LV15063B - An additive for the cleaning and protectant composition for the vehicle external surface, agent which contains this additive and use thereof - Google Patents

Abstract

The invention relates to a cleaning and protectant composition that is suitable for treatment of a vehicle external surface. An additive for the cleaning and protectant composition for the vehicle external surface which contains a quaternary ammonium compound as a surfactant is offered.

Description

The present invention relates to a detergent and cleaning agent useful for treating the exterior surface of a vehicle. in particular, this invention relates to a car care product which provides cleaning of the exterior surface of a vehicle while disinfecting the surface of the vehicle.

Known state of the art

The purpose of car care nowadays is to ensure not only the aesthetic appeal of motor vehicles, to ensure the protection of motor vehicle surfaces, but also to ensure the biosafety of the surfaces, namely, disinfection of the surfaces. There are both general purpose (universal) car care products and specialized car care products, as well as methods of using them. The main drawbacks of car care products and their application methods are their complex composition, the use of expensive substances, the high toxicity of the substances, solvents and other ingredients used, and the considerable amount of waste (mainly waste water) that is generated. Therefore, the development of solutions that reduce the impact on the environment by reducing the formation of waste water and the negative impact of the substances it contains on the aquatic environment is an important task for the development of car care products and their application methods. At the same time, it is critically important to ensure the proper use of car care products that meet known performance standards in order for the solutions developed to be competitive on the market.

A very important task in developing the composition of car care products and the methods of their application is to ensure disinfection of car surfaces. Biological material that settles on the surface of vehicles from the atmosphere, roads, animals, people with whom transport may come into contact, and other processes is a significant part of body contamination. Said biological material includes bacteria, viruses, fragments of viral membranes, DNA, cysts, toxins and other organic substances resulting from the biological activity of living organisms. In view of the growing regional epidemics, global pandemics, bio-terrorism and similar threats, biosecurity is becoming a necessity that requires new solutions, including in the area of vehicle maintenance. The maintenance of public transport, emergency services and army vehicles are of particular importance to biosafety. The purpose of vehicle care compositions is usually not to emphasize the goal of preventing biological material deposits, and this problem is not currently solved.

A large amount of biocides, substances with antimicrobial, antiviral and other biological activity is known to inhibit the development of living organisms. The effect of a biocidal product is linearly dependent on its concentration, but to achieve a biocidal effect it is necessary to achieve a certain concentration of the substance used. At the same time, only a very small proportion (<1%) of the applied amount of biocides used in car care is used for their direct purpose - surface disinfection. Most of the substances used for disinfection end up in sewage / waste and cause environmental pollution. The solution to this problem may be the use of substances characterized by a nonlinear quantity-dependence of the efficiency of use, that is, the use of a synergistic effect.

A surface cleaning composition and method of use based on the use of quaternary ammonium compounds and cationic biocides using the synergistic effect of a combination of the two components are known [1], but the potential of such a composition for car surface care has not been demonstrated. There is a known method of surface cleaning based on the synergistic effect of acyclic terpenes and thymol [2]. Each of these ingredients does not provide a significant, lasting antimicrobial effect over the concentration range studied, but their combined effect outweighs the additive effect, that is, their synergistic action due to the molecular nature of the interaction of the substances used. However, neither this method nor the proposed composition has been used for car surface treatment.

A composition consisting of modified silicone, cationic emulsifier and dispersant is also known [3]. Also known are spray-free anhydrous compositions consisting of polysiloxane and acrylic polymer [4] and biodegradable surfactant-containing spray compositions [5]. However, the known compositions do not completely eliminate the damage caused by abrasive soiling components in the washing process, nor do they ensure complete removal of biological material and disinfection of the surface to be cleaned.

Disclosure of the Invention

The object of the invention is to improve known cleaning agents for the external surfaces of motor vehicles by maintaining the high efficiency of known solutions, simplifying the composition of the used agents, reducing the negative impact of car care products on the environment and providing disinfection of the cleaning surfaces.

There is provided an additive for vehicle exterior surface care products containing surfactants and lower alcohols, wherein the additive contains a fourth ammonium surfactant. The additive may be used in an amount not exceeding 0.1% by weight of the concentrated care product.

The use of this additive in vehicle exterior surface care products results in a reduction in water consumption compared to traditional car care products and is therefore considered to be a water-saving and environmentally friendly solution. The use of the additive ensures high cleaning and disinfection efficiency and reduces detergent consumption as well as complete removal of biological material and disinfection of the surface to be treated.

The object of the present invention is achieved by using conventional auto windscreen cleaning compositions containing surfactants and lower alcohols together with an additive, a surfactant containing a fourth ammonium group. The use of such substances provides a synergistic effect, especially when subsequent cleaning of the cleaned surfaces with a combination of silicone oil and wax.

Brief description of the drawings

Fig. 1 the results of the comparison of the foaming performance of Riwax and Pingo car washes and alkyldimethylammonium chloride (ADAH) in the mixture and separately are shown; 1A - Experiment or Riwax; 1B - Experiments or Pingo. Riwax and Pingo concentrations are 1%.

Fig. 2 - Comparison of the washing performance of Riwax and Pingo car washes and alkyldimethylammonium chloride (ADAH), in a mixture and separately. Riwax and Pingo concentrations are 1%.

Fig. 3 - Analysis of the potential biodegradability of Pingo and Riwax (1%) car window cleaners: Biogas Oxygen Consumption (BSP7) during incubation of the bacterial consortium in the OxiTop® OC-100 system depending on the concentration of alkyldimethylammonium chloride (ADAH) added.

Fig. 4 - Logarithmic reduction of P.fluorescens AM11 KW after 5 minutes of incubation with vehicle cleaners in the presence of 1% Pingo or 1% Riwax, with or without 0.001% ADAH.

Fig. 5 - Comparison of the radius of inhibition formed by Riwax (6.25%) and ADAH (0.001%) in TGA plates with Micrococcus luteus.

The use of the proposed additive involves adding it to commercially available car window cleaners in an amount not exceeding 0.1% by weight of the concentrated care agent and treating the respective surfaces to be cleaned with the mixture.

The additive is intended for use in combination with vehicle surface care products (especially car window care products) containing surfactants and lower alcohols. The additive contains quaternary ammonium surfactants. The invention may utilize automotive glass cleaners available on the Latvian market and provide effective cleaning of exterior surfaces from soil particles, insect debris, oil and other petroleum product residues such as Bioline, Shell, and others, especially Pingo. "And Riwax." The advantage of using the proposed product is the reduction of the number of products used in car care, since the same preparation is used for cleaning both car windows and bodywork.

The car window cleaner should be diluted with water to a concentration of at least 1% of the initial amount, according to the instructions for use. The car cleaning process involves applying an automotive glass cleaner with additives to the car's surface using well-known car care methods, such as spraying or cloth application. Benzylammonium alkyl derivatives of the general formula are added to the dilution process or to the preparation for cleaning:

wherein R _{b is} R ₂ , and R ₃ is (C 1 -C 4) alkyl; and X 'is F, CF, Br or another strong inorganic acid salt.

Benzylammonium alkyl derivatives interact strongly with the outer membranes of living cells and negatively charged, structurally and functionally relevant portions of biomolecules. The anionic surfactant used is particularly active against negatively charged particles (such as clay). Benzylammonium alkyl derivatives are used in concentrations up to 0.1% in the mixture used. It should be noted that these substances alone do not provide bactericidal effects at such concentrations, but as demonstrated by their combination with car care products, they achieve a significant effect due to the interaction between the ingredients of the composition and their action at the molecular level. Such an effect is based on a mechanism of synergistic action. The importance of the synergistic effect is due to the fact that the effect is provided by low concentrations of the substance; thus reducing the amount of substances released into the environment and their negative impact on the environment.

After application of the car window cleaner with the proposed additives on the surface to be cleaned, it may be treated with a silicone mixture consisting of 35 to 65% by weight of a high to medium viscosity silicone fluid (oil) such as polydimethylsiloxane with a viscosity of 200-100000 cSt at 25 ° C, and from 35 to 65% by weight of synthetic silicone wax.

If necessary, the composition may also contain coloring and flavoring agents. The composition may be packaged in an aerosol can, pumpable dispenser or other spray form.

A silicone fluid (oil) is a mixture of silicones containing an alkyl modified silicon polymer such as polydimethylsiloxane, polydiethylsiloxane or other siloxane derivative, preferably polydimethylsiloxane (polydimethylsiloxane is an industrially produced oil with a viscosity of 500 for c). The use of alkylmodified silicon polymer in the cleaning process ensures the dissolution of tar and grease and the formation of a stable emulsion. The alkyl modified silicon polymer has a content of 35-65%, preferably 45%. The other component is synthetic wax. Silicone wax can be a partially or fully methylated silicone derivative (for example, trimethylated silicone wax). The wax content is 65-35%, preferably 55%.

It is recommended to use the described composition in aerosol or spray form. The composition is suitable for filling into an aerosol can or spray of any design. Spray or aerosol application is recommended for both pre-treatment and cleaning stages. However, it is also possible to apply the product in other ways: by using impregnated wipes, sponges or similar carriers suitable for applying the composition to the surface to be cleaned. The product is suitable for all vehicles (passenger cars, motorcycles, heavy machinery, etc.) or specially contaminated parts of vehicles. Vehicles contaminated with biological material may be treated similarly to other vehicles, but in the case of extremely persistent contamination (such as blood), it is recommended that the cleaning process be repeated. In cases where hazardous biological contamination of the surface to be treated is possible, personal protective equipment (gloves, goggles, respirators, bio-safety clothing) should be used. The recommended method of application reduces the risk of contamination spreading because the cleaning process does not produce waste water, but all surface contamination builds up in the fabric used during the final cleaning phase and can be disinfected or destroyed relatively easily.

Examples of realization of the invention.

Dilute “Pingo” or “Riwax” car care product to a concentration of at least 1% of the original according to the instructions for use, add alkyldimethylammonium chloride (ADAH) at a concentration of 0.001% and spray on the surface to be cleaned. Hold for up to 0.5 hours, then spray on the surface with a mixture of silicone oil (45%) and silicone wax (55%) and wipe with a microfiber cloth.

1. Test for the ability of car window cleaners and their mixtures with ADAH to clean.

1.1. Foaming ability a.

The foaming capacity is determined by the perforated disk method LVS EN 12728. A handheld device is used for foaming liquid with a perforated disk for 1 minute (60 cycles per minute). The test liquid and the control liquid (0.02% sodium dodecyl sulphate solution) are foamed in parallel. The experiment was performed in duplicate. The foaming capacity is determined at 26 ± 2 ° C. The volume of foam Vs (%) is calculated by the formula:

Vs = V ₂ / Vix100, where: Vj is the volume in ml of sodium dodecyl sulphate (0.02%); V ₂ - volume of foam of the test sample, ml.

The foam volume is determined after 1, 3, 5, 10 minutes. Test liquid consists of 1% detergent with 0%, 0.1% and 0.001% benzalkonium chloride.

Comparing the foaming capacity of 1% Riwax and Pingo, alone and in admixture with 0.1% or 0.001% ADAH, it is shown that 0.1% ADAH reduced the foaming capacity of the given products, while 0.001% ADAH did not affect the foaming capacity of the tested products. (Fig. 1).

1.2. Washing efficiency.

Description of the method. The washing efficiency is determined by the rotating disk method. Dirt is applied to the disc, which is then immersed in the liquid under investigation and spun at a specified speed.

Ί

Washing time 6 minutes (4 minutes merce and 2 minutes spin). Cutting speed - 150 rpm. Liquid temperature - 25 C. Calculate the percentage of dirt washed after washing.

Dirt composition:

Peanut oil -9.5g Laser Copper Toner - 3.4 g Sunflower oil - 19.0g FeO - 1.9g Diesel oil Clay (Prometheus) -28.5g -36.9g Fe ₂ O ₃ -0.8g

Results. When testing the washing efficiency of individual agents and their mixtures by the rotating disk method, a decrease in efficiency was found in mixtures containing 0.1% ADAH in 1% Riwax or Pingo products. The washing efficiency of the given products was not affected in the presence of 0.001% ADAH (Fig. 2).

2. Potential biodegradability.

Description of the method. The biodegradability potential (biological oxygen demand BSP7) of the tested products was determined with the OxiTop ® OC100 manometric respirometer. Bushnell Haas (BH) medium (g L ' ¹ : MgSCL - 0.2; CaCL · - 0.02; KH ₂ PO ₄ - 1.0; K ₂ HPO ₄ - 1.0; NH ₄ NO ₃ - 1.0 was used FeCl ₃ - 0.05), pH 7.0. 90 ml of medium (including 1% Pingo, 1% Riwax, as well as 0.001% and 0.1% BC1) was added to the bottle with the addition of 3 ml bacterial consortium inoculum (1.2 χ 10 ⁸ CFU) ml ' ¹ ). After incubation for 7 days at 24 ° C with a magnetic stirrer, the manometric readings were read using AchatOC software. The number of colony forming units (KW) was determined after 7 days of incubation by decimal dilution of culture and plating on Tryptone Glucose Yeast Extract Agar (TGA). KW counted after 48 h. incubations at 28 ° C.

Results. Figure 3 shows the bacterial consortium oxygen (BSP7) consumption in closed bottles in the presence of Pingo and Riwax as well as ADAH. As shown by BSP dynamics, 1% Pingo has a higher biodegradability compared to 1% Riwax. This could be related to the chemical composition of the products and / or their microbiological biodegradability. The addition of 0.001% or 0.1% ADAH did not affect the biodegradability of 1% detergents (Fig. 3).

3. Testing of bactericidal activity.

3.1. Quantitative suspension test.

The test was performed using a modified dilution-neutralization test method described in Latvian standard LVS EN 1040: 2006.

Description of the method. Test organism Pseudomonas fluorescens AM11 was prepared by testing two subcultures on tryptone soy agar (TSA) medium for 24 h. 28 ° C. The concentration of colony forming units (KW) in bacterial culture was 5.6 * 10 ⁸ CFU / ml. The bactericidal concentration was determined by adding P. fluorescens AM11 test suspension to dilutions of the test substances in water. After 5 minutes of incubation, 100 μΐ of the resulting liquid is transferred to a centrifuge tube containing 900 μΐ of neutralizer (0.25 mol / L KH2PO4). Five minutes after neutralization, prepare decimal dilutions of the neutralized solution and inoculate on TSA medium in duplicate. Plates are incubated at + 28 C and after 24 h. determines the number of KWs. After 24 hours re-count colonies. If the number of KW has increased, the highest number shall be taken into account.

The bactericidal activity of the agents has been characterized by calculating the logarithmic reduction in the number of KWs by the formula:

Logarithmic reduction = log ₁₀ (-), B where A is the number of KWs before treatment, B is the number of KWs after treatment.

Results. The results of the dilution-neutralization test method are summarized in Figure 4. After 5 minutes of incubation, 1% Pingo and Riwax bactericidal activity was tested on P. fluorescens AM11 KW count under test conditions with log reductions of 3.8 and 2.5, respectively. Addition of ADAH (0.001%) to Riwax (1%) significantly enhanced the antibacterial effect, i.e. from 3 to 9 logs (Fig. 4). In contrast, the addition of 0.001% ADAH to 1% Pingo detergent showed no improvement in bactericidal activity (Fig. 4).

3.2. Agar diffusion test.

Description of the method. The agar diffusion test is based on monitoring the effect of bactericidal agents on the diameter of the inhibition zones. Gram-positive bacteria Micrococcus luteus were used as test organisms in this method. Bacterial suspensions in water were prepared and plated on Petri plates with tripton yeast glucose agar (TGA) (50 μΐ suspensions in 5.2 cm diameter plates, 100 μΐ suspensions in plates 8.5 cm diameter). Using a sterile 200 μΐ pipette tip, 2 holes were pressed into the TGA plate (0 5.2 cm) at a distance of approximately 2 cm. Each variant was tested in triplicate. 40 μΐ of the product or mixture of agents are added to the well. Plates were incubated for 24 h. At + 28 ° C and then the radii of inhibition zones were measured.

Results. In Riwax 6.25% + ADAH 0.001%, the increase in inhibition zone was statistically significant (p <0.05) (Fig. 3). As a result, there is a synergistic interaction between Riwax and ADAH in this variant.

Sources of information cited.

[1] Herdt B., Smith K.R., Straub R., Tauer K. 2012. Wear-resistant antimicrobial compositions and methods of use. WO 2012080918.

[2] Cornmell R.J., Diehl M.A., Golding S., Harp J.R., Stott I.P., Thompson K.M., Truslovv C.L. 2013. Method for disinfecting a surface. WO 2013083590.

[3] Hovve M.W. 1996. Locomotive protectant for use in vvith cleaning compositions. US 5,518,533.

[4] Serobian A. 2008. Sprayable dry vvash and wax composition comprising silicone blend and acrylic-basedpolymer. US 7,399,738.

[5] Schulz M.A., Joseph IIF. W., Deddo M.A. 2011. Sprayable vvash and wax composition. US 7981853.

Claims (6)

An additive for vehicle exterior surface care product comprising a surfactant and lower alcohols and an ammonium surfactant additive, characterized in that the ammonium surfactant is a quaternary ammonium surfactant. The additive of claim 1, wherein the quaternary ammonium-containing surfactants are benzylammonium alkyl derivatives of the general formula: r. wherein R 1, R 2 and R 3 are (C 1 -C 6 alkyl); and X 'is F', Cl ', Br' or another strong inorganic acid salt. The additive according to claim 1 or 2, wherein the quaternary ammonium-containing surfactant is alkyldimethylammonium chloride. Vehicle exterior surface care product comprising a concentrated car care product and an additive according to any one of the preceding claims, wherein the amount of additive does not exceed 0.1% by weight of the concentrated car care product. Use of the agent of claim 4 for cleaning and disinfecting the exterior surface of vehicles. Vehicle exterior surface care kit comprising a silicone mixture, a care product according to claim 4 and an additive according to any one of claims 1 to 3.