Uninterruptible Power Systems

1. Uninterruptible Power Systems A study and comparison of topologies

2. UPS; An introduction An uninterruptible power source is an electromechanical/electrochemical system that provides backup or emergency power to a load when the power supply from the input becomes absent (or becomes unusable due to fluctuations in voltage signal ). The main difference of an UPS from a Auxiliary Power Supply system like generators is that it provides instantaneous or near-instantaneous protection from input power interruptions.

3. UPS; An introduction • Power is stored in an UPS in batteries or flywheels, with flywheels being very uncommon and mostly used for extremely specific purposes. • Uninterruptible Power Systems can broadly classified into two categories based on the network topology : - • On-Line UPS • Off-Line UPS

4. Basic Components • A battery based UPS system consists of three main components : - • Rectifier • Battery (storage) • Inverter • These components are connected in various topologies, along with transformers, to cater to different application needs.

5. Basic Components

6. Interruptions in supply Blackout

7. Interruptions in supply Brownout

8. Interruptions in supply Surge

9. Interruptions in supply Spike

10. Interruptions in supply Frequency Drift

11. Specifications • Hold-up time Time for which the load can continue operating after input voltage has vanished (10~30ms) • Transfer Time Time taken by UPS to switch over from mains supply to storage supply • Backup Time Time for which storage can provide supply at rated voltage and power

12. Conventional topologies 1. Off-line / VFD / passive 2. On-line / VFI / double conversion 3. Line-Interactive / VI

13. Off-line UPS

14. Off-line UPS An off line UPS, during normal operation, feeds raw mains to the critical load through a bypass line and static switch. If the mains transgresses preset limits, the static switch transfers the load to the UPS’s inverter and battery Transfer-time ~ 10ms

15. On-Line UPS

16. On-line UPS In this configuration, the load is always fed from the backup source, and never fed directly supply power. There is no transfer switch involved and hence it has no transient characteristics. Transfer Time = 0

17. Line-Interactive UPS

18. Line-interactive UPS These use off line topology, but address the voltage transgression problems by providing voltage regulation in the raw mains line which supplies the load during normal operation. Transfer Time ~10ms

19. Standardisation The need to standardise UPS topologies has arisen due to following reasons : • Frequently used misnomers like “in-line” and “parallel” and “independent” • Duping of general public by UPS manufacturers by clever renaming of topologies • The term “line” can be referred to as the the supply line or the conversion circuit, resulting in advent of pseudo on-line UPS models

20. Standardisation As per the standards IEC 62040-3 (USA) and ENV 50091-3 (Europe), broad UPS topologies are : passive-standby (formerly off-line); where load is supplied by utility power, which may or may not be filtered. line-interactive ; The inverter is connected in parallel and acts to backup utility power and charges the battery through it reversible characteristics double-conversion (formerly on-line) ; The load is continuously supplied via the rectifier/charger - inverter combination which carries out a double conversion AC-DC-AC

21. Comparison of Topologies We shall compare the following properties between the three topologies 1. Transfer time characteristics 2. Voltage and Frequency dependence 3. Scope of operation 4. Energy Efficiency 5. Reliability

22. Transfer time characteristics

23. Voltage & Frequency dependence • Online UPS is also known as VFI (Voltage and Frequency Independent) UPS because output waveform has no dependence on input waveform. • Offline UPS is also known as VFD (Voltage and Frequency Dependent) UPS because output waveform can get affected by disruptions in both Voltage as well as frequency. • Line-interactive UPS is known as VI (Voltage Independent) UPS because output waveform is shielded against Voltage fluctuations by the AVR but it still is not independent of input waveform's frequency.

24. Scope of Operation

25. Energy Efficiency On-line UPS : 85~92 % • Due to double conversion, rectifier and inverter loss always present. • Higher cost of ownership Off-line/Line-interactive : 96~98 % • Only AVR in circuit during normal mode • AVR is a Transformer, thus efficiency >95% • Lower ownership cost, suitable for domestic usage

26. Reliability Off-line/Line-interactive UPS This topology is generally more reliable because : • Lesser no. of parts • Converter and inverter not always in use • Lower operating temperature On-line UPS Reliability of on-line ups in long term is low as : • conversion circuits always in use • higher operating temperatures and higher heat dissipation

27. Present situation On-line, or double-conversion model is currently considered superior because : - • continuous conversion of the power supplied at the inverter output for the load • isolation of the load from the upstream distribution system • very wide input-voltage tolerances and precise regulation of the output voltage • precise regulation of the output frequency, and possibility of the UPS operation as a frequency converter • much superior performance levels under steady-state and transient conditions • Power factor correction

28. Present situation Circumstances where an off-line or line-interactive UPS is not possible to use : • Load has very low or zero hold up time • Very high voltage loads where fast switching can cause extreme waveform distortion • Load needs tight frequency regulation and supply has frequency drifts very often Other than mentioned circumstances, the use of off-line systems are still more widespread than on-line systems due to the economics of it.

29. Present Situation

30. Alternate models and future scope Modular UPS • UPS is modularised in form of racks. • Adding modules increases capacity, thus making the model scalable • Can be implemented in both off-line and on-line topologies • Easy to achieve N+1 configuration and very cost effective • Replaceability of modules makes maintenance easier • Suitable for IT hubs and Data Centers

31. Alternate models and future scope Hybrid/Double-conversion on-demand • New model being conceived by HewlettPackard and Gammatronics • Works as off-line UPS as long as supply signal is within certain tolerance window. • Can switch over to on-line mode when supply signal distortions are outside tolerance ranges • One of highest efficiency models conceptualised till now

32. Alternate models and future scope Rotary UPS (High Speed flywheel) • Energy stored as rotational kinetic energy in a flywheel which rotates at a very high speed. • Due to it’s nature, flywheels are inherently on-line UPS • Backup times are very low, so used in conjunction with an auxiliary power supply • Can be used in conjunction with an off-line UPS to make it appear as an online UPS

33. Conclusion As we move towards more and more components, including electrical and mechanical ones having computer-based control interfaces, need of UPS systems will keep increasing. Improvement in reliability and efficiency is needed as often momentary loss of power can lead to loss of lives and/or huge damage to property. Market continues to be dominated by traditional on-line and line-interactive models.

34. Conclusion We can expect in future : • Better standardisation of UPS topologies and proper classification of even hybrid modes • Increased efficiency in on-line models • Reduction in transfer times of static transfer switches used in off-line UPS • Improvements in hybrid models to make use of advantages of both models • Development of alternate topologies like on-demand VFI and flywheel-augmented UPS