Heat sink, corresponding lighting device and method of use

The invention claimed is: 1. A heat sink, including: a plate-like portion extending along an axis and having opposed mounting surfaces for at least one heat source, a finned portion thermally coupled with the plate-like portion and including a plurality of annular fins extending around said axis, and tapered fluid flow channels between the fins of said plurality of annular fins, said tapered fluid flow channels extending between first and second sides of the finned portion, said first and second sides opposed in a diametral direction of said finned portion, wherein said tapered fluid flow channels have wider fluid inflow ends at said first side of the finned portion and narrower fluid outflow ends at said second side of the finned portion. 2. The heat sink of claim 1 , including a cylindrical portion arranged around said axis between said plate-like portion and said finned portion. 3. The heat sink of claim 1 , wherein said plurality of annular fins include at least one fin extending orthogonal to said axis. 4. The heat sink of claim 3 , wherein said at least one fin is located at the end of said plurality of the annular fins facing towards said plate-like portion. 5. The heat sink of claim 1 , wherein said plurality of annular fins include at least one fin oblique to said axis. 6. The heat sink of claim 5 , wherein said plurality of annular fins include plural fins oblique to said axis. 7. The heat sink of claim 6 , wherein said plural fins oblique to said axis are oblique to one another. 8. The heat sink of claim 1 , wherein said plate-like portion extends parallel to said diametral direction. 9. A lighting device, including: a heat sink, wherein the heat sink includes, a plate-like portion extending along an axis and having opposed mounting surfaces for at least one heat source, a finned portion thermally coupled with the plate-like portion and including a plurality of annular fins extending around said axis, and tapered fluid flow channels between the fins of said plurality of annular fins, said tapered fluid flow channels extending between first and second sides of the finned portion, said first and second sides opposed in a diametral direction of said finned portion, wherein said tapered fluid flow channels have wider fluid inflow ends at said first side of the finned portion and narrower fluid outflow ends at said second side of the finned portion, the lighting device further including an electrically powered light radiation source, mounted at least one of said opposed surfaces of the plate-like portion. 10. The lighting device of claim 9 , wherein the electrically powered light radiation source is a LED source. 11. A method of using a heat sink, wherein the heat sink includes, a plate-like portion extending along an axis and having opposed mounting surfaces for at least one heat source, a finned portion thermally coupled with the plate-like portion and including a plurality of annular fins extending around said axis, and tapered fluid flow channels between the fins of said plurality of annular fins, said tapered fluid flow channels extending between first and second sides of the finned portion, said first and second sides opposed in a diametral direction of said finned portion, wherein said tapered fluid flow channels have wider fluid inflow ends at said first side of the finned portion and narrower fluid outflow ends at said second side of the finned portion, the method including, arranging said heat sink with said axis arranged horizontally and said plate-like portion arranged vertically, and arranging said heat sink with said second side of the finned portion arranged above said first side of the finned portion. 12. A method of using a lighting device, wherein the lighting device includes, a heat sink, wherein the heat sink includes a plate-like portion extending along an axis and having opposed mounting surfaces for at least one heat source, a finned portion thermally coupled with the plate-like portion and including a plurality of annular fins extending around said axis, and tapered fluid flow channels between the fins of said plurality of annular fins, said tapered fluid flow channels extending between first and second sides of the finned portion, said first and second sides opposed in a diametral direction of said finned portion, wherein said tapered fluid flow channels have wider fluid inflow ends at said first side of the finned portion and narrower fluid outflow ends at said second side of the finned portion, wherein said plate-like portion extends parallel to said diametral direction, and an electrically powered light radiation source mounted at least one of said opposed surfaces of the plate-like portion, the method including, arranging said heat sink with said axis arranged horizontally and said plate-like portion arranged vertically, and arranging said heat sink with said second side of the finned portion arranged above said first side of the finned portion.