农业工程学报
農業工程學報
농업공정학보
2014年
22期
112-119
,共8页
吴福飞%侍克斌%董双快%慈军%努尔开力·依孜特罗甫
吳福飛%侍剋斌%董雙快%慈軍%努爾開力·依孜特囉甫
오복비%시극빈%동쌍쾌%자군%노이개력·의자특라보
混凝土%塑性%渗流%溶蚀%质量损失%强度损失%耐久性
混凝土%塑性%滲流%溶蝕%質量損失%彊度損失%耐久性
혼응토%소성%삼류%용식%질량손실%강도손실%내구성
concretes%plastics%seepage%corrosion%mass loss%strength loss%durability
为了评定塑性混凝土的长期渗流稳定性和使用年限,结合当地原材料的情况,采用膨润土、黏土、水泥、骨料、水和减水剂等来制备塑性混凝土,试验测定了完整或含孔洞塑性混凝土的长期渗流稳定性和使用年限。经过多次试配试验,选定配合比并制作试件,该试件在标准养护28 d后,其抗压强度为1.25 MPa。分别制备、使用2组共12个试件进行溶蚀试验或冲淋试验。溶蚀试验表明,在溶蚀试验的测试初期,渗透系数是不断变化的,尤其在试验前30~40 d是比较明显的,但均在10-7 cm/s数量级。随溶蚀时间的延长,混凝土试件中被溶蚀CaO的数量呈线性递减关系,直至降低到自来水所含CaO的浓度范围,而渗透系数在150~180 d时增至3.0×10-7 cm/s,且逐渐趋于稳定。经180 d的渗流溶蚀作用后,塑性混凝土会产生剪损裂缝和拉断裂缝,甚至有较大的塑性变形,导致试件顶面平均上升位移值高达38.5 mm。通过溶蚀试验计算该塑性混凝土的渗透系数和CaO含量,然后计算塑性混凝土防渗墙使用年限为37.1~60.7 a。冲淋试验表明:水流会在含孔洞的混凝土中产生集中冲刷且局部混凝土中的 CaO 被溶蚀并随水流携带走,经过测定分析,水流从孔中冲蚀出的白色沉淀物为碳酸钙,另有少量的Na+、微量黏土和膨润土颗粒,从而降低了混凝土的质量。在恒压水流作用下,水流对已含孔洞混凝土的冲刷较弱,混凝土中被溶蚀并携带走的CaO较少,即使冲淋197 d后,其前后的质量的损失较小,相对损失不超过1%,但其强度损失较大,高达25.4%。综合研究表明:采用黏土和膨润土制备的塑性混凝土符合土石坝防渗墙防渗的特点,具有水泥用量小、强度低、高抗渗性和使用年限长的特点。
為瞭評定塑性混凝土的長期滲流穩定性和使用年限,結閤噹地原材料的情況,採用膨潤土、黏土、水泥、骨料、水和減水劑等來製備塑性混凝土,試驗測定瞭完整或含孔洞塑性混凝土的長期滲流穩定性和使用年限。經過多次試配試驗,選定配閤比併製作試件,該試件在標準養護28 d後,其抗壓彊度為1.25 MPa。分彆製備、使用2組共12箇試件進行溶蝕試驗或遲淋試驗。溶蝕試驗錶明,在溶蝕試驗的測試初期,滲透繫數是不斷變化的,尤其在試驗前30~40 d是比較明顯的,但均在10-7 cm/s數量級。隨溶蝕時間的延長,混凝土試件中被溶蝕CaO的數量呈線性遞減關繫,直至降低到自來水所含CaO的濃度範圍,而滲透繫數在150~180 d時增至3.0×10-7 cm/s,且逐漸趨于穩定。經180 d的滲流溶蝕作用後,塑性混凝土會產生剪損裂縫和拉斷裂縫,甚至有較大的塑性變形,導緻試件頂麵平均上升位移值高達38.5 mm。通過溶蝕試驗計算該塑性混凝土的滲透繫數和CaO含量,然後計算塑性混凝土防滲牆使用年限為37.1~60.7 a。遲淋試驗錶明:水流會在含孔洞的混凝土中產生集中遲刷且跼部混凝土中的 CaO 被溶蝕併隨水流攜帶走,經過測定分析,水流從孔中遲蝕齣的白色沉澱物為碳痠鈣,另有少量的Na+、微量黏土和膨潤土顆粒,從而降低瞭混凝土的質量。在恆壓水流作用下,水流對已含孔洞混凝土的遲刷較弱,混凝土中被溶蝕併攜帶走的CaO較少,即使遲淋197 d後,其前後的質量的損失較小,相對損失不超過1%,但其彊度損失較大,高達25.4%。綜閤研究錶明:採用黏土和膨潤土製備的塑性混凝土符閤土石壩防滲牆防滲的特點,具有水泥用量小、彊度低、高抗滲性和使用年限長的特點。
위료평정소성혼응토적장기삼류은정성화사용년한,결합당지원재료적정황,채용팽윤토、점토、수니、골료、수화감수제등래제비소성혼응토,시험측정료완정혹함공동소성혼응토적장기삼류은정성화사용년한。경과다차시배시험,선정배합비병제작시건,해시건재표준양호28 d후,기항압강도위1.25 MPa。분별제비、사용2조공12개시건진행용식시험혹충림시험。용식시험표명,재용식시험적측시초기,삼투계수시불단변화적,우기재시험전30~40 d시비교명현적,단균재10-7 cm/s수량급。수용식시간적연장,혼응토시건중피용식CaO적수량정선성체감관계,직지강저도자래수소함CaO적농도범위,이삼투계수재150~180 d시증지3.0×10-7 cm/s,차축점추우은정。경180 d적삼류용식작용후,소성혼응토회산생전손렬봉화랍단렬봉,심지유교대적소성변형,도치시건정면평균상승위이치고체38.5 mm。통과용식시험계산해소성혼응토적삼투계수화CaO함량,연후계산소성혼응토방삼장사용년한위37.1~60.7 a。충림시험표명:수류회재함공동적혼응토중산생집중충쇄차국부혼응토중적 CaO 피용식병수수류휴대주,경과측정분석,수류종공중충식출적백색침정물위탄산개,령유소량적Na+、미량점토화팽윤토과립,종이강저료혼응토적질량。재항압수류작용하,수류대이함공동혼응토적충쇄교약,혼응토중피용식병휴대주적CaO교소,즉사충림197 d후,기전후적질량적손실교소,상대손실불초과1%,단기강도손실교대,고체25.4%。종합연구표명:채용점토화팽윤토제비적소성혼응토부합토석패방삼장방삼적특점,구유수니용량소、강도저、고항삼성화사용년한장적특점。
In order to evaluate long-term seepage stability and service life of plastic concrete that are made of bentonite, clay, cement, soil aggregate, water, superplasticizer, etc., we studied incomplete or contain holes of plastic concrete’s long-term seepage stability and service life. Specimens of plastic concrete were molded after many times of tests, and their compressive strength of 28 days was 1.25 MPa, and meet requirements impermeability grade was S1 which was test code for hydraulic concrete because water pressure measured was 0.2 MPa by step by step method. The preparation of plastic concrete permeability test required to a round-shaped specimen (top diameter is 175 mm, basal diameter is 185 mm, height is 150 mm). Type I was complete specimens of concrete impermeability;and Type II specimens were high in the direction parallel to the reserved five through holes with a diameter of 3.5 mm, plum-shaped layout was on the plane. It was found after long-term corrosion test plastic concrete can produce shear cracks and tensile cracks and even had lager plastic deformation after long-term seepage dissolution by pure water, which led to damage of the plastic concrete. This resulted in an increase of maximum displacement values of top surface of the specimen by 38.5 mm on average. The permeability coefficient was changed in the early (30 to 40 days) penetration test, but they were in 10-7 cm/s orders of magnitude. The permeability coefficient was increased to 3.0×10-7 cm/s and then tended to be stable during 150-180 days. Ca2+were dissolved from the concrete and leached out after long-term seepage dissolution, the amount of Ca2+removed from concrete specimens were linearly decreasing as dissolution time (<150 days). The concentration of Ca2+ in the specimen water seepage fell below 110 mg/L after 180 days of dissolution. Through dissolution experiment, calculating plastic concrete’s coefficient of permeability and content of CaO were done based on the formula of diaphragm wall’s durable years, the calculated service life was 37.1-60.7 years. Drench experiment showed that flows may create preferential erosion in holes in concrete, and Ca(OH)2 in concrete were dissolved and carried away by the flow which led to decrease in weight of plastic concrete. The flow of constant pressure through holes of concrete was relatively weak, and few Ca in concrete were dissolved and carried away. Even after drench 197 d, there was less quality loss compare with the original, the relative loss was not more than 1%. However the concrete strength loss was larger (up to 25.4%). The white precipitates in the hole were CaCO3, and some Na+, trace clay and bentonite particles after laboratory analysis. The studies showed that the features of plastic concrete made of clay and bentonite had a low-intensity, high impermeability and long service life which met the requirement of impervious wall of earth-rock fill dam. Thus, it can be used for embankment dam for seepage prevention.