Fast electro-thermal simulation of large area OLEDs in natural convection environment

2017 23rd International Workshop on Thermal Investigations of ICs and Systems (THERMINIC) Pub Date : 2017-09-01 DOI:10.1109/THERMINIC.2017.8233821

L. Pohl, Z. Kohári, A. Poppe

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引用次数: 1

Abstract

Organic LEDs can be used not only in displays but also in intelligent light sources. Unlike inorganic LEDs, OLEDs do not function as point-like but as surface light sources since manufacturing of large area light sources is more feasible with OLED technologies. Despite their lower luminous efficacy this makes OLEDs still an attractive option especially in high end indoor applications, The major issue in such applications is the homegenity of the luminance of the large OLED panels. In natural convection environment the temperature difference in the same device can reach 20–30°C which can result in up to 30–40% difference in current density and thus in the luminance. CFD simulation is the obvious way to handle this problem but integration of a CFD solver in an OLED simulator may be difficult and the solution times are high. This paper presents the application of three natural convection models for vertical plates in an electro-thermal field solver based OLED simulator as thermal boundary condition. Simulation results of a free-standing 50∗50 mm2 active surface OLED, surrounded by still air, are compared with measurement results.

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自然对流环境下大面积oled的快速电热模拟

有机led不仅可以用于显示器，还可以用于智能光源。与无机led不同，OLED不是点状光源，而是表面光源，因为使用OLED技术制造大面积光源更可行。尽管它们的发光效率较低，这使得OLED仍然是一个有吸引力的选择，特别是在高端室内应用中，这种应用中的主要问题是大型OLED面板的亮度均匀性。在自然对流环境中，同一器件的温差可达20-30℃，这可能导致电流密度相差高达30-40%，从而导致亮度差异。CFD模拟是解决这一问题的明显方法，但将CFD求解器集成到OLED模拟器中可能很困难，而且求解时间也很长。本文介绍了垂直板的三种自然对流模型作为热边界条件在基于电热场求解器的OLED模拟器中的应用。在静止空气包围下的独立50 * 50 mm2有源表面OLED的仿真结果与测量结果进行了比较。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2017 23rd International Workshop on Thermal Investigations of ICs and Systems (THERMINIC)

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