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DTSTART;TZID=US/Alaska:20191007T080000
DTEND;TZID=US/Alaska:20191008T170000
DESCRIPTION:IT IS FINALLY HERE! After 16 long years\, the next edition of I
 EEE 1584 was finally published. In this two-day arc flash training class\,
  Jim Phillips\, P.E.\, introduces the 2018 edition of the IEEE 1584. Jim d
 iscusses the changes\, walks you through the calculations with his new wor
 ksheets and how the 2018 edition is is used in arc flash studies.\n\nThe 2
 018 edition of IEEE 1584 is a major game changer. Almost everything has ch
 anged since the original edition was introduced in 2002.\n\nHighlights of 
 the next edition include:\n\n- Five different electrode configurations to 
 enable more detailed modeling\n- Vertical electrodes in a metal box/enclos
 ure – VCB (also in 2002 Edition)\n- Vertical electrodes terminated in an
  insulating barrier in a metal box/enclosure – VCCB\n- Horizontal electr
 odes in a metal box/enclosure – HCB\n- Vertical electrodes in open air 
 – VOA (also in 2002 Edition)\n- Horizontal electrodes in open air – HO
 A\n\n- More choices for enclosure types and sizes\n- Enclosure correction 
 factor calculation to adjust for specific enclosure size\n- The effect of 
 grounding has been eliminated\n- An arcing current variation factor calcul
 ation replaces the 85% factor\n- Calculations performed at 1 of 3 voltage 
 levels with interpolation to actual voltage\n- The 125 kVA transformer exc
 eption was eliminated\n- Each calculation is performed in 2 steps which in
 cludes an initial calculation based on one of three voltage levels and a s
 econd calculation interpolating to the specific system voltage. The 125 kV
 A “exception” was replaced. Learn why and what has replaced it. What a
 bout the 2 second rule? Jim discusses all this and much more.\n\nCo-sponso
 red by: CH06268 - Alaska Section Chapter\, PE31\n\nSpeaker(s): Jim Phillip
 s\, \n\nAgenda: \n8:00 am to 8:30 am Check in\, Hand out materials 8:30 am
  to 11:30 am Training (breaks will be scheduled during the Class 11:30 am 
 to 12:15 pm Lunch 12:15 pm to 5:00 pm Training (with breaks scheduled\n\nA
 genda – 2018 IEEE 1584 Arc Flash Training Class\n\nINTRODUCTION TO ARC F
 LASH STUDIES\n\nARC FLASH AND OTHER ELECTRICAL HAZARDS\nPhysiological Effe
 cts\, Electrocution\, Tissue Damage\, Internal Organ Damage\, Burns Fibril
 lation\, “Curable” 2nd Degree Burn\n\nCODES AND STANDARDS\nOSHA 29 CFR
  – Part 1910\, Subpart S\, NFPA 70\, National Electrical Code®\, 2018 N
 FPA 70E\, Standard for Electrical Safety in the Workplace\, 2018 IEEE Stan
 dard 1584™\, IEEE Guide for Performing Arc Flash Hazard Calculations\, L
 egal Requirements\, Liability\n\n2018 EDITION – IEEE 1584 – DEVELOPMEN
 T\nHistory of the Development of the 2018 IEEE 1584\, IEEE/NFPA Collaborat
 ion\, Working Group and Project Team\, Almost 2000 New Arc Flash Tests\, W
 hat Took So Long? Range of Applicability\, Data Requirements\, Study Proce
 ss\, Table of Results for the Arc Flash Study Report.\n\nARC FLASH CIRCUIT
  DYNAMICS\nArcing Faults vs. Bolted Faults\, Effect of Current on Overcurr
 ent Device Clearing Time\, Current Limitation\, Effect of Transformer Size
  and Source Strength\n\nMODELING THE ARC FLASH STUDY\nOne-Line\, Data\, Sy
 stem Configuration\, Multiple Sources\n\nELECTRIC UTILITY COMPANY DATA\nWh
 at data should be requested\, minimum and maximum fault current\, why not 
 to use infinite bus calculations\, what if the data can not be obtained?\n
 \nOVERVIEW OF CHANGES TO THE 2018 IEEE 1584\nIntroduction and Summary of t
 he Major Changes\n\nELECTRODE CONFIGURATIONS\nVCB – Vertical electrodes 
 in a metal box/enclosure\, VCCB Vertical electrodes terminated in an insul
 ating barrier in a metal box/enclosure\, HCB – Horizontal electrodes in 
 a metal box/enclosure\, VOA – Vertical electrodes in open air\, HOA – 
 Horizontal electrodes in open air\n\nARCING SHORT CIRCUIT CURRENT CALCULAT
 IONS– LOW VOLTAGE\nCalculation of Intermediate Average Arcing Current\, 
 Calculation Final Arcing Current – Interpolate for Voltage\, Coefficient
 s\, Data\n\nENCLOSURE SIZES AND TYPES\nNew Enclosures\, Sizes and Types\, 
 Gap Distances\n\nENCLOSURE SIZE CORRECTION FACTOR CALCULATIONS\nDeterminin
 g Correction Factor for Enclosure Size. Shallow vs. Typical Enclosure\n\nW
 ORKING DISTANCE\nSelection of Working Distance for Incident Energy Calcula
 tions\n\nARC DURATION\nUsing Time Current Curves\, 2 Second Cut Off\, Arc 
 Sustainability\, 125 kVA Transformer Exception Deletion – Why?\n\nINCIDE
 NT ENERGY CALCULATIONS – LOW VOLTAGE\nCalculation of Intermediate Incide
 nt Energy\, Calculation of Final Incident Energy – Interpolate for Volta
 ge\, Coefficients\, Data\n\nARC FLASH BOUNDARY CALCULATIONS – LOW VOLTAG
 E\nCalculation of Intermediate Arc Flash Boundary\, Calculation of Final A
 rc Flash Boundary – Interpolate for Voltage\, Coefficients\, Data\n\nARC
 ING CURRENT VARIATION FACTOR\nCalculation the Arcing Current Variation Fac
 tor for Minimum Arcing Current\, Replacement for 85% factor\, Applies to a
 ll Voltages\n\nARCING SHORT CIRCUIT CURRENT CALCULATIONS – MEDIUM VOLTAG
 E\nCalculation of Intermediate Average Arcing Current\, Calculation Final 
 Arcing Current – Interpolate for Voltage\, Coefficients\, Data\n\nINCIDE
 NT ENERGY CALCULATIONS – MEDIUM VOLTAGE\nCalculation of Intermediate Inc
 ident Energy\, Calculation of Final Incident Energy – Interpolate for Vo
 ltage\, Coefficients\, Data\n\nARC FLASH BOUNDARY CALCULATIONS – MEDIUM 
 VOLTAGE\nCalculation of Intermediate Arc Flash Boundary\, Calculation of F
 inal Arc Flash Boundary – Interpolate for Voltage\, Coefficients\, Data\
 n\nDC ARC FLASH CALCULATIONS\nV-I Characteristics\, DC Arc Resistance Calc
 ulations\, DC Incident Energy Calculations\, Box vs. Open Arc Calculations
 \, Calculation Worksheets\, Problem Solving\n\nCOMPARISON OF CALCULATION M
 ETHODS AND CONFIGURATIONS\nCalculation Results from 2002 IEEE 1584 Compare
 d to 2018 IEEE 1584\, Comparison or Results for VCB\, VCCB\, HCB\n\nMODELI
 NG TIPS\nSelection of Electrode Configuration\, Enclosure Size\, Gap Dista
 nces\n\nOTHER HAZARD MEASUREMENTS\nLight\, Blast Pressure\, Sound Pressure
 \n\nDETERMINING PPE REQUIREMENTS FROM INCIDENT ENERGY CALCULATIONS\nUsing 
 calculated incident energy to determine PPE requirements. Simplifying the 
 Selection\n\nARC FLASH WARNING LABELS\nJim’s Simplification for Arc Flas
 h Labels to Reduce or Eliminate the Need to Re-Label\, Minimum Requirement
 s\, Label Locations\, ANSI Z535 Requirements\, Incident Energy vs. Site Sp
 ecific PPE vs. Arc Rating\, Signal Words and Colors\n\nBldg: Coast Interna
 tional Inn\, 3450 Aviation Drive\,\, Anchorage\, Alaska\, United States
LOCATION:Bldg: Coast International Inn\, 3450 Aviation Drive\,\, Anchorage\
 , Alaska\, United States
ORGANIZER:seitzak@ieee.org
SEQUENCE:8
SUMMARY:JIM PHILLIP'S 2018 IEEE 1584 ARC FLASH TRAINING CLASS
URL;VALUE=URI:https://events.vtools.ieee.org/m/202167
X-ALT-DESC:Description: <br /><p>IT IS FINALLY HERE!&nbsp\; After 16 long y
 ears\, the next edition of IEEE 1584 was finally published.&nbsp\; In this
  two-day arc&nbsp\;flash training class\, Jim Phillips\, P.E.\, introduces
  the 2018 edition of the IEEE 1584.&nbsp\; Jim discusses the changes\, wal
 ks you through the calculations with his new worksheets and how the 2018 e
 dition is is used in arc flash studies.</p>\n<p>The 2018 edition of IEEE 1
 584 is a major game changer.&nbsp\; Almost everything has changed since th
 e original edition was introduced in 2002.</p>\n<p>Highlights of the next 
 edition include:</p>\n<ul>\n<li>Five different electrode configurations to
  enable more detailed modeling\n<ul>\n<li>Vertical electrodes in a metal b
 ox/enclosure &ndash\; VCB (also in 2002 Edition)</li>\n<li>Vertical electr
 odes terminated in an insulating barrier in a metal box/enclosure &ndash\;
  VCCB</li>\n<li>Horizontal electrodes in a metal box/enclosure &ndash\; HC
 B</li>\n<li>Vertical electrodes in open air &ndash\; VOA (also in 2002 Edi
 tion)</li>\n<li>Horizontal electrodes in open air &ndash\; HOA</li>\n</ul>
 \n</li>\n<li>More choices for enclosure types and sizes</li>\n<li>Enclosur
 e correction factor calculation to adjust for specific enclosure size</li>
 \n<li>The effect of grounding has been eliminated</li>\n<li>An arcing curr
 ent variation factor calculation replaces the 85% factor</li>\n<li>Calcula
 tions performed at 1 of 3 voltage levels with interpolation to actual volt
 age</li>\n<li>The 125 kVA transformer exception was eliminated</li>\n<li>E
 ach calculation is performed in 2 steps which includes an initial calculat
 ion based on one of three voltage levels and a second calculation interpol
 ating to the specific system voltage.&nbsp\; &nbsp\; The 125 kVA &ldquo\;e
 xception&rdquo\; was replaced.&nbsp\; Learn why and what has replaced it.&
 nbsp\; What about the 2 second rule?&nbsp\; Jim discusses all this and muc
 h more.</li>\n</ul><br /><br />Agenda: <br /><p>8:00 am to 8:30 am Check i
 n\, Hand out materials 8:30 am to 11:30 am Training (breaks will be schedu
 led during the Class 11:30 am to 12:15 pm Lunch 12:15 pm to 5:00 pm Traini
 ng (with breaks scheduled</p>\n<p><strong>Agenda &ndash\; 2018&nbsp\; IEEE
  1584 Arc Flash Training Class</strong></p>\n<p><strong>INTRODUCTION TO AR
 C FLASH STUDIES</strong></p>\n<p><strong>ARC FLASH AND OTHER ELECTRICAL HA
 ZARDS</strong><br /> Physiological Effects\, Electrocution\, Tissue Damage
 \, Internal Organ Damage\, Burns Fibrillation\, &ldquo\;Curable&rdquo\; 2n
 d Degree Burn</p>\n<p><strong>CODES AND STANDARDS</strong><br /> OSHA 29 C
 FR &ndash\; Part 1910\, Subpart S\, NFPA 70\, National Electrical Code&reg
 \;\, 2018 NFPA 70E\, Standard for Electrical Safety in the Workplace\, 201
 8 IEEE Standard 1584&trade\;\, IEEE Guide for Performing Arc Flash Hazard 
 Calculations\, Legal Requirements\, Liability</p>\n<p><strong>&nbsp\;2018 
 EDITION &ndash\; IEEE 1584 &ndash\; DEVELOPMENT</strong><br /> History of 
 the Development of the 2018 IEEE 1584\, IEEE/NFPA Collaboration\, Working 
 Group and Project Team\, Almost 2000 New Arc Flash Tests\, What Took So Lo
 ng? Range of Applicability\, Data Requirements\, Study Process\, Table of 
 Results for the Arc Flash Study Report.</p>\n<p><strong>ARC FLASH CIRCUIT 
 DYNAMICS&nbsp\;</strong><br /> Arcing Faults vs. Bolted Faults\, Effect of
  Current on Overcurrent Device Clearing Time\, Current Limitation\, Effect
  of Transformer Size and Source Strength</p>\n<p><strong>MODELING THE ARC 
 FLASH STUDY</strong><br /> One-Line\, Data\, System Configuration\, Multip
 le Sources</p>\n<p><strong>ELECTRIC UTILITY COMPANY DATA</strong><br /> Wh
 at data should be requested\, minimum and maximum fault current\, why not 
 to use infinite bus calculations\, what if the data can not be obtained?</
 p>\n<p><strong>OVERVIEW OF CHANGES TO THE 2018 IEEE 1584</strong><br /> In
 troduction and Summary of the Major Changes</p>\n<p><strong>ELECTRODE CONF
 IGURATIONS</strong><br /> VCB &ndash\; Vertical electrodes in a metal box/
 enclosure\, VCCB Vertical electrodes terminated in an insulating barrier i
 n a metal box/enclosure\, HCB &ndash\; Horizontal electrodes in a metal bo
 x/enclosure\, VOA &ndash\; Vertical electrodes in open air\, HOA &ndash\; 
 Horizontal electrodes in open air</p>\n<p><strong>ARCING SHORT CIRCUIT CUR
 RENT CALCULATIONS&ndash\; LOW VOLTAGE</strong><br /> Calculation of Interm
 ediate Average Arcing Current\, Calculation Final Arcing Current &ndash\; 
 Interpolate for Voltage\, Coefficients\, Data</p>\n<p><strong>ENCLOSURE SI
 ZES AND TYPES</strong><br /> New Enclosures\, Sizes and Types\, Gap Distan
 ces</p>\n<p><strong>ENCLOSURE SIZE CORRECTION FACTOR CALCULATIONS</strong>
 <br /> Determining Correction Factor for Enclosure Size.&nbsp\; Shallow vs
 . Typical Enclosure</p>\n<p><strong>WORKING DISTANCE</strong><br /> Select
 ion of Working Distance for Incident Energy Calculations</p>\n<p><strong>A
 RC DURATION</strong><br /> Using Time Current Curves\, 2 Second Cut Off\, 
 Arc Sustainability\, 125 kVA Transformer Exception Deletion &ndash\; Why?<
 /p>\n<p><strong>INCIDENT ENERGY CALCULATIONS &ndash\; LOW VOLTAGE</strong>
 <br /> Calculation of Intermediate Incident Energy\, Calculation of Final 
 Incident Energy &ndash\; Interpolate for Voltage\, Coefficients\, Data</p>
 \n<p><strong>ARC FLASH BOUNDARY CALCULATIONS &ndash\; LOW VOLTAGE</strong>
 <br /> Calculation of Intermediate Arc Flash Boundary\, Calculation of Fin
 al Arc Flash Boundary &ndash\; Interpolate for Voltage\, Coefficients\, Da
 ta</p>\n<p><strong>ARCING CURRENT VARIATION FACTOR</strong><br /> Calculat
 ion the Arcing Current Variation Factor for Minimum Arcing Current\, Repla
 cement for 85% factor\, Applies to all Voltages</p>\n<p><strong>ARCING SHO
 RT CIRCUIT CURRENT CALCULATIONS &ndash\; MEDIUM VOLTAGE</strong><br /> Cal
 culation of Intermediate Average Arcing Current\, Calculation Final Arcing
  Current &ndash\; Interpolate for Voltage\, Coefficients\, Data</p>\n<p><s
 trong>INCIDENT ENERGY CALCULATIONS &ndash\; MEDIUM VOLTAGE</strong><br /> 
 Calculation of Intermediate Incident Energy\, Calculation of Final Inciden
 t Energy &ndash\; Interpolate for Voltage\, Coefficients\, Data</p>\n<p><s
 trong>ARC FLASH BOUNDARY CALCULATIONS &ndash\; MEDIUM VOLTAGE</strong><br 
 /> Calculation of Intermediate Arc Flash Boundary\, Calculation of Final A
 rc Flash Boundary &ndash\; Interpolate for Voltage\, Coefficients\, Data</
 p>\n<p><strong>DC ARC FLASH CALCULATIONS&nbsp\;&nbsp\;</strong><br /> V-I 
 Characteristics\, DC Arc Resistance Calculations\, DC Incident Energy Calc
 ulations\, Box vs. Open Arc Calculations\, Calculation Worksheets\, Proble
 m Solving</p>\n<p><strong>COMPARISON OF CALCULATION METHODS AND CONFIGURAT
 IONS</strong><br /> Calculation Results from 2002 IEEE 1584 Compared to 20
 18 IEEE 1584\, Comparison or Results for VCB\, VCCB\, HCB</p>\n<p><strong>
 MODELING TIPS</strong><br /> Selection of Electrode Configuration\, Enclos
 ure Size\, Gap Distances</p>\n<p><strong>OTHER HAZARD MEASUREMENTS</strong
 ><br /> Light\, Blast Pressure\, Sound Pressure</p>\n<p><strong>DETERMININ
 G PPE REQUIREMENTS&nbsp\;FROM INCIDENT ENERGY CALCULATIONS</strong><br /> 
 Using calculated incident energy to determine PPE requirements. Simplifyin
 g the Selection</p>\n<p><strong>&nbsp\;ARC FLASH WARNING LABELS</strong><b
 r /> Jim&rsquo\;s Simplification for Arc Flash Labels to Reduce or Elimina
 te the Need to Re-Label\, Minimum Requirements\, Label Locations\, ANSI Z5
 35 Requirements\, Incident Energy vs. Site Specific PPE vs. Arc Rating\, S
 ignal Words and Colors</p>\n<p><strong>&nbsp\;</strong></p>\n<p>&nbsp\;</p
 >\n<p>&nbsp\;</p>
END:VEVENT
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