Core Viewpoint - EVE Hydrogen Energy Co., Ltd. has achieved a significant milestone by obtaining CE certification for its AEM modular hydrogen production system, marking it as the first Chinese company to receive this certification, which enhances its competitiveness in the international hydrogen energy market [4][11][14]. Group 1: CE Certification Achievement - The AEM modular hydrogen production system received CE certification from Bureau Veritas, confirming its compliance with EU standards, including the Machinery Directive 2006/42/EC and Low Voltage Directive 2014/35/EU [11][14]. - This certification signifies that the system's overall safety performance meets EU regulations and demonstrates advanced safety technology capabilities, allowing entry into the European market [11][14]. - The certification process included comprehensive assessments such as HAZOP/LOPA/SIL evaluations, validating the system's excellence in safety, environmental protection, and compliance [14]. Group 2: Technical Specifications and Innovations - The AEM modular hydrogen production system is a highly integrated "hydrogen factory," with a core module size of only 0.45×0.45×0.65m, capable of producing hydrogen at a rate of 1Nm³/h, which can be easily expanded to 20Nm³ [12]. - The system features a self-developed AEM membrane electrode with a low direct current consumption of 4.3 kWh/Nm³, achieving over 30% cost reduction [12]. - The system has rapid startup capabilities, reaching full load in 3 minutes for cold starts and responding in seconds for hot starts, making it adaptable to fluctuations in green electricity [12]. Group 3: Future Developments and Industry Impact - EVE Hydrogen Energy is conducting real-world tests on MW-level electrolyzers and aims to continue technological innovation while accelerating its global expansion [17]. - The company plans to collaborate with upstream and downstream enterprises to build a hydrogen energy industry ecosystem, promote the localization of key materials, and expand hydrogen energy application scenarios [17].

Core Viewpoint - The hydrogen energy industry in China is entering a critical stage characterized by technological innovation and international cooperation, as highlighted in the "China Hydrogen Development Report (2025)" released by the National Energy Administration [2][9]. Group 1: Technological Innovation - Hydrogen production technology is shifting from a dominance of "gray hydrogen" to breakthroughs in "green hydrogen," with renewable energy hydrogen production capacity exceeding 120,000 tons by the end of 2024 [3]. - A multi-modal storage and transportation system for hydrogen is being established, with significant advancements in high-pressure gas storage, liquid hydrogen systems, and solid-state hydrogen storage technologies [3][4]. - Application technologies are evolving, with innovations in industrial, transportation, and energy sectors, such as a 70% reduction in CO2 emissions in steel production and advancements in fuel cell technology for heavy-duty vehicles [4][5]. - The innovation ecosystem is being strengthened through national platforms and local practices, leading to breakthroughs in patents and the establishment of a closed-loop innovation system [5]. Group 2: International Cooperation - China is building a global green hydrogen supply chain through project collaborations along the "Belt and Road" initiative, including significant projects with France and Germany [6][7]. - Collaborative efforts are addressing common technological challenges, such as safety in liquid hydrogen transport and the development of hydrogen internal combustion engines [6][7]. - China has become the largest exporter of electrolyzers, capturing nearly half of the international market, and is transitioning from equipment export to a comprehensive service model [7]. Group 3: Addressing Challenges - The hydrogen energy industry must overcome barriers related to technology commercialization, resource collaboration, and policy-market coordination to support high-quality development [8]. - A "scene-driven" approach to technology development is recommended, focusing on industrial, transportation, and energy sectors to reduce application costs [8]. - The establishment of a "dual circulation" cooperation framework is essential, involving the introduction of international talent and the establishment of overseas research centers [8]. - Policy empowerment and market coordination mechanisms need to be improved, integrating hydrogen energy into the new energy system and optimizing project management policies [8].