Combustor assembly for a gas turbine engine

The invention claimed is: 1. A combustor assembly for a gas turbine engine, comprising: a hanger having a first flange portion extending radially inward therefrom, said first flange portion forming a step including a first wall portion at a first wall thickness and a second wall portion at a second wall thickness that is less than said first wall thickness; a combustor liner fixed to said hanger, said combustor liner having an inner surface extending along an axis of a combustion chamber; a heat shield having a-second flange portions extending radially outward therefrom, said second flange portion in contact with said first wall portion and said second wall portion of said first flange portion, said heat shield at least partially overlapping and confronting said inner surface of said combustor liner along said axis to form an axially extending gap, said heat shield releasably engaged with said hanger, said heat shield forming a plurality of radially outer surfaces between said second flange portions, said radially outer surfaces oppose said first wall portion to form circumferentially extending gaps between said second flange portions, said heat shield forming recesses that oppose said second wall portion to form radially extending gaps, such that air flow passes from the circumferentially extending gaps into said radially extending gaps and into said axially extending gap; and fasteners passing through said first flange portion and said second flange portions and extending in a direction parallel with said axis. 2. The combustor assembly of claim 1 wherein said combustor liner is joined with said hanger at an attachment location by an annular weld joint, and wherein said heat shield overlaps said annular weld joint along said axis. 3. The combustor assembly of claim 1 wherein said hanger and said heat shield are operable to move relative to one another while releasably engaged with one another. 4. The combustor assembly of claim 3 wherein said hanger includes a slot having a slot length extending between a radially inner end and a radially outer end, wherein said heat shield includes an aperture, and wherein said fastener extends through said slot and said aperture along said axis to releasably connect said heat shield with said hanger and to allow relative radial movement between said heat shield and said hanger. 5. The combustor assembly of claim 2 wherein said hanger further comprises: a first axial portion extending along said axis from said first flange portion to said annular weld joint, said heat shield overlapping all of a second axial portion of said hanger. 6. The combustor assembly of claim 5 wherein said heat shield only physically contacts said first flange portion of said hanger and is spaced from and does not contact said second axial portion of said hanger. 7. The combustor assembly of claim 1 further comprising: at least one fluid passageway communicating cooling fluid to said axially extending gap defined between said heat shield and said inner surface of said combustor liner. 8. The combustor assembly of claim 7 wherein said at least one fluid passageway includes a portion bounded by said radially outer surfaces defined by said heat shield and by a radially facing inner surface defined by said hanger. 9. The combustor assembly of claim 7 wherein said at least one fluid passageway includes a portion extending along said axis and respectively bounded on opposites sides by an inner surface of said hanger and an outer surface of said heat shield. 10. The combustor assembly of claim 7 wherein said hanger and said heat shield are operable to move relative to one another while releasably engaged with one another, thereby varying a size of said axially extending gap between said heat shield and said inner surface of said combustor liner. 11. A method comprising the steps of: defining of a combustion chamber with an inner surface of a combustor liner extending along an axis; fixing the combustor liner to a hanger, the hanger having a first flange portion extending radially inward therefrom, said first flange portion forming a step including a first wall portion at a first wall thickness and a second wall portion at a second wall thickness that is less than said first wall thickness; shielding at least part of the inner surface of the combustor liner with a heat shield, the heat shield having second flange portions extending radially outward therefrom, the second flange portions in contact with said first wall portion and said second wall portion of the first flange portion, the heat shield at least partially overlapping and confronting the inner surface of the combustor liner along the axis to form an axially extending gap, said heat shield forming a plurality of radially outer surfaces between said second flange portions, said radially outer surfaces oppose said first wall portion to form circumferentially extending gaps between said second flange portions, said heat shield forming recesses that oppose said second wall portion to form radially extending gaps, such that air flow passes from the circumferentially extending gaps into said radially extending gaps and into said axially extending gap; and releasably engaging the heat shield with the hanger. 12. The method of claim 11 wherein the fixing of the combustor liner to the hanger comprises joining the combustor liner to the hanger by an annular weld joint. 13. The method of claim 11 further comprising the steps of: coupling the heat shield and the hanger together such that the heat shield is at least partially free to expand and contract relative to the hanger in response to changes in temperature; and limiting free expansion and contraction of the heat shield relative to the hanger such that said axially extending gap is maintained between the heat shield and the inner surface of the combustor liner. 14. The method of claim 11 further comprising the step of: directing a stream of cooling fluid to said radially extending gaps between the first flange portion and the recesses, and from said radially extending gaps to said axially extending gap between the heat shield and the inner surface of the combustor liner; and cooling the inner surface of the combustor liner and the heat shield with the cooling fluid. 15. A gas turbine engine comprising: a compressor section operable to compress fluid; a combustor section positioned downstream of said compressor section along a centerline axis and defining a combustion chamber operable to receive compressed fluid from said compressor section; and a turbine section positioned downstream of said combustor section along said centerline axis and operable to receive combustion gases from said combustion chamber; wherein said combustor section includes a combustor assembly comprising: a hanger having a first flange portion extending radially inward therefrom, said first flange portion forming a step including a first wall portion at a first wall thickness and a second wall portion at a second wall thickness that is less than said first wall thickness; a combustor liner fixed to said hanger, said combustor liner having an inner surface extending along said centerline axis; and a heat shield at least partially overlapping and confronting said inner surface of said combustor liner along said centerline axis to form an axially extending gap, said heat shield having a second flange portions extending radially outward therefrom, said second flange portions in contact with of said first wall portion and said second wall portion of said first flange portion, said heat shield releasably engaged with said ha