A method for removing a ceramic coating from a substrate is presented. The method includes contacting the ceramic coating with a composition including a fluoride source and nitric acid. A method of forming a component having a variation in saturation magnetization is presented. The method includes masking selected portions of a surface of a metallic component using a ceramic coating to form a masked metallic component; selectively diffusing nitrogen into the metallic component by exposing the masked metallic component to a nitrogen-rich atmosphere; and removing the ceramic coating from the surface of the metallic component by contacting the ceramic coating with a composition including the fluoride source and nitric acid.

A ceramic deep-frying device capable of withstanding high temperatures and releasing far-infrared energy is made by grinding and mixing mullite, spodumene, energy ceramic material, ball clay, and kaolin clay into clay blank; molding the blank into ceramic green body; and sintering the green body at 1250-1320 C. for 18-24 hours. The device is completely immersed in the oil in a deep-frying vessel while leaving a gap between the device and heating pipe in the vessel or the inner bottom wall of the vessel, for enabling the oil to circulate through the through holes in the device due to temperature difference in the oil, causing the energy ceramic material to release anions and far-infrared rays that decrease van der Waals forces between oil molecules, and hence split, the oil molecules, thereby extending the service life of the oil, shortening the deep-frying time required, and lowering the oil content of deep-fried food.

In an embodiment, a method of manufacturing customized ceramic labial/lingual orthodontic brackets by additive manufacturing may comprise measuring dentition data of a profile of teeth of a patient, based on the dentition data, creating a three-dimensional computer-assisted design (3D CAD) model of the patient's teeth, and saving the 3D CAD model, designing a virtual 3D CAD bracket structure model for a single labial or lingual bracket structure based upon said 3D CAD model, importing data related to the 3D CAD bracket structure model into an additive manufacturing machine, and directly producing the bracket with the additive manufacturing machine by layer manufacturing from an inorganic material including at least one of a ceramic, a polymer-derived ceramic, and a polymer-derived metal.

A method for fabricating a filter member includes: mixing a predetermined amount of zeolite with alumina to form a composite mixture; spraying a coating material onto the composite mixture to form a coated composite mixture including granules; filtering the granules to obtain granules having a predetermined length dimension; shaping the obtained granules to form a compacted disc having a predetermined thickness; and heat-treating the compacted disc to form a filter member.

A method for fabricating a filter member includes: mixing a predetermined amount of zeolite with alumina to form a composite mixture; spraying a coating material onto the composite mixture to form a coated composite mixture including granules; filtering the granules to obtain granules having a predetermined length dimension; shaping the obtained granules to form a compacted disc having a predetermined thickness; and heat-treating the compacted disc to form a filter member.

A method for removing a ceramic coating from a substrate is presented. The method includes contacting the ceramic coating with a composition including a fluoride source and nitric acid. A method of forming a component having a variation in saturation magnetization is presented. The method includes masking selected portions of a surface of a metallic component using a ceramic coating to form a masked metallic component; selectively diffusing nitrogen into the metallic component by exposing the masked metallic component to a nitrogen-rich atmosphere; and removing the ceramic coating from the surface of the metallic component by contacting the ceramic coating with a composition including the fluoride source and nitric acid.

A method for removing a ceramic coating from a substrate is presented. The method includes contacting the ceramic coating with a composition including a fluoride source and nitric acid. A method of forming a component having a variation in saturation magnetization is presented. The method includes masking selected portions of a surface of a metallic component using a ceramic coating to form a masked metallic component; selectively diffusing nitrogen into the metallic component by exposing the masked metallic component to a nitrogen-rich atmosphere; and removing the ceramic coating from the surface of the metallic component by contacting the ceramic coating with a composition including the fluoride source and nitric acid.

The present invention relates to a ceramic glaze with improved aesthetic and technical possibilities for application on ceramic substrates by means of digital inkjet technology, and which comprises a high content of frits and/or ceramic raw materials having a large particle size. Said glaze also comprises water, at least one solvent from the family of glycols, carboxymethylcellulose, sodium chloride, and/or at least one acrylic compound, and/or at least one polyurethane compound.

The present invention relates to a ceramic glaze with improved aesthetic and technical possibilities for application on ceramic substrates by means of digital inkjet technology, and which comprises a high content of frits and/or ceramic raw materials having a large particle size. Said glaze also comprises water, at least one solvent from the family of glycols, carboxymethylcellulose, sodium chloride, and/or at least one acrylic compound, and/or at least one polyurethane compound.

A composite ceramic powder of the present invention includes: a LAS-based ceramic powder having precipitated therein -eucryptite or a -quartz solid solution as a main crystal; and TiO.sub.2 powder and/or ZrO.sub.2 powder,.