Method for operating a device for wireless transfer of energy in the direction of an electrical consumer by means of inductive coupling and device

The invention claimed is: 1. A method for operating a device ( 100 ) for wireless transfer of energy in the direction of an electrical consumer ( 200 ) by means of inductive coupling, the method comprising: providing the device ( 100 ) comprising: a rectifier ( 108 ) for generating a DC voltage (U_S) from a grid voltage (U_N), an inverter ( 102 ) fed from the DC voltage (U_S), which is designed to generate a pulse-width-modulated actuation signal (A_S), a power coil ( 101 ) actuated by means of the pulse-width-modulated actuation signal (A_S), by means of which a magnetic alternating field can be generated to transfer the energy, and a communication unit ( 111 ), which is designed to exchange data bidirectionally with the electrical consumer ( 200 ), and sequentially carrying out a power transfer (LTX), a data exchange (DAT), a measurement of setup parameters (MAP), and a measurement of a resonance frequency (MRF), wherein: during the power transfer (LTX), an electrical actual power emitted by the inverter ( 102 ) is regulated to a predetermined electrical setpoint value, during the data exchange (DAT), data are exchanged between the device ( 100 ) and the electrical consumer ( 200 ) by means of the communication unit ( 111 ), during the measurement of the setup parameters (MAP), objects possibly arranged over the power coil ( 101 ), in particular foreign objects, are detected, during the measurement of the resonance frequency (MRF), a resonance frequency of a resonant circuit ( 103 ) having the power coil ( 101 ) is ascertained, the measurement of the resonance frequency (MRF) is executed immediately before or immediately after the measurement of the setup parameters (MAP) or is executed immediately before or immediately after the data exchange (DAT), and based on the ascertained resonance frequency, an operating frequency is ascertained using which the power coil ( 101 ) is subsequently actuated during the power transfer (LTX). 2. The method according to claim 1 , wherein at least one of the data exchange (DAT) or the measurement of the setup parameters (MAP) is/are carried out in time ranges in which the grid voltage (U_N) has a zero crossing. 3. The method according to claim 1 , wherein the measurement of the resonance frequency (MRF) is carried out in time ranges which end 0.5 ms to 2 ms before zero crossing of the grid voltage (U_N) or is carried out in time ranges which begin 0.5 ms to 2 ms after zero crossing of the grid voltage (U_N). 4. The method according to claim 1 , wherein during the measurement of the resonance frequency (MFR), the inverter ( 102 ) is actuated in a pulse-width-modulated way to switch over an actuation voltage upon a detection of a zero crossing of a current (i_s) in the power coil ( 101 ). 5. The method according to claim 4 , wherein if a predetermined peak amperage of the current (i_s) flowing in the power coil ( 101 ) is exceeded, the measurement of the resonance frequency (MRF) is ended. 6. The method according to claim 1 , wherein the operating frequency is set between 0.5 kHz and 3 kHz greater than the resonance frequency. 7. The method according to claim 1 , wherein the electrical consumer ( 200 ) transfers operating frequency-relevant items of information to the device ( 100 ), wherein the operating frequency is set as a function of the resonance frequency and the operating frequency-relevant items of information. 8. A device ( 100 ) for wireless transfer of energy in the direction of an electrical consumer ( 200 ) by means of inductive coupling, the device ( 100 ) comprising: a rectifier ( 108 ) for generating a DC voltage (U_S) from a grid voltage (U_N), an inverter ( 102 ) fed from the DC voltage (U_S), which is designed to generate a pulse-width-modulated actuation signal (A_S), a power coil ( 101 ) actuated by means of the pulse-width-modulated actuation signal (A_S), by means of which a magnetic alternating field can be generated to transfer the energy, and a communication unit ( 111 ), which is designed to exchange data bidirectionally with the electrical consumer ( 200 ), wherein the device ( 100 ) is configured to carry out the method of claim 1 .