Disclosed herein are sealed devices comprising a first substrate, a second substrate, an inorganic film between the first and second substrates, and at least one weld region comprising a bond between the first and second substrates. The weld region can comprise a chemical composition different from that of the inorganic film and the first or second substrates. The sealed devices may further comprise a stress region encompassing at least the weld region, in which a portion of the device is under a greater stress than the remaining portion of the device. Also disclosed herein are display and electronic components comprising such sealed devices.

The invention relates to a method for the media-tight connection of two plate-shaped components (1, 2), in particular two monopolar plates for the production of a bipolar plate, comprising the steps of: placing the first component (1) on a surface of a clamping device, placing the second component (2) on the first component (1), closing the clamping device, setting a first weld seam (3) on the second component (2), wherein a welding depth (t) is selected that is less than a material thickness (s) of the second component (2), with the result that a bend (5) is formed along the first weld seam (3) owing to the welding distortion, via which bend the second component (2) comes into linear contact with the first component (1), setting a connecting weld seam (4) on the first weld seam (3), with the result that the two components (1, 2) are welded to one another along the bend (5).

In an embodiment, a method of forming a cooling plate, comprises laser welding a plurality of weld lines to physically connect a first substrate and a second substrate wherein the plurality of weld lines forms an inflatable track; and inflating the inflatable track with an inflation fluid to form a cooling channel in the cooling plate. In another embodiment, the cooling plate can comprise a first substrate and a second substrate and a plurality of weld lines can form a fluid tight seal for a cooling channel located therebetween.

A package for encapsulating a functional area against an environment includes a base substrate and a cover substrate, the base substrate together with the cover substrate defining at least part of the package or defining the package, and furthermore including the at least one functional area provided in the package, and a blocking way for reducing permeation between the environment and the functional area. The package may include at least one laser bonding line, and the substrates of the package can be hermetically joined to one another by the at least one laser bonding line, and the laser bonding line has a height (HL) perpendicular to its bonding plane.

An article is produced by welding a first piece to a second piece by a laser beam. The first piece includes an open cavity and a first sealing surface. The second piece has a second sealing surface. The first piece and second piece are inside chamber with a controllable internal pressure that is changed to cause a flow of a gas from the open cavity. The open cavity is closed by moving at least one of the pieces. The first sealing surface forms a partially gas tight preliminary joint with the second sealing surface. The first piece and the second piece define an interface. The chamber is opened after the preliminary joint has been formed. A welded seam is formed by focusing a laser beam to the interface after the chamber is opened. The first sealing surface and the second sealing surface are substantially planar.

A welding method of a battery cover plate includes performing at least two times of continuous welding along a connecting zone between a cover plate and a shell, and adjusting laser welding power, welding speeds, and defocusing amounts. Welding power of a first continuous welding is less than welding power of a second continuous welding. An amount of deformation of the shell is less than or equal to 0.6 mm after the first continuous welding, and the amount of deformation of the shell is less than or equal to 1.0 mm after the second continuous welding.

A method for producing a battery cell involves producing a battery cell with a housing having a first volume containing a multiplicity of electrodes are stacked one on top of another and an electrolyte, wherein the electrolyte can be introduced into the first volume via an opening in the housing.

The present invention relates to a method of joining glass elements with material continuity, to a glass component, to a housing, and to a vacuum insulating panel. The method comprises the following steps providing first and second glass elements, with each of the glass elements having at least one joining region having an outer edge to be joined, introducing a metallic material into the first glass element in the region of the joining region of the first glass element, placing the first and second glass elements onto one another such that the first and second glass elements contact one another at least at one outer edge of the respective joining region; and heating the metallic material in the first glass element so that the glass element at least partially melts in the region of the joining region of the first glass element so that a connection with material continuity is produced between the first and second glass elements.

A hermetically sealed package includes: at least one cover substrate which is sheet-like and includes a flat outer surface and a circumferential narrow side, the at least one cover substrate being formed as a transparent thin film substrate, the at least one cover substrate having a thickness of less than 200 μm; a second substrate which is adjoined to the at least one cover substrate and in direct contact with the at least one cover substrate; at least one functional area enclosed by the hermetically sealed package, the at least one functional area being between the at least one cover substrate and the second substrate; and a laser bonding line which joins the at least one cover substrate and the second substrate directly and in a hermetically tight manner.

A method of manufacturing a secondary battery according to the disclosure includes an attaching step of attaching a sealing plate to an open end of a case main body including a closed bottom, and a welding step of laser-welding the case main body and the sealing plate together by scanning a laser beam along a peripheral edge portion of the sealing plate. In the welding step, the laser beam applied to the peripheral edge portion of the sealing plate and to an edge of the open end of the case main body may be a pulsed laser beam including a rectangular wave and having a pulse width of from 400 μm to 800 μm and a frequency of from 1.2 kHz to 1.4 kHz, and the laser beam is scanned such that adjacent laser pulses of the pulsed laser beam have an overlap rate of 84.4% to 86.6%.