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Microprocessor-Based Relays

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Title: Microprocessor-Based Relays


1
Microprocessor-Based Relays Implementation,
Conflicts, and Corrective Actions
Steven V. Deases AEP Station Engineer
2
Intro Discussion Focus
  • Level High-Level Topic Discussion
  • Scope Station Protection
  • Questions Reserve Questions until the Conclusion
  • Time Limitation Approximately 30 minutes total
  • Prospective AEPs Experiences

3
Intro Discussion Focus
  • Structure
  • Implementation Strategy
  • Conflicts Encountered
  • Corrective Actions
  • Topics
  • Engineering Processes
  • SCADA Communications
  • Commissioning Procedures

4
Intro Presenters Background
  • Work Group
  • AEP Transmission Region Operations Texas
  • Technical Support Engineering
  • Station Equipment and Protection Controls
  • Job Functions
  • Application Engineering Design Review
  • Technical Aid to Field Personnel
  • Project Coordination Administrative Support
  • Technical Training of Technicians and Engineers
  • Process Improvement Quality Control
  • System Performance Analysis Reporting

5
Microprocessor Technology
Evolution of Protection Devices
Electromechanical
Steady State
Microprocessor
6
Microprocessor Technology
  • Advantages
  • More sensitive and scalable
  • Communication Options
  • Fault Oscillography and SER data
  • Better targeting and annunciation
  • More reliable failure alarm also included
  • Advanced protection features all in one box
  • Economical both Financially and Physically
  • Disadvantages
  • Shift in Thought Digital Logic v. Circuitry
  • More Complex Logical Systems
  • Longer Commissioning Procedures
  • Additional Training Requirements

7
Engineering Processes
  • Engineering Aspects Affected
  • Standards
  • Design
  • Documentation
  • Philosophy

8
Engineering Processes
  • Implementation Strategy
  • Develop internal Standard Schemes for Protection
    Control using Microprocessor-based Relays that
    would replace existing Electromechanical Relays
    and phase them out
  • These replacement schemes would be designed with
    a protection zone scope (Line, Bus,
    Transformer, etc.)
  • The developed standards defined details such as
  • relay brand/model options
  • general protection scheme with generic wiring
  • relay panel plate configurations
  • relay setting templates with predetermined logic

9
Engineering Processes
  • Documentation
  • The intent of the documentation was to
    communicate the standards to the design groups
    for implementation
  • Application Guides were written which described
  • What standard schemes were available
  • Where the standard schemes were to be applied
  • What kind of protection was intended
  • The general relay setting philosophy
  • CAD drawings with multiple layers were also
    developed to match the standard relay schemes

10
Engineering Processes
  • Conflicts Encountered
  • Despite the large effort in strategizing the
    implementation process, there still were several
    conflicts encountered
  • Perpetual evolution of standards due to newly
    gained experiences
  • Design Interpretation of standards resulted in
    inconsistent implementation
  • Lack of adequate communication and training of
    standards

11
Engineering Processes
  • Corrective Actions
  • To combat these engineering problems, we created
    and adopted
  • Design Module concept that specifically lays
    out the entire intended design package of
    protection for a specific station application
  • E.g. 25MVA Power Xfmr w/ LV CB (Xfmr and LV Bus
    protection included)
  • Consistent Relay Setting Calculation Sheets
  • Additional Training of how to use these tools and
    the philosophy intent
  • Revision control of Standards

12
SCADA Communications
  • SCADA Communication Components
  • Relay
  • RTU
  • SCADA Master

13
SCADA Communications
  • Implementation Strategy
  • Send all potentially necessary data points to
    RTU, then filter which were actually deemed
    necessary for Dispatchers to be sent to the SCADA
    Master
  • Let local personnel decide which points the SCADA
    system are needed, configure the devices
    themselves, and commission the data path
  • Use existing equipment and communication
    protocols when able

14
SCADA Communications
  • Conflicts Encountered
  • Inconsistent amounts / types of data being sent
    to Dispatch
  • Project Slowdown due to communication discussions
    on every project
  • Little documentation of what was implemented
  • Confusion regarding data identity due to lack of
    data point naming conventions
  • SCADA Alarm Logging was not chronological

15
SCADA Communications
  • Corrective Actions
  • RTU Point Assignment documentation
  • Communication Configurations for relays RTUs
    delivered by engineering
  • Training of advanced commissioning techniques
  • Convert RTUs and Communication Protocol

16
OLD
Hard Wired
Harris
RTU
Relay
SCADA Master
NOW
DNP
Harris
RTU
Relay
SCADA Master
FUTURE
DNP
DNP
RTU
Relay
SCADA Master
17
Commissioning
  • Commissioning Aspects
  • Practices
  • Procedures
  • Troubleshooting

18
Commissioning
  • Implementation Strategy
  • It was initially assumed that commissioning
    Microprocessor-based relays was essentially very
    similar to commissioning Electromechanical
    relays.
  • Test each protection element individually while
    monitoring trip output.
  • Technician can create his own test plan based on
    past electromechanical procedures.

19
Commissioning
  • Conflicts Encountered
  • The Black Box phenomena one device that
    performs multiple functions with several
    different outputs (trips, alarms, targets,
    annunciations, etc.)
  • Element Testing vs. Functional Testing
  • Those installing the scheme often asked, Whats
    the intent of the design?
  • How should the scheme operate for this
    scenario?
  • The procedure for troubleshooting a mis-operation
    or failed test is much different than that of an
    electromechanical relay scheme

20
Commissioning
  • Corrective Actions
  • Commissioning Guides
  • Automated Testing Procedures with Pre-determined
    Test Plans
  • Design Intent Documents provided with each
    engineered job
  • Logic Diagrams matching actual programmed
    internal logic
  • New Training Program at New Training Facility

21
Lessons Learned
  • Process Improvements
  • Re-engineering the process is sometimes needed
  • Continual auditing of the process
  • Specify Process Feedback Loops
  • Identify Experts for Focus Groups
  • Defined Time Interval for Revisions to take place
  • Quality Control
  • Adding quality analysts to team
  • Strengthening peer-review ideals
  • Workforce Solutions
  • Invest in additional engineers, technicians, and
    support staff
  • Invest in Training Programs
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