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Method for determining ideal chemical reinforcement process of high aluminosilicate glass and application thereof

A high aluminum silicate and chemical technology, applied in special data processing applications, chemical process analysis/design, electrical digital data processing, etc., can solve problems such as low efficiency, long experiment cycle, waste of manpower and material resources, etc., to reduce sample size Quantity, reduce test cost, improve efficiency effect

Active Publication Date: 2017-05-17
ZHEJIANG UNIV
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

This method not only wastes manpower and material resources, but also has low efficiency and long experiment cycle

Method used

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Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0029] (1) The chemical composition information of high aluminosilicate glass was obtained by atomic emission spectroscopy, and its specific composition was as follows: Si: 24.5mol%, O: 63.8mol%, Al: 9.1mol%, Na: 2.6mol%. Comparing, satisfying the applicable conditions of the present invention.

[0030] (2) According to the stress layer depth DOL of the target chemically strengthened glass, use the stress layer depth prediction formula DOL=F(t, T) to determine the first condition that the chemical strengthening process needs to meet:

[0031] Set the desired chemical strengthening depth to 50 μm, then the chemical strengthening conditions need to meet: 50=-5623.47+33.24t+20.38T-6.09×10 -2 t 3 -3.94×10 -5 T 3 -1.46×10 -4 TT 2 (1)

[0032] According to the target chemically strengthened glass surface microhardness HV, use the microhardness prediction formula HV1=F(t, T) to determine the second condition that the chemical strengthening process needs to meet:

[0033] Set ...

Embodiment 2

[0038] (1) The chemical composition information of high aluminosilicate glass is obtained by atomic emission spectroscopy, and its specific composition is as follows: Si: 24.9mol%, O: 63.0mol%, Al: 8.6mol%, K: 2.2mol%, Ca : 0.7mol%, after comparison, it meets the applicable conditions of the present invention.

[0039] (2) According to the stress layer depth DOL of the target chemically strengthened glass, use the stress layer depth prediction formula DOL=F(t, T) to determine the first condition that the chemical strengthening process needs to meet:

[0040] Set the desired chemical strengthening depth to 46 μm, then the chemical strengthening conditions need to meet: 46=-5623.47+33.24t+20.38T-6.09×10 -2 t 3 -3.94×10 -5 T 3 -1.46×10 -4 TT 2 (1)

[0041] According to the target chemically strengthened glass surface microhardness HV, use the microhardness prediction formula HV1=F(t, T) to determine the second condition that the chemical strengthening process needs to meet...

Embodiment 3

[0047] (1) The chemical composition information of high aluminosilicate glass is obtained by atomic emission spectroscopy, and its specific composition is as follows: Si: 23.6mol%, O: 63.3mol%, Al: 8.8mol%, Na: 1.7mol%, K : 1.2 mol%, Mg: 0.4 mol%, Ca: 0.1 mol%, after comparison, it meets the applicable conditions of the present invention.

[0048] (2) According to the stress layer depth DOL of the target chemically strengthened glass, use the stress layer depth prediction formula DOL=F(t, T) to determine the first condition that the chemical strengthening process needs to meet:

[0049] Set the desired chemical strengthening depth to 52μm, then the chemical strengthening conditions need to meet: 52=-5623.47+33.24t+20.38T-6.09×10 -2 t 3 -3.94×10 -5 T 3 -1.46×10 -4 TT 2 (1)

[0050] According to the target chemically strengthened glass surface microhardness HV, use the microhardness prediction formula HV1=F(t, T) to determine the second condition that the chemical strengt...

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Abstract

The invention provides a method for determining an ideal chemical reinforcement process of high aluminosilicate glass. The method comprises the following steps: determining a to-be-satisfied condition 1 of a chemical reinforcement process according to the stress layer depth of target chemical reinforcement glass and by means of a stress layer depth prediction formula DOL=F(t,T); determining a to-be-satisfied condition 2 of the chemical reinforcement process according to the surface microhardness of the target chemical reinforcement glass and by means of a microhardness prediction formula HV=F(t,T); and determining an ideal chemical reinforcement process of high aluminosilicate glass, namely values of the chemical reinforcement time t and the chemical reinforcement temperature T. The invention also provides application of the method in preparation of chemically reinforced high aluminosilicate glass. The method provided by the invention can reduce the sample preparation amount, can lower the preparation cost and testing cost of a sample and can realize accurate prediction of the ideal chemical reinforcement process of high aluminosilicate glass, thereby providing important support for determination of the chemical reinforcement process of high aluminosilicate glass.

Description

technical field [0001] The invention belongs to the technical field of performance design of high aluminosilicate glass, and in particular relates to a method for determining an ideal chemical strengthening process of high aluminosilicate glass and its application. Background technique [0002] In order to improve the mechanical strength of glass, especially the microhardness, two methods of physical strengthening and chemical strengthening are usually used. Physically strengthened glass is mainly used for window glass of vehicles and ships, and exterior glass of buildings. Physically strengthened glass has low cost, large output, high mechanical strength, good thermal shock resistance, and the highest safe working temperature can reach 287.78°C. However, the deformation problem inherent in the strengthening process of physically strengthened glass limits its application in fields that require high optical quality. The application of chemically strengthened glass is more ex...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C03C21/00C03C3/083C03C3/087G06F19/00
CPCC03C3/083C03C3/087C03C21/00G16C20/10
Inventor 赵高凌和阿雷詹凌曈占丰宋斌韩高荣
Owner ZHEJIANG UNIV
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