Piston assembly with weld support

What is claimed is: 1. A method, comprising: providing a piston body that forms an entire upper combustion bowl surface, which is free from welds, the piston body forming a first portion of a cooling gallery, the piston body including radially inner and radially outer body mating surfaces and defining a piston axis; assembling a cooling gallery ring with the piston body, the cooling gallery ring forming a second portion of the cooling gallery, the cooling gallery ring including a radially inner ring mating surface and a radially outer ring mating surface; forming the cooling gallery with the first and second portions by laser welding the piston body to the cooling gallery ring along a radially inner interface region, the radially inner interface region including the radially inner mating surfaces of the piston body and the cooling gallery ring; and laser welding the piston body to the cooling gallery ring along a radially outer interface region, the radially outer interface region including the radially outer mating surfaces of the piston body and cooling gallery ring; wherein, at the radially inner interface region, the piston body includes a body step portion formed on the piston body being axially offset to and extending radially from the radially inner body mating surface, the body step portion comprising a laterally extending surface that faces the cooling gallery ring, and the body step portion forming a part of the cooling gallery; and wherein, at the radially outer interface region, the cooling gallery ring includes a cooling gallery step portion being radially offset to and axially extending from the radially outer ring mating surface, a vertically extending surface formed on the cooling gallery step portion that faces the piston body, and the cooling gallery step portion forms a part of the cooling gallery. 2. The method of claim 1 , wherein the laser welding includes directing a weld laser substantially parallel to the piston axis toward the radially mating surfaces of the piston body and cooling gallery ring. 3. The method of claim 1 , wherein the laser welding includes directing a weld laser in a direction toward the radially outer mating surfaces of the piston body and cooling gallery ring, the direction defining a non-parallel angle with respect to the piston axis. 4. The method of claim 1 , wherein the piston body includes a skirt configured to interface with an engine bore surface. 5. The method of claim 1 , further comprising heating at least one of the piston body and the cooling gallery ring prior to the laser welding. 6. The method of claim 1 , wherein the body step portion includes a spatter trap configured to receive weld spatter, the spatter trap defining an enclosed volume adjacent to a weld site associated with one of the radially inner and outer interface regions. 7. The method of claim 1 , wherein the piston body and cooling gallery ring are each formed of an aluminum material. 8. The method of claim 1 , wherein the cooling gallery ring step portion is formed from a gallery ring radial surface and the vertically extending surface that is radially external to the gallery ring radial surface, and the piston body includes a piston body radial surface that faces radially inward and is engaged against the vertically extending surface. 9. A piston assembly, comprising: a piston body having a top surface and having formed therein an uninterrupted unitary upper combustion bowl surface, the piston body having a skirt and forming a first portion of a cooling gallery, the piston body including radially inner and radially outer body mating surfaces and defining a piston axis; and a cooling gallery ring forms a second portion of the cooling gallery and includes a radially inner ring mating surface abutted along a radially inner interface region with the radially inner body mating surface, the cooling gallery ring includes a radially outer ring mating surface abutted along a radially outer interface region with the radially outer body mating surface such that the cooling gallery is substantially enclosed as the first and second portions; wherein the piston body and cooling gallery ring are welded together along the radially inner and radially outer interface regions; wherein, at the radially inner interface region, the piston body includes a body portion formed on the piston body being axially offset to and extending radially from the radially inner body mating surface, the body step portion comprising a laterally extending surface that faces the cooling gallery ring, and the body step portion forming a part of the cooling gallery; and wherein, at the radially outer interface region, the cooling gallery ring includes a cooling gallery step portion being radially offset to and axially extending from the radially outer ring mating surface, a vertically extending surface formed on the cooling gallery step portion that faces the piston body, and the cooling gallery step portion forms a part of the cooling gallery. 10. The piston assembly of claim 9 , wherein the body step portion includes a spatter trap configured to receive weld spatter, and the spatter trap defines an enclosed volume adjacent to a weld site associated with one of the radially inner and outer interface regions. 11. The piston assembly of claim 9 , further comprising a ring insert received within a piston ring groove, the ring insert defining a cavity configured to retain a piston ring. 12. The piston assembly of claim 9 , wherein the cooling gallery ring step portion is formed from a gallery ring radial surface and the vertically extending surface that is radially external to the gallery ring radial surface, and the piston body includes a piston body radial surface that faces radially inward and is engaged against the vertically extending surface. 13. A piston assembly, comprising: a piston body having a top surface and having formed in the top surface an entire combustion bowl within the piston body, the piston body forms a first portion of a cooling gallery, the piston body includes radially inner and radially outer body mating surfaces, and the piston body forms a piston axis; and a cooling gallery ring forms a second portion of the cooling gallery, the cooling gallery ring includes a radially inner ring mating surface abutted along a radially inner interface region with the radially inner body mating surface, the cooling gallery ring includes a radially outer ring mating surface abutted along a radially outer interface region with the radially outer body mating surface such that the cooling gallery is substantially enclosed; wherein, at the radially inner interface region, the piston body includes a body step portion formed on the piston body being axially offset to and extending radially from the radially inner body mating surface, the body step portion comprising a laterally extending surface that faces the cooling gallery ring, and the body step portion forming a part of the cooling gallery; and wherein, at the radially outer interface region, the cooling gallery ring includes a cooling gallery step portion being radially offset to and axially extending from the radially outer ring mating surface, a vertically extending surface formed on the cooling gallery step portion that faces the piston body, and the cooling gallery step portion forms a part of the cooling gallery. 14. The piston assembly of claim 13 , wherein the entire combustion bowl is a unitary surface within the top surface of the piston and the entire combustion bowl surface is free from welds. 15. The piston assembly of claim 13 , wherein the cooling gallery ring step