A Simulation Model for Crowbarring Thyristor Devices - PowerPoint PPT Presentation

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A Simulation Model for Crowbarring Thyristor Devices

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8/9/09. University of North Texas. 2. Advisory Committee ... Significance of the study. Time Line. Questions and Suggestions. 8/9/09. University of North Texas ... – PowerPoint PPT presentation

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Title: A Simulation Model for Crowbarring Thyristor Devices


1
A Simulation Model for Crowbarring Thyristor
Devices
  • By
  • Devender Kasturi

2
Advisory Committee
  • Major Advisor
  • Dr. Albert B. Grubbs.
  • Committee Members
  • Dr. Vijay Vaidyanathan
  • Dr. Monty Smith
  • Industrial Representative
  • Mr. Phillip Havens

3
Overview
  • Introduction
  • Definition of terms
  • Background of the Problem
  • Problem Statement
  • Purpose of the study
  • Methodology
  • Review of Literature

4
Overview
  • Research Questions
  • Assumptions
  • Limitations
  • Hypothesis
  • Expected Outcomes
  • Significance of the study
  • Time Line
  • Questions and Suggestions

5
Introduction
  • Causes for damage of Electronic equipment
  • Wear and tear
  • Overvoltage
  • Overcurrent

6
Overvoltage Overcurrents
  • Lightning
  • Power line cross
  • Conductive spikes
  • Inductive spikes

7
Definition of Terms
  • VDRM Peak Standoff voltage across the device in
    the off condition.
  • IDRM Maximum value of leakage current at VDRM.
  • VT Voltage across the device after it has
    turned on.

8
Definition of Terms
  • VS Maximum voltage across the SIDACtor device
    just before switching on.
  • IH Minimum amount of current required to
    maintain the device in the on state.
  • Surge waveform(ex 10x700?sec)

9
VI characteristics of SIDACtor device
10
Background of the Problem
  • The SIDACtor device
  • Characteristics of actual model
  • Existing SPICE model
  • Comparison of actual device and existing PSpice
    model for a 10x700us surge.

11
Actual Device (P3100) Characteristics
12
Existing PSpice Model (P3100)
13
Actual device Vs Existing model
  • Overshoot of PSpice model is more than 3 times
    than that of actual devices.
  • VT is very high for the PSpice model.

14
Statement of Need
  • There is a need for a new PSPICE model of the
    SIDACtor device.

15
Problem Statement
  • The problem is the characteristics of the actual
    device and that of the existing simulation model
    do not match.

16
Purpose of the Study
  • To develop a PSpice model by modifying the
    existing PSpice model or
  • To develop a new PSpice model.
  • Test the newly developed model for various surge
    waveforms.

17
Research Questions
  • Will the new simulation model have the same
    characteristics as that of actual device?
  • How reliable is the PSpice simulation software?
  • What is the range of operating temperature for
    the device?

18
Methodology
  • Experimental
  • First the existing model is built and tested.
  • Research will be done and the changes that have
    to be done are identified.

19
Methodology
  1. Model is changed and tested for various surge
    events.
  2. Repeat steps 2 and 3 until the simulation model
    characteristics are within 10 of that of actual
    device.

20
Review of Literature
  • Circuit simulators employ Newtons method to
    solve the nonlinear systems of equations that are
    formed during DC and transient analysis.
  • Convergence problems can occur due to poor
    starting points defined for the simulation.

21
Review of Literature
  • Errors in specifying circuit connectivity,
    component values, or model parameter values often
    cause convergence problems.

22
Review of Literature
  • SIDACtors working is similar to that of a
    thyristor except
  • No gate current can be applied to the SIDACtor
  • SIDACtor is bidirectional

23
Assumptions
  • Actual device works properly
  • Test equipment works properly

24
Equation for Current through the thyristor
  • Where Ico1 and Ico2 are leakage currents from
    collector to base and ?1 and ?2 current
    amplification factors

25
Limitations
  • Resources
  • PSPICE software
  • Test Equipment

26
Hypothesis
  • Null Hypothesis
  • The characteristics of the newly developed
    PSpice model and that of actual device differ by
    more than 10.

27
Hypothesis
  • Alternative Hypothesis
  • The characteristics of the newly developed
    PSpice model and that of actual device differ by
    no more than 10.

28
Expected Outcomes
  • The newly developed PSpice model will exhibit a
    lower overshoot.
  • The newly developed PSpice model will exhibit a
    lower VT value.
  • The newly developed PSpice model successfully
    clears all the tests.

29
Significance of the Study
  • The simulation model is used for tests rather
    than the actual device allowing any modifications
    under considerations to be tested.
  • Eventually expedites prototype testing.

30
Timeline
  • April 2003 Review of Literature and current
    model.
  • Summer 2003 Experimental Analysis and Report
    Writing
  • Fall 2003 Final Report

31
Questions Suggestions
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