Abstract
Multi-layer pipe was first developed around 20 years ago. Since its entry, it has been utilized in countless installations across the globe and has recognized an excellent track record of reliability. During this period, it was in relatively limited supply in the UK, and carried a high price tag due to its cutting-edge design and the complicated manufacturing processes involved. The Multi-layer Pipe System (MLP) is a progressive, very hard wearing, and easy to work with system. It is manufactured using a well-engineered combination of toughened Pex-b plastic and overlay welded aluminum.
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Janson LE (1999) Plastics pipes for water supply and sewage disposal. Borealis, Stockholm
Nezbedova E, Zahradnickova A, Salajka Z (2001) Brittle failure versus structure of HDPE pipe resins. J Macromol Sci Phys B 40:507
Lu X, Brown N (1992) A test for slow crack growth failure in polyethylene under a constant load. Polym Test 11:309–319
Šindelarˇ P, Nezbedova E, Šimkova P, Buranˇ Z, Bohaty´ P (2005) Effect of structural parameters on rapid crack propagation and slow crack growth in high density polyethylene pipeline materials. Plast Rubber Compos 34:329–333
Hutař P, Náhlík L, Šestáková L, Ševčík M, Knésl Z, Nezbedová E (2010) A fracture mechanics assessment of surface cracks existing in protective layers of multi-layer composite pipes. Compos Struct 92:1120–1125
Ribaritis E (1987) Visico crosslinkable polyethylene silane copolymer for cable insulation. Neste Polyeten AB
Plueddemann E (1982) Silane coupling agents. Plenum Press, pp 32–33
Farshad M (2005) Determination of the long-term hydrostatic strength of multilayer pipes. Polym Test 24:1041–1048
Frank A, Pinter G, Lang RW (2009) Prediction of the remaining lifetime of polyethylene pipes after up to 30 years in use. Polym Test 28:737–745
Andena L, Rink M, Frassine R, Corrieri R (2009) A fracture mechanics approach for the prediction of the failure time of polybutene pipes. Eng Fract Mech 18:2666–2677
Frank A, Freimann W, Pinter G, Lang RW (2009) A fracture mechanics concept for the accelerated characterization of creep crack growth in PE-HD pipe grades. Eng Fract Mech 76(18):2780–2787
Hutar P, Zouhar M, Nahlik L, Ševčík M, Mašab B (2013) Multilayer polymer pipes failure assessment based on a fracture mechanics approach. Eng Fail Anal 33:151–162
Anderson TL (1991) Fracture mechanics—fundamentals and application. CRC Press Inc., Boca Raton
Hutař P, Nahlik L, Šestáková L, Ševčík M, Knesl Z, Nezbedova E (2010) A fracture mechanics assessment of surface cracks existing in protective layers of multilayer composite pipes. Compos Struct 92:1120–1125
Zouhar M, Vallet L, Hutař P, Nahlik L (2011) Life time estimation of the multilayer plastic pipes. Key Eng Mater 452–453:33–36
Romeo A, Ballarini R (1995) A crack very close to a bi-material interface. Trans ASME 32:614–619
Samimi A, Zarinabadi S (2011) An analysis of polyethylene coating corrosion in oil and gas pipelines. J Am Sci 7(1)
Wang P, Yang Y, Ding G, Qu J, Heshen S (1997) Laser adding coating against wear and its application to mining machine parts. Wear 209:96
Zheng Y, Yao Z, Wei X, Ke W (1995) The synergistic effects between erosion and corrosion in acidic slurry medium. Wear 186/187:555
Ma X, Lin F, Shao H (1991) Study on the wear-resistant adhesive coating in scouring. Lubr Eng. (4):11 (in Chinese)
Iwai Y, Nambu K (1997) Slurry wear properties of pump lining materials. Wear 210:211
Zhang JX, Richardson MOW, Wilcox GD et al (1996) Assessment of resistance of nonmetallic coatings to silt abrasion and cavitation erosion in a rotating disk test rig. Wear 194:149
Parslow GI, Stephenson DJ, Strutt JE et al (1997) Paint layer erosion resistance behavior for use in a multilayer paint erosion indication technique. Wear 212:103
Luo S, Zheng Y, Li J, Ke W (2001) Slurry erosion resistance of fusion-bonded epoxy powder coating. Wear 249:733–738
Luo S, Zheng Y, Li J, Ke W (2003) Effect of curing degree and fillers on slurry erosion behavior of fusion-bonded epoxy powder coatings. Wear 254:292–297
Husain A, Al-Bahar S, Chakkamalayath J, Vikraman A, Al Ghamdi A, Kamshad T, Siriki RS (2015) Differential scanning calorimetry and optical photo microscopy examination for the analysis of failure of fusion bonded powder epoxy internal coating. Eng Failure Anal 56:375–383
Weldon DG (2005) Failure analysis and degree of cure. J Protective Coat Linings (July)48–55
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Rajasekar, R., Sasi Kumar, K.S.K., Sathish Kumar, P. (2016). Multi Layer Pipes. In: Kim, J., Thomas, S., Saha, P. (eds) Multicomponent Polymeric Materials. Springer Series in Materials Science, vol 223. Springer, Dordrecht. https://doi.org/10.1007/978-94-017-7324-9_10
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DOI: https://doi.org/10.1007/978-94-017-7324-9_10
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