GR1009928B - Composition of a washing powder meant for cleaning stains created by face and body sunscreens and other cosmetic products - Google Patents

Abstract

The invention relates to a washing powder composition meant for the cleaning of stains created by sunscreen and other cosmetic products. Said composition is a mixture of the following substances expressed by weight: phosphates (Sodium triphosphate 39.0 %t), acids (Sulfamic acid up to 8.8 %, Oxalic acid 8.8 %), boric acid 8.8 %, Citric acid 8.4%), non-ionic surfactants up to 8.1 %, oxygen-based bleaches up to 7.2 %), Bicarbonate 7.2 %, Sodium silicate 3.0 %, defoaming substance up to0.25%, optical brightener 0.3 % and fragrance up to 0.15 %. The final product has a neutral pH, between 7 and 8, which is more effective against yellow sunscreen stains. At the same time: 1) it can be used with water of different hardness even at low wash temperatures up to 60 degrees Celsius; 2) it does not require the addition of other auxiliary agents such as pre-treatment fluids, bleaches, softeners, enhancers or fabric softeners for the deodorizing of clothes. Finally, it remains effective for various types and colors of fabrics without affecting their quality.

Description

"LAUNDRY CLEANING POWDER FOR CLEANING STAINS FROM SUNSCREEN AND COSMETIC PRODUCTS FOR THE FACE AND BODY WITH DYEING SUBSTANCES"

Application Claims of the determinative product composition in the form of a washing powder for cleaning stains from sunscreens and cosmetic products for the face and body with pigments. In addition, this powder is effective in different water hardnesses and at low washing temperatures up to 60°C and does not affect the quality of the fabrics.

Definition of the technical field of the invention

The technical field covered by the specific composition of the washing powder is the removal of stubborn stains caused by oily bases (UV filters) together with pigments contained in sunscreen products and other cosmetic products such as makeup and lipstick. In order to cover the entire spectrum of solar radiation, modern sunscreens combine organic compounds (e.g. Ethoxylated Ethyl-4-Aminobenzoate (PABA), octyl methoxycinnamate (OMC), benzophenone-3 (BP-3) or octocrylene) and inorganic filters (such as zinc oxide or titanium oxide) that cause stubborn stains on fabrics. In addition, the composition of many sunscreens and other cosmetic products contain various pigments (eg iron compounds) which make it difficult or even intensify the removal of stains (IARC - International Agency for Research on Cancer 2001).

The formulation of the defining powder utilizes the synergistic action of phosphate compounds along with polycarboxylic acids, non-ionic surfactants, oxygen-based bleaching agents and an optical brightener to clean both types of filters against ultraviolet (UV) rays. In addition, the composition of the powder in question allows the use of water of different hardness without the addition of additional salts even at low washing temperatures of up to 60°C.

Reference to the level of the prior art highlighting the disadvantages which the invention is intended to remedy

One of the most frequent problems arising from the use of sun protection products as well as specific cosmetic items such as makeup and lipstick are stains, which are difficult to remove from various types of fabrics (natural or synthetic). There may still be empirical methods or pre-treatment products for fabrics before washing, but these only manage to remove the oily base of the aforementioned stains. However, for those situations where soiled fabrics are washed in hard water, most sunscreens react with the metal ions contained in the hard water and create dark brown stains that are very difficult to remove.

According to a study by Ginnetti et. al. 2018 conducted on 32 commercial sunscreens, the compounds responsible for the stains are the UV filters that the sunscreens contain such as avobenzone, homosalate, octinoxate, octisalate, octocrylene, oxybenzone, titanium dioxide and zinc dioxide. Avobenzone is considered one of the substances that cause the most intense stains. In particular, when avobenzone mixes with the inorganic components present in hard water, it produces brown, rust-like stains (Ginnetti M. 2018). The non-removal of stains also depends on the fiber composition of the garment (usually synthetic garments are easier to clean than cotton or other natural fibers) and the hardness level of the wash water.

On white fabrics, the organic substances used as UV-absorbing filters in sunscreens cause intense yellow stains, while the inorganic substances titanium dioxide and zinc oxide leave faint white stains. In addition, it has been observed that fabrics that are washed in an alkaline solution using chlorine-based detergents (bleach), react with the filters present in the stain resulting in the yellow stain being stabilized due to the high pH and chlorine (Dawn N. Lock 2015 ). An important disadvantage of alkaline determinants is that they activate the acidic hydrogens contained in organic sunscreen filters. With the same mechanism affects chlorine (Christensen Stephen B. 2017).

The iron compounds used as colorants in sunscreens or that may be contained in the washing water can also create an intense problem, which iron compounds during washing react with the organic filters and create brown stains. Attempts to remove brown stains with conventional fixatives, enhancers and bleaches are not successful (Christensen Stephen B. 2017).

Correspondingly, on colored or dark fabrics, organic filters (avobenzone and oxybenzone) left a faint white stain, but titanium dioxide and zinc oxide left strong white stains (Ginnetti M. 2018).

The formulations available to date for the removal of stains from sunscreens and other cosmetics are usually liquid solutions of neutral pH with one or more surfactants, one or more chelating agents and one or more acids in aqueous solvents which aim to pretreat the soiled garment. before washing. Stains can be removed to some extent, but this depends on the hardness of the wash water as well as the type of fabric (natural or synthetic), and the highest possible wash temperature is required to ensure a good result. It is also customary to recommend washing at high temperatures in order to achieve decontamination of the stain, thus increasing the discoloration of colored fabrics (Dawn N. Lock 2015).

The problem of effective cleaning of stains from sunscreens or other cosmetics is mainly faced by professional areas (hotels, spas, restaurants, hair salons), where the cleanliness of linen (sheets, towels, tablecloths, etc.) is of primary importance. In this case, because it is not always easy to separate the fabrics stained by sunscreens or other cosmetics in mass washing of white goods, it is not practical to pre-treat the garment before washing it. Linens must be carefully inspected upon collection to identify areas that require further treatment or use of enhancers, thus increasing cleaning costs.

The impossibility of effectively cleaning stains from sunscreen and other cosmetic products containing pigments, the creation of a versatile cleaning powder, which can act independently without the use of enhancers, bleaches or other treatment liquids, provides a solution. At the same time, it achieves at relatively low temperatures (up to 60°C) the decontamination of the stain regardless of the hardness of the washing water, without of course affecting the quality of the fabrics.

Brief presentation of the invention as defined by the claims

The present disclosure provides information on the composition of sunscreen stain remover powder as well as information on the mode of action of the contained ingredients. The determining powder in question is a mixture of phosphate compounds (Sodium Triphosphate) up to 39.0% w/w, acids (Sulfamic acid up to 8.8% w/w, Oxalic acid 8.8% w/w, Boric acid 8.8% w/w, Citric acid 8.4% w/w), non-ionic surfactants (synthetic primary alcohols as non-ionic surfactants up to 8.1% w/w), oxygen-based bleaching compounds (Sodium Borate 7.2% w/w), Bicarbonate of soda 7.2% w /w, Sodium silicate 3.0% w/w, antifoam (Silicone 0.25% w/w), optical brightener (Indicotine 0.3% w/w) and fragrance up to 0.15% w/w.

The final produced laundry powder with the specific ratio of raw materials, utilizes their synergistic action to clean stains of two types of UV filters that are currently used in sunscreens: (a) organic filters, such as Ethoxylated Ethyl-4-Aminobenzoate (PABA) , octyl methoxycinnamate (OMC), benzophenone-3 (BP-3) or octocrylene, and (b) inorganic filters such as zinc oxide or titanium oxide, reflect UV rays as well as other pigments such as iron ions . The final product produced gives neutral solutions in dilution up to 10% with pH values between 7 and 8, which are more effective against alkaline products proven to leave yellow sunscreen stains. In addition, the composition of the powder in question allows its use with water supply of different hardness without the addition of additional salts even at low washing temperatures up to 60°C.

Thanks to the combination of its ingredients, it is not necessary to add other auxiliary agents such as pre-treatment liquids, bleaches, enhancers or fabric softeners to perfume the clothes. An important element of its action is that it remains effective in removing stains from various types and colors of fabrics such as synthetics, cotton, etc. In addition, it covers different types of stains that may be due to the different composition of sunscreens, edible oils, rust, makeup and lipstick. This is achieved as it successfully cleans the oily base of the stains and at the same time binds all the pigments contained in them, achieving their optimal neutralization.

Pointing out the advantages of the invention and relating them to the elimination of the disadvantages of the prior art

The usual detergents used to remove stains from sunscreen and other cosmetic products containing pigments are mixtures of surfactants with an alkaline pH, cleaning boosters or even bleaches aimed at removing stains in the prewash (Christensen Stephen B. 2017). They obligatorily require the use of salts to adjust the hardness of the washing water, softener and high temperature during washing. Even with these limitations they often cannot be effective against other ingredients in sunscreens and other cosmetics that contribute to blemishes such as pigments.

This problem is solved by the aforementioned cleaning powder with its composition, achieving multiple cleaning benefits against stains from sunscreens and other cosmetic products. The present disclosure provides critical compositional information of the cleaning powder as derived from a diagnosis of the shortcomings of the existing determinative products and method of production thereof.

In particular, the composition of the powder was designed to work at neutral pH, so as to avoid the alkaline environment that mobilizes the free electrons of UV filters and intensifies the intensity of yellow spots from sunscreens. For the same reason, chlorine is not included, which stabilizes the above stains. Thus, a mixture of phosphate compounds, with polycarboxylic acids, non-ionic and anionic surfactants, oxygen-based bleaching agent, sodium silicate, which produce a neutral pH with strong antifouling ability, was used as the basis of the determining product. In addition, an anti-foam agent was used to control foaming inside the washing machine, a fragrance and a brightening agent.

Its composition makes it possible to wash clothes at low temperatures, it is not affected by the hardness of the water, while at the same time it is equally effective on white as well as colored-dark clothes without the need to pre-treat the fabric. The dust cleaning formulation utilizes the synergistic combination of polycarboxylic acids along with phosphates, non-ionic surfactants, oxygen-based bleaching agents and an optical brightener to clean both types of UV filters at a neutral pH regardless of hardness. washing water.

This composition initially ensures in multiple ways the binding of the metal ions which either come from the pigments of the stain from the sunscreen which can be organometallic compounds (e.g. CI 10006 Sodium tris(1,2-naphthoquinone 1- oximato-0,0')ferrate(1-) or even those that may be contained in the hot tap water (e.g. calcium, magnesium, iron). In addition, the phosphate compounds contained in the detergent act as chelating agents of the inorganic compounds (titanium dioxide and zinc dioxide) used as filters in sunscreens, thus cleaning whitish stains from fabrics.

At the same time, the powder contains a suitable combination of polycarboxylic acids aimed at binding the oily base of organic UV filters as well as other pigments that may be contained. Their action is enhanced by the use of non-ionic surfactants (primary alcohols with a small carbon chain range), which improve the degreasing capacity of other substances contained in the cleaner. In this way, the ability to decontaminate stains at neutral pH is achieved.

An important advantage of the product is that it does not require the use of additional products such as washing boosters, bleaches, laundry salts or fabric softener to perfume the fabrics. The composition of the product contains the appropriate substances that reduce the surface tension, bind the ions responsible for the hardness of the water, increase the whiteness of the fabrics without chlorine and perfume the fabrics. Finally, thanks to a substance that is an optical brightening agent, the colors of the fabrics are protected and their brightness is increased.

All this gives the advantage of creating a washing powder for cleaning sunscreen and cosmetic product stains that has a low cleaning cost since it allows washing at low temperatures up to 60°C and is equally effective for professional and domestic applications regardless of fabric type.

Brief description of the illustrations shown in any drawings

The washing powder for cleaning stains from sunscreen or other determining products was developed by its inventor, Mr. Ioannis Fotakopoulos with Identity Card Number AI750760 after long-term tests with different proportions of ingredients until the desired effectiveness was achieved. Mr. Ioannis Fotakopoulos was the owner of the company LAVSTAR - Ioannis Fotakopoulos and Sons O.E. for 23 years. and in this context, as an expert soap maker, he was involved in the production of several key products for which he also conducted efficiency tests.

In order to test the effectiveness of this product, tests were carried out at different washing temperatures for sunscreen stains from different companies with different composition (A.I.S.E International Association for Soaps, Detergents and Maintenance Products 2018). Initially, white cotton fabrics such as 100% cotton hotel sheets were selected to ensure that the fibers are the most absorbent. These sheets after staining were washed for 3 hours at the following temperatures: T=40°C, T=60°C, T=90°C with tap water, which has medium hardness (Ca/Mg ratio is 3 ± 0 ,5). Washing was done by loading 5kg of clothes with 200g of determining powder. After washing they were evaluated for: (1) removal of the yellow stain, (2) removal of the oil base of the stain, (3) visual whiteness of the fabric. The test results are summarized in the following table:

Table 1 Results of washing powder tests for the removal of sunscreen stains on white cotton fabrics (sheets)

The following images show the photos of the fabrics before and after washing: Table 2 Images of laundry powder test results for removing sunscreen stains on white cotton fabrics (sheets) before and after washing

The above test was also carried out on colored fabrics for washing temperature T=40°C and T=60°C with the same amount of powder and washing time. Fabrics were evaluated for (1) off-white/yellow/orange stain removal, (2) oil base removal, (3) retention of color brightness with equally good results.

Table 3 Results of washing powder tests for the removal of sunscreen stains on colored cotton fabrics (sheets)

According to the existing standards for washing powders, the product should be tested for its effectiveness on standard stains, which the inventor is in the process of entrusting to a suitable accredited laboratory. However, the effectiveness of the product has been confirmed by its use by large hotel units, professional cleaners, but also domestic users for which it has received customer satisfaction certificates for this particular powder. These certificates are attached in a separate file

Detailed development of at least one embodiment of the invention using examples, in such a way as to clearly explain the productive application of the invention

The washing powder's cleaning ability against complex stains caused by sunscreen products and other cosmetic products is due to the synergistic action of its contained ingredients. In this context, its percentage composition plays a primary role, which includes: Sodium triphosphate up to 39.0% w/w, Sulfamic acid up to 8.8% w/w, Oxalic acid 8.8% w/w, Boric acid 8.8% w/w, Citric acid 8.4% w/w, Synthetic primary alcohols as non-ionic surfactants up to 8.1% w/w, Sodium borate 7.2% w/w, Bicarbonate of soda 7.2% w/w, Sodium silicate 3.0% w/w, Silicone 0.25% w/ w, Indicotin 0.3% w/w, Fragrance 0.15% w/w

According to the available data there are two main categories of sunscreens the colorless type (invisible on the skin when applied) and the opaque type, which is either a white lotion or cream. Depending on the ingredients contained in the sunscreen, different stains are created on linen and cotton fabrics (Dawn N. Lock 2015). In cases where the sunscreen contains coloring agents, the stains created on the fabric are brown or light brown.

For the removal of stains originating from metallic elements present in sunscreens, a chelating agent is needed which will bind the metallic ions. The phosphate compound sodium triphosphate is used as a chelating agent. In addition, according to the literature, the removal of suntan lotion stains is achieved by the formulation of a detergent that has a pH lower than 7 and consists of one or more acids, for this purpose sulfamic, boric, oxalic and citric acids were selected for the range of applications they have in cleaners.

Sulfamic acid is an acidic fixing agent, used as a substitute for hydrochloric acid to remove rust and metals contained in rust stains. Sunscreens contain inorganic UV filters such as zinc oxide and titanium dioxide, ingredients that have been reported to stain white and black fabrics. Specifically, zinc oxide and titanium dioxide leave off-white (non-sharp) stains on white fabrics and white intense stains on black fabrics. Therefore, sulfamic acid is a key factor in removing the stains left by sunscreens that contain UV filters of inorganic metal compounds.

Oxalic and citric acids were chosen for their ability to remove stains caused by organic UV filters and generally oily bases in cosmetic products.

In addition, boric acid was also complexed<1>, which has a special "affinity" with polyhydroxy compounds, such as polyols. Even in its dilute aqueous solutions, boric acid forms almost instantaneously with polyhydroxy compounds a kind of boric esters with boron in a tetrahedral structure. The formation of the esters is accompanied by the release of hydrogen cation, with the result that the boric acid indirectly becomes a stronger acid by 3 to 4 orders of magnitude.

To enhance the action of the above acids, non-ionic surfactants were used to improve the degreasing performance at low concentration, eliminating the need to use dangerous solvents. The main substance is 2-propyl heptanol which is a synthetic primary alcohol and is compatible with the most commonly used surfactants. It also has a very low odor, even though it is a small chain alcohol. (Edward Smulders 2011).

Said surfactants contain ethoxyl groups. The narrow range of ethoxyl groups makes the final product more effective while also imparting excellent low temperature cleaning performance (AkzoNobel Surface Chemistry n.d.).

The silicone contained in the product reduces the surface tension and improves the effectiveness of the fixing product. Silicone prevents foaming and is also chemically inert as it does not interfere with the chemical system (The Dow Chemical Company 2019).

Sodium perborate is used for applications that require a milder alternative to other bleaching agents. Sodium perborate is not as harsh as sodium hypochlorite and therefore does not fade on colored fabrics (Robinson 2017).

Sodium silicate offers an interesting combination of properties such as alkalinity, hardness binding ability, corrosion protection. Soluble sodium silicates are entirely inorganic and once diluted have no significant effect on the environment. In contact with Ca, Mg, AI or Fe they create insoluble silicates that occur in abundance in nature. When these are neutralized by the acidic ingredients in the recipe, they are recycled into amorphous silica (Silmaco Silicates Manufacturing Company n.d.).

Finally, Indicotin (Disodium 5,5'-(2-(1,3-dihydro-3-oxo-2H-indazol-2-ylidene)-1,2-dihydro-3H-indol-3-one)disulphonate was chosen ) as an optical brightener to ensure the brightness, whiteness of fabrics. Indicotin has the ability to bind to the fibers and cause a bleaching effect, which is due to the conversion of invisible UV radiation into longer wavelength visible light. UV light absorbed by sunlight is radiated as a light blue-green and together with the yellow tint of the stain on the garment produces pure white (Chemicalbook Fluorescent brightener 2016).

If an aqueous solution of boric acid, which is slightly acidic (pH 5.5-6), is added in excess of a polyol, which is a neutral compound, the pH of the solution decreases by 3 to 4 units.

Bibliography

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Claims (3)

1. The composition of the washing powder is obtained as a mixture of phosphate compounds (Sodium Triphosphate) up to 39.0% w/w, acids (Sulfamic acid up to 8.8% w/w, Oxalic acid 8.8% w/w, Boric acid 8.8% w/ w, Citric acid 8.4% w/w), non-ionic surfactants (synthetic primary alcohols as non-ionic surfactants up to 8.1% w/w), oxygen-based bleaching compounds (Sodium Borate 7.2% w/w), Bicarbonate of soda 7.2% w/w, Sodium silicate 3.0% w/w, antifoam (Silicone 0.25% w/w), optical brightener (Indicotin 0.3% w/w) and fragrance up to 0.15% w/w. 2. The specific composition characterized by the above contained ingredients utilizes their synergistic action for the effective cleaning of stains resulting from the filters against ultraviolet rays (UV) and the pigments contained in sunscreen and other cosmetic products. The final product produced gives neutral solutions in dilution up to 10% with pH values between 7 and 8, which are more effective against alkaline products proven to leave yellow sunscreen stains. In addition, the composition of the powder in question allows its use with water supply of different hardness without the addition of additional salts even at low washing temperatures up to 60°C. 3. Thanks to the combination of its ingredients, it is not necessary to add other auxiliary agents such as pre-treatment liquids, bleaches, enhancers or softeners for the fragrance of the clothes. An important element of its action is that it remains effective in removing stains from various types and colors of fabrics such as synthetics, cotton, etc. does not affect the quality of the fabrics.