A vehicle with a Geo-Fenced Ride Control System including: one or more battery modules including one or more battery cells; one or more processors operably connected to the one or more battery cells to control vehicle performance; and a Global Positioning System (GPS) or cellular network receiver configured to determine location of the vehicle; wherein the one or more processors communicates with a remote sever to determine a plurality of available vehicle performance settings for the vehicle based on the location of the vehicle. The vehicle further includes a user input interface configured to receive user input including selection of the vehicle performance setting form the plurality of available vehicle performance settings based on the geographic location of the vehicle.

A battery cell bundle includes a support member including at least one barrier wall including first and second sides; a plurality of first battery cells disposed on the first side of the at least one barrier wall; a plurality of second battery cells disposed on the second side of the at least one barrier wall; a cover member surrounding at least a portion of an outer portion of the plurality of first and second battery cells, and coupled to the support member such that the cover member and the support member define an internal space; and a panel member covering ends of the internal space, wherein the internal space is divided into a plurality of installation spaces by the at least one barrier wall, and wherein the first and second battery cells are disposed in each of the installation spaces.

In order to provide a battery module and the like capable of maintaining a fastened state of a plurality of battery cells with high reliability, battery module includes a plurality of battery cells each having electrode terminals, a pair of end plates that cover both side end surfaces of battery stack including the plurality of stacked battery cells, and a plurality of fastening members that fastens end plates to each other. End plate forms overlapping portion that covers at least a portion of each fastening member covering each side surface of battery cells located on the both side end surfaces of battery stack, and overlapping portion and the fastening members are welded and fixed. According to the above configuration, by welding in a state in which a side surface of fastening member is further covered with overlapping portion, there is an advantage that firm fixation can be achieved while preventing disengagement of fastening member.

In order to provide a battery module and the like capable of maintaining a fastened state of a plurality of battery cells with high reliability, battery module includes a plurality of battery cells each having electrode terminals, a pair of end plates that cover both side end surfaces of battery stack including the plurality of stacked battery cells, and a plurality of fastening members that fastens end plates to each other. End plate forms overlapping portion that covers at least a portion of each fastening member covering each side surface of battery cells located on the both side end surfaces of battery stack, and overlapping portion and the fastening members are welded and fixed. According to the above configuration, by welding in a state in which a side surface of fastening member is further covered with overlapping portion, there is an advantage that firm fixation can be achieved while preventing disengagement of fastening member.

A battery includes a housing and multiple electrode core assemblies in the housing. Each electrode core assembly includes a packing film and an electrode core located in an accommodating cavity defined by the packing film. A spacer is arranged between two adjacent electrode core assemblies connected in series. Each electrode core assembly includes a first electrode and a second electrode extending out of the packing film. The first electrode of a first electrode core assembly is connected to the second electrode of a second electrode core assembly of the two adjacent electrode core assemblies through a connecting portion in a through hole. The spacer includes an outer surface facing the housing. A first positioning portion is formed on the outer surface, A second positioning portion corresponding to the first positioning portion is formed on the inner surface of the housing and is coupled with the first positioning portion.

A battery pack includes a pack case; a plurality of battery modules mounted to the pack case; a plurality of slave modules respectively mounted to the battery modules one by one to monitor a state of the battery module, each slave module having a slave antenna for wireless communication; a master module configured to integrally manage the state of the battery modules based on information obtained from the plurality of slave modules and have a master antenna for wireless communication; and a waveguide installed inside the pack case to form a wireless communication path between the plurality of slave modules and the master module.

A battery pack includes a plurality of battery assemblies, each of the plurality of battery assemblies including a cell stack that includes a plurality of battery cells stacked together and a plate unit covering at least a portion of a side surface of the cell stack, and a linking member configured to electrically connect at least two of the battery assemblies to each other, wherein the plate unit may include an accommodation portion into which the linking member is inserted.

A battery pack includes a plurality of battery assemblies, each of the plurality of battery assemblies including a cell stack that includes a plurality of battery cells stacked together and a plate unit covering at least a portion of a side surface of the cell stack, and a linking member configured to electrically connect at least two of the battery assemblies to each other, wherein the plate unit may include an accommodation portion into which the linking member is inserted.

The present disclosure relates to a battery pack with improved safety through high reliability of temperature measurement of a plurality of battery cells. To achieve the above-described object, the battery pack includes a plurality of battery cells, a temperature sensor configured to measure a temperature of at least one of the plurality of battery cells, a module case configured to receive the plurality of battery cells therein and including a recessed space in which the temperature sensor is disposed, and a holder inserted into the recessed space of the receiving portion. The holder has a size that is large enough to fill at least part of the recessed space and is configured to hold the temperature sensor.

The present disclosure relates to a battery pack with improved safety through high reliability of temperature measurement of a plurality of battery cells. To achieve the above-described object, the battery pack includes a plurality of battery cells, a temperature sensor configured to measure a temperature of at least one of the plurality of battery cells, a module case configured to receive the plurality of battery cells therein and including a recessed space in which the temperature sensor is disposed, and a holder inserted into the recessed space of the receiving portion. The holder has a size that is large enough to fill at least part of the recessed space and is configured to hold the temperature sensor.