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研究生: 蔡承育
Cai, Cheng-Yu
論文名稱: 飛灰/兩性離子型複合水膠作為混凝土自養護劑的可行性研究
Feasibility study of fly ash/amphoteric hydrogel composite as a concrete self-curing agent
指導教授: 許貫中
Hsu, Kung-Chung
學位類別: 碩士
Master
系所名稱: 化學系
Department of Chemistry
論文出版年: 2020
畢業學年度: 108
語文別: 中文
論文頁數: 76
中文關鍵詞: 兩性離子型水膠合成飛灰砂漿混凝土抗壓強度内部濕度乾縮自體收縮
英文關鍵詞: synthetic, fly ash, compressive, dry shrinkage
DOI URL: http://doi.org/10.6345/NTNU202001116
論文種類: 學術論文
相關次數: 點閱:146下載:0
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  • 近年來,學者們提出使用吸水性材料作為自養護劑添加到混凝土中可以有效的改善混凝土的性質,因此本論文主要目的為製備一種飛灰/兩性離子型複合水膠(FA/PDA)作為混凝土的自養護劑,水膠使用丙烯醯胺(AM)、N,N-二甲基胺-3-β-羧基丙烯酸乙酯乙酸鈉鹽(DCA)和飛灰(FA)合成,合成後使用FT-IR光譜作結構鑑定和探討單體比例、起始劑劑量、交聯劑劑量、飛灰含量對於水膠在各種水溶液下吸水率的影響。
    將FA/PDA水膠加到水泥砂漿和混凝土中,作為自養護劑時,探討水膠添加量及水膠內飛灰比例的含量,對於水泥砂漿和混凝土抗壓強度、內部濕度、乾縮量和自體收縮量的影響。
    將FA/PDA水膠置於水溶液中,在吸水率在一開始會先快速的上升,然後趨於平穩後即達到飽和吸水率,實驗結果顯示,FA/PDA水膠,吸水率會隨AM比例、交聯劑劑量、起始劑劑量和飛灰含量增加而增加,當AM/DCA= 3 MBA= 0.3 mole%, APS= 0.5 mole%,FA = 15 wt%有最高的吸水率。
    FA/PDA水膠在去離子水中、0.1M NaCl(aq)、0.1MCaCl2(aq)、Pore solution和水泥漿濾液中的最高的吸水率分別為398.07g/g 、129.63 g/g、116.5 g/g、116.38g/g、73.44 g/g。
    將FA/PDA水膠加入水泥砂漿和混凝土中,抗壓強度隨著水膠量的添加而上升,當水膠劑量為0.2 wt%時有最高的強度,在添加不同種類的FA/PDA水膠發現,飛灰含量為15 wt%的FA/PDA水膠,對水泥砂漿和混凝土的抗壓強度和內部濕度增加、乾縮量和自體收縮量減少,有最好的提升效果。

    In recent years, scientists have proposed that the use of absorbent materials as self-curing agents added to concrete can effectively improve the properties of concrete. Therefore, the main purpose of this paper is to prepare a fly ash/amphoteric ionic composite hydrogel (FA/PDA) as a self-curing agent for concrete, The hydrogel is synthesized using acrylamide (AM), N,N-dimethylamine-3-β-carboxyethyl acrylate sodium salt (DCA) and fly ash (FA). After synthesis, FT-IR spectroscopy is used as structure identification and discussion on the influence of monomer ratio, initiator dosage, crosslinking agent dosage, and fly ash content on the water absorption of water glue in various aqueous solutions.
    Discuss the amount of hydrogel added and the proportion of fly ash in the hydrogel, and the impact on the compressive strength, internal humidity, shrinkage and autogenous shrinkage of cement mortar and concrete, when FA/PDA hydrogel is added to cement mortar and concrete.
    The experimental results show that when the FA/PDA hydrogel is placed in an aqueous solution, the water absorption rate will increase rapidly at the beginning, and then reach the saturated water absorption rate after it stabilizes. The water absorption rate of the FA/PDA hydrogel will vary with the AM ratio, cross-linking agent dosage, initiator dosage and fly ash content increase with the increase. When AM/DCA= 3 MBA= 0.3 mole%, APS= 0.5 mole%, FA = 15 wt%, the highest water absorption rate.
    The highest water absorption rates of FA/PDA hydrogel in deionized water, 0.1M NaCl(aq), 0.1M CaCl2(aq), pore solution and cement slurry filtrate are398.07g/g 、129.63 g/g、116.5 g/g、116.38g/g、73.44 g/g, respectively
    When FA/PDA hydrogel is added to cement mortar and concrete, the compressive strength increases with the addition of the amount of hydrogel. When the amount of hydrogel is 0.2 wt%, it has the highest strength. When adding different types of FA/PDA The hydrogel found that the fly ash content of the hydrogel is 15 wt%, which has the best effect on increasing the compressive strength and internal humidity of cement mortar and concrete, as well as reducing the amount of dry shrinkage and self-shrinkage.

    謝誌 ⅰ 摘要 ⅱ ABSTRACT ⅲ 目錄 ⅴ 表目錄 ⅸ 圖目錄 ⅹ 第一章緒論 1 1-1 前言 1 1-2 實驗目的 2 1-3研究內容 2 第二章 文獻回顧 3 2-1 水膠 3 2-2 水膠的吸水機制 5 2-3 影響水膠吸水率之因素 6 2-3-1 交聯密度 7 2-3-2 親水性官能基種類 7 2-3-3 水溶液之離子強度 7 2-3-4水溶液之pH值 8 2-3-5鹽水溶液的影響 8 2-4 飛灰之簡介 9 2-5 水泥 10 2-5-1 波特蘭水泥之組成 10 2-5-2 水泥之水化 11 2-6 混凝土養護之目的 12 2-6-1混凝土收縮之變形機制 12 2-6-2 混凝土之養護 12 2-7 水膠作為混凝土自養護劑 13 第三章 水膠的合成及實驗流程 15 3-1 實驗流程 15 3-2實驗藥品與實驗設備 16 3-2-1藥品清單 16 3-2-2 實驗儀器 18 3-3-1 DME之合成 19 3-3-2 DCA之合成 20 3-3-3 PDA之合成 21 3-3-4 FA/PDA水膠之合成 23 3-4 聚合物的結構分析與性質鑑定 24 3-4-1 紅外(IR)光譜分析 24 3-4-2 掃描式電子顯微鏡(SEM)之結構鑑定 24 3-4-3 水膠吸水率測量 24 3-4-4 水膠在鹽水溶液吸水率 24 3-4-5 水膠在水泥漿濾液吸水率 24 3-4-6 水膠在pore solution溶液吸水率 24 3-5水膠添加到水泥砂漿之性質分析 25 3-5-1 水泥砂漿試體拌製 25 3-5-2水泥砂漿試體內部濕度之測量 26 3-5-3水泥砂漿乾燥收縮之測量 26 3-5-4水泥砂漿自體收縮之測量 26 3-5-5水泥砂漿試體抗壓強度之測量 26 3-6水膠添加到混凝土之性質分析 27 3-6-1混凝土試體之拌製 27 3-6-2混凝土試體抗壓強度測試 28 3-6-3混凝土乾燥收縮之測量 28 3-6-4混凝土自體收縮之測量 28 第四章 結果與討論 29 4-1 水膠之結構鑑定 29 4-1-1 DME之結構鑑定 29 4-1-2 DCA之結構鑑定 30 4-1-3 PDA之結構鑑定 31 4-1-4 FA/PDA之結構鑑定 32 4-1-5 水膠之表面形態 33 4-2 反應條件對PDA水膠吸水率的影響 35 4-2-1 不同單體比對PDA水膠吸水率的影響 35 4-2-2 交聯劑劑量對PDA水膠吸水率的影響 39 4-2-2 起始劑量對PDA水膠吸水率的影響 42 4-3 飛灰添加量FA/PDA水膠吸水率的影響 46 4-3-1 PDA-FA水膠在去離子水中的吸水率 46 4-3-2 FA/PDA水膠在鹽水溶液的吸水率 48 4-3-3 FA/PDA水膠在pore solution溶液的吸水率 50 4-3-4 FA/PDA水膠在水泥漿濾液的吸水率 52 4-4 FA/PDA水膠對砂漿性質的影響 53 4-4-1 水膠添加量對砂漿抗壓強度的影響 53 4-4-2 FA/PDA水膠對砂漿抗壓強度的影響 55 4-4-3 FA/PDA水膠對砂漿內部濕度的影響 56 4-4-4 FA/PDA水膠對砂漿乾縮的影響 57 4-4-5 FA/PDA水膠對砂漿自體收縮的影響 58 4-5 水泥砂漿之SEM分析表面結構 59 4-6 FA/PDA水膠對混凝土性質的影響 62 4-6-1 水膠添加量對混凝土抗壓強度的影響 62 4-6-2 FA/PDA水膠對混凝土抗壓強度的影響 63 4-6-3 FA/PDA水膠對混凝土乾縮的影響 65 4-6-4 FA/PDA水膠對混凝土自體收縮的影響 66 第五章 結論 67 參考文獻 69

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