A flow aid for an infusion arrangement for infiltrating a resin into a fiber material, wherein at least two different resin-permeable plies, which lie atop one another and are joined to one another in the region of their faces lying atop one another, with one ply being a peel ply which on its exposed face is covered sectionally or over the full area with an adhesive agent, which is covered with a removable protective ply, or which can be activated after the mounting of the flow aid.

A method includes cutting a multilayer base including a plurality of dielectric ceramic bodies and a plurality of internal electrode layers alternately stacked on one another along a cutting line orthogonal to the multilayer base to obtain a plurality of base precursors each including a cut side surface on which the plurality of internal electrode layers is exposed, aligning the plurality of base precursors each to have the cut side surface being opened, applying an air remover to the cut side surface being opened, and placing a side green sheet into contact with the air remover applied to the cut side surface and pressing the side green sheet.

This disclosure relates to a composite textile that can be sustainable, as well as methods and systems for constructing the composite textile and recollecting and harvesting excess material (e.g., remnants). In at least some examples, a first pattern piece is cut from a first material layer, and a second pattern piece is cut from a second material layer. In addition, the first pattern piece can be separated from the first material layer, which can leave a first remnant, and the second pattern piece can be separated from the second material layer, which can leave a second remnant. Once separated, the first pattern piece can be stacked atop the second pattern piece, and the stacked pattern pieces can be entangled to form a composite pattern piece. The remnant associated with the first material layer can be separated from the remnant associated with the second material layer and reused.

The present disclosure relates to methods and apparatuses for stretching, transferring, and bonding elastic parts under tension to an advancing carrier substrate during the assembly of absorbent articles. A continuous carrier substrate may be advanced in a machine direction at a first speed, and a discrete elastic part may be cut from a continuous elastic substrate having a direction of stretch in a cross direction. The speed of the discrete elastic part is changed from a second speed to the first speed, and the central region of the discrete elastic part is stretched in the cross direction. The discrete elastic part is bonded with the continuous carrier substrate such that the stretched central region extends in the cross direction between the first and second longitudinal edges of the continuous carrier substrate. The discrete elastic part may also be bonded with the carrier substrate with adhesive and/or mechanical bonds.

A method for manufacturing a shell element reinforced with support elements comprises providing a skin element that has an outer surface and an inner surface opposite the outer surface, providing a first support element that has an attaching side and a free side opposite the attaching side, attaching the first support element on the skin element such that the attaching side of the first support element faces the inner surface of the skin element. A first recess is introduced into the first support element that proceeds from the free side of the first support element and extends transversely to the first axis. A second support element is provided that has a support side and a front side opposite the support side. The second support element is inserted into the first recess of the first support element such that the support side faces the inner surface of the skin element.

Cards may be populated with components and alignment cues. A fully populated card may then be laminated using either of a clear (e.g., transparent) laminate or an obscure (e.g., opaque) laminate. Visual and/or non-visual alignment cues within a card may be utilized to align a trimming and/or singulation device to the card. The card may be singulated and/or trimmed with the aligned singulation and/or trimming device to position one or more components of the card.

A composite radius filler having a varying cross-sectional shape is pre-conditioned before being pultruded through forming dies. The composite filler radius filler includes a tab ply having a varying width that is laminated onto a supporting, full width base ply.

Provided is a beauty care pack including: a support; and a membrane that is laminated on the support so as to be separated by moisture, formed by electrospinning a polymer material, a water-soluble polymer material and a functional material, and a dry type, in which the functional material is dissolved by moisture, to thereby enable an easy and convenient storage and package, and enable a convenient use since a dry sheet is attached to the face.

A solid electrolytic capacitor includes: an insulating substrate; a capacitor element; a positive electrode lead-out structure; and a negative electrode lead-out structure. The positive electrode lead-out structure includes: a positive electrode terminal formed on the insulating substrate; a first positive electrode connection member formed on the insulating substrate; a second positive electrode connection member electrically connecting the first positive electrode connection member to the positive electrode terminal; and a pillow member configured to electrically connect the capacitor element to the first positive electrode connection member. The first positive electrode connection member has a recessed portion or a through hole. The recessed portion or the through hole overlaps an edge of a bottom surface of the pillow member having a first end of the recessed portion or the through hole disposed outside the edge and a second end of the recessed portion or the through hole disposed inside the edge.

Provided are a magnetic field shield sheet for a wireless charger, a method of manufacturing the sheet, and a receiver for the wireless charger by using the sheet. The sheet includes at least one layer thin magnetic sheet made of an amorphous ribbon separated into a plurality of fine pieces; a protective film that is adhered on one surface of the thin magnetic sheet via a first adhesive layer provided on one side of the protective film; and a double-sided tape that is adhered on the other surface of the thin magnetic sheet via a second adhesive layer provided on one side of the double-sided adhesive tape, wherein gaps among the plurality of fine pieces are filled by some parts of the first and second adhesive layers, to thereby isolate the plurality of fine pieces.