一种新型高功率微波相移器

 研究了一种新型高功率微波相移器同轴插板式相移器,其设计思想为：在同轴波导内插入金属导体板,将同轴波导分为几个扇形截面波导,由于扇形截面波导中传输的TE₁₁模相速度与同轴TEM模的相速度不同,通过改变插入金属板的长度就可以实现相移的调节。设计了中心频率为4 GHz的同轴插板式相移器,并进行了数值模拟验证。结果表明：当相移器同轴波导内半径为2.0 cm,外半径为4.5 cm,相移器总长度为50 cm时,可实现的最大相移量为360°,在3.9~4.1 GHz频率范围内相移器的插入损耗低于0.1 dB。     

超声辅助液相合成多晶SnS纳米粉

本文以Na2S·9H2O和SnCl2·2H2O为反应源物,采用超声辅助液相合成法制备SnS纳米粉.用XRD、TEM和TED等方法对粉体样品进行了表征,检测结果表明粉体样品为具有斜方晶体结构的SnS纳米微粒,其平均晶粒尺寸约为15～25nm.论文还简要讨论了超声波对SnS纳米粉形成的影响,分析认为超声辅助手段的加入有利于多晶SnS纳米粉的形成.     

高峰值功率多注速调管的初步研究

 高峰值功率速调管因其作为高功率微波源而受到各国的重视。采用单电子注方案的高峰值功率速调管存在许多难以克服的问题,如工作电压很高,输出效率偏低,系统体积偏大等。对高峰值功率多注速调管进行了初步的研究,重点研究了S波段50 MW多注速调管的电子光学系统和高频互作用系统。研究表明,在与单注速调管相同的功率电平下,多注速调管的工作电压明显降低,输出效率明显提高,同时,这种管型也存在结构复杂、电子注聚焦和消除非工作模式困难等技术问题。     

DNB引出束流功率及剖面分布测量

 利用束流截止板热量计原理,测量了诊断中性束(DNB)注入托卡马克的束流功率及束流剖面分布。基于热量截止板上正交分布的13只K型热电偶探针测量出DNB引出束流,在加速极电源49 kV,6 A,100 ms的脉冲放电时,采样铜靶上的最高温升为14 ℃,从而计算出注入束流功率达到160 kW并得到束剖面分布。同时通过对热量截止板冷却循环水温升测量值在时间上的积分数值计算,也获得了注入束流总功率,为130 kW。分析了两种测量结果存在差异的原因,实验结果表明惯性束截止板热量计方法是测量粒子束流功率及剖面分布的有效手段。     

高功率离子束在漂移管中的中性化传输

 介绍了“闪光二号”加速器产生的高功率离子束在漂移管中的传输实验。对比了采用中性化措施前后的传输情况，分析了中性化措施对离子束束斑半径、束流均匀性的影响。根据实测的二极管电压模拟得到了传输一定距离后的束流波形，与实测结果符合较好。采取适当的中性化措施后，高功率离子束可以有效传输80 cm以上，束流发散得到抑制，束流均匀性得到改善。     

规格化对高斯消元法计算速度的影响

从计算原理和计算速度两个方面详细地分析比较规格化对求解线性方程组的高斯消元法在消元和回代过程中的影响,其中包括计算公式的变化、计算元素的计算次数、规格化元素的计算次数、计算所有元素所需的元素总数、对复数矩阵和实数矩阵的计算速度的影响等内容的比较,并对IEEE-57、-118、-300节点系统进行编程比较计算。计算结果表明,高斯消元法中规格化的计算虽极为简单,且对回代环节的影响不大,但可以大大提高前代环节的计算速度,从而大大提高求解线性方程组的计算速度,尤其是对复数矩阵。该结论同样适用于电力系统等各个工程领域用高斯消元方法求解线性方程组。更多还原     

Self-Assembled Multistable Scattering Mode for Versatile Energy-Saving Smart Windows

Smart windows are crucial to dynamic control over light transmission to fulfill various demands in energy saving, privacy, and information display; however, most present technologies still perform a single function (often tint or haze adjustment) and require continuous electricity for operation. In this study, novel self-assembled ionic liquid crystals (ILCs) doped with negative cholesteric liquid crystals (CLCs) to offer electrically switchable and stable scattering-mode light modulators are presented. The novel smectic A phase based on the ILCs exhibits high solubility in the adopted nematics, enhancing the LC device's performance in several ways, including improved homogeneity, stable alignment quality, prolonged stability, and simplified fabrication. The LC device can potentially offer a dynamically rapid switching function between stable transparent (imperfect fingerprint textures) states and stable scattering (focal conic textures with small domains) states by using external stimuli and highly maintained multistable states for prolonged periods, even when the external stimuli are removed. The LC device also offers polarization-independent scattering and transparent-mode LC light modulators, low operating voltage, excellent contrast, and broad viewing angles. Its versatility and outstanding field-off stability make it ideal for various applications such as smart lighting, building climate control, energy-saving displays, and augmented reality (AR) glasses.     

Long-Life Lead-Carbon Batteries for Stationary Energy Storage Applications

Owing to the mature technology, natural abundance of raw materials, high recycling efficiency, cost-effectiveness, and high safety of lead-acid batteries (LABs) have received much more attention from large to medium energy storage systems for many years. Lead carbon batteries (LCBs) offer exceptional performance at the high-rate partial state of charge (HRPSoC) and higher charge acceptance than LAB, making them promising for hybrid electric vehicles and stationary energy storage applications. Despite that, adding carbon to the negative active electrode considerably enhances the electrochemical performance. However, carbon brings some adverse effects, such as the severe hydrogen evolution reaction (HER) in the NAM due to the low overpotential of carbon material, promoting severe water loss in LCBs. From a practical application point of view, the irreversible sulfation of the negative active material (NAM) and extreme shedding and softening of the positive active material (PAM) are the main obstacles for next-generation LCBs. Recently, a lead-carbon composite additive delayed the parasitic hydrogen evolution and eliminated the sulfation problem, ensuring a long life of LCBs for practical aspects. This comprehensive review outlines a brief developmental historical background of LAB, its shifting towards LCB, the failure mode of LAB, and possible potential solutions to tackle the failure problems. The detailed LCB′s development towards long life was discussed in light of the reported literature to guide the researcher to date progress. More emphasis was directed toward the new applications of LCBs for stationary energy storage applications. Finally, state-of-the-art progress and further research gaps were pointed out for future work in this exciting era.     

BEPCⅡ大功率波导真空阀门的研制

 大功率波导真空阀门是BEPCⅡ直线加速器微波系统的重点改进项目，作为微波大功率传输和真空密封双重功能的超高真空微波器件，机械结构比较复杂，制造工艺难度大。经过各方努力，已经研究完成16台大功率波导真空阀门，并在2004年全部安装在加速器上使用。目前进入到波导真空阀门的脉冲功率为30~50 MW，高功率运行工作状态良好。对阀门从设计原理、机械结构、微波测试及高功率运行等方面作了较详细的阐述。     

低压供热涂层材料制备及热性能研究

低压供热技术具有安全系数高和节能降耗等优势,因而成为石化稠油长输管线、风力发电叶片冬季防覆冰和室内供暖等领域的研究热点之一。本文制备了一系列低压供热涂层材料,研究不同碳功能填料对涂层发热速率、发热功率及最高发热温度的影响规律,并揭示石墨烯和碳纤维对提升涂层材料热性能的协同作用。其中石墨烯纳米片的还原程度对材料热性能具有重要影响,降低其表面官能团密度对提升涂层供热特性具有促进作用,但是官能团密度过低会导致石墨烯纳米片的团聚现象,引起涂层发热不均匀。加入适量碳纤维可以提高石墨烯的均匀分散性,提升发热速率。优化石墨烯纳米片和碳纤维的比例后,采用24V电压驱动时,涂层材料的发热速率达到7.1℃·s^-1,功率密度为800W·m^-2,最高发热温度为124℃。