Salgenx, based in Madison, Wisconsin, USA, has announced the launch of a revolutionary 3000 kWh saltwater battery system that incorporates in-situ hydrogen production for sustainable and cost-effective power generation. This innovative technology not only offers substantial energy storage capabilities but also produces hydrogen as a byproduct during operation. The hydrogen can then be used to generate additional electricity through a microturbine, increasing the overall system's efficiency and versatility. By utilizing readily available materials like sodium chloride and zinc, Salgenx provides a sustainable alternative to traditional lithium-ion batteries, reducing costs and environmental impacts. The integration of a microturbine allows for the efficient conversion of the produced hydrogen into electrical power, further enhancing the system's capabilities. The system's design also includes heat recovery features, utilizing the heat produced during hydrogen combustion for various applications, such as powering adsorption chillers for air conditioning. Additionally, the system's ability to produce fresh water vapor from seawater and recycle it showcases its commitment to sustainability. Salgenx's saltwater battery system not only offers high energy storage capacity for grid-scale applications but also demonstrates a commitment to environmental responsibility through the use of biodegradable materials like cellulose membranes. The system's safety features, including the use of natural pressure to store hydrogen safely, make it suitable for a wide range of applications, from grid stabilization to remote power generation. Overall, Salgenx's innovative approach to energy storage with in-situ hydrogen production represents a significant advancement in the industry, combining efficiency, sustainability, and versatility in a single system. The company's dedication to advancing green technology and exploring cutting-edge renewable materials positions them as leaders in the pursuit of a cleaner, more sustainable energy future.