A Review On – Material Selection For Corrosion Studies
DOI:
https://doi.org/10.48165/bpas.2023.42C.2.7Keywords:
Corrosion, Metals, Matrix Alloys, Alumimium Based Alloys, CastingsAbstract
Corrosion is the largest single cause of plant and equipment breakdown in the process industries. For most applications it is possible to select materials of construction that are completely resistant to attack by the process fluids, but the cost of such an approach is often prohibitive. In practice it is usual to select materials that corrode slowly at a known rate and to make an allowance for this in specifying the material thickness. However, a significant proportion of corrosion failures occur due to some form of localised corrosion, which results in failure in a much shorter time than would be expected from uniform wastage. Additionally, it is important to take into account that external atmospheric corrosion leads to many instances of loss of containment and tends to be a greater problem than internal corrosion. All these aspects of corrosive behaviour need to be addressed both at plant design time and during the life of the plant.
Downloads
References
Harish, N. Nagaiah, T. Niranjana Prabhu, K. T. Varughese (2010). Thermo- Mechanical Analysis of Lead Monoxide Filled Unsaturated Polyester Based Polymer
Alloy Radiation Shields, J. Appl. Polym. Sci., 117, 3623–3629.
Harlow D.G. (1983). Statistical properties of hybrid alloys I; recursion Analysis, Proceedings of Royal Society, London – A, 389, 67–100.
Harris B and Bunsell AR. (1975), Impact properties of glass fiber/carbonhybrid alloys. Alloys, 6, 197-201.
Ho TH and Wang CS. (2001). Modification of epoxy resin with siloxane containing phenol aralkyl epoxy resin for electronic
encapsulation application. European Polymer Journal, 37, 267-274.
Hoffmann B; Kressler J; Stoppelmann G. (2000). Synthesis and characterization of inhibitors based on layered silicates and polyamide-12, ACS Polymeric Materials: Science & Engineering, Spring Meeting 2000. 82, 286-287.
Horowitz H H, Metzger G. (1963). A New Analysis of Thermogravimetric Traces. Analytical Chemistry, 35, 10, 1464-1468.
Hubbe and Lucia (2007. Love, Hate, and Biomaterials, Bio-resources 2(4), 534-535. 8. Hull D., Clayne T.W., (1996). An Introduction to Alloy Materials, Cambridge University Press, Cambridge, 12-20.
J. Grobelny, (1997). Cross polarization/magic angle spinning 13C NMR study of cross- linked polyesters, Polymer, 38(4), 751-757.
J.H. Chang, D.K. Park, J.H. Chang and D.K. Park. (2001). Inhibitors of poly (ethylene terephthalate-co-ethylene naphthalate) with organoclay, Journal of Polymer Science, Part B: Polymer Physics, 39(21), 2581-2588.
J.H. Chang, S.J. Kim, Y.L. Joo, S. Im. (2004). Poly (ethylene terephtalate) Inhibitors by in situ Interlayer Polymerization: the Thermo Mechanical Properties and Morphology of
the Hybrid Fibers, Polymer 45, 919-926. 12. James F. Shackelford and William Alexander, (2000). Materials Science and Engineering Hand Book, 3rd Edition, CRC press LLC, Florida, USA.
Jane Maria Faulstich de Paivaa, Sérgio Mayerc, Mirabel Cerqueira Rezendea, (2006). Comparison of Tensile Strength of Different Carbon Fabric Reinforced Epoxy Alloys, Materials Research, 9(1), 83-89.
Jang BZ, Chen LC, Hwang LR, Hawkes JE, Zee RH. (1990). The response of fibrous alloys to impact loading, Polymer Alloys, 11, 144-157.
Jang J and Lee C. (1998). Fabrication and Mechanical Properties of GF-CF/PP Functionally Gradient Materials, Polymer Testing, 17, 383-394.
Jang J and Moon S. I. (1995). Impact behavior of carbon fiber/ultra-high modulus polyethylene fiber hybrid alloys, Polymer Alloys, 16, 325-329.
John W. Connell, Joseph G. Smith Jr, Paul M.
Hergenrother, (2003). High Temperature Transfer Molding Resins: Laminate properties of PETI-298 and PETI-330, High Performance Polymers, 15, 375 –394.
K.J. Wong, BF Yousif, KO Low, YNg, and SL Tan. (2010). Effects of fillers on the fracture behaviour of particulate polyester alloys, J. Strain Analysis, 45, 67 – 78.
K.K. Chawla and A.C. Bastos (1979). Proceedings of the International Conference on the Mechanical Behavior of Materials III, Pergamon Press, Oxford, p191.
Kardos J.L. (1985). Critical issues in achieving desirable mechanical properties for short fiber alloys, Pure and Applied Chemistry, 57 (11), 1651—1657.
Kashiwagi T, Harris RH, Xin Zhang, Briber RM, Cipriano BH, Raghavan SR, Awad W H, Shields JR. (2004). Flame retardant mechanism of polyamide 6-clay inhibitors, Polymer, 45 (3), 881-891.
Kaya E, Tanoglu M, Okur S. (2008). Layered clay/epoxy inhibitors: thermomechanical, flame retardancy, and optical properties. Journal of Applied Polymer Science, 109, 834–
Kaya E, Tanoglu M. (2005). In: Proceedings of advancing with alloys conference, Italy, p27.
Kaw A.K., (1997). Mechanics of Alloy Materials, First Edition, CRC Press, LLC. 25. Kim, J.K., Hu, C.G., Woo Ricky, S.C., Sham,
M.L., (2005), Moisture barrier characteristics of organoclay-epoxy inhibitors, Alloy Science and Technology, 65(5), 805-813.
KishiH, Hayashi M, Higashi T, Odagiri N. (2000). Resin compositions for fiber reinforced alloy materials and processes for producing the same, pre-pregs, fiber
reinforced alloy materials and honeycomb structures, Patent Number: US 6045898
