Abstract: Methods of using the alpha-2-adrenergic receptor agonist of Formula I: for improving vision such as in the treatment of ocular conditions such as presbyopia, poor night vision, visual glare, visual starbursts, visual halos, and some forms of myopia (e.g. night myopia) are described.

Abstract: Methods of using the alpha-2-adrenergic receptor agonist of Formula I: for improving vision such as in the treatment of ocular conditions such as presbyopia, poor night vision, visual glare, visual starbursts, visual halos, and some forms of myopia (e.g. night myopia) are described.

Abstract: Methods of using the alpha-2-adrenergic receptor agonist of Formula I: for improving vision such as in the treatment of ocular conditions such as presbyopia, poor night vision, visual glare, visual starbursts, visual halos, and some forms of myopia (e.g. night myopia) are described.

Abstract: Methods of using the alpha-2-adrenergic receptor agonist of Formula I: for improving vision such as in the treatment of ocular conditions such as presbyopia, poor night vision, visual glare, visual starbursts, visual halos, and some forms of myopia (e.g. night myopia) are described.

Abstract: Methods of using the alpha-2-adrenergic receptor agonist of Formula I: for improving vision such as in the treatment of ocular conditions such as presbyopia, poor night vision, visual glare, visual starbursts, visual halos, and some forms of myopia (e.g. night myopia) are described.

Abstract: The present invention relates to therapeutic methods using pharmaceutical compositions comprising one or a combination of co-agonists at the N-methyl-D-aspartate receptor for the treatment of visual system disorders.

Abstract: The present invention relates to therapeutic methods using pharmaceutical compositions comprising one or a combination of co-agonists at the N-methyl-D-aspartate receptor for the treatment of visual system disorders.

Abstract: A mechanism and flow conduits for introducing and transporting a set of separated fluids and a stream of solid fines through passageway in a rotating metallurgical converter for introducing such fluids and solid fines into a liquid metal contained in the converter.Stationary conduits from flow sources connect to a non rotative sleeve which forms the external portion of a rotary joint able to introduce a set of separated fluids into the rotating converter passageways. Each separated stationary fluid conduit connects to port holes in the fixed sleeve to lead the flow to the interior of the sleeve, and connects a circumferential channel formed in rotating rings located between a rotating shaft affixed to the converter vessel trunnion pin and the static sleeve with a seal between each adjacent ring and corresponding channel. A port hole is located in each rotating channel ring for leading the fluid through internal flow paths inside and along the axis of the shaft body.

Abstract: This invention relates to a device used in the selection between two fluids that are to be injected into a liquid metal contained in a metallurgical converter: an oxidizing gas and another gas conveying powdered carbonaceous material; both fluids arrive through different conduits to a selecting valve located at the bottom of a metallurgical converter just before a single conduit tuyere for leading one of the fluids to the liquid metal by means of the selective mechanism in such valve.

Abstract: This invention relates to a rotary joint for introducing a plurality of different separated fluids from a first static system, to a second system that is rotating with respect to the first, namely for passing fluids and solid fines carried in fluids into a rotatable iron converter through rotary trunnion couplings. The separated different fluids are passed simultaneously through a stationary cylindrical sleeve surrounding a rotating core shaft coupled to the trunnion. Conduits housed in such stationary sleeve pass the fluids to separate circumferential channels axially located along the rotating shaft from which a set of independent lines transporting fluids axially through the trunnion which is rotating with respect to the receiving static sleeve. Between the separate channels in the rotating shaft there are seals that do not permit the passage of a fluid from a given channel conduit into any other. This makes the conduction of fluids in the lines and/or channels independent of each other.

Abstract: Improved method for producing steel with the combination of a basic oxygen furnace and a sponge iron plant. The sponge iron produced with a high carbon content, is loaded into the basic oxygen furnace in which oxygen and any type of powder carbon are injected through the bottom. During the melting and refining process, enough reducing gases are produced to yield all the energy needed to reduce iron ore into sponge iron in a batch process following the basic oxygen furnace cycles or continuous cycles. The gas produced per ton of liquid metal in the basic oxygen furnace is enough to produce iron as sponge iron.

Abstract: A method for making high quality liquid iron with substantially no residual chemical elements and a controlled content of carbon, manganese, phosphorous, sulfur and silicon in the final metal. Sponge iron, as raw material, is melted in a vessel or converter with a basic refractory lining. The energy required for melting the sponge iron is provided by the exothermic reaction of carbon from any coal or carbonaceous material and oxygen in solution within the metal bath and by the combustion of other hydro-carbon fluids, all injected to the bath through nozzles preferably located in the bottom of the converter. Further energy is obtained with the post-combustion of gases leaving the metal bath when ascending to the upper port of the converter.