Single-Step Shear-Based Deformation Processing of Electrical Conductor Wires

2020 ◽  
Vol 143 (5) ◽  
Author(s):  
Mohammed Naziru Issahaq ◽  
Srinivasan Chandrasekar ◽  
Kevin P. Trumble
Keyword(s):  
Chip Formation ◽  
Large Strain ◽  
Pure Aluminum ◽  
Single Step ◽  
Electrical Conductor ◽  
Deformation Processing ◽  
Deformation Control ◽  
Mechanical And Electrical Properties ◽  
Process Mechanics ◽  
Formed Product

Abstract Commercial electrical conductor wires are currently produced from aluminum alloys by multi-step deformation processing involving rolling and drawing. These processes typically require 10 to 20 steps of deformation, since the plastic strain or reduction that can be imposed in a single step is limited by material workability and process mechanics. Here, we demonstrate a fundamentally different, single-step approach to produce flat wire aluminum products using machining-based deformation that also ensures adequate material workability in the formed product. Two process routes are proposed: (1) chip formation by free-machining (FM), with a post-machining, light drawing reduction (<20%) to achieve desired finish and (2) constrained chip formation by large strain extrusion machining (LSEM). Using commercially pure aluminum conductor alloys (Al 1100 and EC1350) as representative material systems, we demonstrate key features of the machining-based processing, including (a) single-step processing to achieve flat wire geometries, (b) surface finish (Ra = 0.2 to 1.0 μm) comparable to that of commercial wire products made by drawing/rolling, (c) deformation control independent of wire size, and (d) hardness increases of 50–150% over that of annealed wires, while retaining high electrical conductivity (>56% IACS). The wire microstructure, which can also be varied via the large-strain deformation parameters, is correlated with mechanical and electrical properties. Implications for commercial manufacture of flat wire products are discussed.

Bulk nanostructured materials by large strain extrusion machining

2007 ◽  
Vol 22 (1) ◽  
pp. 201-205 ◽  
Author(s):  
W. Moscoso ◽  
M.R. Shankar ◽  
J.B. Mann ◽  
W.D. Compton ◽  
S. Chandrasekar
Keyword(s):  
Plastic Deformation ◽  
Severe Plastic Deformation ◽  
Nanostructured Materials ◽  
Chip Formation ◽  
Large Strain ◽  
Single Step ◽  
Geometric Parameters ◽  
Dimensional Control ◽  
The Creation

Large strain extrusion machining (LSEM) is presented as a method of severe plastic deformation for the creation of bulk nanostructured materials. This method combines inherent advantages afforded by large strain deformation in chip formation by machining, with simultaneous dimensional control of extrusion in a single step of deformation. Bulk nanostructured materials in the form of foils, plates, and bars of controlled dimensions are shown to result by appropriately controlling the geometric parameters of the deformation in large strain extrusion machining.

High Z - Large Strain Deformation Processing and Its Applications

2006 ◽  
pp. 329-334
Author(s):  
Shiro Torizuka ◽  
Akio Ohmori ◽  
S.V.S. Narayana Murty ◽  
Kotobu Nagai
Keyword(s):  
Large Strain ◽  
Deformation Processing

Chemical, Mechanical and Electrical Properties of Glassy Polymeric Carbon

2006 ◽  
Vol 929 ◽  
Author(s):  
Iulia Muntele ◽  
Claudiu I. Muntele ◽  
Renato Minamisawa ◽  
Bopha Chhay ◽  
Daryush Ila
Keyword(s):  
Atomic Oxygen ◽  
Structural Changes ◽  
Phenolic Resin ◽  
Large Strain ◽  
Atmospheric Oxygen ◽  
Low Density ◽  
Mechanical And Electrical Properties ◽  
Three Stages ◽  
Polymeric Carbon ◽  
Small Thermal Expansion

ABSTRACTGlassy Polymeric Carbon (GPC) is obtained by a molding technique, in various shapes, from a phenolic resin precursor. The heat treatment of the precursor is achieved in three stages up to 1000 °C. Similar GPC materials produced in our laboratory displayed large strain to failure ratio, small thermal expansion coefficient and low density. Like all carbon forms, is attacked by oxygen, especially atomic oxygen. Nevertheless the kinetics for reaction with atmospheric oxygen is very slow. We investigated the composition and structural changes of the phenolic precursor as a function of temperature and evaluated materials stability when exposed to high temperatures in presence of hydrogen or oxygen.

On the Cutting of Metals: A Mechanics Viewpoint

2020 ◽  
Vol 142 (11) ◽  
Author(s):  
Dinakar Sagapuram ◽  
Anirudh Udupa ◽  
Koushik Viswanathan ◽  
James B. Mann ◽  
Rachid M’Saoubi ◽  
...  
Keyword(s):  
Plastic Flow ◽  
Chip Formation ◽  
Metal Cutting ◽  
Large Strain ◽  
Shear Banding ◽  
Continuous Shear ◽  
Recent Developments ◽  
Flow Phenomena ◽  
The Stability

Abstract The mechanics of large-strain deformation in cutting of metals is discussed, primarily from viewpoint of recent developments in in situ analysis of plastic flow and microstructure characterization. It is shown that a broad range of deformation parameters can be accessed in chip formation—strains of 1–10, strain rates of 10–105/s, and temperatures up to 0.7Tm—and controlled. This range is far wider than achievable by any other single-stage, severe plastic deformation (SPD) process. The resulting extreme deformation conditions produce a rich variety of microstructures in the chip. Four principal types of chip formation—continuous, shear-localized, segmented, and mushroom-type—as elucidated first by Nakayama (1974, “The Formation of ‘Saw-Toothed Chip’ in Metal Cutting,” Proceedings of International Conference on Production Engineering, Tokyo, pp. 572–577) are utilized to emphasize the diverse plastic flow phenomena, especially unsteady deformation modes that prevail in cutting. These chip types are intimately connected with the underlying flow, each arising from a distinct mode and triggered by an instability phenomenon. The role of plastic flow instabilities such as shear banding, buckling, and fracture in mediating unsteady flow modes is expounded, along with consequences of the flow modes and chip types for the cutting. Sinuous flow is shown to be the reason why gummy (highly strain-hardening) metals, although relatively soft, are so difficult to cut. Synthesizing the various observations, a hypothesis is put forth that it is the stability of flow modes that determines the mechanics of cutting. This leads to a flow-stability phase diagram that could provide a framework for predicting chip types and process attributes.

On the Application of Arbitrary Lagrangian-Eulerian and Remeshing Techniques to Simulate Certain Machining and Deformation Processing Operations

2019 ◽  
Author(s):  
Vandana A. Salilkumar ◽  
Narayan K. Sundaram
Keyword(s):  
Modeling And Simulation ◽  
Metal Cutting ◽  
Large Strain ◽  
Chip Thickness ◽  
Cutting Fluid ◽  
Arbitrary Lagrangian Eulerian ◽  
Flat Punch ◽  
Friction Modeling ◽  
Deformation Processing ◽  
Computationally Intensive

Abstract Metal cutting and deformation processing operations provide some of the most challenging problems for modeling and simulation in computational plasticity. These challenges include, but are not limited to, extreme plastic deformation, challenges in constitutive and interfacial friction modeling, microstructural effects, mechanical and thermoplastic instabilities, multiphysics effects due to cutting fluid and high temperatures, and are generally computationally intensive. Despite considerable progress in each of these fronts, there is scope to expand the envelope of simulations that capture the deformation physics while being computationally feasible. Moreover, even conventional standard FEA codes can be leveraged for modeling and simulation in more effective ways. In this work, we present three challenging scenarios for modeling, namely large strain extrusion machining (LSEM), forming using a flat punch, and cutting of inhomogeneous metal, using a mix of Arbitrary Lagrangian Eulerian (ALE), conventional Lagrangian FE, and remeshing techniques. Some of these simulations are ‘standard’, while others are first-in-class, and we discuss both specific and general modeling issues that must be considered to obtain good quality solutions. Specific mechanics insights gleaned from each of these case studies are also presented, ranging from the influence of friction in deep punch indentation to the selection of the chip thickness ratio in LSEM. The last part of this work focuses on problems that arise in the simulation of polycrystalline aggregate cutting, and the progress made in addressing them.

Mechanics of large strain extrusion machining and application to deformation processing of magnesium alloys

2012 ◽  
Vol 60 (5) ◽  
pp. 2031-2042 ◽  
Author(s):  
Mert Efe ◽  
Wilfredo Moscoso ◽  
Kevin P. Trumble ◽  
W. Dale Compton ◽  
Srinivasan Chandrasekar
Keyword(s):  
Magnesium Alloys ◽  
Large Strain ◽  
Deformation Processing

scholarly journals Stress-strain curve of pure aluminum in a super large strain range with strain rate and temperature dependency

2017 ◽  
Vol 207 ◽  
pp. 161-166 ◽  
Author(s):  
Yasuhiro Yogo ◽  
Masatoshi Sawamura ◽  
Risa Harada ◽  
Kosei Miyata ◽  
Noritoshi Iwata ◽  
...  
Keyword(s):  
Strain Rate ◽  
Large Strain ◽  
Pure Aluminum ◽  
Strain Curve ◽  
Strain Range ◽  
Temperature Dependency ◽  
Stress Strain Curve ◽  
Stress Strain

Effect of Annealing Treatment on the Mechanical Properties of Cu-Ni-Si/Al-Mg-Si Clad Composite Wires

2017 ◽  
Vol 898 ◽  
pp. 1015-1019
Author(s):  
Zhen Yang ◽  
Xun Jun Mi ◽  
Hao Feng Xie ◽  
Li Jun Peng
Keyword(s):  
Mechanical Properties ◽  
Fracture Behavior ◽  
Pure Aluminum ◽  
Pure Copper ◽  
Annealing Treatment ◽  
Cable Industry ◽  
Mechanical And Electrical Properties ◽  
Treatment Conditions ◽  
Different Temperatures ◽  
Composite Wires

Copper-clad aluminum (CCA) composite wires have been widely used in cable industry. Especially for the application in aerospace, the light weight character of wires is particularly important. To improve the mechanical properties of wires, Cu-Ni-Si alloy and Al-Mg-Si alloy are employed to replace pure copper and pure aluminum, respectively. The objective of this work is to find the appropriate annealing treatment conditions to produce the Cu-Ni-Si/Al-Mg-Si clad composite wires with optimal combination properties. The wires were fabricated by a drawing process and heat treatment at different temperatures and times. Mechanical and electrical properties dependent on outer Cu-Ni-Si, internal Al-Mg-Si and interface properties, are characterized and analyzed. The fracture behavior of Cu-Ni-Si/Al-Mg-Si clad composite wires was studied together with the stress-strain curves of the composite wires.

Nanostructured Materials by Machining

2005 ◽  
Author(s):  
Srinivasan Swaminathan ◽  
M. Ravi Shankar ◽  
Balkrishna C. Rao ◽  
Travis L. Brown ◽  
Srinivasan Chandrasekar ◽  
...  
Keyword(s):  
Nanostructured Materials ◽  
Chip Formation ◽  
Powder Processing ◽  
Bulk Material ◽  
Large Strain ◽  
High Strength Steels ◽  
High Strength ◽  
Advanced Materials ◽  
Fine Grained ◽  
Key Parameter

Large strain deformation, a key parameter in microstructure refinement by Severe Plastic Deformation (SPD) processes, is a common feature of chip formation in machining. It is shown that the imposition of large plastic strains by chip formation can create metals and alloys with nanocrystalline or ultra-fine grained microstructures. The formation of such nanostructured materials is demonstrated in a wide variety of material systems including pure metals, light-weight aluminum alloys, and high strength steels and alloys. Nanocrystalline microstructures with different morphologies are demonstrated. The hardness and strength of the nanostructured chips are significantly greater than that of the bulk material. The production of nanostructured chips by machining, when combined with comminution and powder processing methods, may be expected to lead to the creation of a number of advanced materials with new and interesting combinations of properties. These materials are expected to find wide-ranging applications in the discrete products sector encompassing ground transportation, aerospace and bio-medical industries.

scholarly journals Shear-based deformation processing of age-hardened aluminum alloy for single-step sheet production

2021 ◽  
pp. 1-23
Author(s):  
Xiaolong Bai ◽  
Andrew Kustas ◽  
James B. Mann ◽  
Srinivasan Chandrasekar ◽  
Kevin P Trumble
Keyword(s):  
Single Step ◽  
Rolled Strip ◽  
Rolled Sheet ◽  
Shear Texture ◽  
Deformation Processing ◽  
Deformation Step ◽  
Intense Shear ◽  
Chip Geometry ◽  
Continuous Strip

Abstract Shear-based deformation processing by hybrid cutting-extrusion and free machining are used to make continuous strip, of thickness up to one millimeter, from low-workability AA6013-T6 in a single deformation step. The intense shear can impose effective strains as large as 2 in the strip without pre-heating of the workpiece. The creation of strip in a single step is facilitated by three factors inherent to the cutting deformation zone: highly confined shear deformation, in situ plastic deformation-induced heating and high hydrostatic pressure. The hybrid cutting-extrusion, which employs a second die located across from the primary cutting tool to constrain the chip geometry, is found to produce strip with smooth surfaces (Sa < 0.4 μm) that is similar to cold-rolled strip. The strips show an elongated grain microstructure that is inclined to the strip surfaces – a shear texture – that is quite different from rolled sheet. This shear texture (inclination) angle is determined by the deformation path. Through control of the deformation parameters such as strain and temperature, a range of microstructures and strengths could be achieved in the strip. When the cutting-based deformation was done at room temperature, without workpiece pre-heating, the starting T6 material was further strengthened by as much as 30% in a single step. In elevated-temperature cutting-extrusion, dynamic recrystallization was observed, resulting in a refined grain size in the strip. Implications for deformation processing of age-hardenable Al alloys into sheet form, and microstructure control therein, are discussed.

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