A method for manufacturing an SiO.sub.2TiO.sub.2 based glass upon a target by a direct method, includes: an ingot growing step of growing an SiO.sub.2TiO.sub.2 based glass ingot having a predetermined length on the target by flame hydrolysis by feeding a silicon compound and a titanium compound into an oxyhydrogen flame, wherein the ingot growing step includes: a first step of increasing a ratio of a feed rate of the titanium compound to a feed rate of the silicon compound as the SiO.sub.2TiO.sub.2 based glass ingot grows until the ratio reaches a predetermined value; and a second step of gradually growing the SiO.sub.2TiO.sub.2 based glass ingot after the ratio has reached the predetermined value in the first stage with keeping the ratio within a predetermined range.

An apparatus for processing cover windows includes a first mold including a first support a second support spaced apart from the first support, where the first support and second support are configured to hold processing targets; a second mold; and a third mold spaced apart from the second mold. The second mold includes a first pressurizing portion overlapping with the first support, having a first thickness, and a second pressurizing portion connected with the first pressurizing portion and configured to overlap with the first support, having a second thickness thinner than the first thickness. The third mold includes a third pressurizing portion overlapping with the second support, having a third thickness, and a fourth pressurizing portion connected with the third pressurizing portion and overlapping with the second support, having a fourth thickness thinner than the third thickness.

A mold for molding a glass product is provided. The mold includes a lower mold and an upper mold. The lower mold includes a lower pressing surface. The upper mold includes an upper pressing surface. The upper pressing surface includes a plurality of upper molding surfaces and an upper mold closing surface connecting the plurality of upper molding surfaces. The lower pressing surface includes a plurality of lower molding surfaces and a lower mold closing surface for connecting the plurality of lower molding surfaces. The upper mold closing surface and/or the lower mold closing surface include at least two mold closing regions sequentially arranged from center to outside. The at least two mold closing regions have surface roughnesses increasing from center to outside. The disclosure achieves the technical effect of even filling, synchronous demoulding, and reduced error between mold cavities.

An apparatus for forming 3D glass for a smart phone, including a lower mold set including a first lower mold 52A and a first upper mold 50A having a cavity in which curved glass is formed between the first lower mold and the first upper mold when the first lower mold and the first upper mold are coupled, an upper mold set including a second lower mold 52B and a second upper mold 50B having a cavity in which curved glass is formed between the second lower mold and the second upper mold when the second lower mold and the second upper mold are coupled, and a plurality of support pins 60 supporting the upper mold set in the state in which the upper mold set has been spaced apart from the lower mold set at a specific interval.

An apparatus for forming 3D glass for a smart phone, including a lower mold set including a first lower mold 52A and a first upper mold 50A having a cavity in which curved glass is formed between the first lower mold and the first upper mold when the first lower mold and the first upper mold are coupled, an upper mold set including a second lower mold 52B and a second upper mold 50B having a cavity in which curved glass is formed between the second lower mold and the second upper mold when the second lower mold and the second upper mold are coupled, and a plurality of support pins 60 supporting the upper mold set in the state in which the upper mold set has been spaced apart from the lower mold set at a specific interval.

Refractory glass-forming tools, including glass-forming molds incorporating protective metal nitride surface coatings, with optional alumina barrier layers disposed between the mold bodies and coating for high-temperature nitride coating stability, offering particular advantages for the manufacture by direct molding of optically finished glass products such as information display cover glasses from refractory alkali aluminosilicate glasses at molding temperatures up to and above 800 C.

Disclosed is a method of preparing a solid electrolyte composition for a lithium secondary battery which includes: (a) mixing materials including Li.sub.2O, SiO.sub.2, TiO.sub.2, P.sub.2O.sub.5, BaO, Cs.sub.2O and V.sub.2O.sub.5; (b) melting the mixed materials; (c) rapidly cooling the molten materials at room temperature and compressing the molten materials using a preheated plate to form electrolyte glass having a predetermined thickness; (d) heating the electrolyte glass to eliminate stress at a predetermined temperature range; (e) heating the electrolyte glass to a higher temperature range higher than in the step of heating the electrolyte glass to eliminate stress to be crystallized; and (f) precisely adjusting a thickness of the electrolyte glass by lapping the electrolyte glass.