Reciprocating engine

What is claimed is: 1. A reciprocating engine comprising: a cylinder comprising a cylinder wall; a crankshaft; a connecting rod rotatably coupled to the crankshaft, the connecting rod defining a connecting rod fluid passage extending along a length thereof; and a piston assembly comprising: a piston dome comprising a hot side and a cold side, the piston dome coupled to the connecting rod and positioned within the cylinder, an inlet defined in the piston dome, the inlet in fluid communication with the connecting rod fluid passage and configured to receive a fluid from the connecting rod fluid passage, a piston dome cooling passage formed as a conduit enclosed within and defined by the piston dome, wherein the piston dome cooling passage is formed to circulate the fluid in a set directional flow through the piston dome, such that the piston dome cooling passage extends through the piston dome from the inlet, toward the hot side, proximate the hot side, and from proximate the hot side out of the piston dome via a plurality of exits, wherein the plurality of exits are defined along a lowermost portion of the piston dome and configured to direct the fluid directly onto the cylinder wall. 2. The reciprocating engine of claim 1 , wherein the plurality of exits comprises a plurality of nozzles configured to spray the fluid onto the cylinder wall. 3. The reciprocating engine of claim 2 , wherein each of the plurality of nozzles is configured to spray the fluid directly onto the cylinder wall. 4. The reciprocating engine of claim 1 , further comprising at least one branch point at which the conduit forming the piston dome cooling passages divides into at least two branches, wherein each branch is connected to a respective exit of the plurality of exits. 5. The reciprocating engine of claim 4 , wherein the at least one branch point is disposed proximate the hot side of the piston dome. 6. The reciprocating engine of claim 1 , wherein the connecting rod is a first connecting rod defining a first connecting rod fluid passage, wherein the piston dome is a first piston dome defining a first inlet, a first piston dome cooling passage and a first plurality of exits defined by a first plurality of nozzles, and wherein the reciprocating engine further comprises: a second connecting rod rotatably coupled to the crankshaft, the second connecting rod defining a second connecting rod fluid passage; and a second piston dome coupled to the second connecting rod, the second piston dome defining a second inlet in fluid communication with the second connecting rod fluid passage, a second piston dome cooling passage, and a second plurality of exits defined by a second plurality of nozzles. 7. The reciprocating engine of claim 6 , wherein the crankshaft defines a crankshaft fluid passage, and wherein the crankshaft fluid passage is fluidly connected to each of the first connecting rod fluid passage and the second connecting rod fluid passage. 8. The reciprocating engine of claim 6 , wherein the crankshaft defines a first crankshaft fluid passage fluidly connected to the first connecting rod fluid passage, and wherein the crankshaft additionally defines a separate, second crankshaft fluid passage fluidly connected to the second connecting rod fluid passage. 9. The reciprocating engine of claim 1 , further comprising a heat exchanger configured to receive the fluid from the plurality of exits. 10. The reciprocating engine of claim 9 , further comprising an oil pan, wherein the heat exchanger is in thermal communication with the oil pan. 11. The reciprocating engine of claim 1 , wherein the hot side of the piston dome is configured to be exposed to combustion within the cylinder, and wherein the piston dome cooling passage allows the fluid therein to accept heat from the hot side of the piston dome. 12. The reciprocating engine of claim 11 , wherein at least a first and a second one of the plurality of exits are disposed opposite one another relative to a longitudinal centerline of the cylinder. 13. A piston assembly for a reciprocating engine including a cylinder having a cylinder wall, the piston assembly comprising: a piston dome comprising a hot side and a cold side, an inlet defined in the piston dome and configured to receive a fluid from at least one other component of the reciprocating engine, a piston dome cooling passage formed as a conduit enclosed within and defined by the piston dome and configured to circulate the fluid in a set directional flow through the piston dome, wherein the piston dome cooling passage is formed such that the piston dome cooling passage extends through the piston dome from the inlet, toward the hot side, proximate the hot side, and from proximate the hot side out of the piston dome via a plurality of exits, wherein the plurality of exits are defined along a lowermost portion of the piston dome and configured to direct the fluid directly onto the cylinder wall. 14. The piston assembly of claim 13 , wherein at least one of the plurality of exits is disposed on the cold side of the piston dome. 15. The piston assembly of claim 13 , wherein the plurality of exits comprises a plurality of nozzles configured to spray the fluid onto the cylinder wall. 16. The piston assembly of claim 15 , wherein each of the plurality of nozzles is configured to spray the fluid directly onto the cylinder wall. 17. The piston assembly of claim 13 , further comprising at least one branch point at which the piston dome cooling passage divides into at least two branches, wherein each branch is connected to a respective exit of the plurality of exits. 18. The piston assembly of claim 17 , wherein the at least one branch point is disposed proximate the hot side of the piston dome. 19. A method of cooling a piston assembly for a reciprocating engine, the method comprising: receiving, with an inlet defined in a piston dome, a fluid from at least one other component of the reciprocating engine; circulating the fluid, through at least one piston dome cooling passage formed as a conduit enclosed within and defined by the piston dome, in a set directional flow from the inlet towards a hot side of the piston dome; and ejecting the fluid outside of the piston dome via a plurality of exits in fluid communication with the at least one piston dome cooling passage, wherein the plurality of exits are defined along a lowermost portion of the piston dome and configured to direct the fluid directly onto a cylinder wall of the reciprocating engine. 20. The method of claim 19 , further comprising: dividing, with at least one branch point, the at least one piston dome cooling passage into at least two branches, wherein each branch is connected to a respective exit of the plurality of exits.