Ifayefunmi, Olawale and Mazli, Amirul Husaini and Ismail, Mohd Shahrom (2020) Combined Stability Of Cone-Cylinder Transition Subjected To Axial Compression And External Pressure. Thin-Walled Structures, 157. pp. 1-14. ISSN 0263-8231
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COMBINED STABILITY OF CONE-CYLINDER TRANSITION SUBJECTED TO AXIAL COMPRESSION AND EXTERNAL PRESSURE.PDF Download (697kB) |
Abstract
This paper examines the buckling behaviour of unstiffened mild steel cone-cylinder assembly under (i) axial compression and (ii) combined loading (i.e., axial compression and external pressure). Experimental results on ten (10) laboratory scaled axially compressed cone-cylinder models and their accompanying numerical predictions of collapse load are provided. The tested models are assumed to have the following range of geometric parameter: rcone/rcyl = 0.565–0.721, rcyl/t = 72.17–72.73, β = 8.536◦ – 16.69◦ and a constant wall thickness, t = 1.0 mm. Result confirms the repeatability of the experimental data. Besides that, there is a good agreement between experimental and numerically predicted collapse load with discrepancy calculated to be within 10%. Furthermore, numerical analysis of stability domains for cone-cylinder assembly subjected to simultaneous load actions of axial compression and external pressure was calculated for a range of geometrical parameters of: (i) 50 < rcyl/t < 400 and (ii) 10◦ < β < 30◦. For comparison purpose, the equivalent cylinder approach was also deployed to complete calculation based on ASME code case 2286-2. For the case of dimensionless radius-tothickness ratio, rcyl/t, the result confirms that the ASME code case 2286-2 is unsafe in designing the conecylinder shell with rcyl/t > 400. Whereas, for the case of different cone angle, β, it can be said that the ASME code case 2286-2 may perhaps be safe to use in designing the cone-cylinder shell with β < 20◦. In addition, the current analysis confirms that increasing the (a) dimensionless radius-to-thickness ratio, rcyl/t and (b) increasing the cone angle, β, may further shrink the combined stability plot. Finally, imperfect cone-cylinder shell under combined loading confirms that (i) the shell is remarkably sensitive at the pressure dominant region compared to the force dominant region and (ii) the location of dimple/dent imperfection at cylinder mid-section proves to be the worst-case scenario
Item Type: | Article |
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Uncontrolled Keywords: | Cone-Cylinder Assembly, Buckling, Combined Loading, External Pressure, Axial Compression Combined Loading, Elastic-Plastic ASME Design Codes, Equivalent Cylinder |
Divisions: | Faculty of Mechanical and Manufacturing Engineering Technology |
Depositing User: | Norfaradilla Idayu Ab. Ghafar |
Date Deposited: | 22 Dec 2020 12:52 |
Last Modified: | 22 Dec 2020 12:52 |
URI: | http://eprints.utem.edu.my/id/eprint/24522 |
Statistic Details: | View Download Statistic |
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