The present invention relates to a pressure relief element (11) to be used as an overpressure safety means in devices where a gaseous medium must be rapidly released in case of overpressure, wherein the pressure relief element (11) has at least one notch (9) which is designed as a predetermined breaking point where the pressure relief element (11) breaks at a certain level of overpressure, thereby irreversibly opening an exhaust path for the gaseous medium. The present invention also relates to a pressure relief device of an electrochemical battery, comprising such a pressure relief element and a battery comprising such a pressure relief device.

The present disclosure relates to an upper die configured to hold a substrate, and a lower die configured to be clamped with the upper die and has a cavity. The lower die includes a pot that is communicably connected to a resin injection port provided on the bottom surface of the cavity, and where the resin material is contained, an injection plunger is advanced and retracted inside the pot to inject the resin material into the cavity via the resin injection port, a resin reservoir that is connected to a discharge port provided on the bottom surface of the cavity communicably, and where resin material flown out of the cavity accumulates, a suction hole that is connected to the resin reservoir and that is configured to suction the air via the resin reservoir, through the discharge port, and a switching plunger.

A resin molding apparatus includes: a mold die that is configured to hold an object to be molded, the object including a substrate and a chip on the substrate, and that has a cavity configured to receive a resin material through a gate; a mold clamp mechanism configured to clamp the mold die; and a control section configured to control how the mold die and the mold clamp mechanism are operated, the mold die including: a movable block configured to narrow at least a portion of an internal flow path of the cavity in which internal flow path the chip is not disposed; and a driving mechanism configured to drive the movable block with use of a fluid, the control section being configured to change a driving force of the driving mechanism during resin-molding of the object.

Provided are a micro-needle patch and a manufacturing method thereof. The micro-needle patch includes: a support on one surface of which grooves are formed; a gel membrane for delivery of a transmitter to be transferred in which the grooves are filled with a mixture of the transmitter with a biodradable resin, the mixture being in a gel phase; a plurality of micro-needles projected on the other surface of the support and for penetrating the skin; a first protective film that covers the gel membrane and is adhered on the support; and a second protective film that covers the plurality of micro-needles and is adhered on the other surface, wherein passages are formed by being penetrated from the support to each of the plurality of micro-needles or formed by penetrating the support between the plurality of micro-needles, so that the transmitter of the gel membrane is transferred to the skin.

A method for producing an object having a microstructure. In the production of the objects, use is made of injection molds which have a counterstructure to the desired microstructure of the object, wherein the counterstructure of the injection mold can be obtained by laser structuring. The material and the objects produced therefrom have proven to be surprisingly robust, hard-wearing and slip-resistant, making them particularly suitable for the production of handles for power tools. A material which includes at least one thermoplastic elastomer material, wherein a texture depth of the material is in a range of from 250 to 400 m, preferably in a range of from 300 to 380 m, and more preferably about 325 m. In yet another aspect, the invention relates to use of the material as a surface material for power tools.

Provided herein include various examples of a method for manufacturing aspects of flow cell. The method may include performing chemical processes on a surface of the patterned wafer to prepare the surface of the patterned, singulating the wafer into individual dies, orienting each die on a temporary substrate, where the orienting creates spaces between each individual die, and molding a material over the spaces to create a hybrid wafer comprised of glass and molded material. The method may also include bonding two of the hybrid wafers together, forming a bonded wafer stack.

The invention relates to a mold for small-sized parts, comprising a casing configured to be assembled on a press platen (101, 102) the casing comprising a housing receiving an insert; the insert comprising a housing for a die comprising a molding surface (121, 122); a device for heating the die, the device comprising a rod (131, 132) made of a material susceptible to induction heating mounted in the insert (350) and having one end in contact with the die, a coil (141, 142) surrounding the rod and connected to a high-frequency current generator (151, 152) such that when the coil is electrically powered, it generates an induced current in the rod (131, 132), heating the rod by induction, the rod transmitting heat to the die, wherein an outer diameter of the rod is greater than or equal to an outer diameter of a perimeter delimiting the molding surface (121, 122).

Provided herein is a cell macroencapsulation device composed of hydrogel in a 3D conformation that optimizes encapsulated cell viability and function when transplanted into a vascularized tissue space. The hydrogel macroencapsulation device is intended to reduce or eliminate immune response to the cell graft, while allowing exchange of encapsulated cell-secreted products, such as insulin. Also described herein is an injection-mold and fabrication process to generate the hydrogel macroencapsulation devices for use in the clinic.

Provided herein is a cell macroencapsulation device composed of hydrogel in a 3D conformation that optimizes encapsulated cell viability and function when transplanted into a vascularized tissue space. The hydrogel macroencapsulation device is intended to reduce or eliminate immune response to the cell graft, while allowing exchange of encapsulated cell-secreted products, such as insulin. Also described herein is an injection-mold and fabrication process to generate the hydrogel macroencapsulation devices for use in the clinic.

Provided herein include various examples of a method for manufacturing aspects of flow cell. The method may include performing chemical processes on a surface of the patterned wafer to prepare the surface of the patterned, singulating the wafer into individual dies, orienting each die on a temporary substrate, where the orienting creates spaces between each individual die, and molding a material over the spaces to create a hybrid wafer comprised of glass and molded material. The method may also include bonding two of the hybrid wafers together, forming a bonded wafer stack.