Electrical Design Analysis

Get it on  Huawei AppGallery now! (Keyword: "ElectricalDEAN") ========== Electrical DEAN for Mobile Devices is an electrical design analysis app based on the Philippine Electrical Code, the SI Modernized Metric System, and equivalent provisions from the National Electrical Code (NFPA 70). Electrical design analysis is primarily about detailed calculations of wire gauges, conduit sizes, protective device ratings, fault currents, voltage drops and other technical matters necessary for the safe and proper operation of electrical systems. The Electrical DEAN mobile app is intended as an educational tool for those who are new in the electrical trade, and as a research tool for veterans who need quick calculations to compare with their own electrical designs. Currently, it covers the fundamentals of electrical design analysis: conductor and conduit data, fault currents and voltage drops (1-phase and 3-phase), and general-purpose circuit sizing (circui...

RACEWAY SIZES (CONDUIT AND TUBING) 1.) Raceway Sizing There are three options for sizing raceways according to 2017 PEC Table 10.1.1.1 [ or 2017 NEC Chapter 9 Table 1 ], based on cross-sectional areas: A.) 53% raceway area for 1 conductor (a multiconductor cable is treated as a single conductor [Note 9]) B.) 31% raceway area for 2 conductors C.) 40% raceway area for over 2 conductors 1.1.) Choosing Between Alternatives For future expansion purposes, option (A) is far from practical. This may have use in very specific installations that are assumed to be not needing any expansions, but upgrades will definitely happen and option (A) will eventually become a bottleneck. Option (B) for 2 conductors having a smaller area than either option (A) for 1 conductor or option (C) for over 2 conductors may seem nonsensical, but it actually does make sense. Having 2 conductors usually means 2 live wires supplying loads that may require an equipment grounding conductor ...

WIRE AMPACITIES, INSULATORS, AND IMPEDANCES Below are some useful tables pertaining to ampacities, insulators, and impedances of various wires. These are derived from the 2017 Philippine Electrical Code [ or the 2017 National Electrical Code ], but are rearranged in a manner that is easier to interpret and understand. 1.) Allowable Ampacities of Insulated Conductors in Raceway. The areas, ampacities, and insulation types of the following tables are based on 2017 PEC Table 3.10.2.6(B)(16) [ or 2017 NEC Table 310.15(B)(16) ]. 1.1.) Copper Wire Ampacities --------------------------------------- |  Copper  |  Insulation Max Op. Temp | --------------------------------------- |   Area   | 60degC | 75degC | 90degC | |   mm^2   |  Amps  |  Amps  |  Amps  | --------------------------------------- |    2.0   |    15  |    20  |    25  ...

SITUATION In 2017 PEC Appendix D Example D14 Steps 10.2.d and 10.3.d, computing the fault currents yields almost 19,000 Amperes for point "b" and 11,000 Amperes for point "c". However, this same example as presented in the previous scenario results in fault currents of only around 17,000 Amperes for point "b" and 10,000 Amperes for point "c". Why are they different? ANALYSIS 1.) PROCEDURE IN 2017 PEC EXAMPLE D14 By inspection, it can be verified that all values in 2017 PEC D14 and in the previous scenario are almost identical, except for the new motor per-unit values used in the impedance diagrams of 2017 PEC D14 Steps 10.2.b and 10.3.b. 1.1.) 2017 PEC D14 Step 8 Motor Contribution In this step, the motor per-unit impedance is initially estimated at 0.25 pu (equivalent to a 25% subtransient reactance neglecting resistance), after considering the recommendation in IEEE Std 141-1993 Section 4.5.4.1. Conversion to the common...

The following items are examples listed in 2017 PEC Appendix D (Wiring Design Examples). Example D1: "Single Family Dwelling Unit, up to 50 square meters Floor Area with Load not exceeding 3,680 Volt-Amperes" Example D2: "Single Family Dwelling Unit, up to 150 square meters Floor Area (Not more than six circuits)" Example D3: "Single Family Dwelling Unit, up to 150 square meters Floor Area (More than six circuits)" Example D4: "Single Family Dwelling Unit, up to 150 square meters Floor Area, Optional Calculation" Example D5: "Single Family Dwelling Unit, more than 150 square meters Floor Area, 230 Volts, Single-Phase Service" Example D6: "Single Family Dwelling Unit, more than 150 square meters Floor Area, 400/230 Volts, Three-Phase, 4-Wire Service" Example D7: "Multi Family Dwelling Unit, 230 Volts, Single-Phase Service" Example D8: "Multi Family Dwelling Unit, 400/230 Volts, Three-Phase,...

TREATING DESIGN ANALYSIS AS MANDATORY It is important to keep in mind that, before any actual electrical work is done, everything starts at the design stage. Considerations on SAFETY and QUALITY need to be included (and examined) on paper in order to avoid any mistakes that may result in costly back jobs, or worse, loss of life and property due to electrical fire. Therefore, electrical practitioners in the Philippines need to be aware of the following provisions in the Philippine Electrical Code (PEC) concerning design analysis. ===== 2017 PEC 1.0.1.5 (A) Mandatory Rules. [ 2017 NEC 90.5 (A) ] "Mandatory rules of this Code are those that identify actions that are specifically required or prohibited and are characterized by the use of the terms SHALL or SHALL NOT." ===== 2017 PEC 1.3.2.1 (F) Plan Requirements - Design Analysis . [ This PEC provision does not exist in NEC. ] "Design analysis SHALL be included on the drawings or SHALL be submitted on se...

A SIMPLE COMPARISON OF SYNCHRONOUS AND INDUCTION MOTORS Synchronous Motor = stator windings are the same as those of induction motors = rotor windings are usually flexible copper coils connected to a separate DC exciter = the DC excitation supplied to the field coils produces the rotor magnetic flux = constant speed from no-load to full-load, but may stop when overloaded = works as power factor corrector while providing stable torque to drive loads Induction Motor = stator windings are the same as those of synchronous motors = rotor "windings" are usually rigid aluminum bars, skewed and short-circuited at each end = self-excited via induction like a transformer to produce rotor magnetic flux = variable speed based on frequency, but can be affected by harmonics = can provide high torque to accommodate temporary overloads Each has an advantage, depending on the desired application.

MOTOR EFFICIENCY DISSECTED ANALYSIS 1.) Law of Conservation of Energy (ideal): W,in = W,out 2.) First Law of Thermodynamics (practical): Q = W + dU Total energy = Work done + change in Internal energy W,in = W,out + W,losses W,in > W,out Energy input is always greater than energy output because of energy losses. 3.) Utilizing energy through time: (W,in / t) = (W,out / t) + (W,losses / t) 4.) Power and energy relationship: P = W / t P,in = W,in / t P,out = W,out / t P,losses = W,losses / t 5.) Power flow equation: P,in = P,out + P,losses P,in > P,out Power input is always greater than power output because of power losses. 6.) Usable power and energy: efficiency = (P,out / P,in) * 100 efficiency = (W,out / W,in) * 100 SUMMARY Motor efficiency is all about how well a motor converts energy input into energy output, given imperfections like friction and waste heat.