Methods and systems for creating aerosols

The invention claimed is: 1. An aerosol creation system, comprising: a first pair of counter-rotating rollers; a first nip defined between the first pair of counter-rotating rollers, the first nip having an upstream side and a downstream side; a second pair of counter-rotating rollers positioned adjacent to the first pair of counter-rotating rollers; a second nip defined between the second pair of counter-rotating rollers, the second nip having an upstream side and a downstream side; a fluid source that coats at least one of the rollers in the first pair of counter-rotating rollers and at least one of the rollers in the second pair of counter-rotating rollers; a driving element structured to drive at least one of the rollers in the first pair of counter-rotating rollers and at least one of the rollers in the second pair of counter-rotating rollers to cause fluid to be drawn through the upstream side of the first nip to the downstream side of the first nip and through the upstream side of the second nip to the downstream side of the second nip, wherein a first fluid filament is stretched between diverging surfaces of the first pair of counter-rotating rollers on the downstream side of the first nip until the first fluid filament breaks into a plurality of first droplets, and wherein a second fluid filament is stretched between diverging surfaces of the second pair of counter-rotating rollers on the downstream side of the second nip until the second fluid filament breaks into a plurality of second droplets. 2. The aerosol creation system of claim 1 , wherein the first pair of counter-rotating rollers and the second pair of counter-rotating rollers are positioned in a circular configuration. 3. The aerosol creation system of claim 1 , further comprising a third pair of counter-rotating rollers positioned between the first pair of counter-rotating rollers and the second pair of counter-rotating roller in a circular configuration, and further comprising a third nip defined between the third pair of counter-rotating rollers, the third nip having an upstream side and a downstream side. 4. The aerosol creation system of claim 3 , wherein the circular configuration of the first pair of counter-rotating rollers, the second pair of counter-rotating rollers, and the third pair of counter-rotating rollers defines a central interior space and an exterior diameter. 5. The aerosol creation system of claim 4 , wherein the fluid source is positioned in the central interior space to coat the at least one of the first rollers, the at least one of the second rollers, and the at least one of the third rollers with the fluid from the central interior space to cause the plurality of first droplets, the plurality of second droplets, and the plurality of third droplets to break in a direction away from the exterior diameter. 6. The aerosol creation system of claim 4 , wherein the fluid source is positioned along the exterior diameter of the circular configuration to coat the at least one of the first rollers, the at least one of the second rollers, and the at least one of the third rollers with the fluid from along the exterior diameter to cause the plurality of first droplets, the plurality of second droplets, and the plurality of third droplets to break in a direction toward the central interior space. 7. The aerosol creation system of claim 3 , wherein the fluid source coats at least one of the rollers in the third pair of counter-rotating rollers and wherein the driving element is structured to drive at least one of the rollers in the third pair of counter-rotating rollers to cause fluid to be drawn through the upstream side of the third nip to the downstream side of the third nip so that a third fluid filament is stretched between diverging surfaces of the third pair of counter-rotating rollers on the downstream side of the third nip until the fluid breaks into a plurality of third droplets. 8. The aerosol creation system of claim 1 , wherein the diverging surfaces of the first pair of counter-rotating rollers and the diverging surfaces of the second pair of counter-rotating rollers are physically touching each other. 9. The aerosol creation system of claim 1 , further comprising a first metering blade structured to control a thickness of the fluid coating on the at least one first roller that is coated with the fluid and further comprising a second metering blade structured to control the thickness of the fluid coating on the at least one second roller that is coated with the fluid. 10. The aerosol creation system of claim 1 , wherein the first pair of counter-rotating rollers and the second pair of counter-rotating rollers are positioned within an interior space of a shaft. 11. The aerosol creation system of claim 10 , wherein the interior space of the shaft is pressurized to an interior space pressure on the upstream side of the first nip and the upstream side of the second nip that is greater than a pressure on the downstream side of the first nip and the downstream side of the second nip. 12. The aerosol creation system of claim 10 , wherein the first pair of counter-rotating rollers and the second pair of counter-rotating rollers are positioned within a circular configuration within the interior space of the shaft and further comprising a central spacer positioned within the interior space and structured to secure the first pair of counter-rotating rollers and the second pair of counter-rotating rollers between the central spacer and an interior surface of the shaft. 13. The aerosol creation system of claim 1 , wherein the fluid source is structured to coat both of the first pair of counter-rotating rollers and both of the second pair of counter-rotating rollers with the fluid. 14. The aerosol creation system of claim 1 , further comprising a harvesting element that collects the plurality of first droplets and the plurality of second droplets. 15. A method of creating an aerosol, comprising: drawing a fluid from a fluid source through a first nip, the first nip defined between a first pair of counter-rotating rollers, the first nip having an upstream side and a downstream side; drawing the fluid from the fluid source through a second nip, the second nip defined between a second pair of counter-rotating rollers positioned adjacent to the first pair of counter-rotating rollers in a circular configuration, the second nip having an upstream side and a downstream side; stretching the fluid between diverging surfaces of the first pair of counter-rotating rollers on the downstream side of the first nip to form a first fluid filament between the diverging surfaces of the first pair of counter-rotating rollers; stretching the fluid between diverging surfaces of the second pair of counter-rotating rollers on the downstream side of the second nip to form a second fluid filament between the diverging surfaces of the second pair of counter-rotating rollers; causing the first fluid filament to break into a plurality of first droplets; and causing the second fluid filament to break into a plurality of second droplets. 16. The method of claim 15 , wherein the circular configuration of the first pair of counter-rotating rollers and the second pair of counter-rotating rollers defines a central interior space and an exterior diameter, and further comprising causing the first droplets and the second droplets to break in a direction towards the central interior space. 17. The method of claim 15 , wherein the circular configuration of the first pair of counter-rotating rollers and the second pair of counter-rotat