System And Method For Uninterruptible Power Supply Intelligent Transfer

US 20150256029A1
Filed: 02/18/2015
Published: 09/10/2015
Est. Priority Date: 03/05/2014
Status: Active Grant

First Claim

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1. A method for detecting and compensating for an under voltage fault condition which arises when a low impedance fault occurs on a bypass line of an uninterruptible power supply (UPS) as a result of a disruption of an AC output mains (Vout) signal present on the bypass line, which reduces the Vout signal below a nominal AC mains voltage output (Vout_nominal), and wherein a component is disposed downstream of the UPS and receives power from the UPS as a changeover is made from a high efficiency mode of operation to a voltage/frequency independent (VFI) mode in which the UPS is supplying power to a load, and the component is upstream of the load but downstream of the UPS, the method comprising:

performing successive voltage measurements at a plurality of points during a first half cycle of the Vout signal to integrate the Vout signal until a zero crossing of the Vout signal is detected;

using the successive voltage measurements to detect the disruption of the Vout signal and a percentage of missing voltage area from the Vout signal during the disruption; and

using the UPS to supply a compensation voltage (Vcomp) which is added to the Vout signal to restore the Vout signal to a level at least approximately equal to Vout_nominal.

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Abstract

A method is disclosed which makes use of an intelligent transfer algorithm for a UPS when the UPS is required to switch from a high efficiency mode of operation (VFD or VI) to an independent mode of operation (VFI), as a result of an under voltage condition occurring on the bypass line of the UPS. The method involves performing successive voltage measurements at a plurality of points during a first half cycle of an AC mains (Vout) signal to integrate the Vout signal until a zero crossing of the Vout signal is detected. Successive voltage measurements are used to detect the disruption of the Vout signal and a percentage of missing voltage area from the Vout signal during the disruption. The UPS then supplies a compensation voltage (Vcomp) which is added to the Vout signal to restore the Vout signal to a level at least approximately equal to a nominal AC mains voltage output signal (Vout_nominal).

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1. A method for detecting and compensating for an under voltage fault condition which arises when a low impedance fault occurs on a bypass line of an uninterruptible power supply (UPS) as a result of a disruption of an AC output mains (Vout) signal present on the bypass line, which reduces the Vout signal below a nominal AC mains voltage output (Vout_nominal), and wherein a component is disposed downstream of the UPS and receives power from the UPS as a changeover is made from a high efficiency mode of operation to a voltage/frequency independent (VFI) mode in which the UPS is supplying power to a load, and the component is upstream of the load but downstream of the UPS, the method comprising:
- performing successive voltage measurements at a plurality of points during a first half cycle of the Vout signal to integrate the Vout signal until a zero crossing of the Vout signal is detected;
  
  using the successive voltage measurements to detect the disruption of the Vout signal and a percentage of missing voltage area from the Vout signal during the disruption; and
  
  using the UPS to supply a compensation voltage (Vcomp) which is added to the Vout signal to restore the Vout signal to a level at least approximately equal to Vout_nominal.
- View Dependent Claims (2, 3, 4, 5, 6)
- - 2. The method of claim 1, further comprising setting a predetermined percentage voltage compensation threshold relating to a percentage of voltage that is lost during the disruption of the Vout signal, and below which no action will be taken to compensate for the disruption of the Vout signal.
  - 3. The method of claim 2, further comprising determining if the percentage of missing voltage area from the Vout signal during the disruption has resulted in a percentage of voltage lost from the Vout signal that exceeds the predetermined percentage voltage compensation threshold, and only then using the UPS to supply the compensation voltage (Vcomp).
  - 4. The method of claim 3, further comprising setting a maximum level for Vcomp that is allowed to be applied during any given half cycle of the Vout signal.
  - 5. The method of claim 1, wherein the maximum level for the Vcomp corresponds to a maximum predetermined percentage of Vout_nominal.
  - 6. The method of claim 1, further comprising determining when Vout cannot be restored to Vout_nominalby adding the maximum level for Vcomp before a next zero crossing point will occur, and adding a first portion of Vcomp before said next zero crossing occurs, and a second portion of Vcomp after said next zero crossing has passed.

7. A method for detecting and compensating for an under voltage fault condition which arises when a low impedance fault occurs on a bypass line of an uninterruptible power supply (UPS) as a result of a disruption of an AC output mains (Vout) signal present on the bypass line, which reduces the Vout signal below a nominal AC mains voltage output (Vout_nominal), and wherein a component is disposed downstream of the UPS and receives power from the UPS as a changeover is made from a high efficiency mode of operation to a voltage/frequency independent (VFI) mode in which the UPS is supplying power to a load, and the component is upstream of the load but downstream of the UPS, the method comprising:
- setting a predetermined percentage voltage compensation threshold relating to a percentage of voltage that is lost during the disruption of the Vout signal, and below which no action will be taken to compensate for the disruption;
  
  performing successive voltage measurements at a plurality of points during a first half cycle of the Vout signal to integrate the Vout signal until a zero crossing of the Vout signal is detected;
  
  using the successive voltage measurements to detect the disruption of the Vout signal and a percentage of missing voltage area from the Vout signal during the disruption;
  
  determining if the percentage of missing voltage area from the Vout signal during the disruption has resulted in a percentage of voltage lost from the Vout signal that exceeds the predetermined percentage voltage compensation threshold, and then;
  
  using the UPS to supply a compensation voltage (Vcomp) which is added to the Vout signal to restore the Vout signal to a level at least approximately equal to Vout_nominal.
- View Dependent Claims (8, 9, 10, 11, 12)
- - 8. The method of claim 7, further comprising setting a maximum level for Vcomp that is allowed to be applied during any given half cycle of the Vout signal.
  - 9. The method of claim 8, wherein the maximum level for Vcomp corresponds to a maximum predetermined percentage of Vout_nominal.
  - 10. The method of claim 9, further comprising determining when Vout cannot be restored to Vout_nominalby adding the maximum level for Vcomp before a next zero crossing point will occur, and adding a first portion of Vcomp before said next zero crossing occurs, and a second portion of Vcomp after said next zero crossing has passed.
  - 11. The method of claim 10, further comprising determining when Vout cannot be restored to Vout_nominalby adding the maximum level for Vcomp before a next zero crossing will occur, and further determining if adding a first portion of Vcomp before the next zero crossing occurs would only allow for adding a percentage amount of Vcomp that is less than or equal to the predetermined percentage voltage compensation threshold.
  - 12. The method of claim 11, when determining that adding a first portion of Vcomp before the next zero crossing occurs would only allow for adding a percentage amount of Vcomp that is less than or equal to the predetermined percentage voltage compensation threshold, then applying no portion of Vcomp before the next zero crossing occurs.

13. A system having an intelligent transfer algorithm to detect and compensate for an under voltage fault condition which arises when a low impedance fault occurs on a bypass line of an uninterruptible power supply (UPS) as a result of a disruption of an AC output mains (Vout) signal present on the bypass line, which reduces the Vout signal below a nominal AC mains voltage output (Vout_nominal), and wherein a component is disposed downstream of the UPS and receives power from the UPS as a changeover is made from a high efficiency mode of operation to a voltage/frequency independent (VFI) mode in which the UPS is supplying power to a load, and the component is upstream of the load but downstream of the UPS, the system comprising:
- a UPS on which the intelligent transfer algorithm is running, the UPS configured to;
  
  perform successive voltage measurements at a plurality of points during a first half cycle of the Vout signal to integrate the Vout signal until a zero crossing of the Vout signal is detected;
  
  use the successive voltage measurements to detect the disruption of the Vout signal and a percentage of missing voltage area from the Vout signal during the disruption; and
  
  use the UPS to supply a compensation voltage (Vcomp) which is added to the Vout signal to restore the Vout signal to a level at least approximately equal to Vout_nominal.
- View Dependent Claims (14, 15, 16, 17, 18, 19, 20)
- - 14. The system of claim 13, wherein the UPS makes use of a predetermined percentage voltage compensation threshold relating to a percentage of voltage that is lost during the disruption of the Vout signal, and below which no action will be taken to compensate for the disruption.
  - 15. The system of claim 13, wherein the UPS makes use of a maximum level for Vcomp that is allowed to be applied during any given half cycle of the Vout signal.
  - 16. The system of claim 15, wherein the maximum level for Vcomp corresponds to a maximum predetermined percentage of Vout_nominal.
  - 17. The system claim 13, wherein the UPS is further configured to determine when Vout cannot be restored to Vout_nominalby adding the maximum level for Vcomp before a next zero crossing point will occur, and operates to add a first portion of Vcomp before said next zero crossing occurs, and a second portion of Vcomp after said next zero crossing has passed.
  - 18. The system of claim 17, wherein the UPS is further configured to determine when Vout cannot be restored to Vout_nominalby adding the maximum level for Vcomp before a next zero crossing will occur, and further operates to determine when adding a first portion of Vcomp before the next zero crossing occurs would only allow for adding a percentage amount of Vcomp that is less than or equal to the predetermined percentage voltage compensation threshold, and then takes no action to correct for a reduction of Vout.
  - 19. The system of claim 16, wherein the UPS is configured such that the maximum predetermined percentage of Vout_nominalis set to 10%.
  - 20. The system of claim 14, wherein the UPS is set such that the predetermined percentage voltage compensation threshold comprises a threshold of about 15% of Vout.

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Current Assignee
Vetriv S.R.L.
Original Assignee
Chloride SRL (Emerson Electric Company)
Inventors
CINTI, Ugo, BONORA, Marco, VASSALLO, Guerino

Granted Patent

US 10,014,714 B2
Time in Patent Office

Days
Field of Search
US Class Current

1/1
CPC Class Codes

H02J 9/061 for DC powered loads

H02J 9/062 for AC powered loads

System And Method For Uninterruptible Power Supply Intelligent Transfer

First Claim

3 Assignments

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Abstract

5 Citations

20 Claims

Specification

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System And Method For Uninterruptible Power Supply Intelligent Transfer

First Claim

3 Assignments

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0 Petitions

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Accused Products

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Abstract

5 Citations

20 Claims

Specification

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Solutions

Use Cases

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