Heat exchanger with progressive divided flow circuit, structural load bearing design

What is claimed is: 1. A heat exchanger for cooling an operating fluid flowing within and through the heat exchanger, comprising: a feed fluid circuit including a plurality of feed fluid passages to transport an operating fluid; a heat exchange fluid circuit including a plurality of heat exchange regions that are configured to provide a heat exchange relationship for the heat exchanger, the plurality of heat exchange feed fluid passages being fluidly connected to the feed fluid circuit in a downstream direction of the heat exchanger, the plurality of heat exchange feed fluid passages arranged to provide apportioning of the operating fluid for optimization of heat exchange; and a discharge fluid circuit including a plurality of discharge fluid passages that are fluidly connected to the heat exchange fluid circuit in the downstream direction; wherein the feed fluid circuit includes at least a first feed section having a first set of the plurality of feed fluid passages, and a second feed section having a second set of the plurality of feed fluid passages, the second feed section being located downstream of the first feed section, and wherein each of the second set of the plurality of feed fluid passages is progressively smaller than each of the first set of feed fluid passages, as measured by cross-sectional area transverse to a direction of downstream operating fluid flow through the passages, such that operating fluid from at least the first feed section to the second feed section is divided into progressively smaller flow paths in the downstream direction; wherein the heat exchanger comprises an air-cooled oil cooler configured to cool the operating fluid; wherein each of the plurality of heat exchange regions are configured as a single-pass heat transfer circuit for a local counter-flow configuration, parallel-flow configuration, or crossflow heat exchange configuration relative to an external air flow of the air-cooled oil cooler, or multi-pass heat transfer circuit for a locally mixed-flow heat exchange configuration relative to the external air flow of the air-cooled oil cooler; wherein the heat exchange fluid circuit, to optimize heat transfer performance across all the heat exchange regions, includes at least a plurality of dividing flow-control features that recursively divide the operating fluid flow distributing the operating fluid in the downstream direction into the heat exchange regions, and the heat exchange fluid circuit further includes at least a plurality of combining flow-control features that recursively combine the exiting fluid flow in the downstream direction from the heat exchange feed sections to collect and discharge the operating fluid; wherein the plurality of heat exchange regions are configured to apportion the flow rate of the operating fluid for balancing heat transfer performance and control pressure loss through the heat exchanger; wherein the heat exchange feed sections comprise a tree-like configuration, a fractal-like configuration, or a serial configuration where each feed section utilizes recursively refined or coarsened geometric length scales which augment heat transfer along the progressively smaller flow paths of the second feed section; and wherein a width and height of the heat exchange regions apportion the flow in the heat exchange regions. 2. The heat exchanger according to claim 1 , wherein the discharge fluid circuit includes at least a first discharge section having a first set of the plurality of discharge fluid passages, and a second discharge section having a second set of the plurality of discharge fluid passages, the second discharge section being located downstream of the first discharge section, and wherein each of the second set of the plurality of discharge fluid passages is progressively larger than each of the first set of discharge fluid passages, as measured by cross-sectional area transverse to a direction of downstream operating fluid flow through the passages, such that operating fluid from at least the first discharge section to the second discharge section is combined into progressively larger flow paths in the downstream direction. 3. The heat exchanger according to claim 1 , wherein the heat exchange fluid circuit includes at least a set of the plurality of heat exchange fluid passages that are smaller than an adjacent set of the plurality of feed fluid passages to progressively divide flow in the downstream direction from the feed fluid circuit into the heat exchange fluid circuit. 4. The heat exchanger according to claim 1 , wherein the heat exchange fluid circuit includes at least a set of the plurality of heat exchange fluid passages that are smaller than an adjacent set of the plurality of discharge fluid passages to progressively combine flow in the downstream direction from the heat exchange fluid circuit to the discharge fluid circuit. 5. The heat exchanger according to claim 1 , wherein the feed fluid circuit includes at least a third feed section having a third set of the plurality of feed fluid passages, the third feed section being located downstream of the second feed section, wherein each of the third set of the plurality of feed fluid passages is progressively smaller than each of the second set of feed fluid passages, as measured by cross-sectional area transverse to a direction of downstream fluid flow through the passages, such that operating fluid flow from at least the second feed section to the third feed section is divided into progressively smaller flow paths in the downstream direction, and wherein the discharge fluid circuit includes at least a first discharge section having a first set of the plurality of discharge fluid passages, a second discharge section having a second set of the plurality of discharge fluid passages, and a third discharge section having a third set of the plurality of discharge fluid passages, the second discharge section being located downstream of the first discharge section, and the third discharge section being located downstream of the second discharge section, and wherein each of the second set of the plurality of discharge fluid passages is progressively larger than each of the first set of discharge fluid passages and each of the third set of the plurality of discharge fluid passages is progressively larger than each of the second set of discharge fluid passages, as measured by cross-sectional area transverse to a direction of downstream operating fluid flow through the passages, such that fluid from at least the first discharge section to the second discharge section to the third discharge section is combined into progressively larger flow paths in the downstream direction. 6. The heat exchanger according to claim 5 , wherein the progressively smaller size of first, second and third set of the plurality of feed fluid passages in the downstream direction are recursively smaller in size, and wherein the progressively larger size of first, second and third set of the plurality of discharge fluid passages in the downstream direction are recursively larger in size. 7. The heat exchanger according to claim 1 , wherein the discharge fluid circuit is configured as a mirror image to the feed fluid circuit about an axis that is parallel to both the feed and discharge fluid circuits. 8. The heat exchanger according to claim 1 , wherein the heat exchanger is a plate-fin heat exchanger. 9. The heat exchanger according to claim 8 , wherein the plurality of feed fluid passages, heat exchange fluid passages, and discharge fluid passages are formed between fin structures that are arranged in an array of rows and columns. 10. The heat exchanger according to claim 9 , wherein the fin struc