초록 ▼

An adsorbent material fabricated into a reinforcement-free, self-supported coherent thin sheet and configured for use as a parallel passage contactor element in adsorption/separation applications with gases and liquids is disclosed. The adsorbent sheet material is obtained by enmeshing fine adsorben

An adsorbent material fabricated into a reinforcement-free, self-supported coherent thin sheet and configured for use as a parallel passage contactor element in adsorption/separation applications with gases and liquids is disclosed. The adsorbent sheet material is obtained by enmeshing fine adsorbent particulates in a polymer binder. Particulates include but are not limited to carbon particles, inorganic oxides particles, or ceramic particles, or synthetic polymer resin particles. The adsorbent sheet advantageously contains a large volume percentage of active adsorbent particles. The parallel passage contactor device fabricated from the adsorbent sheet material is characterized by minimal mass transfer resistance and better separation efficiency expressed as height equivalent to a theoretical plate, while it maintains most of the adsorptive properties of the starting particulates, and can be used in gas separation applications with short adsorption cycles, such as rapid pressure swing adsorption, rotary concentrators, rapid electric swing adsorption.

대표청구항 ▼

The invention claimed is: 1. A pressure swing adsorption apparatus comprising a parallel passage contactor comprising an adsorbent material comprising adsorbent particulates and a polymer binder, fabricated into a reinforcement-free, self-supported, flexible, coherent sheet, wherein the adsorbent p

The invention claimed is: 1. A pressure swing adsorption apparatus comprising a parallel passage contactor comprising an adsorbent material comprising adsorbent particulates and a polymer binder, fabricated into a reinforcement-free, self-supported, flexible, coherent sheet, wherein the adsorbent particulates consist of particles from a first group, either alone or admixed with particles from a second group, said particles from the first group include carbon nanoparticles, inorganic oxides nanoparticles, and ceramic nanoparticles and have particle sizes in the range from 10 to 200 nm, and said adsorbent particulates differ from said polymer binder. 2. The pressure swing adsorption apparatus of claim 1 where the adsorbent particles from the second group include activated carbon, inorganic oxides, ceramic materials, or synthetic polymeric resins and have particle sizes in the range from 0.2 μm to 100 μm. 3. The pressure swing adsorption apparatus of claim 1 where the adsorbent particulates have the BET surface area, as measured by nitrogen adsorption, in the range of 200 to 2500 m2/g, and the micropore volume in the range 0.2 to 1 cm3/g. 4. The pressure swing adsorption apparatus of claim 1 where the carbon nanoparticles are surface modified with diazonium salts derivatives to attach specific chemical groups with enhanced gas adsorption or reaction properties. 5. The pressure swing adsorption apparatus of claim 1 where the inorganic oxides nanoparticles are surface modified to enhance gas adsorption or reaction. 6. The pressure swing adsorption apparatus of claim 1 where the particles from said second group are impregnated with inorganic salts, inorganic oxides, inorganic acids, inorganic bases, organic acids, amines, amides, acid chlorides for enhanced gas adsorption or reaction properties. 7. The pressure swing adsorption apparatus of claim 1 where the sheet thickness is in the range of 50 to 1000 μm. 8. The pressure swing adsorption apparatus of claim 1 where the open porosity (void volume fraction) of the sheet is in the range of 30 to 95%. 9. The pressure swing adsorption apparatus of claim 1 where the sheet surface area to total sheet volume ratio is in the range 200 to 2500 m2/cm3 and the sheet micro pore volume to total sheet volume ratio is in the range 0.1 to 0.9. 10. The pressure swing adsorption apparatus of claim 1 where said polymer binder is polyethylene, polypropylene, polytetrafluoroethylene (PTFE), polyvinylchloride (PVC), polyvinylidenechloride (PVDC), polyvinylidenefluoride (PVDF), polyamide, cellulose, cellulose derivates, or any other natural or synthetic polymer that is capable of suspending adsorbent particles in a random manner. 11. The pressure swing adsorption apparatus of claim 1 where the polymer binder is present in the range of 3-30 wt %. 12. The pressure swing adsorption apparatus of claim 1 where the sheet tensile strength is greater than 2 kg/cm2 and where the sheet is flexible and bendable. 13. The pressure swing adsorption apparatus of claim 1 further wherein the adsorbent particulates from the first group are one of the following forms of carbon: carbon nanotubes, carbon fullerenes, or carbon black. 14. The pressure swing adsorption apparatus of claim 13 where the electrical resistivity of the adsorbent material sheet is lower than 200 ohm-cm and the current distribution is uniform. 15. The pressure swing adsorption apparatus of claim 13 further wherein the adsorbent particulates from the second group are activated carbon particles or activated carbon fibers. 16. The pressure swing adsorption apparatus of claim 1 further wherein the particulates from the first group are natural or synthetic zeolites. 17. The pressure swing adsorption apparatus of claim 1 where the sheet is spiral wound or where multiple sheets are layered with gaps between adjacent sheets to allow the flow of gas parallel to the sheet surface. 18. The pressure swing adsorption apparatus of claim 17 where the sheets are separated by polymer netting, by polymer bumps screen printed on the sheet, by corrugation of the sheet, by indents and embosses formed in the sheets, or configured in a honeycomb design. 19. The pressure swing adsorption apparatus of claim 18 where the sheet is made from the adsorbent material of claim 16. 20. The pressure swing adsorption apparatus of claim 19 where the sheet is electrically contacted at opposing ends. 21. The pressure swing adsorption apparatus of claim 17 where an impermeable casing surrounds the contactor and provides connections for gas inlet and outlet. 22. The pressure swing adsorption apparatus of claim 21 where the air permeability measured between inlet and outlet is greater than 10-15 m2. 23. The pressure swing adsorption apparatus of claim 21 where the ratio of total micropore volume to total parallel passage contactor volume is in the range 0.05 to 0.7. 24. The pressure swing adsorption apparatus of claim 21 wherein said adsorbant material further comprises a heterogeneous catalyst. 25. The pressure swing adsorption apparatus of claim 21 wherein said apparatus is a gas filtration device. 26. The pressure swing adsorption apparatus of claim 21 wherein said apparatus is an air dehumidifier. 27. The pressure swing adsorption apparatus of claim 21 wherein said apparatus separates air components. 28. The pressure swing adsorption apparatus of claim 1 further wherein the adsorbent particulates from the second group are activated carbon particles or activated carbon fibers. 29. A pressure swing adsorption parallel passage contactor comprising an adsorbent material comprising adsorbent particulates and a polymer binder, fabricated into a reinforcement-free, self-supported, flexible, coherent sheet, wherein said sheet is spiral wound or layered with gaps between adjacent sheets to allow the flow of gas parallel to the sheet surface where an impermeable casing surrounds the contactor and provides connections for gas inlet and outlet. 30. A parallel passage contactor comprising an adsorbent material comprising adsorbent particulates and a polymer binder, fabricated on a substrate by tape casting or printing to form a sheet, where the substrate thickness is less than 60 microns.