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研究生: 王韡蒨
Wei-Chien Wang
論文名稱: 台灣地區活性粒料之檢測方法研究
Study of the test methods to identify the reactivity of aggregate in Taiwan
指導教授: 李釗
Chau Lee
口試委員:
學位類別: 碩士
Master
系所名稱: 工學院 - 土木工程學系
Department of Civil Engineering
畢業學年度: 91
語文別: 中文
論文頁數: 335
中文關鍵詞: 鹼質與粒料反應岩相分析活性粒料混凝土
外文關鍵詞: petrographic examination, reactive aggregate, concrete, alkali-aggregate reaction
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    • 邇來在興建重要工程之時,主辦單位相當重視在施工前對粒料活性進行檢測,以避免使用活性粒料造成混凝土在數年後發生鹼質與粒料反應。在研析世界各國相關規範後,發現理論基礎相似之試驗方法,在相關試驗變數上多作模糊說明或有不同之規定,且對活性粒料的判定標準亦有不同,顯示許多國家都已建立起適合當地的試驗規範與判定標準。國內專家學者曾對本島29條河川進行粒料活性調查,其中至少有11條河川產的粒料結論不一致,因此本研究的目的在以接受度較高的ASTM C1293為基礎,釐清各種不同試驗間包括ASTM C289、C1260、C227、中國及日本蒸壓法、其他新發展方法及岩相分析等方法之相關性,提出適合於台灣地區活性粒料檢測方法之建議,以供日後建立CNS規範參考,避免誤用活性粒料影響混凝土耐久性。研究成果包括四個主要部份:1.對現有規範運用於台灣地區活性粒料之檢測結果、試驗方法間之相關性比較、適合於台灣地區活性粒料之判別標準檢討;2.岩相分析運用於鹼質與粒料反應之檢測研究;3.發展準確、快速且適合台灣地區活性粒料之檢測方法及判定標準;4.提出適合於台灣地區活性粒料之檢測方法及運用流程之建議。

    Identification of aggregate reactivity is required in many concrete construction projects to reduce the possibility of inducing expansive alkali-aggregate reaction. However, many conflict results have obtained due to many parameters listed in the specifications are not clearly defined. Study of related specifications in the world, the test methods with the same philosophy contain different parameters and different accept level for non-reactive aggregate. The purposes of this research are to clearly establish a test method and accept level for identification of reactive aggregate in Taiwan. ASTM C1293, the concrete prism expansion test, will be the basis of this research. Different methods including ASTM C227, ASTM C1260, and improving methods are to be test. Tests including C289, C227, autoclave method, and petrographic examination of aggregates are used to compare the results of C1293 for defining the accept level for non-reactive aggregate. The results of this research will be the reference for establishment of CNS specification.

    目 錄 中文摘要 英文摘要 符號對照表 第一章 研究動機內容及目的-----------------------------------------------------1 1.1 研究動機------------------------------------------------------------------------------1 1.2 研究內容------------------------------------------------------------------------------3 1.3 研究目的------------------------------------------------------------------------------4 第二章 文獻回顧-----------------------------------------------------------------------5 2.1 鹼質與粒料反應種類及機理------------------------------------------------------5 2.1.1 鹼-氧化矽反應----------------------------------------------------------------5 2.1.1.1 矽石(silica)對鹼-氧化矽反應的影響-----------------------------6 2.1.1.2 鹼-氧化矽反應的形式-------------------------------------------------8 2.1.1.3 鹼-氧化矽反應機理---------------------------------------------------10 2.1.2 鹼-矽酸鹽反應--------------------------------------------------------------13 2.1.3 鹼-碳酸鹽反應--------------------------------------------------------------14 2.2 鹼質與粒料反應的徵狀----------------------------------------------------------16 2.2.1 外觀徵狀-----------------------------------------------------------------------16 2.2.1.1 純混凝土構造物---------------------------------------------------------16 2.2.1.2 鋼筋混凝土構造物------------------------------------------------------19 2.2.2 混凝土構造物內部徵狀-----------------------------------------------------19 2.2.2.1 反應圈---------------------------------------------------------------------21 2.3 鹼質與粒料反應的影響因素----------------------------------------------------21 2.3.1 混凝土中含有反應的活性粒料--------------------------------------------22 2.3.2 孔隙溶液中需含有足夠的氫氧化鹼濃度--------------------------------22 2.3.3 足夠的濕度--------------------------------------------------------------------24 2.3.4 其他影響鹼質與粒料反應的因素-----------------------------------------24 2.4 鑑定方法之類型與比較----------------------------------------------------------27 2.4.1 粒料活性試驗之條件--------------------------------------------------------27 2.4.2 各國試驗規範介紹-----------------------------------------------------------28 2.4.3 各國試驗規範比較-----------------------------------------------------------30 2.4.4 我國國家標準-----------------------------------------------------------------36 2.4.5 其他鑑定方法-----------------------------------------------------------------37 2.4.6 RILEM針對國際AAR研究調查報告--------------------------------------40 2.4.6.1 試驗方法調查報告------------------------------------------------------40 2.4.6.2 試驗程序調查報告------------------------------------------------------41 2.5 相關研究對慣用規範之適用性評估-------------------------------------------42 2.5.1 岩相法(ASTM C295)----------------------------------------------------42 2.5.2 化學法(ASTM C289)----------------------------------------------------42 2.5.3 砂漿棒法(ASTM C227)-------------------------------------------------43 2.5.4 混凝土角柱法(ASTM C1293與CSA A23.2-14A)-------------------44 2.5.5 快速砂漿棒法(ASTM C1260與CSA A23.2-25A)-------------------45 2.6 試驗方法間之比較研究----------------------------------------------------------47 2.6.1 加速砂漿棒法(AMBT)與混凝土角柱試驗法(CPT)比較------47 2.6.2 混凝土角柱試驗法(CPT)與加速混凝土角柱試驗法(ACPT) 比較-----------------------------------------------------------------------------51 2.6.3 快速砂漿棒法(AASHTO T303)與化學法(ASTM C289)比較--52 2.6.4 快速砂漿棒法(ASTM C1260)與傳統砂漿棒法(ASTM C227) 比較----------------------------------------------------------------------------53 2.7 台灣地區鹼質與粒料反應問題及研究現況----------------------------------55 2.8 台灣地區地質及岩石分佈-------------------------------------------------------61 2.9 國內生產砂石粒料種類調查----------------------------------------------------67 2.10 各國鹼質與粒料反應研究發展現況------------------------------------------69 2.10.1 中國鹼質與粒料反應研究-------------------------------------------------69 2.10.2 韓國鹼質與粒料反應研究-------------------------------------------------70 2.10.3 澳大利亞鹼質與粒料反應研究-------------------------------------------70 2.10.4 紐西蘭鹼質與粒料反應研究---------------------------------------------72 2.10.5 丹麥鹼質與粒料反應研究-------------------------------------------------72 2.10.6 挪威鹼質與粒料反應研究-------------------------------------------------73 2.10.6.1 試驗法-------------------------------------------------------------------73 2.10.6.2 挪威判斷粒料活性程序----------------------------------------------73 2.10.7 冰島鹼質與粒料反應研究------------------------------------------------73 2.10.8 法國鹼質與粒料反應研究-------------------------------------------------74 2.10.9 荷蘭鹼質與粒料反應研究-------------------------------------------------74 2.10.10 葡萄牙鹼質與粒料反應研究--------------------------------------------76 2.10.11 英國鹼質與粒料反應研究-----------------------------------------------76 2.10.12 加拿大鹼質與粒料反應研究--------------------------------------------76 2.10.12.1 粒料活性反應評估---------------------------------------------------77 2.10.12.2 實驗室研究------------------------------------------------------------77 2.10.13 美國鹼質與粒料反應研究-----------------------------------------------81 2.10.13.1 大西洋中部區域技術委員會---------------------------------------81 2.10.13.2 AASHTO ASR Lead State Team------------------------------------82 2.10.13.3 波特蘭水泥協會------------------------------------------------------85 2.10.13.4 奧斯丁德州大學之研究---------------------------------------------86 第三章 研發新的檢測技術之可行性探討----------------------------------------87 3.1 以岩相技術鑑識台灣東部地區安山岩之可行性探討----------------------87 3.1.1 安山岩的形成及礦物組成特性--------------------------------------------87 3.1.2 台灣主要安山岩之分佈與岩性--------------------------------------------88 3.1.3 台灣地區安山岩鹼質與粒料反應研究文獻摘要-----------------------89 3.1.3.1 安山岩具鹼質與粒料反應潛勢之礦物組成------------------------89 3.1.3.2 國內安山岩之鹼質與粒料反應相關研究---------------------------89 3.1.4 以岩相技術鑑識台灣東部地區安山岩之可行性-----------------------91 3.2 砂漿棒及混凝土角柱置於中國蒸壓法環境(CECS 48:93)以鑑 別粒料活性之可行性探討-------------------------------------------------------92 3.2.1 各國運用蒸壓方法評估鹼質與粒料反應問題研究與規範-----------92 3.2.1.1 中國之蒸壓方法研究與規範------------------------------------------92 3.2.1.2 日本之蒸壓方法研究與規範------------------------------------------93 3.2.1.3 法國之蒸壓方法研究與規範------------------------------------------94 3.2.1.4 加拿大之蒸壓方法研究------------------------------------------------94 3.2.2 影響蒸壓法試驗結果之因素探討-----------------------------------------95 3.2.3 砂漿棒及混凝土角柱置於中國蒸壓環境以鑑別粒料活性之 可行性------------------------------------------------------------------------101 3.3 混凝土角柱置於ASTM C1260環境以鑑別粒料活性之可行性探討----102 3.3.1 AAR之測長加速試驗法發展----------------------------------------------102 3.3.1.1 Chatterji法----------------------------------------------------------------102 3.3.1.2 ASTM C1260法---------------------------------------------------------103 3.3.1.3 混凝土角柱模擬ASTM C1260環境之研究-----------------------104 3.3.2 混凝土角柱置於ASTM C1260環境以鑑別粒料活性之可行性-----105 第四章 試驗規劃--------------------------------------------------------------------106 4.1 試驗計畫---------------------------------------------------------------------------106 4.1.1 粒料取樣---------------------------------------------------------------------106 4.1.2 試驗方法及試驗流程------------------------------------------------------107 4.2 試驗材料---------------------------------------------------------------------------112 4.3 試驗器材---------------------------------------------------------------------------113 4.4 試驗步驟---------------------------------------------------------------------------114 第五章 單一試驗結果--------------------------------------------------------------124 5.1 初期實驗---------------------------------------------------------------------------124 5.2 化學法------------------------------------------------------------------------------129 5.3 XRD結晶指數分析--------------------------------------------------------------133 5.4 岩相分析---------------------------------------------------------------------------139 5.4.1 XRD礦物成分分析----------------------------------------------------------139 5.4.2 偏光顯微鏡觀察-------------------------------------------------------------161 5.5 傳統測長試驗法------------------------------------------------------------------182 5.5.1 ASTM C227水泥砂漿棒試驗法-----------------------------------------182 5.5.2 ASTM C1293混凝土角柱試驗法----------------------------------------186 5.6 ASTM C1260快速水泥砂漿棒試驗法--------------------------------------188 5.7 蒸壓法------------------------------------------------------------------------------194 5.7.1 中國蒸壓法(CECS 48:93)--------------------------------------------------194 5.7.2 日本蒸壓法(JIS A1804)----------------------------------------------------195 5.8 新發展方法------------------------------------------------------------------------198 5.8.1 混凝土角柱模擬ASTM C1260環境試驗法(CP1260AT)------------198 5.8.2 水泥砂漿棒模擬中國蒸壓環境試驗法(MBAT)----------------------201 5.8.3 混凝土角柱模擬中國蒸壓環境試驗法(CPAT)----------------------201 第六章 現有規範鑑別台灣地區粒料活性之適用性--------------------------204 6.1 現有規範之試驗結果分析------------------------------------------------------204 6.2 現有規範試驗結果比較---------------------------------------------------------208 6.2.1 ASTM C289法與其他試驗方法之比較----------------------------------209 6.2.2 ASTM C1260法與其他試驗方法之比較--------------------------------219 6.2.2.1 兩種試驗相互比較----------------------------------------------------219 6.2.2.2 三種試驗彼此比較----------------------------------------------------230 6.2.3 ASTM C227法與其他試驗方法之比較----------------------------------234 6.2.4 ASTM C1293法與其他試驗方法之比較--------------------------------244 6.2.5 日本蒸壓法與其他試驗方法之比較-------------------------------------248 6.3 現有規範作為台灣地區活性粒料檢測方法探討---------------------------251 6.3.1 適用性探討-------------------------------------------------------------------251 6.3.2 判定標準檢討----------------------------------------------------------------255 第七章 以岩相分析技術鑑識台灣東部地區安山岩活性之差異性研究--261 7.1 鹼質與粒料反應活性試驗結果------------------------------------------------264 7.1.1 各粒料活性試驗結果-------------------------------------------------------264 7.1.2 取樣之安山岩鹼質與粒料反應活性-------------------------------------265 7.2 岩相分析結果---------------------------------------------------------------------266 7.2.1 偏光顯微鏡觀察-------------------------------------------------------------266 7.2.2 X光繞射礦物成份分析-----------------------------------------------------268 7.3 討論---------------------------------------------------------------------------------269 7.3.1 搭配運用偏光顯微鏡觀察及X光繞射分析對判斷安山岩活 性之重要性------------------------------------------------------------------269 7.3.2 安山岩之岩相分析與鹼質與粒料反應活性關係----------------------270 第八章 利用混凝土角柱模擬ASTM C1260環境試驗法評估台灣 地區AAR之適用性--------------------------------------------------------273 8.1 執行構想---------------------------------------------------------------------------273 8.2 試驗結果---------------------------------------------------------------------------274 8.3 粒料活性評估---------------------------------------------------------------------275 8.4 ASTM C1260法適用性檢討-----------------------------------------------------275 8.5 CP1260AT法之適用性探討-----------------------------------------------------277 8.5.1 膨脹行為---------------------------------------------------------------------277 8.5.2 試驗齡期、判定標準及運用建議檢討-----------------------------------279 8.5.3 CP1260AT法與ASTM C227法比較---------------------------------------280 8.5.4 CP1260AT法與ASTM C289法比較---------------------------------------282 8.5.5 CP1260AT法與其它試驗結果比較---------------------------------------283 第九章 利用砂漿棒快速蒸壓法評估台灣地區AAR之適用性--------------286 9.1 執行構想---------------------------------------------------------------------------286 9.2 試驗結果---------------------------------------------------------------------------286 9.3 粒料活性評估---------------------------------------------------------------------287 9.4 蒸壓方法評估台灣地區粒料AAR問題之適用性探討---------------------288 9.4.1 CECS 48:93(APNOR P18-588)試驗法之適用性-----------------------288 9.4.2 MBAT法之適用性評估-----------------------------------------------------288 第十章 利用混凝土角柱快速蒸壓法評估台灣地區AAR之適用性--------295 10.1 執行構想--------------------------------------------------------------------------295 10.2 試驗結果--------------------------------------------------------------------------295 10.3 粒料活性評估-------------------------------------------------------------------296 10.4 蒸壓方法評估台灣地區粒料AAR問題之適用性探討-------------------296 10.4.1 JIS A1804試驗法之適用性-----------------------------------------------297 10.4.2 CPAT法之適用性評估----------------------------------------------------297 第十一章 綜合討論-----------------------------------------------------------------302 11.1 岩相分析----------------------------------------------------------------------302 11.2 現有規範試驗方法----------------------------------------------------------302 11.3 新發展之試驗方法----------------------------------------------------------304 11.4 微觀分析結果----------------------------------------------------------------305 11.5 各試驗方法之綜合評估---------------------------------------------------310 11.6 適合於台灣地區活性粒料檢測方法與判定標準探討--------------------311 11.6.1 岩相分析--------------------------------------------------------------------311 11.6.2 化學法-----------------------------------------------------------------------311 11.6.3 測長法-----------------------------------------------------------------------311 11.6.4 蒸壓法(CPAT)-------------------------------------------------------------312 11.6.5 本文研究成果應用於判定混合料活性之適用性--------------------312 11.7 建議台灣地區活性粒料之檢測方法及運用--------------------------------313 第十二章 結論與建議-------------------------------------------------------------316 12.1 結論--------------------------------------------------------------------------------316 12.2 建議--------------------------------------------------------------------------------319 參考文獻--------------------------------------------------------------------------------320 圖目錄 圖2.1 矽四面體(矽石)---------------------------------------------------------------7 圖2.2 石英結晶結構(SiO2)------------------------------------------------------------7 圖2.3 矽石含量對ASR膨脹之影響(重製示意圖)--------------------------------8 圖2.4 鹼質與粒料反應流程圖-------------------------------------------------------12 圖2.5 混凝土鋪面鹼質與粒料反應裂縫模式----------------------------------------17 圖2.6 裂縫焦點中心-------------------------------------------------------------------18 圖2.7 混凝土外部滲出物-------------------------------------------------------------18 圖2.8 鋼筋混凝土構造物ASR龜裂情形--------------------------------------------19 圖2.9 混凝土發生鹼粒料反應的內部徵狀----------------------------------------20 圖2.10 石英在68 ˚附近不同位置的五個繞射峯值--------------------------38 圖2.11 Nagoya附近的燧石以其CI值和ASTM C289化學法所得的相關 位置及評估(重製示意圖)----------------------------------------------------39 圖2.12 ASTM C227砂漿棒法中含鹼量對膨脹量之影響(重製示意圖)----43 圖2.13 ASTM C1260與ASTM C1293結果比較(重製示意圖)----------------46 圖2.14 四象限法評估二試驗方法示意圖------------------------------------------47 圖2.15 碳酸岩AMBT及CPT膨脹試驗相關圖(重製示意圖)-------------------48 圖2.16 陸源沉積岩AMBT及CPT膨脹試驗相關圖(重製示意圖)-------------49 圖2.17 火成岩及變質岩AMBT及CPT膨脹試驗相關圖(重製示意圖)-------49 圖2.18 AASHTO T303膨脹量與ASTM C289結果比較(重製示意圖)------53 圖2.19 ASTM C227與AMBT試驗結果比較(重製示意圖)---------------------54 圖2.20 CPT試驗結果(重製示意圖)-------------------------------------------------54 圖2.21 國內鹼質與粒料反應疑似案例照片---------------------------------------56 圖2.22 民國89年台灣地區水泥含鹼量調查---------------------------------------57 圖2.23 台灣地質分區------------------------------------------------------------------62 圖2.24 台灣岩石分布圖---------------------------------------------------------------64 圖2.25 澳大利亞降低AAR危害綱要流程------------------------------------------71 圖2.26 使用於評估粒料活性試驗流程圖------------------------------------------75 圖2.27 決定混凝土粒料鹼質與粒料反應活性潛勢流程圖---------------------79 圖2.28 粒料活性全面性調查計畫---------------------------------------------------80 圖2.29 PCA判定粒料活性試驗流程------------------------------------------------85 圖2.30 德州大學研究之判定鹼質與粒料反應活性流程圖---------------------86 圖3.1 台灣地區安山岩鹼質與粒料反應研究判定結果-------------------------91 圖4.1 台灣地區活性粒料之檢測方法研究流程圖------------------------------110 圖4.1(續) 台灣地區活性粒料之檢測方法研究流程圖-------------------------111 圖4.2 ASTM C289法試驗及鑑定粒料活性流程圖------------------------------115 圖4.3 ASTM C227法試驗及鑑定粒料活性流程圖------------------------------116 圖4.4 ASTM C1260法試驗及鑑定粒料活性流程圖----------------------------117 圖4.5 ASTM C1293法試驗及鑑定粒料活性流程圖----------------------------118 圖4.6 中國蒸壓法試驗及鑑定粒料活性流程圖---------------------------------119 圖4.7 日本蒸壓法試驗及鑑定粒料活性流程圖---------------------------------120 圖4.8 ASTM C295法試驗及鑑定粒料活性流程圖-----------------------------121 圖5.1 初期試驗各試驗配比28天圓柱試體抗壓強度---------------------------127 圖5.2 初期實驗混凝土角柱模擬ASTM C1293環境試體長度變化----------127 圖5.3 初期實驗混凝土角柱模擬ASTM C1260環境試體長度變化----------128 圖5.4 ASTM C289「粒料之潛在鹼質與二氧化矽反應」試驗結果--------132 圖5.5 安山岩類 2θ67~69度X光繞射分析--------------------------------------135 圖5.6 石英脈、砂岩及變質砂岩類 2θ67~69度X光繞射分析--------------136 圖5.7 矽質片岩及黑色片岩類 2θ67~69度X光繞射分析--------------------137 圖5.8 綠色片岩及大理岩類 2θ67~69度X光繞射分析-----------------------138 圖5.9 安山岩類 2θ5~60度X光繞射分析----------------------------------------143 圖5.10 石英脈類 2θ5~60度X光繞射分析--------------------------------------144 圖5.11 砂岩及變質砂岩類 2θ5~60度X光繞射分析--------------------------145 圖5.12 矽質片岩類 2θ5~60度X光繞射分析-----------------------------------146 圖5.13 黑色片岩類 2θ5~60度X光繞射分析-----------------------------------147 圖5.14 綠色片岩類 2θ5~60度X光繞射分析-----------------------------------148 圖5.15 石灰岩及大理岩類 2θ5~60度X光繞射分析--------------------------149 圖5.16 各岩石間所含膨潤石(Smectite)之相對比值------------------------150 圖5.17 各岩石間所含伊利石(Illite)和雲母族(Micas)之相對比值-----------151 圖5.18 各岩石間所含閃石(類) (Amphiboles)之相對比值---------------------152 圖5.19 各岩石間所含綠泥石(Chlorite)之相對比值-----------------------------153 圖5.20 各岩石間所含方矽石(Cristobalite, low)之相對比值-------------------154 圖5.21 各岩石間所含石英(Quartz, low)之相對比值---------------------------155 圖5.22 各岩石間所含斜長石(Plagioclase)之相對比值-------------------------156 圖5.23 各岩石間所含鈉長石(Albite)之相對比值-------------------------------157 圖5.24 各岩石間所含方解石(Calcite)之相對比值------------------------------158 圖5.25 各岩石間所含輝石(Augite)之相對比值---------------------------------159 圖5.26 各岩石間所含白雲石(Dolomite)之相對比值---------------------------160 圖5.27 東河紅色安山岩偏光顯微鏡照片----------------------------------------164 圖5.28 東河綠色安山岩偏光顯微鏡照片----------------------------------------165 圖5.29 東河黃色安山岩偏光顯微鏡照片----------------------------------------166 圖5.30 東河變質砂岩偏光顯微鏡照片-------------------------------------------167 圖5.31 石梯坪紅色安山岩偏光顯微鏡照片-------------------------------------168 圖5.32 石梯坪綠色安山岩偏光顯微鏡照片-------------------------------------169 圖5.33 石梯坪黃色安山岩偏光顯微鏡照片-------------------------------------170 圖5.34 三仙台紅色安山岩偏光顯微鏡照片-------------------------------------171 圖5.35 三仙台綠色安山岩偏光顯微鏡照片-------------------------------------172 圖5.36 花蓮溪安山岩偏光顯微鏡照片-------------------------------------------173 圖5.37 花蓮溪變質砂岩偏光顯微鏡照片----------------------------------------174 圖5.38 頭前溪砂岩偏光顯微鏡照片----------------------------------------------175 圖5.39 木瓜溪變質砂岩偏光顯微鏡照片----------------------------------------176 圖5.40 卑南溪變質砂岩偏光顯微鏡照片----------------------------------------177 圖5.41 ASTM C227水泥砂漿棒試驗膨脹量變化--------------------------------185 圖5.42 ASTM C227試驗三個月與六個月膨脹量之比較-----------------------185 圖5.43 ASTM C1293混凝土角柱試驗膨脹量變化------------------------------188 圖5.44 ASTM C1260快速砂漿棒試驗膨脹量變化------------------------------191 圖5.45 安山岩類、東河變質砂岩及混合料之ASTM C227、蒸壓法 及C1260試驗後試體相片---------------------------------------------------192 圖5.45(續) 安山岩類、東河變質砂岩及混合料之ASTM C227、 蒸壓法及C1260試驗後試體相片------------------------------------193~194 圖5.46 中國蒸壓法試驗結果-------------------------------------------------------195 圖5.47 日本蒸壓試驗試體膨脹量-------------------------------------------------197 圖5.48 日本蒸壓試驗試體超音波殘留量----------------------------------------197 圖5.49 混凝土角柱模擬ASTM C1260環境試驗膨脹量變化-----------------200 圖5.50 水泥砂漿棒模擬中國蒸壓法試驗結果----------------------------------203 圖5.51 混凝土角柱模擬中國蒸壓法試驗結果----------------------------------203 圖6.1 象限座標法運用於試驗方法比較之象限定義--------------------------208 圖6.2 ASTM C289與 C1260試驗結果比較-------------------------------------212 圖6.3 ASTM C289與 C227(3個月)試驗結果比較-----------------------------213 圖6.4 ASTM C289與 C227(6個月)試驗結果比較-----------------------------214 圖6.5 ASTM C289與 C1293試驗結果比較-------------------------------------215 圖6.6 ASTM C289與中國蒸壓法試驗結果比較--------------------------------216 圖6.7 ASTM C289與日本蒸壓法試驗結果比較--------------------------------217 圖6.8 ASTM C289與 CI值分析試驗結果比較----------------------------------218 圖6.9 ASTM C1260與 C227(3個月)試驗結果比較----------------------------223 圖6.10 ASTM C1260與 C227(6個月)試驗結果比較---------------------------224 圖6.11 ASTM C1260與 C1293試驗結果比較-----------------------------------225 圖6.12 ASTM C1260與中國蒸壓法試驗結果比較-----------------------------226 圖6.13 ASTM C1260與日本蒸壓法(膨脹量)試驗結果比較--------------227 圖6.14 ASTM C1260與日本蒸壓法(超音波)試驗結果比較--------------228 圖6.15 ASTM C1260與CI值分析試驗結果比較--------------------------------229 圖6.16 ASTM C1260、C227(3個月)與C289試驗結果比較-------------------232 圖6.17 ASTM C1260、C227(6個月)與C289試驗結果比較-------------------232 圖6.18 ASTM C1260、C1293與C289試驗結果比較---------------------------233 圖6.19 ASTM C1260、日本蒸壓法(膨脹量)與C289試驗結果比較---------233 圖6.20 ASTM C227(3個月)與 C1293試驗結果比較---------------------------238 圖6.21 ASTM C227(6個月)與 C1293試驗結果比較---------------------------239 圖6.22 ASTM C227(3個月)與日本蒸壓法膨脹量試驗結果比較------------240 圖6.23 ASTM C227(6個月)與日本蒸壓法膨脹量試驗結果比較------------241 圖6.24 ASTM C227(3個月)與CI值分析結果比較------------------------------242 圖6.25 ASTM C227(6個月)與CI值分析結果比較------------------------------243 圖6.26 ASTM C1293與日本蒸壓法膨脹量試驗結果比較--------------------246 圖6.27 ASTM C1293與CI值分析結果比較--------------------------------------247 圖6.28 日本蒸壓法膨量量與CI值結果比較-------------------------------------250 圖6.29 ASTM C1260、C227、C289及C1293試驗結果綜合比較-----------254 圖6.30 ASTM C1260與ASTM C1293試驗方法比較---------------------------256 圖6.31 日本蒸壓法膨脹量與ASTM C1293試驗方法比較--------------------260 圖7.1 進行岩相分析之安山岩------------------------------------------------------262 圖8.1 ASTM C1260法與ASTM C1293法試驗結果比較-----------------------276 圖8.2 CP1260AT法1個月膨脹量與ASTM C1293法1年膨脹量比較---------278 圖8.3 CP1260AT法3個月膨脹量與ASTM C1293法1年膨脹量比較---------278 圖8.4 CP1260AT法各試驗齡期與ASTM C1293法1年膨脹量趨勢線 相關因子比較-----------------------------------------------------------------279 圖8.5 CP1260AT法與ASTM C227試驗結果比較-------------------------------281 圖8.6 CP1260AT法與ASTM C289試驗結果比較-------------------------------282 圖9.1 MBAT法與CECS 48:93法試驗試體膨脹量比較-----------------------289 圖9.2 MBAT法與ASTM C1293試驗結果比較及建議之判定標準檢討-----290 圖9.3 MBAT法與ASTM C227試驗結果比較------------------------------------291 圖9.4 MBAT法與ASTM C289試驗結果比較------------------------------------292 圖9.5 MBAT法暫行判定標準建議值之檢核-------------------------------------294 圖10.1 CPAT法與ASTM C1293試驗結果比較----------------------------------297 圖10.2 CPAT法試驗結果暫行判定標準檢討------------------------------------298 圖11.1 東河黃色安山岩及變質砂岩進行ASTM C1260試驗之試體 SEM(EDS)圖形---------------------------------------------------------------306 圖11.2 東河黃色安山岩及變質砂岩進行砂漿棒模擬中國蒸壓法 試驗之試體SEM(EDS)圖形------------------------------------------------308 圖11.3 建議新建工程申請之鹼質與粒料反應問題檢核及要求流程圖----315 表目錄 表2.1 具鹼質與粒料反應潛勢之礦物及岩種〔CSA 1994a〕-------------------9 表2.2 各國鹼質與粒料反應試驗法-------------------------------------------------29 表2.3 各國砂漿棒法比較(檢測ASR)------------------------------------------------31 表2.4 各國混凝土角柱試驗法比較(檢測ASR)--------------------------------32 表2.5 混凝土角柱試驗法(檢測ACR)--------------------------------------------32 表2.6 各國快速砂漿棒法比較(檢測ASR)------------------------------------------34 表2.7 各國蒸壓法比較(檢測ASR)---------------------------------------------------35 表2.8 化學法(適用於評估非活性粒料)--------------------------------------------36 表2.9 RILEM調查結果----------------------------------------------------------------40 表2.10 SINTEF及CANMET之AMBT參數比較----------------------------------50 表2.11 SINTEF及CANMET之CPT參數比較--------------------------------------51 表2.12 ABMT和CPT在SINTEF 及CANMET的試驗結果比較---------------51 表2.13 68種粒料AASHTO T303及ASTM C289試驗結果----------------------52 表2.14 國內各河川粒料活性鑑定結果---------------------------------------------58 表2.15 台灣地區單一岩種活性鑑定結果------------------------------------------59 表2.16 國內各河川岩種研究一覽表------------------------------------------------66 表2.17 木瓜溪等河川及地區岩石採集結果---------------------------------------68 表2.18 混凝土最大含鹼量限制------------------------------------------------------69 表2.19 Bérubé鹼質與粒料反應檢測法之建議程序與限制---------------------78 表2.20 Mid-Atlantic RTC建議之檢測及判定標準--------------------------------82 表2.21 Mid-Atlantic RTC建議之有效抑制AAR材料及方法------------------82 表2.22 AASHTO ASR Lead State Team建議之試驗程序及判定標準---------83 表2.23 AASHTO ASR Lead State Team建議之有效抑制AAR材料及方法---84 表3.1 台灣主要安山岩之分佈與岩性----------------------------------------------88 表4.1 水泥成份檢測報告------------------------------------------------------------112 表5.1 初期試驗圓柱試體28天抗壓強度------------------------------------------126 表5.2 ASTM C289試驗結果---------------------------------------------------------130 表5.3 XRD結晶指數CI值------------------------------------------------------------134 表5.4 岩石所含礦物組成------------------------------------------------------------141 表5.5 進行偏光顯微鏡分析岩種項目表------------------------------------------161 表5.6 偏光顯微鏡觀察結果綜合表------------------------------------------------178 表5.7 ASTM C227水泥砂漿棒試驗結果-----------------------------------------184 表5.8 ASTM C1293混凝土角柱試驗結果----------------------------------------187 表5.9 ASTM C1260快速砂漿棒試驗結果----------------------------------------190 表5.10 中國蒸壓法試驗結果-------------------------------------------------------194 表5.11 日本蒸壓法試驗結果-------------------------------------------------------196 表5.12 混凝土角柱模擬ASTM C1260環境試驗膨脹量變化-----------------199 表5.13 砂漿棒及混凝土角柱模擬中國蒸壓法試驗結果----------------------202 表6.1 現有規範判定為活性粒料結果--------------------------------------------205 表6.2 「台灣地區活性粒料之檢測方法研究」試驗結果一覽表-----------206 表6.3 ASTM C289法與其他現有規範相互比對結果符合數-----------------211 表6.4 ASTM C289法與其他現有規範相互比對結果符合率-----------------211 表6.5 ASTM C1260法與其他現有規範相互比對結果符合數---------------222 表6.6 ASTM C1260法與其他現有規範相互比對結果符合率---------------222 表6.7 ASTM C227(3個月)法與其他現有規範相互比對結果符合數-------236 表6.8 ASTM C227(3個月)法與其他現有規範相互比對結果符合率-------236 表6.9 ASTM C227(6個月)法與其他現有規範相互比對結果符合數-------237 表6.10 ASTM C227(6個月)法與其他現有規範相互比對結果符合率------237 表6.11 ASTM C1293法與其他現有規範相互比對結果符合數--------------245 表6.12 ASTM C1293法與其他現有規範相互比對結果符合率---------------245 表6.13 日本蒸壓法與其他現有規範相互比對結果符合數--------------------249 表6.14 日本蒸壓法與其他現有規範相互比對結果符合率--------------------249 表6.15 ASTM C1260修正判定標準後與ASTM C1293結果比較------------257 表6.16 日本蒸壓法修正判定標準後與ASTM C1293結果比較--------------259 表7.1 岩相分析及鹼質與粒料反應活性之試驗結果---------------------------263 表7.2 安山岩之低溫方矽石相對含量比較---------------------------------------269 表8.1 各試驗方法的試驗結果與粒料活性判定---------------------------------274 表8.2 ASTM C1260修正判定標準後與ASTM C1293結果比較--------------277 表8.3 CP1260AT法與ASTM C1293判定結果比較------------------------------280 表8.4 CP1260AT法與ASTM C227判定結果比較-------------------------------281 表8.5 CP1260AT法與ASTM C289判定結果比較-------------------------------283 表8.6 CP1260AT法與與其他現有規範相互比對結果符合數-----------------284 表8.7 CP1260AT法與與其他現有規範相互比對結果符合率-----------------285 表9.1 各試驗方法的試驗結果與粒料活性判定---------------------------------287 表9.2 MBAT法與ASTM C1293法判定結果比較--------------------------------290 表9.3 MBAT法與ASTM C227法判定結果比較---------------------------------292 表9.4 MBAT法與ASTM C289法判定結果比較---------------------------------293 表10.1 各試驗方法的試驗結果與粒料活性判定-------------------------------296 表10.2 CPAT法與ASTM C1293判定結果比較----------------------------------299 表10.3 CPAT法與其他現有規範相互比對結果符合數------------------------300 表10.4 CPAT法與其他現有規範相互比對結果符合率------------------------301 表11.1 各試驗方法之綜合評估-----------------------------------------------------310

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