Decompression device having flow control valves and refrigeration cycle with said decompression device

What is claimed is: 1. A decompression device for a refrigeration cycle device, the decompression device comprising: a refrigerant inlet into which refrigerant flows; a refrigerant outlet from which the refrigerant after being decompressed flows out; and a body part that forms a swirl space in which the refrigerant flowing from the refrigerant inlet swirls at a speed being decompression-boiled and being a gas-liquid two phase refrigerant; a widening taper part connected to a downstream refrigerant side of the refrigerant outlet and having a refrigerant passage sectional area that gradually increases toward the downstream refrigerant side; and a body portion that includes a refrigerant suction port from which the refrigerant is drawn by a jet refrigerant that is jetted from the widening taper part, and a diffuser part in which a pressure of a mix refrigerant that is mixture of the jet refrigerant and the drawn refrigerant drawn from the refrigerant suction port is increased, wherein the refrigerant inlet introduces the refrigerant tangentially to an inner circular surface of the swirl space to promote the swirling of the refrigerant flowing from the refrigerant inlet, the refrigerant outlet has a throttle in which a refrigerant passage area is decreased to decompress the refrigerant, and the gas-liquid two phase refrigerant flows through the throttle of the refrigerant outlet, the swirl space causes the refrigerant to swirl at a swirl speed such that a greater amount of gas-phase refrigerant is distributed to a radial inside of the swirl space than to a radial outside of the swirl space relative to a swirl center line when the swirl center line in the swirl space is defined as a line connecting center points of swirling of the refrigerant, the refrigerant outlet is positioned on an extension line of the swirl center line, the refrigerant inlet and the refrigerant outlet are configured to have 1<Ain/Aout<12, when a passage cross-sectional area of the refrigerant inlet is designated as Ain and a passage cross-sectional area of the refrigerant outlet is designated as Aout, and the swirl space includes a tapered space in which a cross-sectional area of the tapered space gradually decreases toward an open direction of the refrigerant outlet. 2. The decompression device of claim 1 , wherein the refrigerant outlet is connected to a capillary tube. 3. The decompression device of claim 1 , further comprising a swirl speed adjuster which adjusts the swirl speed. 4. The decompression device of claim 3 , wherein the swirl speed adjuster is constructed of an inlet-side flow amount adjustment valve which adjusts a flow amount of the refrigerant flowing into the swirl space from the refrigerant inlet. 5. The decompression device of claim 3 , wherein the body part has a supplemental refrigerant inlet from which the refrigerant flows into the swirl space, a flow direction of the refrigerant flowing into the swirl space from the refrigerant inlet is different from a flow direction of the refrigerant flowing into the swirl space from the supplemental refrigerant inlet, and the swirl speed adjuster is constructed of at least one of an inlet-side flow amount adjustment valve which adjusts the flow amount of the refrigerant flowing into the swirl space from the refrigerant inlet and a supplemental inlet-side flow amount adjustment valve which adjusts the flow amount of the refrigerant flowing into the swirl space from the supplemental refrigerant inlet. 6. The decompression device of claim 3 , wherein the swirl speed adjuster is constructed of an outlet-side flow amount adjustment valve which adjusts the flow amount of the refrigerant flowing out of the refrigerant outlet. 7. The decompression device of claim 1 , wherein the swirl speed is a speed at which the refrigerant at or around the swirl center line is decompression-boiled. 8. The decompression device of claim 1 , wherein the swirl space is formed only by an inner wall surface of the body part. 9. The decompression device of claim 1 , wherein the swirl space is a single space without being separated. 10. A refrigeration cycle device comprising the decompression device of claim 1 . 11. The decompression device of claim 1 , wherein the refrigerant outlet is a single refrigerant outlet. 12. The decompression device of claim 1 , wherein the refrigerant inlet is perpendicular to the swirl center line to promote the swirling of the refrigerant flowing from the refrigerant inlet. 13. The decompression device for the refrigeration cycle device of claim 1 , wherein the refrigeration cycle device has: a compressor that draws and pressurizes refrigerant; and a radiator, the radiator has: a condensing part that condenses a discharged refrigerant discharged by the compressor by promoting a heat radiation of the discharged refrigerant; and a super-cooling part that super-cools a refrigerant flowing from the condensing part to be supercooled liquid refrigerant, the supercooled liquid refrigerant from the super-cooling part flows into the refrigerant inlet. 14. The decompression device for the refrigeration cycle device of claim 1 , wherein, the refrigeration cycle device has an evaporator, and the refrigerant outlet is directly connected to the evaporator via a refrigerant conduit. 15. A decompression device for a refrigeration cycle device, the decompression device comprising: a refrigerant inlet into which refrigerant flows; a refrigerant outlet from which the refrigerant after being decompressed flows out; and a body part that forms a swirl space in which the refrigerant flowing from the refrigerant inlet swirls at a speed being decompression-boiled and being a gas-liquid two phase refrigerant, wherein the refrigerant inlet introduces the refrigerant tangentially to an inner circular surface of the swirl space to promote the swirling of the refrigerant flowing from the refrigerant inlet, the refrigerant outlet has a throttle in which a refrigerant passage area is decreased to decompress the refrigerant, and the gas-liquid two phase refrigerant flows through the throttle of the refrigerant outlet, the swirl space causes the refrigerant to swirl at a swirl speed such that a greater amount of gas-phase refrigerant is distributed to a radial inside of the swirl space than to a radial outside of the swirl space relative to a swirl center line when the swirl center line in the swirl space is defined as a line connecting center points of swirling of the refrigerant, the refrigerant outlet is positioned on an extension line of the swirl center line, the refrigerant inlet and the refrigerant outlet are configured to have 1<Ain/Aout<12, when a passage cross-sectional area of the refrigerant inlet is designated as Ain and a passage cross-sectional area of the refrigerant outlet is designated as Aout, the refrigeration cycle device has an evaporator, and the refrigerant outlet is directly connected to the evaporator via a refrigerant conduit.