JP3678890B2 - Droplet ejection speed measurement system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a droplet ejection speed measurement system for measuring the velocity of a droplet ejected from a nozzle hole, which can measure the droplet velocity with high accuracy with a simple configuration.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, an ink jet printer that forms an image by causing ink droplets (droplets) to fly is known. This ink jet printer lands an image by landing ink droplets ejected from nozzle holes of a printer head on a paper surface. The image quality evaluation items include dot density, dot position accuracy, density unevenness, and sharpness.
[0003]
The dot density, which is one of the quality items, is generally about 300 DPI, but in order to increase the resolution and form a high-quality image, the dot pitch and the dot diameter are set small. The dot density is increased to 400 DPI, 600 DPI, or the like. This dot diameter is proportional to the volume of the ink droplets ejected from the printer head, and the dot diameter increases as the ejection speed of the ink droplets increases.
[0004]
Further, as shown in FIG. 10, since the printer head 1 moves in the main scanning direction with respect to the paper surface and moves the paper surface in the sub-scanning direction to form an image as shown in FIG. It is possible to evaluate the components separately (Δx, Δy). This dot position accuracy is due to both the mechanical accuracy of the printer main body (not shown) and the printer head 1 and the ejection speed accuracy of the ink droplet 5 ejected from the nozzle hole 2 of the printer head 1, and the mechanical accuracy is While the error is relatively small, the accuracy of the ejection speed of the ink droplet 5 greatly affects. The ejection speed accuracy of the ink droplet 5 greatly contributes to the particle formation characteristics of the ink, and errors due to the ejection speed of the ink droplet 5 depend on the processing accuracy and quality of the nozzle hole 2 except for disturbances such as dust. Appear only in the main scanning direction (Δy). Since the allowable value of dot position deviation in this dot position accuracy is usually about 1/4 to 1/2 of the pitch between dots, this allowable value is a very severe value. For example, in the case where the dot position accuracy is 1/3 of the inter-dot pitch under the conditions that the dot density is 300 DPI, the drive frequency for ejecting the ink droplet 5 is 5 kHz, and the distance from the bottom surface of the printer head 1 to the paper surface is 1 mm. The allowable width is 50 mm / sec.
[0005]
As described above, in order to obtain a high-resolution image, it is necessary to measure and control the volume and ejection speed accuracy of the ejected ink droplet 5 with high accuracy.
[0006]
[Problems to be solved by the invention]
However, in such conventional image quality evaluation, after the printer head 1 is assembled to the printer main body, ink droplets 5 are ejected onto the paper surface to perform printing, and the dot density and dot position by the ink droplets 5 are printed. By measuring the accuracy, the speed of the ink droplets 5 ejected with the set volume was indirectly evaluated.
[0007]
However, in this method, errors due to the surface properties of the paper when it is printed on the paper surface, blurring, paper wrinkles, and the like are greatly affected. Therefore, only the ejection speed accuracy of the ink droplet 5 is measured and the printer head 1 alone is measured. The performance evaluation cannot be performed. Further, in this method, since the volume and ejection speed of the ink droplet 5 cannot be disassembled and measured, the adjustment of the mechanical accuracy of the printer main body and the accuracy of the volume and ejection speed of the ink droplet 5 is made by trial and error. There was no choice but to adjust.
[0008]
As a method for solving this problem, instead of evaluating the performance of the printer head 1 based on the image printed by ejecting the ink droplets 5 on the paper surface, a device that directly measures the flying ink droplets 5 in the air is used. Can be considered. As a method of measuring the speed of the droplet (ink droplet) flying in the air, the ink droplet 5 is moved by irradiating the flying ink droplet 5 with a laser beam and utilizing the Doppler effect of the laser beam. There is a so-called laser Doppler method for measuring the speed at which the printer head 1 is measured, and it is conceivable to use a velocimeter employing this method for performance evaluation of the printer head 1 alone.
[0009]
However, an anemometer using this laser Doppler is expensive and, as described above, the allowable width of the ejection speed required when forming an image with a dot density of 300 DPI is 50 mm / sec. The measurement accuracy is about ± 100 mm / sec and cannot be measured with high accuracy.
Accordingly, the present invention is to realize a system for measuring the velocity of the droplets flying through the air directly, for example, thereby enabling the performance evaluation in the printer head single-in click-jet printer, easily performs adjustment The purpose is to get. It is another object of the present invention to provide a system that is excellent in low cost and versatility by allowing the droplet flying speed to be easily measured with a simple configuration.
[0010]
[Means for Solving the Problems]
In order to achieve the above object, the invention described in claim 1 is a droplet ejection velocity measuring system for measuring a velocity of a droplet ejected from a nozzle hole, and illuminates the droplet ejected from the nozzle hole. An imaging means for illuminating the image by illuminating the liquid crystal, a position specifying means for specifying the position of the liquid droplet from a reference position in the video imaged after a predetermined time has elapsed from the ejection, a position of the nozzle hole and an image Calculating means for calculating the velocity of the droplet whose position from the reference position is specified based on the positional relationship between the reference position and the imaging means, the nozzle hole and the droplet from the droplet ejection direction side. By setting the imaging direction obliquely with respect to the ejection direction so that the image can be captured simultaneously, the position identifying means identifies the position in the image of the droplet ejected from the nozzle hole and captured, and the position of the nozzle hole Special position in the video And said calculating means is one which is characterized that you calculate the velocity of the droplets on the basis of the positional relationship between the nozzle hole and droplets in the images that are identified.
[0011]
According to the first aspect of the present invention, the position from the reference position in the image of the droplet imaged when a fixed time has elapsed from the ejection of the nozzle hole is specified, and the positional relationship between the nozzle hole and the reference position in the image The velocity of the droplet is calculated based on Therefore, it is possible to measure the velocity of the droplet ejected from the nozzle hole with high accuracy .
[0012]
Furthermore , the nozzle hole and the droplet are imaged simultaneously by imaging from the oblique direction with respect to the ejection direction, and the velocity of the droplet is calculated based on the positional relationship between the nozzle hole and the droplet in the specified image. The Therefore, it is possible to omit the positioning and measurement of the nozzle hole with respect to the reference position in the video with high accuracy.
[0013]
According to a second aspect of the present invention, in addition to the configuration of the first aspect of the invention, the calculation means also calculates the volume of the droplet from the image of the droplet imaged by the imaging means. It is what.
According to the second aspect of the invention, the volume of the droplet is calculated from the image of the droplet in addition to the speed and the ejection direction. Therefore, the ejection characteristic of the droplet can be measured with high accuracy.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
The present invention will be described below with reference to the drawings.
1 to 6 are views showing a first embodiment of a droplet ejection velocity measuring system according to the present invention, and this embodiment corresponds to the invention described in claims 1 and 2 .
First, the configuration will be described.
[0015]
In FIG. 1 and FIG. 2, the droplet ejection speed measurement system is constructed so as to evaluate the characteristics of the printer head 1 that ejects ink droplets 5 from the nozzle holes 2 when an inkjet printer forms an image. An illumination lamp (illuminating means) 11 that irradiates light onto the ink droplets 5 ejected from the printer head 1, a CCD camera (imaging means) 12 that images the ink droplets 5 ejected from the printer head 1, and a captured image The image processing device 13 that captures the image and processes the image, and the calculation device 14 that calculates the ejection characteristics of the ink droplet 5 based on the result of the image processing are provided.
[0016]
The illumination lamp 11 and the CCD camera 12 are connected to the head gripping member 4 so that the nozzle surface 3 in which the nozzle holes 2 are formed above the surface of the paper to be conveyed is spaced apart at a height h of about 1 mm. 1 is mounted and fixed so that a position below the nozzle surface 3 that is the position of the paper surface by a distance h is imaged from the lateral direction, and is positioned in one of the X-axis and Y-axis directions shown in FIG. The illumination direction and the imaging direction are arranged to coincide with each other. For this reason, as shown in FIG. 3, in the imaging screen W by the CCD camera 12, the position of the paper surface that is separated from the nozzle surface 3 of the printer head 1 by the distance h is the center C in the vertical direction, and the position of the nozzle hole 2 is It is set to be the center C in the horizontal direction.
[0017]
The illumination lamp 11 and the CCD camera 12 face each other with the nozzle hole 2 positioned therebetween, and the CCD camera 12 emits light from the illumination lamp 11 that illuminates the ink droplet 5 ejected from the nozzle hole 2. It is arranged to take in directly. For this reason, the CCD camera 12 captures an image in which the periphery of the ink droplet 5 is white with high luminance, and the ink droplet 5 itself is black with low luminance in the light-shielded portion, regardless of the color of the ink droplet 5 or the background. To do.
[0018]
For example, when forming an image with a dot density of 300 DPI, the image processing apparatus 13 drives the printer head 1 at a driving frequency of 5 kHz to eject ink droplets 5 from the nozzle holes 2. In order to measure the characteristics of the ink droplet 5 at the position, the timing at which the ink droplet 5 reaches the center in the imaging screen W shown in FIG. The illumination lamp 11 is made to flash in synchronization with the timing), and when the image of the CCD camera 12 imaged at that timing is processed and the center C in the video screen is set as the origin (reference position) The position coordinate (Δz) of the center of the ink droplet 5 is specified, and the diameter D of the ink droplet 5 is specified. That is, the image processing device 13 constitutes a position specifying unit. For example, the illumination lamp 11 emits strobe light at a specific frequency such as 1 kHz, and uses the image of the CCD camera 12 imaged at the timing when the ink droplet 5 reaches the center in the imaging screen W shown in FIG. You may do it.
[0019]
The calculation device 14 receives the position coordinates (Δz) of the ink droplet 5 with respect to the center C in the video screen and the diameter D of the ink droplet 5 from the image processing device 13, and the volume and ejection speed of the ink droplet 5 according to the calculation formula described later. The ejection characteristics in the ejection direction are calculated, and the CCD camera 12 has a normal imaging magnification of about 10 μm and a pixel length of about 10 μm. By setting the degree, the measurement accuracy of the injection speed is set to be ± 20 mm / sec. The distance h (distance h to the paper surface) from the nozzle surface 3 (nozzle hole 2) of the printer head 1 used for this calculation processing is measured and set in advance. The distance h may be measured by actually processing the image captured by lowering the magnification so that the nozzle surface 3 of the printer head 1 enters the imaging screen W by the CCD camera 12 and measuring the distance h. Further, the distance h to the center C in the imaging screen W may be measured by bringing the scale into contact with the nozzle surface 3, or may be measured by a non-contact type laser displacement meter in the same manner.
[0020]
The illumination lamp 11 emits strobe light in synchronization with the timing when the ink droplet 5 reaches the center C in the imaging screen W shown in FIG. 3, but the CCD camera 12 like the ink droplets 5a and 5b shown in FIG. May be misaligned from the imaging screen W, or may result in erroneous measurement due to an image of the ink droplet 5 that is not measured symmetrically. For this reason, while observing the imaging screen W before the measurement is started, the timing (the delay time from ejection) of the illumination lamp 11 is changed to change the timing change time and the ink droplet 5 to be imaged. It is possible to prevent erroneous measurement by temporarily calculating the velocity of the ink droplet 5 from the displacement amount of the position. Further, it is possible to prevent the dust that does not change the imaging position even when the strobe emission timing of the illumination lamp 11 is changed from being erroneously specified as the ink droplet 5.
[0021]
Next, measurement of the ejection characteristics of the ink droplets 5 ejected by the printer head 1 will be described using the flowchart shown in FIG. The illumination lamp 11 and the CCD camera 12 are set so that the distance h from the nozzle surface 3 to the center C of the imaging screen W is approximately 1 mm when the printer head 1 is attached to the head gripping member 4.
[0022]
First, the printer head 1 is set on the head gripping member 4 (step P1), the distance h from the center C in the imaging screen W of the CCD camera 12 that has started imaging to the nozzle surface 3 is measured, and the distance h is calculated. Settings are input from an operation unit (not shown) of the arithmetic unit 14 (step P2).
Next, the printer head 1 is driven to start the ejection of the ink droplet 5, and after a time until the ejection is stabilized, the printer head 1 is delayed for a certain time from the ejection of the ink droplet 5, and the image in the imaging screen W shown in FIG. The illumination lamp 11 is driven so that the strobe light is emitted at the timing when the ink droplet 5 reaches the center, and whether the ink droplet 5 is measured symmetrically (whether the ejection of the ink droplet 5 and the strobe light emission are synchronized). Confirm (step P3).
[0023]
Next, imaging of the ink droplet 5 is started (step P4), and after one or several images are captured, the ejection of the ink droplet 5 is stopped (step P5). It should be noted that the number of imaging of the ink droplets 5 may be made plural when the measurement accuracy is increased, and the image processing results may be averaged. The ejection of the ink droplets 5 of the printer head 1 does not vary greatly. It may be calculated only from the image processing result.
[0024]
Thereafter, the volume / ejection speed of the ink droplet 5 is calculated and the ejection characteristics are measured (step P6). After confirming that no error has occurred in the imaging or computation processing after the computation processing is completed, the printer head 1 is removed from the head gripping member 4 (step P7), and this process ends.
In step P6, the ejection characteristics are measured by receiving the diameter D of the ink droplet 5 and the position coordinate (Δz) with respect to the center C in the imaging screen W, which are specified by the arithmetic processing unit 14 performing image processing from the image processing unit 13. The measurement accuracy at this time depends on the measurement accuracy of the apparatus, and is about ± 3 μm and ± 20 mm / sec.
[0025]
Specifically, the volume V of the ink droplet 5 is calculated as follows using the diameter D of the ink droplet 5 specified from the imaging screen W of the CCD camera 12 shown in FIG.
V = πD ^3/6
Further, the ejection speed S of the ink droplet 5 uses the ejection distance L and the delay time T from ejection determined from the position coordinates (Δz) of the ink droplet 5 specified from the imaging screen W of the CCD camera 12 shown in FIG. And is calculated as follows.
[0026]
L = h−Δz
S = (h−Δz) / T
Accordingly, the volume V of the ink droplet 5 can be measured with a measurement accuracy of about ± 3 μm, and the ejection speed can be measured with a measurement accuracy of ± 20 mm / sec. For example, the ejection speed required when forming an image with a dot density of 300 DPI The allowable width (50 mm / sec) can be sufficiently satisfied.
[0027]
As described above, in the present embodiment, the ink droplet 5 ejected from the nozzle hole 2 of the printer head 1 is imaged and processed at the timing when it reaches the position on the paper surface, and the diameter D of the ink droplet 5 is displayed in the imaging screen W. By determining the position coordinate (Δz) from the center C of the ink, the volume V is calculated from the diameter D of the ink droplet 5, and the positional relationship between the ink droplet 5, the center C of the imaging screen W and the nozzle hole 2 The ejection speed S can be calculated, and the ejection characteristics of the printer head 1 can be measured with high accuracy for each element.
[0028]
Further, since the illumination light from the illumination lamp 11 that is blocked by the ink droplet 5 is taken in and an image of the ink droplet 5 is captured, the ink droplet 5 is not indistinguishable from the surrounding color, and the ink The image can be taken regardless of the color.
Therefore, a system for confirming the ejection characteristics of the printer head 1 is constructed at low cost by the illumination lamp 11, the CCD camera 12, the image processing device 13, and the arithmetic device 14 for inspection in the production line of the ink jet printer. Can be used.
[0029]
Next, FIG. 7 to FIG. 9 are views showing a second embodiment of the droplet ejection velocity measuring system according to the present invention, and this embodiment corresponds to the inventions described in claims 1 and 2 . In addition, since this embodiment is comprised substantially the same as the said 1st Embodiment, it attaches | subjects and demonstrates the same code | symbol to the same structure.
This embodiment is constructed by the illumination lamp 11, the CCD camera 12, the image processing device 13, and the arithmetic device 14 as in the above-described embodiment, but as shown in FIG. The CCD camera 12 has an illumination direction with respect to the nozzle surface 3 so that both the ink droplet 5 located at a distance h of approximately 1 mm from the nozzle surface 3 and the nozzle hole 2 of the nozzle surface 3 can be captured in the imaging screen W. The sandwich angle (elevation angle) in the imaging direction is set to 10 degrees and is fixedly positioned.
[0030]
Here, the nozzle surface 3 of the printer head 1 is generally water-repellent, and constitutes a reflective surface that efficiently reflects the illumination light of the illumination lamp 11. For this reason, the CCD camera 12 takes in the illumination light from the illumination lamp 11 reflected by the nozzle surface 3, and is not reflected by the nozzle hole 2 and from the illumination lamp 11 shielded by the ink droplet 5. The illumination light is captured, and an image in which both the ink droplet 5 and the nozzle hole 2 are captured can be captured in the imaging screen W as shown in FIG.
[0031]
Therefore, the image processing device 13 is configured to display the image on the imaging screen W from the image of the CCD camera 12 captured by the illumination lamp 11 strobe light in synchronization with the timing when the ink droplet 5 reaches the position (distance h) on the paper surface. While the nozzle 14 and the position of the ink droplet 5 are specified, the calculation device 14 receives the position coordinates of the specified nozzle hole 2 and the ink droplet 5 and the volume / ejection of the ink droplet 5 according to the above-described calculation formula. The injection characteristics in the speed / injection direction can be calculated. Further, when the nozzle surface 3 is subjected to water repellent treatment, it is not preferable to measure the position of the nozzle hole 2 by directly contacting the surface, and it is difficult to measure with high accuracy using a non-contact type laser displacement meter. In this embodiment, the nozzle hole 2 can be imaged in a setting state in which the ink droplet 5 is imaged. However, in this embodiment, the actual measurement for each set of the printer head 1 takes time. The position coordinates can be specified in advance or simultaneously with the imaging of the ink droplet 5 and used for the calculation. If the position measurement error is ± 1 μm, the injection speed measurement error is ± 6.7 mm / sec.
[0032]
However, since the CCD camera 12 images the nozzle surface 3 at an elevation angle of 10 degrees, as shown in FIG. 9, the ejection distance L of the ink droplet 5 in the Z-axis direction is reduced and measured at the ejection distance L2. However, the elevation angles of the illumination lamp 11 and the CCD camera 12 are set to 10 degrees so that the measurement error due to the reduction falls within the required measurement accuracy range. Needless to say, the accurate injection distance L may be obtained by correcting the injection distance L2 in the Z-axis direction in order to measure with higher accuracy.
[0033]
As described above, in the present embodiment, in addition to the operational effects of the above-described embodiment, the nozzle hole 2 and the ink droplet 5 are simultaneously imaged from the oblique direction, and the ink droplet 5 to the nozzle hole 2 specified in the imaging screen W is captured. The jetting speed and jetting direction can be calculated from the position coordinates, and positioning and measurement of the nozzle hole 2 of the printer head 1 with high accuracy can be omitted. Therefore, the ejection characteristics of the printer head 1 can be measured more easily and easily.
[0034]
【The invention's effect】
According to the first aspect of the present invention, the droplet is ejected from the nozzle hole and a position when the fixed time has elapsed is imaged to identify the position from the reference position, and the positional relationship between the nozzle hole and the droplet with respect to the reference position is determined. since calculating the velocity of the droplets can be directly measured with high accuracy without being affected injection speed of droplets ejected from the nozzle holes by other factors. Thus, for example, can be performed by measuring the ejection velocity of the ink droplets ejected from the printer head in click-jet printers, particularly facilitates the accurate adjustment of the dot position accuracy. In addition, since the imaging of the droplets and the calculation of the speed thereof are possible with a simple configuration, for example, it is possible to make the system excellent in low cost and versatility that can be used for inspection in a production line. .
[0035]
Furthermore , since the nozzle holes and droplets can be imaged simultaneously from an oblique direction, the velocity of the droplets can be easily calculated from the positional relationship with the nozzle holes without positioning and measuring the nozzle holes with respect to the reference position in the image. be able to. Accordingly, more easily injection speed of droplets ejected from the nozzle holes, and can be easily measured, it is possible to further improve the versatility it is possible to further reduce costs.
[0036]
According to the second aspect of the present invention, since the volume of the droplet is also calculated from the captured image of the droplet, the ejection characteristics of the droplet ejected from the nozzle hole are not affected by other factors. Direct measurement with high accuracy. Thus, for example, it is possible to measure the injection characteristics obtained by adding the volume of the ink droplets ejected from the printer head in click-jet printer, the performance evaluation of the more precise adjustment and printer heads. In addition, since the volume of the droplet can be calculated with a simple configuration, it can be optimally used for inspection in the production line, and the system can be made excellent in low cost and versatility.
[Brief description of the drawings]
FIG. 1 is a diagram showing a first embodiment of a droplet ejection velocity measuring system according to the present invention, and is a conceptual diagram showing a schematic overall configuration thereof.
FIG. 2 is a side view illustrating imaging of the droplet.
FIG. 3 is a conceptual diagram illustrating the positional relationship of the imaging screen.
FIG. 4 is a conceptual diagram illustrating the adjustment before the start of measurement.
FIG. 5 is a flowchart for explaining the measurement.
FIG. 6 is a conceptual diagram illustrating the calculation process.
FIG. 7 is a diagram showing a second embodiment of the droplet ejection velocity measuring system according to the present invention, and is a side view showing the configuration of the main part thereof.
FIG. 8 is a conceptual diagram for explaining characteristics of imaging of the droplet.
FIG. 9 is a conceptual diagram for explaining the characteristics of arithmetic processing by imaging the droplet.
FIG. 10 is a perspective view illustrating a printer head that ejects droplets.
[Explanation of symbols]
1 Printer head 2 Nozzle hole 3 Nozzle surface 5 Ink droplet (droplet)
11 Lighting lamp (lighting means)
12 CCD camera (imaging means)
13 Image processing device (position identification means)
14 Arithmetic unit (calculation means)

Claims (2)

A droplet ejection velocity measuring system for measuring a velocity of a droplet ejected from a nozzle hole,
An imaging unit that illuminates a droplet ejected from a nozzle hole with an illuminating unit and images the droplet, and specifies a position of the droplet from a reference position in an image captured when a certain time has elapsed since ejection A position specifying means; and a calculating means for calculating the velocity of the droplet whose position from the reference position is specified based on the positional relationship between the position of the nozzle hole and the reference position in the image ,
By setting the imaging direction obliquely with respect to the ejection direction so that the imaging means can simultaneously image the nozzle hole and the droplet from the ejection direction side of the droplet,
The position specifying means specifies the position in the image of the droplet ejected from the nozzle hole and imaged, and specifies the position in the image of the nozzle hole,
The droplet ejection velocity measuring system, wherein the computing means calculates a droplet velocity based on the positional relationship between the nozzle hole and the droplet in the specified image. The droplet ejection velocity measuring system according to claim 1 , wherein the calculation unit also calculates a volume of the droplet from an image of the droplet imaged by the imaging unit.

Images