The invention comprises a concrete form. The concrete form comprises a first mold for concrete and a second mold for concrete, the first and second molds being in thermal communication with each other. The concrete form also comprises thermal insulating material substantially surrounding the first and second molds but not between the first and second molds. A method of using the concrete form is also disclosed.

Cementitious compositions comprising lime, which may be foamed or non-foamed compositions, may increase carbon dioxide uptake of the cementitious compositions. Said cementitious compositions may be used in various cementing methods including pre-casting methods, cast-in-place methods, and primary or secondary cementing operations in a wellbore. The carbon dioxide may be added to the cementitious compositions during mixing, during pre-conditioning, during curing, or any combination thereof. Further, the carbon dioxide may be delivered as a gas (e.g., a gas that includes 1 vol % to 100 vol % carbon dioxide) or as a gas-entrained admixture that includes the gas, water, and a foaming agent.

Cementitious compositions comprising lime, which may be foamed or non-foamed compositions, may increase carbon dioxide uptake of the cementitious compositions. Said cementitious compositions may be used in various cementing methods including pre-casting methods, cast-in-place methods, and primary or secondary cementing operations in a wellbore. The carbon dioxide may be added to the cementitious compositions during mixing, during pre-conditioning, during curing, or any combination thereof. Further, the carbon dioxide may be delivered as a gas (e.g., a gas that includes 1 vol % to 100 vol % carbon dioxide) or as a gas-entrained admixture that includes the gas, water, and a foaming agent.

Disclosed is a method for producing a porous monolithic material from at least one powder, preferably mineral, the method including at least one step of low-temperature compression of a mixture based on powder and at least one solvent, preferably water. The materials produced by the method have improved mechanical properties compared to the prior art materials. The materials for medical application, such as hydroxyapatite, also have improved biocompatibility compared to the prior art materials. Also disclosed are materials produced by the method.

Disclosed is a method for producing a porous monolithic material from at least one powder, preferably mineral, the method including at least one step of low-temperature compression of a mixture based on powder and at least one solvent, preferably water. The materials produced by the method have improved mechanical properties compared to the prior art materials. The materials for medical application, such as hydroxyapatite, also have improved biocompatibility compared to the prior art materials. Also disclosed are materials produced by the method.

The present invention discloses a decorative High Pressure Laminate (HPL) and production method thereof, which relates to the technical field of building decoration materials. The raw materials of HPL may include magnesium oxide, magnesium sulfate, water, fiber, perlite, glass fabric, quartz powder and modifier, wherein the percentage by weight of magnesium oxide is 35% to 40%, the percentage by weight of magnesium sulfate is 20% to 25%, the percentage by weight of water is 20% to 25%, the percentage by weight of fibers is 5% to 10%, the percentage by weight of perlites is 0.5% to 0.9%, the percentage by weight of glass fabrics is 1% to 2%, the percentage by weight of quartz powder is 8% to 12%, and the percentage by weight of modifier is 0.1% to 0.5%. According to the technical solutions, the disclosed HPL may include magnesium oxide, magnesium sulfate, water, fiber, perlite, glass fabric, quartz powder and modifier according to appropriate proportions, and the product produced has low hygroscopicity, no helogenation, no rust, no discoloration, and has high anti-demolition force; moreover, magnesium sulfate has no corrosion on the glass fabric, thus, the laminate has a long life.

Artificial stone having excellent mechanical and weatherability properties is prepared from a highly filled crosslinkable organosilicon composition where the filler comprises at least 20 weight percent of coarse fillers, the organosilicon component contains silicon-bonded alkoxy and or hydroxyl groups, with a catalyst containing a metal compound and an amidine or guanidine.

Artificial stone having excellent mechanical and weatherability properties is prepared from a highly filled crosslinkable organosilicon composition where the filler comprises at least 20 weight percent of coarse fillers, the organosilicon component contains silicon-bonded alkoxy and or hydroxyl groups, with a catalyst containing a metal compound and an amidine or guanidine.