Monel

Last updated
The Art Deco gate in the entrance hall of the Guardian Building is made from Monel. Guardian Building Art Deco Gate, Detroit.jpg
The Art Deco gate in the entrance hall of the Guardian Building is made from Monel.

Monel is a group of alloys of nickel (from 52 to 67%) and copper, with small amounts of iron, manganese, carbon, and silicon. Monel is not a cupronickel alloy because it has less than 60% copper.

Contents

Stronger than pure nickel, Monel alloys are resistant to corrosion by many aggressive agents, including rapidly flowing seawater. They can be fabricated readily by hot- and cold-working, machining, and welding. [2]

Monel was created in 1905 by Robert Crooks Stanley, who at the time worked at the International Nickel Company (Inco). [3] Monel was named after company president Ambrose Monell, and patented in 1906. [4] One L was dropped, because family names were not allowed as trademarks at that time. [1] The trademark was registered in May 1921, [5] and the name is now a trademark of Special Metals Corporation.

As an expensive alloy, its use is limited to those applications where it cannot be replaced with cheaper alternatives.[ citation needed ] For example, in 2015 Monel piping was three times more expensive than the equivalent piping made from carbon steel. [6]

Properties

Monel is a solid-solution binary alloy. As nickel and copper are mutually soluble in all proportions, it is a single-phase alloy. Compared to steel, Monel is very difficult to machine as it work-hardens very quickly. It needs to be turned and worked at slow speeds and low feed rates. It is resistant to corrosion and acids, and some alloys can withstand a fire in pure oxygen. It is commonly used in applications with highly corrosive conditions. Small additions of aluminium and titanium form an alloy (K-500) with the same corrosion resistance but with much greater strength due to gamma prime formation on aging. Monel is typically much more expensive than stainless steel.

Monel alloy 400 has a specific gravity of 8.80, [7] a melting range of 1300–1350 °C, an electrical conductivity of approximately 34% IACS, and (in the annealed state) a hardness of 65 Rockwell B. [8] Monel alloy 400 is notable for its toughness, which is maintained over a considerable range of temperatures.

Monel alloy 400 has excellent mechanical properties at subzero temperatures. Strength and hardness increase with only slight impairment of ductility or impact resistance. The alloy does not undergo a ductile-to-brittle transition even when cooled to the temperature of liquid hydrogen. This is in marked contrast to many ferrous materials which are brittle at low temperatures despite their increased strength.

Uses

Aerospace applications

In the 1960s, Monel metal found bulk uses in aircraft construction, especially in making the frames and skins of experimental rocket planes, such as the North American X-15, to resist the great heat generated by aerodynamic friction during extremely high speed flight. Monel metal retains its strength at very high temperatures, allowing it to maintain its shape at high atmospheric flight speeds, a trade-off against the increased weight of the parts due to Monel's high density.

Monel is used for safety wiring in aircraft maintenance to ensure that fasteners cannot come undone, usually in high-temperature areas; stainless wire is used in other areas for economy. In addition some fasteners used are made from the alloy.

Oil production and refining

Monel is used in the section of alkylation units in direct contact with concentrated hydrofluoric acid. Monel offers exceptional resistance to hydrofluoric acid in all concentrations up to the boiling point. It is perhaps the most resistant of all commonly used engineering alloys. The alloy is also resistant to many forms of sulfuric and hydrochloric acids under reducing conditions.

Marine applications

Monel's corrosion resistance makes it ideal in applications such as piping systems, pump shafts, seawater valves, trolling wire, and strainer baskets. Some alloys are completely non-magnetic and are used for anchor cable aboard minesweepers [9] or in housings for magnetic-field measurement equipment. In recreational boating, Monel is used for wire to seize shackles for anchor ropes, for water and fuel tanks, and for underwater applications. It is also used for propeller shafts and for keel bolts. On the popular Hobiecat sailboats, Monel rivets [10] are used where strength is needed but stainless steel cannot be used due to corrosion that would result from stainless steel being in contact with the aluminum mast, boom, and frame of the boat in a saltwater environment.

Because of the problem of electrolytic action in salt water (also known as Galvanic corrosion), in shipbuilding Monel must be carefully insulated from other metals such as steel. The New York Times on August 12, 1915 published an article about a 215-foot yacht, "the first ship that has ever been built with an entirely Monel hull," that "went to pieces" in just six weeks and had to be scrapped, "on account of the disintegration of her bottom by electrical action." The yacht's steel skeleton deteriorated due to electrolytic interaction with the Monel. [11]

In seabird research, and bird banding or ringing in particular, Monel has been used to make bird bands or rings for many species, such as albatrosses, that live in a corrosive sea water environment. [12]

Musical instruments

Monel is used as the material for valve pistons or rotors in some higher-quality musical instruments such as trumpets, tubas and French horns. RotoSound introduced the use of Monel for electric bass strings in 1962, and these strings have been used by numerous artists, including Steve Harris of Iron Maiden, The Who, Sting, John Deacon, John Paul Jones and the late Chris Squire. Monel was in use in the early 1930s by other musical string manufacturers, such as Gibson Guitar Corporation, who continue to offer them for mandolin as the Sam Bush signature set. Also, C.F. Martin & Co. uses Monel for their Martin Retro acoustic guitar strings. The Pyramid string factory (Germany) produces 'Monel classics' electric guitar strings, wound on a round core. In 2017, D'Addario string company released a line of violin strings using a Monel winding on the D and G string.

Other

Identification tags made from Monel Dog tags.jpg
Identification tags made from Monel

Good resistance against corrosion by acids and oxygen makes Monel a good material for the chemical industry. Even corrosive fluorides can be handled within Monel apparatus; this was done in an extensive way in the enrichment of uranium in the Oak Ridge Gaseous Diffusion Plant. Here most of the larger-diameter tubing for the uranium hexafluoride was made from Monel. [13] Regulators for reactive cylinder gases like hydrogen chloride form another example, where PTFE is not a suitable option when high delivery pressures are required. These will sometimes include a Monel manifold and taps prior to the regulator that allow the regulator to be flushed with a dry, inert gas after use to further protect the equipment.

In the early 20th century, when steam power was widely used, Monel was advertised as being desirable for use in superheated steam systems. [14] During the world wars, Monel was used for US military dog tags.

Monel doorknobs in the Bryn Athyn Cathedral Brynathyn6.JPG
Monel doorknobs in the Bryn Athyn Cathedral

Monel is often used for kitchen sinks and in the frames of eyeglasses. It has also been used for firebox stays in fire-tube boilers.

Parts of the Clock of the Long Now, which is intended to run for 10,000 years, are made from Monel because of the corrosion resistance without the use of precious metals. [15]

Monel was used for much of the exposed metal used in the interior of the Bryn Athyn Cathedral in Pennsylvania, religious seat of the General Church of the New Jerusalem. This included large decorative screens, doorknobs, etc. [1] Monel also has been used as roofing material in buildings such as the original Pennsylvania Station in New York City. [1]

The greenish roof of New York's Pennsylvania Station was made from Monel Pennsylvania Station Hawley 1910.jpg
The greenish roof of New York's Pennsylvania Station was made from Monel

The 1991–1996 Acura (Honda) NSX came with a key made of Monel. [16]

Oilfield applications include using Monel drill collars. Instruments which measure the Earth's magnetic field to obtain a direction are placed in a non-magnetic collar which isolates them from the magnetic pull of drilling tools located above and below the non-magnetic collars. Monel is now rarely used, usually replaced by non-magnetic stainless steels. [17] [18]

Monel is also used as a protective binding material on the outside of western style stirrups.

Monel is used by Arrow Fastener Co., Inc. for rustproof T50 staples.

Monel has also been used in Kelvinator refrigerators.

Monel was used in the Baby Alice Thumb Guard, a 1930s-era anti-thumb-sucking device. [19]

Monel is used in motion picture film processing. Monel staple splices are ideal for resisting corrosion from use in continuous-run photochemical tanks.

Monel was latterly widely used to manufactrure firebox stays in steam locomotive boilers.

Alloys

Monel is often traded under the ISO standards 6208 (plate, sheet and strip) 9723 (bars) 9724 (wire) 9725 (forgings) and the DIN 17751 (pipes and tubes).

Trade Name ASTM/AISI

Alloy type

 UNS %Cu%Al%Ti%Fe%Mn%Si%Ni
Monel 400B 127, B 164N0440028–342.5 max2.0 max0.5 max63 min
Monel 401N0440128–342.5 max2.0 max63 min
Monel 404N04404Rem0.05 max0.5 max0.1 max0.1 max52–57
Monel K-500B 865N0550027–332.3–3.150.35–0.852.0 max1.5 max0.5 max63 min
Monel 405B 164N0440528–342.5 max2.0 max0.5 max63 min

Monel 400

Monel 400 shows high strength and excellent corrosion resistance in a range of acidic and alkaline environments and is especially suitable for reducing conditions. [20] It also has good ductility and thermal conductivity. Monel 400 typically finds application in marine engineering, chemical and hydrocarbon processing, heat exchangers, valves, and pumps. It is covered by the following standards: BS 3075, 3076 NA 13, DTD 204B and ASTM B164. [21]

Large use of Monel 400 is made in alkylation units, namely in the reacting section in contact with concentrated hydrofluoric acid.

Monel 401

This alloy is designed for use in specialized electric and electronic applications. [22] Alloy 401 is readily autogenously welded by the gas-tungsten-arc process. Resistance welding is a very satisfactory method for joining the material. It also exhibits good brazing characteristics. It is covered by standard UNS N04401.

Monel 404

Monel 404 alloy is used primarily in specialized electrical and electronic applications. [23] The composition of Monel 404 is carefully adjusted to provide a very low Curie temperature, low permeability, and good brazing characteristics.

Monel 404 can be welded using common welding techniques and forged but cannot be hot worked. Cold working may be done using standard tooling and soft die materials for better finish. It is covered by standards UNS N04404 and ASTM F96. Monel 404 is used in capsules for transistors and ceramic to metal seals and other things.

Monel 405

Monel alloy 405, also known as Monel R405, is the free-machining grade of alloy 400. [24] The nickel, carbon, manganese, iron, silicon & copper percent remains the same as alloy 400, but the sulfur is increased from 0.024 max to 0.025-0.060%. Alloy 405 is used chiefly for automatic screw machine stock and is not generally recommended for other applications. The nickel-copper sulfides resulting from the sulfur in its composition act as chip breakers, but because of these inclusions the surface finish of the alloy is not as smooth as that of alloy 400. Monel 405 is designated UNS N04405 and is covered by ASME SB-164, ASTM B-164, Federal QQ-N-281, SAE AMS 4674 & 7234, Military MIL-N-894, and NACE MR-01-75.

Monel 450

This alloy exhibits good fatigue strength and has relatively high thermal conductivity. It is used for seawater condensers, condenser plates, distiller tubes, evaporator and heat exchanger tubes, and saltwater piping. [25]

Monel K-500

Monel K-500 combines the excellent corrosion resistance characteristic of Monel alloy 400 with the added advantages of greater strength and hardness. [26] [27] The increased properties are obtained by adding aluminum and titanium to the nickel-copper base, and by heating under controlled conditions so that submicroscopic particles of Ni3 (Ti, Al) are precipitated throughout the matrix.

The corrosion resistance of Monel alloy K-500 is substantially equivalent to that of alloy 400 except that, when in the age-hardened condition, alloy K-500 has a greater tendency toward stress-corrosion cracking in some environments. Monel alloy K-500 has been found to be resistant to a sour-gas environment. The combination of very low corrosion rates in high-velocity sea water and high strength make alloy K-500 particularly suitable for shafts of centrifugal pumps in marine service. In stagnant or slow-moving sea water, fouling may occur followed by pitting, but this pitting slows down after a fairly rapid initial attack.

Typical applications for alloy K-500 are pump shafts and impellers, doctor blades and scrapers, and oil-well drill collars, instruments, and electronic components.

Monel 502

Monel 502 is a nickel-copper alloy and its UNS no is N05502. This grade also has good creep and oxidation resistance. Monel 502 can be formed in different shapes. Monel 502 can be machined similar to austenitic stainless steels.

See also

Notes

    Related Research Articles

    <span class="mw-page-title-main">Metallurgy</span> Field of science that studies the physical and chemical behavior of metals

    Metallurgy is a domain of materials science and engineering that studies the physical and chemical behavior of metallic elements, their inter-metallic compounds, and their mixtures, which are known as alloys.

    <span class="mw-page-title-main">Stainless steel</span> Steel alloy resistant to corrosion

    Stainless steel, also known as inox, corrosion-resistant steel (CRES) and rustless steel, is an alloy of iron that is resistant to rusting and corrosion. It contains at least 10.5% chromium and usually nickel, as well as 0.2 to 2.11% carbon. Stainless steel's resistance to corrosion results from the chromium, which forms a passive film that can protect the material and self-heal in the presence of oxygen.

    Beryllium copper (BeCu), also known as copper beryllium (CuBe), beryllium bronze, and spring copper, is a copper alloy with 0.5–3% beryllium. Copper beryllium alloys are often used because of their high strength and good conductivity of both heat and electricity. It is used for its ductility, weldability in metalworking, and machining properties. It has many specialized applications in tools for hazardous environments, musical instruments, precision measurement devices, bullets, and some uses in the field of aerospace. Beryllium copper and other beryllium alloys are harmful carcinogens that present a toxic inhalation hazard during manufacturing.

    Cupronickel or copper-nickel (CuNi) is an alloy of copper with nickel, usually along with small quantities of other elements added for strength, such as iron and manganese. The copper content typically varies from 60 to 90 percent.

    <span class="mw-page-title-main">Brazing</span> Metal-joining technique

    Brazing is a metal-joining process in which two or more metal items are joined by melting and flowing a filler metal into the joint, with the filler metal having a lower melting point than the adjoining metal.

    Refractory metals are a class of metals that are extraordinarily resistant to heat and wear. The expression is mostly used in the context of materials science, metallurgy and engineering. The definition of which elements belong to this group differs. The most common definition includes five elements: two of the fifth period and three of the sixth period. They all share some properties, including a melting point above 2000 °C and high hardness at room temperature. They are chemically inert and have a relatively high density. Their high melting points make powder metallurgy the method of choice for fabricating components from these metals. Some of their applications include tools to work metals at high temperatures, wire filaments, casting molds, and chemical reaction vessels in corrosive environments. Partly due to the high melting point, refractory metals are stable against creep deformation to very high temperatures.

    <span class="mw-page-title-main">Aluminium bronze</span> Alloy of copper and aluminum

    Aluminium bronze is a type of bronze in which aluminium is the main alloying metal added to copper, in contrast to standard bronze or brass. A variety of aluminium bronzes of differing compositions have found industrial use, with most ranging from 5% to 11% aluminium by weight, the remaining mass being copper; other alloying agents such as iron, nickel, manganese, and silicon are also sometimes added to aluminium bronzes.

    <span class="mw-page-title-main">Austenitic stainless steel</span> One of the 5 crystalline structures of stainless steel

    Austenitic stainless steel is one of the five classes of stainless steel by crystalline structure. Its primary crystalline structure is austenite and it prevents steels from being hardenable by heat treatment and makes them essentially non-magnetic. This structure is achieved by adding enough austenite-stabilizing elements such as nickel, manganese and nitrogen. The Incoloy family of alloys belong to the category of super austenitic stainless steels.

    <span class="mw-page-title-main">SAE steel grades</span> Standard alloy numbering system for steel grades

    The SAE steel grades system is a standard alloy numbering system for steel grades maintained by SAE International.

    Exotic Materials can include plastics, superalloys, semiconductors, superconductors, and ceramics.

    <span class="mw-page-title-main">Architectural metals</span>

    Metals used for architectural purposes include lead, for water pipes, roofing, and windows; tin, formed into tinplate; zinc, copper and aluminium, in a range of applications including roofing and decoration; and iron, which has structural and other uses in the form of cast iron or wrought iron, or made into steel. Metal alloys used in building include bronze ; brass ; monel metal and nickel silver, mainly consisting of nickel and copper; and stainless steel, with important components of nickel and chromium.

    Incoloy refers to a range of superalloys now produced by the Special Metals Corporation (SMC) group of companies and created with a trademark by the Inco company in 1952. Originally Inco protected these alloys by patent. In 2000, the SMC published a 61-page document entitled "High-Performance Alloys for Resistance to Aqueous Corrosion" highlighting Incoloy, as well as Monel and Inconel products, and their use in fluid environments such as sulfuric acid, hydrochloric acid, hydrofluoric acid, phosphoric acid, nitric acid, other acids as well as freshwater environments.

    <span class="mw-page-title-main">Materials for use in vacuum</span>

    Materials for use in vacuum are materials that show very low rates of outgassing in vacuum and, where applicable, are tolerant to bake-out temperatures. The requirements grow increasingly stringent with the desired degree of vacuum to be achieved in the vacuum chamber. The materials can produce gas by several mechanisms. Molecules of gases and water can be adsorbed on the material surface. Materials may sublimate in vacuum. Or the gases can be released from porous materials or from cracks and crevices. Traces of lubricants, residues from machining, can be present on the surfaces. A specific risk is outgassing of solvents absorbed in plastics after cleaning.

    Alonizing is a diffusion metallizing process in that it is a thermochemical treatment that involves enriching the surface layer of an object with one or more metallic elements. Specifically, alonizing is the diffusion of aluminum into the surface of a base metal through high temperature vapors. The types of metals that can be alonized include all types of wrought and cast steels. This process results in an alloy with the surface properties of aluminum while retaining the base metal's inherent strength and rigidity. Therefore, alonizing does not change the high-temperature mechanical properties of the base metal, which is the advantage of alonizing over simply creating an aluminum alloy.

    <span class="mw-page-title-main">Grupo Compás</span>

    Grupo Compás, which trades as Alloy Valve Stockist, is an industrial alloy valve stockist and distributor based out of Barcelona, Spain and is recognized as one of the fastest growing service companies in Spain. Their customers come from three areas of activity: chemical and petrochemical refineries, combined cycle plants and companies related to the natural gas business, such as BASF, Repsol YPF, Saudi Aramco, Galp, Petrobras, Petronas and Marathon Oil; integrated engineering companies, like Sener, Technip and OneSteel; and valve manufacturers, stockists and specialized distributors, like Econosto and MRC Transmark. Grupo Compás supplies end users internationally, though the bulk of customers come from the US, Australia and European Union.

    Heat exchangers are devices that transfer heat to achieve desired heating or cooling. An important design aspect of heat exchanger technology is the selection of appropriate materials to conduct and transfer heat fast and efficiently.

    <span class="mw-page-title-main">SAE 304 stainless steel</span> Most common stainless steel

    SAE 304 stainless steel is the most common stainless steel. The steel contains both chromium and nickel metals as the main non-iron constituents. It is an austenitic stainless steel, and is therefore not magnetic. It is less electrically and thermally conductive than carbon steel. It has a higher corrosion resistance than regular steel and is widely used because of the ease in which it is formed into various shapes.

    Havar, or UNS R30004, is an alloy of cobalt, possessing a very high mechanical strength. It can be heat-treated. It is highly resistant to corrosion and is non-magnetic. It is biocompatible. It has high fatigue resistance. It is a precipitation hardening superalloy.

    References

    1. 1 2 3 4 Von Margot Gayle; David W. Look; John G. Waite (1992). "Monel". Metals in America's historic buildings: uses and preservation treatments. Diane Publishing. pp. 39–41. ISBN   978-0-16-038073-0. Archived from the original on 2017-02-17. Retrieved 2016-10-23.
    2. "Monel". Encyclopædia Britannica. Archived from the original on August 14, 2014. Retrieved August 12, 2014.
    3. Cherney, Ken; Orasi, Ron (16 February 2009). "Robert Crooks Stanley (1876-1951) – The Grandfather of the nickel industry (Part 1 of 2)". No. August 1989 Inco Triangle. Republic of Mining.
    4. Ambrose Monell U.S. patent 811,239 Issue date: Jan 1906
    5. "Word Mark: Monel". United States Patent and Trademark Office. Trademark Electronic Search System (TESS). Retrieved 3 April 2021.
    6. "Piping Materials and Cost Ratios". www.engineeringtoolbox.com. Archived from the original on 2017-12-26. Retrieved 2015-04-05.
    7. "Physical properties of Monel 400" (PDF). Archived from the original (PDF) on 2015-04-12. Retrieved 2015-04-21.
    8. "Monel 400 (NiCu30Fe, 2.4360, N04400, NA13) :: MakeItFrom.com". www.makeitfrom.com. Archived from the original on 2011-07-03. Retrieved 2010-04-19.
    9. Teeple, H. O. (1953). "Nickel and High-Nickel Alloys". Industrial & Engineering Chemistry. 45 (10): 2215–2232. doi:10.1021/ie50526a033.
    10. Hobie part number 8010261
    11. "New York Times, August 12, 1915: Big Yacht Now Junk After Six Weeks Use". The New York Times. August 12, 1915. Archived from the original on May 23, 2009. Retrieved May 13, 2010.
    12. Ludwig, James P. (1981). "Band Wear and Band Loss in the Great Lakes Caspian Tern Population and a Generalized Model of Band Loss". Colonial Waterbirds. 4: 174–18. doi:10.2307/1521133. JSTOR   1521133.
    13. Milford, Robert (1958). "Engineering Design of Oak Ridge Fluoride Volatility Pilot Plant". Industrial & Engineering Chemistry. 50 (2): 187–191. doi:10.1021/ie50578a032.
    14. International Nickel Company (1921), Monel advertisement in Scientific American, 1921, archived from the original on 2016-04-09, retrieved 2015-03-28
    15. Beech, Martin (2007). "The Clock of the Long Now — A Reflection" (PDF). The Journal of the Royal Astronomical Society of Canada. 101 (1): 4–5. Bibcode:2007JRASC.101....4B. Archived from the original (PDF) on 2011-07-06.
    16. "NSX Keys". Archived from the original on 2011-09-25. Retrieved 2011-07-05.
    17. "Custom Monel Machining Services". WES Engineering Solutions. Archived from the original on 2020-02-23. Retrieved 2021-02-01.
    18. Mitchell, Bill (1995). Advanced Oilwell Drilling Engineering Handbook (10th ed.). Lakewood, CO: Mitchell Engineering. pp. 430–431. ASIN   B0006RMYTW. OCLC   46870163. Archived from the original on 2021-02-01. Retrieved 2021-02-01.
    19. "STOP THUMB SUCKING". graphic-design.tjs-labs.com. Archived from the original on 2017-02-15. Retrieved 2014-02-23.
    20. "Material Data Sheet Alloy 400" (PDF). Archived (PDF) from the original on 28 March 2019. Retrieved 28 Mar 2019.
    21. "Monel K-400 on Azom.com". Archived from the original on August 12, 2014. Retrieved August 12, 2014.
    22. MONEL alloy 401 DATASHEET (PDF). Archived from the original (PDF) on 2017-05-10. Retrieved 2016-03-19.
    23. MONEL alloy 404 DATASHEET (PDF). Archived from the original (PDF) on 2017-05-10. Retrieved 2016-03-19.
    24. "MONEL® Alloy R-405" (PDF). Special Metals. Retrieved 16 January 2023.
    25. "Property of Monel alloys". Archived from the original on April 15, 2015. Retrieved April 10, 2015.
    26. "Material Data Sheet Alloy K-500" (PDF). Archived (PDF) from the original on 8 January 2017. Retrieved 17 November 2017.
    27. MONEL alloy K-500 DATASHEET (PDF) (Report). Archived (PDF) from the original on 2016-03-31. Retrieved 2016-03-19.

    Bibliography

    This page is based on this Wikipedia article
    Text is available under the CC BY-SA 4.0 license; additional terms may apply.
    Images, videos and audio are available under their respective licenses.