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Description  |
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BACKGROUND OF THE INVENTION
This invention relates to a composition and method for removing paint films
from surfaces and more particularly it relates to a novel additive for
increasing the effectiveness of alkaline stripping compositions.
In the manufacture of various commercial articles, it is often the practice
to provide such articles with a protective and/or decorative paint film on
the surface. The term "paint" as used herein includes paints, varnishes,
lacquers and the like, which are formulated from numerous and diverse
components, including acrylic resins, epoxy resins, vinyl resins, alkyd
resins, and the like.
In the course of manufacturing these commercial articles, it sometimes
happens that some of the articles fail to meet the manufacturing
specification because of some defect in the protective and/or decorative
coatings which are applied. When this happens, it is desirable to remove
the defective coating from the article so that it may be recoated rather
than discarded or sold as a "second" with resulting financial loss. In
recent years, however, great improvements have been made in both the
durability and adhesion of paints and similar protective coatings so that
their removal from a surface after they have been applied, cured and/or
dried, has become increasingly difficult. These difficulties have been
encountered particularly when using chemical means to effect the removal
of the coatings, such chemical removal methods generally being preferred
because they tend to limit costly hand operations and are more readily
adapted to a continuous process.
Not only is it desirable to remove the paint on articles from which the
coating is defective, but, additionally, where the articles being coated
are transported on a conveyor line, the hooks which support the article
also become coated with the paint or similar coating during the process.
Since these hooks or hangers are repeatedly introduced into the painting
zone of the process, the paint continues to build up on them adding weight
to the conveyor line and often filling in the hook, if it is not
periodically stripped off or removed. Accordingly, it is desirable to
remove such protective coatings from these hooks or hangers as well as
from defective articles, quickly and completely, and preferably by using
chemical means.
In the past, considerable use has been made of alkaline stripping
compositions in which the article from which the protective coating is to
be removed is immersed for a period of time sufficient to effect a
substantial loosening of the coating. With the advent of improved paint
systems, such as the acrylic paints and lacquers, difficulties have often
been encountered with such alkaline stripping compositions. Frequently, it
has been found that the articles must be immersed in a boiling alkaline
stripping composition for several hours in order to obtain the desired
loosening of the protective coating. In some instances, even longer
contact times have not resulted in an appreciable loosening of the
coating.
U.S. Pat. No. 3,615,827 suggests an alkaline stripping composition
containing a phenol derivative. Since phenol compounds have come under the
increasing scrutiny of environmental interests and administrations of the
Occupational Safety and Health Act, it would be desirable to eliminate
their use. U.S. Pat. Nos. 3,663,447; 3,663,476; and 3,671,465 disclose
stripping compositions containing amine compounds but only as additives
for glycol or phenol systems.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide an improved composition
and method for removing protective and/or decorative paint films from
surfaces to which they have been applied.
It is another object of this invention to provide a stripping composition
which does not depend upon environmentally objectionable phenol
derivatives for its efficacy.
Broadly, the invention includes an accelerator which comprises the
essential organic components of the invention, a concentrate composition
which comprises the accelerator with or without a minor portion of water,
and an aqueous working composition comprising the concentrate composition
diluted with water to the desired working concentration.
Accordingly, the present invention includes a concentrate composition
useful for removing paint films which comprises one or more inorganic
alkaline materials and an accelerator. The accelerator contains a
synergistic combination of amine compounds. Such compositions, when
dispersed in water, are found to give excellent results in removing or
substantially loosening decorative and/or protective paint films from
metal surfaces to which they have been applied. These compositions are
particularly effective in removing such materials containing acrylic,
epoxy, vinyl, or alkyd resin coating components, which coating materials
have heretofore been removed, if at all, only with great difficulty when
using conventional alkaline paint strippers. In the following description,
all percentages are by weight unless otherwise specified.
DETAILED DESCRIPTION OF THE INVENTION
In formulating the aqueous alkaline paint stripping compositions of the
present invention, the concentrate compositions, described above, may be
dissolved in water in amounts sufficient to provide the desired alkalinity
to effect substantial loosening of the paint film to which the composition
is applied, but in amounts insufficient to exceed the maximum solubility
of the accelerator composition in the solution. In this regard, it has
been found that the solubility of the accelerator composition is inversely
proportional to the alkalinity of the stripping solution, so that at lower
alkalinities, more of the accelerator composition can be dissolved in the
stripping solution. Typically, the aqueous alkaline paint-stripping
solutions of the present invention will contain the concentrate
composition in amounts within the range of about 0.5 pounds to about 5
pounds per gallon of solution, with amounts within the range of about 1
pound to about 3 pounds per gallon being preferred. Where the acceleration
has not been combined with the alkaline material they may be separately
added to form the stripping solution in amounts as have been indicated
hereinabove. In its most preferred embodiment, the aqueous alkaline paint
stripping solution contains the alkaline material in an amount of about 1
to 2 pounds per gallon and the accelerator composition in an amount of up
to 10 percent by volume of the stripping solution.
In utilizing the stripping compositions of the present invention, the
aqueous alkaline stripping solution, formulated as has been indicated
hereinabove, is brought into contact with the article from which it is
desired to remove paint or a similar protective or decorative coating. The
contact time needed to effect a substantial loosening of the paint from
the surface will depend on the nature and thickness of the paint which is
to be removed. With some paint, contact times of a few minutes, e.g., 2 to
3 minutes, may be sufficient while with other and more difficult-to-remove
paints, appreciably longer contact times, e.g., 30 minutes or more, may be
desirable. Accordingly, it is not feasible to give specific contact times
because the times of contact used will, in each instance, be those which
will effect a substantial loosening of the paint on the surface.
In this regard, it is to be noted that it is not essential that the
stripping composition of the present invention remain in contact with the
coated surface for a period of time sufficient to effect complete removal
of the coating from the surface. It is only necessary that the contact
time be sufficient to effect a loosening of the paint film on the surface
so that it may be removed by brushing, high-pressure water sprays, or the
like. Generally, it is desirable that the contact between the stripping
composition and the surface from which the coating is to be removed is
effected by immersing the surface in the stripping solution. In this
manner, a thorough and continuous wetting of the surface film by the
stripping solution is obtained, with little or no loss of the stripping
solution. In some instances, however, particularly when less
difficult-to-remove films are to be treated which normally require only
short contact times, other contacting techniques such as spraying,
flooding, or the like, may be utilized.
Normally, the paint-stripping solution is at an elevated temperature of at
least 120.degree.F when it is brought into contact with the surfaces from
which the protective film is to be removed. Preferably, the solution is at
a temperature which is close to its boiling paint with temperatures within
the range of about 90.degree. to about 100.degree.C being typical. It
will be appreciated, however, that in some instances either higher or
lower temperatures, e.g., room temperature may also be used.
After the protective film on the surfaces treated has been substantially
loosened by contact with the stripping solution, and the film has been
removed from the surface, either by retaining the surface in the stripping
solution until removal is complete or by utilizing other techniques on the
loosely adhering film, the surface is in condition to be recoated with a
new protective film. Generally, it is preferred that the surface be water
rinsed so as to remove any of the alkaline stripping solution which may be
retained on the surface prior to again subjecting the surface to the
coating operation. It has been found that by using the aqueous alkaline
stripping solutions described above, in the manner which has been
indicated greatly improved results are obtained in terms of reduction in
the time required to effect a substantial loosening of many different
types of protective film, such as paints, lacquers, varnishes, and the
like.
The following examples demonstrate the stripping ability of the working
solution of the present invention. In each case, the test panels were
first treated with a phosphating solution to form an iron phosphate
coating. Thereafter, the panels were painted with Duracron 200 brand
acrylic based paint supplied by PPG Industries. The paint thickness was
uniform at about 1.1-1.5 mils for all panels. The panels were subsequently
subjected to the stripping solution at a temperature between 90.degree. -
100.degree.C and the time for complete stripping was recorded.
The "first amine" of the invention is an alkanol amine of the formula:
##STR1##
wherein R' is an alkyl group of up to about 4 carbon atoms and R.sub.1 and
R.sub.2 may be hydrogen or alkyl, aryl, or alkanol groups of up to about 7
carbon atoms, preferably, not more than 4 carbon atoms.
Solutions of sodium hydroxide at a concentration of 11/2 lb/gal were
prepared and the following amines were added to 5 vol.% to determine their
individual stripping efficiencies.
TABLE I
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AMINE COMPOUND STRIPPING TIME
MINUTES
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FIRST AMINES
A) Phenyl Diethanolamine
7.63
B) Phenyl Ethanolamine
8.17
C) o-Tolyl Diethanolamine
13.67
D) m-Tolyl Ethanolamine
15.52
E) N-Benzyl Diethanolamine
12.81
F) N-Benzyl Ethanolamine
12.12
G) t-Butyl Diethanolamine
12.17
H) Triisopropanolamine
19.17
I) Diisopropanolamine *NE.sub.30
J) Monoisopropanolamine
*NE.sub.30
SECOND AMINES
Diethanolamine *NE.sub.30
Monoethanolamine *NE.sub.30
o-Phenylene Diamine 19.25
Melamine *NE.sub.30
N-Aminoethyl Piperazine
*NE.sub.30
2-(2-aminoethoxy)-ethanol
*NE.sub.30
2-amino 2-ethyl 1,3 propanediol
*NE.sub.30
3-Methoxy Propylamine *NE.sub.30
Triethanolamine *NE.sub.30
Triisopropanolamine 19.17
Diisopropanolamine *NE.sub.30
Monoisopropanolamine *NE.sub.30
Ethoxy Ethoxy Propylamine
*NE.sub.30
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*NE.sub.30 - No Stripping Effect After 30 Minutes
The "First Amines" (labelled A through J) were then mixed with various of
the "Second Amines" to determine whether the stripping times could be
improved beyond that of the individual amines. Combination accelerators
were prepared having the mole ratios of Table II. The combination
accelerator was then added to 5 vol.% to a 11/2 lb/gal sodium hydroxide
solution and stripping times obtained as for Table I.
TABLE II
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STRIPPING
ACCELERATOR FIRST AMINE/
MOLE RATIO TIME
SECOND AMINE FIRST/SECOND MINUTES
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A/Diethanolamine 2/1 6.45
A/Monoethanolamine 1/1 6.75
A/2-Phenylene Diamine
1/1 4.88
A/2-Phenylene Diamine
2/1 5.56
A/Melamine 1.5/1 7.44
A/2-(2-aminoethoxy)-ethanol
2/1 6.9
A/2-(2-aminoethoxy)-ethanol
2/1 6.90
A/3-Methoxy Propylamine
1/1 7.33
A/3-Methoxy Propylamine
1/2 6.67
A/Triethanol amine 3/1 5.10
B/2-Phenylene Diamine
2/1 7.25
B/2-(2-aminoethoxy)-ethanol
1/1 8.17
B/3-Methoxy Propylamine
1/1 8.00
C/Triethanolamine 3/1 12.08
C/Diethanolamine 2/1 7.81
C/Monoethanolamine 1/1 13.50
C/2-(2-aminoethoxy)-ethanol
1/1 13.50
D/Monethanolamine 1/1 10.00
D/2-Phenylene Diamine
2/1 15.38
D/2-(2-aminoethoxy)-ethanol
1/1 14.25
E/Triethanolamine 3/1 8.75
E/Diethanolamine 2/1 8.33
E/Monoethanolamine 1/1 8.50
F/Diethanolamine 2/1 11.75
F/Monoethanolamine 1/1 10.94
F/2-Phenylene Diamine
2/1 11.92
F/Melamine 3/1 9.67
F/N-Amino Ethyl Piperazine
2/1 10.92
F/2-(2-aminoethoxy)-ethanol
1/1 10.58
F/2-Amino, 2-Ethyl, 1,3
Propanediol 1/1 9.92
F/3-Methoxy Propylamine
1/1 11.83
G/2-Phenylene Diamine
1/1 6.25
G/2-Phenylene Diamine
2/1 7.31
G/Melamine 3/1 10.92
G/Melamine 1.5/1 10.25
G/N-Amino Ethyl Piperazine
1/1 11.75
G/2-(2-aminoethoxy)-ethanol
1/1 10.37
H/Phenyl Diethanolamine
.33/1 6.25
H/Ethoxy Ethoxy Propylamine
.67/1 8.67
H/Ethoxy Ethoxy Propylamine
.33/1 6.67
H/Ethoxy Ethoxy Propylamine
2/1 12.50
I/Phenyl Diethanolamine
.5/1 6.58
I/Diethanolamine 2/1 28.13
I/Ethoxy Ethoxy Propylamine
.5/1 15.75
I/Ethoxy Ethoxy Propylamine
2/1 9.67
J/Phenyl Diethanolamine
1/1 6.69
J/Phenyl Diethanolamine
2/1 6.50
J/Ethoxy Ethoxy Propylamine
1/1 10.50
J/Ethoxy Ethoxy Propylamine
2/1 13.83
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A comparison of the results of Tables I and II indicates that the above
combinations produce results better than expected based upon the effect of
either individual component. The mole ratio of amines which is effective
varies depending upon the particular combination employed and any
particular combination may not be effective at all mole ratios. Generally,
the mole ratio is between about 0.3 and 3.0 to 1.
The accelerator makes up from 3-50% of the concentrate composition (0.15 -
20% of the aqueous working solution). The concentrate composition also
comprises from 50 - 97% alkaline material. A major portion of the alkaline
material is an alkali metal hydroxide. More specifically, the alkaline
material of the present invention contains an alkali metal hydroxide, as
the principal source of alkalinity in an amount of at least about 50
percent by weight of the alkaline material. Desirably, the alkali metal
hydroxide is present in an amount within the range of about 70 percent to
about 97 percent by weight of the composition.
The aqueous working solution contains components equivalent to a 0.5 to 5
lb./gal. solution of the concentrate in water and preferably 1.0 to 3
lb./gal.
In addition to the alkali metal hydroxide, the alkaline materials which are
dispersible in water to form the present paint stripping solution may also
contain other alkaline components if desired. Such alkaline compositions
may include the alkali metal carbonates, alkali metal silicates, alkali
metal phosphates, and the like. Exemplary of the alkali metal phosphates
which may be used in the composition are trisodium phosphate, tetrasodium
pyrophsophate, tetrapotassium pyrophosphate, sodium tripolyphosphate, and
the like. Typically, these latter alkaline material, the alkali metal
silicates, carbonates and phosphates, will be present in the concentrate
composition, when used, in amounts up to about 50 percent by weight of the
composition with amounts within the range of about 3 percent to about 30
percent by weight of the composition being preferred. It is to be
understood that the foregoing amounts refer to the total of all alkaline
material other than the alkali metal hydroxides, which totals may be made
up of only one of the added alkaline materials or of a mixture of two or
more of these materials.
It is to be appreciated, of course, that as used in the specification and
claims, the term "alkali metal" is intended to refer to lithium, sodium,
potassium, cesium, and rubidium. In many instances, the preferred alkali
metal has been found to be sodium so that primary reference hereinafter
will be made to the compounds of sodium. This is not, however, to be taken
as a limitation of the present invention but merely as being exemplary
thereof.
In addition to the alkaline materials indicated hereinabove, the
concentrate compositions of the present invention may also include a
gluconic acid material. Such material is typically present in the
composition in an amount up to about 10 percent by weight of the
composition with amounts within the range of about 2 percent to about 7
percent by weight of the composition being preferred. It is to be
understood that by the term "gluconic acid material" it is intended to
refer to and include gluconic acid itself, water-soluble and/or
water-dispersible forms of gluconic acid such as the alkali metal
gluconates and in particular sodium gluconate, glucono-delta-lactone, and
the like.
Surface active or wetting agents may also be included in the concentrate
composition, typically in amounts up to about 10% by weight of the
composition with amounts within the range of about 1.0 percent to about 7
percent by weight of the composition being preferred. Various suitable
surface-active agents of the anionic, nonionic and cationic types may be
used, provided they are soluble and effective in solutions having a high
alkalinity. In many instances, excellent results have been obtained when
using wetting or surface-active agents of the phosphate ester type and,
accordingly, these materials are preferred. Materials of this type are
exemplified by QS-44, a product of the Rohm and Hass Company.
Additionally, sulfated fatty acid derivatives and sulfonated fatty acid
amide derivatives as described in U.S. Pat. Nos. 2,773,068 and 2,528,378
may be used. Exemplary of these materials are Miranol JEM and Miranol
C.sub.2 M products of the Miranol Chemical Company.
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