The present disclosure relates to a liquid ejection head and a recording apparatus that eject liquid such as ink on a printed medium to perform recording.
Ink jet recording apparatuses which eject droplets with a liquid ejection head to perform recording are widely used. Until droplets ejected from ejection openings of a liquid ejection head land on a printed medium, the air having viscosity situated around the flying droplets is dragged by the movement of the droplets and is moved as well. With the above, an area between an ejection opening surface provided with the ejection openings and the printed medium tends to become lower in pressure than the surroundings thereof, and the surrounding air flows into the above pressure decreased area. It is known that as a result of the above, the droplets ejected particularly from ejection openings, among the ejection openings included in the ejection opening row, positioned at both ends of the ejection openings in an array direction of the ejection openings are drawn to a center side in an ejection openings array direction; accordingly, the droplets do not land on the predetermined position in the printed medium.
With respect to the deviation of the landing position caused by such an airflow generated by ejection of the droplets (hereinafter referred to as an autogenous airflow), Japanese Patent Publication No. 3907685 describes a method in which arrangement intervals of the ejection openings positioned at both ends in the array direction of the ejection openings are set larger than those on the center side in the array direction. It is stated that with the above, the positions of the droplets that land on the printed medium can be corrected to the desired positions and a high quality printed image can be obtained.
In recent years, ink jet recording apparatuses have been used not only for household printing, but also for business printing such as commercial printing and retail photo printing, and the usage of ink jet recording apparatus is increasing. Liquid ejection heads used in such business printing are required to have higher recording performance in speed and in quality. As an example of satisfying such a requirement, recording of printed mediums has been performed while increasing the speed of the relative movement between the recorded medium and the liquid ejection head (hereinafter, merely referred to as relative movement).
As the speed of the relative movement is increased, the influence of an airflow flowing between an ejection opening surface of the liquid ejection head and the printed medium (hereinafter, merely referred to as an inflowing airflow) becomes larger. It is difficult of suppress such an influence exerted by the inflowing airflow with the method described in Japanese Patent No. 3907685.
The present disclosure provides a liquid ejection head capable of suppressing deviation of a landing position of a droplet caused by an inflowing airflow, while achieving high speed recording.
The present disclosure in one aspect is a liquid ejection head including recording element substrates that each include a plurality of ejection opening rows in which ejection openings that eject liquid on a printed medium are arranged, the plurality of ejection opening rows being arranged side by side in a relative movement direction with respect to the printed medium. In the liquid ejection head, in the relative movement direction of the printed medium when the printed medium is viewed from the liquid ejection head, and in the plurality of ejection opening rows provided in the recording element substrate, among the plurality of recording element substrates, positioned on an upstream side in the relative movement direction, arrangement intervals of ejection openings in an end portion area of an ejection opening row positioned on a most upstream side in the relative movement direction are smaller than arrangement intervals of ejection openings in an end portion area of an ejection opening row positioned on a most downstream side in the relative movement direction.
Furthermore, the present disclosure in another aspect is a recording apparatus including a liquid ejection head that ejects liquid on a printed medium, and a conveying member that conveys the printed medium to the liquid ejection head. In the recording apparatus, the liquid ejection head includes recording element substrates that each include a plurality of ejection opening rows in which ejection openings that eject the liquid on the printed medium are arranged, the plurality of ejection opening rows being arranged side by side in a relative movement direction with respect to the printed medium, and in the relative movement direction of the printed medium when the printed medium is viewed from the liquid ejection head, and in the plurality of ejection opening rows provided in the recording element substrate, among the plurality of recording element substrates, positioned on an upstream side in the relative movement direction, arrangement intervals of ejection openings in an end portion area of an ejection opening row positioned on a most upstream side in the relative movement direction are smaller than arrangement intervals of ejection openings in an end portion area of an ejection opening row positioned on a most downstream side in the relative movement direction.
Further features and aspects of the disclosure will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Hereinafter, example embodiments and various aspects of the present disclosure will be described with reference to the drawings.
Note that a liquid ejection head of the present disclosure that ejects a liquid such as ink and a recording apparatus equipped with the liquid ejection head can be applied to devices such as a printer, a copier, a facsimile including a communication system, and a word processor including a printer unit. Furthermore, the liquid ejection head and the recording apparatus can be used in industrial recording apparatuses that combine various kinds of processing apparatus in a multiple manner. The liquid ejection head and the recording apparatus can also be used, for example, for fabricating biochips, for printing electronic circuits, for fabricating semiconductor substrates, and in 3D printing.
Referring to
Furthermore, other than the above, the recording apparatus 1000 includes an ink tank (not shown) that contains ink, a liquid supply passage (not shown) that supplies the ink from the ink tank to the liquid ejection head 3, an electric control unit (not shown) that transmits power and an ejection control signal to the liquid ejection head 3, and the like. In the present example embodiment, the conveyance speed of printed medium 2 is 6 ips.
Referring to
The liquid ejection head 3 includes recording element substrates 10, a flexible wiring substrate (not shown), and an electric wiring board (not shown). Signal input terminals (not shown) and power supply terminals (not shown) are provided in the electric wiring board. The signal input terminals and the power supply terminals are electrically connected to the electric control unit (not shown) provided in the recording apparatus 1000, and supply electric power necessary for the ejection drive signal and the ejection to the recording element substrates 10. The number of signal output terminals and the number of power supply terminals can be small compared to the number of recording element substrates 10 owing to an electric circuit in which wiring provided in the electric wiring board is integrated. With the above, the number of electric connection portions need to be removed when installing the liquid ejection head 3 in the recording apparatus 1000 or when replacing the liquid ejection head can be small.
As illustrated in
The liquid ejection head 3 is a page wide type liquid ejection head in which 15 recording element substrates 10 capable of ejecting the ink of four colors C, M, Y, and K are arranged in a zigzag manner as illustrated in
A configuration of the recording element substrate 10 according to the present example embodiment will be described with reference to
As illustrated in
The ejection openings 13 illustrated in
The energy generating elements 15 are electrically connected to the terminals (not shown) of the recording element substrates 10 by electric wiring (not shown) provided in the recording element substrates 10. Each energy generating element 15 generates heat based on a pulse signal input from a control circuit of the recording apparatus 1000 sequentially through the electric wiring board, the flexible wiring substrate, and the terminals. Note that the energy generating elements 15 are not limited to heating elements, and various types such as piezo elements and the like can be used.
The liquid supplied from the recording apparatus 1000 is supplied into the liquid ejection head 3 through the liquid connection portions 111 (
As illustrated in
Note that in the present example embodiment, the arrangement intervals within each of the plurality of ejection openings (16a to 16c) included in the end portion area of the corresponding one of the ejection opening rows (14a to 14c) are the same. For example, each of the arrangement intervals between the ejection openings 16a at the end portion of the ejection opening row 14a is 42.4 μm and each of the arrangement intervals of the ejection openings 16c at the end portion of the ejection opening row 14c is 42.7 μm. Furthermore, in each ejection opening rows 14a to 14c, the arrangement intervals of the ejection openings in the center area (not shown) in the arrangement direction are 42.3 μm (600 dpi). When the influence of not only the autogenous airflow but also the influence of the inflowing airflow is taken into consideration, compared with when the influence of the autogenous airflow alone is taken into consideration and the arrangement intervals of the ejection openings at the end portion area are set uniformly, deviation in the droplet landing position can be suitably suppressed. Note that the number of ejection openings constituting the ejection openings at the end portion area differ according to the driving condition. In the present example embodiment, the number of ejection openings in each of the end portion areas 16a to 16c is set to seven. Details and effects of such a configuration will be described below.
An influence of the inflowing airflow will be described below with reference to
Owing to the relative movement, the inflowing airflows (30a to 30c) occur between the ejection opening surface in which the ejection openings 13 of the liquid ejection head 3 are formed and the printed medium 2. Note that the inflowing airflow 30a flowing outside the ejection opening rows flows in a straight line. However, in a state in which the ink is ejected from the plurality of ejection openings 13, a so-called air curtain is formed in the direction from the ejection openings to the printed medium due to the flying droplets; accordingly, it is difficult for the inflowing airflow to pass through the area where the ejection opening rows 14 are formed. Accordingly, a portion (30b) of the inflowing airflow flows to the end portion side of the ejection opening row 14a, and a flow that bypasses the ejection opening row 14a occurs. Subsequently, the inflowing airflow 30b becomes a flow that flows toward the center side (the right side in
Directions and sizes of the inflowing airflow 30b flowing through the end portions of the ejection opening rows (14a to 14c) decomposed in the arrangement direction of ejection openings are schematically illustrated in
The influence of such an inflowing airflow acts largely on the ejection opening rows on the most upstream side and on the most downstream side in the plurality of ejection opening rows formed in the recording element substrate 10. Accordingly, in order to correct the deviation in the landing positions of the droplets, in the present example embodiment, the arrangement intervals of the ejection openings in the end portion area of the ejection opening row 14a on the most upstream side of the recording element substrate 10 are set small, and arrangement intervals of the ejection openings in the end portion area of the ejection opening row 14c on the most downstream side are set large. In other words, the arrangement intervals of the ejection openings in the end portion of the ejection opening row 14a on the most upstream side is set smaller than the arrangement intervals of the ejection openings in the end portion of the ejection opening row 14c on the most downstream side. The application of the present disclosure is not limited to only the ejection opening rows on the most upstream side and the most downstream side, and the arrangement intervals of the ejection openings in the end portion area of the ejection opening row adjacent to the ejection opening row positioned on the most upstream side may be set smaller than the arrangement intervals of ejection openings in the end portion area of the ejection opening row adjacent to the ejection opening row positioned on the most downstream side. The above is because, depending on the size of the inflowing airflow, the influence of the inflowing airflow is exerted on the ejection opening rows other than those on the most upstream side and the most downstream side. With such a configuration, deviations in the landing positions of the droplets can be suppressed further.
The deviation in the landing positions of the droplets owing to such inflowing airflow becomes significant when a droplet having a minute volume of 10 picoliters or less is ejected since the inertial mass of the droplet becomes small. The influence of the inflowing airflow on the deviation of the landing positions of the droplets becomes more significant when the relative movement speed between the printed medium and the liquid ejection head is 0.4 m/s or more, when the distance between the printed medium and the liquid ejection head is 2 mm or less, and when the array density of the ejection openings of the liquid ejection head is 600 dpi or more. The present disclosure can be applied more suitably to such cases.
In addition to the inflowing airflow described above, an autogenous airflow created by the ejection of the droplet is generated considerably in a space interposed between the ejection opening surface of the liquid ejection head 3 and the printed medium 2. The autogenous airflow is an airflow that flows into a pressure reduced area created by a droplet flying from the ejection opening dragging the surrounding air such that the area between the ejection opening surface provided with the ejection openings and the printed medium tends to become lower than its surroundings. With the above, the droplets ejected from the ejection openings positioned on both end sides of the ejection openings in the arrangement direction are attracted to the center side in the ejection openings array direction; accordingly, the droplet landing positions are affected. The present disclosure can be applied in a manner similar to the above even when the influence of such an autogenous airflow is considered. Description will be given with reference to
Since the autogenous airflow attracts the surrounding air towards the center portion area (not shown) of the ejection opening rows, the droplets ejected from the ejection openings positioned on both end sides in the ejection openings array direction are, in particular, attracted to the center side (the right side) in the ejection openings array direction. Furthermore, in a case in which the energy generating elements 15 corresponding to the plurality of ejection opening rows are driven at the same time, since the ease of taking in the airflow from the surroundings is different in each of the arranged ejection opening rows, the amount of attraction in each of the ejection opening rows are different. As illustrated in
On the other hand, as described above, the directions in which the inflowing airflows (301 and 302) act on the ejection openings are different in each of the ejection opening rows. Accordingly, the influence exerted on the droplets by the inflowing airflow and the autogenous airflow acts in directions cancelling out each other in the most upstream ejection opening row 14a in the relative movement direction, and directions that enhance each other in the most downstream ejection opening row 14c in the relative movement direction.
Accordingly, in a case in which both the inflowing airflow and the autogenous airflow are considered, the composite component 33a in the most upstream ejecting opening row 14a acts towards the center side in the array direction when the influence exerted on the droplets by the autogenous airflow is larger than the influence exerted on the droplets by the inflowing air. The composite component 33b in the most downstream ejection opening row 14c also acts in a similar manner towards the center side in the array direction; however, since the component 302 of the inflowing airflow and the component 103 of the autogenous airflow act towards the center side in the array direction of the ejection openings, the size of the composite component 33b is larger than that of the composite component 33a. In other words, the distance at which the droplets ejected from the ejection openings in the end portion area of the ejection opening row 14a is dragged towards the center side of the ejection opening row is smaller than the distance at which the droplets ejected from the ejection openings of the ejection opening row 14c is dragged towards the center side of the ejection opening row. Accordingly, the present example embodiment can be applied even when the influence of the autogenous airflow is considered. The arrangement intervals of the ejection openings in the end portion areas of the ejection opening row 14a positioned on the most upstream side are set smaller than the arrangement intervals of the ejection openings in the end portion areas of the ejection opening row 14c positioned on the most downstream side.
As illustrated in
Note that as illustrated in
(A Case in which there are More than Three Ejection Opening Rows)
In the example embodiment described above, for the purpose of description, the recording element substrates in which three ejection opening rows are arranged are used. However, in order to perform one-pass printing with the page wide type head in a more effective manner, it is desirable that the number of ejection opening rows is larger than three. The present disclosure can be applied in a similar manner even in a recording element substrate in which more than three ejection opening rows are arranged. Description will be given below with reference to
As illustrated in
Furthermore, depending on the size of the inflowing airflow, the arrangement intervals of the ejection openings of the third and fourth rows, counted from the most upstream side or the most downstream side in the relative movement direction towards the center side in the juxtaposition direction of ejection opening rows, are set based on the simulation result illustrated in
(A Case in which there are Ejection Opening Rows that are not Used)
In the recording element substrate 10 in which a plurality of ejection opening rows are arranged, there are cases in which, in consideration of the durability life of the recording element substrate, spare rows that are not used initially in the recording are provided or the rows are used alternately to elongate the product life of the liquid ejection head. The influence of the airflow on the recording can only be exerted between the rows being used (performing ejection and recording). In such a case, the rows that are used may be taken into consideration and the present disclosure can be applied to the rows that are used. Description of the present example embodiment will be given with reference to
In the recording element substrate 10 in
It is the same as the first exemplary embodiment in that, among the ejection opening rows used for recording, in the ejection opening row 17a on the most upstream side in the conveyance direction of the printed medium, the inflowing airflow acts in the direction cancelling the influence of the autogenous airflow. Accordingly, the distance in which the droplets are drawn toward the center of the ejection opening row is the smallest in the row on the most upstream side in the conveyance direction of the printed medium among the ejection opening rows that are used, and the amount of deviation of the landing position in the center direction of the ejection opening row is the smallest as well.
Note that the second example embodiment can be applied to the present example embodiment as well. In other words, the arrangement intervals of the ejection openings in the end portion area of the ejection opening row positioned on the most upstream side in the relative movement direction among the ejection opening rows that are used are set smaller than the arrangement intervals of the ejection openings in the end portion area of the ejection opening row adjacent to the ejection opening row on the most upstream side among the ejection opening rows that are used. By so doing, the deviation in the landing position of the droplet can be suppressed further.
(A Case in which there are Rows that are not Used Due to Ejection of Inks of a Plurality of Colors)
In the third example embodiment described above, the type of ink has not been stated; however, the present disclosure can be applied to a case in which a plurality of types of ink are supplied to the same single recording element substrate.
The present disclosure can be applied to either configurations in
In the example embodiment described above, the end portions of a plurality of ejection opening rows provided in a single recording element substrate have been compared with each other; however, the present disclosure can also be applied to the arrangement intervals of ejection openings in end portions of ejection opening rows of recording element substrates that are disposed adjacent to each other and distanced away in the relative movement direction of the recording element substrate and the printed medium.
The component 402 of the inflowing airflow acts towards the center side in the array direction of the ejection openings and the component 403 acts towards the end portion side in the array direction. With the above, by setting the arrangement intervals of the ejection openings in the end portion area of the ejection opening row on the downstream side of the recording element substrates 10a that is on the upstream side in the relative movement direction larger than the arrangement intervals of the ejection openings in the end portion area of the ejection opening row on the upstream side of the recording element substrate 10b that is on the downstream side in the relative movement direction, the deviation in the landing position of the droplet can be suppressed.
In the above description, description was given using the page wide type liquid ejection head, but the present disclosure is not limited to the page wide type liquid ejection head. In other words, the present disclosure can also be applied to a so-called serial-type liquid ejection head which performs recording while reciprocating in the width direction of printed medium. In the serial type liquid ejection head, in a case in which a plurality of ejection opening rows are provided side by side in the movement direction relative to the printed medium, in other words, in a case in which a plurality of ejection opening rows are disposed side by side in the reciprocating direction, the effect of suppressing the influence of the inflowing airflow on the ejected droplet is large when the configuration of the present disclosure is used.
According to the present disclosure, deviation of the landing position of the droplet caused by the inflowing airflow which is generated when the liquid ejection head is used can be suppressed, and a high quality print image can be obtained at a high speed.
While the disclosure has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2018-073919, filed Apr. 6, 2018, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2018-073919 | Apr 2018 | JP | national |