Please use this identifier to cite or link to this item: http://hdl.handle.net/11455/89246
DC FieldValueLanguage
dc.contributor盧崑宗zh_TW
dc.contributor.authorJing-Ping Changen_US
dc.contributor.author張靚萍zh_TW
dc.contributor.other森林學系所zh_TW
dc.date2015zh_TW
dc.date.accessioned2015-12-07T07:00:43Z-
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dc.identifier.urihttp://hdl.handle.net/11455/89246-
dc.description.abstract以亞麻仁油(Linseed oil, LO)與甘油(Glycerol, GL)莫耳比1.0行酯交換反應,獲得具羥基之亞麻仁油甘油酯(Linseed oil glyceride, LOG)。接著將二羥甲基丙酸(Dimethylolpropionic acid, DMPA)分別與六亞甲基二異氰酸酯(Hexamethylene diisocyanate, HDI)及異佛爾酮二異氰酸酯(Isophorone diisocyanate, IPDI)進行反應再添加LOG,並依不同NCO/OH莫耳比(0.7、0.8及0.9)反應合成水性胺酯化油(Waterborne urethane oil, WUO)分散液,並添加金屬乾燥劑成為WUO塗料,探討異氰酸酯種類與NCO/OH莫耳比對於WUO塗料及塗膜性質之影響。結果顯示以異氰酸酯HDI合成之塗膜較軟韌,且其耐磨性、抗彎曲性、耐衝擊性及質量保留率之性質較佳,而以IPDI合成者塗膜較剛硬,具有較高之硬度與玻璃轉移溫度(Glass transition temperature, Tg),但抗彎曲性不佳。隨合成之NCO/OH莫耳比上升,塗膜之質量保留率、Tg與硬度均提高。再於WUO塗料中添加不同含量(0-4.0 phr)之含金屬離子之鄰苯二甲酸單羥乙氧基乙基酯[Mono(hydroxyethoxyethyl) phthalate, M(HEEP)2, M= Zn, Mn, Pb, Ca]抗微生物劑,及與市售奈米銀粉末製成抗微生物性塗料,探討各配方塗膜對於革蘭氏陰細菌之大腸桿菌(Escherichia coli)、革蘭氏陽細菌之金黃色葡萄球菌(Staphylococcus aureus)、褐腐菌之密黏褶菌(Gloeophyllum trabeum)與硫磺菌(Laetiporus sulphureus)及白腐菌之樺褶孔菌(Lenzites betulina)的抗微生物活性;試驗結果發現以HDI合成之WUO塗膜中,添加0.2 phr之Pb(HEEP)2抗微生物效果最佳,而以IPDI合成之塗膜,則以添加0.2 phr之Zn(HEEP)2具最佳之抗微生物效果,相較於市售奈米銀粉末之WUO塗膜,本研究所合成之Zn(HEEP)2、Pb(HEEP)2之抗微生物效果對真菌而言具有較佳之抗微生物活性,而對細菌之抗微生物效果則稍劣於市售奈米銀。抗微生物塗膜性質方面顯示,所有抗微生物塗膜之熱穩定性均優於未添加抗微生物者,其中又以HDI合成且添加Pb(HEEP)2者之Tg最高、但光澤度降低,而添加奈米銀者則塗膜不受影響,而以IPDI合成且添加Zn(HEEP)2及奈米銀者之硬度與Tg均降低。zh_TW
dc.description.abstractThe linseed oil glyceride (LOG) was synthesized using a transesterification process with glycerol (GL) and linseed oil (LO) at a molar ratio of 1.0 (GL/LO). The waterborne urethane oil (WUO) dispersion were prepared from LOG reacting with hexamethylene diisocyanate (HDI) and isophorone diisocyanate (IPDI) as well as dimethylolpropionic acid (DMPA) at various NCO/OH molar (0.7, 0.8 and 0.9), respectively. The WUO coatings were obtained by adding metal driers. The effects of isocyanates type and NCO/OH molar ratios on the WUO coatings and films were examined. The results showed that the properties of WUO films which synthesizing with HDI were soft and tough, while the superior abrasion resistance, bending resistance, impact resistance and mass retention were also obtained. In addition, the properties of films synthesizing with IPDI were rigid, and it possessed higher hardness and glass transition temperature (Tg), however the poor bending resistance was detected. With NCO/OH ratio increasing, the mass retention, Tg and hardness of WUO films increased. Furthmore, in this study the different types and various contents of mono(hydroxyethoxyethyl) phthalate [M(HEEP)2] antimicrobial agents, which the M were Zn, Mn, Pb and Ca, as well as the commercial nano silver powder were adding into WUO coatings as the antimicrobial coating. To compare the effects of the different antimicrobial agents and contents on antimicrobial activity of WUO films against gram negative of Escherichia coli, gram positive of Staphylococcus aureus, brown-rot fungi of Gloeophyllum trabeum and Laetiporus sulphureus as well as white-rot fungus of Lenzites betulina were also assessed. The results showed that the HDI films containing 0.2 phr Pb(HEEP)2 and IPDI films containg 0.2 phr Zn(HEEP)2 had superior antimicrobial activity. Comparing with commercial nano silver powder, the Zn(HEEP)2 and Pb(HEEP)2 had a better antimicrobial efficiency for fungi, while the antimicrobial activity for bacteria was less efficiency. The properties of antimicrobial WUO films showed that the thermal stability of all the antimicrobial film were improved. The films synthesizing with HDI and containing 0.2 phr Pb(HEEP)2 had higher Tg, but lower gloss. However it had no significant effects on adding nano silver powder into the films synthesizing with HDI. Both of hardness and Tg of the films synthesizing with IPDI and containing Zn(HEEP)2 and nano silver powder were decreased as compared with the WUO films without antimicrobial agents.en_US
dc.description.tableofcontents摘要 i Abstract iii 目次 v 表目次 vii 圖目次 xi 第一章 前言 1 第二章 文獻回顧 3 一、聚胺基甲酸酯塗料 3 二、水性PU塗料 5 (一)親水基導入 6 (二)WPU之製程 7 (三)水分散過程與機制 12 三、植物油開發為多元醇樹脂之應用與技術進展 13 四、抗微生物聚合物材料 16 五、金屬離子之抗微生物機制 18 第三章 水性胺酯化油塗料 19 一、材料與方法 19 (一) 試驗材料 19 (二) 以亞麻仁油為基質之WUO塗料製備 21 (三) 試驗方法 24 二、結果與討論 29 (一) 亞麻仁油甘油酯(LOG)之基本性質 29 (二) 預聚合體之基本性質 31 (三) 水分散時WUO離子體之性質變化 36 (四) 不同異氰酸酯與不同NCO/OH莫耳比合成之WUO分散液之基本性質 40 (五) 不同異氰酸酯與NCO/OH莫耳比所合成之WUO塗料與塗膜性質 45 第四章 抗微生物水性胺酯化油塗料 60 一、材料與方法 60 (一) 試驗材料 60 (二)試驗方法 62 二、結果與討論 64 (一) M(HEEP)2之合成與結構 64 (二) 添加M(HEEP)2之WUO塗膜抗微生物活性 70 (三) 抗微生物WUO塗膜之性質 79 第五章 結論 91 參考文獻 93zh_TW
dc.language.isozh_TWzh_TW
dc.rights同意授權瀏覽/列印電子全文服務,2018-08-14起公開。zh_TW
dc.subject亞麻仁油zh_TW
dc.subject六亞甲基二異氰酸酯zh_TW
dc.subject異佛爾酮二異氰酸酯zh_TW
dc.subject水性胺酯化油zh_TW
dc.subject金屬離子之鄰苯二甲酸單羥乙氧基乙基酯zh_TW
dc.subject抗微生物活性zh_TW
dc.subjectLinseed oilen_US
dc.subjectHexamethylene diisocyanateen_US
dc.subjectIsophorone diisocyanateen_US
dc.subjectWaterborne urethane oilen_US
dc.subjectMono(hydroxyethoxyethyl) phthalateen_US
dc.subjectAntibacterial activityen_US
dc.title以亞麻仁油為基質水性胺酯化油木材塗料之合成與抗微生物活性zh_TW
dc.titleSynthesis and antimicrobial activity of linseed oil-based waterborne urethane oil wood coatingsen_US
dc.typeThesis and Dissertationen_US
dc.date.paperformatopenaccess2018-08-14zh_TW
dc.date.openaccess2018-08-14-
item.openairecristypehttp://purl.org/coar/resource_type/c_18cf-
item.openairetypeThesis and Dissertation-
item.cerifentitytypePublications-
item.fulltextwith fulltext-
item.languageiso639-1zh_TW-
item.grantfulltextrestricted-
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