A solar power generation and storage unit includes a solar panel, and a storage battery directly connected to the solar panel, in which a maximum charging voltage of the storage battery is equal to or less than a value that is 10% larger than a maximum output operating voltage of the solar panel.

For the battery capable of bidirectional output in the embodiments, the two ends of the battery are both provided with a battery anode and a battery cathode respectively, such that any end of the battery can provide an anode output terminal and a cathode output terminal simultaneously. Circuit wiring of the battery can be optimized during use, and the first end of the battery capable of bidirectional output is provided with a first battery anode which protrudes outwards, and the second end thereof is provided with a second battery cathode which protrudes outwards. The battery in has a structure which is similar to that of a common battery, thus the battery can be charged with a common charger, then short circuiting is prevented, and no charger needs to be specially designed.

In a loaded condition, the controller increases at least one of the conduction band or the advance angle from a baseline value up to a maximum value within a first torque range below a torque threshold to as to maintain the output speed of the motor at a linear speed-torque profile. After the at least one of the conduction band or the advance angle reaches the maximum value, the controller maintains the at least one of the conduction band or the advance angle at the maximum value within a second torque range greater than or equal to the torque threshold so as to maintain the output speed of the motor at a naturally-curved speed-torque profile.

A battery pack and charger system includes a first battery pack having a first set of battery cells and configured to provide only a first operating voltage and a second battery pack having a second set of battery cells and configured to provide the first operating voltage and a second operating voltage that is different from the first operating voltage and a battery pack charger configured to be able to charge the first battery pack and the second battery pack.

A battery pack and charger system includes a first battery pack having a first set of battery cells and configured to provide only a first operating voltage and a second battery pack having a second set of battery cells and configured to provide the first operating voltage and a second operating voltage that is different from the first operating voltage and a battery pack charger configured to be able to charge the first battery pack and the second battery pack.

An electrical system can include a power supply configured to provide electrical power to components at a time at which the electrical system experiences an electrical fault. The electrical system can include a first battery electrically coupled in parallel to a second battery via an electrical bus, whereby the first and second batteries can provide electrical power to a first electrical load and a second electrical load. Upon experiencing a fault, a first circuit element can electrically decouple the first battery and the second battery by opening a circuit provided by the electrical bus, thereby isolating the first battery from the second battery. Next, the battery experiencing the fault can include a second circuit element that can electrically decouple the battery experiencing the fault from a respective electrical load, while the battery isolated from the fault can continue to provide electrical power to components.

An energy storage device and an electric device are provided in the disclosure. The energy storage device includes a jelly roll assembly and a connector. The jelly roll assembly includes at least one jelly roll. Each of the at least one jelly roll has multiple tabs arranged in a thickness direction of the tabs after winding an electrode sheet. The jelly roll has a first side surface and a first end surface. The multiple tabs are bent at roots of the multiple tabs and attached to the first end surface. The multiple tabs have a connection surface away from the first end surface. The connector is disposed on the connection surface and connected with the multiple tabs. The jelly roll assembly further includes a first insulation patch. The first insulation patch adheres to and covers a surface of the connector away from the first end surface, and extends to the first side surface.

An energy storage device and an electric device are provided in the disclosure. The energy storage device includes a jelly roll assembly and a connector. The jelly roll assembly includes at least one jelly roll. Each of the at least one jelly roll has multiple tabs arranged in a thickness direction of the tabs after winding an electrode sheet. The jelly roll has a first side surface and a first end surface. The multiple tabs are bent at roots of the multiple tabs and attached to the first end surface. The multiple tabs have a connection surface away from the first end surface. The connector is disposed on the connection surface and connected with the multiple tabs. The jelly roll assembly further includes a first insulation patch. The first insulation patch adheres to and covers a surface of the connector away from the first end surface, and extends to the first side surface.

In case a similar component-to-be-loaded is erroneously loaded on a main body side apparatus, contact of terminals are avoided. To this end, a video camera (main body side apparatus) 1 has a main body side terminal 30, and a battery pack (component-to-be-loaded) 100 has a battery side terminal (component-to-be-loaded side terminal) 120. In the vicinity of the battery side terminal of the component-to-be-loaded, a discriminating tab 111 is provided, and a blocking portion 19 is provided in the vicinity of the main body side terminal of the video camera (main body side apparatus) for determining whether or not its loading is permitted based on the combination of concave and convex engagement with respect to the above-mentioned discriminating tab, and when the loading is not permitted due to the interference between the blocking portion and the above-mentioned discriminating tab, an electric connection between the main body side terminal and the battery side terminal (component-to-be-loaded side terminal) is not to be established.

A battery or an accumulator including an anode case, an anode situated inside the anode case, a cathode case joined to the anode case, a seal sealing the cathode case to the anode case, a cathode situated inside the cathode case between the anode and the cathode case, and a membrane between the anode and the cathode. An outer surface of the battery includes at least one marking.