Abstract: An apparatus and process for dehumidification of a gas stream are provided. The apparatus includes a single semi-permeable osmotic membrane, at least one gas stream compartment, and at least one osmotic fluid compartment. The membrane includes a plurality of hydrophobic surfaced pores, at least some of which hydrophobic surfaced pores are water vapor condensing pores. The water vapor condensing pores are sized such that the hydrophobic surfaces of those pores allow water vapor to enter those pores and repulse the water vapor within those pores away from the hydrophobic surfaces causing the water vapor to condense. The hydrophobic surfaced pores provide a liquid travel path across the thickness of the membrane. The membrane restricts transport of an osmotic fluid across the thickness of the membrane. A refrigeration system utilizing a dehumidification unit and a heat pump system utilizing a dehumidification unit are also disclosed.

Abstract: A process and apparatus for dehumidifying a gas stream is provided. The apparatus includes a single semi-permeable osmotic membrane, at least one gas stream compartment formed in part by the osmotic membrane, and at least one osmotic fluid compartment formed in part by the osmotic membrane. The semi-permeable osmotic membrane has randomly arranged pores disposed across a thickness extending between a first side and a second side, and wherein some of the pores are small enough to permit capillary condensation within the membrane, leading to condensate travel across the thickness of the single membrane without requiring a separate capillary condenser, and which single membrane restricts transport of the osmotic fluid across the thickness of the membrane. The first side of the osmotic membrane is exposed to the gas stream compartment, and the second side of the osmotic membrane is exposed to the osmotic fluid compartment.

Abstract: A process and apparatus for dehumidifying a gas stream is provided. The process includes steps of: a) providing a semi-permeable wall having an osmotic membrane with a plurality of pores at least some of which are operably sized to permit capillary condensation, a first side, and a second side; b) placing an osmotic fluid in a compartment formed in part by the semi-permeable wall, wherein the second side of the osmotic membrane is exposed to the osmotic fluid; c) exposing the first side of the osmotic membrane to the gas stream to be dehumidified; and d) maintaining a sufficiently high water concentration gradient across the osmotic membrane during the dehumidification process to result in a flux of water through the osmotic membrane. The apparatus includes at least one semi-permeable osmotic wall, at least one gas stream compartment formed in part by the osmotic wall, and at least one osmotic fluid compartment formed in part by the osmotic wall.

Abstract: A humid gas stream is dehumidified by bringing that stream into contact with the front surface of a hydrophilic capillary condenser layer that captures the water and moves it adjacent the rear surface of the capillary layer. A semi-permeable collodion membrane, is disposed on the rear capillary surface of the condenser layer, and an osmotic fluid, such as glycerol, is disposed adjacent the collodion membrane. An osmotic driving force, resulting from a water concentration gradient across the collodion membrane, transports the condensed water from the condensing layer through the thickness of the membrane and into an osmotic fluid. The collodion membrane also inhibits the osmotic fluid from flowing into the condenser layer.

Abstract: A humid gas stream is dehumidified by bringing that stream into contact with the front surface of a hydrophilic capillary condenser layer that captures the water and moves it adjacent the rear surface of the capillary layer. A semi-permeable collodion membrane, is disposed on the rear capillary surface of the condenser layer, and an osmotic fluid, such as glycerol, is disposed adjacent the collodion membrane. An osmotic driving force, resulting from a water concentration gradient across the collodion membrane, transports the condensed water from the condensing layer through the thickness of the membrane and into an osmotic fluid. The collodion membrane also inhibits the osmotic fluid from flowing into the condenser layer.