Difference between revisions of "MPPT charge controller sizing and selection"
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{| class="wikitable" border=1 style="width: 80%;" | {| class="wikitable" border=1 style="width: 80%;" | ||
! style="width: 20%"|Minimum number of PV modules | ! style="width: 20%"|Minimum number of PV modules | ||
− | ! style="text-align:left;"| = [[Minimum PV source size|minimum PV source size]] ÷ PV module power rating ( | + | ! style="text-align:left;"| = [[Minimum PV source size|minimum PV source size]] ÷ PV module power rating (Step 1) |
|} | |} | ||
− | ====Step 3: Determine PV source power rating==== | + | ====Step 3: Determine maximum charging voltage parameter==== |
+ | The minimum number of PV modules in series must be calculated based upon the maximum required charging voltage for the [[Energy storage|energy storage system]] or the minimum charging voltage provided by the MPPT charge controller manufacturer in the specifications sheet. The maximum system charging voltage parameter is the value for the maximum voltage at which the [[Energy storage|energy storage system]] will be charged. This value depends upon the [[System voltage parameter|system voltage parameter]] and the energy storage system type. The specifications sheet or user manual for the battery that is used in the system should be consulted. | ||
+ | |||
+ | Recommended maximum charging voltage values for a Trojan AGM battery at 25°C<ref name="trojanagm2"> Trojan Battery Company - Specifications sheet for AGM batteries https://www.trojanbattery.com/pdf/AGM_Trojan_ProductLineSheet.pdf</ref> (it is recommended that values at the upper-end of a manufacturers range are used): | ||
+ | *Maximum system charging voltage (12V): 14.1–'''14.7V''' | ||
+ | *Maximum system charging voltage (24V): 28.2–'''29.4V''' | ||
+ | *Maximum system charging voltage (48V): 56.4–'''58.8V''' | ||
+ | |||
+ | ====Step 4: Determine minimum charge current==== | ||
+ | Lead acid batteries last longer and perform better when they are regularly recharged with a current in a certain range - typically between 5-13% of their C/20 rating.<ref name="trojanpaper"> Trojan Battery Company - User's Guide https://www.trojanbattery.com/pdf/TrojanBattery_UsersGuide.pdf</ref><ref name="rollspaper"> The maximum charging current for most lead acid batteries is around 13% of the C/20 rate. Rolls Battery - Battery User Manual https://rollsbattery.com/public/docs/user_manual/Rolls_Battery_Manual.pdf</ref> It is best practice to consult the manual or manufacturer for recommended maximum and minimum charging currents. | ||
+ | |||
+ | {| class="wikitable" border=1 style="width: 80%;" | ||
+ | ! style="width: 20%"|Minimum required charge current | ||
+ | ! style="text-align:left;"| = [[Energy storage sizing and selection#Step 7: Calculate final Ah capacity|final Ah capacity]] × .05 | ||
+ | |} | ||
+ | |||
+ | ====Step 5: Determine available charge current==== | ||
+ | {| class="wikitable" border=1 style="width: 80%;" | ||
+ | ! style="width: 20%"|Available charging current | ||
+ | ! style="text-align:left;"| = PV source power rating (Step 3) × [[Minimum PV source size|Step 1: Deteremine PV source loss parameters|total PV source loss parameter]] ÷ maximum charging voltage parameter (Step 4) | ||
+ | |} | ||
+ | |||
+ | ====Step 6: Determine number of PV modules==== | ||
+ | If a system uses many loads during the day, this will limit the available charging current for the energy storage system and should be taken into account. If the number of PV modules does not meet the recommendations outlined below, increasing the array in size should be considered. | ||
+ | *A minimum charge current of 5% of the C/20 Ah rating is recommended for a system that is used infrequently or is primarily used at night.<ref name="trojanpaper"/><ref name="rollspaper"/> | ||
+ | *A charge current of 10% of the C/20 Ah rating is recommended for a system that is used regularly with significant load usage during the day. | ||
+ | *A maximum charge current of 13% of the C/20 Ah rating is recommended.<ref name="trojanpaper"/><ref name="rollspaper"/> | ||
+ | {| class="wikitable" border=1 style="width: 80%;" | ||
+ | ! style="width: 20%"|Percentage of C/20 rate | ||
+ | ! style="text-align:left;"| = available charging current ÷ [[Energy storage sizing and selection#Step 7: Calculate final Ah capacity|final Ah capacity]] | ||
+ | |} | ||
+ | |||
+ | ====Step 7: Determine PV source power rating==== | ||
This calculation will give a power rating of the PV source based upon the chosen module size and the number of modules required. | This calculation will give a power rating of the PV source based upon the chosen module size and the number of modules required. | ||
{| class="wikitable" border=1 style="width: 80%;" | {| class="wikitable" border=1 style="width: 80%;" | ||
! style="width: 20%"|PV source power rating | ! style="width: 20%"|PV source power rating | ||
− | ! style="text-align:left;"| = | + | ! style="text-align:left;"| = Number of PV modules (Step 2 and Step 6) × PV module power rating (Step 1) |
|} | |} | ||
− | ====Step | + | ====Step 8: Determine minimum current rating of charge controller==== |
An MPPT charge controller is capable of of accepting varying voltages from the array and converting them into current at the proper charging voltage for the [[Energy storage|energy storage system]]. The maximum current charge controller could generate from the PV source can be calculated by dividing the power rating of the array by the [[System voltage parameter|system voltage]]. If the charge controller manufacturer explicitly permits it, the PV source may be oversized somewhat (typically 110-125%). | An MPPT charge controller is capable of of accepting varying voltages from the array and converting them into current at the proper charging voltage for the [[Energy storage|energy storage system]]. The maximum current charge controller could generate from the PV source can be calculated by dividing the power rating of the array by the [[System voltage parameter|system voltage]]. If the charge controller manufacturer explicitly permits it, the PV source may be oversized somewhat (typically 110-125%). | ||
{| class="wikitable" border=1 style="width: 80%;" | {| class="wikitable" border=1 style="width: 80%;" | ||
! style="width: 20%"|Minimum current rating of charge controller | ! style="width: 20%"|Minimum current rating of charge controller | ||
− | ! style="text-align:left;"| = PV source power rating ÷ [[System voltage parameter|system voltage]] | + | ! style="text-align:left;"| = PV source power rating (Step 7) ÷ [[System voltage parameter|system voltage]] |
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::This value must be rounded down to the next whole number (there are no partial modules). | ::This value must be rounded down to the next whole number (there are no partial modules). | ||
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====Step 7: Determine minimum number of PV modules in series==== | ====Step 7: Determine minimum number of PV modules in series==== |
Revision as of 13:29, 25 November 2020
A MPPT charge controller is rated to operate at a particular system voltage, maximum current and maximum voltage. MPPT charge controllers can charge the battery bank with any series and parallel configuration of modules that doesn't exceed the maximum voltage and maximum current, or drop below the required charging voltage of the energy storage system. Exceeding the voltage rating of an MPPT due to cold temperatures can damage it. Many charge controllers allow the current rating to be exceeded to a certain point without damage, just lost energy - it depends on the charge controller. There are several important calculations that must be performed to properly size an MPPT charge controller:
- Should be sized to work with a series and parallel configuration of PV modules that will not damage the charge controller due to high voltages resulting from low temperatures at the project location.
- Should be sized to work with a series and parallel configuration of PV modules that will still be able to properly charge the energy storage system under high temperatures and as PV modules age at the project location.
It is worth noting that most manufacturers now provide charge controller sizing tools that greatly simplify this process - check the website for the manufacturer.
Contents
- 1 Step 1: Determine PV module power rating
- 2 Step 2: Calculate minimum number of PV modules
- 3 Step 3: Determine maximum charging voltage parameter
- 4 Step 4: Determine minimum charge current
- 5 Step 5: Determine available charge current
- 6 Step 6: Determine number of PV modules
- 7 Step 7: Determine PV source power rating
- 8 Step 8: Determine minimum current rating of charge controller
- 9 Step 5: Determine maximum number of PV modules in series
- 10 Step 7: Determine minimum number of PV modules in series
- 11 Step 8: Determine the number of PV modules in series per string
- 12 Step 9: Determine the number of strings of PV modules in parallel
- 13 Step 10: PV source power rating
- 14 Notes/referencse
Step 1: Determine PV module power rating
60-cell and 72-cell modules are the most common module size used with MPPT charge controllers. They range in size from 250W - 400W+.
Step 2: Calculate minimum number of PV modules
This calculation will give a minimum number of modules. The final array size should always be larger than this value, thus if the the result of the calculation is a decimal, it should be rounded up. Different modules sizes and configurations can be explored to find the optimal design.
Minimum number of PV modules | = minimum PV source size ÷ PV module power rating (Step 1) |
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Step 3: Determine maximum charging voltage parameter
The minimum number of PV modules in series must be calculated based upon the maximum required charging voltage for the energy storage system or the minimum charging voltage provided by the MPPT charge controller manufacturer in the specifications sheet. The maximum system charging voltage parameter is the value for the maximum voltage at which the energy storage system will be charged. This value depends upon the system voltage parameter and the energy storage system type. The specifications sheet or user manual for the battery that is used in the system should be consulted.
Recommended maximum charging voltage values for a Trojan AGM battery at 25°C[1] (it is recommended that values at the upper-end of a manufacturers range are used):
- Maximum system charging voltage (12V): 14.1–14.7V
- Maximum system charging voltage (24V): 28.2–29.4V
- Maximum system charging voltage (48V): 56.4–58.8V
Step 4: Determine minimum charge current
Lead acid batteries last longer and perform better when they are regularly recharged with a current in a certain range - typically between 5-13% of their C/20 rating.[2][3] It is best practice to consult the manual or manufacturer for recommended maximum and minimum charging currents.
Minimum required charge current | = final Ah capacity × .05 |
---|
Step 5: Determine available charge current
Available charging current | = PV source power rating (Step 3) × Step 1: Deteremine PV source loss parameters|total PV source loss parameter ÷ maximum charging voltage parameter (Step 4) |
---|
Step 6: Determine number of PV modules
If a system uses many loads during the day, this will limit the available charging current for the energy storage system and should be taken into account. If the number of PV modules does not meet the recommendations outlined below, increasing the array in size should be considered.
- A minimum charge current of 5% of the C/20 Ah rating is recommended for a system that is used infrequently or is primarily used at night.[2][3]
- A charge current of 10% of the C/20 Ah rating is recommended for a system that is used regularly with significant load usage during the day.
- A maximum charge current of 13% of the C/20 Ah rating is recommended.[2][3]
Percentage of C/20 rate | = available charging current ÷ final Ah capacity |
---|
Step 7: Determine PV source power rating
This calculation will give a power rating of the PV source based upon the chosen module size and the number of modules required.
PV source power rating | = Number of PV modules (Step 2 and Step 6) × PV module power rating (Step 1) |
---|
Step 8: Determine minimum current rating of charge controller
An MPPT charge controller is capable of of accepting varying voltages from the array and converting them into current at the proper charging voltage for the energy storage system. The maximum current charge controller could generate from the PV source can be calculated by dividing the power rating of the array by the system voltage. If the charge controller manufacturer explicitly permits it, the PV source may be oversized somewhat (typically 110-125%).
Minimum current rating of charge controller | = PV source power rating (Step 7) ÷ system voltage |
---|
Step 5: Determine maximum number of PV modules in series
PV module cell temperatures below 25°C will increase the voltage a PV module beyond its rating. In locations that experience low temperatures, it is necessary to determine the maximum number of modules in series that will be possible given the minimum temperature at the project location. PV module manufacturers provide a temperature coefficient for voltage that can be used to calculate increases or decreases in power based upon the environmental conditions. This coefficient is referred to as temperature coefficient of open circuit voltage (Voc) and can typically be found on module specifications sheets in -%/°C.
The maximum voltage of the module under standard test conditions - open circuit voltage (Voc) - will be used for this calculation.
% change in Voc at minimum temperature | = (minimum ambient temperature - 25 °C) × temperature coefficient of open circuit voltage (Voc) |
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Voc at minimum temperature | = PV module open circuit voltage (Voc) × ((% change in Voc at minimum temperature ÷ 100) + 1) |
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Maximum number of PV modules in series | = Maximum Voc rating of charge controller ÷ Voc at minimum temperature |
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- This value must be rounded down to the next whole number (there are no partial modules).
Step 7: Determine minimum number of PV modules in series
PV module cell temperatures above 25°C will decrease the voltage a PV module beyond its rating. PV module voltage will also decrease as the module ages. It is therefore important to make sure that the PV source is adequately sized to ensure that at high temperatures and with the passage of time that the array will still be able to provide sufficient voltage to charge the energy storage system. PV module manufacturers provide a temperature coefficient for power that can be used to calculate increases or decreases in power based upon the environmental conditions. This coefficient is referred to as temperature coefficient of open circuit voltage (Voc) and can typically be found on module specifications sheets in -%/°C. The value from the specifictions sheet of a module can be used in these calculatons if a module has been chosen, but a standard average value of (-.48%/°C) will work for both poly and monocrystalline modules.[4]
The operating voltage of the module under standard test conditions - maximum power voltage (Vmp) - will be used for this calculation.
- The mounting system will also affect the ability of the PV source to cool itself. A mounting system temperature adder should be added to the maximum temperature that is used to calculate the decrease in Voc:
- 20°C for pole mount
- 25°C for ground mount
- 30°C for roof mount
- The mounting system will also affect the ability of the PV source to cool itself. A mounting system temperature adder should be added to the maximum temperature that is used to calculate the decrease in Voc:
% change in Vmp at maximum temperature | = (Maximum ambient temperature + Array temperature adder - 25°C) × Temperature coefficient of max power %/°C |
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% change in Vmp at maximum temperature | = (Maximum ambient temperature + Array temperature adder - 25°C) × Temperature coefficient of max power %/°C |
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Vmp at maximum temperature | = maximum power voltage( Vmp) × ((% change in Vmp at maximum temperature ÷ 100) + 1) × module degradation parameter |
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Minimum number of PV modules in series | = maximum charging voltage parameter (Step 6) ÷ Vmp at maximum temperature |
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- This value must be rounded up to the next whole number (there are no partial modules).
Step 8: Determine the number of PV modules in series per string
The final number of PV modules per series string must be less than the maximum number of PV modules in series (Step 5) and greater than the minimum number of PV modules in series (Step 6). If there is not a configuration that is meets this criteria another module should be tested or adjusting some of the parameters can be tested, like the module degradation parameter. As long as the voltage doesn't exceed the rating of the charge controller, more PV modules per string is generally preferrable to use a higher operating voltage and lower current.
Step 9: Determine the number of strings of PV modules in parallel
The final number of strings of PV modules in parallel will be determined by dividing the minimum array size by the final number of PV modules per series string. This calculation should be rounded up. The total short circuit current (Isc) of the parallel strings of modules should not exceed the current rating of the charge controller unless permitted by the manufacturer. A larger charge controller should be chosen if an appropriate series/parallel configuration cannot be found.
Minimum number of strings of modules in parallel | = Minimum number of PV modules (Step 2) ÷ final number of PV modules per series string (Step 7) |
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Step 10: PV source power rating
The total power rating of the PV source can be calculated by multiplying the power rating of the chosen PV module by the final number of PV modules in series (Step 7) and the final number of strings of PV modules in parallel (Step 8).
PV source power rating | = PV module power rating (Step 1) × final number of PV modules in series (Step 7) × the final number of strings of PV modules in parallel (Step 8). |
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Notes/referencse
- ↑ Trojan Battery Company - Specifications sheet for AGM batteries https://www.trojanbattery.com/pdf/AGM_Trojan_ProductLineSheet.pdf
- ↑ 2.0 2.1 2.2 Trojan Battery Company - User's Guide https://www.trojanbattery.com/pdf/TrojanBattery_UsersGuide.pdf
- ↑ 3.0 3.1 3.2 The maximum charging current for most lead acid batteries is around 13% of the C/20 rate. Rolls Battery - Battery User Manual https://rollsbattery.com/public/docs/user_manual/Rolls_Battery_Manual.pdf
- ↑ HOMER - PV Temperature Coefficient of Power https://www.homerenergy.com/products/pro/docs/latest/pv_temperature_coefficient_of_power.html