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EP-4736287-A1 - SYSTEMS AND METHODS FOR CONTROL OF A MEDIUM VOLTAGE DIRECT CURRENT SOLAR PLANT

EP4736287A1EP 4736287 A1EP4736287 A1EP 4736287A1EP-4736287-A1

Abstract

A solar power generation system is provided. The solar power generation system includes a direct current (DC) to DC converter electrically coupled to a medium voltage DC (MVDC) bus and configured to convert LVDC to MVDC power, determine a voltage of the MVDC bus, and, in response to the determined voltage exceeding a threshold output voltage, transmit the MVDC power via the MVDC bus at a DC power level less than a rated DC output power level of the DC to DC converter. The solar power generation system further includes an inverter configured to convert the MVDC power to medium voltage AC (MVAC) power, determine the voltage of the received MVDC power, and, in response to the determined voltage being less than a threshold input voltage, transmit the MVAC power at an AC power level less than a rated AC output power level of the inverter.

Inventors

  • HAWES, NATHANIEL BENEDICT
  • SCHELENZ, OWEN
  • PANT, SIDDHARTH

Assignees

  • GE Grid Solutions LLC

Dates

Publication Date
20260506
Application Date
20240626

Claims (20)

  1. 1. A solar power generation system comprising: at least one photovoltaic (PV) array configured to generate low voltage direct current (LVDC) power; at least one DC to DC converter electrically coupled to a medium voltage DC (MVDC) bus, said DC to DC converter configured to: convert LVDC power received from the at least one PV array to MVDC power; determine a voltage of the MVDC bus; and in response to the determined voltage exceeding a threshold output voltage, transmit the MVDC power via the MVDC bus at a DC power level less than a rated DC output power level of said at least one DC to DC converter; and at least one inverter configured to: receive the MVDC power from the at least one DC to DC converter; convert the MVDC power to medium voltage AC (MV AC) power; determine the voltage of the received MVDC power; and in response to the determined voltage being less than a threshold input voltage, transmit the MV AC power at an AC power level less than a rated AC output power level of said at least one inverter.
  2. 2. The solar power generation system of Claim 1, further comprising an energy storage system configured to: store MVDC power received from said DC to DC converter when a voltage of the MVDC bus is greater than a nominal voltage; and transmit MVDC power to said inverter when voltage of the MVDC bus is less than a nominal voltage.
  3. 3. The solar power generation system of Claim 1, wherein said at least one DC to DC converter is further configured to, in response to the determined voltage being less than or equal to the threshold output voltage, transmit the MVDC power via the MVDC bus at the rated DC output power level of said DC to DC converter.
  4. 4. The solar power generation system of Claim 1, wherein said at least one inverter is further configured to, in response to the determined voltage being greater than or equal to the threshold input voltage, transmit the MV AC power at the rated AC output power level of said inverter.
  5. 5. The solar power generation system of Claim 1, wherein said at least one DC to DC converter is further configured to determine an MVDC power level for transmitting the DC power when the determined MVDC voltage exceeds the threshold input voltage based on a linear function.
  6. 6. The solar power generation system of Claim 1, wherein said at least one inverter is further configured to determine the AC power level for transmitting the MV AC power when the determined MVDC voltage is less than the threshold input voltage based on a linear function.
  7. 7. The solar power generation system of Claim 1, wherein said at least one inverter is configured to: receive a curtailment signal; and determine the AC power level at which to transmit MV AC power further based on the curtailment signal.
  8. 8. The solar power generation system of Claim 1, wherein said at least one DC to DC converter is configured to: generate a power command based on a maximum power point tracking algorithm; and determine the DC power level at which to transmit MVDC power based in part on the generated power command.
  9. 9. The solar power generation system of Claim 1, wherein the rated DC output power level is in a range of about 100 kilowatts to about 500 kilowatts.
  10. 10. A method for controlling a solar power generation system, the solar power generation system including at least one direct current (DC) to DC converter and at least one inverter, the at least one DC to DC converter electrically coupled to a medium voltage DC (MVDC) bus, said method comprising: converting, by the at least one DC to DC converter, low voltage DC (LVDC) power received from at least one photovoltaic (PV) array to MVDC power; determining, by the at least one DC to DC converter, a voltage of the MVDC bus; in response to the determined voltage exceeding a threshold output voltage, transmitting, by the at least one DC to DC converter, the MVDC power via the MVDC bus at a DC power level less than a rated DC output power level of the at least one DC to DC converter; receiving, by the inverter, the MVDC power from the at least one DC to DC converter; converting, by the inverter, the MVDC power to medium voltage AC (MV AC) power; determining, by the inverter, the voltage of the received MVDC power; and in response to the determined voltage being less than a threshold input voltage, transmitting, by the inverter, the MV AC power at an AC power level less than a rated AC output power level of the inverter.
  11. 1 1 . The method of Claim 10, wherein the solar power generation system further includes an energy storage system, and wherein said method further comprises: storing, by the energy storage system, MVDC power received from the at least one DC to DC converter when a voltage of the MVDC bus is greater than a nominal voltage; and transmitting, by the energy storage system, MVDC power to the inverter when voltage of the MVDC bus is less than a nominal voltage.
  12. 12. The method of Claim 10, further comprising, in response to the determined voltage being less than or equal to the threshold output voltage, transmitting, by the at least one DC to DC converter the MVDC power via the MVDC bus at the rated DC output power level of the DC to DC converter.
  13. 13. The method of Claim 10. further comprising, in response to the determined voltage being greater than or equal to the threshold input voltage, transmitting, by the inverter, the MV AC power at the rated AC output power level of the inverter.
  14. 14. The method of Claim 10, further comprising determining, by the at least one DC to DC converter, an MVDC power level for transmitting the DC power when the determined MVDC voltage exceeds the threshold input voltage based on a linear function.
  15. 15. The method of Claim 10, further comprising determining, by the inverter, the AC power level for transmitting the MV AC power when the determined MVDC voltage is less than the threshold input voltage based on a linear function.
  16. 16. The method of Claim 10, further comprising: receiving, by the inverter, a curtailment signal; and determining, by the inverter, the AC power level at which to transmit MV AC power further based on the curtailment signal.
  17. 17. The method of Claim 10, further comprising: generating, by the at least one DC to DC converter, a power command based on a maximum power point tracking algorithm; and determining, by the at least one DC to DC converter, the DC power level at which to transmit MVDC power based in part on the generated power command.
  18. 18. A solar power distribution system comprising: at least one direct current (DC) to DC converter electrically coupled to a medium voltage DC (MVDC) bus, said DC to DC converter configured to: convert low voltage DC (LVDC) power received from at least one photovoltaic (PV) array to MVDC power; determine a voltage of the MVDC bus; and in response to the determined voltage exceeding a threshold output voltage, transmit the MVDC power via the MVDC bus at a DC power level less than a rated DC output power level of said at least one DC to DC converter; and at least one inverter configured to: receive the MVDC power from the at least one DC to DC converter; convert the MVDC power to medium voltage AC (MV AC) power; determine the voltage of the received MVDC power; and in response to the determined voltage being less than a threshold input voltage, transmit the MV AC power at an AC power level less than a rated AC output power level of said at least one inverter.
  19. 19. The solar power distribution system of Claim 18, further comprising an energy’ storage system configured to: store MVDC power received from said DC to DC converter when a voltage of the MVDC bus is greater than a nominal voltage; and transmit MVDC power to said inverter when voltage of the MVDC bus is less than a nominal voltage.
  20. 20. The solar power distribution system of Claim 18, wherein said at least one DC to DC converter is further configured to, in response to the determined voltage being less than or equal to the threshold output voltage, transmit the MVDC power via the MVDC bus at the rated DC output power level of said DC to DC converter.

Description

SYSTEMS AND METHODS FOR CONTROL OF A MEDIUM VOLTAGE DIRECT CURRENT SOLAR PLANT CROSS-REFERENCE TO RELATED APPLICATIONS [0001] This application claims the benefit of priority of U.S. Provisional Application No. 63/510,515, filed June 27, 2023, and entitled ‘’SYSTEMS AND METHODS FOR CONTROL OF A MEDIUM VOLTAGE DIRECT CURRENT SOLAR PLANT,” the contents and disclosures of which are hereby incorporated by reference in their entirety . BACKGROUND [0002] The field of the disclosure relates generally to power generation facilities, and more particularly, to control of a solar power generation facility. [0003] A solar field may be vast, covering many square kilometers, and solar plants may include hundreds of power conversion devices spread throughout the solar field. These power converters must coordinate their actions to regulate, for example, voltage within power transmission busses of the solar plant. For example, the power converters require a fast transient response capability to prevent transient over- and/or under-voltage conditions. A separate communication sy stem may be used to coordinate operation of the power converters. However, due to the size of the solar field and distance between power converters, such communication systems are generally costly. A method of operating the solar plant to regulate voltage while retaining fast transient response capability is therefore desirable. BRIEF DESCRIPTION [0004] In one aspect, a solar power generation system is provided. The solar power generation system includes at least one photovoltaic (PV) array configured to generate low voltage direct current (LVDC) power. The solar power generation system further includes at least one DC to DC converter electrically coupled to a medium voltage DC (MVDC) bus and configured to convert LVDC power received from the at least one PV array to MVDC power, determine a voltage of the MVDC bus, and, in response to the determined voltage exceeding a threshold output voltage, transmit the MVDC power via the MVDC bus at a DC power level less than a rated DC output power level of the at least one DC to DC converter. The solar power generation system further includes at least one inverter configured to receive the MVDC power from the at least one DC to DC converter, convert the MVDC power to medium voltage AC (MV AC) power, determine the voltage of the received MVDC power, and, in response to the determined voltage being less than a threshold input voltage, transmit the MV AC power at an AC power level less than a rated AC output power level of the at least one inverter. [0005] In another aspect, a method for controlling a solar power generation system is provided. The solar power generation system includes at least one DC to DC converter and at least one inverter, the at least one DC to DC converter electrically coupled to a MVDC bus. The method includes converting, by the at least one DC to DC converter, LVDC power received from at least one PV array to MVDC power. The method further includes determining, by the at least one DC to DC converter, a voltage of the MVDC bus. The method further includes in response to the determined voltage exceeding a threshold output voltage, transmitting, by the at least one DC to DC converter, the MVDC power via the MVDC bus at a DC power level less than a rated DC output power level of the at least one DC to DC converter. The method further includes receiving, by the inverter, the MVDC power from the at least one DC to DC converter. The method further includes converting, by the inverter, the MVDC power to MV AC power. The method further includes determining, by the inverter, the voltage of the received MVDC power. The method further includes in response to the determined voltage being less than a threshold input voltage, transmitting, by the inverter, the MV AC power at an AC power level less than a rated AC output power level of the inverter. [0006] In another aspect, a solar power distribution system is provided. The solar power distribution system includes at least one DC to DC converter electrically coupled to an MVDC bus and configured to convert LVDC power received from at least one PV array to MVDC power, determine a voltage of the MVDC bus, and, in response to the determined voltage exceeding a threshold output voltage, transmit the MVDC power via the MVDC bus at a DC power level less than a rated DC output power level of the at least one DC to DC converter. The solar power distribution system further includes at least one inverter configured to receive the MVDC power from the at least one DC to DC converter, convert the MVDC power to MV AC power, determine the voltage of the received MVDC power, and, in response to the determined voltage being less than a threshold input voltage, transmit the MV AC power at an AC power level less than a rated AC output power level of the at least one inverter. BRIEF DESCRIPTION OF DRAWINGS [0007] These and other features, aspects, and advantages of the