New systems, methods and media for simultaneous energy and data transfer are provided. In some aspects of the invention, an energy and data receiver is provided, which may be used to receive data and energy simultaneously, in a unified manner. Energy and information transfer media, which may be included within such a receiver unit, are also provided.

New electrochemical battery recharging, refurbishment and replacement techniques are also provided. In some aspects of the invention, small, fungible battery elements with external contacts may be delivered to a tank comprising contacts. The cells may be delivered to the tank bridging contacts within the tank, powering an appliance. Density differentials, maneuvering protocols and variable contacts between the elements may aid in placing them in selected circuit orders, and in removing them.

A lithium-ion battery module includes a housing having a plurality of partitions configured to define a plurality of compartments within a housing. The battery module also includes a lithium-ion cell element provided in each of the compartments of the housing. The battery module further includes a cover coupled to the housing and configured to route electrolyte into each of the compartments. The cover is also configured to seal the compartments of the housing.

A zinc-air cell, a battery which is a low weight, low volume, or higher energy system, or a combination thereof and an apparatus for recharging the same are disclosed.

An energy system for providing electrical energy to a device where the energy system includes: a first battery for providing a first electrical power over a first time period; a second battery for providing a second electrical power over a second time period, the second battery being a type different from a type of the first battery, the second power being greater than the first power and the second time period being smaller than the first time period; and a controller for controlling initiation of the first battery and the second battery at predetermined times to satisfy a specific power requirement of the device over a time period including the first and second time periods.

An anaerobic aluminum-water electrochemical cell is provided. The electrochemical cell includes: a plurality of electrode stacks, each electrode stack featuring an aluminum or aluminum alloy anode, and at least one cathode configured to be electrically coupled to the anode; one or more physical separators between each electrode stack adjacent to the cathode; a housing configured to hold the electrode stacks, an electrolyte, and the physical separators; a water injection port, in the housing, configured to introduce water into the housing; and an amount of hydroxide base sufficient to form an electrolyte having a hydroxide base concentration of at least 0.5% to at most 13% of the saturation concentration when water is introduced between the anode and the least one cathode.

A battery cell, driven by heat, having a reservoir containing a redox couple electrolyte comprised of paramagnetic and diamagnetic ions. A magnet with a pole, projecting a non-uniform magnetic field unto the electrolyte, the magnetic field having a strong magnetic field area proximal to the magnetic pole and a weak magnetic field area distal to the magnetic pole. A positive electrode is placed in the strong magnetic field area and a negative electrode is placed in the weak magnetic field areas of the electrolyte. Ionic separation occurs as the paramagnetic ions drift to the strong magnetic field area, and the diamagnetic ions are repulsed from the magnetic pole and drift to the weak magnetic field area, causing voltage potential across the positive and negative electrodes. A circuit placed across the positive and negative electrodes of the battery draws electrons from the diamagnetic ions through the negative electrode and the electrical circuit to the positive electrode and into the paramagnetic ions. Paramagnetic ions in the strong field area reduce into converted diamagnetic ions as the paramagnetic ions receive electrons through the positive electrode, the converted diamagnetic ions repelled by the magnetic pole drift to the weak magnetic field area. Additionally, diamagnetic ions proximal to the weak magnetic field area oxidize into converted paramagnetic ions as the diamagnetic ions lose electrons through the negative electrode, the converted paramagnetic ions attracted to the magnetic pole drift to the strong magnetic field area.

The present disclosure pertains to motion-generating particles for desulfation of lead-acid batteries, lead-acid batteries including such motion-generating particles, and methods of making and using the same. For example, the present disclosure provides a lead-acid battery including one or more electroactive plates disposed within a casing; an electrolyte disposed within the casing and surrounding the electroactive plates; a plurality of ferromagnetic particles disposed with the electrolyte within the casing; and one or more electromagnets. The one or more electromagnets may be configured to direct a magnetic field towards the electrolyte to selectively cause movement of the plurality of ferromagnetic particles so as to agitate the electrolyte.

A metal air battery having multiple anode-cathode disc assemblies that include a first and second cathode disc flanking an anode disc. An actuator moves at least one cathode disc relative to the other cathode disc, and thereby facilitates the size of the anode-cathode gap. The anode disc has a hole that engages a power shaft to rotate the anode disc.

A metal air battery having multiple anode-cathode disc assemblies that include a first and second cathode disc flanking an anode disc. An actuator moves at least one cathode disc relative to the other cathode disc, and thereby facilitates the size of the anode-cathode gap. The anode disc has a hole that engages a power shaft to rotate the anode disc.

Systems and methods of the various embodiments may provide a refuelable battery for the power grid to provide a sustainable, cost-effective, and/or operationally efficient solution to energy source variability and/or energy demand variability. In particular, the systems and methods of the various embodiments may provide a refuelable primary battery solution that addresses bulk seasonal energy storage needs, variable demand needs, and other challenges.