Difference between revisions of "Minimum PV source size"
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| − | [[Category:PV source and charge controller sizing]] | + | [[Category:PV source and charge controller sizing and selection]] |
The size of the [[PV module|PV source]], which is determined based upon the [[Load evaluation|load evaluation]] and [[Weather and solar resource evaluation|weather and solar resource evaluation]] will determine the necessary size of the charge controller. The charge controller must be selected at the same time as the PV source as the [[Charge controller#Charge controller types|charge controller type]] - PWM or MPPT - will also determine the possible configurations of PV modules. | The size of the [[PV module|PV source]], which is determined based upon the [[Load evaluation|load evaluation]] and [[Weather and solar resource evaluation|weather and solar resource evaluation]] will determine the necessary size of the charge controller. The charge controller must be selected at the same time as the PV source as the [[Charge controller#Charge controller types|charge controller type]] - PWM or MPPT - will also determine the possible configurations of PV modules. | ||
| − | In this phase of the design process, more than in any other phase, it is necessary to explore different designs using [[PV module|PV module]], [[Series and parallel|series and parallel wiring configurations]], and [[Charge controller|charge controllers]] in order to achieve the highest performance at the lowest cost possible. | + | In this phase of the design process, more than in any other phase, it is necessary to explore different designs using [[PV module|PV module]], [[Series and parallel connections|series and parallel wiring configurations]], and [[Charge controller|charge controllers]] in order to achieve the highest performance at the lowest cost possible. This phase may have to be performed several times. |
| − | An off-grid PV system that depends upon the PV as its single charging source requires an array that is sufficiently sized to be able to generate sufficient energy to both meet the energy needs of the users and to recharge the [[Energy storage|energy storage system]] under less than ideal conditions. Any sizing decisions should therefore lean towards | + | An off-grid PV system that depends upon the PV as its single charging source requires an array that is sufficiently sized to be able to generate sufficient energy to both meet the energy needs of the users and to recharge the [[Energy storage|energy storage system]] under less-than-ideal conditions. Any sizing decisions should therefore lean towards a larger PV source. |
| − | ==Step 1: | + | ====Step 1: Deteremine PV source loss parameters==== |
| − | The | + | The power rating of a PV module is generated under ideal testing conditions in a laboratory (See [[PV module#Standard test conditions|Standard test conditions]]), thus to build a PV system that is going to generate the necessary amount of energy under less than ideal conditions it is necessary that the estimated production that a PV module will generate is reduced to function under the anticipated conditions of use.<ref name="NRELderate">National Renewable Energy Laboratory - Performance Parameters for Grid-Connected PV Systems https://www.nrel.gov/docs/fy05osti/37358.pdf</ref> There are many different parameters that need to be accounted for and without performing extensive testing each of these parameters will largely be an estimate on the part of the designer. It is important to use conservative numbers as an over-sized system is always preferrable to an under-sized system. |
| − | ''' | + | *'''Module degradation parameter:''' The PV module degradation parameter accounts for the gradual reduction in the performance of [[PV module|PV modules]] over time. This is a factor that should be taken into account as a PV system should be designed to function for more than a decade. Module degradation not only affects performance, but can lead to a reduction in voltage over time that impedes the proper charging of the [[energy storage|energy storage system]]. The amount that the performance and voltage decreases per year largely depends upon the quality of the module: |
| − | * | + | :*High-quality modules: approximately .33% per year leading to a value over 20 years of .94 (94% of original power rating).<ref name="nreldegradation"> National Renewable Energy Laboratories - Outdoor PV Module Degradation of Current-Voltage Parameters https://www.nrel.gov/docs/fy12osti/53713.pdf</ref> |
| − | * | + | :*Lower-quality modules or generic brands: approximately .5% per year leading to a value over 20 years of .90 (90% of original power rating).<ref name="nreldegradation" /> |
| + | *'''Shading loss parameter:''' Parameter that accounts for any production losses that the system may experience due to [[Shading|shading]] from nearby obstacles - mountains, trees, other buildings - during the course of the year. The only way to get a accurate value for this parameter is to evaluate the shading at the site using a took like a the [https://www.solarpathfinder.com/ Solar Pathfinder]. The value for this parameter is completely site dependent. If it is anticipated that there will be no shading losses, then the value for this parameter should be 1. If there is a 5% loss, then a value of .95 should be used. | ||
| + | *'''Soiling loss parameter:''' Parameter that accounts for the build-up of dirt on the surface of a PV module, which reduces production as it doesn't allow light to reach the cells of the module. The appropriate value for this parameter depends primarily upon the climate and location in which the system is installed, but also the tilt and cleaning frequency of the PV modules. <ref name="NRELsoiling1">National Renewable Energies Laboratory - Time Series Analysis of Photovoltaic Soiling Station Data: Version 1.0, August 2017 https://www.nrel.gov/docs/fy17osti/69131.pdf</ref><ref name="NRELsoiling2">National Renewable Energy Laboratories - Photovoltaic Module Soiling Map https://www.nrel.gov/pv/soiling.html</ref>Frequent rainfall helps PV modules to self-clean. If a system is installed in a location with minimal windblown dust that receives regular rainfall or in which modules are cleaned weekly, then losses may be as low as 1%. If a system is installed in a location with significant windblown dust that receives very infrequent rainfall or in which modules are never cleaned, then losses may be as high as 50%.<ref name="qatarsoiling">Qatar Environment and Energy Research Institute - PV Soiling Rate Variation over Long Periods https://www.nrel.gov/pv/assets/pdfs/2015_pvmrw_02_figgis.pdf</ref><ref name="soilingreview">Renewable and Sustainable Energy Reviews Volume 59, June 2016 - Power loss due to soiling on solar panel: A review https://www.sciencedirect.com/science/article/pii/S1364032116000745</ref> With PV module cleaning every two months a value of .97 (3% loss) is recommended for locations with minimal windblown dust and a value of .93 (7% loss) is recommended for locations with significant windblown dust.<ref name="qatarsoiling"/><ref name="soilingreview"/> | ||
| + | *'''Wiring loss parameter:''' Parameter that accounts for the loss of voltage due resistance in DC system wiring. The actual value depends upon the system design. Total DC wiring losses - roundtrip from [[PV module|PV source]] to [[Energy storage|energy storage system]] - should be kept below 4%. A value of .96 (4% loss) is recommended for this parameter. | ||
| + | *'''Module mismatch parameter:''' Parameter that accounts for the loss of production that results from PV modules having different characteristics that result from manufacturing inconsistencies. This only applies for systems that have more than 1 PV module. The proper value varies depending upon the module used, but a value of .98 (2% loss) is recommended for this parameter.<ref name="NRELderate"/> | ||
| + | *'''Mounting system temperature adder:''' The [[Mounting system|mounting system]] will 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 losses due to temperature: | ||
| + | :*20°C for pole mount | ||
| + | :*25°C for ground mount | ||
| + | :*30°C for roof mount | ||
| + | *'''PV source temperature loss parameter:''' Parameter that accounts for losses that result from PV module cell temperatures in excesss of the [[PV module#Standard test conditions|standard test condition]] value of 25°C, which are common except in the coolest locations on earth. Cell temperatures are generally 10C-30ºC above ambient temperatures in full sunlight, therefore ambient temperatures must be around 0ºC for cell temperatures to be at 25ºC. The temperature of a PV module depends upon the climate, [[Insolation|insolation]], and how the module is mounted. PV module manufacturers provide a loss coefficient - typically called Temperature coefficient of max power and measured in %/°C - on the specifications sheet of each module that can be used to estimate losses based upon the conditions at the site. The value from the specifiction sheet of a module can be used in these calculations if a module has been chosen, but a standard average value of (-.48%/°C) will work for both poly and monocrystalline modules.<ref name="homer1">HOMER - PV Temperature Coefficient of Power https://www.homerenergy.com/products/pro/docs/latest/pv_temperature_coefficient_of_power.html</ref> | ||
| − | '''MPPT''' | + | ::{| class="wikitable" border=1 style="width: 80%;" |
| − | *Nominal system voltage: 12V, 24V, 48V | + | ! style="width: 20%"|PV source temperature loss parameter |
| − | *Maximum PV source voltage: varies up to 600V | + | ! style="text-align:left;"| = 1 + ([[Weather and solar resource evaluation#Maximum ambient temperature|Maximum ambient temperature]] + Mounting system temperature adder - 25°C) x Temperature coefficient of max power %/°C ÷ 100 |
| − | *Minimum PV source voltage: depends upon nominal voltage and charge controller type | + | |} |
| − | *Maximum PV source current: up to 100A+ | + | |
| + | ::{| class="wikitable" border=1 style="width: 80%;" | ||
| + | ! style="width: 20%"|Total PV source loss parameter | ||
| + | ! style="text-align:left;"| = Module degradation parameter × Shading loss parameter × Soiling loss parameter × Wiring loss parameter × Module mismatch parameter × PV source temperature loss parameter | ||
| + | |} | ||
| + | |||
| + | ====Step 2: Charge controller efficiency parameter==== | ||
| + | All charge controllers lose a certain percentage of all energy that is produced as heat as it is transferred to the [[Energy storage|energy storage system]] and [[:Category:Loads|loads]]. For both PWM and MPPT charge controllers a value of .98 (98% efficient) can be used. | ||
| + | |||
| + | ====Step 3: Energy storage efficiency parameter==== | ||
| + | All [[Energy storage|energy storage systems]] lose a percentage of all energy produced to heat as it is stored and released to power [[:Category:Loads|loads]]. | ||
| + | :Energy storage efficiency parameter values for lead acid battery types: | ||
| + | :*[[Lead acid battery#Flooded lead acid (FLA)|Flooded lead acid (FLA) batteries ]]: .75 (75% efficient)<ref name="trojanpaper"> Trojan Battery Company - Selecting the Proper Lead-Acid Technology http://www.trojanbattery.com/pdf/Trojan_AGMvsFloodedvsGel_121718.pdf</ref> | ||
| + | :*[[Lead acid battery#Valve-regulated lead acid (VRLA)|Valve-regulated lead acid (VRLA) batteries]]: .85 (85% efficient)<ref name="trojanpaper"/> | ||
| + | |||
| + | ====Step 4: Determine minimum size of the PV source==== | ||
| + | Finding the minimum size of the PV source will inform the rest of the design. | ||
| + | {| class="wikitable" border=1 style="width: 80%;" | ||
| + | ! style="width: 20%"|Minimum PV source size | ||
| + | ! style="text-align:left;"| = [[Load and solar resource comparison|Design daily watt-hours required]] ÷ [[Load and solar resource comparison|Design daily insolation]] ÷ Total PV source loss parameter (Step 1) ÷ Charge controller efficiency parameter (Step 2) ÷ Energy storage efficiency parameter (Step 3) | ||
| + | |} | ||
| + | |||
| + | ====Step 5: Determine charge controller type==== | ||
| + | There are two different charge controller types - pulse width modulation (PWM) and maximum power point tracking (MPPT) - each of which has advantages and disadvantages that are are detailed in [[Charge controller#Charge controller types|Charge controller types]]. Two separate designs may be performed with each type of charge controller to determine the best system design. The current and voltage rating of the charge controller will be determined when in either [[PWM charge controller sizing and selection]] or [[MPPT charge controller sizing and selection]]. | ||
| + | |||
| + | :'''PWM:'''<br /> | ||
| + | :The PV source must be configured to operate at the charging voltage of the [[Energy storage|energy storage system]] and below the maximum PV source current rating of the charge controller. | ||
| + | :*Nominal system voltage: 12V, 24V, 48V. | ||
| + | :*Maximum PV source current: 6A-60A | ||
| + | |||
| + | :'''MPPT:'''<br /> | ||
| + | :The PV source must be configured to operate below the maximum PV source voltage rating of the charge controller, above the minimum PV source voltage based upon the maximum charging , and below the maximum PV source current rating of the charge controller. | ||
| + | :*Nominal system voltage: 12V, 24V, 48V | ||
| + | :*Maximum PV source voltage: varies up to 600V | ||
| + | :*Minimum PV source voltage: depends upon nominal voltage and charge controller type | ||
| + | :*Maximum PV source current: up to 100A+ | ||
| + | |||
| + | ==Notes/references== | ||
| + | <references/> | ||
| + | National Renewable Energy Laboratory - [https://www.nrel.gov/docs/fy12osti/54200.pdf Understanding Light-Induced Degradation of c-Si Solar Cells] | ||
Latest revision as of 00:41, 2 March 2021
The size of the PV source, which is determined based upon the load evaluation and weather and solar resource evaluation will determine the necessary size of the charge controller. The charge controller must be selected at the same time as the PV source as the charge controller type - PWM or MPPT - will also determine the possible configurations of PV modules.
In this phase of the design process, more than in any other phase, it is necessary to explore different designs using PV module, series and parallel wiring configurations, and charge controllers in order to achieve the highest performance at the lowest cost possible. This phase may have to be performed several times.
An off-grid PV system that depends upon the PV as its single charging source requires an array that is sufficiently sized to be able to generate sufficient energy to both meet the energy needs of the users and to recharge the energy storage system under less-than-ideal conditions. Any sizing decisions should therefore lean towards a larger PV source.
Contents
Step 1: Deteremine PV source loss parameters
The power rating of a PV module is generated under ideal testing conditions in a laboratory (See Standard test conditions), thus to build a PV system that is going to generate the necessary amount of energy under less than ideal conditions it is necessary that the estimated production that a PV module will generate is reduced to function under the anticipated conditions of use.[1] There are many different parameters that need to be accounted for and without performing extensive testing each of these parameters will largely be an estimate on the part of the designer. It is important to use conservative numbers as an over-sized system is always preferrable to an under-sized system.
- Module degradation parameter: The PV module degradation parameter accounts for the gradual reduction in the performance of PV modules over time. This is a factor that should be taken into account as a PV system should be designed to function for more than a decade. Module degradation not only affects performance, but can lead to a reduction in voltage over time that impedes the proper charging of the energy storage system. The amount that the performance and voltage decreases per year largely depends upon the quality of the module:
- Shading loss parameter: Parameter that accounts for any production losses that the system may experience due to shading from nearby obstacles - mountains, trees, other buildings - during the course of the year. The only way to get a accurate value for this parameter is to evaluate the shading at the site using a took like a the Solar Pathfinder. The value for this parameter is completely site dependent. If it is anticipated that there will be no shading losses, then the value for this parameter should be 1. If there is a 5% loss, then a value of .95 should be used.
- Soiling loss parameter: Parameter that accounts for the build-up of dirt on the surface of a PV module, which reduces production as it doesn't allow light to reach the cells of the module. The appropriate value for this parameter depends primarily upon the climate and location in which the system is installed, but also the tilt and cleaning frequency of the PV modules. [3][4]Frequent rainfall helps PV modules to self-clean. If a system is installed in a location with minimal windblown dust that receives regular rainfall or in which modules are cleaned weekly, then losses may be as low as 1%. If a system is installed in a location with significant windblown dust that receives very infrequent rainfall or in which modules are never cleaned, then losses may be as high as 50%.[5][6] With PV module cleaning every two months a value of .97 (3% loss) is recommended for locations with minimal windblown dust and a value of .93 (7% loss) is recommended for locations with significant windblown dust.[5][6]
- Wiring loss parameter: Parameter that accounts for the loss of voltage due resistance in DC system wiring. The actual value depends upon the system design. Total DC wiring losses - roundtrip from PV source to energy storage system - should be kept below 4%. A value of .96 (4% loss) is recommended for this parameter.
- Module mismatch parameter: Parameter that accounts for the loss of production that results from PV modules having different characteristics that result from manufacturing inconsistencies. This only applies for systems that have more than 1 PV module. The proper value varies depending upon the module used, but a value of .98 (2% loss) is recommended for this parameter.[1]
- Mounting system temperature adder: The mounting system will 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 losses due to temperature:
- 20°C for pole mount
- 25°C for ground mount
- 30°C for roof mount
- PV source temperature loss parameter: Parameter that accounts for losses that result from PV module cell temperatures in excesss of the standard test condition value of 25°C, which are common except in the coolest locations on earth. Cell temperatures are generally 10C-30ºC above ambient temperatures in full sunlight, therefore ambient temperatures must be around 0ºC for cell temperatures to be at 25ºC. The temperature of a PV module depends upon the climate, insolation, and how the module is mounted. PV module manufacturers provide a loss coefficient - typically called Temperature coefficient of max power and measured in %/°C - on the specifications sheet of each module that can be used to estimate losses based upon the conditions at the site. The value from the specifiction sheet of a module can be used in these calculations if a module has been chosen, but a standard average value of (-.48%/°C) will work for both poly and monocrystalline modules.[7]
PV source temperature loss parameter = 1 + (Maximum ambient temperature + Mounting system temperature adder - 25°C) x Temperature coefficient of max power %/°C ÷ 100
Total PV source loss parameter = Module degradation parameter × Shading loss parameter × Soiling loss parameter × Wiring loss parameter × Module mismatch parameter × PV source temperature loss parameter
Step 2: Charge controller efficiency parameter
All charge controllers lose a certain percentage of all energy that is produced as heat as it is transferred to the energy storage system and loads. For both PWM and MPPT charge controllers a value of .98 (98% efficient) can be used.
Step 3: Energy storage efficiency parameter
All energy storage systems lose a percentage of all energy produced to heat as it is stored and released to power loads.
- Energy storage efficiency parameter values for lead acid battery types:
- Flooded lead acid (FLA) batteries : .75 (75% efficient)[8]
- Valve-regulated lead acid (VRLA) batteries: .85 (85% efficient)[8]
Step 4: Determine minimum size of the PV source
Finding the minimum size of the PV source will inform the rest of the design.
| Minimum PV source size | = Design daily watt-hours required ÷ Design daily insolation ÷ Total PV source loss parameter (Step 1) ÷ Charge controller efficiency parameter (Step 2) ÷ Energy storage efficiency parameter (Step 3) |
|---|
Step 5: Determine charge controller type
There are two different charge controller types - pulse width modulation (PWM) and maximum power point tracking (MPPT) - each of which has advantages and disadvantages that are are detailed in Charge controller types. Two separate designs may be performed with each type of charge controller to determine the best system design. The current and voltage rating of the charge controller will be determined when in either PWM charge controller sizing and selection or MPPT charge controller sizing and selection.
- PWM:
- The PV source must be configured to operate at the charging voltage of the energy storage system and below the maximum PV source current rating of the charge controller.
- Nominal system voltage: 12V, 24V, 48V.
- Maximum PV source current: 6A-60A
- MPPT:
- The PV source must be configured to operate below the maximum PV source voltage rating of the charge controller, above the minimum PV source voltage based upon the maximum charging , and below the maximum PV source current rating of the charge controller.
- Nominal system voltage: 12V, 24V, 48V
- Maximum PV source voltage: varies up to 600V
- Minimum PV source voltage: depends upon nominal voltage and charge controller type
- Maximum PV source current: up to 100A+
Notes/references
- ↑ 1.0 1.1 National Renewable Energy Laboratory - Performance Parameters for Grid-Connected PV Systems https://www.nrel.gov/docs/fy05osti/37358.pdf
- ↑ 2.0 2.1 National Renewable Energy Laboratories - Outdoor PV Module Degradation of Current-Voltage Parameters https://www.nrel.gov/docs/fy12osti/53713.pdf
- ↑ National Renewable Energies Laboratory - Time Series Analysis of Photovoltaic Soiling Station Data: Version 1.0, August 2017 https://www.nrel.gov/docs/fy17osti/69131.pdf
- ↑ National Renewable Energy Laboratories - Photovoltaic Module Soiling Map https://www.nrel.gov/pv/soiling.html
- ↑ 5.0 5.1 Qatar Environment and Energy Research Institute - PV Soiling Rate Variation over Long Periods https://www.nrel.gov/pv/assets/pdfs/2015_pvmrw_02_figgis.pdf
- ↑ 6.0 6.1 Renewable and Sustainable Energy Reviews Volume 59, June 2016 - Power loss due to soiling on solar panel: A review https://www.sciencedirect.com/science/article/pii/S1364032116000745
- ↑ HOMER - PV Temperature Coefficient of Power https://www.homerenergy.com/products/pro/docs/latest/pv_temperature_coefficient_of_power.html
- ↑ 8.0 8.1 Trojan Battery Company - Selecting the Proper Lead-Acid Technology http://www.trojanbattery.com/pdf/Trojan_AGMvsFloodedvsGel_121718.pdf
National Renewable Energy Laboratory - Understanding Light-Induced Degradation of c-Si Solar Cells
