A honeycomb filter includes a pillar-shaped honeycomb structure body having a porous partition wall disposed to surround a plurality of cells and a plugging portion provided at an open end on a first end face side or a second end face side of the cells, wherein the partition wall is composed of a material containing cordierite as a main component, a porosity of the partition wall is 60 to 70%, an average pore diameter of the partition wall is 20 to 30 μm, an open porosity of pores existing at the partition wall surface and having equivalent circle diameters exceeding 1.5 μm is 31% or more, and, in a pore diameter distribution which indicates a cumulative pore volume of the partition wall, a half-value width of a first peak including a maximum value of a log differential pore volume is 0.20 or less.

In one aspect, the disclosure relates to processes for preparation of a carbon foam material, the process comprising devolatization of coal-derived pitches or extracts at atmospheric pressure near green coke temperatures, thereby forming a solid coke-like material. In a further aspect, the process can further comprise grinding the solid coke-like material to a powder, providing the ground powder to a mold, and then reheating above green coking temperature (e.g., >600 C.) to further devolatize the material and form a porous solid foam material. The process further provides carbon materials such as carbon composite materials and sp2-hybridized carbon in the form of graphene oxide or graphene. In various aspects, the disclosure relates to the carbon foam and other materials prepared using the disclosed processes. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present disclosure.

In one aspect, the disclosure relates to processes for preparation of a carbon foam material, the process comprising devolatization of coal-derived pitches or extracts at atmospheric pressure near green coke temperatures, thereby forming a solid coke-like material. In a further aspect, the process can further comprise grinding the solid coke-like material to a powder, providing the ground powder to a mold, and then reheating above green coking temperature (e.g., >600 C.) to further devolatize the material and form a porous solid foam material. The process further provides carbon materials such as carbon composite materials and sp2-hybridized carbon in the form of graphene oxide or graphene. In various aspects, the disclosure relates to the carbon foam and other materials prepared using the disclosed processes. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present disclosure.

In one aspect, the disclosure relates to processes for preparation of a carbon foam material, the process comprising devolatization of coal-derived pitches or extracts at atmospheric pressure near green coke temperatures, thereby forming a solid coke-like material. In a further aspect, the process can further comprise grinding the solid coke-like material to a powder, providing the ground powder to a mold, and then reheating above green coking temperature (e.g., >600 C.) to further devolatize the material and form a porous solid foam material. The process further provides carbon materials such as carbon composite materials and sp2-hybridized carbon in the form of graphene oxide or graphene. In various aspects, the disclosure relates to the carbon foam and other materials prepared using the disclosed processes. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present disclosure.

In one aspect, the disclosure relates to processes for preparation of a carbon foam material, the process comprising devolatization of coal-derived pitches or extracts at atmospheric pressure near green coke temperatures, thereby forming a solid coke-like material. In a further aspect, the process can further comprise grinding the solid coke-like material to a powder, providing the ground powder to a mold, and then reheating above green coking temperature (e.g., >600 C.) to further devolatize the material and form a porous solid foam material. The process further provides carbon materials such as carbon composite materials and sp2-hybridized carbon in the form of graphene oxide or graphene. In various aspects, the disclosure relates to the carbon foam and other materials prepared using the disclosed processes. This abstract is intended as a scanning tool for purposes of searching in the particular art and is not intended to be limiting of the present disclosure.

Methods are described to make strong, tough, and/or lightweight glass-ceramic composites having a crystalline phase and an amorphous phase generated by viscous reaction sintering of a complex mixture of oxides and other materials. The present invention further relates to strong, tough, and lightweight glass-ceramic composites that can be used as proppants and for other uses.

Methods are described to make strong, tough, and/or lightweight glass-ceramic composites having a crystalline phase and an amorphous phase generated by viscous reaction sintering of a complex mixture of oxides and other materials. The present invention further relates to strong, tough, and lightweight glass-ceramic composites that can be used as proppants and for other uses.

In a process for manufacturing foamed material an expansion agent, a ceramic base material and water are blended together. The blend is heated and pressurized to homogenize and liquefy or plasticize it. The blend is then extruded through a die where, in the course of the extrusion, superheated water in the blend vaporizes to foam the blend. To make articles of manufacture, extrudate is cut to length, machined and fired, or is injection molded while still malleable and then fired.

In a process for manufacturing foamed material an expansion agent, a ceramic base material and water are blended together. The blend is heated and pressurized to homogenize and liquefy or plasticize it. The blend is then extruded through a die where, in the course of the extrusion, superheated water in the blend vaporizes to foam the blend. To make articles of manufacture, extrudate is cut to length, machined and fired, or is injection molded while still malleable and then fired.

A low-temperature fast-fired lightweight ceramic heat insulation plate and a preparation method thereof. The preparation method comprises: performing ball milling and powder spraying on a raw material containing foamable ceramic waste slag to prepare foamable powder, the foamable ceramic waste slag accounting for 80-100 wt % of the weight of the raw material; uniformly mixing 100 weight portions of the foamable powder with 3-15 weight portions of granular powder of a low-melting-point organic matter to obtain mixed powder materials; pressing the mixed powder materials under 10-20 MPa to prepare a ceramic green body; and firing the ceramic green body at a temperature of 1100-1170 C. to prepare the lightweight energy-saving ceramic heat insulation plate.