Switchgear for controlling the energy supply of an electric motor connected thereto

The invention claimed is: 1. A switchgear, comprising: a control unit; a supply connection; and a first current path including a first electromechanical switch and, connected in series to the first switch, a parallel connection of a second electromechanical switch with a semiconductor switch, wherein the control unit is configured to output a switching signal for the first switch, the second switch and the semiconductor switch, wherein, in the presence of a switching signal, the first and second switches are held in the closed switching state, and wherein the control unit is configured to draw the energy for the switching signals through the supply connection; an energy accumulator, including at least one capacitor; and a measuring device, wherein the control unit configured to monitor the energy supplied through the supply connection via the measuring device, and wherein, if energy supplied through the supply connection reaches a critical range, the control unit is configured to controls the output of the switching signals via the energy of the energy accumulator such that: in a first step, the semiconductor switch is switched to be electrically conducting and then the second switch is opened, and in a second step following the first step, the semiconductor switch is then switched to be electrically non-conducting, and thereafter the first switch is opened. 2. The switchgear of claim 1 , wherein the energy accumulator is chargeable through the supply connection. 3. The switchgear of claim 2 , wherein the energy accumulator is designed to ensure the output of the switching signals required for the first and second steps. 4. A system for the reliable operation of an electric motor, comprising: the switchgear of claim 2 ; a power supply source; and a further switchgear, wherein the further switchgear is inserted into the supply line of the power supply source for the supply connection of the switchgear such that an actuation of the further switchgear interrupts an energy supplied through the power supply source to the switchgear. 5. The switchgear of claim 1 , wherein the energy accumulator is designed to ensure the output of the switching signals required for the first and second steps. 6. The switchgear of claim 1 , wherein the switchgear comprises a second current path including a first electromechanical switch and, connected in series to the first switch, a parallel connection of a second electromechanical switch with a semiconductor switch, wherein the control unit is configured to output a switching signal for the first switch, the second switch and the semiconductor switch of the second current path, wherein, in the presence of a switching signal, the first and second switches of the second current path are held in the closed switching state, and wherein the control unit is designed such that, if energy supplied through the supply connection reaches the critical range, the control unit is configured to control the output of the switching signals via the energy of the energy accumulator such that: in a first step, the semiconductor switch of the second current path is switched to be electrically conducting and then the second switch of the second current path is opened, in a second step following the first step, the semiconductor switch of the second current path is switched to be electrically non-conducting and then the first switch of the second current path is opened. 7. A system for the reliable operation of an electric motor, comprising: the switchgear of claim 6 ; a power supply source; and a further switchgear, wherein the further switchgear is inserted into the supply line of the power supply source for the supply connection of the switchgear such that an actuation of the further switchgear interrupts an energy supplied through the power supply source to the switchgear. 8. The switchgear of claim 1 , wherein the control unit is designed such that, in the second step, at current zero of the energy supplied therethrough, the control unit is configured to switch the semiconductor switch to the electrically non-conducting state. 9. The switchgear of claim 1 , wherein the supply connection is only used for an internal energy supply to the switchgear. 10. A system for the reliable operation of an electric motor, comprising: the switchgear 1 ; a power supply source; and a further switchgear, wherein the further switchgear is inserted into the supply line of the power supply source for the supply connection of the switchgear such that an actuation of the further switchgear interrupts an energy supplied through the power supply source to the switchgear. 11. A method for a switchgear including a control unit, a supply connection and a first current path, wherein the first current path includes a first electromechanical switch and, connected in series to the first switch, a parallel connection of a second electromechanical switch with a semiconductor switch, wherein the control unit is configured to output a switching signal for the first switch, the second switch and the semiconductor switch, wherein, in the presence of a switching signal, the first and second switches are held in the closed switching state, wherein the control unit is configured to draw energy for the switching signals through the supply connection the switchgear including an energy accumulator, which includes at least one capacitor, and a measuring device, the method comprising: monitoring, via the control unit, the energy supplied through the supply connection; and controlling via the control unit, if the energy supplied through the supply connection reaches a critical range, the output of the switching signals via the energy of the energy accumulator such that: in a first step, the semiconductor switch is switched to be electrically conducting and then the second switch is opened, and in a second step following the first step, the semiconductor switch is switched to be electrically non-conducting and then the first switch is opened. 12. The method for the switchgear of claim 11 , wherein, in the second step, at current zero of the energy supplied therethrough, the control unit switches the semiconductor switch to the electrically non-conducting state.