A system having a global navigation satellite system (GNSS) receiver having a GNSS receiver battery receptacle for housing a battery therein, and a handheld receptacle which has an insertion portion which is shaped as an outer portion of the battery and which is adapted for insertion into the battery receptacle of the GNSS receiver instead of the battery, wherein the handheld receptacle has a handheld receptacle battery receptacle to receive the battery therein. The battery can be swapped from the GNSS receiver and the handheld receptacle. A socket can be provided on the handheld receptacle for mounting a computing device thereon in communication with the GNSS receiver. A pole-mount adapter can be used for connecting the GNSS receiver onto a pole below the GNSS battery receptacle and can be mounted and dismounted even when the handheld receptacle is inserted in the GNSS receiver.

A monitoring system for a multi-cell rechargeable energy storage system (RESS) that includes a plurality of battery cells is described. The monitoring system includes a sensor that is arranged to monitor one or multiple heat transfer plates thermally coupled to the plurality of battery cells, a controller is in communication with the sensor. The controller including an instruction set that is executable to monitor, via the sensor, a parameter of the heat transfer plate and detect a thermal runaway event when the parameter of the heat transfer plate exceeds a threshold. The thermal runaway event is communicated to a battery controller.

Provided is an energy storage apparatus including: a neighboring member disposed adjacently to an energy storage device; and a terminal member disposed adjacently to the neighboring member on a side opposite to the energy storage device, wherein the terminal member has: a body extending along the neighboring member; and a bolt member having a head portion and a shaft portion extending from the head portion, and mounted on the body in a state where the shaft portion is made to pass through the body from a neighboring member side, the neighboring member has a protruding portion protruding in an axial direction of the shaft portion, and the protruding portion is inserted into the body at a position where at least a portion of the protruding portion overlaps with a projection region of the shaft portion in the axial direction.

A vehicle battery that includes a partially hollow battery shell, shock-absorbing material, and a mounting base. The battery shell has an upper section and a stepped-in lower section, the lower section having a sidewall and a floor. The shock-absorbing material is attached to the sidewall of the lower section of the battery shell and has a lower edge that extends below the floor of the lower section. The mounting base is attached to the lower edge of the shock-absorbing material and is spaced from the floor of the lower section of the battery shell to isolate the battery shell from a vehicle surface on which it is supported.

A manufacturing method for a secondary battery and a manufacturing apparatus for a secondary battery that are applicable to a secondary battery in which an electrolyte solution injection hole has a diameter of 1.5 mm or more are provided. The secondary battery includes a battery case including a cover plate provided with an electrolyte solution injection hole, and a sealing member sealing the electrolyte solution injection hole. The manufacturing method includes a preparing step and a press-fitting step. The preparing step is preparing a cell in which, after an electrolyte solution is injected to the battery case through the electrolyte solution injection hole, the sealing member is disposed on the electrolyte solution injection hole. The press-fitting step is press-fitting the sealing member into the electrolyte solution injection hole while applying press-fitting load and ultrasonic vibration with a frequency of 20 kHz or more in parallel to a press-fitting direction.

A multi-tasking end effector system includes a base frame connected to a robot arm of a robot. A first shaft is rotatably supported on the base frame. A first pin-wheel assembly is rotatably mounted to the shaft at a first end of the base frame. Multiple first die assemblies are mounted to the first pin-wheel assembly. A second pin-wheel assembly is rotatably mounted to the shaft at a second end of the base frame. Multiple second die assemblies are mounted to the second pin-wheel assembly and individually oriented in mirror image configuration to one of the multiple first die assemblies. An index motor rotates the first shaft and co-rotates paired and mirror image die assemblies. First and second tab-bending actuators mounted to the base frame are operated to bend opposed cell tabs of a battery cell positioned between the first and second pin-wheel assemblies.

A multi-tasking end effector system includes a base frame connected to a robot arm of a robot. A first shaft is rotatably supported on the base frame. A first pin-wheel assembly is rotatably mounted to the shaft at a first end of the base frame. Multiple first die assemblies are mounted to the first pin-wheel assembly. A second pin-wheel assembly is rotatably mounted to the shaft at a second end of the base frame. Multiple second die assemblies are mounted to the second pin-wheel assembly and individually oriented in mirror image configuration to one of the multiple first die assemblies. An index motor rotates the first shaft and co-rotates paired and mirror image die assemblies. First and second tab-bending actuators mounted to the base frame are operated to bend opposed cell tabs of a battery cell positioned between the first and second pin-wheel assemblies.

The present disclosure provides a fluid joint structure including a first body and a second body. The first body includes a first cavity, a first joint element and a first elastic element. The second body includes a second cavity, a second joint element and a second elastic element. The first body is joined with the second body such that the first joint element and the second joint element push against each other to generate a flow path of a fluid for the fluid to flow in the first cavity and the second cavity. Thus, a required fluid is enabled to flow stably in the first body and the second body.

The present disclosure provides a cap assembly for a secondary battery and a secondary battery. The cap assembly includes a cap plate, an electrode terminal, a fixing member, a sealing member and a connecting member, wherein: the cap plate has an electrode lead-out hole; the fixing member is fixed to the cap plate through the connecting member; the electrode terminal includes a terminal board, wherein an outer peripheral surface of the terminal board is surrounded at least in part by the fixing member to fix the electrode terminal to the fixing member, the terminal board is located at a side of the cap plate and covers the electrode lead-out hole, and the outer peripheral surface of the terminal board protrudes out of an inner wall of the electrode lead-out hole; and the sealing member is disposed between the terminal board and the cap plate to seal the electrode lead-out hole.

A battery box includes at least two end plates, at least two side plates, and a plurality of welding members. One of the at least two end plates is provided between two adjacent side plates of the at least two side plates. The at least two end plates and the at least two side plates are connected to one another to enclose a cavity of the battery box. The plurality of welding members are formed by bending an end portion of an end plate of the at least two end plates multiple times. The end portion of the end plate is configured to implement the connection of at least two side plates and the at least two end plates to one another to enclose the cavity of the battery box. The plurality of welding members are configured to be welded to a corresponding side plate.