A dual-beam piezo-magneto-elastic wake-induced vibration energy harvesting system for high-performance wind energy harvesting

Wind-induced vibration energy harvesting has a great potential for utilizing wind energy to supply power for low-powered devices.To improve the working performance of energy harvesters effectively,a suitable structural design is crucial.This paper proposes a dual-beam piezo-magneto-elastic wake-induced vibration energy harvesting system to enhance the functional performance of aeroelastic energy harvesters in environments with variable wind speeds.The system contains two piezoelectric beams coupled by magnets(forming upstream and downstream energy harvesters),and each beam is attached with a foam cylinder.A corresponding dynamic model is provided,and output characteristics are obtained at different wind speeds.Results and experimental verification indicate that both upstream and downstream energy harvesters can realize efficient energy harvesting.When the wind speed exceeds a certain critical value,the amplitudes of the system’s displacement and voltage are high.The wind speed threshold value is approximately 1.25 m/s.When the wind speed and magnet spacing are 10.2 m/s and 20 mm,respectively,the output power of the system reaches 4.9×10^(−4)W.Moreover,the wind speed threshold value of the proposed system can be adjusted by an equivalent nonlinear restoring force.

High-precision alkali-atom density measurement and control methods using light absorption for dual-beam SERF magnetometers

The alkali-atom density measurement method based on light absorption is highly suitable for a spin-exchange relaxationfree(SERF)atomic magnetometer because of its high-precision measurement and complete nonmagnetic interference.In this study,the optical rotation angle detection system based on polarization balance detection is utilized to realize the alkali-atom density real-time measurement without affecting magnetic field measurement.We discovered that there exists an optimal frequency detuning of the probe light,which offers the highest sensitivity in alkali-atom density measurement and the lowest susceptibility to temperature fluctuations in terms of the scale factor.In contrast to conventional light absorption measurements based on pump light,this method demonstrated a threefold improvement in alkali-atom density measurement sensitivity while remaining immune to ambient magnetic fields and incident light intensity fluctuations.Furthermore,we utilized this method to achieve closed-loop temperature control with an accuracy of 0.04℃.

Terahertz dual-beam leaky-wave antenna based on composite spoof surface plasmon waveguide

In this paper, we propose a single-port dual-beam leaky-wave antenna(LWA) in the terahertz(THz) band based on a composite spoof surface plasmon polariton(SSPP) waveguide. The antenna can generate three independent transmission channels by exciting two independent modes inherent to hole and groove structures, respectively. By periodic modulation of the hole and groove structures, we achieve dual-beam scanning through a broad radiation angle using only the -1st space harmonics of the two modes, hence avoiding the instability of the -2rd space harmonic. Within the operating frequency range of 0.62—0.85 THz, the gain ranges from 13.5 d Bi to 17 d Bi for the backward beam, and from 6 d Bi to 11.8 d Bi for the forward beam. The antenna can accomplish continuous backward beam through broadside to forward beam scanning with a total scanning range of 116° and an average efficiency of about 92%. The antenna exhibits a great potential in the design of multi-transceiver radar system in the THz band and multi-beam LWAs.

In-situ transmission electron microscopy observation of the evolution of dislocation loops and gas bubbles in tungsten during H2+and He+dual-beam irradiation

Dislocation loop and gas bubble evolution in tungsten were in-situ investigated under 30 keV H_(2)^(+)and He^(+)dual-beam irra-diation at 973 K and 1173 K.The average size and number density of dislocation loops and gas bubbles were obtained as a function of irradiation dose.The quantitative calculation and analysis of the migration distance of 1/2<111>loops at low irradiation dose indicated that the main mechanism of the formation of<100>loops should be attributed to the high-density helium cluster inducement mechanism,instead of the 1/2<111>loop reaction mechanism.H2+and He+dual-beam irradiation induced the formation of<100>loops and 1/2<111>loops,while increasing the irradiation temperature would increase<100>loop percentage.The percentage of<100>loops was approximately 18.6%at 973 K and increased to 22.9%at 1173 K.The loop reaction between two 1/2<111>loops to form a large-sized 1/2<111>loop was in-situ observed,which induced not only the decrease of the number of 1/2<111>loops but also the significant increase of their sizes.The<100>loops impeded the movement of dislocation line and tended to escape from it instead of being absorbed.With the increase of irradiation dose,the yield strength increment(Δ_(σloop))caused by the change of loop size and density increased first and then decreased slightly,while the yield strength increment(Δ_(σbubble))caused by the change of bubble size and density always increased.Meanwhile,within the current irradiation dose range,Δ_(σloop)was much larger thanΔ_(σbubble).

Fast dual-beam alignment method for stimulated emission depletion microscopy using aggregation-induced emission dye resin

A stimulated emission depletion is capable of breaking the diffraction limit by exciting fluorescent molecules with a solid Gaussian beam and quenching the excited molecules with another donut beam through stimulated emission.The coincidence degree of these two beams in three dimensions will significantly influence the spatial resolution of the microscope.However,the conventional alignment approach based on raster scanning of gold nanoparticles by the two laser beams separately suffers from a mismatch between fluorescence and scattering modes.To circumvent the above problems,we demonstrate a fast alignment design by scanning the second beam over the fabricated sample,which is made of aggregation-induced emission(AIE)dye resin.The relative positions of solid and donut laser beams can be represented by the fluorescent AIE from the labeled spots in the dye resin.This design achieves ultra-high resolutions of 22 nm in the x/y relative displacement and 27 nm in the z relative displacement for fast spatial matching of the two laser beams.This study has potential applications in scenarios that require the spatial matching of multiple laser beams,and the field of views of different objectives,for example,in a microscope with high precision.

一种分光光度法实现的多参数水质在线检测仪

针对传统分光光度法实现的水质在线检测仪存在的检测参数单一、效率低下、光源受环境温度干扰等问题,设计了一种高效快速的多参数水质在线检测仪。该仪器以总磷、CODCr、氨氮为检测对象,通过优化检测流程提高了检测效率。同时采用双光束测量法补偿光源受环境温度的影响。经性能测试显示,该仪器在示值误差、重复性、零点漂移、量程漂移等关键指标上均优于国家标准。

双驱动射频负氢离子源匹配网络设计与实验研究

随着磁约束聚变实验装置对中性束注入器的输出束流强度与脉冲时间的要求越来越高,开展高功率大面积射频离子源的研究迫在眉睫。为了实现大面积、高密度均匀等离子体放电,基于多驱动射频离子源的设计是当前的发展趋势,而阻抗匹配网络是射频功率源将最大功率输送至线圈并耦合至等离子体的关键,故对其结构设计和调谐特性的研究是不可或缺的。基于前期在单驱动射频离子源的研究基础上,结合双驱动射频离子源的放电需求,开展了双驱动阻抗匹配网络优化结构的设计与分析,通过实验中对匹配网络的调谐,成功实现了140 kW高功率和25 kW/1 000 s长脉冲的稳定运行。随后在等离子体稳定放电的基础上研究了两个驱动器之间的功率分配均匀性问题,实验结果表明了该匹配网络的优化设计合理可行,上下驱动器的射频功率分配基本均匀。

基于FIB-SEM双束系统制备TEM原位加热样品

聚焦离子束-扫描电子显微镜(FIB-SEM)双束系统因具有定位精准、加工精度高等优点,被广泛用于微纳尺度样品的高质量制备,如定点截面加工、纳米图形加工、透射电子显微镜(TEM)和三维原子探针样品等。然而,随着TEM原位表征技术的发展,对样品的制备提出了更高的要求。其中,TEM原位加热样品由于受加热芯片几何形状的限制,在样品的提取、转移和减薄等工序上具有较高的技术难度。利用FIB-SEM双束系统,在传统TEM样品制备工艺基础上,通过合理改进制备流程和参数,调整样品提取和减薄顺序,并配合低电压清扫工艺,成功制备了可用于原位加热和表征的TEM样品。

一种宽带双极化波束切换微带天线的设计

以海港码头集装箱堆场的远程(无人化)操控系统为应用背景,提出一种控制方法简单和可实现性好的宽带双极化波束切换微带天线系统。该系统整体由微带阵列天线和波束控制电路两部分组成,其中微带阵列天线包含天线阵A和天线阵B两种类型。所涉及的双极化微带天线采用新型双贴片结构,使得天线实现较宽工作带宽的同时保持较高的极化隔离度;同时,通过在底层辐射贴片上开正方形环槽,实现天线的小型化。波束控制电路采用SP6T射频开关芯片,通过合理的电路设计布局,将两组射频开关集成于一块电路板,在保证低损耗、高速的多波束切换的同时减小了电路尺寸。实测结果表明:该天线的带宽达到21.8%(反射系数小于-10 dB),隔离度大于20 dB,在整个工作频段内该天线系统六个波束能够无缝覆盖-90°~90°工作区,增益优于12 dBi,双极化性能良好。

GaAs基高性能MEMS微波功率检测芯片

为了提高电容式MEMS微波功率检测芯片的性能,设计了一种GaAs基高性能MEMS微波功率传感芯片。通过建立双导固支梁电容模型,分析了传感芯片的传输特性、过载功率与灵敏度特性。在双导固支梁电容模型中提出了平行极板的两个等效条件;同时提出了一种新的梁宽等效方式,解决了双梁结构等效梁宽的失配问题,减小了模型的相对误差。双导固支梁电容模型很好地解释了导向梁的厚长比与初始高度对传感器过载功率和灵敏度的影响。测试结果表明,双导固支梁MEMS微波功率传感芯片在200 mW输入功率内的灵敏度为14.3 fF/W,而灵敏度的理论值为13.5 fF/W,两者的相对误差仅5.6%。因此,该理论模型对固支梁MEMS微波功率传感芯片的设计具有一定的借鉴意义。

大跨度公铁两用双层钢桁桥涡激振动控制研究

桥梁的涡激振动主要受到主梁断面的气动外形、结构动力特性与来流特性的影响,而大跨桥梁是典型的风致敏感结构,所以在大跨度桥梁的设计中应当引起重视。以某大跨度公铁两用双层板桁组合桁架桥为背景,在XNJD-1回流串联风洞中进行了风洞试验,研究了该主梁的涡激振动现象。通过计算流体动力学(computational fluid dynamics, CFD)数值模拟分析了其主梁断面的涡激振动机理,并且将展向周期摄动法应用于钢桁梁的涡激振动控制,采取了一系列气动控制措施来抑制主梁的涡激振动,其中L型分流板与波浪形风嘴完全抑制了主梁的涡激振动。还通过风洞试验研究了波浪形风嘴的几何参数对抑振效果的影响,试验结果表明,波浪形风嘴的抑振效果对幅值变化比较敏感,增大幅值可以有效抑制主梁的涡激振动。

基于太赫兹真空器件的微型阴极抑制膜特性研究

为满足太赫兹真空器件对阴极的大电流密度、小电子注尺寸需求,利用双离子束辅助沉积技术在浸渍钪酸盐阴极表面沉积Ta/Zr抑制膜,并利用聚焦离子束刻蚀技术制备出发射面直径为100μm的微型热阴极。在此基础之上着重研究这种阴极的抑制膜特性,研究表明,Ta/Zr膜层比Zr膜层临界附着力更强,双离子束辅助沉积制备的Ta/Zr抑制膜比磁控溅射制备的Ta/Zr抑制膜更加致密,并且抑制发射寿命更长。阴极良好的抑制效果一方面是因为Ba扩散至Zr中形成高功函数物质,另一方面是因为Ta/Zr复合膜层高度致密有效抑制了Ba的扩散。

基于光谱合束的双波长输出Nd:YAG固体激光器

报道了一种基于光谱合束的Nd:YAG固体激光器双波长光源。系统由两个固体Nd:YAG脉冲激光器通过光谱合束组合而成,两个固体Nd:YAG脉冲激光器可独立工作,有利于输出脉冲的波长调谐、功率调节和相对延迟调整。通过光栅的色散特性以及输出镜的共同外腔反馈将各个激光器锁定在不同波长,从而实现合束,获得的激光源中心波长锁定在1 061.5 nm和1 064.6 nm,两谱线中心间距为3.1 nm,组合光束的输出能量为173 mJ,组合光束的光束质量因子M2为2.8×2.2;两个Nd:YAG激光器独立工作的输出能量分别为94 mJ和92 mJ,在合束方向上的光束质量因子M2分别为2.7和2.1,在非合束方向上的光束质量因子M2分别为2.2和1.9;组合光束的输出能量为两个Nd:YAG激光器能量总和的93%,组合光束的光束质量因子与单个Nd:YAG激光束的光束质量因子M2基本相同。该双波长激光源满足波长间隔小、输出功率大小相近、同光轴等要求,在太赫兹波产生、测速激光雷达以及医疗仪器等应用领域具有重要作用。

面向大容量海洋移动通信的阵列级全双工自干扰抑制

为提高海洋移动通信容量,扩大通信范围,降低传输延时,提出采用双波束发射的阵列级同时收发全双工架构。针对发射阵列对接收阵列的强自干扰问题,设计一种空域数字域联合自干扰抑制算法。空域利用交替迭代算法优化发射和接收波束成形系数;数字域依据最小二乘准则求解线性滤波器的重构系数,重建和对消自干扰信号,最终将残余自干扰抑制到接收机底噪附近。最后从理论上分析了自干扰抑制算法的最大有效各向同性隔离度。理论和仿真结果表明,与传统波束成形自干扰抑制算法相比,所建议的自干扰抑制算法将收发阵列隔离度提高了86.4 dB。

基于有源超表面的低剖面双波束偏转天线

针对传统的波束控制天线剖面高、成本高以及馈电网络复杂的问题,提出了一种基于有源超表面的低剖面双波束偏转天线设计方案。天线由“E”型双波束馈源天线和“7×6”透射型超表面组成。基于电流反转机制,在每个超表面单元上集成2个PIN二极管,实现了1-bit相位分辨率。结合相位补偿定理与远场辐射公式,对超表面单元进行组阵编码,以实现波束调控的性能。该天线的剖面仅为0.162λ0,明显低于其他波束偏转天线。通过设计超表面的偏置网络,实现了天线的双波束偏转。为了验证该方案,对天线进行加工测试。实测结果表明,在工作频率5.47GHz处,双波束的主辐射方向可分别从(ϴ,Φ)=(30°,45°)、(-30°,-41°)偏转到(ϴ,Φ)=(30°,-45°)、(-30°,41°),增益高于8.9 dBi,实测结果与仿真结果具有较好的一致性。所提出的波束控制天线架构为实现低剖面、可调控的多波束天线提供了一种候选方案。

基于双层梁理论的隧道下穿诱发无砟铁路变形计算方法

为研究隧道下穿无砟铁路轨道时板底部脱空对轨道变形的影响,提出一种改进的隧道下穿引起无砟铁路变形的计算方法.首先,将无砟铁路轨道结构简化为双层地基梁模型,建立隧道下穿施工引起无砟铁路变形的控制方程;然后,将无砟铁路分为中间脱空段和两端接地段共三部分,推导隧道下穿施工诱发无砟铁路变形的计算式,对比路基不均匀沉降引起无砟轨道变形的理论计算值与数值模拟结果,验证了理论计算方法的正确性;最后,探讨了新建隧道埋深、隧道下穿施工引起周围地层的损失率,以及既有铁路与隧道间的水平夹角对无砟铁路轨道变形的影响.研究结果表明:当隧道从铁路下方6 m处垂直穿越既有铁路时,轨道中点变形将达到最大值;隧道施工引起周围地层损失率从0.25%增大到2.50%时,轨道中点变形和轨道板底部脱空区宽度将分别增大4.0倍和2.2倍.

基于极化-相位调制的雷达通信一体化波束方向图设计

为进一步实现雷达与通信系统的高效协同,提出一种基于极化相位联合调制的雷达通信一体化发射波束方向图设计方法。首先,通过正交子空间投影方法将权矢量投影至指定流形空间的零空间;然后,针对通信与探测权矢量的不同指标设计目标函数并通过优化算法求解,以实现通信信息的嵌入与极化控制;最后,添加人工噪声干扰以降低非通信方向对通信信息的截获概率。仿真结果表明所提方法可以实现极化调控和旁瓣约束,通信信号相比于已有方法具有更高的传输速率和抗截获概率。

考虑双重非线性的梁-柱结构荷载-变形预测解析方法

既有梁-柱结构的服役荷载主要形式以轴力产生的偏压荷载以及垂直于梁柱结构轴线的服役荷载为主。目前,针对细长结构压弯耦合荷载导致的稳定性问题,主要采用2种方法进行结构分析,即特征值法和荷载-挠度法。由于实际桥梁构件存在一定的几何缺陷和材料刚度退化,采用忽略非线性的特征值法会高估承载能力。以任意截面形式组成的简支梁为例,基于Ritz法,并结合能量平衡条件,分别建立了考虑几何非线性和材料非线性的简支梁-柱结构在偏压荷载和多种竖向作用耦合作用下的第二类稳定解析分析模型,并建立了不同初始缺陷的变截约束混凝土柱有限元分析模型。研究结果表明:解析模型结果与有限元结果相比较,二者吻合良好。建立的解析模型可以精确考虑双重非线性的二阶效应。

铜及铜合金激光熔化焊接工艺的研究进展

激光熔化焊接被认为是连接铜的一种合适工艺,但铜对工业应用最为成熟的红外激光的吸收率非常低,采用红外激光对铜进行焊接还存在一定的挑战。与红外激光相比,铜对短波长的可见光激光的吸收率可提高数倍,因此可见光激光在铜的快速、高质量焊接方面展现出巨大潜力。本文总结了近年来铜及其合金的激光熔化焊接工艺研究进展,对铜的红外激光、可见光激光以及双光束复合激光焊接技术进行了介绍,对比了不同工艺的优缺点,最后对可见光激光焊接和复合焊接技术的应用进行了展望。

驻波场中非均匀手征分层粒子的辐射力特性

随着光学技术的发展,人们对光场与微粒相互作用的研究越来越深入.通过研究驻波场中非均匀手性粒子的辐射力特性,可以深入了解光场对微粒的影响机制,为微纳米尺度下分层手征粒子的操控和应用提供新思路.本文对双高斯波束照射下非均匀手征分层粒子的辐射力展开研究.从广义洛伦兹-米氏理论(generalized Lorentz-Mie theory,GLMT)和球矢量波函数(spherical vector wave functions,SVWFs)出发,推导了双高斯波束(double Gaussian beams,DGBS)的总入射场展开系数.基于边界连续条件和电磁动量守恒定理,得到双高斯波对粒子的辐射力表达式.通过与现有文献进行比较,证明了理论和程序的正确性.详细分析了各种参数对辐射力的影响,如束腰宽度、偏振形式、粒子半径、内外手征参数、折射率、最外层厚度等.研究表明,与单个高斯束相比,反向传播的高斯驻波在捕获或限制非均匀手性分层粒子方面表现出显著优势,提供了更强的粒子操控能力.此外,通过选择合适的偏振态入射,可以在这些参数之间实现微妙的平衡,从而有效地稳定俘获非均匀手性粒子.这些研究对于分析和理解形状复杂多层生物细胞的光学特性具有重要意义,并在多层生物结构微操控方面具有重要应用价值.