The Developing Present and Prospect of High Energy Density Metallic Combustion

Simin Zhu; Kaiqiang He

doi:10.54097/aedmhs26

Authors

Simin Zhu
Kaiqiang He

DOI:

https://doi.org/10.54097/aedmhs26

Keywords:

Metallic combustion, Combustion energy, Energy containing materials, Aluminium based materials, Boron based materials

Abstract

In this paper, we reviewed the developing present and future of high energy density metallic combustion. The review is mainly focused on the aluminium based alloys, born based alloys, hydrogen storage alloys three aspects. We discussed the present and developing trend of kinds of materials.

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References

[1] Liu Xin, Liu Peijin, Guan Yu, Jin Bingning, Yang Tianhao. Experimental Research Methods for the Combustion of Aluminum in Composite Propellants. Journal of Solid Rocket Technology, 2015, 38(6): 833-836.

[2] Gao Ming, Guo Xiaoyan, Zou Meishuai, Yang Rongjie. Combustion Performance of Magnesium/Aluminum Alloy Water-reactive Metal Fuel Propellants. Chinese Journal of Explosives & Propellants, 2015, 38(2): 75-79.

[3] Ren Xiaoxue. Analysis on the Development of Foreign Nano-thermite Technology. Technology & Materials, 2016, 5: 86-89.

[4] Andrey Bezmelnitsyn. Modified Nanoenergetic Composites with Tunable Combustion Characteristics for Propellant Applications. Propellants, Explosives, Pyrotechnics, 2010(10).

[5] Srinivas G, Clapsaddle B J, Bolskar R D. Modified Nanocomposite Thermite Formulations. 40th International Pyrotechnics Seminar, 2014.

[6] E Xiutianfeng, Peng Hao, Zou Jijun, Zhang Xiangwen, Wang Li. Research on High-density Suspension Fuels Containing Nano-aluminum Particles. Journal of Propulsion Technology, 2016, 37(5): 974-978.

[7] Li Meng, Zhao Fengqi, Luo Yang, Xu Siyu, Hao Haixia, Pei Qing, Yao Ergang. Influence of Nano-aluminum Powder and Micron-aluminum Powder on the Energy Characteristics of Composite Propellants. Rare Metal Materials and Engineering, 2015, 44(12): 3060-3064.

[8] Song Guixian, Wu Xionggang. Application Research of Nickel-aluminum Composite Powder in Modified Double-base Propellants. Chemical Propellants & Polymeric Materials, 2016, 14(4): 77-79.

[9] Liu Jingru, Luo Yunjun. Preparation and Properties of Aluminum-based Composites for Solid Propellants. Journal of Solid Rocket Technology, 2010, 33(5): 595-598.

[10] Yin Qiushi, Deng Guodong, Xiao Lei, Zhou Shuai, Lu Leiming, Yu Liuhua. Preparation and Activity of Flake Aluminum Powder. Explosive Materials, 2016, 45(4): 30-34.

[11] Yu Yongzhi, Xiang Shenghai, Li Shipeng, Yu Chao, Li Shuai, Yuan Jianfei. Research on the Influence of Aluminum Powder Content on the Thrust of Rocket Engines. Journal of Ordnance Equipment Engineering, 2016, 37(3): 35-38.

[12] Yang Weijuan, Chen Chao, Zhou Zhijun, Zhang Tianyou, Liu Jianzhong, Zhou Junhu. Research Progress on the Utilization of Aluminum as an Energy Carrier. Energy Engineering, 2014, 6: 7-15.

[13] Yang Dali, Xia Zhixun, Hu Jianxin, Huang Liya, Xiao Yunlei. Experimental Study on the Combustion Characteristics of a Single Droplet of Boron-containing Alcohol. Journal of Propulsion Technology, 2016, 37(11): 2187-2192.

[14] Pei Huixia, E Xiutianfeng, Zhang Lei, Zou Jijun, Zhang Xiangwen. Research on High-density Liquid Hydrocarbon Fuels with Added High-energy Nano-boron Particles. Modern Chemical Industry, 2017, 37(1): 111-114.

[15] Chen Binghong, Liu Jianzhong, Liang Daolun, Li Heping, Zhou Junhu. Influence of Oxidant-coated Boron Particles on the Ignition and Combustion Characteristics of Boron-based Propellants. Chinese Journal of Energetic Materials, 2016, 24(8): 774-780.

[16] Chen Binghong, Liu Jianzhong, Liang Daolun, Zhou Yunan, Zhou Junhu. Research Progress on the Coating Mechanism and Process of Boron Particles. Chinese Journal of Explosives & Propellants, 2016, 39(5): 13-21.

[17] Pang Weiqiang, Zhang Jiaoqiang, Zhang Qiongfang. Analysis of the Coating of Boron Powder and the Composition of Combustion Residues of Propellants Containing Coated Boron. Journal of Solid Rocket Technology, 2006, 29(3): 48-52.

[18] Zhang Jiaoqiang, Pang Weiqiang, Zhang Qiongfang, Su Lihong, Yan Hongxia, Kou Kaichang, Guo Ying. Improved Method for AP-coated Ultrafine Boron Powder. Energetic Materials, 2007, 15(4): 382-386.

[19] Hao Lifeng, Zhang Li, Tang Shimin, Lu Guoqiang, Sun Qingfeng, Zhang Xin. Technical Status and Development Trend of Boron-rich Fuel Propellants. Chemical Propellants & Polymeric Materials, 2015, 13(3): 1-8.

[20] Ma Yi. Analysis on the Application of Hydrogen Storage Materials in High-energy Solid Rocket Propellants. New Materials and New Technologies, 2016, 42(2): 52-52.

[21] Pei Jiangfeng, Zhao Fengqi, Jiao Jianshe, Li Meng, Xu Siyu, Chen Junbo. Energy Characteristics of p(BAMO-AMMO)-based Propellants Containing Metal Hydrides. Explosive Materials, 2014, 43(4): 11-15.

[22] Liu Ting, Chen Xin, Han Aijun, Ye Mingquan, Shi Qingyi, Pan Gongpe. Coatings of Activated Metal Hydride and Application in the Fuel-rich Propellant. Chinese Journal of Energetic Material, 2016, 24(9): 868-873.

[23] Lu Tongjie, Chen Kehai, Wei Wei, Jin Feng. Influence of Metal Hydrides on the Performance of Hybrid Propellants. Chemical Propellants & Polymeric Materials, 2016, 14(6): 12-17.

[24] Chen Xi, Zou Jianxin, Zeng Xiaoqin, Ding Wenjiang. Application of Magnesium-based Hydrogen Storage Materials in Energetic Materials. Chinese Journal of Explosives & Propellants, 2016, 39(3): 1-8.

[25] Yang Yanjing, Zhao Fengqi, Yi Jianhua, Luo Yang. Research Progress on the Application of Nano-hydrogen Storage Materials in Propellants. Energetic Materials, 2016, 24(2): 194-201.

[26] Dou Yanmeng, Li Guoping, Luo Yunjun, Ge Zhen, Yi Jianhua, Zhao Fengqi, Hydrogen Storage Alloys/AP.