JP2006231789A - Liquid ejector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid ejector in which the nozzle forming face in a liquid ejection head can be cleaned surely even when the liquid ejector is used over a long term without complicating the liquid ejector itself. <P>SOLUTION: An ink jet printer comprises a control section having an ROM storing a routine of ink deposition suppression processing. When the processing transits to step S17 as a result of decision processing of steps S10-S16 in the routine of ink deposition suppression processing, a CPU drives an elevator to release sealing of the nozzle forming face in a recording head by a cap. Subsequently, the CPU drives a piezoelectric element to eject cyan ink as a liquid for dispersion from the recording head and then sucks the cyan ink by means of a suction pump and discharges it into a waste tank. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a liquid ejecting apparatus such as an ink jet printer.

  Conventionally, as this type of liquid ejecting apparatus, for example, an ink jet printer described in Patent Document 1 (hereinafter abbreviated as “printer”) has been proposed. This printer includes an ink cartridge and a recording head (liquid ejecting head), and a plurality of liquid ejecting nozzles are provided on a nozzle forming surface which is the lower surface of the recording head. In the printer, the liquid ejection nozzle ejects (discharges) ink (liquid) supplied from the ink cartridge onto the printing paper (target) as ink droplets, thereby printing on the printing paper. .

Further, in the above printer, in order to reduce the ejection failure of the ink ejected from the liquid ejecting nozzle of the recording head, cleaning for discharging bubbles, thickened ink, and the like from the liquid ejecting nozzle is appropriately performed. That is, the printer is provided with a cap (sealing means) for sealing the nozzle forming surface, a suction pump (suction means) communicating with the cap via a tube, and a waste liquid tank. When cleaning is performed, the suction pump is driven with the nozzle formation surface sealed with a cap. The suction pump sucks ink and bubbles that have increased in viscosity from the liquid ejecting nozzle, and discharges the sucked ink and bubbles and the like into the waste liquid tank via the discharge tube.
JP 2000-280488 A

  By the way, when the above cleaning is performed, ink having a relatively high viscosity is discharged into the waste liquid tank. Therefore, there has been a situation that the ink discharged from the discharge port of the discharge tube accumulates in a lump in the waste liquid tank. That is, since cleaning is performed a plurality of times, ink having a relatively high viscosity gradually accumulates in the waste liquid tank, and the deposit made of the ink blocks the discharge port of the discharge tube extending into the waste liquid tank. There was a thing. In addition, there was a situation that the deposit gradually thickened or solidified as time passed. In such a situation, even if further cleaning is performed, the suction pump cannot discharge the ink into the waste liquid tank, and there is a possibility that the discharge tube may be clogged with the ink. That is, the printer described in Patent Document 1 has a problem that the discharge tube extending into the waste liquid tank is clogged with ink, and as a result, cleaning becomes difficult.

  The present invention has been made in view of such circumstances, and an object of the present invention is to reliably clean the nozzle forming surface of the liquid jet head even when the apparatus is used for a long time without complicating the apparatus itself. It is another object of the present invention to provide a liquid ejecting apparatus that can be performed in the same manner.

  In order to achieve the above object, a liquid ejecting apparatus according to an aspect of the invention seals a liquid ejecting head that ejects a plurality of types of liquids including pigments based on driving of an ejecting unit, and a nozzle formation surface of the liquid ejecting head. Sealing means; suction means for sucking each liquid from the liquid ejecting head in a state where the nozzle forming surface is sealed by the sealing means; and each liquid sucked by the suction means from the liquid ejecting head. In a liquid ejecting apparatus including a waste liquid tank that collects as a waste liquid, at least one of the liquids is discharged as a dispersion liquid from the liquid ejecting head toward the sealing unit. Control means for driving the discharge means corresponding to the liquid and causing the suction means to suck the dispersion liquid discharged based on the drive of the discharge means.

  According to the present invention, the dispersion liquid is discharged from the liquid ejecting head toward the sealing means based on the drive of the discharge means, and the dispersion liquid is discharged into the waste liquid tank by the drive of the suction means. Here, if each liquid discharged into the waste liquid tank is accumulated so as to form a lump in a thickened state, a new deposit into the waste liquid tank is generated due to the growth of the thickened liquid deposits. Discharge of liquid is hindered. However, in the present invention, the deposit is dissolved by redispersing the pigment as the main component of the deposit in the dispersion liquid. Therefore, the discharge of each liquid into the waste liquid tank based on the driving of the suction means is not suppressed by the deposit made of each liquid. Further, it is not necessary to separately prepare a dedicated liquid as a dispersion liquid in order to dissolve the deposits, and it is not necessary to provide a dedicated apparatus separately. Therefore, the nozzle forming surface of the liquid ejecting head can be reliably cleaned even when used for a long period of time without complicating the apparatus itself.

  In the liquid ejecting apparatus according to the aspect of the invention, the control unit may discharge a liquid having a relatively high ability of dispersing the pigment from the liquid ejecting head toward the sealing unit as the dispersion liquid. Then, the ejection means corresponding to the dispersion liquid is driven.

  According to this invention, since the dispersion liquid is a liquid having a relatively high ability to disperse the pigment among the liquids, the deposit formed in the waste liquid tank is used as the main component of the deposit. Can be dissolved quickly by more efficiently redispersing.

  The liquid ejecting apparatus according to the aspect of the invention may be detected by an elapsed discharge time detecting unit that detects an elapsed time from the time when the dispersion liquid is discharged from the liquid ejecting head based on the driving of the discharge unit, and the detected elapsed discharge time detecting unit. And an elapsed time determination unit that determines whether or not the detected elapsed time exceeds a predetermined threshold elapsed time, and when the determination result by the elapsed time determination unit is a positive determination, the control unit, The discharge means corresponding to the dispersion liquid is driven so that the dispersion liquid is discharged from the liquid jet head toward the sealing means, and the dispersion liquid is sucked by the suction means.

  According to this invention, the dispersion liquid is discharged into the waste liquid tank every threshold elapsed time. Therefore, when the deposit consisting of each liquid is not generated in the waste liquid tank or has not grown until it inhibits the discharge of new liquid into the waste liquid tank, the liquid for dispersion is not contained in the waste liquid tank. Can be prevented from being discharged. That is, waste of the dispersion liquid can be suppressed.

  The liquid ejecting apparatus according to the aspect of the invention further includes a power-off determining unit that determines whether or not the power switch of the liquid ejecting apparatus is turned off, and when the determination result by the power-off determining unit is a positive determination, The control means drives the ejection means corresponding to the dispersion liquid so that the dispersion liquid is ejected from the liquid ejecting head toward the sealing means, and causes the suction means to suck the dispersion liquid. .

  According to the present invention, when the power switch of the liquid ejecting apparatus is turned off, the dispersion liquid is discharged into the waste liquid tank. Therefore, after that, when the liquid ejecting apparatus is not used for a long period of time, it is possible to suppress the generation of deposits made of each liquid in the waste liquid tank.

  The liquid ejecting apparatus according to the aspect of the invention further includes a suction determination unit that determines whether each liquid ejected from the liquid ejecting head is sucked by the suction unit based on the driving of the suction unit. When the determination result is affirmative, the control unit drives the ejection unit corresponding to the dispersion liquid so that the dispersion liquid is ejected from the liquid ejecting head toward the sealing unit, The dispersion liquid is sucked by the suction means.

  According to the present invention, after each liquid ejected from the liquid ejecting head based on the driving of the suction means is discharged into the waste liquid tank, the dispersion liquid is discharged into the waste liquid tank. That is, since the liquid for dispersion is discharged into the waste liquid tank while each liquid is relatively viscous, the deposit made of each liquid in the waste liquid tank is thickened. Compared to the case, it can be dissolved quickly.

  The liquid ejecting apparatus according to the aspect of the invention includes a suction elapsed time detecting unit that detects an elapsed time after each liquid ejected from the liquid ejecting head is sucked by the suction unit based on the driving of the suction unit, and the suction progress. A suction elapsed time determination unit that determines whether or not a detection elapsed time detected by the time detection unit exceeds a predetermined threshold elapsed time, and the determination result by the suction elapsed time determination unit is a positive determination Further, the control means drives the discharge means corresponding to the dispersion liquid so that the dispersion liquid is discharged from the liquid ejecting head toward the sealing means, and the dispersion liquid is driven by the suction means. To suck.

  According to the present invention, the dispersion liquid is discharged into the waste liquid tank after the threshold elapsed time has elapsed since each liquid ejected from the liquid ejecting head based on the driving of the suction means was discharged into the waste liquid tank. That is, since the dispersion liquid is discharged into the waste liquid tank before the deposit made of each liquid is dried and solidified, the deposit has solidified in the waste liquid tank. It can be dissolved quickly as compared with the case.

  The liquid ejecting apparatus according to the aspect of the invention further includes a temperature detection unit that detects the ambient temperature, and a temperature determination unit that determines whether or not the detected temperature detected by the temperature detection unit is equal to or higher than a predetermined threshold temperature. When the determination result by the temperature determination unit is an affirmative determination, the control unit corresponds to the dispersion liquid so that the dispersion liquid is discharged from the liquid ejecting head toward the sealing unit. The discharge means is driven, and the dispersion liquid is sucked by the suction means.

  According to the present invention, when it is detected that each liquid discharged into the waste liquid tank is disposed in an atmosphere having a temperature equal to or higher than the threshold temperature, the dispersion liquid is discharged into the waste liquid tank. Therefore, the deposit made of each liquid in the waste liquid tank can be dissolved before the thickening or solidification proceeds.

  The liquid ejecting apparatus of the present invention further includes humidity detection means for detecting the atmospheric humidity, and humidity determination means for determining whether the detected humidity detected by the humidity detection means is equal to or lower than a predetermined threshold humidity. When the determination result by the humidity determination means is affirmative, the control means corresponds to the dispersion liquid so that the dispersion liquid is discharged from the liquid ejecting head toward the sealing means. The discharge means is driven, and the dispersion liquid is sucked by the suction means.

  According to the present invention, when it is detected that each liquid discharged into the waste liquid tank is disposed in an atmosphere having a threshold humidity or less that is easy to dry, the dispersion liquid is discharged into the waste liquid tank. Therefore, the deposit made of each liquid pigment in the waste liquid tank can be dissolved before the thickening or solidification proceeds.

  Hereinafter, an embodiment in which the present invention is embodied in an ink jet printer will be described with reference to FIGS. In the following description of the present specification, “vertical direction” and “horizontal direction” indicate the vertical direction and horizontal direction in FIG. 1, respectively.

  As shown in FIG. 1, an ink jet printer 11 as a liquid ejecting apparatus includes a frame 12, and a platen 13 is installed on the frame 12. A recording paper (target) P is fed onto the platen 13 by a paper feed mechanism having a paper feed motor 14. A rod-shaped guide member 15 is installed on the frame 12 in parallel with the longitudinal direction (left-right direction) of the platen 13. A carriage 16 is inserted into and supported by the guide member 15 so as to be capable of reciprocating in the axial direction of the guide member 15. The carriage 16 is connected to a carriage motor 18 via a timing belt 17 provided on the frame 12, and reciprocates along the guide member 15 by driving the carriage motor 18.

  As shown in FIG. 2, a recording head (liquid ejecting head) 19 is mounted on the lower surface of the carriage 16. The lower surface of the recording head 19 is a nozzle forming surface 20, and a plurality (only four are shown in FIG. 2) of liquid jet nozzles 21 are provided on the nozzle forming surface 20. An ink cartridge 22 is detachably mounted on the carriage 16 above the recording head 19, and a plurality of types (multiple colors) of ink (liquid) including pigments are respectively stored in the ink cartridge 22. It is stored in a state where it can be supplied to. Then, each ink is supplied from the ink cartridge 22 to the recording head 19 by driving a piezoelectric element PZ (see FIG. 3) as an ejection unit provided in the recording head 19, and each ink is supplied from each liquid ejecting nozzle 21. Printing is performed by being jetted onto the recording paper P fed onto the platen 13.

  A cleaning device 23 for cleaning the nozzle forming surface 20 (each liquid ejecting nozzle 21) of the recording head 19 is provided in the non-printing region located at the right end in the frame 12. The cleaning device 23 is provided with a main body case 24. The cleaning device 23 includes a cap support member 25 disposed on the upper portion of the main body case 24, a cap (sealing means) 26 supported by the cap support member 25, and the cap 26 for moving up and down. And a lifting device 27 (see FIG. 3). In the main body case 24, a suction pump (suction means) 28 and a waste liquid tank 29 are provided. The suction pump 28 is connected to the cap 26 via the suction tube 30 and is connected to the waste liquid tank 29 via the discharge tube 31. In FIG. 2, for convenience of explanation, the main body case 24, the cap support member 25, and the lifting device 27 are omitted.

  The cap 26 has a bottomed box shape, and a sealing member 32 having a rectangular frame shape made of a flexible material is provided on the entire upper surface of the peripheral wall of the cap 26. Further, a connecting portion 33 that projects from the bottom wall of the cap 26 to the suction tube 30 extending from the suction pump 28 protrudes downward, and a connecting passage 33 a is formed in the connecting portion 33. Has been. Then, when the cap 26 is lifted by the lifting device 27 with the carriage 16 moved to the non-printing area, the cap 26 seals the nozzle forming surface 20 (each liquid ejecting nozzle 21) of the recording head 19. The cap inner space S is formed between the nozzle forming surface 20 and the nozzle forming surface 20.

  When the suction pump 28 is driven in a state where the cap 26 seals the nozzle forming surface 20, the suction pump 28 depressurizes the sealed cap inner space S, and each ink (especially thickening) from each liquid ejecting nozzle 21. Ink) or bubbles. These inks and the like are collected from the cap inner space S into the suction pump 28 through the suction tube 30 and discharged from the suction pump 28 into the waste liquid tank 29 through the discharge tube 31. Yes.

  The waste liquid tank 29 has a bottomed box shape that is open at the top, and a waste liquid absorber 34 made of a porous member is accommodated therein. Further, in the waste liquid tank 29, the discharge port 31 a of the discharge tube 31 is disposed above the waste liquid absorbent 34. Therefore, each ink etc. that has flowed through the discharge tube 31 from the suction pump 28 is discharged from the discharge port 31a toward the upper surface 34a of the waste liquid absorber 34. And most of each ink discharged into the waste liquid tank 29 is absorbed by the waste liquid absorbent 34, while the remaining part is deposited on the waste liquid absorbent 34. That is, due to each ink that has not been absorbed by the waste liquid absorbent 34, a deposit K that forms a lump with the pigment of each ink as a main component is formed below the discharge port 31a. The deposit K gradually increases in viscosity as the solvent of each ink gradually vaporizes, and may eventually solidify.

  The ink cartridge 22 stores a plurality of types of ink (four types in the present embodiment) separately, and each ink is formed by dispersing a pigment in a solvent formed from water or a dispersion liquid. ing. That is, the ink cartridge 22 includes an ink containing 5% by mass of a black pigment (for example, carbon black) (hereinafter referred to as “black ink”) and an ink containing 4% by mass of a cyan pigment (for example, a phthalocyanine compound). (Hereinafter referred to as “cyan ink”). The ink cartridge 22 includes an ink containing 6% by mass of a magenta pigment (for example, a quinacridone compound) (hereinafter referred to as “magenta ink”) and an ink containing 6% by mass of a yellow pigment (for example, an azo compound) ( Hereinafter, “yellow ink” is stored.

  As described above, the cyan ink is generated so that the content of the pigment is minimized as compared with each ink other than the cyan ink. In other words, the cyan ink has the highest water content as compared with each ink other than the cyan ink. Therefore, when cyan ink is sprayed on the deposit K formed on the waste liquid absorber 34, each of the deposits K constituting the deposit K is compared with the case where ink other than cyan ink is sprayed on the deposit K. The pigment is efficiently diluted or redispersed by the solvent constituting the ink. Therefore, in this embodiment, the cyan ink functions as a dispersion liquid which is an ink (liquid) having the highest ability to disperse the pigment among the inks.

Next, the electrical configuration of the ink jet printer 11 of the present embodiment will be described with reference to FIG.
As shown in FIG. 3, the ink jet printer 11 is provided with a control unit 35. The control unit 35 includes a power switch SW of the ink jet printer 11, a temperature sensor SE1 for detecting the ambient temperature, a humidity sensor SE2 for detecting the ambient humidity, and various timers TM1, TM2, and TM3. It is connected. Of the timers TM1 to TM3, the timer TM1 (hereinafter referred to as “first timer”) TM1 has finally been ejected from the liquid ejecting nozzle 21 toward the cap 26 based on the driving of the piezoelectric element PZ. The elapsed time (that is, after being discharged into the waste liquid tank 29) is measured. That is, in the present embodiment, after the first timer TM1 discharges cyan ink (dispersing liquid) from the liquid ejecting nozzle 21 toward the cap (sealing means) 26 based on the driving of the piezoelectric element (discharge means) PZ. It functions as a discharge elapsed time detecting means for detecting the elapsed time.

  In addition, a timer (hereinafter referred to as “second timer”) TM2 measures an elapsed time since the cleaning of the nozzle forming surface 20 by the cleaning device 23 is performed last. That is, in the present embodiment, the second timer TM2 detects the elapsed time after each ink ejected from the liquid ejecting nozzle 21 is aspirated by the suction pump 28 based on the driving of the suction pump (suction means) 28. It functions as a time detection means. In addition, a timer (hereinafter, referred to as “third timer”) TM3 measures a period during which the ink jet printer 11 is disposed in an environment in which thickening or solidification of each ink easily proceeds. Specifically, when the temperature detected by the control unit 35 (CPU 36 described later) based on the signal from the temperature sensor SE1 is equal to or higher than a predetermined threshold temperature, or based on the signal from the humidity sensor SE2, the control unit 35 ( When the humidity detected by the CPU 36) is equal to or lower than a predetermined threshold humidity, the third timer TM3 starts measurement.

  The control unit 35 includes a CPU (control means) 36, and a ROM 37 and a RAM 38 are connected to the CPU 36. The ROM 37 stores a control program for ejecting each ink onto the recording paper P, a control program for cleaning the nozzle forming surface 20 of the recording head 19, and the like. The ROM 37 stores and manages various threshold values (threshold temperature, threshold humidity, etc.). The RAM 38 stores various information that can be appropriately rewritten during the operation of the ink jet printer 11. That is, the RAM 38 has a detected temperature detected by the CPU 36 based on a signal from the temperature sensor SE1, a detected humidity detected by the CPU 36 based on a signal from the humidity sensor SE2, and various elapsed times measured by the timers TM1 to TM3. Etc. are to be memorized. In this regard, in the present embodiment, the temperature sensor SE1 and the CPU 36 constitute a temperature detection unit that detects the ambient temperature in which the ink jet printer 11 is installed. Further, the humidity sensor SE2 and the CPU 36 constitute humidity detecting means for detecting the atmospheric humidity where the ink jet printer 11 is installed.

  Next, an ink accumulation suppression processing routine for allowing the nozzle forming surface 20 to be cleaned over a long period of time among various processing routines executed by the CPU 36 of the present embodiment will be described based on the flowchart shown in FIG. explain. This ink accumulation suppression processing routine is a processing routine for dissolving the deposit K composed of each ink discharged into the waste liquid tank 29.

  As shown in FIG. 4, in the ink accumulation suppression processing routine, the CPU 36 determines whether or not the detected elapsed time measured by the first timer TM1 has exceeded the first threshold elapsed time ST1 stored in the ROM 37. (Step S10). Therefore, in the present embodiment, the CPU 36 functions as an elapsed time determination unit that determines whether or not the detected elapsed time detected based on the signal from the first timer TM1 has exceeded a predetermined first threshold elapsed time ST1. It is like that. The first threshold elapsed time ST1 is a time from when cyan ink is discharged as a dispersion liquid into the waste liquid tank 29 until thickening or solidification of each ink discharged into the waste liquid tank 29 starts. And calculated in advance by experiments.

  And when the determination result of step S10 is affirmation determination, CPU36 transfers the process to step S17 mentioned later. On the other hand, if the determination result of step S10 is negative, the CPU 36 determines whether or not the power switch SW is set to off (step S11). Therefore, in this embodiment, the CPU 36 also functions as a power-off determination unit that determines whether or not the power switch SW of the ink jet printer (liquid ejecting apparatus) 11 has been turned off. The ink jet printer 11 according to the present embodiment is configured such that the main power is turned off after about 10 seconds have elapsed since the power switch SW is set to OFF. Processing is performed. And when the determination result of step S11 is affirmation determination, CPU36 transfers the process to step S17. On the other hand, when the determination result of step S11 is negative, the CPU 36 determines whether or not the nozzle forming surface 20 has been cleaned (step S12). That is, the CPU 36 determines whether or not the suction pump 28 is driven in a state where the nozzle forming surface 20 is sealed with the cap 26. Therefore, in this embodiment, the CPU 36 determines whether or not each ink (liquid) discharged from each liquid ejecting nozzle 21 is sucked by the suction pump 28 based on the driving of the suction pump (suction means) 28. It is supposed to function as well.

  And when the determination result of step S12 is negative determination, CPU36 transfers the process to step S14 mentioned later. On the other hand, if the determination result of step S12 is affirmative, the CPU 36 determines whether or not the detected elapsed time measured by the second timer TM2 has exceeded the second threshold elapsed time ST2 stored in the ROM 37. (Step S13). Accordingly, in the present embodiment, the CPU 36 functions as a suction elapsed time determination unit that determines whether or not the detected elapsed time detected based on the signal from the second timer TM2 exceeds a predetermined second threshold elapsed time ST2. It is supposed to be. Note that the second threshold elapsed time ST2 is a period from when each ink is discharged into the waste liquid tank 29 due to the last cleaning of the nozzle forming surface 20, until the thickening or solidification of each ink starts. It is time and is calculated beforehand by experiment.

  And when the determination result of step S13 is affirmation determination, CPU36 transfers the process to step S17. On the other hand, when the determination result of step S13 is negative, the CPU 36 proceeds to step S14. In step S <b> 14, the CPU 36 determines whether or not the detected temperature detected based on the signal from the temperature sensor SE <b> 1 is equal to or higher than the threshold temperature STE stored in the ROM 37. Therefore, in the present embodiment, the CPU 36 also functions as a temperature determination unit that determines whether or not the detected temperature detected based on the signal from the temperature sensor SE1 is equal to or higher than a predetermined threshold temperature STE. . And when the determination result of step S14 is affirmation determination, CPU36 transfers the process to step S16 mentioned later. On the other hand, when the determination result of step S14 is negative, the CPU 36 determines whether or not the detected humidity detected based on the signal from the humidity sensor SE2 is equal to or lower than the threshold humidity SH stored in the ROM 37 (step). S15). Therefore, in the present embodiment, the CPU 36 also functions as a humidity determination unit that determines whether the detected humidity detected based on the signal from the humidity sensor SE2 is equal to or lower than a predetermined threshold humidity SH. . Note that the temperature above the threshold temperature STE and the temperature below the threshold humidity SH are conditions (temperature and humidity) in which the viscosity or solidification of each ink easily proceeds, and the threshold temperature STE and the threshold humidity SH are calculated in advance by experiments. ing.

  If the determination result in step S15 is negative, the CPU 36 ends the ink accumulation suppression processing routine. On the other hand, when the determination result of step S15 is affirmative, the CPU 36 proceeds to step S16. In step S <b> 16, the CPU 36 determines whether or not the detection elapsed time measured by the third timer TM <b> 3 exceeds the threshold arrangement time ST <b> 3 stored in the ROM 37. In other words, the CPU 36 determines whether or not the elapsed time after the ink jet printer 11 is placed in an environment where the thickening or solidification of each ink easily proceeds exceeds the threshold placement time ST3. Note that the threshold arrangement time ST3 is a time from when the ink jet printer 11 is arranged under the condition where each ink is easily thickened or solidified until the start of thickening or solidification of each ink. It has been calculated.

  If the determination result in step S16 is negative, the CPU 36 ends the ink accumulation suppression processing routine. On the other hand, if the determination result of step S16 is affirmative, the CPU 36 proceeds to step S17. In step S <b> 17, the CPU 36 drives the lifting device 27 to put the nozzle forming surface 20 in an unsealed state with the cap 26. That is, when the cap 26 seals the nozzle forming surface 20, the CPU 36 moves the cap 26 downward based on the drive of the lifting device 27. Subsequently, the CPU 36 drives the piezoelectric element PZ corresponding to the cyan ink to discharge the cyan ink from the liquid ejecting nozzle 21 toward the cap 26 (step S18). Then, the CPU 36 drives the suction pump 28 to cause the suction pump 28 to suck the cyan ink discharged into the cap 26 in step S18 (so-called idle suction) (step S19). Thereafter, the CPU 36 ends the ink accumulation suppression processing routine. Incidentally, the CPU 36 may perform the discharge of the cyan ink and the drive of the suction pump 28 based on the drive of the piezoelectric element PZ at the same time, or may drive the suction pump 28 after the completion of the discharge of the cyan ink. Further, the CPU 36 may drive the suction pump 28 while the cyan ink is being discharged. That is, in this embodiment, the amount of cyan necessary for suppressing the accumulation of each ink (pigment) in the waste liquid tank 29 and the solidification and thickening of the deposit K, and for dissolving the deposit K. As long as the ink is discharged into the waste liquid tank 29 as a dispersion liquid, the discharge timing of the cyan ink and the drive timing of the suction pump 28 may be arbitrary.

  Therefore, as shown in FIG. 5A, when the deposit K has been formed on the waste liquid absorbent 34 in the waste liquid tank 29, the processes after step S17 in the ink deposition suppression process routine are executed. Then, cyan ink is ejected from the liquid ejecting nozzle 21 into the cap 26 based on the driving of the piezoelectric element PZ. Then, the suction pump 28 discharges the cyan ink in the cap 26 into the waste liquid tank 29 through the suction tube 30 and the discharge tube 31 and sprays it on the deposit K. Then, the deposit K is dissolved by redispersing each pigment constituting the deposit K in the cyan ink (solvent constituting the cyan ink) based on the dispersing action of the pigment in the cyan ink. Then, as shown in FIG. 5B, a part of the pigment constituting the deposit K is absorbed by the waste liquid absorbent 34 together with the cyan ink solvent, and the rest is spread on the waste liquid absorbent 34. Will remain. Accordingly, a good discharge space for each ink in the vicinity of the discharge port 31 a of the discharge tube 31 is ensured, and the ink is prevented from being clogged in the discharge tube 31.

Therefore, in this embodiment, the following effects can be obtained.
(1) When the deposit K composed of each ink is formed in the waste liquid tank 29, the waste liquid tank 29 uses one kind of ink (cyan ink) among the respective inks (each liquid including the pigment) as a dispersion liquid. Drain in. Then, the pigment constituting the deposit K in the waste liquid tank 29 is redispersed in the solvent constituting the cyan ink, and as a result, the deposit K is dissolved in the cyan ink. Therefore, the discharge space of each ink in the vicinity of the discharge port 31a of the discharge tube 31 is ensured satisfactorily. In this embodiment, no liquid other than the ink stored in the ink cartridge 22 is used as the dispersion liquid in order to dissolve the deposit K. Further, in order to discharge only the cyan ink into the waste liquid tank 29 in order to dissolve the deposit K, no separate configuration is provided. Accordingly, the nozzle forming surface 20 of the recording head (liquid ejecting head) 19 can be reliably cleaned even when used for a long period of time without complicating the apparatus itself.

  (2) Since the dispersion liquid is cyan ink having the highest ability to disperse the pigment among the inks (liquids), the deposit K formed in the waste liquid tank 29 is more efficiently converted into the deposit K. Can be dissolved by redispersing each pigment in the cyan ink.

  (3) Further, even when an adhering matter made of each ink is generated in the discharge tube 31 based on solidification or thickening of each ink, the adhering matter is contained in the discharge tube 31 with cyan ink as a dispersion liquid. Is discharged into the waste liquid tank 29 together with the cyan ink. Therefore, it is possible to suppress the inside of the discharge tube 31 from being clogged with the deposits made of each ink.

  (4) When the elapsed time since the cyan ink was finally discharged into the waste liquid tank 29 as the dispersion liquid has passed the first threshold elapsed time ST1, the cyan ink is used as the dispersion liquid in the waste liquid tank 29. Will be discharged again. Therefore, when the deposit K made of each ink is not generated in the waste liquid tank 29 or has not grown until the new discharge of each ink into the waste liquid tank 29 is inhibited, the cyan ink is not generated. It is possible to suppress discharge into the waste liquid tank 29. That is, waste of cyan ink can be suppressed.

  (5) When the power switch SW of the ink jet printer (liquid ejecting apparatus) 11 is turned off, the cyan ink is discharged into the waste liquid tank 29 as a dispersion liquid. Therefore, when the ink jet printer 11 is not used for a long period of time, it is possible to prevent the deposit K made of each ink from being generated in the waste liquid tank 29. That is, in the next use, each ink discharged based on the cleaning of the nozzle forming surface 20 can be reliably discharged into the waste liquid tank 29.

  (6) When the elapsed time since the cleaning of the nozzle forming surface 20 (liquid ejecting nozzle 21) by the cleaning device 23 has passed the second threshold elapsed time ST2, cyan ink is used as a liquid for dispersion. It is discharged into the tank 29. That is, before each ink (liquid) is dried and solidified, the cyan ink is discharged into the waste liquid tank 29 as a dispersion liquid. Therefore, the deposit K composed of each ink in the waste liquid tank 29 can be dissolved more quickly than when the deposit K has solidified.

  (7) When the elapsed time since the ink jet printer (liquid ejecting apparatus) 11 is installed at the ambient temperature equal to or higher than the threshold temperature STE has passed the threshold arrangement time ST3, the cyan ink is used as the dispersion liquid and the waste liquid tank 29. It is designed to be discharged inside. Therefore, the deposit K made of each ink (liquid) in the waste liquid tank 29 can be dissolved before the deposit K is thickened or solidified.

  (8) When the elapsed time since the ink jet printer (liquid ejecting apparatus) 11 is installed at the atmospheric humidity equal to or lower than the threshold humidity SH has passed the threshold arrangement time ST3, the cyan ink is used as the dispersion liquid and the waste liquid tank 29. It is designed to be discharged inside. Therefore, the deposit K made of each ink (liquid) in the waste liquid tank 29 can be dissolved before the deposit K is thickened or solidified.

The above embodiment may be changed to another embodiment (another example) as follows.
In the above embodiment, in a state where the cap 26 seals the nozzle forming surface 20, cyan ink is ejected based on driving of the piezoelectric element PZ, and then the cap 26 is moved downward (that is, by the cap 26. The cyan ink in the cap 26 may be sucked by the suction pump 28 after the nozzle forming surface 20 is unsealed. Further, an air opening hole that can be freely opened and closed is provided in the cap 26, and the air opening hole may be opened when the cyan ink in the cap 26 is sucked based on the driving of the suction pump 28. That is, it is only necessary that only the cyan ink ejected into the cap 26 based on the driving of the piezoelectric element PZ in the processing after Step S17 can be discharged into the waste liquid tank 29 based on the driving of the suction pump 28.

  In the above embodiment, the CPU 36 may perform only the determination process of one of steps S14 and S15. Further, the CPU 36 may not perform both of the determination processes in steps S14, S15, and S16. In this case, if the determination results in steps S12 and S13 are negative, the CPU 36 ends the ink accumulation suppression processing routine.

  -Moreover, CPU36 does not need to perform the determination process of step S13. In this case, when the determination result in step S12 is affirmative, that is, immediately after the cleaning of the nozzle forming surface 20 by the cleaning device 23, the CPU 36 discharges cyan ink into the waste liquid tank 29 as a dispersion liquid. You may make it do. In this case, before each ink discharged into the waste liquid tank 29 thickens, the cyan ink is discharged into the waste liquid tank 29 as a dispersion liquid. Therefore, the deposit K made of each ink in the waste liquid tank 29 can be dissolved more quickly than when the thickening of the deposit K has progressed.

  Further, the CPU 36 may not perform the determination process in step S12. In this case, if the determination result in step S11 is negative, the CPU 36 performs the determination process in step S14.

  -Moreover, CPU36 does not need to perform the determination process of step S11. In this case, when the determination result in step S10 is negative, the CPU 36 performs the determination process in step S12. Furthermore, the CPU 36 may not perform the determination process in step S10.

  In the above embodiment, the CPU 36 does not have to perform the ink accumulation suppression processing routine. In this case, it is desirable to discharge the cyan ink as a dispersion liquid into the waste liquid tank 29 immediately after the cap 26 seals the nozzle forming surface 20.

In the above embodiment, the dispersion liquid may be an ink (for example, yellow ink) that has a relatively high ability to disperse the pigment among the inks.
In the above embodiment, the dispersion liquid may be at least one type of ink (for example, magenta ink and black ink).

  In the above embodiment, the liquid ejecting apparatus may be embodied as a liquid ejecting apparatus that ejects another liquid. For example, as a liquid ejecting apparatus for ejecting liquids such as electrode materials and color materials used in the manufacture of liquid crystal displays, EL displays, and surface-emitting displays, as a liquid ejecting apparatus for ejecting bioorganic materials used in biochip manufacturing, and as precision pipettes The sample injection device may be used.

1 is a schematic perspective view showing the inside of an ink jet printer according to an embodiment. FIG. 2 is a schematic cross-sectional view of a cleaning device in the present embodiment. The block circuit diagram which shows the electric constitution in this embodiment. 9 is a flowchart for explaining an ink accumulation suppression processing routine in the present embodiment. (A) is a schematic sectional drawing which shows a mode that cyan ink is sprayed on a deposit, (b) is a schematic sectional drawing which shows a mode that a deposit melt | dissolved with cyan ink.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 11 ... Inkjet printer (liquid ejecting apparatus), 19 ... Recording head (liquid ejecting head), 20 ... Nozzle formation surface, 26 ... Cap (sealing means), 28 ... Suction pump (suction means), 29 ... Waste liquid tank, 36: CPU (control means, elapsed time determination means, power-off determination means, suction determination means, suction elapsed time determination means, temperature detection means, humidity detection means), PZ ... piezoelectric element (discharge means), SE1 ... temperature sensor ( Temperature detection means), SE2 ... humidity sensor (humidity detection means), ST1 ... first threshold elapsed time, ST2 ... second threshold elapsed time, STE ... threshold temperature, SH ... threshold humidity, SW ... power switch, TM1 ... 1st timer (discharge elapsed time detecting means), TM2... Second timer (suction elapsed time detecting means).

Claims (8)

A liquid ejecting head that ejects a plurality of types of liquids including pigments based on driving of the ejecting means; a sealing means that seals a nozzle forming surface of the liquid ejecting head; and the nozzle forming surface is sealed by the sealing means. In a liquid ejecting apparatus comprising: suction means for sucking each liquid from the liquid ejecting head in a stopped state; and a waste liquid tank for collecting each liquid sucked from the liquid ejecting head by the suction means as waste liquid.
The discharge means corresponding to the dispersion liquid is driven so that at least one of the liquids is discharged as the dispersion liquid from the liquid ejecting head toward the sealing means, and the discharge means A liquid ejecting apparatus comprising control means for causing the suction means to suck the liquid for dispersion discharged based on driving. The control means corresponds to the dispersion liquid such that a liquid having a relatively high ability to disperse the pigment among the liquids is ejected as the dispersion liquid from the liquid ejecting head toward the sealing means. The liquid ejecting apparatus according to claim 1, wherein the ejecting unit is driven. Based on the driving of the discharge means, a discharge elapsed time detection means for detecting an elapsed time from the time when the dispersion liquid is discharged toward the sealing means from the liquid jet head, and the discharge elapsed time detection means. And an elapsed time determination unit that determines whether or not the detected elapsed time exceeds a predetermined threshold elapsed time, and when the determination result by the elapsed time determination unit is a positive determination, the control unit The discharge means corresponding to the dispersion liquid is driven so that the dispersion liquid is discharged from the liquid ejecting head toward the sealing means, and the dispersion liquid is sucked by the suction means. Item 3. The liquid ejecting apparatus according to Item 2. A power-off determining unit that determines whether or not the power switch of the liquid ejecting apparatus has been turned off; and when the determination result by the power-off determining unit is a positive determination, the control unit includes the liquid ejecting head 3. The discharge means corresponding to the dispersion liquid is driven so that the dispersion liquid is discharged from the sealing means toward the sealing means, and the dispersion liquid is sucked by the suction means. The liquid ejecting apparatus described. In the case where the apparatus further includes a suction determination unit that determines whether or not each liquid ejected from the liquid ejecting head is sucked by the suction unit based on the driving of the suction unit, and the determination result by the suction determination unit is a positive determination Further, the control means drives the discharge means corresponding to the dispersion liquid so that the dispersion liquid is discharged from the liquid ejecting head toward the sealing means, and the dispersion liquid is driven by the suction means. The liquid ejecting apparatus according to claim 1, wherein the liquid ejecting apparatus is caused to suck. A suction elapsed time detecting means for detecting an elapsed time since each liquid ejected from the liquid ejecting head is sucked by the suction means based on driving of the suction means, and a detection detected by the suction elapsed time detecting means A suction elapsed time determination unit that determines whether or not the elapsed time exceeds a predetermined threshold elapsed time, and when the determination result by the suction elapsed time determination unit is affirmative determination, the control unit, The discharge means corresponding to the dispersion liquid is driven so that the dispersion liquid is discharged from the liquid ejecting head toward the sealing means, and the dispersion liquid is sucked by the suction means. Item 3. The liquid ejecting apparatus according to Item 2. A temperature detection unit for detecting the ambient temperature; and a temperature determination unit for determining whether or not the detected temperature detected by the temperature detection unit is equal to or higher than a predetermined threshold temperature, and a determination result by the temperature determination unit Is affirmative, the control means drives the discharge means corresponding to the dispersion liquid so that the dispersion liquid is discharged from the liquid ejecting head toward the sealing means. The liquid ejecting apparatus according to claim 1, wherein the liquid for suction is sucked by the suction means. Humidity detection means for detecting the atmospheric humidity, and humidity determination means for determining whether the detected humidity detected by the humidity detection means is equal to or lower than a predetermined threshold humidity, the determination result by the humidity determination means Is affirmative, the control means drives the discharge means corresponding to the dispersion liquid so that the dispersion liquid is discharged from the liquid ejecting head toward the sealing means. The liquid ejecting apparatus according to claim 1, wherein the liquid for suction is sucked by the suction means.

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