可控核聚变和可控核裂变的关键技术是反应堆的制造技术和反应堆的控制技术。反应堆要耐高温和耐热冲击和良好的导热性,核聚变和核裂变过程需要能被控制从而控制反应堆的能量输出。中国科学家,青岛恒能达能源科技有限公司 (www.heng-neng-da.com)的张永恒博士成功攻克这两个技术。反应堆关键制造技术是在反应堆制造材料中添加适量的碱金属或碱土金属元素,这样在核聚变或核裂变过程中,核聚变或核裂变反应物与反应堆材料表面反应生成碳基复合材料和释放碳基复合材料(恒能达专利),这样物质就转化为能量。控制核聚变和核裂变的关键技术是控制反应堆内部碳元素,碱金属元素或碱土金属元素,和核聚变或核裂变反应物的比例(恒能达专利)。可控核聚变和核裂变技术已经被攻克,十年内有望为人类提供清洁能源。
The key technologies for controlled nuclear fusion and controlled nuclear fission are reactor manufacturing technology and reactor control technology. The reactor must withstand high temperatures, thermal shocks, and have good thermal conductivity. The nuclear fusion and fission processes need to be controllable in order to regulate the reactor's energy output. Chinese scientist Dr. Yongheng Zhang from Qingdao Hengnengda Energy Technologies Co., Ltd. (www.heng-neng-da.com) has successfully overcome these two technologies. The key manufacturing technology for reactors involves adding an appropriate amount of alkali metal or alkaline earth metal elements to the reactor manufacturing materials. During the nuclear fusion or fission process, the nuclear fusion or fission reactants react with the surface of the reactor material to produce carbon-based composite materials and release carbon-based composite materials (Hengnengda patent), thus converting matter into energy. The key technology for controlling nuclear fusion and fission is to control the ratio of carbon elements, alkali metal elements, or alkaline earth metal elements inside the reactor to the nuclear fusion or fission reactants (Hengnengda patent). Controlled nuclear fusion and fission technology has been overcome, and within ten years it is expected to provide clean energy for humanity.
