Scopri come la simulazione multifisica viene utilizzata per ricerca e sviluppo
In questa sezione troverete i lavori presentati alle Conferenze mondiali COMSOL. Le presentazioni descrivono ricerche e prodotti innovativi progettati con COMSOL Multiphysics da colleghi di tutto il mondo. I temi delle ricerche presentate abbracciano un'ampia gamma di settori produttivi e aree applicative, in ambito elettrico, meccanico, fluidodinamico e chimico. Lo strumento di Ricerca Rapida vi permetterà di trovare le presentazioni che si riferiscono all'area di vostro interesse.
Visualizza gli articoli presentati alla COMSOL Conference 2020
Polymer–metal is a kind of new composite materials rather than traditional metal packaging materials. It has both features of polymer film and sheet metal. However, the polymer film will damage in the sheet metal forming process. Therefore, we try to established a sheet metal forming ... Per saperne di più
Introduction: A metal film whose thickness is smaller than the skin depth, is of high transmission in the visible and half-transparent in the near infrared. However, when the film is divided into discrete nano-strips (i.e. array), an enhanced anomalous reflection and suppressed ... Per saperne di più
节能、高效、紧凑已经成为制冷空调行业的发展趋势,其中强化换热技术尤为关键。因此,本文采用COMSOL软件对微型错排管换热器进行了建立二维模型,基于瞬态模型,采用流动和传热模块进行有无交变压力波的数值模拟分析。结果发现随着交变压力波的添加大大增加了速度场、压力场及温度场的波动情况,使得管内工质边界层破坏降低了传热的热阻综合空化链式理论,交变压力波能够起到强化传热的作用,提高了制冷效率,有利于推动制冷行业的发展。 Per saperne di più
复合型电磁轨道发射装置是轨道型电磁发射器研究的一个重要方向,复合型轨道是对轨道的内表面添加保护层,由于电磁轨道在发射时存在复杂的热量变换,轨道表面材料在吸收这些热量之后会发生脱落、气化甚至是电离等现象。为减弱在发射过程中的烧蚀现象,在轨道的表面添加保护层,使轨道内表面材料具有强的耐热性能,并且强度、韧性较好。运用 COMSOL Multiphysics® 软件仿真模拟复合轨道在发射过程中的温度、电流、应力和应变的变化。 Per saperne di più
基于电化学-热耦合模型,模拟了常温条件下 LiFePO4 /Graphite 锂离子电池的放电过程,并对电池内部正负电极各个位置的电化学反应速度演化规律进行了模拟计算研究。结果表明:放电过程中电极各处的反应速率不同,且是动态变化的。 Electrochemical Thermal Model Based Research for Electrochemical Performance of Lithium Ion Batteries Jia Ming, Tang Yiwei, Cheng Yun, Du Shuanglong, Li Jie (School of ... Per saperne di più
In recent years, fire and explosion accidents of mobile phones and electric vehicles are very common. If the heat generated by the battery cannot be dissipated in time will cause the battery temperature rise, or even thermal runaway. Therefore, it is necessary to decrease the heat ... Per saperne di più
We have developed optically driven micropumps by manipulating microstructures using optical tweezers. In this study, we proposed and developed a novel manipulation method of a single metallic nanowire. In this method, dynamic optical vortex is used not only for manipulating a metallic ... Per saperne di più
目前,脉冲磁体广泛采用导体绕组和加固材料分层交替绕制的工艺(内部层间加固),以提高磁体的整体结构强度。磁体在长期的放电工作过程中,反复经历强电磁力的作用,导体材料(一般为纯铜、铜基合金以及铜基复合材料)在重复的加卸载过程中存在着塑性应变的累积效应,即棘轮效应。导体材料塑性应变的逐渐累积,导致了磁体不可逆电感值的不断增加。因此,磁体的不可逆电感变化可表征磁体内部的整体变形情况,可用于脉冲磁体的疲劳失效预测。 本文基于 COMSOL Multiphysics® 5.1 软件,对脉冲磁体的放电过程建立了电路、电磁场、温度场及结构场的二维轴对称全耦合模型 ... Per saperne di più
摘要:在太空高能带电粒子作用下,航天器上存在绝缘介质深层充电的危险。介质内沉积电荷导致局部出现强电场(达到107V/m),有可能造成介质击穿放电。一方面,充电过程与介质电导率密切相关,而电导率受温度影响显著,另一方面,介质中的通电导体发热会影响介质的局部温度,于是有必要综合考虑介质中电场与热场的耦合变化过程。对此,我们建立了考虑电场与热场耦合变化的介质深层充电模型,并采用 COMSOL Multiphysics® 软件,实现了数值求解。结果表明,在一定的空间辐射环境下,考虑热场是十分重要的,热导率会对充电结果产生不可忽视的影响 ... Per saperne di più
This paper covers the following: * All-Optical Light Modulation of surface plasmon polaritons (SPPs) is achieved using asymmetric single nanoslits. A high on/off switching ratio of >20 dB and phase variation of >? were observed with the device lateral dimension of only about 2 ?m. * ... Per saperne di più