Abstract: A resonant converter includes an inverter for generating an AC voltage which is fed to a resonant arrangement with a capacitor and a transformer. The circuit provides two types of secondary units, each having a secondary winding of the transformer and at least one rectifier element. Secondary units of the first and second type are then distinguished by opposite orientation. At least two output voltages are delivered on the output, a first output voltage of which being supplied as a direct output of a first-type secondary unit and a second output voltage as a “stack output” of a first-type secondary unit and a second-type secondary unit. The two output voltages can be regulated separately and independently of each other with a regulating device by suitably choosing frequency and duty cycle of a pulse width modulated voltage generated by the inverter driven by the regulating device.

Abstract: A resonant converter and a control method for a resonant converter are proposed. The resonant converter comprises a resonant circuit with a transformer, which circuit is supplied with power by an AC inverter with a switched AC voltage, preferably a pulse-width modulated voltage. The circuit comprises a plurality of secondary units each consisting of a secondary winding of the transformer and at least one rectifier element (diode). The secondary units are subdivided into secondary units of the first and second type, secondary units of the first type and secondary units of the second type having opposite orientations. Secondary units of opposite types preferably have either with the same wiring a different winding orientation or with opposite wiring the same winding orientation.

Abstract: The invention relates to a resonant converter (1) which has multiple outputs (7a, 7b) and contains a transformer (4) with a primary winding (5) and at least two secondary windings (6a, 6b) having different winding directions. In this way it is possible to design as cost-effectively as possible a resonant converter with multiple outputs, two of which can be controlled separately from each other.

Abstract: The invention relates to a circuit arrangement with a regulating circuit which is particularly used for regulating a resonant converter having a plurality of outputs.

Abstract: A power supply circuit and a switched-mode power supply with a power supply input circuit are proposed. Known power supply circuits comprise a rectifier supplied with an AC voltage and a first smoothing capacitor. To provide a circuit which is suitable for operation over a wide voltage range, it is proposed that at least a second capacitor be provided which is connected by a switching element to the load terminals so that, when the voltage at the load terminals drops below a voltage threshold, the second capacitor is connected to the load terminals. Further embodiments comprise an apparatus for charging the second capacitor, which is preferably equipped with an apparatus for limiting the voltage at the second capacitor to a charging threshold. By suitable selection of the charging threshold, a capacitor may be used as the second capacitor which, despite a high capacitance value, exhibits a small structural size and low component costs due to the relatively low dielectric strength.

Abstract: The invention relates to a resonant converter (1) which has multiple outputs (7a, 7b) and contains a transformer (4) with a primary winding (5) and at least two secondary windings (6a, 6b) having different winding directions. In this way it is possible to design as cost-effectively as possible a resonant converter with multiple outputs, two of which can be controlled separately from each other.

Abstract: A DC—DC converter includes an inverter and a primary-side circuit with a transformer whose secondary-side voltage is rectified by at least one rectifier for generating an output DC voltage. To avoid an asymmetrical load, which is in particular exhibited by a different load of the rectifier elements (power semiconductors), an electrical magnitude of the DC—DC converter is measured. This magnitude may be, for example, a primary-side current, a primary-side voltage at a capacitance, or a secondary-side, rectified voltage. A parameter for the symmetry deviation is calcuted from the measurement of the magnitude. A symmetry regulation arrangement utilizes the drive of the inverter, for example, the duty cycle of the pulse-width modulated voltage produced by the inverter to minimize the parameter for the symmetry deviation. This achieves an even distribution of the power over the secondary rectifier elements.

Abstract: The invention relates to arrangements for the power supply of integrated circuits. Various solutions are proposed with a view to guaranteeing a power supply satisfying all the technical requirements with regard to ever greater permissible load jumps, greater permissible current change rates and ever tighter tolerances regarding the constancy of the supply voltage in question.

Abstract: The invention relates to a device with a magnetic position sensor comprising a field sensor (5) and analysis electronics (7) for linear displacements of a rod-shaped component (3), in particular the shaft of an actuator, with an element (M) generating a magnetic field (4) and a position sensor measuring the magnetic field strength angle of this field, the field angle signal determined by this sensor being used for displacement path determination. The element generating a magnetic field (4) is an axially magnetized magnet casing (M) which surrounds the rod-shaped component (3) of the actuator itself, is fixedly connected thereto and can rotate therewith about its displacement axis (z).

Abstract: A resonant converter, a regulation method for a resonant converter and a switched-mode power supply with a resonant converter are proposed. A converter comprises an inverter for generating an AC voltage which is fed to a resonant arrangement with a capacitor and a transformer. The circuit provides two types of secondary units, each comprising a secondary winding of the transformer and at least one rectifier element. Secondary units of the first and second type are then distinguished by opposite orientation, for example, opposite direction of winding or oppositely oriented wiring. At least two output voltages are delivered on the output, a first output voltage of which being supplied as a direct output of a first-type secondary unit and a second output voltage as a “stack output” of a first-type secondary unit and a second-type secondary unit, preferably as a series combination of these secondary units.

Abstract: A DC-DC converter, a regulation method for a DC-DC converter and a switched-mode power supply are proposed. The DC-DC converter comprises an inverter and a primary-side circuit with a transformer whose secondary-side voltage is rectified by at least one rectifier for generating an output DC voltage. To avoid an asymmetrical load, which is in particular exhibited by a different load of the rectifier elements (power semiconductors), an electrical magnitude of the DC-DC converter is measured. This magnitude may be, for example, a primary-side current, a primary-side voltage at a capacitance, or a secondary-side, rectified voltage. From the measurement of the magnitude is calculated a parameter for the symmetry deviation for which different symmetry measuring methods are proposed. A symmetry regulation arrangement utilizes the drive of the inverter, for example, the duty cycle of the pulse width modulated voltage produced by the inverter to minimize the parameter for the symmetry deviation.

Abstract: A power supply circuit and a switched-mode power supply with a power supply input circuit are proposed. Known power supply circuits comprise a rectifier supplied with an AC voltage and a first smoothing capacitor. To provide a circuit which is suitable for operation over a wide voltage range, it is proposed that at least a second capacitor be provided which is connected by a switching element to the load terminals so that, when the voltage at the load terminals drops below a voltage threshold, the second capacitor is connected to the load terminals. Further embodiments comprise an apparatus for charging the second capacitor, which is preferably equipped with an apparatus for limiting the voltage at the second capacitor to a charging threshold. By suitable selection of the charging threshold, a capacitor may be used as the second capacitor which, despite a high capacitance value, exhibits a small structural size and low component costs due to the relatively low dielectric strength.

Abstract: A resonant converter and a control method for a resonant converter are proposed. The resonant converter comprises a resonant circuit with a transformer, which circuit is supplied with power by an AC inverter with a switched AC voltage, preferably a pulse-width modulated voltage. The circuit comprises a plurality of secondary units each consisting of a secondary winding of the transformer and at least one rectifier element (diode). The secondary units are subdivided into secondary units of the first and second type, secondary units of the first type and secondary units of the second type having opposite orientations. Secondary units of opposite types preferably have either with the same wiring a different winding orientation or with opposite wiring the same winding orientation.

Abstract: The invention relates to a resonant converter (1) which has multiple outputs (7a, 7b) and contains a transformer (4) with a primary winding (5) and at least two secondary windings (6a, 6b) having different winding directions. In this way it is possible to design as cost-effectively as possible a resonant converter with multiple outputs, two of which can be controlled separately from each other.

Abstract: The invention describes a system for electrical transmission in the field of garments and a corresponding transmitter for this. Electrical circuits in garments are coupled, preferably inductively in a wireless manner with electrical devices and/or electrical circuits in other garments, wherein electrical energy is transmitted via the coupling. Energy transmission in both directions is preferably possible, wherein a distributed system results with sources and devices that can be coupled with each other. The efficiency of the inductive energy transmission is increased by regulation of the frequency, preferably using resonance. In addition, means for information transmission are proposed.

Abstract: The invention relates to a circuit for converting AC voltage in DC voltage for one or two consumers (Rm, Ra), in which a first part of the current is led via a large induction coil (L50) and a first rectifier (Gm) and a second part of the current via a second rectifier (Ga) before the large induction coil in the input side. As a result of the division of the supplied current the induction coil (L50) can be dimensioned accordingly smaller for smoothing the output voltage and, despite this, the circuit can at the same time satisfy relevant standard specifications.

Abstract: The invention relates to a device with a magnetic position sensor comprising a field sensor (5) and analysis electronics (7) for linear displacements of a rod-shaped component (3), in particular the shaft of an actuator, with an element (M) generating a magnetic field (4) and a position sensor measuring the magnetic field strength angle of this field, the field angle signal determined by this sensor being used for displacement path determination. The element generating a magnetic field (4) is an axially magnetized magnet casing (M) which surrounds the rod-shaped component (3) of the actuator itself, is fixedly connected thereto and can rotate therewith about its displacement axis (z).

Abstract: The invention relates to an electric drive device with a DC motor (2) comprising a control circuit with an electronic commutator (3). The invention is characterized in that a derivation of a control signal (V_i_ref) is obtained from an induced motor voltage (E_sample) detected by a measuring device and from a reference value (V_i_av) which serves to regulate the speed of the DC motor (2), and in that the derived control signal (V_i_ref) serves to achieve a substantially constant torque of the DC motor (2) through adjustment of the motor currents (ia, ib, ic).

Abstract: The present invention relates to a control element having a rotary knob (4), having a magnetic circuit and having at least one coil (1). The rotary knob (4) is supported so as to be rotatable with respect to at least a part of the magnetic circuit, the gap (5) present between the rotary knob (4) and the magnetic circuit is filled with a magnetorheologic fluid, and the coil (1) is arranged to exert a variable braking action on the rotary knob (4).

Abstract: An electrical driving device has three permanent-magnet-excited rotors 3 whose shafts 3S extend through intersections S between a circle 4 and 120.degree. spaced-apart radii 5 which diverge from the centre M of the circle. Each of the cylindrical rotors 3 is associated with three stator poles 7.1, 7.2, 7.3, which are spaced from the cylinder circumference by air gaps 6. Three of these stator poles 7.1 which are situated within the circle 4 are connected by means of yoke irons J.sub.1. The stator poles 7.2 and 7.3 situated outside the circle 4 are connected in pairs via yoke bridges J.sub.2. These yoke bridges J.sub.2 are, in their turn, connected to yoke irons J.sub.3, which carry excitation coils 10. At their ends which are remote from the yoke bridges J.sub.2 all the yoke irons J.sub.3 are magnetically connected via a return yoke J.sub.4. The yoke iron J.sub.1, the stator poles 7.1, 7.2 and 7.3, the Yoke bridges J.sub.2 interconnecting them, the yoke iron J.sub.3 and the return yoke J.sub.