Background of the Invention
[0001] This invention relates to an improvement of magnetofluidographic or jet ink (indicated
as ink in thefollowing). More specifically, it relates to an improvement of the hue
of the magnetic fluid forming the ink.
[0002] Usual magnetic fluid is a liquid in which magnetic fine particles of magnetite or
the like having a particle size of 50-200 A are suspended in a dispersion medium by
the aid of surfactant. It has a black-brown color, and it keeps stable for a long
period of time so that neither sedimentation nor aggregation readily takes place in
it. As dispersion medium for such magnetic fluid, paraffin oil, ester oil, silicone
oil, water and the like are used. As the surfactant, carboxylic acids such as oleic
acid, linoleic acid and the like, as well as cationic surfactants and nonionic surfactants,
are used. Such a magnetic fluid is described in EP-A-55065.
[0003] Magnetic fluid finds use in extensive fields such as sealing agent, lubricant, sink
and float separation, oil-water separating agent, recording material and the like.
The excellent characteristic properties of the magnetic fluid of this invention can
be exhibited particularly in the field of recording material.
[0004] As the recording process using a magnetic fluid, there have hitherto been proposed
the ink jet process utilizing magnetic deviation and the recording process utilizing
the protruded part of magnetic fluid by magnetic force (Japanese Patent Kokai (Laid-Open)
No. 23,534/79).
[0005] As the ink for such recording processes, a magnetic fluid diluted with a dispersion
medium to an appropriate viscosity or its mixture with a dye has hitherto been used.
The color of this ink is dependent upon the dispersed fine magnetic particles. When
the fine magnetic particle is y-ferrite, magnetite, Mn ferrite, Ba ferrite, Fe-Zn
ferrite or Mn-Zn ferrite, it apparently has a black or black-brown color, but it turns
to light brown when it is attached on a support such as paper or the like. This tendency
becomes stronger as the magnetic particles become finer.
[0006] Further, when a magnetic fluid is used as a recording material, the recorded image
changes its color with time. For example, an ink in which a magnetite dispersion type
of magnetic fluid is used is a liquid having a black-brown color. However, if its
image is formed on a white high quality paper, the color of the image turns fom black-brown
to light brown in several weeks. The color change is due to that the dispersed magnetic
fine particles are oxidized by air oxygen to form iron oxide (Fe
20
3). Though inks using other magnetic fine particles show no great color change, their
black-brown color is inclined to light brown from the beginning.
[0007] As above, it is an important fault of magnetic fluid when used as an ink that the
recorded image assumes a light brownish color on support or turns to light brown or
yellowish brown with time and that primary colors such as cyan, magenta, yellow, etc.
cannot be obtained therefrom.
[0008] The color of magnetic fluid can be converted from brown to black by adding a dye
as a colorant to the magnetic fluid. However, if a magnetic fluid containing a dye
is formed into an image on white high quality paper, the color of image has a more
intense light brown hue than the color of magnetic fluid itself. This is due to the
difference in permeability into paper between magnetic fine particles and dye molecule.
While the magnetic particle has a size of 50-200 A, the dye molecule has a size of
about several ten A or less so that the latter has a greater permeability into high
quality paper and the dye molecule
heaches the backside of paper by permeation. Thus, there arises a great difference
between the color of magnetic fluid and that of image, which-is an important fault
of dye-containing magnetic fluid used as an ink.
Summary of the Invention
[0009] The object of this invention consists in providing a magnetofluidographic ink or
jet ink having various hue. Particularly it consists in providing ink which, when
used as a recording material on a high quality paper, is free from color separation
between magnetic particle and coloring pigment particle and can give a black-colored
image or an arbitrary single color image.
[0010] The magnetofluidographic or jet ink of this invention can be obtained by stably dispersing
coloring pigment particles in a liquid prepared by dispersing ferromagnetic particles
by the aid of surfactant, with the proviso that the pigment particles have a particle
size of from 50 to 200 A.
Brief Explanation of the Drawings
[0011] Figure 1 is an outlined constructional view of magnetofluidographic apparatus, and
Figure 2 is a partial plan view of said apparatus, wherein:
1 is a multi-stylus, 2 is magnet for protrusion, 2' is shield plate for the magnet
for protrusion, 3 is magnetic fluid, 4 is feeding magnet, 5 is base pedestal, 6 is
protrusion, 7 is recording material, 8 is controlling electrode, 9 is voltage applying,
means and 10 is magnetic fluid tank.
Detailed Explanation of the Invention
[0012] The ink of this invention is characterized by being constituted of magnetic particles
stably dispersed by the aid of surfactant and colloidal coloring pigment particles
having a particle size of 50-200 A.
[0013] In general, typical colloidal particles have a size of about 10 A to several 100
A. The size of colloidal coloring pigment particle to be dis- . persed in this magnetic
fluid is 50-200 A. The colloidal coloring pigment particle has a size comparable to
that of the stably dispersed magnetic particle,
from the viewpoint of dispersion stability and permeability into paper.
[0014] Usually, a pigment exhibits the maximum hiding power when its size is 0.2-0.3 pm,
and pigments usually available commercially have this order of size. However, since
the pigment to be dispersed in the magnetic fluid of this invention should most preferably
have a size comparable to that of the magnetic particle in the magnetic fluid, it
is necessary to make the usually available pigment finely divided. As the method for
dispersing a pigment into a dispersion medium, it is recommendable to pulverize a
mixture of pigment, dispersing medium and dispersion stabilizer for a long period
of time by means of ball mill, attritor, sand grinder or the like. Though any of inorganic
pigments and organic pigments can be used as the pigment, organic pigments are more
preferable than the other in point of coloring power and easiness of pulverization
and dispersion. Since inorganic pigments have higher specific gravity and hardness
than organic pigments, it takes a longer time to pulverize and disperse inorganic
pigments than to do organic pigments. Therefore, in the case of inorganic pigments,
it is allowable to add a dispersion stabilizer in synthesizing the pigment by wet
process before the pigment particle grows up to form a large particle, by which a
pigment having a small particle size can be produced. As above, many of the inorganic
pigments have a structure similar to that of magnetic particle such as ferrite, which
can be dispersed into a form of colloid by a process similar to the wet process for
the production of magnetic fluid. As the dispersion stabilizer, surfactants exhibit
excellent dispersion stability. Surfactants include anionic surfactants, cationic
surfactants, nonionic surfactants, etc., any of which exhibit a dispersing action.
However, the action greatly varies with its combination with pigment and dispersion
medium. Therefore, surfactants having a functional group readily adsorbable on the
pigment are more preferable. For example, when an inorganic pigment consisting of
a metallic oxide such as Cobalt Blue is to be dispersed into a hydrocarbon solvent,
the dispersion can be successfully achieved by using a long chain aliphatic carboxylic
acid giving a carboxylic acid ion having a strong affinity to metallic oxide, such
as oleic acid, or its salt.
[0015] As the dispersion medium, water or nonaqueous dispersion media can be used. Examples
of the nonaqueous dispersion media include hydrocarbon compounds such as paraffins,
aromatic compounds, alicyclic compounds and the like; ethers and esters of aromatic
and aliphatic compounds; monohydric and polyhydric alcohol compounds; silicone compounds
such as decamethylcyclopentasiloxane, dodecamethyl- cyclohexasiloxane, octadecamethylcyclo-
nonasiloxane and the like; and so on. When the magnetic fluid of this invention is
used as an ink, these dispersion media preferably have as low a volatility as possible.
Therefore, compounds having a boiling point not lower than 100°C are suitable for
use as a solvent for the magnetic fluid.
[0016] As ferromagnetic particles, Co, Ni, Fe, their alloys and ferrite compounds can be
thought of, among which ferrite compounds are more preferable from the viewpoint of
dispersion stability in the presence of surfactant. As ferrite compounds, y-ferrite,
as well as simple divalent ferrites (M"Fe",04; M is metal atom) such as Mn ferrite,
magnetite, Co ferrite, Ni ferrite and the like, can be referred to. Further, as multi-component
ferrites, Ni-Zn ferrite, Fe-Zn ferrite, Mn-Zn ferrite, Mn-Fe ferrite, Fe-Ni ferrite
and the like can also be referred to. Among them, the multi-component ferrites are
resistant to oxidation in the air, and the oxidation hardly progresses particularly
in case of Mn-Zn and Ni-Zn ferrites. Further, in a recording process in which as high
a magnetization as possible in low magnetic field is required (for example, magnetofluidography,
Japanese Patent Kokai (Laid-Open) No. 23,534/79), Mn-Zn ferrite is suitable.
[0017] As inorganic pigments, a variety of ones can be utilized. For example, as blue-colored
pigments, cobalt blue, ultramarine, Prussian blue, cerulean blue, manganese blue,
tungsten blue, molybdenum blue and the like can be referred to. As red-colored pigments,
red oxide, red lead oxide, molybdenum red, cobalt red and the like can be referred
to. As black-colored pigments, carbon black can be referred to as a typical one. Apart
from above, pigments of various colors can be used in accordance with the color of
magnetic fluid. In order to make the color of magnetic fluid black and to keep the
black color of the printed product prepared by recording an image on a high quality
paper or the like with the ink for a long period of time, it is recommendable to disperse
a blue-colored pigment in a magnetic fluid dispersion. By it, the brownishly colored
magnetic particles formed by the oxidation of magnetic fluid, if it occurs, can be
made achromatic by the action of the blue-colored pigment. In order to enhance the
blackness of magnetic fluid, it is recommendable to disperse carbon black into it,
in addition to the blue-colored pigment.
[0018] As the organic pigment usable in this invention, the followings can be referred to.
Thus, as examples of blue-colored pigment, there can be referred to phthalocyanine
pigments having a high coloring power such as copper phthalocyanine, copper chloride
phthalocyanine, metal-free phthalocyanine, 'sulfonated copper phthalocyanine and the
like; as well as Erioglaucine (Peacock Blue Lakes), Gracia Peacock Blue (Faste Colors),
Rhoduline Peacock Blue, Victoria Blue, Methyl Violet, (tungstic acid), Methyl Violet
(molybdic acid), Methyl Violet (tannic acid lakes) and the like. As examples of red-colored
pigment, there can be referred to Para Red, Lithol Rubine, Permanent Red 2B, Pigment
Scarlet, Lake Red C, Scarlet Lake 2R, Rose Toner (Fanal Color), Pigment Rubine G (barium,
strontium and calcium lakes), Pigment Rubine 3G (barium, strontium and calcium lakes),
Alizarine Lake, Lithol Red (sodium salt, barium salt and calcium salt), Toluidine
Toner and the like. Among them, the pigments of phthalocyanine type particularly have
a very high coloring power and are excellent in light resistance, chemical resistance
and heat resistance, so that they are most preferable as the coloring pigment used
in this invention. It is needless to say that the above-mentioned pigments are nothing
other than some examples for the explanation of this invention, and they do not limit
the invention.
[0019] Next, examples of this invention will be mentioned below.
[0020] In the examples, the recording of image by the use of magnetic fluid was carried
out according to magnetofluidography. The outline of the magnetofluidography is as
shown in Figure 1.
[0021] That is, multistylus 1 is set on base pedestal 5, and magnet protrusion 2 is attached
by bonding to the multistylus 1 in order to magnetize the latter. The magnet 2 for
protrusion is equipped with a feeding magnet 4, by which magnetic fluid is sucked
up from the magnetic fluid tank 10 and magnetic fluid 3 is fed to magnet for protrusion
2 and multistylus 1. Thus, a protruded port 6 of magnetic fluid 3 having the form
shown in Figure 2 is formed on multistylus 1. When a voltage is applied between multistylus
1 and controlling electrode 8 by means of voltage-applying means 9, a Coulomb force
is exercised on the tip of protruded port 6. Thus, magnetic fluid 3 flies toward recording
material 7 and produces image on recording material 7.
Example 1
[0022] A mixture consisting of 100 g of copper phthalocyanine, 50 cc of oleic acid and 750
cc of kerosene was pulverized and dispersed by means of sand grinder (1,600 rpm) for
a time period of 7 days. The resulting dispersion was mixed with a paraffin base Mn-Zn
ferrite dispersion so that the ratio of copper phthalocyanine to ferrite particle
came to 1:10 by weight, and viscosity of the dispersion was adjusted to about 6 cp
at 20°C with paraffin. With this dispersion, recording was carried out by magnetofluidography
(construction of the apparatus was as shown in Figure 1). The color of magnetic fluid
was blue-black, and the color of the printed image was also blue-black. Neither blurring
nor separation of color was observable on the high quality paper. Hue of the printed
image hardly changed during a period of several months.
[0023] Here, viscosity of the magnet fluid was adjusted to 6 cp at 29°C for the reason that,
in magnetofluidography, a lower viscosity of magnetic fluid gives a more ready response
of magnetic fluid to electric signal and a clearer image. If the viscosity exceeds
20 cp (20°C), the response of magnetic fluid to electric signal becomes difficult
to occur and a clear image is unobtainable. Since a paraffin base magnetic fluid having
a viscosity of 6 cp at 20°C keeps a viscosity of about 10 cp at 0°C, the present recording
experiment was carried out by using a magnetic fluid of which viscosity had been adjusted
to 6 cp at 20°C.
[0024] When a magnet fluid is used for magnetofluidography, a higher magnetization of magnetic
fluid at low magnetic field (100 Oe) is more desirable. A magnetization of at least
35 Gauss (100 Oe) is necessary. When the magnetization is lower than 35 Gauss (100
Oe), no clear image is obtainable. This is for the reason that in magnetofluidography
a magnetic field of about 100 Oe is applied to the tip of stylus with which protruded
part of magnetic fluid is produced and the magnetic fluid is flung in response to
recording signal by the Coulomb force, as shown in Figure 1. If printing is carried
out continuously, the magnetic fluid at the tip of stylus is consumed. However, the
same amount of magnetic fluid as its consumption is fed from the magnetic fluid tank
automatically by the magnetic force of rubber magnet. If magnetization of magnetic
fluid is low at this time, the supply of magnetic fluid cannot follow its consumption,
so that a deficiency of magnetic fluid takes place at the tip of stylus. As the result,
thinning of printed image, or the like, occurs to cause a drop in the quality of printed
image.
Example 2
[0025] A mixture consisting of 100 g of cobalt blue (NF-250-P, manufactured by Nippon Ferro
K.K.), 50 cc of oleic acid and 750 cc of paraffin was pulverized and dispersed for
7 days by means of sand grinder (1,600 rpm). The resulting dispersion was mixed with
a paraffin base Mn-Zn ferrite dispersion so that the ratio of cobalt to ferrite particles
came to 1:4 by weight. After adjusting viscosity of the dispersion to about 6 cp at
20°C by the use of paraffin, a recording experiment was carried out by magnetofluidography.
The color of the magnetic fluid was slightly bluish black, and the color of printed
image was also nearly the same as it. Neither blurring nor separation of color was
observable on high quality paper. The image sample scarcely showed a change in hue
during several months.
Example 3
[0026] A mixture consisting of 100 g of Prussian Blue, 50 cc of oleic acid and 700 cc of
paraffin was pulverized and dispersed for 10 days by means of sand grinder (1,600
rpm). The resulting dispersion was mixed with a paraffin base Mn-Zn ferrite dispersion
so that the ratio of Prussian blue to ferrite particles came to 1:5 by weight. After
adjusting viscosity of the dispersion to about 6 cp at 20°C by the use of paraffin,
a recording experiment was carried out by magnetofluidography. The color of the magnetic
fluid was blue-black, and the printed image also had the same blue-black color. Neither
blurring nor separation of color was observable on high quality paper. This sample
of printed image scarcely showed a change of hue during several months.
Example 4
[0027] The experiment of Example 3 was repeated, except that the Prussian blue was replaced
with ultramarine. The printed image had the same blue-black color as that of magnetic
fluid. Neither blurring nor separation of color was observable on high quality paper.
No change was observable in hue during several months.
Example 5
[0028] A mixture consisting of 100 g of carbon black (M5 manufactured by Mitsubishi Kasei
K.K.) and 800 cc paraffin was pulverized and dispersed by means of sand grinder (1,600
rpm) for days. The resulting dispersion was mixed with the copper phthalocyanine dispersion
obtained in Example 1 and a paraffin base Mn-Zn ferrite dispersion so that the ratio
of copper phthalocyanine, carbon black and ferrite particles came to 1:1:10 by weight.
After adjusting viscosity of this magnetic fluid to about 6 cp at 20°C by the use
of paraffin, the magnetic fluid was recorded on a high quality paper by magnetofluidography.
The color of the printed image was black, and the color of the magnetic fluid was
also black. Neither blurring nor separation of color was observable on high quality
paper. The hue of the printed image scarcely changed during several months.
[0029] Additionally saying, it is also possible to obtain magnetic fluids having various
colors in the same manner as above by using water or other organic solvents as dispersion
medium, although only paraffin was used as dispersion medium in the examples mentioned
above,
[0030] As has been mentioned in the examples presented above, there can be provided according
to this invention a magnetic fluid which, when used as a recording material, enables
a high speed recording, shows no separation of color on high quality paper and gives
a high quality record having a stable hue.
[0031] Although the ink of this invention has been developed as a recording ink utilizing
the phenomenon of protrusion of magnetic fluid under magnetic force, it is also usable
as a recording ink for ink jet, ball point pen and the like.