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Apparatus and method for reducing gaseous inclusions in a glass

一种内含物、气态的技术,应用在玻璃炉设备、玻璃制造设备、供料槽等方向,能够解决高处理成本废物、限制澄清剂澄清和氧再吸收能力等问题

Inactive Publication Date: 2014-07-30
CORNING INC
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  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

Arsenic-containing compounds are often toxic, and the disposal of arsenic-containing glass not only results in waste with high disposal costs, but also creates disposal issues associated with the display device itself after it exceeds the useful life of the display device
Unfortunately, many alternative fining agents typically release less oxygen, and / or at too low temperatures, absorb almost no more O during conditioning associated with established fining agents such as arsenic. 2 , thus limiting the clarification and oxygen reabsorption capacity of the clarifier

Method used

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  • Apparatus and method for reducing gaseous inclusions in a glass
  • Apparatus and method for reducing gaseous inclusions in a glass
  • Apparatus and method for reducing gaseous inclusions in a glass

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no. 1 approach

[0058] In the clarification step, the oxygen released by the clarifier at high temperature can promote the growth of bubbles through the diffusion of dissolved gas into the bubbles. In the fining vessel 406, the gas bubbles float to the free surface of the molten glass 426 where they are broken up and the gas is expelled from the molten glass 426.

[0059] Once the clarification of the molten glass 426 is completed, the molten glass 426 flows into the cooling refractory tube 408 and is cooled to the cooling temperature T C , the cooling temperature is lower than the clarification temperature (T F ), shifting equation (2) to the left, consuming oxygen in the molten glass 426, reducing the size of the bubbles. Eventually, the bubble shrinks to a certain size and collapse occurs simultaneously. Because this embodiment of the invention (as well as previous embodiments) relies on bubble collapse rather than gas venting, no melt free surface is required, but if a melt free surface...

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Abstract

A glass manufacturing system and a method are described herein for reducing gaseous inclusions in high melting temperature or high strain point glasses, such as those that are used as glass substrates in flat panel display devices. In one embodiment, the method including the steps of: (a) heating a batch material within a melting vessel to form molten glass at a melting temperature TM, the molten glass comprising a multivalent oxide material; (b) heating the molten glass within a fining vessel to a fining temperature TF>=TM; and (c) cooling the molten glass within a refractory tube after the first heating step or after the second heating step to a cooling temperature TC less than TM, where the molten glass remains within the refractory tube for a predetermined resident time to reduce a volume of the gaseous inclusions in the molten glass and cause gas species to migrate out of the gaseous inclusions into the molten glass such that at least a portion of the gaseous inclusions collapse into the molten glass.

Description

[0001] Instructions for Divisional Application [0002] The application date of this application is February 8, 2010, the international application number is PCT / US2010 / 023430, the national application number after entering the Chinese national phase is 201080007690.3, and the title is "Equipment for reducing gaseous inclusions in glass" and method” is a divisional application of the invention patent application. [0003] Claiming priority to an earlier U.S. application [0004] This application claims priority to US Patent Application Serial No. 12 / 368,585, filed February 10, 2009. This document, as well as all publications, patents, and patent documents mentioned herein are hereby incorporated by reference in their entirety. technical field [0005] The present invention relates to glass manufacturing systems and methods for reducing gaseous inclusions in glass. In one embodiment, the glass manufacturing systems and methods are particularly useful for reducing gaseous inc...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C03B5/23
CPCC03B5/225C03B5/23C03B7/07C03B5/235C03B5/16
Inventor K·C·安托万M·A·德拉米勒I·M·彼得逊
Owner CORNING INC
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