A battery distribution unit includes a housing having a bottom mounted to a battery case of a battery module and having a component cavity with a contactor therein. The contactor has fixed contacts having terminating ends extending from a bottom end of a contactor housing. The BDU includes terminals at the bottom end of the contactor coupled to the terminating ends and a heat exchanger cap at the bottom end of the contactor. The heat exchanger cap is provided in the component cavity in thermal communication with the fixed contacts and in thermal communication with the battery case of the battery module to dissipate heat from the fixed contacts into the battery case of the battery module.

An electromagnetic relay includes a base, at least one fixed conductive sheet assembly, at least one movable conductive sheet assembly, at least one arc blow component, an electromagnet and an outer cap. The fixed conductive sheet assembly includes a fixed connecting plate and a fixed contact, and the movable conductive sheet assembly includes a movable connecting plate and a movable contact. The base is made of a thermal conductive polymer, and the fixed connecting plate has a first heat conduction part installed in the base and a second heat conduction part connected to the first heat conduction part and extended to an outer side of the base. The electromagnetic relay further includes at least two thermal conduction components installed in the base and symmetrically configured on both opposite sides of the fixed and movable contacts respectively for dissipating the heat generated by the electromagnetic relay.

A vehicle power module assembly including an array of frames each defining a passthrough and step is provided. The frames may be stacked such that the passthroughs are in at least partial registration with one another and the steps align to define an inlet manifold having first and second chambers extending a length of the array. The chambers may be partially open to one another such that the steps influence a momentum of coolant traveling from the first to the second chamber. A pair of endplates may be disposed on either end of the array and configured to retain the frames therebetween. Each of the frames may further define a pair of channels and may be arranged with one another to define a power stage cavity therebetween. A power stage may be disposed within the power stage cavity.

Modular circuit protection devices and configurable panelboard systems include arc-free operation, thermal management features providing safe operation in hazardous environments at lower cost and without requiring conventional explosion-proof enclosures and without entailing series connected separately provided packages such as circuit breaker devices and starter motor contactors and controls.

A guard member is for an electrical switching apparatus of an electrical system. The electrical system includes at least one electrical conductor. The electrical switching apparatus is structured to move from a CLOSED position to an OPEN position in response to a trip condition. The electrical switching apparatus has a terminal end coupled to the electrical conductor. The guard member includes a body having a receiving portion structured to receive the electrical conductor, and a coupling portion extending from the receiving portion and being structured to be coupled to the terminal end. The coupling portion has a number of thru holes in order to dissipate heat generated by the electrical switching apparatus moving from the CLOSED position to the OPEN position.

A switching apparatus provides switching modules, each of which can switch a voltage from an independent power source. Additionally, the switching apparatus provides a single output for independent sources, with the single output providing a power source for a load (e.g., server). In order to dissipate thermal energy, the switching apparatus includes a heatsink that is directly coupled to the switching modules. As a result of the connection between the heatsink and the switching modules, the switching apparatus can reduce the size of the heatsink as well the number of heatsinks. In this manner, the size, footprint, and amount of material of the switching apparatus is reduced, thus reducing the cost of the switching apparatus as well as increasing the ability to provide additional switching apparatuses in a volume, such as a cabinet.

A switching apparatus provides switching modules, each of which can switch a voltage from an independent power source. Additionally, the switching apparatus provides a single output for independent sources, with the single output providing a power source for a load (e.g., server). In order to dissipate thermal energy, the switching apparatus includes a heatsink that is directly coupled to the switching modules. As a result of the connection between the heatsink and the switching modules, the switching apparatus can reduce the size of the heatsink as well the number of heatsinks. In this manner, the size, footprint, and amount of material of the switching apparatus is reduced, thus reducing the cost of the switching apparatus as well as increasing the ability to provide additional switching apparatuses in a volume, such as a cabinet.

A system for switching gases appearing after a short-circuit switching procedure in electrical service devices, particularly in low-voltage power switches, includes a switching gas cooling assembly and particle capture arrangement. Downstream of the flow path of switching gases issuing from at least one switching chamber outlet window, the switching gas cooling assembly is arranged in a blow-out chamber. In the space behind the at least one switching chamber outlet window and prior to entry of the switching gases into the switching gas cooling assembly, there is arranged a flow element around which the switching gases can flow and which has a cross section which corresponds to or is greater than the cross section of the switching chamber outlet window. The flow elements act as the particle capture arrangement and thus as a protection device for the switching gas cooling arrangement.

A system for switching gases appearing after a short-circuit switching procedure in electrical service devices, particularly in low-voltage power switches, includes a switching gas cooling assembly and particle capture arrangement. Downstream of the flow path of switching gases issuing from at least one switching chamber outlet window, the switching gas cooling assembly is arranged in a blow-out chamber. In the space behind the at least one switching chamber outlet window and prior to entry of the switching gases into the switching gas cooling assembly, there is arranged a flow element around which the switching gases can flow and which has a cross section which corresponds to or is greater than the cross section of the switching chamber outlet window. The flow elements act as the particle capture arrangement and thus as a protection device for the switching gas cooling arrangement.

A barrier includes a cover and an attachment apparatus and is usable with an electrical interruption device. The attachment apparatus includes a number of attachment structures that are situated on the cover and that are each structured to be engaged with at least one of the housing of the electrical interruption device and a number of terminal assemblies of the electrical interruption device. The cover is configured to overlie at least a portion of the electrical interruption device and to resist the entry of a probe of known dimensions into electrical contact with components that are electrified even when the electrical interruption device is in an OFF condition.