彭福军 - 哈尔滨工业大学（深圳） - 机电工程与自动化学院

个人简介

彭福军，教授，博士生导师，德国洪堡学者，国家特聘专家，深圳市鹏程孔雀计划A类人才。长期从事空间飞行器机构、空间薄膜可展结构、智能结构与控制等方面的研究与技术开发工作。 1997年7月毕业于南京航空航天大学固体力学专业，获得博士学位。2000年3月至2006年1月先后任德国波鸿大学洪堡研究员和加拿大航天局客座研究员。2006年1月至2021年4月先后任上海宇航系统工程研究所研究员、学术带头人、科技委副主任、中国航天科技集团有限公司上海航天技术研究院副总研究师、空间结构与机构技术专业组组长、上海市空间飞行器机构重点实验室主任。承担国家和省部级科研项目20余项，在薄膜星载天线、薄膜太阳帆和离轨帆、全柔性薄膜太阳电池阵等方向取得多项突破性成果，部分成果已实现在轨飞行验证和工程应用。2021年5月，加入哈尔滨工业大学（深圳）机电工程与自动化学院。发表学术论文100余篇，申请专利40余项。教育经历 1992. 9 — 1997. 7，南京航空航天大学，飞行器工程系，固体力学专业，获博士学位 1988. 9 — 1992. 7，南京航空航天大学，飞行器工程系，飞机设计专业，获学士学位研究与工作经历 1997. 9 — 2000. 8 ，同济大学，土木工程防灾国家重点实验室，博士后，研究方向：高层建筑风振控制，柔性结构建模 2000. 9 — 2002. 1 ，德国波鸿大学，边界层风洞实验室，洪堡研究员，研究方向：高层建筑风振响应主动控制，柔性结构建模 2002. 4 — 2006. 1，加拿大航天局，国家实验室客座研究员，研究方向：薄膜航天器形状控制，智能结构，形状记忆合金驱动控制 2006. 1 — 2012.7，中国航天科技集团公司上海宇航系统工程研究所研究员，大型薄膜空间结构技术方向带头人 2012.7 — 2014.2，中国航天科技集团公司上海宇航系统工程研究所研究员，新技术研究室主任 2013.12—2018.12，中国航天科技集团公司上海航天技术研究院，空间结构与机构领域副总研究师 2014.2—2021.4，中国航天科技集团公司上海航天技术研究院，上海宇航系统工程研究所研究员，科技委副主任 2015.6—2021.4，上海市空间飞行器机构重点实验室主任 2018.7—2021.4，中国航天科技集团公司上海航天技术研究院，空间结构与机构技术专业组组长，上海宇航系统工程研究所飞行器机构专业组组长、动力学仿真与控制专业组组长 2021.5 — 至今，哈尔滨工业大学（深圳），机电工程与自动化学院，教授专业资质与学术兼职复旦大学兼职教授同济大学兼职教授南京航空航天大学兼职教授中国宇航学会空间太阳能电站专业委员会副主任委员上海设计法研究会副理事长中国机械工程学会空间机构分会常委科工局空间太阳能电站论证组专家科技部国家重点研发计划评审专家教育部长江学者计划评审专家留学基金委评审专家

研究领域

空间可展结构空间柔性机器人智能结构与控制折纸结构机械系统动力学与控制

近期论文

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2002.12.01, JOURNAL OF WIND ENGINEERING AND INDUSTRIAL AERODYNAMICS, ”An experimental study of active control of wind-induced vibration of super-tall buildings “ ; 2004.04.01, JOURNAL OF ENGINEERING MECHANICS, “ Study on sinusoidal reference strategy-based adaptive feedforward control applied to benchmark wind-excited building” 2005.01.01, JOURNAL OF INTELLIGENT MATERIAL SYSTEMS AND STRUCTURES, “Development of GA-based control system for active shape control of inflatable space structures”; 2005.03.01, Journal of Intelligent Material Systems and Structures,”Actuator placement optimization and adaptive vibration control of plate smart structures”; 2005.07.09, IEEE ANTENNAS AND WIRELESS PROPAGATION LETTERS, “Space-Borne Deployable P-Band Dual-Circular-Polarization Flexible Antenna Array “ ; 2006.11.01, JOURNAL OF SPACECRAFT AND ROCKETS, “Testing of membrane. Space structure shape control using genetic algorithm”. 2007.03.01, WIND AND STRUCTURES, “Simulation study of SRS-based adaptive feedforward vibration control”; 2008.09.01, ACTAASTRONAUTICA”, Actuation precision control of SMA actuators used for shape control of inflatable SAR antenna”; 2009.01.01, IEEE TRANSACTIONS ON AEROSPACE AND ELECTRONIC SYSTEMS, “Application of SMA in Membrane Structure Shape Control”; 2014.08.18, APPLIED PHYSICS LETTERS, “Tailoring the wrinkle pattern of a microstructured membrane”; 2015.07.15, ADVANCES IN SPACE RESEARCH, “Trajectory classification in circular restricted three-body problem using support vector machine”; 2016.09.23, PHYSICS LETTERS A, “On natural frequencies of non-uniform beams modulated by finite periodic cells”; 2017.05.15, COMPOSITE STRUCTURES,”A study of flattening process of deployable composite thin-walled lenticular tubes under compression and tension”; 2017.09.01, POLYMER TESTING, “Epoxy shape memory polymer (SMP): Material preparation, uniaxial tensile tests and dynamic mechanical analysis”; 2017.12.01, POLYMER TESTING, “Uniaxial tensile tests and dynamic mechanical analysis of satin weave reinforced epoxy shape memory polymer composite”; 2017.12.11, Appllied Acoustics, “Extending and lowering band gaps by multilayered locally resonant phononic crystals”; 2018.02.01, JOURNAL OF MATERIALS SCIENCE, “Manufacturing and 3D printing of continuous carbon fiber prepreg filament”; 2018.02.01, ACTA MECHANICA SOLIDA SINICA, “Piezoelectric Actuator Placement Optimization and Active Vibration Control of a Membrane Structure”; 2018.03.01, JOURNAL OF THE FRANKLIN INSTITUTE-ENGINEERING AND APPLIED MATHEMATICS”, Vibration control of a membrane antenna structure using cable actuators”, 2018.03.26, Nonlinear dynamics, “Active control of large-amplitude vibration of a membrane structure”, 2018.06.19, Polymer, “Formulation and numerical implementation of tensile shape memory process of shape memory polymers”, 2018.08.01, POLYMER TESTING, “Experimental determination of mechanical properties of a single-ply broken twill 1/3 weave reinforced shape memory polymer composite”; 2018.09.01, JOURNAL OF VIBRATION AND CONTROL, “Dynamic model and active vibration control of a membrane antenna structure”; 2018.09.01, MECCANICA, “Wave based active vibration control of a membrane antenna structure”, 2019.02.15, COMPOSITES PART B-ENGINEERING, “Effect of temperature on the mechanical behaviours of a single-ply weave-reinforced shape memory polymer composite “, 2019.07.01, ACTA ASTRONAUTICA, “Research into topology optimization and the FDM method for a space cracked membrane”, 2019.07.01, PROCEEDINGS OF THE INSTITUTION OF MECHANICAL ENGINEERS PART G-JOURNAL OF AEROSPACE ENGINEERING, “Nonlinear vibration control of a membrane antenna structure”, 2019.07.01, Mechanics of Time-Dependent Materials”, Stress relaxation properties of an epoxy-based shape-memory polymer considering temperature influence: experimental investigation and constitutive modeling”, 2019.09.01, JOURNAL OF AEROSPACE ENGINEERING, “Composite Carbon–Epoxy Tubes for Space Structures: Ground Vacuum Radiant Experiments and Structural Behavior Analysis”,; 2019.12.01, Aerospace Systems, “Modal equivalent method of full-area membrane and grid membrane”, 2019.12.05, Composite Structures, “A multi-scale method for predicting ABD stiffness matrix of single-ply weave-reinforced composite”; 2019.8.9,Fibers and Polymers, “Crashworthiness of Thermoplastic Woven Glass Fabric Reinforced Composite Tubes Manufactured by Pultrusion”， 2020.6.12,Polymer Testing,” Experimental methodology for bubble content measurement of thin films”， 2020.2.26,Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, “Microstructure modification and corrosion improvement of AISI1045 steel induced by pseudospark electron beam treatment”， 2019.11.21, Journal of Physics and Chemistry of Solids, “ Improving sound insulation in low frequencies by multiple band-gaps in plate-type acoustic metamaterials”，