Page Comparison

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

...

Sighten‘s production model incorporates key aspects of the industry’s most sophisticated models while maintaining simplicity of user inputs.

...

• Simple and non-assumptive user inputs required: module and inverter quantities/models, pitch, azimuth, and shading

• Hourly production calculations with granular weather data

• Module and inverter-level electrical behavior modeled 

Overview

Full description of Sighten's production calculation

• production Production is simulated for each array on an hourly basis
• primary Primary sources of input:
  • TMY weather data (8760 hours) based on system location
  • PV module electrical specifications per manufacturer spec sheet
    • includes parameters we calculate to construct IV curve (DeSoto)
  • inverter Inverter electrical specifications per manufacturer spec sheets
  • array Array details (e.g. tilt, azimuth, string size, shading, etc)
• for For each hour of a TMY dataset:
  • determine Determine the solar radiation incident on the tilted surface
    •  "unshaded" radiation includes beam radiation component
    • "shaded" radiation assumes no beam radiation
  • determine Determine solar cell temperature based on PV model specifications in both shaded and unshaded conditions
  • construct Construct I-V curve of solar cell based on IV curve parameters calculated as functions of solar cell temperature for both shaded and unshaded conditions (Desoto)
  • determine Determine the AC power generated from the array:
    • NOTE: the percentage shading implies the percentage of PV modules IN EACH STRING that receive "unshaded" radiation versus "shaded" radiation
    • if If the array uses a string inverter:
      • the The string voltage is calculated as a composite of the unshaded and shaded PV modules
      • find Find array max power (DC) by calculating string voltage as a function of a universally-applied string current
      • find Find module voltage on the I-V curve for unshaded module
      • find Find module voltage on the I-V curve for shaded module
      • string String voltage is the sum of voltages generated by unshaded and shaded modules in their respective proportion
      • iterate Iterate until maximum of product of string voltage and array current is found
    • convert Convert array power (DC) into array power (AC) based on inverter efficiency specifications (per spec sheet) and derate assumptions applied to all string inverters:
      • wiring_dc = 0.980
      • mismatch  = 0.980
      • diodes    = 0.995
      • soiling   = 0.950
      • wiring_ac = 0.990
  • if If the array uses microinverters:
    • find Find array max power (DC) by calculating unshaded and shaded module voltages as functions of a individually-managed current
      • find Find module max power (DC) on the I-V curve for unshaded module
      • find Find module max power (DC) on the I-V curve for shaded module
      • convert Convert module power (DC) into module power (AC) for unshaded and shaded modules based on inverter efficiency specifications (per spec sheet) and derate assumptions applied to all microinverters:
        • wiring_dc = 0.995
        • mismatch  = 1.000
        • diodes    = 0.995
        • soiling   = 0.950
        • wiring_ac = 0.990
      • array Array power (AC) is the sum of power (AC) generated by unshaded and shaded modules in their respective proportion of the array
  • If the array uses string inverters with optimizers:
    • Same methodology as for microinverters, but using the following derate factors:
      • wiring dc = 0.980
      • mismatch = 1.000
      • diodes = 0.995
      • soiling = 0.950
      • wiring ac = 0.990

References