Photoluminescent sand preferably includes play sand, photoluminescent pigment, a powdered binder and a curing agent. The play sand is preferably mixed with the photoluminescent pigment to form a photo sand mix. The photo sand mix is then mixed with the powered binder and curing agent to form the photoluminescent sand mix. The photoluminescent sand mix is allowed to cure for between 3-7 days to form the photoluminescent sand.

A macro-cement and associated methods useful for preparing pastes, mortars, concretes and other cement-based materials having high workability, high density, and high strength are disclosed. A method of producing a macro-cement includes cement, supplemental cementitious materials (SCM's), including siliceous submicron-sized particles and nano-sized particles, and polymers in the form of liquid or dry chemical admixtures for concrete. The cement mixture may be used for making ultra-high performance concrete (UHPC).

A macro-cement and associated methods useful for preparing pastes, mortars, concretes and other cement-based materials having high workability, high density, and high strength are disclosed. A method of producing a macro-cement includes cement, supplemental cementitious materials (SCM's), including siliceous submicron-sized particles and nano-sized particles, and polymers in the form of liquid or dry chemical admixtures for concrete. The cement mixture may be used for making ultra-high performance concrete (UHPC).

Disclosed herein are novel compositions for the production of granule products, and uses of the same. Said granule products may comprise one or more of an input material, fibers, a binder, moisture, and an additive. Also disclosed are processes and systems for making the same and methods of using the same. A process for manufacturing granules may include mixing and granulating input material, fibers, a binder, and water using a mixer to produce wet granules, drying and cooling the wet granules, and separating at least one of dry overs and dry fines from the dried, cooled granules using a classifier.

Disclosed herein are novel compositions for the production of granule products, and uses of the same. Said granule products may comprise one or more of an input material, fibers, a binder, moisture, and an additive. Also disclosed are processes and systems for making the same and methods of using the same. A process for manufacturing granules may include mixing and granulating input material, fibers, a binder, and water using a mixer to produce wet granules, drying and cooling the wet granules, and separating at least one of dry overs and dry fines from the dried, cooled granules using a classifier.

A prepreg suitable for use in order to reinforce a concrete or a load bearing material is provided, and the prepreg includes a polymer matrix comprising at least two components, and at least one fiber. The polymer matrix is in a ratio of 50-70% by weight relative to a total weight of the prepreg and the at least one fiber is in a ratio of 30-50% by weight relative to the total weight of the prepreg. Furthermore, the prepreg is used for damaged structures, structures with a modified structural function, or reinforcement in concretes.

A prepreg suitable for use in order to reinforce a concrete or a load bearing material is provided, and the prepreg includes a polymer matrix comprising at least two components, and at least one fiber. The polymer matrix is in a ratio of 50-70% by weight relative to a total weight of the prepreg and the at least one fiber is in a ratio of 30-50% by weight relative to the total weight of the prepreg. Furthermore, the prepreg is used for damaged structures, structures with a modified structural function, or reinforcement in concretes.

An energy-saving building system using a porous silicate material for thermal insulation, comprises a foundation, a retaining wall body, and a roof system. The foundation comprises a ground ring beam and columns, and a porous silicate thermal insulation material is cast around the ground ring beam and the columns; the porous silicate thermal insulation material is composed of an organic lightweight aggregate and a lightweight inorganic matrix, and the lightweight inorganic matrix is provided thereon with a plurality of micropores; the retaining wall body comprises an outer wall disposed on the ground ring beam, the outer wall comprises an outer side support body, an inner side support body, and the porous silicate thermal insulation material cast between the inner and outer side support bodies, and the outer side support body and the inner side support body are connected therebetween by means of a heat insulating connection member.

An energy-saving building system using a porous silicate material for thermal insulation, comprises a foundation, a retaining wall body, and a roof system. The foundation comprises a ground ring beam and columns, and a porous silicate thermal insulation material is cast around the ground ring beam and the columns; the porous silicate thermal insulation material is composed of an organic lightweight aggregate and a lightweight inorganic matrix, and the lightweight inorganic matrix is provided thereon with a plurality of micropores; the retaining wall body comprises an outer wall disposed on the ground ring beam, the outer wall comprises an outer side support body, an inner side support body, and the porous silicate thermal insulation material cast between the inner and outer side support bodies, and the outer side support body and the inner side support body are connected therebetween by means of a heat insulating connection member.

A composition for artificial marble, of the present invention comprises: a binder resin; an inorganic filler excluding zinc oxide; and zinc oxide, wherein the zinc oxide has a size ratio (B/A), in which peak A is a 370 nm to 390 nm region and peak B is a 450 nm to 600 nm region, of approximately 0.01 to 1 during photoluminescence measurement, and has a BET surface area of approximately 10 m.sup.2/g or less.