Ejector using swirl flow

What is claimed is: 1. An ejector using a swirl flow in a vapor compression refrigeration system comprising a condenser and an evaporator, the ejector comprising: an ejector body including: a main inlet into which a main flow in high pressure flows, a nozzle section in fluid communication with the main inlet, a mixing portion in fluid communication with the nozzle section, a diffuser in fluid communication with the mixing portion, and a discharge portion in fluid communication with the diffuser, wherein the main inlet is in fluid communication with the condenser, and a suction pipe inserted in a center of the ejector body, the suction pipe including: a through-hole into which a suction flow in low pressure flows, a leading end portion, an outer surface of which forms a plurality of inclined passages with the nozzle section of the ejector body, the plurality of inclined passages allowing the main flow to be moved to the mixing portion so as to form a swirl flow, wherein the through-hole is in fluid communication with the evaporator, a leading inclined portion which is provided at a leading end of the suction pipe, and a middle inclined portion which is spaced apart from the leading inclined portion, wherein the middle inclined portion has a slope corresponding to a first slope portion of the nozzle section and the leading inclined portion has a slope corresponding to a second slope portion of the nozzle section, wherein the main flow entering through the main inlet of the ejector body and the suction flow entering through the through-hole of the suction pipe are swirled and mixed in the mixing portion of the ejector body, and then are discharged outside through the diffuser and the discharge portion. 2. The ejector using a swirl flow of claim 1 , wherein the leading end portion of the suction pipe comprises a plurality of nozzle grooves formed on the outer surface of the leading end portion, and wherein, when the leading end portion of the suction pipe is inserted in the nozzle section of the ejector body, the plurality of nozzle grooves and an inner surface of the nozzle section form a plurality of nozzles, and the main flow is moved to the mixing portion through the plurality of nozzles. 3. The ejector using a swirl flow of claim 2 , wherein the plurality of nozzle grooves are formed to be inclined with respect to a center line of the suction pipe. 4. The ejector using a swirl flow of claim 3 , wherein the suction pipe is disposed to be movable back and forth with respect to the nozzle section of the ejector body. 5. The ejector using a swirl flow of claim 4 , wherein a main flow receiving portion is formed between the main inlet and the nozzle section of the ejector body, the main flow receiving portion has a diameter larger than a diameter of the nozzle section, and is in fluid communication with the main inlet and the nozzle section, and wherein the suction pipe is movable in the main flow receiving portion. 6. The ejector using a swirl flow of claim 5 , wherein the nozzle section of the ejector body comprises: a first slope portion is formed at a portion of the nozzle section which is connected to the main flow receiving portion; and a second slope portion is formed at a portion of the nozzle section which is connected to the mixing portion. 7. The ejector using a swirl flow of claim 6 , wherein when the leading inclined portion of the suction pipe is in contact with the second slope portion of the nozzle section, the plurality of nozzle grooves are blocked so that the main flow is not moved to the mixing portion. 8. The ejector using a swirl flow of claim 6 , wherein a diameter of the leading end portion of the suction pipe is smaller than a diameter of remaining portions of the suction pipe. 9. The ejector using a swirl flow of claim 5 , wherein the main inlet is disposed eccentrically with respect to the center line of the ejector body. 10. The ejector using a swirl flow of claim 2 , wherein the plurality of nozzle grooves comprises three nozzle grooves. 11. An ejector using a swirl flow in a vapor compression refrigeration system comprising a condenser and an evaporator, the ejector comprising: an ejector body including: a main inlet into which a main flow flows, a nozzle section in fluid communication with the main inlet, a mixing portion in fluid communication with the nozzle section, a diffuser in fluid communication with the mixing portion, and a discharge portion in fluid communication with the diffuser, wherein the main inlet is in fluid communication with the condenser; a suction pipe disposed to be movable in a lengthwise direction of the suction pipe in a center of the ejector body, the suction pipe including a through-hole into which a suction flow flows, wherein the through hole is in fluid communication with the evaporator, the suction pipe including: a leading inclined portion which is provided at a leading end of the suction pipe, and a middle inclined portion which is spaced apart from the leading inclined portion, wherein the middle inclined portion has a slope corresponding to a first slope portion of the nozzle section and the leading inclined portion has a slope corresponding to a second slope portion of the nozzle section; and a plurality of nozzle grooves formed on an outer surface of a leading end portion of the suction pipe, the plurality of nozzle grooves that forms a plurality of passages through which the main flow flowing into the main inlet is moved to the mixing portion when the leading end portion of the suction pipe is inserted in the nozzle section of the ejector body, wherein the main flow entering through the main inlet of the ejector body is moved to the mixing portion through the plurality of nozzle grooves so as to form a swirl flow, and is mixed with the suction flow entering through the through-hole of the suction pipe. 12. The ejector using a swirl flow of claim 11 , wherein the plurality of nozzle grooves are formed to be inclined with respect to a center line of the suction pipe. 13. The ejector using a swirl flow of claim 11 , further comprising: a support member disposed integrally with the ejector body, the support member supporting movement of the suction pipe, wherein a main flow receiving portion is formed between the support member and the nozzle section, has a diameter larger than a diameter of the nozzle section, and is in fluid communication with the main inlet and the nozzle section. 14. The ejector using a swirl flow of claim 13 , wherein the nozzle section of the ejector body comprises, the first slope portion is formed at a portion of the nozzle section which is connected to the main flow receiving portion; and the second slope portion is formed at a portion of the nozzle section which is connected to the mixing portion. 15. The ejector using a swirl flow of claim 14 , wherein the plurality of nozzle grooves are formed on at least one of the leading inclined portion and the middle inclined portion of the leading end portion of the suction pipe. 16. The ejector using a swirl flow of claim 11 , wherein the nozzle section, the mixing portion, the diffuser, and the through-hole of the suction pipe are arranged in a straight line, and the main inlet is formed such that the main flow flows in a tangential direction with respect to the suction pipe. 17. A vapor compression refrigeration cycle apparatus, comprising: a condenser; an evaporator; and an ejector using a swirl flow, wherein the ejector including: an ejector body comprising a main inlet into which a main flow in hi