A system for compensating a voltage line drop includes a shelving unit comprising at least one receiving port, wherein the at least one receiving port includes a connector. The system also includes a power converter operable to generate a line drop compensated output voltage, and a bypass module physically coupled between the connector and the power converter, wherein the bypass module is operable to selectively switch between providing the line drop compensated output voltage from the power converter to a load and bypassing the power converter to provide an uncompensated output voltage to the load.

A system for compensating a voltage line drop includes a shelving unit comprising at least one receiving port, wherein the at least one receiving port includes a connector. The system also includes a power converter operable to generate a line drop compensated output voltage, and a bypass module physically coupled between the connector and the power converter, wherein the bypass module is operable to selectively switch between providing the line drop compensated output voltage from the power converter to a load and bypassing the power converter to provide an uncompensated output voltage to the load.

Systems, methods, and devices for converting electric power are disclosed. Converter modules convert power in a configurable manner in conjunction with a controller.

An assembly for stacking a plurality of circuit boards of an electronics package is provided. The assembly may comprise a chassis structure, a first plurality of printed circuit board (PCB), and a second plurality of PCBs, where the second plurality of PCBs are configured to be coupled to connectors of the first plurality of PCBs that are accessible via connection access points in the chassis structure. The first plurality of PCBs is positioned on a first side of the chassis structure, and the second plurality of PCBs are positioned on a second side of the chassis structure. Positioning tolerancing of the second plurality of PCBs relative to the first plurality of PCBs is provided by the connectors of the first plurality of PCBs.

A system in accordance with present embodiments includes an amusement park system having one or more hardware components and a controller. The controller includes a memory device having a game layer and a software layer stored thereon. The game layer includes game logic, and the software layer includes a game API communicatively coupled to the game layer, a wrapper API communicatively coupled to the game API, and multiple wrappers communicatively coupled to the wrapper API. The controller further includes a processor configured to execute instructions to cause the processor to receive a signal indicative of a change in the hardware components, and, based on the signal indicative of the change in the hardware components, communicate with the hardware components via a wrapper to receive an input from the hardware components, or drive operation of the hardware components.

An electronics installation system, especially for an aircraft or spacecraft, includes at least one mechanical installation structure having a plurality of installation slots each configured to receive an electronic module and at least one wiring configuration slot configured to receive a wiring configuration module, and a connection matrix comprising a plurality of data connections, wherein at least one data connection is provided between each one of the installation slots and at least one wiring configuration slot.

The present invention relates to a contact device for transmitting electrical energy from a preferably spatially fixed bus bar to a tap-off device which is movable along the bus bar or is likewise spatially fixed. For this purpose, the sliding contact elements are configured in the form of sliding clip elements so that the connecting housing of the contact device is clippable onto the bus bar without using tools.

The present invention relates to a contact device for transmitting electrical energy from a preferably spatially fixed bus bar to a tap-off device which is movable along the bus bar or is likewise spatially fixed. For this purpose, the sliding contact elements are configured in the form of sliding clip elements so that the connecting housing of the contact device is clippable onto the bus bar without using tools.

The present invention relates to a contact device for transmitting electrical energy from a possibly movable, but preferably spatially fixed, bus bar to a tap-off device which may be movable along the bus bar or may be likewise spatially fixed. For this purpose, the sliding contact elements are configured in the form of sliding clip elements so that the connecting housing of the contact device is clippable onto the bus bar without using tools.

A power conversion device includes a cooler, a terminal block and a case. The cooler defines an internal space through which a refrigerant flows. The terminal block covers a conducive part. The case accommodates the cooler and the terminal block therein. The case has an opening on its lateral wall portion for allowing connection between the conductive part of the terminal block inside the case and an external load disposed outside the case. At least a part of the terminal block is located closer to the opening than the cooler in a first direction to which an inner surface and an outer surface of the lateral wall portion of the case defining the opening are opposed, and is located between the cooler and an upper end of the opening in a second direction orthogonal to the first direction.