A method for manufacturing composite electroceramics comprises obtaining sintered electroceramic waste material. The waste material is grinded to obtain first ceramic powder having a particle size of 10-400 micron. The first ceramic powder is mixed with NaCl, Li.sub.2MoO.sub.4 or other ceramic powder having a particle size of 0.5-20 micron, in a ratio of 60-90 vol-% said first ceramic powder and 10-40 vol-% NaCl, Li.sub.2MoO.sub.4 or other ceramic powder. The obtained ceramic powder mixture is mixed with aqueous solution of NaCl, Li.sub.2MoO.sub.4 or said other ceramic, in a ratio of 70-90 wt-% the ceramic powder mixture, and 10-30 wt-% the aqueous solution. The obtained homogeneous mass is compressed in a mould for 2-10 min in room temperature and in a pressure of 100-400 MPa. The compressed homogeneous mass is removed from the mould, thereby obtaining electroceramic composite material. Alternatively to the use of the water soluble salt an organometallic precursor compound can be used.

A shaped thermal energy storage ceramic and its method of preparation including milling refractory waste exhibiting a diameter of 1 mm or less to form powder, sieving the powder to retain the powder having a particle size below 250 um, combining with a binder as clay or polymer, and water to form at least one of an extrudable paste and a granulated mixture, forming a green body from at least one of an extrudable paste and a granulated mixture, drying the green body, firing the green body to form the ceramic product at a temperature in the range of 1000 deg C. to 1400 deg C. for a time period in the range of 0.5 hours to 12 hours, and cooling the ceramic product.

A method for treating refractory ceramic products is described herein. The method includes providing a refractory ceramic product, comprising magnesia and at least one of the following salts: one or more alkali salts and one or more alkaline earth salts. The method also includes providing a water-based liquid, combining the refractory ceramic product with the liquid, and separating the refractory ceramic product and the liquid.

A method and apparatus for additive manufacturing is provided whereby a curtain of powder is provided adjacent a vertically oriented build plate, and a laser melts or sinters the powder over a region of the build plate. The curtain of powder is moved relative to the build plate to maintain the same distance between the curtain and the previously deposited layer, and the process repeated to provide a three dimensional structure on the build plate.

A brake disk of a composite material includes a load part and friction parts coupled to opposing sides of the load part, wherein the load part includes a reinforcing part formed of a carbon-carbon fiber (C-CF) material and a matrix part formed of a material including silicon carbide (SiC) and covering the reinforcing part, and a weight ratio of the reinforcing part is equal to or lower than a weight ratio of the matrix part in the load part.

A method for recovering valuable metals and simultaneously preparing ceramsite by roasting cyanide tailing belongs to the area of comprehensive recovery and high value utilization of metallurgical waste residue. In this method, cyanide tailings, bentonite, calcium chloride, coal powder and albite are mixed by ball milling according to certain weight ratio to get a mixture. After drying and roasting twice, dust is collected from the roasted ash, the obtained polymetallic ash is collected and treated. The secondary calcined material is cooled to obtain ceramsite. The invention volatilizes and recovers the valuable metal in the roasting and sintering process of cyanide tailings and directly prepares the ceramsite through reasonable batching, which achieves the effect of recycling cyanide tailings and high-value utilization, can create good economic and environmental benefits, and has significant effect of energy saving and consumption reduction.

According to one aspect of the invention, a method to create a ceramic waste form from used nuclear fuel. An active metal salt waste, a rare earth metal waste, and raw materials are received. The active metal salt waste is combined with the rare earth metal waste, forming a waste salt. The waste salt is then heated to approximately 500 C. The raw materials are also heated to approximately 500 C. The waste salt and raw materials are then blended to form a homogenous waste mixture. The homogenous waste mixture is heated to a first predetermined temperature for a predetermined amount of time, creating a ceramic waste form. The ceramic waste form is cooled to a second predetermined temperature.

According to one aspect of the invention, a method to create a ceramic waste form from used nuclear fuel. An active metal salt waste, a rare earth metal waste, and raw materials are received. The active metal salt waste is combined with the rare earth metal waste, forming a waste salt. The waste salt is then heated to approximately 500 C. The raw materials are also heated to approximately 500 C. The waste salt and raw materials are then blended to form a homogenous waste mixture. The homogenous waste mixture is heated to a first predetermined temperature for a predetermined amount of time, creating a ceramic waste form. The ceramic waste form is cooled to a second predetermined temperature.

A heating element is used, a periphery of the heating element is covered with a net-shaped conductor, the conductor and a carbon fiber bundle are electrically connected with a connecting tool at one end of the heating element, a periphery of the conductor is covered with an outer skin having flexibility, thermal conductivity and an insulating property, and the other end of the heating element is provided with a power supply terminal configured to supply power.

The invention provides a glazed composite manufactured using waste materials, wherein the waste materials are capable of producing ceramic forming oxides, glass modifying oxides and ceramic modifying oxides. The waste materials include ceramic waste and colored glass waste. The invention also provides a method for manufacturing composition of the glazed composite.