It is very difficult to know the exact boundaries of the variable domain for problems with small sample size,and the traditional convex set model is no longer applicable.In view of this,a novel reliability model was p...It is very difficult to know the exact boundaries of the variable domain for problems with small sample size,and the traditional convex set model is no longer applicable.In view of this,a novel reliability model was proposed on the basis of the fuzzy convex set(FCS)model.This new reliability model can account for different relations between the structural failure region and variable domain.Key computational algorithms were studied in detail.First,the optimization strategy for robust reliability is improved.Second,Monte Carlo algorithms(i.e.,uniform sampling method)for hyper-ellipsoidal convex sets were studied in detail,and errors in previous reports were corrected.Finally,the Gauss-Legendre integral algorithm was used for calculation of the integral reliability index.Three numerical examples are presented here to illustrate the rationality and feasibility of the proposed model and its corresponding algorithms.展开更多
In small-sample problems, determining and controlling the errors of ordinary rigid convex set models are difficult. Therefore, a new uncertainty model called the fuzzy convex set(FCS) model is built and investigated...In small-sample problems, determining and controlling the errors of ordinary rigid convex set models are difficult. Therefore, a new uncertainty model called the fuzzy convex set(FCS) model is built and investigated in detail. An approach was developed to analyze the fuzzy properties of the structural eigenvalues with FCS constraints. Through this method, the approximate possibility distribution of the structural eigenvalue can be obtained. Furthermore, based on the symmetric F-programming theory, the conditional maximum and minimum values for the structural eigenvalue are presented, which can serve as nonfuzzy quantitative indicators for fuzzy problems. A practical application is provided to demonstrate the practicability and effectiveness of the proposed methods.展开更多
The molecular dynamics(MD)simulations were used to understand the heat transfer process between the gas phase and the solid skeleton in the nanoporous silica aerogels.The amorphous silica nanoparticles were generated ...The molecular dynamics(MD)simulations were used to understand the heat transfer process between the gas phase and the solid skeleton in the nanoporous silica aerogels.The amorphous silica nanoparticles were generated by the MD simulations and the energy accommodation coefficient(EAC)between the gases and the nanoparticles was calculated based on the results of the nonequilibrium molecular dynamics(NEMD)simulations.The apparent thermal conductivity(ATC)of the gases between the heat source and heat sink was also obtained.The effects of the temperature,the particle diameter and the molecule type on the EAC and the ATC were investigated.The results indicate that the EAC decreases with the increase of temperature within the calculating range.When the preset temperature is constant,the EAC increases with the increasing of the particle diameter and eventually approaches a specific value.When the preset temperature is 300 K and the particle size is 4 nm,the obtained EAC for the N2 gas and the O2 gas is close to each other and both are less than that of the Ar gas.The results also indicate that the heat transferred through the gas-nanoparticle interface is far less than that through the neighbouring nanoparticles in silica aerogels.展开更多
基金funded by National Natural Science Foundation of China(No.51509254).
文摘It is very difficult to know the exact boundaries of the variable domain for problems with small sample size,and the traditional convex set model is no longer applicable.In view of this,a novel reliability model was proposed on the basis of the fuzzy convex set(FCS)model.This new reliability model can account for different relations between the structural failure region and variable domain.Key computational algorithms were studied in detail.First,the optimization strategy for robust reliability is improved.Second,Monte Carlo algorithms(i.e.,uniform sampling method)for hyper-ellipsoidal convex sets were studied in detail,and errors in previous reports were corrected.Finally,the Gauss-Legendre integral algorithm was used for calculation of the integral reliability index.Three numerical examples are presented here to illustrate the rationality and feasibility of the proposed model and its corresponding algorithms.
基金supported by the National Natural Science Foundation of China (Grant 51509254)
文摘In small-sample problems, determining and controlling the errors of ordinary rigid convex set models are difficult. Therefore, a new uncertainty model called the fuzzy convex set(FCS) model is built and investigated in detail. An approach was developed to analyze the fuzzy properties of the structural eigenvalues with FCS constraints. Through this method, the approximate possibility distribution of the structural eigenvalue can be obtained. Furthermore, based on the symmetric F-programming theory, the conditional maximum and minimum values for the structural eigenvalue are presented, which can serve as nonfuzzy quantitative indicators for fuzzy problems. A practical application is provided to demonstrate the practicability and effectiveness of the proposed methods.
文摘The molecular dynamics(MD)simulations were used to understand the heat transfer process between the gas phase and the solid skeleton in the nanoporous silica aerogels.The amorphous silica nanoparticles were generated by the MD simulations and the energy accommodation coefficient(EAC)between the gases and the nanoparticles was calculated based on the results of the nonequilibrium molecular dynamics(NEMD)simulations.The apparent thermal conductivity(ATC)of the gases between the heat source and heat sink was also obtained.The effects of the temperature,the particle diameter and the molecule type on the EAC and the ATC were investigated.The results indicate that the EAC decreases with the increase of temperature within the calculating range.When the preset temperature is constant,the EAC increases with the increasing of the particle diameter and eventually approaches a specific value.When the preset temperature is 300 K and the particle size is 4 nm,the obtained EAC for the N2 gas and the O2 gas is close to each other and both are less than that of the Ar gas.The results also indicate that the heat transferred through the gas-nanoparticle interface is far less than that through the neighbouring nanoparticles in silica aerogels.