JP7037743B2 - Device that discharges liquid - Google Patents

Description

The present invention relates to a device for discharging a liquid.

Conventionally, there is known a device that covers a cleaning liquid accommodating member on the nozzle surface of a liquid ejection head that ejects liquid from a nozzle at the time of non-liquid ejection, and ejects a liquid that brings the cleaning liquid inside the cleaning liquid accommodating member into contact with the nozzle surface. ing.

For example, in Patent Document 1, an inkjet recording device in which a head storage container (cleaning liquid accommodating member) is covered on the nozzle surface of a recording head, the inside of the head storage container is filled with a cleaning liquid, and the entire nozzle surface is immersed in the cleaning liquid for storage. (A device for discharging a liquid) is disclosed. In this device, the ink adhering to the nozzle surface is cleaned with a cleaning liquid.

However, in the conventional device that brings the cleaning liquid inside the cleaning liquid accommodating member into contact with the nozzle surface, the cleaning liquid enters the inside of the nozzle formed on the nozzle surface. Therefore, there is a problem that the liquid inside the nozzle and the cleaning liquid are mixed, and then the state of the liquid discharged from the nozzle (viscosity, solid content concentration, etc.) changes.

In order to solve the above problems, the present invention includes a liquid discharge head having a nozzle for discharging liquid on the nozzle surface, and a cleaning liquid accommodating member for accommodating the cleaning liquid and applying the cleaning liquid to the nozzle surface. The contact preventing means for preventing the cleaning liquid from coming into contact with the nozzle on the nozzle surface when the cleaning liquid inside the cleaning liquid accommodating member is brought into contact with the nozzle surface, and the contact preventing means is the cleaning liquid accommodating member. It is a device for discharging a liquid, which is arranged inside and is a cap member for capping a nozzle on the nozzle surface .

According to the present invention, it is possible to solve the problem caused by the mixture of the liquid inside the nozzle and the cleaning liquid.

Explanatory drawing which looked at the whole structure of the inkjet recording apparatus which concerns on embodiment from the side. Explanatory view of the main part of the inkjet recording device as viewed from above. The perspective view which shows a part of the maintenance recovery mechanism provided in the inkjet recording apparatus. The plan view which shows a part of the maintenance recovery mechanism. The schematic diagram which shows the outline of the drive mechanism of the maintenance recovery mechanism. The schematic diagram which shows the outline of the supply / discharge mechanism of the cleaning liquid in the maintenance recovery mechanism. Explanatory drawing which shows the lifting mechanism (vertical movement mechanism) of a wiper blade in the maintenance recovery mechanism. The flowchart which shows the flow of the cleaning sequence of this embodiment. Explanatory drawing which shows the positional relationship between a recording head and a wiper blade before wiping. Explanatory drawing which shows the positional relationship between a recording head and a wiper blade during wiping. Explanatory drawing which shows the positional relationship between a recording head and a wiper blade just before the end of wiping. Explanatory drawing which shows the positional relationship between a recording head and a wiper blade at the end of wiping. Explanatory drawing which shows the elevating mechanism of the first cap. (A) is an explanatory diagram showing the positional relationship between the recording head and the first cap and the second cap in a state immediately before the carriage moves to the head cap position and starts capping. (B) is an explanatory diagram showing the positional relationship between the recording head and the first cap and the second cap in a state where the first cap is capped and the second cap is not covered with the nozzle surface. (C) is an explanatory diagram showing the positional relationship between the recording head and the first cap and the second cap in a state where the second cap is not covered on the nozzle surface after the capping of the first cap. Explanatory drawing for explaining the number of the 1st cap held in the 2nd cap. (A) and (b) are explanatory views showing the structure and operation of stirring the cleaning liquid by the first cap. Explanatory drawing which shows an example of the shape of the 1st cap for increasing the stirring capacity of the cleaning liquid in a 2nd cap. Explanatory drawing which shows another example of the shape of the 1st cap for increasing the stirring capacity of the cleaning liquid in a 2nd cap. Explanatory drawing which shows the state in the middle of raising or lowering of a 2nd cap. A flowchart showing the flow of the capping sequence. An explanatory plan view of a main part showing an example of a liquid discharge unit. Explanatory view of the main part plan showing another example of a liquid discharge unit. The front explanatory view which shows still another example of a liquid discharge unit.

Hereinafter, an embodiment of a serial type inkjet recording device, which is an image forming device, as a device for discharging a liquid according to the present invention will be described with reference to the drawings.
FIG. 1 is an explanatory view of the overall configuration of the inkjet recording apparatus according to the present embodiment as viewed from the side.
FIG. 2 is an explanatory view of a main part of the inkjet recording device as viewed from above.

In the inkjet recording apparatus 1 of the present embodiment, the carriage 33 is slidably held in the main scanning direction by the master-slave guide rods 31 and 32 which are guide members horizontally laid on the left and right side plates 21A and 21B of the apparatus main body. .. The carriage 33 moves along the guide rods 31 and 32 in the direction indicated by the arrow in FIG. 2 (carriage main scanning direction) via the timing belt driven by the main scanning motor.

The carriage 33 is equipped with two recording heads 34a and 34b (referred to as "recording head 34" when not distinguished) as liquid ejection heads for ejecting liquid ink. The recording head 34 has a nozzle surface having two nozzle rows in which a plurality of nozzles are arranged in a sub-scanning direction orthogonal to the main scanning direction so that the nozzle surface faces downward, that is, the ink ejection direction from the nozzles faces downward. , Attached to the carriage 33.

In the present specification, the "liquid discharge head" is a functional component that discharges and injects liquid from a nozzle. The liquid to be discharged may have a viscosity and surface tension that can be discharged from the head, and is not particularly limited, but the viscosity becomes 30 [mPa · s] or less at room temperature, under normal pressure, or by heating or cooling. It is preferable that it is a thing. More specifically, solvents such as water and organic solvents, colorants such as dyes and pigments, polymerizable compounds, resins, functionalizing materials such as surfactants, biocompatible materials such as DNA, amino acids and proteins, and calcium. , Solvents, suspensions, emulsions, etc. containing edible materials such as natural pigments, such as inks for inkjets, surface treatment liquids, components of electronic and light emitting elements, and formation of electronic circuit resist patterns. It can be used in applications such as liquids and material liquids for three-dimensional modeling. Piezoelectric actuators (laminated piezoelectric elements and thin-film piezoelectric elements), thermal actuators that use electric heat conversion elements such as heat-generating resistors, and electrostatic actuators that consist of a vibrating plate and counter electrodes are used as energy sources for discharging liquid. Includes what to do.

Further, the carriage 33 is equipped with sub-tanks 35a and 35b (referred to as "sub-tank 35" when not distinguished) for supplying ink of each color corresponding to each nozzle row of the recording head 34. Ink cartridges of each color that are detachably attached to the cartridge loading unit 4 are replenished and supplied to the sub tank 35 by the supply pump unit via the supply tubes 36 of each color.

As shown in FIG. 2, a maintenance / recovery mechanism 81 for maintaining and recovering the state of the nozzle of the recording head 34 is arranged in the non-printing area on one side of the carriage 33 in the moving direction. The maintenance / recovery mechanism 81 includes first caps 82a and 82b (referred to as “first cap 82” when not distinguished) and nozzles, which are cap members as contact prevention means for covering the nozzle rows on each nozzle surface of the recording head 34. A wiper blade 83, which is a wiper member for wiping the surface, an empty ejection receiving portion 84 for receiving ink at the time of empty ejection for discharging thickened ink, a carriage lock 87 for locking the carriage 33, and the like are provided.

Further, as shown in FIG. 3 to be described later, a non-replaceable waste liquid tank 100 for accommodating waste liquid (empty ejected ink, etc.) generated by the maintenance / recovery operation is provided below the maintenance / recovery mechanism 81. .. Further, a replaceable waste liquid tank 101 is provided on the side of the maintenance / recovery mechanism 81.

When performing maintenance and recovery of the nozzle of the recording head 34, the carriage 33 is moved to a position facing the maintenance and recovery mechanism 81 which is the home position, capping by the cap portion 82 is performed, and suction from the nozzle is performed. By performing a maintenance / recovery operation such as empty ejection that ejects droplets that do not contribute to formation, it is possible to perform image formation by stable droplet ejection.

Further, as shown in FIG. 2, in the non-printing area on the other side in the moving direction of the carriage 33, an empty ejection receiving portion 88 that receives ink at the time of empty ejection performed during an image forming operation or the like is arranged. The empty discharge receiving portion 88 is provided with an opening 89 or the like corresponding to the nozzle row of the recording head 34.

Next, the maintenance / recovery mechanism 81 in the inkjet recording apparatus of this embodiment will be described with reference to FIGS. 3 to 5.
FIG. 3 is a perspective view showing a part of the maintenance / recovery mechanism 81. FIG. 4 is a plan view showing a part of the maintenance / recovery mechanism 81. FIG. 5 is a schematic diagram showing an outline of the drive mechanism of the maintenance / recovery mechanism 81. FIG. 6 is a schematic diagram showing an outline of the cleaning liquid supply / discharge mechanism in the maintenance / recovery mechanism 81.

In the maintenance / recovery mechanism 81, the second cap 212 as a cleaning liquid accommodating member for applying the cleaning liquid to the nozzle surface, the wiper blade 83, and the wiper cleaner 86 as the wiper cleaning means can be raised and lowered with respect to the frame 211, respectively. Can be moved up and down). The first caps 82a and 82b are held by the second cap 212 and can be raised and lowered (movable up and down) together with the second cap 212.

An empty ejection receiving portion 84 is arranged between the wiper blade 83 and the first cap 82a, and the upper end portion of the empty ejection receiving portion 84 on the wiper blade 83 side scrapes off the ink adhering to the wiper blade 83. The wiper cleaner portion 85 as a second wiper cleaning means to be removed is configured. When cleaning the wiper blade 83, the wiper blade 83 is lowered while the wiper blade 83 is pressed against the wiper cleaner portion 85 by the wiper cleaner 86. As a result, the ink adhering to the wiper blade 83 is scraped off by the wiper cleaner portion 85 of the empty ejection receiving portion 84 and collected by the empty ejection receiving portion 84.

Further, a tubing pump (suction pump) 220, which is a suction means, is connected to the first cap 82a on the side close to the printed area via a flexible tube 219, and the first cap 82a is for suction and moisturizing (hereinafter referred to as “)”. It is simply used as a cap for "for suction"). On the other hand, the suction pump 220 is not connected to the first cap 82b on the side far from the printing area, and the first cap 82b is used only as a moisturizing cap. Therefore, when the suction operation of the recording head 34 is performed, the recording head 34, which is the target of the suction operation, is selectively moved to a position where it can be capped by the first suction cap 82a, and the head suction operation is performed.

Further, below the first caps 82a and 82b and the wiper blade 83 and the like, a camshaft 221 rotatably supported by the frame 211 is arranged. The camshaft 221 has a cap cam 222 for raising and lowering the second cap 212, a wiper cam 224 for raising and lowering the wiper blade 83, and a rotating body that receives the droplets ejected in the empty ejection receiving portion 84. A roller 226, a cleaner cam 228 for swinging the wiper cleaner 86, and a carriage lock cam 229 for raising and lowering the carriage lock 87 are provided.

A motor gear 232 is provided on the motor shaft 231a of the motor 231 and a pump gear 233 provided on the pump shaft 220a of the suction pump 220 is arranged so as to mesh with the motor gear 232. Further, the second intermediate gear 235 is meshed with the first intermediate gear 234 configured coaxially with the pump gear 233, and the second intermediate gear 235 has the third intermediate gear 236 with a one-way clutch 237. Are arranged in mesh with each other. A fifth intermediate gear 239 is meshed with the fourth intermediate gear 238, which is arranged coaxially with the third intermediate gear 236 and rotates integrally, and the fifth intermediate gear 239 has the camshaft described above. The cam gear 240 fixed to 221 is engaged. The intermediate shaft 241 which is the rotation shaft of the third intermediate gear 236 with the clutch 237 and the fourth intermediate gear 238 is rotatably supported by the frame 211.

In the maintenance / recovery mechanism 81 of the present embodiment, when removing ink and impurities adhering to the surface (nozzle surface) of the recording head 34 forming the nozzle 34A, first, the wiper blade is driven via the wiper cam 224 by driving the motor 231. Raise 83. In this state, by moving the carriage 33 in the print area toward the position facing the maintenance / recovery mechanism 81 (non-print area), the wiper blade 83 wipes the nozzle surface of the recording head 34, and adhered ink and impurities. Wipe off such things.

Further, if the nozzle 34A of the recording head 34 is left in a state of being exposed to the outside air, the ink inside the nozzle dries, thickens and sticks, and the ink ejection performance deteriorates. In order to prevent this, the first cap 82 caps the recording head 34 so as to cover the nozzle 34A on the nozzle surface. Also at this time, the motor 231 is driven, the second cap 212 is raised via the cap cam 222, and the first cap 82 that is raised accordingly is brought into contact with the nozzle surface of the recording head 34, and the first cap 82 is brought into contact with the nozzle surface. Capping so as to cover the nozzle 34A on the nozzle surface.

By the way, there is a case that ink or the like remains on the nozzle surface due to unwiped residue that cannot be completely cleaned by wiping alone. If the ink or the like remains on the nozzle surface in this way, the ink or the like sticks to the nozzle surface. When the nozzle surface in which the ink is adhered is wiped again by the wiper blade 83, the adhered ink may be peeled off from the nozzle surface, which may be pushed into the nozzle 34A and cause ejection failure.

In addition, ink tends to accumulate at the wiping end portion (nozzle surface end portion) of the wiping, and the fixed ink gradually accumulates. When the fixed ink protruding from the nozzle surface comes into contact with the recording paper or the like to be ejected by the liquid due to such accumulation, the recording quality (printing quality) is deteriorated.

Further, when the ink is blown to the recording head 34 or the like adjacent to the recording head 34 by wiping the recording head 34 to be cleaned, the ink drips from the recording head 34 and stains the recording paper or the like which is the liquid ejection target. Or, the transport path to which the liquid discharge target is transported is soiled with ink, which stains the recording paper or the like to be transported later, and the recording quality (print quality) is deteriorated. In addition, the ink blown to the adjacent recording head 34 or the like may promote the accumulation of ink due to the wiping of the recording head 34.

Therefore, in the present embodiment, in the cleaning sequence, by bringing the cleaning liquid contained in the second cap 212 into contact with the nozzle surface of the recording head 34, the ink or the like remaining on the nozzle surface cannot be completely cleaned by wiping alone. To remove.

As shown in FIG. 6, a tubing pump (cleaning liquid supply pump) 213 as a supply means is connected to the second cap 212 via a cleaning liquid supply tube 214. The cleaning liquid supply pump 213 supplies the cleaning liquid 216 from the cleaning liquid storage tank 215 to the inside of the second cap 212 through the cleaning liquid supply tube 214. Further, a tubing pump (waste liquid pump) 218 as a discharge means is connected to the second cap 212 via a cleaning liquid waste liquid tube 217. The waste liquid pump 218 discharges the cleaning liquid 216 inside the second cap 212 to the waste liquid tank 101 through the cleaning liquid waste liquid tube 217.

Further, the cleaning liquid supply pump 213 and the waste liquid pump 218 are controlled by the control unit 230 as a control means. More specifically, as will be described later, when a predetermined cleaning liquid replacement condition is satisfied, the control unit 230 controls the waste liquid pump 218 to discharge the cleaning liquid 216 inside the second cap 212, and controls the cleaning liquid supply pump 213. Then, a cleaning liquid replacement operation for supplying a new cleaning liquid 216 to the inside of the second cap 212 is performed. The predetermined cleaning liquid replacement conditions include, for example, the condition that the concentration of the ink content in the cleaning liquid 216 inside the second cap 212 is equal to or higher than the specified concentration (for example, 50%), and the number of capping operations is the specified number of times (for example, 20 times). ) The condition that the above is reached can be mentioned.

Here, when the cleaning liquid 216 contained inside the second cap 212 is brought into contact with the nozzle surface as described above, if the nozzle 34A formed on the nozzle surface also comes into contact with the cleaning liquid 216, the inside of the nozzle 34A The cleaning liquid 216 enters the nozzle. In this case, the ink inside the nozzle and the cleaning liquid are mixed, and then the state of the ink ejected from the nozzle 34A (viscosity, solid content concentration, etc.) changes, and the problem that proper ejection performance cannot be exhibited. cause. Further, in order to solve this problem, when the ink portion mixed with the cleaning liquid 216 is discharged from the nozzle 34A (empty ejection) and then the ink ejection operation for recording (main operation) is performed, the ink portion is used for recording. A new problem arises in that the consumption of no ink is high.

In the present embodiment, a contact preventing means for preventing the cleaning liquid 216 from coming into contact with the nozzle 34A on the nozzle surface when the cleaning liquid 216 inside the second cap 212 is brought into contact with the nozzle surface is provided. By providing such a contact preventing means, when the cleaning liquid 216 inside the second cap 212 is brought into contact with the nozzle surface, the contact preventing means prevents the cleaning liquid 216 from coming into contact with the nozzle 34A on the nozzle surface, and the nozzle. The ink inside and the cleaning liquid 216 do not mix. Therefore, it is possible to solve the problem that the state of the ink ejected from the nozzle 34A (viscosity, solid content concentration, etc.) is changed by the cleaning liquid 216. Further, since the operation of ejecting the ink portion mixed with the cleaning liquid 216 from the nozzle 34A (empty ejection operation) is not required before the main operation of ejecting the ink from the nozzle 34A, the consumption of ink can be suppressed.

The contact preventing means is not particularly limited as long as it can prevent the cleaning liquid 216 from coming into contact with the nozzle 34A on the nozzle surface when the cleaning liquid 216 inside the second cap 212 is brought into contact with the nozzle surface. This embodiment is an example in which the first cap 82, which is a cap member arranged inside the second cap 212 and covers the nozzle 34A on the nozzle surface, is used as the contact prevention means.

Next, the elevating mechanism (vertical movement mechanism) of the wiper blade 83 will be described with reference to FIG. 7.
FIG. 7 is an explanatory diagram showing an elevating mechanism (vertical movement mechanism) of the wiper blade.
The wiper blade 83 is attached to the wiper holder 341. Guide pins 342 and 343 are provided at both ends of the wiper holder 341 in the sub-scanning direction, and the guide pins 342 and 343 are fitted into the guide grooves 346 formed in the guide member 345 (which may be the frame 211 itself). By being aligned, the wiper blade 83 attached to the wiper holder 341 along the guide groove 346 is configured to be movable up and down. A stopper 347, which is a regulating member for restricting the ascent of the guide pin 342, is provided at the upper end of the guide groove 346, and the ascending position of the wiper blade 83 is restricted.

A flexible member 348 is attached between both legs 341a and 241a of the wiper holder 341. A tongue piece 348a provided with a cam pin 349 is formed on the flexible member 348, and the cam pin 349 is movably fitted into the cam groove of the wiper cam 224.

Next, a cleaning sequence, which is a head maintenance using the maintenance / recovery mechanism 81 in the present embodiment, will be described.
FIG. 8 is a flowchart showing the flow of the cleaning sequence of the present embodiment.
When cleaning is started, first, the first cap 82 is removed from the nozzle surface (decapped) from the standby state of the inkjet recording device 1, that is, the capped state in which the nozzle surface is capped by the first cap 82. ) (S1). Subsequently, the carriage 33 is moved in the main scanning direction so that the recording head 34 to be cleaned moves to the maintenance position (the position facing the suction first cap 82a) (S2).

Next, the motor 231 is driven to raise the second cap 212 via the cap cam 222. As a result, the first cap 82 that rises with the second cap 212 first comes into contact with the nozzle surface of the recording head 34, and is capped by the first cap 82 so as to cover the nozzle 34A on the nozzle surface (S3).

Further, the second cap 212 is further raised, and the upper portion of the second cap 212 is raised until it comes into contact with the lower surface of the carriage 33, so that the second cap 212 covers the entire nozzle surface of the recording head 34. Will be. Since the inside of the second cap 212 is filled with the cleaning liquid 216, the cleaning liquid 216 comes into contact with the nozzle surface of the recording head 34. At this time, the nozzle 34A is capped so that the suction first cap 82a covers only the portion in the vicinity of the nozzle on the nozzle surface. Therefore, the ink or the like adhering to the nozzle surface portion other than the nozzle vicinity portion is cleaned by the cleaning liquid 216 without the cleaning liquid 216 coming into contact with the nozzle 34A (S4).

In the present embodiment, when the second cap 212 is put on the nozzle surface, the side surface of the recording head 34 is positioned so as to penetrate into the inside of the second cap 212. Therefore, the side surface of the recording head 34 also comes into contact with the cleaning liquid 216 inside the second cap 212. Therefore, in the present embodiment, the ink adhering to the side surface of the recording head 34 is also cleaned by the cleaning liquid 216.

On the other hand, in order to remove foreign matter, thickening ink, air bubbles, etc. in the nozzle, the suction pump 220 of the maintenance / recovery mechanism 81 is driven, and a head suction operation of sucking a certain amount of ink from the nozzle of the recording head 34 to be cleaned is performed. Do (S5). After the head suction operation, unnecessary ink adheres to the nozzle surface or the meniscus of the nozzle is broken. Therefore, after decapping the first cap 82 (S6), the carriage 33 is moved by the wiper blade 83. The nozzle surface is wiped (S7) to wipe off the ink and form a meniscus of the nozzle. Here, just before the end of wiping, the wiper cam 224 of the maintenance / recovery mechanism 81 is rotated to lower the wiper blade 83. Further, the wiper cleaner 86 presses the wiper blade 83 against the wiper cleaner portion 85 by the cleaner cam 228 that rotates at the same time. As a result, the ink adhering to the wiper blade 83 is scraped off by the wiper cleaner portion 85 of the empty ejection receiving portion 84 and collected by the empty ejection receiving portion 84.

Subsequently, after moving the carriage 33 to retract the recording head 34 to be cleaned to the print area side (S8), the suction pump 220 of the maintenance / recovery mechanism 81 is operated again (S9), and the first suction cap is used. The ink and the like remaining inside the 82a are sucked up.

Further, in the case of the recording head 34 having nozzle rows for different colors, inks of other colors adhering to the wiper blade 83 are mixed in the nozzles at the time of wiping. Therefore, the recording head 34 to be cleaned is moved to the maintenance position (position facing the suction first cap 82a) again (S10), and the recording head 34 is driven to suck the ink in the nozzle to the suction first cap 82a. Empty discharge is performed (S11).

After that, the carriage 33 is moved to retract the recording head 34 to be cleaned to the print area side (S12), and then the suction pump 220 of the maintenance / recovery mechanism 81 is operated again (S13), and the suction first cap 82a is used. It sucks up the ink etc. that was ejected empty inside the carriage. Then, capping is performed by the first cap 82 (S14), and cleaning is completed.

In addition, the cleaning sequence is automatically activated during the printing operation in order to prevent ejection defects such as ink non-ejection (print omission) from entering the nozzle due to mist and paper dust generated during printing. There is automatic cleaning to let you. In automatic cleaning, for example, the amount of ink ejected from the nozzle (ink consumption) is cumulatively counted by soft counting, counting from the end of cleaning, and when the count value exceeds a specified threshold (mainly due to mist). It is activated when (the purpose of preventing print omission) or when the cumulative number of printed sheets exceeds the specified threshold value (the purpose of preventing print omission due to paper dust).

Next, the operation of wiping performed during cleaning will be described with reference to FIGS. 9 to 12.
FIG. 9 is an explanatory diagram showing the positional relationship between the recording head and the wiper blade before wiping.
FIG. 10 is an explanatory diagram showing the positional relationship between the recording head and the wiper blade during wiping.
FIG. 11 is an explanatory diagram showing the positional relationship between the recording head and the wiper blade just before the end of wiping.
FIG. 12 is an explanatory diagram showing the positional relationship between the recording head and the wiper blade at the end of wiping.

As shown in FIG. 9, the wiper is shown in FIGS. 10 and 11 after the wiper blade 83 is made to stand by at the position where the wiper blade 83 is raised via the wiper cam 224 by driving the motor 231 of the maintenance / recovery mechanism 81 in advance, as shown in FIG. As described above, the carriage 33 is moved and the nozzle surface is wiped by the wiper blade 83. At this time, the edge portion of the wiper blade 83 slides in close contact with the nozzle surface, so that the ink or the like adhering to the nozzle surface is attracted to one side after the head suction operation. At the end of wiping, as shown in FIG. 12, the wiper blade 83 to which the ink or the like adheres on the nozzle surface is lowered to remove the ink or the like from the nozzle surface.

Next, the elevating mechanism of the first cap 82 will be described with reference to FIG.
FIG. 13 is an explanatory diagram showing an elevating mechanism of the first cap 82.
The first cap 82 is held so as to be vertically movable with respect to the second cap 212, and the first cap 82 is held between the first cap 82 and the second cap 212 with respect to the second cap 212. A spring 301 is interposed as an urging means for urging the cap 82 upward (nozzle surface side).

The second cap 212 is held by the slider 302 so as to be movable in the front-rear direction (nozzle arrangement direction of the nozzle row of the recording head 34) which is the sub-scanning direction (left-right direction in FIG. 13). The slider 302 is slidably fitted into the guide groove 306 formed in the frame 211 by the guide pins 304 and 305 provided at the front and rear ends, and the slider 302 and the second are provided by the cap cam 222 connected to the slider 302. The cap 212 and the first cap 82 are configured to move up and down integrally.

Guide pins 310 and 311 are provided at both ends of the first cap 82 in the sub-scanning direction, and the guide pins 310 and 311 are provided in engagement holes 312 and 313 such as recesses or grooves formed in the second cap 212. Engaged. Further, a guide shaft 315 is provided on the bottom surface of the first cap 82, and the guide shaft 315 is inserted into the guide hole of the second cap 212 so as to be vertically movable. As a result, the first cap 82 is held so as to be movable up and down with respect to the second cap 212. The spring 301 interposed between the first cap 82 and the second cap 212 urges the first cap 82 to the upper side (the side that presses the first cap 82 against the nozzle surface during capping).

The flexible tube 219 connected to the first suction cap 82a passes through the insertion holes of the slider 302 and the second cap 212, and is capped with respect to the lateral direction (main scanning direction) of the first suction cap 82a. It is connected from below the suction first cap 82a to a position deviated from the center position in the longitudinal direction (secondary scanning direction) of the suction first cap 82a at the center position.

Next, the cleaning operation with the cleaning liquid 216 in the present embodiment will be described.
FIG. 14 is an explanatory diagram showing the positional relationship between the recording head 34 and the first cap 82 and the second cap 212 in a state immediately before the carriage 33 moves to the head cap position and starts capping. (B) is an explanatory diagram showing the positional relationship between the recording head 34 and the first cap 82 and the second cap 212 in a state where the first cap 82 is capped and the second cap 212 is not covered on the nozzle surface. (C) is an explanatory diagram showing the positional relationship between the recording head 34 and the first cap 82 and the second cap 212 in a state where the second cap 212 is not covered on the nozzle surface after the capping of the first cap 82. ..

In the present embodiment, as described above, the cleaning liquid 216 is housed inside the second cap 212. The first cap 82 has a nozzle surface contact point that contacts the nozzle surface of the first cap 82 when the second cap 212 is detached from the nozzle surface, as shown in FIGS. 14 (a) and 14 (b). (The edge of the opening of the first cap 82) is configured to be located above the liquid level of the cleaning liquid 216 filled inside the second cap 212. Specifically, the first cap 82 is urged upward (nozzle surface side) with respect to the second cap 212 by the spring 301, and the nozzle surface contact point of the first cap 82 is inside the second cap 212. It is maintained at a position above the liquid level of the cleaning liquid 216. This prevents the cleaning liquid 216 in the second cap 212 from entering the inside of the first cap 82. As a result, it is possible to suppress a situation in which the cleaning liquid 216 that has entered the inside of the first cap 82 enters the inside of the nozzle 34A when the nozzle 34A is capped by the first cap 82.

In the present embodiment, the cap cam 222 is rotated by the drive of the motor 231 to raise the second cap 212 and also raise the first cap 82 held by the second cap 212. At this time, the nozzle surface contact portion of the first cap 82 held by the second cap 212 is located above the liquid level of the cleaning liquid 216 in the second cap 212 by the spring 301 as described above. , As shown in FIG. 14B, the first cap 82 comes into contact with the nozzle surface in advance and caps the nozzle 34A. As a result, the first cap 82 prevents the cleaning liquid 216 from coming into contact with the nozzle 34A prior to the nozzle surface coming into contact with the cleaning liquid 216 in the second cap 212.

When the cap cam 222 is further rotated by the drive of the motor 231 the second cap 212 is further raised against the urging force of the spring 301, and as shown in FIG. 14 (c), the second cap 212 is the recording head 34. It is covered so as to cover the nozzle surface and the side surface of the. As a result, the cleaning liquid 216 inside the second cap 212 comes into contact with the nozzle surface and side surface of the recording head 34, and the ink adhering to the nozzle surface and side surface of the recording head 34 is cleaned by the cleaning liquid 216.

On the other hand, at the time of decapping, the cap cam 222 is rotated by the drive of the motor 231 from the state shown in FIG. 14C, and the second cap 212 is lowered. At this time, the first cap 82 is in the state shown in FIG. 14 (b) when the second cap 212 is lowered while the state in which the nozzle 34A is capped by the urging force of the spring 301 is maintained. After that, when the cap cam 222 is further rotated by the drive of the motor 231, the second cap 212 is further lowered, and the first cap 82 is also lowered accordingly. As a result, the first cap 82 is separated from the nozzle surface, the nozzle 34A is decapped, and the state shown in FIG. 14A is obtained.

The second cap 212 in the present embodiment has a size capable of accommodating the two recording heads 34a and 34B together, and the cleaning liquid 216 can be brought into contact with the nozzle surfaces of the recording heads 34a and 34B at the same time. A separate second cap 212 may be provided for each of the recording heads 34a and 34B. Further, as shown in FIGS. 15A and 15B, the first caps 82a and 82b are individually attached to each nozzle 34A on all the nozzle surfaces that are brought into contact with the cleaning liquid inside the second cap 212 at once. It is provided in. However, two or more nozzles 34A may be capped with one first cap 82.

Next, the configuration and operation of stirring the cleaning liquid 216 with the first cap 82 will be described.
16 (a) and 16 (b) are explanatory views showing a configuration and an operation of stirring the cleaning liquid 216 by the first cap 82.
The cleaning liquid 216 in the second cap 212 has a different degree of contamination (ink concentration) depending on the location in the second cap 212, depending on the ink color and frequency of use of the nozzle 34A on the nozzle surface in contact with the cleaning liquid 216. Therefore, the cleaning performance of the cleaning liquid portion having a high ink concentration and a high degree of contamination deteriorates at an early stage as compared with other cleaning liquid portions. At this time, for example, when the condition that the concentration of the ink content of the cleaning liquid 216 is equal to or higher than the specified concentration (for example, 50%) is adopted as the cleaning liquid replacement condition of the cleaning liquid 216 in the second cap 212, the ink content of the cleaning liquid 216 is adopted. The frequency of replacement of the cleaning liquid changes depending on the location where the concentration of ink is detected.

For example, when detecting the cleaning liquid part in a place that is easily contaminated (a place where the concentration of ink is likely to be high), the cleaning liquid is replaced too frequently, and the cleaning liquid part (cleaning liquid with less dirt) that can still exhibit sufficient cleaning performance is exhibited. As a result of replacing the part) together, the consumption of the cleaning liquid increases. On the other hand, on the contrary, when the cleaning liquid part in a place where it is hard to get dirty (a place where the concentration of ink is hard to be high) is detected, the cleaning liquid is replaced too infrequently and the cleaning liquid part is dirty and the cleaning performance is deteriorated (the cleaning liquid part). As a result of continued use of the cleaning liquid part with a lot of dirt, cleaning failure occurs.

In the present embodiment, as described above, during the capping operation and the decapping operation, as shown in FIGS. 16A and 16B, the first cap 82 is relative to the second cap 212. Moving. At this time, the first cap 82 moves relative to the cleaning liquid 216 in the second cap 212, so that the cleaning liquid in the second cap 212 is agitated. As a result, the concentration of the ink content of the cleaning liquid 216 in the second cap 212 is made uniform, and by replacing the cleaning liquid at an appropriate time, it is possible to suppress the occurrence of cleaning defects without increasing the consumption of the cleaning liquid. Further, even when the condition that the concentration of the ink content of the cleaning liquid 216 is equal to or higher than the specified concentration (for example, 50%) is adopted as the cleaning liquid replacement condition of the cleaning liquid 216 in the second cap 212, the concentration of the ink content of the cleaning liquid 216 is adopted. The frequency of replacement of the cleaning liquid does not change depending on the location where the ink is detected.

Moreover, as shown in FIGS. 16A and 16B, the first cap 82 moves in the cleaning liquid 216 in the second cap 212 during the capping operation or the decapping operation, so that the cleaning liquid 216 Flows. Since the cleaning liquid 216 that flows in this way can be brought into contact with the nozzle surface and the side surface of the recording head 34, the removal performance of the adhered ink is higher than that of the case where the cleaning liquid 216 that does not flow is brought into contact with the nozzle surface and the side surface of the recording head 34. Is improved.

FIG. 17 is an explanatory diagram showing an example of the shape of the first cap 82 for increasing the stirring capacity of the cleaning liquid 216 in the second cap 212.
The first cap 82 shown in FIG. 17 includes a cap portion 82A that covers the nozzle 34A on the nozzle surface and a stirring portion 82B that agitates the cleaning liquid 216 inside the second cap 212. The cap portion 82A is formed of an elastic body and has a structure having high adhesion to the nozzle surface. The stirring portion 82B is composed of a plate-shaped protruding portion protruding from the outer wall of the cap portion 82A in a direction intersecting the relative movement direction (vertical movement direction) between the first cap 82 and the second cap 212. Therefore, when viewed from the relative movement direction between the first cap 82 and the second cap 212, the area surrounded by the outer edge of the stirring portion 82B is larger than the area surrounded by the outer edge of the cap portion 82A. Has been done. That is, when viewed from the relative moving direction between the first cap 82 and the second cap 212, the area surrounded by the outer edge has a relationship of nozzle row <cap portion <stirring portion of the recording head 34.

When the first cap 82 provided with such a stirring unit 82B moves relative to the cleaning liquid 216 in the second cap 212, the cleaning liquid 216 in contact with the stirring unit 82B is pushed up or pushed down, whereby the cleaning liquid is large in the whole cleaning liquid. It creates a flow and can stir the cleaning liquid 216 in the second cap 212 with a high stirring capacity.

FIG. 18 is an explanatory diagram showing another example of the shape of the first cap 82 for increasing the stirring capacity of the cleaning liquid 216 in the second cap 212.
The example shown in FIG. 18 is an example in which the stirring unit 82B is a propeller-like member. Due to the propeller shape, the first cap 82 moves relative to the cleaning liquid 216 in the second cap 212, so that the cleaning liquid 216 flows in a certain direction along the surface of the propeller, thereby causing the cleaning liquid. A large flow can be generated as a whole, and the cleaning liquid 216 in the second cap 212 can be agitated with a high stirring capacity.

FIG. 19 is an explanatory diagram showing a state in which the second cap 212 is in the process of rising or falling.
As shown in FIG. 19, the inner wall surface of the second cap 212 is formed so as to taper from the cleaning liquid 216 toward the liquid surface of the cleaning liquid 216. As a result, when the cleaning liquid 216 flows, such as when the second cap 212 rises or falls, it is possible to create a flow of the cleaning liquid that directs the cleaning liquid portion near the upper part of the inner wall surface toward the nozzle surface or the side surface of the recording head 34. Due to such a flow, the cleaning liquid in contact with the nozzle surface and the side surface of the recording head 34 can be given momentum, and higher removal performance can be exhibited. In particular, since the cleaning liquid 216 can create a flow that hits the side surface of the recording head 34, the removal performance of the ink adhering to the side surface of the recording head 34 is improved.

Next, the capping sequence in this embodiment will be described.
FIG. 20 is a flowchart showing the flow of the capping sequence.
When the capping sequence is started, first, the carriage 33 is moved in the main scanning direction so as to move the nozzles of all the recording heads 34 to a position where capping is possible (S21). Further, the inkjet recording device 1 of the present embodiment includes a measuring means for measuring the decap time when the cleaning liquid is separated from the nozzle surface. In the present embodiment, the time from the start (or end) of the decap sequence of the recording head 34 to the start (or end) of the next capping sequence is measured as the decap time. Then, the waiting time x and the number of ascending / descending times y are determined according to the decap time (S22). The measurement of the decap time is reset at the end of the capping sequence.

Next, the motor 231 is driven to raise the second cap 212 via the cap cam 222, whereby the second cap 212 and the first cap 82 are raised (S23). After that, first, the first cap 82 comes into contact with the nozzle surface of the recording head 34, and is capped so as to cover the nozzle 34A on the nozzle surface with the first cap 82 (S24). After that, the second cap 212 is further raised to cover the nozzle surface and the side surface of the recording head 34 (S25). As a result, the nozzle surface portion excluding the nozzle 34A and the side surface of the recording head 34 come into contact with the cleaning liquid 216, and the adhering ink is removed by the cleaning liquid 216.

After performing the capping in this way, in the present embodiment, it is determined whether or not the predetermined cleaning liquid replacement condition is satisfied (S26). When, for example, a condition that the number of capping operations has reached a specified number of times (for example, 20 times) or more is adopted as a predetermined cleaning liquid replacement condition, a counting means for counting the number of capping operations is provided and the count value (for example). It is determined whether or not the number of capping operations) has reached the specified number of times. Further, as a predetermined cleaning liquid replacement condition, for example, when the condition that the concentration of the ink content in the cleaning liquid 216 inside the second cap 212 becomes a specified concentration (for example, 50%) or more is adopted, the condition in the cleaning liquid 216 is adopted. A density detecting means for detecting the density of the ink component is provided, and it is determined whether or not the detection result (the density of the ink component in the cleaning liquid 216) of the density detecting means is equal to or higher than the specified density.

When it is determined that the predetermined cleaning liquid replacement condition is satisfied (Yes in S26), the control unit 230 controls the waste liquid pump 218 to discharge the cleaning liquid 216 inside the second cap 212 (S27), and the cleaning liquid supply pump. 213 is controlled to supply a new cleaning liquid 216 to the inside of the second cap 212 (S28).

On the other hand, when it is determined that the predetermined cleaning liquid replacement condition is not satisfied (No in S26), the standby time x determined in the above-mentioned processing step S22 is waited (S29). The longer the decap time when the cleaning liquid is away from the nozzle surface, the higher the viscosity of the ink adhering to the nozzle surface and the like, and the more difficult it is to remove the adhering ink. Therefore, it is necessary that the longer the decap time is, the longer the cleaning liquid 216 is brought into contact with the adhered ink, and the ink is sufficiently softened or melted to be easily removed even if the decap time is long. Therefore, the longer the decap time is, the longer the waiting time x is set, and the cleaning liquid 216 is kept in contact with the nozzle surface and the side surface of the recording head. Ensure a good contact time.

After waiting in this way, next, in order to remove the adhered ink, the second cap 212 is raised and lowered by the number of raising and lowering times y determined in the above-mentioned processing step S22 (S30). At this time, the second cap 212 is moved up and down while maintaining the state in which the nozzle 34A is capped by the first cap 82. As a result, the first cap 82 moves relative to the cleaning liquid 216 in the second cap 212, the cleaning liquid in the second cap 212 flows, and the ink adhering to the nozzle surface and the side surface of the recording head 34 is the cleaning liquid. Removed by 216.

As described above, the longer the decap time when the cleaning liquid is away from the nozzle surface, the higher the viscosity of the ink adhering to the nozzle surface and the like, and the more difficult it is to remove the adhered ink. Therefore, as the decap time is longer, the number of ascending / descending times y is increased, the cleaning liquid 216 is made to flow more, and higher removal performance is produced. As a result, it is possible to remove the adhered ink having a high viscosity increase.

When the cleaning with the cleaning liquid 216 is completed in this way, finally, the concentration of the ink contained in the cleaning liquid 216 in the second cap 212 is detected, and it is determined whether or not the detected concentration is equal to or higher than the specified concentration. (S31). At this time, if it is determined that the concentration is equal to or higher than the specified concentration (No in S31), the control unit 230 controls the waste liquid pump 218 to discharge the cleaning liquid 216 inside the second cap 212 (S27), and supplies the cleaning liquid. The pump 213 is controlled to supply a new cleaning liquid 216 to the inside of the second cap 212 (S28). Then, cleaning with the cleaning liquid 216 is executed again (S29, S30). On the other hand, when it is determined that the concentration is less than the specified concentration (Yes in S31), the capping sequence is terminated.

Table 1 below is a table showing an example of the relationship between the decap time and the waiting time x and the number of ascending / descending times y determined accordingly.
In the example of Table 1 below, the waiting time x is added by 10 seconds and the number of ascending / descending times y is added twice each time the decap time elapses. The relationship with the number of ascending / descending times y is appropriately set.

In the present specification, the "device for discharging a liquid" is a device provided with a liquid discharge head or a liquid discharge unit and driving the liquid discharge head to discharge the liquid. The device for discharging a liquid includes not only a device capable of discharging a liquid to a device to which the liquid can adhere, but also a device for discharging the liquid into the air or into the liquid.

The "device for discharging the liquid" may include means for feeding, transporting, and discharging paper to which the liquid can adhere, as well as a pretreatment device, a posttreatment device, and the like.

For example, as a "device that ejects a liquid", an image forming device that is a device that ejects ink to form an image on paper, and a three-dimensional object (three-dimensional object) are formed in layers in order to form a three-dimensional object. There is a three-dimensional modeling device (three-dimensional modeling device) that discharges the modeling liquid into the powder layer.

Further, the "device for discharging a liquid" is not limited to a device in which a significant image such as characters and figures is visualized by the discharged liquid. For example, those that form patterns that have no meaning in themselves and those that form a three-dimensional image are also included.

The above-mentioned "thing to which a liquid can adhere" means a material to which a liquid can adhere at least temporarily, such as a material to which the liquid adheres and adheres, and a material to which the liquid adheres and permeates. Specific examples include paper, recording paper, recording paper, film, recorded media such as cloth, electronic substrates, electronic components such as piezoelectric elements, powder layers (powder layers), organ models, and media such as inspection cells. Yes, and includes everything to which the liquid adheres, unless otherwise specified.

The material of the "material to which liquid can adhere" is temporary liquid such as paper, thread, fiber, cloth, leather, metal, plastic, glass, wood, ceramics, building materials such as wallpaper and flooring, and textiles for clothing. But it is good if it can be attached.

The "liquid" may have a viscosity and surface tension that can be discharged from the liquid discharge head, and is not particularly limited, but has a viscosity of 30 [mPa · s] at room temperature, under normal pressure, or by heating or cooling. It is preferable that it is as follows. More specifically, solvents such as water and organic solvents, colorants such as dyes and pigments, polymerizable compounds, resins, functionalizing materials such as surfactants, biocompatible materials such as DNA, amino acids and proteins, and calcium. , Solvents, suspensions, emulsions, etc. containing edible materials such as natural pigments, such as inks for inkjets, surface treatment liquids, components of electronic and light emitting elements, and formation of electronic circuit resist patterns. It can be used in applications such as liquids and material liquids for three-dimensional modeling. Specifically, the "liquid" includes an ink, a treatment liquid, a DNA sample, a resist, a pattern material, a binder, a modeling liquid, or a solution containing amino acids, proteins, and calcium, and a dispersion liquid.

Further, the "device for discharging the liquid" includes, but is not limited to, a device in which the liquid discharge head and the device to which the liquid can adhere move relatively. Specific examples include a serial type device that moves the liquid discharge head, a line type device that does not move the liquid discharge head, and the like.

In addition, as a "device for ejecting liquid", a treatment liquid coating device for ejecting a treatment liquid to the paper in order to apply the treatment liquid to the surface of the paper for the purpose of modifying the surface of the paper, raw materials. There is an injection granulator that granulates fine particles of raw materials by injecting a composition liquid dispersed in a solution through a nozzle.

The "liquid discharge unit" is a liquid discharge head integrated with functional parts and a mechanism, and is a collection of parts related to liquid discharge. For example, the "liquid discharge unit" includes a head tank, a carriage, a supply mechanism, a maintenance / recovery mechanism, a main scanning movement mechanism in which at least one of the configurations is combined with a liquid discharge head, and the like.

Here, the term "integration" means, for example, a liquid discharge head and a functional component, a mechanism in which the mechanism is fixed to each other by fastening, bonding, engagement, etc., or one in which one is movably held with respect to the other. include. Further, the liquid discharge head, the functional component, and the mechanism may be configured to be detachable from each other.

For example, as a liquid discharge unit, as shown in FIG. 21, there is a liquid discharge unit 440 in which a recording head 34 and a head tank 441 are integrated. Further, there is a case in which the recording head 34 and the head tank 441 are integrated by being connected to each other by a tube or the like. Here, a unit including a filter can be added between the head tank 441 and the recording head 34 of these liquid discharge units.

Further, as a liquid discharge unit, there is a unit in which a liquid discharge head and a carriage are integrated.

Further, there is a liquid discharge unit in which the liquid discharge head and the scanning movement mechanism are integrated by holding the liquid discharge head movably by a guide member constituting a part of the scanning movement mechanism. Further, as shown in FIG. 22, there is a liquid discharge unit in which the recording head 34, the carriage 33, and the main scanning movement mechanisms 102, 107 to 109 are integrated.

Further, as a liquid discharge unit, there is a carriage to which a liquid discharge head is attached, in which a cap member which is a part of the maintenance / recovery mechanism is fixed, and the liquid discharge head, the carriage, and the maintenance / recovery mechanism are integrated. ..

Further, as a liquid discharge unit, as shown in FIG. 23, a tube is connected to a recording head 34 to which a head tank or a flow path component 444 is attached, and a liquid discharge head and a supply mechanism are integrated. be.

The main scanning movement mechanism shall include a single guide member. Further, the supply mechanism shall include a single tube and a single loading unit.

Further, in the terms of the present application, image formation, recording, printing, printing, printing, modeling, etc. are all synonymous.

What has been described above is an example, and has a unique effect in each of the following aspects.
[First aspect]
In the first aspect, a liquid ejection head (for example, a recording head 34) having a nozzle 34A for ejecting a liquid (for example, ink) on the nozzle surface and a cleaning liquid accommodating member for accommodating the cleaning liquid 216 and applying the cleaning liquid to the nozzle surface. (For example, a second cap 212) is provided, and when the cleaning liquid inside the cleaning liquid accommodating member is brought into contact with the nozzle surface, a contact preventing means (for example, the first) for preventing the cleaning liquid from coming into contact with the nozzle on the nozzle surface. A device for ejecting a liquid (for example, an inkjet recording device 1), which comprises a cap 82).
In this embodiment, even when the cleaning liquid inside the cleaning liquid accommodating member is brought into contact with the nozzle surface, the contact preventing means prevents the cleaning liquid from coming into contact with the nozzle on the nozzle surface. Therefore, the cleaning liquid does not enter the inside of the nozzle, and the liquid inside the nozzle and the cleaning liquid do not mix with each other. Therefore, it is possible to solve the problem that the state of the liquid discharged from the nozzle (viscosity, solid content concentration, etc.) changes depending on the cleaning liquid. Further, since it is not necessary to perform the operation of discharging the liquid component mixed with the cleaning liquid from the nozzle before the main operation of discharging the liquid from the nozzle, the consumption of the liquid can be suppressed. Therefore, it is possible to solve various problems caused by the mixture of the liquid inside the nozzle and the cleaning liquid.

[Second aspect]
The second aspect is characterized in that, in the first aspect, the contact prevention means is a cap member (for example, a first cap 82) that is arranged inside the cleaning liquid accommodating member and caps the nozzle on the nozzle surface. It is something to do.
In this embodiment, it is possible to prevent the cleaning liquid from coming into contact with the nozzle on the nozzle surface by using the cap member that caps the nozzle on the nozzle surface.

[Third aspect]
A third aspect is characterized in that, in the second aspect, the cap member caps the nozzle of the nozzle surface before the cleaning liquid comes into contact with the nozzle surface.
According to this aspect, it is possible to stably prevent the cleaning liquid from coming into contact with the nozzle on the nozzle surface.

[Fourth aspect]
A fourth aspect is characterized in that, in the second or third aspect, the cap member is released from the state in which the nozzle on the nozzle surface is capped after the cleaning liquid is separated from the nozzle surface. ..
According to this aspect, it is possible to stably prevent the cleaning liquid from coming into contact with the nozzle on the nozzle surface.

[Fifth aspect]
A fifth aspect is characterized in that, in any one of the second to fourth aspects, the cap member is configured to be movable relative to the cleaning liquid accommodating member.
According to this aspect, the cleaning liquid in the cleaning liquid accommodating member can be made to flow by the relative movement of the cap member. This makes it possible to improve the cleaning performance of the nozzle surface with the cleaning liquid and to make the concentration of the liquid such as ink mixed in the cleaning liquid in the cleaning liquid accommodating member uniform.

[Sixth aspect]
A sixth aspect is characterized in that, in the fifth aspect, the cap member includes a cap portion 82A for capping a nozzle on the nozzle surface and a stirring portion 82B for stirring the cleaning liquid inside the cleaning liquid accommodating member. Is to be.
According to this aspect, the stirring unit 82B can make the cleaning liquid in the cleaning liquid accommodating member flow more greatly.

[7th aspect]
In the seventh aspect, in the sixth aspect, the stirring portion is composed of a protruding portion protruding from the outer wall of the cap portion in a direction intersecting the relative movement direction of the cap member and the cleaning liquid accommodating member. It is characterized by being present.
According to this aspect, the flow effect of the cleaning liquid by the stirring unit 82B can be enhanced.

[8th aspect]
The eighth aspect is the sixth or seventh aspect, wherein the stirring portion is a propeller-like member.
According to this aspect, the flow effect of the cleaning liquid by the stirring unit 82B can be further enhanced.

[9th aspect]
In the ninth aspect, in any of the fifth to eighth aspects, the number of relative movements between the cap member and the cleaning liquid accommodating member (for example, the number of ascending / descending times y) according to the decap time when the cleaning liquid is away from the nozzle surface. ) Is changed.
According to this aspect, even a liquid such as ink, which has a long decap time and is difficult to clean, can be stably cleaned by flowing a large amount of the cleaning liquid.

[10th aspect]
In the tenth aspect, in any of the second to ninth aspects, when the cleaning liquid is separated from the nozzle surface, the contact point in contact with the nozzle surface is the cleaning liquid inside the cleaning liquid accommodating member. It is characterized in that it is configured to be located above the liquid level of.
According to this aspect, it is possible to prevent the cleaning liquid from entering the inside of the cap member. As a result, it is possible to prevent the cleaning liquid that has entered the inside of the cap member from coming into contact with the nozzle capped by the cap member.

[11th aspect]
The eleventh aspect is the supply means (for example, the cleaning liquid supply pump 213) for supplying the cleaning liquid to the inside of the cleaning liquid accommodating member, and the discharging means for discharging the cleaning liquid from the inside of the cleaning liquid accommodating member in any one of the first to tenth aspects. (For example, a waste liquid pump 218), and when a predetermined cleaning liquid replacement condition is satisfied, the cleaning liquid replacement operation of discharging the cleaning liquid inside the cleaning liquid accommodating member by the discharging means and supplying a new cleaning liquid by the supply means is performed. It is characterized by doing.
According to this aspect, since the cleaning liquid having deteriorated cleaning performance can be replaced with a new cleaning liquid, the cleaning performance by the cleaning liquid can be maintained for a long period of time.

[12th aspect]
In the twelfth aspect, in the eleventh aspect, the predetermined cleaning liquid replacement condition includes the condition that the concentration of the liquid contained in the cleaning liquid is equal to or higher than the specified concentration, and the cleaning liquid inside the cleaning liquid accommodating member is applied to the nozzle surface. When the above condition is satisfied after the contact with the nozzle, the liquid is discharged, which is characterized in that the cleaning liquid inside the cleaning liquid accommodating member is brought into contact with the nozzle surface again after the cleaning liquid replacement operation is performed.
According to this aspect, it is possible to suppress the occurrence of cleaning defects due to the cleaning liquid having deteriorated cleaning performance.

[13th aspect]
A thirteenth aspect is characterized in that, in any one of the first to twelfth aspects, the inner wall surface of the cleaning liquid accommodating member is formed so as to taper from the cleaning liquid toward the liquid surface of the cleaning liquid. Is.
According to this aspect, it is possible to improve the cleaning performance by the cleaning liquid.

[14th aspect]
In the fourteenth aspect, in any of the first to thirteenth aspects, the time for the cleaning liquid inside the cleaning liquid accommodating member to come into contact with the nozzle surface is changed according to the decap time when the cleaning liquid is away from the nozzle surface. It is characterized by that.
According to this aspect, even a liquid such as ink, which has a long decap time and is difficult to clean, can be stably cleaned.

1: Inkjet recording device 33: Carriage 34: Recording head 34A: Nozzle 35: Sub tank 36: Supply tube 81: Maintenance / recovery mechanism 82: First cap 82A: Cap unit 82B: Stirring unit 83: Wiper blade 84: Empty discharge receiving unit 85: Wipe cleaner 86: Wipe cleaner 87: Carriage lock 88: Empty discharge receiving part 89: Opening 211: Frame 212: Second cap 213: Cleaning liquid supply pump 214: Cleaning liquid supply tube 215: Cleaning liquid storage tank 216: Cleaning liquid 217 : Cleaning liquid Waste liquid tube 218: Waste liquid pump 219: Flexible tube 220: Suction pump 221: Camshaft 222: Cap cam 224: Wiper cam 226: Coro 228: Cleaner cam 229: Carriage lock cam 230: Control unit 231: Motor 232: Motor gear 233: Pump gear 234: First intermediate gear 235: Second intermediate gear 236: Third intermediate gear 238: Fourth intermediate gear 239: Fifth intermediate gear 240: Cam gear 241: Intermediate shaft 301: Spring 302: Slider 304: Guide Pin 305: Guide pin 306: Guide groove 310: Guide pin 311: Guide pin 312: Engagement hole 313: Engagement hole 315: Guide shaft 341: Wiper holder 342: Guide pin 343: Guide pin 345: Guide member 346: Guide groove 347: Stopper 348: Flexible member 349: Cam pin

Japanese Unexamined Patent Publication No. 2013-1768898

Claims (16)

A liquid discharge head having a nozzle for discharging liquid on the nozzle surface,
A cleaning liquid accommodating member for accommodating the cleaning liquid and applying the cleaning liquid to the nozzle surface is provided.
It has a contact preventing means for preventing the cleaning liquid from coming into contact with the nozzle on the nozzle surface when the cleaning liquid inside the cleaning liquid accommodating member is brought into contact with the nozzle surface.
The contact preventing means is a device for discharging a liquid, which is arranged inside the cleaning liquid accommodating member and is a cap member for capping a nozzle on the nozzle surface . In the device for discharging the liquid according to claim 1 ,
The cap member is a device for discharging a liquid, which comprises capping a nozzle on the nozzle surface before the cleaning liquid comes into contact with the nozzle surface. In the device for discharging the liquid according to claim 1 or 2 .
The cap member is a device for discharging a liquid, characterized in that the capped state of the nozzle on the nozzle surface is released after the cleaning liquid is separated from the nozzle surface. The device for discharging the liquid according to any one of claims 1 to 3 .
The cap member is a device for discharging a liquid, which is configured to be movable relative to the cleaning liquid accommodating member. In the device for discharging the liquid according to claim 4 ,
The cap member is a device for discharging a liquid, comprising: a cap portion for capping a nozzle on the nozzle surface and a stirring portion for stirring the cleaning liquid inside the cleaning liquid accommodating member. In the device for discharging the liquid according to claim 5 ,
The stirring portion discharges a liquid characterized by being composed of a protruding portion protruding from the outer wall of the cap portion in a direction intersecting the relative moving direction of the cap member and the cleaning liquid accommodating member. Device. In the device for discharging the liquid according to claim 5 or 6 .
The stirring unit is a device for discharging a liquid, which is a propeller-like member. In the device for discharging the liquid according to any one of claims 4 to 7 .
A device for discharging a liquid, which changes the number of relative movements between the cap member and the cleaning liquid accommodating member according to the decap time when the cleaning liquid is away from the nozzle surface. The device for discharging the liquid according to any one of claims 1 to 8 .
The cap member is configured such that when the cleaning liquid is separated from the nozzle surface, the contact point in contact with the nozzle surface is located above the liquid surface of the cleaning liquid inside the cleaning liquid accommodating member. A device that discharges a liquid. The device for discharging the liquid according to any one of claims 1 to 9 .
A supply means for supplying the cleaning liquid to the inside of the cleaning liquid accommodating member,
It has a discharge means for discharging the cleaning liquid from the inside of the cleaning liquid accommodating member.
A device for discharging a liquid, characterized in that, when a predetermined cleaning liquid replacement condition is satisfied, a cleaning liquid replacement operation is performed in which the cleaning liquid inside the cleaning liquid accommodating member is discharged by the discharging means and a new cleaning liquid is supplied by the supply means. A liquid discharge head having a nozzle for discharging liquid on the nozzle surface,
A cleaning liquid accommodating member for accommodating the cleaning liquid and applying the cleaning liquid to the nozzle surface is provided.
A supply means for supplying the cleaning liquid to the inside of the cleaning liquid accommodating member,
A discharge means for discharging the cleaning liquid from the inside of the cleaning liquid accommodating member,
It has a contact preventing means for preventing the cleaning liquid from coming into contact with the nozzle on the nozzle surface when the cleaning liquid inside the cleaning liquid accommodating member is brought into contact with the nozzle surface.
A device for discharging a liquid, characterized in that, when a predetermined cleaning liquid replacement condition is satisfied, a cleaning liquid replacement operation is performed in which the cleaning liquid inside the cleaning liquid accommodating member is discharged by the discharging means and a new cleaning liquid is supplied by the supply means. In the device for discharging the liquid according to claim 10 or 11.
The predetermined cleaning liquid replacement condition includes a condition that the concentration of the liquid contained in the cleaning liquid is equal to or higher than the specified concentration.
When the condition is satisfied after the cleaning liquid inside the cleaning liquid accommodating member is brought into contact with the nozzle surface, the cleaning liquid inside the cleaning liquid accommodating member is brought into contact with the nozzle surface again after performing the cleaning liquid replacement operation. A device that discharges a liquid. The device for discharging the liquid according to any one of claims 1 to 12.
The cleaning liquid accommodating member is a device for discharging a liquid, wherein the inner wall surface thereof is formed so as to taper from the cleaning liquid toward the liquid surface of the cleaning liquid. A liquid discharge head having a nozzle for discharging liquid on the nozzle surface,
A cleaning liquid accommodating member for accommodating the cleaning liquid and applying the cleaning liquid to the nozzle surface is provided.
It has a contact preventing means for preventing the cleaning liquid from coming into contact with the nozzle on the nozzle surface when the cleaning liquid inside the cleaning liquid accommodating member is brought into contact with the nozzle surface.
The cleaning liquid accommodating member is a device for discharging a liquid, wherein the inner wall surface thereof is formed so as to taper from the cleaning liquid toward the liquid surface of the cleaning liquid. The device for discharging the liquid according to any one of claims 1 to 14 .
A device for discharging a liquid, which changes the time for contacting the cleaning liquid inside the cleaning liquid accommodating member with the nozzle surface according to the time when the cleaning liquid is away from the nozzle surface. A liquid discharge head having a nozzle for discharging liquid on the nozzle surface,
A cleaning liquid accommodating member for accommodating the cleaning liquid and applying the cleaning liquid to the nozzle surface is provided.
It has a contact preventing means for preventing the cleaning liquid from coming into contact with the nozzle on the nozzle surface when the cleaning liquid inside the cleaning liquid accommodating member is brought into contact with the nozzle surface.
A device for discharging a liquid, which changes the time for contacting the cleaning liquid inside the cleaning liquid accommodating member with the nozzle surface according to the time when the cleaning liquid is away from the nozzle surface.

Images