Camshaft with an axially displaceable cam pack

The invention claimed is: 1. A camshaft, comprising: a carrier shaft configured to be mounted for rotation along a shaft axis; at least one cam pack configured to be axially displaced on said carrier shaft, said at least one cam pack including at least two cams and at least one adjusting member configured to axially adjust said at least one cam pack; said cams and said at least one adjusting member connected to one another in an axially adjacent configuration as a composite structure; and a rolling element guide with rolling elements configured to mount said composite structure for axially displacement in a direct configuration on said carrier shaft; said at least two cams forming at least one single-part multiple cam element disposed axially adjacent said at least one adjusting member; and said multiple cam element having at least one axially-directed guide groove formed therein in which at least one of said rolling elements is guided for permitting axial displacement and preventing circumferential rotation of said cam pack relative to said carrier shaft. 2. The camshaft according to claim 1 , wherein said carrier shaft has at least one guide groove formed therein in which said at least one rolling element is guided, said at least one cam pack being guided axially by said at least one rolling element and said guide grooves and secured non-rotatably against said carrier shaft. 3. The camshaft according to claim 1 , which further comprises an integrally cast body interconnecting at least said cams or said multiple cam element and said at least one adjusting member, said integrally cast body formed of an aluminum, magnesium or plastic material. 4. The camshaft according to claim 3 , wherein said material is an injection-molded or die-cast material. 5. The camshaft according to claim 3 , wherein said at least one adjusting member has at least two parts including a first part formed as a control contour element and a second part formed by said integrally cast body. 6. The camshaft according to claim 5 , which further comprises a first multiple cam element disposed on a first side of said at least one adjusting member and a second multiple cam element disposed on an opposite, second side of said at least one adjusting member, said multiple cam elements including jointing sections pointing towards one another, said jointing sections being cast with said at least one adjusting member by said integrally cast body. 7. The camshaft according to claim 6 , wherein said jointing sections are cast with said control contour element of said at least one adjusting member. 8. The camshaft according to claim 6 , which further comprises form-locking shoulders disposed on said jointing sections and configured to form a form-locking connection between said at least one adjusting member and said multiple cam elements with said integrally cast body in direction of said shaft axis. 9. The camshaft according to claim 1 , wherein said at least one cam pack includes at least one bearing element. 10. The camshaft according to claim 9 , wherein said at least one bearing element is configured to form a zero-lift cam. 11. A cam pack, comprising: at least two cams; at least one adjusting member configured to axially adjust the cam pack on a carrier shaft; said cams and said at least one adjusting member connected to one another in an axially adjacent configuration as a composite structure; and a rolling element guide with rolling elements configured to mount said composite structure directly on the carrier shaft; said at least two cams forming at least one single-part multiple cam element disposed axially adjacent said at least one adjusting member; and said multiple cam element having at least one axially-directed guide groove formed therein in which at least one of said rolling elements is guided for permitting axial displacement and preventing circumferential rotation of said cam pack relative to said carrier shaft. 12. A method for producing a camshaft, the method comprising the following steps: providing a carrier shaft configured to be mounted for rotation along a shaft axis; providing at least one cam pack including at least two cams and at least one adjusting member configured to axially adjust the at least one cam pack, said at least two cams forming at least one single-part multiple cam element disposed axially adjacent said at least one adjusting member, and said multiple cam element having at least one axially-directed guide groove formed therein; placing the at least one cam pack axially displaceably on the carrier shaft; mutually joining the cams, the at least one adjusting member and a cam adjacent the at least one adjusting member in an axially adjacent configuration as a composite structure; and directly mounting the composite structure on the carrier shaft using a rolling element guide with rolling elements; and guiding at least one of the rolling elements in the at least one guide groove for permitting axial displacement and preventing circumferential rotation of the cam pack relative to the carrier shaft.