초록 ▼

A fluidized-bed reactor comprising a chamber defining a hollow interior region and having a lower surface; a first input for introducing a contaminated gas into the hollow interior region; a plurality of catalyst nanoparticles within the hollow interior region and located on the lower surface, and a

A fluidized-bed reactor comprising a chamber defining a hollow interior region and having a lower surface; a first input for introducing a contaminated gas into the hollow interior region; a plurality of catalyst nanoparticles within the hollow interior region and located on the lower surface, and a fluidizing input for introducing a fluidizing material into the hollow interior region, said fluidizing input having an outlet directed at the lower surface of the chamber, wherein the introduction of the fluidizing material directed at the lower surface fluidizes at least a portion of the catalyst nanoparticles located on the lower surface to create a gaseous dispersion of catalyst nanoparticles that reacts with the contaminated gas to produce a decontaminated gas.

대표청구항 ▼

What is claimed is: 1. A fluidized-bed reactor system comprising: a chamber defining a hollow interior region and having a lower surface, the lower surface defining a portion of the hollow interior region; a first input for introducing a contaminated gas into the hollow interior region, the contami

What is claimed is: 1. A fluidized-bed reactor system comprising: a chamber defining a hollow interior region and having a lower surface, the lower surface defining a portion of the hollow interior region; a first input for introducing a contaminated gas into the hollow interior region, the contaminated gas comprising at least one hydrocarbon contaminant; a plurality of catalyst nanoparticles within the hollow interior region and located on the lower surface, wherein the catalyst nanoparticles have an average particle diameter of about 15 nm to about 25 nm, and wherein the catalyst nanoparticles are capable of catalyzing the break down of a contaminated gas to produce a decontaminated gas comprising carbon dioxide; a reaction product comprising carbon dioxide in the hollow interior region; and a fluidizing input, located downstream of the first input, for introducing a fluidizing material into the hollow interior region, said fluidizing input having an outlet directed towards the lower surface and between about 0° to 90° with respect to the lower surface of the chamber such that the fluidizing material fluidizes at least a portion of the plurality of catalyst nanoparticles located at the lower surface of the chamber to form a gaseous dispersion, and the catalyst nanoparticles being selected from the group consisting of copper, ruthenium, osmium, platinum, silver, nickel, rhodium, palladium, gold, titanium dioxide, aluminum oxide, vanadium pentoxide, iron (III) oxide, zinc oxide, cadmium sulfide, zinc telluride, zirconium oxide, molybdenum disulfide, tin oxide, antimony tetraoxide, cesium dioxide, tungsten trioxide, niobium pentoxide and combinations thereof. 2. The fluidized-bed reactor system of claim 1 wherein the catalyst nanoparticles are partially fluidized by the introduction of the contaminated gas through the first input. 3. The fluidized-bed reactor system of claim 1 further comprising a port for the exit of the decontaminated gas comprising carbon dioxide out of the hollow interior region. 4. The fluidized-bed reactor system of claim 3 further comprising a second input for introducing a backpressure pulse of gaseous material into the hollow interior region through the port. 5. The fluidized-bed reactor system of claim 4 further comprising a gas permeable separation device in communication with both the port and the second input, wherein the exit of decontaminated gas comprising carbon dioxide from the hollow interior region through the gas permeable separation device causes catalyst nanoparticles to collect upon the gas permeable separation device and the entrance of the backpressure pulse into the hollow interior region through the port displaces collected catalyst nanoparticles and allows said collected catalyst nanoparticles to flow through the port directly back into the hollow interior region to join the fluidized catalyst nanoparticles and continue catalyzing the break down of contaminated gas within the hollow interior region. 6. The fluidized-bed reactor system of claim 1, further comprising a humidifier in communication with the first input. 7. The fluidized-bed reactor system of claim 4 further comprising a device for synchronizing the function of the second input for introducing a backpressure pulse of gaseous material into the hollow interior region to function with at least one of the group comprising the first input for introducing a contaminated gas into the hollow interior region, the fluidizing input for introducing a fluidizing material into the hollow interior region and combinations thereof, wherein the device for synchronizing prevents the simultaneous introduction of at least one of the group comprising contaminated gas, fluidizing material, and combinations thereof with a backpressure pulse of gaseous material into the hollow interior region. 8. The fluidized-bed reactor system of claim 1 further comprising an ultraviolet light. 9. The fluidized-bed reactor system of claim 8, wherein the ultraviolet light is positioned within the hollow interior region of the chamber. 10. The fluidized-bed reactor system of claim 8, wherein the ultraviolet light is positioned outside the chamber. 11. The fluidized-bed reactor system of claim 8, further comprising a humidifier in communication with the first input. 12. The fluidized-bed reactor system of claim 1, further comprising a means for agitating the catalyst nanoparticles within the hollow interior region. 13. The fluidized-bed reactor system of claim 12, wherein the means for agitating comprises a shaker device. 14. The fluidized-bed reactor system of claim 12 wherein the means for agitating comprises a vibrator. 15. A method of removing contaminants from a contaminated gas comprising: providing a fluidized-bed reactor comprising: a chamber defining a hollow interior region and having a lower surface, the lower surface defining a portion of the hollow interior region; a first input for introducing a contaminated gas into the hollow interior region, the contaminated gas comprising at least one hydrocarbon contaminant; a plurality of catalyst nanoparticles within the hollow interior region and located on the lower surface, wherein the catalyst nanoparticles have an average particle diameter of about 15 nm to about 25 nm; a fluidizing input, located downstream of the first input, for introducing a fluidizing material into the hollow interior region, said fluidizing input having an outlet directed towards the lower surface and between about 0° to 90° with respect to the lower surface of the chamber to form a gaseous dispersion, wherein the introduction of the fluidizing material directed at the lower surface fluidizes at least a portion of the catalyst nanoparticles located on the lower surface to create a gaseous dispersion of catalyst nanoparticles that catalyzes the break down of the contaminated gas to produce a decontaminated gas comprising carbon dioxide; a port for the exit of the decontaminated gas comprising carbon dioxide out of the hollow interior region; a second input for introducing a backpressure pulse of gaseous material into the hollow interior region through the port; and a gas permeable separation device in communication with both the port and the second input; introducing the contaminated gas into the hollow interior region; introducing the fluidizing material into the chamber and directing the fluidizing material at the lower surface to fluidize at least a portion of the catalyst nanoparticles located on the surface to create a gaseous dispersion of catalyst nanoparticles that catalyze the break down of the contaminated gas to produce a decontaminated gas comprising carbon dioxide; reacting the contaminated gas to produce a decontaminated gas comprising carbon dioxide; passing the decontaminated gas comprising carbon dioxide from the hollow interior region through the port and the separation device so that catalyst nanoparticles are collected on the separation device; and introducing a backpressure pulse into the hollow interior region through the port and separation device so as to displace catalyst nanoparticles from the separation device; and allowing the plurality of catalyst nanoparticles displaced from the gas separation device to directly join the fluidized dispersion of catalyst nanoparticles and continue catalyzing the break down of the contaminated gas within the hollow interior region, the catalyst nanoparticles being selected from the group consisting of copper, ruthenium, osmium, platinum, silver, nickel, rhodium, palladium, gold, titanium dioxide, aluminum oxide, vanadium pentoxide, iron (III) oxide, zinc oxide, cadmium sulfide, zinc telluride, zirconium oxide, molybdenum disulfide, tin oxide, antimony tetraoxide, cesium dioxide, tungsten trioxide, niobium pentoxide and combinations thereof. 16. The method of claim 15, further comprising the step of synchronizing the function of the second input for introducing a backpressure pulse of gaseous material into the hollow interior region to function with at least one of a group comprising the first input for introducing a contaminated gas into the hollow interior region, the fluidizing input for introducing a fluidizing material into the hollow interior region and combinations thereof, wherein the device for synchronizing prevents the simultaneous introduction of at least one of the group comprising contaminated gas, fluidizing material, and combinations thereof with a backpressure pulse of gaseous material into the hollow interior region. 17. A fluidized bed reactor system comprising: a fluidized-bed reactor having a chamber, a plurality of catalyst nanoparticles capable of catalyzing the break down of a contaminated gas to produce a decontaminated gas comprising carbon dioxide, a first input, a fluidizing input located downstream of the first input, a port, a second input and a gas permeable separation device, the chamber defining a hollow interior region with the plurality of catalyst nanoparticles disposed therein and a lower surface defining a portion of the hollow interior region, each of the plurality of catalyst nanoparticles having an average diameter within a range between about 15 and about 25 nanometers, and the first input, the fluidizing input, and the port being in communication with the hollow interior region, the first input configured to direct a contaminated gas into the hollow interior region, the contaminated gas comprising at least one hydrocarbon contaminant, the fluidizing input configured to direct a fluidizing material toward the lower surface and between about 0° to 90° with respect to the lower surface and the plurality of catalyst nanoparticles for fluidizing at least a portion of the plurality of catalyst nanoparticles and creating a gaseous dispersion of catalyst nanoparticles that catalyzes the break down of the contaminated gas to produce a decontaminated gas comprising carbon dioxide, the gas permeable separation device being in communication between the port and the second input, the port configured to direct the decontaminated gas from the hollow interior region through the gas permeable separation device such that the plurality of catalyst nanoparticles collect on the gas permeable separation device, the second input configured to direct a backpressure pulse of gaseous material into the hollow interior region through the gas permeable separation device for displacing the plurality of catalyst nanoparticles previously collected on the gas permeable separation device therefrom, and allowing the plurality of catalyst nanoparticles displaced from the gas separation device to directly join the fluidized dispersion of catalyst nanoparticles and continue catalyzing the break down of the contaminated gas within the hollow interior region, a reaction product comprising carbon dioxide in the hollow interior region, the catalyst nanoparticles being selected from the group consisting of copper, ruthenium, osmium, platinum silver, nickel, rhodium, palladium, gold, titanium dioxide, aluminum oxide, vanadium pentoxide, iron (III) oxide, zinc oxide, cadmium sulfide, zinc telluride, zirconium oxide, molybdenum disulfide, tin oxide, antimony tetraoxide, cesium dioxide, tungsten trioxide, niobium pentoxide and combinations thereof and at least one control device coupled to the second input and at least one of the first and fluidizing inputs, the at least one control device configured to alternate the backpressure pulse of gaseous material through the gas permeable separation device with an entrance of at least one of the contaminated gas and the fluidizing material into the hollow interior region. 18. The fluidized bed reactor system of claim 17, wherein the at least one control device is further configured to introduce the backpressure pulse of gaseous material through the gas permeable separation device for about 0.2 seconds and introduce at least one of the contaminated gas and the fluidizing material into the hollow interior region for about 0.8 seconds. 19. The fluidized bed reactor system of claim 17, wherein the at least one control device comprises at least one of a needle valve, a solenoid, a computer, a generator and a sensor. 20. The fluidized bed reactor system of claim 17, wherein the at least one control device is configured to introduce the backpressure pulse of gaseous material at a force based on at least one of a volume of the hollow interior region, a density of the contaminated gas, a concentration of the contaminated gas, a composition of the contaminated gas, a composition of the plurality of catalyst nanoparticles, an internal pressure of a contaminated gas source, a temperature of a contaminated gas source and a particle build up in the chamber of the fluidized-bed reactor. 21. The fluidized bed reactor system of claim 17, further comprising a gas permeable layer within the hollow interior region of the chamber, the gas permeable layer having the plurality of catalyst nanoparticles thereon in a non-fluidized state, and the fluidizing input being disposed 45 degrees relative to the gas permeable layer and having an outlet directed at the plurality of catalyst nanoparticles on the gas permeable layer. 22. The fluidized bed reactor system of claim 17, wherein the second input has a decontaminated gas passage way, the decontaminated gas passage way configured to receive the decontaminated gas exiting from the hollow interior region through the port and the gas permeable separation device, the decontaminated gas passage way further configured to recycle the decontaminated gas through at least one of the fluidizing inlet and the port into the hollow interior region. 23. The fluidized bed reactor system of claim 22, further comprising a flame ionization detector in communication between the decontaminated gas passage way and the fluidizing input, such that the decontaminated gas passes through the flame ionization detector to the fluidizing input. 24. The fluidized bed reactor system of claim 22, wherein the at least one control device includes a filtration device and a gauge, the filtration device in communication with a decontaminated gas passage way, the filtration device configured to collect the plurality of catalyst nanoparticles that bypasses the gas permeable separation device from the hollow interior region, and the gauge configured to generate a signal indicative of a quantity of catalyst nanoparticles that bypasses the gas permeable separation device, the signal being received by another control device. 25. The fluidized bed reactor system of claim 24, wherein the gauge is further configured to determine a pressure within the fluidized bed reactor system. 26. The fluidized bed reactor system of claim 17, further comprising a gas source coupled to at least one of the second and fluidizing inputs for providing the backpressure pulse of gaseous material and an entrance of the fluidizing material into the hollow interior region, respectively. 27. The fluidized-bed reactor system of claim 1 further comprising water vapor as a reactant in the hollow interior region. 28. The method of claim 15 further comprising introducing water vapor as a reactant into the hollow interior region through the first input. 29. The fluidized bed reactor system of claim 17 further comprising water vapor as a reactant in the hollow interior region.