JP2016041489A - Liquid jet apparatus and liquid jet apparatus control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid jet apparatus and a liquid jet apparatus control method capable of preventing the occurrence of cracking in a pressure generation chamber caused by liquid expansion when a liquid is frozen.SOLUTION: A liquid jet apparatus comprises: a pressure generation chamber 12 that communicates with a nozzle 21 and that ejects a liquid within the pressure generation chamber 12 from the nozzle by a pressure variation generated by driving a driving element 300; a manifold 100 that communicates with the pressure generation chamber 12 and that supplies the liquid to the pressure generation chamber 12; ejection means that ejects the liquid in the pressure generation chamber 12 from the nozzle 21; and control means capable of selecting a mode 1 or a mode 2 and ejecting the liquid from the nozzle. In the mode 1, the liquid in the pressure generation chamber 12 is ejected from the nozzle so that the air is attracted into the pressure generation chamber 12 from the nozzle in response to the operation of the ejection means. In the mode 2, the driving element 300 is driven so that the air is not attracted into the pressure generation chamber even if the driving element is driven.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a liquid ejecting apparatus that includes a liquid ejecting head that ejects liquid from a nozzle opening, and more particularly to an ink jet recording apparatus that includes an ink jet recording head that ejects ink as a liquid and a control method for the liquid ejecting apparatus.

  As a liquid ejecting apparatus that ejects a liquid onto an ejected medium, for example, an ink jet recording apparatus that prints on an ejected medium by ejecting ink as a liquid, such as paper or a recording sheet, is known. Yes.

  An ink jet recording head mounted on such an ink jet recording apparatus has a pressure generating chamber, particularly a diaphragm, when there is no escape of ink in the pressure generating chamber when the ink in the pressure generating chamber is frozen and expanded. There is a problem of causing cracks.

  Accordingly, a liquid ejecting apparatus has been proposed in which, when ink is likely to freeze, the pressure generating chamber is emptied by causing the ink to flow backward from the pressure generating chamber to the reservoir side prior to freezing (see, for example, Patent Document 1). ).

JP 2009-61779 A

  However, in the above-described apparatus, in order to reversely flow ink to the reservoir side, a pump that increases the negative pressure on the reservoir side is required, and there is a problem that the apparatus becomes large and complicated.

  Such a problem exists not only in the ink jet recording apparatus but also in a liquid ejecting apparatus that ejects liquid other than ink.

  In view of such circumstances, it is an object of the present invention to provide a liquid ejecting apparatus and a control method for the liquid ejecting apparatus that can prevent generation of cracks in a pressure generating chamber due to expansion of the liquid during freezing of the liquid. .

[Aspect 1] An aspect of the present invention that solves the above-described problem is a pressure generation chamber that communicates with a nozzle, and a pressure for discharging the liquid in the pressure generation chamber from the nozzle by pressure fluctuation caused by driving of a drive element. Mode 1 or Mode 2 is selected, a generation chamber, a manifold that communicates with the pressure generation chamber and supplies liquid to the pressure generation chamber, a discharge means that discharges the liquid in the pressure generation chamber from the nozzle, and Control means capable of discharging liquid from the nozzle, and the mode 1 generates the pressure so that air is drawn from the nozzle into the pressure generation chamber by the operation of the discharge means. In this mode, the liquid in the room is discharged from the nozzle, and in the mode 2, air is drawn from the nozzle into the pressure generating chamber by driving the driving element. In the liquid ejecting apparatus, the driving element is driven so as not to be lost.
In such an embodiment, air can be taken into the pressure generating chamber from the nozzle by mode 1. Therefore, the liquid to be frozen can be eliminated or reduced from the pressure generating chamber, and cracks in the pressure generating chamber can be prevented even when the liquid is subsequently frozen.

[Aspect 2] Here, in aspect 1, the nozzle includes a first nozzle and a second nozzle. In the mode 1, air is drawn into the manifold from the first nozzle, and the second No air is drawn from the nozzle of the first nozzle, and the air in the manifold drawn from the first nozzle forms a meniscus in the flow path between the pressure generating chamber communicating with the second nozzle and the manifold. The mode is preferable.
In this aspect, with respect to the pressure generation chamber communicating with the first nozzle, the liquid to be frozen can be eliminated or reduced from the pressure generation chamber by drawing air into the pressure generation chamber. In addition, although the liquid remains in the pressure generation chamber connected to the second nozzle, air exists up to the flow path between the pressure generation chamber and the manifold, so that the liquid in the pressure generation chamber Even if it freezes and expands, there is a place for expansion and cracks in the pressure generating chamber can be prevented.

[Aspect 3] In addition, in Aspect 1 or 2, there is further provided a closing means for closing the flow path in the middle of the flow path for supplying the liquid to the manifold. In Mode 1, the flow path is closed by the closing means. It is preferably performed in a closed state.
In such an aspect, even if the amount of liquid discharged by the discharging means is small in mode 1, the amount of liquid supplied to the pressure generating chamber via the manifold can be effectively reduced due to the blockage of the flow path. Air can be effectively drawn in by the formation of pressure. In particular, when the discharge means is a drive element, even if the amount of liquid discharged from the pressure generation chamber via the nozzle is small, the amount of liquid supplied to the pressure generation chamber via the manifold is reduced due to blockage of the flow path. It can be reduced effectively. Therefore, the above relationship can be effectively satisfied regardless of the level of the discharging means.

[Aspect 4] Further, in Aspects 1 to 3, the discharge means is the drive element, and the mode 1 is configured such that air is drawn from the nozzle into the pressure generating chamber by driving the drive element. It is preferable that the driving element is driven.

  In this aspect, each operation of mode 1 or mode 2 can be realized by driving the driving element, and thus control of the liquid ejecting apparatus can be simplified.

[Aspect 5] In the aspect 4, the manifold communicates with the plurality of pressure generation chambers and supplies liquid to the plurality of pressure generation chambers. The mode 1 is driven by the drive element to generate a plurality of pressures. It is preferable that the driving element is driven so that air is drawn from the nozzle into the manifold through at least one pressure generation chamber among the generation chambers.
In such an embodiment, since air is drawn into the manifold, there are a plurality of pressure generation chambers, and expansion due to freezing of the liquid can be used as a escape place in the manifold without drawing air into all the pressure generation chambers. Chamber cracks can be prevented. Note that air may be drawn into all of the pressure generating chambers, but the control becomes simpler than when air is drawn into all of the pressure generating chambers.

[Aspect 6] Further, it is preferable that the cycle of the drive signal for driving the drive element in the mode 1 is shorter than the cycle of the drive signal for driving the drive element in the mode 2.
In this mode, compared with the case of mode 2, in the case of mode 1, the amount of liquid discharged from the pressure generating chamber via the nozzle can be effectively increased by driving the drive element. Therefore, air can be effectively drawn into the pressure generating chamber from the nozzle.

[Aspect 7] Further, it is preferable that the amplitude of the driving signal for driving the driving element in the mode 1 is larger than the amplitude of the driving signal for driving the driving element in the mode 2.
In this mode, compared with the case of mode 2, in the case of mode 1, the amount of liquid discharged from the pressure generating chamber via the nozzle can be effectively increased by driving the drive element. Therefore, air can be effectively drawn into the pressure generating chamber from the nozzle.

[Aspect 8] In addition, in Aspects 1 to 7, further comprising a maintenance means for discharging the air in the pressure generating chamber from the nozzle, and a moving means for relatively moving the medium to be ejected and the nozzle, the control The means is capable of (1) operating the maintenance means in mode 3, (2) in mode 2, relatively moving the medium to be ejected and the nozzle by the moving means, and The driving element is driven so that air is not drawn from the nozzle into the pressure generating chamber by driving the driving element. (3) After the air is drawn from the nozzle into the pressure generating chamber by the mode 1, the mode 3 Therefore, it is preferable not to perform the mode 2 until the air in the pressure generating chamber is discharged.
In such an aspect, after mode 1 is performed, mode 2 is not performed until mode 3 is performed, so that it is possible to prevent the result of the liquid being ejected onto the medium to be ejected in mode 2 from becoming defective.

[Aspect 9] In aspects 1 to 8, it is preferable that the control unit performs mode 1 based on a user's selection as to whether or not to perform mode 1.
In such an aspect, in the case where it is better to execute the mode 1, for example, in the case of long-term storage or product delivery, the implementation of the mode 1 can be performed by the user's selection.

[Aspect 10] In aspects 1 to 8, it is preferable that a detection unit for detecting temperature is further provided, and the control unit performs the mode 1 based on a detection result of the detection unit.
In this aspect, since the mode 1 can be performed by detecting when it is likely to freeze, the mode 1 can be performed without user selection, and the operability is high.

[Aspect 11] Another aspect of the present invention is a pressure generation chamber communicating with a nozzle, and a pressure generation chamber for discharging liquid in the pressure generation chamber from the nozzle by pressure fluctuation generated by driving of a drive element. A control method for a liquid ejecting apparatus, comprising: a manifold that communicates with the pressure generation chamber and supplies liquid to the pressure generation chamber; and a discharge unit that discharges the liquid in the pressure generation chamber from the nozzle. The mode 1 or the mode 2 is selected and controlled so that the liquid is discharged from the nozzle. In the mode 1, the air is drawn from the nozzle into the pressure generating chamber by the operation of the discharge means. In this mode, the liquid in the pressure generating chamber is discharged from the nozzle, and the mode 2 is driven by the driving element so that air is discharged from the nozzle to the pressure generating chamber. So that it is not drawn into a mode for driving the drive element, the control method for a liquid-jet apparatus characterized by.
In such an embodiment, air can be taken into the pressure generating chamber from the nozzle by mode 1. Therefore, the liquid to be frozen can be eliminated or reduced from the pressure generating chamber, and cracks in the pressure generating chamber can be prevented even when the liquid is subsequently frozen.

1 is a schematic perspective view of a recording apparatus according to Embodiment 1 of the present invention. It is a schematic diagram explaining the cap of Embodiment 1. FIG. FIG. 2 is an exploded perspective view of a recording head according to Embodiment 1 of the invention. FIG. 3 is a plan view of the recording head according to Embodiment 1 of the present invention on the liquid ejection surface side. FIG. 3 is a cross-sectional view of the recording head according to the first embodiment of the invention. It is a figure which shows the control structure of the recording device which concerns on Embodiment 1 of this invention. FIG. 3 is a diagram illustrating each mode of the recording apparatus according to the first embodiment of the invention. It is a schematic diagram explaining after implementation of mode 1. FIG. It is a schematic diagram explaining the frozen state after implementation of mode 1. It is a schematic diagram explaining the frozen state when not implementing mode 1. FIG. It is a schematic diagram explaining the cap of Embodiment 1,2. It is sectional drawing which shows an example of the recording head which concerns on other embodiment.

Hereinafter, the present invention will be described in detail based on embodiments.
(Embodiment 1)
FIG. 1 is a perspective view illustrating a schematic configuration of an ink jet recording apparatus that is an example of a liquid ejecting apparatus according to Embodiment 1 of the present invention, and FIG. 2 is a perspective view illustrating a suction cap and a protective cap.

  As shown in FIG. 1, in the liquid ejecting apparatus I of this embodiment, a liquid ejecting head unit 1 is mounted on a carriage 2. The carriage 2 on which the liquid ejecting head unit 1 is mounted is provided so as to be movable in the axial direction with respect to the carriage shaft 2 a attached to the housing 3.

  The housing 3 is provided with storage means 4 in which liquid is stored, and the liquid from the storage means 4 is supplied to the liquid ejecting head unit 1 mounted on the carriage 2 via the tube 4a. . Further, in the vicinity of the storage means 4 of the tube 4a, a closing means 5 that is a choke valve for closing the flow path of each tube 4a is provided.

  Then, the driving force of the driving motor 6 is transmitted to the carriage 2 via the plurality of pulleys 6a and the timing belt 6b, whereby the carriage 2 on which the liquid ejecting head unit 1 is mounted is moved along the carriage shaft 2a. On the other hand, the casing 3 is provided with a conveyance roller 7 as a conveyance means, and the recording sheet S which is a recording medium such as paper is conveyed by the conveyance roller 7. Note that the conveyance means for conveying the recording sheet S is not limited to the conveyance roller, and may be a belt, a drum, or the like.

  In such a liquid ejecting apparatus I, the carriage 2 is moved along the carriage shaft 2a, and the liquid is ejected as droplets by the liquid ejecting head unit 1 and landed on the recording sheet S.

  In addition, a suction cap 8 and a protective cap 9 are provided in a non-printing area on the side of the transport roller 7 that is an end in the moving direction of the carriage 2, and a suction means 8 a is connected to the suction cap 8. ing. The protective cap 9 may not be provided separately from the suction cap 8, and the suction cap 8 may be used as a protective cap.

  In the liquid ejecting apparatus I described above, the liquid ejecting head unit 1 is mounted on the carriage 2 and moves in the main scanning direction. However, the liquid ejecting head unit 1 is not particularly limited thereto. The present invention can also be applied to a so-called line-type recording apparatus that performs printing only by moving the recording sheet S such as paper in the sub-scanning direction while being fixed to the body 3.

  In the example described above, the liquid ejecting apparatus I has a configuration in which the storage unit 4 is mounted on the housing 3, but is not particularly limited thereto. For example, the storage unit 4 is not mounted on the housing 3. Instead, the liquid may be supplied from the outside of the liquid ejecting apparatus I.

  Here, an example of an ink jet recording head constituting the head unit 1 mounted on such an ink jet recording apparatus will be described with reference to FIGS. 3 is an exploded perspective view of the ink jet recording head, FIG. 4 is a plan view of the liquid ejecting surface side of the ink jet recording head, and FIG. 5 is a cross-sectional view taken along line AA ′ of FIG. It is.

  As shown in the figure, the ink jet recording head II of this embodiment includes a plurality of members such as a head main body 11 and a case member 40, and these members are joined together by an adhesive or the like. In the present embodiment, the head body 11 includes a flow path forming substrate 10, a communication plate 15, a nozzle plate 20, a protective substrate 30, and a compliance substrate 45.

The flow path forming substrate 10 constituting the head body 11 is made of a metal such as stainless steel or Ni, a ceramic material typified by ZrO ₂ or Al ₂ O ₃ , a glass ceramic material, an oxide such as MgO or LaAlO _3. Can be used. In the present embodiment, the flow path forming substrate 10 is made of a silicon single crystal substrate. This flow path forming substrate 10 is anisotropically etched from one side so that the pressure generating chambers 12 partitioned by the plurality of partition walls are arranged in parallel with a plurality of nozzle openings 21 through which ink is ejected. Side by side. Hereinafter, this direction is referred to as a direction in which the pressure generating chambers 12 are arranged side by side or a first direction X. Further, the flow path forming substrate 10 is provided with a plurality of rows in which the pressure generation chambers 12 are arranged in parallel in the first direction X, and in this embodiment, two rows. An arrangement direction in which a plurality of rows of the pressure generation chambers 12 in which the pressure generation chambers 12 are formed along the first direction X is provided is hereinafter referred to as a second direction Y.

  Further, the flow path forming substrate 10 has an opening area narrower than that of the pressure generation chamber 12 on one end portion side in the second direction Y of the pressure generation chamber 12, and the flow path resistance of ink flowing into the pressure generation chamber 12. A supply path or the like for providing the above may be provided.

  A communication plate 15 is bonded to one surface side of the flow path forming substrate 10. The communication plate 15 is joined to a nozzle plate 20 having a plurality of nozzle openings 21 communicating with the pressure generating chambers 12.

  The communication plate 15 is provided with a nozzle communication path 16 that communicates the pressure generation chamber 12 and the nozzle opening 21. The communication plate 15 has a larger area than the flow path forming substrate 10, and the nozzle plate 20 has a smaller area than the flow path forming substrate 10. Thus, cost reduction can be achieved by making the area of the nozzle plate 20 relatively small. In the present embodiment, a surface on which the nozzle openings 21 of the nozzle plate 20 are opened and ink droplets are ejected is referred to as a liquid ejecting surface 20a.

  The communication plate 15 is provided with a first manifold portion 17 and a second manifold portion 18 that constitute a part of the manifold 100.

  The first manifold portion 17 is provided through the communication plate 15 in the thickness direction (the stacking direction of the communication plate 15 and the flow path forming substrate 10).

  Further, the second manifold portion 18 is provided to open to the nozzle plate 20 side of the communication plate 15 without penetrating the communication plate 15 in the thickness direction.

  Further, the communication plate 15 is provided with a supply communication passage 19 that communicates with one end portion of the pressure generation chamber 12 in the second direction Y independently for each pressure generation chamber 12. The supply communication path 19 communicates the second manifold portion 18 and the pressure generation chamber 12.

  As the communication plate 15, a metal such as stainless steel or Ni, or a ceramic such as zirconium can be used. The communication plate 15 is preferably made of a material having the same linear expansion coefficient as the flow path forming substrate 10. That is, when a material having a linear expansion coefficient that is significantly different from that of the flow path forming substrate 10 is used as the communication plate 15, warping due to a difference in linear expansion coefficient between the flow path forming substrate 10 and the communication plate 15 due to heating or cooling. Will occur. In this embodiment, by using the same material as the flow path forming substrate 10 as the communication plate 15, that is, a silicon single crystal substrate, it is possible to suppress the occurrence of warping due to heat, cracking due to heat, peeling, and the like.

  The nozzle plate 20 is formed with nozzle openings 21 communicating with the pressure generation chambers 12 via the nozzle communication passages 16. That is, nozzle openings 21 that eject the same type of liquid (ink) are juxtaposed in the first direction X, and the rows of nozzle openings 21 juxtaposed in the first direction X are in the second direction. Two rows are formed in Y.

  As such a nozzle plate 20, for example, a metal such as stainless steel (SUS), an organic substance such as a polyimide resin, a silicon single crystal substrate, or the like can be used. In addition, by using a silicon single crystal substrate as the nozzle plate 20, the linear expansion coefficients of the nozzle plate 20 and the communication plate 15 are made equal, and the occurrence of warpage due to heating or cooling, cracks due to heat, peeling, and the like are suppressed. can do.

  On the other hand, a diaphragm 50 is formed on the surface of the flow path forming substrate 10 opposite to the communication plate 15. In the present embodiment, an elastic film 51 made of silicon oxide provided on the flow path forming substrate 10 side and an insulator film 52 made of zirconium oxide provided on the elastic film 51 are provided as the diaphragm 50. I made it. The liquid flow path such as the pressure generation chamber 12 is formed by anisotropically etching the flow path forming substrate 10 from one side, that is, the side where the nozzle plate 20 is joined. The other surface of the liquid channel such as 12 is defined by the elastic film 51.

  Further, on the insulator film 52 of the vibration plate 50, the first electrode 60, the piezoelectric layer 70, and the second electrode 80 are laminated and formed by film formation and lithography in this embodiment. 300. Here, the piezoelectric actuator 300 is also referred to as a piezoelectric element 300 and refers to a portion including the first electrode 60, the piezoelectric layer 70, and the second electrode 80. In general, one electrode of the piezoelectric actuator 300 is used as a common electrode, and the other electrode and the piezoelectric layer 70 are patterned for each pressure generating chamber 12. In addition, here, a portion that is configured by any one of the patterned electrodes and the piezoelectric layer 70 and in which piezoelectric distortion is generated by applying a voltage to both electrodes is referred to as a piezoelectric active portion. In the present embodiment, the first electrode 60 is used as a common electrode for the piezoelectric actuator 300 and the second electrode 80 is used as an individual electrode for the piezoelectric actuator 300. However, there is no problem even if this is reversed for the convenience of the drive circuit and wiring. In the above-described example, since the first electrode 60 is continuously provided across the plurality of pressure generating chambers 12, the first electrode 60 functions as a part of the diaphragm, but of course, the present invention is not limited thereto. For example, only one of the first electrodes 60 may act as a diaphragm without providing one or both of the elastic film 51 and the insulator film 52 described above.

  A protective substrate 30 having substantially the same size as the flow path forming substrate 10 is bonded to the surface of the flow path forming substrate 10 on the piezoelectric actuator 300 side. The protective substrate 30 has a holding portion 31 that is a space for protecting the piezoelectric actuator 300. The protective substrate 30 is provided with a through-hole 32 that penetrates in the thickness direction (the stacking direction of the flow path forming substrate 10 and the protective substrate 30). The other end portion of the lead electrode 90 opposite to the one end portion connected to the second electrode 80 is extended so as to be exposed in the through hole 32, and the lead electrode 90 and the drive circuit 101 such as a drive IC are connected. The mounted wiring board 102 is electrically connected in the through hole 32.

  In addition, a case member 40 is fixed to the head main body 11 having such a configuration. The case member 40 defines a manifold 100 communicating with the plurality of pressure generating chambers 12 together with the head main body 11. The case member 40 has substantially the same shape as the communication plate 15 described above in a plan view, and is bonded to the protective substrate 30 and is also bonded to the communication plate 15 described above. Specifically, the case member 40 has a recess 41 having a depth in which the flow path forming substrate 10 and the protective substrate 30 are accommodated on the protective substrate 30 side. The concave portion 41 has an opening area larger than the surface of the protective substrate 30 bonded to the flow path forming substrate 10. The opening surface on the nozzle plate 20 side of the recess 41 is sealed by the communication plate 15 in a state where the flow path forming substrate 10 and the like are accommodated in the recess 41. As a result, a third manifold portion 42 is defined by the case member 40 and the head body 11 on the outer peripheral portion of the flow path forming substrate 10. The manifold 100 of this embodiment is configured by the first manifold portion 17 and the second manifold portion 18 provided on the communication plate 15, and the third manifold portion 42 defined by the case member 40 and the head body 11. It is configured.

  In addition, as a material of case member 40, resin, a metal, etc. can be used, for example. Incidentally, the case member 40 can be mass-produced at low cost by molding a resin material.

  A compliance substrate 45 is provided on the surface of the communication plate 15 where the first manifold portion 17 and the second manifold portion 18 open. The compliance substrate 45 seals the openings of the first manifold portion 17 and the second manifold portion 18 on the liquid ejection surface 20a side.

  In this embodiment, the compliance substrate 45 includes a sealing film 46 and a fixed substrate 47. The sealing film 46 is made of a flexible thin film (for example, a thin film having a thickness of 20 μm or less formed of polyphenylene sulfide (PPS) or stainless steel (SUS)), and the fixed substrate 47 is made of stainless steel ( It is formed of a hard material such as a metal such as SUS. Since the region of the fixed substrate 47 facing the manifold 100 is an opening 48 that is completely removed in the thickness direction, one surface of the manifold 100 is sealed only with a flexible sealing film 46. It is a compliance part that is a flexible part.

  The case member 40 is provided with an introduction path 44 that communicates with the manifold 100 and supplies ink to each manifold 100. The case member 40 is provided with a connection port 43 that communicates with the through hole 32 of the protective substrate 30 and through which the wiring substrate 102 is inserted.

  In the ink jet recording head II having such a configuration, when ink is ejected, the ink is taken from the ink cartridge through the introduction path 44 and the inside of the flow path is filled with the ink from the manifold 100 to the nozzle opening 21. Thereafter, according to a signal from the drive circuit 101, a voltage is applied to each piezoelectric actuator 300 corresponding to the pressure generation chamber 12, so that the diaphragm 50 is bent and deformed together with the piezoelectric actuator 300. As a result, the pressure in the pressure generating chamber 12 is increased and ink droplets are ejected from the predetermined nozzle openings 21. In the ink jet recording head II of the present embodiment, the portion from the connection port 43 to the nozzle opening 21 is referred to as a liquid flow path. That is, the liquid flow path includes the connection port 43, the manifold 100, the supply communication path 19, the pressure generation chamber 12, the nozzle communication path 16, and the nozzle opening 21.

  Further, a cover head 105 which is a protective member of the present embodiment is provided on the liquid ejecting surface 20a side of the head body 11. The cover head 105 is bonded to the surface of the compliance substrate 45 opposite to the communication plate 15 and seals the space of the compliance portion 49 opposite to the flow path (manifold 100). The cover head 105 is provided with an exposure opening 106 that exposes the nozzle opening 21. In the present embodiment, the exposure opening 106 has a size that exposes the nozzle plate 20, that is, the same opening as the compliance substrate 45.

  In the present embodiment, the cover head 105 is provided with a bent end from the liquid ejection surface 20a side so as to cover the side surface of the head body 11 (a surface intersecting the liquid ejection surface 20a).

  In the present embodiment, such a cover head 105 is provided so as to protrude from the liquid ejection surface 20a of the nozzle plate 20 toward the recording sheet S in the ink (liquid) ejection direction. Thus, by causing the cover head 105 to protrude toward the recording sheet S from the liquid ejection surface 20 a, the recording sheet S becomes difficult to contact the nozzle plate 20, and the nozzles due to the recording sheet S coming into contact with the nozzle plate 20. Generation | occurrence | production of a deformation | transformation, peeling, etc. of the plate 20 can be suppressed.

  Further, a liquid repellent film having liquid repellency is provided on the same surface as the liquid ejection surface 20 a of the cover head 105, that is, on the surface opposite to the compliance substrate 45, similar to the nozzle plate 20. You may do it.

  Such an ink jet recording head II is mounted on the ink jet recording apparatus I so that the second direction Y is the main scanning direction which is the moving direction of the carriage 2.

  Here, a control configuration of the ink jet recording apparatus I of the present embodiment will be described. FIG. 6 is a block diagram illustrating a control configuration of the ink jet recording apparatus and the liquid jet head inspection apparatus.

  As shown in FIG. 6, the control configuration of the ink jet recording apparatus I of the present embodiment is schematically configured from a printer controller 111 and a print engine 112. The printer controller 111 includes an external interface 113 (hereinafter referred to as an external I / F 113), a RAM 114 that temporarily stores various data, a ROM 115 that stores a control program, and a control unit 116 that includes a CPU and the like. An oscillation circuit 117 that generates a clock signal, a drive signal generation circuit 119 that generates a drive signal to be supplied to the ink jet recording head II, and dot pattern data (bitmap) developed based on the drive signal and print data An internal interface 120 (hereinafter referred to as an internal I / F 120) for transmitting data) to the print engine 112.

  The external I / F 113 receives print data including, for example, a character code, a graphic function, image data, and the like from a host computer (not shown). In addition, a busy signal (BUSY) or an acknowledge signal (ACK) is output to the host computer or the like through the external I / F 113. The RAM 114 functions as a reception buffer 121, an intermediate buffer 122, an output buffer 123, and a work memory (not shown). The reception buffer 121 temporarily stores print data received by the external I / F 113, the intermediate buffer 122 stores intermediate code data converted by the control unit 116, and the output buffer 123 stores dot pattern data. . This dot pattern data is constituted by print data obtained by decoding (translating) gradation data.

  The ROM 115 stores font data, graphic functions, and the like in addition to a control program (control routine) for performing various data processing. The control unit 116 reads the print data in the reception buffer 121 and stores the intermediate code data obtained by converting the print data in the intermediate buffer 122. Further, the intermediate code data read from the intermediate buffer 122 is analyzed, and the intermediate code data is developed into dot pattern data by referring to the font data and graphic functions stored in the ROM 115. Then, the control unit 116 stores the developed dot pattern data in the output buffer 123 after performing necessary decoration processing.

  If dot pattern data corresponding to one line of the ink jet recording head II is obtained, the dot pattern data for one line is output to the ink jet recording head II through the internal I / F 120. When dot pattern data for one line is output from the output buffer 123, the developed intermediate code data is erased from the intermediate buffer 122, and the development process for the next intermediate code data is performed.

  The print engine 112 includes an ink jet recording head II, a paper feed mechanism 124, and a carriage mechanism 125. The paper feed mechanism 124 includes a paper feed motor, a paper feed motor that rotates the paper feed roller, a transport roller 7 and the like, and a print storage medium such as a recording paper is interlocked with a recording operation of the ink jet recording head II. Send out sequentially. That is, the paper feed mechanism 124 relatively moves the print storage medium in the sub-scanning direction.

  The carriage mechanism 125 includes a carriage 2 on which the ink jet recording head II can be mounted, and a carriage drive unit that causes the carriage 2 to travel along the carriage axis 2a along the main scanning direction. As a result, the ink jet recording head II is moved in the main scanning direction. The carriage drive unit is composed of the drive motor 6 and the timing belt 6b as described above.

  The ink jet recording head II has a large number of nozzle openings 13 along the sub-scanning direction, and ejects ink droplets from the nozzle openings 21 at a timing defined by dot pattern data or the like. The piezoelectric element 300 of the ink jet recording head II is supplied with an electrical signal, for example, an ejection drive signal (COM), print data (SI), etc., which will be described later, via an external wiring (not shown). In the printer controller 111 and the print engine 112 configured as described above, the latch that selectively inputs the drive signal having the predetermined drive waveform output from the printer controller 111 and the drive signal generation circuit 119 to the piezoelectric element 300. A driving circuit (not shown) having 132, a level shifter 133, a switch 134, and the like serves as driving means for applying a predetermined driving signal to the piezoelectric element 300.

  The shift register (SR) 131, the latch 132, the level shifter 133, the switch 134, and the piezoelectric element 300 are provided for each nozzle opening 21 of the ink jet recording head II. The latch 132, the level shifter 133, and the switch 134 generate drive pulses from the ejection drive signal and the destruction drive signal generated by the drive signal generation circuit 119. Here, the drive pulse is an applied pulse that is actually applied to the piezoelectric element 300.

  In such an ink jet recording head II, first, print data (SI) constituting the dot pattern data is serially transmitted from the output buffer 123 to the shift register 131 in synchronization with the clock signal (CK) from the oscillation circuit 117. Are set sequentially. In this case, first, the most significant bit data in the print data of all the nozzle openings 21 is serially transmitted. When the most significant bit data serial transmission is completed, the second most significant bit data is serially transmitted. . Similarly, the lower bit data is serially transmitted sequentially.

  When all the nozzles of the print data of the bit are set in the shift registers 131, the control unit 116 causes the latch 132 to output a latch signal (LAT) at a predetermined timing. In response to this latch signal, the latch 132 latches the print data set in the shift register 131. The print data (LATout) latched by the latch 132 is applied to the level shifter 133 which is a voltage amplifier. When the print data is “1”, for example, the level shifter 133 boosts the print data to a voltage value that can drive the switch 134, for example, several tens of volts. The boosted print data is applied to each switch 134, and each switch 134 is connected by the print data.

  A drive signal (COM) generated by the drive signal generation circuit 119 is also applied to each switch 134. When the switch 134 is selectively connected, the piezoelectric element 300 connected to the switch 134 is selected. A driving signal is applied. As described above, in the illustrated ink jet recording head II, it is possible to control whether or not the ejection drive signal is applied to the piezoelectric element 300 based on the print data. For example, since the switch 134 is connected by the latch signal (LAT) during the period when the print data is “1”, the drive signal (COMout) can be supplied to the piezoelectric element 300, and the supplied drive signal ( The piezoelectric element 300 is displaced (deformed) by COMout). Further, since the switch 134 is not connected during the period when the print data is “0”, the supply of the drive signal to the piezoelectric element 300 is cut off. Note that, during the period in which the print data is “0”, each piezoelectric element 300 holds the immediately preceding potential, so that the immediately preceding displacement state is maintained.

  In such an ink jet recording head II, the volume of the corresponding pressure generating chamber 12 changes with charging / discharging of the piezoelectric element 300, so that ink droplets are ejected from the nozzle openings 21 using the pressure fluctuation of the pressure generating chamber 12. Can be discharged.

  Further, the control unit 116 supplies an ejection drive signal that can eject ink droplets from the nozzle openings 21 and a destruction drive signal that destroys the liquid (ink) meniscus of the nozzle openings 21 so that it cannot be ejected. Thus, the drive signal generation circuit 119 is controlled.

  The ejection drive signal is a signal having ejection pulses within one recording period T for driving (ejection driving) the piezoelectric element 300 as a driving element so as to eject ink droplets, and is repeatedly generated every recording period T. .

  On the other hand, the destruction driving signal drives the piezoelectric element 300 as a driving element to destroy the meniscus of the ink (liquid) formed in the nozzle opening 21 and draws air from the nozzle opening 21 by the ejection driving. To do. Such a destructive drive signal is formed, for example, by appropriately changing the voltage, application time, period, etc. of the ejection drive signal. In general, the destruction drive signal preferably has a shorter cycle than the ejection drive signal, and it is preferable to increase the applied voltage, that is, the amplitude. According to this, it is possible to effectively eject a large amount of ink at a time. As a result, it is possible to generate an ink supply shortage state and to draw air from the nozzle opening 21 by the negative pressure. The mode using such a destructive drive signal will be described later.

  As described above, the printer controller 111 serving as the control unit of the present embodiment operates in the discharge unit in addition to the mode 2 in which the piezoelectric element 300 serving as the driving element is driven so that air is not drawn from the nozzle opening 21, that is, In the present embodiment, mode 1 is executed in which the piezoelectric element 300 that is a driving element is operated to discharge air so that air is drawn into the pressure generation chamber 12 from the nozzle opening 21.

  FIG. 7 is a diagram for explaining how the printer controller 111 executes modes 1 to 3.

  The implementation of mode 1 prevents the destruction of the diaphragm and the like due to the pressure increase in the pressure generation chamber 12 due to the freezing of the liquid in the pressure generation chamber 12 and the manifold 100. This is executed when the use environment temperature falls below the liquid freezing temperature during transportation, and is performed based on a user command 201 such as a user turning on a mode 1 selection switch, for example. In addition to the user command 201, the printer controller 111 acquires external temperature information 202 from detection means such as a temperature sensor that measures the environmental temperature, and determines whether to execute mode 1 based on this, Based on this, mode 1 may be executed. Whether the mode 1 is applied to the user's selection or the detection result of the detection means, it is possible to prevent the diaphragm and the like from being broken, and the operability is high.

  In mode 1, in this embodiment, the piezoelectric element 300 is driven by the destructive drive signal described above, whereby air is drawn from the nozzle opening 21.

  The destructive drive signal may be sent to all the piezoelectric elements 300, but may be supplied only to the piezoelectric elements 300 corresponding to some of the nozzle openings 21 where the meniscus is to be destroyed.

  When the piezoelectric element 300 is driven by the destructive driving signal, the meniscus is moved from the vicinity of the nozzle opening 21 toward the pressure generating chamber 12 due to the discharge of the liquid from the nozzle opening 21, and the area of the meniscus is increased. Air can be drawn in. Further, due to the discharge of the liquid from the nozzle opening 21, the supply of the liquid is insufficient, the negative pressure in the communicating pressure generation chamber 12 becomes large, and air is drawn into the pressure generation chamber 12 from the nozzle opening 21. Thus, when the pressure generation chamber 12 is filled with air, even if the temperature of the liquid thereafter freezes, the pressure generation chamber 12 is prevented from being destroyed due to freezing.

  Further, when the air is sufficiently drawn from the nozzle opening 21 as described above into the pressure generating chamber 12 at a plurality of locations, for example, the air accumulates in the manifold 100 and the air is discharged from the nozzle opening 21. Accumulates in the flow path between the pressure generating chamber 12 and the manifold 100 where the pressure is not drawn, and a meniscus is formed there. In this case, even if the liquid in the manifold 100 is frozen, air exists in a part of the flow path that connects the pressure generation chamber 12 and the manifold 100, so that the pressure in the pressure generation chamber 12 increases. However, since the escape route is not blocked, destruction is prevented as a result.

  As described above, the destruction driving signal may be supplied to all the piezoelectric elements 300 or a part of the piezoelectric elements 300, but in any case, air is drawn from at least a part of the nozzle openings 21. When a meniscus is formed in the flow path between the pressure generation chamber 12 and the manifold 100 that enters the manifold 100 and communicates with the nozzle opening 21 that does not draw air, the result is that all the pressure generation chambers 12 This will prevent destruction due to freezing. Thus, the completion of mode 1 is that air is drawn into some of the pressure generation chambers 12 even if not all of the pressure generation chambers 12 are drawn into the air. The process may be completed when a meniscus is formed in the flow path between the pressure generating chamber 12 and the manifold 100 communicating with the nozzle opening 21 that does not draw air. Thereby, compared with the case where air is drawn in in all the pressure generation chambers 12, control becomes simple.

  In this embodiment, air is drawn in by the mode 1 using the driving signal for destruction. However, the driving signal for normal flushing is used without preparing such a special driving signal. Also good.

  Further, when the mode 1 is executed, the discharge from the nozzle opening 21 is performed. However, a discharge region for executing the mode 1 may be specially provided, but it is performed in a region facing the suction cap 8. You may do it.

FIG. 8 schematically shows such a state of air drawing. In FIG. 8, the liquid is represented by a dot pattern, and the air is represented by a white background.
FIG. 8A shows a state in which air is drawn from the nozzle opening 21 to the pressure generating chamber 12, and FIG. 8B shows a state in which air is further drawn and accumulated in the manifold 100. FIG. 8C shows a state in which the air accumulated in the manifold 100 forms a meniscus in the flow path between the pressure generation chamber 12 communicating with the nozzle opening 21 that does not draw air and the manifold 100. Yes.

  That is, the nozzle openings 21 in the three states shown in FIGS. 8A to 8C are mixed regardless of whether the driving signal for destruction is supplied to all the piezoelectric elements 300 or a part of the piezoelectric elements 300. It will be.

FIG. 9 schematically shows a state where the liquid is frozen in such a state. In FIG. 9, the liquid is represented by a dot pattern, the frozen one is represented by hatching, and the air is represented by a white background.
FIG. 9 shows a state of freezing of the pressure generating chamber 12 in the state of FIG. 8C, and only the liquid in the nozzle opening 21 is frozen at the beginning of freezing. As shown in FIG. 9B, the liquid in the pressure generation chamber 12 and the liquid in the manifold 100 are frozen, but air exists in the manifold 100 and air also exists in the flow path communicating with the pressure generation chamber 12. Therefore, the pressure from the pressure generation chamber 12 side can escape into the manifold 100 without blocking the flow path, and destruction in the pressure generation chamber 12 is prevented.

FIG. 10 shows a state when the mode 1 is not executed. In FIG. 10, the liquid is represented by a dot pattern, the frozen one is represented by hatching, and the air is represented by a white background.
As shown in FIG. 10A, when freezing occurs in a state where the liquid is filled from the nozzle opening 21 to the manifold 100, freezing starts from the nozzle opening 21 side and the manifold 100 as shown in FIG. 10B. Even if the liquid in the pressure generation chamber 12 does not freeze, if the flow path that connects the pressure generation chamber 12 and the manifold 100 freezes, the pressure escape chamber in the pressure generation chamber 12 does not exist and breaks down. It will be.

In the above, an example of execution of mode 1 of the embodiment has been described. However, when the mode 1 is executed by driving the piezoelectric element 300 by the destructive drive signal, the choke valve that stops the supply of the liquid from the liquid storage unit 4 The occlusion means 5 may stop the supply of the liquid. Thereby, the amount of wasteful liquid discharge until the air is drawn from the nozzle opening 21 is reduced, and the mode 1 can be executed in a relatively short time, which is preferable.
Further, since the mode 1 is executed by driving the piezoelectric element 300, the control of the liquid ejecting apparatus can be simplified.

  Mode 2 shown in FIG. 7 is a mode for normal printing, and mode 3 is a mode for recovery. After the mode 1 is performed and air is drawn into the flow path, the mode 3 is executed before the printing is performed in the mode 2. That is, after mode 1 is executed, mode 3 is always executed before mode 1. Thereby, it is possible to prevent the mode 2 from being executed without performing the mode 3 and the result of the liquid being discharged onto the discharge target medium from becoming defective.

  Mode 3 is to discharge the air in the pressure generation chamber 12 and the manifold 100 from the nozzle opening 21. In the present embodiment, the mode 3 is performed using the suction cap 8 and the suction means 8a as maintenance means. This is similar to normal suction recovery. In addition, as a maintenance means after the mode 1, not a suction recovery but a means such as a pressurized supply of liquid from the upstream side may be mounted.

  In mode 3 by suction recovery, as shown in FIG. 2, the carriage 2 is moved to a position facing the suction cap 8 by the carriage mechanism, the suction cap 8 is brought into contact with the nozzle plate 20, and the nozzle opening is opened by the suction means 8a. By suctioning from the air 21, the air and the liquid are drawn to fill the manifold 100, the pressure generation chamber 12, and the nozzle opening 21.

  In addition, when the device is left or transported after the mode 1 is executed, the power is turned off. In a normal case, the nozzle plate 20 is protected by the protective cap 9, but the protection by the protective cap 9 is performed. In this embodiment, after the mode 1, the protection by the protective cap 9 is not performed.

  This is shown in FIG. FIG. 11A shows a state where the carriage 2 moves to a region facing the protective cap 9 when the power is turned off, but is stopped in a state where the protective cap 9 is not in close contact with the nozzle plate 20. This state is a stop state after mode 1.

  When the carriage 2 moves to a region facing the protective cap 9 in the non-printing region, the locking member 902 provided on the support member 901 that supports the protective cap 9 is locked to the carriage 2, and the protective cap 9 and the support member 901 are moved. Is moved obliquely upward along the tilt table 903. The state of FIG. 11A is a state where the protective cap 9 and the support member 901 do not move along the inclined base 903, and FIG. 11B shows the state where the protective cap 9 and the support member 901 are along the inclined base 903. The protective cap 9 is moved obliquely upward and is in close contact with the nozzle plate 20.

  In the state of FIG. 11B, the lock rod 911 of the carriage lock mechanism 910 which is a restricting means for restricting the movement of the carriage 2 is inserted into the lock hole 912 of the carriage 2 and fixed. The carriage lock mechanism 910 is normally used when transporting. In the present embodiment, the carriage 2 is fixed to the carriage 2 in order to allow the carriage 2 to be fixed in the state shown in FIG. A second lock hole 913 is provided. Note that when not carrying, the carriage lock may not be performed even in the state of FIG.

  Here, power off includes not only the state where the main switch is turned off but also the off state due to the power saving mode or the like. Here, the power saving mode refers to shutting off the power supply to the drive circuit provided in the liquid ejecting apparatus, shutting off the power supply to the circuit of the detecting means, lowering the voltage of the power supplied to these, This is a state in which at least one of turning off the display of the panel provided in the ejection device is implemented, and is completely distinguished from a standby state such as waiting for printing or an operation state.

  Such a stop state after mode 1 is that the vicinity of the nozzle opening 21 is actively exposed to the environmental temperature, and when there is liquid in the nozzle opening 21, freezing from the liquid in the nozzle opening 21 is caused by the manifold. This is to precede the freezing of the liquid in 100. That is, if the nozzle opening 21 is not protected by the protective cap 9, the vicinity of the nozzle opening 21 and the periphery of the manifold 100 also have the same environmental temperature. The liquid inside will freeze first. Thereby, destruction by the pressure increase resulting from freezing in the pressure generation chamber 12 can be prevented more reliably. On the other hand, when the liquid in the manifold 100 freezes before the liquid in the nozzle opening 21, the liquid is sealed in the pressure generation chamber 12 as shown in FIG. In addition, there is a risk of destruction due to an increase in pressure in the pressure generation chamber 12.

(Embodiment 2)
In the above-described embodiment, the piezoelectric element 300 that is a driving element is used as the discharging unit that executes the mode 1. However, in this embodiment, the suction cap 8 and the suction unit 8a are used as the discharging unit.

  That is, the suction cap 8 is in close contact with the nozzle plate 20, and suction is performed with suction stronger than the recovery of suction, or suction is performed with the closing means 5 closed and the supply of liquid stopped, and then the suction cap 8 Are separated from each other or the inside of the suction cap 8 is opened to the atmosphere so that air is drawn into the pressure generating chamber 12 from the nozzle opening 21.

  Also in this case, the nozzle opening 21 for drawing air is a part, and the states of FIGS. 8A to 8C are mixed.

  In the case of the present embodiment, air can be drawn in from the nozzle opening 21 relatively easily as compared with the case of the first embodiment, but there is a drawback that foreign matter in the suction cap 8 may enter from the nozzle opening 21. . Therefore, the first embodiment is preferable from this point.

  As in the first embodiment, the present embodiment has an advantage that it is not necessary to provide a special device such as a pump for feeding back liquid as in the patent document shown in the related art.

(Other embodiments)
As mentioned above, although one Embodiment of this invention was described, the basic composition of this invention is not limited to what was mentioned above.

  In the above-described embodiment, it is desired to exemplify a recording head having a communication plate 15 between the flow path forming substrate 10 and the nozzle plate 20, but a configuration without the communication plate 15 may be used.

  FIG. 12 illustrates a configuration in which the nozzle plate 20 is directly joined to the flow path forming substrate 10 without including the communication plate. In addition, the same code | symbol is attached | subjected to the same member as embodiment mentioned above, and description is abbreviate | omitted.

  Further, the completion of mode 1 may be a time point when air is drawn into all the pressure generation chambers 12. As a result, even if all the pressure generation chambers 12 are filled with air and then the temperature of the liquid freezes, destruction of the pressure generation chambers 12 due to freezing is prevented.

  In the ink jet recording apparatus I of the first embodiment described above, the ink jet recording head II (head unit 1) is mounted on the carriage 2 and moves in the main scanning direction. However, the present invention is not particularly limited thereto. For example, the present invention can also be applied to a so-called line type recording apparatus in which the ink jet recording head II is fixed and printing is performed simply by moving the recording sheet S such as paper in the sub-scanning direction.

  In the above-described example, the ink jet recording apparatus I fixes the liquid storage means such as an ink tank to the apparatus main body, and connects the liquid storage means and the ink jet recording head II via a supply pipe such as a tube. Although it is an example, it is not specifically limited to this, The liquid storage means does not need to be mounted in the inkjet recording device. In addition, an ink cartridge that is a liquid storage unit may be mounted on the carriage 2.

  Furthermore, in Embodiment 1 described above, the thin film type piezoelectric actuator 300 has been described as the pressure generating means for causing a pressure change in the pressure generating chamber 12, but the present invention is not particularly limited thereto. For example, a green sheet is attached. It is possible to use a thick film type piezoelectric actuator formed by such a method, a longitudinal vibration type piezoelectric actuator in which piezoelectric materials and electrode forming materials are alternately stacked and expanded and contracted in the axial direction. Also, as a pressure generating means, a heating element is arranged in the pressure generating chamber, and droplets are discharged from the nozzle opening by bubbles generated by the heat generated by the heating element, or static electricity is generated between the diaphragm and the electrode. Thus, a so-called electrostatic actuator that discharges liquid droplets from the nozzle openings by deforming the diaphragm by electrostatic force can be used.

  In the above embodiment, the ink jet recording apparatus having the ink jet recording head has been described as an example of the liquid ejecting apparatus. However, the present invention is intended for a wide range of liquid ejecting apparatuses, and includes an ink jet recording apparatus. Of course, the present invention can also be applied to a liquid ejecting apparatus including a liquid ejecting head that ejects liquid other than the above. Other liquid ejecting heads include, for example, various recording heads used in image recording apparatuses such as printers, color material ejecting heads used in the manufacture of color filters such as liquid crystal displays, organic EL displays, and FEDs (field emission displays). Examples thereof include an electrode material ejection head used for electrode formation, a bio-organic matter ejection head used for biochip production, and the like, and can be applied to a liquid ejection apparatus including such a liquid ejection head.

  I ink jet recording apparatus (liquid ejecting apparatus), II ink jet recording head (liquid ejecting head), 1 ink jet recording head unit (liquid ejecting head unit), 8 suction cap, 9 protective cap, 10 flow path forming substrate, 11 Head body, 20 nozzle plate, 20a liquid ejection surface, 21 nozzle opening, 30 protective substrate, 40 case member, 45 compliance substrate, 50 vibration plate, 60 first electrode, 70 piezoelectric layer, 80 second electrode, 100 manifold, 101 drive circuit, 105 cover head (protective member)

Claims (11)

A pressure generation chamber communicating with the nozzle, the pressure generation chamber for discharging the liquid in the pressure generation chamber from the nozzle by pressure fluctuation caused by driving of the drive element;
A manifold that communicates with the pressure generation chamber and supplies liquid to the pressure generation chamber;
Discharging means for discharging the liquid in the pressure generating chamber from the nozzle;
Control means capable of selecting mode 1 or mode 2 and discharging liquid from the nozzle;
With
The mode 1 is a mode in which the liquid in the pressure generation chamber is discharged from the nozzle so that air is drawn into the pressure generation chamber from the nozzle by the operation of the discharge means.
The mode 2 is a mode in which the driving element is driven so that air is not drawn into the pressure generating chamber from the nozzle by driving the driving element.
A liquid ejecting apparatus. The nozzle includes a first nozzle and a second nozzle,
The mode 1 is
Air is drawn into the manifold from the first nozzle;
Air is not drawn from the second nozzle,
In this mode, the air in the manifold drawn from the first nozzle forms a meniscus in the flow path between the pressure generation chamber communicating with the second nozzle and the manifold.
The liquid ejecting apparatus according to claim 1. Furthermore, in the middle of the flow path for supplying the liquid to the manifold, provided with closing means for closing the flow path,
The mode 1 is performed in a state where the flow path is closed by the closing means.
The liquid ejecting apparatus according to claim 1, wherein the liquid ejecting apparatus is a liquid ejecting apparatus. The discharging means is the driving element,
The mode 1 is a mode in which the driving element is driven such that air is drawn from the nozzle into the pressure generating chamber by driving the driving element.
The liquid ejecting apparatus according to claim 1, wherein the liquid ejecting apparatus is a liquid ejecting apparatus. The manifold communicates with the plurality of pressure generation chambers and supplies liquid to the plurality of pressure generation chambers,
The mode 1 is a mode in which the drive element is driven by driving the drive element so that air is drawn into the manifold from the nozzle through at least one pressure generation chamber among the plurality of pressure generation chambers. is there,
The liquid ejecting apparatus according to claim 4. The period of the driving signal for driving the driving element in the mode 1 is shorter than the period of the driving signal for driving the driving element in the mode 2.
The liquid ejecting apparatus according to claim 4, wherein the liquid ejecting apparatus is a liquid ejecting apparatus. The amplitude of the drive signal for driving the drive element in the mode 1 is larger than the amplitude of the drive signal for driving the drive element in the mode 2.
The liquid ejecting apparatus according to claim 4, wherein the liquid ejecting apparatus is a liquid ejecting apparatus. Furthermore, maintenance means for discharging the air in the pressure generating chamber from the nozzle,
A moving means for relatively moving the ejection medium and the nozzle,
The control means includes
(1) In mode 3, the maintenance means can be operated,
(2) In the mode 2, the driving element is configured so that the medium to be ejected and the nozzle are relatively moved by the moving means, and the air is not drawn from the nozzle into the pressure generating chamber by driving the driving element. Drive
(3) After the air is drawn from the nozzle into the pressure generating chamber by the mode 1, the mode 2 is not performed until the air in the pressure generating chamber is discharged by the mode 3.
The liquid ejecting apparatus according to claim 1, wherein the liquid ejecting apparatus is a liquid ejecting apparatus. The control means performs the mode 1 based on a user's selection whether to perform the mode 1;
The liquid ejecting apparatus according to claim 1, wherein the liquid ejecting apparatus is a liquid ejecting apparatus. Furthermore, a detection means for detecting the temperature is provided,
The control means performs the mode 1 based on the detection result of the detection means.
The liquid ejecting apparatus according to claim 1, wherein the liquid ejecting apparatus is a liquid ejecting apparatus. A pressure generation chamber communicating with the nozzle, the pressure generation chamber for discharging the liquid in the pressure generation chamber from the nozzle by pressure fluctuation caused by driving of the drive element;
A manifold that communicates with the pressure generation chamber and supplies liquid to the pressure generation chamber;
Discharging means for discharging the liquid in the pressure generating chamber from the nozzle;
A control method of a liquid ejecting apparatus comprising:
Select mode 1 or mode 2 and control to discharge liquid from the nozzle,
The mode 1 is a mode in which the liquid in the pressure generation chamber is discharged from the nozzle so that air is drawn into the pressure generation chamber from the nozzle by the operation of the discharge means.
The mode 2 is a mode in which the driving element is driven so that air is not drawn into the pressure generating chamber from the nozzle by driving the driving element.
A control method for a liquid ejecting apparatus.

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