高埋深软硬岩互层地质条件下敞开式TBM岩爆段施工方法研究

基于喜马拉雅山区域某软硬岩性互层地质条件下的深埋隧洞工程,为解决该区域TBM施工过程中的岩爆问题,统计分析了TBM施工过程中的岩爆特征;在施工过程中开展了多种岩爆规避试验,形成了一套较完整的有针对性的施工方法： 1）岩爆风险巡查常态化; 2）超前地质预报和超前处理措施相结合; 3）支护材料和支护方式合理化; 4）掘进参数动态调整。在后续的施工中加以应用,取得了较好的效果,可以为类似地质条件下的安全施工提供参考。     

深埋大断面黄土隧道初期支护受力特征分析

为避免初期支护局部破坏对深埋黄土隧道安全产生危害,依托甘肃省境内早胜3号隧道施工开展深埋大断面黄土隧道初期支护受力规律的现场试验研究。通过埋设振弦式传感器对围岩与初期支护接触压力、喷射混凝土应变、钢拱架应变、相邻钢拱架间作用力进行监测,同时建立模拟隧道施工的有限元计算模型,分析得到初期支护内力分布特点。结果表明： 1) 初期支护受力随时间表现出迅速增长—缓慢增长—逐渐稳定的特点,曲线在二次衬砌闭合12 d后基本稳定; 2)应力空间分布上部大下部小,偏压特性明显,荷载理论计算值偏小; 3) 拱顶及边墙区域为初期支护薄弱部位,需采取措施并加强监控量测; 4)数值计算表明锚杆末端轴力较小,设计中可考虑适当缩短锚杆长度。     

丽香铁路黄山哨隧道下穿岩堆段设计施工关键技术

以下穿岩堆段的丽香铁路黄山哨隧道为工程依托,对岩堆段地表开裂及洞内初期支护边墙严重变形的问题进行研究。地表埋设6根测斜管监测地表位移情况,洞内布置3个断面进行围岩压力、钢架内力、二次衬砌内力、初期支护与二次衬砌间的接触压力、锚杆轴力量测。在分析现场岩堆段洞内外受力机制及原因的基础上,根据数值计算结果优化二次衬砌断面型式及进一步加大二次衬砌厚度及配筋。采取以下措施控制隧道岩堆段变形： 1）地表岩堆土石接触面开裂处增设截排水措施; 2）加大隧道初期支护钢架型号及加长岩堆侧边墙径向系统锚杆; 3）加大隧道边墙轮廓曲率并优化隧道二次衬砌型式为圆顺型; 4）隧道预留变形量加大至30 cm; 5）隧道二次衬砌内净空预留50 cm补强空间; 6）隧道拱部设置42小导管超前支护。现场岩堆段采取以上措施后已顺利施工通过,根据洞内外监测结果显示,结构在安全可控范围内。     

基于HMM-SVR的船舶动力设备故障模式识别与状态预测研究

船舶动力设备因故障监测信号样本少、变化缓慢且数据特征呈非线性,使得设备故障模式的准确识别和状态预测比较难。鉴于此,文章研究了基于隐马尔科夫模型的故障模式识别方法,利用该模型将微弱变化的信号特征转换为变化较大的对数似然概率对故障模式实现有效识别。在此基础上进一步提出基于HMM-SVR的设备状态预测模型,将遗传算法用于支持向量回归模型参数寻优,并结合隐马尔科夫模型,实现对设备状态的预测。对船用柴油机进行仿真,结果表明上述模型具有较高的识别率,能准确预测船舶动力设备的当前状态。     

On Safety in Dismantling Temporary Strut of Super-large Tunnels with Double-layer Primary Support北大核心CSCD

More and more multiple-track tunnels and super-large section tunnels have been built, and disman- tling of temporary strut is a weak point of the whole structure during force transfer when the secondary lining is con- structed. It is significant to guarantee structure safety during dismantling of temporary strut. Little systematic re- search on safety in dismantling of temporary strut of the super-large section tunnel with double-layer primary support has been conducted, so the internal force and security of the two-layer primary support of the Xinkaotang tunnel were analyzed by a numerical analysis and site measurement, and it proves the effect of two-layer primary support on the safety during strut dismantling. The research results indicate that: (1) with constant support thickness and one-time longitudinal dismantling length, the safety factor of secondary primary support is larger than that of the first primary support, and the safety factor of the first primary support is larger than that of the single-layer primary support. Change range of safety factor for the first primary support is smaller than that of the single-layer primary support, and the safe factor for the single-layer primary support is smaller than that of the secondary primary support; (2) with the same support pattern, the safety factors increase firstly and then decrease with an increase of the onetime dismantling length. The calculated results of various cases show that the reasonable one-time dismantling length for this project is about 9 m. © 2018, Editorial Office of "Modern Tunnelling Technology". All right reserved.     

Effect of Explosion in a Gas Pipeline Compartment of a Utility Tunnel on Neighboring Metro Tunnels北大核心CSCD

In this paper the numerical simulation analysis of the effect of explosion in the gas pipeline compartment of a utility tunnel on neighboring metro tunnels was conducted using the software AUTODYN. The results show that the TNT equivalent in a fireproof partition with length of 200 m is 41.6 kg when the gas concentration in the gas pipeline compartment reaches 10%; the blast wave has much effect on the crown and arch waist of the round metro tunnel and it’s necessary to take some protective measures in both areas; when the surrounding soil is sand, the utili- ty tunnel is above the round metro tunnel and their alignments are in the same direction, the greater the vertical spacing between the utility tunnel and the metro tunnel, the smaller the effect of the blast wave on the metro tunnel; when the vertical spacing is 7.2 m, the maximum dynamic tensile stress is 1.86 MPa (including the static stress value of 1 MPa in the tunnel segment) and it is slightly smaller than the designed tensile strength of metro tunnel (about 1.89 MPa). The maximum vibration velocity and the maximum displacement meet the structural stability require- ments, so it is suggested the vertical spacing between the utility tunnel and metro tunnel shall not be less than 7.2 m. © 2018, Editorial Office of "Modern Tunnelling Technology". All right reserved.     

Analysis on the Characteristics and Development Trends of the Support Technology of High Ground Stress Tunnels in China北大核心CSCD

Combining the present situation and development trend of different tunnel support technologies at home and abroad, this paper analyzes the problems of rockburst in hard rock tunnels and large deformation in soft rock tunnels caused by high ground stress. It is concluded that: 1) regarding the rockburst problem, the current support technology is mainly influenced by the rock burst mechanism which is dominated by static factors, and so the used support components are generally of smaller deformation performance and "passive support" properties; 2) as the rockburst is the result of dynamic-static stress coupling, and only the anchor bolt has the "active support" attribute in the current "shotcrete+anchor bolt+wire net" support system, so the best support system should have the two functions of active support and energy release in terms of the rockburst problem, and the key focus of the research and development is anchorage members; 3) there are three main support types for large deformation in soft rock tunnels, e.g. the heavy support, layered support and yielding support. Among them, the heavy support system in underground cavern with large deformation is easy to induce excessive surrounding rock pressure, and so the applicable conditions are limited. The layered support system is still not the best choice due to its immature theoretical study, difficult determination of the thickness value and the installation time of each support layer and the interference to construction progress. With the characteristics of timely support and yielding while supporting, the yielding support system can give full play to the performance values of surrounding rocks and supporting materials, and make both of them reach the optimal state, so it is the best choice for supporting the soft rock tunnels with large deformations. © 2018, Editorial Office of "Modern Tunnelling Technology". All right reserved.     

阿赛线改造工程管道防腐保温补口方法

文中介绍了"防腐层+保温层+防护层+封口"复合防腐保温补口结构在阿赛线安全扩能改造工程中的应用,介绍了复合防腐保温补口结构的施工方法和检验方法,总结了现场施工中出现的问题和解决方法,对这种复合补口结构的优点和缺点进行了分析,最后提出了改进建议。     

油田注水管道的腐蚀研究与缓蚀剂评价

油田注水管线所输送介质复杂,腐蚀现象严重,存在安全隐患,一旦因腐蚀泄漏就会造成巨大的经济损失。因此,开展油田注水管道的腐蚀研究及采取措施减缓腐蚀具有重要意义。为此,对某油田注水管道现场采集注入水样及腐蚀产物,通过X-射线衍射及X-射线能谱仪进行分析,分析结果表明腐蚀产物主要是碳酸钙,同时含有一定量的氯化物、碳酸亚铁、硫化物等成分。通过电镜扫描腐蚀产物的微观形貌,发现存在氯离子腐蚀。并通过ICP-OES分析输送介质组分,针对其腐蚀特点及输送介质组分,采用失重法及电化学方法评价了引入季铵盐的咪唑啉缓蚀剂HJD2最佳质量分数及缓蚀机理,实验结果表明该缓蚀剂对该注水管道具有较好的缓蚀作用,在现场注水温度下,最佳质量分数(0.06%)时的缓蚀效率为95.1%,通过注入该缓蚀剂可以有效地减缓该注水管线的腐蚀,延长管线的使用寿命。     

管道输煤工程中煤浆沉降特性的应用分析

文中对煤浆沉降特性进行了详细分析,结论表明质量分数和粒度是影响煤浆颗粒沉降速度的主要因素。然后,从煤浆沉降特性角度出发,总结了管道输煤工程中煤浆制备、筛检超粗颗粒、煤浆储存、长距离管道输送以及终端脱水等环节需采取的相应措施及要求,为煤浆输送管道安全、经济、可靠地运行提供参考。