Air purifier and method of purifying air

What is claimed is: 1 . An air purifier comprising: a reactor having a hollow shape extending in a predetermined direction; a discharge plasma generator which includes a first electrode disposed on an outer wall of the reactor and a second electrode disposed inside the reactor, and generates discharge plasma in a predetermined discharge region; a plurality of dielectric particles disposed in a packed-bed of the reactor; a gas-liquid contact unit disposed at a front end of the reactor; and a fluid mixer disposed at a front end of the gas-liquid contact unit; wherein the fluid mixer comprises a liquid supply unit which supplies fine droplets to a polluted air, wherein the fluid mixer is configured to mix the fine droplets with the polluted air to a gas-liquid mixed fluid air, wherein the gas-liquid contact unit is configured to separates the gas-liquid mixed fluid air into a first purified air and a liquid, wherein at least one micro-channel is defined in at least one dielectric particle of the plurality of dielectric particles and the plurality of dielectric particles has a relative density of about 30 percent or more and about 90 percent or less compared to a reference density of the plurality of dielectric particles in the packed-bed in which the at least one micro-channel is not defined. 2 . The air purifier of claim 1 , wherein the plurality of dielectric particles includes at least one of silicon oxide, boron oxide, aluminum oxide, manganese oxide, titanium oxide, barium oxide, copper oxide, magnesium oxide, zinc oxide, zirconium oxide, yttrium oxide, calcium oxide, nickel oxide, and iron oxide. 3 . The air purifier of claim 1 , wherein a porosity of the packed-bed is greater than about 10 percent and less than or equal to about 90 percent, and the porosity is a ratio of a volume of a void space in the packed-bed to a total volume of the packed-bed. 4 . The air purifier of claim 3 , wherein the plurality of dielectric particles has an average particle diameter of about 0.5 millimeter or more and about 20 millimeters or less. 5 . The air purifier of claim 1 , wherein a ratio of the fine droplets with respect to the first purified air supplied to the reactor is about 0.0001 or more and about 0.001 or less. 6 . The air purifier of claim 1 , wherein a voltage of about 2 kilovolts or more and about 500 kilovolts or less is applied to the predetermined discharge region. 7 . The air purifier of claim 6 , further comprising a voltage generator which applies the voltage to the inside of the reactor. 8 . The air purifier of claim 1 , wherein the first electrode is provided with a silver paste film. 9 . The air purifier of claim 1 , wherein the second electrode extends in the predetermined direction and is separated from the first electrode with a predetermined distance therebetween. 10 . The air purifier of claim 1 , wherein the reactor is provided with a glass conduit extending in the predetermined direction. 11 . The air purifier of claim 1 , wherein the fine droplets include water. 12 . The air purifier of claim 1 , wherein the fine droplets include a basic aqueous solution. 13 . The air purifier of claim 12 , wherein an alkaline strength (PH) of the basic aqueous solution is determined according to an ozone concentration inside the reactor. 14 . The air purifier of claim 12 , wherein the fine droplets are an aqueous sodium hydroxide solution having a molar concentration of about 2 millimoles per liter or more and about 20 millimoles per liter or less. 15 . The air purifier of claim 1 , further comprising a catalyst unit disposed at a rear end of the reactor to remove ozone discharged from the reactor by a catalyst.