Introduction / Context:
Cycloconverters directly convert AC of one frequency to a lower frequency AC without an intermediate DC link. They are widely used in large drives where low-frequency, high-torque operation is needed, such as rolling mills or kilns.
Given Data / Assumptions:
- Traditional thyristor-based cycloconverters (line-commutated).
- Output frequency typically a fraction of input frequency.
- Device topology relies on phase-controlled rectifier bridges.
Concept / Approach:A cycloconverter is realized by combining multiple controlled rectifier bridges (thyristor bridges). By modulating firing angles, the circuit pieces together positive and negative segments to synthesize a low-frequency output waveform directly from the mains.
Step-by-Step Solution:1) Recognize that each “arm” is a controlled rectifier capable of shaping the segment polarity and magnitude.2) By alternately gating the bridges, the output polarity swaps, creating AC at a lower frequency.3) Hence, structurally and functionally, a cycloconverter is indeed a group of controlled rectifiers coordinated by a controller.Verification / Alternative check:Standard power electronics texts show single-phase and three-phase cycloconverter schematics consisting of anti-parallel controlled rectifier sections feeding a load.
Why Other Options Are Wrong:- False: contradicted by the well-known thyristor-bridge construction.
- True but only for DC outputs: incorrect; cycloconverters produce AC outputs.
- Transistor-only: not historically correct for classic industrial cycloconverters.
- Cannot be determined: it can; the construction is standard knowledge.
Common Pitfalls:- Confusing cycloconverters with DC link inverters (AC–DC–AC).
- Assuming PWM transistor inverters; those are different modern topologies.
Final Answer:True (Option A).
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