Connecting rod and internal combustion engine

What is claimed is: 1. A connecting rod, having a big end bearing eye for attachment to a crankshaft, a small end bearing eye for attachment to a piston pin of a piston in a cylinder, and an eccentric adjusting device for adjusting an effective connecting rod length, the eccentric adjusting device having eccentric rods that engage on an eccentric lever of the eccentric adjusting device, and the eccentric adjusting device having an eccentric that is guided in an aperture in the eccentric lever and in the small end bearing eye and that has an aperture for accommodating a piston pin, two lubricating oil bores being introduced into the small end bearing eye at positions so that the piston pin is between the lubricating oil bores and the big end bearing eye and via which a lubricating oil film can be built up between the small end bearing eye and the eccentric, the small end bearing eye having opposite inner and outer circumferential surfaces spaced from one another by a radial wall thickness, all areas of the outer circumferential surface of the small end bearing eye being convexly arcuate and configured so that the radial wall thickness in those regions of the small end bearing eye with the lubricating oil bores is sufficiently larger than adjoining regions of said small end bearing eye to compensate for a weakening caused by the respective lubricating oil bore, while a smaller radial wall thickness in areas of the small end bearing eye adjoining the lubricating oil bore achieves sufficient strength and a weight reduction for the connecting rod. 2. The connecting rod of claim 1 , wherein at least two of the lubricating oil bores are introduced into the small end bearing eye, the lubricating oil bores extend in the radial direction of the small end bearing eye and are spaced apart in a circumferential direction of the small end bearing eye, the small end bearing eye having a larger radial wall thickness in those regions in which the lubricating oil bores are introduced into the bearing eye than in a region between these regions as seen in the circumferential direction of the small end bearing eye. 3. The connecting rod of claim 2 , wherein the small end bearing eye has a smaller radial wall thickness in regions that lie directly opposite or face the extended eccentric rods of the eccentric adjusting device than in regions in which the lubricating oil bores are introduced into the small end bearing eye. 4. The connecting rod of claim 1 , wherein transitions on the small end bearing eye between the regions of different wall thickness are formed continuously and in a manner free from discontinuities. 5. The connecting rod of claim 1 , wherein the outer circumferential surface of the small end bearing eye at the locations that have the lubricating oil bores are concentric with the inner circumferential surface. 6. The connecting rod of claim 5 , wherein the regions of the outer circumferential surface of the small end bearing eye adjoining the regions of the small end bearing eye that have the lubricating oil bores have larger radii of curvature than the regions of the outer circumferential surface of the small end bearing eye that have the lubricating oil bores. 7. The connecting rod of claim 1 , wherein the radial wall thickness in regions of the small end bearing eye adjoining the regions that have the lubricating oil bores is more than half of the radial wall thickness of the regions of the small end bearing eye that have the lubricating oil bores. 8. An internal combustion engine that has an adjustable compression ratio, having at least one cylinder and having a crankshaft, on which at least one connecting rod engages, wherein the at least one connecting rod has a big end bearing eye attached to the crankshaft, a small end bearing eye attached to a piston pin of a piston in the at least one cylinder and an eccentric adjusting device for adjusting an effective connecting rod length, the eccentric adjusting device having an eccentric that interacts with an eccentric lever, and eccentric rods that engage on the eccentric lever and are acted upon by a hydraulic pressure prevailing in hydraulic chambers interacting with the eccentric rods, two lubricating oil bores being introduced into the small end bearing eye at positions so that the piston pin is between the lubricating oil bores and the big end bearing eye and via which a lubricating oil film can be built up between the small end bearing eye and the eccentric, the small end bearing eye having opposite inner and outer circumferential surfaces spaced from one another by a radial wall thickness, all areas of the outer circumferential surface of the small end bearing eye being convexly arcuate and configured so that the radial wall thickness in those regions of the small end bearing eye with the lubricating oil bores is sufficiently larger than adjoining regions of said small end bearing eye to compensate for a weakening caused by the respective lubricating oil bore, while a smaller radial wall thickness in areas of the small end bearing eye adjoining the lubricating oil bore achieves sufficient strength and a weight reduction for the connecting rod. 9. The internal combustion engine of claim 8 , wherein the outer circumferential surface of the small end bearing eye at the locations that have the lubricating oil bores are concentric with the inner circumferential surface. 10. The internal combustion engine of claim 9 , wherein the regions of the outer circumferential surface of the small end bearing eye adjoining the regions of the small end bearing eye that have the lubricating oil bores have larger radii of curvature than the regions of the outer circumferential surface of the small end bearing eye that have the lubricating oil bores. 11. The internal combustion engine of claim 8 , wherein the radial wall thickness in regions of the small end bearing eye adjoining the regions that have the lubricating oil bores is more than half of the radial wall thickness of the regions of the small end bearing eye that have the lubricating oil bores.