以牌号为HGS8000X的空心玻璃微珠为填充材料,以环氧树脂为基体,采用真空辅助模压成型法制备了空心玻璃微珠体积添加量为65%-70%的复合泡沫材料.研究了空心玻璃微珠的体积分数对材料的密度、压缩强度、吸水率以及耐静水压性能的影响.结果表明,当空心玻璃微珠体积分数为67%-69%时,材料综合性能性能最佳,可以保持50 MPa、24 h的吸水率小于1%和压缩强度大于80 MPa的情况下使材料的密度由0.65 g/cm3降低到0.60 g/cm3.分析指出,高微珠含量的复合泡沫材料的性能更大程度上依赖于由于环氧树脂缺失而导致的材料的显微结构和空心玻璃微珠受力状态的改变.
参考文献
| [1] | 华云龙;余同希 .多胞材料的力学行为[J].力学进展,1991,21(4):457-458. |
| [2] | N. GUPTA;KISHORE;E. WOLDESENBET;S. SANKARAN .Studies on compressive failure features in syntactic foam material[J].Journal of Materials Science,2001(18):4485-4491. |
| [3] | Gupta N.;Woldesenbet E.;Kishore. .Compressive fracture features of syntactic foams-microscopic examination[J].Journal of Materials Science,2002(15):3199-3209. |
| [4] | Kim HS.;Oh HH. .Manufacturing and impact behavior of syntactic foam[J].Journal of Applied Polymer Science,2000(8):1324-1328. |
| [5] | Gupta N;Woldesenbet E;Mensah P .Compression properties of syntactic foams:effect of cenosphere radius ratio and specimen aspect ratio[J].Compos Part A,2004,35A(1):103-111. |
| [6] | Bunn P;Mottram J T .Manufacture and compression properties of syntactic foams[J].COMPOSITES,1993,24(7):565-571. |
| [7] | Klempner D;Frisch K C.Handbook of Polymeric Foams and Foam Technology[M].New York:Hanser Publishers,1991 |
| [8] | 卢子兴,石上路,邹波,寇长河,张子龙,李鸿运.环氧树脂复合泡沫材料的压缩力学性能[J].复合材料学报,2005(04):17-22. |
| [9] | Gupta N;Woldesenbet E;Mensh P .Compression properties of syntactic foams:Effect of cenosphere radius ratio and specimen aspect ratio[J].COMPOSITES PART A-APPLIED SCIENCE AND MANUFACTURING,2004,35(1):103-111. |
| [10] | 马新蕾;戴金辉;周金磊.空心玻璃微珠对树脂基复合材料成形及性能的影响[J].材料科学,2013(3):30-34. |
| [11] | 吴则华,陈先,梁忠旭,周媛.室温固化型高强度固体浮力材料[J].高科技与产业化,2008(12):48-50. |
| [12] | 徐玉磊;戴金辉;吴平伟 等.模压成型环氧树脂基复合材料的制备及性能研究[J].材料科学,2014,4(2):36-42. |
上一张
下一张
上一张
下一张
计量
- 下载量()
- 访问量()
文章评分
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%