Solar Power Plant Design and PV Syst

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Solar Power Plant Designing & PV Syst

SUNRATOR ENERGY RESEARCH INSTITUTEwww.sunratorinstitute.com

1

The OutlineAbout SoftwareCheck-List of required information from clientGeographical DetailsImport Meteo dataSystem DesignInput ParametersSimulation & Results

SUNRATOR TECHNOLOGIES LLPA-314, Shivalik, New Delhi-110017011-41605551

About the SoftwareOne of the oldest software, developed by university of Geneva.Main features.Meteorological data analysis.Complete database of PV Modules, Inverter and Meteo data.Import of solar radiation data from Meteonorm, NASA and many others database.Create your self & Import PV Modules & Solar Inverter data from Photon international.Shadow Analysis using 3D Models.Design simulation of grid connected, standalone.Export the data into XPS & convert into pdf.


2. Checklist for the client


Location DetailsCoordinates: Latitude and longitude2. Address

Technical DetailsType of systemPV Module technologyModule CapacityInverter


3. Geographical Details

Check Location on Google Earth latitude (N or S) longitude (E or W)Azimuth Angle (South reference = 0 )


4. Import Meteo DataIrradiation, temperature, wind speed data fetch from various meteorological database Follow these stepsDatabaseClick on geographical siteGo to new optionChoose interactive map & enter location Get geographical coordinate section & verify details choose meteodata sourceClick on import in Monthly meteo section, click on OK button & save the file


5. System DesignThe section provide you Optimum tilt, Estimated Energy Yield, PR & Details Losses.Choose Project Design Option from main menu.Select New project > Go to parameter & click on site & meteo for importing meteo file.Select Country > Scroll Up-Down Choose Meteo file from Site option which you created > OK, Project details will display on Project Designation Section.Go to system Variant > Choose new variant, Save the file .


6. Input ParameterUnder this section we computing Orientation Optimum tilt of module for collecting maximum radiation, pitch to limit the shading losses.System project capacity or area, Selection the of PV Modules & Make, Inverter Rating & Make, Series & no. of Strings Combination.Details losses Thermal parameter, Ohmic Losses, Module quality-LID-Mismatch, Soiling losses.


Orientation Simulate optimum plane tilt w.r.t. yearly meteo yield & pitch selection to limit shading losses.Follow the steps Calculating optimum plane tilt (Calculating for fixed tilt) Default page look like i.e. Tilt 30 , Azimuth 0 Select Fixed Tilted Plane in field type option > enter the latitude value & Azimuth value in field parameter > Change the plane tilt value so that Loss by respected to optimum should be 0% & correspond Global radiation on collector plane should be Maximum.


SystemWhat u have with ? Plant capacity or area , Module & Inverter details.Follow the steps Enter the planned power or available area, the information provided by the client.Select the PV Module > Sort the module base on power or Technology > scroll down the button, Select the Manufacturing company from the list & along with their Module type.


Inverter Selection Pre decide the type of inverter i.e. string or central.Go to > Select the inverter make from the list > sort the inverter based on Power or Voltage.Inverter should be sized in such a way that under loading & over loading (DC to AC ratio) with in acceptable range.A message will appear on dialog box i.e. indicate if there is any error during the selection of inverter.Go the design the array > check no of modules, modules in series & module string.Click on OK > Proceed the next steps.


Losses Ohmic lossesGo to DC circuit: Ohmic losses for the array > Click on loss fraction at STC > Enter the value in between 1.10% - 1.30% (these losses computed considering ohmic losses of array to string combiner box / string monitoring box and string combiner box to inverter DC input.)These losses occur to due to resistance to DC wire in the Module string to string combiner box / String monitoring box and string combiner box to inverter DC input.


Losses AC Ohmic Wiring lossesGo to AC circuit: Inverter to injection point > Click on loss fraction at STC > Enter the value in between 0.50% - 0.80% (these losses occur at inverter output to point of injection of energy into the grid (switch yard). The losses include Ohmic losses in inverter output to LT panel , HT panel.) Transmission line losses are not included on this because it depends upon the point of injection / joint metering panel as per PPA & respective state regulation.The Voltage Drop should be below 2.1%.


External Transformer Go to external transformer > iron loss > enter 0.10% or enter Fixed loss of transformer if known.Resistive/ Inductive losses > enter 0.10%Iron loss : are fixed losses of transformer occur due to hyterersis and eddy current loss in the core of transformer. Silicon is used to reduce these losses.Ohmic/ Inductive loss: are variable losses due to resistance / Inductance of copper winding and loading of the transformer.


Module Quality Loss Go to module quality loss section > Enter the value the according to average deviation of the module tolerance power is positive +3% then module quality loss shall be +3/2= 1.5%.


LID Light Induced Degradation Initial degradation of solar PV module occurs in the very first hours of operation in the actual site. After certain period of time (3.4 months) the power output of the module stabilizes on the certain level compare to STC power.Typically poly C-Si Module degrade @1.0%Mono C-Si Module degrade @ 1.5% Thin film Module degrade @ 2%


Mismatch LossThe mismatch loss is mainly due to the fact that in a string of module, the lowest current drives the current of whole string. This is due to material property of Silicon which is used for the PV module manufacturing. Now when installing real modules in the field, the characteristics of the module are never rigorously identic.Power Loss at MPP The difference between the effective operation conditions and the maximum available power plant. Foe MPP use (grid inverter) the loss is neglected in PV Syst. For fixed operating voltage, it can be quantified from the output simulation result.Go to mismatch Section > Enter the value (it typically happen at 1%) & loss when running at fixed voltage not relevant when MPPT operation (it typically limit to 1.1%)


Soiling LossAccumulation of dirt and its effect on the system performance is an uncertainty which strongly depends on the environment of the system, raining conditions etc.

Considering the project location in Rajasthan where module are frequent face the dust/dirt/sand the soiling loss so power loss can be up to 3% and location like Karnataka/Uttarakhand the power loss can be up to 2% because of less prone to dust & dirt environment.

This power loss can be reduce by increasing the frequency of module cleaning.

7 - Simulation & Results

Simulation Execution Go to simulation & result section > Click on simulation to perform simulation of projects > Click on Simulation


Simulation Execution This simulation shall be perform with consideration of meteo value (Hourly/Daily/Monthly)Click on step by step section > click on continue > Click on OK and to get the simulation result.

Simulation Result This section show the following details Project title Site Location System type Project Capacity Selected Module/Make Inverter Make/ No of invertersEnergy Generation result Energy Yield (For first year of Operation) Specific Yield (in kWh/kWp/year)Performance RatioDetails Report section You can generated the whole result as in report analyze the simulation result save the simulation studies.

MASTER DRAWING LIST

SITE DETAILSREPORTSSLD (SINGLE LINE DIAGRAM)ArrayMODULE MOUNTING STRUCTUREMAIN CONTROL ROOM - ELECTRICALMAIN CONTROL ROOM - CIVIL/ STRUCTUREINVERTER STATION - ELECTRICALINVERTER STATION - CIVIL/ STRUCTURECALCULATIONSEXTERNAL -ELECTRICAL/FA/CCTVEXTERNAL -CIVIL

SITE DETAILS

Site Contour LayoutSoil Test Report

REPORTS

Shadow Analysis ReportPV Syst Report

SLD (SINGLE LINE DIAGRAM)AC Single line diagramAux. single Line diagramDC single Line diagramPLC architecture schematic

Array Array layout HT cable routing layout DC cable routing layout PLC cable routing layout Lightning Protection layout PV Array earthing layout External Lighting layout Foundation details for light pole drawing

MODULE MOUNTING STRUCTURE

GA of Module Mounting Structure Foundation drawing for Module Mounting Structure ArrayFoundation Design Calculations for Module Mounting Structure G.A drawing for SMB mounting structure

MAIN CONTROL ROOM ELECTRICALMain control Room Equipment LayoutMain Control Room Cable Tray & Trench LayoutMain Control Room Earthing LayoutMain Control Room Lighting & Power Layout

MAIN CONTROL ROOM - CIVIL/ STRUCTURE Main Control Room- Architectural drawing Main Control Room- Foundation and Column Details Main Control Room- Beam Details Main Control Room- Roof Slab Details

INVERTER STATION - ELECTRICALInverter Station Equipment LayoutInverter Station Earthing LayoutInverter Station Lighting & Power Layout

INVERTER STATION - CIVIL/ STRUCTUREInverter Station Architectural Details Inverter Station Foundation Details Inverter Station Plinth Beam Details Inverter Station Structural Details

CALCULATIONSAC Cable schedule DC cable scheduleControl cable schedule MWS Sizing calculation Battery Charger sizing calculations Aux. transformer sizing HT Cable CalculationLT cable Calculation DC cable Calculation Earthing calculation LA Protection Calculation

EXTERNAL -ELECTRICAL/FA/CCTVMain Control room - Fire alarm layoutMain Control room -CCTV layout Light fixture catalogue Data sheet / Catalogue for CCTV equipment Data sheet / Catalogue for Fire alarm system

EXTERNAL -CIVIL Main Gate Details Module Cleaning System Layout Transformer Yard Fence and Gate Details Drawing Foundation Drawing for Inverter Transformer Foundation Drawing for Auxiliary Transformer Civil Drawing For Road Precast boundary wall

THANK YOU

Date post:	16-Apr-2017
Category:	Environment
Upload:	sunrator-technologies-llp
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Solar Power Plant Design and PV Syst

Environment