Bauhinia blackeana is often cultivated as a street tree and for horticultural landscaping, and its fruit is in the form of seed pods that burst explosively, also called pod-shatter, to transfer energy to the seeds for dispersal. According to field observations, the difference between the seed pods of B. blackeana and other leguminous plants is that the seed pods maintain the form of "inversion" after pod-shatter, and after a while, they transform into the form of "eversion," which means that the seed pods have two distinct helical shapes. However, no study in the literature has explored this phenomenon so far. To understand the underlying mechanics of the formation of two unique helical shapes of B. blackeana seed pods, we conducted a combined experimental and numerical study. We first measured the layered structure, mechanical properties, and shrinkage ratio of each layer of B. blackeana seed pods. We then created 4D-printed synthetic models that mimic the actual seed pod’s mechanical structure and properties, reproducing the two distinct helical shapes and providing insights into the formation mechanism. Past studies on plant shape transformation used hydrogel or silicone to make synthetic models by filling a mold. However, the filling process requires additional molds and is complicated and time-consuming. In this study, synthetic models were made by 4D printing. 4D printing is an extension of 3D printing technology. Smart materials are added to 3D printing so the model can be deformed again after being stimulated by heat. Therefore, 4D printing can save significant time by manufacturing simple structures and deforming them into complex ones. In addition, the concept of deformation after being stimulated by the environment is similar to the principle of seed pods shape transformation; it is suitable for shape simulation by 4D printing. A fused deposition modeling (FDM) 3D printer was used with PLA and a shape memory filament SMP55 to make a 4D printing model, and experiments were carried out for different printing parameters to observe the effect of the printing parameters on the deformation of the model. Finally, the analysis results of the seed pods correspond to the printing parameters to make a synthetic model to verify the deformation mechanism of the seed pods of B. blackeana. Our experimental results show that the seed pods of B. blackeana are composed of four layers of cells: fiber cells, sclerenchyma cells, parenchyma cells, and exocarp sclerenchyma cells. The arrangement and shrinkage directions of the tissues are perpendicular to each other. Furthermore, the analogy through 4D printing successfully simulates the two helical shapes of B. blackeana seed pods and confirms the corresponding mechanism of these two helical shapes: the "inversion" is a complete four-layer structure, and its helical direction is dominated by the shrinkage of fiber cells. Because the separation of parenchyma cells and sclerenchyma cells allows sclerenchyma cells to shrink, and the main shrinkage direction of sclerenchyma cells is perpendicular to the fiber cells, the seed pods form "eversion" with opposite helical directions. At this time, the "eversion" is dominated by sclerenchyma cells. In addition, this study investigated the energy conversion of B. blackeana seed pods pod-shatter, and the energy conversion efficiency ranged from 4.81% to 58.42%. Although the conversion efficiency varies widely, it is still a more efficient way of seed dispersal than other plant species that utilize a similar mechanism. Moreover, we also demonstrate that the pod-shatter process of the 4D-printed models can occur and be complete within a short time, similar to actual seed pods in the field.