Multiple cooled supports for heat exchange tubes in heat exchanger

What is claimed is: 1. A heat exchanger, comprising: a casing configured to direct a working fluid therethrough; and at least one heat exchanger (HE) section in the casing, each HE section including a pair of spaced supports, each spaced support including: an upstream support and a downstream support, wherein at least one of the upstream support and the downstream support includes a coolant carrying body configured to direct a coolant therethrough; a first cross-support coupled to and extending between respective upstream and downstream supports; at least one second cross-support coupled to and extending between the respective upstream and downstream supports, each second cross-support of the at least one second cross-support vertically distanced from an adjacent cross-support thereabove; and a plurality of tube positioners suspended from each of the cross-supports, each tube positioner positioning a plurality of heat exchange tubes extending across at least a portion of a working fluid path through the casing, wherein each second cross-support of the at least one second cross-support has an upstream end coupled to the upstream support and a downstream end coupled to the downstream support, wherein the upstream end is vertically higher than the downstream end, creating an attack angle with the working fluid path for the respective second cross-support. 2. The heat exchanger of claim 1 , further comprising a pumping system configured to pass the coolant through each coolant carrying body, wherein the coolant cools the at least one of the upstream and downstream supports and at least part of at least one of the first and second cross-supports. 3. The heat exchanger of claim 1 , wherein each first cross-support extends substantially horizontally between respective upstream and the downstream supports at an uppermost end of the respective upstream and downstream supports. 4. The heat exchanger of claim 1 , wherein each tube positioner positions the plurality of heat exchange tubes in a vertical plane. 5. The heat exchanger of claim 1 , wherein the at least one second cross-support comprises a plurality of second cross-supports; and wherein the plurality of tube positioners supported by the first cross-support have progressively longer lengths from an upstream-most tube positioner to a downstream-most tube positioner. 6. The heat exchanger of claim 5 , wherein the plurality of tube positioners, except for the lowermost tube positioners, each have a lowermost end angled to substantially match the attack angle of the respective second cross-support therebelow. 7. The heat exchanger of claim 5 , wherein the plurality of tube positioners supported by the lowermost second cross-support have progressively shorter lengths from an upstream-most tube positioner to a downstream-most tube positioner. 8. The heat exchanger of claim 5 , further comprising a heat exchange tube positioning member on an upper surface of at least one second cross-support, wherein the heat exchange tube positioning member includes a seat for positioning a plurality of lowermost heat exchange tubes supported by a vertically-above cross-support. 9. The heat exchanger of claim 1 , wherein the coolant includes water. 10. The heat exchanger of claim 1 , wherein the at least one HE section includes a plurality of laterally adjacent HE sections configured to span a substantial portion of the working fluid path. 11. The heat exchanger of claim 1 , wherein the heat exchanger is part of a once-through, duct-fired heat recovery steam generator of a combined cycle power plant. 12. The heat exchanger of claim 1 , wherein each pair of spaced supports, the cross-supports, and the plurality of tube positioners are made of a ferritic material. 13. The heat exchanger of claim 1 , wherein each cross-support of the first cross-support and the at least one second cross-support is coupled to respective upstream and downstream supports at a location outside a periphery of the plurality of heat exchange tubes. 14. A once-through, duct-fired heat recovery steam generator (HRSG) of a combined cycle power plant, the once-through duct-fired HRSG comprising: a casing configured to direct a working fluid therethrough; and a plurality of laterally adjacent heat exchanger (HE) sections configured to span a substantial portion of the working fluid path, each HE section including a pair of spaced supports, each spaced support including: an upstream support and a downstream support, wherein at least one of the upstream support and the downstream support includes a coolant carrying body configured to direct a coolant therethrough; a first cross-support coupled to and extending between respective upstream and downstream supports; at least one second cross-support coupled to and extending between the respective upstream and downstream supports, each second cross-support of the at least one second cross-support vertically distanced from an adjacent cross-support thereabove; and a plurality of tube positioners suspended from each cross-support, each tube positioner positioning a plurality of heat exchange tubes extending across at least a portion of a working fluid path through the casing; wherein each tube positioner positions a plurality of heat exchange tubes in a vertical plane; and wherein each pair of spaced supports, the cross-supports, and the plurality of tube positioners are made of a ferritic material, wherein the at least one second cross-support comprises a plurality of second cross-supports, wherein each second cross-support of the plurality of second cross-supports has an upstream end coupled to the upstream support and a downstream end coupled to the downstream support, wherein the upstream end is vertically higher than the downstream end, creating an attack angle with the working fluid path for the respective second cross-support. 15. The once-through, duct-fired HRSG of claim 14 , further comprising a pumping system configured to pass the coolant through each coolant carrying body, wherein the coolant cools the at least one of the upstream and downstream supports and at least part of at least one of the first and second cross-supports. 16. The once-through, duct-fired HRSG of claim 14 , wherein each first cross-support extends substantially horizontally between respective upstream and the downstream supports at an uppermost end of the respective upstream and downstream supports; and wherein the plurality of tube positioners supported by the first cross-support and all second cross-supports of the plurality of second cross-supports except for a lowermost second cross-support have progressively longer lengths from an upstream-most tube positioner to a downstream-most tube positioner. 17. The once-through, duct-fired HRSG of claim 16 , wherein the plurality of tube positioners except for the plurality of tube positioners supported by a lowermost second cross-support each have a lowermost end angled to substantially match the attack angle of the respective second cross-support therebelow; and wherein the plurality of tube positioners supported by the lowermost second cross-support have progressively shorter lengths from an upstream-most tube positioner to a downstream-most tube positioner. 18. The once-through, duct-fired HRSG of claim 14 , further comprising a heat exchange tube positioning member on an upper surface of the at least one second cross-support, wherein the heat exchange tube positioning member includes a seat for positioning a plurality of lowermost heat exchange tubes supported by a vertical