11 1Table A.1 Key Points of Sarbanes‐Oxley Act (SOX)Table A.2 CIP‐002 through CIP‐009 Cybersecurity frameworkTable A.3 Basel II Compliance Benefits
12 3Table C.1 Average maximum inlet temperature per loadTable C.2 Temperatures about the mean value per loadTable C.3 Temperature spread based on the Standard deviation
List of Illustrations
1 Chapter 1Figure 1.1 Hidden Costs of OperationsFigure 1.2 Typical screenshot of SmartWALK™ dashboardFigure 1.3 SmartWALK™ mobile screenshotFigure 1.4 Screenshot of SmartTEAM® Learning Management System
2 Chapter 2Figure 2.1 US Primary Energy Sources.Figure 2.2 Number of Breaches and records exposed from 2005 to 2019Figure 2.3 Fuel Sources for Electricity Generation in the U.S. in 2018Figure 2.4 Potential Causes of Load Interruption or DowntimeFigure 2.5 The Tiers of the Electric Grid from Generation to Chip. Derived f...Figure 2.6 Solar Flare.Figure 2.7 EMP Waveform – MIL‐STD‐461G Test Method RS105Figure 2.8 RS105 Transient Generator and Transmission LineFigure 2.9 Damped Sinusoidal Transient – MIL‐STD‐461G Test Method CS1116Figure 2.10 SmartWALK™ mobile deviceFigure 2.11 The Smart Grid Network and its features.
3 Chapter 3Figure 3.1 “Seven steps” is a continuous cycle of evaluation, implementation...Figure 3.2 Sample SCS ScreenshotFigure 3.3 Sample TCC Curve AnalysisFigure 3.4 Traditional AC DistributionFigure 3.5 DC DistributionFigure 3.6 Electronic BallastFigure 3.7 Absorption ChillerFigure 3.8 Typical Fuel CellFigure 3.9 Microturbine CCHP SystemFigure 3.10 DC Monitoring EquipmentFigure 3.11 SmartTEAM™ mobile screenshotFigure 3.12 Open rear door of containerized Data Center
4 Chapter 4Figure 4.1 Theory of Predictive MaintenanceFigure 4.2 Hazard Risk Category (HRC) Arc Rating (Reference of Chicago Prote...Figure 4.3 Arc Flash BoundariesFigure 4.4 A small thermographic camera and a typical installationFigure 4.5 Sample IR scanning tracking
5 Chapter 5Figure 5.1 GeneratorFigure 5.2 Load Bank TestingFigure 5.3 Generator Control Cabinet
6 Chapter 6Figure 6.1 Basic installation practices for all tanks, whether aboveground o...Figure 6.2 Typical fuel storage and distribution system flow diagram.Figure 6.3 Poorly arranged system.Figure 6.4 System using the same components as in Figure 6.3 but arranging t...Figure 6.5 System using individual components to prevent a single point of f...Figure 6.6 System that further increases reliability by adding redundancy fo...
7 Chapter 7Figure 7.1 Break Before Make ATSFigure 7.2 Basic ATS EnclosureFigure 7.3 Break Before Make ATS with Isolation BypassFigure 7.4 ATS Enclosure Equipped with Isolation BypassFigure 7.5 Closed Transition ATSFigure 7.6 Closed Transition ATS with Isolation BypassFigure 7.7 Closed Transition ATS EnclosureFigure 7.8 Delayed Transition ATSFigure 7.9 Delayed Transition ATS with Isolation BypassFigure 7.10 Delayed Transition Transfer Switch EnclosureFigure 7.11 Soft Load Power Transfer Switch
8 Chapter 8Figure 8.1 Typical Static Switch One Line
9 Chapter 9Figure 9.1 Cost of downtimeFigure 9.2 Power Factor Beer Mug AnalogyFigure 9.3 Power Factor WaveformsFigure 9.4 Typical electric systemFigure 9.5 This undistorted sine wave is also known as the fundamental wavef...Figure 9.6 Three‐phase power is produced from the rotating windings of a gen...Figure 9.7 Types and relative frequency of power quality disturbances.Figure 9.8 Example part of an IEC 61000‐4‐30 Class A Edition 3 compliance ce...Figure 9.9 Transients shown in waveformFigure 9.10 Waveforms of RMS variationsFigure 9.11 Motor‐start waveform signature.Figure 9.12 Voltage swell timeline.Figure 9.13 Unbalance timelineFigure 9.14 Notching waveformFigure 9.15 The fundamental and the 5th harmonic.Figure 9.16 The harmonic spectrum indicating a problem.Figure 9.17 The additive effect of the triplen harmonics.Figure 9.18 Harmonic distortion waveform.Figure 9.19 Interruption timeline.Figure 9.20 CBEMA curveFigure 9.21 ITIC curveFigure 9.22 A portion of data obtained from the Distribution Power Quality M...Figure 9.23 Load problems – Power Quality Troubleshooting ChecklistFigure 9.24 Building distribution problems – Power Quality Troubleshooting C...Figure 9.25 Facility transformer and main service equipment problem – Power ...
10 Chapter 10Figure 10.1 Double Conversion: In normal operationFigure 10.2 Double Conversion: On BatteryFigure 10.3 Double Conversion: Static BypassFigure 10.4 Double Conversion: Internal BypassFigure 10.5 Typical 3‐phase Rectifier Schematic utilizing SCRs as the power ...Figure 10.6 Conventional Delta Conversion Online UPSFigure 10.7 Conventional Two‐Level inverter topology and Variable Width Puls...Figure 10.8 Three‐Level inverter topology and Variable Width Pulse TrainFigure 10.9 Silicon Valence BandFigure 10.10 SiC 73% Reduction Power LossesFigure 10.11 SiC Heat Loss Energy SavingsFigure 10.12 Diesel UPSFigure 10.13 N UPS ConfigurationFigure 10.14 N+1 UPS ConfigurationFigure 10.15 Isolated Redundant UPS ConfigurationFigure 10.16 N+2 UPS ConfigurationFigure 10.17 2N UPS ConfigurationFigure 10.18 2n+1 ConfigurationFigure 10.19 Distributed Redundant UPS ConfigurationFigure 10.20 Typical Wet Cell BatteryFigure 10.21 Typical VRLA BatteryFigure 10.22 Flooded Cell Battery RoomFigure 10.23 Cutaway of a flywheelFigure 10.24 An integrated 300 kVA flywheel/UPS
11 Chapter 11Figure 11.1 2011 ASHRAE Environmental GuidelinesFigure 11.2 Heat transfer in a simple graphical format.Figure 11.3 CRAC Unit – Illustrating the Compressors in Place within the Uni...Figure 11.4 Illustration of CRAH unit with the Chilled Water ValveFigure 11.5 Heat transfer for air‐cooled heat rejection equipment.Figure 11.6 Heat transfer for a cooling tower.Figure 11.7 Generic chiller diagram.Figure 11.8 Air‐cooled chiller diagram.Figure 11.9 Typical packaged air‐cooled chiller.Figure 11.10 Illustration of the CRAC – DX refrigeration loopFigure 11.11 Water‐cooled chiller diagram.Figure 11.12 Typical water‐cooled chiller.Figure 11.13 Schematic overview of a generic cooling tower flow.Figure 11.14 Direct cooling towers on an elevated