Portable proton exchange membrane fuel cells (PEMFCs) have received considerable attention recently because of the suitable material of the development of 3C production processes and green energy techniques. For the key component of portable PEMFCs, bipolar plates, metals such as stainless steel are becoming popular because of their excellent mechanical, electrical, and thermal properties, as well as a low degree of thickness (0.1–0.5 mm). However, current forming techniques cannot efficiently fabricate micro-flow-channels with a high aspect ratio on thin metallic blanks to satisfy the practical demands on portable fuel cells. This study presents the development of a high-pressure hydroforming technique and explains the design and construction of an experimental high-pressure hydroforming apparatus. The apparatus is composed of a two-stage pressure-increase structure to provide high fluid pressure, a high-pressure container and high-pressure seals to maintain and seal the high fluid pressure. Conclusively, this research develops a complete high-pressure hydroforming technique and be applied in forming metallic bipolar plates for portable PEMFCs. The results of our investigation indicate that the process control for the developed apparatus and the repeatability for hydroformed specimens are reasonably acceptable. The aspect ratio of micro-flow channels formed using this apparatus can achieve 0.392 when a working pressure of 250 MPa is applied. Compared with the maximum channel aspect ratio of 0.31 formed using the traditional hydroforming process, the channel aspect ratio formed using the new technique and device is 26.5% higher. Furthermore, finite element and optimization analyses can be performed to boost the forming capability of the developed technique. Consequently, the aspect ratio of formed micro-flow channels can be further increased by 4.8%.