Manifold for an engine assembly

The invention claimed is: 1. An engine assembly, comprising: a turbocharger; a fluid conduit configured to carry a first coolant, wherein the fluid conduit is thermally coupled to the turbocharger such that the first coolant flowing through the fluid conduit extracts heat from the turbocharger; a surge tank; an engine head defining a coolant gallery, wherein the coolant gallery is configured to carry a second coolant; an exhaust manifold integrated with the engine head, wherein the coolant gallery is thermally coupled to the exhaust manifold such that the second coolant extracts heat from the exhaust manifold; a coolant manifold in fluid communication with the fluid conduit and the coolant gallery, wherein the coolant manifold defines: a venting orifice in fluid communication with the surge tank in order to allow vapors to vent from the coolant manifold to the surge tank; a joint passageway in fluid communication with the fluid conduit in order to allow the first coolant to flow from the fluid conduit to the coolant manifold; an interconnection passageway fluidly interconnecting the joint passageway and the coolant gallery in order to allow the first coolant to flow from the joint passageway to the coolant gallery; wherein the coolant manifold is downstream of the fluid conduit such that the first coolant flows from the fluid conduit directly to the coolant manifold; and wherein the coolant gallery is downstream of the fluid conduit such that the second coolant extracts heat from the exhaust manifold after the first coolant has extracted heat from the turbocharger. 2. The engine assembly of claim 1 , wherein the joint passageway has a larger cross-sectional area than the venting orifice. 3. The engine assembly of claim 2 , wherein the interconnection passageway has a larger cross-sectional area than the venting orifice. 4. The engine assembly of claim 1 , wherein the coolant manifold is directly coupled to the engine head. 5. The engine assembly of claim 4 , wherein the coolant gallery in direct fluid communication with the interconnection passageway. 6. The engine assembly of claim 5 , further comprising at least one fastener extending through the coolant manifold and the engine head in order to couple the coolant manifold to the engine head. 7. The engine assembly of claim 1 , wherein the joint passageway is obliquely angled relative to the venting orifice. 8. The engine assembly of claim 7 , wherein the joint passageway is obliquely angled relative to the interconnection passageway. 9. The engine assembly of claim 1 , further comprising a venting conduit fluidly interconnecting the surge tank and the venting orifice. 10. The engine assembly of claim 1 , wherein the coolant manifold is configured to vent the coolant in order to direct the vapors of the coolant to the surge tank while a liquified portion of the coolant does not flow to the surge tank, the engine assembly further includes a venting conduit fluidly coupled to the coolant manifold, the venting conduit is configured to allow the vapors from the coolant to flow from the coolant manifold to the surge tank, the engine assembly further includes a T-coupling coupling the venting conduit to the coolant manifold, the engine assembly includes an engine cooling system, the venting conduit is fluidly coupled to the engine cooling system such that vapors in the engine cooling system are allowed to flow from the engine cooling system to the surge tank through the venting conduit, the venting orifice is a first venting orifice, the coolant manifold defines a second venting orifice to allow the vapors of the coolant to flow from the coolant manifold to the surge thank, the second venting orifice is in direct fluid communication with the joint passageway, the coolant manifold defines a joint vent in direct fluid communication with the first venting orifice, the joint vent is in fluid communication with the venting conduit through the T-coupling to allow the vapors of the coolant to flow to the surge tank through the venting conduit, the second venting orifice is in fluid communication with the joint vent, the interconnection passageway is in direct fluid communication with the joint passageway, the interconnection passageway is in direct fluid communication with the first venting orifice, and the interconnection passageway and the joint passageway each have a larger cross-sectional area than the first venting orifice and the second venting orifice. 11. The engine assembly of claim 10 , wherein the coolant gallery is downstream of the coolant manifold such that the first coolant flows from the coolant manifold to the coolant gallery with the first coolant flowing from the coolant manifold being joined with the second coolant flowing through the coolant gallery, resulting in a mixed coolant, the coolant gallery is thermally coupled exhaust manifold such that the mixed coolant extracts heat from the exhaust manifold after the first coolant has extracted heat from the turbocharger.