Abstract: Electrosurgical generator provides a HF alternating voltage to electrosurgical instruments, including a first/second HF generation unit supplying a first/second HF alternating voltage having a first/second frequency to a first/second output which are configured for connection of a first/second electrosurgical instrument. Upon activation a first current flows to the first electrosurgical instrument and simultaneously a second current flows to the second electrosurgical instrument. That portion of these currents being actually delivered from the electrosurgical instruments to the tissue to be worked on are working currents. They are important for safe operation but cannot be measured directly. An observer unit is configured for indirect determination of said working currents based on measured values of the total currents. The so determined working currents are used as input signals for an inverter controller, achieving improved control of the electrosurgical generator.

Abstract: A method for controlling an ultrasonic transducer of an electrosurgical instrument, the ultrasonic transducer is driven by alternating electrical overall current signal, having a signal frequency, driving the overall current signal results in alternating electrical instrument voltage signal of transducer, depending on mechanical oscillation of transducer, the instrument voltage signal having transducer phase shift with respect to main current component of overall current signal depending on mechanical oscillations of transducer, ultrasonic transducer is having fluctuating mechanical resonance frequency, amplifier is controlled to provide electrical overall current signal and adjust signal frequency towards resonance frequency depending on transducer phase shift, and for determining transducer phase shift, calculating signal coefficients for main current component and instrument voltage signal, signal coefficients being representative for phase relationship of main current component or instrument voltage signa

Abstract: Modular generator system comprising at least two generator types which are composed of a plurality of generator components and differ with regard to their equipment and/or functions. The generator components comprise a power supply and an inverter for generating an output energy for an electrosurgical instrument. The generator types are each of modular design with a plurality of modules: (i) at least one uniform base module having a communication unit, and (ii) at least one individual module which may differ depending on generator type. Individual modules can be a module for the power supply, a module for the inverter, a module for the output connection. Different generator types differ with regard to their individual module equipment. By virtue of such a two-tier module concept, namely uniform base module and differing individual modules, a maximum number of variants can be achieved with a minimum number of different modules.

Abstract: An electrosurgical generator for outputting a HF voltage to an electrosurgical instrument includes a power supply unit, an inverter unit generating the HF voltage, a base module and a plurality of function modules for performing various functions of the electrosurgical generator, at least one thereof being configured for controlling a user interface. Each of the function modules features a galvanically separated local operating power supply includes a transformer being fed by the base module having an operating power distribution unit. A central AC generator is provided generating AC voltage supplied to the operating power distribution unit. The transformers are decentralized at each of the function modules. This combination of centralized AC generation and decentralized transformers increases efficiency, reduces space demand and facilitates effective shielding, thereby providing a more economical, compact and EMR improved electrosurgical generator.

Abstract: An Electrosurgical generator including an inverter unit generating a high-frequency alternating voltage to be supplied to at least two output sockets for connection of electrosurgical instruments. The inverter unit is a multilevel inverter. It includes a plurality of co-operating inverter cells which are connected in a cascaded manner in a first state and being split into at least two groups (I, II) in a second state. The inverter unit is selectively switchable between said first and second state. Each group is assigned one of the output sockets and feeds its HF voltage thereto. This enables simultaneous controlling of the distinct groups and their HF output. Thereby, unwanted interference patterns can be avoided. Uncontrolled low-frequency beat can be largely suppressed, allowing improved control of thermal energy and cutting power. Quality of the work performed can be increased which is beneficial for the patient.

Abstract: An electrosurgical generator including an inverter unit generating HF energy and a high-voltage connection supplying the HF energy to an output socket for an electrosurgical instrument. The high-voltage connection includes a base module with a distribution unit and at least one connection port. The distribution unit comprises a HF distribution line and data communication wiring, both being supplied to the at least one connection port for which a sub module is provided connecting to the HF and the data signals and supplying the output socket. Thereby electrical connections and data communications are established at once. Consequently, inserting a different sub module allows for simplified alteration of type and variant of the generator. A newly developed version of the sub module may just be inserted into the connection port without any need of alteration of the base module. Modernization and updating is facilitated.

Abstract: A generator for the delivery of high frequency alternating current to a medical instrument has a power supply unit, a high frequency generator primary unit (HF generator primary unit), an application unit, and a control unit. The HF generator primary unit is connected to the power supply unit and the application unit and designed to supply the application unit with high frequency alternating current during operation. The application unit is electrically connected in a switchable manner to connections for connecting a medical instrument via at least one relay. The control unit is galvanically separated from the application unit and designed to control the at least one relay and the application unit as applicable. The control unit is connected to the application unit via an intermediate control circuit, wherein the intermediate control circuit is galvanically separated both from the control unit and from the application unit.

Abstract: An electrosurgical generator which outputs high-frequency AC voltage for an electrosurgical instrument includes a leakage current detecting device for the connected electrosurgical instrument. The leakage current detecting device is embodied as a voltage measuring device, the inputs of which are connected in each case via a capacitive coupling to an active and a neutral line of the output line and which has a bipolar voltage divider having a predetermined fixed ratio. An asymmetry detector connected via a capacitive coupling compares upper and lower voltage at the voltage divider, and outputs a fault signal for leakage current in the case of deviation of the ratio of upper to lower voltage from the predetermined fixed ratio.

Abstract: An electrosurgical generator for an electrosurgical instrument includes DC voltage supply and high-voltage inverter that generates high-frequency AC voltage having variable voltage and frequency. Inverter is multilevel inverter controlled by reference signal and having at least two groups of series-connected inverter cells, wherein each group is supplied with different DC voltage and wherein the voltages output by the two groups are summed to be output at output. Group supplied with higher voltage enables fast and large voltage changes with its inverter cells, while inverter cells of other group supplied with lower voltage allow fine setting with high change speed. Dynamic range is improved both from temporal viewpoint and in terms of increased voltage span. The number of HVC cells to be switched may furthermore be varied by way of modulator, wherein further number of LVC cells are switched in an opposing manner for compensation purposes. Switching losses may be reduced.

Abstract: An electrosurgical generator for an electrosurgical instrument includes a DC voltage supply and a high-voltage inverter that generates a high-frequency AC voltage having a variable voltage and frequency that is output at an output for the connection of the electrosurgical instrument. The inverter is configured as a multilevel inverter and includes a plurality of inverter cells connected in a cascaded manner that are driven by a control device. Thanks to the cascading, switching losses incurred in the power semiconductors are reduced, both in terms of value (through the divided and thus lower voltage) and in terms of frequency (through the reduced switching frequency).

Abstract: An electrosurgical generator having connectors for an electrosurgical instrument including a high-voltage generator electrically connected to the connectors and produces a high-frequency alternating current in its activated state and output said high-frequency alternating current via the connectors. The electrosurgical generator has an effective power determination unit including a phase shift determination unit that supplies an output signal representing a phase shift between the current and the voltage of an alternating current output during operation. The phase shift determination unit produces a pulsed DC voltage signal, in which the pulse width reflects a time difference between the zero crossings of the current and the voltage—and consequently the phase shift—and to process the pulsed DC voltage signal by way of a low-pass filter to form a low-pass filter output signal, the magnitude of which depends on the pulse width of the pulses of the pulsed DC voltage signal.

Abstract: An electrosurgical system for treating tissue, including a first and second electrode; a high-frequency high-voltage supply unit which can be electrically connected to first and second electrode and is designed to supply a specified treatment alternating voltage to electrodes; and a measuring unit which can be electrically connected to first and second electrode and has a measurement voltage supply module that is designed to provide a measurement alternating voltage of at least one first and second frequency, wherein the measuring unit is additionally designed to receive an electric response signal for first and second frequency via first and second electrode and determine at least one property of a tissue located between first and second electrode therefrom. The electrosurgical system relates further to an electrosurgical generator for treating tissue, to a method of operating an electrosurgical system, to using electrosurgical system and to applying the method of operating an electrosurgical system.

Abstract: An electrosurgical system for treating tissue, including a first and second electrode; a high-frequency high-voltage supply unit which can be electrically connected to first and second electrode and is designed to supply a specified treatment alternating voltage to electrodes; and a measuring unit which can be electrically connected to first and second electrode and has a measurement voltage supply module that is designed to provide a measurement alternating voltage of at least one first and second frequency, wherein the measuring unit is additionally designed to receive an electric response signal for first and second frequency via first and second electrode and determine at least one property of a tissue located between first and second electrode therefrom. The electrosurgical system relates further to an electrosurgical generator for treating tissue, to a method of operating an electrosurgical system, to using electrosurgical system and to applying the method of operating an electrosurgical system.

Abstract: An electrosurgical generator having connectors for an electrosurgical instrument including a high-voltage generator electrically connected to the connectors and produces a high-frequency alternating current in its activated state and output said high-frequency alternating current via the connectors. The electrosurgical generator has an effective power determination unit including a phase shift determination unit that supplies an output signal representing a phase shift between the current and the voltage of an alternating current output during operation. The phase shift determination unit produces a pulsed DC voltage signal, in which the pulse width reflects a time difference between the zero crossings of the current and the voltage—and consequently the phase shift—and to process the pulsed DC voltage signal by way of a low-pass filter to form a low-pass filter output signal, the magnitude of which depends on the pulse width of the pulses of the pulsed DC voltage signal.

Abstract: A generator for the delivery of high frequency alternating current to a medical instrument has a power supply unit, a high frequency generator primary unit (HF generator primary unit), an application unit, and a control unit. The HF generator primary unit is connected to the power supply unit and the application unit and designed to supply the application unit with high frequency alternating current during operation. The application unit is electrically connected in a switchable manner to connections for connecting a medical instrument via at least one relay. The control unit is galvanically separated from the application unit and designed to control the at least one relay and the application unit as applicable. The control unit is connected to the application unit via an intermediate control circuit, wherein the intermediate control circuit is galvanically separated both from the control unit and from the application unit.