论文信息 - Test Study and Numerical Simulation of Deflation Process of an Air-Supported Membrane Structure

Test Study and Numerical Simulation of Deflation Process of an Air-Supported Membrane Structure

Assessment of the deflation behavior and duration of an air-supported membrane structure is of great importance for making the plan of safety evacuation in the emergence situations but has received few studies. To gain insight into the deflation behavior and duration, field deflation tests of a real air-supported structure were performed, whereby the relationship between the inner air pressure and the duration was determined. Based on the nonlinear finite element (FE) method and the Nozzle theory defining the relationship between air loss and the dimensions of entrances, holes and seams, a simple numerical method is proposed to simulate the deflation process and predict the deflation duration. Factors affecting deflation duration like leakage area and uniform load on membrane surface are given detailed analyses. Through the comparison between the test data and the simulation results, the equivalent leakage area and the uniformly distributed load of the membrane surface are determined to facilitate the assessment of the deflation behavior and duration of the real structure. The method can efficiently analyze the deflation process and predict the deflation duration easily, and the present study is valuable in making plans for dealing with occupants' emergency evacuation and controlled deflations.

Jinghai Gong | Qiang Qing | Jinghai Gong | Qiang Qing

[1] T. Deyle. Inflatable Membrane Solar Concentration Systems for Space-Based Applications , 2007 .

[2] Qingshan Yang,et al. Numerical Simulation of behaviors of air-inflated cushion under wind excitation based on fluid-structure interaction , 2006 .

[3] Jakob A Hopping. Development of rapidly deployable structures for military applications : a system based approach to command post facilities , 2006 .

[4] Larry Bell. Pneumatic Membrane Structures for Space and Terrestrial Applications , 2008 .

[5] Jincheng Zhao,et al. Theoretical analysis and experimental study of an air inflated membrane structure , 2010 .

[6] Donald J. Nefske,et al. A New CAL3D Airbag Inflation Model , 1988 .

[7] Amit Patil,et al. Finite inflation of an initially stretched hyperelastic circular membrane , 2013 .

[8] Yoshihito Saito,et al. Design and construction of a double membrane air-supported structure , 1999 .

[9] Richard L. P. Custer. Test burn and failure mode analysis of an air-supported structure , 1972 .

[10] G. Marckmann,et al. Inflation of elastomeric circular membranes using network constitutive equations , 2003 .

[11] R. D. Wood,et al. Finite element analysis of air supported membrane structures , 2000 .

[12] Li Lian. Review of the Design and Computation of Membrane Structures , 2003 .