Supply device for providing an HF output voltage, HF surgical instrument comprising a corresponding supply device, and method for the operation of an HF generator unit

The invention claimed is: 1. A supply device for providing a high-frequency RF output voltage for application by means of an electrosurgical instrument, the device comprising: an RF generator unit for generating the RF output voltage based on an electrical load; and a control unit comprising: a measuring unit for determining the electrical load while an RF output current of the RF generator unit is applied to the measuring unit; and a signal unit for outputting a haptically perceivable signal to an extent such that cutting of a tissue can be performed by the electrosurgical instrument and wherein a user of the electrosurgical instrument can feel a mechanical resistance when cutting the tissue, wherein the control unit activates the signal unit as a function of the electrical load determined by the measuring unit. 2. The supply device as in claim 1 , wherein the signal unit outputs a signal to the RF generator unit to decrease at least one of the RF output voltage and the RF output current. 3. The supply device as in claim 1 , wherein the signal unit outputs a signal to the RF generator unit to decrease each of the RF output voltage and the RF output current. 4. The supply device as in claim 1 , wherein: the measuring unit comprises an active power calculator for calculating an active power; the control unit further comprises a resistance element for pre-specifying a desired voltage value for the RF generator unit; and the desired voltage value for the RF generator unit is based on the active power. 5. The supply device as in claim 4 , wherein the resistance element comprises an adjustable resistance. 6. The supply device as in claim 4 , wherein the supply device is configured in a voltage-regulated mode for operating the RF generator unit, and wherein a desired power supply voltage of a power supply device varies in order to maintain the RF output voltage essentially constant at the desired voltage value for the RF generator unit. 7. The supply device as in claim 4 , further comprising: an adjustment device for adjusting the desired voltage value for the RF generator unit; and a regulator unit for regulating the RF generator unit consistent with the desired voltage value for the RF generator unit. 8. The supply device as in claim 4 , wherein the desired voltage value for the RF generator unit is determined based on at least the RF output current. 9. The supply device as in claim 8 , wherein the desired voltage value for the RF generator unit is calculated using a pre-specified voltage value and the RF output current. 10. The supply device as in claim 8 , further comprising a comparator unit for determining the desired voltage value for the RF generator unit. 11. The supply device as in claim 10 , wherein the comparator unit determines the desired voltage value for the RF generator unit in accordance with the formula: U Soll1 =U 0 −R i *I a , where U Soll1 is the desired voltage value for the RF generator unit, U 0 is the pre-specified voltage value, R i is a pre-specified resistance, and I a is the RF output current. 12. The supply device as in claim 7 , wherein the regulator unit comprises a proportional-integral (PI) regulator. 13. An RF surgical apparatus comprising: the supply device as in claim 1 ; and an internal resistance adjustment device for adjusting an internal resistance. 14. The RF surgical apparatus as in claim 13 , wherein the internal resistance adjustment device adjusts the internal resistance based on a supply cable resistance of the electrosurgical instrument. 15. The RF surgical apparatus as in claim 13 , further comprising a cutting instrument connected to the supply device. 16. The RF surgical apparatus as in claim 15 , wherein the cutting instrument is an electric scalpel. 17. A method for operating an RF generator unit for at least one electrosurgical instrument, the method comprising the steps of: regulating an RF output voltage in accordance with a control value by means of a voltage regulator; detecting an electrical load of the RF generator unit; and correcting the control value as a function of the detected electrical load, wherein the correcting comprises activating a haptically perceivable signal to an extent such that cutting of a tissue can be performed by the electrosurgical instrument and wherein a user of the electrosurgical instrument can feel a mechanical resistance when cutting the tissue. 18. A method as in claim 17 , wherein the control value is based on a power of the RF generator unit. 19. A method as in claim 17 , wherein the control value is based on an RF output voltage of the RF generator unit. 20. A method as in claim 17 , wherein correcting the control value comprises decreasing the control value when there is a high detected electrical load. 21. A method as in claim 17 , wherein detecting the electrical load comprises measuring an active current. 22. A method as in claim 17 , wherein regulating the RF output voltage comprises calculating the control value with the formula U Soll1 =U 0 −R i *I a , where U Soll1 is the control value for the RF generator unit, U 0 is a pre-specified voltage value, R i is a pre-specified resistance, and I a is the RF output current. 23. A method for performing an electrosurgical procedure comprising the steps of: setting a pre-specified voltage value to indicate with what power or voltage an electrosurgical instrument is to be operated; operating an RF generator unit in accordance with the method as in claim 17 , where the RF generator unit is operated in a voltage-controlled mode such that the RF output voltage is continuously applied to the tissue in a manner consistent with the control value; measuring an RF output current; and decreasing the control value when the measured RF output current increases in order to signal to a person performing the procedure that the impedance of the tissue is rising. 24. A method as in claim 23 , further comprising increasing the control value when the measured RF output current decreases in order to signal to the person performing the procedure that the impedance of the tissue is decreasing. 25. The method as in claim 23 further comprising guiding the instrument through the tissue using a cutting motion; and operating the RF generator unit such that a force required for the cutting motion varies as a function of the tissue impedance.