An atmospheric water generation system absorbs water from an atmospheric air stream into a desiccant flowing along a flow path of a closed desiccant circulation loop. To ensure that the desiccant remains within the closed desiccant circulation loop, the atmospheric water generation system encompasses a membrane-based water extraction device that the desiccant flows through. The desiccant flows through the membrane-based water extraction device on a first side of a membrane, and the membrane separates the desiccant from a water-collection flow. Water absorbed into the desiccant passes from the desiccant, through the porous membrane, and into the water-collection flow, at least in part due to differences in temperature and/or pressure characteristics of the water flow and the desiccant flow. Water collected within the water-collection flow is directed to a storage tank for usage.

A method for pressurizing an assembly line grow pod system is provided. The method includes arranging a dual wall including an outer wall and an inner wall, controlling, with an air pressure controller, first air pressure in the first sealed area and second air pressure in the second sealed area, and controlling, with a master controller, operations of the air pressure controller. The first air pressure of the first sealed area is controlled to be higher than pressure of an exterior area to the outer wall by a predetermined amount.

A cultivation greenhouse includes: an inner lining that forms a housing space for housing a plant to be a cultivation target, the inner lining tightly sealing the housing space; an outer lining that is disposed on an outer side of the inner lining to house the inner lining, the outer lining forming, with the inner lining, a circulation space for flowing outside air; and a circulation device that circulates air outside the outer lining into the circulation space and discharges the air to outside of the outer lining.

A method for pressurizing an assembly line grow pod system is provided. The method includes arranging a dual wall including an outer wall and an inner wall, controlling, with an air pressure controller, first air pressure in the first sealed area and second air pressure in the second sealed area, and controlling, with a master controller, operations of the air pressure controller. The first air pressure of the first sealed area is controlled to be higher than pressure of an exterior area to the outer wall by a predetermined amount.

The present invention is generally related to a system for growing plants in a controlled environment, and more particularly related to a system for growing plants in a mobile and controlled environment wherein the system may be built from re-purposed or recycled materials such as one or more shipping containers or box trailers. The herein disclosed system for growing plants in a mobile and controlled environment may be utilized in locations which are not normally suitable for growing and harvesting crops, thus benefiting the local populations of historically unproductive areas.

An architectural glass for use in a greenhouse comprising a substrate having a coating, the coating comprising a first dielectric layer, a metal layer over the first dielectric layer, a second dielectric layer over the metal layer, and a first protective overcoat over the second dielectric layer, wherein the first protective overcoat comprises silica and alumina. A back surface of the glass substrate can be coated with a scattering layer and a second protective overcoat. The architectural glass can be a monolithic glass or a component in an insulated glass unit. A method of increasing photosynthesis efficiencies in an insulated glass unit to greater than 88%, greater than 90%, or greater than 93% is also disclosed.

An atmospheric water generation system absorbs water from an atmospheric air stream into a desiccant flowing along a flow path of a closed desiccant circulation loop. To ensure that the desiccant remains within the closed desiccant circulation loop, the atmospheric water generation system encompasses a membrane-based water extraction device that the desiccant flows through. The desiccant flows through the membrane-based water extraction device on a first side of a membrane, and the membrane separates the desiccant from a water-collection flow. Water absorbed into the desiccant passes from the desiccant, through the porous membrane, and into the water-collection flow, at least in part due to differences in temperature and/or pressure characteristics of the water flow and the desiccant flow. Water collected within the water-collection flow is directed to a storage tank for usage.

An air dome system may comprise: a membrane unit formed of two layers of membrane material, in which a flow path blocker is formed between the membrane materials, and being extended from the front to the rear to form an inner space; an entrance unit disposed at one end of the membrane unit and into which outside air is introduced and filtered; an air conditioning unit connected to the entrance unit to form an air conditioning space and to control the temperature and humidity of the outside air introduced from the entrance unit; a blower unit formed with a blower space to blow air whose temperature and humidity are controlled by the air conditioning unit or air in the inner space; and a distribution line providing a flow path for supplying air being blown from the blower unit to the inner space and the flow path blocker.