大坝与水工混凝土关键核心技术综述
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摘要
大坝建设是水利水电发展最重要的标志,它对水资源的开发利用发挥着极其重要的作用。水工混凝土作为水工建筑物重要的建筑材料,有着其他材料无法替代的作用。梳理了大坝混凝土材料及分区、水工混凝土原材料、大坝混凝土施工配合比、水工泄水建筑物抗冲磨混凝土、大坝混凝土施工质量与温控防裂、数字大坝与智能大坝建设等方面的关键核心技术,以期为我国水利水电工程建设又好又快的发展提供技术支撑。
Dam construction,as one of the most important symbol of water conservancy and hydropower development,plays a key part in water resources exploitation and utilization. Hydraulic concrete is a crucial construction material to hydraulic structure and cannot be replaced by other materials. This paper reviews some relative key and core technologies,such as dam concrete material and partition,hydraulic concrete raw material,concrete construction mixture ratio,abrasion-resistance concrete in hydraulic outlet works,dam concrete construction quality and temperature control and crack prevention,and digital dam and intelligent dam construction,looking forward to providing technical support for water conservancy and hydroelectric project development in China.
Dam construction,as one of the most important symbol of water conservancy and hydropower development,plays a key part in water resources exploitation and utilization. Hydraulic concrete is a crucial construction material to hydraulic structure and cannot be replaced by other materials. This paper reviews some relative key and core technologies,such as dam concrete material and partition,hydraulic concrete raw material,concrete construction mixture ratio,abrasion-resistance concrete in hydraulic outlet works,dam concrete construction quality and temperature control and crack prevention,and digital dam and intelligent dam construction,looking forward to providing technical support for water conservancy and hydroelectric project development in China.
引文
[1]习近平主持召开中央财经委员会第二次会议强调提高关键核心技术创新能力为我国发展提供有力科技保障[EB/OL].[2018-05-15]. http://www. cac. gov. cn/2018-07/13/c_1123124008. htm.
[2]田育功,付波,杨溪滨,等.大坝混凝土材料与分区创新技术综述[J].水利水电施工,2015(4):8-13.
[3]陈文耀,李文伟.混凝土极限拉伸值问题思考[J].中国三峡建设,2002(3):7-8.
[4]李华,吴笑梅,樊粤明.低热水泥的研究现状及展望[J].广东建材,2006(5):24-26.
[5]王显斌,文寨军.低热硅酸盐水泥及其在大型水电工程中的应用[J].水泥,2014(11):22-25.
[6]中国长江三峡工程开发总公司,中国葛洲坝水利水电工程集团公司.水工混凝土施工规范宣贯辅导材料[M].北京:中国电力出版社,2003.
[7]王博,郜军艳,聂相田.三峡三期工程大坝混凝土生产质量控制[J].华北水利水电大学学报(自然科学版),2015,36(1):25-32.
[8]溪洛渡大坝:从“数字大坝”向“智能大坝”跨越[N/OL].中国青年报,2016-03-22(03).[2018-05-15]. http://zqb. cyol. com/html/2016-03/22/nw. D110000zgqnb_20160322_2-03. htm.
[9]钟登华,王飞,吴斌平,等.从数字大坝到智慧大坝[J].水利发电学报,2015,34(10):1-13.
[2]田育功,付波,杨溪滨,等.大坝混凝土材料与分区创新技术综述[J].水利水电施工,2015(4):8-13.
[3]陈文耀,李文伟.混凝土极限拉伸值问题思考[J].中国三峡建设,2002(3):7-8.
[4]李华,吴笑梅,樊粤明.低热水泥的研究现状及展望[J].广东建材,2006(5):24-26.
[5]王显斌,文寨军.低热硅酸盐水泥及其在大型水电工程中的应用[J].水泥,2014(11):22-25.
[6]中国长江三峡工程开发总公司,中国葛洲坝水利水电工程集团公司.水工混凝土施工规范宣贯辅导材料[M].北京:中国电力出版社,2003.
[7]王博,郜军艳,聂相田.三峡三期工程大坝混凝土生产质量控制[J].华北水利水电大学学报(自然科学版),2015,36(1):25-32.
[8]溪洛渡大坝:从“数字大坝”向“智能大坝”跨越[N/OL].中国青年报,2016-03-22(03).[2018-05-15]. http://zqb. cyol. com/html/2016-03/22/nw. D110000zgqnb_20160322_2-03. htm.
[9]钟登华,王飞,吴斌平,等.从数字大坝到智慧大坝[J].水利发电学报,2015,34(10):1-13.
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