Operating method for an electric energy system of a motor vehicle comprising a fuel cell system, an accumulator and an electric motor

What is claimed is: 1. A method of operating an electric system of a motor vehicle equipped with a fuel cell system, an accumulator, and an electric motor operable as a vehicle drive motor, the fuel cell system, accumulator and electric drive motor being electrically coupled to allow the fuel cell system to supply electric energy to the electric motor and the accumulator, and to allow the accumulator to supply electric energy to the electric motor, the method comprising the acts of: designing the electric system, without an electric voltage converter and without an electric voltage conversion, such that the accumulator is essentially chargeable completely by the fuel cell system alone as well as also by the electric motor alone when operating as a generator; depending on the electric voltage level made available by the fuel cell system and by the accumulator, and on the power required by the electric motor: opening and closing a first switching element as needed, the first switching element being arranged between the fuel cell system and a node point that is electrically coupled to the accumulator and to the electric motor, and opening and closing a second switching element as needed, the second switching element being arranged between the accumulator and the node point, wherein the opening and closing of the first and second switching elements is such that the power requirement of the electric motor is met primarily by the fuel cell system and additionally in an auxiliary manner by the accumulator, and if the electric power made available by the fuel cell system exceeds the power demanded by the electric motor, the excess power of the fuel cell system resulting from a difference between the power made available and the power demanded is fed to the accumulator as long as an admissible charging current of the accumulator is not exceeded and the accumulator still has a defined residual storage capacity, the defined residual storage capacity being at least in an amount of a kinetic energy of the motor vehicle feedable to the accumulator in a current driving state of the vehicle by recuperation via the electric motor operating as the generator. 2. The method according to claim 1 , wherein in cases in which a voltage level provided by the fuel cell system is significantly higher than a voltage level processable by the electric motor and the accumulator, or significantly lower than the voltage level demanded by the electric motor or accumulator, adapting the voltage level of the fuel cell system to the demand by modulating an oxygen content on a cathode side of fuel cells of the fuel cell system, which fuel cell system has at least one hydrogen (air) oxygen fuel cell. 3. The method according to claim 2 , wherein the act of adapting the voltage level of the fuel cell system to lower the voltage level of the fuel cell system as needed is carried out by: changing a rate of exhaust gas returned to the cathode side of the fuel cell, and/or changing an air throughput at the cathode side of the fuel cell. 4. The method according to claim 2 , wherein the act of adapting the voltage level of the fuel cell system to raise the voltage level of the fuel cell system as needed is carried out by: increasing an oxygen content of an airflow flow fed to the cathode side of the fuel cell. 5. The method according to claim 3 , wherein the act of adapting the voltage level of the fuel cell system to raise the voltage level of the fuel cell system as needed is carried out by: increasing an oxygen content of an airflow flow fed to the cathode side of the fuel cell. 6. The method according to claim 4 , wherein the increasing of the oxygen content of the airflow fed to the cathode side of the fuel cell is carried out by: adding oxygen to the airflow, which oxygen was obtained in advance from fed air and stored in a suitable storage material, and/or reducing a nitrogen fraction in the airflow fed to the cathode side of the fuel cell, said reduction being carried out via a molecular sieve. 7. The method according to claim 5 , wherein the increasing of the oxygen content of the airflow fed to the cathode side of the fuel cell is carried out by: adding oxygen to the airflow, which oxygen was obtained in advance from fed air and stored in a suitable storage material, and/or reducing a nitrogen fraction in the airflow fed to the cathode side of the fuel cell, said reduction being carried out via a molecular sieve. 8. The method according to claim 1 , wherein the fuel cell system has a plurality of individual fuel cells, the method further comprising the act of: continuously monitoring the electric voltage of all the individual fuel cells in order to maintain permissible limit values, and preventing an exceeding or falling-below of the permissible limit values by changing a quantity of reaction gas fed to the individual fuel cells. 9. The method according to claim 2 , wherein the fuel cell system has a plurality of individual fuel cells, the method further comprising the act of: continuously monitoring the electric voltage of all the individual fuel cells in order to maintain permissible limit values, and preventing an exceeding or falling-below of the permissible limit values by changing a quantity of reaction gas fed to the individual fuel cells. 10. The method according to claim 3 , wherein the fuel cell system has a plurality of individual fuel cells, the method further comprising the act of: continuously monitoring the electric voltage of all the individual fuel cells in order to maintain permissible limit values, and preventing an exceeding or falling-below of the permissible limit values by changing a quantity of reaction gas fed to the individual fuel cells. 11. The method according to claim 4 , wherein the fuel cell system has a plurality of individual fuel cells, the method further comprising the act of: continuously monitoring the electric voltage of all the individual fuel cells in order to maintain permissible limit values, and preventing an exceeding or falling-below of the permissible limit values by changing a quantity of reaction gas fed to the individual fuel cells. 12. The method according to claim 6 , wherein the fuel cell system has a plurality of individual fuel cells, the method further comprising the act of: continuously monitoring the electric voltage of all the individual fuel cells in order to maintain permissible limit values, and preventing an exceeding or falling-below of the permissible limit values by changing a quantity of reaction gas fed to the individual fuel cells.