真空与低温
真空與低溫
진공여저온
Vacuum and Cryogenics
2015年
5期
260-264
,共5页
沈自才%牟永强%白羽%丁义刚%刘业楠%王志浩
瀋自纔%牟永彊%白羽%丁義剛%劉業楠%王誌浩
침자재%모영강%백우%정의강%류업남%왕지호
聚酰亚胺%力学性能%近紫外%远紫外
聚酰亞胺%力學性能%近紫外%遠紫外
취선아알%역학성능%근자외%원자외
Polyimide%Mechanical property%near ultraviolet%far ultraviolet
聚酰亚胺(PI)薄膜广泛用于航天器热控多层和大型展开结构中,但在空间紫外辐射环境下,其力学性能会发生退化。在近紫外和远紫外辐射环境下,对均苯型PI薄膜力学性能退化规律及退化机理进行研究。研究发现:在辐照初期,近紫外辐射和远紫外辐射均可造成均苯型PI薄膜抗拉强度和断裂伸长率下降,但远紫外辐射下降更加明显;随着曝辐量的增加,PI薄膜的抗拉强度和断裂伸长率均呈指数规律增长,而后趋于稳定,近紫外辐照后薄膜材料的力学性能优于远紫外辐照后薄膜材料的力学性能;断裂和交联是造成薄膜材料力学性能退化的主要原因,在紫外辐照初期以断裂为主,随着曝辐量的增加,以交联为主。
聚酰亞胺(PI)薄膜廣汎用于航天器熱控多層和大型展開結構中,但在空間紫外輻射環境下,其力學性能會髮生退化。在近紫外和遠紫外輻射環境下,對均苯型PI薄膜力學性能退化規律及退化機理進行研究。研究髮現:在輻照初期,近紫外輻射和遠紫外輻射均可造成均苯型PI薄膜抗拉彊度和斷裂伸長率下降,但遠紫外輻射下降更加明顯;隨著曝輻量的增加,PI薄膜的抗拉彊度和斷裂伸長率均呈指數規律增長,而後趨于穩定,近紫外輻照後薄膜材料的力學性能優于遠紫外輻照後薄膜材料的力學性能;斷裂和交聯是造成薄膜材料力學性能退化的主要原因,在紫外輻照初期以斷裂為主,隨著曝輻量的增加,以交聯為主。
취선아알(PI)박막엄범용우항천기열공다층화대형전개결구중,단재공간자외복사배경하,기역학성능회발생퇴화。재근자외화원자외복사배경하,대균분형PI박막역학성능퇴화규률급퇴화궤리진행연구。연구발현:재복조초기,근자외복사화원자외복사균가조성균분형PI박막항랍강도화단렬신장솔하강,단원자외복사하강경가명현;수착폭복량적증가,PI박막적항랍강도화단렬신장솔균정지수규률증장,이후추우은정,근자외복조후박막재료적역학성능우우원자외복조후박막재료적역학성능;단렬화교련시조성박막재료역학성능퇴화적주요원인,재자외복조초기이단렬위주,수착폭복량적증가,이교련위주。
Polyimide film was widely used in multilayered insulation and deployable structures of spacecraft,while their mechanical properties can be damaged by space ultraviolet irradiation. The mechanical property and mechanism of polyimide film in near ultraviolet and far ultraviolet radiation was studied and following results can be obtained:with the increasing of near ultraviolet or far ultraviolet irradiation,the rupture elongation and tensile strength of polyimide decrease firstly and then exponentially increase then tend to stable. In the early stage,the decrease of mechanical properties of poly-imide films in near ultraviolet is faster than in far ultraviolet irradiation. And the mechanical properties of polyimide films irradiated by long duration near ultraviolet are better than in far ultraviolet environment. The breakage and cross linkage of molecular bond is the major cause of change of polyimide’ s mechanical property in ultraviolet environments,and break-age is the major origin in early stage of irradiation and cross linkage is for the increase of mechanical property in subse-quent ultraviolet irradiation.
