Advanced Electrical Design Training
$5500.00
Advanced Electrical Design Training: 5-Day Expert-Level Engineering Course
Course Overview
This advanced Electrical Design Training provides expert-level knowledge for experienced engineers designing complex electrical systems. This intensive 5-day program covers advanced load flow analysis, power quality engineering, harmonics mitigation, transient analysis, arc flash studies, advanced protection coordination, renewable energy integration, and sophisticated modeling techniques using industry-leading software platforms.
Who Should Attend This Advanced Electrical Design Course?
Senior Electrical Design Engineers with 3+ years experience
Lead Engineers managing complex design projects
Power System Engineers in consulting and utilities
Project Engineering Managers overseeing technical teams
Specialist Design Engineers in critical facilities
Protection and Control Engineers designing advanced schemes
Industrial Power Engineers in heavy industries
Energy Consultants providing advanced technical solutions
PhD and Master’s Candidates in power systems
Commissioning Engineers with design responsibilities
Course Objectives
Participants will master:
Advanced power system analysis for complex facilities
Harmonic analysis and power quality engineering
Transient overvoltage analysis and mitigation
Arc flash hazard assessment and mitigation strategies
Advanced protection coordination and relay settings
Renewable energy and energy storage integration
Dynamic motor starting and voltage analysis
Sophisticated modeling in ETAP, SKM, PowerFactory, or PSS/E
Day 1: Advanced Load Flow Analysis and System Studies
Morning Session: Complex Load Flow Studies
Topics Covered:
Advanced load flow analysis techniques and methodologies
Newton-Raphson and Fast Decoupled methods deep-dive
Optimal power flow (OPF) and economic dispatch
Contingency analysis: N-1, N-2, and beyond
Voltage stability assessment: PV and QV curves
Static and dynamic voltage collapse analysis
FACTS devices modeling: SVC, STATCOM, TCSC
Distributed generation impact on load flow
Advanced Concepts:
Multi-area load flow, DC load flow for market studies, probabilistic load flow for uncertainty analysis.
Afternoon Session: Voltage Regulation and Power Factor Optimization
Topics Covered:
Advanced reactive power management strategies
Optimal capacitor placement algorithms
Voltage-VAR optimization (VVO) techniques
On-load tap changer (OLTC) coordination
Step voltage regulator placement and settings
Power factor correction system design for industrial plants
Automatic power factor correction (APFC) panels
Cost-benefit analysis for reactive compensation
Case Study:
Complete voltage profile optimization for industrial facility with multiple voltage levels and generation sources.
Day 2: Harmonic Analysis and Power Quality Engineering
Morning Session: Harmonics and Power Quality
Topics Covered:
Harmonic theory: characteristic and non-characteristic harmonics
Harmonic sources: VFDs, rectifiers, arc furnaces, LED lighting
IEEE 519 and IEC 61000 standards compliance
Total Harmonic Distortion (THD) calculations: voltage and current
Resonance conditions and harmonic amplification
Harmonic load flow analysis using software
K-factor transformers and derating requirements
Telephone Influence Factor (TIF) calculations
Power Quality Issues:
Voltage sags, swells, and interruptions analysis
Flicker assessment and mitigation
Notching and commutation effects
Interharmonics and subharmonics
Afternoon Session: Harmonic Mitigation Design
Topics Covered:
Passive harmonic filter design: single-tuned, high-pass, damped
Filter component sizing and quality factor selection
Active harmonic filter (AHF) specification and application
Hybrid filter solutions for complex installations
Phase-shifting transformers for harmonic cancellation
12-pulse and 18-pulse rectifier configurations
Multi-pulse converter design considerations
Electromagnetic interference (EMI) and mitigation
Design Workshop:
Complete harmonic analysis and filter design for industrial plant with multiple VFD loads.
Day 3: Arc Flash Analysis and Advanced Protection Design
Morning Session: Arc Flash Hazard Assessment
Topics Covered:
Arc flash fundamentals and incident energy calculations
IEEE 1584-2018 standard methodology and updates
NFPA 70E hazard risk categories and PPE selection
Arc flash boundary calculations
Short circuit contribution analysis for arc flash
Incident energy reduction techniques and strategies
Arc flash relay settings and instantaneous protection
Arc-resistant equipment specifications
Software Applications:
Arc flash analysis using ETAP, SKM PowerTools, or EasyPower including label generation and reporting.
Afternoon Session: Advanced Protection Coordination
Topics Covered:
Complex protection coordination schemes
Directional overcurrent protection in loop systems
Distance protection zones and relay settings
Differential protection: transformers, generators, busbars, motors
Adaptive protection and wide-area protection
Microprocessor relay programming and logic design
IEC 61850 communication-based protection
Protection coordination with distributed generation
Advanced Topics:
Loss of field protection for synchronous generators
Negative sequence protection schemes
Under-frequency and under-voltage load shedding
Out-of-step protection and power swing detection
Synchrophasor-based protection schemes
Day 4: Dynamic Analysis and Motor Starting Studies
Morning Session: Transient Stability and Dynamic Analysis
Topics Covered:
Power system transient stability analysis fundamentals
Generator dynamic models: classical, subtransient, transient
Excitation system and governor modeling
Critical clearing time calculations
Multi-machine stability assessment
Fault ride-through requirements for generation
Power system stabilizers (PSS) design and tuning
Remedial action schemes (RAS) and special protection systems
Simulation Workshop:
Time-domain simulation of system disturbances and stability assessment.
Afternoon Session: Motor Starting and Voltage Dip Analysis
Topics Covered:
Large motor starting analysis and design considerations
Starting methods comparison: DOL, star-delta, autotransformer, soft-start, VFD
Voltage dip calculations during motor acceleration
Starting torque vs. load torque curves
Acceleration time calculations
Inrush current and harmonic impacts
Motor reacceleration after voltage dip
Sequential motor starting strategies
Dynamic Simulation:
Complete motor starting study including transient torque, voltage, and current analysis using advanced software.
Day 5: Renewable Energy Integration and Advanced Topics
Morning Session: Distributed Energy Resources Integration
Topics Covered:
Solar PV system electrical design at utility scale
Inverter selection and grid code compliance
Maximum power point tracking (MPPT) and performance
PV plant collection system design
Wind turbine electrical systems and grid integration
Energy storage system (ESS) design: BESS sizing and applications
Microgrid design and islanding considerations
Grid interconnection studies: steady-state and dynamic
Advanced Modeling:
Renewable energy modeling in power system software
Probabilistic analysis for variable generation
Frequency and voltage ride-through capability
Active and reactive power control strategies
Afternoon Session: Advanced Design Applications
Mission-Critical Facility Design:
Data center electrical design: Tier III/IV configurations
2N, N+1, and distributed redundant systems
Automatic and static transfer switches (ATS/STS)
Power distribution unit (PDU) design
UPS systems: topology, sizing, and paralleling
Emergency power off (EPO) systems
Industrial Applications:
Heavy industrial power systems: mining, steel, cement
Arc furnace electrical supply design
Medium voltage motor control and protection
Plant-wide power factor correction
Captive power plant integration
Healthcare Facility Design:
Essential electrical system (EES) per NFPA 99
Isolated power systems for critical care areas
Life safety branch and critical branch design
Equipment system and normal system separation
Advanced Software Mastery Session
ETAP Advanced Features:
Dynamic simulation modules and setup
Optimal load flow and contingency analysis
Reliability assessment and FMEA
Cable thermal analysis and ampacity derating
Protective device evaluation
Custom scripting and automation
DIgSILENT PowerFactory:
RMS and EMT simulation capabilities
Controller design and tuning
Advanced generator and load models
Quasi-dynamic simulation
Python scripting for automation
SKM PowerTools Advanced:
Motor acceleration studies
Optimal protection and coordination
Arc flash mitigation strategies
Transient motor starting analysis
PSS/E for Large Systems:
Utility-scale system modeling
Inter-area oscillation analysis
Contingency screening and ranking
Renewable energy integration studies
Emerging Technologies and Future Trends
Topics Covered:
DC distribution systems: HVDC, MVDC, LVDC applications
Wide bandgap semiconductors: SiC, GaN in power electronics
Solid-state transformers and breakers
Virtual power plants and aggregated DER
Vehicle-to-grid (V2G) technology integration
Artificial intelligence in electrical design
Digital twin technology for power systems
Blockchain applications in energy systems
Design Optimization and Economics
Topics Covered:
Life-cycle cost analysis (LCCA) for electrical systems
Energy efficiency optimization techniques
Demand charge reduction strategies
Peak shaving and load shifting design
Energy management system (EMS) integration
Total cost of ownership (TCO) calculations
Net present value (NPV) and return on investment (ROI)
Sustainability metrics and LEED considerations
Code Compliance and Advanced Standards
International Standards:
IEEE 519: Harmonic control in electrical power systems
IEEE 1584: Arc flash hazard calculation
IEEE 242 (Buff Book): Protection and coordination
IEEE 493 (Gold Book): Reliability design
IEEE 399 (Brown Book): Power system analysis
IEC 60909: Short-circuit current calculation
IEC 61850: Substation automation and communication
IEC 62305: Lightning protection system design
Final Session: Comprehensive Advanced Project
Capstone Design Project:
Complete advanced electrical design for complex facility including:
Multi-voltage level load flow study
Short circuit analysis with motor contribution
Advanced protection coordination study
Arc flash assessment and mitigation plan
Harmonic analysis and filter design
Motor starting and voltage dip study
Renewable energy integration analysis
Transient stability assessment
Power quality improvement recommendations
Equipment specifications and single-line diagrams
Professional Assessment:
Advanced problem-solving examination
Software-based design project presentation
Protection coordination practical exercise
Harmonic analysis case study report
Peer review and technical critique session
Interactive discussion with industry experts
Advanced Professional Certificate
IEEE or equivalent continuing education units (CEUs)
Course Benefits and Learning Outcomes
Upon completion, participants will be able to:
Conduct comprehensive power system analysis for complex facilities
Design harmonic mitigation systems per IEEE 519 compliance
Perform detailed arc flash studies and implement mitigation strategies
Develop advanced protection coordination schemes
Model and integrate renewable energy and storage systems
Analyze transient stability and dynamic system behavior
Use advanced features of ETAP, SKM, PowerFactory, or PSS/E
Design mission-critical and redundant power systems
Optimize power quality and system efficiency
Prepare detailed technical reports and engineering documentation
Lead complex electrical design projects with confidence
Training Methodology
This advanced electrical design course employs:
Expert instruction from senior consulting engineers
Complex real-world case studies from actual projects
Extensive hands-on software modeling exercises
Interactive problem-solving workshops
Peer collaboration on advanced design challenges
Industry best practices and lessons learned
Guest lectures from subject matter experts
Design review and critique sessions
Course Materials Provided
Participants receive:
Advanced electrical design reference manual
Software modeling templates and libraries
IEEE standards excerpts and technical papers
Design calculation spreadsheets and tools
Case study documentation and solutions
Technical specification examples
Professional Certificate of Advanced Training
Access to online resource library
Prerequisites
Required Background:
Bachelor’s degree in Electrical Engineering
Minimum 3 years electrical design experience
Proficiency in load flow and short circuit analysis
Working knowledge of ETAP, SKM, or similar software
Understanding of NEC/IEC codes and standards
Completion of basic electrical design course or equivalent
Software Proficiency
Participants should have working knowledge of at least one:
ETAP (Electrical Transient Analyzer Program)
SKM PowerTools
DIgSILENT PowerFactory
EasyPower
PSS/E (for utility engineers)
Post-Course Benefits
Access to advanced technical support forum
Continuing education units (CEUs) for PE license
Professional networking with senior engineers
Updates on new standards and technologies
Advanced training pathway recommendations
Industry conference and publication recommendations
Keywords: advanced electrical design, power system analysis, arc flash analysis, harmonic analysis, protection coordination, ETAP training, electrical design software, motor starting analysis, transient stability, power quality engineering, renewable energy integration, load flow analysis, IEEE 1584, IEEE 519, advanced protection design, microgrid design, distributed generation, electrical system optimization, mission critical design, data center electrical design
