[8]Hu D F, Liu C, Li Y B. Reliability analysis of toughened vacuum glass based on gray relation decision[J]. Mathematical Problems in Engineering, 2018, 2018: 1-10.
[9]趙驍真,胡東方,江春偉.全鋼化真空玻璃傳熱系數和傳熱指標的灰關(guān)聯(lián)分析[J].節能技術(shù),2021,39(03):221-224.
[10]Zhu Q, Wu W, Yang Y, et al. Finite element analysis of heat transfer performance of vacuum glazing with low-emittance coatings by using ANSYS[J]. Energy and Buildings. 2020, 206: 109584.
[11]化山����,徐志武����,王輝�����,等. 短波紅外線(xiàn)加熱封接技術(shù)在鋼化真空玻璃中的應用[J]. 玻璃. 2017, 44(09): 40-45.
[12]蘇行,胡東方.溫差作用下鋼化真空玻璃封接部位強度分析[J].建筑節能(中英文),2021,49(03):78-81.
[13]Fang Y, Hyde T, Eames P C, et al. Theoretical and experimental analysis of the vacuum pressure in a vacuum glazing after extreme thermal cycling[J]. Solar Energy. 2009, 83(9): 1723-1730.
[14]Memon S, Fang Y, Eames P C. The influence of low-temperature surface induction on evacuation, pump-out hole sealing and thermal performance of composite edge-sealed vacuum insulated glazing[J]. Renewable Energy. 2019, 135: 450-464
[15]Memon S, Eames P C. Design and development of lead-free glass-metallic vacuum materials for the construction and thermal performance of smart fusion edge-sealed vacuum glazing[J]. Energy and Buildings. 2020, 227: 110430.
