Method for the attachment of a hollow element such as a hollow rivet or a nut element to a component consisting of a composite material

The invention claimed is: 1. A method for the attachment of a hollow element to a component ( 130 ) consisting of a composite material being one of a plastic part having a fiber reinforcement in a plastic matrix material or a plastic part having a fabric reinforcement in a plastic matrix material, with the hollow element having a flange part ( 102 ) and a shaft part ( 104 ) or a rivet section ( 106 ) extending away from the flange part ( 102 ), wherein the rivet section ( 106 ) can also be formed at a free end of a shaft part ( 104 ), wherein the hollow element has a central passage ( 108 ), passing an auxiliary convergent tip ( 126 ) from either a flange side of the element ( 100 ) remote from the shaft part ( 104 ) through the passage ( 108 ), or introducing the auxiliary convergent tip from a side of the free end of the shaft part into the passage ( 108 ), such that a converging region ( 128 ) of the auxiliary tip ( 126 ) projects from the free end of the shaft part or of the rivet section ( 106 ); pressing the hollow element ( 100 ) with the tip ( 126 ) to a fore against the component ( 130 ) and piercing the component forming a pierced hole and pressing the convergent tip through the component thereby dilating the pierced hole in the component ( 130 ) and displacing the fibers or fabric of the plastic material and engaging a plastic matrix material with a side ( 114 ) of the flange part adjacent to it, the tip ( 126 ) thus pierces a hole ( 132 ) in the component and the material which is displaced by means of the tip builds up at at least one of an underside and an upper side of the component 130 in a form of thickened portions 134 and 136 respectively, removing the auxiliary convergent tip and forming the rivet section into a rivet bead trapping the component between the flange part and the rivet bead. 2. The method in accordance with claim 1 , wherein the free end of the shaft part ( 104 ) is a rivet section ( 106 ), the method comprising a step of reshaping the rivet section by means of a rivet die to a rivet bead ( 150 ), whereby the component ( 130 ) is trapped between the flange part ( 102 ) and the rivet bead ( 150 ). 3. The method in accordance with claim 1 comprising further steps of providing features ( 120 ) providing security against rotation in a region of the flange part and pressing said features into the matrix material and/or pressing the matrix material into the features in order to form a security against rotation between the hollow element ( 100 ) and the component ( 130 ). 4. The method in accordance with claim 1 , wherein the flange part ( 102 ) is provided with an annular planar contact surface ( 114 ) which is equipped with discrete axial projections ( 120 ) which can be pressed into the matrix material of the component ( 130 ). 5. The method in accordance with claim 1 , wherein the flange part ( 102 ) is provided with an annular planar contact surface ( 114 ) and has an axial ring groove ( 116 ) radially within this contact surface, the ring groove being arranged concentric to the shaft part ( 104 ) with features providing security against rotation such as ribs ( 118 ) and/or recesses providing security against rotation being present at a base region of the ring groove, wherein the matrix material of the component ( 130 ) is pressed into the axial ring groove ( 116 ) and is brought into contact with surfaces of the features ( 118 ) providing security against rotation. 6. The method in accordance with claim 1 , wherein the auxiliary tip ( 126 ) is held in the passage ( 108 ) by a press fit or by a magnetic force. 7. The method in accordance with claim 1 , in which a hollow element ( 100 ) with an internal thread ( 112 ) is used, wherein the auxiliary tip ( 126 ) has an external thread ( 162 ) which is screwed into the internal thread ( 112 ). 8. The method in accordance with claim 1 , wherein the auxiliary tip ( 126 ) has a cylindrical region ( 134 ) which is introduced into the passage ( 108 ) of the hollow element ( 100 ) and has a ring shoulder ( 129 ) between a conically converging region ( 128 ) of the tip ( 126 ) and a cylindrical region ( 134 ) with the ring shoulder being brought into engagement with the free end of the shaft part ( 104 ) of the rivet section ( 106 ) prior to the piercing of the component ( 130 ). 9. The method in accordance with claim 1 , wherein the auxiliary tip ( 126 ) is introduced as a preceding hole punch with piercing tip through the passage ( 108 ) of the hollow element ( 100 ) from the side of the flange remote from the rivet section ( 105 ). 10. The method in accordance with claim 1 , wherein the free end of the hollow shaft part ( 104 ) of the element or of the free end of the rivet section ( 106 ) is given a conically converging shape ( 180 ) which is matched to a conical shape of the auxiliary tip ( 126 ) that is used, whereby the component is partly pierced by a conically converging shape of the auxiliary tip ( 126 ) and partly by the conically converging shape ( 180 ) of the free end of the shaft part or of the rivet section. 11. The method in accordance with claim 1 , wherein the auxiliary tip ( 126 ) has diverging spring tongues ( 206 ) behind a conically converging region, with the diverging shape of the spring tongues ending at a diameter which corresponds to an outer diameter of the free end of the shaft part ( 104 ) or to a free end face of a conically converging shape ( 180 ) of the free end of the shaft part ( 104 ) or of the rivet section ( 106 ) and wherein the spring tongues are pressed inwardly after the piercing of the component part in order to be pressed through the central passage ( 142 ) of the riveting die ( 140 ) or to be withdrawn rearwardly out of the passage ( 108 ) of a nut element ( 100 ). 12. The method in accordance with claim 11 , wherein the auxiliary tip ( 126 ) has a cylindrical extension ( 202 ) to a rear which is guided in a hollow inset ( 200 ) which is positioned and/or screwed into the passage ( 108 ) of the hollow element ( 100 ). 13. The method in accordance with claim 1 , wherein a movement of the tip ( 126 ) through the component ( 130 ) in order to form the hole ( 132 ) is a translatory movement. 14. The method in accordance with claim 1 , wherein an axial movement of the hollow element ( 100 ) with the auxiliary tip ( 126 ) and/or of the auxiliary tip ( 126 ) alone is brought about by a tool which is selected from a group comprising a press, a setting head, a robot, tongs and a C-frame with power cylinder, wherein the component is preferably either free standing during piercing or is supported on a die button, for example a piercing die or a riveting die. 15. The method in accordance with claim 1 , wherein the component is heated, at least in the region of the piercing, to a matrix material dependent temperature at which the matrix material of the composite material does not melt but softens or becomes pasty. 16. The method in accordance with claim 15 , wherein the component is heated to a temperature of 260° C. when the material is PA6. 17. The method in accordance with claim 1 , wherein the component ( 130 ) is either held free standing during the hole formation by means of the auxiliary tip ( 126 ) or is supported on a support having an opening for receiving the tip. 18. A method for the attachment of a hollow element to a component ( 130 ) consisting of a composite material being one of a plastic part having a fiber reinforcement in a plastic matrix material or a plastic part having a fabric reinforcement in a plastic matrix material, with the element having a flang