초록 ▼

Particulates called nanoparticles (principally having a diameter of 10 nm or less) are reliably and easily according to size with high throughput. An impactor includes a particulate size classifying chamber provided with an exhaust port for particulates, a nozzle ejecting to the inside of the partic

Particulates called nanoparticles (principally having a diameter of 10 nm or less) are reliably and easily according to size with high throughput. An impactor includes a particulate size classifying chamber provided with an exhaust port for particulates, a nozzle ejecting to the inside of the particulate size classifying chamber a carrier gas containing particulates to be classified, and a trapping plate as particulate trapping unit provided in the particulate size classifying chamber and selectively trapping particulates ejected from the nozzle.

대표청구항 ▼

1. A particulate size classification apparatus comprising: a particulate size classifying chamber provided with an exhaust port for particulates;a particulate introducing unit having a nozzle ejecting to the inside of the particulate size classifying chamber a carrier gas containing particulates to

1. A particulate size classification apparatus comprising: a particulate size classifying chamber provided with an exhaust port for particulates;a particulate introducing unit having a nozzle ejecting to the inside of the particulate size classifying chamber a carrier gas containing particulates to be classified; anda particulate trapping unit provided in the particulate size classifying chamber and selectively trapping particulates ejected from the nozzle,wherein among the particulates ejected from the nozzle, particulates made uniform in size by not being trapped by the particulate trapping unit are ejected from the exhaust port; andwherein the particulate introducing unit has a particulate introduction pipe introducing the carrier gas into the particulate size classifying chamber, andthe nozzle has a plurality of ejection ports having orifice diameters of different sizes, and is placed separately from the particulate introduction pipe so that the selected ejection port is connected to the particulate introduction pipe. 2. The particulate size classification apparatus according to claim 1, wherein the inside of the particulate size classifying chamber is kept at a low pressure of 2.67×103 Pa or lower at the time of size classification of particulates. 3. The particulate size classification apparatus according to claim 1, wherein the particulate trapping unit is a discoid member having a rotational axis perpendicular to the surface and made rotatable at a predetermined speed, and is placed so as to be movable vertically and laterally. 4. The particulate size classification apparatus according to claim 3, wherein the particulate trapping unit is placed so as to be replaceable in the particulate size classifying chamber kept at a low pressure. 5. The particulate size classification apparatus according to claim 1, wherein the particulate trapping unit is a trapping sheet. 6. The particulate size classification apparatus according to claim 5, wherein in the particulate trapping unit, the position at which particulates ejected from the nozzle can be shifted in a longitudinal direction over time so that the trapping position changes. 7. The particulate size classification apparatus according to claim 1, wherein the particulate trapping unit has a surface having a porous structure. 8. The particulate size classification apparatus according to claim 1, wherein the particulate trapping unit has an aluminum oxide film formed on the surface. 9. The particulate size classification apparatus according to claim 1, wherein the particulate trapping unit has carbon nanotubes provided on the surface. 10. The particulate size classification apparatus according to claim 1, wherein the particulate trapping unit has carbon nanowires provided on the surface. 11. The particulate size classification apparatus according to claim 1, wherein the particulate introducing unit has a gas exhaust port for the carrier gas separately from the nozzle. 12. The particulate size classification apparatus according to claim 11, wherein the particulate introducing unit has a valve adjusting the flow rate of the carrier gas in the upstream of the gas exhaust port, and by adjustment of the valve, the flow rates in the gas exhaust port and the nozzle are each controlled. 13. A particulate size classification method, wherein the particulate introducing unit has a particulate introduction pipe introducing a nozzle and a carrier gas into a particulate size classifying chamber, andthe nozzle has a plurality of ejection ports having orifice diameters of different sizes, and is placed separately from the particulate introduction pipe so that the selected ejection port is connected to the particulate introduction pipe, andwherein the carrier gas containing particulates to be classified is ejected to the inside of the particulate size classifying chamber from the nozzle, particulates are selectively trapped by particulate trapping unit provided in the particulate size classifying chamber, and particulates made uniform in size by not being trapped by the particulate trapping unit are collected. 14. The particulate size classification method according to claim 13, wherein the inside of the particulate size classifying chamber is kept at a low pressure of 2.67×103 Pa or lower at the time of size classification of particulates. 15. The particulate size classification method according to claim 13, wherein the particulate trapping unit is a discoid member having a rotational axis perpendicular to the surface and made rotatable at a predetermined speed, and is placed so as to be movable vertically and laterally. 16. The particulate size classification method according to claim 13, wherein the particulate trapping unit is a trapping sheet. 17. The particulate size classification method according to claim 16, wherein in the particulate trapping unit, the position at which particulates ejected from the nozzle can be shifted in a longitudinal direction over time so that the trapping position changes. 18. The particulate size classification method according to claim 13, wherein the carrier gas is ejected to the inside of the particulate size classifying chamber by the nozzle provided in the particulate size classifying chamber, andwherein the flow rate of the carrier gas is adjusted by a exhaust port provided in the upstream of the nozzle exhausting the carrier gas and a valve provided with an exhaust port. 19. The particulate size classification method according to claim 13, wherein a gas exhaust port for the carrier gas is provided separately from the nozzle, a valve adjusting the flow rate of the carrier gas is provided in the upstream of the gas exhaust port, and the flow rates of the carrier gas in the gas exhaust port and the nozzle are each controlled by adjustment of the valve.