Jet impingement cooling systems and related methods of cooling high heat flux devices

What is claimed is: 1 . A jet impingement cooling system configured to cool a high heat flux device via a cooling fluid, the system comprising: a heatsink body coupled to the high heat flux device or capable of being coupled to the high heat flux device; a first heatsink fin extending from the heatsink body and including an impingement face, an exit face, a fin thickness, and a plurality of exit orifices extending through the fin thickness from the impingement face to the exit face, the exit orifices being spaced-apart from each other across the impingement face to define impingement surfaces of the impingement face between the exit orifices; an exit channel in fluid communication with the plurality of exit orifices at the exit face, a first injection wall including a supply-side face, an injection-side face, a wall thickness between the supply-side face and injection-side face, and a plurality of injection ports extending through a wall thickness from the supply-side face to the injection-side face, the plurality of injection ports being oriented such that impingement jets therefrom are directed to the impingement surfaces, the injection-side face being spaced-apart from the impingement face; a cooling supply channel in fluid communication with the plurality of injection ports at the supply-side face, wherein, in operation, the cooling fluid flows from the cooling supply channel through the injection ports, out the injection ports to impinge against the impingement surfaces and exit through the exit orifices into the exit channel. 2 . The jet impingement cooling system of claim 1 , wherein the plurality of injection ports is offset from the plurality of exit orifices such that longitudinal axes of the injection ports are not in alignment with longitudinal axes of the exit orifices. 3 . The jet impingement cooling system of claim 1 , wherein the plurality of injection ports is offset from the plurality of exit orifices such that no boundary of any injection port overlaps with any boundary of any exit orifice where the plurality of injection ports and plurality of exit orifices are superimposed with each other. 4 . The jet impingement cooling system of claim 1 , further comprising a second heatsink fin extending from the heatsink body and including an impingement face, an exit face, a fin thickness, and a plurality of exit orifices extending through the fin thickness from the impingement face to the exit face, the exit orifices being spaced-apart from each other across the impingement face to define impingement surfaces of the impingement face between the exit orifices, the second heatsink fin being spaced-apart from the first heatsink fin to at least in part define the exit channel, the exit channel being in fluid communication with the plurality of exit orifices of the first and second heatsink fins at the respective exit faces thereof. 5 . The jet impingement cooling system of claim 4 , wherein the exit orifices of the first heatsink fin and the second heatsink fin are offset from each other such that cooling fluid passing through the exit orifices of the first heatsink fin and second heatsink fin into the exit channel do not run into each other head-on. 6 . The jet impingement cooling system of claim 4 , wherein the plurality of exit orifices of the first heatsink fin is offset from the plurality of exit orifices of the second heatsink fin such that longitudinal axes of the exit orifices of the first heatsink fin are not in alignment with longitudinal axes of the exit orifices of the second heatsink fin. 7 . The jet impingement cooling system of claim 4 , wherein the plurality of exit orifices of the first heatsink fin is offset from the plurality of exit orifices of the second heatsink fin such that no boundary of any exit orifice of the first heatsink fin overlaps with any boundary of any exit orifice of the second heatsink fin where the plurality of exit orifices of the first heatsink fin and plurality of exit orifices of the second heatsink fin are superimposed with each other. 8 . A jet impingement cooling system configured to cool a high heat flux device via a cooling fluid, the system comprising: a heatsink coupled to the high heat flux device or capable of being coupled to the high heat flux device, the heatsink including a first impingement surface having exit orifices and impingement regions, the exit orifices spaced-apart from each other and defined in the first impingement surface, and the impingement regions located between adjacent exit orifices; and a first supply surface spaced-apart from the first impingement surface and including injection ports spaced-apart from each other and defined in the supply surface, the injection ports oriented such that impingement jets therefrom are directed to impinge against the impingement regions. 9 . The jet impingement cooling system of claim 8 , wherein, in operation, the cooling fluid flows out of the injection ports as the impingement jets to impinge against the impingement regions and then enters the exit orifices. 10 . The jet impingement cooling system of claim 8 , wherein longitudinal axes of the injection ports are offset from longitudinal axes of the exit orifices. 11 . The jet impingement cooling system of claim 10 , wherein longitudinal axes of the injection ports are generally parallel to the longitudinal axes of the exit orifices. 12 . The jet impingement cooling system of claim 8 , wherein the injection ports are out of alignment with the exit orifices such that no injection port overlaps with any exit orifice when the injection ports and exit orifices are superimposed with each other. 13 . The jet impingement cooling system of claim 8 , further comprising a second supply surface and wherein the heatsink further includes a second impingement surface and an exit channel, the second supply surface spaced-apart from the second impingement surface, which is spaced-apart from the first impingement surface, the exit channel located between the first and second impingement surfaces, the second supply surface including injection ports spaced-apart from each other and defined in the second supply surface, the second impingement surface having exit orifices and impingement regions, the exit orifices spaced-apart from each other and defined in the second impingement surface, the impingement regions of the second impingement surface located between adjacent exit orifices of the second impingement surface, the injection ports of the second supply surface oriented such that impingement jets therefrom are directed to impinge against the impingement regions of the second impingement surface, the exit orifices of the first and second impingement surfaces being in fluid communication with the exit channel. 14 . The jet impingement cooling system of claim 13 , wherein the exit orifices of the first and the second impingement surfaces are out of alignment with each other such that cooling fluid flows passing through the exit orifices of the first and the second impingement surfaces into the exit channel do not run into each other head-on. 15 . The jet impingement cooling system of claim 13 , wherein the exit orifices of the first and the second impingement surfaces are out of alignment with each other such that longitudinal axes of the exit orifices of the first impingement surface are not in alignment with longitudinal axes of the exit orifices of the second impingement surface. 16 . The jet impingement cooling system of claim 15 , wherein the longitudinal axes of the exit orifices of the first impingement surface are generally