Engine crankshaft assemblies with internal stiffening structures

What is claimed: 1. A crankshaft assembly, comprising: a crankshaft body formed with a first material and including: a plurality of bearing journals mutually coaxial to rotate on a crankshaft axis and spaced from each other along a length of the crankshaft body, each of the bearing journals defining therein a journal cavity, a plurality of crankpins spaced from each other along the length of the crankshaft body and axially offset from the crankshaft axis, each of the crankpins defining therein a crankpin cavity, and a plurality of crank webs projecting radially from the crankshaft axis and interconnecting the bearing journals and the crankpins, each of the crank webs defining therein a web cavity; and a stiffening bar disposed in one or more of the journal cavities, the crankpin cavities, and/or the web cavities, the stiffening bar formed with a second material having a second modulus of elasticity greater than a first modulus of elasticity of the first material, the stiffening bar including an I-beam stiffener with an I-shaped transverse cross-section having a leg, an arm, a stem connecting the leg and the arm, a first rounded protrusion projecting radially from an outer-diameter (OD) surface of the leg, and a second rounded protrusion projecting radially from an OD surface of the arm. 2. The crankshaft assembly of claim 1 , wherein the leg and the arm each includes a respective pair of opposing transverse ends with rounded edges. 3. The crankshaft assembly of claim 1 , wherein the arm and the leg have a first thickness and the stem has a second thickness less than the first thickness. 4. The crankshaft assembly of claim 1 , further comprising a filler material disposed within the journal cavities, the crankpin cavities, and/or the web cavities and interposed between the stiffening bar and the bearing journals, the crankpins, and/or the crank webs. 5. The crankshaft assembly of claim 1 , wherein the stiffening bar includes an interface surface at which the stiffening bar contacts inner-diameter (ID) surfaces of the journal cavities, the crankpin cavities, and/or the web cavities, the interface surface having a surface texture configured to increase a mechanical adhesion between the stiffening bar and the crankshaft body. 6. The crankshaft assembly of claim 1 , wherein the I-beam stiffener has an elongated non-linear beam body extending through the journal cavities, the crankpin cavities, and the web cavities. 7. The crankshaft assembly of claim 6 , wherein the beam body of the I-beam stiffener is bent transversely and rotated circumferentially with respect to a center axis of the I-beam stiffener. 8. The crankshaft assembly of claim 1 , wherein the stiffening bar includes a plurality of discrete stiffening bars each mounted within a respective one of the journal cavities, the crankpin cavities, and/or the web cavities. 9. The crankshaft assembly of claim 8 , wherein each of the journal cavities, the crankpin cavities, and the web cavities defines therein a through-hole with a hollow core having opposing open ends, and wherein each of the discrete stiffening bars is located in a respective one of the hollow cores and projects out from the open ends of the hollow core. 10. The crankshaft assembly of claim 1 , wherein the first material includes aluminum, aluminum alloy, or nodular iron, and wherein the second material includes steel, alloy steel, or ceramic. 11. The crankshaft assembly of claim 1 , wherein the crankshaft body, including the bearing journals, the crankpins, and the crank webs, is integrally formed as a single-piece structure. 12. A motor vehicle comprising: a vehicle body; a plurality of road wheels rotatably attached to the vehicle body; and an internal combustion engine (ICE) assembly attached to the vehicle body and operable to output engine torque to one or more of the road wheels to thereby propel the motor vehicle, the ICE assembly having an engine block defining a plurality of cylinder bores, a plurality of pistons each reciprocally movable within a respective one of the cylinder bores, and a crankshaft assembly including: a single-piece crankshaft body formed with a first material and including: a plurality of bearing journals rotatably attached to the engine block, mutually coaxial to rotate on a crankshaft axis, and spaced from each other along a length of the crankshaft body, each of the bearing journals defining therethrough a journal cavity, a plurality of crankpins each coupled to a respective one of the pistons, spaced from each other along the length of the crankshaft body, and axially offset from the crankshaft axis to orbit about the crankshaft axis, each of the crankpins defining therethrough a crankpin cavity, and a plurality of crank webs projecting radially from the crankshaft axis and interconnecting the bearing journals and the crankpins, each of the crank webs defining therethrough a web cavity; and an I-beam stiffener with an elongated non-linear beam body bent transversely and rotated circumferentially with respect to a center axis of the I-beam stiffener, the I-beam stiffener extending through the journal cavities, the crankpin cavities, and the modulus of elasticity greater than a first modulus of elasticity of the first material. 13. A method of manufacturing a crankshaft assembly, the method comprising: forming a crankshaft body with a first material, the crankshaft body including: a plurality of bearing journals mutually coaxial to rotate on a crankshaft axis and spaced from each other along a length of the crankshaft body, each of the bearing journals defining therein a journal cavity, a plurality of crankpins spaced from each other along the length of the crankshaft body and axially offset from the crankshaft axis, each of the crankpins defining therein a crankpin cavity, and a plurality of crank webs projecting radially from the crankshaft axis and interconnecting the bearing journals and the crankpins, each of the crank webs defining therein a web cavity; and locating a stiffening bar in the journal cavities, the crankpin cavities, and the web cavities, the stiffening bar formed with a second material having a second modulus of elasticity greater than a first modulus of elasticity of the first material, the stiffening bar including an I-beam stiffener with an elongated non-linear beam body extending through the journal cavities, the crankpin cavities, and the web cavities, wherein the beam body is bent transversely and rotated circumferentially with respect to the crankshaft axis. 14. The method of claim 13 , wherein the I-beam stiffener has an I-shaped transverse cross-section having an arm, a leg, and a stem connecting the leg and the arm. 15. The method of claim 14 , wherein the leg and the arm each includes a respective pair of opposing transverse ends with rounded edges. 16. The method of claim 14 , wherein the I-shaped transverse cross-section further includes a first rounded protrusion projecting radially from an outer-diameter (OD) surface of the leg and a second rounded protrusion projecting radially from an OD surface of the arm. 17. The method of claim 13 , further comprising adding a filler material within the journal cavities, the crankpin cavities, and/or the web cavities and interposed between the stiffening bar and the bearing journals, the crankpins, and/or the crank webs. 18. The method of claim 13 , wherein the arm and the leg have a first thickness and the stem has a second thickness less than the first thickness. 19. The method of claim 13 , wherein t