interpolation is not possible on the second heater board. Recording device.   10. The apparatus according to claim 1, further comprising notification means for notifying a user of a current leak when any one of the plurality of heater boards is determined to have a current leak. The recording device according to one item. The recording apparatus includes a carriage unit on which the recording head is mounted, and a main unit,
The recording apparatus according to claim 1, wherein the carriage unit includes the first switch, the second switch, and the control unit.   The recording apparatus according to claim 11, further comprising a detection unit configured to detect a temperature of each of the plurality of heater boards in the carriage unit.   The control means is an IC, and controls switching of the first and second switches based on a signal transmitted from a main ASIC included in a main unit via a signal line. 12. The recording apparatus according to 12.

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