Study of Deformation Coating for Sheets by Using Tensile Test

Abstract

This article focuses on the study of the defined values of tensile strain and the effect of low temperature plasma adhesion selected coatings on steel samples using a tensile testing flat test bars. Samples were made by machining and welding technologies. The flat test bars were tested by pulling on a test rig UPC 1200. Part of the samples was treated on the surface prior to coating by a tensile test, second base coat and with a final coat continuous multi plasma system. The selected test samples were determined from the tensile test of the material characteristics apparent from the tensile diagrams. The examined samples were fitted top and base coat. Another group was the KTL basis. The presented graphs show the dependence of the strength on elongation of a sample according to DIN EN ISO 6892-2. The samples were then examined under a stereo microscope SCHUT brand, type SSM-E in the laboratory to conduct coating on a steel sheet at the moment of total violation sectional samples. The base layer, in which the temperature ranges from 160°C - 180°C, was applied by electrophoresis method.

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Dvořák, M. , Schwarzer, E. and Klíma, M. (2015) Study of Deformation Coating for Sheets by Using Tensile Test. Journal of Surface Engineered Materials and Advanced Technology, 5, 73-83. doi: 10.4236/jsemat.2015.52008.

1. Introduction

Distortion between the base steel material and its coating, causing defects occurring during sheet forming, such as sheet surface waviness, warpage, breaking, metal release, inadequate structure of the surface or poor choice of combinations of basic materials and coatings [1] [2] . Current requirements for surface treatment technology is to preserve the integrity of the surface layer and bonds between the surface and the base material after the drawing respectively bending [3] .

Protective coatings play an irreplaceable role at a very wide field of construction materials used [4] -[6] . In the area of testing and assessment of adhesion of protective coatings for sheets is characterized by great variety of methods and procedures [7] -[10] .

Were investigated values of the material characteristics such as: such as e.g. the yield strength Rp0,2, tensile strength Rm is, an elongation A50, Ag apparent from the tensile diagrams. The thickness of the base coat at the sample ranges from 15 - 30 microns. Sheets supplied with a certificate validated and chemical composition have been previously degreased and then scrubbed with a special deburring machine. Designation of material is 1.0322 (DX56D). This is unalloyed quality deep-drawing steel thickness of 1 mm. In Table 1 results of adhesion, samples were sorted from best to worst.

2. Experiments

The aim of the experiment was submission of selected specimens with the proposed dimensions (Figure 1) tensile test. Tensile test of samples was performed on a UPC 1200.

Samples were technologically prepared with using by welding technology with support CO2 and dimensionally adapted for tensile test. Selected samples before tensile test were photographically documented, see Figure 2.

Figure 1. Detailed view on the clamped sample in clamping jaws device.

Table 1. Selected samples with plasma treatment and applying different plasma.

Before own experiments were divided to four groups with different modes of composition of the plasma.

3. Results

3.1. Measured Values for Selected Samples from the Tensile Tests

From tensile tests were processed results of experimental work by a tensile test in the form of tabular and graphical outputs, see Table 2.

The test specimens, see Figure 2 and the width [mm] and thickness b [mm] was subjected to a tensile test. The results are shown in Table 2.

The most variable results for Young’s modulus E [MPa]. Why is this large margin given, has not been found and neither was the subject of this experiment.

Values contractual yield strength Rp [MPa] and the tensile strength Rm [MPa] correspond to the material 1.0322 (DX56D). Like the A50 elongation and contraction Z [%]. The plastic elongation Ag ranged from 9.98 to 21.85 [%].

It was interesting to observe the time to break the sample t [s], which is also significantly different from the method of application of various plasma [11].

Also, the force F [kN] for all samples was very similar with the exception for sample BP16, which was significantly lower and the voltage for rise of the separated parts of the sample Rm1 [MPa] was at sample BP16

Figure 2. Overview of samples which were subjected to tensile test.

Table 2. Measured values for selected samples after tensile test.

different and significantly lower.

Track s [mm] and extension dL [mm] were evaluated by a computer program on the device UPC 1200.

3.2. Graphic Results from the Tensile Test

Results of tensile test are elaborated in Table 2 and results of tension are shown in Figures 3-8.

All these samples were fixed, as shown in Figure 9, where the fixed sample BP7.

3.3. Selected Samples after Tensile Test under the Microscope

Samples BP11, BP16, BP7, TC6, TC9, and Z12 were examined under a stereo-microscope under magnification

Figure 3. Progress of force versus elongation and values of the tensile test, the sample BP11.

Figure 4. Progress of force versus elongation and values of the tensile test, the sample BP16.

Figure 5. Progress of force versus elongation and values of the tensile test, the sample BP7.

Figure 6. Progress of force versus elongation and values of the tensile test, the sample TC6.

10×. These scales in Figures 10-15 are in mm.

The samples were examined under a stereo microscope SCHUT brand, type SSM-E in the laboratory of the Department of Engineering Technology BUT in Brno to conduct coating on a steel sheet at the moment of total violation sectional samples.

3.4. The Principle of High-Frequency Hollow Cathode

The basis of nozzles was used dielectric capillary of quartz glass, which flows argon, including any impurities. The plasma ejected from the cavity and from the plasma nozzle orifice into the external environment, where it acts on the test specimens coated steel sheet. Discharge is over the whole length of its actively generated plasma channel.

Figure 7. Progress of force versus elongation and values of the tensile test, the sample TC9.

Figure 8. Progress of force versus elongation and values of the tensile test, the sample Z12.

Power absorbed at plasma channel multi-jet device was used according to the selected working conditions in the range of 102 - 103 W∙cm−2. Unlike electron beam welding where the power density at the spot welding up to 109 W∙cm−2 [12] .

The thermal effects on the surface of samples can be range from 30˚C to 1600˚C while maintaining substantially no-isometric character of discharge (energetic particles at a temperature up to 10,000 K). Based on these characteristics of the plasma nozzle system provides a high reaction mixture with a high efficiency for the chemical and physical modification of the material surface [13] .

Suitable array of nozzles to linear or other units allows cutting of larger areas of test samples respectively semi-finished steel in industrial practice.

3.5. Composition of the Material Used in KTL

KTL material contains positively charged paint particles (the largest particles leftmost in Figure 1) which have

Figure 9. Demonstration fixing of sample BP7 for experiment.

Figure 10. Sample BP11.

incorporated therein a pigment and a binder (synthetic resin). Another component (see the right side of Figure 16) is negatively charged residues org. COO acids (e.g. acetic acid anions). It is essentially the electro-neutral colloidal solution, wherein the colloidal particles on the resin (CH3) a large positive charge wrapping anions are simple organic acids. The resin is a high molecular weight tertiary amine which in an acidic aqueous environment creates the following structure.

Addition of the organic acid thus formed colloidal solution whose resin part is charged positively and the acidic portion is negatively charged [4] . Thus formed bath after connecting a DC current to the cathode (part of the body to which you want to apply KTL coating) and firmly installed anode enables electro-chemical pro- cesses leading to the exclusion of KTL layer.

3.6. Treatment of the Surface by Plasma Jets

At the base steel sheet and the coat should be seen as a system. When technological forming operations occur,

Figure 11. Sample BP16.

Figure 12. Sample BP7.

however, in distortion of these pairs of common bonds [14] [15] . Disruption of these bonds may in some cases lead to disruption of the integrity of the coating and its subsequent flaking.

Distortion between the base steel material and its coating can cause defects occurring during sheet forming (metal surface waviness, warpage, breaking, metal release, inadequate structure of the surface) or a combination of a bad choice base material and coating.

Goal is thus to maintain the integrity of the coating, i.e. all bonds between the coating and the base material [5] [6] . This can be achieved by optimizing the forming operations, i.e. optimization of process parameters and fur- ther improving the coating technology [16] -[18] .

Plasma-chemical equipment with conveyor is on Figure 17.

4. Conclusion

This paper presents another basic criterion tensile test to detect adhesion of organic coatings in one or more layers

Figure 13. Sample TC6.

Figure 14. Sample TC9.

in the interaction with the metal base.

Experiments have shown the influence of the tensile stress on adhesion coatings. Functional cataphortic coloring bath consists of the following basic components: resin (binder), paste (pigment), which determines the color shade.

Common colors are gray, black eventually white or beige. Further additives (solvents, pH regulator). All these components are homogeneously mixed in demi-water.

By employing various types of gases in the multi-jet plasma system on selected samples of steel with organic coatings were found to what combination of gases is most suitable in terms of adhesion and of course where and in which the interface is coated using multi-jet plasma system optimum.

Experimental results show that using a multi-jet plasma system with optimal composition of low temperature plasma samples are more resistant from the viewpoint of adhesion of the selected organic coating selected flat steel samples structural steel, nominal thickness 1 mm.

Figure 15. Sample Z12.

Figure 16. Molecular structure of colloid solution.

Figure 17. Plasma-chemical equipment with conveyor, laboratory MU Brno.

Experiments with selected samples were evaluated with the result that the sample should the best BP11 resistant coating from the viewpoint of adhesion. This coating was treated with the following procedure application:

The sheet material 1.0322 (DX56D), which was properly degreased, subsequently the sheet surface was treated by multi-jet plasma system Ar + N2 mixtures, that have proven to improve adhesion of a tensile test and subsequently applied the base coat (KTL).

Note

The article is supported by project Technical University in Brno, Faculty of Mechanical Engineering: BUT FME-S-12-5 from 2012 and VAV 13313.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1] Hermann, F. and Schiller, M. (2007) Testing of Paints and Protective Coatings. Pardubice-Green Suburb: SYNPO PLC.
[2] Test of Resistance of Coatings (2004) Measuring Equipment, Thickness, Hardness, Gloss Meters, Thermometers. Pro- Inex Instruments, Ltd., Ostrava.
[3] Dvorák, M., et al. (2001) Technology II. Academic Publishing CERM, Ltd., Brno, 236-238.
[4] CSN EN ISO 1519 (2002) Paints Substance—Bend Test (Cylindrical Mandrel). Czech Standards Institute.
[5] CSN EN ISO 7438 (2005) Metallic Materials Bend Test. Czech Standards Institute, 11-12.
[6] CSN ISO 24213 (2009) Metallic Materials—Sheets and Belt: Evaluation Method of Suspension for Flexural Bending. Czech Standards Institute, 14-15.
[7] Blanks, T. (1985) Metals Handbook: Mechanical Testing. American Society for Metals, 837-842.
[8] Cada, R. (1998) Surface Formability of Metallic Materials. Technical University of Ostrava, Ostrava, 90-92.
[9] CSN EN ISO 20482 (2004) Metallic Materials-Sheet and Belts-Bulge Tests According to Erichsen. Czech Standards Institute, Prague.
[10] CSN EN 13144 (2003) Metallic and Other Inorganic Coatings: Method for Quantitative Measurement of Adhesion for Tensile Test. Czech Standards Institute, 12-13.
[11] Dvorák, M. and Schwarzer, E. (2013) Study of Formability of Coated Sheets from the Plasma Chemical Pretreatment of Surfaces. International Journal of Engineering and Innovative Technology (IJEIT), 3, 356-360.
[12] Patent EP 1077021, US 6,525,481 (2005) Method of Making a Physically and Chemically active Environment by Means of Plasma Jet and the Related Plasma JET. Masaryk University, Brno, 5-6.
[13] Krejcík, V. (1988) Surface Treatment of Metals II. Publishing House of Technical Literature, Prague.
[14] Kraus, V. (2000) Surface Modification. University of West Bohemia, Plzeň, 218-220.
[15] Kreibich, V. (1996) Theory and Technology of Surface Treatment. Publishing House of CVUT, Prague, 89-92.
[16] Forejt, M. and Píska, M. (2006) Theory of Machining, Molding and Tool. CERM, Academic Publishing, Ltd., Brno, 225-226.
[17] Husek, M. and Dvorák, M. (2010) Test of Adherence Multifunctional Coating on the Sheet Using a Graduated Bending Jig. Engineering Technology, 15, 15-20.
[18] Dvorák, M. and Schwarzer, E. (2012) New Methods Testing of Adhesion of the Coating to Sheet Metal by Bending. Journal of Surface Engineered Materials and Advanced Technology (JSEMAT), 2, 61-64.

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