文 | 星辰新能 近日，星辰新能在内蒙蒙西地区集中开发的三座新型独立储能电站已全部顺利并网投运： 鄂尔多斯谷山梁 300MW/1200MWh独立储能电站、 乌兰察布察 右后旗 200MW/800MWh独立储能电站以及 乌兰察布星钒涛宇 250MW/1000MWh独立储能电站。 鄂尔多斯谷山梁300MW/1200MWh独立储能电站 这三座新型独立储能电站将布局在电网的关键节点，直接接受电网调度，能够发挥容量支撑、调频调压、黑启动等系统级功能，是保障电力安全供应和电 网稳定运行的"压舱石"和"调节器"！ 三座电站均采用了 "磷酸铁锂电池 + 全钒液流电池" 的混合架构 ，为项目全生命周期的安全运营与稳定收益构筑技术基石。结合星辰自主开发的AI大模型 进一步赋能电力交易，在交易策略层面，混合储能系统展现出独特的协同价值。通过智能算法对电价曲线和电网调度指令的预测，系统能够动态优化充放 电策略： 磷酸铁锂电池专注于秒级、分钟级的高频交易机会，全钒液流电池则聚焦小时级的峰谷套利。 在项目属地政府全力支持及内蒙古电力（集团）有限责任公司、内蒙古超高压供电分公司、乌兰察布供电分公司、乌兰察布电力工程公司的通力协助下， 从 ...

Core Viewpoint - The article discusses the announcement of the "2025 National Green Computing Power Facility List" by six government departments, highlighting the importance of promoting green and low-carbon development in computing power facilities [2][6]. Group 1: Announcement Details - The announcement was made on December 29, 2025, by the Ministry of Industry and Information Technology, National Development and Reform Commission, Ministry of Commerce, Financial Regulatory Bureau, State Administration of Government Affairs, and National Energy Administration [2][3]. - The list includes 60 computing power facility projects across various sectors, including industry, information communication, energy, internet, finance, and public institutions [2][6]. Group 2: Sector-Specific Facilities - In the energy sector, notable facilities include the State Power Investment Corporation Gui'an Data Center and the Southern Power Grid Green Smart Data Center [2][6]. - The information communication sector features multiple data centers from China Telecom and China Mobile, such as the Hangzhou Intelligent Computing Center and the Wenzhou Coastal Data Center [7][8]. - The list also includes facilities from the internet sector, such as the Karamay Carbon and Water Cooling Data Center and the Douyin-Zhonglian Green Big Data Industrial Base [9][10]. - Financial institutions are represented by data centers from the Bank of Communications and China People's Insurance Group [11][12]. - Public institutions have data centers listed, including the Beijing Urban Sub-center Administrative Office Area Data Center [12][13]. Group 3: Future Trends - The construction of green computing centers is becoming a core area at the intersection of technology and energy, with energy storage solutions being integral to this development [14]. - The upcoming 14th International Energy Storage Summit and Exhibition (ESIE 2026) will focus on how energy storage technology can ensure reliable power supply for computing centers and enhance energy efficiency [14][18].

Group 1 - The core viewpoint of the article highlights the significant advancements in sodium-ion battery technology, particularly by CATL, which plans to apply sodium batteries on a large scale across various sectors by 2026, marking a new trend of "sodium-lithium dual stars shining" [2] - CATL's sodium battery, launched in April 2025, is the world's first large-scale production sodium-ion battery, which effectively reduces reliance on lithium resources due to sodium's inherent safety and abundant availability [2] - The sodium battery product line includes two categories: sodium passenger vehicle power batteries and sodium 24V heavy truck start-stop integrated batteries, both capable of operating in extreme temperatures from -40°C to 70°C, redefining battery performance limits [2] Group 2 - Sodium-ion batteries are gaining attention as a new energy storage technology, with advantages such as high power, good low-temperature performance, high safety, and low cost, making them suitable for applications like hybrid vehicles, UPS, and frequency regulation storage [3] - The sodium battery industry is rapidly advancing, with over a hundred companies actively involved in building a complete industrial chain that covers key materials, manufacturing, and system integration, indicating significant development potential and market prospects [3] - The upcoming 14th International Energy Storage Summit and Exhibition, sponsored by CATL, will take place from March 31 to April 3, 2026, in Beijing, showcasing the growth of the energy storage industry [4]

Core Viewpoint - The seminar on innovative applications of new energy storage technologies aims to foster collaboration and innovation in the energy storage sector across the Beijing-Tianjin-Hebei region, addressing challenges and opportunities in energy transition [2]. Group 1: Seminar Overview - The seminar was supported by the Beijing Municipal Science and Technology Commission, the Zhongguancun Energy Storage Industry Technology Alliance, and the Hebei Provincial Science and Technology Department, focusing on building a platform for industry exchange [2]. - Over 120 experts and representatives from the energy storage industry participated in the seminar [4]. Group 2: Technological Innovations - The Chinese Academy of Sciences presented advancements in high-safety lithium battery technology, highlighting the need for improved safety measures in energy storage systems [6]. - Solid-state battery technology and sodium-ion batteries are being developed to address safety concerns, with water-based lithium batteries showing promise in terms of safety and cost-effectiveness [6]. Group 3: Regional Development and Challenges - The State Grid Hebei Electric Power Research Institute discussed the rapid development of the energy storage industry in Hebei, emphasizing the need for innovative business models and addressing challenges such as site approval and unclear profitability [9]. - The National Energy Investment Group shared insights on the operational practices of energy storage in Hebei, noting a total installed capacity of 9.5 million kilowatts and the importance of strategic site selection for energy storage projects [11]. Group 4: Industry Practices and Solutions - Various companies presented their solutions, including multi-source and multi-topology grid solutions, commercial energy storage practices, and the development of vanadium flow battery technology [14][15][24]. - The independent storage investment model was analyzed, highlighting the need for clear revenue sources and effective project management strategies [21]. Group 5: Future Trends and Market Opportunities - The energy storage market is expected to grow significantly due to increasing renewable energy installations and the rising demand for data center power [17]. - Companies are encouraged to define products based on specific scenarios and leverage AI technologies for better market positioning [17].

Core Viewpoint - Huawei Digital Energy has successfully completed the explosion-proof test for its LUNA2000-5015 series energy storage system, demonstrating its technical strength in safety protection and risk control in energy storage systems [2][5]. Group 1: Test Results and Standards - The UL 9540A standard is a key safety testing standard for evaluating thermal runaway and its propagation risks in battery energy storage systems, influencing the admission of energy storage projects globally [4]. - The explosion-proof test was conducted under extreme conditions, where the energy storage system's explosion vent effectively opened, allowing for rapid pressure release while maintaining the integrity of the box structure [5]. - The test results provide credible data support for subsequent large-scale combustion tests, establishing a foundation for standardized explosion-proof testing in the industry [5]. Group 2: Safety Design Layers - The energy storage system incorporates a multi-layered safety architecture, including: - First layer: Directed smoke exhaust design to reduce the risk of smoke accumulation within the box [8]. - Second layer: Active exhaust design to control gas concentration below 25% LFL in case of failure of the first layer [8]. - Third layer: Precise explosion venting design to mitigate risks during an explosion [8]. - Fourth layer: High-strength box design to ensure structural integrity during an explosion, safeguarding personnel [8]. Group 3: Future Directions - Huawei Digital Energy aims to continue enhancing safety compliance and reliability throughout the lifecycle of energy storage technologies, collaborating with industry partners to iterate on safety technologies and testing methods [5].

Core Viewpoint - The article commemorates the contributions of Wu Feng, a prominent scientist in the field of green secondary batteries and energy materials in China, highlighting his significant achievements and impact on the industry and education [2][4][10]. Group 1: Contributions to Energy Technology - Wu Feng was a key figure in the development of new secondary battery technologies, focusing on lithium-ion and nickel-hydrogen batteries, which were crucial for China's energy security and "dual carbon" strategy [2][5]. - He led the creation of China's first nickel-hydrogen battery pilot base and the first automated production line, marking a significant transition from laboratory research to large-scale production [7]. - Wu's innovative approaches included the development of lithium-containing hydrogen storage alloys and high-performance metal foam collectors, which were essential for enhancing battery capacity and manufacturing processes [5][7]. Group 2: Academic and Educational Impact - Wu Feng dedicated over 40 years to teaching and research, emphasizing the integration of theory and practice, and nurturing a generation of talents in the fields of new energy materials and electrochemistry [3][11]. - He was committed to mentoring students, having trained over 200 graduate students, many of whom have become leaders in the battery and energy materials sectors [11][15]. - His teaching philosophy focused on inspiring innovative thinking among young scholars, ensuring the continuity of knowledge and expertise in the industry [11][15]. Group 3: Recognition and Awards - Wu Feng received numerous prestigious awards, including the National Technology Invention Award and the International Lifetime Achievement Award from the International Automotive Lithium Battery Association, recognizing his contributions to battery technology [3][10][18]. - His work was instrumental in establishing a robust research framework for green secondary batteries in China, significantly advancing the country's position in the global energy technology landscape [9][10].

Core Viewpoint - The establishment of the first batch of national zero-carbon parks marks a significant shift from local exploration to a systematic national project aimed at achieving zero-carbon goals, with energy system transformation and high integration of renewable energy being central to this initiative [2][6]. Group 1: National Zero-Carbon Park Construction - The first batch of national zero-carbon parks includes 52 parks, with construction deadlines set for 2027 to 2030 [2]. - The distribution of parks varies by region, with some provinces like Chongqing, Zhejiang, and Tibet having one park, while others like Xinjiang and Jilin have three [2]. - The transition to zero-carbon parks emphasizes the need for energy system transformation and the integration of renewable energy, highlighting the critical role of energy storage as a regulatory resource [2][11]. Group 2: Policy Evolution - The development of low-carbon parks in China has evolved through several stages, including ecological parks, low-carbon parks, near-zero carbon parks, and now zero-carbon parks [3][4]. - The "13th Five-Year Plan" period saw the formal inclusion of carbon emission intensity in national assessments, while the "14th Five-Year Plan" marks the transition of zero-carbon park construction from pilot projects to a national strategy [6] [10]. Group 3: Key Tasks for Zero-Carbon Parks - Eight key tasks have been identified for the construction of zero-carbon parks, including energy structure transformation, energy efficiency improvement, industrial structure adjustment, resource recycling, infrastructure upgrades, technology innovation, energy and carbon management enhancement, and support for reform and innovation [7]. Group 4: Energy Storage Requirements - Various regions have set energy storage requirements for zero-carbon parks, with some provinces like Shanghai requiring a storage system configuration ratio of 15% to 30% [9]. - Other provinces, such as Jiangsu and Sichuan, have established specific metrics for new energy storage capacity relative to average daily electricity consumption [9][10]. Group 5: Green Electricity Supply and Storage Integration - The construction of zero-carbon parks necessitates a collaborative approach to carbon reduction, with a focus on increasing the use of clean energy through high proportions of non-fossil energy [11][13]. - Policies have been introduced to facilitate the direct supply of green electricity and the integration of source-network-load-storage systems, allowing for a more efficient energy consumption model [14][15]. Group 6: New Energy Storage Opportunities - The potential for new energy storage applications is significant, particularly in high-energy-consuming industries, with provinces like Shandong and Inner Mongolia showing high electricity consumption in these sectors [17][20]. - The integration of energy storage solutions is essential for ensuring the stability and flexibility of the energy system, enabling the effective consumption of renewable energy [23][27]. Group 7: Case Studies - Notable examples of zero-carbon parks include the Ordos Zero Carbon Industrial Park, which utilizes 80% of its energy from wind and solar sources, and the Beijing JinFeng Technology Park, which has achieved renewable energy "carbon neutrality" [24][25][26]. - These case studies illustrate the successful implementation of integrated energy systems that combine various renewable sources and storage technologies to achieve sustainability goals [24][25][26].

Core Viewpoint - The article highlights the successful grid connection of the first phase of the Binzhou Beihai Independent Shared Energy Storage Project, which features a capacity of 303.5MW and 602.3MWh, showcasing a multi-technology integration approach for large-scale energy storage [2]. Group 1 - The project utilizes three core technologies: lithium iron phosphate batteries, supercapacitors, and all-vanadium flow batteries, enabling it to handle instantaneous energy fluctuations and adapt to various energy application scenarios [2]. - The independent shared operation model maximizes the value of energy storage resources, facilitating flexible interaction with the grid and enhancing the region's capacity for renewable energy consumption [2]. - Upon operation, the project can store 600,000 kWh of electricity, sufficient to meet the daily electricity needs of 120,000 households [2]. Group 2 - The project serves as a replicable model for the development of the new energy storage industry in the city and province, aligning with the region's renewable energy consumption requirements [3]. - The project reflects the transformation of Binzhou's energy structure and aims to optimize the business environment to support the advancement of renewable energy projects, contributing to high-quality local economic and social development [3].

Core Viewpoint - The collaboration between沃太能源 and Eltodo a.s. aims to deploy a total of 320MWh battery energy storage systems in Czech Republic, marking a significant step towards enhancing the country's green energy infrastructure [2][3]. Group 1: Project Details - The project will be the largest independent energy storage project in the Czech Republic, contributing to the development of a green power system and supporting regional energy transition [3]. -沃太能源 will provide energy storage equipment and lifecycle services, customizing solutions based on project needs, including the deployment of 46 Aster 5000 liquid-cooled storage systems for the Chvaletice project and 18 for the Kladno project [5]. - The battery energy storage systems (BESS) will participate in grid frequency regulation and provide essential grid support services, stabilizing fluctuations from wind and solar power, thus enhancing the grid's capacity to integrate high proportions of renewable energy [5]. Group 2: Industry Events -沃太能源 has confirmed participation in the 14th International Energy Storage Summit and Exhibition (ESIE 2026), inviting stakeholders to join the global energy storage industry event [6]. - The event is scheduled to take place from March 31 to April 3, 2026, at the Beijing Capital International Exhibition Center [7].

Core Viewpoint - China Mobile has announced a centralized procurement project for lithium iron phosphate batteries for communication from 2026 to 2028, with a procurement scale of approximately 8.229 billion Ah (2.633 GWh) [2][4]. Group 1: Procurement Details - The number of winning bidders is set to be between 9 to 10, with share allocations varying based on the number of bidders. If 9 companies win, the shares will be 17.07%, 14.63%, 13.41%, 12.20%, 10.98%, 9.76%, 8.54%, 7.32%, and 6.09%. If 10 companies win, the shares will be 15.63%, 13.54%, 12.50%, 11.46%, 10.42%, 9.38%, 8.33%, 7.29%, 6.25%, and 5.20% [2][4][5]. - The highest bid limit is set based on the average market price of lithium iron phosphate and electrolyte as of the last pricing cycle before the bid submission deadline [5]. Group 2: Bidder Qualifications - Bidders must be legally established independent entities within the People's Republic of China and must be manufacturers, as agent bids and joint bids are not accepted [6][7]. - Bidders must provide a complete range of capacity specifications for the lithium iron phosphate battery products, with a sales performance of no less than 50 million RMB in the domestic market from July 1, 2022, to June 30, 2025 [6][7]. Group 3: Submission and Evaluation Process - Bids must be submitted electronically through China Mobile's procurement system, with a deadline set for February 9, 2026, at 10:00 AM [11]. - The evaluation of bids will include a qualification review, and any bids that do not pass this review will be rejected [10].