BG61538B1 - Method for accelerated testing of protection layers on metallic surfaces - Google Patents

Abstract

The inention relates to a method for the determination of the corrosion effect on chromatic films on galvanic coatings of zinc, zinc alloys and cadmium. The alteration of the potential of the chromatized specimen is registered in anodic pollarization in galvanostatic mode and defined electrolytic medium. A measure for the corrosion control capability is the height of the maximum of the anodic potential - a higher maximum corresponds to a better control ability where there is excellent correlation of the results of the tests in saline mist. Testing can start immediately after drying of the chromatic film and the assessment about its corrosion control properties is obtained in less than one hour. Besides, the anodic pothential is measured on a small defined surface which enables the determination of the evenness of the chromatic film along the surface.

Description

The invention relates to a method for the determination of the corrosion protection of chromate films on galvanic coatings of zinc, zinc alloys and cadmium.

State of the art

The corrosion protection properties of the chromatographic films are in practice determined in chambers in which, at 35 ° C, they are treated with salt mist with certain properties. The results are highly reliable and the method is internationally recognized and standardized [1]. The duration of the test is determined by the type and quality of the film. For example, yellow chromate films on zinc coatings should withstand at least 4 days of salt mist testing without the appearance of zinc corrosion products. Additionally, it is required that the chromatographed specimens should be at least 24 hours prior to the test itself.

There is a known method for estimating and predicting the corrosion resistance of chromate films on Zn coatings by measuring the drilling voltage (and u) through these films [2]. It is based on the effect of Friting, according to which any dielectric located between two electrodes is pierced if the voltage applied to it reaches a value in the order of 10 ⁶ w / v. It was found that there is a good correlation between the corrosion resistance of chrominated Zn coatings in neutral salt mist [1] and u.

In the study of the corrosion protection properties of alloy zinc coatings, the method of isopotential contour mapping was also used [3]. By this method the potential difference between the points of the sample surface in a suitable medium (a solution of NaCl or NH4D1 _{) is} measured by two Aβ / Aβ comparators (21 microelectrodes, one of which scans the surface by a given program.) The measured signals, serve to map potential maps to the surface.

SUMMARY OF THE INVENTION

The essence of the invention consists in recording the variation of the potential of the chromatized sample with the time of anodic polarization in a galvanostatic mode and a defined electrolyte environment. A measure of the corrosion resistance is the height of the maximum anode potential of a better defensive cap corresponds to a higher maximum, with a very good correlation with the salt mist test results.

An advantage of the method is that the test can begin immediately after drying the chromatographic film and the evaluation of its corrosion protection properties is obtained for less than an hour. Additionally, the anode potential is measured on a small, defined area of the surface, which allows determination of the uniformity of the chromate film.

Description of the attached figures

Figure 1 is a schematic diagram of an apparatus for measuring anode potential;

Figure 2 - Typical variations in anode potential of chromatized samples over time with anodic polarization in galvanostatic mode and has the following indications: 1 - Zn, blue chromate film; 2 - Zn, yellow chromate film IV; 3 - Zn, yellow chromatographic film I; 4 Zn-R, yellow chromate film V; 5-Zn-R, black chromate film;

Figure 3 is a correlation between the maximum anode potential and corrosion resistance according to DIN 50 021-88 for chromate films on zinc, alloy zinc and cadmium coatings, and has the following meanings: a correlation curve, y = 17.63341n (x) - 59.4609 ; * - Zin, yellow film I; □ - Zin, yellow film And; Z-Yellow, yellow film III; D - Zn, yellow film VI; + - Zin, blue film; F-SD, yellow film VII; -F; - Zn-Co, yellow film VIII; O-Zn-R, black film. The anode potentials were measured in an electrolyte with a NaCl composition of 6 b / 1 + 1a ₂ SO ₄ 94 w / 1, pH 6 ± 0.3 at anode current density of 15 A /

II III I άπι ² and a temperature of 18-22 ° C by using a galvanostat with an output voltage of 150 V and the time of activation 10 μχ and fast acting writing instrument with input impedance 2 μΩ.

Figure 4 is a modification of the anode maximum depending on the maturation time of the chromatographic film and has the following indications: - · yellow film I; ♦ - yellow film II; - yellow film III.

An embodiment of the invention

With the device schematically represented in FIG. (13a) on galvanic coating of zinc, zinc alloy or cadmium (13b) over time under the influence of anodic straight current with constant force.

The device consists of fast high-voltage galvanostat 14, milimeter 15, electrolytic cell 9 with comparator electrode 5, and high speed input register 17. In addition to the circuit, a memorable oscilloscope 16 can be included.

A cage 9 is mounted on a selected location from sample 13c (sample or detail) with a zinc, alloy zinc or cadmium coating 13b and a formed film 13a. The latter may be made of an electrically conductive material (e.g. titanium BT 1-0) or non-conductive material (e.g., plexiglass). In the second case, the cell requires the introduction of a counter-electrode from a conductive material resistant to the measuring electrolyte (e.g., platinum).

The contact isolating washer 12 provides, through the electrolyte 10, a fluid contact between the sample 13 and the cell 9 on a defined area (e.g., 8 m ² ).

Measurements may be carried out using the following exemplary electrolytes: sodium chloride 100 g / l; sodium chloride 6β / 1 and sodium sulfate 94β / 1, and pH 6 ± 0.3.

The second solution is chemically less active and the maximum anode potential values are higher, allowing for a better differentiation of the chromate films with respect to their corrosive effect.

The potential of the chromatograph 13 is measured relative to the reference electrode (Aβ / AβΟ1) 5. In its upper part, the reference electrode 5 is connected by means of a brass 3 with a brass connection 1 inserted into the Teflon nut 2, which is mounted in the housing 4 made of conductive material, e.g. teflon. The lower working portion of the comparator electro10 enters the glass capillary 6 closed with graphite 11 and filled with 10% sodium chloride solution 8. By means of the guide sleeve 7, the entire structure is mounted on the cell 9, whereby the capillary 6 with compar15 the electrode 5 is immersed in the measuring electrolyte 10.

After establishing the stationary potential φ _ο, through the cell 9, the electrolyte 10, the specimen 13 and the milliammeter reading is passed pos20 stantly current from the galvanostat 14, so that the current density is between 5 and 75 A / dm ^2. Pattern 13 is linked as an anode. The cathode of the cell 9 is made of a conductive material (or other suitable counter-electrode in a current-conducting cell). The change in potential of the chromatograph is recorded using the typewriter 17. The potential goes up to a maximum of 50 to 200mm after the galvanic nostatic switching of the current (Figure 2). Therefore, for measurements, short-time and fast-acting type electromagnets should be used. For precision measurements in the circuit, the 35 oscillator 16 can be switched on. The output voltage of the electromagnet and the input resistance of the typewriter must be high enough to obtain reliable anode potential values. For chromate films with good protective properties, curve motion after the maximum is characterized by oscillations of potential from several hundred millivolts to several volts.

The validity of the method is shown by 45 study of the correlation correlation between the maximum anode potential _{αA Β1I} and the corrosivity of the chromatic films determined in salt mist according to DIN 50 021-88.

Between the maximum anode potential of chromate films obtained from different chromate solutions on zinc alloys3

Zinc and cadmium coatings, measured in a solution containing 6 g / l of sodium chloride + 94 g / l of sodium sulphate, and their corrosion protection in salt fog, a logarithmic dependence is established (Figure 3). The value of the 5 correlation coefficient d = 0,9070 shows a very strong correlation.

The dependence shown in Fig. 3 is removed after maturation of the chromatographic films for not less than 24 H. The study of samples chromated in different chromatographic solutions, however, indicates that the measurement according to the present invention can be started and immediately after drying the chromatographic film (Table 1, Figure 4).

Table 1. Dependence of the maximum anode potential of chromate film from maturation time

Maturation time [b] Yellow Films 1 Yellow Figures II Yellow Figures III Relative coefficient d 0 42.5 56.0 39.6 0.9722 24 41.8 53.9 39.8 0.9621 48 43.3 53.7 392 0.9949 96 42.8 51.0 39.4 0.9964 192 44.4 51.9 40.0 1.0000

Application of the invention

According to the proposed method, an apparatus is produced which allows for the express determination and evaluation of the corrosivity of chromate films formed on zinc, alloy zinc and cadmium coatings. Assessing the protective properties of chromate films by this method will greatly accelerate laboratory testing, and galvanizing plants will contribute to effective control of technologies and coatings.

Claims (2)

1. Method for accelerated testing of protective layers on metal surfaces and, in particular, for determining the corrosion resistance of chromate films on zinc, zinc alloys and cadmium coatings, characterized by the electrochemical measurement of the change in the potential of the electrode system metal coating - chromium40 tan Comparative electrode in electrolytic medium over a part of the surface of the working electrode, with anodic polarization with direct current depending on time and subsequent measurement of the height of max. Mumma this potential. A method according to claim 1, characterized in that the measurement and evaluation of the corrosion resistance can be carried out immediately after drying the freshly formed chromate films.