Parameterized Design and Dynamic Analysis of a Reusable Launch Vehicle Landing System with Semi-Active Control

Reusable launch vehicles (RLVs) are a solution for effective and economic transportation in future aerospace exploration. However, RLVs are limited to being used under simple landing conditions (small landing velocity and angle) due to their poor adaptability and the high rocket acceleration of current landing systems. In this paper, an adaptive RLV landing system with semi-active control is proposed. The proposed landing system can adjust the damping forces of primary strut dampers through semi-actively controlled currents in accordance with practical landing conditions. A landing dynamic model of the proposed landing system is built. According to the dynamic model, an light and effective RLV landing system is parametrically designed based on the response surface methodology. Dynamic simulations validate the proposed landing system under landing conditions including the highest rocket acceleration and the greatest damper compressions. The simulation results show that the proposed landing system with semi-active control has better landing performance than current landing systems that use passive liquid or liquid–honeycomb dampers. Additionally, the flexibility and friction of the structure are discussed in the simulations. Compared to rigid models, flexible models decrease rocket acceleration by 51% and 54% at the touch down moments under these two landing conditions, respectively. The friction increases rocket acceleration by less than 1%. However, both flexibility and friction have little influence on the distance between the rocket and ground, or the compression strokes of the dampers.

[1]  Lauren Dreyer Latest developments on SpaceX's Falcon 1 and Falcon 9 launch vehicles and Dragon spacecraft , 2009, 2009 IEEE Aerospace conference.

[2]  Disha Saxena,et al.  Vibration Control of MR Damper Landing Gear , 2013 .

[3]  Mingyang Huang Control strategy of launch vehicle and lander with adaptive landing gear for sloped landing , 2019, Acta Astronautica.

[4]  E. Wagner,et al.  Opportunities for Suborbital Space and Atmospheric Research Facilities on Blue Origin's New Shepard Crew Capsule , 2016 .

[5]  Ming Zhang,et al.  Design and landing dynamic analysis of reusable landing leg for a near-space manned capsule , 2018 .

[6]  S. Engell,et al.  Approximately time-optimal fuzzy control of a two-tank system , 1994, IEEE Control Systems.

[7]  Ming Zhang,et al.  Dynamic analysis for vertical soft landing of reusable launch vehicle with landing strut flexibility , 2019 .

[8]  Richard Benney,et al.  INVESTIGATION OF THE APPLICATION OF AIRBAG TECHNOLOGY TO PROVIDE A SOFTLANDING CAPABILITY FOR MILITARY HEAVY AIRDROP , 2001 .

[9]  Heow Pueh Lee,et al.  The design and dynamic analysis of a lunar lander with semi-active control , 2019, Acta Astronautica.

[10]  H. R. van Nauta Lemke,et al.  Application of a fuzzy controller in a warm water plant , 1976, Autom..

[11]  Patrick Sgarlata,et al.  Operational lessons of the DC-X propulsion system operations , 1995 .

[12]  Weixiong Goh Preliminary Design of Reusable Lunar Lander Landing System , 2017 .

[13]  Soumitra Dutta,et al.  Fuzzy logic applications: Technological and strategic issues , 1993 .

[14]  J. Klevanski,et al.  CALLISTO - Reusable VTVL launcher first stage demonstrator , 2018 .

[15]  Ke Wu,et al.  Recent progress on development trend and key technologies of vertical take-off vertical landing reusable launch vehicle , 2016 .

[16]  Ming Zhang,et al.  Optimization and Performance Analysis of Oleo-Honeycomb Damper Used in Vertical Landing Reusable Launch Vehicle , 2018 .

[17]  B. Titurus,et al.  Liquid spring damper for vertical landing Reusable Launch Vehicle under impact conditions , 2019, Mechanical Systems and Signal Processing.

[18]  P.J. King,et al.  The application of fuzzy control systems to industrial processes , 1977, Autom..

[19]  J. Rabinow The magnetic fluid clutch , 1948, Electrical Engineering.