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CONNECTOR THEORY. FAILURE MODES AND PRACTICAL APPLICATION. Your Presenter: Arnie Cobb Product Manager Distribution Connector Products. THE ENTIRE ELECTRICAL SYSTEM. And all the expensive equipment…. ….depend on the integrity of power connectors to deliver valuable electric service,.
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CONNECTOR THEORY FAILURE MODES AND PRACTICAL APPLICATION Your Presenter: Arnie Cobb Product Manager Distribution Connector Products
….depend on the integrity of power connectors to deliver valuable electric service, … and this won’t cut it!
WHY DO YOU CHOOSE A PARTICULAR CONNECTOR? • Based on Application • For Mechanical Strength • For Conductivity • Combination of Strength & Conductivity • Sometimes Best Compromise For Reliability • Choice Will Affect Installed Cost
MECHANICAL STRENGTH • Full Tension, ANSI Class 1 (mainly auto splices & deadends) • Typically 95% of Conductor RBS • Some Cases 90% (guying products) • Partial Tension, ANSI Class 2 (bolted, compression) • 40% of Conductor RBS • Minimum Tension, ANSI Class 3 (jumpers, etc) • 5% of Conductor RBS • NEW TENSION CLASS (Included in ANSI C119.4, 2011) • NORMAL TENSION, ANSI Class 1A (mainly bolted deadends) • 60% of Conductor RBS
CONDUCTIVITY, Bronze vs Aluminum Which is More Conductive ? Bronze = 16.4% IACS(typical cast 83600 cu alloy) Aluminum = 37% IACS (typical cast 356-T6) Then why use Bronze? Mechanical strength, Expansion/Contraction, Corrosion issues
PAD-TO-PAD CONNECTIONS ACTUAL CONTACT ZONE • Actual contact zone is concentrated at high pressure, low resistance, area close to bolt holes. • Only about 5% of pad surface area. • Effective contact zone can be increased (resistance reduced) by using conductive hardware. • The number of bolted holes more significant than total pad area.
HARDWARE Conductive Hardware Provides maximum conductivity in single-metal connections. Aluminum or Bronze Hardware will have 4 – 5 times the conductivity of steel 2024-T4 Al Bolts Aluminum-to-Aluminum connections Bronze Hardware Copper & Bronze Connections
FAILURE MECHANISMS • Oxidation and Corrosion • Creep and Stress Relaxation • Thermal Expansion & Ratcheting
OXIDATION • Occurs in the presence of oxygen • Forms a high-resistance coating on metallic surface • Oxides form immediately on copper and aluminum • Thickness depends on temperature on copper • Oxide growth rate on aluminum depends on humidity and temperature • Oxide growth is self-limiting as metal oxide coating covers surface. • Oxide coating protects metal structure from further attack. • Good for structural metals • Bad for electrical connections. Acts as an insulator on conductor.
OXIDATION - FACT or MYTH? • Do You Need To Scrub New Conductor Prior To Installation? • Does Copper Oxidize? • Are You Supposed To Scrub Conductor Dry Or Through Inhibitor?
CORROSION – A BIMETALLIC ISSUE! • Refers to the deterioration of a metal in the presence of water • Loss of electrons to the cathode metal • Generates the release of ions into the solution • Causes the release of material from the anode metal • Material with the more negative galvanic potential corrodes • Aluminum corrodes in galvanic action with copper
CORROSION / OXIDATION PREVENTION • Contact Sealants and Joint Compounds • Seal out both water and air • Water out => No galvanic corrosion • Air out => No oxidation of contact surfaces including conductor strands. Seals out contaminates in polluted atmospheres. • Must remain pliable over wide temperature range • Synthetic types have highest temperature stability
CORROSION - FACT or MYTH? • Does Corrosion Only Happen with Bi-Metallic Connections? • Which Connector On Top (aluminum or bronze) & Why? • Will Tin Plating Reduce Corrosion Rate? • Do You Wire Brush Tin Plated Connectors? Why or Why Not?
INHIBITORS - TYPES • Base Material • Petroleum Base • Original base material • Good product but will tend to break down at high temperatures & evaporates leaving a dry mass • Non Petroleum Base (Veg Oil, Synthetic) • Usually more stable at higher temperatures • Will not harm rubber gloves or cable polymeric materials • Grit Type • Non Gritted • For use on Grooves/Bolted & Pads • Non Conductive Grit • For use on Compression only • Grit usually made from Silicon Oxide which is an Insulator • Grit helps improve gripping strength • Can cause threaded fasteners to gall • Conductive Grit • For use on Compression, Grooves (away from bolt threads), & Pads • Has a micro grit that will not cause arc points like non-conductive grit varieties on grooves and pads • Grit helps improve gripping strength as well as conductivity
CREEP AND STRESS RELAXATION • Applied Mechanical Stress from Clamping force… • Material may creep (elongate) and eventually fail. • Applied stress should be less than the yield strength of material. • Creep is Plastic Deformation, Intensified at High Temperatures • Reduction of residual contact pressure over time.
THERMAL EXPANSION AND THERMAL RATCHETING • Metals expand when exposed to heat. • Different metals have different rates thermal expansion. • Thermal ratcheting • Repeated process of expansion and contraction • From changes in temperature due to current load cycling.
BELLEVILLE WASHERS A Properly Sized / Designed Belleville Washer balances the Clamping Force of the Bolt, Which in our case is approximately 4400 Lbf . Split Ring Lock Washers compress at only about 350 Lbf
THERMAL RATCHETINGFACT or MYTH? • Are Set Screws In Current Path Susceptible to Thermal Ratcheting? • Can You Over Tighten a Belleville Washer?
A LEADING FAILURE WE SEE ONRETURNED GOODS OVER TORQUE Is over torque worse than over torque?
BOLT ELONGATION Excessive Torque will exceed yield strength and accelerate creep ultimately providing less clamping force. Cross Section of ½-13 Bolt 2024-T4 Aluminum Bolts 43 KSI Yield @ 50C = 6098 lb!
SPLICE INSTALLATION - FACT or MYTH? How close together should splices be installed? To each other? To a terminating device?(auto & compression) See anything wrong with these pictures?
WHAT DOES ANSI SAYS ON THE SUBJECT? For Mechanical Testing of Deadends, Splices, Compression…Basically All Mechanical Connectors
OUR RECOMMENDATIONS • No closer than ANSI testing procedure specifications for exposed conductor length. • A good “Rule of Thumb” is: • No closer than 3X the length of the splice for 4/0 and smaller conductor. • Example: Splice for #2 conductor is 12” long. Therefore no closer than 3 feet. • If possible, the longer the distance the better. • When ANSI test procedure is exposed conductor length is longer than rule of thumb, ANSI rules apply. • Minimum tension requirement of 15% or greater (Competitors and Lineman’s Handbook agree) • Splices in slack span (less than 10%) are not recommended.
AUTOMATIC SPLICES ON SLACK SPAN Should automatic splices be installed on slack span? See anything wrong with these pictures?
REVIEW • Aluminum conductor should be wire brushed. • Formally recommended through inhibitor, now okay dry • Inhibit, Inhibit, Inhibit • Non Gritted - For Use On Grooves/Bolted & Pads • Non Conductive Grit – For Use On Compression Only • Conductive Grit - For Use On Compression, Grooves (away from bolt threads), & Pads • Torque Is An Issue. Don’t Over-Torque! • Bi-metallic Connections – Aluminum On Top • Remember Copper Salts • Do Not Wire Brush Tin Plated Connectors. • Tin Plating Is Very Thin And Is Easily Scrubbed Off • Do Not Reuse hardware. • Do Not Use Automatics (Splices Or Deadends) On Slack Span. • Minimum Distance Between Splices = 3X The Length Of The Splice or ANSI Spec