Abstract: An electrode for an electrochemical energy accumulator includes a catalyst layer, where the catalyst layer includes an electrically conductive matrix and a chemically active material which is intercalated into the electrically conductive matrix. A protective coating is disposed on the catalyst layer, where the protective coating includes at least one metal oxide and methionine.

Abstract: A redox flow battery pipe which is disposed between a tank that stores an electrolyte and a battery element and through which the electrolyte flows includes a plurality of parallel portions arranged in parallel and a plurality of bent portions connecting the parallel portions adjacent to each other. The pipe includes a meandering portion in which the parallel portions and the bent portions are integrally molded so as to be alternately connected. A ratio of a center-to-center distance X to an outer diameter D satisfies 1.2 or more and 2.5 or less where D represents an outer diameter and X represents a distance between centers of the parallel portions adjacent to each other.

Abstract: A battery charging control method and apparatus is disclosed. The battery charging control method includes inputting a preset magnitude of a current to a battery during a preset period of time, identifying a diffusion characteristic of a material in the battery, and determining whether to change the magnitude of the current to be input to the battery based on the identified diffusion characteristic of the material, in which the diffusion characteristic may be determined based on a distribution of the material in one or more of a cathode of the battery, an anode of the battery, and an electrolyte of the battery in response to the input of the current in the battery.

Abstract: An apparatus comprises a plurality of negative electrode reservoirs configured to contain a negative electrode material, at least one positive electrode reservoir configured to contain a positive electrode material and a reaction chamber. A heating system is configured to heat negative electrode material within a selected negative electrode material reservoir and to heat positive electrode material in the at least one positive electrode material reservoir to maintain the electrode materials in the selected reservoirs in a fluid state while maintaining, in a non-fluid state, negative electrode material in a non-selected negative electrode reservoir. An electrode material distribution system is configured to transfer, during a discharge state of the apparatus, fluid negative electrode material from the selected negative electrode reservoir to the reaction chamber.

Abstract: A thermal management system comprises two pumps and three coolant loops. The loops are interconnectable such that most if not all of the functions of the thermal management system can be accomplished with one of the two pumps deactivated or inoperable. The thermal management system is selectively configurable to utilize waste heat from a battery, an electrical drivetrain system, and/or a wireless charger to heat cabin air. The thermal management system is further selectively configurable to heat or cool a battery, to cool an electrical drivetrain system, and to cool a wireless charger.

Abstract: A multiple particle reduced order model to adjust charging applied to a load based on accurately predicting lithium plating potential in real time during the life of a lithium battery cell. In the current multi-particle reduced order modeling system, the current density and the potential distributions are solved iteratively. Once the current distribution is solved, lithium concentration distribution is solved without involving any iterative process. By solving the lithium concentration distribution as a separate step after the iteratively determined current density and potential distributions, the computation time required by the model to generate an output is dramatically reduced by avoiding solving multiple partial derivative equations iteratively. Based on the potential distribution information provided by the output of the model, lithium plating potential can be determined, and actions can be taken, such as modified charging techniques and rates, to minimize future lithium plating.

Abstract: Microporous sheet product and methods of making and using the same. In one embodiment, the microporous sheet product is made by a process that includes melt-extruding a sheet material using an extrusion mixture that includes a thermoplastic polymer, a non-cross-linked elastomer having a molecular weight of at least 50,000 Da, and a compatibilizing agent. By way of example, the thermoplastic polymer may be a polyolefin, the non-cross-linked elastomer may be a polyisobutylene, and the compatibilizing agent may be mineral spirits. After extrusion, the sheet material may be cooled, and the sheet material may be stretched. The microporous sheet product may be used, for example, as a battery separator, as a food packaging material, as a diffusion barrier in the ultrafiltration of colloidal matter, and in disposable garments.

Abstract: An electrochemical cell includes a bifunctional air cathode, an anode, and a ceramic electrolyte separator disposed substantially between the bifunctional air cathode and the anode. The anode includes a solid metal and an electrolyte configured to transition to a liquid phase in an operating temperature range. The electrolyte includes at least one of an alkali oxide, boron oxide, a carbonate, a phosphate, and a group III-X transition metal oxide.

Abstract: A hybrid charging/discharging solar energy storage apparatus includes: a solar power generator configured to receive incident solar light and generate electricity; a power converter configured to receive at least power generated by the solar power generator as input power and convert the input power into output power by changing a voltage of the input power; an energy storage unit comprising a plurality of modules configured to store power; a load connection line connected to a load configured to consume power of at least one of the power converter and the energy storage unit; and a power controller configured to control charging and discharging of the energy storage unit according to preset charging/discharging policies.

Abstract: Embodiments described herein relate generally to electrochemical cells including a selectively permeable membrane and systems and methods for manufacturing the same. In some embodiments, the selectively permeable membrane can include a solid-state electrolyte material. In some embodiments, electrochemical cells can include a cathode disposed on a cathode current collector, an anode disposed on an anode current collector, and the selectively permeable membrane disposed therebetween. In some embodiments, the cathode and/or anode can include a slurry of an active material and a conductive material in a liquid electrolyte. In some embodiments, a catholyte can be different from an anolyte. In some embodiments, the catholyte can be optimized to improve the redox electrochemistry of the cathode and the anolyte can be optimized to improve the redox electrochemistry of the anode. In some embodiments, the selectively permeable membrane can be configured to isolate the catholyte from the anolyte.

Abstract: A lithium ion battery including a core-shell structured fire extinguishing particle is disclosed. When the battery is overheated to a predetermined temperature, a shell of the fire extinguishing particle coated on one surface or both surfaces of a porous separator is melted, a fire extinguishing material disposed in an inner space of the shell is released into an electrolytic solution of the battery, and as a result, it is possible to prevent the battery from being ignited or exploded even though the battery is overheated. Further, the melted shell clogs pores of the porous separator to block lithium ions from moving, such that the battery is blocked from being driven, thereby preventing the battery from being overheated any more.

Abstract: A battery, in particular a vehicle battery for a vehicle which is at least electrically drivable, including a battery housing, and at least one first battery module, the first battery module including at least one battery cell, and including at least one battery terminal for connecting the battery to a vehicle. The battery includes at least one second battery module, including at least one battery cell, inside the battery housing, the second battery module being connectable to the first battery module and energy being thereby transmitted between the battery modules, at least one thermal insulation element at least largely surrounding the first battery module, whereby the first battery module is thermally insulated and thermally separated from the second battery module.

Abstract: A process for reducing nitrogen oxides in an exhaust stream, such as a vehicle exhaust stream, and apparatus for carrying out the process. The process comprises providing a first composition comprising aqueous urea, a second composition comprising ammonium carbamate and an exhaust stream comprising nitrogen oxides. A process for producing the ammonium carbamate is also provided. The second composition may be introduced into the exhaust stream (10) when the exhaust stream has a temperature below a threshold temperature and the first composition may be introduced into the exhaust stream when the exhaust stream has a temperature at or above the threshold temperature.

Abstract: A battery has a case, an external environment information acquisition component, and an internal environment information acquisition component. The case houses one or more cells. The external environment information acquisition component acquires specific external environment information (such as temperature and amount of sunlight) on the outside of the case. The internal environment information acquisition component acquires specific internal environment information (such as temperature and humidity) on the inside of the case.

Abstract: Membraneless electrochemical cells and batteries are disclosed. The cells comprise electrolyte solutions that are not miscible. The cells and batteries disclosed herein may be used to deliver electricity to process applications.

Abstract: An anode for a galvanic cell is constructed from an anode material containing a main component, which releases lithium ions during a discharge process of the galvanic cell, and at least one additive. The at least one additive has an electrochemical potential which is higher with respect to elemental lithium than an electrochemical potential of the main component with respect to elemental lithium. The at least one additive has a charging capacity and a discharging capacity, and the charging capacity does not deviate from the discharging capacity by more than 10%.

Abstract: A redox flow battery according to the present invention is provided with a battery module including a battery cell or a stack, and a pair of electrolyte tanks, and a replacement of a pump is applied for each battery module to transfer electrolyte to the battery cell and the stack such that shunt current is reduced. In addition, each battery module is provided with the pair of the electrolyte tanks such that a transfer distance of the electrolyte can be reduced, and a fluid controller using pressure instead of a pump for each module such that power required for driving the pump can be reduced and efficiency of the battery can be improved.

Abstract: A lithium-sulfur battery which includes an electrolyte containing lithium-ions, an anode and a cathode containing sulfur. The lithium-sulfur battery also contains a surface layer which is arranged between the anode and the cathode. The lithium-sulfur battery further includes areas on the cathode side which contain polysulfides. The surface layer of the lithium-sulfur battery contains at least one graphene layer which is permeable to lithium ions and impermeable to polysulfides.

Abstract: A battery cell has positive and negative cell tabs protruding from a first edge and a cell stack-up within a pouch. Anode and cathode foils are connected to the cell tabs proximate the first edge, with the anode foils connected to each other proximate a second edge. An outermost current collector of the anode foils exists with respect to a thickness of the cell stack-up. The cathode foils are connected to the positive cell tab proximate the first edge. The anode foils are connected to each other and the negative cell tab proximate the second edge, such that the outermost current collector forms an internal bus bar between the first and second edges. The battery cell has asymmetrical packaging and symmetrical internal current paths. A system includes a battery pack driving a load, with the battery pack having battery cells constructed as set forth above.

Abstract: Provided is a cell module assembly including: a plurality of cell modules arranged at a predetermined interval; and a pack structure including a pack tray that supports the plurality of cell modules and in which a passage is formed, wherein at least one first venting hole is formed in each of the plurality of cell modules, and a second venting hole matched to the at least one first venting hole and communicating with the passage is formed in the pack tray.

Abstract: A secondary high energy density lithium ion cell includes a cathode comprising a high voltage cathode active material, a lithium metal anode, and a non-aqueous electrolyte, wherein the non-aqueous electrolyte comprises an imide salt with a fluorosulfonyl group and a perchlorate salt, wherein the electrolyte is electrochemically stable at operating voltages greater than 4.2V.

Abstract: Electrochemical cells that cycle lithium ions and methods for suppressing or minimizing deposition of transition metal ions at negative electrodes are provided. The electrochemical cells include a positive electrode, a negative electrode, a separator disposed therebetween, and an electrolyte system including one or more lithium salts, one or more solvents, and at least one additive complexing compound. The at least one additive complexing compound includes an alkyl group having greater than or equal to 4 carbon atoms and less than or equal to 22 carbon atoms and a transition metal ion trapping group. The at least one additive compound associates with a surface of the separator via van der Waal's interactive forces and is further capable of complexing with transition metal ion within the electrochemical cell to sequester or tether the ions generated by contaminants to minimize or suppress the deposition of transition metal cations on the negative electrode.

Abstract: Provided is a power supply device for a vehicle in which charge movement between a plurality of cell groups can be suppressed. The plurality of cell groups each include a plurality of cells connected in series to each other and are each provided on one of the plurality of wiring paths. A plurality of switches are connected in series to the plurality of cell groups in the plurality of wiring paths. A deterioration diagnosis unit specifies, from the plurality of cell groups, a deteriorated cell group that has deteriorated. A switch controller turns off, among the plurality of switches, a deteriorated switch that is connected to the deteriorated cell group.

Abstract: A prismatic battery stack includes a first lithium-ion battery cell and a second lithium-ion battery cell. The battery stack also includes a first channel disposed around the first lithium-ion battery cell and the second lithium-ion battery cell. The battery stack includes a second channel disposed around the first lithium-ion battery cell and the second lithium-ion battery cell. The first channel and the second channel serve as heat sinks.

Abstract: An electrochemical cell includes a negative electrode that contains lithium and an electrolyte system. In one variation, the electrolyte system includes a first liquid electrolyte, a solid-dendrite-blocking layer, and an interface layer. The solid dendrite-blocking layer is ionically conducting and electrically insulating. The dendrite-blocking layer includes a first component and a distinct second component. The dendrite-blocking layer has a shear modulus of greater than or equal to about 7.5 GPa at 23° C. The interface layer is configured to interface with a negative electrode including lithium metal on a first side and the dendrite blocking layer on a second opposite side. The interface layer includes a second liquid electrolyte, a gel polymer electrolyte, or a solid-state electrolyte. The dendrite-blocking layer is disposed between the first liquid electrolyte and the interface layer.

Abstract: A storage battery system control method includes at least the following steps. Respective current SOC (state of charge) values of the large capacity storage battery system and the high power storage battery system are acquired. Electrical power, which is required to operate the frequency control service for the purpose of suppressing frequency fluctuations, to the large capacity storage battery system and the high power storage battery system, in accordance with the respective SOC values. The respectively allocated electrical power is charged or discharged by driving the large capacity storage battery system, or alternatively, the high power storage battery system, or alternatively, the large capacity storage battery system and the high power storage battery system.

Abstract: A method and apparatus for fast charging a battery with optimal charging. In an arrangement, a system includes a battery charger for applying a voltage to a rechargeable battery; and a controller coupled to the battery charger and monitoring at least one of a battery voltage, a battery temperature, and the current flowing into the battery; wherein the system is configured to apply a charging current from the battery charger by calculating an open cell anode voltage and an anode resistance of the battery, and determining the charging current. In additional arrangements, lithium ion plating is prevented by the charging current. Additional methods and arrangements are disclosed.

Abstract: A management device manages a secondary battery which includes a positive electrode having an active material with a characteristic where a potential flat portion exists in a relationship between a capacity and a potential. The management device includes a management unit which detects an occurrence of temporary degradation of the secondary battery when an SOC correlation associated value which is associated with an SOC of the secondary battery is acquired and the SOC which corresponds to the acquired SOC correlation associated value is equal to or less than a preset prescribed SOC or when a state value relating to a voltage of the secondary battery is acquired and a magnitude relationship between the acquired state value relating to the voltage of the secondary battery and a preset threshold value satisfies a predetermined condition.

Abstract: A storage cell includes a battery module including a plurality of unit cells; a case for housing the battery module; and a connector installed on a side-wall of the case and electrically connected to the unit cells constituting the battery module. By providing a part of the case with a cut-away portion, a connector housing space is formed. The connector protrudes from a cut-away side-wall that defines a connector housing space and is located in the connector housing space.

Abstract: Embodiments described herein relate generally to devices, systems and methods of producing high energy density batteries having a semi-solid cathode that is thicker than the anode. An electrochemical cell can include a positive electrode current collector, a negative electrode current collector and an ion-permeable membrane disposed between the positive electrode current collector and the negative electrode current collector. The ion-permeable membrane is spaced a first distance from the positive electrode current collector and at least partially defines a positive electroactive zone. The ion-permeable membrane is spaced a second distance from the negative electrode current collector and at least partially defines a negative electroactive zone. The second distance is less than the first distance.

Abstract: An exemplary battery assembly includes, among other things, a frame, and a thermal fin extending through an aperture in the frame. The thermal fin is configured to transfer thermal energy between a battery cell and a thermal exchange plate. An exemplary method of thermal energy transfer within a battery pack includes, among other things, transferring thermal energy between at least one battery cell and a thermal exchange plate using a thermal fin that extends through an aperture in a frame.

Abstract: Provided are cooling subsystems for a vehicle energy-storage system comprising a heat exchanger disposed between two battery modules. The heat exchanger can be thermally coupled to each of a plurality of cells of the battery modules at an end of each cell and fluidly coupled to a coolant system, the heat exchanger transferring heat from the plurality of cells.

Abstract: A battery module (10) having a multiplicity of battery cells (11), in particular solid electrolyte cells, a battery management system (12) for performing open-loop and/or closed-loop control of the battery cells (11). The battery cells (11) are combined in sections (13) which form a heating region (14) and have at least one associated heating element (15), wherein the heating element (15) can be open-loop and/or closed-loop controlled by the battery management system (12) in such a way that temperature control of the sections (13) can be implemented in certain regions by the respective heating element (15).

Abstract: A battery including an anode, a cathode, a separator, and a liquid electrolyte including a lithium salt, a non-aqueous solvent, and an additive compound including a functionalized matrix having a polymer or copolymer or silica. The cathode material can be an NMC or LCO material. The electrode formed from the cathode or anode material can include a matrix additive. The matrix additive can be adhered to the separator or other inert component of the battery.

Abstract: An apparatus comprises a plurality of negative electrode reservoirs configured to contain a negative electrode material, a plurality of positive electrode reservoirs configured to contain a positive electrode material and a reaction chamber. A heating system is configured to heat negative electrode material within a selected negative electrode material reservoir and to heat positive electrode material in a selected positive electrode material reservoir to maintain the electrode materials in the selected reservoirs in a fluid state while maintaining, in a non-fluid state, negative electrode material in a non-selected negative electrode reservoir and positive electrode material in a non-selected positive electrode reservoir.

Abstract: Disclosed is a battery module, which includes a plurality of battery cells, a case frame configured to accommodate the plurality of battery cells, and a case cover mounted to a front side and a rear side of the case frame to package the plurality of battery cells together with the case frame, the case cover having an anti-exposure channel provided therein to prevent a flame generated when the battery cells are ignited from being exposed to the outside.

Abstract: Systems and methods are disclosed for estimating a full-charge battery cell capacity without a coulomb counting device. First and second measured voltages of the battery cell are measured during a charging or discharging period. The first and second measured voltages of the battery cell are converted to percentages of remaining battery life. The amount of charge delivered to the battery cell and/or delivered from the battery cell during charging/discharging is calculated. The change in the percentage of remaining battery life is compared to the amount of charge delivered to the battery cell and/or delivered from the battery cell to calculate various battery cell evaluation calculations, including a full-charge battery cell capacity.

Abstract: An object of the present disclosure is to provide a solid electrolyte material with excellent ion conductivity at a low temperature. The present disclosure achieves the object by providing a solid electrolyte material to be used for a fluoride ion battery, the solid electrolyte material comprising: a solid electrolyte particle including a crystal phase, that has a Tysonite structure and contains an F element, as a main phase; and CsF; and the CsF content in the solid electrolyte material is 50% by weight or less.

Abstract: A battery system that includes a battery cell. The battery cell defines a proximal end and a distal end where the proximal end is a positive terminal and the distal end is a negative terminal. A first busbar couples to the proximal end and a second busbar couples to the distal end to complete an electrical circuit. A first energy transfer conduit carries a fluid that cools and/or heats the battery cell. The first busbar or the second busbar couple to the first cooling conduit.

Abstract: A power storage module includes power storage elements and cooling members that are in contact with the power storage elements to transfer heat. The cooling member includes an enclosing member, refrigerant, and an absorbing member absorbing the refrigerant, and the enclosing member includes a first sheet member and a second sheet member that are connected in a liquid tight manner, and the refrigerant and the absorbing member are arranged within the enclosing member. The cooling member is arranged to be inclined with respect to a horizontal plane such that a section thereof being in contact with the power storage element to transfer heat is on a lower level.

Abstract: The present invention provides an aqueous redox flow battery comprising a negative electrode immersed in an aqueous liquid negative electrolyte, a positive electrode immersed in an aqueous liquid positive electrolyte, and a cation-permeable separator (e.g., a porous membrane, film, sheet, or panel) between the negative electrolyte from the positive electrolyte. During charging and discharging, the electrolytes are circulated over their respective electrodes. The electrolytes each comprise an electrolyte salt (e.g., a lithium or sodium salt), a redox reactant. The negative redox reactant comprises a pyridinium compound of Formula (I) as described in the specification.

Abstract: Provided is a Na based secondary battery including: an anode containing sodium or a sodium alloy; a cathode containing a metal halide, which is a halide of at least one metal selected from a group consisting of alkali metals, transition metals, and Groups 12 to 14 metals, and a solvent dissolving the metal halide; and a sodium ion conductive solid electrolyte separating the cathode and the anode from each other.

Abstract: According to one embodiment, an electronic device includes a housing, an antenna, and a sheet metal member. The antenna is contained in the housing with a gap formed between the antenna and the housing. The sheet metal member is supporting the antenna to be thermally connected with the antenna.

Abstract: The invention relates to a battery system, in particular for a hybrid drive, comprising a housing and a plurality of battery cells arranged within the housing, said cells being combined to give a cell block, wherein a container having a variable inner volume is arranged between the cell block and at least one housing wall, by means of which container the cell block can be braced relative to the housing, wherein the container is filled with a curable or cured medium.

Abstract: An improved battery monitoring system for liquid electrolyte batteries is provided. The battery monitoring system includes a network of sensors for monitoring the condition or performance of a plurality of liquid electrolyte batteries, for example lead-acid batteries. The sensors are adapted to share data regarding battery condition or battery performance to a standalone device over a wireless local area network. A server in electrical communication with the standalone device receives some or all of the data for analysis, which can result in maintenance alerts and other alerts being sent to the standalone device. The improved battery monitoring system can reduce or eliminate the manual inspection of lead-acid batteries and can improve battery operation and longevity by ensuring an appropriate level of maintenance for each lead-acid battery.

Abstract: A method for monitoring a state of at least one predetermined battery cell of a battery having a number of series-connected or series-connectable battery cells. In one example, the method includes placing the battery, during a first phase, into a first state in which the battery cells in each case have a predefined charging state, discharging the battery, which is in the first state, during a second phase following the first phase, charging the battery during a third phase, following the second phase, up to a point in time at which at least one battery cell of the battery has the predefined charging state, detecting the voltage provided by the at least one predetermined battery cell at least temporarily, and determining information for detecting the state of the at least one predetermined battery cell by evaluating the detected voltage.

Abstract: The present disclosure relates to a method for making a lithium-sulfur battery separator. The method comprises providing a separator substrate, and forming a functional layer on at least one surface of the separator substrate. A method for forming the functional layer comprises applying a first carbon nanotube layer on the at least one surface; dispersing a plurality of graphene oxide sheets and a plurality of manganese dioxide nanoparticles in a solvent to form a mixture; and depositing the mixture on a surface of the first carbon nanotube layer to form a first graphene oxide composite layer; applying a second carbon nanotube layer on a surface of the first graphene oxide composite layer; and forming a second graphene oxide composite layer on a surface of the second carbon nanotube layer.

Abstract: A method for managing an authorized operating range of a battery, the authorized operating range being limited between a minimum level and a maximum level of state of charge of the battery. The method includes estimating a state of health in power of the battery, the state of health in power characterizing capacity of the battery to supply a minimum required power level across an entirety of the operating range; and determining the minimum level of state of charge of the battery in accordance with the estimated state of health in power, the minimum level of state of charge being increased when the state of health in power decreases.

Abstract: A power supply system includes a first energy storage, a second energy storage, a power transmission circuit, and circuitry. The circuitry acquires a request supply amount, a request output amount, and failure detection information. The circuitry controls the power transmission circuit in accordance with the at least one of the request supply amount and the request output amount such that a ratio of an amount of electric power supplied from or to the first energy storage and an amount of electric power supplied from or to the second energy storage is to be a first ratio in a normal operating. The circuitry controls the power transmission circuit in accordance with the at least one of the request supply amount and the request output amount such that the ratio is to be a second ratio which is different from the first ration in a partial failure state.

Abstract: A battery management device includes an SOC estimation unit, a storage unit, and a lithium deposition determination unit. The lithium deposition determination unit compares a differential coefficient of a battery voltage with respect to an SOC estimated by the SOC estimation unit and a differential coefficient of a battery voltage with respect to a reference SOC read from the storage unit, and determines that, if a difference is observed between the differential coefficients, lithium is deposited in a lithium ion secondary battery.