JP2015120280A - Ink jet recording device and pressure regulation device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ink jet recording device including an ink circulation type ink jet head.SOLUTION: An ink jet recording device includes: an ink jet head including an ink supply port which communicates with an ink pressure chamber and supplies an ink and an ink discharge port which communicates with the ink pressure chamber and discharges the ink that is not discharged from a nozzle; a gas chamber 350 containing a gas contacting with the ink transferred from the ink discharge port; a gas chamber 360 containing a gas contacting with the ink supplied to the ink supply port; and a pressure regulation part which regulates pressures of the gas chambers. The ink jet recording device makes prints while circulating the ink.

Description

Embodiments described herein relate generally to a pressure adjusting device that adjusts the pressure in a gas chamber, and an ink jet recording apparatus that includes a device that adjusts the pressure of an ink circulation type ink jet head.

An ink jet recording apparatus having an ink circulation type ink jet head circulates ink without staying in the vicinity of the nozzles. For this reason, it is possible to prevent the deterioration of the ink and the settling of the color material, and the ink ejection stability can be improved.

The ink circulation type inkjet head receives ink through a supply pipe that supplies ink from the ink tank, and returns the ink to the ink tank through a reflux pipe that discharges ink that has not been ejected from the nozzles in the head. The ink tank is an element that stores ink distributed to the inkjet head, and is installed at a location away from the inkjet head. To supply ink from the ink tank to the inkjet head, adjust the ink supply pressure so that ink does not leak from the nozzle of the inkjet head when ink is not ejected, and eject ink from the nozzle according to the print signal for image formation When doing so, it is necessary to adjust the ink supply pressure to a level that does not hinder ink ejection.

In a conventional ink jet recording apparatus, an ink tank having a large capacity for storing ink or a pressure adjusting device for adjusting the ink supply pressure is installed at a predetermined position in the ink jet recording apparatus, and ink is placed between the ink tank and the ink jet head. A special circulation mechanism and piping to circulate was required.

As a result, it is necessary to secure a space for installing the ink tank below the ink jet head, a space for arranging the pressure adjusting device for supplying ink, and a space for drawing a pipe connecting the ink tank and the pressure adjusting device. There is a problem that it becomes a factor that leads to an increase in size.

JP 2009-160807 A

A conventional ink jet recording apparatus including an ink circulation type ink jet head has an ink circulation device including an ink jet head, a supply line, a reflux line, and an ink tank. The ink tank is disposed below the nozzle of the inkjet head, and a filter is provided between the inkjet head and the tank to form a negative pressure in the head.

In a conventional ink jet recording apparatus, an ink tank having a large capacity for storing ink or a pressure adjusting device for adjusting the ink supply pressure is installed at a predetermined position in the ink jet recording apparatus, and ink is placed between the ink tank and the ink jet head. A special circulation mechanism and piping to circulate was required.

As a result, it is necessary to secure a space for installing the ink tank below the ink jet head, a space for arranging the pressure adjusting device for supplying ink, and a space for drawing a pipe connecting the ink tank and the pressure adjusting device. There is a problem that it becomes a factor that leads to an increase in size.

In order to solve the above problems, an ink jet recording apparatus according to an embodiment includes an ink pressure chamber having a nozzle for ejecting ink, an ink supply port that communicates with the ink pressure chamber, and communicates with the ink pressure chamber. An ink jet head having an ink discharge port for discharging ink that has not been ejected from the nozzle, a first gas chamber containing a gas in contact with the ink conveyed from the ink discharge port, and ink supplied to the ink supply port A second gas chamber containing a gas in contact with the first gas passage, and a first communication passage provided with a first opening / closing means for prohibiting the opening to the atmosphere or the atmosphere, and a second communication passage communicating with the first gas chamber. A third gas chamber having a second opening / closing means for opening and closing the two communicating passages, a fourth gas chamber communicating with the third gas chamber and having a variable volume, and a third opening / closing hand for opening and closing the passages The provided has a third communication passage for communicating said fourth gas chamber and the second gas chamber, and the fourth communication passage in communication with the fourth gas chamber and the third gas chamber, the.

1 is a front view schematically showing an ink jet recording apparatus according to an embodiment. 1 is a plan view schematically showing an ink jet recording apparatus according to an embodiment. It is sectional drawing of the nozzle vicinity of a circulation type inkjet head. It is sectional drawing showing the flow of the ink of a circulation type inkjet head. It is a perspective view of the ink circulation device according to the embodiment. It is the perspective view seen from the other surface of the ink circulation apparatus which concerns on embodiment. It is sectional drawing which shows the internal structure of the ink circulation apparatus which concerns on embodiment, and an inkjet head. It is a control part block diagram which controls an inkjet recording device. It is a figure which shows the structure of 1st Embodiment of a pressure adjustment part. It is a figure explaining operation | movement of 1st Embodiment of a pressure adjustment part. It is a figure explaining operation | movement of 1st Embodiment of a pressure adjustment part. It is a figure explaining operation | movement of 1st Embodiment of a pressure adjustment part. It is a figure explaining operation | movement of 1st Embodiment of a pressure adjustment part. It is a figure explaining operation | movement of 2nd Embodiment of a pressure adjustment part.

Hereinafter, embodiments will be described with reference to the drawings. In the drawings, like numerals indicate like or similar features.

(First embodiment)
FIG. 1 is a front view of an example of an inkjet recording apparatus 1.

Ink jet recording units 4 (a) to (e) composed of the ink jet head 2 and the ink circulation device 3 are arranged on the carriage 100 in parallel, in the present embodiment, five in number. As will be described later, the ink-jet head 2 contains ink I (see FIG. 3), and ejects ink I from nozzles 51 provided on the nozzle plate 52 in accordance with image forming signals. As will be described later, the ink circulation device 3 supplies the ink I to the inkjet head 2, collects the ink I remaining without being ejected from the nozzles 51, and supplies the recovered ink to the inkjet head 2 again to supply the ink. Circulate. The ink jet head recording unit 4 (a) has an ink jet head 2 that ejects ink I downward in the direction of gravity, and an ink circulation device 3 on the top thereof. The inkjet head recording units 4 (b) to 4 (e) each have the same configuration as the inkjet recording unit 4 (a).

The inkjet recording unit 4 (a) discharges cyan ink, 4 (b) discharges magenta ink, 4 (c) discharges yellow ink, and 4 (d) discharges black ink. The ink jet recording unit 4 (e) discharges white ink. The ink jet recording unit 4 (e) ejects transparent glossy ink, special ink that develops color when irradiated with infrared rays or ultraviolet rays, in addition to white ink. A carriage 100 on which the ink jet recording units 4 (a) to 4 (e) are mounted is fixed to a conveyance belt 101, and the conveyance belt 101 is connected to a motor 102. By rotating the motor 102 forward or backward, the carriage 100 reciprocates in the direction of arrow A. The ink jet head recording units 4 (a) to 4 (e) shown in FIG. 1 eject ink in the direction of gravity (arrow C direction).

The table 103 is a sealed container having a small-diameter hole 110 on the upper surface, and the recording medium S mounted on the upper surface is fixed by applying a negative pressure to the inside of the container with a pump 104. The recording medium S is paper, resin or metal film, plate material, or the like. The table 103 is mounted on the slide rail 105 and reciprocates in the direction of arrow B in FIG. The inkjet head 2 has a nozzle plate 52 on which a plurality of nozzles 51 (see FIG. 3) for ejecting ink I are formed, and the distance h between the nozzle plate 52 and the recording medium S is constant while the inkjet head 2 reciprocates. Is maintained. In the inkjet head 2, 300 nozzles 51 are arranged in the longitudinal direction. The inkjet recording apparatus 1 forms an image while reciprocating the inkjet recording units 4 (a) to 4 (b) so as to be orthogonal to the conveyance direction of the recording medium S. That is, the longitudinal direction in which the nozzles are arranged is the same as the conveyance direction of the recording medium S, and the inkjet recording apparatus 1 forms an image on the recording medium S with a width of 300 nozzles.

A maintenance unit 310 is arranged at a position outside the moving range of the table 103 in the scanning range in the A direction of the ink jet recording units 4 (a) to 4 (e). The position where the inkjet head 2 faces the maintenance unit 310 is the standby position P of the inkjet head 2. The maintenance unit 310 is a case that is open at the top, and is provided to be movable up and down (in the directions of arrows C and D in FIG. 1). When the carriage 100 is moving in the direction of arrow A for image formation, the maintenance unit 310 moves downward C and waits, and when the image forming operation is completed, it moves upward D. When the image forming operation is completed, the inkjet head 2 returns to the standby position P, the maintenance unit 310 moves upward D, and covers the nozzle plate 52 of the inkjet head 2. The maintenance unit 310 prevents (cap function) ink evaporation and dust and paper dust from adhering to the nozzle plate 52.

The maintenance unit 310 includes a rubber blade 120 that removes ink, dust, paper dust, and the like attached to the nozzle plate 52 of the inkjet head 2. When the carriage 100 is moved in the direction of arrow A for image formation, the maintenance unit 310 is moved downward, and the blade 120 is spaced downward C from the nozzle plate 52. When ink, dust, and paper dust adhering to the nozzle plate 52 are removed, the nozzle 120 moves upward D, and the blade 120 contacts the nozzle plate 52. The maintenance unit 310 includes a mechanism for moving the blade 120 in the B direction. The blade 120 can wipe the surface of the nozzle plate 52 and remove ink, dust, and paper dust (wipe function).

The maintenance unit 310 includes a waste ink receiver 130. When performing the maintenance operation, the ink that has been deteriorated in the vicinity of the nozzles can be discarded (spit function) in the waste ink receiving unit 130 by forcibly ejecting the ink from the nozzles 51. The waste ink receiving unit 130 stores waste ink generated by wiping with the blade 120 and waste ink generated by the spit operation.

FIG. 2 is a plan view of an example of the ink jet recording apparatus 1.

The carriage 100 on which the ink jet recording units 4 (a) to 4 (e) are mounted reciprocates in the A direction along the two rails 140 by the movement of the conveyance belt 101. The table 103 on which the recording medium S is mounted reciprocates in the B direction. In accordance with an image signal for printing by the ink jet recording apparatus 1, the carriage 100 mounted with the ink jet recording units 4 (a) to 4 (e) and the table 103 on which the recording medium S is placed are moved back and forth from the nozzle 51. An image can be formed on the entire surface of the recording medium S by ejecting ink. This is a so-called serial type ink jet recording apparatus.

The ink cartridge 106 (a) is filled with cyan ink and communicates with the ink circulation device 3 of the ink jet recording unit 4 (a) via the tube 107. The ink cartridge 106 (b) is filled with magenta ink and communicates with the ink circulation device 3 of the ink jet recording unit 4 (b) via the tube 107. Similarly, the ink cartridge 106 (c) is filled with yellow ink and communicates with the ink circulation device 3 of the inkjet recording unit 4 (c). The ink cartridge 106 (d) is filled with black ink and communicates with the ink circulation device 3 of the inkjet recording unit 4 (d). The ink cartridge 106 (e) is filled with white ink and communicates with the ink circulation device 3 of the inkjet recording unit 4 (e).

Each of the ink jet recording units 4 (a) to 4 (e) has a configuration in which the ink circulation device 3 is stacked above the ink jet head 2. By providing the ink circulation device 3 above the inkjet head 2, the interval in the direction in which the inkjet recording units 4 (a) to 4 (e) are arranged on the carriage 100 is narrowed, and the carriage 100 in the transport direction (A direction) is reduced. The width can be shortened. The carriage 100 is conveyed in the A direction by a distance obtained by adding at least twice the width of the carriage 100 to the maximum width of the recording medium S. Therefore, the narrower the carriage 100, the shorter the conveyance distance and the higher the printing speed, and the smaller the apparatus.

  The inkjet head 2 applied to the inkjet recording apparatus 1 according to the embodiment will be described.

3A and 3B are cross-sectional views of the portion of the inkjet head 2 that ejects ink I. FIG. The inkjet head 2 forms a nozzle branch portion 53 on the upper surface side of a nozzle plate 52 having nozzles 51 that eject ink. The nozzle branching portion 53 is a portion that branches into ink that ejects ink flowing in the direction of arrow E in FIG. 3 from the nozzle 51 and ink that flows through the inkjet head 2 as it is and returns to the ink circulation device 3. The inkjet head 2 has an actuator 54 on the surface facing the nozzle 51. The actuator 54 is a unimorph piezoelectric diaphragm in which a piezoelectric ceramic 55 and a diaphragm 56 are laminated. PZT (lead zirconate titanate) was used as the piezoelectric ceramic material. Gold electrodes are formed on the upper and lower surfaces of PZT, and the piezoelectric ceramic 55 is formed by polarization treatment. Thereafter, the piezoelectric ceramic 55 was joined to the diaphragm 56 made of silicon nitride to form the actuator 54. A meniscus 290 that is an interface between ink and air is formed in the nozzle 51 by the surface tension of the ink.

FIG. 3A shows a state where the electric field is not applied to the piezoelectric ceramic 55 and the actuator 54 is not deformed. FIG. 3B shows how the ink droplet ID is ejected by deforming the actuator 54. By applying an electric field to the piezoelectric ceramic 55 to deform the actuator 54, the ink I in the nozzle branching portion 53 becomes an ink droplet ID and is ejected from the nozzle 51.

With reference to FIG. 4, the flow of ink inside the inkjet head 2 having the portion for ejecting the ink described in FIG. 3 will be described.

The inkjet head 2 includes a nozzle plate 52, a substrate 60 having the actuator 54 shown in FIG. 3, a manifold 61, an ink supply port 160 through which ink flows, and an ink discharge port 170 through which ink flows from the inkjet head 2 to the ink circulation device 3. , Is composed of.

The nozzle plate 52 has a first nozzle row having a plurality of nozzles 51 (a) arranged in the back direction from the front side of the paper, and a second nozzle row having a plurality of nozzles 51 (b) arranged in the back direction from the front side of the paper. doing. As described above, the ink I is ejected through the nozzles 51 (51 (a) and 51 (b)). In other words, the inkjet head 2 is long in the back direction from the front side of the paper, and the nozzles 51 (a) and 51 (b) are arranged in the longitudinal direction. A plurality of nozzles 51 (a) and 51 (b) are arranged in the B direction (see FIG. 5), and are arranged in a direction orthogonal to the moving direction of the carriage 100.

The substrate 60 has a flow path 180 through which ink passes. The nozzle plate 52 is bonded to the substrate 60 so as to form the flow path 180. An actuator 54 that generates a pressure for ejecting ink faces the flow path 180 and is provided corresponding to each nozzle 51. A boundary wall 190 is provided between the adjacent nozzles 51 so that the pressure generated in the ink in the flow path 180 by the actuator 54 is concentrated on the nozzles 51. A flow path 180 surrounded by the nozzle plate 52, the actuator 54, and the boundary wall 190 becomes the ink pressure chamber 150. A plurality of ink pressures 150 are provided corresponding to the nozzles 51 (a) 51 (b) of the first nozzle row and the second nozzle row. Each of the first nozzle row and the second nozzle row has 300 nozzles. The ink I flows into the ink pressure chamber 150 from one end, passes through the ink branching portion 53, and flows out from the other end. A part of the ink is ejected from the nozzle 51 at the ink branching portion 53 in the ink pressure chamber 150 and the rest flows out from the other end.

A plurality of ink pressure chambers 150 formed corresponding to each nozzle 51 (a) in the first nozzle row and a plurality of ink pressure chambers 150 formed corresponding to each nozzle 51 (b) in the second nozzle row; The flow path 180 between them is a common ink chamber 58. The common ink supply chamber 58 is connected to one inlet of the ink pressure chamber 150 and supplies ink to all the ink pressure chambers 150.

The ink flowing out from the other end side of the plurality of ink pressure chambers 150 corresponding to the first nozzle row and the plurality of ink pressure chambers 150 corresponding to the second nozzle row to the common ink chamber 59 connected to the first second nozzle row. Inflow. The common ink chamber 59 is a part of the flow path 180 provided in the substrate 60.

The manifold 61 is connected to the substrate 60 and supplies ink to the flow path 180. The manifold 61 has an ink supply port 160 through which ink flows in the direction of arrow F, and an ink distribution passage 62 that communicates from the ink supply port to the common ink supply chamber 58. An in-head temperature sensor (upstream) 280 is attached to the ink distribution passage 62 in order to detect the temperature of ink supplied to the inkjet head 2. The manifold 61 has an ink discharge port 170 that discharges ink in the direction of arrow G, and an ink circulation passage 63 that communicates from the two common ink chambers 59 to the ink discharge port 170. An in-head temperature sensor (downstream) 281 is attached to the ink circulation path 63 in order to detect the temperature of ink discharged from the inkjet head 2. Ink temperature sensors (upstream) 280 and (downstream) 281 detect the temperature of ink supplied to or discharged from the inkjet head 2 and take into account changes in ink viscosity due to ink temperature in the inkjet head 2 Thus, the ink circulation device 3 is controlled.

Ink I moves through the inkjet head 2 in the order of the ink supply port 160, the ink distribution passage 62, the common ink supply chamber 58, the ink pressure chamber 150, the common ink chamber 59, the ink circulation passage 63, and the ink discharge port 170. A part of the ink I is ejected from the nozzle 51 according to the image signal, and the remaining ink I moves and circulates from the ink discharge port 170 to the ink circulation device 3.

FIG. 5 shows an inkjet recording unit 4 in which the ink circulation device 3 is disposed above the inkjet head 2 and the ink circulation device 3 and the inkjet head 2 are integrated. FIG. 6 is a diagram of the ink jet recording unit 4 viewed from a direction different from that in FIG. FIG. 7 is a view of the inside of the inkjet head 2 and the ink circulation device 3 as seen from the front. The ink circulation device 3 will be described with reference to these.

The ink circulation device 3 is used to maintain the ink pressure in the ink casing 200, the ink supply pipe 208 that supplies ink to the inkjet head 2, the ink return pipe 209 that returns ink from the inkjet head 2, and the ink pressure in the nozzles 51 of the inkjet head 2. Are provided with a pressure adjusting unit 203 for adjusting the pressure inside the ink casing 200. The ink circulation device 3 feeds ink downward (arrow C, which is the direction of gravity) through the ink supply pipe 208, and the inkjet head 2 ejects ink further downward.

An ink supply pump 202 is provided on the outer wall surface of the ink casing 200 to supply the ink casing 200 with the amount of ink consumed by printing or maintenance operations. A supply-side ink chamber 210 and a recovery-side ink chamber 211 are provided so that the ink I can be stored inside the ink casing 200, a first plate 300 that covers the recovery-side ink chamber 211, and a second that covers the supply-side ink chamber 210. It is sealed with a plate 301. The ink supply pump 202 supplies ink to the recovery side ink chamber 211.

An ink amount measurement sensor 205 </ b> A that measures the amount of ink in the ink casing 200 is attached to the first plate 300 that seals the ink casing 200. An ink amount measurement sensor 205 </ b> B is attached to the second plate 301. The ink amount measurement sensor 205C has a configuration in which a piezoelectric diaphragm is attached to the ink casing 200, and vibrates the ink in the ink casing 200 by vibrating the piezoelectric diaphragm with an alternating voltage. Ink vibrations transmitted through the ink casing 200 by the ink amount measurement sensor 205C are detected by the ink amount measurement sensors 205A and 205B, and the ink amount is measured.

In order to adjust the ink viscosity in the ink casing 200, a heater 207 for heating the ink is provided outside the ink casing 200. The heater 207 is attached to the ink casing 200 with an adhesive having high thermal conductivity. An ink temperature sensor 282 is attached in the vicinity of the heater 207 of the ink casing 200. The ink temperature sensor 282 and the heater 207 are connected to a control board 500 to be described later, and the heater 207 is controlled so that a desired ink viscosity is obtained during printing.

The ink supply pump 202 shown in FIG. 5 is attached to the outer wall of the ink circulation device 3 of the ink jet recording unit. A tube 107 for feeding ink from the ink cartridge 106 to the ink circulation device 3 is connected to the ink supply port 221. The ink supply port 221 is an ink inflow port through which ink flows into the ink supply pump 202. The ink supply pump 202 supplies ink from the ink supply port 221 to the collection-side ink chamber 211 in the ink circulation device 3.

The ink supply pump 202 is a piezoelectric pump. The ink supply pump 202 conveys ink by periodically changing the volume (pump chamber 240) in the pump by bending the piezoelectric vibration plate in which the piezoelectric element and the metal plate are bonded, and the ink is supplied by two check valves. The conveyance direction is set to one direction. One check valve 242 of the ink supply pump 202 is provided between the ink supply port 221 and the pump chamber 240, and the other check valve 243 is provided between the pump chamber 240 and the ink outlet 241. . When the piezoelectric diaphragm is deflected and the pump chamber 240 is expanded, the check valve 242 is opened, ink flows into the pump chamber 240, and the check valve 243 is closed. When the piezoelectric diaphragm is deflected in the reverse direction and the pump chamber 240 contracts, the check valve 242 is closed and the check valve 243 is opened, so that ink flows out of the pump chamber 240. This is repeated to feed ink.

The ink cartridge 106 that supplies ink to the collection-side ink chamber 211 is disposed relatively below the gravity direction (C direction) from the ink circulation device 3. By disposing the cartridge 106 below, the water head pressure of the ink in the cartridge 106 is kept lower than the set pressure of the recovery-side ink chamber 211. With this configuration, the ink I is supplied to the recovery-side ink chamber 211 only when the ink supply pump 202 is driven.

The ink circulation pump 201 sucks the ink I from the suction hole 212 of the recovery side ink chamber 211 and causes the ink I to flow into the supply side ink chamber 210 from the discharge hole 213. The supply-side ink chamber 210 that is sealed increases in internal pressure as the amount of ink increases, and the ink I flows into the inkjet head 2 through the ink supply pipe 208.

As shown in FIG. 6, the ink circulation pump 201 is provided on a surface opposite to the surface of the first plate 300 that covers the recovery-side ink chamber 211 and the second plate 301 that covers the supply-side ink chamber 210. A control board 500 to be described later is held by the inkjet recording unit 4 so as to cover the ink circulation pump 201. The control board 500 controls the ink circulation pump 201, the ink supply pump, the pressure adjustment unit 203, and the like.

The ink casing 200 of the ink circulation device 3 includes a supply-side ink chamber 210 that supplies ink to the inkjet head 2 via an ink supply tube 208 and a recovery-side ink chamber that returns ink from the inkjet head 2 via an ink return tube 209. 211. The ink casing 200 is made of aluminum. The ink casing 200 formed of aluminum has a vacant chamber serving as a supply-side ink chamber 210, and a resin plate 300 is fixed to the frame portion forming the vacancy of the supply-side ink chamber 210 with an adhesive, thereby supplying the supply-side ink chamber. 210 is formed. Similarly, the resin plate 301 is fixed to the frame portion of the recovery side ink chamber 211 with an adhesive so as to form the recovery side ink chamber 211 of the ink casing 200. The material of the resin plates 300 and 301 is polyimide resin.

In the ink casing 200, the recovery-side ink chamber 211 and the supply-side ink chamber 210 are integrally provided via a common wall 245. The arrangement direction of the collection-side ink chamber 211 and the supply-side ink chamber 210 is the same as the nozzle arrangement direction of the inkjet head 2 (the longitudinal direction (B direction) of the inkjet head 2). That is, the arrangement direction of the collection-side ink chamber 211 and the supply-side ink chamber 210 provided above the inkjet head 2 is arranged in a direction substantially orthogonal to the scanning direction of the carriage 100.

The upper part of the ink level b in the recovery-side ink chamber 211 is a first air chamber 350 (first gas chamber). The first air chamber 350 communicates with the second air chamber 352 located above the first air chamber 350 through the opening 351. The second air chamber 352 is provided with a communication hole 223 that is connected to the detection unit of the pressure sensor 204. The pressure sensor 204 communicates with the first air chamber 350 of the recovery-side ink chamber 211 and detects the atmospheric pressure in the first air chamber 350.

The upper part of the ink liquid level a of the supply side ink chamber 210 is a third air chamber 360 (second gas chamber). The ink circulation device 3 has two concave portions 353 and 363, and a convex portion 370 of a pressure adjusting portion 203 (see FIG. 9) described later is engaged with the concave portion 363 and the convex portion 372 is engaged with the concave portion 353. ing. The third air chamber 360 communicates with the fourth air chamber 362 through an air passage provided in the convex portion 370 and an opening 361. The fourth air chamber 362 is provided with a communication hole 222 that is connected to the detection unit of the pressure sensor 204. The pressure sensor 204 communicates with the third air chamber 360 of the supply side ink chamber 211 and detects the atmospheric pressure in the third air chamber 360.

The pressure sensor 204 has two pressure detection ports with one chip, and measures the pressure in the two air chambers of the first air chamber 350 and the third air chamber 360. The pressure sensor 204 outputs the air pressure in the upper part of the supply-side ink chamber 210 and the upper part of the recovery-side ink chamber 211 as an electrical signal, and is connected to a control board 500 (see FIG. 8) described later. In the first air chamber 350 and the third air chamber 360, nitrogen or an inert gas can be put in place of air.

The ink casing 200 includes a suction hole 212 for sucking ink from the collection-side ink chamber 211 and a discharge hole 213 for feeding ink to the supply-side ink chamber 210. The collection-side ink chamber 211 and the supply-side ink chamber 210 are adjacent to each other via a common wall 245. The ink circulation pump 201 is provided across the adjacent collection-side ink chamber 211 and supply-side ink chamber 210, sucks ink from the suction holes 212, and sends the ink to the supply-side ink chamber 210 through the discharge holes 213. .

The ink circulation pump 201 is a piezoelectric pump similar to the ink supply pump 202 described above. The ink circulation pump 201 feeds ink by periodically changing the volume (pump chamber) in the pump by bending the piezoelectric vibration plate in which the piezoelectric element and the metal plate are bonded, and the ink is supplied by two check valves. The liquid feeding direction is set to one direction. One check valve (A) of the ink circulation pump 201 is provided between the suction hole 212 and the pump chamber, and the other check valve (B) is provided between the pump chamber and the discharge hole 213. . When ink flows into the pump chamber, the check valve (A) is opened and the check valve (B) is closed. When ink flows out from the pump chamber, the check valve (A) is closed and the check valve (B) is opened. By repeating this, ink is fed from the recovery side ink chamber to the supply side ink chamber.

When the ink circulation pump 201 having the above-described configuration is operated, ink is sucked from the recovery-side ink chamber 211 through the suction hole 212 and is transported to the supply-side ink chamber 210 through the ink circulation pump 201 and the discharge hole 213. In the supply-side ink chamber 210 that is sealed, the internal pressure increases as the amount of ink increases, and the ink flows into the inkjet head 2 through the ink supply pipe 208.

FIG. 8 is a block diagram of a control board 500 that controls the operation of the inkjet recording apparatus 1. Connected to the control board 500 are a power source 550, a display device 560 for displaying the status of the ink jet recording apparatus 1, and a keyboard 570 as an input device. The control board 500 includes a microcomputer 510 that controls the operation, a memory 520 that stores a program, and an AD conversion unit 530 that captures output voltages of the pressure sensor 204 and the heater temperature sensors 280, 281, and 282. Further, the control board 500 includes a drive circuit 540, and the inkjet recording unit 4, the carriage motor 102 that moves the inkjet recording unit 4 relative to the recording medium S, the pressure adjustment motors 254 and 255, the slide rail 105, and the pump 104. 201, 202, heater 207, and the like are operated.

The pressure adjustment unit 203 will be described. A meniscus 290 is formed in the nozzle 51 from which the ink of the inkjet head 2 is discharged. When ink is ejected from the nozzle 51, the meniscus 290, which is the interface between the ink and air, is broken and ejected as ink droplets. If the pressure applied to the meniscus 290 is higher than the air pressure (positive pressure), the ink leaks from the nozzle 51. If the pressure applied to the meniscus 290 is lower than the air pressure (negative pressure), the ink maintains the meniscus 290 and remains in the nozzle 51. Therefore, when ink is not discharged, the ink pressure in the ink pressure chamber 150 is adjusted to −0.5 to −4.0 kPa, and the meniscus 290 is maintained. Since the nozzle 51 is arranged so that the ink is ejected downward in the direction of gravity, if it is larger than this range (positive pressure side), the ink leaks from the nozzle due to slight vibration or the like. On the other hand, if it is smaller (negative pressure side), air is sucked from the nozzle, resulting in ejection failure. Of course, the inside of the ink pressure chamber 150 is normally kept at a negative pressure, and when the actuator 54 is operated, the ink in the ink pressure chamber becomes a positive pressure, and the ink is ejected from the nozzle 51.

The pressure adjusting unit 203 is for maintaining the pressure of the meniscus 290 of the inkjet head 2 in the above range.

FIG. 9 shows the pressure adjustment unit 203. The pressure adjustment unit 203 includes a pressure adjustment chamber 261 and a pressure adjustment chamber 262. FIG. 9A is a top view and a side view of the pressure adjusting unit 203. FIG. 9B is an exploded view showing the inside of the pressure adjusting chamber 261. FIGS. 10A, 10 </ b> B, and 10 </ b> C illustrate the operation of the pressure adjusting unit 203 depending on the positions of the pistons 252 and 253.

The pressure adjustment chamber 261 includes a cylinder 250 communicating with the supply-side ink chamber 210, a piston 252 housed in the cylinder 250, and a pulse that moves the piston 252 up and down (H direction) to change the volume of the cylinder 250. The motor 254 is configured. The volume (fourth gas chamber 270) surrounded by the cylinder 250 and the piston 252 is varied to change the pressure. A male screw is fixed to the rotating shaft of the pulse motor 254, and a female screw is formed at a portion where the piston 252 is fitted. The piston 252 is formed in an oval shape with a center portion shaft 316 having a flat surface portion, and is slidably fitted into an oval shaft hole 318 having a flat surface portion provided in the cylinder 250. Is preventing. The piston 252 slides up and down in the cylinder 250 by the rotation of the pulse motor 254. A rubber seal 314 is attached to the piston 252 to keep the inside of the cylinder 250 airtight. The cylinder 250 has a communication conduit 256 that communicates with the supply-side ink chamber 210. Inside the communication pipe 256, a spring and an opening / closing member 257 that closes a communication hole that connects the cylinder 250 and the air chamber 360 in the supply-side ink chamber 210 by urging the spring and opens when urged by the piston 252. Is attached.

The pressure adjustment chamber 262 includes a cylinder 251 communicating with the recovery-side ink chamber 211, a piston 253 housed inside the cylinder 251, and a pulse for moving the piston 253 up and down (H direction) to change the volume of the cylinder 251. The motor 255 is configured. The volume (third gas chamber 272) surrounded by the cylinder 251 and the piston 253 is varied to change the pressure. The cylinder 251, piston 253, and pulse motor 255 have the same configuration as the pressure adjustment chamber 261 described above. The cylinder 251 has a communication conduit 258 that communicates with the recovery-side ink chamber 211 and a communication conduit 259 that communicates the inside of the cylinder 251 with the atmosphere. An open / close member 263 (first open / close means) that closes the spring and the communication hole with the atmosphere by the biasing of the spring and opens when biased by the piston 253 is attached to the inside of the communication conduit 259. The pressure adjustment chamber 262 is configured such that when the piston 253 is at the lower limit of the cylinder 251, the piston 253 (second opening / closing means) closes the upper end 306 of the communication line 258 between the recovery-side ink chamber 211 and the cylinder 251. ing. Therefore, in this embodiment, the piston 253 functions as a function for opening and closing the first opening / closing means, and further as a second opening / closing means for opening and closing the communication pipe 258.

Further, a communication path 260 is provided between the cylinder 250 of the pressure adjustment chamber 261 and the cylinder 251 of the pressure adjustment chamber 262 so that they are always in communication. The piston 252 in the cylinder 250 of the pressure adjustment chamber 261 and the piston 253 in the cylinder 251 of the pressure adjustment chamber 262 are respectively moved up and down (in the H direction) to change the volume of air in the cylinders 250 and 251, The pressure inside the ink casing 200 is adjusted by controlling the communication or blockage with the ink casing 200.

The movement range and position of the piston will be described based on the configuration of the pressure adjusting unit 203 described above. As shown in FIG. 10, the home position (piston reference position) of the piston 253, the atmospheric release position, and the lower limit position in the cylinder 251 will be described. FIGS. 10A, 10 </ b> B, and 10 </ b> C show a state where the position of the piston 252 in the pressure adjustment chamber 261 is the same and the piston 253 in the pressure adjustment chamber 262 is changed. F indicates a filter provided at the air intake.

FIG. 10A shows the home position (x1) of the piston 253. In the home position, the piston 253 is in a position where the tip 305 of the opening / closing member 263 provided in the communication pipe 259 that communicates the third gas chamber 272 with the atmosphere does not contact. Since the tip 305 of the opening / closing member 263 is not pushed, the opening / closing member 263 keeps the communication pipe line 259 closed. Further, the leading end 306 of the communication pipe 258 that communicates the third gas chamber 272 and the air chamber 350 in the recovery-side ink chamber 211 enters the third gas chamber 272. The tip 305 of the opening / closing member 263 and the tip 306 of the communication pipe 258 are separated by a distance G in the moving direction of the piston 253. When the piston 253 is at the home position, the piston 253 does not block the opening at the tip 306 of the communication conduit 258. Pressure adjustment is performed in this state.

FIG. 10B shows the position of the piston 253 that opens the third gas chamber 272 to the atmosphere. In the atmosphere release position (x2), the piston 253 biases the tip 305 of the opening / closing member 263 provided in the communication pipe 259 that communicates the third gas chamber 272 with the atmosphere. When the tip 305 is energized, the opening / closing member 263 is opened and the third gas chamber 272 is opened to the atmosphere. Since the position of the piston 253 is between the distal end 305 of the opening / closing member 263 and the distal end 306 of the communication conduit 258, the opening of the distal end 306 of the communication conduit 258 is kept open. As a result, the air chamber 350 in the recovery-side ink chamber 211 is opened to the atmosphere through the opening / closing member 263 and the third gas chamber 272, as indicated by the dashed arrow.

FIG. 10C shows the lower limit position (x3) of the piston 253. At the lower limit position, the piston 253 biases the tip 305 of the opening / closing member 263 to open the opening / closing member 263, and further closes the opening of the tip 306 of the communication conduit 258. At this time, the gas chamber 350 of the recovery-side ink chamber 211 is sealed.

As shown in FIG. 11, when the piston 252 takes the following position in the cylinder 250, the pressure of the ink recovery chamber side air chamber 350 can be adjusted and the air flow path in the cylinder 252 can be switched. FIGS. 11A, 11 </ b> B, and 11 </ b> C show a state where the position of the piston 253 in the pressure adjustment chamber 262 is the same and the piston 250 in the pressure adjustment chamber 261 is changed. FIG. 11A shows the adjustment upper limit position (x4). The upper limit adjustment position of the piston 252 in the pressure adjustment chamber 261 is a position that does not reach the ceiling of the cylinder 250 in the upward direction with respect to the home position. FIG. 11B shows the adjustment lower limit position (x5). The adjustment lower limit position of the piston 252 in the pressure adjustment chamber 261 is a position that does not reach the opening / closing member 257 in the downward direction with respect to the home position. The pressure can be adjusted by moving the piston 252 between the adjustment upper limit position and the adjustment lower limit position to change the volume of the fourth gas chamber 270 in the cylinder 252. FIG. 11C shows the communication position (x6). The communication position indicates a position where the piston 252 pushes down the tip 309 of the opening / closing member 257 to open the opening / closing member 257. When the piston 252 reaches the communication position, the opening / closing member 257 is opened, and air between the cylinder 250 and the air chamber 360 on the ink supply side flows.

The pressure adjustment operation will be described. When the power is turned on, both pistons 252 and 253 move upward for a predetermined time. The positions of the pistons 252 and 253 at the time when the power is turned on vary depending on the position in the cylinders 250 and 251 where the pistons 252 and 253 are finished before the power is turned on. Therefore, the positions of the pistons 252 and 253 in the cylinders 250 and 251 are indefinite when the power is turned on. Since the positions of the pistons 252 and 253 are indefinite, the pistons 252 and 253 are once moved to the uppermost portions 265 and 266 (ceiling) of the cylinders 250 and 251. The time for moving the piston is the time required for the pistons 252 and 253 to collide with the ceilings 265 and 266 from the lowest position in the cylinders 250 and 251 (initial movement time). When the pistons 252 and 253 collide with the ceilings 265 and 266 during the initial movement time during which the pistons 252 and 253 are moving upward, the pulse motors 254 and 255 are driven so as to step out and stop.

Next, the pistons 252 and 253 are moved downward from the positions colliding with the ceilings 265 and 266 to a predetermined position, and the positions are stored as home positions. When the pistons 252 and 253 move in the future, the number of pulses moved is counted to recognize the vertical position.

The function of the pressure adjusting unit at the positions of the pistons 252 and 253 in FIG. The piston 253 of the pressure adjustment chamber 262 is (x2) in the atmospheric release position, and the piston 252 of the pressure adjustment chamber 261 is (x6) in the communication position. In this state, since communication is made through a path indicated by a broken-line arrow in the drawing, both the supply-side ink chamber 210 and the recovery-side ink chamber 211 are in an atmospheric release state, and the internal pressure becomes atmospheric pressure. This state is used, for example, when the empty ink casing 200 is initially filled with ink from the ink cartridge 106 at the start of use of the inkjet apparatus.

The function of the pressure adjusting unit at the positions of the pistons 252 and 253 in FIG. The piston 253 of the pressure adjusting chamber 262 is set to a position not communicating with the atmosphere, for example, a home position. As a result, the recovery-side ink chamber 211 and the pressure adjustment chamber 261 are in communication with each other through a broken-line arrow path in the drawing and are in a sealed state. In this state, the pressure inside the recovery-side ink chamber 211 is adjusted by moving the piston 252 of the pressure adjustment chamber 261 up and down in the direction of arrow H. When the piston 252 is moved upward in the range up to the adjustment upper limit position (x4), the air volume of the cylinder 250 increases and the pressure of the air chamber 350 in the recovery-side ink chamber 211 decreases. Conversely, when the piston 252 of the pressure adjustment chamber 261 is moved in the downward direction within the range not reaching the adjustment lower limit position (x6), the volume of the cylinder 250 is reduced and the pressure of the air chamber 350 in the recovery-side ink chamber 211 is reduced. To increase. The pressure in the air chamber 350 is adjusted by increasing or decreasing the pressure.

The pressure sensor 204 detects the respective pressures of the air chamber 360 in the supply-side ink chamber 210 and the air chamber 350 in the recovery-side ink chamber 211. The lengths of the ink paths from the supply-side ink chamber 210 and the recovery-side ink chamber 211 to the nozzles 51 of the inkjet head 2 are designed to be substantially the same. Since the ink path length is the same, the pressure of the nozzle 51 is obtained by adding the pressure due to the water head difference between the nozzle surface and the ink surface of both ink chambers to the average value of the pressure of the supply side ink chamber 210 and the pressure of the recovery side ink chamber 211. Become. Good ink ejection can be maintained by moving the piston 252 of the pressure adjustment chamber 261 communicated with the recovery-side ink chamber 211 up and down so that the pressure of the nozzle 51 becomes a predetermined pressure.

The function of the pressure adjusting unit at the positions of the pistons 252 and 253 in FIG. In order to maintain the negative pressure in the collection-side ink chamber 211 constant, the pistons 252 and 253 of the pressure adjustment chambers 261 and 262 are operated. The range in which the piston 252 can move in the vertical direction in order to adjust the pressure is between a position where it collides with the ceiling 265 when the piston 252 is raised and a position where it contacts the opening / closing member 257 when the piston 252 is lowered. There may be a case where a pressure change is required in the recovery-side ink chamber 211 beyond the pressure that can be varied by moving the piston 252 within a range in which the piston 252 can move in the vertical direction. Further, depending on the position of the piston 252 before starting the pressure adjustment, the pressure in the recovery-side ink chamber 211 is adjusted only by changing the pressure in the cylinder 252 by moving up and down within the range in which the piston 252 can move. Sometimes you can't. For example, when the piston 252 reaches the adjustment lower limit position (x5) shown in FIG.

In this case, the piston 253 of the pressure adjustment chamber 262 is moved to the (x3) lower limit position, the recovery-side ink chamber 211 is sealed, the opening / closing member 263 is opened, and the pressure adjustment chamber 261 is brought to atmospheric pressure. Thereafter, the piston 252 of the pressure adjustment chamber 261 is raised to the adjustment upper limit position (x4). While the piston 252 is raised to the adjustment upper limit position (x4), the cylinder 250 of the pressure adjustment chamber 261 communicates with the atmosphere through the path indicated by the broken line arrow in the figure, and the open / close member 257 is closed, so that the supply-side ink chamber 210 is Since the sealed state is maintained and the piston 253 is lowered, the collection-side ink chamber 211 is also sealed. Therefore, even if the piston 252 moves, it does not affect the pressures in the recovery-side ink chamber 211 and the supply-side ink chamber 210. Next, the piston 253 of the pressure adjusting chamber 262 is raised, and the opening / closing member 263 is closed. Thereafter, when the piston 252 of the pressure adjusting chamber 261 is lowered, the pressure in the recovery-side ink chamber can be increased. If this is repeated, the pressure in the recovery-side ink chamber 211 can be sufficiently increased even when the piston 252 having a limited movable range is used. Conversely, the absolute value of the negative pressure in the collection-side ink chamber 211 can be increased.

Thereafter, the piston 253 of the pressure adjusting chamber 262 is moved to the home position, the recovery-side ink chamber 211 in FIG. 12B is sealed, and the piston 252 of the pressure adjusting chamber 261 is moved in the adjusting direction to move to a predetermined position. Get pressure.

The function of the pressure adjusting unit at the positions of the pistons 252 and 253 in FIG. The piston 252 is in a position other than (x6), and the piston 252 is in the (x2) position. Since the pistons 252 and 253 are in these positions, the air chamber 350 in the collection-side ink chamber 211, the third gas chamber 272 in the cylinder 251 and the fourth gas chamber 270 in the cylinder 250 are opened to the atmosphere. This state is used, for example, when the zero point of the pressure sensor 204 that measures the atmospheric pressure in the first air chamber 350 is corrected to atmospheric pressure (0 in gauge pressure).

The function of the pressure adjusting unit at the positions of the pistons 252 and 253 in FIG. The piston 252 opens the opening / closing member 257, and the piston 253 closes the tip 306 of the communication pipe 258. Since the pistons 252 and 253 are in these positions, the air chamber 360 and the communication pipe 260 in the supply-side ink chamber 210 are opened to the atmosphere. This state is used, for example, when it is desired to raise the liquid level a of the supply-side ink chamber 210.

As shown in FIG. 13A, when the piston 253 is at the home position (x1), the inner surface of the piston 253 and the tip 305 of the opening / closing member 263 are separated by a distance H. When the piston 253 moves within the distance H, the air chamber 350 in the recovery-side ink chamber 211 is sealed. In this sealed state, the gas is compressed and pressure fluctuations occur in the air chamber 350. When it is necessary to reduce this pressure fluctuation, as shown in FIG. 13B, while the piston 253 is moving within the distance H, the piston 252 is moved backward by the same distance as the moving distance. . In this embodiment, the size of the cylinder 250 and the piston 252 (first size) and the size of the cylinder 251 and the piston 253 (second size) are the same, so the pistons 252 and 253 are reversed by the same distance. By moving, pressure fluctuation can be reduced. When the first size is different from the second size, the pressure fluctuation can be reduced by making the volume fluctuation caused by the movement equal.

When the ink jet recording apparatus 1 is first printed, it is necessary to fill the ink circulation device 3 and the ink jet head 2 with ink from the ink cartridge 106. That is, cyan ink is filled from the ink cartridge 106 (a) to the ink circulation device 3 and the inkjet head 2 of the inkjet recording unit 4 (a). Similarly, magenta ink, yellow ink, black ink, and white ink are filled from the ink cartridges 106 (b) to (e) to the inkjet recording units 4 (b) to 4 (e), respectively. When an initial filling operation is instructed from the keyboard of the control unit, the operation is performed in the following order.

The inkjet recording unit 4 is returned to the standby position, and the maintenance unit 310 is raised to cover the nozzle plate 52. The pressure adjustment unit 203 is in the state shown in FIG. The ink supply pump 202 is driven to feed ink from the ink cartridge 106 to the collection-side ink chamber 211 of the ink casing 200 together with the air in the tube 107. However, since the flow path resistance inside the inkjet head 2 is large, the inkjet head 2 and ink does not flow into the supply-side ink chamber 210 in a short time. When the ink amount sensor 205B in the collection-side ink chamber 211 detects that the ink has flowed into the suction hole 212, the pressure adjusting unit 203 starts adjusting the pressure in the ink casing 200, and at the same time, the ink circulation pump 201 is driven for a predetermined time. To do. The ink is sent from the recovery side ink chamber 211 to the supply side ink chamber 210 via the ink circulation pump 201. When the liquid amount detection results of the collection-side ink chamber 211 and the supply-side ink chamber 212 by the piezoelectric sensors 205A and 205B reach the suction hole 212 and the discharge hole 213 of the circulation pump 201, the ink filling is completed. When the amount of ink in the collection-side ink chamber 211 has not reached, the ink supply pump 202 is driven to feed ink from the ink cartridge 106 to the collection-side ink chamber 211 of the ink casing 200. When the ink amount sensor 205B detects that the ink has flowed into the suction hole 212, the pressure adjusting unit 203 starts adjusting the pressure in the ink casing 200, and at the same time, the ink circulation pump 201 is driven for a predetermined time. The ink is sent from the recovery side ink chamber 211 to the supply side ink chamber 210 via the ink circulation pump 201. When the liquid amount detection results of the collection-side ink chamber 211 and the supply-side ink chamber 212 by the piezoelectric sensors 205A and 205B reach the suction hole 212 and the discharge hole 213 of the circulation pump 201, the ink filling is completed. By repeating this operation, the ink amounts in the collection-side ink chamber 211 and the supply-side ink chamber 210 are made appropriate, and the initial filling operation is completed. Since the pressure adjusting unit 203 operates and the ink casing 200 is in a sealed state, the meniscus pressure of the nozzle 51 is maintained at a negative pressure even when the power is turned off, and ink does not leak.

The pressure sensor 204 outputs the pressure as a voltage. When the pressure sensor 204 is used for a long time or the environmental (temperature) condition changes, a difference occurs between the pressure and the output voltage. Therefore, the pressure can be accurately detected by storing the output voltage value of the atmospheric pressure and obtaining the pressure (gauge pressure) from the difference from the output voltage value at the time of pressure detection. When it is time to store the output voltage of atmospheric pressure, the pressure adjustment chambers 261 and 262 are communicated with the atmosphere. Since the pressure in the recovery-side ink chamber 211 is atmospheric pressure, the output voltage value at that time is stored in the memory of the control unit. When the pressure in the ink casing 200 becomes atmospheric pressure, the meniscus of the nozzle 51 of the inkjet head 2 becomes positive pressure, and ink may leak from the nozzle 51. However, since the operation of setting the atmospheric pressure is completed in a short time, if the recovery-side ink chamber 211 is adjusted to a predetermined pressure after storing the output voltage value of the atmospheric pressure, the ink does not leak out from the nozzles 51. The timing for storing the output voltage value of the atmospheric pressure in the memory is performed when the apparatus is turned on.

As another timing for storing the output voltage value of the atmospheric pressure in the memory, it can be performed at regular intervals by a timer built in the apparatus. When the output voltage value is stored in the memory at regular intervals, the printing operation is stopped when the timing occurs while printing by the inkjet head recording unit 4. In order not to stop the printing operation, the output voltage value is stored in the memory after the printing is finished by shifting the timing for storing the output voltage value of the atmospheric pressure even when a predetermined time elapses with the timer.

A printing operation will be described. When a printing operation is instructed from a keyboard or a computer, the maintenance unit 310 is separated from the nozzle plate 52. The pressure adjusting unit 203 adjusts the pressure in the collection-side ink chamber 211 in the state shown in FIG. The ink circulation pump 201 is driven, and the ink circulates from the collection side ink chamber 211 in the order of the ink circulation pump 201, the supply side ink chamber 210, the inkjet head 2, and the collection side ink chamber 211. When the ink level (a) (b) detected by the ink amount sensors 205A and 205B of the supply side ink chamber 210 and the recovery side ink chamber 211 is not the desired ink level, the ink supply pump 202 is driven. Then, the ink is supplied from the ink cartridge 106 to the recovery-side ink chamber 211 until the desired ink liquid level is reached. The heater 207 attached to the ink casing 200 is energized and heated until the ink reaches a desired temperature. When the desired temperature is reached, the energization of the heater is controlled so that the ink temperature falls within a certain range.

Next, the inkjet head 2 ejects ink corresponding to image data to be printed to the recording medium S in synchronization with the scanning of the carriage 100. An image is formed on the recording medium S by moving the recording medium S by a predetermined distance on the slide rail 105 and repeating the operation of ejecting ink in synchronization with the scanning of the carriage 100. When ink is ejected from the inkjet head 2, the amount of ink in the ink casing 200 decreases instantaneously, and the pressure in the recovery-side ink chamber 211 decreases. When the pressure sensor 204 detects that the pressure in the collection-side ink chamber 211 has decreased, the pressure adjustment unit 203 executes the pressure adjustment operation described with reference to FIG. 8B, and the ink supply pump 202 is driven to discharge. The ink corresponding to the ink amount thus delivered is sent to the collection-side ink chamber 211.

Here, the volume of the ink droplets ejected from the inkjet head 2 is constant, and the number of ink droplets ejected from the image data can also be calculated. Therefore, the amount of ink used is estimated by their product. For this reason, the ink amount in the ink casing 200 during the printing operation immediately returns to a predetermined amount.

When the ink in the ink cartridge 106 runs out, even if the ink supply pump 202 is driven for a predetermined time, the ink liquid level in the collection-side ink chamber 211 does not reach a desired height. When the ink liquid level in the collection-side ink chamber 211 does not reach a desired height, the display device is caused to execute a display indicating that the ink cartridge 106 is empty.

(Second Embodiment)
A second embodiment of the pressure adjustment unit 203 will be described with reference to FIG. The pressure adjustment chamber 261 of the first embodiment has a communication pipe line 256 that communicates the fourth gas chamber 270 and the air chamber 360 above the supply-side ink chamber 210. In 2nd Embodiment, it does not have the structure corresponded to this communication pipe line 256 and the opening-and-closing member 257. FIG. The other configuration is the same as that of the first embodiment. Details will be described below.

The pressure adjustment chamber 261 includes a cylinder 250, a piston 252 housed in the cylinder 250, and a pulse motor 254 that moves the piston 252 up and down (H direction) to change the volume of the cylinder 250. The volume (fourth gas chamber 270) surrounded by the cylinder 250 and the piston 252 is varied to change the pressure. The pressure adjustment chamber 262 includes a cylinder 251 communicating with the recovery-side ink chamber 211, a piston 253 housed inside the cylinder 251, and a pulse for moving the piston 253 up and down (H direction) to change the volume of the cylinder 251. The motor 255 is configured. The volume (third gas chamber 272) surrounded by the cylinder 251 and the piston 253 is varied to change the pressure. The cylinder 251 has a communication conduit 258 that communicates with the recovery-side ink chamber 211 and a communication conduit 259 that communicates the inside of the cylinder 251 with the atmosphere. An open / close member 263 (first open / close means) that closes the spring and the communication hole with the atmosphere by the biasing of the spring and opens when biased by the piston 253 is attached to the inside of the communication conduit 259. The pressure adjustment chamber 262 is configured such that when the piston 253 is at the lower limit of the cylinder 251, the piston 253 (second opening / closing means) closes the upper end 306 of the communication line 258 between the recovery-side ink chamber 211 and the cylinder 251. ing. Therefore, in this embodiment, the piston 253 functions as a function for opening and closing the first opening / closing means, and further as a second opening / closing means for opening and closing the communication pipe 258.

Further, a communication path 260 is provided between the cylinder 250 of the pressure adjustment chamber 261 and the cylinder 251 of the pressure adjustment chamber 262 so that they are always in communication. The piston 252 in the cylinder 250 of the pressure adjustment chamber 261 and the piston 253 in the cylinder 251 of the pressure adjustment chamber 262 are respectively moved up and down (in the H direction) to change the volume of air in the cylinders 250 and 251, The pressure inside the ink casing 200 is adjusted by controlling the communication or blockage with the ink casing 200.

The movement range and position of the piston will be described. As shown in FIG. 14, the home position (piston reference position), the atmospheric release position, and the lower limit position of the piston 253 in the cylinder 251 will be described. FIGS. 14A, 14 </ b> B, and 14 </ b> C show a state in which the position of the piston 253 in the pressure adjustment chamber 261 is the same and the piston 252 in the pressure adjustment chamber 262 is changed. F indicates a filter provided at the air intake.

FIG. 14A shows the home position (x1) of the piston 253. In the home position, the piston 253 is in a position where the tip 305 of the opening / closing member 263 provided in the communication pipe 259 that communicates the third gas chamber 272 with the atmosphere does not contact. Since the tip 305 of the opening / closing member 263 is not pushed, the opening / closing member 263 keeps the communication pipe line 259 closed. Further, the leading end 306 of the communication pipe 258 that communicates the third gas chamber 272 and the air chamber 350 in the recovery-side ink chamber 211 enters the third gas chamber 272. The tip 305 of the opening / closing member 263 and the tip 306 of the communication pipe 258 are separated by a distance G in the moving direction of the piston 253. When the piston 253 is at the home position, the piston 253 does not block the opening at the tip 306 of the communication conduit 258.

When the piston 253 is set to the home position and the piston 252 in the cylinder 250 is moved downward (H direction), the pressure in the gas chamber 270 increases. When the piston 252 is moved upward, the pressure in the gas chamber 270 decreases. By repeating this, pressure adjustment can be performed.

FIG. 14B shows the position of the piston 253 that opens the third gas chamber 272 to the atmosphere. In the atmosphere release position (x2), the piston 253 biases the tip 305 of the opening / closing member 263 provided in the communication pipe 259 that communicates the third gas chamber 272 with the atmosphere. When the tip 305 is energized, the opening / closing member 263 is opened and the third gas chamber 272 is opened to the atmosphere. Since the position of the piston 253 is between the distal end 305 of the opening / closing member 263 and the distal end 306 of the communication conduit 258, the opening of the distal end 306 of the communication conduit 258 is kept open. As a result, the air chamber 350 in the recovery-side ink chamber 211 is opened to the atmosphere through the opening / closing member 263 and the third gas chamber 272, as indicated by the dashed arrow.

FIG. 14C shows the lower limit position (x3) of the piston 253. At the lower limit position, the piston 253 biases the tip 305 of the opening / closing member 263 to open the opening / closing member 263, and further closes the opening of the tip 306 of the communication conduit 258. At this time, the gas chamber 350 of the recovery-side ink chamber 211 is sealed.

Although an embodiment of the present invention has been described, this embodiment is presented as an example and is not intended to limit the scope of the invention. The novel embodiment can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. This embodiment and its modifications are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

DESCRIPTION OF SYMBOLS 1 ... Inkjet recording device 2 ... Inkjet head 3 ... Ink circulation device 4, 4a-4e ... Inkjet recording part 51 ... Nozzle 100 ... Carriage 150 ... Ink pressure chamber 160 ... Ink supply port 170 ... Ink discharge port 200 ... Ink casing 201 ... Ink circulation pump 202 ... Ink supply pump 203 ... Pressure adjustment unit 210 ... Supply side ink chamber 211 ... Recovery side ink chamber 250 ... Cylinder 251 ... Cylinder 252 ... Piston (movable body)
253 ... Piston (second opening / closing means)
254, 255 ... pulse motor 256 ... third communication passage 257 ... third opening / closing means 258 ... second communication passage 259 ... first communication passage 260 ... fourth communication passage 263 ... first opening / closing means 270 ... fourth gas chamber 272 ... Third gas chamber 350 ... Air chamber (first gas chamber)
352 ... Air chamber (second gas chamber)

Claims (5)

An ink pressure chamber having a nozzle for ejecting ink; an ink supply port that communicates with the ink pressure chamber and supplies ink; and an ink ejection port that communicates with the ink pressure chamber and discharges ink that has not been ejected from the nozzles. An inkjet head having
A first gas chamber containing a gas in contact with the ink conveyed from the ink discharge port;
A second gas chamber containing a gas in contact with the ink supplied to the ink supply port;
Second opening / closing means that communicates with a first communication path that includes first opening / closing means that prohibits opening to the atmosphere or opening to the atmosphere, and that communicates with a second communication path that communicates with the first gas chamber to open / close the second communication path. A third gas chamber comprising:
A fourth gas chamber communicating with the third gas chamber and having a variable volume;
A third opening / closing means for opening / closing the passage; and a third communication passage for communicating the second gas chamber and the fourth gas chamber;
An inkjet recording apparatus comprising: the third gas chamber; and a fourth communication path communicating with the fourth gas chamber.
A movable body that varies the volume of the third gas chamber while maintaining the hermeticity of the third gas chamber;
2. The ink jet recording apparatus according to claim 1, wherein the first opening / closing means normally prohibits opening to the atmosphere, and the movable body opens to the atmosphere by contacting the first opening / closing means.
A movable body that varies the volume of the third gas chamber while maintaining the hermeticity of the third gas chamber;
2. The ink jet recording apparatus according to claim 1, wherein the second opening / closing means normally opens the second communication path and closes the second communication path when the movable body moves.
A third gas chamber having a second opening / closing means that communicates with the first communication path including the first opening / closing means that prohibits the opening to the atmosphere or the atmosphere, and communicates with the second communication path to switch the opening / closing of the second communication path;
A fourth gas chamber communicating with the third gas chamber and having a variable volume;
A third opening / closing means for switching between opening and closing; a third communication passage communicating with the fourth gas chamber;
A pressure regulating device comprising: the third gas chamber and a fourth communication passage communicating with the fourth gas chamber.
A third gas chamber having a second opening / closing means that communicates with the first communication path including the first opening / closing means that prohibits the opening to the atmosphere or the atmosphere, and communicates with the second communication path to switch the opening / closing of the second communication path;
A fourth gas chamber communicating with the third gas chamber and having a variable volume;
A pressure regulating device comprising: the third gas chamber and a fourth communication passage communicating with the fourth gas chamber.

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