Vectra® LCP Lead-Free Soldering © 2013 Celanese EE-003 AM 10/13 Why is Electronics Going Lead-Free? ► Comply with RoHS – Restriction of hazardous substances ► Comply with WEEE – Waste from electrical/ electronic equipment Fact – Lead ingestion in the body harms living things Fact – Lead pollution in air and water has been tackled Fact – Lead perceived by many environmentalists as unconditionally “a bad thing” Fact – Promotion of “lead-free” products has won market share © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 2 Wave Soldering General view of inerted wave soldering machine The wave solder profile Source: Department of Computing & Electronic Technology - University of Bolton © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 3 The Reflow Process There are four heating modes involved with SMT reflow processes: ► Convection ► Conduction ► Latent heat ► Infrared radiation (IR) These last three methods of heat transfer can be implemented at all levels upwards from low-volume batch systems. “Cones” of hot gas from the plenum box Convection is the main runner for larger users and on high-volume flow-line systems. It became popular because blowing hot gas at the circuit provided a more controllable and consistent heating regime. Source: Department of Computing & Electronic Technology - University of Bolton © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 4 Lead-Free Solder – What is Changing? Lead-Free Solder Composition Melting Point Range Comments 48 Sn/52 In 118°C eutectic Low melting point, expensive, low strength 42 Sn/58 Bi 138°C eutectic Established, availability concern of Bi 93.5 Sn/3Sb/2Bi/1.5 Cu 218°C eutectic High strength, excellent thermal fatigue 95.5 Sn/3.5 Ag/1 Zn 218-221°C High strength, good thermal fatigue 99.3 Sn/0.7 Cu 227°C High strength and high melting point 95 Sn/5 Sb 232-240°C Good shear strength and thermal fatigue 97 Sn/2 Cu/0.8 Sb/0.2 Ag 226-228°C High melting point 96.5 Sn/3.5 Ag High strength and high melting point 221°C eutectic Peak Temp in Reflow Soldering Process Lead-Free Solder 250-260°C Sn-Pb 220-230°C Melting Point Lead-Free Solder 210-230°C Sn-Pb 183°C Source: Department of Computing & Electronic Technology - University of Bolton © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 5 IR/Convection Reflow Profile (IPC/JEDEC J-STD-020C) Source: Department of Computing & Electronic Technology - University of Bolton Temperatures vs. Time and Definitions © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 6 Components Through Hole – (also spelled “thru-hole”). Of a component, having pins designed to be inserted into holes and soldered to pads on a printed board. ► High power design ► Hobbyist projects ► Component “shielded” by PCB during soldering, not exposed to the high temp of solder solution SMD – A method of assembling printed wiring boards or hybrid circuits, where components are attached to pads on the board surface. ► High density ► Smaller assemblies ► Low power ► Component exposed to direct high heat Source: Department of Computing & Electronic Technology - University of Bolton © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 7 Celanese Portfolio for E&E Celanex® PBT Fortron® PPS Vectra® LCP Vectra LCP Ei and S Series Temperature Conventional Lead Free Temperature Celanex PBT Fortron PPS Vectra LCP Through Hole © 2013 Celanese EE-003 AM 10/13 SMT Vectra® LCP Lead-Free Soldering 8 Vectra® Liquid Crystal Polymer Halogen-Free. Always was – always will be. You May Not Have Needed Vectra® LCP from Celanese Before Now, But… Here’s the Halogen-Free High-Performance Solution to Drive Greener Electronics 2013Ticona Celanese EE-003 AMUS 10/13 ©©2009 EE-003 10/09 EN Vectra® LCP Lead-Free Soldering 9 Lead-Free Soldering Vectra® LCP vs. High Temperature Polymers ► Advantages ‒ High HDT/A ↔ No softness at Reflow Peak Temp ‒ High Tm ↔ Higher safety factor for LF Soldering ‒ High heat resistance ↔ Thinner walls and smaller parts ‒ Lower humidity absorption ↔ Less susceptible for blistering ‒ Higher flow ↔ Less internal part stress, lower warpage ‒ Low warpage ↔ Safety factor for assembly ‒ High dimensional stability ↔ Fewer risks of contact failure ‒ Low CTE variations ↔ Fewer risks of contact failure ‒ Inherent UL-94 V0 ↔ FR additives could attack metal contacts ‒ Lower injection cycle time ↔ Lower price per part ► Considerations ‒ Design is critical ‒ Weaker welding lines © 2013 Celanese EE-003 AM 10/13 ↔ Optimum properties ↔ Design related Vectra® LCP Lead-Free Soldering 10 The Heat Deflection Temperature vs. Tm Reflow Peak Temp 350 DTUL/A @ 1.8 MPa 330 310 290 270 Vectra® S135 PPS PPA PA HTN PA 46 Vectra E130i Reflow Peak Temp PCT 250 Vectra A130 230 210 240 260 280 300 320 340 360 380 Melting Temperature °C Note: Vectra LCP grades 30% GF Reinforced Reflow Peak Temperature is a Big Factor for Failure © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 11 Dimensional Stability Stable dimensions after exposure to surface mount technology temperatures (reflow soldering) ► Change of length vs. 4.149-inch tool dimension ► SIMM molded at manufacturer’s recommended conditions ► SMT simulated by hot oil bath exposure at 260°C 4.5 Shrinkage (mils/inch) 4 3.5 3 As molded 2.5 2 1.5 1 0.5 0 Vectra E130i PPS 40GF PPS 40GF HF PPA 33GF V0 HTN 35GF V0 Dimensional Variations Could Cause Contact Failure © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 12 Dimensional Stability 0.20 @251oC As-mold After IR reflow 0.16 Warpage (mm) @287oC 0.12 0.08 0.04 0.00 E130i E471i E480i E488i S135 S471 S475 “Low Warpage Grades” Smaller than “GF-reinforced Grades” Vectra® E130i is Better Than Most High Temp Polymers But… © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 13 Spiral Flow vs. Other Resins Vectra E130i PPS 40 PCT PPA PET FR 0 50 100 150 Spiral Flow (Inches) Each molded at manufacturer’s recommended conditions and three injection pressures normalized to 30 Kpsi. Cavity thickness = 0.125 in. High Flow = Less Internal Stress, Thinner Walls © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 14 Vectra® LCP: Flow Path Length Flow path length of Vectra LCP as a function of polymer and filler Flowability (0.5 mm thickness) by Injection Pressure (MPa) 60 Mpa 100 80 Mpa 100 Mpa 90 Flow length (mm) 80 70 60 50 40 30 20 10 0 A130 E130i E471i S135 S471 S475 High Flow = Less Internal Stress, Thinner Walls © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 15 Flatness Typical convection oven Typical convection oven Contact No-contact Failure = Quality and Reliability Problems + Costs © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 16 Key Factors Influencing Flatness Material Flowability Deformation Processing Design © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 17 Rework = Time and Cost Cross-section of a hot-gas QFP removal tool View of a QFP gas nozzle from underneath Soldering iron rework of an SM assembly Source: Department of Computing & Electronic Technology - University of Bolton 1 = quick change support 2 = vacuum cup 3 = nozzle nest (corresponds to the component housing) 4 = gas openings Rework Can Damage Some Components, Increase Costs © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 18 Water Absorption Water Absorption (ppm) 40000 Cross section of blistering sample (connector housing) LCP GF30 PPS GF40 PA6TGF30 PA46 GF40 80 100 30000 25000 20000 15000 10000 5000 0 20 40 60 Time (hours) 40000 LCP GF30 PPS GF40 PA9T GF33 PA6TGF30 PA46 GF40 35000 Water Absorption (ppm) PA9T GF33 35000 Condition: 60°C; 95%RH 30000 25000 20000 15000 10000 5000 0 20 40 60 80 100 PA 6T GF30FR Condition: Time (hours) Condition: 35°C; 85%RH PA 46 GF30FR 40°C; 95%RH; 96 hrs; IR Reflow @ 265°C High Water Absorption + Temp = Quality and Reliability Problems © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 19 Vectra® LCP: Viscosity Viscosity as a function of shear rate 1000 Viscosity (Pas) LCP Conventional polymer 100 10 1 10 100 1000 10000 Shear rate (1/sec ) Cost Saving: Low Viscosity = Small Machine © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 20 Vectra® LCP: Wall Thickness Effect of wall thickness on rigidity (Vectra E130i natural) Tensile strength 250 200 150 100 50 0 4mm 3.2mm 1.6mm 0.8mm 0.7mm 0.6mm Thickness of the test bar Material Saving: Low Wall Thickness is an Advantage © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 21 Vectra® LCP Grade Selection Guideline E488i, S471, S475, V143LC S471 S135 E130i E471i E473i S471 S475 Flatness Improvement Heat Resistance Improvement Flow Improvement General Purpose Standard Grade S135 V143LC E830i Pd E820iLDS E840iLDS © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering Weld or Knit Line Improvement Platable Grades 22 V-0 Halogen-free Material Considerations Wall thickness Vectra S475 – Super flow; high temperature; low warp <0.4 mm Vectra S135 – High flow; highest HDT Vectra E473i – Good flow; low warp Vectra E471i – Good balance of flow, flatness and HDT Vectra E130i – High flow; high HDT ≥0.4 mm ≥0.8 mm Vectra E488i – Good flow; low warp Vectra V143LC – Good flow; high weldline strength Chlorine Level < 900 (ppm) Fortron 1140LC6 – Good flow; high mechanical strength Chlorine Level < 900 (ppm) Vectra E150i – Good flow; high stiffness Celanex® XFR Lead-Free Solderable Not Lead-Free Solderable Note: All grades Br free © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 23 Vectra® LCP Production Advantages ► High productivity with rapid cycle times ‒ 30% to 50% of PPS, PPA, PCT ‒ 50% to 75% of PES, PEI, PSO ► Low injection pressures ‒ 50% of PPA ‒ 10% to 20% of PEI, PES, PSO, PCT ► Outstanding dimensional stability ‒ Low mold shrinkage (often <.001”) ‒ Low coefficient of thermal expansion ‒ Low warp ► ► ► ► Low tool temperatures (50°F-200°F) No outgassing, vent plugging or steel corrosion No deflashing necessary Extremely stable – Use of up to 50% regrind Delivers Total Lower Per-Part Cost © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 24 Contact Information Disclaimer This publication was printed on 1 October 2013 based on Celanese’s present state of knowledge, and Celanese undertakes no obligation to update it. Because conditions of product use are outside Celanese’s control, Celanese makes no warranties, express or implied, and assumes no liability in connection with any use of this information. Nothing herein is intended as a license to operate under or a recommendation to infringe any patents. Copyright © 2013 Celanese or its affiliates. All rights reserved. Americas 8040 Dixie Highway, Florence, KY 41042 USA Product Information Service t: +1-800-833-4882 t: +1-859-372-3244 Customer Service t: +1-800-526-4960 t: +1-859-372-3214 e: info-engineeredmaterials-am@celanese.com Europe Am Unisys-Park 1, 65843 Sulzbach, Germany Product Information Service t: +(00)-800-86427-531 t: +49-(0)-69-45009-1011 e: info-engineeredmaterials-eu@celanese.com Asia 4560 Jinke Road, Zhang Jiang Hi Tech Park Shanghai 201203 PRC Customer Service t: +86 21 3861 9266 f: +86 21 3861 9599 e: info-engineeredmaterials-asia@celanese.com © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 25 Back-up Slides © 2013 Celanese EE-003 AM 10/13 26 RoHS Product Compliance © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 27 Glossary ► BGA = Ball Grid Array – A leadless IC package with a large number of terminations arranged in a matrix on the bottom of the package. Connections are made through solder terminations on the underside of the array, either in the form of solder balls (most common) or pillars. These are reflowed onto the board, forming pillars between the board and component. ► Flux – A chemically active agent that speeds the wetting process of metals with molten solder: a short-form way of describing a complex of rosin, activators and solvents. When heated, fluxes remove minor surface oxidation, minimize oxidation of the base metal, and promote the formation of an intermetallic layer between solder and base metal. Flux will not remove oils, dirt or fingerprints – only a solvent can remove these. ► IR Reflow – Use of infrared energy to bring solder to its melting point. ► JEDEC = Joint Electronic Device Engineering Council – JEDEC is the semiconductor engineering standardization body of the Electronic Industries Association (EIA), and develops and publishes configuration standards for semiconductor device packages. ► PCA = Printed Circuit Assembly – An assembly designed to perform a specific function, consisting of a printed circuit board to which separately manufactured electrical, electromechanical and mechanical component parts have been added. ► PCB = Printed Circuit (Board) – The generic term for completely processed “printed wiring,” where predetermined conductive patterns are used to interconnect electronic components on a common insulating base. It includes single-sided, double-sided and multilayer boards made with rigid, flexible and rigid-flex materials, but the most usual PCB is a substrate of copper-clad epoxy-glass laminate material which has been etched to form a pattern of conductive traces. More correctly, but less usually, referred to as a “Printed Wiring Board” (PWB). Especially within the computer industry, the term is also loosely applied to a board onto which semiconductor components are connected, although this is properly called a Printed Circuit Assembly (PCA). ► Reflow Soldering – A process of joining metallic surfaces (without melting the base metals) through the mass heating of pre-placed solder (usually in the form of paste) to create solder fillets in the metallized areas. Source: Department of Computing & Electronic Technology - University of Bolton © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 28 Glossary ► RoHS (Restriction of Hazardous Substances) EU Directive No. 2002/95/EC passed Feb-2003 restricts use of: (4) Heavy Metals: Lead, Mercury, Cadmium, Hexavalent Chromium (2) FR’s: Polybrominated Biphenyls (PBB’s), Polybrominated Diphenylethers (PBDE’s) Effective Date: July 1, 2006 for all E/E products sold to customers in EU countries ► Solder – A fusible alloy used to join two or more metals at temperatures below their individual melting points. Solders which melt readily are “soft solders,” others fusing at a higher temperature (usually taken as above 425°C) are “hard solders.” Solders consisting mostly of tin and lead are normally used for soldering electronic assemblies. The tin in solder forms an intermetallic with copper (or nickel) in the surface being bonded. ► Solder Balls – Small spheres of solder which have separated from the main body of the solder joint and adhere to laminate, mask or conductors. Most often associated with the use of solder paste containing excessive oxides or moisture. Baking of paste may minimize formation of solder balls, but over-baking may cause excessive balling. ► Solder Paste (cream) – A homogeneous combination of minute spherical solder particles, flux, solvent and a gelling or suspension agent, which has the consistency and viscosity of a paste and is used in surface mount reflow soldering. Solder paste can be deposited on a substrate by solder dispensing and screen or stencil printing. ► Soldering – Process by which two or more metal surfaces are bonded together via an intermediary alloy called a solder. ► SMD (SMC) = Surface Mount Device (Component) – An electronic device designed for mounting onto lands on the surface of a substrate rather than by insertion into holes in the substrate. SMD is a registered service mark of North American Philips Corp. (Assembléon) to denote resistors, capacitors, SOICs and SOTs. ► SMT = Surface Mount Technology – A method of assembling printed wiring boards or hybrid circuits, where components are attached to pads on the board surface, as distinct from through-hole technology, where component leads are inserted into holes. The result is higher component density, and smaller assemblies. ► Through-Hole – 1) (noun) A hole that extends though the entire circuit board, which may or may not be plated, depending on its function. Plated through-holes are used for the attachment and electrical connection to the printed board of component terminations, including pins and wires. 2) (adjective) (also spelled ‘thru-hole’). Of a component, having pins designed to be inserted into holes and soldered to pads on a printed board. Contrast with surface mount. Source: Department of Computing & Electronic Technology - University of Bolton © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 29 Glossary ► Through-Hole Technology – The science applied to making electrical connection of components to and through the surface of a conductive pattern using component holes (in contrast to SMT). ► Wave Soldering – A method of soldering components to printed circuit boards by moving the boards over a continuously flowing and circulating wave of molten solder in a solder bath. The process permits precise control of the depth of immersion in the molten solder and minimizes heating of the board. SMDs are held in place during wave soldering with adhesives and are mounted on the secondary side (wave side) of the PCB. ► WEEE (Waste Electrical and Electronic Equipment) EU Directive No. 2002/96/EC passed Feb-2003 requires producers to: Set up systems to provide for the treatment of WEEE products Effective Date: 08/13/05 ► Wetting – In general, wetting is the ability of a liquid to flow across a surface as opposed to sticking to itself. Wetting occurs when the attraction between liquid and surface is greater than the surface energy of the liquid, drawing a molecularly thin layer across itself. Wetting in soldering applies to molten solder spreading along the base metal/metallization surfaces to produce a relatively uniform, smooth, unbroken and adherent film of solder. A good intermetallic bond between surfaces is formed. One action of flux is to reduce the surface tension of the solder to enhance wetting. Good wetting is indicated by a low “contact angle” (positive wetting angle) between the solder fillet and the base metal/metallization. ► Whisker – A slender needle-shaped growth between conductors and lands which occurs after the printed board has been manufactured. Source: Department of Computing & Electronic Technology - University of Bolton © 2013 Celanese EE-003 AM 10/13 Vectra® LCP Lead-Free Soldering 30