JP2011521363A5 - - Google Patents

Claims (46)

A method for selecting between centralized and distributed maximum power point tracking in an energy generation system including a plurality of energy generation devices, each of the energy generation devices coupled to a corresponding local transducer. Each local converter includes a local controller for the corresponding energy generator, the method comprising:
Determining whether the energy generating device is operating under sub-ideal conditions;
Placing the energy generation system in a centralized maximum power point tracking (CMPPT) mode when the energy generation device is operating under sub-ideal conditions; and
Placing the energy generation system in a distributed maximum power point tracking (DMPPT) mode when the energy generation device is not operating under sub-ideal conditions;
Including methods.   The method of claim 1, wherein placing the system in the CMPPT mode comprises disabling the local controller and enabling a global controller.   The method of claim 1, wherein placing the system in the DMPPT mode includes enabling the local controller and disabling a global controller.   The method of claim 1, wherein when the system is in the DMPPT mode, determining whether the probability that at least one of the energy generating devices is shaded exceeds a predetermined threshold. The method further comprising: 5. The method of claim 4, wherein when it is determined that the probability that at least one of the energy generating devices is shaded exceeds the predetermined threshold.
Identifying at least one potentially hidden energy generating device; and
Performing a full characteristic scan on each identified potentially hidden energy generator;
A method further comprising: 6. A method according to claim 5, wherein
Identifying at least one inferior energy generating device based on the full characteristic scan; and
Providing a correction to each identified inferior energy generator;
A method further comprising: The method of claim 1, wherein determining whether the energy generator is operating under sub-ideal conditions.
For each energy generating device, calculating a probability that the energy generating device is shaded based on an output power value associated with each of the energy generating devices;
Identifying the maximum value of the calculated probability;
Comparing the maximum value of the calculated probability to a DMPPT threshold; and
Determining that the energy generator is operating under sub-ideal conditions when the maximum value of the calculated probability is less than the DMPPT threshold;
Including methods.   8. The method of claim 7, further comprising comparing the maximum value of the calculated probability to a diagnostic threshold when the system is in the DMPPT mode. 9. The method of claim 8, wherein the maximum value of the calculated probability is greater than the diagnostic threshold.
(I) identifying each energy generator whose calculated probability that the energy generator is shaded is greater than the diagnostic threshold as an energy generator that may be shaded; and
(Ii) performing a full characteristic scan for each energy generating device identified as potentially shadowed;
A method further comprising: The method of claim 9, comprising:
(I) identifying at least one inferior energy generating device based on the full characteristic scan; and
(Ii) providing corrections to each identified inferior performance energy generator;
A method further comprising:   The method of claim 1, wherein the energy generating device comprises a photovoltaic panel. A method for selecting between centralized and distributed maximum power point tracking in an energy generation system including a plurality of energy generation devices, each of the energy generation devices coupled to a corresponding local transducer. Each local converter includes a local controller for the corresponding energy generator, the method comprising:
Calculating an output power value for each of the energy generating devices;
For each energy generating device, calculating a probability that the energy generating device is shaded based on the output power value for the energy generating device;
Identifying the maximum value of the calculated probability;
Comparing the maximum value of the calculated probability to a distributed maximum power point tracking (DMPPT) threshold;
Placing the energy generation system in a centralized maximum power point tracking (CMPPT) mode when the maximum value of the calculated probability is less than the DMPPT threshold; and
Placing the energy generation system in a DMPPT mode when the maximum value of the calculated probabilities is greater than or equal to the DMPPT threshold;
Including methods.   13. The method of claim 12, wherein when the system is in the DMPPT mode, determining whether the probability that at least one of the energy generators is shaded exceeds a predetermined threshold. The method further comprising:   14. The method of claim 13, wherein determining whether the probability that at least one of the energy generating devices is shaded exceeds the predetermined threshold is the maximum of the calculated probability. Comparing the value to a diagnostic threshold. 15. The method of claim 14, wherein the maximum value of the calculated probability is greater than the diagnostic threshold;
(I) identifying each energy generator whose calculated probability that the energy generator is shaded is greater than the diagnostic threshold as an energy generator that may be shaded;
(Ii) performing a full characteristic scan on each identified potential energy generator;
(Iii) identifying at least one inferior energy generating device based on the full characteristic scan; and
(Iv) providing corrections to each identified inferior energy generating device;
A method further comprising:   The method of claim 12, wherein the energy generating device comprises a photovoltaic panel. A central array controller capable of selecting between centralized and distributed maximum power point tracking for an energy generation system including a plurality of energy generation devices, each of the energy generation devices corresponding to a corresponding local The central array controller, wherein each central converter includes a local controller for the corresponding energy generator,
A diagnostic module capable of determining whether the energy generating device is operating under sub-ideal conditions; and
When the energy generator is operating under sub-ideal conditions, the energy generation system is in a centralized maximum power point tracking (CMPPT) mode, and the energy generator is not operating under sub-ideal conditions; A control module capable of placing the energy generation system in a distributed maximum power point tracking (DMPPT) mode;
Including a central array controller.   18. The central array controller of claim 17, wherein the control module can place the system in the CMPPT mode by disabling the local controller and enabling a global controller. There is a central array controller.   18. The central array controller of claim 17, wherein the control module enables the system to enter the DMPPT mode by enabling the local controller and disabling a global controller. There is a central array controller.   18. The central array controller of claim 17, wherein when the system is in the DMPPT mode, the diagnostic module further has a predetermined threshold for the probability that at least one of the energy generators is shaded. A central array controller capable of determining whether it has been exceeded. 21. The central array controller of claim 20, wherein when the probability that at least one of the energy generators is shaded exceeds the predetermined threshold, the diagnostic module further comprises ,
(I) identifying at least one potentially hidden energy generating device; and
(Ii) performing a full characteristic scan on each identified potential energy generator;
Is possible, a central array controller. The central array controller of claim 21, wherein the diagnostic module further comprises:
(I) identifying at least one inferior energy generating device based on the full characteristic scan; and
(Ii) providing corrections to each identified inferior performance energy generator;
Is possible, a central array controller.   The central array controller of claim 17, wherein the energy generating device includes a photovoltaic panel. A method of activating a local converter for one of a plurality of energy generating devices in an energy generating array, the local converter including a power stage and a local controller, the method But,
Comparing a device voltage for the energy generating device to a voltage activation level; and
Automatically activating the local converter when the device voltage exceeds the voltage activation level;
Including methods.   25. The method of claim 24, wherein automatically activating the local converter includes generating a non-zero supply voltage for the local controller.   25. The method of claim 24, wherein automatically activating the local transducer comprises setting at least one pin of the local controller.   25. The method of claim 24, wherein automatically activating the local converter comprises writing a predetermined value to a register in the local controller.   25. The method of claim 24, wherein automatically activating the local transducer comprises performing an activation procedure on the local transducer, the activation procedure comprising: A method comprising at least one of: register initialization, clock synchronization, voltage comparison for at least a subset of the energy generators in the array, and synchronous activation of at least a subset of the energy generators in the array. .   25. The method of claim 24, wherein the energy generator is included within a string of energy generators and automatically activating the local transducer includes a power stage Operating the power stage at a predetermined conversion ratio until each energy generator in the string is operational. 25. The method of claim 24, wherein automatically activating the local transducer.
Comparing a device current for the energy generating device with an activation current level; and
Performing maximum power point tracking for the energy generating device at the local controller when the device current exceeds the activation current level;
Including methods. A method according to claim 30, comprising
Automatically deactivating the local converter when the device current falls below the activation current level by monitoring the device current for a specified time period; and
Completing the deactivation of the local converter when the device current remains below the activation current level for the specified time period;
A method further comprising:   25. The method of claim 24, wherein the energy generating device comprises a photovoltaic panel. A method of deactivating a local converter for one of a plurality of energy generating devices in an energy generating array, the local converter including a power stage and a local controller, The method is
Comparing a device current for the energy generating device with an activation current level; and
Automatically deactivating the local converter when the device current falls below the activation current level;
Including methods.   34. The method of claim 33, wherein automatically deactivating the local converter comprises generating a zero supply voltage for the local controller.   34. The method of claim 33, wherein automatically deactivating the local transducer comprises setting at least one pin of the local controller.   34. The method of claim 33, wherein automatically deactivating the local converter comprises writing a predetermined value to a register in the local controller.   34. The method of claim 33, wherein automatically deactivating the local transducer comprises performing a deactivation procedure for the local transducer, the deactivation. A method wherein the procedure includes at least one of synchronization with a backup unit and synchronous deactivation of at least a subset of energy generating devices in the array. 34. The method of claim 33, wherein automatically deactivating the local transducer comprises:
Monitoring the device current for a specified time period; and
Completing the deactivation of the local converter when the device current remains below the activation current level for the specified time period;
Including methods.   34. The method of claim 33, wherein the energy generating device comprises a photovoltaic panel. A system for activating and deactivating a local transducer for one of a plurality of energy generating devices in an energy generating array, comprising:
A local controller capable of performing maximum power point tracking on the energy generator and capable of turning on and off the power stage of the local converter; and
An activator coupled to the local controller, the activator capable of automatically activating and deactivating the local controller;
Including the system.   41. The system of claim 40, wherein the activator includes a power supply capable of generating a supply voltage for the local controller.   42. The system of claim 41, wherein the activator generates a non-zero supply voltage at the power supply when a device voltage for the energy generator exceeds a voltage activation level. It is possible to automatically activate the system.   43. The system of claim 42, wherein when the device current for the energy generating device falls below an activation current level, the activator generates the local supply voltage by generating a zero supply voltage at the power supply. A system capable of automatically deactivating a dynamic controller.   42. The system of claim 41, wherein the power supply includes a shutdown node, and the power supply is capable of generating a non-zero supply voltage when the voltage level at the shutdown node is greater than a specified voltage. And a system capable of generating a supply voltage of zero when the voltage level at the shutdown node is less than or equal to the specified voltage. 45. The system of claim 44, wherein
The power supply further includes an input node and an output node;
The activator further includes a first resistor, a second resistor, a third resistor, and a diode;
The first and second resistors are coupled in series between the input node and ground, and the third resistor and the diode are coupled to the output node and the first and second resistors together. And the shutdown node is coupled to the node to which the first and second resistors are coupled together,
system.   41. The system of claim 40, wherein the energy generating device includes a photovoltaic panel.