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Description  |
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BACKGROUND OF THE INVENTION
The present invention relates to a cleaning composition to be used for
cleaning oil-based paint from brushes and other tools such as rollers and
sponges that have been used to apply said oil-based paint. The method of
cleaning of oil-based paint from paintbrushes and painting tools has until
now been done by soaking the brushes or tools in a solvent such as mineral
spirits or turpentine. While this method effectively cleans the brush or
painting tool it has serious environmental, health and safety drawbacks.
The solvents used for this purpose are generally flammable creating a
serious fire hazard. Secondly, they are also volatile organic compounds
which quickly evaporate and contribute to hydrocarbon pollution of the
atmosphere and resultant high ground level ozone concentrations. Thirdly,
they are health hazards which can cause injury to internal organs due to
inhalation and can cause dermatitis due to contact with the skin. Fourthly
they are inconvenient to use and difficult to dispose of properly. Patents
have been issued for safer paint brush cleaners but none so far have
enjoyed commercial success.
U.S. Pat. No. 4,606,840 describes a composition containing hydrocarbons or
chlorohydrocarbons, ketone, glycol, alcohols and/or other solvents, and a
liquid surfactant and cosurfactant in a formulation containing water that
is useful in cleaning paint from brushes and allows the cleaning to be
finished off in water. The formulation described by this patent contains a
high concentration of hazardous chemicals that could represent a health
hazard to the user of the formulation as well as a danger to the
environment.
U.S. Pat. No. 4,812,255 describes a paint remover for uncured paint
containing organic carboxylic acid, N-methyl-2-pyrrolidone (NMP) and an
alkylene glycol ether. This formulation is expensive and contains a high
percentage of corrosive acids.
U.S. Pat. No. 5,098,592 describes a formulation for removing varnish and
paint from wood or metal which comprises activating NMP and/or BLO with
about 1-30% by weight of an activated compound which is ethyl
3-ethoxypropionate (EEP). This paint remover would be prohibitively
expensive for use in cleaning uncured paint from brushes and tools.
U.S. Pat. No. 4,251,383 describes a cleaning liquid containing an essential
oil (eucalyptus oil), a softening agent (a fixed oil derivative such as
coconut oil diethanolamide), and surfactants. It is stated that the
formulation is useful in removing soil, stains, varnishes and the like
from various surfaces and natural fibers. It appears that this formulation
is designed for removing stains and not for removing large amounts of
paints from paintbrushes. In any case the use of large amounts (50-70 %)
of eucalyptus oil or other essential oil will render the formulation
prohibitively expensive for cleaning paintbrushes.
U.S. Pat. No. 5,104,567 describes the use of a blend of 90-99% vegetable
oil (in particular soy oil) and 1-10% of a surfactant emulsifier for
cleaning ink from machine parts and rubber sheets in the printing
industry. The cleaning process can be finished off with water. I have
shown through experimentation that more than 10% surfactant is required to
remove paint from paint brushes in a fashion that allows them to be
finished up with water. At surfactant levels of 10% or below, partial
removal of paint from the paintbrush will occur but a significant amount
of paint will remain in the brush when the brush is washed with water.
This residual paint will adhere tightly and will not wash out with
subsequent treatment with the paint brush cleaner. Many patented and
commercial paint removers are intended for removing both cured and uncured
paint from surfaces and brushes and as such contain aggressive cleaning
agents such as ketones, chlorocarbons, N-methyl-2-pyrrolidone, methylene
chloride and other chemical substances. Such aggressive cleaning methods
are not necessary for normal cleaning of oil-based paint from paint
brushes. The paint that remains in paint brushes and other painting tools
does not cure for a matter of hours after use allowing time for the
brushes to be cleaned with a much less aggressive, inexpensive and safer
cleaning liquid.
SUMMARY OF THE INVENTION
It is, therefore, the object of the present invention to provide a new
method for cleaning uncured oil based paint from paintbrushes and other
painting tools and articles which avoids the previously disclosed
disadvantages of the prior art. The method that I have invented
accomplishes this object by first contacting the paintbrush or other
painting tool with a formulation which contains vegetable oil, a
lipophilic surfactant and a hydrophilic surfactant for about 30 seconds
followed by washing the paintbrush in water. The formulation comprises
from about 0 to about 30% of the lipophilic surfactant and from about 11
to about 45% of the hydrophilic surfactant.
The lipophilic surfactant serves as an activator for the vegetable oil to
facilitate the removal of the paint from the pores of the paintbrush
bristles. The large amount of hydrophilic surfactant is necessary in order
to prevent the paint from coming out of the emulsion as the emulsion is
being infinitely diluted by the wash water stream.
The term "paintbrush" as used in this specification and appended claims
shall always be construed to include all articles and appliances
conventionally used to mix, manufacture or apply oil-based and water-based
paints and varnishes including brushes, rollers, tools, mixers, spraying
apparatus and all other such equipment.
DETAILED DESCRIPTION OF THE INVENTION
An effective cleaning formulation and method for cleaning uncured oil-based
paint and varnish from paintbrushes and other painting tools that is as
effective as the use of turpentine or mineral spirits can be prepared from
blending vegetable or mineral oil with emulsifying surfactants in the
proper ratios.
It is well known that uncured oil-based paints are readily soluble in
mineral spirits and a number of other solvents due to the similarity of
the chemical structure of the drying oils used in the paint formulation to
that of the non-polar hydrocarbon solvents. Polar solvents such as water
are repelled by oil-based paint. Surfactants however can be used to
overcome the natural repulsion between the oils in the paint and water and
thus create an emulsion. Technology similar to this is used to make
waterborne (latex) paints.
Experiments I have performed in cleaning oil-based paint from paint brushes
with surfactants show that the gross unadhered paint that is within a
paintbrush can be emulsified with the proper combination of surfactants
and water. The paint that has adhered to the bristles of the brush however
can not be cleaned from the brush in this manner.
Other experiments I have performed show that when vegetable oil and the
proper surfactants are used together in the proper ratio a formulation can
be created that is effective in cleaning paintbrushes and other painting
tools. The vegetable oil in the formulation frees the paint from the paint
brush bristles and allows the surfactants to emulsify the
paint/oil/surfactant mixture in water so that the brush can be properly
cleaned. In order for the cleaning to be effective however the
oil/surfactant blend must first be worked into the paintbrush long enough
for the oil to dilute the paint in the pores of the paintbrush bristles.
This takes about 30 seconds. After this, water can be added to form an
emulsion and wash out the paint/oil/surfactant mixture. Usually a second
treatment is required to remove small amounts of residual paint. Before
the second treatment it is important to get as much water out of the brush
as possible since excessive water will cause the oil in the cleaning
mixture to emulsify prematurely and prevent it from dislodging the paint
from the paint brush bristles.
Surfactants
A wide range of surfactants can be used to produce an effective paint brush
cleaner. It is essential to have a hydrophilic surfactant that will form a
stable emulsion of the paint and vegetable oil as the emulsion is being
diluted under running water. It is also desirable to have a lipophilic
surfactant that will facilitate the removal of the paint from the pores of
the bristles. In establishing the best formulation it is necessary to
balance the cost versus efficiency of the surfactants since some
surfactants are effective in smaller concentrations but cost more.
I have found that effective formulations must have a considerable amount of
hydrophilic surfactant present in the range of 11 to 45%. The lipophilic
content necessary for an effective formulation depends on the solvency
demonstrated by the surfactant/oil combination without water present and
on the hydrophilic/lipophilic balance (HLB) exhibited by the surfactants
after water is added. HLB values for most available surfactants are well
known by those skilled in this art. The explanation of HLB Methodology is
contained in Rosen, Milton J., "Surfactants and Interfacial Phenomena",
Wiley & Sons (N.Y. 1978), pages 242-5, incorporated herein by reference.
The most effective formulations have an HLB in the range of 9.0-15.0. Even
more preferred combinations have an HLB of about 10-13 and most preferred
combinations have HLB of 11-12.
My experiments show that effective formulations can be made with from 0 to
30% lipophilic surfactant present.
In some cases a single surfactant can be used if it has the right HLB
(Hydrophilic/Lipophilic Balance) and the ability to act as a solvency
promoter when no water is present and to act as a hydrophilic surfactant
when water is present.
The surfactants suitable for the practice of the present invention must
provide the proper emulsion stability, and they must be non-toxic.
Representative surfactants which are suitable for the present invention
include
A. Anionic agents
1. Sodium, potassium and ammonium soaps derived from fatty acids having
from 10 to 22 carbon atoms.
2. Amine soaps derived from fatty acids having from 10 to 22 carbon atoms
and primary, secondary and tertiary amines such as monoethanolamine,
diethanolamine and triethanolamine, and cyclic amines such as morpholine,
e.g., triethanolamine stearate.
3. Rosin soaps such as sodium salts of rosin acids such as abietic acid.
4. Alkali metal salts of sulfate compounds which can be represented by the
formula ROSO.sub.3 H wherein the R group represents an organic moiety such
as a fatty alcohol having up to 22 carbon atoms. These include sodium
lauryl sulfate, sodium cetyl sulfate, sodium monolauryl glyceryl sulfate,
an oil such as sulfated castor, olive, teaseed, neat's foot cottonseed,
rape seed, corn and rice, oil, etc.
5. Alkali metal salts of sulfonated compounds which can be represented by
the formula RSO.sub.3 H wherein the R group represents an organic moiety
having from 8 to 22 carbon atoms. These include alkane sulfonates such as
dioctyl sodium sulfosuccinate, oxyethylated alkyl lauryl sulfate, alkyl
aromatic sulfonates such as sodium isopropylnaphthalenesulfonate, sodium
dodecylbenzenesulfonate, sodium sulfonaphthylstearate.
B. Nonionic agents
1. Ethers such as condensation products of alkyphenols with from 6 to 20
moles of ethylene oxide, the phenols being monoalkylated, dialkylated or
polyalkylated with alkyl side chains having from 5 to 18 carbon atoms and
the corresponding naphthalene or diphenyl compounds; polyoxyethylene and
polyoxyethylene-polyoxypropylene copolymers.
2. Esters such as compounds which can be represented by the formula RCOOR'
wherein R is a long hydrocarbon chain derived from a fatty acid having
from 12 to 22 carbon atoms and R' is a polyhydric alcohol, e.g., glyceryl
monostearate, diethylene glycol monolaurate, sorbitan fatty acid esters
derived, for example from lauric, palmitic, stearic and oleic acids.
3. Ether-esters wherein polyoxyethylene chains are found with an unreacted
hydroxy group of esters of fatty acids and polyhydric alcohols.
4. Fatty acid amides such as lauroyl diethanolamide.
C. Ampholytic
1. Surfactants such as those having amino and carboxy groups, e.g., dodecyl
B-alanine, imidazoline derivatives.
2. Surfactants containing amino and sulfuric acid or sulfonic groups formed
by condensing an alkane-sulfonamide with formaldehyde and methyltaurine.
Suitable representative surfactants include sorbitan trioleate, sorbitan
tristearate, sorbitan sesquioleate, glycerol monostearate, sorbitan
monopalmitate, sorbitan monolaurate, polyoxyethylene lauryl ether,
polyethylene glycol monostearate, triethanolamine oleate, polyoxyethylene
glycol monolaurate, polyethylene sorbitan monostearate,
polyoxyethylenesorbitan monooleate, polyoxyethylene sorbitan monolaurate,
sodium oleate, potassium oleate, sodium lauryl sulfate, lauroyl
imidazoline, sodium dodecylbenzene sulfonate, sodium monoglyceride
sulfate, sodium alkaralkyl polyglycol sulfate, sodium oleyl laurate,
sodium dioctyl sulfosuccinate, lauryl polyglycol, ether sodium
dibutylnaphthalenesulfonate, alkyl phenol polyglycol ether, sorbitan
monolaurate polyglycol ether, sulfonated castor oil, tall oil polyglycol
ester, alkyl dimethyl benzylammonium chloride alkyl naphthalene pyridinium
chloride, cetyl dimethyl ethylammonium bromide, alkyl dimethyl
chlorobenzylammonium chloride, dibutyl phenyl phenol sulfonate, ester of
colaminoethylformyl methyl pyridinium chloride, sulfonated methyl
oleylamide, sorbitan monolaurate polyglycol ether, polyglycol oleate,
sodium lauryl sulfoacetate, sodium 2-ethylhexanol sulfate, sodium
7-ethyl-2-methyl-undecanol-4 sulfate, sodium 3,9-diethyltridecanol-6
sulfate, sodium lauryl and myristyl collamide sulfate and N-(sodium
sulfoethyl) oleamide, etc. The preferred surfactants are fatty acid esters
and fatty alcohol esters.
Cationic agents may be useful only to the limited extent of balancing
properties of the primary types of surfactants A,B, and C above.
Representative cationic types are:
1. Amine salts (e.g. hydrochlorides and acetates) derived from straight
chain fatty amines having from 8 to 18 carbon atoms, e.g., octyldecylamine
hydrochloride.
2. Quaternary ammonium salts formed by alkylation of fatty amines with
methyl chloride, dimethylsulfate, benzylchloride and the like. These
compounds can be represented by the formula (RR'R"R'''N)Y wherein each of
R, R', R'', R''' is a long chain aliphatic group of from 8 to 22 carbon
atoms or a fatty acid amide; short aliphatic group such as methyl, ethyl,
or propyl, an aromatic group such as phenyl or benzyl radical; or a
heterocyclic group such as pyridine or piperidine; and Y represents an
inorganic or lower organic ion such as chloride, bromide or acetate
radical, e.g., triethanolamine stearate cetyl trimethyl ammonium bromide,
benzylalkonium chloride.
Preferred Small Brush Surfactants
The following groups of surfactants are judged suitable for use in this
invention primarily for small brushes and in combination with water in the
cleaning composition (25-50 water). These materials are commercially
available as household detergents such as Joy.RTM. and Sunlight.RTM. as
noted in Example 1.
One surfactant system consists of from 30-90 parts by weight of the
surfactant system of a Ca-sensitive first surfactant selected from the
group consisting of water-soluble C.sub.9 -C.sub.15 -alkyl benzene
sulphonates, alkane sulphonates having 8-20 carbon atoms, olefin
sulphonates having from 8-20 carbon atoms, di-C.sub.8-20 -alkyl
sulphosuccinates, di-C.sub.6-12 -alkyl phenol sulphosuccinates, primary
and secondary alkyl sulphates having 8-20 carbon atoms, C.sub.8-20 -alkyl
polyethoxy sulphates having 1-25 ethoxy groups, and mixtures thereof, and
from about 70-10 parts by weight of said system of a less Ca-sensitive
second surfactant selected from the group consisting of water-soluble
nonionic condensation products obtained by condensing from 5-30 moles of
an alkylene oxide, preferably ethylene or propylene oxide, with one mole
of an organic hydrophobic compound, aliphatic or alkyl aromatic in nature,
having 8-24 carbon atoms and at least one reactive hydroxyl, amino, amido
or carboxyl group; C.sub.8-20 -alkyl sulphobetaines; amine oxides
containing one long chain alkyl moiety of from 10-28 carbon atoms and two
moieties which can be either alkyl radicals or hydroxyalkyl radicals
having from 1 to 4 carbon atoms, C.sub.8-20 -alkyl polyethoxy sulphates
having 1-25 ethylene oxide groups, and mixtures thereof, said surfactants
(1) and the ion-active surfactants of group (2) being present in the form
of their alkali metal salts, ammonium salts, lower alkanolamine salts,
lower alkylamine salts or mixtures thereof.
Examples of nonionic water-soluble condensation products obtained by
condensing 5-30 moles of an alkylene oxide with one mole of an organic
hydrophobic compound are:
1. the condensates of the ethylene oxide with aliphatic straight chain or
branched chain, primary or secondary alcohols of more than 8 carbon atoms
such as those derived from tallow or coconut fatty acids, containing 5-20
ethylene oxide groups, and branched chained C.sub.11 -C.sub.15 alcohols
condensed with 5-20 ethylene oxide groups.
2. the condensates of ethylene oxide with alkylphenols, in which the
phenols may be mono- or polyalkylated and the total number of carbon atoms
in the side chain or chains is from 5 to 18. Specific examples are
condensates of one mole nonyl phenol with 8 to 15 moles of ethylene oxide.
3. the condensates of ethylene oxide with fatty acid esters preferably
mono-fatty acid esters of the sugar alcohols, sorbitol and manitol.
4. polyethenoxyesters obtained by reacting ethylene oxide with carboxylic
acids, the latter being natural fatty acids or synthetic fatty acids made
from oxidated paraffin wax having from 8-20 carbon atoms of alkylbenzoic
or naphthenic acids having from 5-18 carbon atoms in the alkyl chain.
5. the condensation products of fatty acyl alkanolamides of the type
C.sub.7-17 alkyl-CO--NHC.sub.2 H.sub.4 OH, C.sub.7-17 alkyl--CO N(C.sub.2
H.sub.4 OH).sub.2 with ethylene oxide.
6. the condensation products of C.sub.8-18 alkyl-, C.sub.8-1-8 alkenyl and
C.sub.8-18 alkylaryl amines with ethylene oxide. A specific example is the
condensation product of one mole of a dodecylamine with 9-12 moles of
ethylene oxide.
Typical examples of surfactant systems are alkyl benzene sulphonate/alkyl
polyethoxy sulphate mixtures; alkyl benzene suphonate/alkyl polyethoxy
sulphate/nonionic mixtures; alkyl sulphate/alkyl benzene sulphonate/alkyl
polyethoxy sulphate mixtures and alkyl sulphate/alkyl polyethoxy
sulphate/amine oxide mixtures. Other useful surfactant systems are those
in use in Joy and Dawn dishwashing liquids. These are believed to be based
on the systems in U.S. Pat. Nos. 4,316,824 and 4,133,779. These are:
(a) 10% to about 50% of an anionic surfactant which has the general formula
RO(C.sub.2 H.sub.4 O)x--SO.sub.3 M wherein R is an alkyl group containing
from about 10 to about 16 carbon atoms, M is selected from the group
consisting of sodium, potassium, ammonium, monoethanol ammonium, diethanol
ammonium, triethanol ammonium, calcium and magnesium cations and mixtures
thereof, and the ethoxylate distribution is such that, on a molar basis
the compounds wherein X is O are from about 54% to about 60%, wherein X is
1 are from about 15% to about 20%, wherein X is 2 are from about 10% to
about 13%, and wherein X is 3 are from about 6% to about 7% of the total,
and there is sufficient magnesium to at least neutralize 50% of the
anionic surfactant wherein x is 0.
(b) from 1% to about 20% of a suds stabilizer;
(c) from about 0% to about 10% of a detergency builder selected from
inorganic phosphates, polyphosphates, silicates, and carbonates, organic
carboxylates, phosphonates and mixtures thereof; and
(d) from about 20% to about 88% water.
Alternatively small brush surfactant systems can utilize vegetable oil and
a surfactant of:
(a) a semi-polar organic nonionic detergent selected from the group
consisting of (1) water-soluble amine oxides having one alkyl
oxyhydroxyalkyl moiety of 8 to 28 carbon atoms and two alkyl moieties
selected from the group consisting of alkyl groups and hydroxyalkyl groups
of 1 to 3 carbon atoms, (2) water-soluble phosphine oxides having one
alkyl or hydroxyalkyl moiety of 8 to 28 carbon atoms and two alkyl moeties
selected from the group consisting of alkyl groups and hydroxyalkyl groups
of 1 to 3 carbon atoms, (3) water-soluble sulfoxides having one alkyl or
hydroxyalkyl moiety of 8 to 18 carbon atoms and an alkyl moiety selected
from the group consisting of alkyl and hydroxyalkyl groups of 1 to 3
carbon atoms, and (4) mixtures thereof; and
(b) an alkaline earth metal salt of an anionic detergent selected from the
group consisting of (1) linear alkyl benzene sulfonates having 9 to a5
carbon atoms in the alkyl group, (2) alkyl sulfates having 8 to 22 carbon
atoms, (3) paraffin sulfonates having 8 to 22 carbon atoms, (4) olefin
sulfonates having 8 to 22 carbon atoms, (5) alkyl ether sulfates having 8
to 22 carbon atoms in the alkyl group and 1 to 30 ethylene oxide units (6)
alkyl glyceryl ether sulfonates having 8 to 22 carbon atoms in the alkyl
group and (7) mixtures thereof in a weight ratio of semi-polar nonionic
detergent to anionic detergent of from 1:100 to 1:2.
Types of Oils
A wide variety of vegetable oils can also be used with some being more
effective than others but all tested were acceptable. These include Soy,
canola, caruso, corn, safflower, peanut, rapeseed, coconut, palm,
sunflower, grape oil and any other suitable vegetable oil as well as
blends thereof. Oils that do not preserve well will not be suitable. It is
possible to use mineral oil as a replacement for the vegetable oil but the
resultant brush cleaner will not be as environmentally acceptable.
Other Optional Ingredients
Well known types of additives to enhance the quality of the cleaning
composition can be added in effective amounts including electrolytes,
detergency builders, builder salts which can be added to promote the
cleaning and soil-removal efficiency of the surfactants of the
composition, e.g. phosphates, polyphosphates, phosphonates, carbonates,
polyacetates and polycarboxylates; lather promoting agents, such as
coconut fatty acid diethanoi amide; hydrotropes and solubilising agents,
such as the lower alkanols containing 2-4 carbon atoms, especially
ethanol, urea, sodium or potassium toluene sulphonate and sodium or
potassium xylene sulphonate, which are generally added to promote phase
stability especially of compositions with high concentrations of
surfactants; preservatives; perfume and coloring agents; and other
functional additives. Thickening agents act as protective colloids,
operating to prevent coagulation and de-emulsification of the composition.
They further act to prevent coagulation of the emulsion particles which
constitute the composition of the present invention.
Suitable thickening agents for use in the composition of this invention
include colloidal alumina, colloidal silica, alginic acid and derivatives
thereof, "Carbopol" (carboxyvinyl polymer), cellulose derivatives such as
"Klucel" (cellulose ethers), "Methocel" (methyl cellulose), "Natrosol"
(hydroxyethyl cellulose), sodium carboxymethyl cellulose, gelatin, gums
such as agar, tragacanth, acacia gum, guar gum, and the like and egg yolk,
lecithin, pectin, thixin, and resins like ethyleneoxide polymers.
EXAMPLES
In the following examples various compositions were formulated and tested
as paint brush cleaners. The test used to judge effectiveness consisted of
cleaning polyester, natural bristle, and polyolefin test brushes (one
inch, three inch and four inch) with the subject formulation by first
saturating the brush in an oil based type paint and then cleaning it in a
measured amount of the subject cleaning formulation. Each cleaning
consisted of working the formulation into the brush for about 30 seconds
and then rinsing the brush with water for about 1 minute. The number of
applications of cleaning liquid required to thoroughly clean the brush was
recorded as the test result. Results are reported on the natural bristle
brush only since the cleaner was equally effective on all three types of
brush tested. I also performed experiments with formulations wherein water
was used as diluent in the formulation.
Example 1.
Formulations with Household Surfactant Blends
JOY and Dawn brand household dishwashing liquids were used in combination
with various vegetable oils. JOY is formulated from alkyl sulfate and
alkyl ethoxylated sulfate together with detergency builders and water.
SUNLIGHT is formulated from alkyl benzene sulfonate, alkyl
polyethoxysulfate, lemon juice, other electrolytes and water. Water makes
up about 40-60% of the formulations. Brushes made from natural bristle,
polyolefin, and polyester were used. Paints used were alkyd and
polyurethane oil-based paint. The type of paint and the type of brush had
no significant effect on the results and are thus not identified in the
results below. For one inch brushes one tablespoon of cleaning liquid was
used for each cleaning. Proportionally more cleaning liquid was used on
larger brushes. Cleaning liquid was worked into the brush for 30 seconds
and then the brush was washed with water for one minute. The number of
cleanings was recorded and cleaning efficiency was judged on a scale of
1-5 with 5 being perfectly clean and 1 being hardly cleaned at all.
Results of 2 and above are acceptable.
__________________________________________________________________________
CLEANINGS
CLEANING
SIZE
SURFACTANT
% OIL % REQUIRED
EFFICIENCY
BRUSH
__________________________________________________________________________
SUNLIGHT 33 SOY/5% 67
2 5 1"
OLIVE OIL
SUNLIGHT 33 SOY 67
2 5 1"
JOY 33 SOY/5% 67
2 5 1"
OLIVE OIL
JOY 33 SOY 67
2 5 1"
JOY 33 SAFFLOWER
67
2.5 4 1"
SUNLIGHT 100
NONE 0 2+ 1 1"
SUNLIGHT 50 SOY 50
2 5 1"
SUNLIGHT 50 SOY 50
5+ 1 4"
SUNLIGHT 33 SOY 67
3 3 3"
__________________________________________________________________________
JOY IS A PRODUCT AND REGISTERED TRADEMARK OF THE PROCTOR AND GAMBLE
COMPANY PATENTED UNDER U.S. PAT. NOS. 4,133,779 & 4,316,824.
SUNLIGHT IS A PRODUCT AND REGISTERED TRADEMARK OF LEVER BROS. AND IS
PATENTED UNDER U.S. PAT. NO. 4,614,612.
The above formulations were very effective on one inch brushes.
Example 2
Formulations with Commercially Available Surfactants Using 3 and 4 Inch
Brushes
Experiments were performed with surfactants readily available in the
commercial market that had the proper lipophilic and hydrophilic
properties and that were safe to use. These formulations were tested on 3
and 4 inch brushes in the same manner as in EXAMPLE 1 except that between
2 and 8 tablespoons of cleaning formulation were used.
__________________________________________________________________________
LIQUID
SURFACTANT SURFACTANT WATER
TYPE USED NUMBER CLEAN.
A % B % % OIL % (TLBS)
CLEANINGS
EFF.
__________________________________________________________________________
TWEEN 20 17
SPAN 20 17
0 SOY 66
2 3 4
TWEEN 20 17
SPAN 20 17
0 SOY 66
3 3 5
TWEEN 20 22
SPAN 20 11
0 SOY 66
4 5+ 2
TWEEN 20 11
SPAN 20 22
0 SOY 67
4 3 3
TWEEN 20 20
NONE 0 SOY 80
4 5+ 2
TWEEN 20 23
SPAN 20 23
8 SOY 46
4 2 5
TWEEn 20 14
SPAN 20 14
22 SOY/5%
44
2 5+ 2
OLIVE
JL 80X 50 SOY 50
4 5+ 2
TWEEN 60 25
SPAN 60 25
0 SOY 50
4 5+ 2
SDBS 33
SLES 17
0 SOY 50
4 5+ 2
Z504 21
ZB090 11
0 SOY 67
4 5+ 2
Z504 21
ZB090 11
0 SOY 67
8 2 5
BRIJ 30 25 SOY/5%
75
3 3 4
OLIVE
BRIJ 30 25 LIGHT 75
3 4 4
MINERAL
__________________________________________________________________________
CLEANING EFFICIENCES OF 4 AND ABOVE WERE JUDGED TO PERFORM ACCEPTABLY.
TWEEN IS AN ICI TRADEMARK FOR THAT COMPANY'S POLYSORBATE SURFACTANT. SPAN
IS AN ICI TRADENAME FOR THAT COMPANY'S SORBITAN SURFACTANTS. BRIJ IS AN
ICI TRADENAME FOR THAT COMPANY'S OLETH SURFACTANT. JL80X IS A TEXACO, INC
TRADEMARK FOR THAT COMPANY'S ETHOXYLATED NONIONIC SURFACTANT.
SLES = SODIUM LAURYL ETHER SULFATE, SDBS = SODIUM DODECYL BENZENE
SULFONATE, Z504 & ZB090 ARE ALKYLPHENOL ETHOXYLATES.
Example 2 demonstrates that satisfactory paintbrush cleaners can be
formulated from a number of surfactant/oil blends. In some cases a single
surfactant can be used if it has the right HLB (Hydrophilic/Lipophilic
Balance) and the ability to act as a solvency promoter when no water is
present and to act as a hydrophilic surfactant when water is present. Also
it is possible to use mineral oil as a replacement for the vegetable oil
but the resultant brush cleaner will not be as environmentally acceptable.
I have found that effective formulations must have a considerable amount
of hydrophilic surfactant present in the range of 10 to 45%. The
lipophilic content necessary for an effective formulation depends on the
solvency demonstrated by the surfactant/oil combination without water
present and on the hydrophilic/lipophilic balance (HLB) exhibited by the
surfactants after water is added. The most effective formulations have an
HLB in the range of 9.0-15.0. My experiments show that effective
formulations can be made with from 0 to 30% lipophilic surfactant present.
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