A power interface system is provided. The power interface system can include a power interface device coupleable to a structure, wherein the power interface device can include a receptacle region and a plurality of pin receiving apertures. The power interface system may include an electrical device module sized and shaped to be received in the receptacle region, the electrical device module having a plurality of contact pins, each of the plurality of contact pins sized and shaped to be coupleably received in one of the pin receiving apertures. The electrical device module can be rotatably moveable with respect to the receptacle region between an uncoupled orientation and a coupled orientation, with the electrical device module being secured to the power interface device in the coupled orientation. Related devices and methods are also provided.

A docking station for a medical device is described. In some examples, the docking station includes a frame and a base plate coupled to the frame. At least a portion of the base plate is coupled to a lower portion of the frame. In some examples, an electronic connector of the docking station is configured to couple to the medical device and to provide power to the medical device when the medical device is docked to the docking station. In some examples, a docking mechanism is coupled to an upper portion of the frame and configured to retain the medical device.

A medical mechatronic male interface device couples a surgical assistance system to a mount. The male interface device includes a base including an end face and a functional body extending from the end face, a first mechanical coupling for positive and/or non-positive coupling to a medical mechatronic female interface device, and at least one first electronic interface configured to connect to a second electronic interface of the female interface device. The functional body includes a centering device that centers the surgical assistance system free of play relative to the base. The centering device includes a first functional surface, a second functional surface, and a third functional surface that together at least partially define a three-sided pyramid. The first mechanical coupling includes a first undercut and a second undercut on the functional body that each define a segment engageable from behind.

A card connector, a card holder, and a terminal device, where the card connector includes a plurality of first terminals and one or more second terminals. The first terminals are arranged to form a first card access area that installs a first card, and the first terminals are configured to be electrically coupled to the first card. The one or more second terminals are distributed on a periphery of the first card access area, the first terminals and the one or more second terminals form a second card access area that installs a second card, and the first terminals and the one or more second terminals are configured to be electrically coupled to the second card.

The present disclosure provides an intelligent lighting control system including an electrical connector interface. The lighting control system includes a module housing, a switch control circuit positioned in the module housing and including a processor configured to modulate a flow of electrical energy to a lighting circuit via a dimmer circuit to produce a plurality of lighting scenes. The lighting control system includes a graphical user interface coupled to the module housing and communicably coupled to the switch control circuit. The lighting control system includes a first electrical connector electrically connected to the switch control circuit and at least one of extending from and recessed in a surface of the module housing. The electrical connector includes a plurality of electrical pins. The first electrical connector is configured for a press fit engagement with a second electrical connector of a base module.

An embodiment of a cradle has a cradle body configured to support a printing device. The cradle has first and second printer capture flanges extending from the cradle body proximate a capture end of the cradle body. The cradle has first and second biased latches extending from the cradle body between the capture end and a release end of the cradle body. The cradle has a biased release member movable between a first position and a release position. The cradle has a release linkage supported by the cradle body, the release linkage coupling the biased release member and the first and second biased latches, wherein the release linkage is structured to drive the first and second biased latches from respective locked positions to respective unlocked positions in response to movement of the biased release member from a first position to a release position.

Apparatuses, methods, and computer program products are described herein. An example disclosed printing device includes a printer body; a cradle engagement surface configured to interface with a cradle, the cradle engagement surface defining a first recess and a second recess disposed proximate a first side of a battery compartment; and a bumper attachment extending from the printer body and disposed proximate a front side of the printer body, the bumper attachment defining at least two capture cavities structured to slideably receive reciprocally structured first and second printer capture flanges extending from the cradle.

The present invention is related to a stacking structure having a docking station and using one of a USB Type-C and a direct current (DC) power supply, including a first stack layer, a first connection member and a second stack layer. The first stack layer has a first connection port including at least two electric power conductors. The first connection member is configured on the first stack layer and has a first engagement portion. The second stack layer has a second connection port and a second engagement portion, wherein the second connection port includes at least two electric power conductors, the second connection port of the second stack layer is used to electrically connect thereto the first connection port of the first stack, and the second engagement portion is used to connect thereto the first engagement portion.

An electrical component socket includes a socket body arranged on a circuit board and including a receiving portion configured to receive an electrical component. The socket body includes an arrangement portion in which a row of contact pins to be in contact with leads of an IC package is arranged. At least one of these contact pins and another one of the contact pins adjacent to the at least one of the contact pins have an arrangement pitch that is narrower than a pitch between the terminals of the electrical component, and the other one of the contact pins and still another one of the contact pins adjacent to the other one of the contact pins have an arrangement pitch that is substantially equal to the pitch between the terminals of the electrical component.

The present description discloses a battery pack capable of being detachably attached to an apparatus including an apparatus terminal having a flat plate-like shape by sliding the battery pack in a sliding direction along the apparatus terminal. The battery pack includes a battery terminal capable of engaging with the apparatus terminal so as to be electrically connected therewith. The battery terminal includes a pair of elastic clamping pieces configured to receive the apparatus terminal when the battery pack is attached to the apparatus and to clamp the apparatus terminal from both sides of the apparatus terminal. In the battery pack, the pair of the elastic clamping pieces extends in a direction perpendicular to the sliding direction.