Study on inhomogeneous cooling behavior of extruded profile with unequal and large thicknesses during quenching using thermo-mechanical coupling model

• Published in: Transactions of Nonferrous Metals Society of China Vol. 30; no. 5; pp. 1211 - 1226
• Main Authors: LIU, Zhi-wen, YI, Jie, LI, Shi-kang, NIE, Wen-jie, LI, Luo-xing, WANG, Guan
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.05.2020
• Subjects: aluminum profile; heat transfer coefficient; thermo- mechanical coupling model; unequal and large thicknesses; water quenching; water quenching; unequal and large thicknesses; thermo- mechanical coupling model; heat transfer coefficient; aluminum profile
• ISSN: 1003-6326
• DOI: 10.1016/S1003-6326(20)65290-6

The interfacial heat transfer coefficient between hot profile surface and cooling water was determined by using inverse heat conduction model combined with end quenching experiment. Then, a Deform-3D thermo-mechanical coupling model for simulating the on-line water quenching of extruded profile with unequal and large thicknesses was developed. The temperature field, residual stress field and distortion of profile during quenching were investigated systematically. The results show that heat transfer coefficient increases as water flow rate increases. The peak heat transfer coefficient with higher water flow rates appears at lower interface temperatures. The temperature distribution across the cross-section of profile during quenching is severe nonuniform and the maximum temperature difference is 300 °C at quenching time of 3.49 s. The temperature difference through the thickness of different parts of profile first increases sharply to a maximum value, and then gradually decreases. The temperature gradient increases obviously with the increase of thickness of parts. After quenching, there exist large residual stresses on the inner side of joints of profile and the two ends of part with thickness of 10 mm. The profile presents a twisting-type distortion across the cross-section under non-uniform cooling and the maximum twisting angle during quenching is 2.78°.