Abstract: The invention relates to a method for setting a dead time between the opening of a first switching element (31) of a half bridge (2) and the closing of a second switching element (32) of the half bridge (2), comprising the steps: reducing the dead time of a switching cycle relative to the dead time of a preceding switching cycle, and determining a temperature of at least one of the switching elements (31, 32); wherein the steps of reducing the dead time and of determining the temperature are repeated for subsequent switching cycles until a critical dead time is reached, in the case of which a termination condition, which depends on the determined temperature, is fulfilled; and wherein the dead time is set using the critical dead time.

Abstract: The invention relates to an electrical conductor (1) having an electrical contact element (2) that is associated in particular with an interface (21) and has at least one electrical contact point (17), wherein the conductor (1) has a bundle (3) of electrical individual cores (4). Provision is made for the individual cores (4) to be carbon-nanostructure-based fibers (CNB), in particular carbon nanotubes (CNT), and for a segment (9) of each individual core (4) to have at least the one contact point (17) of the contact element (2). The invention further relates to an electrical interface (21).

Abstract: The invention relates to an electrical conductor (1) having an electrical contact element (2) that is associated in particular with an interface (21) and has at least one electrical contact point (17), wherein the conductor (1) has a bundle (3) of electrical individual cores (4). Provision is made for the individual cores (4) to be carbon-nanostructure-based fibers (CNB), in particular carbon nanotubes (CNT), and for a segment (9) of each individual core (4) to have at least the one contact point (17) of the contact element (2). The invention further relates to an electrical interface (21).

Abstract: The invention relates to a circuit assembly, to a system and to a method for switching a high-voltage battery (201) and to a vehicle having such a circuit assembly and such a system. The circuit assembly comprises a transistor for conducting a current from the battery (201) to a load and comprises a diode (202) for conducting a return current into the battery (201). The circuit assembly is configured to provide a pre-charging current by means of the pulsed switching of the transistor (203).

Abstract: The invention relates to a detection device (100) for detecting an arc (104a-i; 909) occurring between a first current-carrying element (103; 903a) and at least one conductive element (103b, 108; 903b, 907), comprising at least one measuring device (101; 901, 902), which is designed to measure a current (I) flowing through the first current-carrying element (103a; 903a), and an analysis device (102) which is designed to determine a frequency spectrum of the measured current (I) and to detect the arc (104a-i; 909) occurring between the first current-carrying element (103a; 903a) and the at least one conductive element (103b, 108; 903b, 907) on the basis of a high-frequency range of the determined frequency spectrum.

Abstract: The invention relates to a method for setting a dead time between the opening of a first switching element (31) of a half bridge (2) and the closing of a second switching element (32) of the half bridge (2), comprising the steps: reducing the dead time of a switching cycle relative to the dead time of a preceding switching cycle, and determining a temperature of at least one of the switching elements (31, 32); wherein the steps of reducing the dead time and of determining the temperature are repeated for subsequent switching cycles until a critical dead time is reached, in the case of which a termination condition, which depends on the determined temperature, is fulfilled; and wherein the dead time is set using the critical dead time.

Abstract: The invention relates to a detection device (100) for detecting an arc (104a-i; 909) occurring between a first current-carrying element (103; 903a) and at least one conductive element (103b, 108; 903b, 907), comprising at least one measuring device (101; 901, 902), which is designed to measure a current (I) flowing through the first current-carrying element (103a; 903a), and an analysis device (102) which is designed to determine a frequency spectrum of the measured current (I) and to detect the arc (104a-i; 909) occurring between the first current-carrying element (103a; 903a) and the at least one conductive element (103b, 108; 903b, 907) on the basis of a high-frequency range of the determined frequency spectrum.

Abstract: The present invention relates to a charging circuit for an electrical energy accumulator and a method for operating a charging circuit. Common components are used for charging and discharging the electrical energy accumulator. According to the invention, a charging circuit comprises step-up and step-down functionalities and combines them with rectifier and/or inverter functionalities. In this way, a circuit arrangement is created which allows a flexible circuit design with a small number of components.

Abstract: The present invention relates to a charging circuit for an electrical energy accumulator and a method for operating a charging circuit. Common components are used for charging and discharging the electrical energy accumulator. According to the invention, a charging circuit comprises step-up and step-down functionalities and combines them with rectifier and/or inverter functionalities. In this way, a circuit arrangement is created which allows a flexible circuit design with a small number of components.

Abstract: The invention relates to a converter circuit (50) for transferring electrical energy, in particular for application in a motor vehicle wiring system (38, 42), which converter circuit comprises an electromagnetic transfer unit (60) having three electromagnetic transfer members (62, 64, 66) that can be electromagnetically coupled to each other in order to transfer electromagnetic energy, wherein the first electromagnetic transfer member (62) is connected to a first bi-directional converter circuit that comprises a first voltage connection pole pair (80) for connecting an AC voltage source and/or sink (54), wherein the second electromagnetic transfer member (64) is connected to a rectifier converter circuit that is connected on the outlet side to an electrical energy store (88), and wherein the third electromagnetic transfer member (66) is connected to a second bi-directional converter circuit that comprises a second voltage pole pair (96) for connecting a DC voltage source and/or sink (98), and a control unit (

Abstract: In a circuit configuration for generating a stabilized power supply voltage, an in-phase regulator LR and a switched-mode regulator SR are connected in parallel to one another and are between terminal A1 where the input voltage is supplied and terminal A2 where stabilized output voltage UA is obtained. The regulators are adjusted so that in the normal case, the output voltage of switched-mode regulator SR is slightly higher than that of in-phase regulator LR.

Abstract: A liquid crystal cell for a liquid crystal display screen having a pair of plates joined together by a frame to form a chamber for a liquid crystal layer which is hermetically sealed from the exterior of the cell and has a closable access passage characterized by the access passage receiving a ductile metal plug of a metal which is selected from a group consisting of indium, tin, lead and aluminum and a sealing coating covering the plug and a portion of the exterior of the cell surrounding the passage. In one embodiment, the passage is a groove extending inward from an edge of one of the plates and has a depth which decreases as the distance from the edge increases so that it merges with the interior surface of the plate inward of the frame which may be formed with the recess facing the groove.