A porous electrode for electrochemical cells, methods of making the same and its application are described. The porous electrode is comprised of a porous conductive layer and an insulating layer, whereas the pores inside the conductive layer function as mini-containers for the active metal for rechargeable batteries, and the insulating material covers the top conductive surface of the conductive layer and blocks the sites where active metal dendrite would otherwise preferentially grow. An example of such electrodes is a porous copper foil with top surface coated with polyvinylene difluoride (PVDF). Electrochemical cells containing the invented electrode, such as rechargeable lithium batteries, sodium batteries and aluminum batteries, have good cycle life and safety performance.

A porous electrode for electrochemical cells, methods of making the same and its application are described. The porous electrode is comprised of a porous conductive layer and an insulating layer, whereas the pores inside the conductive layer function as mini-containers for the active metal for rechargeable batteries, and the insulating material covers the top conductive surface of the conductive layer and blocks the sites where active metal dendrite would otherwise preferentially grow. An example of such electrodes is a porous copper foil with top surface coated with polyvinylene difluoride (PVDF). Electrochemical cells containing the invented electrode, such as rechargeable lithium batteries, sodium batteries and aluminum batteries, have good cycle life and safety performance.

An electrode assembly is provided. The electrode assembly has a plurality of electrode plates having one or both sides of each of the electrode plates that are coated with an electrode active material and are stacked with a separator interposed between the respective electrode plates. The separator includes a surplus outer periphery of a size greater than the outer periphery of an electrode plate, an electrode tab which extends from the outer periphery of the electrode plate and protrudes outwardly beyond the outer periphery of the separator is formed on each electrode plate, and at least some of the separators forming the electrode assembly have an insulation-enhancing part for suppressing heat shrinkage of a separator formed in the surplus outer peripheries thereof which are adjacent to the respective electrode tabs.

A battery comprises: at least one electrical energy storage cell; an enclosure in which the at least one electrical energy storage cell is housed, the enclosure having a bottom made from a material with low thermal conductivity having at least one flow channel for a cooling fluid; a thermal plate made from a material with a high thermal conductivity, laying down on the bottom the thermal plate being in thermal contact with the at least one electrical energy storage cell; and a cradle, facing the bottom and separated from the bottom by a space.

In an embodiment, a hydrogen monitoring system comprises a plurality of sensing elements that individually comprise a working electrode, a counter electrode, an insulating layer located in between the working electrode and the counter electrode, a catalyst located on an end of both the working electrode and the counter electrode, an electrolyte located on the end of the sensing elements on both the working electrode and the counter electrode, between the working electrode and the counter electrode, and in contact with the catalyst, and an electrical circuit located on an opposite end of the sensing element that connects the working electrode and the counter electrode.

The present application relates to a battery cell and an electronic device. The battery cell according to an embodiment comprises: an electrode assembly, including an electrode plate; and a shell, receiving the electrode assembly and including a first edge seal, a second edge seal and a circular edge seal connecting the first edge seal and the second edge seal, wherein the circular edge seal defines a virtual circular arc region with a radius R and a radian angle Ø, wherein the electrode plate has a first edge, a second edge, and a third edge connecting the first edge and the second edge, and a virtual extension line of the first edge and a virtual extension line of the second edge intersect to form a virtual intersection point A; a point on the third edge has a minimum distance L relative to the virtual intersection point A; and the virtual extension lines of the first edge and the second edge form a corner at the virtual intersection point A toward the third edge, and an angle of the corner is greater than 0 degrees and less than 180 degrees. The battery cell and the electronic device provided by the present application have higher safety performance, a higher space utilization ratio and a higher energy density.

An assembled battery disclosed here includes a plurality of single cell array units each including single cells that are arranged in a lamination direction of a positive electrode and a negative electrode of an electrode body as an arrangement direction. The single cell array units are disposed parallel to each other such that arrangement directions of the single cells constituting the units are parallel to each other. Then, in the assembled battery, none of the single cells included in each of the single cell array units is directly electrically connected to adjacent single cells in the same unit, but is directly electrically connected to any one of the single cells constituting another single cell array unit through a bus bar.

The disclosure relates to microbattery devices and assemblies. In an embodiment, a device includes a plurality of microbatteries, a first flexible encapsulation film, and a second flexible encapsulation film. Each of the microbatteries includes a first contact terminal and a second contact terminal spaced apart from one another. The first flexible encapsulation film includes a first conductive layer electrically coupled to the first contact terminal of each of the microbatteries, and a first insulating layer on the first conductive layer. The second flexible encapsulation film includes a second conductive layer electrically coupled to the second contact terminal of each of the microbatteries, and a second insulating layer on the second conductive layer.

A solid electrolyte according to an embodiment includes a lithium-containing phosphoric acid compound with a cubic crystal structure.

Provided is a solid electrolyte material represented by the following composition formula (1)
Li.sub.3−3δ−aY.sub.1+δ−aM.sub.aCl.sub.6−x−yBr.sub.xI.sub.y  Formula (1) where M is one or more kinds of elements selected from the group consisting of Zr, Hf, and Ti; −1<δ<2; 0<a<1.5; 0<(3−3δ−a); 0<(1+δ−a); 0≤x≤6; 0≤y≤6; and (x+y)≤6.