A method for producing a high-purity hydrogen chloride gas comprises performing a purification process that includes the steps 1) to 3) below on a byproduct hydrogen chloride gas: 1) a crude hydrochloric acid generation step of allowing water to absorb the byproduct hydrogen chloride gas; 2) a volatile organic impurity-removed hydrochloric acid generation step of bringing the crude hydrochloric acid obtained in the step 1) into contact with an inert gas at a liquid temperature of 20 to 45° C. to dissipate volatile organic impurities; and 3) a high-purity hydrogen chloride gas generation step of supplying the volatile organic impurity-removed hydrochloric acid obtained in the step 2) to a distillation column and performing distillation under conditions of a column bottom temperature of higher than 60° C. and 108° C. or lower and a column top temperature of 60° C. or lower to distill out a high-purity hydrogen chloride gas.

An apparatus and a process to recover high purity helium from a low helium content feed stream are disclosed. The apparatus includes a first dual reflux pressure swing adsorption (DRPSA) unit and a second DRPSA unit, each unit comprising a high pressure adsorption column and a low pressure adsorption column configured in fluid communication with the high pressure adsorption column. The first DRPSA unit is arranged to receive and separate the feed stream into a first reflux product and a first heavy product and circulate the first reflux product and the first heavy product between the high and low pressure adsorption columns to produce an intermediate helium-enriched stream. The second DRPSA unit is arranged to receive and separate the intermediate helium-enriched stream into a second reflux product and a second heavy product and circulate the second reflux product and the second heavy product between the high and low pressure adsorption columns to produce a high purity helium stream and a waste stream containing helium. The waste stream from the second DRPSA unit is recycled to one of a plurality of locations in the first DRPSA unit to increase helium recovery in the high purity helium stream produced in the second DRPSA unit.

A method for producing a high-purity hydrogen chloride gas comprises performing a purification process that includes the steps 1) to 3) below on a byproduct hydrogen chloride gas: 1) a crude hydrochloric acid generation step of allowing water to absorb the byproduct hydrogen chloride gas; 2) a volatile organic impurity-removed hydrochloric acid generation step of bringing the crude hydrochloric acid obtained in the step 1) into contact with an inert gas at a liquid temperature of 20 to 45 C. to dissipate volatile organic impurities; and 3) a high-purity hydrogen chloride gas generation step of supplying the volatile organic impurity-removed hydrochloric acid obtained in the step 2) to a distillation column and performing distillation under conditions of a column bottom temperature of higher than 60 C. and 108 C. or lower and a column top temperature of 60 C. or lower to distill out a high-purity hydrogen chloride gas.

This invention introduces practical procedures for concentration, purification and utilization of rare antigravitational hydrogen atoms created during early universe or later violent astronomical events following pair-production symmetry. A tall cryogenic concentration container maintains liquid hydrogen at extremely low, uniform and stable temperature with minimal convection and thermal diffusion. Rare molecules with zero gravity containing one rare antigravitational hydrogen atoms drift up and accumulate to the top by buoyancy. The concentrated zero-gravity hydrogen molecules are then chemically and/or physically broken down into individual atoms and recombined resulting in hydrogen molecules carrying normal gravity, zero gravity, and repulsive antigravity, respectively. When liquified and maintained in the cryogenic concentration container, the antigravitational hydrogen molecules are repelled to the top to be separated and purified. Cryogenic containers holding purified antigravitational liquid hydrogen can provide sustained levitation and propulsion for vehicles, aircrafts, space elevators, satellites, and spacecrafts consuming no fuel or energy.