A power converter, includes a housing and a busbar arrangement, which is arranged inside the housing, wherein the power converter is designed to guide an alternating current along the busbar arrangement, the power converter also includes at least one planar flux-conducting element made of a magnetically highly permeable material, which is arranged between a wall of the housing and the busbar arrangement.

Provided are a motor drive device that reduces the likelihood of mounting error during manufacture, and a method for manufacturing the same. The motor drive device is provided with: a substrate; a first mounting region for mounting first circuit component; a second mounting region for mounting a second circuit component; a first pair of connection points for connecting a first connecting wire member, constituting a first path for supplying electric current to the first circuit component, onto the substrate such that at least a part of the first connecting wire member overlaps the second mounting region; and a second pair of connection points for connecting second connecting wire member, constituting a second path for supplying electric current to the second circuit component, onto the substrate such that at least a part of the second connecting wire member overlaps the first mounting region.

A cell-contacting system for a battery module having an array of a plurality of battery cells. Cell connectors connect the cell terminals of the battery cells. The signal lines of a printed circuit board connect a signal source of one of the cell connectors to a signal management circuit or a connection interface. A plastics material carrier plate fits onto the battery cell array and has a first receiving region for the printed circuit board and a plurality of second receiving regions for one each of the plurality of cell connectors. The carrier plate has a base plate and frame elements for receiving the printed circuit board and the cell connectors. Snap-action hooks on the frame elements allow the printed circuit board or the cell connectors to be snap-fit into the corresponding receiving regions.

A battery module includes battery cells being arrayed, a cell-monitoring unit configured to monitor each battery cell of the battery module, a battery cell side circuit board electrically connected to the battery cells, and a cell-monitoring unit side circuit board electrically connected to the cell-monitoring unit and the battery cell side circuit board. The battery cell side circuit board and the cell-monitoring unit side circuit board are connected to each other and voltage detection lines on the battery cell side circuit board and a voltage detection lines on the cell-monitoring unit side circuit board are electrically connected. The electric circuits of the voltage detection lines on the battery cell side circuit board are aligned in order of their electric potentials and the electric circuits of the voltage detection lines on the cell-monitoring unit side circuit board are aligned in order of their electric potentials.

A circuit structure includes a first busbar constituted by a cladding material, a second busbar, an insulating member including an insulating portion located between the first busbar and the second busbar, and an electronic component provided on the first busbar and the second busbar so as to straddle the insulating portion. The electronic component has a connection terminal bonded to the first busbar.

An inverter power assembly includes: a mounting frame; a power module mounted on the mounting frame; and a capacitor electrically connected to the power module. The inverter power assembly has the power module mounted on the mounting frame and the capacitor electrically connected to the power module, which leads to a simple and compact structure and a reasonable arrangement for the entire inverter power assembly.

This converter comprises: a housing having heat dissipation fins formed on the top surface thereof; a printed circuit board disposed in the inner space of the housing; and a bus bar, the bottom surface of which is in surface contact with the top surface of the printed circuit board, wherein the heat dissipation fins and the bus bar can be disposed overlapping each other in a vertical direction to enhance heat dissipation efficiency and can be further reduced in weight.

A component is disclosed. In an embodiment a component includes a first region suitable for a feedthrough of at least one bus bar and a second region in which at least one discrete device is arranged, wherein the first region and the second region are separated from one another by a cooling region thermally decoupling the first region from the second region.

A current sensor assembly includes a housing; a plurality of shields which are accommodated inside the housing and open toward the top of the housing; a plurality of bus bars to which three-phase current is applied and which are arranged spaced apart from each other so as to go past the plurality of shields, respectively; and a current sensor unit which includes a printed circuit board and a plurality of current sensors disposed on the printed circuit board to measure the current applied to the bus bars. The shields, the bus bars, and the current sensor unit are configured to be accommodated inside the housing, and the current sensors are spaced apart from the bus bars and disposed in the inner spaces of the shields.

A busbar module includes: a circuit body having a flexible circuit board; busbars; and a holder. The circuit body has: conductor layers and protective layers to form a multiple-layered structure of wiring patterns; a band-shaped main strip to be located to extend in a stacking direction of cells; and a band-shaped branch strip branched from the main strip. The branch strip has: a bent portion extending in the stacking direction and having a bent shape around an axis crossing the stacking direction; and a connection portion disposed closer to an end of the branch strip than the bent portion and connected to the corresponding busbar. The bent portion has a thin-layer portion having a shape formed by removing, from the flexible circuit board, a part of the protective layers corresponding to a part of the conductor layers without being used as the wiring pattern in the branch strip.