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Mohamad, Barhm
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Publications (5/5 displayed)
- 2024Predicting Damage in Notched Functionally Graded Materials Plates through extended Finite Element Method based on computational simulationscitations
- 2020Characterization and mechanical behaviour of similar and dissimilar parts joined by rotary friction welding
- 2017Remaining Life Assessment of Refinery Furnace Tubes Using Finite Element Method
- 2016Remaining Life Assessment of Refinery Furnace Tubes Using Finite Element Method
- 2016Remaining Life Assessment of Refinery Furnace Tubes Using Finite Element Method
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article
Remaining Life Assessment of Refinery Furnace Tubes Using Finite Element Method
Abstract
Crude oil heater 9Cre-1Mo steel tubes from a refinery plant were studied, after 5 years of service at nominally 650 Cº and 3 bar, to predict their remnant lives. The investigation included dimensional, hardness and tensile measurements in addition to accelerated stress rupture tests between 650 Cº and 700 Cº and microstructural examination. Tube specimens were taken from two sections, the overheated side and the side which only saw the nominal operating temperature. The method employed involved the prediction of the increase in temperature with increasing sediment deposition during the operating life times using an FEM model. In addition the predicted temperatures are used to derive appropriate creep properties at relevant temperatures in a 3D pipe FEM creep analysis to predict the pipe deformation rate. All compare well with the actual service exposed pipe measurements and layer deposition. The overheated side revealed a small loss of creep strength in a stress rupture test. A layer of sediment (appr. 10 mm thickness) consisting basically of sintered carbon (coke) spread over the inside of the tube was acting as a thermal barrier causing the temperature to rise above 650 Cº. Analysis for the overheated side predicted an upper bound temperature of 800 Cº and a life of about 50 h suggesting that failure by creep rupture could occur rapidly in the sediment region.