Abstract: A method for manufacturing a microcrystalline glass, the microcrystalline glass manufactured according to the method, and a use thereof are provided. The method includes: (1) nucleation of a raw glass sheet, followed by primary crystallization, where: the primary crystallization temperature is x1, the primary crystallization time is t, and the primary crystallization temperature x1 and the primary crystallization time t satisfy the following conditions: first, ?a×t+652?x1??a×t+667, where a is a constant, 0.1?a?0.25, and tis 10 to 300 min; and second, y1=0.0029x1+b, where y1 is the glass density after primary crystallization, and 2.440 g/cm3?y1?2.490 g/cm3, b is a constant, and 0.55?b?0.60; and (2) secondary crystallization of the glass sheet which has been subject to primary crystallization.

Abstract: A salt bath for glass reinforcement, including a nitrate and a metal compound. The mass fraction of the nitrate is not less than 50%, and the nitrate is in a molten state. The metal compound is fused into the nitrate, and the metal compound contains the same metal element as the nitrate. The mass fraction of the metal element in the molecular formula corresponding to the metal compound is greater than the mass fraction in the molecular formula corresponding to the nitrate. Thus, compared with the existing salt bath, under the condition of the same mass, the salt bath can provide more effective amount of metal ions, thereby increasing the strength of glass after reinforcement, and at the same time, the lifetime of the salt bath is increased, reducing the waste of resources and environmental pollution.

Abstract: Disclosed in the present invention is a multi-crystal nucleus transparent glass-ceramic and a preparation method therefor, said preparation method comprising the following steps: during glass production, adding a plurality of types of nucleation agents, and after processing, acquiring a mother glass having certain outer dimensions; and placing the mother glass obtained in S2 under a temperature of T1 and heating for 1 h-6 h to perform annealing treatment, after the annealing treatment is complete, placing under a temperature of T2 and heating 1 h-6 h to perform nucleation treatment, and after nucleation treatment is complete, placing under a temperature of T3 and heating 0-3 h to perform crystallization treatment. T1<T2. The present invention produces a glass-ceramic containing multiple types of crystal nuclei and having crystal phases of lithium disilicate and petalite.

Abstract: Provided in the present invention is a rare earth-doped reinforced glass-ceramic, and a preparation method and a use therefor. Raw materials rare earth-doped reinforced glass-ceramic comprise at least one of the following rare earth oxides: Ta2O5, La2O3, Y2O3, Tm2O3, or Nb2O5. In the present invention, a glass article doped with at least one rare earth oxide from among Ta2O5, La2O3, Y2O3, Tm2O3, or Nb2O5 is subjected to thermal treatment and ion exchange to produce the rare-earth doped reinforced glass-ceramic. In the rare earth-doped reinforced glass-ceramic, due to the high field strength and high accumulation effects of the rear earth element, the crystal size of the glass-ceramic is caused to low, and the crystal ratio thereof to be high, thus being able to effectively improve the mechanical performance and visible light transmittance of the glass-ceramic, and effectively controlling uniform devitrification of the glass. The invention is suitable for use in cover panels of electronic devices.

Abstract: A microcrystalline glass containing a water-repellent and oil-repellent composite coating layer on the surface, a preparation method and application thereof. The coated glass is a microcrystalline glass or a glass ceramic containing a water-repellent and oil-repellent composite coating layer on the surface, which is characterized in that from the outmost surface of the glass, it includes: a water-repellent and oil-repellent layer, an intermediate layer, a bottom layer and a microcrystalline glass or a glass ceramic, wherein, the intermediate layer is the intermediate layer containing ionic crystals with a lattice energy of 700-3000 kJ/mol and formed by the same, the bottom layer includes compounds containing Si—O bonds or a mixed silicon oxide layer.

Abstract: An anti-reflective glass, a preparation method and an application thereof are provided. The anti-reflective glass comprises a glass matrix, at least one surface of the glass matrix is provided with an undulating hill morphology layer, which forms a whole piece with the glass matrix, the hill morphology layer consists of a plurality of irregularly distributed hill raised micro-structures along a Z-axis direction. The present anti-reflective glass has hill morphology surface which can significantly reduce the light reflectivity and increase the light transmittance, the perspective effect of the light is improved; the preparation method simplifies the etching process effectively, and the condition is controllable, the undulating hill morphology formed on the glass surface by etching is effectively ensured, and the optical performance is stable.

Abstract: The present invention relates to safe strengthened glass with a low-variation-amplitude tensile stress region, a preparation method and an application. The change curve of the compressive stress and tensile stress of the strengthened glass meets a specific function relationship; within the range of 0.45-0.

Abstract: A salt bath for glass reinforcement, including a nitrate and a metal compound. The mass fraction of the nitrate is not less than 50%, and the nitrate is in a molten state. The metal compound is fused into the nitrate, and the metal compound contains the same metal element as the nitrate. The mass fraction of the metal element in the molecular formula corresponding to the metal compound is greater than the mass fraction in the molecular formula corresponding to the nitrate. Thus, compared with the existing salt bath, under the condition of the same mass, the salt bath can provide more effective amount of metal ions, thereby increasing the strength of glass after reinforcement, and at the same time, the lifetime of the salt bath is increased, reducing the waste of resources and environmental pollution.

Abstract: Disclosed are a strengthened glass article and a manufacturing method therefor. The strengthened glass article surface has a surface compressive stress layer formed by an ion exchange method, and the internal tensile stress distributions in different regions of the strengthened glass article are different. The manufacturing method comprises: step S1, coating a partial region of glass to be strengthened with a high temperature-resistant protective coating, and subjecting the protective coating to curing; step S2, placing the glass to be strengthened into a first ion exchange salt bath for chemical strengthening; step S3, taking out the glass to be strengthened from the first ion exchange salt bath, and washing the glass to be strengthened; and step S4, removing the protective coating on the glass to be strengthened. The strengthened glass article not only can ensure that the overall strength meets requirements, but also has sufficient strong safety performance.

Abstract: Disclosed is a mother glass. The mother glass has a thickness range of 0.4 mm-2.0 mm, the transmittance of light with wavelength of 550 nm to the mother glass is in a range of 86%-92.2%; the refraction coefficient of the mother glass is in a range of 1.48-1.54; and the alkali metal oxide content in the mother glass is 11 mol %-22 mol %, wherein the Na oxide content is 5 mol %-18 mol %, and the Al oxide content is 7 mol %-16 mol %. A reinforced glass prepared from the same mother glass and a preparation method therefore are also disclosed.

Abstract: The present invention provides an on-line method for stabilizing surface compressive stress of chemically-tempered glass, which comprises the steps of: placing glass to be tempered together with a stabilizer in a tempering furnace containing a molten salt bath for glass tempering; and after reacting at a temperature for a period of time, removing the glass and the stabilizer from the tempering furnace. The stabilizer is capable of chemically reacting with impurity ions in the molten salt bath for glass tempering, to remove the impurity ions in the molten salt bath. Therefore, the presence of the stabilizer allows the impurity ion content in the molten salt bath for glass tempering to be stable without gradual accumulation.

Abstract: The present invention provides an on-line method for stabilizing surface compressive stress of chemically-tempered glass, which comprises the steps of: placing glass to be tempered together with a stabilizer in a tempering furnace containing a molten salt bath for glass tempering; and after reacting at a temperature for a period of time, removing the glass and the stabilizer from the tempering furnace. The stabilizer is capable of chemically reacting with impurity ions in the molten salt bath for glass tempering, to remove the impurity ions in the molten salt bath. Therefore, the presence of the stabilizer allows the impurity ion content in the molten salt bath for glass tempering to be stable without gradual accumulation.