基于摩阻和振荡力的水力振荡器安放位置计算方法

水力振荡器是目前缓解定向托压最有效的方法之一。在大斜度井、大位移井、水平井等复杂结构井中应用越来越广泛,并取得了较好的应用效果。但目前没有形成一套水力振荡器合理安放位置计算方法,导致应用效果参差不齐。基于摩阻和振荡力,建立了安放位置计算模型,并制作了优选图版。现场应用效果表明,该安放位置计算方法有效可行。可为水力振荡器现场应用提供理论支持和技术指导。

水力振荡器在C26-12X井中的应用

C26-12X井钻进至3 385 m时,滑动钻进出现严重的托压问题。为解决该问题,开展了水力振荡器缓解托压现场试验。应用效果表明,水力振荡器缓解托压效果明显,滑动钻进造斜效率提高1倍,滑动钻进行程钻速提高3.7倍,滑动钻进机械钻速提高2.17倍。C26-12X井水力振荡器的成功应用,为同类型的井解决托压问题提供了技术指导。

自激振荡钻具振荡力计算及影响因素分析

自激振荡钻具是利用自激振荡原理,将连续的高压钻井液转化为间歇周期性的脉冲射流,以增强钻头冲击力和减少岩屑重复破碎,进而提高机械钻速的井下工具。该工具以其结构简单、无密封件和工作可靠等优势得到广泛应用。然而由于自激振荡钻具的振荡力使用解析法难以计算,使得其结构优化和现场应用受到限制。文章基于大涡模型理论,对自激振荡钻具内部流场进行模拟,进而计算出工具振荡力的大小,并计算分析了钻井液密度、钻井液排量和工具最小水眼尺寸变化对振荡力的量化影响,指出钻井液密度和钻井液排量是影响工具振荡力的主要因素,同时现场应根据实际许用节流压降选用合适的最小水眼尺寸。文章的研究工作为工具内部结构的优化提供方法,同时也为现场合理使用该工具提供依据。

振荡螺杆钻具的关键结构优化与试验研究

针对水平井钻井托压导致的机械钻速低与钻头磨损的问题,研制了振荡螺杆钻具以应对该技术难题。通过数值仿真方法,研究了动阀片位于0°~360°不同旋转位置时,振荡螺杆内部流体的速度和压力分布规律以及旋转角度与阀孔半径对静阀片进出口压降和阀片之间有效过流面积的影响规律,对阀孔内径尺寸进行优化设计;利用振荡螺杆整机试验系统对其压降和过流面积等关键性能参数进行测试,在焦页81-9HF井对样机的使用效果进行了现场测试。结果表明:压降和过流面积曲线以45°为一个周期循环,在0°~360°范围内的总体形态为“波浪形”;阀孔半径为18.5 mm时静阀片进出口压降最大且阀孔通道的过流面积大小适中,产生的振荡力最大且流速不会太低而影响振荡力的传递效果;室内测试的压降、频率与振荡力结果论证了优化结构的可靠性;现场测试表明振荡螺杆可以减小钻头和提速工具的磨损,同时还可以提升钻进效率。该研究可以为振荡螺杆的结构优化设计提供一定的理论和技术参考。

具有奇异振荡的三维非自治线性Kelvin-Voigt-Brinkman-Forchheimer方程的一些估计

主要研究具有奇异振荡力的三维非自治线性Kelvin-Voigt-Brinkman-Forchheimer方程,先对其具有时间相关外力的辅助线性方程进行一般估计,再通过这些一般估计推导出其具有奇异振荡力线性方程的估计.

四氯化碳回收一例

四氯化碳回收一例山东省青州一中张秋花（２６２５００）高中化学课本第一册，学生分组实验，氯、澳、碘的性质实验，实验步骤（５）革取过程中，要回收到大量的碘和四氯化碳的混和液。为了节约资金，变废为宝，我们把四氯化碳作了回收利用。具体作法是：把回收后的混和液...

如何鉴别失效农药

乳剂类农药鉴别四法: 观察法 将药瓶静置,若药液浑浊不清或出现分层(油水分离),并有沉淀物生成或絮状物悬浮,说明该药剂已基本失效。 振荡法 对已出现油水分层的农药,先用力振荡药瓶,再静置1小时后观察,仍出现分层,说明该药液已变质失效。 热溶法

农药是否失效鉴别法

据《经济日报》介绍,正确使用农药,是防治病虫害、保证农业高产稳产的关键一环。眼下,令农民发愁的是市场上出现了不少假冒伪劣农药,有些人误用因过期而失效的农药,不仅起不到杀虫防灾的作用,有的反而起了负面作用。

Nucleation of Kinetic Ising Model Under Oscillating Field

We have studied the nucleation process of a two-dimensional kinetic Ising model subject to a bias oscillating external field, focusing on how the nucleation time depends on the oscillation frequency. It is found that the nucleation time shows a clear-cut minimum with the variation of oscillation frequency, wherein the average size of the critical nuclei is the smallest, indicating that an oscillating external field with an optimal frequency can be much more favorable to the nucleation process than a constant field. We have also investigated the effect of the initial phase of the external field, which helps to illustrate the occurrence of such an interesting finding.

Coarse-grained Simulations of Chemical Oscillation in Lattice Brusselator System

The oscillation behavior of a two-dimension lattice-gas Brusselator model was investigated. We have adopted a coarse-grained kinetic Monte Carlo （CG-KMC） procedure, where m×m microscopic lattice sites are grouped together to form a CG cell, upon which CG processes take place with well-defined CG rates. Such a CG approach almost fails if the CG rates are obtained by a simple local mean field （s-LMF） approximation, due to the ignorance of correlation among adjcent cells resulting fl＇om the trimolecular reaction in this nonlinear system. By proper incorporating such boundary effects, thus introduce the so-cMled b-LMF CG approach. Extensive numerical simulations demonstrate that the b-LMF method can reproduce the oscillation behavior of the system quite well, given that the diffusion constant is not too small. In addition, the deviation from the KMC results reaches a nearly zero minimum level at an intermediate cell size, which lies in between the effective diffusion length and the minimal size required to sustain a well-defined temporal oscillation.

Characterizing pressure fluctuation into single-loop oscillating heat pipe

The pressure characteristics inside single loop oscillating heat pipe （OHP） having 4.5 mm inner diameter copper tube with the loop height of 440 mm were addressed. Distilled water was used as working fluid inside the OHP with different filling ratios of 40%, 60% and 80% of total inside volume. Experimental results show that the thermal characteristics are significantly inter-related with pressure fluctuations as well as pressure frequency. And the pressure frequency also depends upon the evaporator temperature that is maintained in the range of 60-96 ℃. Piezoresistive absolute pressure sensor （Model-Kistler 4045A5） was used to take data. The investigation shows that the filling ratio of 60% gives the highest inside pressure magnitude at maximum number of pressure frequency at any of set evaporator temperature and the lowest heat flow resistance is achieved at 60% filling ratio.

A new wide area damping controller design method considering signal transmission delay to damp interarea oscillations in power system

Wide area damping controller(WADC) is usually utilized to damp interarea low frequency oscillation in power system. However, conventional WADC design method neglects the influence of signal transmission delay and damping performance of WADC designed by the conventional method may deteriorate or even has no effect when signal transmission delay is beyond delay margin, an index that denotes delay endurance degree of power system. Therefore, a new design method for WADC under the condition of expected damping factor and required signal transmission delay is presented in this work. An improved delay margin with less conservatism is derived by adopting a new Lyapunov-Krasovskii function and more compact bounding technique on the derivative of Lyapunov-Krasovskii functional. The improved delay margin, which constructs the correlation of damping factor and signal transmission delay, can be used to design WADC. WADC designed by the proposed method can ensure that power system satisfies expected damping factor when WADC input signal is delayed within delay margin. Satisfactory test results demonstrate the effectiveness of the proposed method.

Pressure distribution inside oscillating heat pipe charged with aqueous Al_2O_3 nanoparticles,MWCNTs and their hybrid

Effective thermal performance of oscillating heat pipe(OHP)is driven by inside pressure distribution.Heat transfer phenomena were reported in terms of pressure and frequency of pressure fluctuation in multi loop OHP charged with aqueous Al2O3 and MWCNTs/Al2O3 nanoparticles.The influences on thermal resistance of aqueous Al2O3,MWCNTs as well as the hybrid of them in OHP having 3 mm in inner diameter were investigated at 60% filling ratio.Experimental results show that thermal characteristics are significantly inter-related with pressure distribution and strongly depend upon the number of pressure fluctuations with time.Frequency of pressure depends upon the power input in evaporative section.A little inclusion of MWCNTs into aqueous Al2O3 at 60% filling ratio achieves the highest fluctuation frequency and the lowest thermal resistance at any evaporator power input though different nanofluids cause different thermal performances of OHPs.

Evaluation of the Madden-Julian oscillation in HiRAM

The aim of this study was to understand the cause of Madden–Julian oscillation(MJO)bias in the High Resolution AtmosphericModel(HiRAM)driven by observed SST through process-oriented diagnosis.Wavenumber-frequency power spectrum and composite analyses indicate that HiRAM underestimates the spectral amplitude over theMJO band and mainly produces non-propagating rather than eastward-propagating intraseasonal rainfall anomalies,as observed.Column-integrated moist static energy(MSE)budget analysis is conducted to understand the MJO propagation bias in the simulation.It is found that the bias is due to the lack of a zonally asymmetric distribution of the MSE tendency anomaly in respect to the MJO convective center,which is mainly attributable to the bias in vertical MSE advection and surface turbulent flux.Further analysis suggests that it is the unrealistic simulation of MJO vertical circulation anomalies in the upper troposphere as well as overestimation of the Rossby wave response that results in the bias.

Simulation of the QBO in IAP-AGCM:Analysis of momentum budget

The quasi-biennial oscillation(QBO),a dominant mode of the equatorial stratospheric(~100–1 hPa)variability,is known to impact tropospheric circulation in the middle and high latitudes.Yet,its realistic simulation in general circulation models remains a challenge.The authors examine the simulated QBO in the 69-layer version of the Institute of Atmospheric Physics Atmospheric General Circulation Model(IAP-AGCML69)and analyze its momentum budget.The authors find that the QBO is primarily caused by parameterized gravity-wave forcing due to tropospheric convection,but the downward propagation of the momentum source is significantly offset by the upward advection of zonal wind by the equatorial upwelling in the stratosphere.Resolved-scale waves act as a positive contribution to the total zonal wind tendency of the QBO over the equator with comparable magnitude to the gravity-wave forcing in the upper stratosphere.Results provide insights into the mechanism of the QBO and possible causes of differences in models.

Effects of Arbitrarily Directed Field on Spin Phase Oscillations in Biaxial Molecular Magnets

Quantum phase interference and spin-parity effects are studied in biaxial molecular magnets in a magnetic field at an arbitrarily directed angle. The calculations of the ground-state tunnel splitting are performed on the basis of the instanton technique in the spin-coherent-state path-integral representation, and complemented by exactly numerical diagonalization. Both the Wentzel–Kramers–Brillouin exponent and the pre-exponential factor are obtained for the entire region of the direction of the field. Our results show that the tunnel splitting oscillates with the field for the small field angle, while for the large field angle the oscillation is completely suppressed. This distinct angular dependence, together with the dependence of the tunnel splitting on the field strength, provides an independent test for spin-parity effects in biaxial molecular magnets. The analytical results for the molecular magnet are found to be in good agreement with the numerical simulations, which suggests that even the molecular magnet with total spin is large enough to be treated as a giant spin system.

Low Frequency Oscillations of the Heat Distribution in the Global Upper Ocean Layers

The heat distributions in the upper layers of the ocean have been studied and some important low frequency oscillations （LFOs） are already found and quantified by using various characteristic factors. In this paper, the ‘heat center＇ of a sea area is defined with a simple method. Then the temperature data set of the upper layer of the global ocean （from surface down to 400 m, 1955-2003） is analyzed to detect the possible LFOs. Not only some zonal LFOs, which were reported early, but also some strong LFOs of the vertical and meridional heat distribution, which might imply some physical sense, are detected. It should be noted that the similar vertical oscillation pattern can be found in the Pacific Ocean, Atlantic Ocean and Indian Ocean. Results from some preliminary studies show that the vertical LFO might be caused by the solar irradiance anomalies. This study may help reveal some unknown dynamical processes in the global oceans and may also benefit other related studies.

Improving Dynamic Stability of Yunnan Provincial and South China Power System by PSS

For solving the dynamic instability problem of Yunnan Provincial Power System (YNPS) and the South China Interconnected Power System (SCIPS), Lubuge Hydropower Station was chosen to install Power System Stabilizer (PSS). This paper introduces the principles and methods of parameter selection for PSS, in addition to field test. The test results show that the PSS installed can significantly improve the system damping.

Validity and reliability of three methods of stiffness assessment

Background：Stiffness is commonly assessed in relation to injury and athletic performance.The purpose of this research was to compare the validity and reliability of 3 in vivo methods of stiffness assessment using 1 cohort of participants.Methods：To determine inter-day reliability,15 female netballers were assessed for stiffness twice within 1 week using unilateral hopping（vertical stiffness）,free oscillations of the calf,and myometry of various muscles of the triceps surae.To establish convergent construct validity,stiffness was compared to static and dynamic strength measurements.Results：Test–retest stiffness results revealed that vertical stiffness produced moderate to high reliability results and myometry presented moderate to very high reliability.In contrast,the free oscillation technique displayed low to moderate reliability.Vertical stiffness demonstrated a significa t correlation with rate of force development during a squat jump,whilst myometer stiffness measurements from 3 sites in the lower limb revealed significan correlations with isometric rate of force development.Further,significan negative correlations were evident between the eccentric utilisation ratio and various myometer stiffness results.No relationships were established between the free oscillation technique and any of the performance measurements.Conclusion：These results suggest that vertical stiffness and myometry are valid and reliable methods for assessing stiffness.

Non-linearity in the dynamic world of human movement

Non-linear dynamics,fractals,periodic oscillations,bifurcations,chaos,and other terminologies have been used to describe human biological systems in the literature for a few decades.The eight manuscripts included in this special issue discussed the historical background,