Engineering/Applied Chemistry CODE NO: 07A1BS07/07A1BS04 I B.TECH MECHNICAL/CIVIL ENGINEERING Unit No: IV Nos. of slides: 58
Engineering/Applied Chemistry PROTECTIVE COATINGS & THEIR APPLICATIONS Term: 2008-09 Unit-IV Power Point Presentations Text Books: A text book of Engineering Chemistry by Jain & Jain, Chemistry of Engineering Materials by C.P. Murthy, C.V. Agarwal and A. Naidu
INDEX UNIT-IV PPTS Srl. Module as per Lecture PPT No. Session Planner No. Slide No. ------------------------------------------------------------------------------------------------1. Surface Preparation L-1,2 L1,2-1 to L1,2-19 2. Metallic Coatings L-3,4 L3,4-1 to L3,4-28 3. Cathodic Coatings L-5,6 L5,6-1 to L5,6-18 4. Chemical Conversion Coatings L-7,8 L7,8-1 to L7,8-18
SURFACE PREPARATIONS
L1,2-1
SOLVENT CLEANING ALKALI CLEANING SAND-BLASTING
MECHANICAL CLEANING
PICKING AND ETCHING L1,2-
SOLVENT CLEANING: Solvent
cleaning is used to remove oils, greases, buffing compounds and fatty substances. This involves in cleaning the surfaces by the application of organic solvents like naphtha, chlorinated hydrocarbons (CCl4), toluene, xylene or acetone. This is followed by cleaning with steam and hot water, containing wetting agents and alkalis. This treatment provides a metal surface, readily wetted by aqueous L1,2-
ALKALI CLEANING:
Alkali
cleaning is particularly well-adapted for the removal of old paint coating from metal surfaces. Alkali cleaning agents are trisodium phosphate along with soaps and wetting agents like caustic soda. An alkali treatment is always to be followed by a very thorough rinsing with water and then immersion in a slightly acidic solution of 0.1% chromic acid or
L1,2-
ALKALI CLEANING:
Alkali
cleaning method can be made more effective by the application of an electric current, and making the “metal cathodic” in alkaline medium. The copious evolution of hydrogen at the cathode metal results in strong agitation, which helps to dislodge the oily substances. L1,2-
SAND-BLASTING: Sand
blasting is used or removing oxide scales, particularly when a slightly roughened surface is desired. Paint coatings on sand-blasted surface are, particularly, more durable than those on metal surfaces cleaned by other methods. Sand-blasting is especially suitable for large steel surfaces
L1,2-
SAND-BLASTING: However,
the proves required expensive equipment and the sandblasting operation is dangerous to health of workers, because of the possibility of disease, silicosis, unless special protective measures are taken. The process consists in introducing the sand an abrasive into an air stream, under pressure of 25 to 100 atmospheres. The blast is impacted on the metal surface to be cleaned. The sand-blast impact removes any L1,2scale present and also causes a certain
MECHANICAL CLEANING: Mechanical
cleaning removes loose rust and other impurities from the surface. This is, generally, done by hand cleaning with a bristle brush plus some abrasive like sand and detergent like soap. Impact tools like dull chisels, knife scrapers, wire brushes, grinding wheels and cutters are also used for removing strongly adhering scales, etc. the remaining dust and loose L1,2-
PICKING AND ETCHING: Acid
picking is more convenient method of scale removal in many cases than mechanical cleaning and sand-blasting. It is, usually, accomplished by immersing the metal except Al in an acid-pickling solution. Al is picked in alkaline solution. Acid-pickling of steel is accomplished by dipping in warm dil.H2SO4 or in cold HCl solution to L1,2-
PICKING AND ETCHING: For cleaning of articles made of copper, brass or nickel, the pickling bath consists of dilute HNO3 or a mixture of dil Nitric acid and dil. Sulphuric acid. If the cleaning operation is carried out in an efficient manner, it provides a clean, smooth surface for electro-deposition. Moreover, the deposit obtained is adherent, tough, and bright in L1,2-
Generally, there are two types of metallic coatings are protection from corrosion. Anodic coatings 2. Cathodic coatings And some other coatings like Chemical conversion coatings Organic coatings 1.
ANODIC COATINGS: Anodic
coatings are those in which, the metal used for is more anodic than the metal which is to be protected. For example, coating of Aluminum, Cadmium and Zinc on steel surface are anodic, because their electrode potentials are lower than that of the base metal iron. Therefore sacrificially, anodic coatings protect the underlying
ANODIC COATINGS: Zinc
being anodic is attacked, leaving the underlying cathodic metal like iron or steel unattacked. Even if it is exposed when pores, breaks or discontinuities occur in such type of coating. Zinc dissolves anodically, since being anodic to iron while the iron is protected, Hence, an anodic coating when properly prepared give high electrical insulation to the base metal and imparts good corrosion resistance and resistance to abrasion and stain.
Galvanization: Galvanization
is a process in which the iron article is protected from corrosion by coating it with a thin layer of zinc. In this process, at first iron or steel is cleaned by pickling with dilute sulphuric acid solution (H2SO4) at a temperature range of 60-900C for 15 to20 minutes. Therefore, it removes scale, rust and other impurities present if any and then washed well and dried. Then after, dipped in the bath molten zinc which is at 425-4500C. To prevent it from oxide formation, the surface of bath is covered with a flux (NH4Cl).
Galvanization: When
the iron piece is taken out it is coated with a thin layer of zinc. And to remove excess zinc, it is passed through a pair of hot rollers; lastly, it is annealed at a temperature of 4500C and then cooled slowly . For the protection of iron and steel products, it is most widely used in the form of wires, pipes, nails, bolts, screws, buckets,
CATHODIC COATINGS: TINNING: The process of coating tin over the iron or steel articles to protect it from corrosion is known as tinning. Tin is a nobler metal than iron, therefore, it is more resistance to chemical attack. In this process, at first Iron sheet is treated in dilute sulphuric acid (pickling) to remove any oxide film if present. A cleaned Iron sheet is passed through a bath molten flux. Like Zinc chloride, then through molten tin and finally through a suitable vegetable oil.
CATHODIC COATINGS: METAL CLADING: The surface to be protected is sandwiched between two thin layers of coat metal and pressed between rollers. The finished product may be welded at the edges or riveted at some points. The coat metal has to be anodic to the base metal and only plain surfaces can be cladded.
ELECTOPLATING; Electroplating
is the process or method of coating metals and nonmetals, to change their surface properties such as to improve the appearance, to properties such as to improve the appearance to corrosion and wear or chemical attack. Electroplating is the electrodeposition of metal, by means electrolysis over surface of metals,
ELECTOPLATING; The
wear resistance of a metal part can be improved by electroplating a harder metal on its surface. The metals most often plated on base metals or materials are chromium, Nickel and Rhodium. For example metals like Iron which are easily corroded by atmospheric air, moisture and CO2 are coated electrolytically with base metals such as nickel or chromium which
Some of the applications of electroplating are, 1. Plating for protection from corrosion and chemical attack. 2. Plating for decoration. 3. Plating for special for special surface and engineering effects. 4. Electroforming 5. Plating on non-metallic materials. Therefore, this process is widely used in automobiles, aircrafts, refrigerators, jewellery,
METAL SPRAYING: In
this process, the coating metal in the molten state is sprayed on the roughened surface of the base metal. The metal thus sprayed adheres t be the base metal surface. The sprayed-coatings are continuous, but some what porous. Consequently, a sealeroil or paint is applied on such a
METAL SPRAYING: The process offers certain advantages over the other methods, due to its: 1. greater speed of work 2. Applicability to large surfaces and 3. Ease of application, even of thick coatings to restricted area. However, adhesion strength of such coatings is, usually, lesser than those obtained by hotdipping or electroplating. It is, therefore, essential to have a clean and roughened metal surface on which a proper adhesion is to be secured. The surface is, generally, roughened
Sprayed-coatings can be applied by the following 2 techniques. wire-gun method 2. Powder metal method •
1. wire-gun method wire-gun method is more widely used for common metals. In this, the wire of the coating metal is melted by an oxyacetylene flame and atomized by a blast of compressed air.
2. Powder metal method in
this, finely divided powdered metal is sucked from the powder chamber and then heated as it passes through the flame of the blow-pipe. The blow-pipe disintegrates the metal into a cloud of molten globules, which are then adsorbed on the base metal surface.
CEMENTATION: Cementation
is the process in which base metal is packed in the powdered coating metal and heated to the temperature just below the melting point. Resulting in the formation of layers of alloys of varying composition. Generally an inert or reducing atmosphere is usually maintained during this process. Due to the diffusion of coating metal into base metal, an alloy of two
CEMENTATION: It
is also suitable for coating small articles of uneven surfaces and shapes such as screws, bolts, valves and gauge tools. The coating metals used in this process such as zinc, chromium and aluminum are those which can alloy even with iron.
COLORISING: Colorizing
is carried out by first sand-blasting the metal objects and then heating then in a tightly-packed drum with a mixture of aluminium powder and aluminium oxide, together with a trace of ammonium chloride as a flux. Air is excluded and in some process, a reducing atmosphere of hydrogen is used. The layer formed has an approximate composition of Al3Fe2, corresponding to about 25% al by weight. Colorizing is frequently applied, especially for the protection of
CHROMIZING: Chromizing
is carried out by heating together a mixture of 55% chromium powder and 45% alumina, together with the base metal parts at about 1300 to 14000C for 3 to 4 hours. The use of alumina prevents the coalescence of chromium particles. Chromizing is also produced by the interaction of a mixture of volatile chromous chloride and hydrogen with steel parts at about 10500C. The diffusion of chromium into iron
The process is believed to occur in three stages: The process is believed to occur in three stages:
1. Fe + CrCl2 FeCl2 + Cr (Displacement) 2. CrCl2 + H2 Cr + 2HCl (Reduction) 3. CrCl2 Cr + Cl2 (Thermal
The
corrosion-resistance of chromized coatings corresponds to that of ferrite stainless steels. The chromium content in the diffusion layers varies, generally, from 10 to 20%. The layers are supposed to be solid solutions of iron and chromium. Chromizing process is fairly extensively applied for the protection of gas turbine blades.
SHERADIZING: Sheradizing
is the process of cementation, using zinc powder as coating metal. The iron articles to be coated are first cleaned and then packed with “zinc dust” in a drum. The drum is then sealed tightly so that oxidation of zinc is minimum.
SHERADIZING: The
drum is slowly rotated for 2 to 3 hours and its temperature is kept between 350 to 3700C, either by gas heating or electricity. During this process, zinc gets diffused into iron forming Fe-Zn alloy at the surface. At the end of the process, the surface of the articles becomes
Applications of SHERADIZING: sherardizing
is used especially for small steel articles like bolts, screws, nuts, threaded-parts, washers, valves and gauge tools. The main advantage of sherardizing is that coating is quite uniform, even if the surface has crevices or depression. Moreover, there is practically no change in the dimension of
CHEMICAL CONVERSION COATINGS:
PHOSPHATE COATING:
Phosphate
coating is obtained by the chemical reaction of aqueous solution of phosphate of iron, manganese and Zinc with base metals such as Iron, Steel and Zinc. The chemical reaction produces a surface film consisting of manganese iron phosphates or Zinc-iron phosphates. For increasing the reaction rate,
PHOSPHATE COATING: Application
of phosphate coating on the base metal surface can be done by brushing or spraying. This coating so not offers corrosion resistance but offer excellent bases for painting, impregnation with oils etc. Iron and Manganese coatings are generally used to reduce wear caused by friction. Phosphate coating can be done on other metals such as Aluminum, Cadmium and Tin.
CHROMATING: ORGANIC
COATINGS Chromating is the process of coating a surface film with a mixture of trivalent and hexavalent chromium for protection from corrosion. Chromating is generally used for the protection of Zinc, Aluminum, Magnesium and Cadmium-plated parts. They are produced by immersion of the article in a bath of acid potassium chromate, followed by immersion in a
CHROMATING: The
properties of chromate coatings are amorphous, nonporous and more corrosion resistant than phosphate coatings. These are also sometimes used as base for paints, lacquers and enamels.
Anodizing: The
process of formation of conversion coating on a metal surface by anodic oxidation is known as Anodizing. This formation of an oxide coating by anodizing may be used to improve the wear resistance of certain metals. This process is usually applied to aluminum, magnesium, zinc and their alloys. And in anodizing, the work is the anode, and oxide layers are built up
ORGANIC COATINGS
PAINTS: Paint may be defined as the mechanical dispersion mixture of pigments and fillers which are in a liquid medium and later becomes film forming oil. The volatile liquids such as thinners are again added to these liquids.
CONSTITUENTS OF PAINT
CONSTITUENTS OF PAINT: Pigment Vehicle or drying oil Thinners d. Driers Fillers or extenders Plasticizers Antiskinning agents
Pigment: It
is solid constituent present in paint which provides a decorative colour effect to protect it from ultraviolet rays. Pigment is one of the essential constituents of paint. The essential functions of pigments areTo provide desired color, opacity and strength to the paint. To give aesthetical appeal to the paint film, To give protection the paint film by reflecting harmful ultraviolet light,
Vehicle or drying oil: It
is a film-forming constituent of the paint. The liquid portion of the paint in which the pigment is dispersed is called as vehicle or drying oil. The important functions of vehicle oil are: They hold the pigment on the metal surface They form the protective film, They impart water-repellency, durability and toughness to the film, and
Thinners: Viscosity (or consistency) of the paints are reduced by the addition of thinners. So that the paints can be easily applied on the metal surface. The important functions of thinners are: Thinners reduce the viscosity of the paint to suitable consistency, so that it can be easily handled and applied to the metal surface. They dissolve the film-forming material and also the other desirable additives in the vehicle. They evaporate rapidly and help the drying of the paint film. They suspend the pigments in the paint film. They increase the elasticity of the paint film,
Driers: The
drying of the oil is accelerated or catalyzed by driers. They do this by oxidation, polymerization and condensation. In fact, driers are oxygen carrier catalysts. The important functions of the driers areLinileates, borates, naphthalene’s, resonates and tungstates of heavy metals like Pb, Zn, Co and Mn. Surface driers: Cobalt substances,
e. Fillers or extenders: Fillers are inert materials which are used
to improve the properties and reduce the cost of the paint. The important functions of fillers are: They reducing the cost of the paint.(Expensive pigments which have excellent hiding power (like TiO2 and ZnSO4) are used in a admixture with cheap extenders for reducing the cost without reducing the efficiency), They serve to fill the voids in the film, They increase random arrangement of the primary pigment particles, and act as carriers for the pigment color, They improve the durability of the film
f. Plasticizers: Plasticizers
are added to the paint film to give elasticity to the paint film and to prevent cracking of the film. Ex: Tri cresyl phosphate, triphenyl phosphate, dibutyl tartarate, and tributyl phthalate.
g.. Antiskinning agents: antiskinning agents prevent the gelling and skinning of the paint film. E.g. Polyhydroxy phenols
Requirements of a Paint: The
adhesion capacity of the paint should be high to the material on which it is to be used. The paint should spread easily over the surface to be protected. On drying, the paint film should not be cracked.
Requirements of a Paint: The
paint film should have high corrosion resistance property so as to protect the painted surface from the corrosion environment. The paint film should be stable.
Requirements of a Paint: The
paint film should be prepared such a way as to be applicable easily by spraying or brushing. The paint film should yield a smooth and
Requirements of a Paint:
The paint film obtained on the surface should be tough, uniform and adherent. The colour of the film should be stable and should not get affected by the environment conditions.