Wieland-K81® Rolled Products
Transcription
Wieland-K81® Rolled Products
Wieland-K81® Rolled Products CuSn0,15 C14415 Material Designation Chemical Composition (Reference) Typical Applications EN CuSn0.15 Sn 0.1 % UNS* C14415 Cu balance · Components for the electrical industry · Connector pins · Fuse boxes in automobiles · Leadframes for semiconductors * Unified Numbering System (USA) Physical Properties* Electrical Conductivity MS/m %IACS 51 88 Thermal Conductivity W/(m·K) 350 Coefficient of Electrical Resistance** 10-3/K 3.2 Coefficient of Thermal Expansion** 10-6/K 18.0 Density 8.93 g/cm3 Modulus of Elasticity GPa Specific Heat J/(g·K) Poisson’s Ratio 130 0.385 0.34 * Reference values at room temperature ** Between 0 and 300 °C Fabrication Properties Corrosion Resistance Capacity for Being Cold Worked excellent Machinability fair Capacity for Being Electroplated excellent Capacity for Being Hot-Dip Tinned excellent Soft Soldering excellent Wieland-K81® has good corrosion resistance in natural atmosphere (also sea air) and industrial atmosphere. In different waters and neutral saline solutions, it exhibits better resistance to corrosion through abrasion and pitting than SF-Cu. Wieland-K81® is insensitive to stress corrosion. Resistance Welding fair Gas Shielded Arc Welding excellent Laser Welding good Mechanical Properties K81 R250 R300 56 R360 R420 Tensile Strength Rm MPa 250–320 300–370 54 360–430 420–490 Yield Strength Rp0.2 MPa ≥ 200 ≥ 250 52 ≥ 300 ≥ 350 Elongation A50mm % ≥9 ≥ 450 ≥3 ≥2 Temper H060 El. Conductivity (MS/m) Temper Hardness HV 60–90 85–110 Intermediate tempers are feasible. Higher elongation values can be obtained 48by additional heat treatments. H085 44 El. Conductivity (MS/m) 56 54 52 50 48 46 44 R250 H060 R300 H085 Temper 0° K81 6 R250 H060 H105 R300 105–130 H085 H120 Temper R360 120–140 H105 R420 H120 Bendability (Strip Thickness t ≤K81 0.5 mm) K81 R360 H105 R420 H120 Rel. Bending Radius r/t 90° Electrical Conductivity 46 6 5 4 3 bending edge –I rolling direction bending edge II rolling direction 2 1 0 R250 H060 R300 H085 Temper R360 H105 R420 H120 Wieland-K81® CuSn0,15 C14415 Resistance K81 to Softening 130 Temper R300 400 °C 425 °C 500 °C 120 110 100 110 90 80 70 60 50 40 0 5 10 15 20 Time (min) 25 Temper R360 400 °C 425 °C 500 °C 120 Vickers Hardness HV Vickers Hardness HV K81 130 30 100 Vickers hardness after heat treatment (typical values) 90 80 70 60 50 40 0 5 10 15 20 Time (min) 25 30 K81 (wh) Thermal Stress Relaxation Stress remaining after thermal relaxation as a function of Larson-Miller parameter (F. R. Larson, J. Miller, Trans ASME74 (1952) 765–775) given by: P = (20 + log(t))*(T + 273)*0.001. Time t in hours, temperature T in °C. Example: P = 9 is equivalent to 1.000 h/118 °C. Measured on rolled to temper specimens parallel to rolling direction. Total stress relaxation depends on the applied stress level. Furthermore, it is increased to some extent by cold deformation. 100 Residual Stress (%) 90 80 70 60 50 40 Temper R300, R360, R420 7.0 8.0 9.0 10.0 Larson-Miller parameter P 11.0 Fatigue Strength The fatigue strength is defined as the maximum bending stress amplitude which a material withstands for 107 load cycles under symmetrical alternate load without breaking. It is dependent on the temper tested and is about 1/3 of the tensile strength Rm. · Standard coils with outside diameters up to 1400 mm · Traverse-wound coils with drum weights up to 1.5 t Wieland-Werke AG Dimensions Available · Hot-dip tinned strip · Contour-milled strip www.wieland.com Graf-Arco-Str. 36, 89079 Ulm, Germany, Phone +49 731 944 2030, Fax +49 731 944 4257, [email protected] This printed matter is not subject to revision. No claims can be derived from it unless there is evidence of intent or gross negligence. The product characteristics are not guaranteed and do not replace our experts’ advice. · Strip thickness from 0.10 mm, thinner gauges on request · Strip width from 3 mm, however min. 10 x strip thickness 10/14 Bm (R+G) Types and Formats Available