JP2009143046A - Maintenance method for fluid injector, and fluid injector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a maintenance method for a fluid injector and the fluid injector, capable of avoiding a fluid from being wasted uselessly in an initial filling operation. <P>SOLUTION: A state is held between a plurality of fluid flow parts under the condition where a uniform pressure is applied, because a valve is closedly held for a fixed time, after a communication passage is decompressed under a valve-opened state to supply the fluid in the midway of each fluid flow part. Positions of tips of the fluid are thereby aligned in a substantially equal distance with respect to a width-widened part after the fixed time lapses. The fluid is supplied to the width-widened part respectively from the state with the substantially equal distance with respect to the width-widened part, since a negative pressure is accumulated thereafter in the communication passage, to open the valve. A dispersion of a filling speed for the fluid is hardly generated because less affected by pipe resistance of a fluid flow passage or the like, compared with a case of supplying directly the fluid from a fluid storage part, and the dispersion of the filling speed for the fluid is hardly generated by this manner. A decompression operation or the like for eliminating the dispersion, for example, is not thereby required frequently to avoid the fluid from being wasted uselessly. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a maintenance method for a fluid ejecting apparatus and a fluid ejecting apparatus.

  As a fluid ejecting apparatus that ejects a fluid, for example, an ink jet recording apparatus is known. An ink jet recording apparatus is an apparatus that records characters, images, and the like on a recording medium, and is configured such that ink is ejected onto a recording medium from nozzles provided on a recording head (ejection head). In particular, a so-called off-carriage type printer is known in which a large-capacity ink cartridge is arranged at a position away from the ejection head and ink is supplied from the ink cartridge to the ejection head via a supply pipe (for example, a patent) Reference 1).

  An off-carriage type printer is an operation that fills a series of flow paths (hereinafter collectively referred to as a communication path) such as a supply tube and a subtank from an ink cartridge (initial filling) when it is first used after being shipped. Operation). Generally, in the initial filling operation, the inside of the cap is decompressed while the nozzle surface of the recording head is sealed with the cap, and ink is filled by sucking the ink in the communication path from the nozzle side.

  What is important in the initial filling operation is that bubbles (air layers) do not remain in the communication path. However, as in Patent Document 1, an off-carriage type printer having a very long supply tube is affected by ink movement resistance, so that a sufficient flow rate for eliminating bubbles is obtained. Is difficult. In particular, when the widened portion of the supply tube such as a sub tank is provided, air bubbles (air layer) tend to remain in the widened portion due to the structure, which is a major factor that hinders ink filling.

  On the other hand, in the initial filling method according to Patent Document 1, a so-called choke suction operation is performed. The choke suction operation is an operation of increasing the negative pressure on the downstream side of the on-off valve by performing the suction operation with the on-off valve closed. When the on-off valve is opened from the state where the negative pressure is increased by the choke suction operation, the air in the sub tank can be discharged and ink can be efficiently filled into the supply flow path.

When the choke suction operation is performed for a plurality of supply tubes, the ink moving speed is often different for each supply tube, and the filling speed varies. In order to eliminate this variation, the actual situation is that the suction operation is performed a plurality of times after the choke suction operation. According to such a series of filling operations including a plurality of suction operations, the flow of ink can be changed in a pulsating manner, so that bubbles can be efficiently discharged.
JP 2006-137181 A

  However, in the filling method as described above, the suction operation is performed in accordance with the ink supply from the supply tube having a low filling speed, that is, even when the ink from the supply tube having a high filling speed is completely filled. Since the suction operation is performed until the ink from the supply tube is filled, a part of the ink supplied from the supply tube having a high filling speed is discharged from the nozzle by the suction and discarded. .

  In view of the circumstances as described above, an object of the present invention is to provide a maintenance method of a fluid ejecting apparatus and a fluid ejecting apparatus that can avoid waste of fluid in an initial filling operation.

  In order to achieve the above object, a maintenance method for a fluid ejection device according to the present invention includes an ejection head that ejects fluid from a nozzle opening, a fluid storage section that stores the fluid, and the fluid storage section that is connected to the ejection head. And a plurality of fluid circulation portions for circulating the fluid between the nozzle openings, a valve provided on the upstream side of the fluid circulation portion, and a widening portion provided on the downstream side of the fluid circulation portion. In the maintenance method of the fluid ejecting apparatus, the nozzle opening, the ejection head, the widening portion, the plurality of fluid circulation portions, and the fluid storage portion are communication paths, and the pressure reducing means for decompressing the communication paths is provided. A first step of depressurizing the communication path with the valve opened and supplying the fluid partway through the plurality of fluid circulation portions; and after supplying the fluid, the valve A second step of closing, a third step of reducing the communication passage more greatly than the pressure reduction in the first step with the valve closed after the valve is closed; and after the pressure reduction of the communication passage, the valve And a fourth step of releasing.

  According to the present invention, in order to open the valve by depressurizing the communication path in a state where the valve is opened and supplying the fluid to the middle of the fluid circulation part, then closing the valve, and then accumulating negative pressure in the communication path. The fluid is supplied to the widened portion from a state that is approximately equidistant from the widened portion. Compared with the case where the fluid is directly supplied from the fluid storage part, the influence of the pipe resistance of the fluid circulation part is reduced, so that the fluid filling speed is less likely to vary. Thereby, for example, it is not necessary to repeatedly perform a pressure reducing operation for eliminating variations, and waste of fluid can be avoided.

The maintenance method for the fluid ejecting apparatus is characterized in that, in the first step, the fluid is supplied to an upstream side of the widened portion of the fluid circulation portion.
According to the present invention, since the fluid is supplied to the upstream side from the widened portion of the fluid circulation portion, the fluid can be supplied to the nozzle opening from a state where there is a fluid at a short distance to the widened portion. Thereby, the variation in the filling speed of the fluid can be eliminated.

The maintenance method for the fluid ejecting apparatus is characterized in that, in the second step, the state where the valve is closed is maintained for a certain period.
According to the present invention, since a uniform pressure is applied between the plurality of fluid circulation portions, the position of the tip of the fluid is substantially equidistant with respect to the widened portion after a predetermined time has elapsed. It will be. Thereby, since the start line of the movement of the fluid when the valve is opened in the fourth step is aligned, the occurrence of variations in the fluid filling speed can be more reliably suppressed.

The maintenance method for the fluid ejecting apparatus includes the fifth step of closing the valve after opening the valve in the fourth step, and the communication path with the valve closed after the valve is closed. The method further includes a sixth step of reducing the pressure and holding the valve for a certain period, and a seventh step of opening the valve after the pressure is reduced and held for a certain period.
According to the present invention, after the fourth step, the valve is closed (fifth step), and in this state, the communication path is decompressed and held for a certain period (sixth step), and then the valve is opened (seventh step). Therefore, the air layer (bubbles or the like) generated in the widened portion can be drawn into the ejection head, and the fine bubbles can be combined and enlarged. If there is an air layer in the widened portion, the flow of fluid into the widened portion and into the ejection head is hindered. In the present invention, since the air layer can be drawn together to the ejection head, it is possible to prevent the fluid flow from being hindered.

The maintenance method for the fluid ejecting apparatus is characterized by repeatedly performing the fifth step to the seventh step.
According to the present invention, since the fifth step to the seventh step are repeated, the air layer drawn into the ejection head can be further drawn toward the nozzle opening side. When the fifth step to the seventh step are repeatedly performed, the conditions such as the suction strength may be changed.

The maintenance method of the fluid ejecting apparatus further includes an eighth step of decompressing the communication path in a state where the valve is opened after the communication path is decompressed in the seventh step.
According to the present invention, after the seventh step, the communication path is depressurized (eighth step) with the valve opened, so that the ejection head is filled with fluid with almost no air layer mixed therein. Can do.

The maintenance method for the fluid ejecting apparatus is characterized by repeating the eighth step.
According to the present invention, since the eighth step is repeatedly performed, minute bubbles in the nozzle opening can be discharged, and the meniscus can be adjusted. When the eighth step is repeatedly performed, the conditions such as the suction strength may be changed.

The maintenance method for the fluid ejecting apparatus is characterized in that after opening the valve, the outside of the nozzle opening in the ejecting head is cleaned.
According to the present invention, after the valve is opened in the seventh step, the eighth step, and the ninth step, the outside of the nozzle opening in the ejection head is cleaned. Even when the fluid has been ejected to the outside, the outside of the nozzle opening can be kept clean.

  The fluid ejection device according to the present invention includes: an ejection head that ejects fluid from a nozzle opening; a fluid storage portion that stores the fluid; and the fluid that is connected to the ejection head and between the fluid storage portion and the ejection head. A plurality of fluid circulation portions that circulate, a valve provided on the upstream side of the fluid circulation portion, and a widening portion provided on the downstream side of the fluid circulation portion, the nozzle opening, in the ejection head The fluid widening section, the plurality of fluid circulation sections, and the fluid storage section serve as communication paths, and have a pressure reducing means for reducing the pressure of the communication paths. A controller is provided that controls the pressure of the passage to supply the fluid halfway through the plurality of fluid circulation portions and to open the valve after the supply of the fluid.

  According to the present invention, in order to open the valve by depressurizing the communication path in a state where the valve is opened and supplying the fluid to the middle of the fluid circulation part, then closing the valve, and then accumulating negative pressure in the communication path. The fluid is supplied to the widened portion from a state that is approximately equidistant from the widened portion. Compared with the case where the fluid is directly supplied from the fluid reservoir, the influence of the piping resistance of the fluid flow path is reduced, so that the fluid filling speed is less likely to vary. Thereby, it is possible to obtain a fluid ejecting apparatus that can avoid waste of fluid in the initial filling operation.

  Embodiments of the present invention will be described below with reference to the drawings. In the present embodiment, an ink jet printer (hereinafter referred to as printer 1) is exemplified as the liquid ejecting apparatus according to the invention.

FIG. 1 is a partially exploded view showing a schematic configuration of a printer 1 according to the present embodiment.
The printer 1 includes a printer main body 5 and a carriage 4 on which a sub tank (enlarged portion) 2 and a recording head (ejection head) 3 are mounted.

  The printer main body 5 is provided with a carriage moving mechanism 65, a capping mechanism 14 used for a cleaning operation and a moisturizing operation of the recording head 3, and an ink cartridge 6 for storing ink L supplied to the sub tank 2. . The printer body 5 is provided with a paper feed mechanism (not shown) that transports the recording paper. The paper feed mechanism is composed of a paper feed motor or the like, and the paper feed mechanism sequentially feeds the recording paper onto the platen 13 so as to be linked to the recording (printing / printing) operation. In addition, the printer body 5 is provided with a control unit 60 that comprehensively controls the operation of the printer 1.

  The carriage moving mechanism 65 is a moving mechanism that reciprocates the carriage 4 along the longitudinal direction (width direction) of the printer body 5, and includes a guide shaft 8, a pulse motor 9, and a pulse motor that are installed in the width direction of the printer body 5. The driving pulley 10 connected to the rotating shaft of the motor 9, the idle pulley 11 provided at the end in the width direction of the printer body 5, and the timing spanned between the drive pulley 10 and the idle pulley 11. A belt 12 is provided. The carriage 4 is connected to the timing belt 12. By driving the pulse motor 9, the carriage 4 reciprocates along the guide shaft 8 between the drive pulley 10 and the idle pulley 11.

  The capping mechanism 14 includes a cap member 15 and a suction pump 16. The cap member 15 is a tray-shaped member made of, for example, an elastic material such as rubber. The cap member 15 is located outside the recording area in the moving area of the carriage 4, for example, at the end of the printer body 5 (on the driving pulley 10 side). Has been placed. The place where the cap member 15 is disposed is the home position of the carriage 4. The home position is a place where the carriage 4 stands by when the printer 1 is turned off or when recording is not performed for a long time.

  The ink cartridge 6 is a fluid storage part in which ink L used for recording is stored. The ink cartridge 6 and the sub tank 2 are connected by an ink supply tube (fluid circulation part) 34. The ink L in the ink cartridge 6 is supplied to the sub tank 2 through the ink supply tube 34. A valve 34 a is provided in the vicinity of the ink cartridge 6 in the ink supply tube 34. The valve 34a is automatically opened and closed by a control device (not shown), for example. In this embodiment, since four types of ink L, black (B), cyan (C), magenta (M), and yellow (Y) are used, the ink cartridge 6, the sub tank 2, the ink supply tube 34, and the valve are used. Four sets of 34a are arranged. The configuration may be such that three or less types or five or more types of ink are used. In this case, the number of sets of the ink cartridge 6, the sub tank 2, the ink supply tube 34, and the valve 34a corresponding to the type of ink is arranged.

FIG. 2 is a cross-sectional view illustrating the configuration of the sub tank 2 and the recording head 3.
As shown in the figure, the sub tank 2 is a widened portion provided at the end of the ink supply tube 34, and is molded from a resin material such as polypropylene. The sub tank 2 has an ink chamber 27, an elastic sheet 26, a needle connection portion 28, a connection flow path 29, and a tank portion filter 30.

  The ink chamber 27 is a concave portion having a bowl shape in cross section, and is a portion that holds ink supplied from the ink supply tube 34. The ink chamber 27 is connected to an ink supply tube 34 via an ink inlet (not shown). The left side of the ink chamber 27 in the figure is formed to be narrow, and the right side in the figure is an opening.

  The elastic sheet 26 is a transparent sheet attached to the opening of the ink chamber 27. The elastic sheet 26 can be deformed in both directions of contracting the ink chamber 27 and expanding the ink chamber 27. The pressure variation of the ink L is absorbed by the deformation of the elastic sheet 26, and the ink L is supplied to the recording head 3 side in a state where the pressure variation is absorbed in the sub tank 2. Thus, the sub tank 2 functions as a pressure damper.

  The needle connection portion 28 is a portion into which the ink introduction needle 22 is inserted, and is provided so as to protrude below the sub tank 2. A seal member 31 is fitted into the needle connection portion 28. The seal member 31 is configured such that the ink introduction needle 22 is fitted in a liquid-tight manner. The connection channel 29 is a channel through which ink flows between the ink chamber 27 and the needle connection part 28. The tank filter 30 is a filter that filters ink moving from the ink chamber 27 to the connection flow path 29, and is attached to the boundary between the connection flow path 29 and the ink chamber 27.

The recording head 3 includes an introduction needle unit 17, a head case 18, a flow path unit 19, and an actuator unit 20.
The introduction needle unit 17 has an ink introduction needle 22, a filter 21, and an ink introduction path 23. The ink introduction needle 22 is a cylindrical member having a tapered upper end, and the tapered upper end is attached to the sub tank 2. At the upper end of the ink introduction needle 22, an introduction port for introducing the ink L from the sub tank 2 into the introduction needle is provided. The filter 21 is disposed so as to cover the lower end surface of the ink introduction needle 22. The ink introduction path 23 communicates with the inside of the ink introduction needle 22 via the filter 21. The lower end of the ink introduction path 23 is connected to the inside of the head case 18 via the packing 24.

FIG. 3 is a cross-sectional view showing the configuration of the head case 18 and the flow path unit 19 of the recording head 3.
As shown in the figure, the flow path unit 19 is joined to the bottom of the head case 18.

  The head case 18 is a hollow box-shaped member made of synthetic resin, and a case flow path 25 and a housing empty portion 37 are formed inside the head case 18. The case channel 25 is formed so as to penetrate the height direction of the head case 18. The upper end of the case flow path 25 communicates with the ink introduction path 23 of the introduction needle unit 17 through the packing 24. The lower end of the case flow path 25 communicates with the common ink chamber 44 in the flow path unit 19, and the ink L introduced from the ink introduction needle 22 passes through the ink introduction path 23 and the case flow path 25 to the common ink chamber 44 side. To be supplied.

  The introduction needle unit 17 is attached to the upper end surface of the accommodation hollow portion 37 with the packing 24 interposed. The actuator unit 20 is housed in the housing space 37. The actuator unit 20 includes a plurality of piezoelectric vibrators 38 arranged in a comb-like shape, a fixed plate 39 to which the piezoelectric vibrators 38 are joined, and wiring for supplying a drive signal from the printer main body side to the piezoelectric vibrators 38. It is comprised from the flexible cable 40 as a member. Each piezoelectric vibrator 38 has a fixed end portion joined to a fixed plate 39 and a free end portion protruding outward from the front end surface of the fixed plate 39, and is attached to the fixed plate 39 in a so-called cantilever state. Yes. The fixed plate 39 that supports each piezoelectric vibrator 38 is made of, for example, stainless steel having a thickness of about 1 mm. The actuator unit 20 is housed and fixed in the housing space 37 by bonding the back surface of the fixing plate 39 to the inner wall surface of the case that defines the housing space 37.

  The flow path unit 19 includes a vibration plate (sealing plate) 41, a flow path substrate 42, and a nozzle substrate 43. The diaphragm 41, the flow path substrate 42, and the nozzle substrate 43 are stacked in this order, and are joined and integrated with an adhesive (not shown). The diaphragm 41, the flow path substrate 42, and the nozzle substrate 43 are members that form a series of ink flow paths (liquid flow paths) from the common ink chamber 44 to the nozzle openings 47 through the ink supply ports 45 and the pressure chambers 46. It is. The pressure chamber 46 is formed as an elongated space in a direction orthogonal to the arrangement direction (nozzle row direction) of the nozzle openings 47. The common ink chamber 44 communicates with the case channel 25 and is a space into which the ink L from the ink introduction needle 22 side is introduced. The ink L introduced into the common ink chamber 44 is distributed to each pressure chamber 46 through the ink supply port 45.

  The nozzle substrate 43 is a plate material made of a metal such as stainless steel, for example, and has a plurality of nozzle openings 47 arranged at a pitch (for example, 180 dpi) corresponding to the dot formation density. The nozzle openings 47 are provided in a total of 22 rows corresponding to each sub tank 2. One nozzle row is composed of, for example, 180 nozzle openings 47.

  A flow path substrate 42 disposed between the nozzle substrate 43 and the vibration plate 41 is a flow path portion that becomes an ink flow path, specifically, a common ink chamber 44, an ink supply port 45, and an empty space that becomes a pressure chamber 46. It is a plate-like member in which a section is formed. The flow path substrate 42 is produced, for example, by subjecting a silicon wafer, which is a crystalline base material, to anisotropic etching. The vibration plate 41 is a double-structured composite plate material in which an elastic film is laminated on a metal support plate such as stainless steel. An island portion 48 to which the tip surface of the piezoelectric vibrator 38 is joined is formed in a portion corresponding to the pressure chamber 46 of the vibration plate 41 by removing the support plate in an annular shape by etching or the like. This island part 48 functions as a diaphragm part.

  The vibration plate 41 is configured such that the elastic film around the island portion 48 is elastically deformed in response to the operation of the piezoelectric vibrator 38, seals one opening surface of the flow path substrate 42, and the compliance portion 49. It has come to function as. As for the portion corresponding to the compliance portion 49, the support plate is removed by etching or the like as in the diaphragm portion, and only the elastic film remains.

  In the recording head 3, when a drive signal is supplied to the piezoelectric vibrator 38 through the flexible cable 40, the piezoelectric vibrator 38 expands and contracts in the longitudinal direction of the element, and accordingly, the island portion 48 approaches the pressure chamber 46. It moves in the direction or the direction away from it. The volume of the pressure chamber 46 is changed by the movement of the island portion 48, and a pressure fluctuation occurs in the ink L in the pressure chamber 46, and the ink droplet D is ejected from the nozzle opening 47 by this pressure fluctuation.

  In the printer 1 described above, the nozzle opening 47, the recording head 3, the sub tank 2, the ink supply tube 34, and the ink cartridge 6 are connected by the communication path 32 so that the pressure in the communication path 32 can be made constant. It has become.

Next, an initial filling operation of the printer 1 configured as described above will be described with reference to FIGS.
FIG. 4 is a flowchart showing a process of the initial filling operation of the printer 1. 5 to 9 are diagrams schematically showing the state of the ink cartridge 6, the ink supply tube 34, the sub tank 2, and the recording head 3 during the initial filling operation. FIG. 10 is a diagram schematically showing the state of the ink introduction needle 22 during the initial filling operation.

  Prior to the initial filling operation, the control unit 60 moves the recording head 3 to the maintenance position (home position) so that the recording head 3 and the capping mechanism 14 face each other. The recording head 3 is arranged so that the region surrounded by the cap member 15 includes the nozzle region 47R, and the lower surface 43a of the nozzle substrate 43 and the cap member 15 are brought into contact with each other. By bringing the cap member 15 into contact, the space including the nozzle region 47R is sealed.

  When the printer 1 has not been used since it was shipped, nothing is contained in the ink supply tube 34. After the sealed space is formed by the capping mechanism 14, the control unit 60 opens the valve 34a as shown in FIG.

  The control unit 60 operates the suction mechanism 16 of the capping mechanism 14 with the valve 34a opened. The communication path 32 is sucked by the operation of the suction mechanism 16 (ST01). Due to the suction of the communication path 32, the pressure is reduced from the nozzle opening 47 side into the ink supply tube 34. By reducing the pressure in the ink supply tube 34, the ink L is supplied from each ink cartridge 6 into the ink supply tube 34.

  The control unit 60 stops the suction mechanism 16 when the ink L has reached the middle of the ink supply tube 34, preferably before the sub tank 2, closes the valve 34a, and holds this state for a certain period (ST02). ). Since the communication path 32 is held in an equal pressure state, a uniform pressure (negative pressure) is applied to the ink L in the ink supply tube 34. Even when the position of the tip of the ink L varies due to the piping resistance of the ink supply tube 34 or the like, the position of the tip of the ink L moves during the holding period, and the ink supply tube 34 has a substantially uniform position. Will be aligned.

  After a certain period of time, the control unit 60 activates the suction mechanism 16. The communication path 32 is sucked by the suction mechanism 16 (ST03), and the communication path 32 is decompressed. Since the communication path 32 is sucked with the valve 34a closed (choke suction), negative pressure is accumulated in the communication path 32. After a predetermined negative pressure is accumulated in the communication path 32, the control unit 60 opens the valve 34a (ST04). When the valve 34 a is opened, the ink L held in the ink supply tube 34 is vigorously supplied into the sub tank 2 by the negative pressure accumulated in the communication path 32, and also enters the recording head 3 through the communication path 32. Ink L is supplied. The predetermined negative pressure is a negative pressure larger than the negative pressure in the communication path 32 when the communication path 32 is sucked in ST01, so that the ink L is supplied at a speed faster than the ink supply speed in ST01. Supplied. The suction / suction mechanism 16 may be stopped before opening the valve 34a, may be stopped simultaneously, or may be stopped after opening.

  When the ink L is supplied, an air layer such as bubbles may be generated in the ink L within the ink supply needle 22. The generated bubbles are floating in the ink L as shown in FIG. 10A, and do not pass through the filter 21 just by being sucked with the valve 34a opened. Therefore, after the ink L is supplied, the choke suction operation is repeated, so that the ink L passes through the filter 21 at a speed faster than the flow rate when the valve 34a is opened, thereby causing bubbles generated in the ink L as shown in FIG. It is removed by passing through the filter 21. In other words, the predetermined negative pressure accumulated during the suction of the choke is a negative pressure that can obtain a flow rate at which bubbles can pass through the filter 21. Further, the negative pressure due to the suction with the valve 34a opened is such a negative pressure that the flow rate is such that bubbles cannot pass through the filter 21.

  Prior to the choke suction, the controller 60 operates the suction mechanism 16 with the valve 34a opened, and causes the bubbles A in the ink L to adhere to the filter 21 as shown in FIG. Thereafter, the controller 60 closes the valve 34a (ST05-1), and operates the suction mechanism 16 in this state to choke the communication path 32 (ST06-1). Bubbles A adhering to the filter 21 by this suction operation are pressed against the filter 21 and are spread in the lateral direction. The expanded air bubbles A come into contact with each other, and as shown in FIG. After a predetermined negative pressure is accumulated in the communication passage 32 by the choke suction, the control unit 60 opens the valve 34a (ST07-1).

  By performing the step ST07-1, the control unit 60 causes the bubble A, which has become larger due to the coupling, to pass through the filter 21 along with the flow of the ink L as shown in FIG. Will be. The bubbles A sent out into the recording head 3 are discharged together with the ink L through the nozzle openings 47.

  After removing the bubbles in the ink L, the control unit 60 wipes the outside of the nozzle opening 47 such as the lower surface 43 a of the nozzle substrate 43. The ink attached to the outside of the nozzle opening 47 is removed by wiping. Thereafter, the controller 60 fills the ink L up to the nozzle openings 47 of the recording head 3 as shown in FIG. Specifically, the suction mechanism 16 is operated with the valve 34a opened. By the operation of the suction mechanism 16, the communication path 32 is sucked by low speed suction (ST08-1). By this suction operation, the ink L is gradually filled into the nozzle openings 47.

Wiping is performed after low speed suction, and then ST08-1 is repeated once again (ST08-2). When suction is performed in ST08-2, suction is performed at a lower speed than in the case where suction is performed in ST08-1. By performing ST08-2, bubbles at the tip of the ink L filled in the nozzle openings 47 are removed and the meniscus is adjusted. Wiping may be performed after ST08-2.
Thus, the initial filling operation is completed.

  As described above, according to the present embodiment, the communication path 32 is decompressed with the valve 34a opened, and the ink L is supplied to the front of the sub tank 2, and then the valve 34a is closed and held for a certain period of time. It is held in a state where a uniform pressure is applied between the plurality of ink supply tubes 34. For this reason, after a certain period of time has passed, the position of the tip of the ink L is substantially equidistant from the sub tank 3. Thereafter, the communication path 32 is choked and accumulated, and when the valve 34a is opened by accumulating negative pressure in the communication path 32, the ink L is applied to the recording head 3 from the state where the leading end of the ink L is substantially equidistant from the sub tank 2. Since the ink is supplied, it is possible to suppress variation in the filling speed of the ink L between the ink supply tubes 34. Accordingly, it is not necessary to repeatedly perform, for example, a pressure reducing operation for eliminating the variation thereafter, and waste of ink can be avoided.

1 is a schematic configuration diagram of a printer according to an embodiment of the present invention. FIG. 3 is a plan view of a main part around a recording head. FIG. 3 is a plan view showing a nozzle formation surface of a recording head. The flowchart which shows the step of initial filling operation | movement. Process drawing which shows the mode of initial filling operation | movement. The process drawing. The process drawing. The process drawing. The process drawing. The process drawing.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Printer (fluid ejecting apparatus) 2 ... Sub tank (widening part) 3 ... Recording head (ejection head) 6 ... Ink cartridge (fluid storage part) 14 ... Capping mechanism 15 ... Cap member 16 ... Suction mechanism 32 ... Communication path 34 ... Ink supply tube (fluid flow path) 34a ... Valve 47 ... Nozzle opening L ... Ink (fluid)

Claims (5)

An ejection head that ejects fluid from a nozzle opening;
A fluid reservoir for storing the fluid;
A plurality of fluid circulation portions connected to the ejection head and allowing the fluid to circulate between the fluid reservoir and the nozzle openings;
A valve provided on the upstream side of the fluid circulation part, and a widening part provided on the downstream side of the fluid circulation part,
A maintenance method for a fluid ejecting apparatus, wherein the nozzle opening, the ejection head, the widened portion, the plurality of fluid circulation portions, and the fluid storage portion are communication passages, and includes a decompression unit that depressurizes the communication passages. And
A first step of depressurizing the communication path in a state where the valve is opened, and supplying the fluid halfway through the plurality of fluid circulation portions;
A second step of closing the valve after supplying the fluid;
After the valve is closed, a third step of reducing the communication passage more greatly than the pressure reduction in the first step in a state where the valve is closed;
And a fourth step of opening the valve after depressurization of the communication path. A maintenance method for a fluid ejection device, comprising: The maintenance method for a fluid ejecting apparatus according to claim 1, wherein in the first step, the fluid is supplied to an upstream side of the widened portion of the fluid circulation portion. The maintenance method for the fluid ejection device according to claim 1, wherein in the second step, a state where the valve is closed is maintained for a certain period of time. A fifth step of closing the valve after opening the valve in the fourth step;
A sixth step of reducing the communication path in a state in which the valve is closed after the valve is closed, and maintaining the pressure for a certain period;
The fluid ejection device maintenance method according to claim 1, further comprising: a seventh step of opening the valve after the communication path is depressurized and held for a certain period of time. An ejection head that ejects fluid from a nozzle opening;
A fluid reservoir for storing the fluid;
A plurality of fluid circulation sections connected to the ejection head and configured to circulate the fluid between the fluid storage section and the ejection head;
A valve provided on the upstream side in the fluid circulation part;
A widened portion provided on the downstream side of the fluid circulation portion,
The nozzle opening, in the ejection head, in the widened portion, in the plurality of fluid circulation portions and in the fluid storage portion are communication passages, and is a fluid ejection device having pressure reducing means for decompressing the communication passages,
A control unit is provided that controls the pressure of the communication path to be reduced to the middle of the plurality of fluid circulation units while the valve is opened, and the valve is opened after the supply of the fluid. A fluid ejecting apparatus.

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