To improve the transmission performance of XCTD channel, this paper proposes a method to measure directly and fit the channel transmission characteristics by using frequency sweeping method. Sinusoidal signals with a ...To improve the transmission performance of XCTD channel, this paper proposes a method to measure directly and fit the channel transmission characteristics by using frequency sweeping method. Sinusoidal signals with a frequency range of 100 Hz to 10 k Hz and an interval of 100 Hz are used to measure transmission characteristics of channels with lengths of 300 m, 800 m, 1300 m, and 1800 m. The correctness of the fitted channel characteristics by transmitting square wave, composite waves of different frequencies, and ASK modulation are verified. The results show that when the frequency of the signal is below 1500 Hz, the channel has very little effect on the signal. The signal compensated for amplitude and phase at the receiver is not as good as the uncompensated signal.Alternatively, when the signal frequency is above 1500 Hz, the channel distorts the signal. The quality of signal compensated for amplitude and phase at receiver is better than that of the uncompensated signal. Thus, we can select the appropriate frequency for XCTD system and the appropriate way to process the received signals. Signals below1500 Hz can be directly used at the receiving end. Signals above 1500 Hz are used after amplitude and phase compensation at the receiving end.展开更多
How long the ultra deep well can extend and what is the ultra deep well's maximum hydraulic extension depth are always concerned and studied by drilling engineers. The well's maximum hydraulic extension depth ...How long the ultra deep well can extend and what is the ultra deep well's maximum hydraulic extension depth are always concerned and studied by drilling engineers. The well's maximum hydraulic extension depth can be predicted by the maximum hydraulic extension depth prediction model. To overcome the disadvantage that previous prediction model did not consider the effects of temperature and only applies to horizontal wells, a prediction model of maximum hydraulic extension depth for ultra deep wells considering effects of temperature is established. Considering the effects of temperature coupled with the constraints of drilling pump rated pressure and rated power, the prediction result of ultra deep well's maximum hydraulic extension depth is modified. An ultra deep well developed by Sinopec in Shunbei oilfield, China, is analyzed, and its wellbore temperature profile and maximum hydraulic extension depth are analyzed and predicted. Results show that the maximum hydraulic extension depth with considering temperature is larger than that without considering temperature. With the identical depth, the higher inlet temperature and the greater geothermal gradient mean the higher drilling fluid temperatures in the drill string and annulus as well as the larger maximum hydraulic extension depth. Besides, the maximum depth decreases with the increase in drilling fluid flow rate and density, while it increases with the increase in drilling pump rated pressure and rated power. To ensure the designed depth can be reached, there exists the maximum drilling fluid flow rate and density, as well as the minimum drilling pump rated pressure and rated power. This study is important for accurately predicting the ultra deep well's maximum depth within the limit capacity of drilling pump. In addition, it also plays a major role in avoiding drilling hazards.展开更多
结合CTD/LADCP(Conductivity-Temperature-Depth/Lowed Acoustic Doppler Current Profiler)观测实例,从作业海况、水下单元架构、水下姿态三方面分析研究下放式海洋观测中同轴铠装缆自缠绕/打结状况发现,仪器观测架在布放过程中存在旋...结合CTD/LADCP(Conductivity-Temperature-Depth/Lowed Acoustic Doppler Current Profiler)观测实例,从作业海况、水下单元架构、水下姿态三方面分析研究下放式海洋观测中同轴铠装缆自缠绕/打结状况发现,仪器观测架在布放过程中存在旋转现象,旋转产生的扭力作用于同轴铠装缆;扭力得不到释放,在海况较差的情况下极易造成同轴铠装缆的自缠绕/打结。为解决这些问题,本文进一步提出了一套实用的改进方案,在既保证能够在较差海况下作业、又不减少观测仪器的前提下,改进仪器观测架和同轴铠装缆的连接结构,同时增加机械转环及附属结构。观测实践证明,该方案可以有效避免与CTD/LADCP观测类似的下放式观测中同轴铠装缆因自缠绕造成的“打结”现象的出现,大大提高了现场观测效率,保证了仪器安全和数据顺利传输。该技术源自基本海洋观测实践,可为广大海洋调查工作者提供有益的借鉴。展开更多
建立了基于低温等离子体(Low temperature plasma)剥蚀系统将固体样品直接引入电感耦合等离子体质谱(ICP-MS)并用于电路板镀层中Au,Ni和Cu的深度分析。此实验中采用介质阻挡放电(DBD)方式产生低温等离子体探针,逐层剥蚀样品表面,由ICPM...建立了基于低温等离子体(Low temperature plasma)剥蚀系统将固体样品直接引入电感耦合等离子体质谱(ICP-MS)并用于电路板镀层中Au,Ni和Cu的深度分析。此实验中采用介质阻挡放电(DBD)方式产生低温等离子体探针,逐层剥蚀样品表面,由ICPMS检测元素信号。对DBD所用放电气体种类、外加电场功率、放电气体流速和采样深度等实验条件进行优化。在优化条件下,应用LTP-ICPMS在30 s内完成电路板镀层(20μm Au/10μm Ni/Cu基底)的逐层剥蚀和深度分析,元素种类和分层顺序与X射线光电子能谱(XPS)相吻合,镀层的分辨率可拓展至微米水平,表明此技术可直接用于固体样品的深度分析。展开更多
基金financially supported by the National Key Research and Development Program of China(Grant No.2016YFC1400400)
文摘To improve the transmission performance of XCTD channel, this paper proposes a method to measure directly and fit the channel transmission characteristics by using frequency sweeping method. Sinusoidal signals with a frequency range of 100 Hz to 10 k Hz and an interval of 100 Hz are used to measure transmission characteristics of channels with lengths of 300 m, 800 m, 1300 m, and 1800 m. The correctness of the fitted channel characteristics by transmitting square wave, composite waves of different frequencies, and ASK modulation are verified. The results show that when the frequency of the signal is below 1500 Hz, the channel has very little effect on the signal. The signal compensated for amplitude and phase at the receiver is not as good as the uncompensated signal.Alternatively, when the signal frequency is above 1500 Hz, the channel distorts the signal. The quality of signal compensated for amplitude and phase at receiver is better than that of the uncompensated signal. Thus, we can select the appropriate frequency for XCTD system and the appropriate way to process the received signals. Signals below1500 Hz can be directly used at the receiving end. Signals above 1500 Hz are used after amplitude and phase compensation at the receiving end.
基金supported by Sinopec Research Institute of Petroleum Engineering,Beijing,Chinathe National Natural Science Foundation of China (Grant No. 51821092)+1 种基金the New Technology for Design and Control of Complex Well and Cluster Well (Grant No. 2017ZX05009-003)the Key Technology of Drilling Technology and Wellbore Working Fluid(Grant No. 2016YFC0303303)。
文摘How long the ultra deep well can extend and what is the ultra deep well's maximum hydraulic extension depth are always concerned and studied by drilling engineers. The well's maximum hydraulic extension depth can be predicted by the maximum hydraulic extension depth prediction model. To overcome the disadvantage that previous prediction model did not consider the effects of temperature and only applies to horizontal wells, a prediction model of maximum hydraulic extension depth for ultra deep wells considering effects of temperature is established. Considering the effects of temperature coupled with the constraints of drilling pump rated pressure and rated power, the prediction result of ultra deep well's maximum hydraulic extension depth is modified. An ultra deep well developed by Sinopec in Shunbei oilfield, China, is analyzed, and its wellbore temperature profile and maximum hydraulic extension depth are analyzed and predicted. Results show that the maximum hydraulic extension depth with considering temperature is larger than that without considering temperature. With the identical depth, the higher inlet temperature and the greater geothermal gradient mean the higher drilling fluid temperatures in the drill string and annulus as well as the larger maximum hydraulic extension depth. Besides, the maximum depth decreases with the increase in drilling fluid flow rate and density, while it increases with the increase in drilling pump rated pressure and rated power. To ensure the designed depth can be reached, there exists the maximum drilling fluid flow rate and density, as well as the minimum drilling pump rated pressure and rated power. This study is important for accurately predicting the ultra deep well's maximum depth within the limit capacity of drilling pump. In addition, it also plays a major role in avoiding drilling hazards.
文摘结合CTD/LADCP(Conductivity-Temperature-Depth/Lowed Acoustic Doppler Current Profiler)观测实例,从作业海况、水下单元架构、水下姿态三方面分析研究下放式海洋观测中同轴铠装缆自缠绕/打结状况发现,仪器观测架在布放过程中存在旋转现象,旋转产生的扭力作用于同轴铠装缆;扭力得不到释放,在海况较差的情况下极易造成同轴铠装缆的自缠绕/打结。为解决这些问题,本文进一步提出了一套实用的改进方案,在既保证能够在较差海况下作业、又不减少观测仪器的前提下,改进仪器观测架和同轴铠装缆的连接结构,同时增加机械转环及附属结构。观测实践证明,该方案可以有效避免与CTD/LADCP观测类似的下放式观测中同轴铠装缆因自缠绕造成的“打结”现象的出现,大大提高了现场观测效率,保证了仪器安全和数据顺利传输。该技术源自基本海洋观测实践,可为广大海洋调查工作者提供有益的借鉴。