The disclosed subject matter concerns earth based mixtures, methods of preparing mixtures, and a process of forming articles of manufacture, as well as a process of manufacturing articles in molds configured for compression molding of earth based mixtures in accordance with the disclosed subject matter, including mixtures containing one or more of, e.g., sand, silt, clay, minerals, or any combination thereof.

The disclosed subject matter concerns earth based mixtures, methods of preparing mixtures, and a process of forming articles of manufacture, as well as a process of manufacturing articles in molds configured for compression molding of earth based mixtures in accordance with the disclosed subject matter, including mixtures containing one or more of, e.g., sand, silt, clay, minerals, or any combination thereof.

Bentonite-based grout fluids and methods of using the grout fluids are provided. A method of using a grout fluid includes placing a geothermal conduit in at least one hole in the earth, providing a grout fluid consisting essentially of water and a bentonite-based grout, wherein the bentonite-based grout consists essentially of calcium carbonate, a bentonite, one or more grout-setting modifiers, and one or more thermally conductive materials, introducing the grout fluid into a space between the geothermal conduit and sidewalls of the at least one hole so that the grout fluid is in contact with the geothermal conduit, and after introducing the grout fluid, allowing the grout fluid to set to fix the geothermal conduit to the at least one hole, wherein after setting, the grout fluid has a hydraulic conductivity of between about 1×10.sup.−7 cm/s and about 1×10.sup.−9 cm/s.

Bentonite-based grout fluids and methods of using the grout fluids are provided. A method of using a grout fluid includes placing a geothermal conduit in at least one hole in the earth, providing a grout fluid consisting essentially of water and a bentonite-based grout, wherein the bentonite-based grout consists essentially of calcium carbonate, a bentonite, one or more grout-setting modifiers, and one or more thermally conductive materials, introducing the grout fluid into a space between the geothermal conduit and sidewalls of the at least one hole so that the grout fluid is in contact with the geothermal conduit, and after introducing the grout fluid, allowing the grout fluid to set to fix the geothermal conduit to the at least one hole, wherein after setting, the grout fluid has a hydraulic conductivity of between about 1×10.sup.−7 cm/s and about 1×10.sup.−9 cm/s.

The present invention relates to a composition of an intracanal medication agent for medicating root canals for a predetermined period of time. According to one aspect of the invention, there is provided an intracanal medication composition based on a calcium hydroxide component, comprising: calcium hydroxide or a calcium hydroxide producing component as a powder component; and at least one of diethyl sulfoxide (DMSO), N-methyl-2-pyrrolidone (NMP) and diethylene glycol monoethyl ether (DEGEE) as a liquid component.

The present invention relates to a composition of an intracanal medication agent for medicating root canals for a predetermined period of time. According to one aspect of the invention, there is provided an intracanal medication composition based on a calcium hydroxide component, comprising: calcium hydroxide or a calcium hydroxide producing component as a powder component; and at least one of diethyl sulfoxide (DMSO), N-methyl-2-pyrrolidone (NMP) and diethylene glycol monoethyl ether (DEGEE) as a liquid component.

Mix formulation for 3D printing of structures is described, including a composition of an aluminosilicate source and an activator. Also described is a method that includes combining a composition having an aluminosilicate source and an activator with aggregate to yield a mixture, extruding a first quantity of the mixture through a nozzle to form a first layer of the mixture, extruding a second quantity of the mixture through the nozzle to form a second layer of the mixture substantially on the first layer, and curing the first layer and the second layer to yield a structure printed using a 3D printer.

The invention relates to a formulation of a low carbon construction binder including, in a dehydrated form, a raw clay matrix and a deflocculating agent. It also relates to a construction binder, a method of preparing this construction binder, as well as a construction material comprising the construction binder according to the invention.

The invention relates to a formulation of a low carbon construction binder including, in a dehydrated form, a raw clay matrix and a deflocculating agent. It also relates to a construction binder, a method of preparing this construction binder, as well as a construction material comprising the construction binder according to the invention.

The long strand fiberglass-impregnated waterproofing compound may provide a pre-mixed waterproofing compound that eliminates the need for a worker to combine the various elements prior to application. The compound may benefit from the use of long strand fiberglass so as to provide additional strength and resiliency to the compound and may be provided in a container suitable for preventing the compound from drying out before it is applied. The advantages of such a compound include creating a seamless waterproof seal on a surface, as well as adding structural rigidity and strength to the surface, while reducing the amount of time needed to apply the compound. The compound comprises, generally, a waterproofing material combined with a structural lattice in a portable container.