A method and a system capable of removing carbon dioxide directly from ambient air, and obtaining relatively pure CO.sub.2. The method comprises the steps of generating usable and process heat from a primary production process; applying the process heat from said primary process to co-generate substantially saturated steam, alternately repeatedly exposing a sorbent to removal and to capture regeneration system phases, wherein said sorbent is alternately exposed to a flow of ambient air during said removal phase, to sorb, and therefore remove, carbon dioxide from said ambient air, and to a flow of the process steam during the regeneration and capture phase, to remove the sorbed carbon dioxide, thus regenerating such sorbent, and capturing in relatively pure form the removed carbon dioxide. The sorbent can be carried on a porous thin flexible sheet constantly in motion between the removal location and the regeneration location.

A honeycomb rotor recovering and concentrating apparatus recovers a gas such as carbon dioxide from flue gases and the like and may be capable of utilizing low-temperature waste heat 100 C. or less. The proposed method involves sorbing carbon dioxide while vaporizing and cooling by contacting a water-insoluble carbon dioxide sorbing material (solid amines, etc.) having an acidic gas sorptive capacity with a mixed gas containing carbon dioxide in a wet state. Warm water is brought into contact with the water-insoluble carbon dioxide sorbing material sorbed with carbon dioxide to desorb high concentration of carbon dioxide. The warm water is separated from the water-insoluble carbon dioxide sorbent material desorbed from carbon dioxide. Then the apparatus is returned from the separation step to the sorption step. Thereby, it is possible to drastically increase the recovery rate and recovery concentration of acidic gas (carbon dioxide) continuously.

A packed bed for a heat exchanger may comprise a frame and a first fin layer disposed within the frame. A second fin layer may be disposed within the frame. A first perforated sheet may be disposed between the first fin layer and the second fin layer. A sorbent material may be disposed within a volume of at least one of the first fin layer or the second fin layer.

A system and method for producing biogas (methane) from a mixture of poultry manure and methanogens through an anerobic digestion process which makes use of jute filters within the chamber to absorb excess ammonium nitrogen from the mixture of poultry manure.

Disclosed herein is a system for purifying air; for the capture of solid residues (soot), and the transformation of CO.sub.x and NO.sub.x (and even methane) present in contaminated air generated by industrial combustion. The purifying air system comprises an air entrance (c); a first module (A), made up of mechanical filters; a second module (B), downwards from the first module (A), and it corresponds to a series of small reactors with molecular converters (nucleophile chemical agents) to capture and transform carbon oxides (CO.sub.x) and nitrogen oxides (NO.sub.x); and an exit for decontaminated air (D).

An odor adsorbent material, an odor detection kit, and a method for using the same for rapidly identifying a facility where binding of an odor component had occurred among facilities used in a distribution route of a commodity. The odor detection kit includes at least two pieces of an odor adsorbent material, a package section that includes at least two storage sections and is configured to store the odor adsorbent material, and a sheet section. The odor detection kit is installed in a facility. At least one of the pieces of the odor adsorbent material is exposed to open space in the facility, recovered therefrom, and sealed and stored. At the time of testing, occurrence of odor emission in the facility is determined by comparing odor components adsorbed by each of the pieces of the odor adsorbent material.

This invention relates in certain aspects to a process for removing oxygenates from a stream, preferably a hydrocarbon stream comprising contacting an organosilica material with the hydrocarbon steam, where the organosilica material is a polymer of at least one monomer of Formula [Z.sup.1OZ.sup.2SiCH.sub.2].sub.3, wherein Z.sup.1 represents a hydrogen atom, a C.sub.1-C.sub.4 alkyl group, or a bond to a silicon atom of another monomer and Z.sup.2 represents a hydroxyl group, a C.sub.1-C.sub.4 alkoxy group, a C.sub.1-C.sub.6 alkyl group or an oxygen atom bonded to a silicon atom of another monomer.

A system and method for enhancement of CO.sub.2 concentration in closed or semi closed spaces, wherein said system comprises a unit (3) for capturing CO.sub.2 from ambient air, said unit further comprises two process units (134, 172) capable of 5 adsorbing and desorbing CO.sub.2 on an adsorbent, and working alternately in adsorbing and desorbing mode.

Carbon dioxide capture systems in accordance with various embodiments of the present disclosure are provided. In one embodiment, an apparatus for capturing carbon emissions from a vehicle is provided, comprising: an exhaust feeder comprising a first end and a second end, wherein the first end connects to the vehicle and receives exhaust gases emitted from the vehicle; a housing connected to the second end and secured to an exterior surface of the vehicle, wherein the housing receives the exhaust gases emitted from the vehicle via the exhaust feeder; wherein the housing comprises: at least one gas deflector surface that directs the exhaust gases to a sorbent material configured to capture carbon dioxide from the exhaust gases; a detachable section that allows for removal and installation of the sorbent material; and an exit port that allows for release of residual gases after the sorbent material captures carbon dioxide.

A self-rescuer device comprises an intake pump that creates a gas stream. The gas stream enters a first sieve that separates carbon dioxide, carbon monoxide, and oxygen from the gas stream to create a mixture. The remaining gas stream flows to a second sieve that separates nitrogen from the remaining gas stream and vents the residual gas to outside of the self-rescuer device through a residual output. The separated mixture is directed to a gas processor separates the oxygen from the mixture. A nitrogen storage canister coupled to the separated output of the second sieve stores the separated nitrogen, and an oxygen storage canister coupled to the separated output of the first sieve stores and concentrates the separated oxygen until a purity threshold is met. Habitable nitrogen and oxygen are metered from their storage canisters and supplied to a user through a breathing mask within an exterior mask shell.