Industrial porcelain enamel (also known as glass lining, glass-lined steel, or glass fused to steel) is the use of porcelain enamel (also known as vitreous enamel) for industrial, rather than artistic, applications. Porcelain enamel, a thin layer of ceramic or glass applied to a substrate of metal, [1] is used to protect surfaces from chemical attack and physical damage, modify the structural characteristics of the substrate, and improve the appearance of the product.
Enamel has been used for art and decoration since the period of Ancient Egypt, and for industry since the Industrial Revolution. [1] It is most commonly used in the production of cookware, home appliances, bathroom fixtures, water heaters, and scientific laboratory equipment. [2]
The most important characteristic of porcelain enamel, from an industrial perspective, is its resistance to corrosion. [3] Mild steel is used in almost every industry and a huge array of products; porcelain enamel is a very economic way of protecting this, and other chemically vulnerable materials, from corrosion. It can also produce very smooth, glossy finishes in a wide array of colours; these colours will not fade on exposure to UV light, as paint will. Being a fired ceramic, porcelain enamel is also highly heat-resistant; this allows it to be used in high-temperature applications where an organic anti-corrosion coating or galvanization may be impractical or even dangerous (see Metal fume fever ). [3]
Porcelain enamel also sees less frequent employment of some of its other properties; examples are its abrasion resistance, where it may perform better than many metals; its resistance to organic solvents, where it is entirely impervious; its resistance to thermal shock, where it can resist rapid cooling from temperatures 500°C and higher; and its longevity. [3]
Porcelain enamel is used most often in the manufacture of products that will be expected to come under regular chemical attack or high heat such as cookware, burners, and laboratory equipment. It is used in the production of many household goods and appliances, especially those used in the kitchen or bathroom area: pots, pans, cooktops, appliances, sinks, toilets, bathtubs, even walls, counters, and other surfaces. [4]
Porcelain enamel is also used architecturally as a coating for wall panels. It may be used externally to provide weather resistance and desirable appearance, or internally to provide wear resistance; for example, on escalator side panels and tunnel walls. In recent years, agricultural silos have also been constructed with porcelain enamelled steel plates to protect the interior from corrosion and the exterior from weathering; this may indicate a future trend of coating all outdoor mild steel products in a weather-resistant porcelain enamel. [4]
The application of industrial porcelain enamel can be a complicated process involving many different and very technical steps. All enamelling processes involve the mixture and preparation of frit, the unfired enamel mixture; the preparation of the substrate; the application and firing; and then finishing processes. Most modern applications also involve two layers of enamel: a ground-coat to bond to the substrate and a cover-coat to provide the desired external properties.
Because frits frequently must be mixed at higher temperatures than the firing requires, most modern industrial enamellers do not mix their own frits completely; frit is most often purchased from dedicated frit producers in standard compositions and then any special ingredients added before application and firing. [5]
For ground coats, the composition of a frit for any given application is determined primarily by the metal used as the substrate: different varieties of steel, and different metals such as aluminium and copper, require different frit compositions to bond to them. For cover coats, the frit is composed to bind to the ground-coat and produce the desired external properties. [6] Frit is normally prepared by mixing the ingredients and then milling the mixture into a powder. The ingredients, most often metal oxides and minerals such as quartz (or silica sand), soda ash, borax, and cobalt oxide, are acquired in particulate form; the precise chemical composition and amount of each ingredient must be carefully measured and regulated. [7] Once prepared, this powdered frit is then slumped and stirred to promote even distribution of materials; most frits are smelted at temperatures between 1150 and 1300°C. After smelting, the frit is again milled into a powder, most often by ball mill grinding. [8]
For wet application of enamel, a slurry of frit suspended in water must be created. To remain in suspension, frits must be milled to an extremely fine particle size, or mixed with a suspension agent such as clay or electrolytes. [9]
The metal to be used as a substrate is primarily determined by the application to which the product will be put, independent of any enamel considerations. Most commonly used are steels of various compositions, but also used are aluminium and copper. [10]
Before the application of enamel, the surface of the substrate must be prepared with a number of processes. The most important processes are the cleaning of the surface of the substrate; all remnants of chemicals, rusts, oils, and other contaminants must be completely removed. To facilitate this, frequent processes performed on substrates are degreasing, pickling (which can also etch the surface and provide anchoring points for the enamel), alkaline neutralization, and rinsing. [11]
Enamel may be applied to the substrate via many different methods. These methods are most often delineated into either wet or dry applications, determined by whether the enamel is applied as a dry powder or a liquid slurry suspension.
The simplest method of dry application, especially for cast-iron substrates, is to heat the substrate and roll it in powdered frit. The frit particles melt on contact with the hot substrate and adhere to its surface. This method requires a high level of operator skill and concentration to achieve an even coating, and due to its inconstant nature is not often used in industrial applications. [12]
The most common method of dry application used in industry today is electrostatic deposition. Before application, the dry frit must be encapsulated in an organic silane; this allows the frit to hold an electrical charge during application. An electrostatic gun fires the dry frit powder onto the electrically earthed metal substrate; electrical forces bind the charged powder to the substrate and it adheres. [13]
The simplest method of wet application is to dip the substrate in a bath of liquid slurry; complete immersion coats all available surfaces of the substrate. Dipping is not often used in industry, however, because many preliminary trial dippings are required before the thickness of the coat can be predicted reliably enough for the desired application. [14]
A form of dipping suitable for modern industrial application is flow coating. Rather than dip the product in a bath of slurry, slurry is flowed over the surface of the substrate to be coated. This method allows for much more economical use of slurry and time; it is capable of allowing very rapid production runs. [15]
Wet enamel may also be sprayed onto the product using specialized spray guns. Liquid slurry is fed into the nozzle of a spray gun, and compressed air atomizes the slurry and ejects it from the nozzle of the gun in a controlled jet. [15]
Firing, where coated substrates are passed through a furnace to experience long periods of stable high temperatures, converts the adhering particles of frit into a continuous glass layer. The effectiveness of the process is highly dependent on the time, temperature, and the quality or thickness of the coating on the substrate. Most frits for industrial applications are fired for as low as 20 minutes, but frits for very heavy-duty industrial applications may take double this time. Porcelain enamel coatings on aluminium substrates may be fired at temperatures as low as 530°C, but most steel substrates require temperatures in excess of 800°C. [16]
Porcelain enamel has been applied to jewelry metals such as gold, silver, and copper since antiquity for the purposes of decoration. It was not until the Industrial Revolution that ferrous metals first became the subject of porcelain enamelling processes; these first attempts were met with limited success. A reliably successful technique was not developed until the middle of the 19th century, with the development of a method for enamelling cast-iron cooking pots in Germany. [1] It was not long before this method of enamelling became outdated with the development of new ferrous substrates, and most modern research into porcelain enamelling is concerned with creating an acceptable bond between enamels and new metal substrates. [17]
The production of porcelain enamelled products on an industrial scale first began in Germany in 1840. [18] The method used was very primitive compared to modern methods: the product was heated to a very high temperature and dusted with enamel, then immediately fired. This frequently resulted in poor adhesion or a spotty coat; two coats were always required to achieve a continuous, corrosion-resistant surface. [18] It could only be applied to cast- and wrought-iron, and only used for relatively simple products like pots and pans.
The ability to apply porcelain enamel to sheet steels was not developed until 1900, [19] with the discovery that making minor changes to the composition of the enamel, such as including cobalt oxides as minor components, could drastically improve its adhesion ability to carbon steels. Concurrent with this development was the first use of wet-slurry enamel application; this allowed porcelain enamel to be applied to much more complex shapes by dipping the shape into the liquid enamel slurry.
Up until the 1930s, all enamel applications required two coats of enamel: an undercoat to adhere to the substrate which was always blue (due in part to the presence of cobalt oxides), and a top coat of the desired colour (most often white). It was not until 1930 that the use of zero carbon steel (steel with less than 0.005% carbon content) as a substrate was linked to allowing lighter-colored enamels to adhere directly to the substrate. [20]
Galvanization or galvanizing is the process of applying a protective zinc coating to steel or iron, to prevent rusting. The most common method is hot-dip galvanizing, in which the parts are submerged in a bath of hot, molten zinc.
Corrosion is a natural process that converts a refined metal into a more chemically stable oxide. It is the gradual destruction of materials by chemical or electrochemical reaction with their environment. Corrosion engineering is the field dedicated to controlling and preventing corrosion.
Hot-dip galvanization is a form of galvanization. It is the process of coating iron and steel with zinc, which alloys with the surface of the base metal when immersing the metal in a bath of molten zinc at a temperature of around 450 °C (842 °F). When exposed to the atmosphere, the pure zinc (Zn) reacts with oxygen (O2) to form zinc oxide (ZnO), which further reacts with carbon dioxide (CO2) to form zinc carbonate (ZnCO3), a usually dull grey, fairly strong material that protects the steel underneath from further corrosion in many circumstances. Galvanized steel is widely used in applications where corrosion resistance is needed without the cost of stainless steel, and is considered superior in terms of cost and life-cycle. It can be identified by the crystallization patterning on the surface (often called a "spangle").
Vitreous enamel, also called porcelain enamel, is a material made by fusing powdered glass to a substrate by firing, usually between 750 and 850 °C. The powder melts, flows, and then hardens to a smooth, durable vitreous coating. The word comes from the Latin vitreum, meaning "glass".
A whiteboard is a glossy, usually white or black surface for making non-permanent markings. Whiteboards are analogous to blackboards, but with a smoother surface allowing rapid marking and erasing of markings on their surface. The popularity of whiteboards increased rapidly in the mid-1990s and they have become a fixture in many offices, meeting rooms, school classrooms, and other work environments.
Terne plate is a form of tinplate: a thin steel sheet coated with an alloy of lead and tin. The terne alloy was in the ratio of 10-20% tin and the remainder lead. The low tin content made it cheaper than other tinplates.
Plating is a surface covering in which a metal is deposited on a conductive surface. Plating has been done for hundreds of years; it is also critical for modern technology. Plating is used to decorate objects, for corrosion inhibition, to improve solderability, to harden, to improve wearability, to reduce friction, to improve paint adhesion, to alter conductivity, to improve IR reflectivity, for radiation shielding, and for other purposes. Jewelry typically uses plating to give a silver or gold finish.
Metallizing is the general name for the technique of coating metal on the surface of objects. Metallic coatings may be decorative, protective or functional.
A coating is a covering that is applied to the surface of an object, usually referred to as the substrate. The purpose of applying the coating may be decorative, functional, or both.
Powder coating is a type of coating that is applied as a free-flowing, dry powder. Unlike conventional liquid paint which is delivered via an evaporating solvent, powder coating is typically applied electrostatically and then cured under heat or with ultraviolet light. The powder may be a thermoplastic or a thermoset polymer. It is usually used to create a hard finish that is tougher than conventional paint. Powder coating is mainly used for coating of metals, such as household appliances, aluminium extrusions, drum hardware, automobiles, and bicycle frames. Advancements in powder coating technology like UV curable powder coatings allow for other materials such as plastics, composites, carbon fiber, and MDF to be powder coated due to the minimum heat and oven dwell time required to process these components.
Fusion bonded epoxy coating, also known as fusion-bond epoxy powder coating and commonly referred to as FBE coating, is an epoxy-based powder coating that is widely used to protect steel pipe used in pipeline construction from corrosion. It is also commonly used to protect reinforcing bars and on a wide variety of piping connections, valves etc. FBE coatings are thermoset polymer coatings. They come under the category of protective coatings in paints and coating nomenclature. The name fusion-bond epoxy is due to resigning cross-link and the application method, which is different from a conventional paint. In 2020 the market size was quoted at 12 billion dollars.
A Conversion coating is a chemical or electro-chemical treatment applied to manufactured parts that superficially converts the material into a thin adhering coating of an insoluble compound. These coatings are commonly applied to protect the part against corrosion, to improve the adherence of other coatings, for lubrication or for decoration.
The salt spray test is a standardized and popular corrosion test method, used to check corrosion resistance of materials and surface coatings. Usually, the materials to be tested are metallic and finished with a surface coating which is intended to provide a degree of corrosion protection to the underlying metal.
A frit is a ceramic composition that has been fused, quenched, and granulated. Frits form an important part of the batches used in compounding enamels and ceramic glazes; the purpose of this pre-fusion is to render any soluble and/or toxic components insoluble by causing them to combine with silica and other added oxides. However, not all glass that is fused and quenched in water is frit, as this method of cooling down very hot glass is also widely used in glass manufacture.
Aluminized steel is steel that has been hot-dip coated on both sides with aluminium-silicon alloy. This process assures a tight metallurgical bond between the steel sheet and its aluminium coating, producing a material with a unique combination of properties possessed neither by steel nor by aluminium alone. Aluminized steel shows a better behavior against corrosion and keeps the properties of the base material steel for temperature lower than 800 °C (1,470 °F). For example, it is commonly used for heat exchangers in residential furnaces, commercial rooftop HVAC units, automotive mufflers, ovens, kitchen ranges, water heaters, fireplaces, barbecue burners, and baking pans. This steel is very useful for heating things up because it transfers heat faster than most other steels.
This is a list of pottery and ceramic terms.
Substrate is a term used in materials science and engineering to describe the base material on which processing is conducted. This surface could be used to produce new film or layers of material such as deposited coatings. It could be the base to which paint, adhesives, or adhesive tape is bonded.
Automotive paint is paint used on automobiles for both protection and decoration purposes. Water-based acrylic polyurethane enamel paint is currently the most widely used paint for reasons including reducing paint's environmental impact.
Black oxide or blackening is a conversion coating for ferrous materials, stainless steel, copper and copper based alloys, zinc, powdered metals, and silver solder. It is used to add mild corrosion resistance, for appearance, and to minimize light reflection. To achieve maximal corrosion resistance the black oxide must be impregnated with oil or wax. One of its advantages over other coatings is its minimal buildup.
According to EN 13523-0, a prepainted metal is a ‘metal on which a coating material has been applied by coil coating’. When applied onto the metallic substrate, the coating material forms a film possessing protective, decorative and/or other specific properties.
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