Rums floating Omkareshwar FSPV IM_16112021.pdf

1
Information Memorandum
of
600 MW OmkareshwarFSPV
At Khandwa, Madhya Pradesh, India

2
Contents
•Salient Features of the Omkareshwar Reservoir
•Project Site Analysis
•Capacity Packaging –Unit wise allocation
•Technical Assessment
•Resource Assessment
•Evacuation Infrastructure and Metering Arrangement
•Road Infrastructure, Assembly Areas & Launch Sites
•Transaction Features
•Bid Documents

3
Salient Features
of the FSPV Solar
Park

4
Project Site Details
Site parameters Value
Top of the reservoir level 203.00 m
Reservoir Capacity 141,547.8 m3
Water available for irrigation 327,000 Acres
Catchment Area 64,880 sqkm
Spillway type Gated ogee spillway
Air temperature Min 11-12 °C (in the month of Dec-Jan)
Max 40-45 °C (in the months of May)
Wind Speed range 9-20 km/h, no major typhoon occurrence in
the area
Rainfall Min 80 mm to Max 240 mm
Dam Parameters Value
Location 22º14’25’’N, 76º09’45’’
Active Capacity 27,877 m3
Estimated surface available 11 Sq km
Height of dam from foundation 57.00 m
Maximum water level 199.62 m
Full reservoir level 196.60 m
Flood Cushion 3.60 m
Spillway crest level 179.60 m
Gross storage 0.987 billion m3
Live storage 0.299 billion m3
Design flood 88.315 Cumecs
Maximum observed flood since 2007 38.028 Cumecs(2013-2014)
Powerhouse 520 MW (8 Nos of 65 MW)
Earthquake monitoring station Operational
Omkareshwar

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Salient Features of the Proposed Omkareshwar Floating Solar Park
World’s Largest 600 MW Floating Solar Power Park at the Omkareshwar Reservoir.
In principle approval for secured financing in place for the Floating Park Infrastructure
Estimated investment for the Park ~ INR 30,000 Million
Detailed Feasibility finalized for the Floating Solar PV Park
Off-take arrangements to be secured and confirmed prior to the issuance of the final RfP

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Project Attractiveness …….1
1. RUMSL as an experienced Solar Park Developer with 1000 MW of installed capacity and another 1500 MW successfully transacted
and under implementation
2. Technology Agnostic
3. Certainty of Power Offtake:
•Availability of accredited procurer –Indian Railway (prospective).
•State Government commitment of power procurement through State Discoms.
4. Payment ensured through payment security mechanism:
•Letter of credit.
•Payment Security Fund.
5. No delays due to land/ site acquisition:
•Requisite approvals in place for availability of Reservoir.
•Land lease for substations, manufacturing & storage facilities in place.
•Assembly & launch areas identified.
6. Environment & Social: No/ limited E&S concerns expected

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Project Attractiveness …….2
1.Planned development of evacuation infrastructure by RUMSL.
2.Avoidance of project delay due to effective State and Central Government level coordination by RUMSL.
3.MNRE Grant to be availed for reducing solar park charges.
4.Bidders will be able to access all project documents via the Data Room.
5.Multiple studies undertaken to reduce risk during project development/ operation i.e. (Detailed Project Report and Detailed Technical
Due Diligence).
6.Omkareshwar Floating Solar Park is likely to become a major tourist hub attracting large scale visibility.

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Project Site
Analysis

9
Site Survey
Thesitesurveyswereundertakentoacquireinformationonthewaterbedintheformofacontourmaps.Detailsrelatedtothedepthofthe
waterbedwithreferencetothedatumlevelwascollectedintwostages:
•Stage1:InvolvedconductingareccestudyusingaSingleBeamEchoSounder(SBES)forlargeridentifiedarea.
•Stage2:InvolvedbathymetrystudywithMulti-beamEchoSounder(MBES).
Survey Study area
Salientfeatures
1.SinglebeamRecce-survey:
•DatacollectedusingReal-TimeKinematic
DifferentialGPS(RTKDGPS)andSingle
BeamDualFrequencyEchoSounder,Survey
linesat100m,covering20sq.km,bankto
bank
•Informationonthereservoirbedatvery
coarselevel,preliminaryassessmenthelped
inselectingsuitablesiteof12Sq.kmfor
600MWFSPVonwhichfurtherdetailed
studieswereconducted.Resultswillprovide
thefollowing:
✓ Broaddetailsonthereservoirbedtopography
✓ depthofthewateratdifferentlocations
✓ Presenceofsubmergedislands,presenceof
obstacles such as submerged
poles/pillars/trees
✓ Roughestimateonthedepthofsoft/loose
sedimentspresentonreservoirbed

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Site Survey
Salientfeatures
2.MultibeamBathymetrySurvey:
•Usingmulti-beamechosounderforfullcoverageoftheselectedareawithatleast25%overlapatsuitablelinespacing
•100%coverage,areacovered>12sq.km
•Detailedreservoirbedtopography,sedimentationregions,
•Detailedinformationonthesubmergedislandssize,shape,length,heights
•Identificationofsteepchangesintheelevationofthereservoirbed
3.Geophysical:
•ReservoirbedimagingusingSideScanSonar(SSS)coveringabout12sq.km
✓ Underwatermorphology
✓ Sedimentscharacteristics,presenceofdebris
✓ Identificationofunderwater/sunkenobjects
✓ Presenceofboulders,rockoutcrops,submergedstructures.
✓ GeomorphologicalfeaturesofthereservoirbedusingSubBottomProfiler(SBP)coveringabout12sq.km
4.Watervelocitymeasurement
•15daysmeasurementofcurrentspeed,magnitudeanddirection,itsvariationovertime
•VelocitysimulationfordamgatesopeningduringfloodscenariosconsideringreservoirwatersurfaceelevationatFRLandMWL

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Site Survey
Salientfeatures
5.GeotechnicalSurvey:
•ReservoirbedsoilcharacteristicsusingVibrocorer
✓TypeofthereservoirbedmaterialanditsclassificationasperUnifiedSoilClassificationSystem
✓Assessmentofthestrengthparameterstri-axialshear,directshear,cohesionandangleofrepose.
•ReservoirsedimentcharacteristicsusingStandardPenetrationTest
✓TypeofthesedimentmaterialcollectedandUSCS
✓Assessmentofthestrengthparameterstri-axialshear,directshear,cohesionandangleofrepose.
•Reservoirwaterqualityanalysis
✓ Analysisofreservoirwaterforthepresenceofanychemicals,minerals,salinity
6.Topography Study
•MappingofgroundlevelswithallfeaturesreferencedtoMeanSeaLevel(MSL)inthestudyarea

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Site Survey
Single Beam vsMultibeam Bathymetry Survey
SingleBeamSurvey(Toidentifythemostappropriateareafor
FSPV)
•100 X 100 Metre Grid
•Total area covered -25 Square Kilometers
MultiBeamSurvey(TomapreservoirbeddetailsforFSPV
installation)
•40 X 40 Metre Grid with 100% coverage of reservoir bed details
with 25% overlap
•Total area covered -12 Square Kilometers

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•ReccesurveywasconductedatKaveri
branchcoveringanareaof25sq.km
fromwestbanktoeastbankofthe
reservoir
•AreasnotsuitableforFSPVi.e
protrudingislands,inaccessibleareas,
shallowdepthswereidentified
•Maxdrawdownlevel(MDDL)was
considered
•Basedontheaboveandconsideringa
safebufferof1.5mbelowMDDL
(192.0),areaequivalentto12sq.km
wasconsideredforfurtherdetailed
explorationofthereservoir
Single Beam Recce Survey …….1
Note: Detailed Maps files will be provided in the Data Room

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Results:
•ShallowdepthwasfoundfromSouth-East(SE)directiontoNorth-West(NW).
•Depthvariesfrom1.0mto4.0mapproximately,exceptasmallcreekhavingdepth5.0metreto10.0metreapproximately
•Onbothshoresideareashallowdepthareobservedvaryingfrom0.6to4.0metreapprox.
•Shallowdepthareaswereobserved,wherethedepthvariedfrom2.8to4.8metreswithsometreesin-betweenthelocation625883.460E,
2453953.800Nand624814.99E,2454964.940Ninapproximatelya100metrescorridor.
•ShallowwaterareafoundinNEdirection,depthvariesfrom3.9metreto4.6metrebetweenlocation622749.840E,2457330.930Nand
622341.740E,2457577.390Naround50metrecorridor.
•Restalltheareahavingsufficientdepthvariesfrom5.0metreto26.7metre.DepthincreasesfromNEtoSWuptocentreandthen
decreasestowardsSWdirection.
Single Beam Recce Survey ……..2

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Multibeam Bathymetry Analysis …….1
Multibeam bathymetry chart of the entire survey area of 12 sq. km
Note: Detailed Maps files will be provided in the Data Room
•Highly undulated and rugged riverbed
•Gentletomoderategradients(upto10º)
•Steeptoverysteepgradients(upto50º)
alongtheriverchannelsandtheperipheryof
Islands
•Comparatively less rugged than the upper half
•Steeptoverysteepgradients(upto44º)alongthe
riverchannelsandattheperipheryofIslands
Gentletomoderate
gradients(upto10º)inthe
southwesternandsouth-
easternregions

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Multibeam Bathymetric analysis …….2
Minimum
Water depth
1.7m
Maximum Water
depth 35.8m
Maximum
Water depth
18.3m
Minimum
Water depth
2.0m
•Area 1: Highlights an undulated
riverbed across the entire surveyed
corridor.
•Bathymetry varies between 1.7m to
35.8 m. (w.r.t MDDL of 193.54 m)
Survey Area –1
•Area 2: Highlights a smooth riverbed
with gradual gradient towards centre of
survey corridor.
•Undulated river-bed recorded at centre
towards the southwest side
•Bathymetry varies between 2.0m to
18.3m. (w.r.t MDDL of 193.4 m)Survey Area –2
Minimum Water depth
1.4m
Maximum Water
depth 25.6m
•Area 3: Highlights a smooth riverbed
near the banks. Rest of the area
recorded as undulated riverbed.
•Bathymetry varies in survey area-3
between 1.4m to 25.6 m (w.r.t MDDL of
193.54 m)
Survey Area –2
Survey Area –1
Survey Area –3
Survey Area –2
Survey Area –1
Survey Area –3

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Geo-physical Survey -Riverbed features …….1
Type 1: Low Reflective Sediments
(Silty Fine Sand)
Type 2: Medium Reflective sediments
(Isolated sediment patches)
Type 3 : High reflective Sediments
(Weathered Bedrock)
Bed type Observations during survey
Type -1
Low Reflective
Sediments (Silty
Fine Sand)
•A large percentage of the reflections detected in
survey corridors are low reflective sediments
classified as Type 1.
•Type 1 sediments consist of fine sands and silts.
•Survey corridors were found to contain most of
these sediments.
Type -2
Medium Reflective
sediments
(Isolated sediment
patches)
•These sediments were recorded as isolated
sediment patches within the survey corridor.
•Based on data interpretation, they are Hard
sediments/Boulder bed, with Medium reflectivity.
•These sediments were recorded near the reservoir
banks and in the center of the survey corridor.
Type -3
High reflective
Sediments
(Weathered
Bedrock)
•Sediments showing high reflectivity to the sonar
frequency are classified as Type-3. These sediments
were identified as weathered bed rock.
•These sediments were recorded at reservoir banks
within the survey corridor.
Sidescansonarrevealsriverbedofvaryingreflectivityto100kHzfrequency

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Geo-physical Survey -Riverbed features …….2
scattered to numerous boulders in the north-eastern
portion
possible Hardground/ROCK with intermittently occurring
pockets of gravelly SILT/CLAY in the north-western portion
Fine sediments (mainly SILT/CLAY) in the south-eastern
portion
sonar contact (linear object) in the southern portion
•Fine sediments with scattered to numerous possible boulders are observed throughout the surveyed area
•Patches of coarse sediments are observed mainly in the north-western and west-southwestern portions
•Scattered patches of hardground are observed mainly in the north-western, southern, central and south-eastern portions
•Possible Hardground/ROCK exposures with intermittently occurring pockets of sediments are observed mainly along the peripheryofthe islands and
the surveyed area boundary in the north-western, western, southwestern and south-eastern portions of the surveyed area
•Total of two hundred and sixty-two sonar contacts were identified in the entire surveyed area, some of the contacts listed may be remnants of existing
huts or other structures that were originally present in the area and were submerged in the reservoir that resulted from the construction of the dam.
These may be partially covered by sediments hence may not present as geometrical shapes in the side scan sonar records.

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UNITA:
•Uppermostparallelreflectoridentifiedwithinthe
surveyedcorridor.
•Acousticallytransparentsedimentsinterpretedas
parallelbeddedsiltysandswithclays.
•Faintinternalreflectionconfigurationattributedto
changesinstiffness,typeofsediments(Siltyfine
Sand)anddensity,increasingwithdepth.
•Internalreflectionconfigurationneitheruniformnor
presenteverywhere.
UNITB(OccursdirectlybelowtheUNIT‘A’):
•Exhibitsmediumtohighacousticimpedanceto
seismicenergies,inhibitingfurtherpenetrationof
acousticsignals
•Interpretedasweatheredbedrock&recordeddown
tothelimitofpenetrationofacousticsignal.
Geo-physical Survey -Shallow Stratigraphy …1
Apartfromtheabove,noothersignificantfeaturesor
anomaliesassociatedwithshallowgaswereevidentfrom
therecordswithinthesurveycorridor,whichcouldbe
hazardoustothemarineconstructionactivities. Note: Detailed PDF files will be provided in the Data Room

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•Uppermostlayertobemadeupofpredominantly
finesediments(mainlySILT/CLAY)inmostpartsand
coarsersediments(mainlyclayeySAND)insome
portions
•Baseofthesesedimentsformstheprominentseism
stratigraphicreflectorinterpretedasthetopof
possibleHardground/ROCK.
Geo-physical Survey -Shallow Stratigraphy …2
•Maximumdepthofprominentreflectoris3mbelowtheriverbed,
observednearthesouth-centralportionofthesurveyedarea.
•Minimumdepthof0m(possiblehardgroundexposures/rockwith
intermittentlyoccurringpocketsoffine/coarsesediments),
mainlyalongtheperipheryofthesurveyedareaandislands.
•Fewscatteredareas(withminimumdepthof0m)arealso
observedinthenorth-western,southwesternandsouthernparts
ofthesurveyedarea.
prominent seismic stratigraphic reflector in the north-western region of the surveyed area
possible hardground exposures/ outcropping rock with intermittently occurring pockets of gravelly sandy
SILT/CLAY in the south-eastern region of the surveyed area.

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Geotechnical Survey …1
Soil sampling and analysis
Type of survey Details Soil
samples
Reservoir bed sample
using Vibrocorer
(Transaction Advisory)
•500 X 500 m
grid size
•Soil sediment
collection
depth up to
3m
47 Nos
Soil sample using rotary
rigs
(Detailed Project
Report)
•Bore hole
samples
•at 5m avg
depth
10 Nos
Soil sample using
Standard Penetration
Test
(World Bank Pre
Feasibility Study)
•500 X 500 m
grid size
•Soil sediment
collection
depth up to
3m
41 Nos
Water samples were collected from same location at three different depths

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Geotechnical Survey …2
6%
25%
46%
23%
Soil grain size
distribution (in mm)
Gravel >/= 4.75
Sand 4.75 to 0.075
Silt 0.075 to 0.002
Clay < /= 0.005
Reservoir bed soil characteristics
Group symbol
USCS
% Major division (typical names)
CH 73%
clays of high plasticity liquid limits more than 50% (inorganic clays
of high plasticity, fat clays, sandy clays of high plasticity)
CL 15%
clays of low plasticity liquid limits less than 50% (inorganic clays of
low to medium plasticity, gravely, sandy and silty clays)
GP 2%
clean gravels less than 5% passes 200 sieve (Poorly graded gravels,
gravel sand mixtures or sand gravel cobbelmixtures)
SM 8%
sand with fines, more than 12% passes no. 200 sieve (silty sands,
silt sand mixtures)
SP 2% Poorly graded sand, gravely sands
Laboratorytestswerecarriedouttoobtain
physicalpropertieslikesoilclassification,grain
sizedistributionincludinghydrometric
analysis,organicmaterialcontent,drydensity,
Atterberglimits,watercontent,undrained
sheartest,shearparameters(cohesion,angle
offriction).MechanicalanalysisandAtterberg
LimitswereconductedaccordingtoIS2720
relevantparts.
Physical properties of soil
Organic content (%) 11 to 20
Dry density, gm/cm3 0.67to 1.34
AtterbergLimits
Avg. Liquid limit(%)
Avg. Plastic limit (%)
Avg. Plasticity Index
57.2
27.6
29.6
Avg.WaterContent (%) 52
*USCS Unified Soil Classification System
Reservoir water quality
Water quality
parameters
Min Max Average
Remarks/Permissible Limits
(limits as per IS 456-2000)
pH 6.55 8.07 7.67> 6 (Moderately Alkaline)
Total Dissolved Solids168 208 190.22000 mg/lt
Calcium as CA 6.4 34.1 29.5
Nitrate <1.0
Chloride Content 4 30.8 6.9
No limit specified in IS 456.
However, value ranged between <
2000 mg/l Specified for Class I in
CIRIA Sp. Publication No. 31.
Sulphates as SO4 5.2 6.8 6.0NA
Total Suspended Solids 1 30 10.9NA
Suspended Sediments 5 0 10.9NA
Organic Matter 5 48 7.1200 mg/l
Salinity 0.001 9 0.07
Sulphate as SO3 4.4 5.7 5.04< 400 mg/l

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Geotechnical Survey ……..3
Approach
•Ageotechnicalsurveywasconductedontwelveboreholes(BH-1toBH-12)uptofivemetersbelowreservoirbottomdepth.
•Sub-surfaceinvestigationcompletedasperIS:1892-1979usingrotaryrigs(Calyx,8HP,Engine).
•StandardPenetrationTests(SPT)carriedoutatevery1.5mverticalintervaluptobedrock(inaccordancewithIS2131-1981).
•Samplingpointswerespacedat500mX500mintervalinbothdirections,coresamplesfromupto3metreshavebeentaken.
•EachsampleretrievedfromSPTspooninspectedforvisualidentificationofstrataandthensubjectedtolaboratorytesting.
•LaboratorytestsincludedmechanicalanalysisandAtterbergLimits(asperIS-2720).
Bore Hole
(BH) No.
East North
BH termination depth
(Metres.)
BH-01 619575.581 2458394.121 5.00
BH-02 620561.221 2458225.263 5.45
BH-03 621482.308 2457835.905 5.45
BH-04 622232.535 2457174.725 5.45
BH-05 622887.456 2456419.028 5.25
BH-06 623599.302 2455716.692 5.26
BH-07 624402.309 2455120.723 5.12
BH-08 625009.799 2454326.395 5.00
BH-09 625664.296 2453678.504 5.45
BH-10 624293.690 2456488.234 5.25
BH-11 625143.841 2457014.773 5.25
BH-12 626063.453 2457407.599 5.00

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Anchors proposed
Findings
•For deeper areas -the non-penetrating gravity anchors would be
the optimal solution
•For the shallow parts on top of rock -the Southwest side borehole
10, 11 & 12 or in the Northwest part of boreholes 7, 8 & 9, the
standard solution is to use rock bolts.
•Embedment anchors can be optimal choice for locations with
cohesive sediments which are best suited to, though not too stiff to
impede penetration
•Final decision will be based on detailed installation planning post
determination of anchor positions.
BH 1: Rock Bolt Anchor
BH 2: to BH6: Non penetrating Gravity Anchor
BH 7 to BH 12: Combination of Non penetrating Gravity and
Rock Bolts

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Water Current Velocity Measurement
ADCP 1 ADCP 2
Max current measures in
15 days observation
Average Current velocity
-Surface layer
-Mid layer
-Bottomlayer
Max. 0.336 m/s at surface on 5
th
June 2021
0.037
0.028
0.026
Max. 0.295 m/s at surface on 5
th
June
2021
0.033
0.028
0.028
Current Direction
-Surface layer
-Mid layer
-Bottomlayer
SE, ESE & SSE, NW, WNW
E, ESE, SE & NW, NNW, WNW
SE, SSE, ESE & NW, NNW, WNW
E, ESE,SE, SSE & N, NNW, NW, WNW
E, ESE, SE, E & N, W
E, ESE,SE, SSE & N, NNW, NW,W,
WSW
Occurrence
0-0.01m/s
> 0.01 m/s
97%
Dueto rain/extreme weather/
discharge from dam
97%
Dueto rain/extreme weather/
discharge from dam
Current magnitude more at the surface level and
decreases gradually towards bottom
more at the surface level and decreases
gradually towards bottom
Currentroseplot(surfacespeedvs
direction)atADCP1
Currentroseplot(middepthspeed
vsdirection)atADCP1
Currentroseplot(nearbottomdepth
vsdirection)atADCP1
Currentroseplot(surfacespeedvs
direction)atADCP2
Current rose plot (mid depth speed
vs direction) atADCP 2
Current rose plot (near bottom speed
vs direction) at ADCP 2
ADCP No Location Depth wrtCD
(m)
Location 01
76°11.164’E
22°12.935’N 15.9
Location 02
76°12.706’E
22°11.221’N
7.9
Velocity and Current direction of water flow at
the surface, at half of the water depth, and 0.5
m above the reservoir bed for fifteen days
upstream

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Simulation of water velocity
HEC-RAS5.0.3,byUSArmyofCorpsofEngineers(USACE)developedattheHydrologicEngineeringCenterwasusedforconductingthevelocity
simulationstudies.Flowmeshcellsize150X150mu/s,250X250md/swascreated.Damwasintroducedasconnectionbetweentheupstreamand
downstreamflowarea.
23numbersofradialcrestgates,20X18mwereconsidered
Upstreamboundarycondition:Twosimulationscenariosweredone,bykeepingtheupstreamwastersurfaceelevation:
1.WhenthereservoirisatFRL(196.6)
2.WhenthereservoirisatMWL(199.6)
Downstreamboundarycondition:normaldepthof0.01m
Flowsimulationswerecarriedoutfor25,50,75and100%releasesthrough23numbersradialcrestgatesbycontrollingthegateopeningheight.
Flood release scenarios
Simulated velocity (m/sec) for MRL (199.6)Simulated velocity (m/sec) for FRL (196.6)
Max Min Mean Max Min Mean
100% ofMaximum flood discharge (88,000
cusecs)
2.472 0.041 0.513 2.432 0.035 0.415
70%ofMaximum flood
discharge(60,000cusecs)
2.424 0.041 0.525 2.446 0.017 0.426
50%ofMaximum flood discharge
(40,000cusecs)
1.850 0.030 0.370 1.849 0.00 0.369
25%ofMaximum flood
discharge(20,000cusecs)
1.564 0.023 0.342 1.69 0.00 0.314

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Simulated water velocities
100% ofMaximum flood discharge 75% ofMaximum flood discharge
50% ofMaximum flood discharge 25% ofMaximum flood discharge
100% ofMaximum flood discharge 75% ofMaximum flood discharge
50% ofMaximum flood discharge 25% ofMaximum flood discharge
WhenthereservoirisatFRL(196.6) WhenthereservoirisatMWL(199.6)

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Capacity
Packaging –Unit
wise allocation

29
•CapacityoftheReservoir:CalculatingthesurfacearearequirementsperMWFloatingSolar:2Hectares/MWppostremovalofall
obstructions.
-Truecapacity–capacitypostremovalofobstructionsinthereservoirlikeislands,patchesofvegetationetc.
-Postremovalofallobstructions,floatingsolarplots(FSplots)mappedtodiscoverthe'truecapacity’.
•OrientationofPlots:
-CanbeeitherSouthorientedorEast-Westorientedanddependsupongeneration&simulatedanchoring&mooringrequirements.
-Inbothcases,FSplotswouldbeofregularshape(arectangle/square).
•DesignofPlots:
-Industrybestpractice-assembleandinstall5MWACplotswhichconsistoftwoequalsub-plotsof2.5MWAC.
-2.5MWACallowstheuseofexistingBoS(centralinverters,transformersetc.)fromthemarketwithoutcustomisation
-DCcapacityoversizedby40%(forevery2.5MWACsub-plot,theDCarraycapacityis3.5MWp).
-Useof425Wpsolarpanels,whichsavespace.
-Dimensionsof2.5MWACsub-plots-250metresby115Metres.
•BufferbetweenPlots(island):
-Bufferof25Metresbetweentwoplotsof5MWAC(toaccomodatestationkeepingarrangements)
-Provideadequateassemblyandtowingareasforeachpackageandeachplot/sub-plot
To arrive at the capacity and area of the reservoir, the plot sizing has been done based on some standard rules
Reservoir Plotting -Approach

30
Reservoir Plotting -Design
Units
No of Blocks
AC
Capacity
(MW)
5
MW
2.5 MW
A 17 6 100
B 18 4 100
C 20 0 100
D 15 10 100
E 20 0 100
F 20 0 100
Total110 20 600
•Assessed Capacity
is 600 MW (AC)
•Six units of
capacities 100 MW
identified

31
Tourism spot is being developed to promote solar tourism at Gunjari near the Northwestern Half of Unit 1.
Reservoir Plotting -Allocation for upcoming Boat Club

32
Technical
Assessment

33
Technology Options
Advantages
•Low freight cost
•Ability to cope with
environmental forcings
•Evaporative cooling
Disadvantages
•No local manufacturing
•Energy generation –low
tilt
•Scalability
•Suited for off-shore
Typology -Membrane Typology -Modular
Advantages
•High stability
•Ability to cope with env.
forcings& extreme weather
conditions
•Ease of O&M
Disadvantages
•No local manufacturing
•Higher Cost
Typology -Hybrid
Advantages
•High stability
•Ability to cope with env.
forcing
•Ease of O&M
Disadvantages
•No local manufacturing
•Higher Cost
Typology –Pure Float
Advantages
•Scalability
•Most popular in India
•Local manufacturing
available
•Relatively lower Cost
Disadvantages
•Ability to cope with env.
factors
•High freight costs
•Anchoring only from
periphery
For RfP, all the technology options will be open. For the purpose of cost estimation, Pure Float technology has been considered.

34
Secondary mooring line
Primary mooring line
Buoy
Anchor (fixed type)
Load considered per primary
mooring line ~ 12.5 MT
N
General representation of Pure Float system

35
HELICAL
ANCHOR PRECURSIVE EARTH
DRIVEN
DRAG ANCHORS
DEAD WEIGHT
Anchor Types
Proposed anchor design
•BH 2 to BH 6: Dead weight anchor applicable if force is within 1.5-2.5 MT
•Remaining Bore holes: Helical/ PercursiveAnchors applicable for force in excess of 2.5
MT
The design of anchors would depend
on
-Bearing capacity of the soil
(Survey results)
-Force exerted on anchor
(Simulation studies)

36
Mooring systems
WEIGHT
MOORI
NG
CHAIN
EYE
BOL
T
ANCHO
R
BUOY
High High
High High
High Medium
Low
High Medium
Chain
Wire
High Molecular
Weigh Polyethylene
Mooring Lines
Nylon
Polyester
Damage
Resistance
Fatigue
Resistance
StrengthWeight
Material
stiffness
High High
High
Low
Low
Low
Low
Low
Low
Medium Medium
Medium Medium
Medium
Medium
Medium
Types of mooring lines
•Chainbasedmooringsystemareconsideredrobustbutaresusceptibleto
corrosionandwear
•Wirebasedmooringlinesmaybeprotectedfromcorrosion(grease/
cathodicprotection)butcangetdamagedduetocontact/bending
•Aramid/HMPE basedmooringlinesaresusceptibletocompressionfatigue
•Nylonropebasedmooringlines,dependentonconstruction,maybe
fatigueresistant
•Polyesterbasedmooringlinesareconsideredtoberelativelydurable
•All the options are available
•Combination of Chain and Polyester Rope to be considered

37
Technical Standards
PV Modules
•Terrestrial photovoltaic (PV)
modules –design
qualification (IEC 61215)
•Degrees of protection -IP
Codes (IEC 60529)
•Salt mist corrosion testing of
modules (IEC 61701)
•Junction boxes for PV
modules –safety
requirements & tests (IEC
62790)
•Photovoltaic (PV) module
safety qualification (IEC
61730)
•Ammonia corrosion testing
(IEC 62716)
•Photovoltaic modules –cyclic
(dynamic) mechanical load
testing (IEC 62782)
•PV modules transportation
testing (IEC 62759)
•Test methods for detection of
Potential Induced
Degradation (IEC 62804 –1)
•Light induced degradation
test (IEC 63202)
Flotation devices (General and
environment)
•Standards for floating wind turbine
structures (DNV GL-ST-0119)
•Standards for tidal turbines (DNV
GL-ST-0164)
•General principles on reliability for
structures (ISO 2394)
•Recommended practice for design,
development and operation of
floating solar photovoltaic systems
(DNV GL RP 0584)
•Code of practice for design loads
(other than earthquake) for
buildings and structures (IS 875)
•Criteria for Earthquake resistant
design of structures (IS 1893)
•Minimum design loads and
associated criteria for buildings
and other structures (ASCE 7)
Recommended practice for design
against accidental loads (DNV GL-
RP-C204)
•Recommended Practice for
Environmental conditions and
Environmental loads (DNV GL-RP-
C205)
Flotation devices
(Structural Design)
•Plain and reinforced
concrete –code of
practice (IS 456)
•General construction in
steel –code of practice
(IS 800)
•Code of practice for the
use of cold-formed
Light Gauge Steel
structural members in
general building
construction (IS 801)
•Code of practice for
use of aluminum alloys
in structures (IS 8147)
•Structural plastics
design manual (ASCE
Manual)
•Composite components
(DNVGL-ST-C501)
Flotation devices
(Anchoring &
Moorings)
•Design and analysis of
station-keeping
systems for floating
structures (API RP
2SK)
•Specification for
mooring chain (API
Spec 2F)
•In-service inspection
of mooring hardware
for floating structures
(API RP 2I)
•Mooring integrity
management (API RP
2MIM)
•Design of inshore
moorings and floating
structures (BS 6349-
6)
•DNV Standards
Inverters
•Standard for interconnecting
distributed resources with electrical
power systems (IEEE 1547)
•Low-voltage switchgear and control
gear assemblies (IEC 61439-1 & 2)
•Safety of power connectors for use
in PV power systems (IEC 62109-1 &
2)
•Utility interconnected PV inverters –
test procedures for islanding
prevention measures (IEC 62116)
•Procedure for measuring efficiency
(IEC 61683)
•Electromagnetic compatibility (EMC)
(IEC 61000-6-2 & 4)
•Safety requirements for power
electronic converter system and
equipment (IEC 62477)
•Characteristics of utility interface
(IEC 61727)
•BoScomponents for PV Systems
(IEC 62093)
•PV power generating systems –EMC
requirements and test methods for
power conversion equipment (IEC
62920)
•No relevant Indian standard that covers the design of plastics such as HDPE
•In case of plastic -based flotation device, factor of safety may be adopted using principles outlined in Plastic design manual by ASCE and ISO 2394
•Wind tunnel testing in an atmospheric boundary layer wind tunnel is recommended
•The standards available for plastics are not specific to design of flotation devices
•UV testing for a minimum of 2000 h is recommended, with the change in physical less than 5% of the initial value after test.

38
Resource
Assessment

39
Approach
Resource Assessment & Annual Energy Yield Estimation
Solar Radiation Resource Assessment & Energy Yield
Estimation
Conversion to
typical Metrology
Year (TMY) data
format
Optimize
representative
database for energy
yield estimation
Intensity distribution
pattern of global &
diffuse irradiance
Assessment of solar
irradiance and
metrological data
Satellite Data
NASA SSE Data
Time Series Data
Meteonorm 7.2
PV Syst (Dynamic)
simulation
Site Characteristics
•Optimum tilt
•Site Azimuth
•Ambient Temp.
•Wind velocity
Solar Resource
Solar irradiance over
solar PV module under
selected design
approach
Results -Energy Yield , CUF , Performance Ratio
Energy Yield
Estimation
Define solar
PV module &
inverter
Define technical
losses (electrical,
system & optical)
Solar PV
system size
optimization
Parameters Resource Assessment
GHI NASA, Meteonorm7.2
Meteorological data
(Wind speed,
Temperature)
NASA, Meteonorm7.2
Yield Assessment
PV system capacity 600 MW AC
Modules Simulated Tier 1 -445 Wp Mono-PERCmodule
Inverter Type Tier 1 -2500 kVA Inverter
Orientation
Two scenarios for placement of panels has been
considered:
•Panels oriented Due South
•Panels oriented east-west
Angle of Inclination
Two Options with scenarios have been evaluated
•Due South: 10°(Scenarios: 8°,9°,11°and 12°)
•East-West: 10°(Scenarios: 8°,9°,11°and 12°)
DC:AC DC to AC ratio taken as 1:4 for PV Systsimulation
Losses
•Water Surface Albedo: Between 0.06-0.1
•Soiling Loss: 1.5% to 3%; LID:2%;
•Module Mismatch loss: 1.1%;
•Thermal loss factor: 0.4%

40
Average Global Horizontal Irradiance (GH) –Omkareshwar Site
4.63
5.38
6.18
6.65 6.66
5.51
4.27
3.79
4.71
5.23
4.71
4.33
4.76
5.63
6.43
6.86
6.96
5.74
4.19 4.11
5.17
5.69
4.86
4.45
5.17
5.40
0.00
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
GHI (kWh/sq m/day) –NASA Data
Meteonorm Av - NASA Av - Meteonorm
•High solar irradiance, Average Annual GHI is in 1,870 –1,971 kWh/sqm
-NASA data is satellite based monthly averaged daily data based gathered for 22 years on 100X100 spatial resolution: 1.71
(kWh/sq.m/day)
-Meteonorm data is interpolated on ground and satellite-based data which is available in monthly form for 29 years: 2
(kWh/sq.m/day)

41
Average daily GHI across 12 months-Omkareshwar site
Source: Meteonorm

42
Temperature & wind speed
20.50
23.30
28.70
32.50
33.20
29.70
26.60
25.90
26.70 26.30
23.70
20.70
18.80
21.60
26.80
30.80
32.70
29.40
26.30
25.00 25.40 25.60
22.40
20.00
26.50
25.40
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
Ambient Temperature (
O
C)
NASA Meteonorm Av - NASA Av - Meteonorm
3.15
3.40 3.32 3.35
3.77
4.14
3.63
3.33
2.67
2.08 2.19
2.65
2.50
2.90
3.50
4.10
5.50
5.70
5.40
4.50
3.30
2.20
1.80
2.00
3.14
3.60
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
Average Wind Speed (m/s)
NASA-at 10m Meteonorm at less than 10m Av - NASA Av - Meteonorm
•Annual average
ambient
temperature
range25.40°C-
26.50°C
•Annual average
windspeedasper
NASAat10m
heightis3.14m/s
and3.60m/sas
perMeteonorm
•Temperatureand
windspeedfeeds
inPVSystfor
energy yield
estimation

43
Orientation and tilt angle of solar PV Modules
Due South
orientation
East-West
orientation

44
CUF and Energy Yield Estimation
Annual Energy Yield Estimation
•Energy Yield assessment for the East-West configuration is comparable with yield for the Due South configuration
•Simulation studies to determine the cost differential between two scenarios
Resource Parameter North-South East-West
Albedo 0.06 0.06 0.06 0.06 0.06 0.06 0.06 0.06 0.06 0.06
Module tilt 10° 8° 9° 11° 12° 10° 8° 9° 11° 12°
AC Capacity MW 600 600 600 600 600 600 600 600 600 600
Annual Generation (GWh) -P50 1,2921,2751,2811,291 1,290 1,274 1,286 1,284 1,277 1,274
Annual Generation (GWh) -P75 1,2651,2491,2541,264 1,268 1,247 1,259 1,257 1,250 1,248
Annual Generation (GWh) -P90 1,2401,2251,2301,240 1,244 1,223 1,235 1,233 1,226 1,224
Annual Generation (GWh) -P99 1,1991,1841,1891,198 1,202 1,182 1,193 1,192 1,185 1,183
PR % 77.6577.3577.3477.31 77.29 79.24 78.57 78.58 78.64 78.65
CUF –P50 (AC Capacity) 24.58%24.27%24.38%24.57%24.55% 24.24%24.47%24.44%24.30% 24.25%
CUF -P75 (AC Capacity) 24.07%23.77%23.87%24.06% 24.14% 23.74%23.96%23.93%23.79% 23.75%
CUF -P90 (AC Capacity) 23.61%23.31%23.42%23.60% 23.68% 23.28%23.50%23.47%23.34% 23.29%
CUF -P99 (AC Capacity 22.82%22.53%22.63%22.81%22.89% 22.50%22.71%22.68%22.55% 22.51%

45
Evacuation
Infrastructure &
Metering Arrangement

46
Floating Solar Power Flow from the Park to the Off takers
Floating Solar
PV Park Site
220 kV Tx Lines
STU/ CTU
Substation
Grid Connectivity
Power
Procurer
Power
Procurer
Power
Procurer
33 kV Tx Lines
33/ 220 kV
Substation

47
Proposed Connectivity
Evacuation Infrastructure
SPD
(Developer)
System
SPPD
(RUMSL)
System
STU/ CTU
System
•Beneficiaries:
-Off-take within MP : 400 MW
-Outside the state: 200 MW (proposed)
•Evacuation Options
-MPPTCL System: Khandwa 220 kV S/S
-PGCIL System: Khandwa 400 kV S/S
•Sub-stations (2 Nos)
-33/220 kV S/S at Chitramod
-33/220 kV S/S at Saktapur
-6x110 MVA transformation capacity
•Transmission System (2 Tr Lines)
-Chitramod –Khandwa 220 kV D/C T/L
-Saktapur –Khandwa 220 kV D/C T/L
Key Highlights
33 kV bus bar
100 MW 100 MW 100 MW 100 MW 100 MW 100 MW
220 kV
33/220 kV
Chitramod S/S
110 MVA Tr
110 MVA Tr
110 MVA Tr
220 kV
33/220 kV
Saktapur S/S
110 MVA Tr
110 MVA Tr
110 MVA Tr
220 kV D/C
Line
220 kV D/C
Line
400 kV Khandwa Bus
220 kV Khandwa Bus

48
Sub-station Location map
Omkareshwar Floating Solar Project
Evacuation Plan for 600 MW
The power generated by proposed 6
packages will be evacuated through 33
kV lines/ cables to two 33/220 kV
substations.
•Substation 1: Saktapur (33/220
kV) for evacuating power from
packages D, E & F (300 MW)
•Evacuation Substation 2:
Chitramod (33/220 kV) for
evacuating power from packages A,
B & C (300 MW)
GPS (In Degrees Minutes Seconds)
Location GPS (N) GPS (E)
Saktapur 22
0
11'34.5''76
0
15'21.3''
Chitramod 22
0
12'24.2''76
0
06'27.5''
Saktapur
22
0
11'34.5‘’
North
76
0
15'21.3‘’
East
Chitramod
22
0
12'24.2’’
North
76
0
06'27.5‘’
East

49
Evacuation Infrastructure : Overall Layout of the Floating Solar Park at Omkareshwar
Unit B
Unit C
Unit D
Unit E
Unit A
Unit F
5 MW x 17 + 2.5MW x 6 AC Plots
5 MW x 18 + 2.5MW x 4 AC Plots
5 MW x 20 AC Plots
5 MW x 15 + 2.5MW x 10 AC Plots
5 MW x 20 AC Plots
5 MW x 20 AC Plots
33 kV
33 kV
33/220 kV
Chitramod
Substation
33/220 kV
Saktapur
Substation
220/400 kV Khandwa
Substation
ISTS Customer
(200 MW
equivalent
energy)
MPPMCL
(400 MW
equivalent
energy)
Solar Power Developers Jurisdiction
Solar Park Developers
Jurisdiction(RUMSL)

50
Chitramod S/S Saktapur S/S
Khandwa PGCIL S/S
Proposed Route Map for 220 kV Transmission Line

51
Road Infrastructure,
Assembly Areas &
Launch Sites

52
Road Infrastructure
Totalof2Nos.siteshavebeenidentifiedforconstructionof33/220KVSub-Stations
33/220 KV Sub-Stations
SaktapurSite
•ToevacuatepowerfromUnitsD,EandF.
•Singlelaneroadalreadyexists,roadinfrastructurewillbe
widenedandstrengthenedbyRUMSL
ChitramodSite
•ToevacuatepowerfromUnitsA,BandC.
•Singlelaneroadalreadyexists,roadinfrastructure
willbewidenedandstrengthenedbyRUMSL

53
Road Infrastructure
Totalof4sites(Gunjari,Bilaya,Indhawadi&Saktapur)havebeenidentifiedforassemblyandlaunchingofsolarmodules.
A. Gunjari
•ToassemblefloatersandsolarPVmodulesforUnitA.
•Roadtobeconstructedfromnearestvillagetothe
assembly/launchsite.
B. Bilaya
•ToassemblefloatersandsolarPVmodulesfromUnits
B,C,andF.
•Singlelaneroadalreadyexists,roadinfrastructure
willbewidenedandstrengthenedbyRUMSL
Assembly Areas and launch sites

54
Road Infrastructure
C. Indhawadi
•ToassemblefloatersandsolarPVmodulesforUnitD.
•Singlelaneroadalreadyexists,roadinfrastructurewillbe
widenedandstrengthenedbyRUMSL
D. Saktapur
•ToassemblefloatersandsolarPVmodulesfromUnitsD.
•Singlelaneroadalreadyexists,roadinfrastructurewillbe
widenedandstrengthenedbyRUMSL
Assembly Areas and launch sites

55
Transaction Features

56
FSPV Project
Developer
Site Specific
Project Off Taker
•NHDC
•NVDA
Developer
RUMSL
•MPPTCL
•PGCIL
Park Operator
Evacuation
•Government of
Madhya Pradesh
•MOP/ MNRE
EPC
Financing
Institution
•MPERC
•CERC
Regulatory
Policy
•MPPMCL
•Inter-state Off
taker (s)
Power Purchase
Agreement (PPA)
Implementation Service and
Connectivity Agreements
Connectivity
Agreement
Coordination Agreement
Upfront and Operating (incl
Lease) charges
Tariff
CTU/ STU Tariff
Lease Charges
Commercial Arrangements
Transaction Structure ……1
Coordination/ Approvals
Commercial Arrangement
Payment
Coordination
Agreement
Lease
Agreement

57
Key Contracts
PPA Main WUPA/ LUPA Unit WUPA/ LUPA ISA
SPD
(Project developer)
Power procurer
(MPPMCL & ….. )
•Unit-wise PPAs
•Each procurer to
have separate PPA
GoMP
(NVDA, NRE Dept)
SPPD
(RUMSL)
SPPD
(RUMSL)
SPD
(Project Developer)
•Unit-wise LUPA
•Each UnitLUPA to
have above three
parties
SPDs
(Project developers)
Power procurers
(MPPMCL & …..)
•Park wise CA amongst
above parties
•Meant for proper
coordination from PPA
signing to project life on
all techno-commercial
matters
SPPD
(RUMSL)
SPD
(Project developer)
CA
SPPD
(RUMSL)
•Unit-wise ISA
•Primarily to deal with
evacuation
infrastructure related
issue
•Park-wise main
WUPA/ LUPA
•RTU / access is
provided to SPPD
(RUMSL) from
Revenue Dept.,
through NVDA, NRE
Dept., GoMP
WUPA: water use permission agreement LUPA: land use permission agreement; ISA: implementation support agreement;
CA: coordination agreement
Transaction Structure ……2
SPPD
(RUMSL)
GoMP
(NVDA, NRE Dept)

58
Roles & responsibilities of Solar Power Park Developer (SPPD) & Solar Project
Developer (SPD)
Essential Responsibilities
•Providing necessary land and water bodies for project
•Developing approach road, water and drainage etc.
•Developing internal infrastructure system, including power evacuation system
•Identify procurers and develop necessary Project Agreements
Responsibilities of SPPD
Essential Responsibilities
•Erection, Procurement and Commissioning of project
•To maintain environment and social safeguards
•Right of Access to SPPD
•Connect to the evacuation infrastructure developed by SPPD
•Insurance of the project and related structure
•To maintain necessary approval for creating and maintaining project
Responsibilities of SPD

59
(Bid Process timelines)
Key Timelines
Sl. Activity Date Remarks
1 Release of Draft RFP, IM and preliminary data (Data Room) 2
nd
Nov. 2021 Bidders shall have access to RFP and
information in data room after online
registration
2 Facilitated Site Visit (1 day) 16
th
Nov. 2021 Site visit to be arranged by RUMSL
3 1
st
Pre-bid Meeting 22
nd
Nov. 2021 Pre-bid meeting (Virtual / @Bhopal)
Last date of query submission by Bidders on RFP* 25
th
Nov. 2021
4 Issuance of revised RFP and draft Project Agreements 3
rd
Dec. 2021 To be uploaded in Data Room
5 2
nd
Pre-bid Meeting 20
th
Dec. 2021 Pre-bid meeting (Virtual / @Bhopal)
Last date for query submission by Bidders on Project
Agreements
22
nd
Dec. 2021
6 Issuance of Preliminary Envt. Screening Report 30
th
Dec. 2021 To be uploaded in Data Room
7 Issuance of final RFP and Project Agreements 30
th
Dec. 2021 All information including Draft ESIA Report
8 Issuance of Final ESIA Report 25
th
Jan 2022 To be uploaded in Data Room
9 Submission of Bids 31
st
Jan 2022 Online Technical and Financial Bid submission
10Opening of Technical Bids 1
st
Feb. 2022 Virtual Opening
11Evaluation of Technical Bids 15
th
Feb. 2022 Including clarifications from Bidders
12Evaluation of Financial Bids (for technically qualified Bidders) 20
th
Feb. 2022 After presentation to Bid Evaluation Committee
13Reverse Auction & Selection of Successful Bidder for respective
Package
25
th
Feb. 2022 To be informed to the Selected Bidders
separately
14Signing of PPA and Project Agreements 1
st
March 2022 To be informed to the Selected Bidders
separately

60
Thank You!

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