R. W. Kirchner scite author profile

Equipment made of NiCrMo alloys of the Ni 16 Cr 16 Mo W and Ni 22 Cr 16 Mo types is used extensively in the chemical industry, in particular because the corrosion resistance in the as‐welded condition could be improved in recent years by controlling C and Si contents to very low levels. A new type of alloy — Hastelloy Developmental Alloy C‐455 — has high resistance to carbide and intermetallic phase precipitation at high temperatures. By reducing the amount of these phases it has been possible to considerably improve the high temperature properties, the corrosion resistance and the mechanical properties of the alloy. The new material may be exposed to sensitizing range temperatures (550–1090 °C) for a long time without becoming susceptible to corrosion: it is, therefore, readily weldable. Contrary to NiCrMo alloys known so far there are almost no problems when the material is exposed to hydrochloric and sulfuric acids.

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Sensitization of Wrought High Nickel Alloys

Brown¹,

Kirchner²

1973

CORROSION

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An Evaluation of Nickel‐rich Alloys In Wet Process Phosphoric Acid

Kirchner¹

1971

Materials & Corrosion

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IntroductionPhosphoric acid is an important chemical intermediate and is used primarily in fertilizer production. It is;lso used extensively as an intermediate in the production of detergents, water treatment, chemicals and leavening agents.Phosphoric acid is produced by two basic methods: the wet process involving reaction of phosphate rock with an acid (sulfuric, nitric, hydrochloric) and the furnace process in which phosphorous is burned with air to produce PzO5 gas which is then hydrated to form phosphoric acid. This report is concerned only with phosphoric acid that is produced by the wet process using sulfuric acid digestion.Extensive corrosion data have been published on the resistance of metals to reagent grade phosphoric acid. In contrast however, only limited test data are available on the resistance of metals in the wet phosphoric acid process. It should be noted that all the published corrosion data were obtained from immersion tests and are not useful in predicting the resistance of metals under heat transfer conditions.Operating experience with chemical process equipment has indicated that the corrosion rates of metals are accelerated when heat is transferred through the metal. For this reason, it is often necessary to fabricate the heating coils of a process reactor from a more corrosion resistant alloy than the walls of the reactor vessel. This accelerated corrosion attack of the coils is attributed to the extreme heating of a thin layer of fluid adjacent to the metal surface. In the case of very high solution temperatures, localized boiling is also responsible for increased corrosion attack. (1-14) describe the use of laboratory equipment to reproduce corrosive plant conditions involving heat transfer and elevated temperatures. The studies indicated that a hot wall test apparatus could satisfactorily simulate the heat flow through metal walls and its effects on corrosion. The test method was originally developed by N. D. Gyoves (1) and was used to predict the life of heat transfer surfaces in service in atomic energy installations. The investigations performed by Fisher and Whitney (2) concluded that the skin temperatures of the metal is the controlling factor in the corrosion Several publications JahrgangHeft 711971 attack and not the amount of heat flux flowing through the metal.Producers of phosphoric acid indicated interest in the potential use of corrosion-resistant metals for process equipment. Of specific interest were materials for evaporators for processing superphosphoric acid at higher temperatures. Several companies had indicated that they were evaluating processes for production of superphosphoric acid that required materials exceeding the temperature and pressure capabilities of impervious graphite which is commonly used in heat transfer equipment. Thus they were interested in metals and alloys suitable for these conditions and displaying acceptable corrosion resistance. Acid producers from Virginia and Florida cooperated in the study by providing samples of their crude phosphoric ...

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R. W. Kirchner

An Improved Ni-Cr-Mo Alloy for Corrosion Service

New Ni‐Cr‐Mo alloy demonstrates high‐temperature structural stability with resultant increases in corrosion‐resistance and mechanical properties

Sensitization of Wrought High Nickel Alloys

An Evaluation of Nickel‐rich Alloys In Wet Process Phosphoric Acid

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