Abstract: A FET is formed on a semiconductor substrate, a curved surface having a radius of curvature is formed on an upper end of an insulation, a portion of a first electrode is exposed corresponding to the curved surface to form an inclined surface, and a region defining a luminescent region is subjected to etching to expose the first electrode. Luminescence emitted from an organic chemical compound layer is reflected by the inclined surface of the first electrode to increase a total quantity of luminescence taken out in a certain direction.

Abstract: A method for producing an organic electroluminescent element including a transparent substrate, a transparent electrode, an organic functional layer unit, and an electrode counter to the transparent electrode disposed in sequence, the method including: forming a preform of an element satisfying the following expression: ?Exy?0.05, wherein 0° is an angle orthogonal to the transparent substrate and ?Exy represents a chromaticity difference of a reflected color measured at a tilted angle within a range of 0 to 80° with respect to the transparent substrate; and irradiating a specific region of the preform of the element with light.

Abstract: The present disclosure discloses a battery pouch that includes a cavity. The battery pouch also includes a first transition between a first side of the battery pouch and a second side of the battery pouch. The first side of the battery pouch includes a first sealed portion having a minimum threshold distance between the cavity and the edge of the battery pouch. More specifically, the first sealed portion is located between a first outer edge of the cavity and a first outer edge of the battery pouch. The battery pouch also includes a second side having a second sealed portion with minimum threshold distance. Other embodiments are also described and claimed.

Abstract: An electrochemical device includes a plurality of electrode assemblies arranged spaced apart from each other in a same direction and a casing member which packages the electrode assemblies, in which the casing member includes a plurality of accommodation portions which accommodates the electrode assemblies, respectively, and a connecting portion which connects between two adjacent accommodation portions, a thickness of the connecting portion is less than a thickness of the accommodation portions, and the connecting portion is bent defining a curved bending portion.

Abstract: There is provided a pouch-type battery that includes an exterior packaging member having an accommodating space in which an electrode and an electrolyte are accommodated and which has a curved shape at least in a first direction. The exterior packaging member includes a first film member on which a cup section having the accommodating space inside is provided, a second film member disposed to face the first film member, and a sealing section around the cup section, with which the first and second film members are bonded to each other and the accommodating space is sealed. A top surface of the cup section of the first film member has a curved shape and is provided with a plurality of concave portions or convex portions, and the sealing section has a curved shape in the first direction and is configured of a flat surface on which neither concave portion nor convex portion is provided.

Abstract: A packaging film is formed by a laminated film including a plurality of layers, and is configured to be bent into a tube-shape to form a tube-type packaging member having flexibility. Further, the packaging film includes an innermost layer, an outermost layer, and a barrier layer arranged between innermost layer and the outermost layer, as the plurality of layers. The barrier layer is a metallic layer. The innermost layer and the outermost layer are each formed by a thermal fusion resin layer. An adhesive agent bonding overlapped adjacent layers of the plurality of layers has electrolyte resistance.

Abstract: There is provided an energy storage device including: an electrode body; a lid portion; and a case main body having a body portion in a shape of a container which is open on one end side and for housing the electrode body inside itself and a sealing portion for surrounding and retaining the lid portion from an outer periphery on the opening side of the body portion, wherein an outside diameter of the sealing portion is smaller than an outside diameter of the body portion.

Abstract: A battery module includes a housing that defines an inner volume and includes an airflow path from an aperture formed in a first end member of the housing, through the inner volume, and to an aperture formed in a second end member of the housing; a plurality of power cells mounted in the inner volume of the housing, each of the power cells including a vent member at an end of the power cell; and a flame arrestor mounted across the airflow path and between the plurality of power cells and the aperture formed in the second end member of the housing. The flame arrestor includes a screen that includes a plurality of fluid pathways sized to allow an airflow from the airflow path through the fluid pathways and sized to impede a combusted fluid to pass therethrough.

Abstract: A modular battery pack system includes a chassis for selective insertion and removal of a plurality of battery cells. The chassis includes a plurality of battery cell compartments, a backplane assembly, and one or more mechanical actuators. The plurality of battery cell compartments are each configured to receive a battery cell. The backplane assembly is configured to provide electrical connection from one or more batteries in the plurality of battery cell compartments to a load. The one or more mechanical actuators are configured to selectively establish electrical communication between the backplane assembly and the one or more batteries when the battery cell is within one of the plurality of battery compartments.

Abstract: A first end plate is disposed at one end, in a stacking direction, of a stacked body of secondary battery cells. A second end plate is disposed at the other end, in the stacking direction, of the stacked body of the secondary battery cells. A restraining member is joined to the first end plate and the second end plate. The restraining member applies, to the first end plate and the second end plate, restraint loads that sandwich and restrain the stacked body from both sides in the stacking direction. The first end plate is movable relative to the second end plate in the state where the restraining member is joined to both the first end plate and the second end plate.

Abstract: Present embodiments include a lithium ion battery module having a lineup of prismatic lithium ion battery cells positioned within a cell receptacle area of a housing of the lithium ion battery module. The prismatic battery cells of the lineup are spaced apart from one another in a spaced arrangement by fixed protrusions extending from internal surfaces of the housing forming the cell receptacle area, and the fixed protrusions extend inwardly to form a plurality of discontinuous slots across a width of the cell receptacle area.

Abstract: An electronic device having a semi-rigid battery pack is disclosed. The semi-rigid battery pack offers an internal power supply with relatively high energy density (energy per volume) with a stiff cover covering the battery pack to shield other internal components from the battery pack. The cover may also be formed with a larger dimension than that of the battery pack such that when the battery pack undergoes a swelling event, the battery pack increases its volume while still be contained by the cover. In this manner, other internal components may be positioned proximate to the cover without being affected by the battery pack. In another embodiment, a mold member covers an outer peripheral portion and supports the battery pack while allowing the battery pack to undergo a swelling event.

Abstract: A traction battery assembly for a vehicle includes an array of cells stacked on a tray. The array of cells defines opposing longitudinal sides and opposing lateral sides. First and second L-shaped components are attached to the tray. Each of the components includes an end wall and a sidewall that are integrally formed to define a substantially 90° corner. The first and second components are attached together such that each of the sidewalls is disposed adjacent one of the longitudinal sides and each of the end walls is disposed adjacent one of the lateral sides to form a housing around the tray that has an open top and an open bottom.

Abstract: Present embodiments include a series of lithium battery modules having a plurality of electrochemical cells having different electrical characteristics such as voltages and/or capacities. The battery modules are each constructed using components, architectures, production methods, among other things, in common with each other. The lithium ion battery modules may include a first battery module type having a first capacity and a first voltage, a second battery module type having a second capacity and a second voltage, and, in some embodiments, additional battery module types (e.g., a third battery module type having a third capacity and a third voltage) having different voltages and/or capacities. The lithium ion battery modules may all have the same footprint.

Abstract: A battery module includes a housing including a first interior surface, a second interior surface opposite the first interior surface, and a compressed cell assembly disposed within an interior space of the housing between the first and second interior surfaces. The compressed cell assembly includes a plurality of prismatic battery cells arranged in a cell stack that includes a first end, a second end opposite the first end, and a retaining wall disposed between the first end of the cell stack and the first interior surface of the housing. The retaining wall includes a first surface in contact with the first end of the cell stack and a second surface opposite the first surface that contacts the first interior surface of the housing. The first and second interior surfaces are configured to maintain the compressed cell assembly in a compressed state having a compression force above a predetermined threshold.

Abstract: A battery module includes a housing configured to receive a plurality of electrochemical cells, a skeletal frame coupled with the housing, and a framework disposed proximate to the skeletal frame. Moreover, the framework is substantially aligned with the skeletal frame and configured to transfer a force applied to the framework to the skeletal frame.

Abstract: The present disclosure includes a battery module that includes a plurality of lithium ion battery cells disposed within a battery module packaging. Each of the plurality of lithium ion battery cells is individually held in place within the battery module packaging by a restraining medium. The restraining medium conformally covers a substantial portion of the surface of each of the plurality of lithium ion battery cells and prevents each of the plurality of lithium ion battery cells from expanding during operation of the battery module.

Abstract: Present embodiments include a lithium ion battery module having a lineup of prismatic lithium ion battery cells positioned within a cell receptacle area of a housing of the lithium ion battery module. The prismatic battery cells of the lineup are spaced apart from one another in a spaced arrangement by fixed protrusions extending from internal surfaces of the housing forming the cell receptacle area, and the fixed protrusions extend inwardly to form a plurality of discontinuous slots across a width of the cell receptacle area.

Abstract: A battery module of the present invention includes: a battery group configured of a plurality of cylindrical batteries; a holder configured to retain the battery group so that the respective batteries are bundled in parallel to each other; and a casing being closed by the holder and including a storing space for housing the battery group, wherein the casing includes an opposing wall portion facing the holder, the opposing wall portion includes hole portions that retain the batteries by peripheries or inner circumferential surfaces of the hole portions, and guiding portions formed on the peripheries or the inner circumferential surfaces of the hole portions and configured to guide the batteries by causing the batteries to come closer to centers of the hole portions, such that central axis lines of the batteries pass through the centers of the hole portions, upon when the batteries are inserted into the storing space.

Abstract: Present embodiments include a lithium ion battery module and associated lithium ion battery cells. The lithium ion battery cells include a prismatic cell casing enclosing electrochemically active components. The cell thickness, the cell width, the cell length, and the electrochemically active components are such that the lithium ion battery cell has a volumetric energy density between 82 Watt-hours per Liter (Wh/L) and 153 Wh/L, and has a nominal voltage between 2.0 V and 4.2 V.

Abstract: An energy storage apparatus includes: a housing which has a container body and a lid portion provided with external connection terminals; an energy storage module which is arranged in the housing, the energy storage module having a cell stack; a bolt which restricts movement of the energy storage module with respect to a bottom wall of the container body; and a support member which restricts movement of the energy storage module with respect to the lid portion.

Abstract: A battery module mounting system includes a housing of the battery module configured to receive a plurality of electrochemical cells, a lid coupled to a side of the housing, and a cage configured to secure the housing to a vehicle. Additionally, the cage includes a coupling mechanism configured to engage with the lid in a tongue and groove configuration to block movement of the housing in at least three directions when engaged.

Abstract: A battery module includes a housing having an interior defined by multiple sides, one side of which is a lid. The battery module also includes lithium ion electrochemical cells disposed in the housing, each cell having a vent through which gases may be vented. Moreover, the battery module includes a first chamber defined by interior aspects of the housing. Furthermore, the first chamber receives vented gases directed in a first direction from the electrochemical cells. In addition, the battery module includes a surface of the first chamber. The surface is configured to direct the vented gases in a second direction. The battery module also includes a second chamber defined partially by the lid. The second chamber receives the vented gases from the first chamber and directs the vented gases from the housing.

Abstract: A separator according to the embodiment includes a porous base material having a thermoplastic resin. The porous base material has a heat-resistant porous layer on at least one surface thereof. The heat-resistant porous layer contains inorganic particles, a resin, and sulfur. A lithium ion secondary battery according to the embodiment, includes: the separator interposed between a positive electrode and a negative electrode; and an electrolyte solution. The heat-resistant porous layer is disposed between the positive electrode and the porous base material. Sulfur is distributed unevenly in the heat-resistant porous layer so as to exist in larger amount near a surface thereof opposite to the porous base material.

Abstract: An energy storage device includes: an electrode having a composite layer formed by applying a composite directly or indirectly onto a substrate and a non-applied portion, onto which the composite is not applied; and a separator layered on the electrode to face the composite layer. Here, a drawn area is formed in at least. a part of the non-applied portion, and an intermediate layer is interposed at least between the drawn area and the composite layer.

Abstract: An energy storage device includes a positive electrode provided with a positive composite layer containing a positive active material, a negative electrode provided with a negative composite layer containing a negative active material, and a separator partitioning between the positive electrode and the negative electrode, wherein the separator includes a substrate uniaxially drawn into a sheet shape and a coating layer coating at least one of surfaces of the substrate, and the coating layer has an anisotropic structure with orientation in a direction different from a drawing direction of the substrate.

Abstract: A power supply system for a portable electronic device is disclosed. The power supply system includes a number of battery cells distributed between a number of structural support members of a housing of the portable electronic device. The battery cells of the power supply can be separated so that they can be individually installed between the structural support members of the housing. After installing the battery cells a battery busbar of the power supply system can be subsequently slid through openings defined by the structural support members so that the battery busbar can electrically couple together battery cells separated by structural support members. The battery busbar can also be electrically coupled to a battery management unit of the power supply system, which can also be separated from the battery cells by a structural support member.

Abstract: A battery module includes a housing having an opening and a plurality of electrochemical cells disposed in the housing. The plurality of electrochemical cells have electrode terminals. The battery module also includes a carrier defined by an outside boundary and coupled to the plurality of electrochemical cells. The outside boundary of the carrier and the housing are in a nested arrangement. The battery module also includes a bus bar assembly disposed on the carrier, the bus bar assembly includes bus bars that electrically couple the electrode terminal of one of the plurality of electrochemical cells to a respective electrode terminal of another one of the plurality of electrochemical cells.

Abstract: The present disclosure includes a battery module having a first electrochemical cell with a first terminal and a second electrochemical cell having a second terminal. The battery module also includes a bus bar connection electrically connecting the first and second electrochemical cells. The bus bar connection includes a first adapter covering at least a portion of the first terminal of the first electrochemical cell, where the first adapter includes a first recess positioned proximate to the first terminal, and a second adapter covering at least a portion of the second terminal of the second electrochemical cell, where the second adapter includes a second recess positioned proximate to and at least partially aligned with the first recess. Further, the bus bar connection includes a bus bar that spans between the first recess of the first adapter and the second recess of the second adapter to create an electrical path.

Abstract: A bus bar module of the present invention is disposed on one end side of each battery in a battery group consisting of a plurality of batteries having terminals at their ends in a longitudinal direction. The bus bar module includes a bus bar made of a conductive metal and electrically connecting the terminals of the respective batteries in the battery group; and an insulating laminate portion that is laminated, at least on an inner surface of the bus bar, among the inner surface facing the ends of the batteries and an outer surface on an opposite side of the inner surface of the bus bar. The insulating laminate portion has an insulating material comprising thermoplastic elastomer and/or rubber.

Abstract: A rechargeable battery, includes an electrode assembly including a first electrode and a second electrode; a case for accommodating the electrode assembly; a cap plate in an opening of the case to seal the case, including a terminal hole, and connected to the first electrode through a lead tab; and first and second electrode terminals electrically coupled to the electrode assembly and protruding away from the cap plate, the first electrode terminal including plurality of lead terminals connected to the cap plate, and a plate terminal supported by the plurality of lead terminals to be spaced apart from the cap plate.

Abstract: A rechargeable battery includes an electrode assembly including a first electrode and a second electrode, a case for accommodating the electrode assembly, a cap plate in an opening of the case to seal the case, and electrode terminals electrically coupled to the electrode assembly, each electrode terminal having a rivet terminal extending through a terminal hole in the cap plate, a first end of the rivet terminal being electrically coupled to the electrode assembly, and a second end of the rivet terminal protruding out of the cap plate and including a protruding portion, and a conductive terminal coupled to the protruding portion of the rivet terminal, the conductive terminal and the protruding portion of the rivet terminal including different metals.

Abstract: A rechargeable battery includes a case; an electrode assembly accommodating the case; a cap plate sealing an opening of the case; terminals electrically coupled to the electrode assembly and penetrating the cap plate; terminal plates on the cap plate and coupled to a respective one of the terminals; and a connecting member including a sinuous body located between the cap plate and the terminal plate to electrically couple the cap plate and the terminal plate.

Abstract: A battery terminal includes a terminal body and a component terminal. The terminal body is connected to a rod-like electrode which projects from a terminal mounting surface of a battery and extends toward an outer periphery of the terminal mounting surface. An external fuse (electrical component) is connected to the component terminal. The terminal body and the component terminal are formed by being cut integrally from a single plate made of a conductive metal.

Abstract: A battery terminal includes a terminal main body provided in opposed plates thereof as a pair, formed by folding approximately in a U shape a strip plate made of a conductive metal, respectively with electrode insertion holes in which a rod-like electrode projecting from a terminal attaching surface in a battery is sequentially inserted, and formed to extend toward an outer edge of the terminal attaching surface at time of being connected to the rod-like electrode, and a joint joining the pair of the opposed plates in a state in which the opposed plates surface-contact and overlap each other on an opposite side of a folded part as seen from the electrode insertion hole.

Abstract: The present disclosure includes a battery module having a housing configured to receive one or more electrochemical cells. The housing includes a bottom internal surface and a recessed portion disposed in the bottom internal surface and proximate to a low point on the bottom internal surface, wherein the recessed portion defines an airspace configured to retain fluid within the housing away from the one or more electrochemical cells.

Abstract: A li-ion battery with replaceable electrodes is provided. The battery compromises operation space to make the electrode sheets replaceable and side chamber to vent electrolyte through electrolyte pipeline for stopping reactions inside the battery.

Abstract: A method for the manufacturing of electrodes with at least one porous surfacial layer comprising anisotropic electrochemically active particles. It also relates to electrodes made using such a method. The method comprises the following steps: (a) coupling of paramagnetic nanoparticles to said active particles for the generation of composites; (b) preparation of a slurry of said composites, including a solvent mixed with a binder able to release a volatile component; (c) application of said slurry to a substrate to form a film; (d) application of a magnetic field to the film and orienting said active particles leading to a substrate in which said active particles are arranged with their shortest axes aligned along a preferred axis parallel to said substrate; (e) during or after application of said magnetic field evaporation of said solvent with solidification of the binder and release of said volatile component under formation of said surfacial layer.

Abstract: A method and apparatus for manufacturing electrochemical cells. The apparatus and method includes the modification of solid phase material used in electrochemical cells, such as batteries, into a viscous phase for ease of metering and dispensing onto a hot wall reactor to create a substantially uniform cloud of vapor to be deposited on a substrate or other stacks of cells in a continuous or semi-continuous process and having the useful advantage of depositing large volumes of materials for economical manufacturing.

Abstract: In an example, the present invention provides a method for forming a film of material for a solid state battery or other energy storage device. The method includes providing a first precursor species, and providing a second precursor species. The method also includes transferring the first precursor species through a first nozzle and outputting the first precursor species in a first molecular form and transferring the second precursor species through a second nozzle and outputting the second precursor species in a second molecular form. The method includes causing formation of first plurality of particles, ranging from about first diameter to about a second diameter, by intermixing the first precursor species with the second precursor species. The method also includes cooling the first plurality of particles at a rate of greater than 100° C./s to a specified temperature.

Abstract: An electrode complex includes: a complex which includes a porous active material molded body which is formed by being three-dimensionally connected with a plurality of particulate active material particles containing a lithium double oxide and a plurality of particulate noble metal particles containing a noble metal with a melting point of 1000° C. or higher and includes a communication hole, and a solid electrolyte layer formed on the surface of the active material molded body containing the communication hole of the active material molded body; and a current collector which is provided by being bonded to the active material molded body on one surface of the complex.

Abstract: A method of preparing a homogeneously dispersed chlorine-modified lithium manganese-based AB2O4 spinel cathode material is provided. Furthermore, a homogeneously dispersed chlorine-modified lithium manganese-based AB2O4 spinel cathode material is provided. In addition, a lithium or lithium ion rechargeable electrochemical cell is provided incorporating a homogeneously dispersed chlorine-modified lithium manganese-based AB2O4 spinel cathode material in a positive electrode.

Abstract: A positive electrode collector includes a main body layer and a surface layer. The surface layer is provided at least at a portion of a surface of the main body layer where the positive electrode mixture layer is provided, and is made of a carbon material. A first positive electrode active material is made of first lithium complex oxide having a layered crystal structure. A second positive electrode active material includes a particle made of second lithium complex oxide having an olivine crystal structure, a carbon film provided at least at a part of a surface of the particle, and alginic acid salt provided at least at a part of a surface of the carbon film. A conducting agent in the positive electrode mixture layer includes a carbon particle and alginic acid salt provided at least at a part of a surface of the carbon particle.

Abstract: An electrode material including electrode active material particles having a carbonaceous film formed on the surfaces thereof in which the coatability of the carbonaceous film can be guaranteed even when a crushing process is carried out, and the rate characteristics and the like are not degraded during charge and discharge, an electrode and a lithium ion battery having excellent charge and discharge characteristics for which the electrode material is used are provided. The electrode material includes electrode active material particles having a carbonaceous film formed on surfaces thereof, and an affinity value to N-methyl-2-pyrrolidone measured through pulse NMR is in a range of 5000 to 20000.

Abstract: A negative active material including: a composite particle including a non-carbonaceous nanoparticle that allows lithiation and delithiation of lithium ions, and a (meth)acryl polymer disposed on a surface of the non-carbonaceous nanoparticle; and a crystalline carbonaceous nanosheet.

Abstract: Disclosed is a method for manufacturing an electrode, which comprises drying an electrode sheet including a current collector and an electrode active material slurry coated to the current collector and containing an electrode active material, a binder and a solvent, wherein the electrode sheet is dried by a mid-infrared lamp which irradiates mid-infrared rays with a wavelength of 1 ?m to 3 ?m to the electrode sheet, and a surface temperature of the electrode sheet has a constant region in the range of 50° C. to 70° C. Since an electrode is dried by using a mid-infrared lamp, the electrode may be uniformly dried, and an adhesion force between the electrode active material layer and the current collector may be greatly improved, which allows great enhancement of characteristics of a battery to which the electrode is applied.

Abstract: Spherical particles comprising (A) at least one mixed transition metal hydroxide or mixed transition metal carbonate of at least 3 different transition metals selected from nickel, cobalt, manganese, iron, chromium and vanadium, (B) at least one fluoride, oxide or hydroxide of Ba, Al, Zr or Ti, where the transition metals in transition metal hydroxide (A) or transition metal carbonate (A) are predominantly in the +2 oxidation state, where fluoride (B) or oxide (B) or hydroxide (B) is present to an extent of at least 75% in an outer shell of the spherical particles in the form of domains and is encased to an extent of at least 90% by transition metal hydroxide (A) or transition metal carbonate (A).

Abstract: Provided is a lithium secondary battery using a positive electrode active material which operates at a charging voltage in a region exceeding 4.3 V, and a novel positive electrode active material for a lithium secondary battery which can further enhance the output characteristics. Proposed is a positive electrode active material for a lithium secondary battery including positive electrode active material particles obtained by equipping the entire surface or a part of the surface of lithium manganese-containing composite oxide particles (also referred to as the “core particles”) operating at a charging voltage in a region exceeding 4.3 V in a metal Li reference potential with a layer A containing at least Ti, Al, Zr, or two or more kinds of these, and C.

Abstract: Provided herein are methods of processing electrode active material structures for use in electrochemical cells or, more specifically, methods of forming surface layers on these structures. The structures are combined with a liquid to form a mixture. The mixture includes a surface reagent that chemically reacts and forms a surface layer covalently bound to the structures. The surface reagent may be a part of the initial liquid or added to the mixture after the liquid is combined with the structures. In some embodiments, the mixture may be processed to form a powder containing the structures with the surface layer thereon. Alternatively, the mixture may be deposited onto a current collecting substrate and dried to form an electrode layer. Furthermore, the liquid may be an electrolyte containing the surface reagent and a salt. The liquid soaks the previously arranged electrodes in order to contact the structures with the surface reagent.

Abstract: Described here is a method for making an anode of a rechargeable battery, comprising incorporating a composition comprising LixM into the anode, wherein M is a Group 14 element. Also described here is an anode comprising a composition comprising LixM, wherein M is a Group 14 element, and a rechargeable battery comprising the anode.