Tool clamping system

The invention claimed is: 1. A tool-clamping system comprising: two metallic shaft portions, wherein the first shaft portion has a locking pin at an end and the second shaft portion has a locking sleeve at an end, wherein, in order to establish a releasable drive connection, the first shaft portion can be introduced coaxially, by way of its locking pin, into the locking sleeve of the second shaft portion and the two shaft portions can be pivoted in relation to one another, in a locking pivoting movement, about a common geometrical longitudinal axis into a locking pivot position, wherein, over the course of the locking pivoting movement, at least one latching formation arranged on the circumference of the locking pin, snap-fits over at least one corresponding mating latching formation of the locking sleeve, the locking pin and/or locking sleeve being elastically deformed in the process, wherein the tool clamping system is devoid of additional clamping components. 2. The tool-clamping system as claimed in claim 1 , wherein the latching formation and/or the mating latching formation are/is configured in the form of a radial formation. 3. The tool-clamping system as claimed in claim 1 , wherein, in the locking pivot position, a radial flow of forces which stems from the elastic deformation prevails between the locking pin and the locking sleeve. 4. The tool-clamping system as claimed in claim 1 , wherein, over the course of the locking pivoting movement, the two shaft portions form a pivoting end stop when the locking pivot position is reached, and therefore, in the locking pivot position between the locking pin and the locking sleeve, a form fit which acts in at least two pivoting directions prevails between the two shaft portions. 5. The tool-clamping system as claimed in claim 4 , wherein, over the course of the locking pivoting movement, at least one stop formation arranged on the circumference of the locking pin, comes into blocking engagement with at least one corresponding mating stop formation of the locking sleeve and forms the pivoting end stop. 6. The tool-clamping system of claim 5 , wherein the at least one stop formation is one of at least three stop formations distributed over the circumference of the locking pin, and wherein the at least one corresponding mating stop formation is one of at least three corresponding mating stop formations of the locking sleeve. 7. The tool-clamping system as claimed in claim 1 , further comprising: an unlocking pivot position in respect of the pivoting of the two shaft portions in relation to one another, it being possible, in said unlocking pivot position, for the first shaft portion to be introduced coaxially, by way of its locking pin, into the locking sleeve of the second shaft portion, and an unlocking pivoting region in respect of the pivoting of the two shaft portions in relation to one another, it being possible, within said unlocking pivoting region, for the first shaft portion to be introduced coaxially, by way of its locking pin, into the locking sleeve of the second shaft portion. 8. The tool-clamping system as claimed in claim 7 , wherein at least one shaft portion has an introduction slope which, when the locking pin is introduced into the locking sleeve, assists alignment of the two shaft portions in relation to one another into the unlocking pivot position. 9. The tool-clamping system as claimed in claim 7 , wherein, in the unlocking pivot position and/or in the unlocking pivoting region, an amount of radial play is provided between the locking pin and the locking sleeve. 10. The tool-clamping system as claimed in claim 1 , wherein, as seen in a cross section transverse to the common geometrical longitudinal axis, the latching formation and/or the mating latching formation form/forms a contour with a radial elevation. 11. The tool-clamping system as claimed in claim 10 , wherein contour regions on either side of the radial elevation are arranged differently in the radial direction such that at the beginning of the locking pivoting movement, in an unlocking pivot position, an amount of radial play is present between the locking pin and the locking sleeve and wherein in the locking pivot position, a radial flow of forces prevails between the locking pin and the locking sleeve. 12. The tool-clamping system as claimed in claim 1 , wherein, in respect of the common geometrical longitudinal axis, the locking pin and/or the locking sleeve are/is of rotationally symmetrical configuration at least in part, and/or wherein, as seen in a cross section transverse to the common geometrical longitudinal axis of the locking pin and/or of the locking sleeve, a contour is constant at least over an axial portion. 13. The tool-clamping system as claimed in claim 1 , wherein, as seen in a cross section transverse to the common geometrical longitudinal axis, a contour of the locking pin has a polygonal basic shape with an odd number of corner regions which each form a latching formation, wherein, as seen in a cross section transverse to the common geometrical longitudinal axis, the locking pin has a triangular basic shape of which the corner regions form the latching formations. 14. The tool-clamping system as claimed in claim 1 , wherein, when the locking pin is introduced axially into the locking sleeve, the two shaft portions form an axial end stop when an axial end-introduction position is reached, wherein, for forming the axial end stop, an annular shoulder, which is aligned with the common geometrical longitudinal axis, follows the locking pin. 15. The tool-clamping system as claimed in claim 1 , wherein, during the locking pivoting movement, the two shaft portions form an additional form fit with one another and, in the locking pivot position, this additional form fit blocks axial withdrawal of the first shaft portion from the second shaft portion counter to the introduction direction. 16. The tool-clamping system as claimed in claim 1 , wherein one shaft portion is a shank of a rotating tool and the other shaft portion is a tool side of a clamping chuck. 17. The tool-clamping system as claimed in claim 1 , wherein one shaft portion is the spindle side of a clamping chuck and the other shaft portion is the drive spindle of a machine-tool unit. 18. A clamping chuck for a rotating tool, wherein the clamping chuck has a spindle side for connection to a drive spindle of a machine-tool unit and a tool side for connection to the tool, wherein the spindle side or the tool side forms the shaft portion of the tool-clamping system as claimed in claim 1 . 19. A machine-tool unit comprising: a drive spindle and a tool drive assigned to the drive spindle, further comprising a clamping chuck as claimed in claim 18 . 20. The machine-tool unit as claimed in claim 19 , further comprising a vibration generator, the vibration generator, for vibration drilling, introducing vibrations in particular in the axial direction into the drive spindle, and wherein the vibrations run via the clamping chuck. 21. The machine-tool unit as claimed in claim 20 , further comprising a tool-changeover device, said tool-changeover device accommodating a plurality of clamping chucks fitted with tools, wherein, for tool changeover, the tool-changeover device introduces the locking pin into the locking sleeve. 22. The machine-tool unit as claimed in claim 20 , wherein, for tool changeover, the tool drive executes the locking pivoting movement, wherein, during the locking pivoting movement,