A device for restoring energy parameters of a battery is provided. The device includes a supporting frame, a controller, and a battery container configured to receive the battery therein, the battery container being operably coupled to a controlling inverter and a motor comprising a motor reductor. The controlling inverter is configured to regulate a rotational speed of the motor. The motor reductor is configured to facilitate rotation of the battery container. Methods of restoring energy parameters of a battery are also provided.

Dual-functional energy storage systems that couple ion extraction and recovery with energy storage and release are provided. The dual-functional energy storage systems use ion-extraction and ion-recovery as charging processes. As the energy used for the ion extraction and ion recovery processes is not consumed, but rather stored in the system through the charging process, and the majority of the energy stored during charging can be recovered during discharging, the dual-functional energy storage systems perform useful functions, such as solution desalination or lithium-ion recovery with a minimal energy input, while storing and releasing energy like a conventional energy storage system.

Dual-functional energy storage systems that couple ion extraction and recovery with energy storage and release are provided. The dual-functional energy storage systems use ion-extraction and ion-recovery as charging processes. As the energy used for the ion extraction and ion recovery processes is not consumed, but rather stored in the system through the charging process, and the majority of the energy stored during charging can be recovered during discharging, the dual-functional energy storage systems perform useful functions, such as solution desalination or lithium-ion recovery with a minimal energy input, while storing and releasing energy like a conventional energy storage system.

Aspects of the disclosure involve a battery pack involving one or more stacks of battery cells, where the stacks of battery of cells are captured between plates or other members that are controlled to maintain force on the cells to manage the pressure on the cells in the stack. Some battery cells technologies, such as some forms of solid-state cells, optimally operate under a controlled stack pressure provided by the systems described herein.

A rechargeable electrical energy accumulator including a metal-air electrochemical cell, or battery, and an oxygen and nitrogen separator/concentrator connected to the battery for separating and concentrating, separately, the oxygen and nitrogen present in the air The battery includes a container made of non-conductive material and a reaction chamber, the reaction chamber containing at least one metal anode, at least one cathode, connected to said oxygen and nitrogen separator/concentrator, and an electrolyte placed in contact with said at least one metal anode and at least one cathode. The metal-air battery includes capabilities for inertization of the anode by interposing an inert gas between said at least one anode (and said electrolyte when the battery is not in use, ultrasonic piezoelectric transducers, positioned near the edge of the container and/or on the surface of the least one anode, immersed in the electrolyte, the piezoelectric ultrasonic transducers generating a continuous ultrasonic pressure wave.

Particular embodiments described herein provide for a privacy cover in an electronic device. The battery system can be configured to monitoring one or more condition of a battery using a battery electrolyte controller that is separate from the battery, adjusting one or more properties of an electrolyte in an electrolyte conduit, where the electrolyte conduit is coupled to an inlet and an outlet on the battery, and activating a pump to move the electrolyte with the adjusted one or more properties into the battery.

A battery may include a first electrode, a second electrode, an electrolyte, and at least one acoustic device configured to generate acoustic streaming during a charging and/or a discharging of the battery. The charging of the battery may trigger cations from the first electrode to travel through the electrolyte and deposit on the second electrode while the discharging of the battery may trigger cations from the second electrode to travel through the electrolyte and deposit on the first electrode. The acoustic streaming may drive a mixing and/or a turbulent flow of the electrolyte, which may increase a charge rate and/or a discharge rate of the battery by increasing diffusion rate of cations and/or anions. The mixing and/or the turbulent flow may further prevent a formation of dendrites on the first electrode and/or the second electrode by at least homogenizing a distribution of the cations and/or anions in the electrolyte.

An electrode structure with built-in ultrasonic structures, having an electrode which is a positive electrode or a negative electrode; an ultrasonic vibration module is built into the electrode; the ultrasonic vibration module has an ultrasonic vibration element and an insulating material layer surrounding all outer surfaces the ultrasonic vibration element; wire connection terminals electrically connected with the ultrasonic vibration element are provided at a top end of or on a top end of the electrode. An ultrasonic solid lithium battery, an ultrasonic lithium battery, and an ultrasonic lead-acid battery formed by applying more than one of the above electrode structure in a solid lithium battery, a lithium battery, and a lead-acid battery respectively are also provided.

An ultrasonic solid-state lithium battery with built-in ultrasonic vibrating effect, including a battery case; and a positive electrode, a negative electrode and solid electrolyte installed on the battery case. A built-in ultrasonic vibrating module is provided within the positive electrode and/or negative electrode and/or solid electrolyte. The ultrasonic vibrating module has an ultrasonic vibrating element and an insulating layer covering the peripheral surfaces of the ultrasonic vibrating element. Wiring terminals electrically connected with the ultrasonic vibrating element are provided on or above a top end of the positive electrode and/or negative electrode and/or solid electrolyte.

Improved battery systems, apparatuses, and methods for use in electric air, land, and marine vehicles and mobile, portable, and stationary electrical appliances and devices are provided. The systems employ acoustic and current manipulation of anode interface deposits including dendrites on or proximate lithium and other anodes. This invention may employ multistatic ultrasonic phased arrays and current modulation to 1) minimize deposit, e.g., dendrite, initiation and formation by acoustic stirring, 2) acoustically image dendritic growths to monitor changes in dendrite growths, 3) cue dendrite cleaning and battery shutdown to avoid short circuit, 4) induce failure in dendritic structure and shearing of at least a portion of the dendrite from the anode, and 5) transport sheared dendrites and other dead metal to a graveyard.