A Tool for Removing Metal Inclusions from the Surface of Paint and Varnish Car Coatings

In this article, we presents the synthesis and research of a tool for removing metal inclusions from the surface of car paint coatings. The optimal composition of the product was determined, which includes sodium laureth sulfate, citric acid, sulfosalicylic acid, hydrogen peroxide and water. As a result of the conducted studies, a connection was established between the composition and the physicochemical, surface-active properties of the developed agent. Approbation of this tool was carried out, which confirmed its effectiveness and showed that within 30–45 s after applying the developed tool, not only are metal inclusions on the surface of car paint coating removed but also mineral contaminants in the form of sand, earth, clay and other particles. The aim of the work was to develop and optimize a method for obtaining a low-toxicity, highly effective agent for removing metal inclusions from the surface of car paint coatings and to investigate its effectiveness, as well as its physicochemical, optical and surface-active properties.


Introduction
The high level of modern automobilization has led to a number of issues connected with car operation [1]. The field of auto detailing has undergone intensive development. Auto detailing can be divided into three components: external detailing, internal detailing and engine detailing. Exterior detailing, which consists of the repair, restoration and protection of car paint coatings, is of particular importance.
Booking (application of a film on the reserve of paint and varnish) is used in external detailing and involves installation of deflectors on the car's hood, as well as application of special protective tools [2].
Nowadays, most corrosion removal methods are based on the use of highly concentrated substances, such as phosphoric acid, hydrochloric acid, sulfuric acid, etc. [3][4][5]. These components are chemically aggressive substances that excessively destroy metal surfaces [6,7]. As car paint is chemically sensitive, the use of chemically mild means is mandatory [8,9].
The use of special protective agents on car paint coatings includes the application of liquid or paste-like compositions to the prepared surface, which interact with the top layer of the treated coating and form a thin protective film on it [8]. The following methods are used to protect the body paint coating of cars [9]: (1) Application of special wax-based polishing compositions; (2) Application of special latex or vinyl-based compositions; (3) Application of special silicon-dioxide-based nanocomposites.
To ensure high-quality auto detailing, the surface preparation stage of paint coating is essential. A range of preparations are available to clean the surface step by step from pollutants of various nature, including bituminous particles, metal inclusions and contamination in the form of sedimentary rocks (sand, dust, etc.) [10].
Most tools used to clean the surface of a car's paintwork of metal inclusions contain sulfur compounds that, when interacting with contamination, are destroyed by the release of hydrogen sulfide [11][12][13]. Hydrogen sulfide is a toxic gaseous compound with an unpleasant, pungent odor that irritates the mucous membrane of the respiratory tract [14][15][16][17][18].
A review of literature data on the automotive chemical market showed [19][20][21] that most car surface cleaning and dirt removal products contain the following components:

1.
Surfactants. Compounds from the group of ionic and nonionic surfactants are used as surfactants: sodium laureth sulfate, Berol 226, APG and others [14]. Surfactants are used to improve tool contact to remove metal inclusions and impurities from the surface of the car's paintwork, to disperse and solubilize contamination surfactant micelles and facilitate their subsequent removal from the surface of the car's paintwork. Computer quantum-chemical modeling of Fe-sulfosalicylic acid complexes in the QChem 5.0 program using the IQmol molecular editor. Construction parameters: calculation: energy; method: HF; basis: 6-31 G; convergence: 5; force field: chemical [25]; -Optical microscopy on an IM 7200 microscope ("Meiji Techno" Inc., Tokio, Japan). Microscopy of contaminated samples of car paint and varnish coatings was carried out on a surface area of 1 cm 2 ; - The surface tension was determined on an automatic DCAT tensiometer ("DataPhysics Instruments GmbH", Filderstadt, Germany); -Viscometry was performed on a "Fungilab Expert" rotary viscometer ("Fungilab S. A.", Madrid, Spain), the action of which is based on the use of viscous friction arising in a layer of liquid flowing in an annular gap between a rotating and stationary cylinder.
All studies were carried out in a threefold repetition. The significance of the experimental results was determined using the Fisher criterion.

Method of Obtaining a Tool for Removing Inclusions from the Surface of Car Paint and Varnish Coatings
In the developed low-toxicity, highly effective agent, sodium laureth sulfate was used as a surfactant-an anionic surfactant with both lyophilic and lyophobic properties-which is widely used as a foaming agent, emulsifier, detergent, and strong cleaning and wetting agent in the household industry, cosmetology and pharmacology [26]. Due to its excellent washing and cleaning ability, sodium laureth sulfate is used for the production of liquid household and technical cleaning products [27].
Sulfosalicylic acid, which is used in analytical chemistry as a reagent for the detection and isolation of metal ions, was used as an indicator. For example, the Fe 3+ ion forms pinkish-brown monosulfosalicylate, brown disulfosalicylate and yellow trisulfosalicylate [28].
The method for obtaining a low-toxicity, highly effective agent for removing metal inclusions on the surface of car paint coatings includes the following stages: (1) In the first stage, sodium laureth sulfate and sulfosalicylic acid are dissolved in water and mixed; (2) Then, hydrogen peroxide is added to the reaction mass, and the whole system is mixed for 15 min; (3) Then, citric acid is introduced into the reaction mass; (4) Then, the reaction mixture is mixed for 20 min; (5) Finally, the resulting product is packaged.

Investigation of the Optical Properties of Sulfosalicylic Acid Complexes with Trivalent Iron Ions (Fe 3+ )
To determine the possibility of using sulfosalicylic acid as an indicator of Fe 3+ ions in the composition of a metal inclusion removal agent, the absorption spectra of 0.01 M solutions of iron chloride FeCl 3 , sulfosalicylic acid and their mixtures were measured. The solutions were prepared by the exact weighting method: the exact mass of the reagent was hung on an analytical balance scale; then, it was transferred to a 100 mL Mora flask and filled with distilled water until full. The prepared solutions were kept for 24 h at room temperature. The optical density was measured using a UNICO 2802 spectrometer (United Products & Instruments, Inc., Suite E Dayton, NJ, USA) with quartz cuvettes. The measurement parameters were as follows: -Measuring range: 200-1100 nm; 1. Scanning step: 0.5 nm; 2. Thickness of the cuvette: 10 mm.
Data processing was carried out in OriginPro 2018 software.

Determination of the Effect of the Active Acidity of the Medium on the Optical Properties of Fe-Sulfosalicylic Acid Complexes
To determine the effect of the active acidity of the medium on the optical properties of the sulfosalicylic acid-Fe complexes, a series of buffer solutions with different values of active acidity of the medium (pH 4 to 13) was prepared. To this end, a solution of a mixture of phosphoric, acetic and boric acids with a concentration of 0.04 M of each acid was prepared. Then, the required volume of 0.2 N NaOH solution was added to 100 mL of the acid mixture, as shown in Table 2. The resulting solutions were kept for 24 h after preparation. Then, 9 mL of buffer solutions with a certain value of the active acidity of the medium were mixed with 0.5 mL of 0.01 M solution of iron chloride FeCl 3 and 0.5 mL of 0.01 M solution of sulfosalicylic acid. The optical density of the obtained solutions was measured using a UNICO 2802 spectrometer (United Products & Instruments, Inc., Suite E Dayton, NJ, USA) with quartz cuvettes. The measurement parameters were as follows: - Measuring range: 300-1100 nm; -Scanning step: 0.5 nm; -Thickness of the cuvette: 10 mm.
Data processing was carried out in OriginPro 2018 software.

Determination of the Optimal Complexing Agent for the Removal of Metal Inclusions on the Surface of Car Paint and Varnish Coatings
A series of samples of a mixture of sulfosalicylic acid and Fe 3+ ions containing the following complexing agents was prepared: orthophosphoric, citric, oxalic and oxy-ethylidene diphosphonic acids, as well as Trilon B. The solutions were prepared by the exact weighting method: 0.1 g of the complexing agent and 0.1 g of sulfosalicylic acid were hung on analytical balance scales; then, the reagents were transferred to a 100 mL Mora flask and filled with distilled water until full.
Using quartz cuvettes, the optical density was measured with a UNICO 2802 spectrometer (United Products & Instruments, Inc., USA). The measurement parameters were as follows: To determine the optimal composition of a low-toxicity, highly effective tool for removing metal inclusions on the surface of paint coatings of cars, which provides for the complete removal of impurities and metal inclusions, we optimized its method of attainment through neural network processing of experimental data. Mathematical processing of the received data was carried out in Statistica 12.0 software.
Preliminary experiments made it possible to identify the factors (variable parameters) with the greatest impact on the physicochemical and surface-active properties of the tool for removing metal inclusions:
The levels of variation of all these variable parameters are presented in Table 3.  10 15 In to study the four selected factors at four variable levels, an orthogonal plan of 16 experiments was used in threefold repetition [30][31][32].
To study the mutual influence of all factors with a minimum number of experiments, the Greek-Latin squares method was used, and a planning matrix was formed (Table 4).  The numerical values of the variable parameters for each experiment are presented in Table 5.  5  15  10  10  13  11  0  10  30  14  11  5  15  20  15  11  10  0  10  16  11  15  5  0 As a result of the experiment, the values of the response functions for each experiment were obtained (Table 6). As a result of mathematical processing of the obtained experimental data, a neural network was formed in Neural Statistica Network 12.0 software [33], the architecture of which is shown in Figure 1. As a result of the experiment, the values of the response functions for each experiment were obtained (Table 6). As a result of mathematical processing of the obtained experimental data, a neural network was formed in Neural Statistica Network 12.0 software [33], the architecture of which is shown in Figure 1.  Four series of sulfosalicylic acid solutions with concentrations of 0.0001, 0.001, 0.01 and 0.1 M and four series of iron chloride solutions with the same concentrations were prepared. The solutions were prepared by the exact weighting method: the exact mass of the reagent was hung on an analytical balance scale; then, it was transferred to a 100 mL Mora flask and filled with distilled water until full. The prepared solutions were kept for 24 h at room temperature. The obtained solutions of sulfosalicylic acid and iron (III) chloride were alternately mixed and the absorption spectra in the UV and visible regions were measured. The optical density was measured using a UNICO 2802 spectrometer (United Products & Instruments, Inc., USA) with quartz cuvettes. The optical density of the absorption band at 500 nm was determined from these spectra. Data processing was carried out in OriginPro 2018 software.

Identification of Contaminants on the Surface of Car Paint and Varnish Coatings
To identify dirt on the surface of a car's paintwork, 10 mm × 10 mm metal plates were used that were cut from various parts of a car: the hood, front bumper, rear bumper, fender and front door. Energy dispersion analysis of the samples was carried out on a MIRA-LMU scanning electron microscope with an AZtecEnergy Standard/X-max 20 (Standard) elemental composition determination system from Tescan.

Investigation of the Composition of Road Dust
A sampling of road dust was collected in the city of Stavropol. For this study, 5 parallel samples were taken on different highways weighing 1 g each. The obtained samples were dried at 50 • C for 4 h. Energy dispersion analysis of the samples was carried out on a MIRA-LMU scanning electron microscope with an AZtecEnergy Standard/X-max 20 (standard) elemental composition determination system from Tescan.

Results and Discussion
In the first stage, we studied optical properties as an indicator for Fe 3+ ions of sulfosalicylic acid complexes to determine the possibility of using sulfosalicylic acid as a highly effective, low-toxicity agent for removing metal inclusions on the surface of car paint coatings. To this end, the absorption spectra of 0.01 M solutions of iron chloride (FeCl 3 ), sulfosalicylic acid and their mixtures were measured. The obtained data are presented in Figure 2.  Analysis of the obtained data revealed that aqueous solutions of iron (III) chloride and sulfosalicylic acid do not absorb radiation in the visible region of the spectrum, and their selective absorption bands are in the ultraviolet region at and λ1 = 295 nm and λ2 = 310 nm, respectively. However, in the absorption spectrum of a mixture of iron (III) chloride and sulfosalicylic acid and absorption in the ultraviolet region, there is a bright, high-intensity band at 500 nm characteristic of complexes of sulfosalicylic acid and iron ions [34].
Next, an experiment was carried out to determine the effect of the active acidity of the medium on the optical properties of these complexes. To this end, we used a series of samples of complexes of sulfosalicylic acid and iron ions with different active acidity values of the medium (pH from 4 to 13). To quantify the effect of the active acidity of the medium on the optical properties of complexes of Fe 3+ ions with sulfosalicylic acid, the absorption spectra of the obtained samples were measured, which are shown in Figure 3. Analysis of the obtained data revealed that aqueous solutions of iron (III) chloride and sulfosalicylic acid do not absorb radiation in the visible region of the spectrum, and their selective absorption bands are in the ultraviolet region at and λ 1 = 295 nm and λ 2 = 310 nm, respectively. However, in the absorption spectrum of a mixture of iron (III) chloride and sulfosalicylic acid and absorption in the ultraviolet region, there is a bright, high-intensity band at 500 nm characteristic of complexes of sulfosalicylic acid and iron ions [34].
Next, an experiment was carried out to determine the effect of the active acidity of the medium on the optical properties of these complexes. To this end, we used a series of samples of complexes of sulfosalicylic acid and iron ions with different active acidity values of the medium (pH from 4 to 13). To quantify the effect of the active acidity of the medium on the optical properties of complexes of Fe 3+ ions with sulfosalicylic acid, the absorption spectra of the obtained samples were measured, which are shown in Figure 3.  Analysis of the obtained data revealed that the maximum active acidity value of the medium of a highly effective, low-toxicity agent for removing metal inclusions from the surface of a car's paintwork, at which the presence of iron ions with the formation of bard complexes is detected, is pH = 6.
According to the literature data [35], at different pH values, the reaction of sulfosalicylic acid with Fe 3+ ions occurs with the formation of other Fe-sulfosalicylic acid complexes: monosulfosalicylate, disulfosalicylate and trisulfosalicylate acids. To determine the most energetically favorable type of interaction of one Fe 3+ ion with sulfosalicylic acid molecules, quantum chemical modeling was performed in QChem software using the IQmol molecular editor. Figure 4 shows the model, the electron density distribution, the electron density gradient and the molecular orbitals of the sulfosalicylic acid molecule.  Analysis of the obtained data revealed that the maximum active acidity value of the medium of a highly effective, low-toxicity agent for removing metal inclusions from the surface of a car's paintwork, at which the presence of iron ions with the formation of bard complexes is detected, is pH = 6.
According to the literature data [35], at different pH values, the reaction of sulfosalicylic acid with Fe 3+ ions occurs with the formation of other Fe-sulfosalicylic acid complexes: monosulfosalicylate, disulfosalicylate and trisulfosalicylate acids. To determine the most energetically favorable type of interaction of one Fe 3+ ion with sulfosalicylic acid molecules, quantum chemical modeling was performed in QChem software using the IQmol molecular editor. Figure 4 shows the model, the electron density distribution, the electron density gradient and the molecular orbitals of the sulfosalicylic acid molecule.  Analysis of the obtained data revealed that the maximum active acidity value of the medium of a highly effective, low-toxicity agent for removing metal inclusions from the surface of a car's paintwork, at which the presence of iron ions with the formation of bard complexes is detected, is pH = 6.
According to the literature data [35], at different pH values, the reaction of sulfosalicylic acid with Fe 3+ ions occurs with the formation of other Fe-sulfosalicylic acid complexes: monosulfosalicylate, disulfosalicylate and trisulfosalicylate acids. To determine the most energetically favorable type of interaction of one Fe 3+ ion with sulfosalicylic acid molecules, quantum chemical modeling was performed in QChem software using the IQmol molecular editor. Figure 4 shows the model, the electron density distribution, the electron density gradient and the molecular orbitals of the sulfosalicylic acid molecule.    Figure 5 shows the results of quantum chemical modeling to determine the most energetically favorable type of interaction of one Fe 3+ ion with different parts of the sulfosalicylic acid molecule, corresponding to the formation of iron monosulfosalicylate in an acidic medium. For calculations, the free two bonds of the Fe 3+ ion were subjected to hydration. The calculated data of chemical energy are presented in Table 7.   Figure 5 shows the results of quantum chemical modeling to determine the most energetically favorable type of interaction of one Fe 3+ ion with different parts of the sulfosalicylic acid molecule, corresponding to the formation of iron monosulfosalicylate in an acidic medium. For calculations, the free two bonds of the Fe 3+ ion were subjected to hydration. The calculated data of chemical energy are presented in Table 7.   Figure 5 shows the results of quantum chemical modeling to determine the most energetically favorable type of interaction of one Fe 3+ ion with different parts of the sulfosalicylic acid molecule, corresponding to the formation of iron monosulfosalicylate in an acidic medium. For calculations, the free two bonds of the Fe 3+ ion were subjected to hydration. The calculated data of chemical energy are presented in Table 7.  According to theoretical concepts [36], the most stable type of compound is one with minimal energy. Analysis of the obtained data showed that the most energetically favorable type of interaction of the Fe 3+ ion with a sulfosalicylic acid molecule in an acidic medium proceeds with the formation of a chemical bond with a sulfo group.
In the next stage, the interaction of the Fe 3+ ion with two sulfosalicylic acid molecules was simulated, which is characteristic of the formation of disulfosalicylate in the neutral pH region. To this end, models of molecules of three possible types of interaction of the Fe 3+ ion with two sulfosalicylic acid molecules were obtained. To simplify the calculations, the free bond of the Fe 3+ ion was subjected to hydration. The calculated chemical energy data are shown in Table 8, and the model of the most energetically favorable type of interaction of the Fe 3+ ion with a sulfosalicylic acid molecule is presented in Figure 6. Table 8. Calculated data of the chemical energy of iron disulfosalicylate molecules.

Type of Interaction
Chemical Energy, kJ/mol Interaction of the Fe 3+ ion with carboxyl and hydroxyl groups of two sulfosalicylic acid molecules 246.6674 Interaction of the Fe 3+ ion with the carboxyl and hydroxyl groups of a sulfosalicylic acid molecule and the sulfo group of another molecule 100.598 Interaction of the Fe 3+ ion with the sulfo groups of two sulfosalicylic acid molecules 34.5888  According to theoretical concepts [36], the most stable type of compound is one with minimal energy. Analysis of the obtained data showed that the most energetically favorable type of interaction of the Fe 3+ ion with a sulfosalicylic acid molecule in an acidic medium proceeds with the formation of a chemical bond with a sulfo group.
In the next stage, the interaction of the Fe 3+ ion with two sulfosalicylic acid molecules was simulated, which is characteristic of the formation of disulfosalicylate in the neutral pH region. To this end, models of molecules of three possible types of interaction of the Fe 3+ ion with two sulfosalicylic acid molecules were obtained. To simplify the calculations, the free bond of the Fe 3+ ion was subjected to hydration. The calculated chemical energy data are shown in Table 8, and the model of the most energetically favorable type of interaction of the Fe 3+ ion with a sulfosalicylic acid molecule is presented in Figure 6. Table 8. Calculated data of the chemical energy of iron disulfosalicylate molecules.

Type of Interaction Chemical Energy, kJ/mol
Interaction of the Fe 3+ ion with carboxyl and hydroxyl groups of two sulfosalicylic acid molecules 246.6674 Interaction of the Fe 3+ ion with the carboxyl and hydroxyl groups of a sulfosalicylic acid molecule and the sulfo group of another molecule 100.598 Interaction of the Fe 3+ ion with the sulfo groups of two sulfosalicylic acid molecules 34.5888 In the next stage, the interaction of Fe 3+ with three sulfosalicylic acid molecules was simulated, which is characteristic of the formation of trisulfosalicylate in the alkaline region. The structural formulae of the obtained models are presented in the Table 9. In the next stage, the interaction of Fe 3+ with three sulfosalicylic acid molecules was simulated, which is characteristic of the formation of trisulfosalicylate in the alkaline region. The structural formulae of the obtained models are presented in the Table 9.  The chemical energy of all types of interaction of three molecules of sulfosalicylic acid and an iron ion was calculated in QChem software using the IQmol molecular editor. The results of the calculation of chemical energy are presented as a histogram in Figure 7.   Through sulfo groups of sulfosalicylic acid molecules   As a result of the simulation, it was determined that the molecular system of interaction of three sulfosalicylic acid molecules and an iron ion has the lowest energy when binding an iron ion to sulfo groups and that this configuration of the molecule is the most optimal. A model of the energetically favorable configuration of the iron trisulfosalicylate molecule is presented in Figure 8. As a result of the simulation, it was determined that the molecular system of interaction of three sulfosalicylic acid molecules and an iron ion has the lowest energy when binding an iron ion to sulfo groups and that this configuration of the molecule is the most optimal. A model of the energetically favorable configuration of the iron trisulfosalicylate molecule is presented in Figure 8. Analysis of the obtained data revealed that sulfosalicylic acid exhibits pronounced indicator properties with respect to trivalent iron ions and can be used as an indicator in the developed low-toxicity, highly effective tool for removing metal inclusions on the surface of car paint coatings.
Next, an experiment was conducted to determine the optimal complexing agent for a low-toxicity, highly effective tool for removing metal inclusions on the surface of car paint coatings. The choice of the optimal complexing agent determines the compound that has the least effect on the interaction of the indicator-sulfosalicylic acid with iron ions (Fe 3+ )-with the formation of iron sulfosalicylates, which display intense staining in aqueous solutions due to a high-intensity absorption band at 500 nm.
To this end, a series of samples of a mixture of sulfosalicylic acid and Fe 3+ ions containing the following complexing agents was prepared: orthophosphoric, citric, oxalic and oxy-ethylidene diphosphonic acids, as well as Trilon B. To quantify the effect of complexing agents on the processes of indication of iron ions with Fe 3+ sulfosalicylic acid, the absorption spectra of the obtained samples were measured, and the results are shown in Figure 9. Analysis of the obtained data revealed that sulfosalicylic acid exhibits pronounced indicator properties with respect to trivalent iron ions and can be used as an indicator in the developed low-toxicity, highly effective tool for removing metal inclusions on the surface of car paint coatings.
Next, an experiment was conducted to determine the optimal complexing agent for a low-toxicity, highly effective tool for removing metal inclusions on the surface of car paint coatings. The choice of the optimal complexing agent determines the compound that has the least effect on the interaction of the indicator-sulfosalicylic acid with iron ions (Fe 3+ )-with the formation of iron sulfosalicylates, which display intense staining in aqueous solutions due to a high-intensity absorption band at 500 nm.
To this end, a series of samples of a mixture of sulfosalicylic acid and Fe 3+ ions containing the following complexing agents was prepared: orthophosphoric, citric, oxalic and oxy-ethylidene diphosphonic acids, as well as Trilon B. To quantify the effect of complexing agents on the processes of indication of iron ions with Fe 3+ sulfosalicylic acid, the absorption spectra of the obtained samples were measured, and the results are shown in Figure 9.
Analysis of the obtained data revealed that the most intense absorption band at 500 nm is observed in a sample containing citric acid. This fact determines the choice of citric acid as a complexing agent in the composition of the developed low-toxicity, highly effective tool for removing metal inclusions on a car's paintwork.
Furthermore, the composition of the developed low-toxicity, highly effective tool for removing metal inclusions on a car's paintwork was optimized. To study the effect of the concentration of components on the active acidity of the developed product, the response surface data shown in Figure 10 were analyzed. Analysis of the obtained data revealed that the most intense absorption band at 500 nm is observed in a sample containing citric acid. This fact determines the choice of citric acid as a complexing agent in the composition of the developed low-toxicity, highly effective tool for removing metal inclusions on a car's paintwork.
Furthermore, the composition of the developed low-toxicity, highly effective tool for removing metal inclusions on a car's paintwork was optimized. To study the effect of the concentration of components on the active acidity of the developed product, the response surface data shown in Figure 10 were analyzed. It was found that the active acidity of the agent for detecting and removing metal inclusions significantly depends on the concentration of sulfosalicylic and citric acids. Moreover, we found that the higher the acid concentration, the lower the pH. This is because due to the process of dissociation of acid molecules in the aqueous medium, protons are released, the appearance of which causes a drop in the acidity of the medium. With a decrease in the concentration of acids, an increase in active acidity is observed, with a maximum achievable pH value = 5.8 ± 0.2. It is important to note that due to the buffering of the product, the active pH acidity does fall below 4.4.
Considering the effect of the concentration of components on the surface tension of the developed product, the response surface data are shown in Figure 11. Analysis of the obtained data revealed that the most intense absorption band at 500 nm is observed in a sample containing citric acid. This fact determines the choice of citric acid as a complexing agent in the composition of the developed low-toxicity, highly effective tool for removing metal inclusions on a car's paintwork.
Furthermore, the composition of the developed low-toxicity, highly effective tool for removing metal inclusions on a car's paintwork was optimized. To study the effect of the concentration of components on the active acidity of the developed product, the response surface data shown in Figure 10 were analyzed. It was found that the active acidity of the agent for detecting and removing metal inclusions significantly depends on the concentration of sulfosalicylic and citric acids. Moreover, we found that the higher the acid concentration, the lower the pH. This is because due to the process of dissociation of acid molecules in the aqueous medium, protons are released, the appearance of which causes a drop in the acidity of the medium. With a decrease in the concentration of acids, an increase in active acidity is observed, with a maximum achievable pH value = 5.8 ± 0.2. It is important to note that due to the buffering of the product, the active pH acidity does fall below 4.4.
Considering the effect of the concentration of components on the surface tension of the developed product, the response surface data are shown in Figure 11. Analysis of the obtained data revealed that the surface tension of the tool for detecting and removing metal inclusions depends only on the concentration of sodium laureth sulfate. This is because sodium laureth sulfate, unlike other components of the product, has the greatest surface activity because it is an anion-active surfactant. The surface tension of the developed product does not correlate with the concentrations of other components, with values in the range of 80 to 250 mN·m −1 . The effect of the concentration of components on the dynamic viscosity of the developed product is presented in Figure 12. It was found that the active acidity of the agent for detecting and removing metal inclusions significantly depends on the concentration of sulfosalicylic and citric acids. Moreover, we found that the higher the acid concentration, the lower the pH. This is because due to the process of dissociation of acid molecules in the aqueous medium, protons are released, the appearance of which causes a drop in the acidity of the medium. With a decrease in the concentration of acids, an increase in active acidity is observed, with a maximum achievable pH value = 5.8 ± 0.2. It is important to note that due to the buffering of the product, the active pH acidity does fall below 4.4.
Considering the effect of the concentration of components on the surface tension of the developed product, the response surface data are shown in Figure 11. Analysis of the obtained data revealed that the surface tension of the tool for detecting and removing metal inclusions depends only on the concentration of sodium laureth sulfate. This is because sodium laureth sulfate, unlike other components of the product, has the greatest surface activity because it is an anion-active surfactant. The surface tension of the developed product does not correlate with the concentrations of other components, with values in the range of 80 to 250 mN•m −1 . The effect of the concentration of components on the dynamic viscosity of the developed product is presented in Figure 12. Data analysis revealed that the dynamic viscosity of the agent for detecting and removing metal inclusions significantly depends on the concentration of sodium laureth sulfate. The dependence is a quadratic function with an extremum at a concentration of sodium lauryl sulfate in the order of 10 ppm. It is also important to note that at a concentration of sodium laureth sulfate of more than 25 ppm, citric and sulfosalicylic acids change the viscosity, which is probably due to the influence of these components on the structure of sodium laureth sulfate gels, leading to changes in the structural, mechanical and surface-active properties of this surfactant. Analysis of the obtained data revealed that the surface tension of the tool for detecting and removing metal inclusions depends only on the concentration of sodium laureth sulfate. This is because sodium laureth sulfate, unlike other components of the product, has the greatest surface activity because it is an anion-active surfactant. The surface tension of the developed product does not correlate with the concentrations of other components, with values in the range of 80 to 250 mN•m −1 . The effect of the concentration of components on the dynamic viscosity of the developed product is presented in Figure 12. Data analysis revealed that the dynamic viscosity of the agent for detecting and removing metal inclusions significantly depends on the concentration of sodium laureth sulfate. The dependence is a quadratic function with an extremum at a concentration of sodium lauryl sulfate in the order of 10 ppm. It is also important to note that at a concentration of sodium laureth sulfate of more than 25 ppm, citric and sulfosalicylic acids change the viscosity, which is probably due to the influence of these components on the structure of sodium laureth sulfate gels, leading to changes in the structural, mechanical and surface-active properties of this surfactant.
To study the effect of the concentration of components on the redox potential of the developed product, the response surface data shown in Figure 13 were analyzed. For all samples considered and on all the obtained response surfaces, an oxidizing medium with E > 0 mV was observed, with values ranging from 540 to 580 mV. To study the effect of the concentration of components on the redox potential of the developed product, the response surface data shown in Figure 13 were analyzed. For all samples considered and on all the obtained response surfaces, an oxidizing medium with E > 0 mV was observed, with values ranging from 540 to 580 mV.
An experiment was conducted to study the effect of the concentration of sulfosalicylic acid and iron ions on the optical properties of the iron complex. To this end, an experiment was conducted in which a series of solutions of sulfosalicylic acid and iron chloride was prepared with concentrations ranging from 0.0001 to 0.1 M. Then, the obtained solutions were alternately mixed, and the absorption spectra in the ultraviolet and visible regions were measured. The optical density of the absorption band at 500 nm was determined from these spectra. The surface presented in Figure 14 was constructed by mathematically processing the experimental data. Data analysis revealed that the dynamic viscosity of the agent for detecting and removing metal inclusions significantly depends on the concentration of sodium laureth sulfate. The dependence is a quadratic function with an extremum at a concentration of sodium lauryl sulfate in the order of 10 ppm. It is also important to note that at a concentration of sodium laureth sulfate of more than 25 ppm, citric and sulfosalicylic acids change the viscosity, which is probably due to the influence of these components on the structure of sodium laureth sulfate gels, leading to changes in the structural, mechanical and surface-active properties of this surfactant.
To study the effect of the concentration of components on the redox potential of the developed product, the response surface data shown in Figure 13 were analyzed. For all samples considered and on all the obtained response surfaces, an oxidizing medium with E > 0 mV was observed, with values ranging from 540 to 580 mV. An experiment was conducted to study the effect of the concentration of sulfosalicylic acid and iron ions on the optical properties of the iron complex. To this end, an experiment was conducted in which a series of solutions of sulfosalicylic acid and iron chloride was prepared with concentrations ranging from 0.0001 to 0.1 M. Then, the obtained solutions were alternately mixed, and the absorption spectra in the ultraviolet and visible regions were measured. The optical density of the absorption band at 500 nm was determined from these spectra. The surface presented in Figure 14 was constructed by mathematically processing the experimental data. Analysis of the data showed that the dependence of the optical density of solutions, D, on the concentration of iron chloride is complex and represents a parabola with an  An experiment was conducted to study the effect of the concentration of sulfosalicylic acid and iron ions on the optical properties of the iron complex. To this end, an experiment was conducted in which a series of solutions of sulfosalicylic acid and iron chloride was prepared with concentrations ranging from 0.0001 to 0.1 M. Then, the obtained solutions were alternately mixed, and the absorption spectra in the ultraviolet and visible regions were measured. The optical density of the absorption band at 500 nm was determined from these spectra. The surface presented in Figure 14 was constructed by mathematically processing the experimental data. Analysis of the data showed that the dependence of the optical density of solutions, D, on the concentration of iron chloride is complex and represents a parabola with an Analysis of the data showed that the dependence of the optical density of solutions, D, on the concentration of iron chloride is complex and represents a parabola with an extremum at C (FeCl 3 ) = 0.05 M and, from the concentration of sulfosalicylic acid, a curve with a maximum value of C (sulfosalicylic acid) = 0.1 M.
Before the production and testing of prototypes of a low-toxicity, highly effective agent for removing metal inclusions on the surface of car paint coatings, the microstructure of the surface of a car's paintwork was studied in order to detect and identify contaminants. To this end, microscopy was performed on contaminated samples of a car's paintwork with a surface area of 1 cm 2 using an IM 7200 MEIJI TECHNO optical microscope. The resulting micrograph is shown in Figure 15.
with a maximum value of C (sulfosalicylic acid) = 0.1 M.
Before the production and testing of prototypes of a low-toxicity, highly effective agent for removing metal inclusions on the surface of car paint coatings, the microstructure of the surface of a car's paintwork was studied in order to detect and identify contaminants. To this end, microscopy was performed on contaminated samples of a car's paintwork with a surface area of 1 cm 2 using an IM 7200 MEIJI TECHNO optical microscope. The resulting micrograph is shown in Figure 15. Analysis of the obtained data showed the presence of polydisperse particles of various sizes and irregular shapes on the surface of the car's paintwork. In order to determine the distribution of pollution particles, mathematical processing of the obtained data was carried out. The results are shown in Figure 16.  Analysis of the obtained data showed the presence of polydisperse particles of various sizes and irregular shapes on the surface of the car's paintwork. In order to determine the distribution of pollution particles, mathematical processing of the obtained data was carried out. The results are shown in Figure 16.
extremum at C (FeCl3) = 0.05 M and, from the concentration of sulfosalicylic acid, a curve with a maximum value of C (sulfosalicylic acid) = 0.1 M.
Before the production and testing of prototypes of a low-toxicity, highly effective agent for removing metal inclusions on the surface of car paint coatings, the microstructure of the surface of a car's paintwork was studied in order to detect and identify contaminants. To this end, microscopy was performed on contaminated samples of a car's paintwork with a surface area of 1 cm 2 using an IM 7200 MEIJI TECHNO optical microscope. The resulting micrograph is shown in Figure 15. Analysis of the obtained data showed the presence of polydisperse particles of various sizes and irregular shapes on the surface of the car's paintwork. In order to determine the distribution of pollution particles, mathematical processing of the obtained data was carried out. The results are shown in Figure 16.  As a result of mathematical processing and analysis of the data shown in Figure 16, inclusions with a monomodal size distribution, an average surface area of about 25 µm 2 and an average particle diameter of about 5 µm were found.
In order to identify particles of contamination and inclusions on the surface of the car's paintwork, an energy-dispersion microanalysis was performed using a scanning electron microscope. The obtained EDS spectrum and its interpretation are shown in Figure 17 and Table 10, respectively.
As a result of mathematical processing and analysis of the data shown in Figure 16, inclusions with a monomodal size distribution, an average surface area of about 25 μm 2 and an average particle diameter of about 5 μm were found.
In order to identify particles of contamination and inclusions on the surface of the car's paintwork, an energy-dispersion microanalysis was performed using a scanning electron microscope. The obtained EDS spectrum and its interpretation are shown in Figure 17 and Table 10, respectively.  In the process of energy-dispersion microanalysis, SEM micrographs, as well as multilayer and element-by-element maps, of the contaminated surface of the paint coating were obtained, which are shown in Figures 18 and 19.  In the process of energy-dispersion microanalysis, SEM micrographs, as well as multilayer and element-by-element maps, of the contaminated surface of the paint coating were obtained, which are shown in Figures 18 and 19.   We established that the particle inclusions on the surface of the car's paintwork were not only metallic materials but also mineral-containing sedimentary rocks in the form of particles of earth, sand, clay and other materials, including elements such as iron, potassium, magnesium, aluminum, sodium, silicon, chlorine and calcium, among others [37][38][39][40][41].
In order to confirm this fact, an energy-dispersion microanalysis of road dust was carried out using a scanning electron microscope. The obtained SEM micrographs, multilayer and element-by-element maps of road dust particles, and the EDS spectrum and We established that the particle inclusions on the surface of the car's paintwork were not only metallic materials but also mineral-containing sedimentary rocks in the form of particles of earth, sand, clay and other materials, including elements such as iron, potassium, magnesium, aluminum, sodium, silicon, chlorine and calcium, among others [37][38][39][40][41].
In order to confirm this fact, an energy-dispersion microanalysis of road dust was carried out using a scanning electron microscope. The obtained SEM micrographs, multilayer and element-by-element maps of road dust particles, and the EDS spectrum and its interpretation are presented in Figures 20-22 and Table 11.  Energy-dispersion microanalysis established the similarity of the compositions of contaminants on the surface of the car's paintwork and road dust particles. Therefore, it can be concluded that most of the inclusions on the surface of the car are represented by metal particles and particles of road dust containing various mineral compounds.
At this research stage, the manufactured prototypes of a low-toxicity, highly effective tool for removing metal inclusions were tested on the surface of a car. The car's paintwork was treated with the resulting agent; application was carried out with a spray gun. The results of the experiment are shown in Figure 23.    Analysis of the obtained photos showed that the prototypes of the developed lowtoxicity, highly effective agent actively react with metal inclusions after 30 s, with the appearance of bright bard staining caused by the formation of iron disulfosalicylate.
Optical microscopy and energy-dispersion microanalysis confirmed the complete removal of metal inclusions by experimental samples of the developed low-toxicity, highly effective agent. The obtained results are presented in Figures 24 and 25 and in Table 12.  Energy-dispersion microanalysis established the similarity of the compositions of contaminants on the surface of the car's paintwork and road dust particles. Therefore, it can be concluded that most of the inclusions on the surface of the car are represented by metal particles and particles of road dust containing various mineral compounds.
At this research stage, the manufactured prototypes of a low-toxicity, highly effective tool for removing metal inclusions were tested on the surface of a car. The car's paintwork was treated with the resulting agent; application was carried out with a spray gun. The results of the experiment are shown in Figure 23. Analysis of the obtained photos showed that the prototypes of the developed low-toxicity, highly effective agent actively react with metal inclusions after 30 s, with the appearance of bright bard staining caused by the formation of iron disulfosalicylate.
Optical microscopy and energy-dispersion microanalysis confirmed the complete removal of metal inclusions by experimental samples of the developed low-toxicity, highly effective agent. The obtained results are presented in Figures 24 and 25 and in Table 12. Analysis of the obtained photos showed that the prototypes of the developed low-toxicity, highly effective agent actively react with metal inclusions after 30 s, with the appearance of bright bard staining caused by the formation of iron disulfosalicylate.
Optical microscopy and energy-dispersion microanalysis confirmed the complete removal of metal inclusions by experimental samples of the developed low-toxicity, highly effective agent. The obtained results are presented in Figures 24 and 25 and in Table 12. We found that with the use of the developed tool, metal inclusions containing iron and its derivatives on the surface of car paint coatings, as well as mineral contaminants containing sodium, potassium, chlorine and other elements, are completely removed.
Further tests of the developed product were carried out at the "Pride-Auto" Inc. specialized detailing center (Stavropol, Russia). The paintwork of a BMW X7 series car was used for experiments (Supplementary Materials). The process of applying prototypes of the developed tool for removing metal inclusions was carried out in the following order: 1.
Two-phase car surface washing;
Washing the surface of the car.
Based on the test results of the developed product, a contract was concluded with a Russian network of auto-detailing centers, "Pride-Auto" Inc., to supply tools for removing metal inclusions from the surface of paint and varnish car coatings.   We found that with the use of the developed tool, metal inclusions containing iron and its derivatives on the surface of car paint coatings, as well as mineral contaminants containing sodium, potassium, chlorine and other elements, are completely removed.
Further tests of the developed product were carried out at the "Pride-Auto" Inc. specialized detailing center (Stavropol, Russia). The paintwork of a BMW X7 series car was used for experiments (Supplementary Materials). The process of applying prototypes of the developed tool for removing metal inclusions was carried out in the following order: 1. Two-phase car surface washing; 2. Removal of metal particles (using the developed means); 3. Washing the surface of the car.
Based on the test results of the developed product, a contract was concluded with a Russian network of auto-detailing centers, "Pride-Auto" Inc., to supply tools for removing metal inclusions from the surface of paint and varnish car coatings.

Conclusions
A method for obtaining a tool for removing metal inclusions on the surface of car paint coatings was developed and optimized. The developed tool consists of sodium laureth sulfate as a surfactant, citric acid as a complexing agent, sulfosalicylic acid as an

Conclusions
A method for obtaining a tool for removing metal inclusions on the surface of car paint coatings was developed and optimized. The developed tool consists of sodium laureth sulfate as a surfactant, citric acid as a complexing agent, sulfosalicylic acid as an indicator and water as a solvent. Hydrogen peroxide was also used to intensify the process of converting water-insoluble forms of iron into soluble forms. We found that sulfosalicylic acid exhibits pronounced indicator properties with respect to trivalent iron ions. An intense band at 500 nm is observed in the absorption spectra. The optimal types of interaction of iron ions with sulfosalicylic acid molecules were determined using computer quantum chemical model. The maximum value of the active acidity of the medium of the tool for removing metal inclusions from the surface of a car's paintwork at which the presence of iron ions with the formation of bard complexes will be indicated is pH = 6. The optimal composition of a low-toxicity, highly effective tool for removing metal inclusions on the surface of car paint coatings, providing the most complete removal of impurities and metal inclusions was established as ω (sulfosalicylic acid) = 2%-4%, ω (sodium laureth sulfate) = 5%-15%, ω (H 2 O 2 ) = 1%-5% and ω (citric acid) = 2%-4%.
The influence of the component composition of the agent for the detection and removal of metal inclusions on its physicochemical and surface-active properties was investigated. We established that the developed product's dynamic viscosity and surface tension correlate only with the concentration of sodium laureth sulfate, with optimal concentrations of 20-50 MPa·s and 80-250 mN·m −1 , respectively. We found that with a decrease in acid concentrations, an increase in the active acidity of the product is observed. Moreover, we found that the maximum achievable pH value is 5.8 ± 0.2. It is important to note that due to the agent's buffering, the active acidity does not drop below pH 4.4. We also found that an oxidizing medium with E > 0 is observed in all the samples considered and on all the response surfaces obtained, with values in the range of 540 to 580 mV. We established that the dependence of the optical density of solutions on the concentration of iron chloride is complex and represents a parabola with an extremum at C (FeCl 3 ) = 0.05 M and, on the concentration of sulfosalicylic acid, a curve with a maximum value of C (sulfosalicylic acid) = 0.1 M.
Experimental samples of a tool for removing metal inclusions were manufactured and tested. We found that 30-45 s after applying the developed product, not only were metal inclusions on the surface of car paint coatings removed but also mineral contaminants in the form of sand, earth, clay and other particles containing elements such as potassium, magnesium, aluminum, sodium, silicon, chlorine an calcium.
Product testing led to a contract with a Russian network of auto-detailing centers, "Pride-Auto" Inc. to supply tools for removing metal inclusions from the surface of paint and varnish car coatings. Currently, the developed product is used in 17 auto-detailing centers.