2024 铝合金油气滑半连铸产品中出现的热裂纹问题严重影响了其工业化生产及综合性能。 本文利用ProCAST 铸造分析软件，基于移动边界法的宏观温度场模型，利用 CAFE (cellular automata finite element) 模块模拟铸锭微观组织对比实际晶粒尺寸，验证了模型可靠性；基于热弹塑性模型模拟了铸锭所受的主应力、等效应力以及切应力，分析了热裂纹的产生原因。 对铸锭进行热裂纹敏感性判据 HTI (hot tearing indicator) 分析，结果表明，沿半径方向距离边缘约 40 mm 处裂纹倾向性最大且成环状，与实际铸锭中的裂纹位置和形状一致。 基于第三强度理论，得到了 φ254 mm的 2024 铝合金半连铸最佳工艺区间，铸造温度为 685~695 ℃ ，铸造速度为 59~62 mm/min 。 经验证，获得了表面质量良好，无裂纹的 2024 铝合金铸锭。

Hot cracking easily occurs in the semi-continuous casting of 2024 aluminum alloy, further seriously affecting its industrial production and comprehensive performance. Numerical simulation technology is an important method to solve the problem of hot cracks. The CAFE (cellular automata finite element) module of ProCAST casting analysis software was used to simulate the solidification microstructure. First, the macroscopic temperature field of the semi-continuous casting process is simulated by the moving boundary method. Macroscopic temperature fields are used for microstructure simulation. The actual grain size is consistent with the simulated grain size. Therefore, the model is proven to be reliable. Principle stress, equivalent stress and shearing stress on the ingot were simulated based on the thermo-elasticity model. The causes of cracks were analysed by stress field simulation. In addition, the hot tearing indicator (HTI) was used to judge the crack tendency in ProCAST. The results show that the cracking tendency is greatest along the radius direction at a distance of  approximately 40 mm from the edge and in a ring shape. The crack location and shape in the simulated ingot are consistent with those in the actual ingot. Based on the third strength theory, the optimal process of semi-continuous casting of 2024 aluminum alloy with φ254 mm was explored. A casting temperature of 685~695 ℃ and a casting speed of 59~62 mm/min are the most reasonable process parameters. After test verification, 2024 aluminum alloy ingots with good surface quality and no cracks are obtained.