Safety helmet with a resiliently attached shock-absorbing shell and process for manufacturing same

What is claimed is: 1. A safety helmet comprising: an arched helmet shell encompassing a helmet shell interior area; a holding ring with a curved holding ring edge, the holding ring being located in the helmet shell interior area and permanently connected to the arched helmet shell; an arched shock-absorbing shell with a curved shock-absorbing shell edge, the arched shock-absorbing shell being located in the helmet shell interior area, adjoining the arched helmet shell and configured to absorb kinetic energy, wherein the curved shock-absorbing shell edge areally adjoins the curved holding ring edge; and a resilient element projection located in the helmet shell interior area, the resilient element projection comprising an end portion supported at the holding ring, the end portion engaging an outer surface of the holding ring, wherein the resilient element projection touches the curved shock-absorbing shell edge and the resilient element projection is configured to move the arched shock-absorbing shell away from the holding ring and to press the arched shock-absorbing shell against the arched helmet shell. 2. A safety helmet in accordance with claim 1 , wherein: the holding ring comprises a holding ring projection pointing towards the arched shock-absorbing shell; the holding ring projection engages with a corresponding recess of the arched shock-absorbing shell; the one end portion is located at a position outside of the holding ring; the resilient element projection comprises a second end portion touching the curved shock-absorbing shell edge; the resilient element projection being located at a spaced location from the arched helmet shell; and the second end portion is located at a position outside of the arched shock-absorbing shell. 3. A safety helmet in accordance with claim 2 , wherein the holding ring projection is located between the arched helmet shell and the arched shock-absorbing shell. 4. A safety helmet in accordance with claim 1 , wherein: the arched shock-absorbing shell comprises a shock-absorbing shell projection pointing towards the arched helmet shell; the arched helmet shell comprises a stop element pointing towards the arched shock-absorbing shell; and the shock-absorbing shell projection and the stop element together limit a movement of the arched shock-absorbing shell relative to the arched helmet shell in at least one direction. 5. A safety helmet in accordance with claim 1 , wherein: the curved holding ring edge extends in a plane and has at least one adjoining protruding area, protruding from this plane, which at least one adjoining protruding area adjoins the curved shock-absorbing shell edge; and a profile of the at least one adjoining protruding area corresponds to a profile of an adjoining area of the curved shock-absorbing shell edge. 6. A safety helmet in accordance with claim 1 , wherein: the arched shock-absorbing shell has an outwardly arched projection; the arched helmet shell has a groove; and the projection of the arched shock-absorbing shell engages with the groove of the arched helmet shell. 7. A safety helmet in accordance with claim 1 , further comprising a bearing ring, wherein: the bearing ring encompasses the head of a user of the safety helmet and is configured to be in contact with the head of the user of the safety helmet in at least one area; and a distance is formed between the holding ring and the bearing ring. 8. A safety helmet in accordance with claim 7 , wherein: a circumferential dimension of the bearing ring is variable; and a distance is formed between the arched shock-absorbing shell and the bearing ring. 9. A process for manufacturing a safety helmet, the process comprising the steps of: providing an arched helmet shell encompassing a helmet shell interior area; providing a holding ring with a curved holding ring edge; providing an arched shock-absorbing shell with a curved shock-absorbing shell edge, the arched shock-absorbing shell being configured to absorb kinetic energy; providing at least one resilient element projection located in the helmet shell interior area, the resilient element projection comprising an end portion supported at the holding ring, the end portion engaging an outer surface of the holding ring; wherein the resilient element projection touches the curved shock-absorbing shell edge; inserting the shock-absorbing shell into the helmet shell interior area such that the shock-absorbing shell is located in the helmet shell interior area and adjoins the arched helmet shell; subsequent to the step of inserting the shock-absorbing shell, inserting the holding ring into the helmet shell interior area such that the shock-absorbing shell edge areally adjoins the holding ring edge and the resilient element presses the shock-absorbing shell away from the holding ring and against the helmet shell; and permanently connecting the inserted holding ring to the arched helmet shell with the resilient element pressing the shock-absorbing shell against the arched helmet shell. 10. A process according to claim 9 , further comprising providing a computer program, which is executable on a computer and causes the computer during the execution to actuate one or more 3D printers such that an actuated 3D printer produces at least one of the shock-absorbing shell, the holding ring, and the resilient element. 11. A process according to claim 9 , further comprising providing a 3D printer, which is configured to produce at least one of the shock-absorbing shell, the holding ring, and the resilient element. 12. A process according to claim 11 , further comprising: providing at least another 3D printer configured to produce at least one of the shock-absorbing shell, the holding ring and the resilient element; producing at least one of the shock-absorbing shell, the holding ring and the resilient element with the other 3D printer. 13. A process according to claim 12 , wherein the 3D printer and the other 3D printer: are at different locations; or produce different components of the safety helmet; or are at different locations and produce different components of the safety helmet. 14. A safety helmet comprising: an arched helmet shell encompassing a helmet shell interior area; a holding ring with a curved holding ring edge, the holding ring being located in the helmet shell interior area and permanently connected to the arched helmet shell; an arched shock-absorbing shell with a curved shock-absorbing shell edge, the arched shock-absorbing shell being located in the helmet shell interior area, adjoining the arched helmet shell and configured to absorb kinetic energy, wherein the arched shock-absorbing shell edge areally adjoins the curved holding ring edge; and a resilient element located in the helmet shell interior area and supported at an outer surface of the holding ring, wherein the resilient element is in contact with the arched shock-absorbing shell edge and the outer surface of the holding ring, the resilient element being configured to apply a force to the arched shock-absorbing shell such the arched shock-absorbing shell moves away from the holding ring and presses the arched shock-absorbing shell against the arched helmet shell. 15. A safety helmet in accordance with claim 14 , wherein: the holding ring comprises a projection pointing towards the arched shock-absorbing shell; the projection engages with a corresponding recess of the arched shock-absorbing shell; the resilient element being located at a spaced location from the arched helmet shell; and each and every portion of the resilient element