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BATTERY HIGH-VOLTAGE BOX, BATTERY PACK, AND VEHICLE

Resumen de: US20260116221A1

A battery high-voltage box, a battery pack, and a vehicle. The battery high-voltage box includes a battery positive interface, a battery negative interface, a power transmission main circuit, a controlled switch module, and a precharge circuit. The power transmission main circuit is connected to the battery positive interface and the battery negative interface respectively, the controlled switch module is disposed on the power transmission main circuit, and the precharge circuit is connected in parallel with the controlled switch module; the precharge circuit, when in a conductive state, is configured to precharge an external load, such that the external load can be precharged through the precharge circuit in the battery high-voltage box.

ELECTRODE ASSEMBLY STRUCTURE, SECONDARY BATTERY, AND METHODS OF MANUFACTURE

Resumen de: US20260121221A1

“electrode assembly having a porous electrically insulating material, and first and second endplates. The electrode assembly comprises opposing first and second longitudinal end surfaces separated along a stacking direction of an electrode and a counter electrode of the electrode assembly. First and second endplates are separated in the stacking direction and overlie the first and second longitudinal end surfaces.”

ANODE HAVING HIGH TOP LAYER SPHERICITY

Resumen de: US20260121029A1

0000 Anodes having high top layer sphericity may include a first active material layer including a plurality of first active material particles having a first particle sphericity and a first particle size layered onto and directly contacting a current collector, and a second active material layer including a plurality of second active material particles having a second particle sphericity and a second particle size layered onto and directly contacting the first layer. The second particle sphericity is greater than the first particle sphericity. In some examples, the second particle size is greater than the first particle size.

POSITIVE ELECTRODE MATERIAL PRECURSOR AND PREPARATION METHOD AND APPLICATION THEREOF

Resumen de: US20260121041A1

0000 A positive electrode material precursor and a preparation method thereof and an application thereof are provided. The positive electrode material precursor is a core-shell structure, including an inner core, an outer shell, and an intermediate layer provided between the inner core and the outer shell; where the inner core is formed by accumulating a first sheet-like material, and the first sheet-like material is formed by stacking a plurality of layers of a primary sheet-like material; the intermediate layer is formed by accumulating the primary sheet-like material; the outer shell is formed by accumulating a second sheet-like material, and the second sheet-like material is formed by stacking a plurality of layers of the primary sheet-like material; and a layer number of the layers of the primary sheet-like material in the second sheet-like material is less than that in the first sheet-like material.

ELECTROCHEMICAL DEVICE AND ELECTRONIC DEVICE

Resumen de: US20260121068A1

An electrochemical device includes a negative electrode plate. The negative electrode plate includes a negative electrode current collector, a first negative electrode active material layer, and a second negative electrode active material layer, and the first negative electrode active material layer is located between the negative electrode current collector and the second negative electrode active material layer. The first negative electrode active material layer includes a first silicon-based material, the second negative electrode active material layer includes a second silicon-based material, Dv10 of the first silicon-based material is 3 μm to 10 μm, Dv10 of the second silicon-based material is 1 μm to 4 μm, and Dv10 refers to a particle size corresponding to a cumulative volume percentage of 10% in a volume-based particle size distribution starting from small particles.

Battery Extinguishing Container

Resumen de: US20260121217A1

An energy storage container is proposed which comprises an exhaust air outlet and a feed device. The feed device is arranged to add a dilution fluid to the fire fluid flowing through the exhaust air outlet in the event of a fire.

SYSTEMS AND METHODS FOR DETECTION OF BATTERY DEFORMATION

Resumen de: US20260121140A1

A battery pack comprising a housing defining a volume. The battery pack includes a battery module arranged within the housing, where the battery module comprises a plurality of battery cells configured to provide an electrical output. The battery pack includes a first detector positioned within the battery module proximate to the plurality of battery cells, where the first detector is configured to detect a deformation of one of the plurality of battery cells to identify a potential thermal runaway.

POSITIVE ELECTRODE ACTIVE MATERIAL AND PREPARATION METHOD AND USE THEREOF

Resumen de: US20260121034A1

A positive electrode active material, and a preparation method and a use thereof. The chemical formula of the positive electrode active material is Li1+aNaxPyNi0.5+bMn1.5+cMzOd, where −0.1≤a≤0.2, −0.2≤b≤0.2, −0.2≤c≤0.2, 3.8≤d≤4.3, 0

OXIDE PRECURSOR AND PREPARATION METHOD AND APPLICATION THEREOF

Resumen de: US20260121045A1

0000 An oxide precursor, a preparation method thereof, and an application thereof are provided. The oxide precursor has a chemical general formula of NiCoMnAlMO, where 0

ENERGY STORAGE BATTERY CABINET AND ENERGY STORAGE SYSTEM HAVING SAME

Resumen de: US20260121196A1

An energy storage battery cabinet includes: a cabinet body and at least two battery cell layer groups. The cabinet body has a first direction, a second direction, and a third direction which are substantially orthogonal to each other. The at least two battery cell layer groups are disposed in the cabinet body along the third direction. Each of the at least two battery cell layer groups includes at least one battery cell in each of the first direction and the second direction. Two adjacent battery cell layer groups of the at least two battery cell layer groups in the third direction abut against each other.

Binder for Anode for Secondary Battery, Anode for Secondary Battery Including Binder, and Lithium Secondary Battery Including Anode

Resumen de: US20260121053A1

0000 The present invention relates to a binder for an anode for a secondary battery, an anode including the binder, and a secondary battery including the anode. More particularly, the present invention relates to a binder for an anode for a secondary battery that has excellent heat resistance and mechanical properties and an improved binding force because a copolymer is used for the binder, and an anode for a secondary battery. In addition, expansion and shrinkage of the anode may be efficiently suppressed, such that charge and discharge life characteristics and performance of the secondary battery may be improved.

Battery and Electronic Device

Resumen de: US20260121128A1

In a circumference direction of a roll core of a battery cell of a battery, a positive electrode tab is electrically connected to a positive electrode plate at a first location, and a negative electrode tab is electrically connected to a negative electrode plate at a second location, where a winding end of the positive electrode plate extends beyond a winding end of the negative electrode plate, and the first location is any location at which the positive electrode plate extends beyond the winding end of the negative electrode plate. A part of the positive electrode plate between the second location and the first location is a positive electrode extension section, at least an inner surface of the positive electrode extension section is passivated, and the inner surface is a surface of a side that is of the positive electrode extension section and that faces the negative electrode plate.

ROLL STACKING DEVICE FOR SECONDARY BATTERIES

Resumen de: US20260116674A1

A roll stacking device for secondary batteries according to the present embodiment comprises: an input conveyor for transferring cells; a discharge conveyor spaced apart from the input conveyor; and a roll module having rolls for stacking the cells transported by the input conveyor on the upper side of the discharge conveyor in a forward-backward direction, wherein the rolls include a roll body on which at least one cell seating portion is formed and an adsorption pad which is mounted on the roll body and adsorbs the cells.

A METHOD FOR SEPARATING MANGANESE IN LEACHING OF COBALT AND/OR NICKEL FROM DELITHIATED SOLID RAW MATERIAL AND USE OF DELITHIATED SOLID RAW MATERIAL COMPRISING CATHODE MATERIAL

Resumen de: US20260116775A1

The present disclosure provides a method for separating manganese in leaching of cobalt and/or nickel from delithiated solid raw material, the method comprising providing delithiated solid raw material comprising cobalt and/or nickel, providing5 acidic solution, combining the delithiated solid raw material with the acidic solution, allowing cobalt and/or nickel in the delithiated solid raw material to leach to obtain a leach solution comprising cobalt and/or nickel, providing manganese in the leach solution as the only reducing agent, and allowing the manganese to precipitate as manganese dioxide while the cobalt and/or nickel are dissolved. The present0 disclosure also provides use of delithiated solid raw material comprising cathode material in the method.

CATHODE ACTIVE MATERIAL AND PREPARATION METHOD THEREOF, CATHODE PLATE, BATTERY, AND ELECTRICAL DEVICE

Resumen de: US20260121042A1

Provided are a cathode active material and a preparation method thereof, a cathode plate, a battery, and an electrical device. The cathode active material includes a plurality of primary particles. The equivalent number N(003) of (003) crystallographic planes and the equivalent number N(104) of (104) crystallographic planes of the cathode active material satisfy: N(003)*N(104) ranges from 1*104 to 3*104;N(003)=D(003)d(003);and⁢N(1⁢0⁢4)=D(1⁢0⁢4)d(1⁢0⁢4),where: D(003) is an average thickness of crystallites in the cathode active material perpendicular to the (003) crystallographic plane, in nm; d(003) is an interplanar spacing of the (003) crystallographic planes in the crystallites of the cathode active material, in nm; D(104) is an average thickness of the crystallites in the cathode active material perpendicular to the (104) crystallographic plane, in nm; and d(104) is an interplanar spacing of the (104) crystallographic planes in the crystallites of the cathode active material, in nm.

COMPOSITE CATHODE MATERIAL COMPRISING CERAMIC OXIDE ELECTROLYTE, LITHIUM ELECTRODE MATERIAL AND ENHANCING AGENT

Resumen de: US20260121062A1

The present invention relates to a solid composite cathode material comprising a ceramic oxide electrolyte material and a lithium electrode material. It was found that the addition of lithium halide to the selected electrolyte and cathode materials strongly enhances the electrochemical performance.

ELECTROCHEMICAL DEVICE AND ELECTRONIC DEVICE

Resumen de: US20260121022A1

An electrochemical device includes a positive electrode, a negative electrode, and an electrolyte. The positive electrode includes a positive active material layer. The positive active material layer includes a first powder and a second powder. After the electrochemical device is fully discharged, an X-ray diffraction pattern of the positive active material layer exhibits a first diffraction peak in a diffraction angle 2θ range of 17.3° to 19.3°, and exhibits a second diffraction peak in a 2θ range of 19.8° to 21.8°.

PRODUCING METHOD OF SHEET FOR SOLID SECONDARY BATTERY, BINDER FOR ELECTRODE FOR SOLID SECONDARY BATTERY, ELECTRODE-PRODUCING COMPOSITION, ELECTRODE MIXTURE, AND ELECTRODE

Resumen de: US20260121106A1

0000 Method for producing a solid-state secondary battery electrode, using PTFE, capable of reducing resistance of the electrode and achieving strength of a positive electrode mixture sheet, and a binder. Method for producing a solid-state secondary battery sheet, including (1) preparing a composition for producing a secondary battery sheet by using a binder that is a powder which comprises a polytetrafluoroethylene resin and a conductive aid homogeneously mixed and which is free of an active material, and (2) applying a shear force while mixing the composition for producing a secondary battery sheet to obtain an electrode mixture, wherein step (2) is carried out with a content of a solvent in the composition for producing a secondary battery sheet being 10% by mass or less.

PRODUCING METHOD OF ELECTRODE FOR SECONDARY BATTERY USING NON-AQUEOUS ELECTROLYTE, BINDER FOR ELECTRODE FOR SECONDARY BATTERY USING NON-AQUEOUS ELECTROLYTE, BINDER FOR ELECTRODE FOR SECONDARY BATTERY, ELECTRODE-PRODUCING COMPOSITION, ELECTRODE MIXTURE, AND ELECTRODE

Resumen de: US20260121057A1

0000 Provided is a method for producing a secondary battery electrode, using PTFE, capable of reducing electrical resistance thereof and achieving excellent strength at the same time, and a binder. A method for producing a secondary battery electrode using a non-aqueous electrolytic solution, including step (1) of preparing a powder composition for producing an electrode by using a binder that is a powder which is composed of a composition essentially including a polytetrafluoroethylene resin and a conductive aid and which is free of an active material, and step (2) of applying a shear force while mixing the composition for producing an electrode to obtain an electrode mixture, wherein step (2) is carried out with a content of a solvent in the composition for producing an electrode being 10% by mass or less.

BATTERY MODULE, BATTERY PACK COMPRISING SAME, AND VEHICLE

Resumen de: US20260121191A1

0000 Disclosed is a battery module having a reinforcement member to reinforce the mechanical strength of a module case. To achieve the above-described object, the battery module according to the present disclosure includes a plurality of secondary batteries arranged in at least one direction, a module case including a cover portion, a bottom portion and a side portion to form an internal space in which the plurality of secondary batteries is mounted, and a reinforcement member disposed in the module case and fixed to a lower surface of the cover portion and an upper surface of the bottom portion.

METHOD FOR SYNTHESIZING MIXED ZIRCONIUM SALT ELECTROLYTE MATERIAL AND USE IN LITHIUM METAL BATTERY

Resumen de: US20260121132A1

The present invention provides a synthesis method for a mixed zirconium salt electrolyte material and use in a lithium metal battery. The preparation method includes the following steps: first, preparing a turbid solution of a zirconium-containing mixed electrolyte material using an existing commercial lithium battery electrolyte solution as a raw material; second, centrifuging the turbid solution obtained in the first step, taking a lower-layer precipitate, and then washing away excess impurities with a commercial carbonate electrolyte solution solvent; third, drying a white precipitate obtained after washing in the second step, and then grinding and pulverizing to obtain a mixed zirconium salt electrolyte material.

Positive Electrode Active Material for Secondary Battery and Lithium Secondary Battery Including the Same

Resumen de: US20260121046A1

Provided is a positive electrode active material for a secondary battery, which is a lithium composite transition metal oxide containing nickel, cobalt, and manganese and having a nickel content accounting for 60 mol % or more of metals excluding lithium and is in the form of a single particle having an average particle diameter (D50) of 1 to 10 μm, wherein a 100-nm region from the surface toward the center of a particle of the lithium composite transition metal oxide has crystal structures of a Fd3M space group and a Fm3m space group, and a phase ratio (Fd3M/Fm3m), which is a ratio of the maximum straight length of portions occupied by the crystal structure of the Fd3M space group and the crystal structure of the Fm3m space group, is 0.2 to 0.7, as determined in a cross-sectional image file of the particle surface part of the lithium composite transition metal oxide particle, which is obtained using transmission electron microscopy (TEM).

CATHODE ACTIVE MATERIAL AND METHOD FOR PREPARING SAME, CATHODE PLATE, BATTERY, AND ELECTRIC DEVICE

Resumen de: US20260121043A1

0000 Provided are a cathode active material and a preparation method thereof. The cathode active material is secondary particles. An equivalent number R<(003) >of (003) crystallographic planes of the cathode active material and an equivalent number R<(104) >of (104) crystallographic planes of the cathode active material satisfy that R<(104)>/R<(003) >ranges from 1.4 to 1.8, R<(003)>=A<(003)>/B<(003)>, and R<(104)>=A<(104)>/B<(104)>, where represents an average thickness of crystallites in the cathode active material in a direction perpendicular to the (003) crystallographic plane, in nm, B<(003) >represents an interplanar spacing of the (003) crystallographic planes in the crystallites of the cathode active material, in nm, A<(104) >represents an average thickness of the crystallites in the cathode active material in a direction perpendicular to the (104) crystallographic plane, in nm, and B<(104) >represents an interplanar spacing of the (104) crystallographic planes in the crystallites of the cathode active material, in nm.

SENSING CONNECTION METHOD

Resumen de: US20260121258A1

A lead connection for coupling a first end of a lead to a post and a bushing of a battery is described. The lead connection includes a first weld that includes the bushing and the post welded to the bushing. The lead connection also includes a second weld. The second weld includes the first weld and the first end of the lead. At least a portion of the first weld is distributed around and over the first end of the lead to electrically couple first end of the lead to the bushing and the post.

CONNECTOR

Nº publicación: US20260121236A1 30/04/2026

Solicitante:

LG ENERGY SOLUTION LTD [KR]
LG ENERGY SOLUTION, LTD.

Resumen de: US20260121236A1

A connector may include a connector housing, a terminal configured to be inserted into the connector housing in a predetermined insertion direction, and a terminal block configured to be inserted into the connector housing, the terminal block surrounding the terminal, and being configured to restrict movement of the terminal in an opposite direction to the insertion direction. In addition, the connector housing may include a first protrusion configured to lock the terminal block.