JP2012171342A - Inkjet printer and image recording method of the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform high-quality image recording even when ink reciprocating motion is switched.SOLUTION: An inkjet printer includes: a transportation section which transports a recording medium; an ink head which discharges ink onto the transported recording medium for recording an image; a first ink reservoir section connected to the ink head through a first ink path; a second ink reservoir section connected to the ink head through a second ink path; a pressurizing/depressurizing means which pressurizes or depressurizes the insides of the first and second ink reservoir sections for switching the direction of ink flow between the first and second ink reservoir sections via the ink head; and a control section which controls the transportation section, the ink head, and the pressurizing/depressurizing means. The direction of ink flow to the ink head is switched at gaps between pages of the recording medium.

Description

  The present invention relates to an ink jet printer having an ink reciprocating path and an image recording method thereof.

In general, an ink jet printer that mounts an ink head having a plurality of nozzles and performs image recording (printing) by discharging ink from these nozzles onto a recording medium is known.
For example, Patent Document 1 discloses an ink jet printer having an ink head, a supply path for supplying ink to the ink head, and a discharge path for discharging ink from the ink head. In this ink jet printer, an ink cartridge is connected to one end of the supply path, and an ink tank is connected to one end of the discharge path, and the image is moved back and forth between the ink cartridge and the ink tank via the ink head. Make a record.

Japanese Patent No. 3419220

  In the ink jet printer described in Patent Document 1, when the ink reciprocating movement is switched, the ink head nozzle is affected by the influence of the inertial force due to the ink flow or the pressure fluctuation generated due to the instability at the start of pump driving. Pressure is not stable. For this reason, non-ejection of ink and variations in ejection amount occur, leading to degradation of image recording quality.

  SUMMARY An advantage of some aspects of the invention is that it provides an ink jet printer capable of performing high-quality image recording even when there is a switching operation of reciprocation of ink, and an image recording method thereof.

  One embodiment of the present invention includes a transport unit that transports a recording medium, an ink head that records an image by ejecting ink onto the recording medium transported by the transport unit, and a first ink path to the ink head. By pressurizing and depressurizing the connected first ink reservoir, the second ink reservoir connected to the ink head by the second ink path, and the first and second ink reservoirs. A pressure-increasing / decreasing unit that switches an ink flow direction between the first and second ink storage units via the ink head, and a control unit that controls the transport unit, the ink head, and the pressure-increasing / decreasing unit. The timing at which the direction of the ink flowing to the ink head is switched by the pressurizing and depressurizing means and the timing at which the recording medium is conveyed by the conveying unit are different. Parts is an inkjet printer for controlling.

  In one embodiment of the present invention, an ink head that records an image by ejecting ink onto a recording medium, a first ink reservoir connected to the ink head by a first ink path, and a second A second ink reservoir connected to the ink head by an ink path, and switching a direction of ink flow between the first and second ink reservoirs via the ink head In the image recording method of an ink jet printer that records images on a plurality of recording media conveyed at time intervals, the direction of ink flowing through the ink head is switched during the predetermined time interval.

  According to the present invention, it is possible to provide an ink jet printer that can perform high-quality image recording even when there is a switching operation of reciprocation of ink, and an image recording method thereof.

FIG. 1 is a schematic diagram illustrating the configuration of an inkjet printer. FIG. 2 is a schematic diagram showing an ink path of the ink jet printer. FIG. 3 is a cross-sectional view of the ink head. FIG. 4 is a perspective view of the ink head. FIG. 5 is a diagram showing temporal changes in pressure and flow rate during ink reciprocation. FIG. 6 is a flowchart showing the operation of the ink jet printer during image recording in the first embodiment. FIG. 7 is a time chart showing the pressure, medium supply, and image recording operations in the first embodiment. FIG. 8 is a time chart showing pressure, medium supply, and image recording operations in the first embodiment. FIG. 9 is a flowchart illustrating switching of ink reciprocation, medium supply, and image recording operations according to the second embodiment. FIG. 10 is a time chart showing the pressure, medium supply, and image recording operations in the second embodiment. FIG. 11 is a time chart showing pressure, medium supply, and image recording operations in the second embodiment. FIG. 12 is a flowchart illustrating switching of ink reciprocation, medium supply, and image recording operations according to a modification of the second embodiment. FIG. 13 is a time chart showing pressure, medium supply, and image recording operations in a modification of the second embodiment. FIG. 14 is a time chart showing pressure, medium supply, and image recording operations in the third embodiment. FIG. 15 is a schematic diagram illustrating a configuration of an ink jet printer according to the fourth embodiment. FIG. 16 is a schematic diagram illustrating an ink path of the ink jet printer according to the fifth embodiment. FIGS. 17A to 17C are schematic views showing the configuration of the ink path in the sixth embodiment. FIGS. 18A to 18C are schematic views showing the configuration of the ink path in the seventh embodiment. FIG. 19 is a schematic diagram showing the configuration of the ink path in the eighth embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a schematic diagram showing the configuration of the ink jet printer 1.
The ink jet printer 1 roughly includes a supply unit 3 that accommodates and supplies the recording medium 2, a conveyance unit 4 that conveys the supplied recording medium 2, and an ink head 100 that ejects ink onto the recording medium 2. An image recording unit 5, a cleaning unit 6 for cleaning the ink head 100, a discharge unit 7 for discharging and storing the image-recorded recording medium 2, an ink path 20 (FIG. 2) including the ink head 100, and And a control unit 8 that controls each component of the ink jet printer 1. Each of these components is housed in a housing (not shown).

  In the following description, the conveyance direction of the recording medium 2 is the X direction, the direction orthogonal to the X direction is the Y direction or the width direction (main scanning direction), and the direction orthogonal to the X direction and the Y direction is the Z direction or the vertical direction (vertical). Direction).

  The supply unit 3 includes a supply tray 9 and a pickup roller 10. The supply tray 9 accommodates, for example, a sheet cut into a predetermined size as the recording medium 2. The pickup roller 10 comes into contact with the recording medium 2 accommodated in the supply tray 9, takes out the recording medium 2 in contact one by one, and feeds it to the transport unit 4.

  The conveyance unit 4 includes a registration roller pair 11, a driven roller 12, tension rollers 13 and 14, a driving roller 15, a conveyance belt 16, a platen 17, and a suction fan 18. Each of these components is held by a carrier frame (not shown).

  The registration roller pair 11 is located on the most upstream side in the medium conveyance direction of the conveyance unit 4, and the recording medium 2 fed by the pickup roller 10 is conveyed thereby. The registration roller pair 11 temporarily stops the conveyance of the recording medium 2, corrects the conveyance posture, adjusts the timing of the conveyance start, and conveys the recording medium 2 to the conveyance belt 16.

  The conveyor belt 16 is a belt-like endless belt, and a large number of holes (not shown) are provided on the surface thereof. The conveyor belt 16 is held in a tensioned state by four rollers, for example, a driven roller 12, two tension rollers 13 and 14, and a driving roller 15. A motor (not shown) is connected to the driving roller 15, and the conveyance belt 16 rotates (moves) clockwise in FIG. 1 by driving this motor.

  A platen 17 and a suction fan 18 are provided below the conveyor belt 16. The platen 17 is processed so that a region facing the image recording unit 5 is at least a flat surface, and a large number of holes (not shown) are formed on the surface thereof. The suction fan 18 sucks air from a large number of holes in the conveyor belt 16 and the platen 17. As a result, the recording medium 2 is adsorbed onto the conveyance belt 16 and conveyed downstream at a predetermined conveyance speed.

The image recording unit 5 is provided above the conveying unit 4 (platen 17) so as to be opposed thereto. The image recording unit 5 is an ink head 100 (100a, 100b, 100c, 100c, 100c, 100c, 100c) that discharges cyan (C), black (K), magenta (M), and yellow (Y) ink in order from the upstream side in the medium conveyance direction. 100d) and a head holding member 19 that holds the ink head 100. In the present embodiment, a plurality of ink heads 100 that are less than the width of the recording medium 2 are fixed to the head holding member 19 in the width direction of the recording medium 2 so as to be equal to or larger than the recording area width in the recording medium 2. A line head 21 is configured. Specifically, the line head 21 is configured by fixing six ink heads 100 to the head holding member 19 in a staggered manner. The configuration of the image recording unit 5 is a single pass method in the present embodiment, but may be a serial method.
The ink head 100 (line head 21) is one of the components of the ink path 20. Details of the ink path 20 will be described later.

  The cleaning unit 6 has a cleaning unit 22 (22a, 22b, 22c, 22d) corresponding to each line head 21. The cleaning unit 22 is provided for cleaning the ink head 100, and has a blade member for wiping the nozzle surface of the ink head 100, a cap member for capping the nozzle surface, and the like, although not particularly illustrated. As shown in FIG. 1, each cleaning unit 22 is moved to a position downstream of the corresponding ink head 100 in the medium conveyance direction (retracted position) by a moving mechanism (not shown), and at the time of cleaning. It is disposed at a position facing the corresponding ink head 100 (cleaning position).

  The discharge unit 7 includes a discharge roller pair 23 and a discharge tray 24. The discharge roller pair 23 sandwiches the recording medium 2 on which the image has been recorded by the image recording unit 5 and discharges the recording medium 2 to the discharge tray 24. The discharge tray 24 accommodates the discharged recording medium 2.

  In the ink jet printer 1 configured as described above, at the time of image recording, the recording medium 2 taken out one by one from the supply unit 3 is transported to the transport unit 4, and an image is recorded by the image recording unit 5. The recorded recording medium 2 is discharged to the discharge unit 7. A series of these operations is controlled by the control unit 8.

Next, the ink path 20 will be described with reference to FIG.
In the following, only the ink path 20 related to a representative one color ink will be described, but a similar ink path is provided for each ink color.

  The ink path 20 includes an ink head 100 (line head 21) that discharges ink to the recording medium 2, an ink cartridge 60 that serves as a first ink storage unit that stores ink to be supplied to the ink head 100, and the ink head 100. And an ink tank 50 as a second ink storage part for storing the discharged ink. The ink cartridge 60 and the ink head 100 are connected by a first ink path (first tube) 31 with the heating unit 30 interposed therebetween. The ink head 100 and the ink tank 50 are connected by a second ink path (second tube) 32 with the cooling unit 40 interposed therebetween. That is, the ink path 20 is an ink reciprocating path that allows ink to flow from the ink cartridge 60 to the ink tank 50 via the ink head 100 and further allows ink to flow from the ink tank 50 to the ink cartridge 60 via the ink head 100. is there.

First, the configuration of the ink cartridge 60 will be described.
The ink cartridge 60 includes an exterior 61 and a flexible spout pack (bag body) 62. The spout pack 62 filled with ink is inserted into the sealed exterior 61. Yes. The ink cartridge 60 is detachable with respect to the first ink path 31. When the ink cartridge 60 is mounted, a hollow needle (not shown) provided at one end of the first ink path 31 is passed through the spout pack 62, and the spout is removed. The ink in the pack 62 is connected to flow to the first ink path 31.

  The ink cartridge 60 is provided with a passage communicating between the exterior 61 and the spout pack 62, and one end of the air passage 33 is connected to the passage. On the other end side of the air path 33, a pump 34 is provided as pressure increasing / decreasing means. The air path 33 further communicates with one end of the air path 35, and a pressure sensor 72 that detects the pressure in the air path 33 is provided in the air path 35. The pump 34 is configured by, for example, a tube pump, and is controlled by the control unit 8 so as to exhaust air inside the exterior 61 by forward rotation and to reversely suck air into the exterior 61. That is, the spout pack environment is depressurized during normal rotation and pressurized during reverse rotation. The pressure at this time is detected by the pressure sensor 72.

Next, the configuration of the ink tank 50 will be described.
The ink tank 50 has a hermetically sealed configuration, and a float 70 that detects the ink level is swingably provided therein. This float 70 holds a magnet (not shown). Outside the ink tank 50, a liquid level sensor 71 having a Hall element is attached at a position facing the magnet of the float 70. One end of the second ink path 32 is connected to a pipe (not shown) extending to the vicinity of the bottom surface of the ink tank 50.

  An opening communicating with the air in the ink tank 50 is provided on the upper surface of the ink tank 50, and one end side of the air path 36 is connected to the opening. In addition, a pump 37 serving as a pressure increasing / decreasing means is provided on the other end side of the air path 36. The air path 36 further communicates with one end side of the air path 38, and the air path 38 is provided with a pressure sensor 73 that detects the pressure in the air path 36. The pump 37 is configured by, for example, a tube pump, and is controlled by the control unit 8 so that the air inside the ink tank 50 is exhausted by normal rotation and the air is reversed and sucked into the ink tank 50. That is, the air inside the ink tank 50 is depressurized during forward rotation and pressurized during reverse rotation. The pressure at this time is detected by the pressure sensor 73.

Next, the heating unit 30 and the cooling unit 40 will be described.
The heating unit 30 is disposed in the vicinity of the ink head 100 in the first ink path 31. The heating unit 30 has an ink path made of a metal having high thermal conductivity such as copper or aluminum, and a heating element is wound around the ink path. The outside of the heating element is covered with a cover made of a resin having low thermal conductivity, etc., and is insulated from the outside air to increase heat exchange efficiency (heating efficiency). The cooling unit 40 is disposed in the vicinity of the ink tank 50 in the second ink path 32. The cooling unit 40 also has an ink path made of a metal having high thermal conductivity such as copper or aluminum, and in order to increase the contact area with the outside air, a fin-shaped part is formed on a part of the metal part. have. Further, a fan is provided opposite to the fin-shaped portion, and air is wiped on the fin-shaped portion to enhance heat exchange efficiency (cooling efficiency).

Next, the internal structure of the ink head 100 will be described with reference to FIGS.
A frame 102 that surrounds the periphery of the ink head 100 and surrounds the center is a cavity, and a piezoelectric element 104 is bonded to the one surface of the base 103 in a pair. Has been. The frame 102 and the piezoelectric element 104 are provided at the same height in the Z direction so as to close the cavity. Further, the nozzle plate 101 is laminated in the Z direction and bonded to the frame 102 and the piezoelectric element 104.

  In the piezoelectric element 104, a plurality of grooves are formed in the X direction, and these grooves form a channel 104a. These channels 104a are dug parallel to the Y direction. The channel 104a has, for example, a pitch of about 170 μm, a width of 85 μm, and a depth of about 300 μm. The two piezoelectric elements 104 forming a pair are arranged with a half pitch shift in the Y direction. In addition, a plurality of nozzles (nozzle holes) 101b that eject ink are formed on the nozzle surface 101a of the nozzle plate 101 in the Z direction at the center of each channel 104a. These nozzles 101b are arranged in the Y direction corresponding to the channel 104a.

  As shown in FIG. 4, the base 103 has a plurality of holes 103 a arranged in the Y direction at the center of the pair of piezoelectric elements 104. These holes 103a are, for example, through holes having a diameter of about 1 mm and arranged at intervals of 3 mm. Similarly, a plurality of holes 103 b are arranged at the position of the gap in the X direction between the frame 102 and the piezoelectric element 104.

  On the other surface side of the base 103, flow path members 105 and 106 are laminated in the Z direction and bonded. The flow path member 105 includes, in the Y direction, one flow path 105a facing the plurality of holes 103a of the base 103, and two flow paths 105b facing the plurality of holes 103b of the base 103. These three parallel flow paths (grooves) are formed. The flow path member 106 is bonded onto the flow path member 105 so as to cover the flow paths 105a and 105b.

  The flow path member 106 is provided with two pipe-shaped ink ports 107 and 108 as an ink introduction part communicating with the nozzle 101b. The hole of the ink port 107 is connected to the flow path 105 a, and the hole of the ink port 108 is connected to the connection flow path 106 b that connects the two flow paths 105 b inside the convex portion 106 a of the flow path member 106. Furthermore, the other end side of the first ink path 31 whose one end side is connected to the ink cartridge 60 is connected to the ink port 107. The ink port 108 is connected to the other end of the second ink path 32 having one end connected to the ink tank 50.

  Briefly describing the flow of ink inside the ink head 100, the ink flowing from the ink port 107 passes through the flow path 105a to the entire width of the ink head 100, and the piezoelectric elements 104 paired with the plurality of holes 103a. Is fed over the entire width at the center of the. The supplied ink is divided in the direction of each piezoelectric element 104 here, passes through each channel 104a, and reaches the gap between the frame 102 and the piezoelectric element. The reached ink passes through the two flow paths 105b from the plurality of holes 103b, merges in the connection flow path 106b, and flows out from the ink port 108. In addition, it is possible to flow ink from the ink port 108 to the ink port 107 in the opposite direction to the above flow.

  The electrode wiring of the channel 104a is connected to the FPC 109 on which the drive IC 110 is mounted at the electrode connection surface 103c of the base 103, and is driven by applying a voltage waveform to each channel 104a. The base 103 is preferably made of a metal having a sufficiently high thermal conductivity as compared with the piezoelectric element 104.

  The ink ports 107 and 108 pass through holes 111 c and 111 d provided in the fixing member 111, and are bonded to and integrated with the fixing member 111 at the through portions. The fixing member 111 is integrated with the cover 113 by screws. The drive IC 110 is pressed and adhered to the inner surfaces of the covers 112 and 113 by an elastic member such as a spring (not shown).

  A temperature sensor (thermistor) 114 for detecting the temperature of the ink is provided at the center of the base 103. The output of the temperature sensor 114 shows substantially the same value as the temperature of the ink flowing through the channel 104a on the back side because the base 103 is made of a material having high thermal conductivity. Since the viscosity of the ink changes depending on the ink temperature, it is necessary to appropriately control the voltage applied to the piezoelectric element in order to maintain an appropriate ink discharge amount. Therefore, the voltage of the piezoelectric element is controlled by the control unit according to the temperature detected by the temperature sensor 114.

  The piezoelectric element 104 generates heat when driven. Part of this heat generation is radiated to the outside together with the ejected ink. A part of the heat is transferred to the base 103 and radiated to the outside air of the ink head 100. Most of the remaining heat is stored in the base 103 and the flow path members 105 and 106. In order to prevent the temperature increase of the ink head 100 due to such heat accumulation, the ink head 100 causes ink other than the ejected ink to flow by flowing ink from the ink ports 107 to 108 or from the ink ports 108 to 107. Designed to take away excess heat and flow.

  Further, when the piezoelectric element 104 is driven, the drive IC 110 generates heat. The generated heat is transferred to the covers 112 and 113. Since these covers 112 and 113 are provided with a large number of heat radiation projections 112a and 113a on the outer surface, the surface area of the air around the ink head 100 increases. The heat dissipation effect is enhanced.

Next, ink reciprocation in the ink path 20 will be described.
In the present embodiment, the first ink path 31 has an inner diameter of 4 mm and a length of 400 mm, for example, and the second ink path 32 has an inner diameter of 5 mm and a length of 300 mm, for example. The water head difference of the ink cartridge 60 with respect to the nozzle surface 101a of the ink head 100 is H1, the water head difference of the ink tank 50 is H2, and for example, H1 is set to 100 mm in the −Z direction and H2 is set to 250 mm in the −Z direction. In the standby state, ink is filled from the ink cartridge 60 to the ink tank 50 via the first ink path 31, the ink head 100, and the second ink path 32, and the amount of ink in the ink tank 50 is The ink level is the liquid level height at which the liquid level sensor 71 is turned on. At this time, the pumps 34 and 37 are stopped, and the air paths 33 and 36 are in a sealed state.

  In the standby state, immediately after the liquid level sensor 71 is turned on, a pressure is generated in the air passages 33 and 36 to cancel the water head difference between the ink cartridge 60 and the ink tank 50, so that the inside of the nozzle 101 b is depressed. A meniscus is formed to create a state where the ink flow is stopped. The generation of this pressure is effected by rotating the pumps 34, 37 forward or backward while monitoring the pressure in the air passages 33, 36 with the pressure sensors 72, 73. After the desired pressure is generated, the pumps 34, 37 are stopped.

In the present embodiment, the pressure generated in the air paths 33 and 36 is calculated by the product of the water head differences H1 and H2, the ink density ρ, and the gravitational acceleration g. For example, in the above-described case, when ρ = 900 kg / m ³ and g = 9.8 m / s ² , the pressure generated from the difference between the head differences H1 and H2 (−150 mm) is ρ × g × (H2−H1). ) = − 1323 Pa. In order to generate a pressure that cancels this in the air paths 33 and 36 to create a negative pressure at which a meniscus is formed in the nozzle 101b, for example, the air chamber pressure P1 in the ink cartridge 60 is set to −100 Pa (air path 33). The air chamber pressure P2 inside the ink tank 50 is set to 1223 Pa (the same applies to the air path 36). That is, the pressure difference between the air path 33 and the air path 36 is set to be −1323 Pa. When this value is set, the pressure in the nozzle 101b is calculated to be −982 Pa.

  Next, a case where the ink in the ink tank 50 is caused to flow from the standby state to the ink cartridge 60 via the second ink path 32, the ink head 100, and the first ink path 31 will be described.

  First, the pump 34 is rotated forward to reduce the air chamber pressure P <b> 1 inside the ink cartridge 60. At the same time, the pump 37 is reversed to increase the air chamber pressure P <b> 2 inside the ink tank 50. When the surface tension of the ink is 28 dyn / cm and the diameter of the nozzle 101b is about 25 μm, the meniscus is not broken up to about −4500 Pa and does not suck air from the nozzle 101b. In general, there is an optimum nozzle pressure for ejecting ink. By maintaining this nozzle pressure, the amount of ejected ink becomes constant, and the probability of occurrence of ejection failure is minimized. Here, −1000 Pa ± 200 Pa is set as the optimum discharge nozzle pressure.

Here, it is necessary for the pressures P1 and P2 to satisfy both the nozzle pressure suitable for image recording and the flow rate for preventing temperature rise of the ink head 100. This point will be described in detail.
The channel resistance is calculated from the diameter and length of the tube and the viscosity of the ink. In the case of the radius r, the length L, and the ink viscosity η, the flow path resistance R of the ink flowing in the tube is calculated by R = 8Lη / πr ⁴ . Further, the relationship between the flow rate Q of ink flowing in the tube and the pressure difference ΔP is ΔP = RQ.

  The flow resistance of the first tube 31 is R1, the flow resistance of the second tube 32 is R2, the flow resistance of the line head 21 including the six ink heads 100 arranged in parallel is Rh, and the pressure due to the water head difference H1. Is the pressure difference ΔP from the ink tank 50 to the ink cartridge 60, and ΔP = (P1 + h1) − (P2 + h2). The flow path resistance R from the ink tank 50 to the ink cartridge 60 is calculated by R = R1 + R2 + Rh. The ink flow rate Q flowing through the line head 21 is calculated by Q = ΔP / R from the above relational expression. The pressure (nozzle pressure) Ph of the nozzle 101b at this time is calculated from the pressure from the ink cartridge 60 side when the flow path resistance value forming the line head 21 is symmetrical with respect to the nozzle 101b. Ph = P1 + h1− (R1 + Rh / 2) × Q (Ph = P2 + h2 + (R2 + Rh / 2) may be used).

  In addition, as described above, one of the purposes of flowing ink into the ink head 100 is to take away the amount of heat generated in the piezoelectric element 104 and prevent the ink head 100 from rising in temperature. For example, when it is necessary to flow approximately 0.53 ml / s of ink per head from the heat generation amount of the ink head 100 at 25 ° C., in order to prevent the temperature rise of the line head 21 including the six ink heads 100. The required ink flow rate is approximately 3.21 m 2 / s or more. Since h1, h2, R1, R2, and Rh are constants, the flow rate Q can be determined only by the combination of pressures P1 and P2. For example, if P1 = −3780 Pa and P2 = 2560 Pa, the line head 21 is The ink flow rate of the flowing ink is approximately 3.21 m 2 / s, and the nozzle pressure Ph is −1002 Pa, which is close to the optimum nozzle pressure range for image recording. As described above, the pressures P1 and P2 are set so as to satisfy both the nozzle pressure suitable for image recording and the flow rate for preventing the temperature rise of the ink head 100.

Next, a case where the ink in the ink cartridge 60 is caused to flow to the ink tank 50 via the first ink path 31, the ink head 100, and the second ink path 32 will be described.
In this case, the pump 34 is reversed to increase the air chamber pressure P <b> 1 inside the ink cartridge 60. At the same time, the pump 37 is rotated forward to reduce the air chamber pressure P <b> 2 inside the ink tank 50. Here, even when ink is flowed from the ink cartridge 60 to the ink tank 50, the pressures P1 and P2 are the nozzle pressure and ink suitable for image recording, as in the case of flowing ink from the ink tank 50 to the ink cartridge 60 described above. It is necessary to satisfy both the flow rate for preventing the temperature rise of the head 100. However, even when ink is allowed to flow from the ink cartridge 60 to the ink tank 50, as described above, h1, h2, R1, R2, and Rh are constants, so that the flow rate Q can be determined only by the combination of the pressures P1 and P2. . For example, if P1 = 3540 Pa and P2 = −1910 Pa are set, the ink flow rate Q at 25 ° C. can be set to 3.21 ml / s, the nozzle pressure Ph can be set to −997 Pa, and a desired flow rate and nozzle pressure can be obtained. be able to.

  The ink viscosity η varies with temperature. That is, the ink has a large viscosity η when the temperature is low, and the viscosity η becomes small when the temperature is low. However, based on the temperature detected by the temperature sensor 114 in the ink head 100, the control unit 8 detects the pressure with the pressure sensors 72 and 73 so that the pressures P1 and P2 are calculated in advance corresponding to the ink temperature. By controlling the pumps 34 and 37, it is possible to set a desired constant flow rate Q and an optimum discharge nozzle pressure Ph.

  As described above, by periodically changing the settings of the pressures P <b> 1 and P <b> 2, the ink flow in the ink path 20 is periodically switched, and the ink is reciprocated while passing through the line head 21. Note that the pressures P1 and P2 are the flow rate in the desired range and the flow rate in the desired range regardless of whether the ink is supplied from the ink tank 50 to the ink cartridge 60 or the ink is supplied from the ink cartridge 60 to the ink tank 50. The nozzle pressure is set to be applied.

Next, changes with time in pressure and flow rate during ink reciprocation will be described with reference to FIG.
FIG. 5 shows transitions of the pressures P1 and P2, the nozzle pressure Ph, and the ink flow rate Q during the ink reciprocation.
In a state where the power of the inkjet printer 1 is OFF or in a standby state where image recording is not performed, the pumps 34 and 37 are stopped, and the nozzle pressure Ph is approximately −982 Pa as shown by the waveform portion 80. In this state, the flow rate Q is zero.

  When an image recording instruction is given to the inkjet printer 1, the pump 34 starts normal rotation and the pump 37 starts reverse operation in response to an operation signal from the control unit 8. The pump 34 discharges air to the outside from the air chamber between the exterior 61 in the ink cartridge 60 and the spout pack 62, and reduces the pressure until the pressure P1 in the ink cartridge 60 becomes −3780 Pa. A state in which the pressure P1 decreases toward −3780 Pa is the waveform portion 78, and the pressure P1 is rapidly decreased by the operation of the pump 34 having a high rotational speed. The pump 37 takes in air from the outside air and pressurizes it until the pressure P2 in the ink tank 50 becomes 2560 Pa. The state where the pressure P2 increases toward 2560 Pa is the waveform portion 79, and the pressure P2 is rapidly increased by the operation of the pump 37 having a high rotational speed. By this series of operations, ink flows from the ink tank 50 toward the ink cartridge 60 via the ink head 100 (line head 21).

The pumps 34 and 37 operate at a high rotational speed when the pressure is greatly changed, such as at the time of activation or when the ink reciprocation is switched. Further, the pumps 34 and 37 perform an operation at a low rotational speed when the change in pressure after reaching a desired pressure is small. Due to the low rotation speed operation, the pressure P2 is maintained at 2560 Pa, which is the state of the waveform portion 88, and the pressure P1 is maintained at -3780 Pa, which is the state of the waveform portion 89.
In this embodiment, the amount of air that is sent to and discharged from the air chamber is changed by changing the rotation speed of the pump, so that the amount of change in pressure is increased or decreased. Instead, it is only necessary to arbitrarily set an operation in which the amount of movement of air per unit time is large and an operation in which the amount of air movement is small in accordance with the required amount of change in pressure.

  Next, when a predetermined time set (7 seconds in FIG. 5) elapses, the operations of the pumps 34 and 37 are reversed. The pump 34 takes air from outside air into the air chamber between the exterior 61 in the ink cartridge 60 and the spout pack 62 and pressurizes the air until the pressure P1 becomes 3540 Pa. The waveform portion 91 is a state in which the pressure P1 rapidly increases toward 3540 Pa due to the operation with the high rotational speed of the pump 34 as described above. The pump 37 discharges the air in the ink tank 50 to the outside and reduces the pressure until the pressure P2 becomes -1910 Pa. The state where the pressure P2 rapidly decreases toward -1910 Pa due to the operation with the high rotational speed of the pump 37 as described above is the waveform portion 90. By this series of operations, ink flows from the ink cartridge 60 into the ink tank 50 via the ink head 100 (line head 21).

  By the operation of the pumps 34 and 37 having a low rotational speed as described above, the pressure P1 is maintained at 3540 Pa which is the state of the waveform portion 86, and the pressure P2 is maintained at −1910 Pa which is the state of the waveform portion 87.

  As described above, the operation of flowing ink from the ink tank 50 to the ink cartridge 60 and the operation of flowing ink from the ink cartridge 60 to the ink tank 50 are repeatedly switched at the set operation intervals of the pumps 34 and 37. Thus, the nozzle pressure Ph (waveform portion 85) suitable for image recording is obtained while continuously supplying ink to the ink head 100.

  Here, in the above series of operations, there is a portion where the ink flow becomes zero at the timing of switching the ink flow. The waveform part 92 shows the state.

  That is, immediately after the operation of the pumps 34 and 37 is started or immediately after the forward / reverse rotation of the pumps 34 and 37 is switched, a desired pressure (for example, P1: -3780 Pa, P2: 2560 Pa, P1: 3540 Pa, P2: −1910 Pa) is reached in a short time, and the pressures P1 and P2 are rapidly increased by increasing the number of revolutions of the pumps 34 and 37 in order to secure the ink flow rate Q necessary to take the heat of the ink head 100. To change. Therefore, the waveforms of the pressures P1 and P2 are in an unstable state in which overshoots and undershoots are generated as in the waveform portions 81 and 82, and the nozzle pressure Ph is also as in the waveform portions 83 and 84. Is disturbed. Further, the flow rate Q flowing through the ink head 100 also varies as shown by the waveform portion 93 due to the influence. This is because the two pumps 34 and 37 have different air feeding and suction capabilities, different air chamber sizes between the ink tank 50 and the ink cartridge 60, and the static / dynamic inertia of the ink and pump. This is because a variation occurs in timing and amount of change in pressure due to force.

  The disturbance of the nozzle pressure Ph does not destroy the meniscus, so that air is not sucked into the ink head 100 from the nozzle 101b and ink does not leak. However, the nozzle pressure Ph at this time is a pressure not suitable for image recording, that is, a pressure deviating from −1000 Pa ± 200 Pa which is the range of the optimum discharge nozzle pressure.

  For this reason, in the present embodiment, the conveyance timing of the recording medium is controlled so that image recording is not performed during the time (waveform portions 83 and 84) in which the nozzle pressure Ph is disturbed. This control will be described with reference to FIG. 6 and FIG.

  FIG. 6 is a flowchart showing the operation of the inkjet printer 1 at the time of image recording in the present embodiment, and FIG. 7 shows changes in pressures P1 and P2 and nozzle pressure Ph that vary in the present embodiment, medium supply operation, and medium. It is a time chart which shows the timing (trigger) of the image recording operation | movement corresponding to supply operation | movement. In the upper time chart of FIG. 7, the vertical axis indicates pressure (Pa) and the horizontal axis indicates elapsed time (s), and in the lower time chart, the vertical axis indicates drive signals (ON / OFF) and the horizontal axis. Indicates the elapsed time (s). The horizontal axes (elapsed time (s)) of both time charts indicate the same timing.

  In FIG. 7, the waveforms of the pressures P1, P2 and the nozzle pressure Ph are extracted from FIG. 5, and are given the same reference numerals as in FIG. The drive signal indicating the medium supply operation indicates that one recording medium 2 is supplied at the rising edge of the convex portion (drive signal) 131. In addition, the drive signal indicating the image recording operation indicates that an image is recorded by ejecting ink from the ink head 100 during the convex portion (drive signal) 132. Further, p1 to p9 given in the drive signal 132 of the image recording operation indicate how many recording media are recorded, and (p1) to (p1) on the drive signal 131 of the medium supply operation. The same applies to (p9).

  First, the user inputs an image recording instruction to the inkjet printer 1 using an input unit (not shown) (step S1). In this embodiment, as an example, an instruction to perform image recording is input to nine A4 size recording media whose long sides are positioned in the Y direction.

  Subsequently, the medium supply timing corresponding to the length of the recording medium in the conveyance direction (in this embodiment, the length of the short side of the A4 size recording medium) is set by the control unit 8 (step S2). In this medium supply timing setting, it is determined how many images can be recorded by the timing at which the operation of switching the ink flow is performed, and based on this, the number N of sheets that can be supplied is set (step S2). . For example, in this embodiment, as shown in the time chart of the recording operation on the lower side of FIG. 7, image recording of p1 to p4, that is, N = 4 is set. Further, a waiting time Tw for delaying the timing for supplying the recording medium is set so that the image recording operation is not performed at the timing when the ink flow is switched (step S2). This setting will be described later.

  Next, the control unit 8 outputs a drive signal 131 (p1) for supplying the first recording medium, and the medium supply operation to the transport unit 3 is started (step S3). As shown in FIG. 7, an operation of flowing ink to the line head 21 is started after a time Ta from the start of the medium supply operation. As described above, ink is sent from the ink tank 50 to the ink cartridge 60 via the line head 21 by rotating the pump 34 forward and the pump 37 reversely from the standby state (the state where no ink flows). (Step S4).

At the initial stage when the liquid feeding operation is started, the forward rotation operation with a high rotation speed of the pump 34 and the reverse rotation operation with a high rotation speed of the pump 37 are performed. Ph is not obtained. The time until the nozzle pressure Ph is stabilized is T1. Since the time T1 varies depending on the configuration of the ink path 20, it is set according to the configuration.
In this way, the ink is fed after Ta time has elapsed since the first medium supply signal 131 (p1) is output so that the image recording operation is not performed during the time T1 when the nozzle pressure Ph is unstable. The operation to start is started.

  It is determined that the pressures P1 and P2 detected by the pressure sensors 72 and 73 have reached the vicinity of a set pressure (for example, P1 = −3780 Pa, P2 = 2560 Pa) at which an optimum nozzle pressure Ph = 1000 Pa ± 200 Pa is obtained for image recording. Then, the pump 34 is shifted to a forward rotation operation with a low rotation speed, and the pump 37 is shifted to a reverse rotation operation with a low rotation speed. The time during which the pressures P1 and P2 are close to the setting and the nozzle pressure Ph suitable for image recording is stably obtained is T2.

  After a time Tn from the start of the first medium supply operation, the recording medium reaches the image recording start position facing the nozzle surface 101a of the ink head 100, and the first image recording drive signal 132 ( p1) is issued (step S5). The first image recording operation is performed after the time Tn (the same time as Ta + T1) has elapsed since the start of the first medium supply operation.

  After the time Tr has elapsed since the first medium supply signal 131 (p1) is output, the drive signal 131 (p2) for supplying the second recording medium is output, and the second recording medium is conveyed by the transport unit 3. Sent to. The medium supply drive signals 131 are output at intervals of a predetermined time Tr up to N sheets (in this embodiment, N = 4, p1 to p4 in FIG. 7) set in step S2, and each drive signal 131 is output. The drive signal 132 for image recording is output after the time Tn has elapsed from the start of the recording. (Signal 133) between the first image recording signal 132 (p1) and the second image recording signal 132 (p2) is a paper gap, that is, an image-recorded recording medium and an image is recorded from this. A state in which image recording by the image recording unit 4 is not performed with the recording medium is shown.

  While the medium supply operation and the image recording operation are being performed, it is confirmed at any time whether or not the image recording of the number designated in step S1 (9 sheets in the present embodiment) has been completed (step S6). . If completed, the process proceeds to YES symbol B and shifts to an end operation. If not completed, the process proceeds to step S7 which is NO.

  If the recording of the instructed number of images has not been completed, it is confirmed whether or not the number N of sheets that can be supplied set in step S2 (four in this embodiment) has been reached (step S7). If not, the process returns to step S5 to continue the image recording operation. If it has reached, the process proceeds to step S8, the medium supply operation is stopped, and the medium supply operation is waited for the waiting time Tw set in step S2. In this embodiment, the control unit 8 performs control so that the image recording operation is not performed during the time T1 during which the ink flow is switched by waiting for the medium supply operation.

  In FIG. 7, the convex signal indicated by the broken line in the drive signal for the medium supply operation is the fifth medium supply signal when the fifth recording medium is supplied without such control. When the fifth image is recorded after this medium supply timing, the fifth image recording operation is performed during T1, which is a time for switching the ink flow, which may cause a recording failure. Therefore, in the present embodiment, the timing of performing the image recording operation is set to the timing (p5: drive signal 131) that is deviated from the time T1 by delaying the fifth medium supply operation by the waiting time Tw.

  After Tr + Tw time after the drive signal 131 (p4) for supplying the fourth recording medium is output, the drive signal 131 (p5) for supplying the fifth recording medium is output and the fifth medium supply The operation is started (step S9). Then, after the time Ta has elapsed since the start of the medium supply operation for the fifth sheet, the pump 34 is reversed and the pump 37 is rotated forward so that the ink flow is reversed, and the ink cartridge 60 passes through the line head 21. Then, the ink is fed to the ink tank 50 (step S10).

  Even at the stage of reversing the liquid feeding operation, since the reverse rotation operation with a high rotation speed of the pump 34 and the forward rotation operation with a high rotation speed of the pump 37 are performed, the fluctuations in the pressures P1 and P2 are large and the appropriate nozzle pressure Ph is Not obtained. The time until the nozzle pressure Ph is stabilized is T1. When it is determined that the pressures P1 and P2 detected by the pressure sensors 72 and 73 have reached the vicinity of the set pressure (for example, P1 = 3540 Pa, P2 = −1910 Pa) at which the optimum nozzle pressure Ph for image recording is obtained. The pump 34 is shifted to a reverse rotation operation with a low rotation speed, and the pump 37 is shifted to a normal rotation operation with a low rotation speed. The time during which the pressures P1 and P2 are close to the setting and the nozzle pressure Ph suitable for image recording is stably obtained is T2.

  After a time Tn from the start of the fifth medium supply operation, the recording medium reaches the image recording start position facing the nozzle surface 101a of the ink head 100, and the fifth image recording drive signal 132 ( p5) is issued (step S11). The fifth image recording operation is performed after the time Tn (same time as Ta + T1) has elapsed since the fifth medium supply operation was started. In other words, at the time when the ink feeding operation is started (or when the ink feeding operation is switched) so that the image recording operation is not performed during the unstable time T1 when the nozzle pressure Ph is not suitable for image recording. On the other hand, the timing for starting the medium supply is set so as to wait for the conveyance of the recording medium.

  After the time Tr has elapsed since the fifth medium supply signal 131 (p5) is output, the drive signal 131 (p6) for supplying the sixth recording medium is output, and the sixth recording medium is conveyed by the transport unit 3. Sent to. The medium supply drive signals 131 are output at intervals of a predetermined time Tr up to N sheets (in this embodiment, N = 4, p5 to p8 in FIG. 7) set in step S2, and each drive signal 131 is output. The image recording drive signal 132 (p6) is made after the time Tn has elapsed from the start of the recording start. In the same manner as described above, the image recording is not performed in the paper gap between the fifth image recording signal 132 (p5) and the sixth image recording signal 132 (p6) (signal 133). Indicates the state.

  While the medium supply operation and the image recording operation are being performed, it is confirmed at any time whether or not the recording of the number of images designated in step S1 has been completed (step S12). If completed, the process proceeds to YES symbol B and shifts to an end operation. If not completed, the process proceeds to step S13 which is NO.

  If the recording of the instructed number of images has not been completed, it is confirmed whether or not the supplyable number N set in step S2 has been reached (step S13). If not, the process returns to step S11 to continue the image recording operation. If it has reached, the process proceeds to step S14, the medium supply operation is stopped, and the medium supply operation is waited for the set waiting time Tw as in step S8. That is, by delaying the ninth medium supply operation by the waiting time Tw, the timing at which the image recording operation is performed is set to the timing (p9: drive signal 131) that is removed from the time T1.

  After Tr + Tw time from when the drive signal 131 (p8) for supplying the eighth recording medium is output, the drive signal 131 (p9) for supplying the ninth recording medium is output to supply the ninth medium. The operation is started (step S15). Then, after a time Ta from the start of the ninth medium supply operation, the pump 34 is rotated in the forward direction and the pump 37 is rotated in the reverse direction so as to reverse the ink flow, so that the ink tank 50 passes through the line head 21. Ink is fed to the ink cartridge 60 (step S16).

Then, after the time Tn has elapsed from the ninth medium supply signal, the ninth image recording is performed, and all the image recording is completed.
When all the image recording is completed, the medium supply operation is stopped (step S17), and immediately after the liquid level sensor 71 of the ink tank 50 is turned on so that the ink path 20 is in a standby state, A pressure that cancels the water head difference between the ink cartridge 60 and the ink tank 50 is generated in the air paths 33 and 36, and the pumps 34 and 37 are stopped (step S18).

Next, setting of the number N of sheets that can be supplied and the waiting time Tw will be described with reference to FIG.
In the following description, the distance from the medium supply start position to the image recording position in the inkjet printer 1 is Lh [mm], the recording medium conveyance speed is V [mm / s], and the length of one recording medium in the conveyance direction is as follows. Is L1 [mm], and the paper gap is L2 [mm].

The number N of sheets that can be supplied can be obtained from the number of times that image recording can be performed during the time T2 when the nozzle pressure Ph is stable. Since the time required for image recording on one recording medium is L1 / V and the time of the paper gap 133 is L2 / V, the quotient calculated by T2 / (L1 / V + L2 / V) is A, and the remainder is If Te,
T2 / {(Ll + L2) / V} -T2 / Tr = A ... Te
It is. Te indicates the extra time. If image recording can be performed on one recording medium within this time Te, A + 1 can be supplied N, and if image recording cannot be performed on one recording medium within time Te, A The number of sheets that can be supplied is N. In other words,
If Te ≧ L1 / V, N is A + 1
If Te <L1 / V, N is A
It is. Further, the waiting time Tw for delaying the medium supply operation is Tw = Tp−Tr × N, using the obtained number N of sheets that can be supplied.

The timing for supplying the medium should be earlier by the time Ta than the operation for switching the ink flow, and from the time Tn = Lh / V from the start of the medium supply operation to the start of the image recording operation. Ta = Tn−T1 = Lh / V−T1.
Further, the interval Tp for switching the ink flow is expressed as Tp = T1 + T2, and the medium supply interval Tr when N sheets of images are recorded is Tr = (L1 + L2) / V.

For example, if the time during which ink can be fed in one direction is 7 seconds, Tp = T1 + T2 = 7 seconds, and if the time T1 is set from the configuration of the ink path 20, the value of T2 is also determined, By using L1, L2, Lh, and V, which are fixed values, N, Tw, Tr, Tn, Tp, and Ta can be obtained.
Note that the above setting is merely an example, and the present invention is not limited to this setting, and the medium supply timing may be set so that image recording is not performed at the timing of switching the ink flow. That is, the supply (conveyance) timing of the recording medium may be controlled so that the ink flow switching operation is completed between the page gaps of the supplied recording medium.

FIG. 8 is a time chart showing the transition of pressure when an image recording instruction is executed on nine A3 size recording media and the timing of the image recording operation corresponding to the medium supply operation and the medium supply operation.
In FIG. 8, the point different from the case of FIG. 7 is that two images are recorded by the liquid feeding operation in one direction, and the waiting time Tw ′ is set. As described above, the number N of images that can be recorded by the liquid feeding operation in one direction and the waiting time Tw (Tw ′) are set according to the size of the recording medium.

  According to this embodiment, the ink is supplied to the ink head while reciprocating the ink, and the timing at which the direction of the ink flowing to the ink head is switched is different from the timing at which the recording medium is conveyed (supplied), that is, Since the timing for starting the conveyance operation of the recording medium is controlled based on the timing for switching the ink flow, image recording is not performed at the time of switching. In other words, the timing at which the recording medium is conveyed (supplied) is controlled so that the direction in which the ink flows is switched between the page gaps of the recording medium conveyed first and the recording medium conveyed next. Yes. Accordingly, the line head 21 (ink head 100) can eject ink in a state where the nozzle pressure Ph suitable for image recording is applied, and can record a high-quality image.

Hereinafter, second to eighth embodiments will be described.
Hereinafter, the basic configuration of the inkjet printer 1 is the same as that of the first embodiment shown in FIGS. 1 to 4 unless otherwise specified, and the method of setting the nozzle pressure Ph to a pressure suitable for image recording is also the same. It is. Accordingly, with respect to these configurations and settings, the same reference numerals are given to the same portions, and illustrations and descriptions thereof are omitted, and mainly the configurations and operations of different portions will be described.

(Second Embodiment)
A second embodiment of the present invention will be described with reference to FIGS. 9 and 10.
FIG. 9 is a flowchart showing the operation of the inkjet printer 1 during image recording in the second embodiment, and FIG. 10 is a time chart corresponding to this. FIG. 10 is a time chart when an image recording instruction is executed on nine A4 size recording media.

  First, as in the first embodiment, the user inputs an image recording instruction to the inkjet printer 1 using an input unit (not shown) (step S1). Subsequently, the control unit 8 sets a time Tc for switching the ink flow according to the length in the conveyance direction of the recording medium (in this embodiment, the length of the short side of the A4 size recording medium) (step Sc). S19). The time Tc for switching the ink flow is set so that the operation for switching the ink flow is not performed during the image recording operation. This setting will be described later.

  Next, as in the first embodiment, the drive signal 131 (pl) for supplying the first recording medium is issued, whereby the medium supply operation to the transport unit 3 is started (step S3). After a time Ta from the start of the medium supply operation, an operation of flowing ink to the line head 21 is started. Hereinafter, the driving of the pumps 34 and 37 in step S4, the first image recording operation in step S5, and the confirmation of the completion of image recording in step S6 are the same as in the first embodiment. If it is determined in step S6 that the recording of the designated number of images has been completed, the process proceeds to a symbol B of YES, and the process proceeds to an end operation. If not completed, the process proceeds to step S20 which is NO.

  If the recording of the designated number of images has not been completed, it is confirmed whether or not the time Tc set in step S19 has elapsed since the first medium supply was started (step S20). If not, the process returns to step S5 to continue the image recording operation. If it has elapsed, the process proceeds to step S10. By performing the ink switching operation in accordance with the interval of time Tc, the paper gap passes under the ink head, that is, the time during which image recording is not performed and the time during which the nozzle pressure Ph is not suitable for image recording (nozzle pressure (Time until Ph is stabilized) The timing is synchronized with T1.

  For example, as shown in FIG. 10, the operation of reversing the ink flow is performed at a timing Ta after the drive signal 131 (p5) for supplying the fifth recording medium is output. This timing is also the time when the time Tc has elapsed since the ink feeding operation was started. That is, from the start of the first image recording operation to the completion of the fourth image recording operation, an operation of flowing ink from the ink tank 50 to the ink cartridge 60 is performed, and the fourth image recording operation is performed. And a paper gap 133 between the first image recording operation and the fifth image recording operation, and an operation of switching ink flow from the ink cartridge 60 to the ink tank 50 from the fifth image recording operation. . After the time Ta has elapsed since the start of the medium supply operation for the fifth sheet, the pump 34 is rotated in the reverse direction and the pump 37 is rotated in the forward direction so as to reverse the ink flow. Ink is fed to the tank 50 (step S10).

  At the stage of reversing the liquid feeding operation, as described above, fluctuations in P1 and P2 are large and an appropriate nozzle pressure Ph is not obtained, and the time until the nozzle pressure Ph becomes stable is T1. Further, when it is determined that the pressures of Pl and P2 detected by the pressure sensors 72 and 73 have reached the vicinity of the set pressure (P1 = 3540 Pa, P2 = −1910 Pa) at which the optimum nozzle pressure is obtained for image recording. The pump 34 shifts to a reverse rotation operation with a low rotation speed, and the pump 37 shifts to a normal rotation operation with a low rotation speed. The time during which the pressures P1 and P2 are close to the setting and the nozzle pressure Ph suitable for image recording is stably obtained is T12.

  After time Tn from the start of the fifth medium supply operation, the recording medium reaches the image recording start position facing the nozzle surface 101a of the ink head 100, and the fifth drive signal 132 (p5) is received. Is issued (step S11). The fifth image recording operation is performed after the time Tn (the same time as Ta + T1) has elapsed since the start of the fifth medium supply operation. In other words, the ink feeding is performed so that the ink discharge is waited at the timing when the medium supply is started so that the image recording operation is not performed during the unstable time T1 when the nozzle pressure Ph is not suitable for image recording. The time for starting the operation (or the time for switching the ink feeding operation) is set.

  After the time Tr has elapsed since the fifth medium supply signal 131 (p5) is output, the drive signal 131 (p6) for supplying the sixth recording medium is output, and the sixth recording medium is conveyed by the transport unit 3. Sent to.

  While the medium supply operation and the image recording operation are being performed, as in the first embodiment, it is confirmed at any time whether or not the number of image recordings designated in step S1 has been completed (step S12). If completed, the process proceeds to YES symbol B and shifts to an end operation. If not completed, the process proceeds to step S21 which is NO.

  If the recording of the designated number of images has not been completed, it is confirmed whether or not the time Tc for switching the ink set in step S19 has elapsed since the start of the fifth medium supply operation (step S21). ). If not, the process returns to step S11 to continue the image recording operation. If it has elapsed, the process proceeds to step S16. As described above, by performing the ink switching operation in accordance with the interval of the time Tc, the paper gap passes through the ink head, that is, the time when the image recording is not performed, and the time T1 when the nozzle pressure Ph is not suitable for the image recording. (= Time until the nozzle pressure Ph is stabilized).

  After the time Ta after the ninth medium supply signal 131 is output, an operation of reversing the ink flow is performed. By rotating the pump 34 forward and the pump 37 reversely, ink is fed from the ink tank 50 to the ink cartridge 60 via the line head 21 (step S16).

Then, after the time Tn has elapsed from the ninth medium supply signal, the ninth image recording is performed, and all the image recording is completed.
When all image recording is completed, the medium supply operation is stopped (step S17), and the pumps 34 and 37 are stopped (step S18), as in the first embodiment.

Next, the setting of the time Tc for switching the ink flow will be described with reference to FIG.
The time Tc for switching the ink flow needs to satisfy the condition Tc ≦ Tmax, where Tmax is the maximum time during which ink can be fed in one direction. If this condition is deviated, the ink in the ink tank 50 is emptied and air is sent to the ink head 100, which may cause ejection failure. Therefore, the number of images that can be recorded during the time Tmax is determined, and the time Tc is set so as to perform an operation of switching the ink flow after the recording of the number of images is completed.

The number N of images that can be recorded during the time Tmax is given by assuming that the quotient calculated by (Tmax−T1) / Tr is A and the remainder is Te.
(Tmax−T1) / Tr = A... Te
It is. Te indicates the extra time. If image recording can be performed on one recording medium within this time Te, A + 1 can be supplied N, and if image recording cannot be performed on one recording medium within time Te, A The number of sheets that can be supplied is N. In other words,
If Te ≧ L1 / V, N is A + 1
If Te <L1 / V, N is A
It is. Further, the time Tc for switching the ink flow is Tc = Tr × N, using the obtained number N of media that can be supplied.

The ink flow may be started at the timing after the time Ta when the medium supply operation is started. The time Tn = Lh / V from the start of the medium supply operation to the start of the image recording operation. Therefore, Ta = Tn−T1 = Lh / V−T1.
The medium supply interval (Tr) when image recording is performed is Tr = (L1 + L2) / V.

  Note that the above setting is merely an example, and the present invention is not limited to this setting, and the timing for switching the ink flow may be set so that image recording is not performed at the timing when the medium is supplied. That is, the timing for switching the ink flow may be controlled so that the operation for switching the ink flow is completed between the page gaps of the supplied recording medium.

FIG. 11 is a time chart showing the transition of pressure when an image recording instruction is executed on nine A3 size recording media and the timing of the image recording operation corresponding to the medium supply operation and the medium supply operation.
In FIG. 11, the difference from the case of FIG. 10 is that two image recording operations are performed by the liquid feeding operation in one direction, and a time Tc ′ for switching the ink flow is set. Thus, the time Tc (Tc ′) for switching the ink flow is set according to the size of the recording medium.

  According to this embodiment, the ink is supplied to the ink head while reciprocating the ink, and the timing at which the direction of the ink flowing to the ink head is switched is different from the timing at which the recording medium is conveyed (supplied), that is, Since the timing of switching the ink flow is controlled based on the timing of transporting (supplying) the recording medium, image recording is not performed at the time of switching. In other words, the switching timing is controlled so that the direction in which the ink flows is switched between the page gaps between the recording medium conveyed in advance and the recording medium conveyed subsequently. Accordingly, the line head 21 (ink head 100) can eject ink in a state where the nozzle pressure Ph suitable for image recording is applied, and can record a high-quality image. In the present embodiment, the timing at which the direction of the ink flowing through the ink head is switched in accordance with the timing and conditions (the number of recorded images and the size of the recording medium) for supplying the recording medium is controlled. And the number of recorded images per unit time can be improved.

(Modification)
FIG. 12 is a flowchart showing the operation of the inkjet printer 1 during image recording in a modification of the second embodiment.
In the present modification, the difference from the flowchart of the second embodiment shown in FIG. 9 is that steps S22 to S25 are added.

  In this modification, after step S20, it is confirmed whether there is any change in the size of the recording medium to be supplied (step S22). If there is a change, the process proceeds to YES, the setting of the time Tc for switching the ink flow set in step S19 is changed to the time Tc '(step S23), and the process proceeds to step S10. If there is no change, the process proceeds to NO and proceeds directly to step S10.

  By adding such steps, it is possible to change the setting of the time Tc for switching the ink flow for each ink flow in one direction even when an image recording instruction to a recording medium of a different size is performed. It is possible to perform an operation that does not perform the image recording operation at the timing when the flow changes.

In this modified example, it corresponds to the case where recording media of different sizes coexist, and the set value of Tc is reconsidered for each operation of changing the ink flow. The review of the set value will be described.
First, an operation of flowing ink from the ink tank 50 to the ink cartridge 60 is performed after the time Ta has elapsed after the first medium supply signal 131 is output, and image recording is started.

Next, the number of images that can be recorded during the maximum time Tmax during which ink can be fed in one direction is obtained, and the ink switching time Tc is obtained.
Here, if the lengths in the transport direction of the recording media p1 to pN (N is a natural number) are L1 ′ to LN ′,
Tmax ≧ T1 + Ll ′ / V
+ L2 / V + L2 '/ V
+ ...
+ L2 / V + LN '/ V = Tc
Up to the number of sheets satisfying the above relationship is defined as the number of sheets that can be supplied in one direction, and the time is Tc.

  At this time, if Tmax−Tc = Tdef, Tdef is the remaining liquid feeding time that occurs because the ink flow is reversed due to the timing of the image recording operation, although ink can still be fed. Since this Tdef affects the maximum time Tmax ′ in which the ink can be fed after the ink flow is reversed, the number of recorded images after the ink flow is reversed in consideration of this time, A time Tc ′ for switching the ink flow is obtained.

For example, if image recording on the recording media p1 to p4 is performed in the flow in the previous one direction, image recording from p5 is performed after the ink feeding direction is reversed. here,
Tmax ′ ≧ T1 + L5 ′ / V
+ L2 / V + L6 '/ V
+ ...
+ L2 / V + LN '/ V = Tc'
Up to the number of sheets that satisfies the above relationship is the number of sheets that can be supplied in one direction, and the time is Tc ′.

  At this time, since Tmax ′ = Tmax−Tdef = Tc, Tc ≧ Tc ′. Further, when Tmax′−Tc ′ = Tdef ′, Tdef ′ is a remaining liquid feeding time that occurs because the ink flow is reversed due to the timing of the image recording operation although the ink can still be fed.

Based on the same idea, Tmax ′ = Tmax−Tdef ′ is set, and the number of recordable images, Tc ″ is obtained, and the time for switching the ink flow is set.
Note that the above setting is merely an example, and the timing for switching the ink flow may be set so that image recording is not performed at the timing for switching the ink flow. That is, the timing for switching the ink flow may be controlled so that the operation for switching the ink flow is completed between the page gaps of the supplied recording medium.

  FIG. 13 is a time chart in the case where recording media of different sizes are mixed, and image recording of three A4 horizontal sizes, four A3 vertical sizes, one A4 horizontal size, and four B4 vertical sizes is continuously performed. ing.

In FIG. 13, Tmax, Tmax ′, Tmax ″ are the times during which ink can be fed, Tc, Tc ′, Tc ″ are the ink switching timings, and the nozzle pressure Ph suitable for image recording is stably obtained. If the time is T13, T14, T15, T16 in chronological order,
Tmax ≧ T1 + T13 = Tc
Tmax ′ ≧ T1 + T14 = Tc ′
Tmax ″ ≧ T1 + T15 = Tc ″
The image recording operation of 3 sheets of A4 size (drive signal 146) and 1 sheet of A3 size (drive signal 147) is performed within the time period of T13, and 3 sheets of A3 size (drive signal 147) are within the time period of T14. Within the time of image recording operation T15, an image recording operation of one A4 size (driving signal 146) and three B4 sizes (driving signal 148) is performed. The remaining B4 size (driving signal 148) image recording is performed within the time period T16, whereby the image recording is completed, and then the operation for shifting the ink path 20 to the standby state is performed.

  In this modification, even when recording media of different sizes are mixed, high-quality image recording can be performed efficiently.

(Third embodiment)
A third embodiment of the present invention will be described with reference to FIG.
FIG. 14 is a time chart showing transitions of the pressures P1 and P2 and the nozzle pressure Ph in the third embodiment and the timing (trigger) of the image recording operation corresponding to the medium supply operation and the medium supply operation.

  In this embodiment, when image recording is continuously performed on recording media of different sizes, the ink flow is switched every time one image recording is completed. For example, as shown in FIG. 14, when an image recording instruction is issued in the order of one A4 horizontal size, two A3 vertical sizes, one B4 vertical size, one A4 horizontal size, and one A3 vertical size, A4 Horizontal image recording (driving signal 152), ink flow switching, A3 vertical image recording first sheet (driving signal 153), ink flow switching, A3 vertical image recording second sheet (driving signal 153), ink flow ,..., The operation of switching the ink flow every time one image recording is completed, like the first A3 vertical image recording (drive signal 153).

  For example, if an image is recorded on a recording medium having a large size after an image is recorded on a recording medium having a small size by the first image recording operation, the time for feeding ink is short in the first image recording operation. For this reason, there is a possibility that a sufficient amount of ink for feeding ink cannot be secured when recording the second image. Therefore, in this embodiment, the operation of feeding ink is started from the time Ts before the first medium supply drive signal 149 is started, and the image recording is performed from the first medium supply drive signal 149. In addition to the time Tn, the setting of Tmax / 2≈Ts + Tn is established so that the image recording is started after performing the liquid feeding operation for approximately half the maximum time Tmax that can be fed in one direction. Yes.

  By setting this time, the flow of reciprocating ink is operated around about half the time of Tmax, and even if image recording is performed on a recording medium having a different size, there is no shortage of ink. The ink flow can be switched every time the image recording is completed.

  Further, when the image recording is continuously performed alternately on the recording medium having a small size and the recording medium having a large size like A4, A3, A4, A3,..., The position where the ink reciprocates slightly deviates, There is a risk of deviating from the range of Tmax. Considering such a case, when the deviation from the time of Tmax / 2 deviates from the arbitrarily set threshold value, the liquid feeding direction in one direction is extended and the timing for supplying the recording medium is delayed accordingly. Control is performed.

  In this embodiment, since the recording medium is transported and the direction of the ink flowing through the ink head is switched every time one image recording is completed, the image recording is not performed at the time of switching. In other words, the switching timing is controlled so that the direction in which the ink flows is switched between the page gaps between the recording medium conveyed in advance and the recording medium conveyed subsequently. Accordingly, the line head 21 (ink head 100) can eject ink in a state where the nozzle pressure Ph suitable for image recording is applied, and can record a high-quality image.

(Fourth embodiment)
A fourth embodiment of the present invention will be described with reference to FIG.
The ink jet printer 1 according to the present embodiment has a medium position sensor 25 as a medium position detecting unit that detects the leading edge (edge) of the recording medium 2 and detects the position at a position above the driven roller 12 and opposed thereto. ing. The medium position sensor 25 is located upstream of the ink head 100 by a predetermined distance L25 in the medium conveyance direction, and is fixed to a conveyance unit frame (not shown) to which the image recording unit 4 is fixed.

  The medium position sensor 25 detects the leading end of the recording medium 2 conveyed from the registration roller pair 11, thereby obtaining the time until the recording medium 2 is conveyed below the ink head 100. And the timing for switching the flow of ink in the ink path 20 are determined. Since the medium position sensor 25 is fixed to the image recording unit 4, there is no deviation in the relative positional relationship, and the time until the recording medium 2 is conveyed below the ink head 100 is accurately detected. be able to. That is, if the transport speed is V, the recording medium 2 can easily reach the image recording start position of the ink head 100 in the time of L25 / V after the medium position sensor 25 detects the edge of the recording medium 2. Can be calculated. Furthermore, it is also possible to control the ink ejection timing of the ink head 100 by the control unit 8 based on the information detected by the medium position sensor 25.

  According to this embodiment, since the medium position sensor capable of detecting the front end of the recording medium and detecting the position of the conveyed recording medium with high accuracy is provided, the position of the recording medium can be accurately obtained, and the ink It is possible to accurately determine the timing for switching the flow of the.

(Fifth embodiment)
A fifth embodiment of the present invention will be described with reference to FIG.
In this embodiment, the difference from the ink path 20 of the first embodiment is that the ink liquid level of the ink cartridge 60 and the ink tank 50 is arranged at a position higher than the nozzle surface 101 a of the ink head 100. .

  Even in such a positional relationship, by setting the pressures P1 and P2, it is possible to reciprocate the ink via the ink head 100 while maintaining the nozzle pressure suitable for image recording. For example, the ink liquid level of the ink cartridge 60 and the ink tank 50 is positioned 100 mm higher than the nozzle surface 101 a of the ink head 100, and the flow path resistance values of the first ink path 31, the second ink path 32, and the line head 21. A case similar to that of the first embodiment will be described.

  The ink jet printer 1 can set the nozzle pressure Ph to −998 Pa by setting P1 = P2 = −1880 Pa in a state where image recording is not performed. In the case where ink is allowed to flow from the ink tank 50 to the ink cartridge 60 during image recording, a nozzle pressure of −1004 Pa suitable for image recording can be obtained by setting P1 = −5540 Pa and P2 = 350 Pa. Further, when ink is allowed to flow from the ink cartridge 60 to the ink tank 50, a nozzle pressure of −998 Pa suitable for image recording can be obtained by setting P1 = 1780 Pa and P2 = −4120 Pa.

  Also in this embodiment, as in the first to third embodiments, the recording medium transport operation timing and / or the ink flow switching timing are set so that the image recording operation is not performed when the ink flow is switched. Control.

(Sixth embodiment)
A sixth embodiment of the present invention will be described with reference to FIG.
In the present embodiment, the configuration of the ink path 20 is different from that of the ink path 20 of the first embodiment.

  In the ink path 20 of this embodiment, the pressures P1 and P2 in these tanks are set by the water head differential pressure of the two ink tanks 50 and 51.

  The ink path 20 detects the ink head 100 (line head 21), the ink tank 50, the ink tank 51 in place of the ink cartridge 60 of the first embodiment, and the ink amounts in the ink tanks 50 and 51, respectively. In addition, liquid level sensors 71 and 74 provided in the vicinity thereof, and a tank elevating part 52 for elevating and lowering the ink tanks 50 and 51 to a desired height, respectively. Also in the present embodiment, as in the first embodiment, the ink tank 51 and the ink head 100 are connected by the first ink path (first tube) 31, and the ink head 100 and the ink head 100 are connected. The tank 50 is connected by a second ink path (second tube) 32. Although not shown, the ink tanks 50 and 51 have ports that communicate with the atmosphere.

  In the standby state (state in which image recording is not performed), the height of the ink tanks 50 and 51 is approximately the position in the Z direction with respect to the position where the nozzle pressure Ph of the ink head 100 can maintain a negative pressure, for example, the nozzle surface 101a. The position is higher by 110 mm (FIG. 17A). When an image recording operation is instructed, the ink tank 50 is raised and the ink tank 51 is lowered by the tank elevating unit 52. Here, the first and second ink paths 31 and 32 are tubes of the same length and φ5 mm (flow path resistance R1 = R2), and the ink viscosity ρ and the line head 21 of the same as in the first embodiment are used. If the flow path resistance is Rh (the flow path resistance symmetrical to the ink inlets on both sides), the ink flow rate of 3.21 ml / s for depriving the heat of the line head 21 can be secured. The amount of movement of the ink tanks 50 and 51 is 280 mm, the height of the ink tank 50 is moved to a position higher by 167 mm from the nozzle surface, and the height of the ink tank 51 is moved to a position lower by 393 mm from the nozzle surface (see FIG. 17 (b)). The ink level is maintained at this position until the liquid level sensor 71 of the ink tank 50 is turned from ON to OFF. At this time, ink flows from the ink tank 50 to the ink tank 51 via the line head 21, and the amount of ink flowing to the line head 21 is 3.21 ml / s.

  Next, when the liquid level sensor 71 changes from ON to OFF, the ink tank 50 is lowered and the ink tank 51 is raised by the tank elevating unit 52. The amount of movement of the ink tanks 50 and 51 is 280 × 2 = 560 mm, the height of the ink tank 50 is as low as 393 mm from the nozzle surface, and the height of the ink tank 51 is as high as 167 mm from the nozzle surface. (FIG. 17C). The liquid level sensor 74 of the ink tank 51 is maintained at this position until it is turned from ON to OFF. At this time, ink flows from the ink tank 51 to the ink tank 50 via the line head 21, and the amount of ink flowing to the line head 21 is 3.21 ml / s.

When the image recording operation is completed and the ink reciprocation is stopped, the ink tanks 50 and 51 are returned to the positions shown in FIG.
As described above, in the standby state, the ink is reciprocated in the line head by alternately repeating the states of FIGS. 17B and 17C at the position of FIG. 17A during the image recording operation. .

  In this embodiment as well, as in the first to third embodiments, the recording medium conveyance operation timing and / or the ink flow switching timing are set so that the image recording operation is not performed when the ink flow is switched. Control.

(Seventh embodiment)
A seventh embodiment of the present invention will be described with reference to FIG.
In the present embodiment, the configuration of the ink path 20 is different from that of the ink path 20 of the first embodiment.

  In the ink path 20 of the present embodiment, the pressures P1 and P2 in the tanks are set by increasing and decreasing the air in the tanks by expanding and contracting the bellows 300 and 301 provided in the two ink tanks 50 and 51, respectively.

  The ink path 20 pressurizes and depressurizes the ink head 100 (line head 21), the ink tanks 50 and 51, the liquid level sensor 71 provided in the vicinity of the ink tank 50, and the air in the ink tanks 50 and 51, respectively. Cylinders 304 and 305 and rods 308 and 309 that respectively have bellows 300 and 301 and rods 308 and 309 and operate the rods 308 and 309 relative to the bellows 300 and 301 in response to an electrical signal from the control unit 8. Plate members 306 and 307 that are fixed to one end of the cylinder and transmit the pushing and pulling force of the cylinders 304 and 305. The plate members 306 and 307 are fixed to the bellows 300 and 301, respectively, detect the position of one end of the plate members 306 and 307, and detect the length of the bellows 300 and 301 when they are expanded and contracted by the position detection sensors 302 and 303. is doing.

  In the standby state (state in which image recording is not performed), the pressures P1 and P2 in the ink tanks 50 and 51 are set to a negative pressure in consideration of the water head differential pressure from the nozzle surface 101a to the liquid level in the ink tank. Such a negative pressure level is maintained. When an image recording instruction is given, the rod 308 of the cylinder 304 comes out, so that the plate member 306 pushes the bellows 300 and the bellows 300 contracts. At the same time, when the rod 309 of the cylinder 305 is retracted, the plate member 307 pulls the bellows 301, and the bellows 301 extends. The pressure in the ink tank changes due to the volume fluctuation of the bellows.

  The pressure change of the ink tank 50 at this time can be calculated by previously obtaining the volume change amount of the air chamber formed by the bellows 300 and the ink tank 50 with respect to the stroke amount of the rod 308. In the present embodiment, the displacement amount of the rod 308 is detected by the position detection sensor 302, and the pressure P2 in the ink tank 50 is obtained according to the amount. Similarly, the pressure change in the ink tank 51 can be calculated by previously obtaining the volume change amount of the air chamber formed by the bellows 301 and the ink tank 51 with respect to the stroke amount of the rod 309. In the present embodiment, the displacement amount of the rod 309 is detected by the position detection sensor 303, and the pressure P1 in the ink tank 51 is obtained according to the amount.

  The cylinders 304 and 305 move to a position where P1 and P2 are at a desired pressure, and maintain the positions. This state is shown in FIG. At this time, the ink flows from the ink tank 50 to the ink tank 51 via the ink head 100.

  As time passes, the pressures P1 and P2 decrease, and the ink flow also decreases. This is not preferable because the ink flow rate necessary for preventing the temperature rise of the ink head cannot be secured. Therefore, the time that cannot be secured is obtained in advance, and when that time elapses, the operation proceeds to the next operation.

  For example, after 5 seconds from the state of FIG. 18B, the rod 308 of the cylinder 304 is retracted, so that the plate member 306 pulls the bellows 300, and the bellows 300 extends. At the same time, when the rod 309 of the cylinder 305 comes out, the plate member 307 pushes the bellows 301 and the bellows 301 contracts. The cylinders 304 and 305 move and maintain their positions until the pressures P2 and P1 reach a desired pressure. This state is shown in FIG. At this time, the ink flows from the ink tank 51 to the ink tank 50 via the ink head 100. When the liquid level sensor 71 of the ink tank 50 is in the initial liquid level position that is turned from OFF to ON, the following operation is performed.

To continue the reciprocating motion of the ink, as shown in FIGS. 18B and 18C, the bellows are continuously expanded and contracted alternately. When the image recording is finished and the ink reciprocation is stopped, the cylinder is returned to the initial position shown in FIG.
As described above, when the image recording is not performed, the state shown in FIG. 18A and the state shown in FIGS. 18B and 18C are alternately repeated during the image recording operation, so that the ink is applied to the line head. Is reciprocated. In this embodiment as well, as in the first to third embodiments, the recording medium conveyance operation timing and / or the ink flow switching timing are set so that the image recording operation is not performed when the ink flow is switched. Control.

(Eighth embodiment)
An eighth embodiment of the present invention will be described with reference to FIG.
The ink path 20 is different from the ink path 20 of the seventh embodiment in that there is no air in the ink tank, and the ink flow is switched by directly pushing and pulling the ink (incompressible) by the expansion and contraction of the bellows. Yes. When this method is used, since there is no air layer in the path, it is possible to use ink that easily aggregates and solidifies when it comes into contact with air.

  As shown in FIG. 19, the ink path 20 is provided so as to face the bellows 310 with the ink tank 50 sandwiched in the Z direction, and with the bellows 301 with the ink tank 51 sandwiched in the Z direction. And a position sensor 312 disposed in the vicinity of the bellows 310 so as to detect the position of the bellows 310. The position sensor 312 may be disposed in the vicinity of the bellows 311 so as to detect the position of the bellows 311. The spring constant K2 of the bellows 310, 311 is set larger than the spring constant K1 of the bellows 300, 301 (K2> K1), and does not fully extend with respect to the stroke amount of the bellows 300, 301 extending and contracting, and A stroke amount (a range in which the characteristics of the spring constant can be obtained) is secured.

  The operations of the cylinders 304 and 305 and the bellows 300 and 301 and the position detection method when the image recording is not performed or when the operation for performing the image recording is instructed are the same as those in the seventh embodiment.

  In this embodiment, the inside of the ink path 20 is filled with non-compressible ink, and volume fluctuations in the bellows 300 and the ink tank 50 and between the bellows 301 and the ink tank 51 are sensitively transmitted to the ink path. The bellows 310 and 311 serve as a damper that absorbs the fluctuation and prevents a sudden pressure fluctuation. For example, in the case where the bellows 310 and 311 are not provided, even if the movement of the bellows 300 is performed only 100 ms faster than the bellows 301, a pressure fluctuation at a level of several tens of kPa occurs in the path, and the nozzle of the ink head Ink may drip from the nozzle or air may be sucked from the nozzle. In order to prevent such a problem, bellows 310 and 311 are provided.

  In addition, when the amount of ink in the path is reduced by the image recording operation, the return of the bellows 310 is reduced and the state changes to a slightly contracted state. Therefore, the position is detected by the position sensor 312, and the ink in the path is insufficient. When it is determined that the ink has been discharged, an operation of feeding ink from the ink cartridge to the ink tank is performed. As described above, the operation of flowing ink to the line head is enabled.

  According to the present embodiment, since there is no air layer in the ink path portion, it is possible to use ink that easily aggregates and solidifies when the air is touched. In the present embodiment as well, as in the first to third embodiments, the recording medium conveyance operation timing and / or the ink flow switching timing are controlled so that the image recording operation is not performed when the ink flow is switched. To do.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to the above-mentioned embodiment, In the range which does not deviate from the summary of this invention, various improvement and change are possible.

The following are the additional claims of the present invention.
[1] A transport unit that transports a recording medium;
An ink head having a plurality of nozzles for discharging ink to the recording medium conveyed by the conveyance unit, and having first and second ink introduction units communicating with the nozzles;
A first ink reservoir connected to the first ink inlet by a first ink path;
A second ink reservoir connected to the second ink introduction part by a second ink path;
By supplying air into the first and second ink reservoirs and sucking air in the first and second ink reservoirs, the first and second ink reservoirs are pressurized and depressurized. Pressurizing and depressurizing means;
A controller that controls the transport unit, the ink head, and the pressure-increasing / decreasing means,
The pressurizing / depressurizing unit is configured to cause the controller to pressurize the first ink reservoir and depressurize the second ink reservoir, and to decompress the first ink reservoir and the first ink reservoir. And the second operation of pressurizing the inside of the two ink reservoirs alternately to change the direction of the ink flowing to the ink head from the direction of flowing from the first ink introducing unit to the second ink introducing unit. In the ink jet printer that can be switched between the direction of flow from the second ink introduction unit to the first ink introduction unit,
The control unit waits for either the conveyance of the recording medium by the conveyance unit or the ink ejection of the ink head when the direction of ink flow is reversed by the pressurizing and depressurizing unit. Inkjet printer.

  DESCRIPTION OF SYMBOLS 1 ... Inkjet printer, 2 ... Recording medium, 3 ... Supply part, 4 ... Conveyance part, 5 ... Image recording part, 6 ... Cleaning part, 7 ... Discharge part, 8 ... Control part, 20 ... Ink path, 21 ... Line head , 30 ... heating unit, 31 ... first ink path, 32 ... second ink path, 33 ... air path, 34 ... pump, 35 ... air path, 36 ... air path, 37 ... pump, 38 ... air path 40 ... Cooling unit, 50, 51 ... Ink tank, 52 ... Tank lifting / lowering unit, 60 ... Ink cartridge, 70 ... Float, 71 ... Liquid level sensor, 72, 73 ... Pressure sensor, 74 ... Liquid level sensor, 100 ... Ink Head, 101 ... Nozzle plate, 101a ... Nozzle surface, 101b ... Nozzle, 102 ... Frame, 103 ... Base, 104 ... Piezoelectric element, 104a ... Channel, 105, 106 ... Channel member, 105a 105b ... passage, 106a ... protrusion, 106b ... connection channel, 107 ... ink port, 114 ... temperature sensor.

Claims (9)

A transport unit for transporting the recording medium;
An ink head for recording an image by ejecting ink onto the recording medium conveyed by the conveyance unit;
A first ink reservoir connected to the ink head by a first ink path;
A second ink reservoir connected to the ink head by a second ink path;
Pressurizing and depressurizing means for switching the direction of ink flow between the first and second ink reservoirs via the ink head by pressurizing and depressurizing the first and second ink reservoirs;
A controller that controls the transport unit, the ink head, and the pressure-increasing / decreasing means,
An ink jet printer that controls the control unit so that a timing at which the direction of the ink flowing to the ink head is switched by the pressurizing / depressurizing unit and a timing at which the recording medium is conveyed by the conveying unit are different.   2. The ink jet printer according to claim 1, wherein the control unit controls the timing at which the recording medium is conveyed with respect to the timing at which the direction of the ink flowing through the ink head is switched.   2. The ink jet printer according to claim 1, wherein the control unit controls the timing at which the direction of the ink flowing through the ink head is switched with respect to the timing at which the recording medium is conveyed. The transport unit includes a medium position detection unit that detects a front end of the transported recording medium,
4. The ink jet printer according to claim 1, wherein the timing for conveying the recording medium is detected by the medium position detecting means.   5. The ink jet printer according to claim 4, wherein the control unit controls ink ejection timing of the ink head based on information detected by the medium position detecting means.   4. The ink jet printer according to claim 3, wherein the control unit changes a cycle for switching the direction of the ink flowing through the ink head according to the length of the recording medium in the transport direction. An ink head for recording an image by ejecting ink onto a recording medium;
A first ink reservoir connected to the ink head by a first ink path;
A second ink reservoir connected to the ink head by a second ink path,
Image recording of an ink jet printer that records images on a plurality of recording media conveyed at predetermined time intervals while switching the direction of ink flow between the first and second ink reservoirs via the ink head In the method
An image recording method, wherein the direction of ink flowing through the ink head is switched during the predetermined time interval.   The image recording method according to claim 7, wherein the direction of the ink flowing through the ink head during the predetermined time interval is switched by controlling the predetermined time interval.   The image recording method according to claim 7, wherein the direction of the ink flowing through the ink head during the predetermined time interval is switched by controlling the switching of the direction of the ink flowing through the ink head.

Images