Properties of Zinc Phosphate Coatings on Carbon Steel Using a Thermostatic Cell and a Mobile System

Phosphate coatings can prevent or minimize the environmental corrosion of metals and they are often used as the base for subsequent coatings or painting processes. In this work a mobile device was used to perform carbon steel phosphating, which will work against corrosion. The methodology used involved mechanical cleaning of the substrate as well as a chemical cleaning to eliminate possible contaminants on the metal surface. Following that, the superficial phosphating was performed to find the ideal conditions that gave the best results. Finally, the results from SEM and XRD analysis showed the morphology and surface composition of the coatings obtained from both studied methods. The results from the applied dipped cell method compared with the mobile system indicated the reliability of the methods.


Introduction
The effect of corrosion is of concern in the health sector. It can cause disease-corrosion in metals used for implants. The risk of metals being transferred to the environment can cause infections in respiratory diseases. The damage caused at a global level by rust can result in high costs and human loss. It is estimated that 5 tons of steel are dissolved in each second. This phenomenon is invisible in each piece of metal, since it involves a few nano meters or picometers, but when this is multiplied by the quantity of steel used in the world in different areas, the total corrosion is a high value [1]. One of the objectives of this work is to reduce this loss using surface coatings based on the zinc phosphate technique with a mobile device. This work has been carried out using zinc phosphate dipped coatings at room temperature on mild steel at 25 °C for 30minutes in the phosphate solution [2], as well as magnesium phosphate on low carbon steel using the electrochemical cathodic immersion method [3]. Phosphate processing with benzotriazole produce a different morphology to other magnesium deposits on carbon steel [4].
Although the surface characterization of zinc coatings on low carbon steel showed that coatings were not hard, but on the other hand they reduced the corrosion and provide a good adhesion for subsequent coatings [5]. There are other types of coatings produced by dipping which have different surface morphologies, such as iron-phosphate coatings on low carbon steel [6]. They are also used to prevent or minimize corrosion and give good adhesion for paints and back coverings.

Methodology
The chemical composition of the phosphate solution is given in Table 1. The composition of carbon steel samples used for containing is as follows: 0.10% C, 0.60% Mn, 0.030% P, 0.035% S and the remaining is Fe. The samples were obtained from industrial residues from 3 steel scrapheaps. From each one, 10 samples of were chosen and prepared for coatings. The samples were machined to give the geometric forms required for analysis. The surface of the samples was cleaned mechanically. The paint residue was removed by acetone and degreased by ethanol. The composition of zinc phosphate solution was zinc shown in Table 1. The proposed mechanism of the reaction phosphoric acid with the surface of iron was as follows: A soluble ferrous dihydrogen phosphate was produced, and hydrogen gas was released. Local phosphoric acid depletion occurred at the metal/solution interface. When the primary iron, zinc or manganese phosphates are dissociated in the aqueous solution, the following reactions occur [7]: The overall reaction is Neutralization of the phosphoric acid in equation (1) alters the direction of equilibrium in all other equations (2), (3) and (4), so that they have the tendency to produce phosphates which are shown to the right of the chemical reactions and cause the deposition of hydrogen phosphates and insoluble phosphates on the metal surface. As reaction (1) takes place, the phosphating solution that contains zinc or manganese phosphate with little or no dissolved iron, it is clearly observed that the untreated samples produce coatings which always contain ferrous dihydrogen phosphate derived from the steel samples. After prolonged use, a manganese phosphate bath frequently contains more iron in solution than manganese and produces coatings of three or more times iron than manganese. The compounds produced from the reaction of iron (Fe) in the carbon steel samples with the phosphating solution have the following chemical formulas.

Coating process using a thermostatic cell
The phosphating process produces a relatively inert film (Passivation) on the surface of a material (often a metal) which prevents the interaction of the external agent and the metal. The chemical reaction is reduced or completely impeded by increasing the adhesion of the paint on the metal surface. This will prevent the corrosion and improve lubrication for forming or drawing processes. It can be also the base for subsequent coatings or paints. The primary coating on the carbon steel surface (1) was deposited by thermostatic immersion cell (2) using a phosphating solution (3). This process gives a primary coating with better paint adhesion. The phosphating solution passes through a latex tube (4) which is connected to the water bath (5) fixed at different temperatures: 20, 30, 40, 50, 60, 70 and 80 °C by using a regulator (6) that maintain the temperature at the required value as shown in Figure 1.  The structure and components of the process for applying nickel metal coatings by the Watts bath method (Mobile method) was shown in Figure 2. The heating operation was performed approximately one meter above the mobile device [9]. The fluid with the desired temperature was carried out and circulated the electrolyte for deposition on the substratum. When this temperature had been reached, the solution flowed by gravity through an insulated hose towards the body of the mobile device. Then, this solution dispersed on the metal surface by direct contact of the electrolyte solution with the surface of the metal sample. The remaining solution was collected and transferred to a vessel which was immersed in the water bath. The coating solution was returned back to the water bath through an insulated duct using a diaphragm pump, as shown in Figure 2. Figure 3 shows the hemispherical main body forming an inner chamber, which was made of nylon. The device had hex nuts which attached to a flexible insulated duct to carry the phosphate solution. At the top of the main body of the device, there was a connector which carried the coating solution from the outlet of the duct to the body of the device. This connector had a perforated lower spherical outlet that dispersed the solution on the surface. Inside the chamber above a perforated circular plate, there were spheres of ceramic material which assist the distribution of the solution within the body of the device to be spread evenly along the entire circular perforated plate. Around this plate, there was a circular nut that has the ability to access to the interior chamber device when cleaning was required [10,11].

Results and Discussion
Results of the phosphating process using the thermostatic cell  Figure 4 shows the weight increase of the samples coated at different temperatures using the thermostatic cell. At all temperatures: 13, 20, 30 ... 80 °C, it was observed that the surface coatings increased the mass of the samples. At 90 °C, the solution started to boil, which means it was no longer possible to coat all the surfaces. The formed bubbles prevented the coating process, so that the metal began to corrode. The optimum temperature for coating the entire surface of the samples was 80 °C. It can be clearly noticed that the content of the phosphate coating increased with the increase in the temperature. This means that the surface of the sample was more and more covered with the phosphate coating until it was became completely covered. The thickness of the obtained layer using the thermostatic cell method was equal to 77μm, ( Figure 5).  X-ray microscopy   Figure 8 shows the weight of the coated studied samples at different temperatures using the mobile phosphating system. It was found the mass of the surface coatings increased with temperature till it reaches 50 °C, then the metal began to corrode. It was found that the optimum coating temperature for the entire surface of the substrate was 40 °C, unlike the dipped process, which had a higher optimum coating temperature (80 °C). Coating at different temperatures was done using this process. The SEM technique shows that 40 °C was the ideal temperature to coat all the sample surface (Table 3).  X-ray microscopy Figure 9: XRD for phosphating coatings of the samples at 40 °C using the mobile device method.

Results of the mobile device
X-ray analysis were performed on the coatings obtained from phosphating the samples at different temperatures of the carbon steel using the mobile device method (Figure 9).

Conclusion
The methodology used for metal surface coatings, using the mobile device method, can be used to do the field work without the need to remove the deteriorated carbon steel components. In this way, the maintenance costs associated with disassemble and transportation of the components, could be reduced. The characteristics of the primary coatings by the immersion methods gave a layer of thickness of 15.1μm at a temperature of 80 °C. The characteristics of the primary coatings by the spray method using the mobile device gave a reaction mechanism similar to immersion, but with thicknesses of 3.6μm at 40 °C. At higher temperatures, the metal substrate underwent accelerated corrosion. Therefore, it is recommended to use a temperature of 40 °C to obtain an evenly homogeneous with very well adhered coatings on the metal surface.