The disclosure relates to a power pack to be used when there is a need for an efficient or portable power source, for example, when the electrical grid is saturated, overused, unreliable or inoperative. The power pack is configured to utilize a renewable energy source, such as solar energy, to charge a rechargeable battery within a battery pack. Said battery pack, through the use of a battery management system, may then provide AC or DC power to an external device that requires electricity, or store power for a later use.

A power supplying system that includes a power supplying mechanism, an electric load, a power line, and a storage pack. The power supplying mechanism supplies a DC power. The electric load is connected to the power supplying mechanism by the power line. The storage pack is connected to the power line. The charging/discharging curve of the storage pack has a step difference that passes through the rated voltage of the power supplying mechanism. An average discharging voltage on a lower-SOC side of the start point of the step difference is 20% or more of the rated voltage. An average charging voltage on a higher-SOC side of the end point of the step difference is +20% or less of the rated voltage.

An autonomous, modular energy generation, storage and transmission apparatus, system, and method is provided. An apparatus is tube shaped and includes solar and thermionic energy conversion layers, and a battery module. A system of modular apparatuses may be connected together to form a transmission network. Such devices are particularly suited for outdoor application on highway jersey walls, and for indoor application on office cubicle walls. A method of charging battery modules in the apparatus is provided, along with a method of distributing the same in commerce.

Various enhanced power supply configurations for satellite devices are discussed herein. In one example, satellite device includes a chassis and a power control module. The satellite device also includes an array of polygonal-shaped power units combined into a geometric arrangement by disposing the polygonal-shaped power units around the power control module within the chassis. In some examples, the polygonal-shaped power units comprise a rhomboid chassis or enclosure that provides arrangement into a hexagonal array when coupled to eight further rhomboid power units. Other polygonal arrays can be formed using arrangements of the repeating polygonal-shaped power units.

A panel according to an embodiment includes a translucent layer arrangement and a battery cell embedded at least partially into the translucent layer arrangement.

A modular energy storage system has: a battery module with a battery and internal circuitry; a control module with a power outlet, internal charge-and-discharge electrical components, and a power inlet for connection to a power source in use; the battery module defining a top seat that has an associated electrical connector; and the battery module being mounted to the control module below the control module by the top seat, whose respective associated electrical connector connects to the internal charge-and-discharge electrical components to permit the control module to: charge the battery module with power from the power source; and discharge the battery module by transferring power from the battery module to the power outlet.

Energy storage radiators are disclosed. The structure of the radiator may be used as a battery to store and release energy, as well as serving to regulate the temperature of that battery and the associated device or vehicle. The structure may be configured to provide mechanical support, an enclosure, an attachment point, or an extension for a vehicle or a device. By designing an energy storage radiator to function as a battery, a separate battery superstructure may not be required. Also, the heat to be radiated away can be used to keep the battery in its operating temperature range. This may provide mass reduction of the radiator structures or materials, as well as make those materials multifunctional and replace material elsewhere with respect to conventional systems.

An energy storage canopy associated with a local building is provided. The energy storage canopy includes support members that can support compartments, which may be integral with or removable from the energy storage canopy. Each compartment includes a plurality of high capacity batteries to store electrical energy, at least one power conditioner to allow coupling high capacity batteries to an external unit. The external unit may be a power grid, a building, other loads, or the like.

A power system includes a bidirectional power transfer inverter that receives grid power and can be electrically connected with electric vehicle supply equipment, and an auxiliary battery electrically connected with the bidirectional power transfer inverter and that supplies power to the bidirectional power transfer inverter and electric vehicle supply equipment while the grid power is unavailable.

An inflatable tent storage assembly for a tent being storable includes a box having a square shape. The box has a front wall, a back wall, a bottom wall and a top wall. The box has an interior where a tent is stored in a closed position within. The tent has a mattress being inflatable. A pump is positioned within the interior of the box and the pump fills and removes air from the mattress. In addition, a solar panel is integrated within the top wall of the box and a battery is in electric communication with the solar panel. A switch is position on the front wall of the box. The switch includes a fill position, a drain position, and an off position. A handle is positioned on the front wall of the box and a pair of wheels is positioned on the bottom wall of the box.