Frictional shifting element for a vehicle transmission

The invention claimed is: 1. A frictional shift element for a motor vehicle transmission, comprising: a first metal frictional element allocated to a first carrier; and a second metal frictional element allocated to a second carrier, the second metal frictional element being a friction partner for the first metal frictional element, the second metal frictional element contactable with the first metal frictional element for torque transfer at an overlapping area between the first and second metal frictional elements, wherein one of the first metal frictional element or the second metal frictional element has an annular metal frictional surface, wherein the other of the first metal frictional element or the second metal frictional element has a corresponding metal frictional surface with a plurality of frictional surfaces, each friction surface of the plurality of frictional surfaces protruding along a radial direction into the overlapping area, the frictional surfaces of the plurality of frictional surfaces distributed over a circumference of an approximately annular base body of the other of the first metal frictional element or the second metal frictional element, wherein the frictional surfaces of the plurality of frictional surfaces are formed as one piece with the other of the first metal frictional element or the second metal frictional element, and wherein the first and second metal frictional elements, except for the overlapping area between the first and second metal frictional elements, are spaced from each other in the radial direction such that coolant, lubricant, or both coolant and lubricant is flowable along the radial direction between the first and second metal frictional elements. 2. The frictional shift element of claim 1 , wherein the first metal frictional element is an outer multi-disk and the second metal frictional element is an inner multi-disk, the first carrier being an outer multi-disk carrier and the second being an inner multi-disk carrier, the outer multi-disk having an outer toothing for connecting to the outer multi-disk carrier, the outer multi-disk also having the annular frictional surface, the inner multi-disk having an inner toothing for connecting to the inner multi-disk carrier, the inner multi-disk also having the plurality of frictional surfaces, the frictional surfaces of the plurality of frictional surfaces distributed over the circumference of the inner multi-disk, the frictional surfaces of the plurality of frictional surfaces also protruding outwardly along the radial direction and positioned to overlap with the annular frictional surface of the outer multi-disk, the frictional surfaces of the plurality of frictional surfaces spaced apart along the circumference of the outer multi-disk. 3. The frictional shift element of claim 1 , wherein the first element is an outer multi-disk and the second metal frictional element is an inner multi-disk, the first carrier being an outer multi-disk carrier and the second being an inner multi-disk carrier, the inner multi-disk having the annular frictional surface, the inner multi-disk also having an inner toothing for connecting to the inner multi-disk carrier, the outer multi-disk having an outer toothing for connecting to the outer multi-disk carrier, the outer multi-disk also having the plurality of frictional surfaces, the frictional surfaces of the plurality of frictional surfaces distributed over the circumference of the inner multi-disk, the frictional surfaces of the plurality of frictional surfaces also protruding inwardly along the radial direction and positioned to overlap with the annular frictional surface of the inner multi-disk, the frictional surfaces of the plurality of frictional surfaces spaced apart along the circumference of the inner multi-disk. 4. The frictional shift element of claim 1 , wherein each frictional surface of the plurality of frictional surfaces is tooth-shaped at the approximately annual base body of the other of the first metal frictional element or the second metal frictional element. 5. The frictional shift element of claim 4 , wherein each tooth-shaped frictional surfaces of the plurality of frictional surfaces is shaped across a plurality of consecutive radii along a circumferential direction. 6. The frictional shift element of claim 5 , wherein a first radius of plurality of consecutive radii proximate an inner or outer circumference of the annual base body is larger than a second radius of plurality of consecutive radii proximate the tooth-shaped frictional surfaces. 7. The frictional shift element of claim 1 , wherein a rib-shaped reinforcement is formed on both sides of each of the plurality of frictional surfaces along a circumferential direction, the rib-shaped reinforcement extending along the circumferential direction. 8. The frictional shift element of claim 1 , wherein a spring clip element is compressed along an axial direction at one or more of the plurality of frictional surfaces such that the spring clip element urges the first and second metal frictional elements apart along the axial direction in an unactuated state of the frictional shift element. 9. The frictional shift element of claim 8 , wherein the spring clip element is formed as one piece with the plurality of frictional surfaces. 10. The frictional shift element of claim 8 , wherein the spring clip element is positioned on both sides of the one or more of the plurality of frictional surfaces along a circumferential direction. 11. The frictional shift element of claim 10 , wherein the spring clip element projects in the axial direction from the one or more of the plurality of frictional surfaces. 12. The frictional shift element of claim 11 , wherein the spring clip element acts on the one of the first metal frictional element or the second metal frictional element. 13. The frictional shift element of claim 1 , wherein frictional elements of the first carrier are urged apart proximate toothing of the first carrier and friction elements of the second carrier are also urged apart proximate toothing of the second carrier by a plurality of spring elements. 14. The frictional shift element of claim 1 , wherein the annular frictional surface and the plurality of frictional surfaces are turned towards each other and are beveled or conical in an axial direction. 15. The frictional shift element of claim 1 , wherein a thickness of the plurality of frictional surfaces along an axial direction is smaller than a thickness of the other of the first metal frictional element or the second metal frictional element proximate toothing of the other of the first metal frictional element or the second metal frictional element. 16. The frictional shift element of claim 1 , wherein a thickness of the annular frictional surface along an axial direction is smaller than a thickness of the one of the first metal frictional element or the second metal frictional element proximate toothing of the one of the first metal frictional element or the second metal frictional element. 17. The frictional shift element of claim 1 , wherein chamfers or radii are provided for the plurality of frictional surfaces in a circumferential direction. 18. The frictional shift element of claim 1 , wherein the first metal frictional element is at least one first metal frictional element and the second metal frictional element is at least one second metal frictional element, each frictional surface of the one of the at least one first metal frictional element or the at least one second metal frictional element arranged in an