| 11. | In case of higher ripple currents the lifetime could be influenced positively with force cooling.
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| 12. | Reverse voltage or ripple currents higher than specified can destroy the dielectric and thus the capacitor.
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| 13. | Therefore, polymer capacitors can handle higher ripple current.
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| 14. | Ripple currents generates heat inside the capacitor body.
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| 15. | Ripple currents generate heat inside the capacitor body.
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| 16. | In polymer Ta-e-caps the heat generated by the ripple current influences the reliability of the capacitors.
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| 17. | The types of capacitors used for power applications have a specified rated value for maximum ripple current.
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| 18. | Well-designed circuits pay attention to the ESR, ripple current rating, pulse operation, and temperature rating of capacitors.
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| 19. | In solid tantalum electrolytic capacitors the heat generated by the ripple current influences the reliability of the capacitors.
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| 20. | In a circuit with significant ripple current, an increase in ESR will increase heat dissipation, thus accelerating aging.
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