Plug-in connection system, in particular for fluidic lines, fittings or assemblies

The invention claimed is: 1. A plug-in connection system for fluid lines, fittings, or assemblies, comprising a first coupling part, a second coupling part, and a holding element, the second coupling part being plugged into a receiving opening of the first coupling part along a central axis defined by the first coupling part, the holding element engaging one of the first and second coupling parts and being configured to latch with a counter-holding element formed on the other of the first and second coupling parts, wherein the holding element has a spreading surface which, by sliding relative to a counter spreading surface of the counter-holding element, causes a spreading movement of the holding element transversely with respect to the central axis along a spreading path during plugging in of the second coupling part with the first coupling part along an installation path, the spreading surface having a spreading contour facing the counter spreading surface and adapted to a counter contour of the counter spreading surface, the counter contour and the spreading contour engaging one another during insertion of the second coupling part into the first coupling part during an installation phase, such that the spreading path of the holding element changes in a non-linear manner depending on its position along the installation path, wherein in the installation phase includes a main installation phase between an initial installation phase and final installation phase, the main installation phase having a length traversed by the second coupling part along the installation path that is greater than another length traversed by the second coupling part along the installation path during at least one of the initial and final installation phases, and wherein the spreading contour of the spreading surface is configured to create an installation force increasing up to a maximum installation force in the initial installation phase that is generally maintained in the main installation phase and greater than an installation force in the final installation phase. 2. The plug-in connection system according to claim 1 , wherein the spreading contour of the spreading surface is adapted to the counter contour in such a way that in an initial installation phase along the installation path, the spreading path is over-proportionally modified relative to a linear installation path. 3. The plug-in connection system according to claim 1 , wherein the spreading contour of the spreading surface engages the counter contour in such a way that in a final installation phase along the installation path of the spreading path is sub-proportionally modified relative to a linear installation path. 4. The plug-in connection system according to claim 1 , wherein the spreading contour of the spreading surface engages the counter contour in such a way that in a main installation phase between an initial and final installation phase along the installation path, one of an over-proportional, proportional, or sub-proportional modification of the spreading path occurs relative to a linear installation path. 5. The plug-in connection system according to claim 1 , wherein the spreading contour of the spreading surface engages the counter contour in such a way that in a main installation phase between an initial and final installation phase along the installation path, an installation force (F M ) deviates from an average value of the installation force in the main installation phase by no more than 20 percent. 6. The plug-in connection system according to claim 1 , wherein at least one of the spreading contour of the spreading surface and the counter contour at least partially has a cylindrical or conical configuration cross-sectional straight boundary of its outside surface. 7. The plug-in connection system according to claim 1 , wherein at least one of the spreading contour of the spreading surface and the counter contour is at least partially configured in the shape of one of a calotte, a ball, an ellipsoid, and a rotation paraboloid in a cross-sectional convex boundary of its outside surface. 8. The plug-in connection system according to claim 1 , wherein one of the spreading contour of the spreading surface and the counter contour at least partially has a cross-sectional concave boundary of its outside surface in a configuration in the shape of a segment of a rotation hyperboloid. 9. The plug-in connection system according to claim 1 , wherein at least one of the spreading contour of the spreading surface and the counter contour includes several sections each of which has a different configuration. 10. The plug-in connection system according to claim 1 , wherein the spreading contour of the spreading surface engages the counter contour in such a way that the spreading contour and the counter contour linearly contact one another in one of an initial installation phase, a final installation phase and a main installation phase between the initial and final installation phases. 11. The plug-in connection system according to claim 1 , wherein the second coupling part is a plug part that can be plugged in a sealing manner into the receiving opening of the first coupling part along the axis (X-X) with a shaft, wherein at least one groove is circumferentially configured in one of the first and second coupling parts for sealing, a circumferential seal of an elastomer material being arranged in the groove. 12. The plug-in connection system according to claim 11 , wherein the circumferential seal is provided with a sliding material. 13. The plug-in connection system according to claim 1 , further comprising a locking device including two external, radial holding bars, on the first and second coupling parts, the holding bars being axially adjacent in a plug-in direction when the first and second coupling parts are fully engaged, the locking device further including at least one holding section part provided with the holding element and engaging the holding bars. 14. The plug-in connection system according to claim 13 , wherein the holding part axially and radially engages the holding bars of the first and second coupling parts in a form-fitting manner with at least one holding section having a C-shaped axial sectional view, wherein the holding part is radially latched to the second coupling part, the holding part being radially elastically movable in a region of the holding section. 15. The plug-in connection system according to claim 13 , wherein at least one of the holding part provided with holding elements and the counter holding element is ring-shaped, at least one recess being provided in the circumferential direction in a region of one of the holding element and the counter holding element. 16. The plug-in connection system according to claim 1 , wherein at least one of the holding element and the counter holding element is ring-shaped and a variation in at least the shape of one of the spreading contour and the counter contour is provided in a circumferential direction. 17. The plug-in connection system according to claim 1 , wherein the spreading contour engages the counter contour in such a way that in a main installation phase between an initial and final installation phase along the installation path, an installation force (F M ) deviates from an average value of the installation force in the main installation phase by no more than 15 percent. 18. The plug-in connection system according to claim 1 , wherein the spreading contour of the spreading surface engages the counter contour in such a way that in a main installation phase b