The invention relates to the use of feldspar granules with a particular combination of oxide constituents in the manufacture of artificial agglomerate stone materials and to the agglomerate stone materials resulting thereof.

This invention discloses an artificial stone with glass as main material, which is characterized by that, its raw materials calculated by mass percent include: resin 8-16%, quartz sand aggregate 0-45%, glass particle aggregate 14-60%, quartz powder 0-32%, glass powder 0-32%, ultrafine quartz powder 0-5% and pigment 0-2%; its main materials also include curing agent and coupling agent, the mass ratio of the curing agent and the resin used is 0.5-2:100, and the mass ratio of the coupling agent and the resin used is 0.5-2:100; in the formula of artificial stone, the total mass of glass particle aggregate and glass powder is greater than the total mass of quartz sand aggregate, quartz powder and ultrafine quartz powder. The artificial stone in this invention takes glass particle and powder materials as main fillers, a new formula system is formed, and a new artificial stone is obtained, with a better permeability.

This invention discloses an artificial stone with glass as main material, which is characterized by that, its raw materials calculated by mass percent include: resin 8-16%, quartz sand aggregate 0-45%, glass particle aggregate 14-60%, quartz powder 0-32%, glass powder 0-32%, ultrafine quartz powder 0-5% and pigment 0-2%; its main materials also include curing agent and coupling agent, the mass ratio of the curing agent and the resin used is 0.5-2:100, and the mass ratio of the coupling agent and the resin used is 0.5-2:100; in the formula of artificial stone, the total mass of glass particle aggregate and glass powder is greater than the total mass of quartz sand aggregate, quartz powder and ultrafine quartz powder. The artificial stone in this invention takes glass particle and powder materials as main fillers, a new formula system is formed, and a new artificial stone is obtained, with a better permeability.

An artificial stone with non-natural mineral as main material, its raw materials calculated by mass percent include: resin 8-16%, quartz sand aggregate 0-45%, glass particle aggregate 14-60%, quartz powder 0-32%, glass powder 0-32%, tile powder 5-32%, ultrafine quartz powder 0-5% and pigment 0-2%; its main materials also include curing agent and coupling agent; in the formula of artificial stone, the total mass of glass particle aggregate and glass powder is greater than the total mass of quartz sand aggregate, quartz powder and ultrafine quartz powder. Glass particle aggregate and glass powder are made of recycled waste glass, and tile powder is made of recycled waste vitreous polished tiles. The artificial stone in this invention takes non-natural minerals as main fillers, a new formula system is formed, which adopts wastes as main padding, provides more recycling applications of wastes and has more environmental protection meanings.

An artificial stone with non-natural mineral as main material, its raw materials calculated by mass percent include: resin 8-16%, quartz sand aggregate 0-45%, glass particle aggregate 14-60%, quartz powder 0-32%, glass powder 0-32%, tile powder 5-32%, ultrafine quartz powder 0-5% and pigment 0-2%; its main materials also include curing agent and coupling agent; in the formula of artificial stone, the total mass of glass particle aggregate and glass powder is greater than the total mass of quartz sand aggregate, quartz powder and ultrafine quartz powder. Glass particle aggregate and glass powder are made of recycled waste glass, and tile powder is made of recycled waste vitreous polished tiles. The artificial stone in this invention takes non-natural minerals as main fillers, a new formula system is formed, which adopts wastes as main padding, provides more recycling applications of wastes and has more environmental protection meanings.

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.

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.

Disclosed is a method for preparing high-strength coral aggregate concrete under low pressure conditions, including the following steps: weighing cement, mineral admixture, coral aggregate, mixing water, water reducer, and defoamer; mixing the cement and the mineral admixture well to obtain a cementing material; putting the coral aggregate, sea water, water reducer, defoamer, and 55-85% of the cementing material into a closed mixing system to stir for 10-15 min under low pressure conditions, and pouring the remaining cementing material into the mixing system to stir for additional 10-15 min to prepare the high-strength coral aggregate concrete. The high-strength coral aggregate concrete obtained has advantages of high mechanical properties, high compactness, excellent impermeability and durability, drawing on local resources in construction engineering on remote islands and reefs, and maximum resource utilization.

Disclosed is a method for preparing high-strength coral aggregate concrete under low pressure conditions, including the following steps: weighing cement, mineral admixture, coral aggregate, mixing water, water reducer, and defoamer; mixing the cement and the mineral admixture well to obtain a cementing material; putting the coral aggregate, sea water, water reducer, defoamer, and 55-85% of the cementing material into a closed mixing system to stir for 10-15 min under low pressure conditions, and pouring the remaining cementing material into the mixing system to stir for additional 10-15 min to prepare the high-strength coral aggregate concrete. The high-strength coral aggregate concrete obtained has advantages of high mechanical properties, high compactness, excellent impermeability and durability, drawing on local resources in construction engineering on remote islands and reefs, and maximum resource utilization.

A high toughness inorganic composite artificial stone panel and preparation method are disclosed. The panel includes a surface layer, an intermediate metal fiber toughening layer and a substrate toughening layer. The surface layer includes the following components: 40-70 parts of quartz sand, 10-30 parts of quartz powder, 20-45 parts of inorganic active powder, 0.5-4 parts of pigment, 0.3-1 part of water reducer and 3-10 parts of water. The intermediate metal fiber toughening layer includes the following components: 40-60 parts of inorganic active powder, 45-65 parts of sand, 0.8-1.5 parts of water reducer, 6-14 parts of water and 4-8 parts of metal fiber. The substrate toughening layer includes the following components: 30-50 parts of inorganic active powder, 30-55 parts of quartz sand, 15-20 parts of quartz powder, 0.5-1.2 parts of water reducer, 4-8 parts of water and 0.8-2.5 parts of toughening agent.