A battery module includes: a battery cell stack including a plurality of battery cells; a first connection member coupled to anode terminals of the plurality of battery cells; and a second connection member coupled to cathode terminals of the plurality of battery cells. The first connection member includes a first common node to which a first module terminal is coupled. The second connection member includes a second common node to which a second module terminal is coupled. The first common node is located between a center of the battery cell stack and a first battery cell, among first and second battery cells located at outermost sides of the battery cell stack. The second common node is located between the second battery cell and the center of the battery cell stack.

A battery module includes: a battery cell stack including a plurality of battery cells; a first connection member coupled to anode terminals of the plurality of battery cells; and a second connection member coupled to cathode terminals of the plurality of battery cells. The first connection member includes a first common node to which a first module terminal is coupled. The second connection member includes a second common node to which a second module terminal is coupled. The first common node is located between a center of the battery cell stack and a first battery cell, among first and second battery cells located at outermost sides of the battery cell stack. The second common node is located between the second battery cell and the center of the battery cell stack.

An apparatus for storing one or more battery modules (100) comprising a containment tray (300, 500, 700, 1000) defined by opposing front and back faces (314, 316, 714, 716, 1014, 1016), opposing side faces (318, 718, 1018), and opposing top and bottom surfaces (310, 312, 522, 532, 710, 712 1010, 1011, 1012) oriented perpendicular to the front, back, and side faces, wherein the containment tray has a receiving area (302, 518, 702, 1002) formed in the top surface for receiving one or more battery modules, the receiving area comprising a receiving surface (320, 520, 720, 1020) oriented parallel to and located between the opposing top and bottom surfaces for supporting the one or more battery modules.

A battery module for a system for the storage of electrical energy for an electric drive vehicle. The battery module has: a group of chemical batteries arranged parallel to and beside one another; at least two connection plates which rest against opposite ends of the group of chemical batteries so as to electrically connect the poles of the chemical batteries to one another; two support bodies coupled to opposite ends of the group of chemical batteries so as to provide the chemical batteries with a stable mechanical support; two lids, which are coupled to the support bodies so as to create respective collecting chambers having at least one draining opening; and at least two tie rods, which are arranged on opposite sides of the battery module and tie together the lids and the support bodies in a packed manner.

A battery pack assembly or enclosure comprises one or more batteries having an electrochemical cell and an enclosure having at least an outer wall configured to create a sealed volume of space substantially around the batteries. An atmosphere of the volume of space comprises gas having a thermal conductivity less than 0.018 watts per meter per degree Celsius. This atmosphere of gas provides an insulative layer between the outer wall of the enclosure and the batteries. With this insulative layer, the battery pack assembly can be subjected to autoclaving without damaging the batteries. The battery pack assembly can be used to power surgical tools or other devices that are subjected to autoclaving.

Embodiments of the present invention relate to modular devices. The modular device comprises an enclosure having a main body and an extending member. A battery positioned at least within the main body. The extending member includes a coupling element. The coupling element is designed to provide electrical communication with another extending member when the extending member and the other extending member are in communication with each other. The coupling element is designed to provide structural support when in communication with the other extending member. The coupling element is in electrical communication with the battery. The modular device is designed in a manner to couple with another modular device via the coupling element.

A printing apparatus, having a casing, a printer, and a battery cover, is provided. The casing includes a battery compartment, to which a battery is attachable, and a terminal arranged inside the battery compartment. The printer is powered by the battery to print an image on a printable tape. The battery cover is attachable to the casing and, when at an attached position, covers at least a part of the battery compartment. The casing includes a guide arranged outside the battery compartment to guide the battery cover toward the attached position in the casing. The battery cover includes a first wall portion, which contacts the guide at an outer face thereof and slides along the guide as the battery cover moves toward the attached position, and a pressing portion to press the battery in the battery compartment against the terminal as the first wall portion slides along the guide.

A modular battery system provides propulsive power to the rotor system of an aircraft. The modular battery system includes an array of battery modules arranged in at least one stack. Each battery module includes a plurality of battery cells, a first side having positive and negative receptacles and a second side, that is opposite of the first side, having positive and negative plugs. The receptacles and plugs are configured such that adjacent battery modules in a side-by-side relationship are electrically coupled together via plug and receptacle connections and such that the battery modules are electrically coupled together in parallel. An interconnection electrically couples each stack of battery modules together via plug and receptacle connections with one of the battery modules in each stack such that the stacks of battery modules are electrically coupled together in parallel.

An electrical apparatus includes first and second battery interfaces disposed on a housing for electrically and mechanically connecting first and second battery packs in series. A controller is disposed within the housing and includes an apparatus microprocessor that receives first and second communication signals respectively outputted from respective microprocessors of the first and second battery packs. A first signal communication path communicates the first communication signal from the first battery pack microprocessor to the apparatus microprocessor by shifting a first voltage range of the first communication signal to a second voltage range that is suitable for inputting into the apparatus microprocessor. A second signal communication path communicates a third communication signal from the apparatus microprocessor to the first battery pack microprocessor by shifting the second voltage range of the third communication signal to a first voltage range that is suitable for inputting into the first battery pack microprocessor.

An electrical apparatus includes first and second battery interfaces disposed on a housing for electrically and mechanically connecting first and second battery packs in series. A controller is disposed within the housing and includes an apparatus microprocessor that receives first and second communication signals respectively outputted from respective microprocessors of the first and second battery packs. A first signal communication path communicates the first communication signal from the first battery pack microprocessor to the apparatus microprocessor by shifting a first voltage range of the first communication signal to a second voltage range that is suitable for inputting into the apparatus microprocessor. A second signal communication path communicates a third communication signal from the apparatus microprocessor to the first battery pack microprocessor by shifting the second voltage range of the third communication signal to a first voltage range that is suitable for inputting into the first battery pack microprocessor.