1. Field of the Invention
The present invention relates to a method for manufacturing an ink jet recording head used in a recording apparatus that performs a recording operation by discharging ink or the like.
2. Description of the Related Art
Ink jet recording apparatuses (hereinafter, referred to as “recording apparatus”) as one type of a recording apparatus are broadly used for an output apparatus connected to a computer and the like and are commercialized. Recently, in order to perform high image-quality recording at higher speed, an ink jet recording head (hereinafter, referred to as a “recording head”) having a longer recording width is desirable.
As a general recording apparatus, there is widely known a type in which a recording head having discharge ports used for discharging ink performs recording by scanning a recording medium such as a paper sheet while discharging ink. In addition, in the case of a head having a long recording width, there is also known a recording apparatus that can perform recording at high speed by fixing a recording medium on a conveying belt and scanning the recording medium.
In order to configure the recording head having a long recording width as above by using one recording element substrate, the recording element substrate needs to be formed to be long. However, in such a case, there is a very high likelihood that defective products are produced. This leads to a decrease in a yield of the recording element substrate and the like. Accordingly, a configuration is considered in which a recording head having a long recording width as a whole is realized by arranging a plurality of recording element substrates having an appropriate length (that is, an appropriate number of nozzles) on a support substrate having a length that is equal to or greater than the recording width.
However, when the support substrate is formed to be long, a warped state or undulation of the support substrate may occur. When the recording element substrates are fixed along the support substrate surface, the ink discharging direction is changed for each recording element substrate, whereby the precision of landing of ink decreases. In addition, when there is a variation in the thicknesses of the recording element substrates, a distance from a discharge port to a recording medium varies depending on each recording element substrate, whereby the precision of landing of ink decreases.
Thus, in Japanese Patent Application Laid-Open No. 2006-256051, a configuration is proposed in which surfaces forming ink discharge ports of the recording element substrates are made flush with each other by variation of the thickness of an adhesive that bonds a support substrate and the recording element substrate for each recording element substrate. In FIG. 3A of Japanese Patent Application Laid-Open No. 2006-256051, recording head units (recording element substrates) are bonded and fixed to a long substrate (support substrate) with the adhesive. Even when a warped state of the long substrate occurs or there is a variation in the thicknesses of the recording head units, the discharge port forming surfaces are made flush with each other by changing the thickness of the adhesive beneath each recording head unit.
However, in the above-described technique, there are the following problems.
In the method disclosed in Japanese Patent Application Laid-Open No. 2006-256051, in a case where an electricity-heat transducing element is used as an element that generates energy used for discharging ink, when the heat generated for discharging the ink conducts the support substrate, heat conduction differs depending on a difference in the thickness of the adhesive for each recording element substrate. In other words, the heat dissipating characteristics are different for each recording element substrate. As a result, the amount of discharged ink or the discharge speed of ink differs for each recording element substrate, whereby the recording quality is lowered.
A method for manufacturing an ink jet recording head according to this embodiment includes measuring heights of a main surface of a support substrate at least at three measurement points, and setting a reference surface that passes through two measurement points of the main surface out of the measurement points. The method further includes acquiring a distance from the measurement point that is not included in the two measurement points in the reference surface to the reference surface. It is assumed that the recording element substrates are arranged at a plurality of arrangement portions disposed on the support substrate, and the recording medium is arranged in parallel to the reference surface, at a predetermined distance from the reference surface. Under the assumption, the method further includes calculating an amount of landing deviation that is a difference between a position at which a line extending from the recording element substrate in a direction perpendicular to the reference surface intersects a recording medium and a position at which a line extending in a direction to which an ink discharge port of the recording element substrates face is directed intersects the recording medium. Furthermore, the method yet further includes determining arrangement positions of the recording element substrates on the support substrate by correcting the positions of the arrangement portions according to the amounts of landing deviation.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Hereinafter, embodiments will be described with reference to the accompanying drawings. In the accompanying drawings, the same reference numeral is assigned to configurations having the same function, and the description thereof may not be repeatedly made.
Preferred embodiments of the present invention will now be described in detail according to the accompanying drawings.
A plate stand 2 of the shape measuring apparatus, on which a support substrate 1 as a measuring object is mounted, is mounted on a stage 4 and is movable in the longitudinal directions (the directions of arrows illustrated in the figure) of the support substrate 1. In addition, a relief hole 7 is formed in the plate stand 2. Above the position located on the plate stand 2 in which the support substrate 1 is arranged, a displacement sensor 5 is disposed and is supported by a supporting means not illustrated in the figure.
First, the shape of the support substrate is measured in step S101. Step S101 will now be described with reference to
The support substrate 1 is placed on the plate stand 2, with a recording element substrate bonding surface 6 as a first main surface facing up. The surface 13 of the support substrate 1 on the opposite side of the recording element substrate bonding surface 6 is a second main surface. In addition, at both ends of the support substrate 1, bolt holes 3 used for fixing a recording head to a recording apparatus are formed at four places. The shape of the support substrate 1 may not be flat but be bent more or less in the thickness direction. As described above, the relief hole 7 is formed in the plate stand 2. Accordingly, even when the support substrate 1 is warped to protrude toward the plate stand 2 side, the support substrate 1 is stable on the plate stand 2.
Next, the positions for measuring the shape of the support substrate 1 will be described. In the recording head according to this embodiment, a plurality of recording element substrates, and more specifically, ten recording element substrates are assumed to be arranged on one support substrate 1.
Here, the arrangement portions 8a to 8j will be described in detail. One corner (the left end in
When the stage 4 is scanned so that the sensing position of the displacement sensor 5 becomes each of the measurement points, that is, it becomes each of the positions A1 to A10, B1 to B10, and C1 to C10, a distance from the displacement sensor 5 to each position on the recording element substrate bonding surface 6 is measured for each position. Then, a distance from the displacement sensor 5 to the upper face of the plate stand 2 is measured. The height of the recording element substrate bonding surface 6 can be acquired from a difference between both the measured values.
When the support substrate 1 is approximately flat in the entire area of the support substrate 1 and has no roughness, the surface 13 (the second main surface) located on the opposite side of the recording element substrate bonding surface 6 may be measured by mounting the support substrate 1 upside down.
Next, the thicknesses of the recording element substrates 9a to 9j are measured in step S102. Step S102 will be described with reference to
As described above, in this embodiment, since ten recording element substrates 9 are arranged on one support substrate 1, the thicknesses of all the ten recording element substrates 9 are measured. Here, a recording element substrate arranged in the arrangement portion 8a illustrated in
In a case where a plurality of recording elements is formed on one silicon substrate using photolithography technique and is cut out into a plurality of the recording element substrates 9, the thicknesses of the recording element substrates 9 acquired by being cut out from the same silicon substrate are approximately uniform. Thus, in a case where all the recording element substrates 9 arranged on one support substrate 1 are acquired by being cut out from the same silicon substrate, measurement of the thicknesses of the individual recording element substrates 9 can be omitted. In such a case, designed thicknesses of the recording element substrates 9 may be used as the thicknesses Ta to Tj of the recording element substrates 9.
Next, an imaginary reference surface is set in step S103. Step S103 will be described with reference to
Next, a control device not illustrated in the figure calculates the slope of the arrangement portions 8a to 8j in step S104. Step S104 will be described with reference to
First, calculation of the slope of the arrangement portion 8a of the recording element substrate 9 that is located closest to the base point S will be described.
Next, the amounts of warped states of the arrangement portions 8a to 8j are calculated in step S105. Step S105 will be described with reference to
Next, the amount of deviation of landing of ink is calculated in step S106. Step S106 will be described with reference to
The discharge direction of ink is a direction to which the discharge port is directed, that is, a direction deviated from a direction perpendicular to the reference surface 20 by the slope θ of the arrangement portion that is calculated in step S104. Accordingly, the landing position of an ink droplet discharged from each recording element substrate 9 is deviated from the landing position of the ink droplet in a case where there is no warpage (slope θ), that is, a position (predetermined position) at which a line extending from the recording element substrate 9 in a direction perpendicular to the reference surface 20 intersects the recording medium 31. The calculation of the amount X of deviation of landing can be performed through the following equation.
Amount of Deviation of Landing X=(K+R−T−t)×tan θ
Here, K is a distance between the reference surface and a recording medium.
R is the amount of the warped state of the recording element substrate arrangement portion that is calculated in step S105.
T is the thickness of the recording element substrate that is measured in step S102.
t is the thickness of an adhesive.
θ is the slope of the recording element substrate arrangement portion that is calculated in step S104.
The amounts of deviation of landing, which are calculated for the recording element substrates 9a to 9j by using the above-described equation, are denoted by Xa to Xj. In a case where the sign of the amount X of deviation of landing is positive, the landing position is deviated from the center position C of the recording element substrate arrangement portion 8 to the opposite side of the base point S (the right side in the figure). On the other hand, in a case where the sign of the amount X of deviation of landing is negative, the landing position is deviated from the center position C to the base point S side (the left side in the figure).
When the support substrate is in a shape that is convex downward as in
Finally, the actual arrangement positions 8a′ to 8j′ of the recording element substrates 9a to 9j are calculated in step S107. Step S107 will be described with reference to
A recording operation using a recording head that is manufactured by bonding and fixing the recording element substrates 9a to 9j at the actual arrangement positions 8a′ to 8j′ corrected in the above-described step can be performed well without being influenced by the warping of the support substrate 1, variations in the thicknesses of the recording element substrates 9a to 9j, and the like. Accordingly, a high recording quality can be realized.
According to general technique, since the thickness of an adhesive that bonds each recording element substrate to the support substrate is not uniform, heat conductivity differs for each recording element substrate. However, according to this embodiment, since the thickness t of the adhesive bonding each recording element substrate 9 to the support substrate 1 can be formed to be uniform, the heat conductively for each recording element substrate can be uniform.
A method for manufacturing an ink jet recording head according to a second embodiment will now be described. The second embodiment is the same as the first embodiment illustrated in the flowchart illustrated in
Since the diagrams referred to for describing the shape measuring step S101 for a support substrate according to this embodiment are the same as illustrated in
Next, the method for interpolating the heights of the places at which the heights are not measured will be described with reference to
This method is effective in shortening the time required for the measurement process in a case where the behavior of the warping of the support substrate 1 is in a relatively simple shape such as that when there is only one local maximum point or one local minimum point. In step S102 and steps subsequent to step S102, the same as that of the first embodiment is performed, whereby excellent recording may be performed.
In this embodiment, the heights of three places are measured, and the heights of other places are acquired from the graph. The number of the measurement points at which the heights are measured may be three or more. As the number of the measurement points at which the heights are measured increases, the accuracy and precision in measurement further improves.
A method for manufacturing an ink jet recording head according to a third embodiment will now be described. The third embodiment is the same as the first embodiment illustrated in the flowchart illustrated in
In this embodiment, when the shape of the support substrate 1 is measured, the measurement operation is performed in the same state in terms of the recording head, that is, in the state in which the recording head of the recording apparatus performs a recording operation. The measurement of the shape of the support substrate 1 according to the first embodiment is performed in the state in which the support substrate 1 is placed on the plate stand 2 at the ambient temperature (about 25° C.) at which the recording head is manufactured. When a recording operation is actually performed by using the recording head, the recording head is fixed to a head mounting portion of the recording apparatus by inserting and fastening bolts into bolt holes 3 formed on both ends of the support substrate 1. In addition, when the recording operation is performed, ink is used while it is kept warm at 35° C. Thus, in this embodiment, in order to measure the shape of the support substrate 1 in the same state as that under the ambient temperature of the actual use, both ends of the support substrate 1 are fixed by using the bolts, and the shape is measured at the ambient temperature of 35° C. The necessity thereof will be described below.
Thus, in the shape measuring step S101 for the support substrate 1 according to this embodiment, the entire shape measuring apparatus for the support substrate 1 that is illustrated in
In this embodiment, since the installation of the recording head to the recording apparatus is achieved by the fixing of both ends of the support substrate with bolts, fixation at the time of measurement is similarly performed. However, the invention is not limited thereto. Thus, it is important to perform a measurement operation by using the same method as that used for installing the recording head to the recording apparatus or a method similar thereto.
A method for manufacturing an ink jet recording head according to a fourth embodiment will now be described. The fourth embodiment is the same as the first embodiment illustrated in the flowchart illustrated in
In this configuration, the arrangement portions 8a to 8j are arranged such that, the end portion A1, located on the base point S side, of the arrangement portion 8a is located at a position distanced from the center of the positioning pin 51 located on one corner (the left side in
In the shape measuring step S101 for the support substrate 1 according to this embodiment, similarly to the method used for mounting the recording head on the recording apparatus, both ends of the support substrate 1 and the fixing stand 50 are fixed with bolts, and the heights of the arrangement portions 8a to 8j are measured by using a measurement device having the same configuration as that illustrated in
Next, the reference surface setting step S103 according to this embodiment will be described with reference to
Here, step S102 of measuring the thicknesses of the recording element substrates, step S104, and steps subsequent to step S104 are the same as those of the first embodiment. By performing such steps, excellent recording can be performed even when the portion used for determining the position at the time when the recording head is mounted on the recording apparatus is spaced apart from the recording element substrate.
A fifth embodiment will now be described. In the first to fourth embodiments, the landing positions are calculated without actually discharging ink. However, in this embodiment, based on a result of actual discharging of ink, the arrangement positions of the recording element substrate that is manufactured thereafter are corrected. Hereinafter, detailed description will be followed with reference to drawings. When the same configuration as that of the first embodiment is denoted, the same reference numeral as that of the first embodiment will be used.
The flowchart of a method for manufacturing a recording head according to this embodiment is illustrated in
First, a recording head used for checking a landing position is manufactured in step S501. Step S501 will now be described. By arranging recording element substrates 9a to 9j at predetermined positions on a support substrate 1, the manufacturing of the recording head is completed. Here, the predetermined positions are the predetermined positions illustrated in
Next, the landing positions are measured in step S502. Step S502 will now be described. In step S502, the recording head manufactured in step S501 is mounted on a recording apparatus, and ink is actually discharged from all the discharge ports onto a recording medium.
Next, the correction positions of the recording element substrates 9a to 9j are calculated in step S503. This step will now be described. In this embodiment, a method for correcting the positions of the arrangement portions 8b to 8j with the position of the arrangement portion 8a being fixed will be described. However, for example, the positions of the arrangement portions 8a to 8d and 8f to 8j may be corrected by using the arrangement portion 8e located near the center as a reference.
First, in order to calculate the corrected position of the arrangement portion 8b, the amount Δab of deviation of the gap Dab between landing dots from the constant gap D is calculated. As a result, when Δab is “0,” the arrangement portion 8b is maintained at the current position without any change. When Δab is a positive value, the arrangement portion 8b is placed closer to the arrangement portion 8a by Δab. In contrast, when Δab is a negative value, the arrangement portion 8b is separated away from the arrangement portion 8a by Δab. The position calculated as above is set as the position of the arrangement portion 8b after correction.
Next, the corrected position of the arrangement portion 8c is calculated. Here, as the distance compared with the constant gap D, a value acquired by adding the correction amount Δab of the arrangement portion 8b calculated in advance to Dbc measured in step S502 is used as Δbc. Then, similarly to the above-described step, the corrected position of the arrangement portion 8c is calculated. As a result, when Δbc is “0,” the arrangement portion 8c is maintained at the current position without any change. When Δbc is a positive value, the arrangement portion 8c is placed closer to the arrangement portion 8b by Δbc. In contrast, when Δbc is a negative value, the arrangement portion 8c is separated away from the arrangement portion 8b by Δbc. Thereafter, by using the same method, the corrected positions of the arrangement portions 8d to 8j are calculated.
Then, when the recording element substrates are arranged at the positions after correction in a recording head manufactured thereafter, the gaps between landing dots formed by ink discharged from the recording element substrates 9a to 9j can be configured as the constant gap D, whereby excellent recording can be acquired.
Since only the recording head used for checking landing positions need to be measured, this embodiment is advantageous in terms of time in a case where the individual variation in the shape and the deformation of the support substrate 1 is small.
While the present invention 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. 2010-060846, filed Mar. 17, 2010, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2010-060846 | Mar 2010 | JP | national |
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Number | Date | Country | |
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20110225824 A1 | Sep 2011 | US |