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Nichrome (also known as NiCr, nickel-chromium or chromium-nickel) is a family of alloys of nickel and chromium (and occasionally iron[1]) commonly used as resistance wire, heating elements in devices like toasters, electrical kettles and space heaters, in some dental restorations (fillings) and in a few other applications.
Patented in 1906 by Albert Marsh (US patent 811,859[2]), nichrome is the oldest documented form of resistance heating alloy.
The A Grade nichrome alloy is 80% nickel and 20% chromium by mass, but there are many other combinations of metals for various applications.
Properties
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C Grade Nichrome is consistently silvery in colour, is corrosion-resistant, has a high melting point of about 1,400 °C (2,550 °F), and has an electrical resistivity of around 112 μΩ–cm, which is around 66 times higher resistivity than copper of 1.678 μΩ–cm.[3]
Almost any conductive wire can be used for heating, but most metals conduct electricity with great efficiency, requiring them to be formed into very thin and delicate wires to create enough resistance to generate heat. When heated in air, most metals then oxidize quickly, become brittle and break. Nichrome wire, when heated to red-hot temperatures, develops an outer layer of chromium oxide,[4] which is thermodynamically stable in air, is mostly impervious to oxygen, and protects the heating element from further oxidation.
Nichrome alloys are known for their high mechanical strength and their high creep strength.[5] The properties of nichrome vary depending on its alloy. Figures given are representative of typical material and are accurate to expressed significant figures. Any variations are due to different percentages of nickel or chromium.
Standard compositions
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Nichrome alloys for use in resistance heating are described by both ASTM and DIN standards.[6][7] These standards specify the relative percentages of nickel and chromium that should be present in an alloy. In ASTM three alloys that are specified contain, amongst other trace elements:
Properties by composition
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Each standard composition of nichrome has unique material properties. Some general ones are given as follows:[8]
Table of nichrome alloys Alloy % Content Density[g/cm3]
Ni Cr Fe NiCr 80/20 80 20 0 8.3 NiCr 70/30 70 30 0 8.1 NiCr 60/16 60 16 Remainder 8.2 NiCr 35/20 35 20 Remainder 7.9Uses
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Because of its low cost of manufacture, strength, ductility, resistance to oxidation, stability at high temperatures, and resistance to the flow of electrons, nichrome is widely used in electric heating elements in applications such as hair dryers and heat guns. Typically, nichrome is wound in coils to a certain electrical resistance, and when current is passed through it the Joule heating produces heat.
Nichrome is used in the explosives and fireworks industry as a bridgewire in electric ignition systems, such as electric matches and model rocket igniters.
Industrial and hobby hot-wire foam cutters use nichrome wire.
Nichrome wire is commonly used in ceramic as an internal support structure to help some elements of clay sculptures hold their shape while they are still soft. Nichrome wire is used for its ability to withstand the high temperatures that occur when clay work is fired in a kiln.
Nichrome wire can be used as an alternative to platinum wire for flame testing by colouring the non-luminous part of a flame to detect cations such as sodium, potassium, copper, calcium, etc.
Other areas of usage include motorcycle mufflers, in certain areas in the microbiological lab apparatus, as the heating element of plastic extruders by the RepRap 3D printing community, in the solar panel deployment mechanism of spacecraft LightSail-A, and as the heating coils of electronic cigarettes.
The alloy price is controlled by the more expensive nickel content. Distributor pricing is typically indexed to market prices for nickel.
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Toxicity
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Nickel is a common allergen, a 1984 study by the University of Puerto Rico showed that 28.5% of people tested had some kind of allergic reaction following contact with nickel.[9]
See also
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References
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The nickel-chromium system reveals that chromium is fairly soluble in nickel. It has a maximum soluble rate of 47% at eutectic temperature, which then decreases to approximately 30% at room temperature. Several commercial alloys are based on this solid solution. These alloys have superior resistance to high-temperature corrosion and oxidation, and optimal wear resistance.
Adding small quantities (less than 7%) of chromium to nickel can increase the sensitivity of the alloy to oxidation. The reason behind this is the increase in the diffusion rate of oxygen in the scale. This trend reverses once addition levels go beyond 7% chromium, and increases up to an addition level of about 30%. There is minimal change above this level.
Oxidation resistance can arise due to the formation of an extremely adherent protective scale. The adherence and coherence of the scale can be enhanced by adding small quantities of other reactive elements like cerium, silicon, zirconium, calcium, etc. The scale thus formed is a blend of nickel and chrome oxides (NiO and Cr2O3). These join together and form nickel chromite (NiCr2O4), with a spinel-type structure.
Increased addition of chromium leads to a noticeable increase in electrical resistivity. An addition level of 20% chromium is said to be ideal for electrical resistance wires, which can be used in heating elements.
This composition integrates optimal electrical properties with optimal ductility and strength, making it ideal for wire drawing. Commercial grades include Brightray and Nichrome. Small alterations to this composition may be done to enhance it for specific applications.
The incorporation of suitable reactive alloying elements will influence the properties of the scale. The alloy’s operating conditions largely govern the composition that should be used. Table 1 shows the differences in composition between alloys used for intermittent and continuous applications.
Table 1. Suitable compositions for heating elements used intermittently and continuously.
Element Intermittent Continuous Cr 20 20 Si 1.5 0.5 Ca 0.1 0.05 Ce 0.05 - Ni Balance BalanceWhile the effect of the compositional alterations on the mechanical properties is negligible, increased addition of reactive elements helps to inhibit flaking of the scale during cyclic heating and cooling. This effect does not pose much problem to heating elements that operate nonstop; therefore, it is not necessary for the addition levels to be very high.
The binary 90/10 Ni/Cr alloy is also used for heating elements. This alloy has the highest operating temperature of 1100 °C. Thermocouples are the other applications of this alloy.
The 90/10 Ni/Cr alloy is usually used in thermocouples, together with a 95/5 Ni/Al alloy. This combination, which is referred to as chromel-alumel, has a maximum operating temperature of 1100 °C, similar to heating elements. This thermocouple becomes vulnerable to drift in the region of 1000 °C because of preferential oxidation, following continuous usage for a prolonged period. It has been discovered that the addition of silicon overcomes this effect. Commercial grades include Nisil (which has 4.5% Si and 0.1% Mg) and Nicrosil (which has 14% Cr and 1.5% Si).
The 80/20 Ni/Cr alloy has better resistance to hot corrosion and oxidation than inexpensive iron-nickel-chromium alloys. Hence, it is mostly used for cast and wrought parts for high-temperature applications. This alloy is ideal for applications that are prone to oxidation.
Alloys with higher chromium content are more ideal for applications that are prone to fuel ashes and/or deposits such as, alkali metal salts like sulfates. This is because, fuel ashes tend to react with the oxide scale. Ashes that contain vanadium are quite aggressive and have a fluxing effect on the scale, thus increasing the vulnerability of the alloy to degradation caused by oxidation.
In sulfur-containing environments, chromium sulfide (Cr2S3, with a melting point of 1550 °C) is formed preferentially to nickel sulfide. But, formation of nickel sulfide is favored, as this deters the formation of the nickel/nickel-sulfide eutectic that has a low melting point. Ultimately, local chromium supplies can be depleted, leaving sulfur to react with nickel and form the eutectic compound with a low melting point. This results in a liquid phase attack.
Alloys that have undergone this type of attack have wart-like formations on their surface. The preferential formation of chromium sulfides shows that alloys with higher chromium levels are more resilient to this form of attack.
Nickel/chromium alloys with over 30% chromium have a two-phase structure including ?-nickel and a-chromium. Since the a-chromium phase is brittle, the ductility of the alloy decreases with an increase in chromium content.
Table 2 illustrates the properties of certain binary alloys. The addition of approximately 1.5% niobium boosts ductility and strength, while simultaneously minimizing embrittlement after high-temperature exposure, given that impurities such as nitrogen, carbon, and silicon are minimized.
Table 2. Tensile and ductility properties for some Ni/Cr alloys at room temperature
Cr Content (%) Tensile Str (MPa) Elong. (%) 35 480 62 50 540-680 7-24 60 800-1000 1-2Alloys with up to about 35% chromium content can be hot worked. Beyond this level, they are mostly suited only for casting. A specific level of ductility gain can be realized by adding titanium or zirconium. One such example is Inconel 671 (with 48% Cr and 0.35% Ti) that is used in applications like duplex tubing for coal-fired superheating tubing.
Wear mechanisms are complicated; however, good corrosion resistance and high hardness add to good wear resistance. Ni/Cr alloys offer a cheaper alternative to materials like weld-deposited cobalt-chrome alloys with added tungsten and carbon, that are usually used in wear-resistant applications.
An example of a Ni/Cr alloy for this type of application is an alloy containing 8%–12% Cr, 1%–4% Fe, 3%–4% Si, 0.3%–1.0% C, 1.5%–2.5% B, and the remaining portion Ni. The hardness of a coating of this material deposited by inert gas shielded arc methods would fall in the range of 40 to 50 Rockwell C.
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The nickel-chromium system reveals that chromium is fairly soluble in nickel. It has a maximum soluble rate of 47% at eutectic temperature, which then decreases to approximately 30% at room temperature. Several commercial alloys are based on this solid solution. These alloys have superior resistance to high-temperature corrosion and oxidation, and optimal wear resistance.