1)  buried pipeline
埋管管道
2)  burying pipe
埋管
1.
It analyzes causes on generating quality deficiency of drilling-grouting pile from burying pipe、clipping pipe、water seepage of conduit and collapse and introduces relative prevention measures and its treatment,which to ensure quality of grouting pile and prevent various accidents.
从埋管、卡管、导管进水、塌孔等方面分析了产生钻孔灌注桩质量缺陷的原因,并介绍了相应的防治处理措施,以保证灌注桩的质量,防止各种事故的发生。
3)  immersed tube
埋管
1.
The convection heat transfer coefficient of immersed tube in the heat transferring zone is impacted by the velocity of the moving zone nearby and its data and change trend are obviously different with those of the common bubbling bed.
垃圾焚烧系统中 ,内旋流流化床存在不同布风速度的移动区、流动区和换热区 ,处于换热区的埋管的对流换热系数受附近流动区气流参数的影响 ,其变化趋势及数值大小与普通鼓泡型流化床之间有明显不同 :最大的对流换热系数明显高于鼓泡床 ;换热区尚未流化时 ,对流换热系数已经大幅提高 ;整条换热曲线的变化比较平缓 ,易于流化床浓相床内换热。
2.
Heat transfer coefficients between immersed tube and bed materials in HSFB were measured with help of a fast response heat transfer probes.
在自建的旋流流化床冷态实验台上,采用基于微型热流密度感应薄膜制成的传热探针,测量了旋流流化床中埋管与床料的传热系数,研究流化风速、颗粒粒径、探针位置和密相区二次风射流等因素对埋管传热系数的影响。
3.
The heat transfer of immersed tubes in fluidized beds is influenced by the uneven distribution of fluidized air, and the coefficient of that is not only a function of fluidized air velocity in heat transfer zone, but also is correlative with the air velocity in fluidized zone nearby.
非均匀布风对流化床埋管换热特性有一定的影响,埋管的对流换热系数不仅是埋管所处换热区流化速度的函数,而且与相邻的流动区流化速度有一定关系。
4)  buried pipe
埋管
1.
By using thermal dynamic simulation and computational Fluid Dynamics (CFD) techniques in conjunction with the thermal comfort PMV / PPD model, investigates the indoor temperature, velocity and thermal comfort in rooms respectively with natural ventilation and ventilation with a buried pipe system.
将热舒适评价标准PMV/PPD模型与建筑动态热模拟及计算流体动力学(CFD)模拟相结合,分别对重庆地区自然通风房间和埋管送风通风房间进行了室内气候及热舒适性模拟与分析。
2.
The influencing factors of wear of buried pipes in ebullition boiler are analyzed,and the anti-wear measures are put forward.
分析了沸腾锅炉埋管磨损的影响因素,提出了抗磨措施。
3.
Analysis on the wear reason of buried pipe system for coal-sline CFB and its solving measures are presented herein.
介绍某循环流化床锅炉埋管系统损坏原因及解决方法。
5)  pipe laying method
埋管法
1.
This paper analyzes the sources of the gas on the coal mining surface and reasons of the gas accumulation in upper corner, and expounds the principles and practical application of pipe laying method in the goaf to treat the upper corner gas.
分析了采煤工作面的瓦斯来源及上隅角瓦斯积聚的原因,论述了采空区埋管法治理上隅角瓦斯的原理及实践应用。
6)  embedded pipe
预埋管
1.
Research on Repairing Concrete s Crack Through Embedded Pipe;
预埋管灌浆修补混凝土裂缝试验研究
2.
The turbine base frame operating layer of a 600 MW coal-fired unit is a complicated reinforced concrete structure,marked by dense steel bars and strictly required construction accuracy of various embedded parts,directly-buried bolts and embedded pipes.
600MW燃煤机组汽轮机基座运转层是一个复杂的钢筋混凝土结构,钢筋密集,各专业预埋件、直埋螺栓、预埋管的施工精确度要求非常高。
3.
Repairing concrete crack through embedded pipe is a new attempt in the field of structure repairing and a preparation for a kind of intelligent concrete with self-healing capability.
预埋管混凝土裂缝灌浆修补技术,是混凝土裂缝修补技术中的一种新尝试,同时也为新型自愈合仿生混凝土材料的研究和开发作前期准备。
参考词条
补充资料:埋管式地源热泵技术促进节能产业
直接利用地下土壤和地上空间季节性温度差,在夏季用于空调制冷、在冬季用于供暖供热的设想,如今已经变为现实。目前,这项地源热泵新技术经过众多天津市科研技术人员多年的反复试验已获得成功,天津市企业又将该技术发展为埋管式地源热泵,应用范围更加广泛。该技术现已运用在天津市红桥区老干部活动中心等工程中。  

   目前,国家鼓励发展可再生能源和新能源的高技术产业专项,其中太阳能供热和地源热泵供热制冷被列入重点领域。据介绍,地下土壤中蕴藏着丰富的温度资源,夏季地下土壤的温度低于地上空间的温度,冬季地下土壤的温度高于地上空间的温度。地源热泵技术就是利用这种季节性温度差,通过专门装置在夏季将地下土壤的低温资源转换到地上空间制冷,在冬季将地下土壤的高温资源转换到地上空间供热。而埋管式地源热泵更为直接,它把换热器埋设在土壤中,管内有密闭的水循环与土壤进行热量的交换,冬天吸收土壤蕴藏的热量,夏天把热量释放到土壤中储存,待冬天再用,对地下水资源不会造成影响。采用这种技术制造的中央空调不燃油、不燃气、不燃煤,根据需要灵活控制,开关由己,冷暖自如。    

   技术人员介绍说,按2005年全市房屋施工面积3000万平方米计算,如果其中1000万平方米建筑采用埋管式地源热泵技术,每年可节约标准煤11.9万吨,可减少烟气排放量13亿立方米,并且比传统中央空调系统运行费降低30%到60%。  
说明:补充资料仅用于学习参考,请勿用于其它任何用途。