JP5217338B2 - Droplet ejector - Google Patents

Description

  The present invention relates to a droplet ejection device, and more particularly to a droplet ejection device provided with a gas permeable film.

  In an apparatus having a liquid ejecting head that ejects liquid droplets, such as an ink jet printer, a liquid supply flow path for supplying a liquid to the liquid ejecting head may be provided as disclosed in Patent Document 1. Patent Document 1 has a recording head provided on a carriage, and an ink cartridge for storing ink to be supplied to the recording head. Ink from the ink cartridge is supplied to the recording head via the sub tank.

  Further, the sub tank of Patent Document 1 is provided with a ventilation film. This ventilation film does not allow ink to pass through, but selectively allows air to pass through. Then, the deaeration pump sucks the inside of the sub tank through the ventilation film to reduce the pressure in the sub tank, thereby introducing the ink from the ink cartridge into the sub tank. In addition, air bubbles in the ink are caused to flow out by sucking the sub tank after the power is turned off. As a result, the gas is separated (gas-liquid separation) from the ink in the sub tank, so that the problem that the gas flows into the head side is suppressed.

Japanese Patent Laying-Open No. 2005-288770 (FIG. 2)

  However, according to Patent Document 1, the inside of the sub tank is sucked when ink is introduced into the sub tank, but thereafter, the inside of the sub tank is not sucked until the power is turned off. Therefore, in Patent Document 1, when the printing operation of the recording head is executed after the ink is introduced into the sub tank, the bubbles in the ink continue to flow out. As a result, the depressurized state in the sub tank is deteriorated, and the bubbles are sufficiently discharged from the ink. There is a possibility that bubbles may flow into the head side together with ink without being separated.

  An object of the present invention is to provide a liquid droplet ejecting apparatus that is easy to hold in a state where a liquid supply flow path to a liquid ejecting head is sufficiently gas-liquid separated.

The liquid droplet ejecting apparatus of the present invention includes a liquid ejecting head having an ejection port for ejecting liquid droplets, a liquid supply channel that supplies liquid to the liquid ejecting head, and a first suction that is always in communication with the liquid supply channel. A gas permeation device installed in a communication section between the flow path, the suction means for sucking the gas in the liquid supply flow path via the first suction flow path, and the liquid supply flow path and the first suction flow path An opening / closing means that takes one of a membrane, a blocking state that blocks communication between the first suction channel and the suction unit, and an open state that allows the first suction channel and the suction unit to communicate with each other; Pressure detecting means for detecting the pressure in one suction flow path, and suction control means for controlling the suction means, wherein the opening / closing means sucks the gas in the first suction flow path by the suction means And the suction means is in the first suction flow path. The suction control means is in the shut-off state after the gas is sucked, and when the pressure detection means detects that the inside of the first suction flow path has become a predetermined pressure or higher, the suction control means A first one-way valve for restricting a direction in which the gas in the first suction channel flows so that the inside of the liquid supply channel is sucked and the opening / closing unit flows only in a direction toward the suction unit; A charge tank provided between the one-way valve in the suction flow path and the liquid supply flow path, the charge tank having a cross section in a direction perpendicular to the extending direction of the first suction flow path; Has a cross-sectional area larger than the area .

  According to the droplet ejecting apparatus of the present invention, the first suction channel that is always in communication with the liquid supply channel via the gas permeable membrane, and the first suction channel and the suction means are connected after the liquid supply channel is aspirated. Since the opening / closing means for blocking is provided, the inside of the liquid supply channel after suction can be held in a state of less than a predetermined pressure. In addition, pressure detecting means for detecting the pressure in the first suction flow path is provided, and when it is detected that the pressure in the first suction flow path is equal to or higher than a predetermined pressure, the suction means sucks the liquid supply flow path. Therefore, even if gas flows in after the liquid supply passage is sucked and the pressure rises, the liquid supply passage can be sucked again and returned to a state below the predetermined pressure. This makes it easier to maintain the gas-liquid separated state in the liquid supply channel.

Further, since the one-way valve is provided as the opening / closing means, when the suction means sucks the liquid supply channel, gas flows in the direction of the suction means in the first suction channel, whereas the suction means supplies the liquid. Even if the suction of the flow path is stopped, the gas is prevented from flowing into the liquid supply flow path from the suction means side. In the first suction channel, a charge tank is provided between the liquid supply channel and the one-way valve. For this reason, when the first suction channel is sucked, the charge tank is also held at a predetermined pressure. Therefore, it is possible to suppress the speed at which the pressure in the first suction channel increases after the liquid supply channel is sucked.

  In the present invention, the one-way valve has a valve body that is movable between an open position that opens the first suction flow path and a closed position that closes the first suction flow path. When the suction means sucks the first suction flow path, the valve body moves to the open position by a suction force acting from the suction means side, and the suction means sucks the first suction flow path. When stopped, it is preferable to move to the closed position by reducing the suction force acting from the suction means side. According to this configuration, the suction means moves to the open position when sucking the first suction flow path, and moves to the closed position when the suction is stopped, so that a one-way valve is easily realized.

  In the present invention, a part of the wall surface defining the first suction flow path has flexibility, and the pressure detection means is detected to be displaced according to a deformation of a part of the wall surface. A member and a sensor for detecting whether or not the detected member is located at a predetermined detection position, and when the internal pressure of the first suction flow path becomes high, a part of the wall surface It is preferable that the member is deformed so as to be displaced toward the predetermined detection position. According to this configuration, when the pressure in the first suction channel increases, the wall surface is deformed, and the detected member is displaced to a predetermined detection position. Then, when the sensor detects that the detected means has reached the detection position, it can be easily detected whether or not the inside of the first suction channel is equal to or higher than the predetermined pressure.

  In the present invention, further comprising a volume variable chamber that communicates with the first suction flow path and changes in volume according to the pressure in the first suction flow path. Volume detection means capable of detecting the volume of the volume variable chamber with a plurality of values, and based on the volume detected by the volume detection means, the pressure in the first suction flow path with a plurality of values. It is preferable to detect. According to this configuration, since the pressure detection means can detect the pressure in the first suction flow path with a plurality of values, the process of sucking the liquid supply flow path more appropriately based on the detection result of the pressure detection means. Can be executed.

According to another aspect of the present invention , there is provided a liquid droplet ejecting apparatus including a liquid ejecting head having an ejection port for ejecting liquid droplets, a liquid supply channel that supplies a liquid to the liquid ejecting head, and the liquid supply channel. A first suction channel that is always in communication, a suction unit that sucks the gas in the liquid supply channel via the first suction channel, and a communication portion between the liquid supply channel and the first suction channel One of a gas permeable membrane installed in the gas, a blocking state in which communication between the first suction channel and the suction unit is blocked, and an open state in which the first suction channel and the suction unit are communicated with each other. An opening / closing means, a pressure detection means for detecting the pressure in the first suction flow path, and the pressure detection means when the pressure detection means detects that the pressure in the first suction flow path is equal to or higher than a predetermined pressure. and suction control means for sucking the liquid supply passage, the liquid ejecting heads An ejection port capping means including a cap movable relative to the liquid ejection head between a sealing position that is in close contact with the ejection port and covers the ejection port, and an open position that opens the ejection port; and an internal space of the cap The second suction channel communicating with the first suction channel and the second suction channel communicating with the second suction channel or not communicating with the second suction channel, or the second suction channel communicating with the second suction channel. Switching means for switching whether or not to communicate with the first suction flow path , the opening and closing means is in the open state when the suction means sucks the gas in the first suction flow path, The suction means enters the shut-off state after sucking the gas in the first suction flow path, and the suction control means detects the pressure detection means when the pressure in the first suction flow path falls below the predetermined pressure. If the suction means is detected, The switching means is controlled to communicate with the second suction flow path, and the injection port capping means is controlled to move the cap to the sealing position, and then the internal space of the cap is sucked. Control the suction means . According to this configuration, it is possible to selectively execute the suction of the internal space of the cap and the suction of the liquid supply channel using one suction means.

Further, by sucking the internal space of the cap that has moved to the sealing position, it is possible to suck the liquid around the jet port of the liquid jet head and the liquid in the jet port. Here, if the amount of gas sucked from the internal space of the cap is large, bubbles in the liquid ejecting head are discharged from the ejection port together with the liquid, but if the amount of gas sucked from the internal space of the cap is small, the liquid supply Bubbles drawn from the flow path to the liquid jet head may not be completely discharged. On the other hand, according to the above-described configuration, the internal space of the cap is sucked when the inside of the first suction flow path falls below a predetermined pressure, so that air bubbles are sufficiently excluded from the liquid supply flow path. The space can be aspirated. For this reason, it is possible to reduce the amount of gas flowing into the liquid ejecting head from the liquid supply channel, and to avoid bubbles remaining in the liquid ejecting head.

  Further, in the present invention, the suction control means may be arranged such that when the pressure detection means detects that the inside of the first suction channel is equal to or higher than the predetermined pressure, the suction means It is preferable that the suction port is sucked by the suction means after the gas is sucked. According to this configuration, since the ejection port is sucked after the bubbles in the liquid supply channel are eliminated, the bubbles in the liquid supply channel are suppressed from being drawn toward the liquid ejection head, and the ejection port is sucked. However, the problem that bubbles cannot be exhausted can be avoided.

  Further, in the present invention, it is provided with a print control means for performing a printing process by ejecting liquid droplets from the ejection port, and the print control means is configured to perform the pressure measurement when the inside of the first suction channel falls below the predetermined pressure. It is preferable to start the printing process when the detection means detects it. According to this configuration, since the printing process is started when the inside of the first suction channel falls below the predetermined pressure, the liquid supply channel can be obtained by executing the printing process with insufficient gas-liquid separation in the liquid supply channel. It is possible to avoid gas from flowing into the injection port side.

  In the present invention, the suction control means causes the print control means to start the printing process when the pressure detection means detects that the inside of the first suction flow path is equal to or higher than the predetermined pressure. Prior to this, it is preferable to cause the suction means to suck the gas in the liquid supply channel. According to this configuration, when the pressure inside the first suction channel is equal to or higher than the predetermined pressure, the liquid supply channel is sucked before executing the printing process. Therefore, it is possible to execute the printing process after reliably setting the inside of the liquid supply channel to a predetermined pressure.

According to still another aspect of the present invention, a liquid ejecting apparatus includes a liquid ejecting head having an ejection port for ejecting liquid droplets, a liquid supply channel that supplies liquid to the liquid ejecting head, and the liquid supply channel. A first suction channel that is always in communication, a suction unit that sucks the gas in the liquid supply channel via the first suction channel, and a communication portion between the liquid supply channel and the first suction channel One of a gas permeable membrane installed in the gas, a blocking state in which communication between the first suction channel and the suction unit is blocked, and an open state in which the first suction channel and the suction unit are communicated with each other. Opening / closing means, pressure detection means for detecting pressure in the first suction flow path, and suction control means for controlling the suction means, wherein the suction means is configured such that the suction means is the first suction flow path. When the gas inside is aspirated, it becomes the open state, The suction means enters the shut-off state after sucking the gas in the first suction flow path, and the suction control means determines that the pressure detection means is set when the pressure in the first suction flow path exceeds a predetermined pressure. When detected, the suction means sucks the inside of the liquid supply channel, and when the internal pressure becomes low, the first suction channel is crushed by a differential pressure with the outside, and the pressure is lower than the predetermined pressure. that having a pressure limiter which closes the flow path becomes a certain value. According to this configuration, the pressure limiter closes the flow path when the pressure in the first suction flow path is too low compared to the predetermined pressure. Therefore, an excessive load is prevented from being applied to the gas permeable membrane because the pressure in the first suction flow path is excessively lowered.

  A preferred embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a plan view showing a schematic configuration of an ink jet printer 1 of the present embodiment. In the following description, a direction from right to left in FIG. 1 is defined as a main scanning direction, and a direction from bottom to top in FIG. 1 is defined as a sub-scanning direction.

  The inkjet printer 1 has an inkjet head 8 (liquid ejection head) that ejects ink. The inkjet head 8 includes a carriage 9 and a head body 30 fixed to the carriage 9. The head main body 30 has a plurality of nozzles 30a for ejecting ink formed on the lower surface, and is fixed to the carriage 9 so that these nozzles 30a are exposed downward. A sub tank 31 to be described later is fixed to the upper surface of the head body 30.

  Guide frames 23 and 24 are installed in the ink jet printer 1, and both of these guide frames 23 and 24 are parallel to the main scanning direction and are spaced apart from each other in the sub-scanning direction. The carriage 9 is installed so as to straddle the guide frames 23 and 24, and is installed on the guide frames 23 and 24 so as to be able to reciprocate along the main scanning direction. A carriage moving unit 25 is installed on the main body frame 1 a of the inkjet printer 1. The carriage moving unit 25 has a drive motor, and the carriage 9 is reciprocated in the main scanning direction by the drive motor.

  The ink jet printer 1 includes main tanks 5 a to 5 d that supply ink of each color to the head main body 30. The main tanks 5a to 5d store yellow (Y), magenta (M), cyan (C), and black (Bk) inks, respectively.

  The main tanks 5a to 5d are respectively provided with remaining amount detection units 6a to 6d for detecting the remaining amount of ink stored in the tank. The remaining amount detection units 6a to 6d detect the remaining amount of ink in the main tanks 5a to 5d, and the remaining amount of ink is less than a predetermined value that is nearly empty (the amount that is not completely empty but is still capable of printing). ) Is transmitted to the control unit 100 described later. In the remaining amount detection units 6a to 6d, for example, a float that floats on the ink surface in the tank and a shielding plate that passes through a predetermined detection position as the float moves according to the ink surface are installed in the tank. The optical sensor detects that the shielding plate has passed the detection position, and transmits the detection result to the control unit 100.

  The ink stored in the main tanks 5 a to 5 d is temporarily stored in the sub tank 31 via the ink tubes 14 a to 14 d and then supplied to the head main body 30. In this embodiment, as described above, the ink tubes 14 a to 14 d and the sub tank 31 form an ink supply channel (liquid supply channel) for supplying ink from the main tanks 5 a to 5 d to the head body 30. Yes. The ink supplied to the head main body 30 is ejected downward from each nozzle 30a. The ink jet printer 1 has a paper transport unit 26 (see FIG. 3). The paper transport unit 26 transports the print paper P to a predetermined printing position below the guide frames 23 and 24. On the printing paper P transported to the printing position, the ink ejected from the head main body 30 lands.

  An absorbing member 22 is installed between the guide frames 23 and 24. The absorbing member 22 is disposed in the vicinity of one end (left end in FIG. 1) of the guide frames 23 and 24 in the main scanning direction, and moves the carriage 9 in the main scanning direction so that the head main body 30 is directly above it. It is arranged so that it can be positioned. The absorbing member 22 is made of a porous material such as urethane foam, and can absorb ink ejected from the head body 30. The control unit 100 moves the carriage 9 above the absorbing member 22 and ejects ink from the head body 30 to cause the absorbing member 22 to absorb the ink. Thereby, the flushing process of the nozzle 30a is performed.

  In the ink jet printer 1, a maintenance capping unit 20 (ejection port capping means) is installed in a region where the nozzles 30 a are formed on the lower surface of the ink jet head 8. The capping unit 20 has a suction cap 21 (cap), and the suction cap 21 is arranged so as to be positioned directly below the head body 30 when the carriage 9 moves to a predetermined maintenance position. Such a maintenance position is set near the right end of the guide frames 23 and 24 in FIG.

  Two protrusions 21 b and 21 c protruding upward are fixed to the upper surface of the suction cap 21. Each of the protrusions 21b and 21c has a rectangular shape in plan view. The protrusions 21b and 21c are formed so as to surround the nozzle 30a formed on the lower surface of the head main body 30 in a plan view when the carriage 9 is in the maintenance position.

  Further, when the carriage 9 is in the maintenance position, the suction cap 21 is retracted downward from the sealing position where the protrusions 21 b are brought into close contact with the lower surface of the head body 30 to cover the nozzle 30 a and from the lower surface of the head body 30. Thus, it is installed in the inkjet printer 1 so as to be movable in the vertical direction between the open position where the nozzle 30a is opened. On the other hand, the capping unit 20 has a moving mechanism (not shown) that moves the suction cap 21 between a sealing position and an opening position. Further, two suction ports 21 a are formed on the upper surface of the suction cap 21. These suction ports 21a are respectively formed in regions where the two protruding portions 21b and 21c surround the planar view. Incidentally, the region surrounded by the protrusion 21b surrounds the nozzle 30a for discharging pigment ink (for example, Bk), and the region surrounded by the protrusion 21c surrounds the nozzle 30a for discharging the dye ink (for example, Y, M, C). Thus, pigment ink and dye ink can be distinguished and sucked.

  The ink jet printer 1 is provided with a suction pump 81 (suction means) and a flow path switching unit 82 (switching means). The suction pump 81 and the flow path switching unit 82 are connected to each other via the air tube 16. The flow path switching unit 82 has first to fourth ports 82a to 82d. The first to third ports 82 a to 82 c are respectively connected to one end of the air tubes 16, 17 a and 17 b, and the fourth port 82 d is connected to one end of the air tube 18. The other ends of the air tubes 17a and 17b are connected to two suction ports 21a formed in the suction cap 21, respectively. The flow path switching unit 82 can selectively communicate any one of the second to fourth ports 82b to 82d with the first port 82a. Thereby, for example, by connecting the first port 82a and the second port 82d, the suction pump 81 can suck air from one of the suction ports 21a via the air tubes 16 and 17a. Further, by connecting the first port 82a and the third port 82c, the suction pump 81 can suck air from the other of the suction ports 21a via the air tubes 16 and 17b.

  On the other hand, the other end of the air tube 18 is connected to the charge tank 84. The charge tank 84 is for accumulating pressure together with the air chamber 51 described later by causing the suction pump 81 to suck air. An internal space 84 a is formed in the charge tank 84, and one end of the internal space 84 a communicates with the air tube 18. The other end of the internal space 84 a communicates with one end of the air tube 19. The internal space 84a is a cross section in which the area of the cross section perpendicular to the air flow direction (direction indicated by the one-dot chain line arrow) from the other end to the one end is perpendicular to the extending direction of the air tubes 18 and 19. It is comprised so that it may become larger than the area of. On the other hand, the other end of the air tube 19 is connected to the sub tank 31.

  A one-way valve 83 is installed in the middle of the air tube 18. FIG. 2 is an example of the one-way valve 83. In the one-way valve 83, a valve chamber 83b communicating with the air tube 18 on the flow path switching unit 82 side and a valve chamber 83c communicating with the air tube 18 on the charge tank 84 side are formed. A valve body 83a is accommodated in the valve chambers 83b and 83c. The valve body 83a has an umbrella part, and the umbrella part is configured to be deformed according to a differential pressure between the valve chamber 83b and the valve chamber 83c. As a result, when the suction pump 81 sucks the air tube 18, the pressure in the valve chamber 83b decreases. Therefore, the suction force acting from the valve chamber 83b side exceeds the suction force acting from the valve chamber 83c side, and the valve body 83a is positioned at the open position where the communication portion between the valve chambers is opened. When the suction pump 81 stops the suction of the air tube 18, the pressure in the valve chamber 83b increases and the suction force from the valve chamber 83b side decreases. Accordingly, the suction force from the valve chamber 83c side exceeds the suction force from the valve chamber 83b side, and the valve body 83a is positioned at the closed position where the communication portion between the valve chambers is closed.

  Therefore, the one-way valve 83 is located in the open position when the suction pump 81 sucks the air tube 18, and moves to the closed position when the suction pump 81 stops sucking the air tube 18. Thus, the one-way valve 83 restricts the flow of air in the air tube 18 so as to flow only in the direction from the charge tank 84 toward the flow path switching unit 82.

  Further, in the middle of the air tube 19, the pressure detection unit 60 (pressure detection means) described later capable of detecting the magnitude of the pressure in the air tube 19 and the pressure in the air tube 19 are activated when the pressure is greatly reduced. A pressure limiter 69 to be described later is installed.

  In this way, the sub tank 31 and the flow path switching unit 82 communicate with each other via the air tubes 18 and 19 and the charge tank 84 (the first suction is performed by the air tubes 18 and 19 and the charge tank 84. The flow path is configured). Then, the air in the sub tank 31 is sucked through the air tubes 16 and 18, the charge tank 84 and the air tube 19 by connecting the first port 82 a and the fourth port 82 d to the flow path switching unit 82. Can be sucked.

  The inkjet printer 1 includes a control unit 100 that controls various operations. The inkjet printer 1 stores hardware such as a processor circuit and various storage devices. The storage device stores various software including a program for operating the processor circuit. The control unit 100 is constructed by combining these hardware and software. As shown in FIG. 3, the control unit 100 includes a print control unit 101 (print control unit) that controls the print operation of the inkjet printer 1. The print control unit 101 controls the conveyance of the printing paper by the paper conveyance unit 26, the movement of the carriage 9 by the carriage movement unit 25, and the ejection of the ink from the inkjet head 8 based on the image data, whereby characters, symbols, and graphics are controlled. A printing operation for forming a predetermined image including the image on the printing paper is executed. The control unit 100 also has a suction control unit 102 (suction control means) that controls the suction operation by the suction pump 81. The suction control unit 102 switches the flow path switching unit 82 so that the air in the sub tank 31 can be sucked or the suction cap 21 can be sucked. The suction control unit 102 moves the capping unit 20 between a sealing position that covers the nozzle 30a and an open position that opens the nozzle 30a. Then, the driving of the suction pump 81 is controlled. Thus, the suction control unit 102 performs a suction operation of sucking the sub tank 31 or sucking the nozzle 30a. The control unit 100 also includes a remaining amount determination unit 103 that determines the remaining amount of ink in the main tanks 5a to 5d.

  Furthermore, detection results from the remaining amount detection units 6 a to 6 d and the pressure detection unit 60 are input to the control unit 100. The control unit 100 controls the printing operation and the suction operation based on the detection results from the remaining amount detection units 6 a to 6 d and the pressure detection unit 60. When the detection results from the remaining amount detection units 6a to 6d indicate that the remaining amount of ink in the main tanks 5a to 5d is almost empty, a warning is given that the remaining amount of ink is nearly empty. The control unit 100 may display a message to be displayed on a display device (not shown). In addition, when the detection results from the remaining amount detection units 6a to 6d indicate that the remaining amount of ink in the main tanks 5a to 5d is almost empty, the control unit 100 indicates the detection result. Start counting the number of times the corresponding main tank ink is ejected. The number of injections is used in the main tank remaining amount determination process described later.

  The ink jet head 8 will be described in more detail with reference to FIGS. FIG. 4 is a perspective view of the inkjet head 8 with the head cover, the sub tank 31 and the like removed from the carriage 9. FIG. 5 is a plan view of the inkjet head 8 with the head cover removed from the inkjet head 8. The carriage 9 has a substantially rectangular parallelepiped shape, and has a box shape opened upward. A sub tank 31 and a head body 30 are accommodated in the carriage 9, and a head cover covers the carriage 9 from above. 4 and 5, the head cover is not shown.

  The sub tank 31 has an introduction part 31a, and the ink tubes 14a to 14d and the air tube 19 are connected to the introduction part 31a. A head main body 30 is fixed to the bottom of the carriage 9. An opening 30c, which is an ink inlet, is formed on the upper surface of the head body 30 (FIG. 4). The opening 30c has four inlets according to the four colors of ink. The sub tank 31 is accommodated in the carriage 9 above the head body 30 so that the ink supply ports of the respective colors from the sub tank 31 communicate with the introduction ports of the respective colors of the openings 30c.

  An ink flow path (not shown) is formed in the head body 30 with one end communicating with the nozzle 30a and the other end communicating with the opening 30c. A jet actuator 30b is attached to the upper surface of the head body 30 (FIG. 4). The ejection actuator 30 b is a unit that applies ejection energy for ejecting ink from the nozzles 30 a formed on the lower surface of the head main body 30 to the ink filled in the ink flow path in the head main body 30. The ejection actuator 30b includes, for example, a piezoelectric layer and an electrode layer that deforms the piezoelectric layer by generating an electric field in the piezoelectric layer. When a predetermined drive signal is supplied to the electrode layer, the piezoelectric layer is deformed, and pressure fluctuation for ink ejection is generated in the ink in the ink flow path.

  From the upper surface of the ejection actuator 30b, a flexible wiring board 72 for supplying a drive signal for ink ejection to the electrode layer is drawn upward and connected to the control unit 100 (FIG. 4). In the flexible wiring board 72, wiring for transmitting an electrical signal is provided. A driver circuit board 73 is mounted on the flexible wiring board 72. The control unit 100 transmits a control signal for ink ejection to the driver circuit board 73 via the flexible wiring board 72, and the driver circuit board 73 converts the control signal from the control unit 100 into a drive signal to eject the ejection actuator 30b. To supply. The driver circuit board 73 extends along the vertical direction and the sub-scanning direction, and has a long shape with respect to the sub-scanning direction. The surface facing the flexible wiring board 72 is along a plane perpendicular to the main scanning direction, and the surface opposite to the surface in the sub-scanning direction is also along a plane perpendicular to the main scanning direction.

  A heat sink 71 is installed in the carriage 9 to prevent the driver circuit board 73 from overheating. The heat sink 71 is a member made of a metal material, and has a long shape in the sub-scanning direction as shown in FIGS. 4 and 5. The heat sink 71 is disposed between the driver circuit board 73 and the sub tank 31 in the main scanning direction. The surface of the heat sink 71 facing the driver circuit board 73 is disposed along the surface of the driver circuit board 73 and is in contact with the driver circuit board 73 so as to be in close contact therewith. Further, it is fixed to the driver circuit board 73 with an adhesive or the like so as to be held in close contact with the driver circuit board 73. An elastic member or the like may be provided that applies an urging force that holds the driver circuit board 73 in close contact with the heat sink 71. Thereby, the heat generated from the driver circuit board 73 is reliably transmitted to the heat sink 71.

  Hereinafter, the configuration in the sub-tank 31 will be described with reference to FIGS. 5 and 6. In FIG. 5, the internal configuration of the sub tank 31 is indicated by a broken line. FIG. 6 is a longitudinal sectional view of the sub tank 31 taken along line VI-VI in FIG.

  As shown in FIG. 6, the sub tank 31 has a tank body 31b and a lid member 31c. In the tank main body 31b, as shown in FIG. 5, ink storage chambers 41 to 44 for storing ink are formed. In addition, ink channels 45 to 48 for introducing ink from the ink tubes 14a to 14d into the ink storage chambers 41 to 44 are formed in the tank body 31b. The ink supplied from the main tanks 5a to 5d via the ink tubes 14a to 14d flows into the ink storage chambers 41 to 44 via the ink flow paths 45 to 48. Ink storage chambers 41 to 44 store Bk, C, M, and Y inks, respectively. Although only the ink storage chamber 42 is shown in FIG. 6, the configuration of the ink storage chamber 42 shown in FIG. 6 is the same as the common configuration of the ink storage chambers 41 to 44 unless otherwise specified. To do.

  The ink storage chambers 41 to 44 have a substantially rectangular parallelepiped shape that is long in the sub-scanning direction, and are arranged along the main scanning direction. The ink storage chambers 42 to 44 are all formed to have the same volume, while the ink storage chamber 41 is formed to have a larger volume than the other ink storage chambers. This is because Bk color ink is stored in the ink storage chamber 41, and the Bk color is generally consumed earlier, so that more ink can be stored at a time than the ink storage chambers of other colors.

  In the tank main body 31b, communication holes 41a to 44a are formed above the ink storage chambers 41 to 44. The upper surface of the tank body 31b is along a horizontal plane, and the communication holes 41a to 44a are all open on the upper surface of the tank body 31b. A gas permeable film 53 is attached to the upper surface of the tank body 31b by bonding or the like so as to close the openings of the communication holes 41a to 44a. The gas permeable film 53 is a film that allows gas to pass through but does not allow ink or solid other than gas to pass through. For example, a porous fluororesin film is used.

  In the tank main body 31 b, ink flow paths 41 b to 44 b that are ink supply flow paths to the head main body 30 are formed below the ink storage chambers 41 to 44. The ink flow paths 41 b to 44 b communicate with the respective inlets of the opening 30 c formed on the upper surface of the head main body 30. In order to make the drawing easier to see, FIG. 5 does not show the ink flow paths 41b to 44b, and FIG. 6 shows only the ink flow path 42b.

  An air chamber 51 and an air flow path 52 are formed in the lid member 31c. The air chamber 51 has a rectangular planar shape that is long in the main scanning direction, and is a recess that is opened on the lower surface of the lid member 31c. The air chamber 51 is formed so as to straddle the ink storage chambers 41 to 44 in the main scanning direction. The air chamber 51 communicates with one end of the air flow path 52. The other end of the air flow path 52 communicates with the air tube 19.

  Hereinafter, the pressure detection unit 60 will be described with reference to FIG. The air tube 19 has a pressure detection region 19a including a wall surface that expands and contracts according to the internal pressure. The pressure detection unit 60 has an optical sensor 62 and a shielding plate 61 (detected member) installed outside the pressure detection region 19a. The optical sensor 62 includes a light emitting unit 62a that emits light, and a light receiving unit 62b that includes a light receiving unit on an extension line of the emitted light α. The light receiving unit 62b outputs a signal indicating the intensity of the received light to the control unit 100.

  On the other hand, the wall surface facing the optical sensor 62 in the pressure detection region 19a is formed of an elastic film 63. The elastic coating 63 is formed of an elastic material that is easily deformed in accordance with the internal pressure as compared with other portions of the air tube 19. Instead of a film made of an elastic material such as the elastic film 63, another flexible member such as a resin film may be provided. A biasing member 64 that biases the elastic film 63 toward the optical sensor 62 is installed in the pressure detection region 19a. Thereby, the elastic film 63 is deformed so as to protrude to the optical sensor 62 as shown in FIG. 7A when the pressure in the air tube 19 is equal to or higher than a predetermined pressure. When the pressure in the air tube 19 decreases, the air tube 19 is deformed so as to retract into the air tube 19 against the urging force of the urging member 64 due to the differential pressure inside and outside the air tube 19. .

  On the other hand, the shielding plate 61 is fixed to the outer surface of the elastic coating 63, and the fixing position thereof is the outgoing light α on the path of the outgoing light α in accordance with the deformation of the elastic coating 63 as described above. 7 (a) is shielded from the position (detection position) to be displaced from the position to the position shown in FIG. 7 (b). Further, the urging force of the urging member 64 is such that when the pressure in the air tube 19 is equal to or higher than a predetermined pressure, the shielding plate 61 shields the emitted light α, and the pressure in the air tube 19 is lower than the predetermined pressure. In this case, the shielding plate 61 is set so as to be separated from the path of the outgoing light α. Therefore, the control unit 100 can determine whether or not the shielding plate 61 exists on the path of the outgoing light α based on the received light intensity indicated by the signal from the light receiving unit 62b, and thereby the pressure in the air tube 19 can be determined. It can be determined whether or not is below a predetermined pressure. In this way, the pressure detection unit 60 can detect whether or not the inside of the air tube 19 is held in a state of less than a predetermined pressure. If the elastic film 63 is a film that has sufficient flexibility and is easily deformed in accordance with a change in pressure, the urging member 64 can be omitted.

  However, if the pressure in the air tube 19 falls below a predetermined pressure and continues to decrease, the pressure in the air chamber 51 may be excessively decreased, and an excessive load may be applied to the gas permeable membrane 53. In order to avoid such a situation, a pressure limiter 69 is provided in this embodiment. As shown in FIG. 8A, the pressure limiter 69 is a tubular member having a size that allows the air tube 19 to be inserted therein. An opening 19b of the air tube 19 on the air chamber 51 side is inserted into one end of the pressure limiter 69, and an opening 19c of the air tube 19 on the pressure detection unit 60 side is inserted into the other end of the pressure limiter 69. Yes. When the pressure in the air tube 19 becomes lower than the predetermined pressure, the pressure limiter 69 is deformed according to the pressure difference between the inside and outside and is deformed so as to be crushed toward the central axis. And when the inside of the air tube 19 reaches a certain pressure, it is adjusted so that the inside is completely closed as shown in FIG. This prevents the pressure in the air tube 19 from excessively decreasing.

  Hereinafter, the control content of the control unit 100 will be described in more detail. The control unit 100 refers to the detection result of the pressure detection unit 60. When it is determined that the pressure in the air tube 19 has become equal to or higher than the predetermined pressure, the suction control unit 102 of the control unit 100 executes an air chamber suction process that causes the suction pump 81 to suck the air chamber 51. Such air chamber suction processing will be described. First, when the air tubes 16 and 18 are not in communication with each other, the suction control unit 102 controls the flow path switching unit 82 so that they are in communication with each other. As a result, the suction pump 81 and the air chamber 51 communicate with each other via the air tubes 16 and 18, the charge tank 84, the air tube 19, and the air flow path 52 (first suction flow path). Then, by driving the suction pump 81, the inside of the air chamber 51 is sucked, and based on the detection result of the pressure detection unit 60, the state in the air tube 19 is lower than a predetermined pressure, that is, the air chamber 51 has a predetermined pressure. The suction by the suction pump 81 is performed until the state becomes lower.

  Here, the one-way valve 83 described above is installed in the middle of the air tube 18, and the flow of air in the air tube 18 is restricted so as to flow only in the direction from the charge tank 84 toward the flow path switching unit 82. ing. As a result, when the pressure in the air chamber 51 (in the air tube 19 and the charge tank 84) is lowered to a state below a predetermined pressure, the suction pump 81 is stopped or the flow path is switched to the flow path switching unit 82 to change the air. When the chamber suction process is terminated, the valve element 83a is positioned at a closed position where the valve body 83a is closed by the differential pressure between the valve chamber 83b and the valve chamber 83c. Therefore, the inflow of air into the air chamber 51 is suppressed, and the state in which the air chamber 51 is less than a predetermined pressure can be maintained.

  On the other hand, since the air chamber 51 is separated from the ink storage chambers 41 to 44 via the gas permeable film 53, the ink storage chambers 41 to 44 are passed through the gas permeable film 53 by holding the air chamber 51 below a predetermined pressure. The air inside can be separated from the ink (gas-liquid separation) and sucked into the air chamber 51. That is, in the present embodiment, the gas in the ink storage chambers 41 to 44 is sucked by the air chamber suction process for sucking the air chamber 51. That is, the air chamber suction process sucks the ink supply channel (liquid supply channel) from the main tanks 5a to 5d through the ink storage chambers 41 to 44 to the head body 30. The predetermined pressure is adjusted to a size such that the inside of the ink storage chambers 41 to 44 is sufficiently gas-liquid separated through the gas permeable film 53, and is, for example, a pressure below atmospheric pressure. Therefore, when the pressure in the air chamber 51 is maintained below a predetermined pressure, the gas-liquid separation state in the ink storage chambers 41 to 44 is maintained, and air flows from the ink storage chambers 41 to 44 into the head body 30. To be suppressed.

  The control unit 100 further executes various control processes based on the detection result of the pressure detection unit 60. Hereinafter, the control processing based on the detection result of the pressure detection unit 60 will be described in order. The first process is a maintenance process for the nozzle 30a. FIG. 9 is a flowchart showing each step of the maintenance process of the nozzle 30a. First, the control unit 100 determines whether or not the inside of the air tube 19 is below a predetermined pressure based on the light intensity indicated by the signal from the light receiving unit 62b of the pressure detection unit 60 (S1). And if it determines with the inside of the air tube 19 not being below the predetermined pressure (S1, NO), the suction control part 102 of the control part 100 will perform an air chamber suction process (S3). Then, the air chamber suction process is continuously executed until the inside of the air tube 19 falls below a predetermined pressure (S1, NO, and S3).

  If it is determined that the inside of the air tube 19 has fallen below the predetermined pressure (S1, YES), the suction controller 102 starts a nozzle suction operation (S2). Hereinafter, the nozzle suction operation will be described. The suction control unit 102 first controls the flow path switching unit 82 so that the air tube 16 and the air tube 17a are in communication with each other. As a result, the suction pump 81 and the internal space in one protrusion 21b of the suction cap 21 are in communication with each other via the air tubes 16 and 17a and the suction port 21a (second suction flow path).

  Next, the suction control unit 102 moves the carriage 9 to the maintenance position above the capping unit 20, and controls the capping unit 20 to move the suction cap 21 to the sealing position for sealing the nozzle 30a. Let As a result, the nozzle 30 a is covered with the suction cap 21. Then, the suction pump 81 is controlled to suck the internal space in one protrusion 21 b of the suction cap 21. Further, the suction control unit 102 controls the flow path switching unit 82 to cause the air tubes 16 and 17b to communicate with each other, and causes the suction pump 81 to suck the internal space in one protrusion 21c of the suction cap 21. As a result, the ink in the nozzle 30a that is surrounded by the other protrusion 21c in plan view is sucked. According to the nozzle suction operation described above, excess ink around the nozzle 30a and air mixed in the ink flow path are removed. Further, the nozzle 30a surrounded by the one protrusion 21b and the nozzle 30a surrounded by the other protrusion 21c can be sucked separately.

  In the nozzle maintenance process, as described above, based on the detection result of the pressure detection unit 60, when the air chamber 51 (in the air tube 19) has a predetermined pressure or more, the air chamber suction process is executed, and the air chamber 51 The inside of the air chamber 51 is continuously sucked until the inside becomes less than a predetermined pressure. And after the inside of the air chamber 51 becomes less than predetermined pressure, it transfers to nozzle suction operation | movement. Therefore, it is avoided that the nozzle suction operation is started without the air chamber 51 reaching a state below the predetermined pressure. As a result, air is prevented from flowing from the ink storage chambers 41 to 44 into the head body 30 by performing the nozzle suction operation with insufficient gas-liquid separation in the ink storage chambers 41 to 44. In addition, if the suction amount in the nozzle suction operation is small, bubbles that have flowed into the ink flow path may not be sufficiently removed by the nozzle suction operation, but in the present embodiment, as described above, air is discharged before the nozzle suction operation. The chamber suction process is executed, and the nozzle suction operation is executed after the inside of the air chamber 51 falls below a predetermined pressure. Accordingly, since the nozzle suction operation is executed after gas-liquid separation (removal of gas) from the ink in the ink storage chambers 41 to 44, the amount of gas flowing from the ink storage chambers 41 to 44 into the head body 30 is reduced. Even if the suction amount is small in the nozzle suction operation, bubbles can be prevented from remaining in the ink flow path.

  The second process is a printing process. FIG. 10 is a flowchart showing each step when starting the printing process. First, the control unit 100 detects whether or not the inside of the air tube 19 is below a predetermined pressure based on the light intensity indicated by the signal from the light receiving unit 62b of the pressure detection unit 60 (S11). And if it determines with the inside of the air tube 19 not being less than the predetermined pressure (S11, NO), the suction control part 102 of the control part 100 will perform an air chamber suction process (S13). Then, the air chamber suction process is continued until the inside of the air tube 19 falls below a predetermined pressure (S11, NO, and S13). When it is determined that the inside of the air tube 19 has fallen below the predetermined pressure (S11, YES), the print control unit 101 of the control unit 100 starts a printing operation (S12).

  In the printing process, as described above, based on the detection result of the pressure detection unit 60, when the air chamber 51 is at a predetermined pressure or higher (in the air tube 19), the air chamber suction process is executed. The air chamber 51 is continuously sucked until the pressure becomes less than a predetermined pressure. Then, after the inside of the air tube 19 becomes less than a predetermined pressure, the printing operation is started. Accordingly, it is possible to avoid starting the printing operation without reaching the predetermined pressure in the air chamber 51. This prevents the air from flowing from the ink storage chambers 41 to 44 to the head body 30 by performing the printing operation with insufficient gas-liquid separation in the ink storage chambers 41 to 44.

  The suction of the air chamber 51 by the suction pump 81 may be continued or stopped at the start of the printing operation. Even if the suction is stopped, the inside of the air chamber 51 is maintained at a pressure lower than the predetermined pressure by the one-way valve 83 as described above. Thereafter, when the printing operation is started, the ink is ejected from the nozzle 30a, and the ink moves from the main tanks 5a to 5d to the ink storage chambers 41 to 44 in order to supplement the ejected amount. As a result, the air contained in the liquid in the main tanks 5a to 5d may move into the ink storage chambers 41 to 44, but the air chamber 51 is maintained in a state of less than a predetermined pressure. This air can also be separated.

  The third process is a main tank remaining amount determination process. When the inside of the air chamber 51 is made less than a predetermined pressure by the air chamber suction process, the inside of the air chamber 51 is held in a state below the predetermined pressure by the action of the one-way valve 83. In this case, even if the air suction process is performed, if the pressure in the air chamber 51 does not decrease at all and the air chamber 51 remains at a predetermined pressure or higher, any ink in the main tanks 5a to 5d is used. Is emptied, and it is considered that the air inside thereof enters the air chamber 51 through the ink storage chambers 41 to 44. Based on this phenomenon, the remaining amount determination unit 103 of the control unit 100 executes a remaining amount determination process that identifies an empty tank among the main tanks 5a to 5d. FIG. 11 is a flowchart showing each step of the remaining amount determination process.

  First, the control unit 100 determines whether the pressure in the air chamber 51 (in the air tube 19) is equal to or higher than a predetermined pressure based on the detection result of the pressure detection unit 60 (S21). When it is determined that the pressure is not higher than the predetermined pressure (S21, NO), the remaining amount determination unit 103 of the control unit 100 determines that there is no empty tank among the main tanks 5a to 5d and ends the remaining amount determination process. . If it is determined that the pressure is equal to or higher than the predetermined pressure (S21, YES), the suction control unit 102 of the control unit 100 executes an air chamber suction process (S22). Then, after executing the air chamber suction process, the remaining amount determination unit 103 determines again whether or not the inside of the air chamber 51 is equal to or higher than the predetermined pressure based on the detection result of the pressure detection unit 60 (S23). . Here, if it is determined that the air chamber 51 has recovered from a state below the predetermined pressure (S23, NO), it is determined that there is no empty tank among the main tanks 5a to 5d, and the remaining amount determination process is performed. finish.

  On the other hand, when it is determined that the pressure in the air chamber 51 still remains higher than the predetermined pressure (S23, YES), the remaining amount determination unit 103 is one in which any of the main tanks 5a to 5d is emptied. Is determined. Next, the remaining amount determination unit 103 acquires which of the main tanks 5a to 5d the remaining amount of ink has become less than a predetermined value based on the detection results of the remaining amount detection units 6a to 6d (S24). That is, when any of the main tanks 5a to 5d is empty, any of the detection results of the remaining amount detection units 6a to 6d should indicate that the remaining amount of ink is less than a predetermined value. is there. Therefore, the remaining amount determination unit 103 acquires the detection result of the remaining amount detection units 6a to 6d indicating that the remaining amount of ink is less than the predetermined value as the main tanks 5a to 5d being empty. To do.

  Next, the remaining amount determination unit 103 determines whether or not there are a plurality of main tanks acquired as having become empty in S24 (S25). And when the acquired main tank is single (S25, NO), the process after S27 is performed. On the other hand, when there are a plurality of acquired main tanks (S25, YES), the remaining amount determination unit 103 determines the number of ink ejections after the detection results of the remaining amount detection units 6a to 6d indicate a state of being nearly empty. refer. Of the plurality of main tanks whose detection results of the remaining amount detection units 6a to 6d indicate a state close to empty, the main tanks that are closest to the empty state as viewed from the number of injections are empty among the main tanks 5a to 5d. Get as a state main tank. And the empty alerting | reporting operation | movement which alert | reports to a user that the acquired main tank is empty among main tanks 5a-5d is performed (S27). The empty notification operation is executed by displaying characters indicating the empty main tank on the display device, for example.

  Hereinafter, the effect of this embodiment is demonstrated.

  According to the present embodiment, the inside of the ink storage chambers 41 to 44 is maintained in a gas-liquid separated state even after the suction in the air chamber 51 is stopped by the action of the one-way valve 83 as described above. Therefore, even if the printing operation is started or the nozzle suction operation is started thereafter, the situation where air flows into the head main body 30 from the ink storage chambers 41 to 44 is suppressed.

  In addition, since various control processes are executed based on the pressure detection unit 60, the air chamber 51 is suctioned until it becomes less than a predetermined pressure, or after the air chamber 51 reaches a predetermined pressure, printing operation and nozzle suction are performed. Control to start the operation is possible. As described above, since the air chamber 51 is sucked so as to be less than the predetermined pressure based on the detection result of the pressure detection unit 60, the air chamber 51 is gas-liquid during the printing operation, before and after the printing operation, and before the nozzle suction operation. It becomes possible to maintain the separated state.

  In the main tank remaining amount determination process, when the detection result of the pressure detection unit 60 indicates that the pressure is equal to or higher than a predetermined pressure, the detection result of the pressure detection unit 60 is once again after executing the air chamber suction process. It is determined whether or not the pressure is equal to or higher than the predetermined pressure. When the pressure is still higher than or equal to the predetermined pressure, it is determined that any of the main tanks 5a to 5d is empty. Therefore, when the main tanks 5a to 5d are not emptied but are merely temporarily introduced into the air chamber 51 for another reason, it is erroneously determined that the main tanks 5a to 5d are empty. Is suppressed. That is, it can be determined with high accuracy that the main tank is empty.

  Further, in the main tank remaining amount determination process, after determining that at least one of the main tanks 5a to 5d is empty based on the detection result of the pressure detection unit 60, the detection results of the remaining amount detection units 6a to 6d are used. Based on this, it is narrowed down which main tank is empty. As a result of the narrowing down, when a plurality of main tanks are acquired as being empty, the narrowing is further performed based on the number of ink ejections. Therefore, an empty main tank can be obtained with higher accuracy.

  A charge tank 84 is connected between the air chamber 51 and the one-way valve 83. Since the charge tank 84 is configured to have a larger cross-sectional area than the air tubes 18 and 19, these are compared with the case where the air chamber 51 and the one-way valve 83 are connected only by the air tube. The volume between can be increased. As a result, it is possible to earn a volume for storing pressure, so that a situation in which the air chamber 51 immediately becomes equal to or higher than the predetermined pressure just by a small amount of air entering the air chamber 51 is avoided. It is possible to keep the inside of the storage chambers 41 to 44 in a gas-liquid separation state for a longer period.

  A pressure limiter 69 is installed in the middle of the air tube 19, and the pressure limiter 69 closes the air tube 19 when the pressure in the air tube 19 decreases too much. Therefore, even if the pressure in the air chamber 51 is significantly lower than the predetermined pressure during the air chamber suction processing, the pressure in the air chamber 51 is too low due to the air limiter 69 closing the air tube 19. It is prevented.

  Hereinafter, other embodiments according to the one-way valve and the pressure detection unit will be described. FIG. 12 is a sectional view of a one-way valve 183 that replaces the one-way valve 83 described above. In the one-way valve 183, a valve chamber 183c communicating with the air tube 18 on the flow path switching unit 82 side and a valve chamber 183d communicating with the air tube 18 on the charge tank 84 side are formed. A valve body 183b is accommodated in the valve chambers 183c and 183d. The valve body 183b is movably disposed between a closed position where the communication portion between the valve chamber 183c and the valve chamber 183d is closed and an open position where the communication portion is opened. A biasing member 183a is installed in the valve chamber 183c, and the biasing member 183a biases the valve body 183b toward the closed position. Thus, when the suction pump 81 is not sucking the air tube 18, the valve body 183 b is positioned at a closed position that closes the communication portion between the valve chambers. On the other hand, when the suction pump 81 sucks the air tube 18, the pressure in the valve chamber 183c decreases. As a result, the suction force acting from the valve chamber 183c side exceeds the resultant force of the biasing force of the biasing member 183a and the suction force acting from the valve chamber 183d side, and the valve body 183b opens the communication portion between the valve chambers. It is designed to be positioned in the open position. When the suction pump 81 stops the suction of the air tube 18, the suction force acting from the valve chamber 183c side is reduced, and the resultant force of the biasing force of the biasing member 183a and the suction force acting from the valve chamber 183d side is The valve body 183b moves to the closed position. With the above configuration, the one-way valve 183 can restrict the flow of air in the air tube 18 so as to flow only in the direction from the charge tank 84 toward the flow path switching unit 82, similarly to the one-way valve 83. .

  FIG. 13 is a longitudinal sectional view of a pressure detection unit 160 that replaces the pressure detection unit 60 described above. The pressure detection unit 160 is installed together with a bellows tank 184 that is an embodiment different from the charge tank 84. The pressure detection unit 160 includes a detection tank 162 and a bellows tank 184 installed inside the detection tank 162. The bellows tank 184 is a member having a bellows shape that expands and contracts in the vertical direction according to the internal pressure, and is fixed to the bottom surface in the detection tank 162. An air channel 162 a is formed in the detection tank 162, and the air channel 162 a communicates with the air tubes 18 and 19 and the bellows tank 184.

  The detection tank 162 is open upward, and a switch unit 161 is fixed on the upper surface of the detection tank 162. The switch unit 161 has a switch lever 161a. The switch lever 161a is tilted so that its tip is positioned upward (the state shown in FIG. 13A), and is tilted so as to be positioned downward (the state shown in FIG. 13B). It is installed in the switch unit 161 so that it can move between. The switch unit 161 is provided with means for urging the switch lever 161a to be in the second state. The switch unit 161 transmits a detection signal indicating whether the switch lever 161a is in the first state or the second state to the control unit 100.

  The bellows tank 184 is installed so that the upper end abuts against the switch lever 161a and holds the switch lever 161a in the first state as shown in FIG. 13A when the internal pressure is equal to or higher than a predetermined pressure. . Then, when the pressure in the bellows tank 184 decreases, the bellows tank 184 contracts downward. When the pressure is lower than a predetermined pressure, the upper end is separated from the switch lever 161a and the switch lever 161a is adjusted to the second state. ing.

  With the above configuration, the control unit 100 can determine whether or not the switch lever 161a is in the second state based on the detection signal from the pressure detection unit 160, whereby the inside of the bellows tank 184 is less than a predetermined pressure. It can be determined whether or not. In addition, pressure can be stored in the bellows tank 184 by contraction of the bellows tank 184.

  Hereinafter, still another embodiment relating to the pressure detection unit will be described. FIG. 14 is a longitudinal sectional view of a pressure detection unit 260 that replaces the pressure detection unit 60 described above. As illustrated in FIG. 14, the pressure detection unit 260 includes an air flow path 263, a bellows tank 284, and a volume detection sensor 261.

  The air flow path 263 extends in the left-right direction in FIG. 14, and communicates with the air tubes 19, 18 at communication ports 263 a, 263 b provided at both left and right ends in the figure. In addition, a communication port 263c that connects the air flow path 263 and a charge chamber 284c (described later) of the bellows tank 284 is provided on the upper surface of the air flow path 263 at substantially the center of FIG.

  The bellows tank 284 extends in the vertical direction of FIG. 14, and a charge chamber 284c (volume variable chamber) surrounded by a ceiling wall 284b and a side wall 284a is formed therein. The ceiling wall 284b is a wall that defines the upper end of the charge chamber 284c, and has a substantially circular planar shape. The side wall 284a is a wall that defines the side surface of the charge chamber 284c, and extends downward from the outer edge of the ceiling wall 284b while being alternately bent outward and inward of the charge chamber 284c. As a result, when a force is applied to the ceiling wall 284b in the vertical direction, the ceiling wall 284b moves in the vertical direction, the bending angle θ of the side wall 284a changes, and the volume of the charge chamber 284c changes. The lower end of the charge chamber 284c is open and connected to the communication port 263c. Thereby, the air flow path 263 and the charge chamber 284c communicate.

  In the bellows tank 284, before the charge chamber 284c is sucked, as shown in FIG. 14A, the ceiling wall 284b is at the highest position and the bending angle θ of the side wall 284a is maximum. . Then, when the gas is sucked from the tube 18 by the suction pump 81, the pressure in the charge chamber 284c decreases. As a result, a downward force is generated on the ceiling wall 284b due to the difference between the external pressure and the pressure in the charge chamber 284c. Therefore, as shown in FIG. 14B, the ceiling wall 284b moves downward, and accordingly, the bending angle θ of the side wall 284a becomes small. Due to such deformation of the bellows tank 284, the volume of the charge chamber 284c decreases.

  Conversely, as shown in FIG. 14B, when the gas in the ink storage chambers 41 to 44 is discharged to the air chamber 51 through the gas permeable film 60 when the inside of the charge chamber 284 c is depressurized. The gas flows through the air tube 19 into the charge chamber 284c. As a result, the pressure in the charge chamber 284c increases, and the downward force generated by the pressure difference between the charge chamber 284c and the outside decreases. Therefore, in the bellows tank 284, the ceiling wall 284b moves upward, and the bending angle θ of the side wall 284a increases accordingly. Due to such deformation of the bellows tank 284, the volume of the charge chamber 284c increases.

  Here, when the bending angle θ of the side wall 284a is smaller than the state of FIG. 14A, an upward repulsive force in FIG. 14 is generated on the side wall 284a to return to the state of FIG. The repulsive force increases as the bending angle θ of the side wall 284a becomes smaller than the state shown in FIG. The force generated by the differential pressure between the inside and outside of the charge chamber 284c balances with the repulsive force, whereby the deformation of the charge tank 284 is held in a stopped state. Therefore, in a state where the deformation of the charge tank 284 is stopped, the volume of the charge chamber 284c is smaller as the pressure in the charge chamber 284c is lower. That is, the pressure in the charge chamber 284c and the volume of the charge chamber 284c are in a predetermined relationship.

  Since the charge chamber 284c is provided between the air tubes 18 and 19, the combined volume of the air tubes 18, 19 and the charge chamber 284c is compared with the volume when the bellows tank 284 is not provided. The charge chamber 284c becomes larger. That is, by providing the pressure detection unit 260, the same function as the above-described charge tank 84 is realized.

  The volume detection sensor 261 is a sensor for detecting the volume in the charge chamber 284c, and includes a movable portion 262, a plurality of slits 262a, and a slit detection sensor 264. The movable portion 262 is installed so as to move in the vertical direction together with the ceiling wall 284b of the bellows tank 284. The plurality of slits 262a are provided at the right end portion of the movable portion 262 in FIG. 14, and each of the slits 262a extends in the left-right direction in the drawing and is arranged in the up-down direction. The slit detection sensor 264 detects that each slit 262a has passed through the slit detection sensor 264 in the vertical direction. Since the plurality of slits 262a move in the vertical direction together with the ceiling wall 284b, the slit detection sensor 264 detects that each slit 262a has passed through the slit detection sensor 264, whereby the volume of the charge chamber 284c is set to a plurality of values. Can be detected. The detection result of the slit detection sensor 264 is output to the control unit 100.

  Here, as described above, the position of the ceiling wall 284b, that is, the volume of the charge chamber 284c and the pressure in the charge chamber 284c have a predetermined correspondence relationship. Therefore, in the volume detection sensor 261, the slit detection sensor 264 detects that each of the plurality of slits 262a moving in the vertical direction together with the ceiling wall 284b has passed through the slit detection sensor 264, whereby the inside of the charge chamber 284c. The pressure can be detected by a plurality of values.

  The controller 100 executes the air chamber suction process based on the detection result of the slit detection sensor 264. As described above, according to the detection result of the slit detection sensor 264, the pressure in the charge chamber 284c can be detected by a plurality of values. Therefore, according to the pressure detection unit 260, compared to the pressure detection unit 60, it is possible to cause the control unit 100 to execute more detailed processing corresponding to a plurality of pressure detection values. For example, it is possible to execute processing such as changing the amount of suction by the suction pump 81 according to the pressure detection value or rapidly sucking the air chamber 51 when it is detected that the pressure detection value has rapidly increased.

  FIG. 15 shows a pressure detection unit 360 that can detect pressure with a plurality of values in the same manner as the pressure detection unit 260. The pressure detection unit 360 is provided with a volume detection sensor 361 instead of the volume detection sensor 261. The volume detection sensor 361 includes a lever 362, a fixed base 363, a movable plate 364, a plurality of slits 364a, and a slit detection sensor 366.

  The lever 362 extends substantially along a straight line, and is rotatably supported by support portions 362a and 362b at a portion slightly on the right side and a left end portion of the substantially central portion in FIG. The fixed base 363 is fixed to the upper surface of the ceiling wall 284b, and the support 362b is provided on the fixed base 363.

  The movable plate 364 is a plate-like body provided at the tip of the lever 362 on the right side in FIG. 15, and the right edge in the drawing has an arc shape centered on the support portion 362a. The plurality of slits 364a are formed at substantially equal intervals along the arc-shaped edge on the right side of the movable plate 364 in the drawing. The slit detection sensor 366 is the same as the slit detection sensor 264 described above, and detects that each slit 364a has passed through the slit detection sensor 366 in the vertical direction.

  In this case, when the pressure in the charge chamber 284c is reduced and the ceiling wall 284b is lowered, the fixing base 363 is lowered together with the ceiling wall 284b. As a result, the lever 362 rotates around the support portion 362a, and the movable plate 364 located on the opposite side of the fixed base 363 with respect to the support portion 362a moves upward. Then, by detecting that each slit 364a has passed through the slit detection sensor 366 by the slit detection sensor 366, the volume in the charge chamber 284c can be detected by a plurality of values. Thus, the pressure in the charge chamber 284c can be detected with a plurality of values. Note that the movement direction of the slit 364a with respect to the volume change of the charge chamber 284c is opposite to the movement direction of the slit 262a described above.

  In the pressure detection unit 360, the ceiling wall 284b is changed by changing the ratio of the length between the support portion 362a and the support portion 362b in the lever 362 and the length between the support portion 362a and the movable plate 364. Since the amount of movement of the movable plate 364 (the plurality of slits 364a) with respect to the amount of movement can be changed, the degree of freedom in sensor design is improved.

  Hereinafter, an inkjet printer 401 according to an embodiment different from the inkjet printer 1 will be described with reference to FIGS. In FIG. 16, a part of the internal configuration of the carriage 9 is indicated by a dotted line. However, in order to make the drawing easier to see, the head main body 30 and the ink storage chambers 41 to 44 provided at the lower part in the carriage 9 are illustrated. The illustration is omitted. In the following, description of the same configuration as that of the inkjet printer 1 will be omitted as appropriate. Further, the same components as those of the ink jet printer 1 will be described with the same reference numerals.

  Unlike the inkjet printer 1, the inkjet printer 401 does not have the pressure limiter 69, but has a pressure control unit 90 instead. Also in the present embodiment, as in the above-described embodiment, when the pressure in the air chamber 51 becomes equal to or higher than the predetermined pressure, the suction pump 81 sucks the air chamber 51 so as to be less than the predetermined pressure. May fall below a predetermined pressure and the pressure may drop too much. The pressure control unit 90 prevents the pressure in the air chamber 51 from excessively decreasing, as will be described later. Further, a heat sink 471 and a mist repair unit 77 communicating with the pressure control unit 90 are provided. Hereinafter, these configurations will be described. FIG. 17 is a plan view of a state where the head cover is removed from the inkjet head 408 of the present embodiment. As shown in FIGS. 16 and 17, the pressure control unit 90 is installed in the middle of the air flow path 52 in the sub tank 431. The inside of the pressure control unit 90 communicates with the air flow path 52 and also communicates with the inside of the heat sink 471 through the air tube 75.

  FIG. 18 is a horizontal sectional view of the pressure control unit 90. A pressure control chamber 91 is formed in the pressure control unit 90, and the pressure control chamber 91 communicates with the three openings 91a, 91b, and 91c. The air flow path 52 on the air chamber 51 side communicates with the opening 91a, and the air flow path 52 on the suction pump 81 side communicates with the opening 91b. The opening 91 c communicates with the air tube 75 through the valve chamber 93. A biasing member 94 and a part of the valve body 92 are accommodated in the pressure control chamber 91. The valve body 92 is disposed so as to penetrate the communicating portion between the pressure control chamber 91 and the valve chamber 93, and has a sealing position (position shown in FIG. 18A) for sealing the opening 91c and the opening 91c. It is installed so as to be movable between an open position (a position shown in FIG. 18B) to be opened.

  The urging member 94 urges the valve body 92 toward the sealing position, and the urging force of the urging member 94 depends on the differential pressure between the pressure control chamber 91 and the valve chamber 93. And is adjusted to move between the sealing positions. More specifically, the urging force of the urging member 94 is such that the valve element 92 is held in the sealing position even when the pressure control chamber 91 is less than the predetermined pressure, but the pressure in the pressure control chamber 91 is predetermined. When the value is lower than a certain value lower than the pressure, the valve body 92 is adjusted to move to the open position as follows. That is, the inside of the valve chamber 93 is opened to the outside of the inkjet head 408 through the mist collecting unit 77 as described later, and is maintained at, for example, atmospheric pressure. On the other hand, when the inside of the pressure control chamber 91 is sucked and reaches a value lower than the predetermined pressure, the differential pressure between the valve chamber 93 and the pressure control chamber 91 increases. Then, the urging member 94 cannot maintain the valve body 92 in the sealed position against the differential pressure, and the valve body 92 moves from the sealed position to the open position. As a result, when the pressure in the pressure control chamber 91 falls below the certain value, air is taken into the pressure control chamber 91 from the outside of the inkjet head 408 through the valve chamber 93 and communicates with the pressure control chamber 91. The pressure in the air chamber 51 increases. When the pressure in the pressure control chamber 91 recovers until the pressure reaches a certain value or more, the biasing member 94 seals the valve element 92 against the differential pressure between the valve chamber 93 and the pressure control chamber 91. The position is moved to seal the opening 91c. Thus, the opening 91c takes an open state and a closed state according to the pressure in the pressure control chamber 91, but the openings 91a and 91b are always open. In other words, the air flow path 52 is always held in communication with the pressure control chamber 91.

  As shown in FIGS. 16 and 17, the ink-jet head 408 is provided with a heat sink 471 instead of the heat sink 71. The heat sink 471 is a member made of a metal material having a substantially rectangular parallelepiped shape that is long in the sub-scanning direction. A cavity 471 a is formed inside the heat sink 471. The cavity 471a extends along the sub-scanning direction, and opens at both ends of the heat sink 471 in the sub-scanning direction. One ends of air tubes 75 and 76 are connected to these two openings, respectively. The other end of the air tube 76 is connected to a mist collecting unit 77 fixed to the inner surface of the carriage 9. The mist repair unit 77 has an internal space 77b, and the internal space 77b communicates with the inside of the air tube 76 through an opening 77a that opens to the inside of the carriage 9. On the other hand, a communication hole 9 a that communicates with the internal space 77 b is formed in the side wall of the carriage 9, and the communication hole 9 a opens to the outside of the carriage 9, that is, to the outside of the inkjet head 408. A filter 78 made of a porous material or the like is attached to the communication hole 9a so as to cover the communication part between the carriage 9 and the internal space 77b.

  According to the above embodiment, the opening 91c is opened when the pressure in the pressure control chamber 91 of the pressure control unit 90 falls below the certain value lower than the predetermined pressure. On the other hand, the opening 91 c communicates with the outside of the inkjet head 408 via the air tube 75, the heat sink 471, the air tube 76, and the mist collecting unit 77. Therefore, external air is taken into the pressure control chamber 91 through the opening 91c, and the pressure in the air chamber 51 increases. And if the inside of the air chamber 51 becomes more than the above certain value, the opening 91c is sealed, and the pressure does not increase any more. As described above, for example, when the air chamber 51 is excessively sucked during the air chamber suction process and the pressure in the air chamber 51 becomes too lower than the predetermined pressure, the pressure control unit 90 causes the external air to be discharged. Is adopted. Therefore, it is possible to prevent the pressure in the air chamber 51 from excessively decreasing, and avoiding an excessive pressure being applied to the gas permeable film 53 installed at the communication portion between the air chamber 51 and the ink storage chambers 41 to 44. can do. This prevents the gas permeable membrane from being peeled off or damaged by excessive pressure.

  In addition, when the opening 91 c is opened in the pressure control unit 90, air outside the inkjet head 408 is taken in via the mist collecting unit 77. A filter 78 made of a porous material or the like is attached to the opening of the mist collecting unit 77. On the other hand, when ink is ejected from the nozzles 30a during the printing operation, so-called ink mist in which a large number of fine ink droplets float around the ink jet head 408 may occur. If such ink mist enters the ink jet head 408, there is a possibility that the electrical circuit or the like may be touched to cause a short circuit, or the ejection actuator 30b may malfunction. However, according to the above configuration, when air is taken from the mist collecting unit 77, the filter 78 attached to the opening of the mist collecting unit 77 collects the ink mist. Ink mist can be reduced. Further, the provision of the filter 78 prevents the ink from flowing into the air tube 75 and the heat sink 471 and clogging the flow path. Further, since the suction action of the suction pump 81 is utilized, a configuration for collecting ink mist without providing a suction pump for collecting mist is realized.

  Further, when the opening 91 c is opened, the air taken in from the mist collecting unit 77 passes through the cavity 471 a in the heat sink 471. Therefore, the heat transmitted from the driver circuit board 73 to the heat sink 471 is discharged from the heat sink 471 by the airflow passing through the cavity 471a. Further, since the cavity 471a is formed so as to extend along the extending direction (sub-scanning direction) of the driver circuit board 73, the heat generated from the driver circuit board 73 can be efficiently discharged. Further, since the suction action of the suction pump 81 is used, a configuration in which the heat of the heat sink 471 is discharged without providing a suction pump for cooling the heat sink 471 is realized.

  In addition, it is possible to always execute the cooling of the heat sink 471 and the collection of the ink mist by the mist collecting unit 77 by continuously operating the suction pump 81.

  In the present embodiment, the pressure control chamber 91 communicates with the inside of the heat sink 471 and the inside of the mist collecting unit 77 through the opening 90c. However, it may be communicated with only one of these, or may not be communicated with any of them and may be opened to the outside of the pressure control unit 90. Further, the air tube 75 may not communicate with the cavity 471 a inside the heat sink 471, and the opening of the air tube 75 may be disposed near the surface of the heat sink 471.

<Other variations>
The above is a description of a preferred embodiment of the present invention, but the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope described in the means for solving the problem. It is possible.

  For example, in the above-described embodiment, both the maintenance process of the nozzle 30a and the air chamber suction process can be executed by one suction pump 81, but a suction pump may be prepared for each.

  In the remaining amount determination process of the above-described embodiment, it may be determined only that at least one of the main tanks 5a to 5d is empty based only on the detection result of the pressure detection unit 60.

  In addition, when the flushing process is executed in the above-described embodiment, the flushing process may be started after the air chamber 51 is sufficiently sucked based on the detection result of the pressure detection unit 60.

  Moreover, in the above-mentioned embodiment, the one gas permeable film 53 is affixed so that all the communicating holes 41a-44a may be covered. However, two or more gas permeable membranes 53 may be attached. For example, a total of four gas permeable membranes 53 may be attached so as to cover each of the communication holes 41a to 44a.

  Moreover, in the above-mentioned embodiment, the sub tank 31 has the tank main body 31b and the cover member 31c. However, these may be integrally formed from the beginning.

  In the above-described embodiment, a method in which the head main body 30 and the sub tank 31 move together with the carriage 9 is employed. However, a fixed ink jet head may be employed. Further, unlike an ink jet printer, the present invention may be applied to an apparatus that ejects various liquids such as a liquid other than ink, for example, an apparatus that applies a colored liquid to produce a color filter of a liquid crystal display device. Further, a so-called thermal method may be employed as means for applying ejection energy to the ink in the head body 30.

  In the above-described embodiment, the one-way valve 83 and the one-way valve 183 are provided to keep the air chamber 51 in a state of less than a predetermined pressure. However, instead of such a one-way valve, communication between the suction pump 81 and the air chamber 51 can be interrupted or communicated in the middle of the suction flow path from the suction pump 81 to the air chamber 51. Opening / closing means may be provided. For example, such opening / closing means may be provided in a communication portion between the suction pump 81 and the air tube 16. When the suction pump 81 sucks the air chamber 51, the opening / closing means communicates the suction pump 81 and the air chamber 51. When the suction pump 81 stops sucking the air chamber 51, the opening / closing means causes the suction pump 81 and the air chamber 51 to communicate with each other. Block communication with 51. Thereby, even after the suction pump 81 stops the suction, a configuration that can hold the air chamber 51 in a state of less than a predetermined pressure is realized.

  In the above-described embodiment, the sub tank 31 is mounted on the carriage 9. However, the sub tank 31 may not be mounted on the carriage 9 and may be installed anywhere from the main tanks 5 a to 5 d to the carriage 9. In the above-described embodiment, the suction pump 81 is configured to suck the air chamber 51 formed in the sub tank 31. However, the suction flow path (first suction flow path) of the suction pump 81 is connected to any position of the ink supply flow path from the main tanks 5a to 5d to the head body 30, and air is sucked therefrom. As long as it is configured as such, it may be sucked from any position.

  For example, FIG.19 and FIG.20 has shown the Example by which the suction flow path of the suction pump 81 is connected to the location different from a sub tank. 20 is a cross-sectional view taken along the line α-α in FIG. 19 and includes a configuration around the vertical cross section of the ink chamber 141. The configuration around the vertical cross section of the ink chambers 142 to 144 is the same as that in FIG. In the inkjet printer 1000 of this modification, as shown in FIG. 19, an exhaust unit 190 is provided between the ink cartridges 5a to 5d and the tubes 14a to 14d. In the exhaust unit 190, ink chambers 141 to 144 and an air chamber 151 are formed. The tubes 14a to 14d communicate with the ink chambers 141 to 144 at the upper part of the exhaust unit 190 in FIG. Further, the ink cartridges 5a to 5d communicate with the ink chambers 141 to 144 via tubes 15a to 15d, respectively. The ink in the ink cartridges 5a to 5d is supplied to the sub tank 31 via the tubes 15a to 15d, the ink chambers 141 to 144, and the tubes 14a to 14d, respectively.

  As shown in FIG. 20, a tube 14a is connected to the left end of the ink chamber 141 via a communication port 141a, and a tube 15a is connected to the right end of the ink chamber 141 via a communication port 141b. The ink chambers 142 to 144 and the tubes 14b to 14d and 15b to 15d are similarly connected. The air chamber 151 extends over the ink chambers 141 to 144 above the ink chambers 141 to 144 (see FIG. 19). The air chamber 151 is connected to the tube 19 via the communication port 152, and the air chamber 151 and the charge tank 84 are connected via the tube 19. The communication port 152 is provided at the right end of the exhaust unit 190 in FIG.

  As shown in FIGS. 19 and 20, gas permeable films 153 a to 153 d are provided at the communication portions between the ink chambers 141 to 144 and the air chamber 151, respectively. The gas permeable films 153a to 153d are provided at positions overlapping the ink chambers 141 to 144 in plan view (see FIG. 19), and constitute walls that partition the ink chambers 141 to 144 and the air chamber 151. . In this modification, gas permeable films 153a to 153d are provided corresponding to the ink chambers 141 to 144, respectively, but one gas permeable film is located above the ink chambers 141 to 144, and the ink chambers 141 to 144 are provided. 144 may be provided over 144.

  According to this modification, in the exhaust unit 190, the gas in the ink chambers 141 to 144 passes through the gas permeable films 153 a to 153 d and is discharged to the air chamber 151 and is discharged from the air chamber 151 to the tube 19. In this modification, the gas flow path from the gas chamber 152 to the suction pump 81 via the tube 19, the charge tank 84, the tubes 18 and 16, corresponds to the first suction flow path according to the present invention.

1 is a plan view of an ink jet printer according to an embodiment of the present invention. It is sectional drawing of the one-way valve of FIG. FIG. 2 is a block diagram showing an electrical configuration of the ink jet printer of FIG. 1. FIG. 2 is a perspective view of a state where a sub tank or the like is removed from a carriage in the ink jet head of FIG. 1. FIG. 2 is a plan view of the ink jet head of FIG. 1 with a head cover removed. It is a longitudinal cross-sectional view of the sub tank along the VI-VI line of FIG. FIG. 2 is a peripheral view of the pressure detection unit of FIG. 1. It is a horizontal sectional view of the pressure limiter of FIG. It is a flowchart of the nozzle maintenance process which a control part performs. It is a flowchart of the printing process which a control part performs. It is a flowchart of the remaining amount determination process of the main tank which a control part performs. It is another embodiment different from FIG. 2 concerning a one-way valve. This is an embodiment different from FIG. 7 related to the pressure detection unit. This is an embodiment different from FIGS. 7 and 13 related to the pressure detection unit. It is another embodiment which concerns on a pressure detection unit. FIG. 2 is a plan view of an inkjet printer according to another embodiment different from FIG. 1. FIG. 17 is a plan view of the ink jet head of FIG. 16 with a head cover removed. It is a horizontal sectional view of the pressure control unit of FIG. It is a top view which shows the modification from which the suction flow path from a suction pump differs. FIG. 20 is a cross-sectional view taken along the line α-α in FIG.

DESCRIPTION OF SYMBOLS 1 Inkjet printer 8 Inkjet head 19a Pressure detection area 20 Capping unit 21 Suction cap 30 Head body 30a Nozzle 30b Injection actuator 31 Sub tank 51 Air chamber 53 Gas permeation film 69 Pressure limiter 71 Heat sink 71a Cavity 73 Driver circuit board 77 Mist collecting unit 78 Filter 81 Suction pump 82 Channel switching unit 84 Charge tank 90 Pressure control unit 100 Control unit 184 Bellows tanks 5a to 5d Main tanks 6a to 6d Remaining amount detection units 16 to 19 Air tubes 41 to 44 Ink storage chambers 41a to 44a Communication hole 60, 160, 260, 360 Pressure detection unit 83, 183 One-way valve

Claims (9)

A liquid jet head having a jet port for jetting droplets;
A liquid supply channel for supplying a liquid to the liquid ejecting head;
A first suction channel that is always in communication with the liquid supply channel;
A suction means for sucking the gas in the liquid supply flow path through the first suction flow path;
A gas permeable membrane installed in a communication portion between the liquid supply channel and the first suction channel;
Opening / closing means for taking either one of a blocking state for blocking communication between the first suction channel and the suction unit and an open state for connecting the first suction channel and the suction unit;
Pressure detecting means for detecting the pressure in the first suction flow path;
A suction control means for controlling the suction means,
The opening / closing means is in the open state when the suction means sucks the gas in the first suction flow path, and is in the shut-off state after the suction means sucks the gas in the first suction flow path. And
The suction control means causes the suction means to suck the inside of the liquid supply flow path when the pressure detection means detects that the inside of the first suction flow path becomes equal to or higher than a predetermined pressure ,
As the opening / closing means, it has a one-way valve that restricts the flow direction of the gas in the first suction flow path so as to flow only in the direction toward the suction means,
A charge tank is provided between the one-way valve and the liquid supply flow path in the first suction flow path, and the charge tank extends along a direction orthogonal to the extending direction of the first suction flow path. A liquid droplet ejecting apparatus having a cross-sectional area larger than a cross-sectional area . The one-way valve has a valve body movable between an open position for opening the first suction flow path and a closed position for closing the first suction flow path, and the valve body includes the suction means. Moves to the open position by the suction force acting from the suction means side when sucking the first suction flow path, and when the suction means stops the suction of the first suction flow path, The liquid droplet ejecting apparatus according to claim 1 , wherein the liquid droplet ejecting apparatus moves to the closed position when the suction force acting from the lowering is reduced. A part of the wall surface defining the first suction flow path has flexibility;
The pressure detection means includes a detected member that is displaced according to a deformation of a part of the wall surface, and a sensor that detects whether or not the detected member is located at a predetermined detection position.
Some of the walls, the internal pressure of the first suction passage becomes high, wherein the detection member to claim 1 or 2, characterized in that deforms to displace toward the predetermined detection position Droplet ejector. And further comprising a variable volume chamber that communicates with the first suction flow path and whose volume changes in accordance with the pressure in the first suction flow path.
The pressure detection means has volume detection means capable of detecting the volume of the volume variable chamber with a plurality of values, and based on the volume detected by the volume detection means, the liquid-droplet jetting apparatus according to claim 1 or 2, characterized in that for detecting pressure at a plurality of values. A liquid jet head having a jet port for jetting droplets;
A liquid supply channel for supplying a liquid to the liquid ejecting head;
A first suction channel that is always in communication with the liquid supply channel;
A suction means for sucking the gas in the liquid supply flow path through the first suction flow path;
A gas permeable membrane installed in a communication portion between the liquid supply channel and the first suction channel;
Opening / closing means for taking either one of a blocking state for blocking communication between the first suction channel and the suction unit and an open state for connecting the first suction channel and the suction unit;
Pressure detecting means for detecting the pressure in the first suction flow path;
Suction control means for causing the suction means to suck the inside of the liquid supply flow path when the pressure detection means detects that the inside of the first suction flow path has become a predetermined pressure or higher;
An ejection port capping unit including a cap movable relative to the liquid ejection head between a sealing position that is in close contact with the liquid ejection head and covers the ejection port and an open position that opens the ejection port;
A second suction flow path communicating with the internal space of the cap;
The suction means communicates with the first suction channel and is not communicated with the second suction channel, or communicates with the second suction channel and is not communicated with the first suction channel. and a switching means for switching whether the to,
The opening / closing means is in the open state when the suction means sucks the gas in the first suction flow path, and is in the shut-off state after the suction means sucks the gas in the first suction flow path. And
The suction control means controls the switching means to cause the suction means to communicate with the second suction flow path when the pressure detection means detects that the inside of the first suction flow path falls below the predetermined pressure. In addition, the droplet ejection device is characterized in that the suction port capping unit is controlled to move the cap to the sealing position, and then the suction unit is controlled to suck the internal space of the cap . When the pressure detecting means detects that the inside of the first suction flow path is equal to or higher than the predetermined pressure, the suction control means causes the suction means to suck the gas in the liquid supply flow path and then The droplet ejecting apparatus according to claim 5 , wherein suction of the ejection port is performed by a suction unit. A printing control means for performing a printing process by ejecting droplets from the ejection port;
The printing control means, when the first suction passage is detected by the pressure detecting means and below said predetermined pressure, claim 1-6, characterized in that to start the print process 1 Item 2. A droplet ejecting apparatus according to Item. When the pressure detection means detects that the inside of the first suction flow path is equal to or higher than the predetermined pressure, the suction control means causes the suction means to start before the print control means starts the printing process. The liquid droplet ejecting apparatus according to claim 7 , wherein the gas in the liquid supply channel is sucked. A liquid jet head having a jet port for jetting droplets;
A liquid supply channel for supplying a liquid to the liquid ejecting head;
A first suction channel that is always in communication with the liquid supply channel;
A suction means for sucking the gas in the liquid supply flow path through the first suction flow path;
A gas permeable membrane installed in a communication portion between the liquid supply channel and the first suction channel;
Opening / closing means for taking either one of a blocking state for blocking communication between the first suction channel and the suction unit and an open state for connecting the first suction channel and the suction unit;
Pressure detecting means for detecting the pressure in the first suction flow path;
A suction control means for controlling the suction means,
The opening / closing means is in the open state when the suction means sucks the gas in the first suction flow path, and is in the shut-off state after the suction means sucks the gas in the first suction flow path. And
The suction control means causes the suction means to suck the inside of the liquid supply flow path when the pressure detection means detects that the inside of the first suction flow path becomes equal to or higher than a predetermined pressure,
The first suction passage, the internal pressure is crushed by the pressure difference between the external becomes lower, characterized by having a pressure limiter which closes the flow path when the pressure is lower there than the predetermined pressure Droplet ejector.

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