基于设备故障的间歇化工过程反应型调度

间歇化工过程生产中的不确定性因素很多,由于其不可预见性和多样性,不可能在产生原调度的同时给出不确定因素的最合适的处理方案,而是需要在不确定因素发生时结合过程的实际情形,来对原调度进行反应型调度.本文考察了设备故障的影响,根据设备故障的特点和所加工物料的性质,分故障产品重加工、故障工序继续加工和故障工序重加工三类加以分析和处理,建立了该问题的数学模型并用遗传算法来对该问题进行求解.文中给出设备故障反应型调度的算例,通过设备的维修时间、物料的处理方式以及故障发生时间对反应型调度的灵敏度分析揭示了基于设备故障的间歇化工过程反应型调度的实质.     

基于办公网络在线实验系统的实现

虚拟仪器技术的发展及应用,使远程实验办公成为可能。本文研究了基于办公网络的MatLab在线实验系统组建的多种技术方案,系统设计采用了Active X组件,COM组件等混合编程技术,服务器采用.NET框架、SQL数据库技术和网页制作技术,使先进的实验资源为办公网络中的所有用户所利用,满足办公环境下在线实验的需求。     

一种信号调制识别网络的轻量化设计

神经网络在信号调制识别领域得到了广泛关注和研究。针对现有调制识别算法为提高识别准确率,导致模型尺寸过大、计算时间过长的问题,提出了一种调制识别神经网络的轻量化设计方案。该方案由信号失真校正模块和分类模块两部分组成。其中,信号失真校正模块通过参数估计器提取相位偏移信息,再经参数转换器对相位偏移进行参数校正,保证信号识别精度;分类模块由一维卷积神经网络(One-Dimensional Convolutional Neural Network, 1D-CNN)、选通递归单元(Gated Recurrent Unit, GRU)和高斯衰减层构成,从时间和空间的角度有效提取信号特征,并减少冗余参数量以缩减模型大小。仿真结果表明,所提方案与同精度网络相比,平均识别准确率提升0.21%,计算时间缩减到1/3.4,模型尺寸缩减到1/7.77。     

A preliminary attempt to use radiomic features in the diagnosis of extra-articular long head biceps tendinitis

Magnetic Resonance Materials in Physics, Biology and Medicine - This study aims to present a radiomic application in diagnosing the long head of biceps (LHB) tendinitis. Moreover, we evaluated...     

手推式电子叉车秤倾角与称重误差补偿算法研究

针对电子叉车秤在使用过程中出现的车体倾斜导致称重误差精度下降等问题,提出了一种有效的称重误差补偿算法。首先,分析电子叉车秤倾斜角度对称重性能的影响,搭建一个多方向可变角度倾斜的实验平台,以模拟叉车秤的倾斜状态并获取精确的称重数据。其次,根据所获得的数据与称重误差补偿原理,建立倾斜状态下电子叉车秤的称重误差补偿算法模型,并运用最小二乘法及多层感知机非线性回归方法识别模型参数。最后,本文对具有1 500 kg量程和0.02 kg感量的电子叉车秤进行了倾斜测试实验,结果表明,在地面倾角不超过1.5°的范围内,在任意倾斜方向仪器最大允许误差MPE<0.75 kg,具有3 000分度数的精度。     

无线充电系统电磁屏蔽与效率优化技术研究

在电动汽车无线电能传输系统中,磁屏蔽效果往往以牺牲传输效率为代价,如何减少磁泄漏的同时提高传输效率是一 个难题。 为此本文提出了一种新型强耦合磁屏蔽结构来减少系统磁泄漏。 首先,提出了一种强耦合磁屏蔽线圈结构,基于提出 的屏蔽线圈结构,分析了屏蔽线圈阻抗特性对系统漏磁与传输效率的影响;其次,给出了一种漏磁优化流程,运用提出的优化流 程,得到了满足设计要求的各线圈参数;最后,根据得到的线圈参数研制了一套基于电动汽车带磁屏蔽结构的无线充电系统,通 过仿真和实验验证了所提结构与方法的有效性。 结果显示,提出的新型强耦合磁屏蔽线圈不仅使系统的磁泄漏有效降低了 28%,且传输效率提升了近 4%。     

基于同步相量数据幅频特征的次超同步振荡模式辨识

随着可再生能源和高压直流输电的快速发展,次超同步振荡事故频发,对现有电力系统振荡的在线监测提出了更高要求。为此,提出了一种基于同步相量数据幅频特征的次超同步振荡模式辨识方法。首先分析了次同步振荡和超同步振荡对同步相量测量装置(phasor measurement unit, PMU)数据的影响机制,结果表明,PMU数据的正负频谱与次超同步振荡的模态线性相关。其次利用多点PMU数据相干谱判别振荡与噪声,有效减少了噪声引起的误判断。然后对次超同步振荡下的PMU数据开展频谱分析,建立了4个幅频特征量,并将振荡数据的特征集合作为输入训练并优化极限梯度提升树(extreme gradient boosting, XGBoost)模型,建立幅频特征与振荡模式的映射关系。所提方法利用振荡环境下PMU数据的固有幅频特征以及XGBoost算法强大的泛化性与计算效率,实现了噪声环境下次超同步振荡模式的快速、准确辨识。最后,利用仿真数据和实测数据验证了所提方法的有效性和实用性。     

Soft Robotic-Adapted Multimodal Sensors Derived from Entirely Intrinsic Self-Healing and Stretchable Cross-Linked Networks

Flexible sensing technologies that play a pivotal role in endowing robots with detection capabilities and monitoring their motions are impulsively desired for intelligent robotics systems. However, integrating and constructing reliable and sustainable flexible sensors with multifunctionality for robots remains an everlasting challenge. Herein, an entirely intrinsic self-healing, stretchable, and attachable multimodal sensor is developed that can be conformally integrated with soft robots to identify diverse signals. The dynamic bonds cross-linked networks including the insulating polymer and conductive hydrogel with good comprehensive performances are designed to fabricate the sensor with prolonged lifespan and improved reliability. Benefiting from the self-adhesiveness of the hydrogel, strong interfacial bonding can be formed on various surfaces, which promotes the conformable integration of the sensor with robots. Due to the ionic transportation mechanism, the sensor can detect strain and temperature based on piezoresistive and thermoresistive effect, respectively. Moreover, the sensor can work in triboelectric mode to achieve self-powered sensing. Various information can be identified from the electrical signals generated by the sensor, including hand gestures, soft robot crawling motions, a message of code, the temperature of objects, and the type of materials, holding great promise in the fields of environmental detection, wearable devices, human-machine interfacing, and robotics.     

Multifunctional Organic Potassium Salt Additives as the Efficient Defect Passivator for High-Efficiency and Stable Perovskite Solar Cells

Despite the rapid developments are achieved for perovskite solar cells (PSCs), the existence of various defects in the devices still limits the further enhancement of the power conversion efficiency (PCE) and the long-term stability of devices. Herein, the efficient organic potassium salt (OPS) of para-halogenated phenyl trifluoroborates is presented as the precursor additives to improve the performance of PSCs. Studies have shown that the 4-chlorophenyltrifluoroborate potassium salt (4-ClPTFBK) exhibits the most effective interaction with the perovskite lattice. Strong coordination between  BF₃⁻/halogen in anion and uncoordinated Pb²⁺/halide vacancies, along with the hydrogen bond between F in  BF₃⁻ and H in FA⁺ are observed. Thus, due to the synergistic contribution of the potassium and anionic groups, the high-quality perovskite film with large grain size and low defect density is achieved. As a result, the optimal devices show an enhanced efficiency of 24.50%, much higher than that of the control device (22.63%). Furthermore, the unencapsulated devices present remarkable thermal and long-term stability, maintaining 86% of the initial PCE after thermal test at 80 °C for 1000 h and 95% after storage in the air for 2460 h.     

Phase-Separated Polyzwitterionic Hydrogels with Tunable Sponge-Like Structures for Stable Solar Steam Generation

Solar steam generation (SSG) through hydrogel-based evaporators has shown great promise for freshwater production. However, developing hydrogel-based evaporators with stable SSG performance in high-salinity brines remains challenging. Herein, phase-separated polyzwitterionic hydrogel-based evaporators are presented with sponge-like structures comprising interconnected pores for stable SSG performance, which are fabricated by photopolymerization of sulfobetaine methacrylate (SBMA) in water-dimethyl sulfoxide (DMSO) mixed solvents. It is shown that driven by competitive adsorption, the structures of the resulting poly(sulfobetaine methacrylate) (PSBMA) hydrogels can be readily tuned by the volume ratio of DMSO to achieve phase separation. The optimized phase-separated PSBMA hydrogels, combining the unique anti-polyelectrolyte effects of polyzwitterionic hydrogels, demonstrate a rapid water transport capability in brines. After introducing photothermal polypyrrole particles on the surface of the phase-separated PSBMA hydrogel evaporators, a stable water evaporation rate of ≈2.024 kg m⁻² h⁻¹ and high solar-to-vapor efficiency of ≈97.5% in a 3.5 wt.% brine are obtained under simulated solar light irradiation (1.0 kW m⁻²). Surprisingly, the evaporation rates remain stable even under high-intensity solar irradiation (2.0 kW m⁻²). It is anticipated that the polyzwitterionic hydrogel evaporators with sponge-like porous structures will contribute to developing SSG technology for high-salinity seawater applications.