完整後設資料紀錄
DC 欄位語言
dc.contributor.author陳恆祐en_US
dc.contributor.authorHeng-You Chenen_US
dc.contributor.author潘以文en_US
dc.contributor.authorYii-Wen Panen_US
dc.date.accessioned2014-12-12T02:19:53Z-
dc.date.available2014-12-12T02:19:53Z-
dc.date.issued1998en_US
dc.identifier.urihttp://140.113.39.130/cdrfb3/record/nctu/#NT870015037en_US
dc.identifier.urihttp://hdl.handle.net/11536/63739-
dc.description.abstract軟弱岩石的透水係數除了與顆粒粒徑分佈、孔隙大小、泥質含量及膠結物種類等因素有關,且深受試體飽和度之影響,如欲以傳統之定水頭或變水頭滲透實驗方法正確決定材料滲透性常有其困難。為求正確決定材料滲透性,本研究乃研製一微流量幫浦,藉由伺服馬達強制控制流經試體之微流量,以控制固定流量之方式來控制滲透試驗之進行,經量測試體兩端之水壓差即可正確決定試體之滲透性。本儀器可控制圍壓與反水壓,因此可藉由檢核B值來確認飽和程度。本研究由台中大坑及新竹寶山分別取回黃色砂岩之岩樣,進行一系列由室內定流量三軸透水試驗。所求得的滲透係數整理如下:台中大坑黃色砂岩介於2.9 ×10-5~8.3 ×10-5cm/s;新竹寶山黃色砂岩介於為2.7 ×10-4~3.2 ×10-4cm/s,灰色粉砂岩則介於為8.6 ×10-6~9.1 ×10-6cm/s。若試體材料性質相同(譬如:無明顯相通不連續面或無明顯差異極大之互層),現場的透水性質與室內透水試驗結果相近,對本批岩樣而言,室內透水試驗結果可做為描述現場岩體透水性質之依據。 又軟弱岩石因環境影響而可能產生弱化,進而可能造成強度下降或變形性增加;本研究對軟弱砂岩施以滲流弱化模擬,再以微觀方式量測組構的變化,觀察分析岩石顆粒與膠結物之改變情形,探討其滲流對微組構的影響。本研究利用三軸透水儀器模擬滲流作用,再觀察其滲流前後微組構的變化,發現岩石的平面孔隙率在滲流後比滲流前增大了2~3%。推測主要是細顆粒填充物之間與顆粒接觸的邊緣會有孔隙有局部增大的情形,可能是滲流水經過時會先溶解掉充當膠結的黏土礦物,使細顆粒間的凝聚力降低,造成崩解分離,而滲流水將溶解的膠結物與細顆粒填充物攜出帶走。zh_TW
dc.description.abstractThe permeability of weak rock depends on the grain characteristics, pores, cementation, and saturation of material. In this study, a device of constant-flow permeability test was built up for correctly determining the true permeability of weak rock specimen. In the test, a constant-flow pump is developed to control a constant flow through a specimen in a triaxial cell. The head difference between two ends of the specimen is measured. Then, the permeability of the specimen is calculated on the basis of the Darcy's law. The developed device is able to control the confining pressure and the back-pressure of a specimen; hence, the saturation of specimen can be examined by checking the B value. A series of constant-flow permeability tests on samples of weak sandstone from Ta-kang, Taichung and from Bau-san, Hsinchu were carried out and compared with the in-situ permeability test. The permeability of Ta-kang sandstone lies within 2.9 ×10-5~8.3 ×10-5cm/s. The permeability of Bau-san sandstone lies within 2.7 ×10-4~3.2 ×10-4cm/s, which is found closely consistent with the result from the in-situ lugeon test. Weak sandstone usually will degrade when it is exposed to unfavorable environmental conditions. The degradation of weak sandstone may results in the reduction in its strength and deformability. This study also attempts to investigate the microstructure change of weak sandstone after the degradation due to seepage through the material. By comparing the microstructure of sample before and after the degradation due to seepage, it was found that the void of sandstone increases significantly after degradation. On the basis of microscopic observation, the reason is possibly due to an increase of void near the grain-matrix interface in the material and/or the dissolution of the cementation/matrix.en_US
dc.language.isozh_TWen_US
dc.subject滲透性質zh_TW
dc.subject定流量zh_TW
dc.subject微組構zh_TW
dc.subject弱化zh_TW
dc.subjectpermeabilityen_US
dc.subjectconstant-rate flowen_US
dc.subjectmicrostructreen_US
dc.subjectdegradationen_US
dc.title軟岩的滲透性質及滲流對微組構之影響zh_TW
dc.titleThe Permeability of Weak Sandstone and The Microstructure Change due to Seepageen_US
dc.typeThesisen_US
dc.contributor.department土木工程學系zh_TW
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