Model-driven CT reconstruction algorithm for nano-resolution x-ray phase contrast imaging

The low-density imaging performance of a zone plate-based nano-resolution hard x-ray computed tomography(CT)system can be significantly improved by incorporating a grating-based Lau interferometer. Due to the diffraction, however,the acquired nano-resolution phase signal may suffer splitting problem, which impedes the direct reconstruction of phase contrast CT(nPCT) images. To overcome, a new model-driven nPCT image reconstruction algorithm is developed in this study. In it, the diffraction procedure is mathematically modeled into a matrix B, from which the projections without signal splitting can be generated invertedly. Furthermore, a penalized weighted least-square model with total variation(PWLSTV) is employed to denoise these projections, from which nPCT images with high accuracy are directly reconstructed.Numerical experiments demonstrate that this new algorithm is able to work with phase projections having any splitting distances. Moreover, results also reveal that nPCT images of higher signal-to-noise-ratio(SNR) could be reconstructed from projections having larger splitting distances. In summary, a novel model-driven nPCT image reconstruction algorithm with high accuracy and robustness is verified for the Lau interferometer-based hard x-ray nano-resolution phase contrast imaging.

Phase-field study for the splitting behaviour of precipitate under applied stress

This paper employs the phase-field method to study the splitting behaviour of a single coherent particle under an applied uniaxiai stress. It finds that the splitting behaviour is greatly influenced by the initial shape of precipitates, the bulk free energy condition, the degree of supersaturation and the ratio of the interfacial energy to the elastic strain energy, etc. The simulated results demonstrate that the aspect ratio of the particle determines whether the splitting can occur and how many split plates can be obtained. The splitting of particle is sensitive to the interracial energy, i.e. the splitting becomes more and more difficult with increasing the ratio of the interracial energy to the elastic strain energy. And increasing the magnitude of the applied stress is favourable to the splitting. The splitting process is also explained from the point of view of the corresponding diffusion potential.

THE SOLUTION FOR TRANSIENT TWO-PHASE FLOW BY SPLIT FLUX VECTOR METHOD

In this paper the transient two-phase flow equations and their eigenvalues are first introduced. The flux vector is then split into subvectors which just contain a specially signed eigenvalue. Using one-sided spatial difference operators finite difference equations and their solutions are obtained. Finally comparison with experiment shows the predicted results produce good agreement with experimental data.

Flux vector splitting solutions for coupling hydraulic transient of gas-liquid-solid three-phase flow in pipelines

The gas-liquid-solid three-phase mixed flow is the most general in multiphase mixed transportation. It is significant to exactly solve the coupling hydraulic transient problems of this type of multiphase mixed flow in pipelines. Presently, the method of characteristics is widely used to solve classical hydraulic transient problems. However, when it is used to solve coupling hydraulic transient problems, excessive interpolation errors may be introduced into the results due to unavoidable multiwave interpolated calculations. To deal with the problem, a finite difference scheme based on the Steger- Warming flux vector splitting is proposed. A flux vector splitting scheme is established for the coupling hydraulic transient model of gas-liquid-solid three-phase mixed flow in the pipelines. The flux subvectors are then discretized by the Lax-Wendroff central difference scheme and the Warming-Beam upwind difference scheme with second-order precision in both time and space. Under the Rankine-Hugoniot conditions and the corresponding boundary conditions, an effective solution to those points located at the boundaries is developed, which can avoid the problem beyond the calculation region directly induced by the second-order discrete technique. Numerical and experimental verifications indicate that the proposed scheme has several desirable advantages including high calculation precision, excellent shock wave capture capability without false numerical oscillation, low sensitivity to the Courant number, and good stability.

THE UPWIND OPERATOR SPLITTING FINITE DIFFERENCE METHOD FOR COMPRESSIBLE TWO-PHASE DISPLACEMENT PROBLEM AND ANALYSIS

For compressible two-phase displacement problem, a kind of upwind operator splitting finite difference schemes is put forward and make use of operator splitting, of calculus of variations, multiplicative commutation rule of difference operators, decomposition of high order difference operators and prior estimates are adopted. Optimal order estimates in L 2 norm are derived to determine the error, in the approximate solution.

宽带分裂波束探鱼仪相位校准与方位角估计模块的实现

宽带分裂波束探鱼仪在渔业资源调查中有着广泛应用,其方位角估计精度决定了能否准确确定目标鱼群的方向和位置。为了提高方位估计的精度和效率,提出了一种基于改进的正交数字下变频技术的相位校准算法,对该算法进行了仿真,并基于现场可编程逻辑门阵列(Field Programmable Gate Array,FPGA)实现了该算法;然后采用Vitis HLS平台构建了方位角估计知识产权(IP)核,在提高方位角估计精度的同时降低了浮点计算时延;最后用信号发生器进行了测试。结果显示:模块的方位角估计误差不超过0.05°,整体计算延迟不超过420 ns,逻辑资源消耗不超过45%,与系统指标相符。该研究成果已成功应用于宽带分裂波束探鱼仪中,显著提升了系统精度和性能,并产生了一定的经济效益。

牵引供电技术研究现状及关键性技术

我国电气化铁路里程稳居世界第一。牵引供电系统作为电气化铁路的能量心脏,其整体性能的优劣直接影响铁路的安全、稳定、经济运营。我国现有牵引供电系统面临着严重的电能质量问题,以及大量电分相制约列车速度等问题。为此,本文针对既有的分相供电系统与发展中的同相供电系统,分别从工作原理、发展现状、面临问题、关键技术等方面进行系统地梳理归纳。通过分析现有研究的成果以及不足之处,总结出构建新一代牵引供电系统仍需完善的关键性技术与未来研究趋势。希望为相关领域学者进行更深入的研究提供借鉴与参考。

基于复合控制的清洁能源光伏发电并网分相电流控制研究

清洁能源对可持续发展战略的实现具有重要意义。针对清洁能源光伏发电并网分相电流控制存在的问题,研究提出了一种基于电力电子变压器的分相电流复合控制策略。采用分相电流调控方式,以变换器输出的负载电流,向单相牵引负载供电,减小电网中各节点间的不对称。仿真实验结果表明:通过研究提出的基于电力电子变压器的复合控制策略,在电网侧电压大小不一致的情况下,通过调节逆变器的输出,仍能获得期望的交流电压。研究的成果在清洁能源光伏发电领域具有广泛的应用前景和重要的实际意义。

Ag/g-C_(3)N_(4)复合光催化剂的制备及其光解水产氢性能研究

通过光沉积法制备了银含量不同的银/石墨相氮化碳(Ag/g-C_(3)N_(4))复合光催化剂。通过扫描电子显微镜、X射线衍射仪、X射线光电子能谱仪、紫外-可见漫反射光谱仪等对其表面形貌、结构、化学组成及光学性能进行了表征和测试。结果表明:Ag/g-C_(3)N_(4)复合光催化剂主要由不规则的大块颗粒和许多大小、形状不一的小颗粒组成;Ag纳米颗粒的引入没有改变g-C_(3)N_(4)的晶体结构,Ag纳米颗粒以零价金属形式存在;Ag/g-C_(3)N_(4)复合光催化剂紫外区光吸收性能显著提高;Ag纳米颗粒的引入有效地抑制了光生电子-空穴对的复合,同时也促进了电荷的迁移。光解水产氢实验表明,Ag含量不同的Ag/g-C_(3)N_(4)复合光催化剂的产氢速率相比于g-C_(3)N_(4)都明显提升,且1%Ag/g-C_(3)N_(4)的产氢速率最高,达到了636.71μmol/(g·h),是g-C_(3)N_(4)产氢速率的8.9倍。

中红外量子级联激光器1×16锁相阵列设计

针对中红外波段单管量子级联激光器存在输出功率有限的问题,提出相干阵列通过光放大后合束提升激光器功率的方法,研究波长为4.6μm的1×16量子级联激光器锁相阵列的结构设计与优化。通过设计低传输损耗、高光限制因子的单模波导确定器件各层材料外延厚度;通过设计由100%反射率和50%反射率的布拉格反射镜组成的种子激光器实现4.6μm单波长激光输出;通过设计由1×2多模干涉耦合器(MMI)和弯曲波导组成的1×16分束器实现低损耗均匀分束并锁相;通过设计输出端口的Al_(2)O_(3)增透膜厚度并利用电注入放大的方式实现激光器阵列的大功率输出。最终确定波导上GaInAs层厚度为0.25μm,下GaInAs层厚度为0.1μm,上包层InP厚度为3μm,下包层InP厚度为1μm。当单模波导宽度为5μm时,波导损耗为0.055 dB·cm^(-1),光限制因子为0.733。100%反射镜刻蚀深度为0.2μm,周期为728 nm,占空比为0.5,周期数为1000;50%反射镜刻蚀深度为0.2μm,周期为727 nm,占空比为0.1,周期数为690;当阵列间距为35μm时,分束器尺寸为3080μm×605μm,损耗为0.254 dB,其中MMI尺寸为19μm×126μm;出射端口采用0.7μm的Al_(2)O_(3)增透膜,透射率达到0.975。最后比较了不同放大器阵列间距的温度与远场分布,相关研究结论可为量子级联激光器锁相阵列的研制提供设计参考。

民用建筑供配电系统中无功补偿设计探讨

以国家现行标准和规范为依据,结合项目设计经验,介绍民用建筑供配电系统中无功补偿设计,重点对无功补偿方式、串联电抗器电抗率选择、电容器补偿容量等问题进行研究和探讨。

低压配电网络线损计算方法研究

针对配电网管理要求的不断提高,线损的准确计算越来越重要,因此,文章分别介绍等值电阻法、分相等值电阻法、电压损失率法3种计算方法,说明各算法优缺点,选取实际三相不平衡低压配电网作为案例,通过分析得到:在计算三相不平衡低压配电网负荷时,采用分相等值电阻法的计算结果最精确,可以提高供电公司的经济效益,具有一定的应用价值。

500 kV断路器本体三相不一致防误动回路优化与运用

镇雄公司在用西开生产的LW13A-550/Y型500 kV分相操作断路器本体三相不一致保护回路存在多方面的安全隐患。断路器处于合闸状态,当三相不一致跳闸出口继电器故障或因人为误碰、误动将会使断路器误跳闸。介绍了在原有回路的基础上以精简的优化方式高效地解决了上述存在的问题,有效防止运行中的断路器误跳闸,进一步提高涉网设备安全性、稳定性、可靠性。

全分相无功补偿的策略研究与示范应用

随着电力系统对电能质量的要求越来越高,通过无功功率补偿可以提高电网功率因数、降低线路损耗、改善电压质量,因此对无功补偿装置的经济性、可靠性和精准性提出了更高要求。文章提出的“全分相无功补偿装置”开创性应用智能判据融合控制系统,创新采用了“124888”编码控制逻辑,实现“31档”全分相自动补偿,在补偿方式上能对每一相进行单独补偿,从而达到任一相无功平衡。并通过实例验证该方案的有效性,结果验证了该装置具有响应时间短、补偿精度高的优点。

钙钛矿相PbTiO_(3)-CdS微米片复合光催化剂的制备及其分解水产氢性能研究

为实现钙钛矿基半导体复合材料的高效光解水产氢,以钙钛矿相钛酸铅(PbTiO_(3),PTO)微米片为衬底,采用水热法制备钙钛矿相钛酸铅-硫化镉(PTO-CdS)微米片复合材料。探究水热温度和CdS负载量对复合材料的形貌及物相的影响;通过TEM、XPS及UV-Vis对复合材料的微结构、表面化学状态和光吸收特性进行表征;通过光解水产氢实验对复合材料的光催化活性进行测定和分析。结果表明:水热条件下,钙钛矿相PTO微米片对CdS的生长具有显著调控作用,与单独生长时尺寸约3μm的枝杈晶形貌不同,PTO-CdS微米片复合材料中的CdS为三角形纳米颗粒,尺寸约50 nm,均匀分散地生长在PTO微米片表面,且PTO与CdS之间界面清晰;水热温度和CdS负载量对复合材料的形貌和物相影响显著,水热温度为160℃、CdS负载量为6%时制备的PTO-CdS微米片复合材料尺寸均一,负载均匀,纯度和结晶度良好;PTO-CdS微米片复合材料在模拟太阳光下表现出光催化分解水产氢特性,其中PTO-CdS-6%的产氢速率达到141.45μmol/h/g,是PTO微米片产氢效率的17倍,是CdS枝杈晶产氢效率的53倍。该研究为高效钙钛矿基半导体复合光催化剂的设计提供了思路。

基于改进SVPWM控制的三相Split源逆变器研究

三相Split源逆变器是一种可以实现升压作用的新型变换器,通常可采用传统的SVPWM调制。本文研究了一种改进的SVPWM调制策略,通过对传统七段式SVPWM中零矢量的重新分配,能够有效提高逆变器的升压能力。仿真结果表明,相比传统SVPWM调制策略,采用改进SVPWM调制具有更高的输出电压和更好的THD特性,并且能够有效减少电感电流的低频分量。

空气源分体式热管-热泵供暖系统在煤矿井口防冻中的特性研究

为提高空气源热泵的性能,同时更好地满足煤矿井口防冻特殊工艺要求,将空气源热泵与热管技术相耦合,使用小压比热泵机组搭建了空气源分体式热管-热泵供暖系统实验平台。该耦合系统中蒸发器和冷凝器两端均采用相变传热的方式,并对其进行不同运行工况下的性能特性研究,结果表明:该耦合供暖系统即使在0℃左右的室外条件下,耦合机组的系统制热性能仍可达到4.5以上,远远优于传统空气源热泵机组。

Branch Quality Control of Gas-Liquid Two-Phase Flow Using a Novel T-Junction Type Distributor

In order to eliminate mal-distribution and ensure the side arm to produce desirable gas quality a special distributor is proposed. The experimental distributor mainly consists of a straight through section,a gas extraction line,a liquid extraction line and a side arm branch. A gas orifice and a liquid orifice are mounted at the gas and liquid extraction line respectively to control the outlet gas quality. The diameter of the liquid orifice was set to 2. 50 mm and three gas orifices with different size( dG= 2. 65,5. 00,10. 00 mm) were tested. The experiments were carried out at an air-water two-phase flow loop. The gas superficial velocity ranged from 6. 0 to 20. 0 m /s and the liquid superficial velocity was in the range of 0. 02- 0. 18 m /s. Flow patterns such as wave flow,slug flow and annular flow were observed. The gas quality of the side arm branch was found mainly determined by the flow area ratio of the gas orifice to the liquid orifice and independent of gas and liquid superficial velocity,flow patterns and extraction flux.

轴裂相整数槽集中绕组永磁容错电机及其匝间短路故障抑制研究

针对传统分数槽集中绕组永磁容错电机相间隔离能力弱、匝间短路故障抑制能力不足的问题,该文提出一种轴裂相整数槽集中绕组永磁容错电机。该电机各相绕组沿轴向独立排布,实现了相间的电、磁、热及物理隔离。首先,介绍轴裂相整数槽集中绕组电机的基本结构,阐述其工作原理,分析其电磁性能。然后,理论分析该轴裂相整数槽集中绕组永磁电机匝间短路故障的抑制机理。在考虑绝缘接触电阻变化的基础上,将所提轴裂相整数槽集中绕组永磁电机与传统分数槽集中绕组永磁电机在不同接触电阻情况下的故障电流、损耗和温升进行对比和分析。研究表明,相比于传统分数槽集中绕组永磁容错电机,该文所提轴裂相整数槽集中绕组永磁容错电机在故障的各个阶段,其匝间短路故障的严重性均较低,并且故障对健康相的影响很小,实现了从电机结构上抑制和隔离匝间短路故障的目的。最后,加工一台轴裂相整数槽集中绕组永磁电机样机,完成对样机匝间短路电流和故障温升的测试,实验结果与理论分析和仿真结果一致,证明了上述分析的正确性。

Strong interactions in molybdenum disulfide heterostructures boosting the catalytic performance of water splitting: A short review

Two-dimensional materials(2DMs) have attracted substantial attention due to their abundant active sites and their ultrahigh surface area for different catalytic applications due to the high lateral-longitudinal ratio. Transition metal dichalcogenides(TMDs), especially MoS2, as one of the 2DMs most often studied, have shown superior activity in electrochemical applications. Recently, combinations of different 2DMs have been widely studied, and they appear to be the most promising strategy available to develop state of the art catalysts for different reactions.In this article, we review the interactions between MoS2 and other materials as well as the novel assembly induced phase transitions of TMDs and their underlying mechanisms. Several methods for inducing the phase transition of TMDs by building MoS2-based heterostructures have been introduced. The electronic coupling between these counterparts has significantly enhanced their conductivity and optimized the energy states of the materials, thus introducing enhanced activity as compared to their original counterparts. The ideas summarized in this article may shed new light on and help to develop next-generation green energy materials by designing and constructing highly active two-dimensional catalysts for efficient water splitting.