小云峰大坝大体积混凝土温控技术研究
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摘要
水工混凝土结构开裂问题长期以来困扰着工程界,一直未能得到很好的解决。裂缝的出现和存在会对结构整体性、安全性带来不利影响。一旦混凝土开裂,想通过修补以恢复结构的整体性是十分困难的,因此对于水工混凝土开裂应以预防为主。从目前的研究成果来看,大体积混凝土的开裂主要受混凝土自身的物理力学特性、施工养护方式、内外温差及外部约束等因素的影响。
论文通过对引起小云峰大坝大体积混凝土开裂各种因素的对比分析,确定了控制混凝土出机、入仓、浇筑温度,进行一期、中期、二期通水冷却的施工措施。通过对温控施工技术实施过程中的监测与数据分析,提出了减少冷却降温幅度、延长二期冷却混凝土龄期、取消温度分区、减小冷却降温速率的施工改进措施。
笔者以小云峰水电站工程大坝为研究背景,较深入地分析了本工程特点以及引起大坝大体积混凝土开裂的各种因素,建立了小云峰大坝温控防裂技术体系和管理体系,解决了温控技术难题,保证了温控标准的具体实施,可为同类工程项目的建设提供借鉴。
Hydraulic concrete structure cracking has not been solved at all times。The problem is always in trouble for engineering field。Crack appearance and existing will be disadvantages in structure integrity and safety。Once concrete cracks, the strcucture integrity will be in difficulty to mend and restore。Therefore, hydraulic concrete crack will mainly be prevented。In view of present research results, mass concrete crack mainly will be restricted to its physical characteristics, construction maintenance, inside and outside difference in temperature, etc。
In variety of structure style and restriction conditions, the situation of structure crack is complex。Meanwhile, effect of construction scheme, water flow, sunshine, cold weather, and various seasons, etc, cracks will appear at any time。Therefore, management and implement of Xiaoyunfeng Dam concrete temperature control on base of the frame of quality management system, which owner was responsible for the project, design ensured the works, construction guaranteed, construcion supervision was for speciality, experts gave double check, and the government monitored。Mainly prevented from structure crack through water of spillway gate chamber and flood discharge tunnel line concret, needed comprehensive analysis and study, various effects of concrete cracks acted。Mass concrete structure in pouring construction and dismantled mode board, water dischaged stage, rule of temperature field of long term run and stress field, combined concrete material design and construction design, temperatur measures and maintenance measures, and etc, esuring structure to be in safe stress condition in whole construction, and prevent that cracks should not appear。The principle expressed by responsible for themselves, subsection control, successively checked, very strictly in work。Temperature control management system established that played an decisive role on dam temperature technology problem solved, optimized and various temperatur control standard implemented。
论文通过对引起小云峰大坝大体积混凝土开裂各种因素的对比分析,确定了控制混凝土出机、入仓、浇筑温度,进行一期、中期、二期通水冷却的施工措施。通过对温控施工技术实施过程中的监测与数据分析,提出了减少冷却降温幅度、延长二期冷却混凝土龄期、取消温度分区、减小冷却降温速率的施工改进措施。
笔者以小云峰水电站工程大坝为研究背景,较深入地分析了本工程特点以及引起大坝大体积混凝土开裂的各种因素,建立了小云峰大坝温控防裂技术体系和管理体系,解决了温控技术难题,保证了温控标准的具体实施,可为同类工程项目的建设提供借鉴。
Hydraulic concrete structure cracking has not been solved at all times。The problem is always in trouble for engineering field。Crack appearance and existing will be disadvantages in structure integrity and safety。Once concrete cracks, the strcucture integrity will be in difficulty to mend and restore。Therefore, hydraulic concrete crack will mainly be prevented。In view of present research results, mass concrete crack mainly will be restricted to its physical characteristics, construction maintenance, inside and outside difference in temperature, etc。
In variety of structure style and restriction conditions, the situation of structure crack is complex。Meanwhile, effect of construction scheme, water flow, sunshine, cold weather, and various seasons, etc, cracks will appear at any time。Therefore, management and implement of Xiaoyunfeng Dam concrete temperature control on base of the frame of quality management system, which owner was responsible for the project, design ensured the works, construction guaranteed, construcion supervision was for speciality, experts gave double check, and the government monitored。Mainly prevented from structure crack through water of spillway gate chamber and flood discharge tunnel line concret, needed comprehensive analysis and study, various effects of concrete cracks acted。Mass concrete structure in pouring construction and dismantled mode board, water dischaged stage, rule of temperature field of long term run and stress field, combined concrete material design and construction design, temperatur measures and maintenance measures, and etc, esuring structure to be in safe stress condition in whole construction, and prevent that cracks should not appear。The principle expressed by responsible for themselves, subsection control, successively checked, very strictly in work。Temperature control management system established that played an decisive role on dam temperature technology problem solved, optimized and various temperatur control standard implemented。
引文
[1]吴荣昌.大体积混凝土施工中温度裂缝的控制技术[J].重庆建筑,2006,(5):14-16页(Z1)
[2]田雨泽,张彤.大体积混凝土施工的裂缝预控[J].低温建筑技术,2002,(3):4-6页.
[3]邢金栋,何健健,王希君.大跨度主梁大体积混凝土冬期施工应用[J].低温建筑技术,2006,(03):11-13页.
[4]高安平.大体积混凝土基础承台温度裂缝控制[J].福建建材,2006,(03):22-23页
[5]胡明华,刘雷军,陈冲.大体积混凝土温度裂缝的原因及防治措施[J].工程建设与设计,2007,(12):16-17页
[6]徐志光.大体积钢筋混凝土裂缝原因和控制技术[J].广东建材,2006,(07):10-11页
[7]梁铭健.大体积混凝土施工方案[J].广东建材,2008,(05):9-10页
[8]孔德水,李学金.超长大体积钢筋混凝土结构无缝施工技术[J].国防交通工程与技术,2006,(02):21-22页
[9]石峰,曹景文.大体积混凝土结构施工技术应用探讨[J].赤峰学院学报(自然科学版),2008,(05):25-26页.
[10]麦润强.大体积混凝土的施工技术[J].广东建材,2007,(04):20-21页
[11]戴镇潮.大体积混凝土的防裂[J].混凝土,2001,(09):21-22页
[12]周树奎.夏季浇筑大体积混凝土出现温度裂缝的防治[J].黑龙江水利科技,2007,(06):19-20页
[13]曹可之.大体积混凝土结构裂缝控制的综合措施[J].建筑结构,2002,(08):25-26页
[14]薛志宏,张延明.大体积混凝土施工工艺的探讨[J].吉林勘察设计,2007,(01):29-30页
[15]李彤.厚大体积混凝土承台施工温度裂缝控制实例[J].建筑技术开发,2001,(10):35-36页
[16]万小华.大体积混凝土施工技术探讨[J].山西建筑,2008,(12):13-14页.
[17]何文忠,王济川.钢筋砼结构及其屋面梁、板裂缝的分析鉴定和处理[J].四川建筑科学研究,1999,(03):15-16页
[18]胡明罡,贺群.由于温度效应导致框架梁开裂的事故分析[J].四川建筑科学研究,2000,(01):19-20页.
[19]赵海东,赵鸣,沈水明.超长钢筋混凝土结构的温度响应[J].四川建筑科 学研究,2000,(04):26-27页.
[20]王孔藩,许清风,朱雷.结构裂缝控制与渗漏防治[J].四川建筑科学研究,2003,(03):31-32页.
[21]胡建勤.高性能混凝土抗裂性能及其机理的研究[D].武汉理工大学,2002,(05):19-20页.
[22]彭小平.低热高性能高贝利特水泥大坝混凝土的研究[D].重庆大学,2002,(08):25-26页.
[23]张宇鑫.大体积混凝土温度应力仿真分析与反分析[D].大连理工大学,2002,(03):12-13页.
[24]刘勇军.水工混凝土温度与防裂技术研究[D].河海大学,2002,(02):18-19页
[25]谢先坤.大体积混凝土结构三维温度场、应力场有限元仿真计算及裂缝成因机理分析[D].河海大学,2001,(01),23-24页
[26]曾斌.北盘江特大桥锚碇大体积混凝土温控技术[A].开拓进取再创辉煌——贵州省公路学会2008年技术交流论文集[C],2008,(02):16-17页
[27]钱晓倩,詹树林.养护条件对混凝土早期收缩的影响[A].全国高强与高性能混凝土及其应用专题研讨会论文集[C],2005,(04):15-16页.
[28]Tatro Stephen B, Schrader Ernest K Thermal considerations for roller-compacted concrete[J].ACI Journal,1988,3:242-258.
[29]Ditchey E J, Schrader E K, Monksvill dam temperature studies[A],:Trans of the 16 International Congress on Large Dams[C],San Francisco 1988,:Vol.3:12-21.
[2]田雨泽,张彤.大体积混凝土施工的裂缝预控[J].低温建筑技术,2002,(3):4-6页.
[3]邢金栋,何健健,王希君.大跨度主梁大体积混凝土冬期施工应用[J].低温建筑技术,2006,(03):11-13页.
[4]高安平.大体积混凝土基础承台温度裂缝控制[J].福建建材,2006,(03):22-23页
[5]胡明华,刘雷军,陈冲.大体积混凝土温度裂缝的原因及防治措施[J].工程建设与设计,2007,(12):16-17页
[6]徐志光.大体积钢筋混凝土裂缝原因和控制技术[J].广东建材,2006,(07):10-11页
[7]梁铭健.大体积混凝土施工方案[J].广东建材,2008,(05):9-10页
[8]孔德水,李学金.超长大体积钢筋混凝土结构无缝施工技术[J].国防交通工程与技术,2006,(02):21-22页
[9]石峰,曹景文.大体积混凝土结构施工技术应用探讨[J].赤峰学院学报(自然科学版),2008,(05):25-26页.
[10]麦润强.大体积混凝土的施工技术[J].广东建材,2007,(04):20-21页
[11]戴镇潮.大体积混凝土的防裂[J].混凝土,2001,(09):21-22页
[12]周树奎.夏季浇筑大体积混凝土出现温度裂缝的防治[J].黑龙江水利科技,2007,(06):19-20页
[13]曹可之.大体积混凝土结构裂缝控制的综合措施[J].建筑结构,2002,(08):25-26页
[14]薛志宏,张延明.大体积混凝土施工工艺的探讨[J].吉林勘察设计,2007,(01):29-30页
[15]李彤.厚大体积混凝土承台施工温度裂缝控制实例[J].建筑技术开发,2001,(10):35-36页
[16]万小华.大体积混凝土施工技术探讨[J].山西建筑,2008,(12):13-14页.
[17]何文忠,王济川.钢筋砼结构及其屋面梁、板裂缝的分析鉴定和处理[J].四川建筑科学研究,1999,(03):15-16页
[18]胡明罡,贺群.由于温度效应导致框架梁开裂的事故分析[J].四川建筑科学研究,2000,(01):19-20页.
[19]赵海东,赵鸣,沈水明.超长钢筋混凝土结构的温度响应[J].四川建筑科 学研究,2000,(04):26-27页.
[20]王孔藩,许清风,朱雷.结构裂缝控制与渗漏防治[J].四川建筑科学研究,2003,(03):31-32页.
[21]胡建勤.高性能混凝土抗裂性能及其机理的研究[D].武汉理工大学,2002,(05):19-20页.
[22]彭小平.低热高性能高贝利特水泥大坝混凝土的研究[D].重庆大学,2002,(08):25-26页.
[23]张宇鑫.大体积混凝土温度应力仿真分析与反分析[D].大连理工大学,2002,(03):12-13页.
[24]刘勇军.水工混凝土温度与防裂技术研究[D].河海大学,2002,(02):18-19页
[25]谢先坤.大体积混凝土结构三维温度场、应力场有限元仿真计算及裂缝成因机理分析[D].河海大学,2001,(01),23-24页
[26]曾斌.北盘江特大桥锚碇大体积混凝土温控技术[A].开拓进取再创辉煌——贵州省公路学会2008年技术交流论文集[C],2008,(02):16-17页
[27]钱晓倩,詹树林.养护条件对混凝土早期收缩的影响[A].全国高强与高性能混凝土及其应用专题研讨会论文集[C],2005,(04):15-16页.
[28]Tatro Stephen B, Schrader Ernest K Thermal considerations for roller-compacted concrete[J].ACI Journal,1988,3:242-258.
[29]Ditchey E J, Schrader E K, Monksvill dam temperature studies[A],:Trans of the 16 International Congress on Large Dams[C],San Francisco 1988,:Vol.3:12-21.