Heat transfer surfaces with flanged apertures

The invention claimed is: 1. A heat transfer surface for a heat exchanger comprising: a corrugated member having parallel, spaced-apart ridges and planar fins extending therebetween; wherein each of the spaced-apart ridges being continuous and in contact with an entire width of the planar fin; each planar fin being formed with a plurality of spaced-apart apertures, each aperture having opposed peripheral edge portions; the peripheral edge portions defining each of the plurality of spaced-apart apertures being only on the planar fin and avoiding contacting the spaced-apart ridges; said opposed edge portions of each aperture including respective flanges that extend outwardly from a single side of the planar fin forming said aperture and terminate at a free end; wherein the apertures are elongated, having a longitudinal axis extending in a direction transverse to the ridges; wherein the flanges associated with each aperture extend outwardly from the single side of the planar fin and are angled relative to the planar fin, each flange forming an obtuse angle with the planar fin and avoiding contact with another surface, and wherein the heat transfer surface is disposed such that: the ridges are disposed perpendicular and the planar fins are disposed normal with respect to incoming fluid flow; and the apertures and the flanges are cooperatively configured for conducting incoming fluid therethrough such that the incoming fluid travels directly through the apertures. 2. A heat transfer surface as claimed in claim 1 wherein the flanges associated with each aperture are continuous around the periphery of the aperture. 3. A heat transfer surface as claimed in claim 1 wherein the flanges associated with each aperture are interrupted around the periphery of the aperture. 4. A heat transfer surface as claimed in claim 1 wherein the heat transfer surface has a low pressure drop direction parallel to the planar fins and a high pressure drop direction transverse to the planar fins, and wherein the apertures are aligned in the high pressure drop direction. 5. A heat transfer surface as claimed in claim 1 wherein the heat transfer surface has a low pressure drop direction parallel to the planar fins and a high pressure drop direction transverse to the planar fins, and wherein the apertures are offset in the high pressure drop direction. 6. A heat transfer surface as claimed in claim 1 wherein the flanges all extend in the same direction in the heat transfer surface. 7. A heat transfer surface as claimed in claim 1 wherein the flanges on alternating planar fins extend in opposite directions in the heat transfer surface. 8. A heat transfer surface as claimed in claim 1 wherein the planar fins are inclined with respect to one another. 9. A heat transfer surface as claimed in claim 1 wherein the planar fins are parallel to one another. 10. A heat transfer surface as claimed in claim 1 wherein the flanges associated with each aperture are disposed at different angles relative to the planar fins. 11. A heat transfer surface as claimed in claim 1 wherein the flanges associated with each aperture are of different widths. 12. A heat transfer surface as claimed in claim 1 wherein the apertures in each planar fin are located in spaced-apart groups. 13. A heat transfer surface as claimed in claim 1 wherein the apertures are different shapes. 14. A heat transfer surface as claimed in claim 1 wherein the apertures are different sizes. 15. A heat transfer surface as claimed in claim 1 wherein the apertures are spaced apart differently in adjacent planar fins. 16. A heat transfer surface for a heat exchanger, comprising: a corrugated member having parallel, spaced-apart ridges and planar fins extending therebetween; wherein each of the spaced-apart ridges being continuous and in contact with an entire width of the planar fin; each planar fin being formed with a plurality of spaced-apart apertures for the flow of a fluid therethrough, wherein the apertures are elongated, having a longitudinal axis extending in a direction transverse to the ridges; each aperture having opposed peripheral edge portions; the peripheral edge portions defining each of the plurality of spaced-apart apertures being only on the planar fin and avoiding contacting the spaced-apart ridges; said opposed edge portions including respective flanges that extend outwardly from a single side of the planar fin forming said aperture and terminate at a free end, the free ends defining an opening therebetween that is smaller than the associated aperture formed in the planar fin, and wherein the flanges avoid contact with another surface, and wherein the heat transfer surface is disposed such that: the ridges are disposed perpendicular and the planar fins are disposed normal with respect to incoming fluid flow; and the apertures and the flanges are cooperatively configured for conducting incoming fluid therethrough such that the incoming fluid travels directly through the apertures. 17. A heat transfer surface as claimed in claim 16 wherein the flanges associated with each aperture are continuous around the periphery of the aperture, the flanges forming a volcano-like structure. 18. A heat transfer surface as claimed in claim 16 wherein the heat transfer surface has a low pressure drop direction parallel to the planar fins and a high pressure drop direction transverse to the planar fins, and wherein the apertures are aligned in the high pressure drop direction. 19. A heat transfer surface as claimed in claim 16 wherein the heat transfer surface has a low pressure drop direction parallel to the planar fins and a high pressure drop direction transverse to the planar fins, and wherein the apertures are offset in the high pressure drop direction. 20. A heat transfer surface as claimed in claim 16 wherein the planar fins are one of: inclined with respect to one another, or parallel to one another.