Abstract: A Power-over-Ethernet (PoE) device (200) for use in a PoE system is described. The PoE device (200) comprising a first PoE port (210) for connecting the device to an upstream PoE device or a central control unit, a second PoE port (220) for connecting the device to a downstream device or PoE device and a control unit (240) for controlling data (335) and/or power communication (400) between the first (210) and second (220) PoE port. The control unit (240) further comprises a first power input terminal (305) connected to the first PoE port (210) to receive electrical power (320) for powering the control unit (240).

Abstract: The present invention relates to a high voltage generator (100) for supplying an X-ray tube (200), the high voltage generator (100) comprising: a voltage regulator device (100-1), which is configured to provide a DC voltage; a plurality of N generator devices (100-2), which are coupled to the regulator device (100-1) and which comprise a switched-mode power circuit (100-2A) and which are configured to provide a waveform pattern (WP); and a plurality of N transformer devices (100-3), which are coupled to the generator device (100-2) and which are configured to provide a high voltage output pattern (HVOP) by means of the provided waveform pattern (WP) and further configured as a serial connection of the N transformer devices (100-3), whereby all provided high voltages HVOP are added, thereby yielding a higher voltage (THV) in the X-ray tube and wherein each of the plurality of the N generator devices (100-2) is configured to provide the waveform patterns (WP) adjusted to produce a substantially flat-pulse shape

Abstract: The present invention relates to a bobbin assembly (1000-3) comprising: a plurality of winding slots (1000-4), each of which comprises a winding (10) with one turn per layer; and a plurality of isolation slots (1000-5), each of which comprises one single loop of the winding (10), and each of the isolation slots (1000-5) is adjacent to at least one winding slot (1000-4) of the plurality of winding slots (1000-4), and each of the winding slots (1000-4) is adjacent to at least one isolation slot (1000-5) of the plurality of isolation slots (1000-5).

Abstract: The present invention relates to a device for controlling a plurality of cells of a battery, the device comprising: a battery control module, comprising a plurality of cell control units, each assigned to one of the cells, wherein each cell control unit is configured to change a charge balance of the assigned cell and to measure at least one cell parameter of the assigned cell; and a main control module, which is configured to define a preferred range of the state-of-charge of the battery cells for a charging-discharging-cycle, wherein the preferred range is reduced compared to a full range, the main control module further configured to provide a first group of selected cells, on which a charging-discharging-cycle is performed including a fully charged state within the full range, and a second group of non-selected cells, on which the charging-discharging-cycle is performed within the preferred range.

Abstract: The invention relates to a high voltage transformer (50) comprising: a magnetic core (5); a low voltage winding (10); a high voltage winding (20); at least one inner sleeve (30); and a coil bobbin (24) for carrying the high voltage winding (20), wherein the coil bobbin (24) is configured to be arranged inside the at least one inner sleeve (30) and configured to be attached to the at least one inner sleeve (30) at an outer perimeter of the at least one inner sleeve (30); and wherein the coil bobbin (24) comprises at least one field-control electrode (22), which is adapted to shape an electric field generated by the high voltage winding (20).

Abstract: The invention relates to an AC/DC converter circuit (100) and a method for converting N?2 AC supply voltages (U1, U2, U3) into DC voltage. This is achieved by feeding the AC supply voltages to first terminals (a1, a2, a3) of full bridge converters (11, 12, 13), wherein the second terminals (b1, b2, b3) of these rectifiers are coupled to each other. The outputs (d11, d1?, d2, d2?, d3, d3?) of the rectifiers are fed to the DC terminals of intermediate converters (21, 22, 23). The AC terminals (e1, e1?, e2, e2?, e3, e3?) of the intermediate converters are connected to the primary sides of transformers (31, 32, 33), wherein the secondary sides of these transformers are provided to further rectifiers (41, 42, 43). The circuit design allows using MosFETs of limited voltage capability for processing 380 V three-phase AC current, thus achieving a high efficiency.

Abstract: A voltage multiplier 10 comprises a series of multiplier stages 12a, 12b, 12c, 12d. Each multiplier stage, for example 12b, comprises a first input 16b, a second input 14b, a first output 16c and second output 14c. The first and second outputs of a preceding multiplier stage are interconnected with first and second inputs of a subsequent multiplier stage. Furthermore, each multiplier stages, for example 12b, comprises two series connected diode elements D5, D6 having the same current conducting direction. The two series connected diode elements D5, D6 interconnect the first input 16b and the first output 16c. The second output 14c is coupled between the two series connected diode elements D5, D6. Each multiplier stage, for example 12b, comprises a buffer capacitor C6 interconnecting the respective first input 16b and the respective first output 16c.

Abstract: The present invention relates to a bidirectional semiconductor switch (M1, M2) with extremely low control power consumption and a bootstrap circuit which allows reliable start of operation of the switch and the hosting device after unlimited duration of mains interruptions. Intelligent control options are provided by operating from a small energy storage and no extra means are required to recover from a depleted energy storage condition. The absence of audible noise and mechanical wear also enables more frequent recharging cycles and allows smaller and thus cheaper energy storage components.

Abstract: A voltage multiplier 10 comprises a series of multiplier stages 12a, 12b, 12c, 12d. Each multiplier stage, for example 12b, comprises a first input 16b, a second input 14b, a first output 16c and second output 14c. The first and second outputs of a preceding multiplier stage are interconnected with first and second inputs of a subsequent multiplier stage. Furthermore, each multiplier stages, for example 12b, comprises two series connected diode elements D5, D6 having the same current conducting direction. The two series connected diode elements D5, D6 interconnect the first input 16b and the first output 16c. The second output 14c is coupled between the two series connected diode elements D5, D6. Each multiplier stage, for example 12b, comprises a buffer capacitor C6 interconnecting the respective first input 16b and the respective first output 16c.

Abstract: A power supply unit for an X-ray radiation source (10) comprises a high voltage generator (4) for providing a basic current for the operation of an X-ray tube (10), a waveform generator (6) and a pulse transformer (2) for providing superposable voltage peaks and a control unit (8) for generating a counterbalance at an input (12) of the pulse transformer (2) to prevent saturation effects. Providing different reference waveform patterns lead to the prevention of overshooting and ringing.

Abstract: An electrical inverter 18 for transforming an DC current into an AC current comprises at least one half-bridge 54. The half bridge 54 comprises at least two series connected semiconductor switches 58a, 58b, 58c, 58d inter-connecting an input terminal 54, 56 with an output terminal 50 of the inverter 18. A snubber capacitor 62a, 62b is connected in parallel to at least two semiconductor switches 58a, 58b, 58c, 58d of the half bridge 54.

Abstract: An imaging system (100) includes a stationary gantry (102) and a rotating gantry (104). The rotating gantry (104) includes a first component (110, 114, 116) supplied with first power and a second component supplied with second power, wherein the first and second power are different. A contactless power chain (118) includes a first transformer (202, 204, 306) for transferring the first power from the stationary gantry (102) to the rotating gantry (104) and a second transformer (202, 204, 306) for transferring the second power from the stationary gantry (102) to the rotating gantry (104). The first and second transformers (202, 204, 306) are shifted relative to each other along the longitudinal axis (108) by a pre-determined finite non-zero distance (240). In another embodiment, an imaging system (100) includes a stationary gantry (102) and a rotating gantry (104) that rotates about a longitudinal axis (108).

Abstract: The present invention relates to a bidirectional semiconductor switch (M1, M2) with extremely low control power consumption and a bootstrap circuit which allows reliable start of operation of the switch and the hosting device after unlimited duration of mains interruptions. Intelligent control options are provided by operating from a small energy storage and no extra means are required to recover from a depleted energy storage condition. The absence of audible noise and mechanical wear also enables more frequent recharging cycles and allows smaller and thus cheaper energy storage components.

Abstract: A power supply unit for an X-ray radiation source (10) comprises a high voltage generator (4) for providing a basic current for the operation of an X-ray tube (10), a waveform generator (6) and a pulse transformer (2) for providing superposable voltage peaks and a control unit (8) for generating a counterbalance at an input (12) of the pulse transformer (2) to prevent saturation effects. Providing different reference waveform patterns lead to the prevention of overshooting and ringing.

Abstract: The invention relates to a management unit (1) and a method for operating such a unit in a Power-over-Ethernet (PoE) installation. The management unit (1) comprises at least one first port (12a) to which an external device (2) can be connected, and it is adapted to control the power delivered at a first port (12a) in dependence on predetermined switching rules.

Abstract: A Power-over-Ethernet (PoE) device (200) for use in a PoE system is described. The PoE device (200) comprising a first PoE port (210) for connecting the device to an upstream PoE device or a central control unit, a second PoE port (220) for connecting the device to a downstream device or PoE device and a control unit (240) for controlling data (335) and/or power communication (400) between the first (210) and second (220) PoE port. The control unit (240) further comprises a first power input terminal (305) connected to the first PoE port (210) to receive electrical power (320) for powering the control unit (240).

Abstract: A method and a control device control a switching device for providing a resonant circuit with a switching voltage for generating a resonant current in order to provide a required output power at an output of a resonant power converter.

Abstract: The invention relates to a method for controlling the luminous flux of a lighting arrangement (3) for illuminating the interior of a building (5), wherein the lighting arrangement (3) comprises at least one artificial lighting device (17), which artificial lighting device (17) is supplied with electrical power by a power source system (9) comprising a first power source (11) being a photovoltaic device (13) for generating electrical power and an access to at least one second power source (15), the method comprising the steps of: —pre-selecting a luminous flux characteristic curve (47, 49), which specifies a monotonically increasing dependence of the luminous flux of the artificial lighting device (17) on the light intensity outside the building (5); —Determining the light intensity outside the building (5); and Supplying the at least one artificial lighting device (17) with the electrical power required for generating the luminous flux according to said selected luminous flux characteristic curve (47, 49), wh

Abstract: The invention is directed to a voltage rectifier (23) comprising at least two diode arrays (33, 34, 35, 36) each comprising plural diodes (33a, 33b, 33p, 34a, 34b, 35a, 35b, 35p, 36a, 36b, 36c, 36d, 36p) connected in series. The diode arrays are arranged in an enclosure (47). The diode arrays are arranged in a special arrangement for providing an even distribution of a field strength. According to an embodiment and with respect to the figures, the vertical distance between an enclosure (47) and the diode arrays (33, 34, 35, 36) increases when horizontally distancing from the direct current terminals. Further, the invention provides a voltage generator (21) and a voltage rectifier (23) having such a voltage rectifier.

Abstract: A DC/AC power inverter control unit of a resonant-type power converter circuit (400), in particular a DC/DC converter, for supplying an output power for use in a high-voltage generator circuitry of an X-ray radiographic imaging system, a 3D rotational angiography device, or X-ray computed tomography device, comprises an interphase transformer (406) connected in series to at least one series resonant tank circuit (403a and 403a? or 403b and 403b?) at the output of two DC/AC power inverter stages (402a+b) supplying a multi-primary winding high-voltage transformer (404). The interphase transformer (406) removes a difference (?I) in resonant output currents and (I1 and I2) of the DC/AC power inverter stages (402a+b). In addition, a control method is disclosed which assures that the interphase transformer (406) is not saturated. Furthermore, the control method ensures zero current operation and provides for minimized input power losses.