Three-phase AC voltage controller (full-wave) feeding a star-connected resistive load What is the permissible firing angle range α for a 3-phase full-wave regulator with a resistance load (star connection)?
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A0 ≤ α ≤ 180°
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B0 ≤ α ≤ 150°
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C0 ≤ α ≤ 120°
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D0 ≤ α ≤ 90°
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E15° ≤ α ≤ 165°
Answer
Correct Answer: 0 ≤ α ≤ 150°
Explanation
Introduction / Context:Three-phase AC voltage controllers (also called regulators) use phase control on each phase to vary the RMS output voltage supplied to a load. For a resistive, star-connected load, the achievable control range of the firing angle α is limited by natural commutation intervals and overlap between phases.
Given Data / Assumptions:
- Three-phase, full-wave regulator topology (two antiparallel thyristors per phase).
- Star-connected purely resistive load (no significant inductance).
- Idealized commutation without overlap for the range reasoning.
Concept / Approach:In a 3-phase full-wave controller, each phase can be delayed by α with respect to its phase voltage zero crossing. Because line-to-line voltages are displaced by 60°, the control range is restricted so that proper conduction sequences still occur without creating undefined intervals. For R-loads, the classical limit for full control is α up to 150° so that at least one device can conduct as phase voltages cycle.
Step-by-Step Solution:Phase-angle control is measured from each phase voltage zero crossing.With three phases 60° apart, conduction windows must overlap sufficiently to maintain defined output.Analysis of the conduction pattern shows that beyond α = 150°, proper conduction ceases; therefore α is limited to 0–150°.
Verification / Alternative check:Standard drive and power-electronics texts tabulate these limits: for 3-phase full-wave controllers on R-loads, α ∈ [0°, 150°] ensures continuous, predictable gating sequences.
Why Other Options Are Wrong:
- 0–180°: exceeds the permissible commutation window.
- 0–120° or 0–90°: needlessly restrictive; full control up to 150° is achievable.
- 15–165°: does not reflect the standard definition of α or the true upper bound.
Common Pitfalls:
- Confusing rectifier α limits with AC controller limits.
- Ignoring the 60° phase displacement effect on conduction windows.
Final Answer:0 ≤ α ≤ 150°