In this study, we studied the method of using general architectural glass instead of using the existing acrylic material for high luminance flat lighting. The flat panel lighting used the side illumination method to increase the ease of installation and aesthetic satisfaction. In general, glass has an amorphous structure with a lower angle of refraction than acrylic, so it is not suitable for use in flat panel lighting as a light guide, but in this study, the role of light distribution characteristics and diffusion patterns in the case of using such a glass light guide. Quantitative simulations were conducted to confirm new possibilities. In the simulation, the backlight estimation method was used, and about 10,000,000 rays were placed within a unit area in order to obtain a result similar to the real thing. As a result of the simulation, the geometry of the diffusion pattern could be specified, and the value of the geometry could be quantified using the ratio of the diameter and height of the pattern. As a result of the calculation, it was found that the maximum amount of light was generated around 75 degrees by quantitatively calculating the ratio and the outgoing light angle at which the maximum value of the outgoing light occurred between 05 and 1.0. As a result of these studies, it was confirmed that it is possible to use ordinary glass at the same time as a transparent window and light-emitting lighting at night.
In this study, the flat glass and adsorption pad were modeled using SolidWorks Simulation, to understand the deformation characteristics of the vertical flat glass by the adsorption pressure during vertical transport of LCD. The horizontal and vertical displacements and equivalent stresses of the flat glass were investigated by the structural analysis. From the displacement and stress visualization according to the adsorption pressure, the higher the adsorption pressure, the larger the glass surface protruded. The horizontal deformation of flat glass increased with increasing thickness and the vertical deformation increased with decreasing thickness. In addition, the maximum equivalent stress applied to the flat glass increased significantly as the adsorption pressure increased and the thickness decreased. As a result of the structural analysis, the thinner the thickness of the plate glass, the greater the effect on the adsorption pressure. Especially, the effect of the adsorption pressure was clearly observed at the thickness of 0.5mm.
A laser glass cutting system using a femto-second laser was evaluated for Flat Panel Display (FPD) glass. A theoretical analysis of the ablation threshold and depth is described using an explicit analytic form. Experiments for clean and deep grooves were performed using a 3W femto-second laser, and the relationships between the input energy and the scribing depth as well as the threshold energy are presented. Mechanical breaking after the scribing process was carried out and the results are compared with a theoretical method. It was found that a two-sided LCD panel glass can be cut clearly using the laser cutting method. The methodology was found to be very effective as a mass-production cutting system.
평판디스플레이용 진공패널의 제작시 진공으로 유지된 패널을 구성하는 유리판이 받는 응력과 변위를 계산하였다. 유리판의 두께, 패널의 크기 및 실링폭의 크기를 변수로 하여 실제로 진공패널을 제작한 후 패널의 파괴양상과 변위를 측정하였다. 유리판의 파괴양상과 변형측정을 통하여 유리판에 걸리는 최대응력은 테두리부분에 걸리는 것을 확인하였다. 제작된 진공패널이 갖는 응력분포 및 변위의 분포는 패널을 진공실링할 때 사용한 실런트의 폭에 크게 의존하였다. 패널의 실링폭이 커질수록 모서리가 완전 고정된 조건으로 계산한 결과와 유사하였다. 두께가 3mm인 유리판을 사용해서 80×120textrmmm2</TEX> 크기의 패널을 제작할 때 실링폭이 20mm인 경우 측정된 변위는 57μm였으며, 이 값은 모서리가 완전히 고정된 조건으로 계산한 갈인 54μm와 비슷하였다.