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Power System for Ocean Bottom Observatories

This presentation discusses the design and implementation of a scalable power system for ocean bottom observatories, with a focus on redundancy and high reliability. The power distribution and control strategies are presented, along with testing methodologies.

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Power System for Ocean Bottom Observatories

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  1. Power System for Ocean Bottom Observatories Taken from the Cabled Observatory Presentation School of Ocean and Earth Science and Technology February 2006

  2. The Plan • The Supply should be SCALABLE. • There should be redundancy wherever practical. • High voltage converters present serious reliability concerns. • Low voltage converters can be stacked to achieve both scaling and high reliability.

  3. HV Power Distribution • Start with High Voltage Distribution. • Line losses go down with square of voltage. • Step it down with fixed-ratio transformers. • This is the main power conversion. • Keep complexity to a minimum. • Do any necessary regulation at low voltage. • Wide-range COTS regulators available. • Voltage variations will be well within range. • Use REDUNDANT regulators.

  4. Limited Current Power Distribution • Design power modules for nominal current. • Stack more converter for higher power. • This increases primary voltage and secondary current. • The secondary voltage remains the same. • The size of the voltage drop then determines your available power.

  5. Simplified POWER SUPPLY Stack

  6. Incremental Failure Tolerance(8-converter stack) • If any one power converter module fails: • The step-down ratio changes by 8/7. • There is 14% increase in secondary voltage. • The regulators can easily handle that. • If two power converters fail: • There is 33% increase in secondary voltage. • This is still within the regulation range. • Available power decreases slightly, but system remains fully functional.

  7. Redundancy • The previous slide suggests a scheme for redundancy: • Extra converters can placed on the stack. • Simply shorting the input removes them from active duty. • They can be brought on line as needed to replace a failed unit or to increase power capacity. • Very minimal circuitry is required to implement.

  8. Power Supply Control • Simple Rabbit 3000 microcontroller. • Isolated voltage-to-frequency converters monitor all significant voltages. • Isolated Magnetoresistive-effect sensors used for currents. • Thermistor probes for temperatures. • Backplane used for modular power converters.

  9. Rabbit 3000 Controllers

  10. Power Module Backplane

  11. Converter Modules

  12. Testing • Use a variety of fully dynamic loads. • Use continuous maximum cycling with pseudo-random pattern generator to simulate every possible static and transient load condition.

  13. Dynamic Test Load

  14. Dynamic Load Testing

  15. Conclusions… • This Second Generation Power Supply has greatly expanded operating margins. • Modular design allows for easy testing and easy maintenance. • The pseudo-random test load tests for a wide range of operating conditions.

  16. Conclusions… • The power system is multiple-fault tolerant in the critical areas and has very few single-point failure modes. • Rigorous system testing will weed out infant-mortality and rare-event failures.

  17. Discussion • Design development • System power • Data Communication • System Control • Proof Module

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