A method of making a structural lightweight and thermal insulating concrete is described. The concrete has a coarse aggregate partly replaced by recycled plastic pieces. This enables the concrete to maintain a high compressive strength, low thermal conductivity, and low weight, while providing a use for waste plastic. The waste plastic pieces may comprise polyethylene in the form of flakes, fibers, or granules. Due to its low unit weight, adequate compressive strength and high thermal resistance the developed concrete can be used as a structural lightweight and thermal insulating concrete. The use of this concrete leads to economic and environmental benefits.

The present invention specifically relates to equipment and a method for preparing an aerogel thermal insulation mortar for a high-temperature kiln thereof. The equipment comprises a top box, a support frame platform, a processing mechanism, an agitation mechanism, a receiving mechanism and a docking mechanism, wherein the top box is provided with a partition frame capable of dividing an inner space thereof into a first material discharge cavity, a second material discharge cavity, a third material discharge cavity and a fourth material discharge cavity respectively; the receiving mechanism is mounted on an inner top of the support frame platform and docked with the top box; the docking mechanism is mounted on the receiving mechanism; an inner bottom of the support frame platform is provided with a collection box; one side of the top box is provided with a door panel.

Provided is an aerogel blanket and a method for producing the same, wherein a catalyzed sol is sufficiently and uniformly impregnated into a blanket in an impregnation tank, and the catalyzed sol is allowed to stay in the impregnation tank for a specific time to control fluidity while achieving a viscosity at which the catalyzed sol can be easily introduced into the blanket, thereby forming a uniform aerogel in the blanket. As a result, the uniformity of pore structure and thermal insulation performance of an aerogel blanket are improved, the loss of raw materials is reduced through the impregnation process, the occurrence of process problems is reduced, and the generation of dust is reduced.

A method includes utilizing a component A selected from mineral component, sand, wood flour or combinations thereof, for reducing the thermal conductivity of a mineral foam produced by a including contacting a cement slurry and an aqueous foam, the cement composition used to prepare the cement slurry comprising the component A and Portland clinker.

The invention discloses a high impermeability and low thermal conductivity inorganic lightweight foam concrete and its preparation method, including the following mass fraction of raw materials: 1260?1540 parts of ordinary silicate cement, 20?60 parts of nano-silica, 460?740 parts of fly ash, 360?440 parts of aggregate, 9?11 parts of redispersible latex powder, 7.2?8.8 parts of polypropylene fiber, 27?33 parts of quick-setting agent, 500 parts of fluorine-free foam, 900?1100 parts of water. 33 parts, 500 parts of fluorine-free foam, 900?1100 parts of water. The high impermeability and low thermal conductivity inorganic lightweight foam concrete prepared by the present invention has a simple formulation, good workability, light weight and low thermal conductivity, and is suitable for the construction of thermal insulation system for building exterior walls.

The present invention specifically relates to equipment and a method for preparing an aerogel thermal insulation mortar for a high-temperature kiln thereof. The equipment comprises a top box, a support frame platform, a processing mechanism, an agitation mechanism, a receiving mechanism and a docking mechanism, wherein the top box is provided with a partition frame capable of dividing an inner space thereof into a first material discharge cavity, a second material discharge cavity, a third material discharge cavity and a fourth material discharge cavity respectively; the receiving mechanism is mounted on an inner top of the support frame platform and docked with the top box; the docking mechanism is mounted on the receiving mechanism; an inner bottom of the support frame platform is provided with a collection box; one side of the top box is provided with a door panel.

A composition including a binder and a variable thermal conductivity material satisfying a conditional expression 1, wherein a content of the variable thermal conductivity material is from 300 parts by weight to 10,000 parts by weight with respect to a content of 100 parts by weight of the binder:
?.sub.max/?.sub.25?1.2[conditional expression 1] (wherein, ?.sub.25 represents a thermal conductivity at 25? C., and ?.sub.max represents the maximum value of a thermal conductivity at 200? C. or 500? C.).

A porous plate-shaped filler of the present invention is a plate shape having an aspect ratio of 3 or more, a surface shape is one of a round shape, an oval and a round-corner polygonal shape, and its minimum length is from 0.1 to 50 m. Furthermore, a sectional shape is one of an arch shape, an elliptic shape, and a quadrangular shape in which at least a part of corners is rounded. Consequently, it is possible to obtain the heat insulation film in which the porous plate-shaped fillers 1 are easy to be laminated and the heat insulation effect improves.

A structural lightweight concrete composition comprising cement, a fine aggregate such as sand, a natural coarse aggregates, such as limestone, scoria or perlite or mixtures thereof, a synthetic coarse aggregate comprising a polymeric material, such as polypropylene beads, an industrial waste byproduct in the form of fine particles, such as silica fume or heavy oil ash, a superplasticizer, such as a polycarboxylate ether and water demonstrating lower thermal conductivity and sufficient compressive strength. Concrete products made therefrom and methods for producing such products are also provided.

A lightweight thermal insulating cement-based material is formed from a mixture that includes cement, water and a foaming agent. The foaming agent can be an aluminum powder or a surfactant. The insulating material has a maximum use temperature of about 900 degrees Celsius or more.