一家深低温技术公司完成近5亿元融资，已获得核聚变等领域客户数亿元订单丨早起看早期

Core Viewpoint - Zhongke Qingneng has successfully completed nearly 500 million yuan in PreA++ financing, focusing on deep low-temperature technology and addressing critical technological challenges in various advanced fields [5][7]. Financing Information - Financing Round: PreA++ - Financing Amount: Nearly 500 million yuan - Investors: Led by Dinghui Baifu, with participation from Weilai Capital, Guoxin Fund, Kunpeng Capital, and several other notable investment institutions [7]. Company Overview - Established: June 2022 - Location: Gongyi City, Henan Province - Focus: Specializes in hydrogen liquefaction, helium liquefaction, and deep low-temperature sensing systems, providing core equipment and low-temperature technology services for fields like controllable nuclear fusion, hydrogen energy, aerospace, quantum computing, and civilian superconductivity [9][10]. Technological Highlights - Achievements: Developed a 3kW@4.5K helium refrigerator, the largest in China's nuclear fusion field, and delivered a 1 ton/day hydrogen liquefaction equipment, the first domestically produced for aerospace applications [10][11]. - Future Plans: A 5 tons/day hydrogen liquefaction plant is expected to be operational by September 2026, marking China's first commercial facility of its kind [10]. Market Size - Global deep cooling equipment market is projected to reach $25 billion by 2024, with China's low-temperature equipment market expected to grow to 52.98 billion yuan by 2025, maintaining a compound annual growth rate of 8%-9% [13]. Team Background - The core technology system is derived from years of research in low-temperature fields at Hefei Energy Institute. The CEO, Pan Weiwei, has extensive experience in research and management [15]. CEO Insights - The company focuses on deep low-temperature technology as a foundational infrastructure, essential for various advanced scientific fields, including quantum computing and medical accelerators [18][20]. - The demand for low-temperature systems is driven by the need for extreme conditions in scientific research and high-precision experiments, with over 95% of new large scientific installations requiring such systems [23].