Study of cutting quality for TFT-LCD glass substrate

Liu, Chi-sheng

24 August 2006

This study is the method of using the mechanical type to cut the substrate of the glass , under the circumstances that the glass surface is cut directly, probably produced 10¡ã20% of the depth of crack that is the thickness of glass, and then pulled the glass and split by mechanical stress , use the ANSYS and finite element method carry on relevant research and compare, survey the perfect cutting parameter to increase the yield in the future. This study is in order to find out the surface fracture stress distribution status after cutting and take advantage with the finite element method ,and compare with the result of median crack when glass substrate after cutting .It discuss with change parameter of the cutting pressure and Cutting depth ,than to compare with finite element method, it regard as discussing the quality after cutting to reduce the risk of surface defect.

median crack

finite element method

glass substrate cutting

Analysis of the Wave Propagation in Two-Dimensional Phononic Crystal Using the Finite Element Method

Song, Pei-Jing

28 August 2006

In this work we apply the finite element method to analyze the wave transmission property of solid/fluid composite medium, phononic crystal. The sound attenuation spectrum is obtained to show the forbidden bands of the band gap. First, we construct the finite element model for a two-dimensional phononic crystal, studied by Sánchez-Pérez etc. with PWE and experimentally, constituted of a rectangular array of parallel circular stainless steel cylinders in air. It has demonstrated that our simulation work was feasible; then, we performed the experimental measurements and simulations by using the narrow and wide frequencies. The results show agreement between the experiments and the simulations. We also simulated the crystal samples of filling fraction 5 % and 10 % for square and hexagon lattice, respectively, in both the [100] and [110] direction. The full band gaps are determined from the combination of the results. We have investigated the finite element simulation for the solid/fluid phononic crystal successfully. Both work the results of experiment in the reference and in this work are compared with the FEM simulation. It demonstrates that the finite element method is a good tool for the design of phononic crystal in application to new type sound absorption (isolation) material.

band gaps

absorption (isolation) material

phononic crystal

finite element method

形状・位相最適化解析の比較検討

丸山, 新一, MARUYAMA, Shinichi, 竹内, 謙善, TAKEUCHI, Kenzen, 畔上, 秀幸, AZEGAMI, Hideyuki

10 1900

No description available.

Optimum Design

Numerical Analysis

Finite-Element Method

Traction Method

シェルの面外変動に対する形状最適化

青山, 大樹, AOYAMA, Taiki, 畔上, 秀幸, AZEGAMI, Hideyuki

03 1900

No description available.

Optimum Design

Numerical Analysis

Finite-Element Method

Traction Method

大変形する弾性体の変形後形状を規定した形状同定問題の解法

長谷, 高明, NAGATANI, Takaaki, 畔上, 秀幸, AZEGAMI, Hideyuki

11 1900

No description available.

Optimum Design

Numerical Analysis

Finite-Element Method

Traction Method

固有振動数制約付き Mindlin 板・シェル構造の重量最小形状設計

下田, 昌利, SHIMODA, Masatoshi, 辻, 二郎, TSUJI, Jiro, 神田, 康宏, KANDA, Yasuhiro, 畔上, 秀幸, AZEGAMI, Hideyuki

09 1900

No description available.

Optimum Design

Shape Optimization

Finite Element Method

Shell

Traction Method

板・シェル構造の固有振動問題に対する形状最適化の数値解法

下田, 昌利, SHIMODA, Masatoshi, 畔上, 秀幸, AZEGAMI, Hideyuki, 辻, 二郎, TSUJI, Jiro, 神田, 康宏, KANDA, Yasuhiro

10 1900

No description available.

Optimum Design

Numerical Analysis

Finite Element Method

Shell

Traction Method

板・シェル構造の面内変動による形状最適化の数値解法

下田, 昌利, SHIMODA, Masatoshi, 畔上, 秀幸, AZEGAMI, Hideyuki, 辻, 二郎, TSUJI, Jiro, 神田, 康宏, KANDA, Yasuhiro

11 1900

No description available.

Optimum Design

Numerical Analysis

Finite Element Method

Shell

Traction Method

最適化解析の最前線

畔上, 秀幸, AZEGAMI, Hideyuki

11 1900

No description available.

Optimum Design

Numerical Analysis

Finite-Element Method

Gradient Method

音場を対象とした形状最適化問題の解法(車内音低減問題)

畔上, 秀幸, AZEGAMI, Hideyuki, 松浦, 易広, MATSUURA, Yasuhiro, 丸山, 新一, MARUYAMA, Shinichi

11 1900

No description available.

Optimum Design

Numerical Analysis

Finite-Element Method

Traction Method