JP6341648B2 - Inkjet recording device - Google Patents

Description

The present invention relates to Lee inkjet recording apparatus.

  Technologies related to inkjet have been proposed. For example, Patent Document 1 discloses an ink jet recording apparatus. In this ink jet recording apparatus, a plurality of types of ink are classified into at least two ink groups, and inks belonging to different ink groups are alternately arranged in adjacent nozzle rows in the recording head. Patent Document 2 discloses an ink jet recording apparatus. In this ink jet recording apparatus, the head of the printing unit has a nozzle row in which a plurality of nozzles are arranged in a straight line over a length corresponding to the entire width of the recording paper in a direction substantially orthogonal to the feeding direction of the recording paper. Nozzles are arranged at a nozzle density of 300 (300 npi) or more per inch. The applicant has proposed a technique relating to an ink jet recording method in Patent Document 3.

JP 2011-46061 A JP 2005-313626 A JP 2012-87504 A

  The ink jet recording apparatus can record an image on a recording medium with high quality. Therefore, the ink jet recording apparatus is used not only for home use but also in the industrial field. When the inventor increases the nozzle density with an inkjet head and narrows the interval between adjacent nozzles, when the ink is continuously ejected from each nozzle and an image is recorded, the landing position of the ejected ink deviates from the target position. As a result, it has been recognized that the image quality may deteriorate. The inventor has recognized that the higher the drive frequency and the shorter the ink ejection interval, the lower the image quality. Furthermore, the inventor has recognized that the image quality decreases as the distance between the ejection surface on which the nozzle is formed by the inkjet head and the recording surface of the recording medium increases. For example, when a recording medium having a variation in thickness or a protrusion on the recording surface is targeted, the interval between the ejection surface and the recording surface is increased in order to prevent contact between the ejection surface and the recording medium. For example, when the recording medium is a fluffy fabric, the interval between the ejection surface and the recording surface may be set to several mm to 10 mm or more.

The present invention can suppress deterioration of the image quality, it is possible to record an image suitable picture quality, and to provide a Lee inkjet recording apparatus.

In one aspect of the present invention, a plurality of nozzles that eject ink of the same color including a plurality of first nozzles and a plurality of second nozzles having the same diameter as the first nozzle are formed, An inkjet head that continuously ejects the ink; and a placement unit that includes a placement surface on which a recording medium on which an image is recorded by the ink continuously ejected from each nozzle is placed. The plurality of first nozzles are aligned in the first direction at a first interval having a nozzle density of 25 npi or less and a center-to-center distance of 20.32 times the diameter of the first nozzle to form a first nozzle row. The plurality of second nozzles are aligned in the first direction at the first interval to form a second nozzle row, and the first nozzle row and the second nozzle row have a center-to-center distance. The first interval at a second interval of one interval or more Provided in a state in which adjacent in a second direction perpendicular to the direction, further movement, comprising a moving part for reciprocating the inkjet head in the second direction, the inkjet head is in the second direction by the moving unit When the ink is continuously ejected from the nozzles in a state where the nozzles are in operation, the ink-jet head is driven by a drive signal having a drive frequency of 1 kHz or more and 20 kHz or less, and the ejection surface of the inkjet head on which the plurality of nozzles are formed; The third interval between the recording surface and the recording surface of the recording medium placed on the mounting surface is 1 mm or more and 10 mm or less. The nozzle is provided above the mounting surface, and at each nozzle, 45 pl or more in one discharge. The ink of 90 pl or less is ejected, and the placement unit is moved according to the movement of the inkjet head in the second direction by the moving unit. The loaded placed said recording medium mounting surface intermittently conveyed to the other side from one side of the first direction, an ink jet recording apparatus.

According to this, the landing position deviation of the ejected ink can be suppressed in the range where the drive frequency is 1 kHz or more and 20 kHz or less and the interval (third interval) between the ejection surface and the recording surface is 1 mm or more and 10 mm or less. . Along with this, it is possible to land the ink on the target position with high accuracy. As a result of examining the above-described problems, the inventor has reached the following idea. That is, an air flow wall corresponding to this nozzle row may be formed by the ink ejected simultaneously or at the same timing from each nozzle forming a predetermined one nozzle row. A plurality of walls of the airflow are formed corresponding to each of the plurality of nozzle rows. Furthermore, for example, a vortex may be generated in a region partitioned by an air flow wall of each nozzle row by a predetermined operation during image recording. The ejected ink is considered to be affected by the vortex generated in the vicinity of the nozzle that ejected the ink during the flight. The influence of the vortex generated between the walls of the airflow is more easily received as the ink droplet amount is smaller, and the affected ink is caused to flow in different directions and land at a position shifted from the target position. In this regard, the plurality of first nozzles and the plurality of second nozzles are arranged at a first interval such that the nozzle density is 25 npi (nozzles per inch) or less and the center-to-center distance is 20.32 times or more the diameter of the first nozzle. Aligned in the first direction, the first nozzle row and the second nozzle row are arranged adjacent to each other in the second direction at a second interval greater than or equal to the first interval , and ink of 45 pl or more and 90 pl or less is ejected once. By ejecting from each nozzle, it becomes possible to suppress the formation of air current walls and the generation of eddy currents, and the ejected ink can be smoothly ejected . An image can be recorded on the recording surface while reciprocating the inkjet head in the second direction. The occurrence of wind ripples can be suppressed and deterioration of image quality can be prevented. The “first interval at which the nozzle density is 25 npi or less” is 1.016 mm (first interval = 1 (inch) × 25.4 (mm) / 25) or more when “1 inch = 25.4 mm”. Become.

In the ink jet recording apparatus, the ink jet head, the third distance is greater than or equal to 3mm prior SL, is provided above the placement surface, it may be. According to this, it is possible to record an image on the recording surface while preventing the recording medium from coming into contact with the ejection surface.

According to the present invention, suppressing a decrease in image quality, an image of suitable quality can be recorded, can be obtained Lee inkjet recording apparatus.

1 is a perspective view illustrating a schematic configuration of an ink jet recording apparatus. It is the figure which looked at the inkjet head from the discharge surface side in which the nozzle was formed. 3 is a photograph showing image quality criteria.

  Embodiments for carrying out the present invention will be described with reference to the drawings. The present invention is not limited to the configurations described below, and various configurations can be employed in the same technical idea. For example, some of the configurations shown below may be omitted or replaced with other configurations. Other configurations may be included.

<Inkjet recording apparatus>
The ink jet recording apparatus 10 will be described with reference to FIGS. 1 and 2. In the inkjet recording apparatus 10, the recording medium 14 is conveyed and an image is recorded on the recording surface 15 of the recording medium 14. In the ink jet recording apparatus 10, images are recorded on various recording media 14. Examples of the recording medium 14 include fabrics and building materials. In the present embodiment, a case where the recording medium 14 is a long fabric will be described as an example. The ink colors used for image recording are four colors, black, magenta, yellow, and cyan. The ink color may be a color other than these. The number of ink colors may be 3 colors or less or 5 colors or more. The halftone dot pattern attached to the portion of the recording medium 14 illustrated on the downstream side in the transport direction in FIG. 1 corresponds to the image recorded on the recording medium 14.

  As shown in FIG. 1, the ink jet recording apparatus 10 includes a transport unit 20, a recording unit 30, a moving unit 40, and main tanks 50K, 50M, 50Y, and 50C. The transport unit 20 transports the recording medium 14 placed on the transport surface 21 along the longitudinal direction of the recording medium 14. That is, the transport unit 20 including the transport surface 21 has a side surface as a mounting unit including a mounting surface on which the recording medium 14 on which an image is recorded is placed.

  In the present embodiment, the direction in which the recording medium 14 is transported by the transport unit 20 is referred to as “transport direction”. The transport direction is a direction along the longitudinal direction of the recording medium 14 and is a direction orthogonal to the short direction of the recording medium 14. The short direction of the recording medium 14 is the width direction of the recording medium 14 and coincides with the direction (main scanning direction) in which the recording unit 30 is reciprocated by the moving unit 40 as described later. In the present embodiment, the transport direction and the opposite direction are referred to as “longitudinal direction” in accordance with the longitudinal direction of the recording medium 14. The conveyance direction and the opposite direction may be referred to as “sub-scanning direction” with respect to the main scanning direction described above. The direction orthogonal to each of the transport direction and the opposite direction is referred to as the “short direction” according to the short direction of the recording medium 14.

  The recording unit 30 includes inkjet heads 31K, 31M, 31Y, 31C and a carriage 34. The inkjet head 31K is an inkjet head that ejects black ink and records an image with the black ink. A plurality of nozzles 32 for discharging black ink are formed in the inkjet head 31K (see FIG. 2). The inkjet head 31M is an inkjet head that discharges magenta ink and records an image with the magenta ink. A plurality of nozzles 32 that eject magenta ink are formed in the inkjet head 31M (see FIG. 2).

  The inkjet head 31Y is an inkjet head that discharges yellow ink and records an image with the yellow ink. A plurality of nozzles 32 for discharging yellow ink are formed on the inkjet head 31Y (see FIG. 2). The ink jet head 31C is an ink jet head that discharges cyan ink and records an image with the cyan ink. A plurality of nozzles 32 that discharge cyan ink are formed in the inkjet head 31C (see FIG. 2). The inkjet heads 31K, 31M, 31Y, and 31C have the same configuration. The inkjet heads 31K, 31M, 31Y, and 31C may be formed by arranging a plurality of head units in the longitudinal direction, or in the longitudinal direction and the lateral direction.

  In each of the inkjet heads 31K, 31M, 31Y, and 31C, the plurality of nozzles 32 are classified into a plurality of first nozzles 321 and a plurality of second nozzles 322 (see FIG. 2). The first nozzle 321 and the second nozzle 322 are nozzles having the same diameter. In each of the inkjet heads 31K, 31M, 31Y, and 31C, the plurality of first nozzles 321 and the plurality of second nozzles 322 are arranged in a staggered manner. The plurality of first nozzles 321 are aligned in the first direction at a first interval W1 with a nozzle density of 25 npi or less to form a first nozzle row LA. The plurality of second nozzles 322 are aligned in the first direction at the first interval W1 to form the second nozzle row LB. In the ink jet recording apparatus 10 that records an image by reciprocating the recording unit 30 in the lateral direction, the “first direction” is the longitudinal direction.

  In the present embodiment, in each of the inkjet heads 31K, 31M, 31Y, and 31C, the plurality of nozzles 32 are classified into a first nozzle 321 and a second nozzle 322, and each of the inkjet heads 31K, 31M, 31Y, and 31C. A configuration in which two nozzle rows are formed will be described as an example. The nozzle rows formed in the inkjet heads 31K, 31M, 31Y, and 31C may be classified into three or more by arranging the plurality of nozzles 32 into three or more. In the present embodiment, the “nozzle 32” does not distinguish between the first nozzle 321 and the second nozzle 322, or is a collective term for these. In FIG. 2, in each of the inkjet heads 31K, 31M, 31Y, and 31C, the number and arrangement of the plurality of nozzles 32 (the first nozzle 321 and the second nozzle 322) are illustrated in a simplified manner. In FIG. 2, the plurality of first nozzles 321 and the plurality of second nozzles 322 are not illustrated with a nozzle density of 25 npi or less as described above.

  In each of the inkjet heads 31K, 31M, 31Y, and 31C, the first nozzle array LA and the second nozzle array LB are provided adjacent to each other in the second direction at the second interval W2. When the plurality of first nozzles 321 and the plurality of second nozzles 322 are arranged in a staggered manner, the first nozzle row LA and the second nozzle row LB are in a positional relationship shifted by a predetermined amount in the first direction. The second direction is a direction orthogonal to the first direction. In the ink jet recording apparatus 10 that records an image by reciprocating the recording unit 30 in the short direction, the “first direction” is the longitudinal direction as described above. Therefore, the “second direction” is the short direction. In the following description, the first direction is the longitudinal direction and the second direction is the short direction.

  The first interval W1 is the distance between the centers of the nozzles 32 adjacent in the longitudinal direction, and the second interval W2 is the distance between the centers of the first nozzle row LA and the second nozzle row LB adjacent in the short direction. When the nozzle density is 25 npi, the first interval W1 is 1.016 mm (first interval W1 = 1 (inch) × 25.4 (mm) / 25). The second interval W2 is an interval equal to or greater than the first interval W1. Accordingly, the second interval W2 is set to a range equal to or greater than the first interval W1 “1.016 mm” when the nozzle density is 25 npi. The second interval W2 is set in consideration of the influence of an airflow wall described later in addition to the number of nozzle rows. The state shown in FIG. 2 is a state where “second interval W2 = first interval W1”.

  Inkjet heads 31K, 31M, 31Y, and 31C are mounted on the carriage 34 in a state where they are positioned at predetermined positions. As shown in FIG. 1, the inkjet heads 31 </ b> K, 31 </ b> M, 31 </ b> Y, and 31 </ b> C are mounted on the carriage 34 while being adjacent to each other in the lateral direction. The arrangement order of the inkjet heads 31K, 31M, 31Y, and 31C may be different from that shown in FIG. These arrangement orders are appropriately determined in consideration of various conditions.

  The recording unit 30 is provided above the conveyance surface 21 of the conveyance unit 20. At this time, the third gap G3 (see FIG. 1) between the ejection surfaces 33 of the inkjet heads 31K, 31M, 31Y, and 31C and the recording surface 15 of the recording medium 14 is, for example, wider than 2 mm, specifically, 3 mm or more. Set to The third interval G3 is appropriately set in consideration of the variation in the thickness of the recording medium 14 and / or the state of the recording surface 15 (fluffing or the like). For example, in the case where a fabric having fuzz on the recording surface 15 becomes the recording medium 14, the third gap G3 may be 10 mm. However, the third gap G3 is about 20 mm at the maximum. The ejection surface 33 is each surface of the inkjet heads 31K, 31M, 31Y, 31C on which the nozzles 32 are formed. The ejection surfaces 33 of the inkjet heads 31K, 31M, 31Y, and 31C are included in the same virtual plane (horizontal plane). The recording medium 14 conveyed by the conveyance unit 20 passes through the recording unit 30 with the recording surface 15 facing the ejection surface 33 with a third gap G3.

  The moving unit 40 reciprocates the recording unit 30 in the short direction. As shown in FIG. 1, the moving unit 40 includes two pulleys 41 and 42 and a timing belt 43. The two pulleys 41 and 42 are provided on both sides in the lateral direction with respect to the transport unit 20. For example, a motor (not shown) is connected to the pulley 41, and the pulley 42 is rotatably supported. The pulley 41 rotates as the motor rotates. The timing belt 43 is stretched over pulleys 41 and 42 in a state where tension is applied. The recording unit 30 is attached to the timing belt 43 via a support unit 46 fixed to the carriage 34.

  When the inkjet recording apparatus 10 records an image, the motor connected to the pulley 41 reciprocally rotates clockwise and counterclockwise. As the motor rotates, the pulley 41 rotates back and forth on both the left and right sides (for the rotation direction of the pulley 41, see “arc-shaped arrow” shown inside the pulley 41 in FIG. 1). When the pulley 41 rotates counterclockwise by rotating the motor in a predetermined direction, the timing belt 43 also rotates counterclockwise. The pulley 42 rotates following the timing belt 43 that rotates counterclockwise. Accordingly, the recording unit 30 moves from the second side in the short direction to the first side. When the recording unit 30 reaches the first moving end in the short direction, the rotation direction of the motor is reversed and the pulley 41 rotates to the right. When the pulley 41 rotates to the right, the timing belt 43 also rotates to the right. The pulley 42 rotates following the timing belt 43 that rotates clockwise. Accordingly, the recording unit 30 moves from the first side in the lateral direction to the second side. When the recording unit 30 reaches the moving end on the second side in the short direction, the rotation direction of the motor is reversed again, and the pulley 41 rotates left again. The reciprocating movement of the recording unit 30 in the short direction by the moving unit 40 is repeated until the image recording is completed.

  The main tank 50K is a tank that stores black ink. The black ink flows out of the main tank 50K, flows through the supply tube 51K, and is supplied to the inkjet head 31K. The main tank 50M is a tank that stores magenta ink. The magenta ink flows out from the main tank 50M, flows through the supply tube 51M, and is supplied to the inkjet head 31M. The main tank 50Y is a tank that stores yellow ink. The yellow ink flows out of the main tank 50Y, flows through the supply tube 51Y, and is supplied to the inkjet head 31Y. The main tank 50C is a tank that stores cyan ink. The cyan ink flows out of the main tank 50C, flows through the supply tube 51C, and is supplied to the inkjet head 31C.

  In FIG. 1, the supply tubes 51K, 51M, 51Y, and 51C are simplified. The supply tubes 51K, 51M, 51Y, and 51C are provided in a state that can accommodate the reciprocating movement of the recording unit 30 in the short direction.

  In the inkjet recording apparatus 10, when an image is recorded on the recording medium 14 by reciprocating the recording unit 30 in the short direction, the recording medium 14 is conveyed in the conveying direction by the conveying unit 20. The conveyance of the recording medium 14 by the conveyance unit 20 is performed intermittently according to the movement of the recording unit 30 in the short direction. The inks of the respective colors are ejected toward the recording medium 14 from the nozzles 32 respectively formed on the inkjet heads 31K, 31M, 31Y, and 31C at a predetermined timing when the recording unit 30 moves in the short direction. The inks of the respective colors ejected from the nozzles 32 of the inkjet heads 31K, 31M, 31Y, 31C land on the recording surface 15 of the recording medium 14. An image is recorded on the recording surface 15 of the recording medium 14 by the landed ink of each color.

<Example>
An experiment was conducted to confirm the effectiveness of the inkjet heads 31K, 31M, 31Y, and 31C of this embodiment. Hereinafter, the present experimental method and experimental results will be described with reference to FIG. 3 and Tables 1 to 5.

<Experiment method>
In this experiment, similar to the above-described ink jet recording apparatus 10, an ink jet recording apparatus of a type in which an image is recorded by reciprocating a recording unit including an ink jet head was used. In the experiment, one color ink was ejected from one inkjet head, and a solid image of the one color was recorded on the recording surface of the recording medium. Coated paper was used as the recording medium. The conditions for inkjet recording were the following conditions (1) to (4).

(1) Distance between discharge surface and recording surface: 1mm, 2mm, 3mm, 5mm, 10mm
(2) Ink drop amount: 45 pl / drop, 90 pl / drop (3) Nozzle density: 100 npi, 50 npi, 33.3 npi, 25 npi
(4) Drive frequency: 1 kHz, 2 kHz, 3 kHz, 5 kHz, 10 kHz, 20 kHz
The diameter of the nozzle formed on the inkjet head was 50 μm. Regarding condition (3), the interval between adjacent nozzles in one nozzle row (refer to “first interval W1” in FIG. 2 is referred to as “first interval W1” as described above) is 0.254 mm when the nozzle density is 100 npi. (1 inch = 25.4 mm and the same). Similarly, when the nozzle density is 50 npi, it is 0.508 mm. When the nozzle density is 33.3 npi, it is 0.762 mm. When the nozzle density is 25 npi, it is 1.016 mm. A plurality of nozzle rows are formed in the ink jet head of the recording unit included in the ink jet recording apparatus used in the experiment. The interval between adjacent nozzle rows (see “second interval W2” in FIG. 2) W2 ") was constant at 1.016 mm corresponding to a first interval W1 of 25 npi. The interval between adjacent nozzle rows is 20.32 times (1.016 / 0.05) the nozzle diameter “50 μm”.

  The image quality of the recorded image was classified into three levels: good (judgment result: ◯), slightly bad (judgment result: Δ), and bad (judgment result: x). When a printed pattern was not recognized in the recorded image, the determination result was “good (◯)” (see “image quality: good” in FIG. 3). If the recorded image has a slight wind pattern, the determination result is “slightly bad (Δ)” (see “image quality: slightly bad” in FIG. 3). When a wind pattern is clearly recognized in the recorded image, the determination result is “defective (×)” (see “image quality: defective” in FIG. 3).

<Experimental result 1>
Table 1 shows an experimental result 1 when the interval between the ejection surface and the recording surface (refer to “third interval G3” in FIG. 1 is referred to as “third interval G3” as described above) is 1 mm. When the third gap G3 was 1 mm, no printed pattern was observed in the recorded image regardless of the nozzle density, ink droplet amount, and drive frequency conditions, and the image quality was good.

<Experimental result 2>
Table 2 shows the experimental result 2 when the third gap G3 is 2 mm. When the third gap G3 was 2 mm, no printed pattern was observed in the recorded image and the image quality was good regardless of the nozzle density, the appropriate amount of ink, and the drive frequency.

<Experimental result 3>
Table 3 shows the experimental result 3 when the third gap G3 is 3 mm. When the third gap G3 was 3 mm, a wind pattern was confirmed at each nozzle density of 100 npi, 50 npi, and 33.3 npi, and a decrease in image quality was observed. In the case of 100 npi, when the driving frequency was 2 kHz or higher, the image quality was lowered to “bad”. This was the same for both ink drops of 45 pl and 90 pl.

  At 50 npi, when the ink droplet amount was 45 pl and the driving frequency was 3 kHz or higher, or when the ink droplet amount was 90 pl and the driving frequency was 10 kHz or higher, the image quality was lowered to “slightly poor”. At 33.3 npi, when the ink droplet amount was 45 pl and the driving frequency was 10 kHz or more, the image quality was lowered to “slightly poor”.

On the other hand, when the nozzle density was 25 npi, no printed pattern was observed in the recorded image regardless of the ink droplet amount and the driving frequency, and the image quality was good.

<Experimental result 4>
Table 4 shows the experimental result 4 when the third gap G3 is 5 mm. When the third gap G3 was 5 mm, a wind pattern was confirmed at each nozzle density of 100 npi, 50 npi, and 33.3 npi, and a decrease in image quality was observed. At 100 npi, when the drive frequency was 2 kHz or higher, the image quality was reduced to “bad”. This was the same for both ink drops of 45 pl and 90 pl.

  At 50 npi, when the ink droplet amount was 45 pl and the driving frequency was 2 kHz or higher, or when the ink droplet amount was 90 pl and the driving frequency was 3 kHz or higher, the image quality was lowered to “bad”. When the ink droplet amount was 90 pl and the drive frequency was 2 kHz, the image quality was lowered to “slightly poor”.

  At 33.3 npi, when the ink droplet amount was 45 pl and the driving frequency was 3 kHz and 5 kHz, the image quality was lowered to “slightly poor”, and when it was 10 kHz or higher, it was lowered to “bad”. When the ink droplet amount was 90 pl and the drive frequency was 10 kHz or more, the image quality was lowered to “slightly poor”.

On the other hand, when the nozzle density was 25 npi, no printed pattern was observed in the recorded image regardless of the ink droplet amount and the driving frequency, and the image quality was good.

<Experimental result 5>
Table 5 shows the experimental result 5 when the third gap G3 is 10 mm. When the third gap G3 was 10 mm, a wind pattern was confirmed at each nozzle density of 100 npi, 50 npi, and 33.3 npi, and a decrease in image quality was observed. At 100 npi, when the drive frequency was 2 kHz or higher, the image quality was reduced to “bad”. This was the same for both ink drops of 45 pl and 90 pl.

  At 50 npi, when the ink droplet amount was 45 pl and the driving frequency was 2 kHz or higher, or when the ink droplet amount was 90 pl and the driving frequency was 3 kHz or higher, the image quality was lowered to “bad”. When the ink droplet amount was 90 pl and the drive frequency was 2 kHz, the image quality was lowered to “slightly poor”.

  At 33.3 npi, when the ink droplet amount was 45 pl and the driving frequency was 2 kHz, the image quality was lowered to “slightly poor”, and when it was 3 kHz or more, it was lowered to “bad”. When the ink droplet amount was 90 pl and the drive frequency was 3 kHz or more, the image quality was lowered to “bad”.

On the other hand, when the nozzle density was 25 npi, no printed pattern was observed in the recorded image regardless of the ink droplet amount and the driving frequency, and the image quality was good.

<Discussion>
Wind ripples are thought to be caused by airflow walls. The wall of the air flow is formed corresponding to each nozzle row by ink ejected simultaneously or at the same timing from each nozzle forming a predetermined one nozzle row. When there are a plurality of nozzle rows, a plurality of air flow walls are formed corresponding to each of the plurality of nozzle rows. Further, for example, a predetermined operation during image recording, such as conveyance of the recording medium and / or reciprocating movement of the recording unit, generates vortex in the region partitioned by the air flow walls of each nozzle row. The ejected ink is affected by, for example, the vortex generated near the nozzle that ejected the ink. As is clear from the above results, wind ripples are more likely to occur as the nozzle density is increased, the drive frequency is increased, and the third interval G3 is increased. When the third gap G3 was set to 3 mm or more, deterioration in image quality was recognized depending on conditions (see Tables 3 to 5). However, when the nozzle density is 25 npi and the second interval W2 between adjacent nozzle rows is 1.016 mm corresponding to 25 npi, good image quality is realized even when the third interval G3 is 3 mm or more. By setting the nozzle density to 25 npi and the second interval W2 between the adjacent nozzle rows to 1.016 mm corresponding to 25 npi, each condition of the third interval G3 (1 mm to 10 mm), the ink droplet amount, and the driving frequency is satisfied. Regardless, it is possible to suppress the occurrence of wind ripples and to prevent deterioration in image quality.

  When the nozzle diameter is 50 μm, in the nozzle row in which the nozzle density is 25 npi, the first interval W1 is 20.32 times (1.016 / 0.05) the nozzle diameter. If one nozzle row is used as a reference, the first interval W1 may be 20.32 times or more the nozzle diameter in order to suppress the occurrence of wind ripples. When a plurality of nozzle rows are formed, the second interval W2 is preferably 20.32 times or more the nozzle diameter.

<Effect of this embodiment>
In each of the inkjet heads 31K, 31M, 31Y, 31C in which the first nozzle row LA and the second nozzle row LB are formed, the plurality of first nozzles 321 are arranged in the longitudinal direction at a first interval W1 at which the nozzle density is 25 npi or less. The first nozzle array LA is formed by alignment, and the second nozzle array LB is formed by aligning a plurality of second nozzles 322 in the longitudinal direction at a first interval W1 at which the nozzle density is 25 npi or less (see FIG. 2). The first nozzle row LA and the second nozzle row LB are provided adjacent to each other in the lateral direction at a second interval W2 that is equal to or greater than the first interval W1 (see FIG. 2).

  Therefore, regardless of the driving frequency and the third interval G3, it is possible to suppress the landing position deviation of the ejected ink. Along with this, it is possible to land the ink on the target position with high accuracy. When the nozzle density is increased, the ejected ink is considered to be affected by the eddy current generated in the vicinity of the nozzle that ejected the ink during the flight. The influence of the vortex generated between the walls of the airflow is more easily received as the ink droplet amount is smaller, and the affected ink is caused to flow in different directions and land at a position shifted from the target position. In this regard, the plurality of first nozzles 321 and the plurality of second nozzles 322 are respectively aligned in the longitudinal direction at a first interval W1 at which the nozzle density is 25 npi or less, and the first nozzle row LA and the second nozzle row LB are aligned with each other. By providing adjacent to each other in the short direction at a second interval W2 that is equal to or greater than one interval W1, it is possible to suppress the formation of air current walls and the generation of vortex flow, and as a result, the ink after discharge can be smoothly discharged. You can fly. It is possible to suppress an image quality deterioration and to record an image with a suitable image quality.

  Further, since the third gap G3 can be increased, specifically, 3 mm or more, high-quality images can be recorded on various recording media 14. Even when the recording medium 14 has a variation in thickness and / or has a protrusion on the recording surface 15, image recording is performed while preventing contact with the ejection surface 33 of the recording medium 14. Can do.

<Modification>
This embodiment can also be performed as follows. Some configurations of the modifications shown below can be appropriately combined and employed. Effects similar to those described above can also be obtained by an ink jet recording apparatus employing the following configuration. Hereinafter, points different from the above will be described, and description of similar points will be omitted as appropriate.

  (1) In the above, the case where the inkjet recording apparatus 10 is a recording apparatus of a type that records the image by reciprocating the recording unit 30 in the short direction has been described as an example (see FIG. 1). An ink jet head in which a first nozzle row having a plurality of first nozzles having a nozzle density of 25 npi or less and a second nozzle row having a plurality of second nozzles having a nozzle density of 25 npi or less are formed as a line-type ink jet head. It can also be adopted. In a line-type inkjet head, nozzles that eject ink of each color are arranged in the short direction. For example, in a line-type inkjet head for each color, the plurality of nozzles are formed in a range equal to or larger than the width W4 (see FIG. 1) of the recording medium 14 in the short direction.

  Even in a line-type inkjet head, the plurality of nozzles are classified into a plurality of first nozzles and a plurality of second nozzles. In each color inkjet head, the plurality of first nozzles and the plurality of second nozzles are arranged in a staggered manner. The plurality of first nozzles are aligned in the first direction at a first interval with a nozzle density of 25 npi or less to form a first nozzle row. The plurality of second nozzles are aligned in the first direction at a first interval to form a second nozzle row. The first nozzle row and the second nozzle row are provided adjacent to each other in the second direction at a second interval. In the line-type inkjet head, the “first direction” described above is a short direction, and the “second direction” described above is a longitudinal direction. In other words, in the line-type inkjet head, the “first direction” is the main scanning direction in which the first nozzle row and the second nozzle row extend, and the “second direction” is the first nozzle row and the first nozzle row. The sub-scanning direction is perpendicular to the direction in which the two nozzle rows extend. The second interval between the first nozzle row and the second nozzle row is set to be equal to or greater than the first interval, as described above. The nozzle rows formed on the ink jet heads for the respective colors may be classified into three or more by dividing a plurality of nozzles into three or more rows.

  In an ink jet recording apparatus including a recording unit using a line type ink jet head, the moving unit 40 and the support unit 46 are omitted. The conveyance of the recording medium 14 by the conveyance unit 20 is continuously performed.

  (2) In the above description, the inkjet recording apparatus 10 that records the image by transporting the recording medium 14 in the transport direction by the transport unit 20 and passing the recording unit 30 in the middle of transport has been described as an example (see FIG. 1). The movement of the recording medium and the recording unit in the longitudinal direction may be performed relatively. For example, it is assumed that the recording medium is a strip having a predetermined length. The ink jet recording apparatus includes a table-like placement unit, and the recording medium is placed on the upper surface (placement surface) of the table-like placement unit. The ink jet recording apparatus includes a moving unit corresponding to the moving unit 40 described above and another moving unit that moves the recording unit in the longitudinal direction. The other moving unit moves the recording unit intermittently in the longitudinal direction in accordance with the reciprocating movement of the recording unit. Another moving unit may move the recording unit in the longitudinal direction by moving the moving unit corresponding to the moving unit 40 to which the recording unit is attached in the longitudinal direction.

DESCRIPTION OF SYMBOLS 10 Inkjet recording device 14 Recording medium 15 Recording surface 20 Conveyance part 21 Conveyance surface 30 Recording part 31K, 31M, 31Y, 31C Inkjet head 32 Nozzle 33 Discharge surface 34 Carriage 40 Moving part 41, 42 Pulley 43 Timing belt 46 Support part 50K, 50M, 50Y, 50C Main tank 51K, 51M, 51Y, 51C Supply tube 321 First nozzle 322 Second nozzle G3 Third interval LA First nozzle row LB Second nozzle row W1 First interval W2 Second interval W4 Width

Claims (2)

A plurality of nozzles for ejecting ink of the same color including a plurality of first nozzles and a plurality of second nozzles having the same diameter as the first nozzle are formed, and the ink is continuously ejected from each nozzle. An inkjet head,
A mounting portion including a mounting surface on which a recording medium on which an image is recorded by the ink continuously ejected from each nozzle is placed;
The plurality of first nozzles are aligned in a first direction at a first interval having a nozzle density of 25 npi or less and a center-to-center distance of 20.32 times or more of the diameter of the first nozzle to form a first nozzle row. And
The plurality of second nozzles are aligned in the first direction at the first interval to form a second nozzle row,
The first nozzle row and the second nozzle row are provided in a state where the center-to-center distance is adjacent to a second direction orthogonal to the first direction at a second interval equal to or greater than the first interval .
And a moving part for reciprocating the inkjet head in the second direction,
The inkjet head is
When the ink is continuously ejected from each nozzle while being moved in the second direction by the moving unit, the ink is driven by a driving signal having a driving frequency of 1 kHz or more and 20 kHz or less,
A third interval between the ejection surface of the inkjet head in which the plurality of nozzles are formed and the recording surface of the recording medium placed on the placement surface is 1 mm or more and 10 mm or less. Provided above,
In each of the nozzles, the ink of 45 pl or more and 90 pl or less is ejected by one ejection,
The placement unit intermittently moves the recording medium placed on the placement surface from one side to the other side in the first direction according to the movement of the inkjet head in the second direction by the moving unit. Inkjet recording apparatus that conveys optically. The ink-jet head, the third distance is greater than or equal to 3mm prior SL, is provided above the placement surface, the ink jet recording apparatus according to claim 1.