Focusing on DP590 steel, this study employs numerical simulation to investigate the formation mechanism of temperature field inhomogeneity during continuous casting and its impact on multi-pass rough rolling. A 2D continuous casting temperature field model developed in Abaqus, defined with modeling parameters including a slab size of 1600 × 230 mm, a casting speed of 1.1 m min⁻¹, and specific water volume 1.99 l kg⁻¹, reveals the thermal evolution during the cooling process. A 3D heating-rolling model incorporating defined parameters of work roll radius 500 mm, speed 6 rad s⁻¹ further analyzes how temperature inhomogeneity affects rolling force and stress–strain distribution. The results demonstrate that the non-uniform temperature field significantly exacerbates rolling force fluctuations, with the rolling force under 600 s of heating increasing by approximately 15%–20% compared to a uniform 1200 °C temperature field, while simultaneously inducing a stress gradient along the thickness direction (stress difference exceeding 20 MPa between surface and core) and non-uniform strain distribution (strain difference reaching 0.68); however, extending the heating duration to 1200s reduces the core-surface temperature difference to below 300 °C, achieving stress–strain distribution uniformity comparable to isothermal conditions. Optimized heating processes enhance deformation uniformity, resolving the conflict between low-energy production and product quality in low-speed casting scenarios.