Resistance module for increasing runup torque for a rotor of an electric machine comprising a rotor winding

What is claimed is: 1. A resistance module for increasing a runup torque for a rotor of an electric machine with a rotor winding, said resistance module comprising: a first connection point; a second connection point; a plurality of electrically-conductive layers electrically connected to the first connection point and to the second connection point, each of the layers surrounding an axis of the resistance module at least partially in a circumferential direction and having a layer start point and a layer end point, at least one of the layers configured in an undulating shape in the circumferential direction, with undulations projecting radially outwards; a first insulating layer disposed between neighboring ones of the layers, a tie point to which the layer end point of one of the layers is electrically connected to the layer start point of a neighboring one of the layers; and at least one fastening element disposed between two neighboring undulations in the circumferential direction and radially outside of the layers. 2. The resistance module of claim 1 , wherein the layers are disposed in coaxial relationship to the axis and configured in a helical shape. 3. The resistance module of claim 1 , wherein neighboring layers extend from their layer start point to their layer end point in an opposing direction of rotation. 4. The resistance module of claim 1 , wherein at least one of the layers is configured in the form of a flat material or of sheet steel and/or made predominantly of aluminum. 5. The resistance module of claim 1 , further comprising a hub disposed in coaxial relationship to the axis and connected with the layers in a torsion-proof manner, said hub configured for connection with a shaft of the electric machine in a torsion-proof manner. 6. The resistance module of claim 5 , further comprising a second insulating layer disposed between the hub and the layers. 7. The resistance module of claim 1 , wherein the at least one fastening element is connected rigidly to the layers, and further comprising a third insulating layer disposed between the at least one fastening element and the layers. 8. The resistance module of claim 1 , further comprising a fastening ring arranged in coaxial relationship to the axis and disposed in an axial direction adjacent to the layers, said at least one fastening element being connected to the fastening ring in a torsion-proof manner. 9. An electric machine, comprising a resistance module as set forth in claim 1 . 10. An exciter for increasing a runup torque for a rotor of an electric machine with a rotor winding, said exciter comprising: a secondary winding configured for connection to a shaft of the electric machine in a torsion-proof manner; a rectifier connected electrically to the secondary winding; and a resistance module connected electrically to the rectifier, said resistance module comprising a first connection point, a second connection point, a plurality of electrically-conductive layers electrically connected to the first connection point and to the second connection point, each of the layers surrounding an axis of the resistance module at least partially in a circumferential direction and having a layer start point and a layer end point, at least one of the layers configured in an undulating shape in the circumferential direction, with undulations projecting radially outwards, a first insulating layer disposed between neighboring ones of the layers, a tie point to which the layer end point of one of the layers is electrically connected to the layer start point of a neighboring one of the layers, and at least one fastening element disposed between two neighboring undulations in the circumferential direction and radially outside of the layers. 11. The exciter of claim 10 , further comprising a switch configured to bridge the layers of the resistance module. 12. The exciter of claim 10 , wherein the layers are disposed in coaxial relationship to the axis and configured in a helical shape. 13. The exciter of claim 10 , wherein neighboring layers extend from their layer start point to their layer end point in an opposing direction of rotation. 14. The exciter of claim 10 , wherein at least one of the layers is configured in the form of a flat material or of sheet steel and/or made predominantly of aluminum. 15. The exciter of claim 10 , wherein the resistance module includes a hub disposed in coaxial relationship to the axis and connected with the layers in a torsion-proof manner, said hub configured for connection with a shaft of the electric machine in a torsion-proof manner. 16. The exciter of claim 15 , wherein the resistance module includes a second insulating layer disposed between the hub and the layers. 17. The exciter of claim 16 , wherein the at least one fastening element is connected rigidly to the layers, said resistance module including a third insulating layer disposed between the at least one fastening element and the layers. 18. The exciter of claim 10 , wherein the resistance module includes a fastening ring arranged in coaxial relationship to the axis and disposed in an axial direction adjacent to the layers, said at least one fastening element being connected to the fastening ring in a torsion-proof manner. 19. A rotor of an electric machine, comprising: a resistance module comprising a first connection point, a second connection point, a plurality of electrically-conductive layers electrically connected to the first connection point and to the second connection point, each of the layers surrounding an axis of the resistance module at least partially in a circumferential direction and having a layer start point and a layer end point, at least one of the layers configured in an undulating shape in the circumferential direction, with undulations projecting radially outwards, a first insulating layer disposed between neighboring ones of the layers, a tie point to which the layer end point of one of the layers is electrically connected to the layer start point of a neighboring one of the layers, and at least one fastening element disposed between two neighboring undulations in the circumferential direction and radially outside of the layers; and a rotor winding electrically connected to the resistance module. 20. The rotor of claim 19 , further comprising a switch configured to bridge the layers of the resistance module. 21. The rotor of claim 19 , further comprising a secondary winding configured for connection to a shaft of the electric machine in a torsion-proof manner, and a rectifier connected electrically to the secondary winding, said resistance module being connected electrically to the rectifier.