The design of astonishing combinations of benzoxazine resins with various fillers is nowadays of great interest for high quality products,especially in ballistic armors.The objective of this study is to investigate a ...The design of astonishing combinations of benzoxazine resins with various fillers is nowadays of great interest for high quality products,especially in ballistic armors.The objective of this study is to investigate a new hybrid material prepared as multi-layered composite plate by hand lay-up technique.Different composites were manufactured from Kevlar fabrics reinforced polybenzoxazine,which was filled with silane treated microcrystalline cellulose(MCC Si)at various amounts in the interlayers.The developed materials were tested for their flexural,dynamic mechanical and ballistic performance.The aim was to highlight the effect of adding different amounts of MCC Si on the behavior of the different plates.Compared to the baseline,the dynamic mechanical and bending tests revealed an obvious decrease of the glass transition of 21℃and a notable increase in storage modulus and flexural strength of about 180%and17%,respectively,upon adding 1%MMC Si as filler.Similarly,the ballistic test exhibited an enhancement in kinetic energy absorption for which the composite supplemented with 1%MCC Si had the maximal energy absorption of 166.60 J.These results indicated that the developed panels,with interesting mechanical and ballistic features,are suitable to be employed as raw materials to produce body armor.展开更多
This work presents a strategy for the mesoscopic engineering of hierarchically structured sodium alginate(SA)aerogels to enhance the macroscopic performance.The strategy was implemented by meso-functionalizing and reo...This work presents a strategy for the mesoscopic engineering of hierarchically structured sodium alginate(SA)aerogels to enhance the macroscopic performance.The strategy was implemented by meso-functionalizing and reorganizing SA aerogels via controlled heterogeneous nucleation,in which microcrystalline cellulose-manganese dioxide(MCC-MnO_(2))nano-crystallites worked as template.Due to the short rod-like structure and abundant hydroxyl groups of MCC-MnO_(2),the organized mesostructure of SA aerogels was reconstructed during the assembly of SA molecule chains,which gave rise to a significant enhancement in macroscopic performance of SA areogels.For instance,the functionalized and reconstructed MCC-MnO_(2)/SA aerogels acquired a more than 70%increase in mechanical strength with an excellent deformation recovery.Furthermore,an almost double enhancement of removal capacity for metal ions(i.e.,Cu^(2+)and Pb^(2+))and organic dyes(i.e.,congo red and methylene blue)was obtained for MnO_(2)/SA aerogels,with an 87%repossession of the pollutants removal performance after 5 operation cycles.展开更多
文摘The design of astonishing combinations of benzoxazine resins with various fillers is nowadays of great interest for high quality products,especially in ballistic armors.The objective of this study is to investigate a new hybrid material prepared as multi-layered composite plate by hand lay-up technique.Different composites were manufactured from Kevlar fabrics reinforced polybenzoxazine,which was filled with silane treated microcrystalline cellulose(MCC Si)at various amounts in the interlayers.The developed materials were tested for their flexural,dynamic mechanical and ballistic performance.The aim was to highlight the effect of adding different amounts of MCC Si on the behavior of the different plates.Compared to the baseline,the dynamic mechanical and bending tests revealed an obvious decrease of the glass transition of 21℃and a notable increase in storage modulus and flexural strength of about 180%and17%,respectively,upon adding 1%MMC Si as filler.Similarly,the ballistic test exhibited an enhancement in kinetic energy absorption for which the composite supplemented with 1%MCC Si had the maximal energy absorption of 166.60 J.These results indicated that the developed panels,with interesting mechanical and ballistic features,are suitable to be employed as raw materials to produce body armor.
基金Project supported by the National Natural Science Foundation of China (Grant No. 12074322)Shenzhen Science and Technology Plan Project (Grant No. JCYJ20180504170208402)+1 种基金Science and Technology Project of Xiamen City (Grant No. 3502Z20183012)Science and Technology Planning Project of Guangdong Province,China (Grant No. 2018B030331001)
文摘This work presents a strategy for the mesoscopic engineering of hierarchically structured sodium alginate(SA)aerogels to enhance the macroscopic performance.The strategy was implemented by meso-functionalizing and reorganizing SA aerogels via controlled heterogeneous nucleation,in which microcrystalline cellulose-manganese dioxide(MCC-MnO_(2))nano-crystallites worked as template.Due to the short rod-like structure and abundant hydroxyl groups of MCC-MnO_(2),the organized mesostructure of SA aerogels was reconstructed during the assembly of SA molecule chains,which gave rise to a significant enhancement in macroscopic performance of SA areogels.For instance,the functionalized and reconstructed MCC-MnO_(2)/SA aerogels acquired a more than 70%increase in mechanical strength with an excellent deformation recovery.Furthermore,an almost double enhancement of removal capacity for metal ions(i.e.,Cu^(2+)and Pb^(2+))and organic dyes(i.e.,congo red and methylene blue)was obtained for MnO_(2)/SA aerogels,with an 87%repossession of the pollutants removal performance after 5 operation cycles.
