JPH0151346B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a color ink jet recording apparatus that performs color recording by ejecting ink droplets of different colors from a plurality of orifices.

In the following description, the present invention will be explained with reference to a two-color inkjet recording apparatus, but the present invention can also be applied to a multi-color recording apparatus having two or more colors or a full-color recording apparatus.

The inkjet recording method is a recording method that has attracted attention in recent years, and has many advantages as shown below.

(1) Use plain paper.

(2) High-speed printing is possible.

(3) Less noise when printing.

(4) The device is compact.

(5) Easy to maintain.

(6) Color printing is easy.

Conventionally, many types of inkjet recording methods have been proposed. The present inventors previously devised an inkjet recording device based on a completely new ejection principle. An example of this is shown in FIG. 1. This inkjet recording device includes a plurality of orifices that are arranged side by side on an ink ejection surface and ejects ink as droplets, a common ink chamber that is arranged parallel to the ink ejection surface, and Inkjet recording is performed using a head equipped with a number of liquid chambers that communicate an orifice with the common ink chamber. In the figure, 1 is the head, 2 is a substrate forming this head, and 3 is a grooved head. The groove cover 4 is a liquid chamber formed by the groove cover 3, 5 is a heater, 6 is an orifice for discharging ink, 7 and 7' are ink supply pipes, and 8 is a common ink chamber. As shown, the head 1 is composed of a smooth substrate 2 and a groove cover 3 having a number of grooves forming a liquid chamber 4. As shown in FIG. A heater 5 as a means for generating thermal energy is formed on the substrate 2 using a microfabrication method such as sputtering, vapor deposition, or etching in response to a print signal. Ink discharged from the orifice 6 in the form of droplets is introduced into the common ink chamber 8 through the ink supply pipes 7 and 7', and is supplied to each liquid chamber 4. The ink supplied into each liquid chamber generates bubbles due to the thermal energy provided by the heater 5, and is ejected from the orifice 6 in the form of droplets due to the sudden pressure change caused by the bubbles. One of the ink supply pipes 7, 7' may be used to remove air bubbles contained in the ink.

The present inventors further improved the apparatus shown in FIG. 1 and devised an inkjet recording apparatus for performing color recording. An example is shown in FIG.
This is common to multiple orifices that are arranged side by side on the ink ejection surface and eject droplets of ink of two or more different colors, and ink of each color that is arranged parallel to the above ink ejection surface for each color of ink. A device that performs multiple inkjet recordings using a head equipped with a common ink chamber for each color and a number of liquid chambers that communicate each orifice with the common ink chamber for each color corresponding to the color of the ink to be ejected. It is. In the inkjet device shown in FIG. 2, two different tones are ejected. Ink of one color is introduced into a common liquid chamber 8 of that color through a supply pipe 7, and a common hole 9 is opened in a part of the common liquid chamber 8, and a common hole 9 is opened in a part of the liquid chamber. ', and when a signal is applied to a heater (not shown) in the liquid chamber, the ink is ejected from the orifice 10. The same goes for the other color of ink, which is supplied to each liquid chamber corresponding to that color, and is ejected from the orifice corresponding to that color.

This color inkjet recording device is capable of performing multicolor inkjet recording, but the following disadvantages are observed in devices that simply adopt the recording method that has been applied to conventional monochrome recording. Ta.

(1) Ink has different physical properties for each color, and therefore the ejected droplet arrival point for each color is different.

(2) The droplet ejection frequency for each color changes due to the recorded information, making the droplets unstable.

(3) As a result, the resulting multi-color image causes image unevenness and image distortion.

In a head that uses ink of two or more colors, it is preferable to use a head as shown in FIG. 2, since it is necessary to facilitate ink supply and to reduce the size of the head. Therefore, the present inventors
As a result of pursuing the cause of the above-mentioned disadvantages, the following conclusion was reached. That is, the common liquid chamber-orifice distance (liquid chamber length) l ₁ for each color shown in FIG.
and l ₂ are different, and the ink liquid viscosity is different for each color, and the ink liquid viscosity changes depending on the droplet ejection frequency, and the inner wall resistance of the ink is different. be. That is, since the viscous resistance on the inner wall of the liquid chamber differs for each color, the liquid ejection speed, ejection response frequency, etc. differ for each color, and as a result, the quality of the resulting multicolor image recorded by inkjet recording deteriorates.

The present invention aims to provide a color inkjet recording apparatus that solves the above-mentioned disadvantages.

That is, an object of the present invention is to obtain a multicolor inkjet recorded image with excellent print quality without color unevenness or distortion in a color inkjet recording device that uses a plurality of color inks with different physical properties, and to The purpose of this is to always make the droplets of each color arrive at the same point during recording to obtain uniform dots.

Still another object is to obtain good color images by forming good droplets for each color with a simple device.

In order to achieve the above object, the present inventors came to the following conclusion. Now, the viscous resistance (equal to the liquid chamber wall resistance) δ exhibited by a liquid having a liquid chamber length l, a viscosity η, and a density ρ passing through the liquid chamber radius R is expressed by the following equation.

δ=3η・l/ρ・R ³ ...(1) Therefore, the viscous resistance δ ₁ of the ink of each color passing through the liquid chamber of the inkjet recording device shown in FIG.
The ratio of δ ₂ is expressed by the following formula. However, the liquid viscosity is η ₁ ,
Let η ₂ be the liquid density, ρ ₁ and ρ ₂ be the liquid chamber lengths, l ₁ and l ₂ be the liquid chamber lengths, and R ₁ and R ₂ be the liquid chamber radii. However, R ₁ = R ₂ .

δ ₁ / δ ₂ =3η ₁・l ₁ /ρ ₁・R ³ / ₁ /3η ₂・l ₂ /ρ
₂・R ³ / ₂ = η ₁・l ₁ /ρ ₁ /η ₂・l ₂ /ρ ₂ ...(2) Since viscous resistance is equal, δ ₁ = δ ₂ , (2)
The formula is: η ₁・l ₁ /ρ ₁ =η ₂・l ₂ /ρ ₂ ...(3) Therefore, the present inventors believe that in order for formula (3) to hold,
The present invention was achieved by noting that even if the liquid chamber lengths l ₁ and l ₂ are different, it is sufficient to adjust η and ρ.

That is, the color inkjet recording device of the present invention includes a plurality of orifices that are arranged side by side on an ink ejection surface and eject ink of two or more different colors as droplets; one common ink chamber for each color of ink arranged side by side; a plurality of parallel ink chambers communicating between each orifice and the common ink chamber for each color corresponding to the color of the ink to be ejected; A color inkjet recording apparatus comprising: a liquid chamber; and an energy generating means provided for each of the liquid chambers and generating energy for ejecting ink; The invention is characterized in that each common ink chamber is provided with an ink viscosity adjusting device that heats or cools the ink in the common ink chamber for each color so as to equalize substantial viscous resistance.

Further, in one embodiment, the energy generating means is a heater that generates thermal energy as energy used for ejecting ink, and the energy generating means is a heater that generates thermal energy as energy used for ejecting ink, and the energy generating means is a heater that generates thermal energy as energy used for ejecting ink. It is characterized by ejecting ink as droplets using pressure changes.

FIG. 3 shows an embodiment of the invention. The illustrated embodiment shows an ink viscosity adjusting device 11 mounted above a common ink chamber 8. This viscosity adjusting device 11 has a common ink chamber 8 that performs heating or cooling action.
In addition to the ink in the liquid chamber, the liquid viscosity of the ink for each color is changed to equalize the substantial viscous resistance within the liquid chamber. When a fixed ink is used, a fixed heating or cooling action is sufficient, but it is better if the heating or cooling means has a variable temperature so that the liquid viscosity can be adjusted according to the state of the ink for each color. This is desirable because it can be adjusted.

Next, the present invention will be further explained in detail with reference to Examples.

Example 1 An experiment was conducted at room temperature of 25° C. using a multicolor inkjet recording apparatus shown in FIG. However, the liquid chamber length in this recording head is l ₁ = 2 (mm), l ₂
= 3 (mm).

An ink having the composition shown below was introduced into the liquid chamber of _L2 .

Water 60 (gr.) Ethylene glycol 40 (gr.) Black dye 1 (〃) Water Black manufactured by Orient Chemical Industry Co., Ltd.
200L The liquid viscosity of the above black ink η ₂ = 2.6 (cps), the liquid density ρ ₂ = 1.1 (gr./cm ³ ), and the liquid path length of the recording head l ₁ (2
mm), l ₂ (3 mm), Substituting the above into equation (3), η ₁ = 3/2×2.6×ρ ₁ /ρ ₂ ...(4) If ρ ₁ = ρ ₂ , then The required liquid viscosity η ₁ was as follows.

η ₁ = 3.9 (cps) ...(5) Here, as the other ink, the black dye of the above black ink was replaced with a red dye (Waterless #9, manufactured by Orient Chemical Industry Co., Ltd.). The ink was introduced into the corresponding common ink chamber 8, and the viscosity adjusting device 11 according to the present invention was activated.
Actually, by cooling the ink to 12°C and increasing the liquid viscosity, the viscosity of equation (5) was obtained and the viscous resistance was made equal. When the viscosity adjusting device 11 was not activated, the viscous resistance was not equal, so the ejected droplets varied for each color, making it impossible to obtain a good color image.
As a result of using the viscosity adjusting device 11 according to the present invention, all of the ejected droplets became uniform, and good recording was obtained over a wide range.

As described above, by using the present invention, in a multicolor inkjet recording device that ejects ink droplets of two or more different colors from a plurality of orifices, at least one color of ink is heated or cooled to adjust the liquid viscosity. By adjusting the viscous resistance of the ink and ejecting droplets uniformly, it is possible to obtain a high-quality multicolor inkjet recorded image with little dot misalignment and color unevenness.

[Brief explanation of drawings]

FIG. 1 is a perspective view showing a monochrome inkjet recording device, FIG. 2 is a perspective view showing a color inkjet recording device, and FIG. 3 is a perspective view showing the device shown in FIG. 2 in which the present invention is implemented. be. 1... Head, 2... Board, 3... Groove cover, 4
...liquid chamber, 5...heater, 6...orifice,
7, 7'...Ink supply pipe, 8...Common ink chamber,
9...Ink supply hole, 9'...Ink supply hole, 1
0... Orifice, 11... Viscosity adjustment device.

Claims (1)

[Scope of Claims] 1. A plurality of orifices arranged in parallel on an ink ejection surface and ejecting ink of two or more different colors as droplets; orifices arranged parallel to the ink ejection surface and arranged in parallel to each other for each color of ink; one common ink chamber for each color of ink; a plurality of liquid chambers parallel to each other that connect each orifice with the common ink chamber for each color corresponding to the color of ink to be ejected; A color inkjet recording device comprising: an energy generating means provided for each of the liquid chambers and generating energy for ejecting ink; A color inkjet recording apparatus characterized in that each common ink chamber is provided with an ink viscosity adjusting device for heating or cooling the ink in the common ink chamber for each color so as to equalize the resistance. 2. The energy generating means is a heater that generates thermal energy as energy used for ejecting ink, and utilizes rapid pressure changes caused by bubbles generated by the thermal energy generated by the heater. A color inkjet recording device according to claim 1, characterized in that the ink is ejected as droplets.