Safety brake device for an elevator installation

We claim: 1. A safety brake device for a load receiving component of an elevator installation, the safety brake device comprising: brake equipment, the brake equipment being configured to work with a guide rail for the load receiving component, the brake equipment comprising a cam disc rotatable about a cam disc axis; and an electrically controlled activating mechanism, the activating mechanism being configured to activate the safety brake device by rotating the cam disc through an activation rotational angle such that the cam disc contacts the guide rail, the activating mechanism comprising a pivotably mounted activating lever and an activating spring, the activating spring directly causing a pivot movement of the activating lever prior to contact of the cam disc with the guide rail, the activating lever being fixed in an initial position in a first operating state of the safety brake device and the activating lever being pivotally driven by the activating spring from the initial position to an end position when the activating mechanism is released in a second operating state of the safety brake device, the activating lever being coupled with the cam disc such that the pivot movement of the activating lever from the initial position toward the end position rotates the cam disc through the activation rotational angle. 2. The safety brake device according to claim 1 , the electrically controlled activating mechanism further comprising an electromagnet, the activating lever being fixable in the initial position by activating the electromagnet, the activating lever being releasable by deactivating the electromagnet for moving the activating lever toward the end position. 3. The safety brake device according to claim 2 , the activating lever being configured to rotate the cam disc when the electromagnet is deactivated, where contact between the cam disc and the guide rail further rotates the cam disc. 4. The safety brake device according to claim 1 , the cam disc comprising: a periphery with a flat surface; and a peripheral section adjoining the flat surface, the peripheral section having a radius increasing with rotational angle. 5. The safety brake device according to claim 4 , the cam disc further comprising a cylindrical projection, the cylindrical projection eccentrically arranged with respect to the axis of rotation of the cam disc, the cylindrical projection comprising a convex outer surface receivable by a concave inner surface of a first brake element. 6. The safety brake device according to claim 5 , further comprising a second brake element, the second brake element including a concave inner surface that cooperates with a convex peripheral outer surface of the cylindrical projection, the second brake element including a cut-out through which the periphery of the cam disc protrudes. 7. The safety brake device according to claim 6 , the second brake element comprising a straight, tangential peripheral section of the peripheral section of the cam disc. 8. The safety brake device according to claim 1 , the safety brake device being displaceable in the load receiving component or in a support frame of the load receiving component. 9. The safety brake device according to claim 8 , further comprising a lever abutment, the lever abutment being configured to move the activating lever into a resetting position when the load receiving component is raised for resetting the safety brake device. 10. The safety brake device according to claim 1 , further comprising a switch activatable by the pivot movement of the activating lever or by rotation of the cam disc. 11. The safety brake device according to claim 1 , the activating lever being a first activating lever, the first activating lever being connected by a shaft to a second activating lever, the second activating lever being part of another safety brake device. 12. The safety brake device according to claim 1 being arranged on the load receiving component. 13. The safety brake device according to claim 1 , wherein the activating spring is a torsion spring. 14. A safety brake device method, comprising: retaining an activating lever of a safety brake device in an initial position using an activated electromagnet; directly pivoting the activating lever from the initial position toward an end position using an activating spring and by deactivating the electromagnet; rotating a rotatably mounted cam disc using the pivoting activating lever; moving a periphery of the cam disc into contact with a guide rail, the guide rail moving relative to the safety brake device; and further rotating the cam disc using the guide rail, wherein a peripheral section of the cam disc having an increasing radius rolls on the guide rail, the cam disc and a brake element of brake equipment being pressed against the guide rail and braking a load receiving component. 15. The method according to claim 14 , further comprising resetting the safety brake device, the resetting comprising, moving the load receiving component relative to the brake equipment, the brake equipment being fixedly seated on the guide rail, the moving being limited by an upper abutment and a lower abutment, as a result of the moving the load receiving component and using a lever abutment, pivoting the activating lever against the activating spring into a resetting position, and activating the electromagnet. 16. The method according to claim 15 , further comprising: pressing the lower abutment against the brake equipment; and releasing the cam disc from against the guide rail. 17. The method according to claim 14 , wherein the activating spring is a torsion spring. 18. A safety brake device for a load receiving component of an elevator installation, the safety brake device comprising: brake equipment for connecting the load receiving component with a guide rail by friction couple, the brake equipment comprising a cam disc rotatable about a cam disc axis; and an electrically controlled activating mechanism for activating the safety brake device by rotating the cam disc through an activation rotational angle such that the cam disc contacts the guide rail, the activating mechanism comprising a pivotably mounted activating lever and an activating spring, the activating spring directly causing a pivot movement of the activating lever prior to contact of the cam disc with the guide rail, the activating lever being fixable in an initial position and being pivotally driven by the activating spring, the activating lever being movable from the initial position toward an end position when the activating mechanism is released, the activating lever being coupled with the cam disc such that the pivot movement of the activating lever from the initial position toward the end position rotates the cam disc through the activation rotational angle. 19. The safety brake device according to claim 18 , the electrically controlled activating mechanism further comprising an electromagnet, the activating lever being fixable in the initial position by activating the electromagnet, the activating lever being releasable by deactivating the electromagnet for moving the activating lever toward the end position. 20. The safety brake device according to claim 19 , the activating lever being configured to rotate the cam disc when the electromagnet is deactivated, where contact between the cam disc and the guide rail further rotates the cam disc. 21. The safety brake device according to claim 18 , the cam disc comprising a periphery wi