Bend radius

About: Bend radius is a research topic. Over the lifetime, 3303 publications have been published within this topic receiving 35415 citations. The topic is also known as: minimum bend radius.

Container seal for the storage of dangerous liquid material

Abstract: Exemplary embodiments provide a seal between an open body end of a container body and an edge of a lid which is pressable into the open end of the body in a sealing manner, both made from sheet metal, wherein at the end of the body the sheet metal is bent outward by approximately 180° with a bending radius, the lid edge, which is separated from a lid surface by a channeled bead, extending axially upward with its radially external defining edge of the bead beyond an axial position of the lid surface and being bent outwards with a radius which is larger than the bending radius at the body end, to form a rolled edge for receiving an annular sealing material filling the rolled edge and extending downwards, wherein a sheet edge of the rolled edge terminates at a radial distance before the defining edge, said distance being dimensioned such that during the sealing process the body end, with the bending radius thereof in contact with the defining edge of the lid, may be inserted between the same and the sealing material into the interior of the rolled edge.

Fiber optic cable stripping and measurement apparatus

Abstract: A fiber optic cable stripping and measuring apparatus that includes a mounting base having a template clamp connected thereto, the template clamp securing an optical component connected to the fiber optic cable. The apparatus further includes a fiber clamp connected to mounting base for securing a first portion of the fiber optic cable. A pair of fiber take up mandrels are provided adjacent to the fiber clamp for winding excess fiber optic cable, if excess cable is desired. The apparatus also includes a fiber stripper, spaced from take up mandrels, for scoring a buffer layer of the fiber optic cable. The fiber stripper enables the buffer layer of a portion of the fiber optic cable to be removed to expose optical fiber within the fiber optic cable. The apparatus further includes a cylindrical marking mandrel spaced from the fiber stripper and having a circumference that exceeds the minimum bend radius of the fiber optic cable. The cylindrical marking mandrel has a marking groove formed on its periphery so that the exposed optical fiber of the fiber optic cable may be marked at predetermined locations.

Fiber optic cable for cordage or tactical applications

Abstract: A fiber optic cable is provided having a at least one fiber element, a layer of aramid strength members, and a jacket disposed over said layer of aramid strength members The layer of aramid strength members is wound at a lay length that is equal to or lesser than a predetermined bend radius

Enhanced Thermoelectric Properties of Bi2Te3‐Based Micro–Nano Fibers via Thermal Drawing and Interfacial Engineering

Abstract: High‐performance thermoelectric (TE) materials with great flexibility and stability are urgently needed to efficiently convert heat energy into electrical power. Recently, intrinsically crystalline, mechanically stable, and flexible inorganic TE fibers that show TE properties comparable to their bulk counterparts have been of interest to researchers. Despite remarkable progress in moving TE fibers toward room‐temperature TE conversion, the figure‐of‐merit value (ZT) and bending stability still need enhancement. Herein, interfacial‐engineering‐enhanced TE properties of micro–nano polycrystalline TE fibers fabricated by thermally drawing Bi2Te3‐based bulks in a glass‐fiber template are reported. The interfacial engineering effect comes from generating stress‐induced oriented nanocrystals to increase electrical conductivity and producing strain‐distorted interfaces to decrease thermal conductivity. The 4 µm‐diameter fibers achieve a 40% higher ZT (≈1.4 at 300 K) than their bulk counterparts and show a reversible bending radius of 50 µm, approaching the theoretical elastic limit. This fabrication strategy works for a wide range of inorganic TE materials and benefits the development of fiber‐based micro‐TE devices.

Design optimization and evaluation of the 3 kA MgB2 cable at 4.3 K for the superconducting link project at CERN

Abstract: High-current superconducting links (SC links) are being developed at CERN for powering the superconducting magnets of the High-Luminosity Large Hadron Collider upgrade. The links contain MgB2 cables, each about 100 m long, rated at currents of up to 18 kA. The assembly of the cables is carried out with reacted wires; cable geometry and cabling processes take into account the mechanical properties of the reacted MgB2 conductor. The production of the cables as well as their final installation requires good mechanical stability, flexibility and electrical performance. The superconductor should have good mechanical strength in view of the stresses during cabling (tension and bending), operation at cryogenic temperatures (Lorentz forces and thermal contraction) and handling installation (tension and bending) at room temperature. Moreover, the electrical integrity of the MgB2 wire (I C degradation ≤5%) should be ensured after the cabling process for the SC links. Therefore, the study of the mechanical properties of the MgB2 wire and the definition of the cable design parameters are crucial for the project. In the present work we report on the optimization and validation of the design of the 18-strand, 3 kA MgB2 cable by assessing the electromechanical behaviour of 3 kA MgB2 superconducting cables produced with different cabling parameters. The critical current (I C ) of the MgB2 wires was measured after triple bending and axial tensile load, and strands extracted from the cables were tested to quantify the critical current degradation. Electrical measurements of two, 2 m long, 18-strand MgB2 cables were carried out in the FRESCA test facility at CERN and no degradation was observed. Cabling parameters such as the bending radius and the twist pitch were evaluated, and the most appropriate geometries for the MgB2 18-strand cables have been selected. Numerical simulations were performed to allow a detailed study of the strains developed in the MgB2 strands due to the mechanical loading. The present results have been successfully transferred to industry for the first industrial production in the framework of the SC Link project.