A cement mixture is disclosed that includes an aqueous mending agent that is disbursed within but isolated from the cement mixture, wherein the aqueous mending agent will form molecular bonds with hardened cement that is formed by the cement mixture when the mending agent is permitted to flow within the hardened cement.

A cement mixture is disclosed that includes an aqueous mending agent that is disbursed within but isolated from the cement mixture, wherein the aqueous mending agent will form molecular bonds with hardened cement that is formed by the cement mixture when the mending agent is permitted to flow within the hardened cement.

The invention relates to a method for producing a solid construction material which is preferably substantially free of hydraulic binder, comprising the steps of: a. extracting a mineral fraction comprising argillaceous particles of a soil; b. optionally adjusting the particle size of the mineral fraction extracted, in particular in relation to its clay, sand, gravel or loam content, if necessary; c. preparing a first aqueous grout from at least one part of the mineral fraction extracted and optionally adjusted in terms of particle size; d. adding a dispersant that can disperse the argillaceous particles in the first grout in order to obtain a second aqueous grout, e. adding a coagulant that can promote the agglomeration of the argillaceous particles in the second grout in order to obtain an aqueous construction material grout; f introducing the construction material grout into a formwork; and g. allowing the evaporation of the water contained in the material grout in order to obtain a solid construction material.

The invention relates to a method for producing a solid construction material which is preferably substantially free of hydraulic binder, comprising the steps of: a. extracting a mineral fraction comprising argillaceous particles of a soil; b. optionally adjusting the particle size of the mineral fraction extracted, in particular in relation to its clay, sand, gravel or loam content, if necessary; c. preparing a first aqueous grout from at least one part of the mineral fraction extracted and optionally adjusted in terms of particle size; d. adding a dispersant that can disperse the argillaceous particles in the first grout in order to obtain a second aqueous grout, e. adding a coagulant that can promote the agglomeration of the argillaceous particles in the second grout in order to obtain an aqueous construction material grout; f introducing the construction material grout into a formwork; and g. allowing the evaporation of the water contained in the material grout in order to obtain a solid construction material.

The present invention relates to an additive for hydraulically setting compositions, comprising a colloidally disperse preparation of at least one water-soluble salt of a polyvalent metal cation, at least one compound capable of releasing an anion which forms a sparingly soluble salt with the polyvalent metal cation, and at least one polymeric dispersant which comprises anionic and/or anionogenic groups and polyether side chains.

The present invention relates to an additive for hydraulically setting compositions, comprising a colloidally disperse preparation of at least one water-soluble salt of a polyvalent metal cation, at least one compound capable of releasing an anion which forms a sparingly soluble salt with the polyvalent metal cation, and at least one polymeric dispersant which comprises anionic and/or anionogenic groups and polyether side chains.

A hydraulic binder includes a Portland clinker having a Blaine specific surface of 4000 to 5500 cm.sup.2/g, from 2.5 to 8% of sulphate expressed by mass of SO.sub.3 relative to the mass of clinker, from 1.5 to 10% of calcium nitrite and/or calcium nitrate expressed as anhydrous mass relative to the mass of clinker and from 15 to 50% of a mineral addition including calcium carbonate by mass relative to the total mass of binder.

A hydraulic binder includes a Portland clinker having a Blaine specific surface of 4000 to 5500 cm.sup.2/g, from 2.5 to 8% of sulphate expressed by mass of SO.sub.3 relative to the mass of clinker, from 1.5 to 10% of calcium nitrite and/or calcium nitrate expressed as anhydrous mass relative to the mass of clinker and from 15 to 50% of a mineral addition including calcium carbonate by mass relative to the total mass of binder.

Bioactive, ceramic medical cements and methods for its use in treatment of bones and teeth in mammals are disclosed. This cement is non-exothermic and non-toxic, based upon setting of hydraulic ceramic compounds containing calcia, alumina, and silica phases. The self-hardening cement sets in vivo and in high humidity environments, and can be used in vivo without being easily washed out of the site. It also has dimensional stability, is resistant to acids present in an infection site or supragingivally, and has biocompatibility advantages of low inflammation and the formation of calcification layers in direct apposition to body tissue. Options include the addition of various radiopaque materials, and a variety of delivery systems including powder and liquid, capsule or pouch delivery, multiple pastes, or a unitary paste.

Bioactive, ceramic medical cements and methods for its use in treatment of bones and teeth in mammals are disclosed. This cement is non-exothermic and non-toxic, based upon setting of hydraulic ceramic compounds containing calcia, alumina, and silica phases. The self-hardening cement sets in vivo and in high humidity environments, and can be used in vivo without being easily washed out of the site. It also has dimensional stability, is resistant to acids present in an infection site or supragingivally, and has biocompatibility advantages of low inflammation and the formation of calcification layers in direct apposition to body tissue. Options include the addition of various radiopaque materials, and a variety of delivery systems including powder and liquid, capsule or pouch delivery, multiple pastes, or a unitary paste.