Abstract:A method of setting air-gap thermal resistance at the bottom of cooling mold was proposed to improve the homogeneity of circumferential microstructure and mechanical properties of BFe10-1-1 cupronickel tube produced by heating-cooling combined mold (HCCM) horizontal continuous casting. The influences of thermal-resistance angle on the heat transfer during continuous casting,circumferential microstructure and mechanical properties of the tube were investigated. The results show that for non-thermal resistance,the tube mainly consists of “V” type columnar grains at both the upper and lower parts,and axial columnar grains whose growth direction has an angle of 29°-36° to the axial direction at the lateral part. The morphology and number of the columnar grains at circumference of the tube are inhomogeneous,which induces apparent inhomogeneity of the tensile strength and elongation to failure of the tube. For the thermal-resistance angle of 8°-32°,with increasing the thermal-resistance angle,the angle between the columnar grain and the axial direction decreases,and the homogeneity of circumferential microstructure and mechanical properties of the tube is improved. The appropriate thermal-resistance angle at the bottom of cooling mold for BFe10-1-1cupronickel tube is 32°. Setting air-gap thermal resistance at the bottom of cooling mold improves the homogeneity of both circumferential heat transfer and temperature filed in the solidified zone of the tube during HCCM horizontal continuous casting,which is mainly responsible for enhancing the homogeneity of microstructure and mechanical properties of BFe10-1-1 cupronickel tube.

Key words: BFe10-1-1 tube; heating-cooling combined mold; horizontal continuous casting; thermal resistance; microstructure homogeneity