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Claims  |
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What is claimed is:
1. The method of ink jet printing employing a jet printing ink having a
viscosity below about 5 cps at 20.degree. C. and an electrical resistivity
below about 3000 ohm cm., said ink comprising a solvent consisting
predominantly of water, lower alcohols, or mixtures thereof and having
dissolved therein soluble dyestuff, a volatile base, film-forming polymer
means, and multivalent metal ion means for cross-linking said polymer on
drying, said polymer containing carboxyl groups substantially inert to
said metal ion means in the presence of said volatile base but being
cross-linked therewith upon evaporation thereof to form an ionically
cross-linked polymer substantially insoluble in water, said soluble
dyestuff being present in an amount equal to at least about 10% of the dry
weight of said polymer.
2. The ink jet printing method according to claim 1 wherein said polymer
means comprises an acrylic polymer and said base comprises a source of
ammonia sufficient to provide a pH greater than about 7.5.
3. The ink jet printing method according to claim 2 wherein said metallic
ion means comprises zinc.
4. The ink jet printing method according to claim 2 wherein said polymer
contains from about 2 to about 8 percent by weight of said polymer.
5. The ink jet printing method according to claim 4 having a resistivity
below about 1500 ohm cm. and comprising by weight about 2 to 8 percent
polymer, 1 to 8 percent dyestuff, sufficient volatile base to provide a pH
greater than about 7.5, from 0 to about 2 percent ionizable salt means for
increasing conductivity, and sufficient solvent to provide a viscosity
below about 3 cps at 20.degree. C.
6. The ink jet printing method according to claim 5 comprising about 3 to 5
percent polymer and about 1 to 3 percent dyestuff, said polymer being a
polymer of acrylic or lower alkyl acrylic acid.
7. The ink jet printing method according to claim 1 wherein said solvent
includes a minor portion of a drying retardant comprising an alcohol,
glycol, glycol ether, or mixtures thereof having from about six to sixteen
carbon atoms.
8. A jet printing ink having a viscosity below about 5 cps at 20.degree. C.
and an electrical resistivity below about 3000 ohm cm., said ink
comprising a solvent consisting predominantly of water, lower alcohols, or
mixtures thereof and having dissolved therein soluble dyestuff, a volatile
base, film-forming polymer means and multivalent metal ion means for
cross-linking said polymer on drying, said polymer containing carboxyl
groups substantially inert to said metal ion means in the presence of said
volatile base but being cross-linked therewith upon evaporation thereof to
form an ionically cross-linked polymer substantially insoluble in water,
said soluble dyestuff being present in an amount equal to at least about
10% of the dry weight of said polymer.
9. An ink according to claim 8 wherein said polymer means comprises an
acrylic polymer and said base comprises a source of ammonia sufficient to
provide a pH greater than about 7.5.
10. An ink according to claim 8 wherein said solvent includes a minor
portion of a drying retardant comprising an alcohol, glycol, glycol ether,
or mixtures thereof having from about six to sixteen carbon atoms. |
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Claims |
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Description |
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This invention relates to ink jet printing, and more particularly to ink
jet printing with an improved ink.
Jet printing systems are well known and are described, for example, in U.S.
Pat. Nos. 2,566,443; 3,060,429; 3,416,153; and 3,596,275; and in an
article entitled "INK JET PRINTING" by Fred J. Kamphoefner, pages
584-592of the IEEE Transactions on Electron Devices, Vol. Ed-19, No. 4,
April, 1972. In such systems, a stream of ink droplets is generated from a
capillary tube and selectively directed toward a target surface. Most
commonly, the droplets are charged and selectively deflected as desired by
one or more electric fields. The inks employed must have low viscosities
for passage through the capillary tube and ejection orifice, and low
resistivity for ease of charging. Generally the viscosity should be below
about 5 centipoises at 20.degree. C. and preferably is below about 3
centipoises, and the resistivity is below about 3,000 and preferably is
below about 1500 ohm-cm.
As shown, for example, in U.S. Pat. No. 4,024,096, suitable viscosities and
resistivities for ink jet printing inks have been obtained by employing as
solvents lower alcohols, C.sub.1 to C.sub.5 and preferably methanol, water
or mixtures thereof. For printing on absorptive surfaces such as porous
paper, dye solutions have been used. For printing on nonsorptive or
impervious surfaces such as metal, glass, plastic or ceramics, soluble
resin binders have been added, principally shellac or novolac. Small
amounts of ionizable salts have also been dissolved in the solvent to
increase conductivity where necessary.
Since the materials heretofore employed have been soluble in water or
alcohol and have been fixed on the target surface merely by drying, they
have relatively low resistance to abrasion and to contact with moisture
and alcohol. Moreover, adhesion to some surfaces has been deficient. For
many applications, for example product dating or batch coding, improved
inks are desirable which have greater permanence.
The theory of the type of polymer system employed in the present invention
is not new and substances with similar characteristics have been used as
floor polishes, removable protective coatings, and as pigmented viscous
inks for more conventional printing processes. The special demands of ink
jet printing, however, particularly with respect to the resistivity of the
ink, imposes further important specifications for a desirable ink
composition. For this reason, many of the presently known substances would
be unsuitable for ink jet printing.
It is a primary object of the present invention to provide improved ink jet
printing with inks which are easily formulated, readily applied to a
variety of target surfaces, provide good stability in the printing
apparatus, and which assure greater permanence and adhesion to target
surfaces. It is a further object to employ inks for jet printing which are
stable in solution but which rapidly cross-link merely by drying. It is
another object of the invention to provide an ink jet printing method
utilizing inks of low resistivity for ease of charging.
SUMMARY OF THE INVENTION
In accomplishing the foregoing and related objects, the improved ink jet
printing of the invention employs inks containing as binders polymers
which have unesterified free carbonyl groups along their chains; for
example, polymers or copolymers of acrylic or lower alkyl acrylic acids.
In accordance with one aspect of the invention, these polymers are soluble
in basic solutions of alcohol or water containing substantial dissolved
dyestuff, and can be rapidly cross-linked with multivalent metal ions such
as zinc or the like. In accordance with the related aspect of the
invention, where the solubilizing base is volatile, for example ammonia
obtained from a source such as ammonium hydroxide, ammonium carbonate,
morpholine or the like, the cross-linking ionic bonds are rapidly formed
merely on drying. After drying, and removal of base by evaporation, the
cross-linked polymer is insoluble in water and alcohol and is resistant to
removal by abrasion. In accordance with a further related aspect of the
invention, the ink can nevertheless be removed by vigorous application of
alkaline solutions, which is an advantage for cleaning the printing
apparatus and in applications such as coding and recoding of reusable
containers.
In accordance with yet another aspect of the invention, a readily ionizable
salt may be employed to lower resistivity of the ink, although sufficient
conductivity is typically obtained without the use of such a salt.
DETAILED DESCRIPTION
According to the present invention, the improved jet printing is obtained
employing an ink comprising the ingredients in approximately the
proportions by weight shown in Table 1 below.
TABLE 1
______________________________________
Preferred
Ingredient Broad Range Range
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(1) Acrylic polymer
2 - 8% 3 - 5%
(2) Soluble dye, % of (1)
10 - 100% 30 - 70%
(3) Volatile base, to pH
>7.5 >8
(4) Multivalent metal ion
sufficient to polymerize (1)
on drying
(5) Ionizing salt 0 - 2% none
(6) Drying retardant
0 - 30% 10 - 25%
(7) Primary solvent
balance balance
Viscosity, 20.degree. C.
<5 cps <3 cps
Resistivity, ohm-cm
<3000 <1500
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The acrylic polymer may be of any of a number of known polymers of acrylic
or lower alkyl acrylic which have a plurality of carboxyl groups and which
are soluble in basic ammonia water solutions. Such materials are
commercially available as RHOPLEX B-336 of the Rohm and Haas Company;
BRIGHT PLATE 23 and JONCRYL of S. C. Johnson and Sons, Inc.; and as
CARBOSET resins from the B. F. Gooorich Chemical Co. While higher
molecular weight materials can be employed, low to moderate molecular
weights are preferred to obtain higher polymer content in the low
viscosity inks. Any suitable soluble dye can be employed. Basic and acid
dyes are suitable with basic dyes being preferred.
The primary solvent is water, a lower alcohol, preferably methanol, or
mixtures thereof. Additional higher boiling solvents may be employed as
drying retardants, for example alcohols, glycols, glycol ethers, or
mixtures thereof having from about 6 to 16 carbon atoms and which are
miscible with the primary solvent.
Any suitable volatile base can be employed, preferably a source of ammonia
such as ammonium hydroxide, ammonium carbonate, morpholene or the like, or
mixtures thereof. A readily ionizable salt, for example potassium
thiocyanate or the like, can also be employed to lower resistivity of the
ink if necessary. However, such water soluble salts can increase the water
sensitivity of the dried inks and are preferably omitted. Normally,
sufficient conductivity is obtained in the ink from the ionizing polymer,
dyes and volatile bases employed.
Any suitable multivalent metal ion complex stable in basic solution but
ionically cross-linking the polymer under lower pH conditions may be
employed. A number of such metal ions are known. Zinc which forms a
complex with ammonia and readily cross-links the acrylic polymers in the
absence of ammonia is preferred. Other usable metals include calcium,
cadmium, cobalt, copper, nickel, aluminum, tin and zirconium suitably
complexed in basic solution. Complexes thereof are disclosed for example
in U.S. Pat. Nos. 2,849,334 and 2,919,205. Commercial solutions of acrylic
polymers are available which include zinc ammonia complexes. Where
addition is necessary, a suitable zinc solution may be made by dissolving
zinc oxide in ammonia water, for example in the following weight
proportions:
Zinc oxide: 7.2
Water: 71.4
Concentrated Ammonium hydroxide: 8.7
Ammonium carbonate: 12.7
Sufficient complex ion solution should be included to polymerize the
polymer on drying, for example up to about 15 parts of the above zinc
ammonia solution per 100 parts of acrylic polymer.
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Preferred Example
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BRIGHT PLATE 23 20.9
Soluble dye 1.5
Ammonium carbonate, 10% in H.sub.2 O
6.67
Methanol 50.0
Methyl cellosolve 4.3
Ethylene glycol monobutyl ether
16.0
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The resulting solution was filtered (approximately one micron pore size)
and thereafter had a resistivity of 444 ohm cm., a viscosity at 20.degree.
C. of 2.45 centipoises, and a pH of 8.8.BRIGHT PLATE 23 is the product of
S. C. Johnson & Sons, Inc. and comprises an acrylic polymer, about 16% by
weight solids, in a basic water solution of zinc ions and ammonia. The
soluble dye is preferably a basic dye, for example Rhodamine B, basic
violet 10, C.I. 45170.
In the above example, methyl cellosolve and ethylene glycol monobutyl ether
are employed as drying retardants to prevent premature drying in the
capillaries or other portions of the jet printing apparatus. Rapid drying
on the target is obtained. Still faster drying can be obtained by omitting
the retardants if desired. While a mixture of methanol and water is
employed as the primary solvent, either may be employed alone if desired.
The present invention permits the use of water alone which is an advantage
in cost, flammability, and toxicity.
Extended testing of ink jet printing employing the ink of the preferred
example has shown long successful printing runs without clogging of the
capillaries, with rapid drying, with good extended print quality, and with
good adhesion and permanence to a variety of surfaces, including metal and
plastic.
The inks of the present invention are believed to be true solutions.
However, colloidal solutions may be used if filterable without substantial
separation through a filter having a pore size substantially smaller than
the printer capillary tube, for example through a filter having a pore
size of about one micron. Minor amounts of other compatible ingredients
may also be included. For example, minor amounts of other resins
compatible with the acrylic polymer may be used as adhesion promoters for
particular surfaces. Also, chelating agents such as ethylene diamine
tetraacetic acid or the like may be included as scavengers for metal ion
impurities to promote stability.
It should be understood that the foregoing description is for the purpose
of illustration and that the invention includes all equivalents and
modifications within the scope of the appended claims.
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