The world is currently grappling with a major crisis related to excessive carbon emissions, mainly caused by fossil fuel energy use. This situation highlights the urgent need to develop and implement alternative technologies. Renewable energy generation and energy storage equipment play a vital role in solving this problem. In the current context, aluminum-sulfur batteries have emerged as a promising electrochemical energy storage technology due to their high energy density, safety properties, and cost-effectiveness. These batteries can achieve large capacities by utilizing aluminum as the anode and sulfur as the cathode, two economically viable and readily available elements. The theoretical capacity of aluminum is 2982 mAh/g, while that of sulfur is 1675 mAh/g. However, the unclear phase transition of elemental sulfur during charge-discharge cycles poses challenges, resulting in insufficient cycle stability. This study aims to develop an in-situ X-ray diffraction analysis platform to enhance our understanding of the phase transition mechanisms that occur in aluminum-sulfur batteries. Initially, sulfur-carbon cathode materials were synthesized using a melt diffusion method with sulfur contents varying from 18 to 77 wt.%. The cathode material is then applied as a coating to the metal current collector, including beryllium, nickel, and aluminum. In situ analysis during charge-discharge cycles contributes to a comprehensive understanding of electrochemical stability and related phenomena. Research shows that beryllium metal corrodes when it undergoes charge and discharge cycles, resulting in perforations. Metallic nickel exhibits a weakened X-ray diffraction signal due to its significant X-ray absorption, thus limiting its applicability in analytical studies. In comparison, aluminum is a very promising candidate as a metallic current collector material due to its electrochemical stability and low X-ray absorptivity. Furthermore, the internal resistance of batteries using aluminum current collectors was observed to be five times lower than that of batteries using nickel current collectors. Therefore, in the application of in-situ X-ray diffraction analysis, aluminum foil has the potential to become an electrochemically stable and cost-effective metal current collector material.