Optimizing high-performance power electronic equipment, such as power converters, requires multiscale simulations that incorporate the physics of power semiconductor devices and the dynamics of other circuit components, especially in conducting design of experiments (DoEs), defining the safe operating area of devices, and analyzing failures related to semiconductor devices. However, current methodologies either overlook the intricacies of device physics or do not achieve satisfactory computational speeds. To bridge this gap, this article proposes a hybrid-parallel collaborative (HPC) framework specifically designed to analyze the partial differential–algebraic equation (PDAE)-modeled power electronic equipment, integrating the device physics and circuit dynamics. The HPC framework employs a dynamic iteration to tackle the challenges inherent in solving the coupled nonlinear PDAE system and utilizes a hybrid-parallel computing strategy to reduce computing time. Physics-based system partitioning, along with hybrid-process-thread parallelization on shared and distributed memory, is employed, facilitating the simulation of hundreds of partial differential equations-modeled devices simultaneously without compromising speed. Experiments based on the hybrid-line commutated converter and reverse-blocking integrated gate-commutated thyristors are conducted under three typical real-world scenarios: semiconductor device optimization for the converter, converter design optimization, and device failure analysis. The HPC framework delivers simulation speed up to 60 times faster than the leading commercial software, while maintaining carrier-level accuracy in the experiments. This speedup becomes more pronounced as the number of semiconductor devices increases. This shows great potential for comprehensive analysis and collaborative optimization of devices and electronic power equipment, particularly in extreme conditions and failure scenarios.